01 Receiving Delta_IA MDS_VFD C2000_UM_EN_20140826 Delta IA MDS VFD C2000 UM EN 20140826

User Manual: Delta_IA-MDS_VFD-C2000_UM_EN_20140826

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Delta Classical Field Oriented Control AC Motor Drive C2000 Series User Manual

201408

Delta Classical Field Oriented
Control AC Motor Drive
C2000 Series User Manual

PLEASE READ PRIOR TO INSTALLATION FOR SAFETY.
 AC input power must be disconnected before any wiring to the AC motor drive is made.
 Even if the power has been turned off, a charge may still remain in the DC-link
DANGER

capacitors with hazardous voltages before the POWER LED is OFF. Please do not
touch the internal circuit and components.
 There are highly sensitive MOS components on the printed circuit boards. These
components are especially sensitive to static electricity. Please do not touch these
components or the circuit boards before taking anti-static measures. Never reassemble
internal components or wiring.
 Ground the AC motor drive using the ground terminal. The grounding method must
comply with the laws of the country where the AC motor drive is to be installed.
 DO NOT install the AC motor drive in a place subjected to high temperature, direct
sunlight and inflammables.
 Never connect the AC motor drive output terminals U/T1, V/T2 and W/T3 directly to the

CAU TION

AC mains circuit power supply.
 Only qualified persons are allowed to install, wire and maintain the AC motor drives.
 Even if the 3-phase AC motor is stop, a charge may still remain in the main circuit
terminals of the AC motor drive with hazardous voltages.
 If the AC motor drive is stored in no charge condition for more than 3 months, the
ambient temperature should not be higher than 30 °C. Storage longer than one year is
not recommended, it could result in the degradation of the electrolytic capacitors.
 Pay attention to the following when transporting and installing this package (including
wooden crate, wood stave and carton box)
1.

If you need to sterilize, deform the wooden crate or carton box, please do not
use steamed smoking sterilization or you will damage the VFD.

2.

Please use other ways to sterilize or deform.

3.

You may use high temperature to sterilize or deform. Leave the packaging
materials in an environment of over 56℃ for 30 minutes.

4.

It is strictly forbidden to use steamed smoking sterilization.

The warranty does

not covered VFD damaged by steamed smoking sterilization.
NOTE

The content of this manual may be revised without prior notice. Please consult our distributors or download the most updated
version at http://www.delta.com.tw/industrialautomation

I

Table of Contents
CHAPTER 1 INTRODUCTION ..................................................................................................................1-1
1-1 Receiving and Inspection..................................................................................................1-1
1-2 Nameplate Information.....................................................................................................1-1
1-3 Model Name....................................................................................................................1-2
1-4 Serial Number.................................................................................................................1-2
1-5 RFI Jumper.....................................................................................................................1-3
1-6 Dimensions.....................................................................................................................1-7
CHAPTER 2 INSTALLATION ..................................................................................................................2-1
2-1 Minimum Mounting Clearance and Installation......................................................................2-1
2-2 Minimum mounting clearance.............................................................................................2-2
CHAPTER 3 UNPACKING ........................................................................................................................3-1
3-1 Unpacking.........................................................................................................................3-1
3-2 The Lifting Hook..............................................................................................................3-13
CHAPTER 4 WIRING ................................................................................................................................4-1
4-1 Wiring...............................................................................................................................4-1
4-2 System Wiring Diagram.....................................................................................................4-6
CHAPTER 5 MAIN CIRCUIT TERMINALS .............................................................................................5-1
5-1 Main Circuit Diagram.........................................................................................................5-1
5-2 Main Circuit Terminals.......................................................................................................5-5
CHPATER 6 CONTROL TERMINALS ......................................................................................................6-1
6-1 Specifications of Control Terminal........................................................................................6-3
6-2 Analog input terminals (AVI, ACI, AUI, ACM) .......................................................................6-5
6-3 Remove the Terminal Block................................................................................................6-7
CHAPTER 7 OPTIONAL ACCESSORIES .............................................................................................7-1
7-1 All Brake Resistors and Brake Units Used in AC Motor Drives................................................7-2
7-2 Non-fuse Circuit Breaker....................................................................................................7-5
7-3 Fuse Specification Chart ....................................................................................................7-6
7-4 AC/DC Reactor..................................................................................................................7-7
7-5 Zero Phase Reactor.........................................................................................................7-10
7-6 EMI Filter........................................................................................................................7-12
7-7 Digital Keypad.................................................................................................................7-16
7-8 Panel Mounting...............................................................................................................7-19
7-9 Conduit Box Kit...............................................................................................................7-21
7-10 Fan Kit.........................................................................................................................7-29
II

7-11 Flange Mounting Kit ......................................................................................................7-42
7-12 USB/RS-485 Communication Interface IFD6530…........................................................7-55
CHAPTER 8 OPTION CARDS ..................................................................................................................8-1
8-1 Removed key cover...........................................................................................................8-2
8-2 Screws Specification for option card terminals.....................................................................8-5
8-3 EMC-D42A......................................................................................................................8-10
8-4 EMC-D611A....................................................................................................................8-10
8-5 EMC-R6AA.....................................................................................................................8-10
8-6 EMC-BPS01....................................................................................................................8-11
8-7 EMC-PG01/02L...............................................................................................................8-12
8-8 EMC-PG01/02O..............................................................................................................8-15
8-9 EMC-PG01/02U...............................................................................................................8-18
8-10 EMC-PG01R.................................................................................................................8-20
8-11 CMC-MOD01.................................................................................................................8-22
8-12 CMC-PD01....................................................................................................................8-26
8-13 CMC-DN01....................................................................................................................8-28
8-14 CMC-EIP01...................................................................................................................8-31
8-15 EMC-COP01.................................................................................................................8-36
CHAPTER 9 SPECIFICATION ..................................................................................................................9-1
9-1 230V Series…………………………………...........................................................................9-1
9-2 460V Series…………………………………...........................................................................9-2
9-3 Environment for Operation, Storage and Transportation………………………….......................9-4
9-4 Specification for Operation Temperature and Protection Level…….........................................9-5
9-5 Derating of ambient tempeture and altitude…………………….……........................................9-6
CHAPTER 10 DIGITAL KEYPAD ...........................................................................................................10-1
10-1 Descriptions of Digital Keypad ………………………………….............................................10-2
10-2 Function of Digital Keypad KPC-CC01.............................................................................10-5
10-3 TPEditor Installation Instruction ....................................................................................10-23
10-4 Fault Code Description of Digital Keypad KPC-CC01.......................................................10-36
CHAPTER 11 SUMMARPY OF PARAMETERS ..................................................................................... 11-1
CHAPTER 12 DESCRIPTION OF PARAMETER SETTINGS ................................................................12-1
CHAPTER 13 WARNING CODES ..........................................................................................................13-1
CHAPTER 14 FAULT CODES AND DESCRIPTIONS............................................................................14-1
CHAPTER 15 CANOPEN OVERVIEW ...................................................................................................15-1
CHAPTER 16 PLC FUNCTION ..............................................................................................................16-1
CHAPTER 17 HOW TO SELECT THE RIGHT AC MOTOR DIRVE .......................................................17-1
III

CHAPTER 18 SUGGESTIONS AND ERROR CORRECTIONS FOR STANDARD AC MOTOR DRIVES
.................................................................................................................................................................18-1
CHAPTER 19 EMC STANDARD INSTALLATION GUIDE………………………………………………….19-1
CHAPTER 20 SAFETY TORQUE OFF FUNCTION………………………………………………………….20-1
APPENENDIX A. PUBLICATION HISTORY…………………………………………………………………..A-1

Application

Control BD V1.20;
Keypad
V1.04;

IV

Chapter 1 IntroductionC2000 Series

Chapter 1 Introduction
1-1 Receiving and Inspection
After receiving the AC motor drive, please check for the following:
1.

Please inspect the unit after unpacking to assure it was not damaged during shipment. Make sure that
the part number printed on the package corresponds with the part number indicated on the
nameplate.

2.

Make sure that the voltage for the wiring lie within the range as indicated on the nameplate. Please
install the AC motor drive according to this manual.

3.

Before applying the power, please make sure that all the devices, including power, motor, control
board and digital keypad, are connected correctly.

4.

When wiring the AC motor drive, please make sure that the wiring of input terminals “R/L1, S/L2, T/L3”
and output terminals”U/T1, V/T2, W/T3” are correct to prevent drive damage.

5.

When power is applied, select the language and set parameter groups via the digital keypad
(KPC-CC01). When executes trial run, please begin with a low speed and then gradually increases
the speed untill the desired speed is reached.

1-2 Nameplate Information
AC Driv e Model
Input Volt age/Current
Output Voltage/Current

MODE L:VFD0 07 C43 A
INPUT:
Nor mal D uty: 3 PH 3 80 -4 80 V 5 0/6 0Hz 4 .3A
Hea vy D uty: 3 PH 3 80 -4 80 V 5 0/6 0Hz 4 .1A

OUTPUT:
Nor mal D uty: 3 PH 0 -4 80 V 3 A 2 .4 KVA 1 HP
Hea vy D uty: 3 PH 0 -4 80 V 2 .9A 2 .3K VA 1 HP

Frequency Range
Firmware Version

FREQUENCY RANGE:
Normal Duty: 0-600Hz
Heavy Dut y: 0-300Hz
Ver si on: VX.XX

Cert ifications
Enclosure type (IPXX)
007C43A7T14300002

Serial Number

DELTA ELECTRONICS. INC.
MADE IN XXXXXXX

1-1

Chapter 1 IntroductionC2000 Series

1-3 Model Name

VFD 007 C 43 A
Ve rs io n ty p e
A: Wall mounted
S: Same capacity but miniaturized
(conduit box included)
U: Same capacity but miniaturized
In p u t v o lta g e
23:230V 3-PHASE
43:460V 3-PHASE
C2 0 0 0 se rie s
A p p lic a b le mo to r c a p a c ity
0 0 7 :1 HP(0 .7 5 k W )~ 4 5 0 0 :6 0 0 HP(4 5 0 kW )
Re fe r to th e s p e c ifica tio n s fo r d e ta ils
S e rie s n a me (Va ria b le F re q u e n c y Driv e )

1-4 Serial Number

007C43A T 1 4 3 0 0002
Prod uction n umber
Produ cti on we ek
T: Ta uyuan W: W uji an
S: S han gha i
460 V 3-PHASE 1 H P(0.7 5kW)

1-2

Pro ductio n ye ar
Produ cti on factory
Mod el nu mb er

Chapter 1 IntroductionC2000 Series

1-5 RFI Jumper
RFI Jumper: The AC motor drive may emit the electrical noise. The RFI jumper is used to suppress the
interference (Radio Frequency Interference) on the power line.

Frame A~C
Screw Torque: 8~10kg-cm(6.9-8.7 lb -in.)
Loosen the screws and remove the MOV-PLATE. Fasten the screws back to the original position after
MOV-PLATE is removed.

1-3

Chapter 1 IntroductionC2000 Series

Frame D0~H
Remove the MOV-PLATE by hands, no screws need to be loosen.

Isolating main power from ground:
When the power distribution system of the Power Regenerative Unit is a floating ground system (IT) or an
asymmetric ground system (TN), the RFI short short-circuit cable must be cut off. Cutting off the
short-circuit cable cuts off the internal RFI capacitor (filter capacitor) between the system's frame and the
central circuits to avoid damaging the central circuits and (according to IEC 61800-3) reduce the ground
leakage current.
Important points regarding ground connection
 To ensure the safety of personnel, proper operation, and to reduce electromagnetic radiation, the
Power Regenerative Unit must be properly grounded during installation.
 The diameter of the cables must meet the size specified by safety regulations.
 The shielded cable must be connected to the ground of the Power Regenerative Unit to meet safety
regulations.
 The shielded cable can only be used as the ground for equipment when the aforementioned points are
met.
 When installing multiple sets of Power Regenerative Units, do not connect the grounds of the Power
Regenerative Units in series. As shown below
Ground terminal

Best wiring setup for ground wires

1-4

Chapter 1 IntroductionC2000 Series

Pay particular attention to the following points:
 After turning on the main power, do not cut the RFI short-circuit cable while the power is on.
 Make sure the main power is turned off before cutting the RFI short-circuit cable.
 Cutting the RFI short-circuit cable will also cut off the conductivity of the capacitor. Gap discharge may
occur once the transient voltage exceeds 1000V.
If the RFI short-circuit cable is cut, there will no longer be reliable electrical isolation. In other words, all
controlled input and outputs can only be seen as low-voltage terminals with basic electrical isolation. Also,
when the internal RFI capacitor is cut off, the Power Regenerative Unit will no longer be electromagnetic
compatible.
 The RFI short-circuit cable may not be cut off if the main power is a grounded power system.
 The RFI short-circuit cable may not be cut off while conducting high voltage tests. When conducting a
high voltage test to the entire facility, the main power and the motor must be disconnected if leakage
current is too high.
Floating Ground System(IT Systems)
A floating ground system is also called IT system, ungrounded system, or high impedance/resistance
(greater than 30Ω) grounding system.


Disconnect the ground cable from the internal EMC filter.



In situations where EMC is required, check whether there is excess electromagnetic radiation affecting
nearby low-voltage circuits. In some situations, the adapter and cable naturally provide enough
suppression. If in doubt, install an extra electrostatic shielded cable on the power supply side between
the main circuit and the control terminals to increase security.



Do not install an external RFI/EMC filter, the EMC filter will pass through a filter capacitor, thus
connecting power input to ground. This is very dangerous and can easily damage the Power
Regenerative Unit.

Asymmetric Ground System(Corner Grounded TN Systems)
Caution: Do not cut the RFI short-circuit cable while the input terminal of the Power Regenerative Unit
carries power.
In the following four situations, the RFI short-circuit cable must be cut off. This is to prevent the system
from grounding through the RFI capacitor, damaging the Power Regenerative Unit.
RFI short-circuit cable must be cut off
1 Grounding at a corner in a triangle configuration

L1

2 Grounding at a midpoint in a polygonal
configuration

L1

L2
L2

L3

L3

1-5

Chapter 1 IntroductionC2000 Series

3 Grounding at one end in a single-phase

4 No stable neutral grounding in a three-phase

configuration

autotransformer configuration

L1

L1

L1
L2
L2
L3

N

L3

RFI short-circuit can be used
Internal grounding through RFI capacitor, which reduces

L1

electromagnetic radiation. In a situation with higher
requirements for electromagnetic compatibility, and using a
symmetrical grounding power system, an EMC filter can be
installed. As a reference, the diagram on the right is a
symmetrical grounding power system.

L2
L3

1-6

Chapter 1 IntroductionC2000 Series

1-6 Dimensions
Frame A
VFD007C23A; VFD007C43A/E; VFD015C23A; VFD015C43A/E; VFD022C23A; VFD022C43A/E;
VFD037C23A; VFD037C43A/E; VFD040C43A/E; VFD055C43A/E

Unit: mm [inch]

Frame
A1

W

H

D

W1

H1

D1*

S1

Φ1

Φ2

Φ3

130.0

250.0

170.0

116.0

236.0

45.8

6.2

22.2

34.0

28.0

[5.12]

[9.84]

[6.69]

[4.57]

[9.29]

[1.80]

[0.24]

[0.87]

[1.34]

[1.10]

D1*: Flange mounting

1-7

Chapter 1 IntroductionC2000 Series

Frame B
VFD055C23A; VFD075C23A; VFD075C43A/E; VFD110C23A; VFD110C43A/E; VFD150C43A/E

See Detail A

See Detail B

Detail A (Mounting Hole)

Detail B (Mounting Hole)
Unit: mm [inch]

Frame
B1

W

H

D

W1

H1

D1*

S1

Φ1

Φ2

Φ3

190.0

320.0

190.0

173.0

303.0

77.9

8.5

22.2

34.0

43.8

[7.48]

[12.60]

[7.48]

[6.81]

[11.93]

[3.07]

[0.33]

[0.87]

[1.34]

[1.72]

D1*: Flange mounting

1-8

Chapter 1 IntroductionC2000 Series

Frame C
VFD150C23A; VFD185C23A; VFD185C43A/E; VFD220C23A; VFD220C43A/E; VFD300C43A/E

See Detail A

See Detail B

Detail A (Mounting Hole)

Detail B (Mounting Hole)
Unit: mm [inch]

Frame
C1

W

H

D

W1

H1

D1*

S1

Φ1

Φ2

Φ3

250.0

400.0

210.0

231.0

381.0

92.9

8.5

22.2

34.0

50.0

[9.84]

[15.75]

[8.27]

[9.09]

[15.00]

[3.66]

[0.33]

[0.87]

[1.34]

[1.97]

D1*: Flange mounting

1-9

Chapter 1 IntroductionC2000 Series

Frame D0
D0-1: VFD370C43S; VFD450C43S;

D
W
W1

D1
D2

H3

H1

H2

SEE DETAIL A

S2

SEE DETAIL B

S1

S1

DETAIL A
(MOUNTING HOLE)

DETAIL B
(MOUNTING HOLE)
Unit: mm [inch]

Frame
D0-1

W

H1

D

W1

H2

H3

D1*

D2

S1

S2

280.0

500.0

255.0

235.0

475.0

442.0

94.2

16.0

11.0

18.0

[11.02]

[19.69]

[10.04]

[9.25]

[18.70]

[17.40]

[3.71]

[0.63]

[0.43]

[0.71]

D1*: Flange mounting

1-10

Chapter 1 IntroductionC2000 Series

Frame D0
D0-2: VFD370C43U; VFD450C43U;

D
W
W1

D1
D2

H

H3

H1

H2

SEE DETAIL A

S2

SEE DETAIL B

3

3

2

2

1

1

S1

S1

DETAIL A
(MOUNTING HOLE)

DETAIL B
(MOUNTING HOLE)
Unit: mm [inch]

Frame
D0-2

W

H

D

W1

H1

H2

H3

280.0 614.4 255.0 235.0 500.0 475.0 442.0

D1*

D2

S1

S2

Φ1

Φ2

Φ3

94.2

16.0

11.0

18.0

62.7

34.0

22.0

[11.02] [24.19] [10.04] [9.25] [19.69] [18.70] [17.40] [3.71] [0.63] [0.43] [0.71] [2.47] [1.34] [0.87]
D1*: Flange mounting

1-11

Chapter 1 IntroductionC2000 Series

Frame D
D1: VFD300C23A; VFD370C23A; VFD550C43A; VFD750C43A
D
W
W1

D1
D2

H3

H1

H2

SEE DETAIL A

S2
SEE DETAIL B

S1

S1

DETAIL A
(MOUNTING HOLE)

DETAIL B
(MOUNTING HOLE)

Unit: mm [inch]
Frame
D1

W

H

D

W1

H1

H2

H3

D1*

D2

S1

S2

330.0

-

275.0

285.0

550.0

525.0

492.0

107.2

16.0

11.0

18.0

[10.83] [11.22] [21.65] [20.67] [19.37] [4.22]

[0.63]

[0.43]

[0.71]

[12.99]

Φ1

Φ2

Φ3

-

-

-

D1*: Flange mounting

1-12

Chapter 1 IntroductionC2000 Series

Frame D
D2: VFD300C23E; VFD370C23E; VFD550C43E; VFD750C43E
D
W
W1

D1

H3

H1

D2

H

H2

SEE DETAIL A

S2

SEE DETAIL B

1

1

3

3

2

2

S1

S1

DETAIL A
(MOUNTING HOLE)

DETAIL B
(MOUNTING HOLE)

Unit: mm [inch]
Frame
D2

W

H

D

W1

H1

H2

H3

D1*

D2

S1

S2

Φ1

Φ2

Φ3

330.0

688.3

275.0

285.0

550.0

525.0

492.0

107.2

16.0

11.0

18.0

76.2

34.0

22.0

[12.99]

[27.10] [10.83] [11.22] [21.65]

[20.67] [19.37]

[4.22]

[0.63]

[0.43]

[0.71]

[3.00]

[1.34]

[0.87]

D1*: Flange mounting

1-13

Chapter 1 IntroductionC2000 Series

Frame E
E1: VFD450C23A; VFD550C23A; VFD750C23A; VFD900C43A; VFD1100C43A
W

D

W1

H3

H1

H2

D1

Unit: mm [inch]

Frame
E1

W
370.0
[14.57]

H
-

D

W1

300.0 335.0

H1
589

H2

H3

D1*

560.0 528.0 143.0

D2

S1, S2

S3

Ф1

Ф2

Ф3

18.0

13.0

18.0

-

-

-

[11.81] [13.19 [23.19] [22.05] [20.80] [5.63] [0.71] [0.51] [0.71]
D1*: Flange mounting

1-14

Chapter 1 IntroductionC2000 Series

Frame E
E2: VFD450C23E; VFD550C23E; VFD750C23E; VFD900C43E; VFD1100C43E
W

D

W1

H3

H1

?

?
?

?

?

?

?

?

H

H2

D1

Unit: mm [inch]

Frame
E2

W

H

D

W1

370.0 715.8 300.0 335.0

H1
589

H2

H3

D1*

560.0 528.0 143.0

D2

S1, S2

S3

Ф1

Ф2

Ф3

18.0

13.0

18.0

22.0

34.0

92.0

[14.57] [28.18] [11.81] [13.19 [23.19] [22.05] [20.80] [5.63] [0.71] [0.51] [0.71] [0.87] [1.34] [3.62]
D1*: Flange mounting

1-15

Chapter 1 IntroductionC2000 Series

Frame F
F1: VFD900C23A; VFD1320C43A; VFD1600C43A
W
W1

D
D1

H3

H2
H1

See Detail A

See Detail B

S3

D2

S1

S2
Detail A (Mounting Hole)

S1

Detail B (Mounting Hole)

Unit: mm [inch]

Frame

W

H

F1

420.0
[16.54]

-

D

W1

H1

H2

H3

300.0 380.0 800.0 770.0 717.0
[11.81] [14.96] [31.50] [30.32] [28.23]

D1*

D2

S1

S2

S3

124.0
[4.88]

18.0
[0.71]

13.0
[0.51]

25.0
[0.98]

18.0
[0.71]

D1*: Flange mounting

1-16

Chapter 1 IntroductionC2000 Series

Frame F
F2: VFD900C23E; VFD1320C43E; VFD1600C43E
W
W1

D
D1

H3

H

H2
H1

See Detail A

S3

See Detail B

D2

1
3
3
2

2

1

2

2

S1

S2
Detail A (Mounting Hole)

S1

Detail B (Mounting Hole)

Unit: mm [inch]

Frame
F2

W

H

D

W1

H1

H2

H3

420.0 940.0 300.0 380.0 800.0 770.0 717.0
[16.54] [37.00] [11.81] [14.96] [31.50] [30.32] [28.23]

Frame

Ф1

Ф2

Ф3

F2

92.0
[3.62]

35.0
[1.38]

22.0
[0.87]

D1*

D2

S1

S2

S3

124.0
[4.88]

18.0
[0.71]

13.0
[0.51]

25.0
[0.98]

18.0
[0.71]

D1*: Flange mounting

1-17

Chapter 1 IntroductionC2000 Series

Frame G
G1: VFD1850C43A; VFD2200C43A
W

D

H3

H1

H2

W1

S3

Unit: mm [inch]

Frame

W

H

G1

500.0
[19.69]

-

D

W1

H1

H2

H3

S1

397.0 440.0 1000.0 963.0 913.6 13.0
[15.63] [217.32] [39.37] [37.91] [35.97] [0.51]

1-18

S2

S3

Ф1

Ф2

Ф3

26.5
[1.04]

27.0
[1.06]

-

-

-

Chapter 1 IntroductionC2000 Series

Frame G
G2: VFD1850C43E; VFD2200C43E
W

D

H3

H1

H

H2

W1

S3

Unit: mm [inch]

Frame
G2

W

H

D

W1

H1

H2

H3

S1

500.0 1240.2 397.0 440.0 1000.0 963.0 913.6 13.0
[19.69] [48.83] [15.63] [217.32] [39.37] [37.91] [35.97] [0.51]

1-19

S2

S3

Ф1

Ф2

Ф3

26.5
[1.04]

27.0
[1.06]

22.0
[0.87]

34.0
[1.34]

117.5
[4.63]

Chapter 1 IntroductionC2000 Series

Frame H
H1: VFD2800C43A; VFD3150C43A; VFD3550C43A; VFD4500C43A

1-20

Chapter 1 IntroductionC2000 Series

Unit: mm [inch]

Frame
H1

Frame
H1

W
H
D
W1
W2
700.0 1435.0 398.0 630.0 290.0
[27.56] [56.5] [15.67] [24.8] [11.42]
H5
-

D1
45.0
[1.77]

W3

W4

W5

W6

-

-

-

-

D2

D3

D4

D5

D6

-

-

-

-

-

1-21

H1

H2
1346.6
1403.0
[55.24] [53.02]

S1
S2
S3
13.0 26.5 25.0
[0.51] [1.04] [0.98]

H3

H4

-

-

Ф1

Ф2

Ф3

-

-

-

Chapter 1 IntroductionC2000 Series

Frame H
H2: VFD2800C43E-1; VFD3150C43E-1; VFD3550C43E-1

Unit: mm [inch]

Frame
H2

Frame
H2

W
H
D
W1
W2
W3
W4
W5
700.0 1745.0 404.0 630.0 500.0 630.0 760.0 800.0
[27.56] [68.70] [15.91] [24.8] [19.69] [24.8] [29.92] [31.5]
H5
-

W6
-

H1
H2
1729.0 1701.6
[68.07] [66.99]

D1
D2
D3
D4
D5
D6
S1
S2
S3
51.0 38.0 65.0 204.0 68.0 137.0 13.0 26.5 25.0
[2.01] [1.50] [2.56] [8.03] [2.68] [5.39] [0.51] [1.04] [0.98]

1-22

H3

H4

-

-

Φ1

Φ2

Φ3

-

-

-

Chapter 1 IntroductionC2000 Series

Frame H
H3: VFD2800C43E; VFD3150C43E; VFD3550C43E

Unit: mm [inch]

Frame
H3

Frame
H3

W
H
D
W1
W2
W3
W4
W5
700.0 1745.0 404.0 630.0 500.0 630.0 760.0 800.0
[27.56] [68.70] [15.91] [24.8] [19.69] [24.8] [29.92] [31.5]
H5
-

W6
-

H1
H2
1729.0 1701.6
[68.07] [66.99]

H3

H4

-

-

D1
D2
D3
D4
D5
D6
S1
S2
S3
Φ1
Φ2
Φ3
51.0 38.0 65.0 204.0 68.0 137.0 13.0 26.5 25.0 22.0 34.0 117.5
[2.01] [1.50] [2.56] [8.03] [2.68] [5.39] [0.51] [1.04] [0.98] [0.87] [1.34] [4.63]

1-23

Chapter 1 IntroductionC2000 Series

Digital Keypad
KPC-CC01

1-24

Chapter 2 InstallationC2000 Series

Chapter 2 Installation
2-1 Minimum Mounting Clearance and Installation
NOTE

Prevent fiber particles, scraps of paper, shredded wood saw dust, metal particles, etc. from
adhereing to the heat sink

Install the AC motor drive in a metal cabinet. When installing one drive below another one,
use a metal separation between the AC motor drives to prevent mutual heating and to
prevent the risk of fire accident.

Install the AC motor drive in Pollution Degree 2 environments only: normallyl only
nonconductive pollution occurs and temporary conductivity caused by condensation is
expected.
The appearances shown in the following figures are for reference only.


Airflow direction:
(Blue arrow) inflow
(Red arrow) outflow
Single drive installation
Side-by-side horizontal installation(Frame A-C)
(Frame A-H)

Multiple drives, single side-by-side horizontal installation（Frame A~C, G, H）

2-1

Chapter 2 InstallationC2000 Series

Multiple drives, side-by-side installation (Frame D0, D, E, F) Install metal separation between the drives.

Multiple drives side-by-side vertical installation (Frame A~H )
Ta: Frame A~G
Ta*: Frame H
When installing one AC motor drive below another one (top-bottom installation), use a metal separation
between the drives to prevent mutual heating. The temperature measured at the fan’s inflow side must be
lower than the temperature measured at the operation side. If the fan’s inflow temperature is higher, use
a thicker or larger size of metal seperature. Operation temperature is the temperature measured at 50mm
away from the fan’s inflow side. (As shown in the figure below)

2-2 Minimum mounting clearance
Frame

A (mm)

B (mm)

C (mm)

D (mm)

A~C

60

30

10

0

D0~F

100

50

-

0

G

200

100

-

0

H

350

0

0

200 (100, Ta=Ta*=40℃)

VFD007C23A; VFD007C43A/E; VFD015C23A; VFD015C43A/E; VFD022C23A;
VFD022C43A/E; VFD037C23A; VFD037C43A/E; VFD040C43A/E; VFD055C43A/E;
VFD055C23A; VFD75C23A; VFD075C43A/E; VFD110C23A; VFD110C43A/E;
Frame B
VFD150C43A/E;
VFD150C23A; VFD185C23A; VFD185C43A/E; VFD220C23A; VFD220C43A/E;
Frame C
VFD300C43A/E;
Frame D0 VFD370C43S; VFD450C43S; VFD370C43U; VFD450C43U;
Frame D
VFD300C23A/E; VFD370C23A/E; VFD550C43A/E; VFD750C43A/E;
Frame A

2-2

Chapter 2 InstallationC2000 Series

Frame E
Frame F
Frame G
Frame H

VFD450C23A/E; VFD550C23A/E; VFD750C23A/E; VFD900C43A/E; VFD1100C43A/E;
VFD900C23A/E; VFD1320C43A/E; VFD1600C43A/E;
VFD1850C43A; VFD2200C43A; VFD1850C43E; VFD2200C43E;
VFD2800C43A; VFD3150C43A; VFD3550C43A; VFD4500C43A; VFD2800C43E-1;
VFD3150C43E-1; VFD3550C43E-1; VFD4500C43E-1; VFD2800C43E; VFD3150C43E;
VFD3550C43E; VFD4500C43E

NOTE

1. The minimum mounting clearances stated in the table above applies to AC motor drives frame A to D. A drive fails
to follow the minimum mounting clearances may cause the fan to malfunction and heat dissipation problem.

NOT E
※

The mounting clearances stated in the figure is for installing the drive in an
open area. To install the drive in a confined space (such as cabinet or
electric box), please follow the following three rules: (1) Keep the minimum
mounting clearances. (2) Install a ventilation equipment or an air conditioner
to keep surrounding temperature lower than operation temperature. (3)
Refer to parameter setting and set up Pr. 00-16, Pr.00-17, and Pr. 06-55.

※

The following table shows the heat dissipation and the required air
volume when installing a single drive in a confined space. When
installing multiple drives, the required air volume shall be multiplied
by the number the drives.

※

Refer to the chart (Air flow rate for cooling) for ventilation equipment
design and selection.

※

Refer to the chart (Power dissipation) for air conditioner design and
selection.

※

Different control mode will affect the derating. See Pr06-55 for more
information.

※

Ambient temperature derating curve shows the derating status in
different temperature in relation to different protection level.

※

If UL Type 1 models need side by side installation, please remove top
cover of FrameA~C, and please do not install conduit box of Frame D
and above.

Air flow rate for cooling
Flow Rate (cfm)
Model No.
VFD007C23A
VFD015C23A
VFD022C23A
VFD037C23A
VFD055C23A
VFD075C23A
VFD110C23A
VFD150C23A
VFD185C23A
VFD220C23A

External Internal
14
14
10
40
66
58
166
166
166

14
14
14
12
12
12

Total
14
14
10
54
80
73
178
178
178

Flow Rate (m3/hr)
External Internal
24
24
17
68
112
99
282
282
282

24
24
24
20
20
20

2-3

Total
24
24
17
92
136
124
302
302
302

Power dissipation of AC motor
drive
Power Dissipation
Loss External
Internal
Total
(Heat sink)
33
27
61
56
31
88
79
36
115
113
46
159
197
67
264
249
86
335
409
121
529
455
161
616
549
184
733
649
216
865

Chapter 2 InstallationC2000 Series

Air flow rate for cooling
Flow Rate (cfm)
Model No.

External Internal

Total

Flow Rate (m3/hr)
External Internal

Total

VFD300C23A/E
VFD370C23A/E
VFD450C23A/E
VFD550C23A/E
VFD750C23A/E
VFD900C23A/E

179
179
228
228
246
224

30
30
73
73
73
112

209
209
301
301
319
336

304
304
387
387
418
381

51
51
124
124
124
190

355
355
511
511
542
571

VFD007C43A/E
VFD015C43A/E
VFD022C43A/E
VFD037C43A/E
VFD040C43A/E
VFD055C43A/E
VFD075C43A/E
VFD110C43A/E
VFD150C43A/E
VFD185C43A/E
VFD220C43A/E
VFD300C43A/E
VFD370C43A/E
VFD450C43A/E
VFD550C43A/E
VFD750C43A/E
VFD900C43A/E
VFD1100C43A/E
VFD1320C43A/E
VFD1600C43A/E
VFD1850C43A/E
VFD2200C43A/E

14
10
10
10
40
66
58
99
99
126
179
179
179
186
257
223
224
289

14
14
14
21
21
21
30
30
30
30
73
73
112
112

14
10
10
10
54
80
73
120
120
147
209
209
209
216
330
296
336
401
454
454

24
17
17
17
68
112
99
168
168
214
304
304
304
316
437
379
381
491

24
24
24
36
36
36
51
51
51
51
124
124
190
190

24
17
17
17
92
136
124
204
204
250
355
355
355
367
561
503
571
681
771
771

Power dissipation of AC motor
drive
Power Dissipation
Loss External
Internal
Total
(Heat sink)
913
186
1099
1091
220
1311
1251
267
1518
1401
308
1709
1770
369
2139
2304
484
2788
33
45
71
103
116
134
216
287
396
369
476
655
809
929
1156
1408
1693
2107
2502
3096

25
29
33
38
42
46
76
93
122
138
158
211
184
218
257
334
399
491
579
687

59
74
104
141
158
180
292
380
518
507
635
866
993
1147
1413
1742
2092
2599
3081
3783
4589
5772

VFD2800C43A/E

769

1307

6381

VFD3150C43A/E

769

1307

7156

VFD3550C43A/E

769

1307

8007

VFD4500C43A/E
769
1307
※ The required airflow shown in chart is for installing single drive in a
confined space.
※ When installing the multiple drives, the required air volume should
be the required air volume for single drive X the number of the
drives.

※

※

※

2-4

11894
The heat dissipation shown in
the chart is for installing single
drive in a confined space.
When installing the multiple
drives, volume of heat
dissipation should be the heat
dissipated for single drive X
the number of the drives.
Heat dissipation for each
model is calculated by rated
voltage, current and default
carrier.

Chapter 2 InstallationC2000 Series
NOTE

Normal control Ambient temperature derating curve

Advanced control Ambient temperature derating curve

2-5

Chapter 3 UnpackingC2000 Series

Chapter 3 Unpacking
The AC motor drive should be kept in the shipping carton or crate before installation. In order to retain the
warranty coverage, the AC motor drive should be stored properly when it is not to be used for an extended
period of time.

3-1 Unpacking
The AC motor drive is packed in the crate. Follows the following step for unpack:
Frame D
Crate 1 (VFDXXXCXXA)
Crate 2 (VFDXXXCXXE)
Loosen the 12 cover screws to open the crate.
Loosen the 4 screws on the iron plates. There are 4
iron plates and in total of 16 screws.

Remove the EPEs and manual.

Remove the crate cover, EPEs, rubber and
manual.

Loosen the 8 screws that fastened on the pallet
and remove the wooden plate.

3-1

Chapter 3 UnpackingC2000 Series

Lift the drive by hooking the lifting hole. It is now
ready for installation.

Loosen the 10 screws on the pallet, remove the
wooden plate.

Lift the drive by hooking the lifting hole. It is now
ready for installation.

Frame E
Crate 1 (VFDXXXCXXA)
Crate 2 (VFDXXXCXXE)
Loosen the 4 screws on the iron plates. There are 4 Loosen the 4 screws on the iron plates. There are
iron plates and in total of 16 screws.
4 iron plates and in total of 16 screws.

3-2

Chapter 3 UnpackingC2000 Series

Remove the crate cover, EPEs and manual.

Remove the crate cover, EPEs, rubbers and
manual.

Loosen the 8 screws on the pallet as shown in the
following figure.

Loosen the 10 screws on the pallet and remove the
wooden plate.

Lift the drive by hooking the lifting hole. It is now
ready for installation.

Lift the drive by hooking the lifting hole. It is now
ready for installation.

3-3

Chapter 3 UnpackingC2000 Series

Frame F
Crate 1 (VFDXXXCXXA)
Remove the 6 clips on the side of the crate with a
flat-head screwdriver. (As shown in figure below.)

Crate 2 (VFDXXXCXXE)
Remove the 6 clips on the side of the crate with a
flat-head screwdriver. (As shown in figure below.)

6

6

5

5

4

4
1

1

2

2

3

3
Remove the crate cover, EPEs and manual.

Remove the crate cover, EPEs, rubbers and
manual.

Loosen the 5 screws on the pallet
as shown in the following figure.

Loosen the 9 screws on the pallet and remove the
wooden plate.

5

9

4
3

wood plate2

2

wood plate1

1

3-4

8

7

6

5

4

3

2

1

Chapter 3 UnpackingC2000 Series

Lift the drive by hooking the lifting hole. It is now
ready for installation

Lift the drive by hooking the lifting hole. It is now
ready for installation.

.
Frame G
Crate 1 (VFDXXXCXXA)
Crate 2 (VFDXXXCXXE)
Remove the 6 clips on the side of the crate with a Remove the 6 clips on the side of the crate with a
flathead screwdriver. (As shown in figure below.)
flathead screwdriver. (As shown in figure below.)
4

4

5

5

6

6

1

1
2

2
3

Remove the crate cover, EPEs and manual.

3

Remove the crate cover, EPEs, rubber and manual.

3-5

Chapter 3 UnpackingC2000 Series

Loosen the 5 screws as shown in following figure:
3

Loosen the 12 screws and remove the wooden
plate.

4

11 5 4
6

5

12

1

wood plate5
wood plate4

98
10

3

7
wood plate1
wood plate2
wood plate3

1

2

2

Lift the drive by hooking the lifting hole. It is now
ready for installation.

Lift the drive by hooking the lifting hole. It is now
ready for installation.

Frame H
Crate 1 (VFDXXXC43A)
Crate 2 (VFDXXXC43E-1)
Remove the 8 clips on the side of the crate with a Remove the 8 clips on the side of the crate with a
flathead screwdriver. (As shown in figure below.)
flathead screwdriver. (As shown in figure below.)

3-6

Chapter 3 UnpackingC2000 Series

Remove the crate cover, EPEs and manual.

Remove the crate cover, EPEs, rubbers and
manual.

Loosen the 6 screws on the top then remove 6
metal washers and 6 plastic washers as shown in
figure below.

Loosen the 6 screws on the top then remove 6
metal washers and 6 plastic washers as shown in
figure below.

Lift the drive by hooking the lifting hole. It is now
ready for installation.

Loosen 6 of the M6 screws on the side and remove
the 2 plates, as shown in below. The removed
screws and plates can be used to secure the AC
motor drive from the external.

3-7

Chapter 3 UnpackingC2000 Series

Secure the drive from the external. (Skip to the
next step if this situation does not apply to you.)
Loosen 8 of M8 screws on the both sides and place
the 2 plates that were removed from the last step.
Fix the plates to AC motor drive by fasten 8 of the
M8 screws. (As shown in below)
Torque: 150~180kg-cm (130.20~156.24lb-in.)

Lift the drive by hooking the lifting hole. It is now
ready for installation.

Frame H
Crate 3 (VFDXXXC43E)
Use flathead screwdriver to remove the clips on the side of the crate, 8 clips in total.

3-8

Chapter 3 UnpackingC2000 Series

Remove the crate cover, EPEs, rubber and manual.

Loosen the 6 screws on the cover, remove 6 metal washers and 6 plastic washers as shown in below:

Loosen 6 of the M6 screws on the side and removes the 2 plates, as shown in following figure. The
removed screws and plates can be used to secure AC motor drive from the external.

3-9

Chapter 3 UnpackingC2000 Series

Secure the drive from the internal.
Loosen 18 of the M6 screws and remove the top
cover as shown in figure 2. Mount the cover (figure
1) back to the drive by fasten the M6 screws to the
two sides of the drive, as shown in figure 2.
Torque: 35~45kg-cm (30.38~39.06lb-in.)

Secure the drive from the external.
Loosen 8 of the M8 screws on the both sides and
place the 2 plates that were removed from the last
step. Fix the plates to rive by fasten 8 of the M8
screws. (As shown in figure below).
Torque: 150~180kg-cm (130.20~156.24lb-in.)

Figure 1
Top cover (Use M12 screws)

Figure 2
Fasten 6 of the M6 screws back to the original position where it was removed. As shown in the figure:

3-10

Chapter 3 UnpackingC2000 Series

Lift the drive by hooking the lifting hole. It is now ready for installation.

Frame H Secure the drive
(VFDXXXC43A)
Screw: M12*6

Torque: 340-420kg-cm [295.1-364.6lb-in.]

3-11

Chapter 3 UnpackingC2000 Series

(VFDXXXC43E) & (VFDXXXC43E-1)

Secure the drive from the internal.
Screw: M12*8
Torque: 340-420kg-cm [295.1-364.6lb-in.]

Secure the drive from the external.
Screw: M12*8
Torque: 340-420kg-cm [295.1-364.6lb-in.]

3-12

Chapter 3 UnpackingC2000 Series

3-2 The Lifting Hook
The arrows indicate the location of the lifting holes of frame D to H, as shown in figure below:

D0

E

D

Figure 1

Figure 2

Figure 3

G

F

Figure 4

Figure 5

3-13

Figure 6

Chapter 3 UnpackingC2000 Series

Ensure the lifting hook properly goes through the
lifting hole, as shown in the following diagram.
(Applicable to Frame D0~E)

Ensure the angle between the lifting holes and the
lifting device is within the specification, as shown
in the following figure. (Applicable to Frame D0~E)

(Applicable to Frame F~H)

(Applicable to Frame F~H)

3-14

Chapter 3 UnpackingC2000 Series

Weight
VFDXXXXCXXA
27 kg(59.5 Ibs.)

37.6 kg(82.9 Ibs.)

63.6 kg(140.2 Ibs.)

VFDXXXXCXXE
29 kg(63.9 Ibs.)

40 kg(88.2 Ibs.)

66 kg(145.5 Ibs.)

88kg(193.8 Ibs.)

85kg(187.2 Ibs.)

130kg(286.5 Ibs.)

H1: VFD2800C43A; VFD3150C43A; VFD3550C43A; VFD4500C43A

235kg (518.1lbs)

H2: VFD2800C43E-1; VFD3150C43E-1; VFD3550C43E-1; VFD4500C43E-1

H3: VFD2800C43E; VFD3150C43E; VFD3550C43E; VFD4500C43E

3-15

257kg (566.6lbs)

263kg (579.8lbs)

Chapter 4 WiringC2000 Series

Chapter 4 Wiring
After removing the front cover, examine if the power and control terminals are clearly noted. Please read
following precautions before wiring.
 Make sure that power is only applied to the R/L1, S/L2, T/L3 terminals. Failure to comply may result
in damage to the equipments. The voltage and current should lie within the range as indicated on the
nameplate (Chapter 1-1).
 All the units must be grounded directly to a common ground terminal to prevent lightning strike or
electric shock.
 Please make sure to fasten the screw of the main circuit terminals to prevent sparks which is made
by the loose screws due to vibration
 It is crucial to turn off the AC motor drive power before any wiring installation are
made. A charge may still remain in the DC bus capacitors with hazardous voltages

DANGER

even if the power has been turned off therefore it is suggested for users to measure
the remaining voltage before wiring. For your personnel saftery, please do not
perform any wiring before the voltage drops to a safe level < 25 Vdc. Wiring
installation with remaninig voltage condition may caus sparks and short circuit.
 Only qualified personnel familiar with AC motor drives is allowed to perform
installation, wiring and commissioning. Make sure the power is turned off before
wiring to prevent electric shock.
 When wiring, please choose the wires with specification that complys with local
regulation for your personnel safety.
 Check following items after finishing the wiring:
1.

Are all connections correct?

2.

Any loosen wires?

3.

Any short-circuits between the terminals or to ground?

4-1

Chapter 4 WiringC2000 Series

4-1 Wiring

4-2

Chapter 4 WiringC2000 Series

4-3

Chapter 4 WiringC2000 Series

Figure 1 (For Frame G and above)
Power



Transformer



VFD-C2000

R / L11
S /L21

R
S

T/ L31

T

DC+
R / L12
S /L22
T/ L32
DC-

Figure 2
SINK（NPN）/SOURCE（PNP）Mode
Sourc e Mode
w ith internal power (+24VD C)

MI1

MI1

MI2

MI2

~

2

~

1 Sink Mode
with internal power (+24VDC )

MI8

MI8

+2 4V

DCM

COM

COM

DCM

internal c irc ui t

3 Sink Mode
with external power

+2 4V

4 Sourc e Mode
with external power

MI2

MI2

~

MI1

~

MI1

MI8

MI8

+2 4V

+2 4V

COM

COM

DCM

external power +24V

internal c irc ui t

DCM

internal c irc ui t

external pow er +24V

4-4

internal c irc ui t

Chapter 4 WiringC2000 Series

Figure 3
Function of DC Link
 Applicable to Frame E~H
 Operation Instruction
1. When RST power is off, please disconnect terminal r and terminal s. (As circled in dotted line,
uninstall the gray section and properly store cable r and cable s. Cable r and cable s are not
available in optional accessories, do not dispose them.)
After terminal r and terminal s are cleared, user may now connect new power source to terminal r
and terminal s. Please connect 220Vac for 220V model and 440 Vac for 440V model.
When the drive power is on, if terminal r and terminal s are not connected to new power source
(220 Vac for 220V model and 440Vac for 440 V model), the digital keypad will display an error
message “ryF”.
2. When DC Link is used as a DC Bus connection (RST power is applied), it is not required to
remove terminal r and terminal s.
NOTE

Common DC Bus can only be applied to the drives with same power range. If in your case the
drives are in different power range, please contact with us (Delta Industrial Automation Business
Unit).

r s

4-5

Chapter 4 WiringC2000 Series

4-2 System Wiring Diagram
Power input terminal
Power input
terminal
NFB or fuse

There may be a large inrush current during
NFB or fuse power on. Refer to 7-2 NFB to select a suitable
NFB or fuse.

Electromagnetic
contactor
AC reactor
(input terminal)

Electromagnetic
contactor

Zero-phase
reactor

+

B1

B2
U/T1 V/T2 W/T3

AC reactor
(input terminal)

BR
VFDB
BR

R/L1 S/L2 T/L3 E

Brake
resistor

EMI filter

E
Zero-phase
reactor

Motor

Switching ON/OFF the primary side of the
electromagnetic contactor can turn the integrated
elevator device ON/OFF, but frequent switching is
a cause of machine failure. Do not switch ON/OFF
more than once an hour. Do not use the
electromagnetic contactor as the power switch
for the integrated elevator drive; doing so will
shorten the life of the integrated elevator drive.
When the main power supply capacity is
greater than 500kVA, or when it switches
into the phase capacitor, the instantaneous
peak voltage and current generated will
destroy the internal circuit of the integrated
elevator drive. It is recommended to install
an input side AC reactor in the integrated
elevator drive. This will also improve the
power factor and reduce power harmonics.
The wiring distance should be within 10m.
Please refer to 7-4.

Used to reduce radiated interference, especially
in environments with audio devices, and reduce
Zero-phase
input and output side interference.
reactor
The effective range is AM band to 10MHz.
Please refer to Appendix 7-5.
Can be used to reduce electromagnetic
interference.

EMI filter
AC reactor
(output terminal)

Please supply power according to the rated
power specifications indicated in the manual
(refer to 9 Specifications Table).

Brake resistor Used to shorten deceleration time of the motor.
Please refer to 7-1.
The wiring length of the motor will affect the size
of the reflected wave on the motor end. It is
AC reactor
(output terminal) recommended to install an AC reactor when the
motor wiring length is greater than 20 meters.
Refer to 7-4.

4-6

Chapter 5 Main Circuit TerminalsC2000 Series

Chapter 5 Main Circuit Terminals
5-1 Main Circuit Diagram
For frame A~C
* Provid e 3-ph ase inpu t power

Brake resis tor
(optio nal)
Jumper

Fus e/NFB(No F use Bre aker)

-

+1

+2

B1

B2
U(T1)

R(L1)
R(L1)
S(L2)
T(L3)

S(L2)

V(T2)

T(L3)

W(T3)

For frame A~C
* Provide 3-phase i nput power
F us e/NF B(No F use B reaker)

DC choke
(optional)
J umper

-

+2

+1

R(L1)
R(L1)
S(L2)
T(L3)

Mo tor

IM
3~

Br ak e r es istor
(optional)

B1

B2
U(T 1)

S(L2)

V(T2)

T(L3)

W(T 3)

Motor

IM
3~

For frame D0 and above D0
* Provide 3-phase input power
Fuse/NFB(No Fuse Breaker)

+1/DC+

R(L1)

U(T1)

R(L1)
S(L2)
T(L3)

-/DC-

S(L2)

V(T2)

T(L3)

W(T3)

5-1

Motor

IM
3~

Chapter 5 Main Circuit TerminalsC2000 Series

For Frame G and above
Power



Transformer

R
S

R / L11
S /L21

T

T/ L31



VFD-C2000

DC+
R / L12
S /L22
T/ L32
DC-



NOTE
Please remove short circuit plate of FRAME G and H if 12 pulse is implemented



Before implementing 12 pulse, consult Delta for more detail

Terminals

Descriptions

R/L1, S/L2, T/L3

AC line input terminals 3-phase

U/T1, V/T2, W/T3

AC drive output terminals for connecting 3-phase induction motor
Applicable to frame A~C

+1, +2

Connections for DC reactor to improve the power factor. It needs to remove the
jumper for installation.
Connections for brake unit (VFDB series)

+1/DC+, -/DC-

(for 230V models: ≦22kW, built-in brake unit)
(for 460V models: ≦30kW, built-in brake unit)
Common DC Bus

B1, B2

Connections for brake resistor (optional)
Earth connection, please comply with local regulations.

5-2

Chapter 5 Main Circuit TerminalsC2000 Series

Main power terminals


Do not connect 3-phase model to one-phase power. R/L1, S/L2 and T/L3
has no phase-sequence requirement, it can be used upon random
selection.



It is recommend to add a magnetic contactor (MC) to the power input wiring
to cut off power quickly and reduce malfunction when activating the
protection function of the AC motor drive. Both ends of the MC should have
an R-C surge absorber.



Fasten the screws in the main circuit terminal to prevent sparks condition
made by the loose screws due to vibration.



Please use voltage and current within the specification.



When using a general GFCI (Ground Fault Circuit Interrupter), select a
current sensor with sensitivity of 200mA or above and not less than
0.1-second operation time to avoid nuisance tripping.



Please use the shield wire or tube for the power wiring and ground the two
ends of the shield wire or tube.



Do NOT run/stop AC motor drives by turning the power ON/OFF. Run/stop
AC motor drives by RUN/STOP command via control terminals or keypad. If
you still need to run/stop AC motor drives by turning power ON/OFF, it is
recommended to do so only ONCE per hour.

Output terminals for main circuit


When it needs to install the filter at the output side of terminals U/T1, V/T2,
W/T3 on the AC motor drive. Please use inductance filter. Do not use
phase-compensation capacitors or L-C (Inductance-Capacitance) or R-C
(Resistance-Capacitance), unless approved by Delta.



DO NOT connect phase-compensation capacitors or surge absorbers at the
output terminals of AC motor drives.



Use well-insulated motor, suitable for inverter operation.



Note down the rated data and the torque force of the wiring when the output
terminal is below 75℃.

This information provides the right wiring method

to wire terminals (It corresponds to the terminals of the motor wire and
non-motor wire).


When the AC drive output terminals U/T1, V/T2, and W/T3 are connected to
the motor terminals U/T1, V/T2, and W/T3, respectively, the motor will rotate
counterclockwise (as viewed on the shaft end of the motor) when a forward
operation command is received. To permanently reverse the direction of
motor rotation, switch over any of the two motor leads

Fo wa rd
Running

5-3

Chapter 5 Main Circuit TerminalsC2000 Series

Terminals for connecting DC reactor, external brake resistor, external
brake resistor and DC circuit


This is the terminals used to connect the DC reactor to improve the power
factor. For the factory setting, it connects the short-circuit object. Please
remove this short-circuit object before connecting to the DC reactor.
DC rea ct or (o ption al)
+1



+2

Connect a brake resistor or brake unit in applications with frequent
deceleration ramps, short deceleration time, too low brake torque or
requiring increased brake torque.
Brak e re sistor
(optional)

Brak e re sistor
(optional)

BR

Brak e un it
(o ption al)

VFDB

B2

B1



+

-

The external brake resistor of Frame A, B and C should connect to the
terminals (B1, B2) of AC motor drives.



For those models without built-in brake resistor, please connect external
brake unit and brake resistor (both of them are optional) to increase brake
torque.



When the terminals +1, +2 and - are not used, please leave the terminals
open.



DO NOT connect [+1, -], [+2, -], [+1/DC+, -/DC-] or brake resistor directly to
prevent drive damage.



DC+ and DC- are connected by common DC bus, please refer to Chapter
5-1(Main Circuit Terminal) for the wiring terminal specification and the wire
gauge information.



Please refer to the VFDB manual for more information on wire gauge when
installing the brake unit.

5-4

Chapter 5 Main Circuit TerminalsC2000 Series

5-2 Main Circuit Terminals
Frame A

Main circuit terminals:
R/L1, S/L2, T/L3, U/T1, V/T2, W/T3,
Models

Max. Wire
Gauge

, B1, B2, +1, +2, -

Min. Wire Gauge

Torque
(±10%)

14 AWG (2.1mm2)
VFD007C23A
VFD015C23A
12 AWG (3.3mm2)
VFD022C23A
10 AWG (5.3mm2)
VFD037C23A
8 AWG (8.4mm2)
VFD007C43A
14 AWG (2.1mm2)
VFD007C43E
14 AWG (2.1mm2)
VFD015C43A
14 AWG (2.1mm2)
M4
VFD015C43E
14 AWG (2.1mm2)
8 AWG
20kg-cm
(8.4mm2)
(17.4 lb-in.)
VFD022C43A
14 AWG (2.1mm2)
(1.962Nm)
VFD022C43E
14 AWG (2.1mm2)
2
VFD037C43A
10 AWG (5.3mm )
VFD037C43E
10 AWG (5.3mm2)
VFD040C43A
10 AWG (5.3mm2)
VFD040C43E
10 AWG (5.3mm2)
VFD055C43A
10 AWG (5.3mm2)
VFD055C43E
10 AWG (5.3mm2)
UL installations must use 600V, 75℃ or 90℃ wire. Use copper wire
only.
1. Figure 1 shows the terminal specification.
2. Figure 2 shows the specification of insulated heat shrink tubing that
comply with UL (600V, YDPU2).
Figure 1
Figure 2

5-5

Chapter 5 Main Circuit TerminalsC2000 Series

Frame B

Main circuit terminals:
R/L1, S/L2, T/L3, U/T1, V/T2, W/T3,
Models

Max. Wire
Gauge

, B1, B2, +1, +2, -

Min. Wire Gauge

Torque
(±10%)

VFD055C23A
8 AWG (8.4mm2)
VFD075C23A
6 AWG (13.3mm2)
VFD110C23A
4 AWG (21.2mm2)
M5
VFD075C43A
8 AWG (8.4mm2)
35kg-cm
4 AWG
(30.4 lb-in.)
VFD075C43E
8AWG (8.4mm2)
(21.2mm2)
(3.434Nm)
VFD110C43A
8 AWG (8.4mm2)
2
VFD110C43E
8 AWG (8.4mm )
VFD150C43A
6 AWG (13.3mm2)
VFD150C43E
6 AWG (13.3mm2)
UL installations must use 600V, 75℃ or 90℃ wire. Use copper wire
only.
NOTE

Terminal D+ [+2 & +1]: Torque: 45 kg-cm [39.0lb-in.] (4.415Nm) (±10%)
1. VFD110C23A must use 600V, 90℃ wire when surrounding
temperature exceeds 45℃.
2. Figure 1 shows the terminal specification.
3. Figure 2 shows the specification of insulated heat shrink tubing that
comply with UL (600V, YDPU2).
Figure 1
Figure 2

5-6

Chapter 5 Main Circuit TerminalsC2000 Series

Frame C

Main circuit terminals:
R/L1, S/L2, T/L3, U/T1, V/T2, W/T3,
Models

Max. Wire
Gauge

, B1, B2, +1, +2, -

Min. Wire Gauge

Torque
(±10%)

VFD150C23A
1 AWG (42.4mm2)
VFD185C23A
1/0 AWG (53.5mm2)
VFD220C23A
1/0 AWG (53.5mm2)
M8
VFD185C43A
4 AWG (21.2mm2)
1/0 AWG
80kg-cm
VFD185C43E
4 AWG (21.2mm2)
(53.5mm2)
(69.4 lb-in.)
VFD220C43A
4 AWG (21.2mm2)
(7.85Nm)
2
VFD220C43E
4 AWG (21.2mm )
VFD300C43A
2 AWG (33.6mm2)
VFD300C43E
2 AWG (33.6mm2)
UL installations must use 600V, 75℃ or 90℃ wire. Use copper wire
only.
NOTE

Terminal D+ [+2 & +1]: Torque: 90 kg-cm [78.2lb-in.] (8.83Nm) (±10%)
1. VFD220C23A must use 600V, 90℃ wire when surrounding
temperature exceeds 40℃.
2. Figure 1 shows the terminal specification.
3. Figure 2 shows the specification of insulated heat shrink tubing that
comply with UL (600V, YDPU2).
Figure 1
Figure 2

c

5-7

Chapter 5 Main Circuit TerminalsC2000 Series

Main circuit terminals:
R/L1, S/L2, T/L3, U/T1, V/T2, W/T3,

, +1/DC+, -/DC-

Torque
(±10%)
1/0 AWG (53.5mm2)
VFD370C43S
M8
VFD450C43S
2/0 AWG 2/0 AWG (67.4mm2)
80kg-cm
(67.4mm2) 1/0 AWG (53.5mm2)
(70 lb-in.)
VFD370C43U
2
(7.85Nm)
VFD450C43U
1/0 AWG (53.5mm )
UL installations must use 600V, 75℃ or 90℃ wire. Use copper wire
only.
Specification of grounding wire: 2AWG*2(33.6mm2*2)
Figure on the right shows the specification of insulated heat shrink
tubing that comply with UL (600V, YDPU2).
Models

Min. Wire Gauge

11 Max.

Max. Wire
Gauge

+0
-2

22 Max.
8.2 Min.

8.2 Min.
Ring lug

13±1.5

32 Max.

Ring lug

13 Min.

13 Min.

Frame D0

Heat Shrink Tube
WIRE

5-8

Heat Shrink Tube
WIRE

Chapter 5 Main Circuit TerminalsC2000 Series

Main circuit terminals:
R/L1, S/L2, T/L3, U/T1, V/T2, W/T3,
Max. Wire
Gauge

Models

, +1/DC+, -/DC-

Min. Wire Gauge

Torque
(±10%)

4/0 AWG (107mm2)
VFD300C23A
VFD370C23A
250MCM (127mm2)
300MCM
2
(152mm )
VFD550C43A
3/0 AWG (85mm2)
VFD750C43A
300MCM (152mm2)
M8
VFD300C23E
3/0 AWG (85mm2)
200kg-cm
(173 lb-in.)
VFD370C23E
4/0 AWG (107mm2)
2
(19.62Nm)
VFD370C43E
1/0 AWG (53.5mm )
4/0 AWG.
2
2
(107mm )
VFD450C43E
1/0 AWG (53.5mm )
VFD550C43E
2/0 AWG (67.4mm2)
VFD750C43E
4/0 AWG (107mm2)
1. UL installations must use 600V, 75oC or 90 oC wires. Use copper
wire only.
2. Figure 1 shows the terminal specification.
3. Figure 2 shows the specification of insulated heat shrink tubing
that comply with UL (600V, YDPU2).
Figure 1
17 Max.

Figure 2

28 Max.
8.2 Min.
Ring lug
48 Max.

Frame D

28 Max.

5-9

Chapter 5 Main Circuit TerminalsC2000 Series

Frame E

Main circuit terminals:
R/L1, S/L2, T/L3, U/T1, V/T2, W/T3,
Models

Max. Wire
Gauge

, +1/DC+, -/DC-

Min. Wire Gauge

VFD450C23A

1/0AWG*2 (53.5mm2*2)

VFD550C23A

3/0AWG*2 (85mm2*2)

VFD750C23A
VFD900C43A

300MCM*2
4/0 AWG*2 (107mm2*2)
(152mm2*2)
1/0AWG*2 (53.5mm2*2)

Incorrect installation may
result in damage to option
or inverter.Please refer to
operation manual for
installation instructions.

VFD1100C43A

3/0AWG*2 (85mm2*2)

VFD450C23E

1/0AWG*2 (53.5mm2*2)

VFD550C23E

2/0AWG*2 (67.4mm2*2)

VFD750C23E

4/0 AWG*2
(107mm2*2)

M8
200kg-cm
(173 lb-in.)
(19.62Nm)

3/0AWG*2 (85mm2*2)

VFD900C43E

1/0AWG*2 (53.5mm2*2)

VFD1100C43E

2/0AWG*2 (67.4mm2*2)

UL installations must use 600V, 75oC or 90 oC wires. Use copper
wire only.
2. Specification of grounding wire : 300MCM [152 mm2]
Torque: M8 180kg-cm (156 lb-in.) (17.64Nm) (±10%), as shown in
Figure 2.
3. Figure 1 shows the specification for ring lug.
4. Figure 3 shows the specification of insulated heat shrink tubing
that comply with UL (600C, YDPU2).
E
Figure 1
Figure 2
17.0MAX.

31MAX.
8. 2M I

26.5MAX.
Figure 3

5-10

28.0MAX.

N.
65.0MAX.

16-4

+0

1.

70MAX.

警
告
錯誤的安裝將會導
致變頻器及選配品
損壞，安裝前請務
必參閱使用手冊後
才進行裝配。

Torque
(±10%)

8.2MIN

.

Chapter 5 Main Circuit TerminalsC2000 Series

Main circuit terminals:
R/L1, S/L2, T/L3, U/T1, V/T2, W/T3, +1/DC+, -/DCModels

Max. Wire
Gauge

Min. Wire Gauge

Torque
(±10%)

300MCM*2 (152mm2*2)

VFD900C23A

300MCM*2
4/0 AWG*2 (107mm2*2)
(152mm2*2)
VFD1600C43A
300MCM*2 (152mm2)
VFD1320C43A

M8
200kg-cm
4/0 AWG*2 (107mm2*2) (173 lb-in.)
VFD900C23E
(19.62Nm)
4/0 AWG*2
VFD1320C43E
3/0AWG*2 (85mm2*2)
2
(107mm *2)
VFD1600C43E
4/0 AWG*2 (107mm2*2)
1.
2.

VFD900C23A/E installations must use 90℃ wire.
For other model, UL installations must use 600V, 75℃ or 90℃
wire. Use copper wire only.

Specification of grounding wire
：300MCM*2 [152 mm2*2]
Torque: M8 200kg-cm (173 lb-in.) (19.62Nm) (±10%)
5. Figure 1 shows the specification for ring lug.
4. Figure 2 shows the specification of insulated heat shrink tubing
that comply with UL (600C, YDPU2).
Figure 1
Figure 2

16-4

+0

3.

70MAX.

Frame F

31MAX.
8.2MI
N.

26.5MAX.

5-11

Chapter 5 Main Circuit TerminalsC2000 Series

Main circuit terminals:
R/L11, R/L12, S/L21, S/L22, T/L31, T/L32
Models

Max. Wire
Gauge

Min. Wire Gauge

Torque
(±10%)

2/0AWG*4 (67.4mm2*4)

VFD1850C43A

M8
VFD2200C43A 300MCM*4 3/0AWG*4 (85mm2*4) 200kg-cm
2
VFD1850C43E (152mm *4) 1/0AWG*4 (53.5mm2*4) (173 lb-in.)
(19.62Nm)
VFD2200C43E
2/0AWG*4 (67.4mm2*4)

Main circuit terminals:
U/T1, V/T2, W/T3, +1/DC+, -/DCMax. Wire
Models
Min. Wire Gauge
Gauge
400MCM*2 (203mm2*2)
VFD1850C43A

Torque
(±10%)

M12
VFD2200C43A 500MCM*2 500MCM*2 (253mm2*2) 408kg-cm
2
VFD1850C43E (253mm *2) 300MCM*2 (152mm2*2) (354lb-in.)
( 40Nm)
VFD2200C43E
400MCM*2 (203mm2*2)
UL installations must use 600V, 75℃ or 90℃ wire. Use copper
wire only.
Use 600V, 90℃ wire for VFD2200C43A when the surrounding
temperature is over 45℃.
Figure 1 and Figure 2 show the specification for using ring lug.

1.
2.
3.

Specification for grounding wire : 300MCM*4 [152 mm2*2]
Torque: M8 200kg-cm (173 lb-in.) (19.62Nm) (±10%), as shown
in Figure 1
5. Figure 3 and Figure 4 shows the specification of insulated heat
shrink tubing that comply with UL (600C, YDPU2).
Figure 1
Figure2
R/L11, R/L12, S/L21, S/L22, U/T1, V/T2, W/T3, +1/DC+, -/DCT/L31, T/L32,

31MAX.
8.2MI
N.

42.0(MAX.)

12.2(MIN.)

42.0(MAX.)
70.0(MAX.)

26.5MAX.

21.0(MAX.)

16-4

+0

4.

54MAX.

Frame G

Figure 3

Figure 4

5-12

Chapter 5 Main Circuit TerminalsC2000 Series

Frame H

Main circuit terminals:
R/11,R12,S/21,S/22,T/31,T/32, U/T1,V/T2, W/T3, +1/DC+, -/DCModels

Max. Wire
Gauge

Min. Wire Gauge

VFD2800C43A

4/0 AWG*4 (107mm2*4)

VFD3150C43A

300MCM*4 (152mm2*4)

VFD3550C43A

300MCM*4 (152mm2*4)

VFD4500C43A

300MCM*4 (152mm2*4)

VFD2800C43E-1

3/0 AWG*4 (85mm2*4)

Torque
(±10%)

M8
200kg-cm
VFD3150C43E-1 300MCM*4 4/0 AWG*4 (107mm *4)
(173 lb-in.)
2
VFD3550C43E-1 (152mm *4) 250MCM*4 (127mm2*4) (19.62Nm)
2

VFD4500C43E-1

300MCM*4 (152mm2*4)

VFD2800C43E

300MCM*4 (152mm2*4)

VFD3150C43E

4/0 AWG*4 (107mm2*4)

VFD3550C43E

300MCM*4 (152mm2*4)

VFD4500C43E
300MCM*4 (152mm2*4)
1. VFD4500C43A, VFD4500C43E-1, VFD4500C43E need to use
90℃ wire.
2. UL installations must use 600V, 75℃ or 90℃ wire. Use copper
wire only.
3. Figure 1 shows the specification for using the ring lug.
4.

5.

Specification of grounding wire : 300MCM*4 [152 mm2*4],
Torque: M8 200kg-cm (173 lb-in.) (19.62Nm) (±10%), as
shown in figure 1.
Figure 2 shows the specification of heat shrink tubing that
comply with UL (600C, YDPU2).

Figure 1

Figure 2

5-13

Chapter 6 Control TerminalsC2000 Series

Chapter 6 Control Terminals
Please remove the top cover before wiring the multi-function input and output terminals,
The drive appearances shown in the figures are for reference only, a real drive may look different.
Remove the cover for wiring. Frame A~H
Frame C
Frame A&B
Loosen the screws and press the tabs on both sides Screw torque: 12~15Kg-cm [10.4~13lb-in.]
Loosen the screws and press the tabs on both sides
to remove the cover.
to remove the cover.
Screw torque: 12~15Kg-cm [10.4~13lb-in.]

Frame D0&D
Screw torque: 12~15Kg-cm [10.4~13lb-in.] To remove the cover, lift it slightly and pull outward.
Loosen the screws and press the tabs on both sides to remove the cover.

Frame E
Screw torque: 12~15Kg-cm [10.4~13lb-in.] To remove the cover, lift it slightly and pull outward.

6-1

Chapter 6 Control TerminalsC2000 Series

Frame F
Screw torque: 12~15Kg-cm [10.4~13lb-in.] To remove the cover, lift it slightly and pull outward

Frame G
Screw torque: 12~15Kg-cm [10.4~13lb-in.] To remove the cover, lift it slightly and pull outward

Frame H
Screw torque: 14~16Kg-cm [12.15~13.89lb-in.] To remove the cover, lift it slightly and pull outward

6-2

Chapter 6 Control TerminalsC2000 Series

6-1 Specifications of Control Terminal

Wire Gauge: 26~16AWG（0.1281-1.318mm2）,
Torque: (A) 5kg-cm [4.31Ib-in.] (0.49Nm) (As shown in figure above)
(B) 8kg-cm [6.94Ib-in.] (0.78Nm) (As shown in figure above)
Wiring precautions:
Reserves 5mm and properly install the wire into the terminal; fasten the installation by a
slotted screwdriver. If the wire is stripped, sort the wire before install into the terminal.
 Flathead screwdriver: blade width 3.5mm, tip thickness 0.6mm
 In the figure above, the factory setting for S1-SCM is short circuit. The factory setting for
+24V-COM is short circuit and SINK mode (NPN); please refer to Chapter 4 Wiring for more
detail.
Terminals
Terminal Function
Factory Setting (NPN mode)


+24V
COM
FWD
REV

MI1
~
MI8

Digital control signal common

+24V5% 200mA

(Source)
Digital control signal common (Sink) Common for multi-function input terminals
FWD-DCM:
Forward-Stop command
ON forward running
OFF deceleration to stop
REV-DCM:
Reverse-Stop command
ON reverse running
OFF deceleration to stop
Refer to parameters 02-01~02-08 to program the
multi-function inputs MI1~MI8.
Source mode
ON: the activation current is 3.3mA≧11Vdc
OFF: cut-off voltage≦5Vdc

Multi-function input 1~8

Sink Mode
ON: the activation current is 3.3mA ≦13Vdc
OFF: cut-off voltage≧19Vdc
Digital frequency meter

DFM

DFM

DCM
DCM

MO1

Digital frequency signal common
Multi-function Output 1
(photocoupler)

Regard the pulse voltage as the output monitor signal
Duty-cycle: 50%
Min. load impedance: 1kΩ/100pf
Max. current: 30mA
Max. voltage: 30Vdc
The AC motor drive releases various monitor signals, such as
drive in operation, frequency attained and overload indication,
via transistor (open collector).

6-3

Chapter 6 Control TerminalsC2000 Series

Terminals

Terminal Function

Factory Setting (NPN mode)
MO1

MO2

Multi-function Output 2
MO2

(photocoupler)

MCM

MCM

Multi-function Output Common

Max 48Vdc 50mA

RC1

Multi-function relay output 1 (N.O.) Resistive Load:
a
3A(N.O.)/3A(N.C.) 250VAC
Multi-function relay output 1 (N.C.) 5A(N.O.)/3A(N.C.) 30VDC
b
Inductive Load (COS 0.4):
1.2A(N.O.)/1.2A(N.C.) 250VAC
Multi-function relay common

RA2

Multi-function relay output 2 (N.O.) a

RB2

It is used to output each monitor signal, such as drive is in
Multi-function relay output 2 (N.C.) b operation, frequency attained or overload indication.

RC2

Multi-function relay common

+10V

Potentiometer power supply

Analog frequency setting: +10Vdc 20mA

-10V

Potentiometer power supply

Analog frequency setting: -10Vdc 20mA

RA1
RB1

2.0A(N.O.)/1.2A(N.C.) 30VDC

Analog voltage input
+10V AVI circuit

AVI

Impedance: 20kΩ
Range: 0~20mA/4~20mA/0~10V =0~Max. Output Frequency

AVI

(Pr.01-00)
AVI switch, factory setting is 0~10V

ACM
internal circuit

Analog current input
ACI

ACI circuit

Impedance: 250Ω
Range: 0~20mA/4~20mA/0~10V = 0 ~ Max. Output

ACI

Frequency (Pr.01-00)
ACI Switch, factory setting is 4~20mA
ACM

internal circuit

Auxiliary analog voltage input
+10V

AUI

AUI ( -10V~+ 10V)

Range: -10~+10VDC=0 ~ Max. Output Frequency(Pr.01-00)

A CM
-1 0V

Impedance: 20kΩ

inter nal c irc ui t

6-4

Chapter 6 Control TerminalsC2000 Series

Terminals

Terminal Function

Factory Setting (NPN mode)
0~10V Max. output current 2mA, Max. load 5kΩ
-10~10V maximum output current 2mA, maximum load 5kΩ
Output current: 2mA max
Resolution: 0~10V corresponds to Max. operation frequency
Range: 0~10V  -10~+10V
AFM 1 Switch, factory setting is 0~10V

AFM1

0~10V Max. output current 2mA, Max. load 5kΩ
0~20mA Max. load 500Ω
Output current: 20mA max
Resolution: 0~10V corresponds to Max. operation frequency
Range: 0~10V  4~20mA
AFM 2 Switch, factory setting is 0~10V

AFM2

ACM
STO1
SCM1
STO2
SCM2

Analog Signal Common

Common for analog terminals

Default setting is shorted
Power removal safety function for EN954-1 and IEC/EN61508

When STO1~SCM1;STO2~SCM2 is activated, the activation current is 3.3mA≧11Vdc

SG+
SG-

Modbus RS-485

SGND
RJ-45

PIN 1,2,7,8 : Reserved
PIN 4: SG-

PIN 3, 6: SGND
PIN 5: SG+

NOTE: Wire size of analog control signals: 18 AWG (0.75 mm2) with shielded wire

6-2 Analog input terminals (AVI, ACI, AUI, ACM)


Analog input signals are easily affected by external noise. Use shielded wiring and keep it as
short as possible (<20m) with proper grounding. If the noise is inductive, connecting the shield to
terminal ACM can bring improvement.



If the analog input signals are affected by noise from the AC motor drive, please connect a
capacitor and ferrite core as indicated in the following diagram.

AVI/ACI/AUI
C
AC M

ferrite core

Wind each wires 3 times or more around the core
Digital inputs (FWD, REV, MI1~MI8, COM)


When using contacts or switches to control the digital inputs, please use high quality components
to avoid contact bounce.



The “COM” terminal is the common side of the photo-coupler. Any of wiring method, the “common
point” of all photo-coupler must be the “COM”.
6-5

Chapter 6 Control TerminalsC2000 Series



When the photo-coupler is using internal power supply, the switch connection for Sink and Source
as below:
MI-DCM: Sink mode
MI-+24V: Source mode



When the photo-coupler is using external power supply, please remove the short circuit cable
between the +24V and COM terminals. The connection mode is Sink mode or Source mode is
according to the below:
The “+” of 24V connecting to “COM: Sink mode
The “-“ of 24V connecting to COM: Source mode

Transistor outputs (MO1, MO2, MCM)
 Make sure to connect the digital outputs to the right polarity.


When connecting a relay to the digital outputs connect a surge absorber across the coil and
check the polarity.

6-6

Chapter 6 Control TerminalsC2000 Series

6-3 Remove the Terminal Block
1. Loosen the screws by screwdriver. (As shown in figure below).

2. Remove the control board by pulling it out for a distance 6~8 cm (as 1 in the figure) then lift the control
board upward(as 2 in the figure).

6-7

Chapter 7 Optional AccessoriesC2000 Series

Chapter 7 Optional Accessories
7-1 All Brake Resistors and Brake Units Used in AC Motor Drives
7-2 Non-fuse Circuit Breaker
7-3 Fuse Specification Chart
7-4 AC/DC Reactor
7-5 Zero Phase Reactor
7-6 EMI Filter
7-7 Digital Keypad
7-8 Panel Mounting
7-9 Conduit Box Kit
7-10 Fan Kit
7-11 Flange Mounting Kit
7-12 USB/RS-485 Communication Interface IF6530

7-1

Chapter 7 Optional Accessories C2000 Series

The optional accessories listed in this chapter are available upon request. Installing additional
accessories to your drive would substantially improve the drive’s performance. Please select an applicable
accessory according to your need or contact the local distributor for suggestion.

7-1 All Brake Resistors and Brake Units Used in AC Motor Drives
230V
Applicable
Motor
HP

kW

1
2
3
5
7.5
10
15
20
25
30
40
50
60
75
100
125

0.7
1.5
2.2
3.7
5.5
7.5
11
15
18
22
30
37
45
55
75
90

*1 125%Braking Torque 10%ED
Braking
Torque
(kg-m)
0.5
1.0
1.5
2.5
3.7
5.1
7.5
10.2
12.2
14.9
20.3
25.1
30.5
37.2
50.8
60.9

Brake
Unit
*4VFDB
2015*2
2022*2
2022*2
2022*3
2022*4
2022*4

*3Braking Resistor series for
each Brake Unit
BR080W200*1
BR200W091*1
BR300W070*1
BR400W040*1
BR1K0W020*1
BR1K0W020*1
BR1K5W013*1
BR1K0W4P3*2 2 series
BR1K0W4P3*2 2 series
BR1K5W3P3*2 2 series
BR1K0W5P1*2 2 series
BR1K2W3P9*2 2 series
BR1K5W3P3*2 2 series
BR1K2W3P9*2 2 series
BR1K2W3P9*2 2 series
BR1K5W3P3*2 2 series

Resistor value
spec. for each
AC motor Drive
80W200Ω
200W91Ω
300W70Ω
400W40Ω
1000W20Ω
1000W20Ω
1500W13Ω
2000W8.6Ω
2000W8.6Ω
3000W6.6Ω
4000W5.1Ω
4800W3.9Ω
6000W3.3Ω
7200W2.6Ω
9600W2Ω
12000W1.65Ω

*2 Max. Brake Torque
Total
Min.
Braking
Resistor
Current (A) Value (Ω)
1.9
63.3
4.2
47.5
5.4
38.0
9.5
19.0
19
14.6
19
14.6
29
13.6
44
8.3
44
8.3
58
5.8
75
4.8
97
3.2
118
3.2
145
2.1
190
1.6
230
1.6

Max. Total
Braking
Current (A)
6
8
10
20
26
26
28
46
46
66
80
120
120
180
240
240

Peak
Power
(kW)
2.3
3.0
3.8
7.6
9.9
9.9
10.6
17.5
17.5
25.1
30.4
45.6
45.6
68.4
91.2
91.2

460V
Applicable
Motor

*1 125%Braking Torque 10%ED
Braking
Torque
(kg-m)

Brake
Unit

*3Braking Resistor series for
each Brake Unit

*2 Max. Brake Torque

Resistor value
Total
Min.
Max. Total
spec. for each
Braking
Resistor
Braking
AC motor Drive Current (A) Value (Ω) Current (A)

Peak
Power
(kW)

HP

kW

1
2
3
5
5.5
7.5
10
15
20
25
30

0.7
1.5
2.2
3.7
4.0
5.5
7.5
11
15
18
22

0.5
1.0
1.5
2.5
2.7
3.7
5.1
7.5
10.2
12.2
14.9

-

BR080W750*1
BR200W360*1
BR300W250*1
BR400W150*1

80W750Ω
200W360Ω
300W250Ω
400W150Ω

1
2.1
3
5.1

190.0
126.7
108.6
84.4

4
6
7
9

3.0
4.6
5.3
6.8

-

BR1K0W075*1

1000W75Ω

10.2

54.3

14

10.6

-

1000W75Ω
1500W43Ω
2000W32Ω
2000W32Ω
3000W26Ω

10.2
17.6
24
24
29

47.5
42.2
26.2
23.0
23.0

16
18
29
33
33

12.2
13.7
22.0
25.1
25.1

40

30

20.3

-

4000W16Ω

47.5

14.1

54

41.0

50

37

25.1

4045*1

4800W15Ω

50

12.7

60

45.6

60

45

30.5

4045*1

6000W13Ω

59

12.7

60

45.6

75

55

76

9.5

80

60.8

75

4030*2
4045*2

8000W10.2Ω

100

37.2
50.8

9600W7.5Ω

100

6.3

120

91.2

125

90

60.9

4045*2

12000W6.5Ω

117

6.3

120

91.2

150

110

74.5

4110*1

BR1K0W075*1
BR1K5W043*1
BR1K0W016*2
2 series
BR1K0W016*2
2 series
BR1K5W013*2
2 series
2 parallel,
BR1K0W016*4
2 series
2 parallel,
BR1K2W015*4
2 series
2 parallel,
BR1K5W013*4
2 series
BR1K0W5P1*4
4 parallel
2 parallel,
BR1K2W015*4
2 series
2 parallel,
BR1K5W013*4
2 series
5 parallel,
BR1K2W015*10
2 series

12000W6Ω

126

6.0

126

95.8

*4VFDB

7-2

Chapter 7 Optional AccessoriesC2000 Series

460V
Applicable
Motor
HP

kW

*1 125%Braking Torque 10%ED
Braking
Torque
(kg-m)

*3Braking Resistor series for
each Brake Unit

Brake
Unit

*2 Max. Brake Torque

Resistor value
Total
Min.
Max. Total
spec. for each
Braking
Resistor
Braking
AC motor Drive Current (A) Value (Ω) Current (A)

Peak
Power
(kW)

6 parallel,
18000W4Ω
190
4.0
190
144.4
2 series
6 parallel,
215 160
108.3 4160*1 BR1K5W012*12
18000W4Ω
190
4.0
190
144.4
2 series
7 parallel,
21000W3.4Ω
225
3.4
225
172.1
250 185
125.3 4185*1 BR1K5W012*14
2 series
5 parallel,
300 220
148.9 4110*2 BR1K2W015*10
24000W3Ω
252
3.0
252
190.5
2 series
6 parallel,
375 280
189.6 4160*2 BR1K5W012*12
36000W2Ω
380
2.0
380
288.8
2 series
6 parallel,
425 315
213.3 4160*2 BR1K5W012*12
36000W2Ω
380
2.0
380
288.8
2 series
7 parallel,
475 355
240.3 4185*2 BR1K5W012*14
42000W1.7Ω
450
1.7
450
344.2
2 series
1
* Calculation for 125% brake toque: (kw)*125%*0.8; where 0.8 is motor efficiency.
Because there is a resistor limit of power consumption, the longest operation time for 10%ED is 10sec (on: 10sec/ off: 90sec).
*2 Please refer to the Brake Performance Curve for “Operation Duration & ED” vs. “Braking Current”.
*3 For heat dissipation, a resistor of 400W or lower should be fixed to the frame and maintain the surface temperature below
50℃; a resistor of 1000W and above should maintain the surface temperature below 350℃.
*4 Please refer to VFDB series Braking Module Instruction for more detail on braking resistor.
175

132

89.4

4160*1

BR1K5W012*12

NOTE
1.

Definition for Brake Usage ED%
Explanation: The definition of the brake usage ED (%) is for assurance of enough time for the brake unit and brake resistor to
dissipate away heat generated by braking. When the brake resistor heats up, the resistance would increase with
temperature, and brake torque would decrease accordingly. Recommended cycle time is one minute.

For safety concern, install an overload relay (O.L) between the brake unit and the brake resistor in conjunction with the
magnetic contactor (MC) prior to the drive for abnormal protection. The purpose of installing the thermal overload relay is to
protect the brake resistor from damage due to frequent brake, or due to brake unit keeping operating resulted from unusual
high input voltage. Under such circumstance, just turn off the power to prevent damaging the brake resistor.
NFB

MC

R/L1
S/L2
T/L3
O.L.

V FD

MOTOR

R/L1 U/T1
S/L2
V/T2
T/L3
W/T3

MC

+(P)

SA

- (N)

Varistor

IM

+ (P) (N )

B1

O.L.

Brake unit
VFDB
XXXX
B2
MASTER
Thermal relay
or Temperature Switch
Trip Contact

T hermal relay

M1 M2

+ Brake (P) (N)

Resistor

B1

Brake unit
VFDB
XXXX
B2

MASTER
Temperature
M1 M2
switch

T hermal relay
O.L.

Brake
Resistor

22Parallel /Serie
Temperature switch

When AC Drive is equipped with a DC reactor, please read user manual to know th
wiring method of input
。 circuit of brake unit +(P).
Do Not connect input circuit -(N) to the neutral point of the power system.
2.

If damage to the drive or other equipment is due to the fact that the brake resistors and brake modules in use are not
provided by Delta, the warranty will be void.
7-3

Chapter 7 Optional Accessories C2000 Series
3.

Take into consideration the safety of the environment when installing the brake resistors. If the minimum resistance value is
to be utilized, consult local dealers for the calculation of Watt figures.

4.

When using more than 2 brake units, equivalent resistor value of parallel brake unit can’t be less than the value in the
column “Minimum Equivalent Resistor Value for Each AC Drive” (the right-most column in the table). Please read the wiring
information in the user manual of brake unit thoroughly prior to operation

5.

This chart is for normal usage; if the AC motor drive is applied for frequent braking, it is suggested to enlarge 2~3 times of
the Watts.
Thermal Relay:
Thermal relay selection is basing on its overload capability. A standard braking capacity for C2000 is 10%ED (Tripping
time=10s). The figure below is an example of 406V, 110kw AC motor drive. It requires the thermal relay to take 260%
overload capacity in 10s (Host starting) and the braking current is 126A. In this case, user should select a rated 50A thermal
relay. The property of each thermal relay may vary among different manufacturer, please carefully read specification.
60
40
30
20

Tripping time
Second

6.

10
8
6
4
3
2
1
0.8
0.6
0.4
0.3
0.8

1

1.5

2

3

4

5

6 7 8 9 10

Multiple of current setting

7-4

xln (A)

15

Chapter 7 Optional AccessoriesC2000 Series

7-2 Non-fuse Circuit Breaker
Comply with UL standard: Per UL 508, paragraph 45.8.4, part a.
The rated current of the breaker shall be 2~4 times of the maximum rated input current of AC motor
drive.
3-phase 230V
Model
VFD007C23A
VFD015C23A
VFD022C23A
VFD037C23A
VFD055C23A
VFD075C23A
VFD110C23A
VFD150C23A
VFD185C23A
VFD220C23A
VFD300C23A/E
VFD370C23A/E
VFD450C23A/E
VFD550C23A/E
VFD750C23A/E
VFD900C23A/E

Recommended
non-fuse breaker (A)
15
20
30
40
50
60
100
125
150
200
225
250
300
400
450
600

3-phase 460V
Model
VFD007C43A/E
VFD015C43A/E
VFD022C43A/E
VFD040C43A/E
VFD037C43A/E
VFD055C43A/E
VFD075C43A/E
VFD110C43A/E
VFD150C43A/E
VFD185C43A/E
VFD220C43A/E
VFD300C43A/E
VFD370C43A/E/S/U
VFD450C43A/E/S/U
VFD550C43A/E
VFD750C43A/E
VFD900C43A/E
VFD1100C43A/E
VFD1320C43A/E
VFD1600C43A/E
VFD1850C43A/E
VFD2200C43A/E
VFD2800C43A/E
VFD3150C43A/E
VFD3550C43A/E

7-5

Recommended
non-fuse breaker(A)
5
10
15
20
20
30
40
50
60
75
100
125
150
175
250
300
300
400
500
600
600
800
1000
1200
1350

Chapter 7 Optional Accessories C2000 Series

7-3 Fuse Specification Chart
 Use only the fuses comply with UL certificated.
 Use only the fuses comply with local regulations.
230V Model
VFD007C23A
VFD015C23A
VFD022C23A
VFD037C23A
VFD055C23A
VFD075C23A
VFD110C23A
VFD150C23A
VFD185C23A
VFD220C23A
VFD300C23A/E
VFD370C23A/E
VFD450C23A/E
VFD550C23A/E
VFD750C23A/E
VFD900C23A/E

460VModel

Input Current I(A)
Heavy Duty
Normal Duty
6.1
11
15
18.5
26
34
50
68
78
95
118
136
162
196
233
315

6.4
12
16
20
28
36
52
72
83
99
124
143
171
206
245
331

Input Current I(A)
Heavy Duty
Normal Duty

Line Fuse
I (A)

Bussmann P/N

20
35
50
80
100
130
175
250
300
350
400
500
700
800
1000
1000

JJS-20
JJS-35
JJS-50
JJS-80
JJS-100
JJS-130
JJS-175
JJS-250
JJS-300
JJS-350
DLS-R-400
DLS-R-500
JJN-700
JJN-800
JJN-1000
KTU-1000

Line Fuse
I (A)

Bussmann P/N

VFD007C43A/E
4.1
4.3
10
JJS-10
VFD015C43A/E
5.6
5.9
15
JJS-15
VFD022C43A/E
8.3
8.7
20
JJS-20
VFD037C43A/E
13
14
30
JJS-30
VFD040C43A/E
14.5
15.5
35
JJS-35
VFD055C43A/E
16
17
45
JJS-45
VFD075C43A/E
19
20
70
JJS-70
VFD110C43A/E
25
26
90
JJS-90
VFD150C43A/E
33
35
125
JJS-125
VFD185C43A/E
38
40
125
JJS-125
VFD220C43A/E
45
47
150
JJS-150
VFD300C43A/E
60
63
200
JJS-200
VFD370C43/S/U
70
74
300
DLS-R-300
VFD450C43/S/U
96
101
350
DLS-R-350
VFD550C43A/E
108
114
400
DLS-R-400
VFD750C43A/E
149
157
600
DLS-R-600
VFD900C43A/E
159
167
600
JJN-600
VFD1100C43A/E
197
207
800
JJS-800
VFD1320C43A/E
228
240
800
KTU-800
VFD1600C43A/E
285
300
800
KTU-800
VFD1850C43A/E
361
380
800
KTU-800
VFD2200C43A/E
380
400
1000
KTU-1000
VFD2800C43A/E
469
494
1200
KTU-1200
VFD3150C43A/E
527
555
1200
KTU-1200
VFD3550C43A/E
594
625
1600
KTU-1600
＊ Contact Delta Electronics or an authorized distributor for corresponding fuse of VFD4500C43A/E

7-6

Chapter 7 Optional AccessoriesC2000 Series

7-4 AC/DC Reactor
When the AC Motor Drive is connected directly to a large-capacity power transformer
(600kVA or above) or when a phase lead capacitor is switched, excess peak currents may
occur in the power input circuit due to the load changes and the converter section may be
damaged. To avoid this, it is recommend to use a serial connected AC input reactor (3%) at
the AC Motor Drive mains input side to reduce the current and improve the input power
efficiency.

AC Input/output Reactor
200V~230V/ 50~60Hz
Type KW

Rated Amps
3%
Max. continuous
HP of AC Reactor
impedance
Amps (Arms)
(Arms)
(mH)

5%
3%
Built-in
impedance
Input AC reactor
DC reactor
(mH)
Delta part #

007 0.75

1

5

8.64

2.536

4.227

X

N/A

015

1.5

2

8

12.78

1.585

2.642

X

N/A

022

2.2

3

11

18

1.152

1.922

X

N/A

037

3.7

5

17

28.8

0.746

1.243

X

N/A

055

5.5

7.5

25

43.2

0.507

0.845

X

N/A

075

7.5

10

33

55.8

0.32

0.534

X

DR033AP320

110

11

15

49

84.6

0.216

0.359

X

DR049AP215

150

15

20

65

111.6

0.163

0.271

X

DR065AP162

185 18.5

25

75

127.8

0.169

0.282

X

N/A

220

22

30

90

154.8

0.141

0.235

X

N/A

300

30

40

120

205.2

0.106

0.176

O

N/A

370

37

50

146

250.2

0.087

0.145

O

N/A

450

45

60

180

307.8

0.070

0.117

O

N/A

550

55

75

215

367.2

0.059

0.098

O

N/A

750

75

100

255

435.6

0.049

0.083

O

N/A

900

90

125

346

592.2

0.037

0.061

O

N/A

380V~460V/ 50~60Hz
Type KW

Rated Amps
3%
Max. continuous
HP of AC Reactor
impedance
Amps (Arms)
(Arms)
(mH)

5%
3%
Built-in
impedance
Input AC reactor
DC reactor
(mH)
Delta part #

007 0.75

1

3

5.22

8.102

13.502

X

N/A

015

1.5

2

4

6.84

6.077

10.127

X

N/A

022

2.2

3

6

10.26

4.050

6.752

X

N/A

037

3.7

5

9

14.58

2.700

4.501

X

N/A

040

4

5

10.5

17.1

2.315

3.858

X

N/A

055

5.5

7.5

12

19.8

2.025

3.375

X

N/A

075

7.5

10

18

30.6

1.174

1.957

X

DR018A0117

110

11

15

24

41.4

0.881

1.468

X

DR024AP880

150

15

20

32

54

0.66

1.101

X

DR032AP660

7-7

Chapter 7 Optional Accessories C2000 Series
Type KW

Rated Amps
3%
Max. continuous
HP of AC Reactor
impedance
Amps (Arms)
(Arms)
(mH)

5%
3%
Built-in
impedance
Input AC reactor
DC reactor
(mH)
Delta part #

185 18.5

25

38

64.8

0.639

1.066

X

N/A

220

22

30

45

77.4

0.541

0.900

X

N/A

300

30

40

60

102.6

0.405

0.675

O

N/A

370

37

50

73

124.2

0.334

0.555

O

N/A

450

45

60

91

154.8

0.267

0.445

O

N/A

550

55

75

110

189

0.221

0.368

O

N/A

750

75

100

150

257.4

0.162

0.270

O

N/A

900

90

125

180

307.8

0.135

0.225

O

N/A

1100 110

150

220

376.2

0.110

0.184

O

N/A

1320 132

175

260

444.6

0.098

0.162

O

N/A

1600 160

215

310

531

0.078

0.131

O

N/A

1850 185

250

370

633.6

0.066

0.109

O

N/A

2200 220

300

460

786.6

0.054

0.090

O

N/A

2800 280

375

550

941.4

0.044

0.074

O

N/A

3150 315

420

616

1053

0.039

0.066

O

N/A

3550 355

475

683

1168.2

0.036

0.060

O

N/A

4500 450

600

866

1468.8

0.028

0.047

O

N/A

DC Reactor
200V~230V/ 50~60Hz
Type

kW

HP

Rated Amps of AC Reactor

Max. continuous Amps

Inductance（mh）

007

0.75

1

5

8.64

5.857

015

1.5

2

8

12.78

3.660

022

2.2

3

11

18

2.662

037

3.7

5

17

28.8

1.722

055

5.5

7.5

25

43.2

1.172

075

7.5

10

33

55.8

0.851

110

11

15

49

84.6

0.574

150

15

20

65

111.6

0.432

185

18.5

25

75

127.8

0.391

220

22

30

90

154.8

0.325

380V~460V/ 50~60Hz
Type

kW

HP

Rated Amps of AC Reactor

Max. continuous Amps

Inductance（mh）

007

0.75

1

3

5.22

18.709

015

1.5

2

4

6.84

14.031

022

2.2

3

6

10.26

9.355

037

3.7

5

9

14.58

6.236

040

4

5

10.5

17.1

5.345

7-8

Chapter 7 Optional AccessoriesC2000 Series
Type

kW

HP

Rated Amps of AC Reactor

Max. continuous Amps

Inductance（mh）

055

5.5

7.5

12

19.8

4.677

075

7.5

10

18

30.6

3.119

110

11

15

24

41.4

2.338

150

15

20

32

54

1.754

185

18.5

25

38

64.8

1.477

220

22

30

45

77.4

1.247

THD
Motor Drive

Without Built-in DC Reactor

Spec

With Built in DC Reactor

3% Input

5% Input

4%

3% Input

5% Input

AC Reactor

AC Reactor

DC Reactor

AC Reactor

AC Reactor

5th

38.5%

30.8%

25.5%

27.01%

25.5%

7th

15.3%

9.4%

18.6%

9.54%

8.75%

11th

7.1%

6.13%

7.14%

4.5%

4.2%

13th

3.75%

3.15%

0.48%

0.22%

0.17%

THDi

43.6%

34.33%

38.2%

30.5%

28.4%

Reactor Spec.

Note:

THDi may have some difference due to different installation conditions and environment

According to IEC61000-3-12, DC Reactor is designed with 4% system impedance, and AC Reactor is designed
with 3% system impedance.

7-9

Chapter 7 Optional Accessories C2000 Series

C

B

G

7-5 Zero Phase Reactors

D
A

F

E

UNIT: mm(inch)
model
RF008X00A
RF004X00A

A

B

C

D

E

F

98
(3.858)
110
(4.331)

73
(2.874)
87.5
(3.445)

36.5
(1.437)
43.5
(1.713)

29
(1.142)
36
(1.417)

56.5
(2.224)
53
(2.087)

86
(3.386)
96
(3.780)

G(Ø)
5.5
(0.217)
5.5
(0.217)

Torque
< 10kgf/cm2
< 10kgf/cm2

C

H

B

G

F
D

E
UNIT: mm(inch)

model
RF002X00A

A
200
(7.874)

B
172.5
(6.791)

C
90
(3.543)

D
78
(3.071)

E
55.5
(2.185)

F
184
(7.244)

G(Ø)
5.5
(0.217)

H
22
(0.866)

Torque
<45kgf/cm2

UNIT: mm(inch)
model

A

B

C

D

E

F

G(Ø)

H

I

RF300X00A 241(9.488) 217(8.543) 114(4.488) 155(6.102) 42(1.654) 220(8.661) 6.5(0.256) 7.0(0.276) 20(0.787)

7-10

Chapter 7 Optional AccessoriesC2000 Series
Reactor
model (Note)

Recommended Wire Size

Wiring
Method

Qty

Corresponding motor drives
VFD007C23A; VFD015C23A; VFD022C23A;

RF008X00A

≦8 AWG

≦8.37 mm2

Diagram A

1

VFD037C23A; VFD007C43A; VFD015C43A;
VFD022C43A; VFD037C43A; VFD040C43A
VFD055C43A
VFD055C23A; VFD075C23A; VFD110C23A;

RF004X00A

≦4 AWG

2

≦21.15 mm

Diagram A

1

VFD110C43A; VFD150C43A; VFD075C43A;
VFD110C43A; VFD150C43A
VFD150C23A; VFD185C23A; VFD220C23A;

RF002X00A

≦2 AWG

≦33.62 mm2

Diagram A

1

VFD300C23A; VFD370C23A; VFD185C43A;
VFD220C43A; VFD300C43A; VFD370C43A;
VFD450C43A; VFD550C43A; VFD750C43A
VFD450C23A; VFD550C23A; VFD750C23A;
VFD900C23A; VFD900C43A; VFD1100C43A;

RF300X00A

≦300 MCM

≦152 mm

2

Diagram A

1

VFD1320C43A; VFD1600C43A; VFD1850C43A;
VFD2200C43A; VFD2800C43A; VFD3150C43A;
VFD3550C43A; VFD4500C43A

Note: 600V insulated cable wire

Diagram A
Please put all wires through at least one core without winding.
Zero Phase Reactor

R/L1

U/T1

S/L2

V/T1

T/L3

W/T1

MOTOR

Note 1: The table above gives approximate wire size for the zero phase reactors but the selection is ultimately
governed by the type and diameter of cable fitted i.e. the cable must fit through the center hole of zero phase
reactors.
Note 2: Only the phase conductors should pass through, not the earth core or screen.
Note3: When long motor output cables are used an output zero phase reactor may be required to reduce radiated
emissions from the cable.

7-11

Chapter 7 Optional Accessories C2000 Series

7-6 EMI Filter
CE Cable Length
Model

input
Current

Applicable EMI
Filter

Zero Phase
Reactor

default carrier frequency

Radiation
Emission
default carrier
frequency

EN61800-3
C1

EN61800-3
C2

EN61800-3
C2

50m

100m

Pass

50m

100m

Pass

50m

100m

Pass

VFD007C23A

6.4A

VFD015C23A

12A

VFD022C23A

16A

VFD037C23A

20A

50m

100m

Pass

VFD055C23A

28A

50m

100m

Pass

VFD075C23A

36A

50m

100m

Pass

VFD110C23A

52A

50m

100m

Pass

VFD150C23A

76A

50m

100m

Pass

VFD185C23A

83A

50m

100m

Pass

VFD220C23A

99A

50m

100m

Pass

VFD300C23A

124A

50m

100m

Pass

VFD370C23A

143A

50m

100m

Pass

VFD450C23A

171A

50m

100m

Pass

VFD550C23A

206A

50m

100m

Pass

VFD750C23A

245A

50m

100m

Pass

VFD900C23A

331A

50m

100m

Pass

VFD007C43A

4.3A

50m

100m

Pass

VFD015C43A

5.9A

50m

100m

Pass

VFD022C43A

8.7A

50m

100m

Pass

VFD037C43A

14A

50m

100m

Pass

VFD040C43A

15.5A

50m

100m

Pass

VFD055C43A

17A

50m

100m

Pass

VFD075C43A

20A

50m

100m

Pass

VFD110C43A

26A

50m

100m

Pass

VFD150C43A

35A

50m

100m

Pass

VFD185C43A

40A

50m

100m

Pass

VFD220C43A

47A

50m

100m

Pass

VFD300C43A

63A

50m

100m

Pass

VFD370C43A

74A

50m

100m

Pass

VFD450C43A

101A

50m

100m

Pass

VFD550C43A

114A

50m

100m

Pass

VFD750C43A

157A

50m

100m

Pass

EMF021A23A

EMF056A23A

RF008X00A

RF004X00A

KMF3100A
RF002X00A
B84143D0150R127

B84143B0250S020

RF300X00A

B84143B0400S020
EMF014A43A
RF008X00A
EMF018A43A

EMF039A43A

RF004X00A

KMF370A
RF002X00A
B84143D0150R127

7-12

Chapter 7 Optional AccessoriesC2000 Series
CE Cable Length
Model

input
Current

VFD900C43A

167A

VFD1100C43A

207A

VFD1320C43A

240A

VFD1600C43A

300A

VFD1850C43A

380A

VFD2200C43A

400A

VFD2800C43A

494A

VFD3150C43A

555A

VFD3550C43A

625A

VFD4500C43A

866A

Applicable EMI
Filter

Zero Phase
Reactor

B84143D0200R127

MIF3400B
RF300X00A

MIF3800
B84143B1000S020

default carrier frequency

Radiation
Emission
default carrier
frequency

EN61800-3
C1

EN61800-3
C2

EN61800-3
C2

50m

100m

Pass

50m

100m

Pass

50m

100m

Pass

50m

100m

Pass

50m

100m

Pass

50m

100m

Pass

50m

100m

Pass

50m

100m

Pass

50m

100m

Pass

50m

100m

Pass

EMI Filter Installation
All electrical equipment, including AC motor drives, will generate high-frequency/low-frequency noise and will
interfere with peripheral equipment by radiation or conduction when in operation. By using an EMI filter with correct
installation, much interference can be eliminated. It is recommended to use DELTA EMI filter to have the best
interference elimination performance.
We assure that it can comply with following rules when AC motor drive and EMI filter are installed and wired
according to user manual:

EN61000-6-4

EN61800-3: 1996

EN55011 (1991) Class A Group 1 (1st Environment, restricted distribution)

General precaution
1.
2.
3.
4.
5.

EMI filter and AC motor drive should be installed on the same metal plate.
Please install AC motor drive on footprint EMI filter or install EMI filter as close as possible to the AC motor drive.
Please wire as short as possible.
Metal plate should be grounded.
The cover of EMI filter and AC motor drive or grounding should be fixed on the metal plate and the contact area
should be as large as possible.

Choose suitable motor cable and precautions
Improper installation and choice of motor cable will affect the performance of EMI filter. Be sure to observe the
following precautions when selecting motor cable.
1. Use the cable with shielding (double shielding is the best).
2. The shielding on both ends of the motor cable should be grounded with the minimum length and maximum
contact area.
3. Remove any paint on metal saddle for good ground contact with the plate and shielding.

7-13

Chapter 7 Optional Accessories C2000 Series
Remove any paint on metal saddle for good ground contact with
the plate and shielding.

saddle

the plate with grounding

Figure 1

Saddle on both ends

Saddle on one end
Figure 2

The length of motor cable
When motor is driven by an AC motor drive of PWM type, the motor terminals will experience surge voltages
easily due to components conversion of AC motor drive and cable capacitance. When the motor cable is very long
(especially for the 460V series), surge voltages may reduce insulation quality. To prevent this situation, please follow
the rules below:
 Use a motor with enhanced insulation.
 Connect an output reactor (optional) to the output terminals of the AC motor drive
 The length of the cable between AC motor drive and motor should be as short as possible (10 to 20 m or less)
 For models 7.5hp and above:
Insulation level of motor

1000V

1300V

1600V

460VAC input voltage

66 ft (20m)

328 ft (100m)

1312 ft (400m)

230VAC input voltage

1312 ft (400m)

1312 ft (400m)

1312 ft (400m)

 For models 5hp and less:
Insulation level of motor

1000V

1300V

1600V

460VAC input voltage

66 ft (20m)

165 ft (50m)

165 ft (50m)

230VAC input voltage

328 ft (100m)

328 ft (100m)

328 ft (100m)

NOTE

Never connect phase lead capacitors or surge absorbers to the output terminals of the AC motor drive.

7-14

Chapter 7 Optional AccessoriesC2000 Series
 If the length is too long, the stray capacitance between cables will increase and may cause leakage current. It
will activate the protection of over current, increase leakage current or not insure the correction of current
display. The worst case is that AC motor drive may damage.
 If more than one motor is connected to the AC motor drive, the total wiring length is the sum of the wiring length
from AC motor drive to each motor.
 For the 460V series AC motor drive, when an overload relay is installed between the drive and the motor to
protect motor over heating, the connecting cable must be shorter than 50m. However, an overload relay
malfunction may still occur. To prevent the malfunction, install an output reactor (optional) to the drive or lower
the carrier frequency setting (Pr.00-17).
NOTE

When a thermal O/L relay protected by motor is used between AC motor drive and motor, it may malfunction
(especially for 460V series), even if the length of motor cable is only 165 ft (50m) or less. To prevent it, please use AC
reactor and/or lower the carrier frequency (Pr. 00-17 PWM carrier frequency).

7-15

Chapter 7 Optional Accessories C2000 Series

7-7 Digital Keypad
7-7-1 KPC-CE01

A : LED Disp lay
D ispla y freq uen cy, cu rre nt, vo ltag e and erro r etc.

: Status Indi cator
F: Fre que ncy C omma nd
H: Outp ut Frequ ency
U: User De fine d Uni ts
ERR: CAN Erro r Ind icator
RU N: CAN Ru n Indi ca tor

C : Function

(Re fer to the chart foll ow s for deta il de scripti on )

Key

Description

ESC

ESC Key
Press ESC key to return to the previous page. It also functions as a return to last category key in the sub-menu.
Menu Key
Press MENU key under any condition will return to the main MENU.
Menu content:
1. Parameter Detail
3. Keypad locked
2. Copy Parameter
4. PLC Function
ENTER Key
Press ENTER and go to the next level. If it is the last level then press ENTER to execute the command.
HAND ON Key
1. HAND key will operates according to the parameter settings when the source of HAND master frequency
command and the source of HAND operation command is properly set,. The factory setting of the source
command for frequency and operation are from the digital keypad .
2. Press HAND key in stop status, the drive setting switches to the parameter setting of HAND. Press HAND
key in during operation, the drive will come to stop then switches to the parameter setting of HAND.
3. When process complete: H/A LED ON.
Auto Operation Key
1. AUTO function executes according to the parameter settings of the source of AUTO frequency and AUTO
operation. The factory setting is the external terminal (source of operation is 4-20mA).
2. Press the ATUO key in stop status, the drivel switches to auto-setting. Press the auto key during operation
status, the drivel will come to stop and switch to auto-setting.
3. When process complete: H/A LED is OFF
Operation Direction Key
1. FWD/REV key controls the operation direction but will NOT activate the drive. FWD: forward, REV: reverse.
2. The drive operates in the direction as shown by the LED light.
Start Key
1. This button is functional only when the keypad is the source of the command.
2. This button allows the motor drive to run by following its settings. See Description of LED functions for LED
status
3. Press repeatedly the “RUN” button is allow while the motor drive is stopping.
Stop Key.
1. STOP key has the highest priority in command.
2. Press STOP key, the drive will come to stop under any condition.
3. The RESET key can be used to reset the drive when faults occur. If the RESET key is not responding, check
MENU  Fault Records and check the most recent fault.

MENU

ENTER
HAND

AUTO

FWD/REV
RUN

STOP

7-16

Chapter 7 Optional AccessoriesC2000 Series

Descriptions of LED Functions
LED

Descriptions
Steady ON: operation indicator of the AC motor drive, including DC brake, zero speed, standby,
restart after fault and speed search.
Blinking: drive is decelerating to stop or in the status of base block.
Steady OFF: drive doesn’t execute the operation command
Steady ON: stop indicator of the AC motor drive.
Blinking: drive is in the standby status.
Steady OFF: drive doesn’t execute “STOP” command.
Operation Direction LED 『Green light= Forward』；
『Red light= Reversely』
Steady ON: the drive is running forward.
Blinking: the drive is changing direction.
Steady Off: the drive is running reversely.
RUN (Green light):
LED
status
OFF
CANopen at initial

Condition/State
No LED

Blinking CANopen at pre-operation
CANopen ~”RUN”
Single
flash

ON

CANopen at stopped

CANopen at operation status
No LED

ERR (Red light):
LED
status
OFF
Single One message fail
flash

CANopen ~”ERR”

Double
flash

Triple
flash

Condition/ State
No Error

Guarding fail or heartbeat fail

SYNC fail

ON

Bus off

7-17

Chapter 7 Optional Accessories C2000 Series

7-7-2 Dimension

7-7-3 RJ45 Extension Lead for Digital Keypad
Part #

Description

CBC-K3FT

3 feet RJ45 extension lead (approximately 0.9m)

CBC-K5FT

5 feet RJ45 extension lead (approximately 1.5 m)

CBC-K7FT

7 feet RJ45 extension lead (approximately 2.1 m)

CBC-K10FT

10 feet RJ45 extension lead (approximately 3 m)

CBC-K16FT

16 feet RJ45 extension lead (approximately 4.9 m)

7-18

Chapter 7 Optional AccessoriesC2000 Series

7-8 Panel Mounting (MKC-KPPK)
For MKC-KPPK model, user can choose wall mounting or embedded mounting, protection level is IP56.
Applicable to the digital keypads (KPC-CC01 & KPC-CE01).

Wall Mounting

Embedded Mounting

accessories*1

accessories*2

Screw *4 ~M4*p 0.7 *L8mm
Torque: 10-12kg-cm (8.7-10.4lb-in.)
Panel cutout dimension
Unit: mm [inch]

Screw *4 ~M4*p 0.7 *L8mm
Torque: 10-12kg-cm (8.7-10.4lb-in.)

Panel cutout dimension

Unit: mm [inch]

Normal cutout dimension
Panel
1.2mm
1.6mm
2.0mm
thickness
A
66.4 [2.614]
B
110.2 [4.339] 111.3 [4.382] 112.5 [4.429]
*Deviation: ±0.15mm /±0.0059inch

Cutout dimension (Waterproof level: IP56)
Panel
1.2mm
1.6mm
2.0mm
thickness
A
66.4 [2.614]
B

110.8 [4.362]
*Deviation: ±0.15mm /±0.0059inch

7-19

Chapter 7 Optional Accessories C2000 Series

7-20

Chapter 7 Optional AccessoriesC2000 Series

7-9 Conduit Box Kit


Appearance

Frame D0
Applicable models
VFD370C43S/43U; VFD450SC43S/43U;

Frame D
Applicable models

Model number『MKC-D0N1CB』

Model number『MKC-DN1CB』

ITEM
Description
1 Screw M5*0.8*10L
2 Bushing Rubber 28
3 Bushing Rubber 44
4 Bushing Rubber 73
5 Conduit box cover
6 Conduit box base

ITEM
Description
1 Screw M5*0.8*10L
2 Bushing Rubber 28
3 Bushing Rubber 44
4 Bushing Rubber 88
5 Conduit box cover
6 Conduit box base

Qty.
4
2
2
2
1
1

VFD300C23A/23E; VFD370C23A/23E;VFD370C43A/43E;
VFD450C43A/43E; VFD550C43A/43E; VFD750C43A/43E
Qty.
4
2
2
2
1
1

Frame E
Applicable models

Frame F
Applicable models

VFD450C23A/23E; VFD550C23A/23E; VFD750C23A/23E;
VFD900C43A/43E; VFD1100C43A/43E

VFD900C23A/23E; VFD1320C43A/43E; VFD1600C43A/43E

Model number『MKC-EN1CB』

Model number『MKC-FN1CB』

ITEM
Description
Qty.
1 Screw M5*0.8*10L
6
2 Bushing Rubber 28
2
3 Bushing Rubber 44
4
4 Bushing Rubber 100 2
5 Conduit box cover
1
6 Conduit box base
1

ITEM
Description
Qty.
1 Screw M5*0.8*10L
8
2 Bushing Rubber28
2
3 Bushing Rubber 44
4
4 Bushing Rubber 100 2
5 Conduit box cover
1
6 Conduit box base
1

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Chapter 7 Optional Accessories C2000 Series
Frame G
Applicable models
VFD1850C43A/43E; VFD2200C43A/43E

Model number『MKC-GN1CB』
ITEM
Description
Qty.
1 Screw M5*0.8*10L
12
2 Bushing Rubber 28
2
3 Bushing Rubber 44
2
4 Bushing Rubber 130 3
5 Conduit box cover
1
6 Conduit box base
1

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Chapter 7 Optional AccessoriesC2000 Series


Conduit Box Installation

Frame D0
1.
Loosen the cover screws and press the tabs on each side of the cover to remove the cover, as shown in the
following figure. Screw torque: 12~15kg-cm (10.4~13 Ib-in)

2.

Remove the 5 screws shown in the following figure. Screw torque:24~26kg-cm (20.8~22.6Ib-in)

3.

Install the conduit box by fasten the 5 screws shown in the following figure.
Screw torque:24~26kg-cm (20.8~22.6Ib-in)

4.

Fasten the 2 screws shown in the following figure. Screw torque: 12~15kg-cm (10.4~13 Ib-in)

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Chapter 7 Optional Accessories C2000 Series
Frame D
1.
Loosen the cover screws and press the tabs on each side of the cover to remove the cover, as shown in the
following figure. Screw torque: 12~15kg-cm (10.4~13 Ib-in)

2.

Remove the 5 screws shown in the following figure. Screw torque:24~26kg-cm (20.8~22.6Ib-in)

3.

Install the conduit box by fasten the 5 screws shown in the following figure.
Screw torque:24~26kg-cm (20.8~22.6Ib-in)

4.

Fasten the 2 screws shown in the following figure. Screw torque: 12~15kg-cm (10.4~13 Ib-in)

7-24

Chapter 7 Optional AccessoriesC2000 Series
Frame E
1. Loosen the 4 cover screws and lift the cover; Screw torque: 12~ 15 kg-cm (10.4~13Ib-in).

2. Fasten the 6 screws shown in the following figure and place the cover back to the original position. Screw
torque: 24~26kg-cm (20.8~22.6Ib-in).

3. Fasten the 4 screws shown in the following figure. Screw torque:12~15kg-cm (10.4~13Ib-in)』

7-25

Chapter 7 Optional Accessories C2000 Series
Frame F
1.

Loosen the cover screws and press the tabs on each side of the cover to remove the cover, as shown in the
following figure. Screw torque: 12~15kg-cm (10.4~13 Ib-in).

4

1
2

3

2.

Install the conduit box by fastens the 4 screws, as shown in the following figure.
Screw torque: 24~26kg-cm (20.8~22.6Ib-in).

5
7

8
6

3.

Install the conduit box by fasten all the screws shown in the following figure
Screw 9~12 torque: 12~15kg-cm (10.4~13.6Ib-in)
Screw 13~16 torque: 24~26kg-cm (20.8~22.6Ib-in)

12

15
9
10

13
14
16

11

7-26

Chapter 7 Optional AccessoriesC2000 Series
Frame G
1.
On the conduit box, loosen 7 of the cover screws and remove the cover「Screw torque: 24~26kg-cm
(20.8~22.6Ib-in)」. On the drive, loosen 4 of the cover screws and press the tabs on each side of the cover to
remove the cover, as shown in the following figure. Screw torque: 12~15kg-cm (10.4~13Ib-in).

4

1
2

3

Remove the top cover and loosen the screws.
M5 Screw torque: 24~26kg-cm (20.8~22.6Ib-in)
M8 Screw torque: 100~120kg-cm (86.7~104.1Ib-in)

2.

Install the conduit box by fastening all the screws shown in the following figure.
M5 Screw torque: 24~26kg-cm (20.8~22.6Ib-in)
M8 Screw torque: 100~120kg-cm (86.7~104.1Ib-in)

7-27

Chapter 7 Optional Accessories C2000 Series
Fasten all the screws. Screw torque: 24~26kg-cm (20.8~22.6Ib-in).

Place the cover back to the top and fasten the screws (as shown in the figure).
Screw torque: 12~15kg-cm (10.4~13Ib-in).

7-28

Chapter 7 Optional AccessoriesC2000 Series

7-10 Fan Kit


Frames of the fan kit

Frame A

Heat sink Fan Model『MKC-AFKM』

Applicable Model
VFD015C23A; VFD022C23A; VFD037C23A;VFD022C43A/43E;
VFD037C43A/43E;VFD040C43A/43E; VFD055C43A/43E

Frame B

Heat sink Fan Model『MKC-BFKM1』

Applicable Model
VFD055C23A; VFD075C43A/43E

Frame B

Heat sink Fan Model 『MKC-BFKM2』

Applicable Model
VFD075C23A; VFD110C23A; VFD110C43A/43E;
VFD150C43A/43E

Frame B

Capacitor Fan Model 『MKC-BFKB』

Applicable Model
VFD055C23A; VFD075C23A; VFD110C23A;VFD075C43A/43E;
VFD110C43A/43E;VFD150C43A/43E

7-29

Chapter 7 Optional Accessories C2000 Series
Frame C

Capacitor Fan Model 『MKC-CFKB1』

Applicable Model
VFD150C23A; VFD185C23A; VFD220C23A

Frame C

Capacitor Fan Model 『MKC-CFKB2』

Applicable Model
VFD185C43A/43E; VFD220C43A/43E;VFD300C43A/43E

Frame C

Heat sink Fan 『MKC-CFKM』

Following Model use one set of MKC-CFKM:
VFD185C43A/E; VFD220C43A/E; VFD300C43A
Following Model use two sets of MKC-CFKM
VFD150C23A; VFD185C23A; VFD220C23A; VFD300C43E

Frame D0

Heat sink Fan Model
『MKC-D0FKM』

Capacitor Fan Model
『MKC-DFKB』

Heat sink Fan Model
『MKC-DFKM』

Capacitor Fan Model
『MKC-DFKB』

Applicable Model
VFD370C43S/43U; VFD450C43S/43U;

Frame D
Applicable Model
VFD300C23A/23E; VFD370C23A/23E; VFD370C43A/43E;
VFD450C43A/43E; VFD550C43A/43E; VFD750C43A/43E

7-30

Chapter 7 Optional AccessoriesC2000 Series
Frame E

Heat sink Fan Model 『MKC-EFKM1』

Applicable Model
VFD450C23A/23E; VFD550C23A/23E

Frame E

Heat sink Fan Model『MKC-EFKM2』

Applicable Model
VFD750C23A/23E; VFD900C43A/43E; VFD1100C43A/43E

Frame E

Capacitor Fan Model 『MKC-EFKB』

Applicable Model
VFD450C23A/23E; VFD550C23A/23E; VFD750C23A/23E;
VFD900C43A/43E; VFD1100C43A/43E

Frame F

Heat sink Fan Model 『MKC-FFKM』

Applicable Model
VFD900C23A/23E; VFD1320C43A/43E; VFD1600C43A/43E
;

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Chapter 7 Optional Accessories C2000 Series
Frame F

Capacitor Fan Model 『MKC-FFKB』

Applicable Model
VFD900C23A/23E; VFD1320C43A/43E; VFD1600C43A/43E

Frame G

Heat sink Fan Model 『MKC-GFKM』

Applicable Model
VFD1850C43A/43E; VFD2200C43A/43E

Frame H

Heat sink Fan Model 『MKC-HFKM』

Applicable Model
VFD2800C43A/43E; VFD3150C43A/43E; VFD3550C43A/43E;
VFD4500C43A/43E
VFD2800C43E-1; VFD3150C43E-1; VFD3550C43E-1;
VFD4500C43E-1

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Chapter 7 Optional AccessoriesC2000 Series


Fan Removal

Frame A
Model『MKC-AFKM』: Heat Sink Fan
Applicable model
VFD015C23A; VFD022C23A; VFD022C43A/43E; VFD037C23A; VFD037C43A/43E; VFD040C43A/43E; VFD055C43A/43E
1. Refer to Figure 1, press the tabs on both side of the fan to 2. Disconnect the power terminal before removing the fan.
successfully remove the fan.
(As shown below.)

Figure 2

Figure 1
Frame B
Model『MKC-BFKM1』Heat Sink Fan
Applicable model
VFD055C23A; VFD075C43A/43E;VFD075C23A;
1. Refer to Figure 1, press the tab on both side of the fan to
successfully remove the fan.

2.

Disconnect the power terminal before removing the fan.
(As shown below.)

Figure 2

Figure 1
Frame B
Model『MKC-BFKM2』Heat Sink Fan

Applicable model
VFD075C23A; VFD110C23A; VFD110C43A/43E; VFD150C43A/43E
1. Refer to Figure 1, press the tab on both side of the fan to
2. Disconnect the power terminal before removing the fan.
successfully remove the fan.
(As shown below.)

Figure 1

Figure 2

7-33

Chapter 7 Optional Accessories C2000 Series
Frame B
Model『MKC-BFKB』Capacitor Fan
Applicable model
VFD055C23A; VFD075C23A; VFD075C43A/43E; VFD110C23A; VFD110C43A/43E;
VFD150C43A/43E
Disconnect fan power and pull out the fan by using flathead screwdriver. (As shown in the larger picture)

Frame C
Model『MKC-CFKM』Heat Sink Fan
Applicable model
Single fan kit applicable models (only fan kit 1 is required to be installed): VFD185C43A/E; VFD220C43A/E; VFD300C43A
Duo fan kit applicable models (both fan kit 1 and 2 are required to be installed): VFD150C23A; VFD185C23A; VFD220C23A;
VFD300C43E
1.

(As shown Figure 1) Before removing the fan, remove the cover by using a slotted screwdriver.

Figure 1

7-34

Chapter 7 Optional AccessoriesC2000 Series
2.

(As shown in Figure 2), remove the power connector, loosen the screw and remove the fan kit. When installing the fan kit,
have the label on the fan kit facing inside of the motor drive.
Screw’s torque force: 10~12kgf-cm (8.7~10.4(lb-in)

Figure 2
Frame C
Model『MKC-CFKB1』Capacitor Fan
Applicable model
VFD150C23A; VFD185C23A; VFD220C23A
Model『MKC-CFKB2』Capacitor Fan
Applicable model
VFD185C43A/43E; VFD220C43A/43E; VFD300C43A/43E
Disconnect fan power and pull out the fan by using flathead screwdriver. (As shown in the larger picture)

Figure 1

7-35

Chapter 7 Optional Accessories C2000 Series
Frame D0
Model 『MKC-DFKB』Capacitor Fan
Applicable model
VFD370C43S/43U; VFD450C43S/43U;
1. Loosen screw 1 and screw 2, press the tab on the right and 2.
left to remove the cover, follow the direction the arrows
indicate. Press on top of digital keypad to properly remove
it. Screw 1, 2『Torque :12~15kgf-cm (8.6~10.4lb-in)』

(Figure 2) Loosen screw 3, press the tab on the right and
the left to remove the cover. Screw 3『Torque : 6~8kgf-cm
(5.2~6.9lb-in)』

3

1
2

Figure 2

Figure 1
3.

Loosen screw 4 (figure 3) and disconnect fan power and
pull out the fan. (As shown in the enlarged picture 3)
Screw 4『Torque : 10~12kgf-cm (8.6~10.4lb-in)』

4

Figure 3
Frame D0
Model 『MKC-D0FKM』Heat Sink Fan
Applicable model
VFD370C43S/43U; VFD450C43S/43U;
1. Loosen the screw and remove the fan kit. 『Screw torque: 24~26kgf-cm (20.8~22.6lb-in)』
2. (As shown Figure 1) Before removing the fan, remove the cover by using a slotted screwdriver.

1
2
3
4

Figure 1

7-36

Chapter 7 Optional AccessoriesC2000 Series
Frame D
Model 『MKC-DFKB』Capacitor Fan
Applicable model
VFD300C23A/23E; VFD370C23A/23E; VFD550C43A/43E; VFD750C43A/43E;
1.

Loosen screw 1 and screw 2, press the on the right and the 2.
left to remove the cover, follow the direction the arrows
indicate. Press on top of digital keypad to properly remove
it. Screw 1, 2『Torque :12~15kgf-cm (10.4~13lb-in)』

(Figure 2) Loosen screw 3, press the tab on the right and
the left to remove the cover.
Screw 3, 4『Torque : 6~8kgf-cm (5.2~6.9lb-in)』

3

4

1
2

Figure 2

Figure 1
3.

Loosen screw 5 (figure 3) and disconnect fan power and pull out the fan. (As shown in the enlarged picture 3)
Screw 5『Torque :10~12kgf-cm (8.6~10.4lb-in)』

5

Figure 3
Frame D
Model『MKC-DFKM』Heat Sink Fan
Applicable model
VFD300C23A/23E; VFD370C23A/23E; VFD370C43A/43E; VFD450C43A/43E; VFD550C43A/43E; VFD750C43A/43E;
1.
2.

Loosen the screw and remove the fan kit. 『Screw torque: 24~26kgf-cm (20.8~22.6lb-in)』
(As shown Figure 1) Before removing the fan, remove the cover by using a slotted screwdriver.

1
2
3
4

Figure 1

7-37

Chapter 7 Optional Accessories C2000 Series
Frame E
Applicable model
VFD450C23A/23E; VFD550C23A/23E; VFD750C23A/23E; VFD900C43A/43E; VFD1100C43A/43E;
Model『MKC-EFKM1』Heat Sink Fan
1.

Model『MKC-EFKM2』Heat Sink Fan

Loosen screw 1~4 (figure 1) and disconnect fan power
1.
and pull out the fan. (As shown in the enlarged picture 3)
Screw1~4『Torque : 24~26kgf-cm (20.8~22.6lb-in)』

Loosen screw 1~4 (figure 2) and disconnect fan power
and pull out the fan. (As shown in the enlarged picture 3)
Screw1~4『Torque : 24~26kgf-cm (20.8~22.6lb-in)』

1

1

2

2
3

3

4

4

Figure 2

Figure 1
Model『MKC-EFKB』Capacitor Fan
1.

Loosen screw 1~2 (figure 3) and disconnect fan power and pull out the fan. (As shown in the enlarged picture 3)
Screw1~2『Torque : 24~26kgf-cm (20.8~22.6lb-in)』

1
2

Figure 3
Frame F
Applicable model
VFD900C23A/23E; VFD1320C43A/43E; VFD1600C43A/43E;
Fan model『MKC-FFKM』Heat Sink Fan
Loosen the screws and plug out the power of fan before removing (figure 1). Screw torque: 12~15kg-cm (10.4~13Ib-in)』

1
4

3
2

Figure 1

7-38

Chapter 7 Optional AccessoriesC2000 Series
Fan model 『MKC-FFKB』Capacitor Fan
(1) Loosen the screw (figure 1) and removes the cover.
torque: 14~16kg-cm (12.2~13.9Ib-in).

Screw (2) Loosen the screw (figure 2) and removes the cover. Screw
torque: 24~26kg-cm (20.8~22.6Ib-in).
7

5
8
4

6
1
3

2

Figure 1

Figure 2

(3) Loosen the screws and remove the fan. (figure 3 and figure 4) Screw torque: 24~26kg-cm (20.8~22.6Ib-in).

11
10
9

9

10

11

Figure 3

Figure 4

Frame G
Applicable model
VFD1800C43A/43E; VFD2200C43A/43E;
Fan model『MKC-GFKM』Heat Sink Fan
(1) Loosen the screw (figure 1) and remove the cover. Screw
torque: 12~15kg-cm (10.4~13Ib-in).

(2) For 1~8 shown in the figure 2: Loosen the screws
Screw torque:35~40kg-cm (30.4~34.7lb-in)
For 9~10 shown in the figure 2: Loosen the screws and
removes the cover.
Screw M4 torque: 14~16kg-cm (12.2~13.9 Ib-in).

9

4

1

10
6

3

7
8

2
1
4

2

3

5

Figure 1

Figure 2

7-39

Chapter 7 Optional Accessories C2000 Series
(3) Loosen screw 1,2,3 and remove the protective ring (as
(4) Lift the fan by putting your finger through the protective
holes, as indicates in 1 and 2 on the figure 4.
shown in figure 3) Screw torque: 14~16kg-cm (12.2~13.9 Ib-in).

4
1
2

5

1

3
2

.
Figure 4

Figure 3
Frame H
Applicable model
VFD2800C43A/43E; VFD3150C43A/43E; VFD3550C43A/43E; VD4500C43A/43E
Fan model 『MKC-HFKM』Heat Sink Fan
(1) Loosen the screw and remove the top cover (figure 1)
Screw torque: 14~16kg-cm (12.2~13.9Ib-in)

(2) Loosen the screw and remove the top cover (figure 2).
Screw torque: 24~26kg-cm (20.8~22.6Ib-in).

7

8
9
10
11
12

5
4

6
3
1

2

Figure 1

Figure 2

7-40

Chapter 7 Optional AccessoriesC2000 Series
(3) Disconnect the fan (figure 3).

(4) Loosen the screw and remove the fan. Make sure fan power
is properly disconnected before removal. Screw torque:
24~26kg-cm (20.8~22.6Ib-in). (figure 4)

15
15
14
13

Figure 3

18
17
16

14
13

Figure 4

7-41

18
17
16

Chapter 7 Optional Accessories C2000 Series

7-11 Flange Mounting Kit
Applicable Models, Frame A~F
Frame A
『MKC-AFM1』
Applicable model
VFD015C23A; VFD022C23A; VFD022C43A/43E

Screw 1 *4
M3*P 0.5; L=6mm
Screw 2*8
M6*P 1.0; L=16mm
Accessories 1*1

Accessories

2*2

Accessories 3*2

『MKC-AFM』
Applicable model
VFD007C23A; VFD007C43A/43E; VFD015C43A/43E; VFD037C23A; VFD037C43A/43E; VFD040C43A/43E;
VFD055C43A/43E

Screw *8
M6*P 1.0; L=16mm
Accessory 2*2

Accessory t 3*2

Cutout dimension

Unit: mm [inch]

7-42

Chapter 7 Optional AccessoriesC2000 Series

『MKC-AFM1』Installation
1.

Install accessory 1 by fastening 4 of the screw 1(M3) (figure 1). Screw torque: 6~8kg-cm (5.21~6.94Ib-in).

Figure 1

2.

Install accessory 2&3 by fastening 2 of the screw 2(M6) (figure 2). Screw torque: 25~30kg-cm (21.7~26Ib-in).

3.

Install accessory 2&3 by fastening 2 of the screw 2(M6) (figure 3). Screw torque: 25~30kg-cm (21.7~26Ib-in).

4.

Plate installation, place 4 of the screw 2 (M6) (figure 4) through accessory 2&3 and the plate then fasten the
screws. Screw torque: 25~30kg-cm (21.7~26Ib-in).

Figure 2

Figure 3

Figure 4

7-43

Chapter 7 Optional Accessories C2000 Series

『MKC-AFM』 Installation
1.

Fasten screw*2(M6) and accessory 2 &3. Screw torque: 25~30kg-cm (21.7~26Ib-in). (figure 1)

2.

Fasten screw*2(M6) and accessory 2 &3. Screw torque: 25~30kg-cm (21.7~26Ib-in). (figure 2)

3.

Plate installation, place 4 of the screw *4 (M6) through accessory 2&3 and the plate then fasten the screws.
Screw torque: 25~30kg-cm (21.7~26Ib-in). (figure 3)

Figure 1

Figure 2

Figure 3

7-44

Chapter 7 Optional AccessoriesC2000 Series

Frame B
『MKC-BFM』
Applicable model
VFD055C23A; VFD075C23A; VFD110C23A; VFD075C43A/43E; VFD110C43A/43E; VFD150C43A/43E

Screw 1 *4 ~ M8*P 1.25;
Screw 2*6 ~ M6*P 1.0;
Accessory 1*2

Accessory 2*2

Cutout dimension

Unit: mm [inch]

7-45

Chapter 7 Optional Accessories C2000 Series

『MKC-BFM』Installation
1.

Install accessory 1& 2 by fastening 4 of the screw 1(M8). Screw torque: 40~45kg-cm (34.7~39.0Ib-in).
(As shown in the following figure)

2.

Plate installation, place 6 of the screw 2 (M6) through accessory 1&2 and the plate then fasten the screws.
Screw torque: 25~30kg-cm (21.7~26Ib-in). (As shown in the following figure)

7-46

Chapter 7 Optional AccessoriesC2000 Series

Frame C
『MKC-CFM』
Applicable model
VFD150C23A; VFD185C23A; VFD220C23A; VFD185C43A/43E; VFD220C43A/43E; VFD300C43A/43E
Screw 1*4 ~ M8*P 1.25;
Screw 2*8 ~ M6*P 1.0;
Accessory 1*2

Accessory 2*2

Cutout dimension

Unit: mm [inch]

7-47

Chapter 7 Optional Accessories C2000 Series

『MKC-CFM』Installation
1.

Install accessory 1& 2 by fastening 4 of the screw 1(M8). Screw torque: 50~55kg-cm (43.4~47.7Ib-in).
(As shown in the following figure)

2.

Plate installation, place 8 of the screw 2 (M6) through Accessory 1&2 and the plate then fasten the screws.
Screw torque: 25~30kg-cm (21.7~26Ib-in). (As shown in the following figure)

7-48

Chapter 7 Optional AccessoriesC2000 Series

Frame D0
Applicable model
VFD370C43S/U; VFD450C43S/U
Cutout dimension

Unit: mm [inch]

M10*P1.5(4X)
OR 11.0[0.43](4X)

7-49

Chapter 7 Optional Accessories C2000 Series

Frame D
Applicable model
VFD300C23A/23E; VFD370C23A/23E; VFD550C43A/43E; VFD750C43A/43E
Cutout dimension

Unit: mm [inch]

M10*P1.5(4X)
OR 11.0[0.43](4X)

7-50

Chapter 7 Optional AccessoriesC2000 Series

Frame E
Applicable model
VFD450C23A/23E; VFD550C23A/23E; VFD750C23A/23E; VFD900C43A/43E; VFD1100C43A/43E;
Cutout dimension

Unit: mm [inch]

7-51

Chapter 7 Optional Accessories C2000 Series

Frame D0&D&E
1. Loosen 8 screws and remove Fixture 2 (as shown in 2. Loosen 10 screws and remove Fixture 1 (as shown
in the following figure).
the following figure).

3. Fasten 4 screws (as shown in the following figure).
Screw torque: 30~32kg-cm (26.0~27.8Ib-in).

4. Fasten 5 screws (as shown in the following figure).
Screw torque: 30~32kg-cm (26.0~27.8Ib-in).

5. Fasten 4 screws (as shown in the following figure).
Screw torque: 24~26kg-cm (20.8~22.6Ib-in).

6. Fasten 5 screws (as shown in the following figure).
Screw torque: 24~26kg-cm (20.8~22.6Ib-in).

7.

Place 4 screws (M10) through Fixture 1&2 and the
plate then fasten the screws. (as shown in the
following figure)
Frame D0/D M10*4
Screw torque: 200~240kg-cm (173.6~208.3Ib-in).
Frame E M12*4
Screw torque: 300~400kg-cm (260~347Ib-in).

7-52

Chapter 7 Optional AccessoriesC2000 Series

Frame F
Applicable model
VFD900C23A/23E; VFD1320C43A/43E; VFD1600C43A/43E
Cutout dimension

Unit: mm [inch]

M12*P1.75(4X)
OR 13.0[0.51](4X)

7-53

Chapter 7 Optional Accessories C2000 Series

Frame F
1. Loosen 12 screws and remove Fixture 2.

2. Loosen 12 screws and remove Fixture 2.
Screw torque: 24~26kg-cm (20.8~22.6Ib-in).

1

1
6
5

6
5

4
3
2

12
7

4
3
2

12
7

8
FIXTURE 2

8

9

FIXTURE2

10

9

11

10
11

3. Loosen screw 13 ~26 and remove Fixture 1.

4.

Install Fixture 1 by fasten screw 13 ~26
Screw torque: 24~26kg-cm (20.8~22.6Ib-in).

13
19
18
17

13
19
18
17

20

20

26

16

26

14

16
14
15

25

15

25

24

24

FIXTURE1

FIXTURE1

23

23
21
22

5.

Place 4 of the M12 screws through Fixture 1&2 and
plate then fasten the screws.
Screw torque: 300~400kg-cm (260~347Ib-in).
Screws M12*4

7-54

21

22

Chapter 7 Optional AccessoriesC2000 Series

7-12 USB/RS-485 Communication Interface IFD6530
Warning
 Please thoroughly read this instruction sheet before installation and putting it into use.
 The content of this instruction sheet and the driver file may be revised without prior notice. Please
consult our distributors or download the most updated instruction/driver version at
http://www.delta.com.tw/product/em/control/cm/control_cm_main.asp

1. Introduction
IFD6530 is a convenient RS-485-to-USB converter, which does not require external power-supply and complex
setting process. It supports baud rate from 75 to 115.2kbps and auto switching direction of data transmission. In
addition, it adopts RJ-45 in RS-485 connector for users to wire conveniently. And its tiny dimension, handy use of
plug-and-play and hot-swap provide more conveniences for connecting all DELTA IABU products to your PC.
Applicable Models: All DELTA IABU products.

(Application & Dimension)

2. Specifications
Power supply

No external power is needed

Power consumption

1.5W

Isolated voltage

2,500VDC

Baud rate

75, 150, 300, 600, 1,200, 2,400, 4,800, 9,600, 19,200, 38,400, 57,600, 115,200 bps

RS-485 connector

RJ-45

USB connector

A type (plug)

Compatibility

Full compliance with USB V2.0 specification

Max. cable length

RS-485 Communication Port: 100 m

Support RS-485 half-duplex transmission

7-55

Chapter 7 Optional Accessories C2000 Series
 RJ-45
PIN

Description

PIN

Description

1

Reserved

5

SG+

2

Reserved

6

GND

3

GND

7

Reserved

4

SG-

8

+9V

3. Preparations before Driver Installation
Please extract the driver file (IFD6530_Drivers.exe) by following steps. You could find driver file
(IFD6530_Drivers.exe) in the CD supplied with IFD6530.
Note: DO NOT connect IFD6530 to PC before extracting the driver file.
STEP 1

STEP 2

STEP 3

STEP 4

STEP 5
You should have a folder marked SiLabs under drive C. c:\ SiLabs

7-56

Chapter 7 Optional AccessoriesC2000 Series

4. Driver Installation
After connecting IFD6530 to PC, please install driver by following steps.

7-57

Chapter 7 Optional Accessories C2000 Series

5. LED Display
1. Steady Green LED ON: power is ON.
2. Blinking orange LED: data is transmitting.

7-58

Chapter 8 Optional Cards C2000 Series

Chapter 8 Option Cards
8-1 Removed Key Cover
8-2 Srews Specification for Option Card Terminals
8-3 EMC-D42A
8-4 EMC-D611A
8-5 EMC-R6AA
8-6 EMC-BPS01
8-7 EMC-PG01/02L
8-8 EMC-PG01/02O
8-9 EMC-PG01/02U
8-10 EMC-PG01R
8-11 CMC-MOD01
8-12 CMC-PD01
8-13 CMC-DN01
8-14 CMC-EIP01
8-15 EMC-COP01

8-1

Chapter 8 Optional Cards C2000 Series

Please select applicable option cards for your drive or contact local distributor for suggestion.
To prevent drive damage during installation, please removes the digital keypad and the cover before
wiring. Refer to the following instruction.

8-1 Removed key cover
Frame A&B&C
Screw Torque: 8~10Kg-cm [6.9~8.7lb-in.]

Frame D0
Screw Torque: 8~10Kg-cm [6.9~8.7lb-in.]

Frame D
Screw Torque: 8~10Kg-cm [6.9~8.7lb-in.]

8-2

Chapter 8 Optional Cards C2000 Series

Frame E
Slightly lift the cover then pull to remove. Screw Torque: 12~15Kg-cm [10.4~13lb-in.]

Frame F
Screw Torque: 12~ 15 Kg-cm [10.4~13lb-in.]

Frame G
Screw Torque: 12~15Kg-cm [10.4~13lb-in.]

8-3

Chapter 8 Optional Cards C2000 Series

Frame H
Screw Torque: 14~16Kg-cm [12.15~13.89lb-in.]

1 RJ45 (Socket) for digital keypad
KPC-CC01; KPC-CE01

1
3

Slot 3

Please refer to CH10 Digital Keypad for more details on
KPC-CE01.
Please refer to CH10 Digital Keypad for more details on
optional accessory RJ45 extension cable.

4

Slot 2 Slot 1

2

2 Communication extension card (Slot 1)
CMC-MOD01;

CMC-PD01;

CMC-DN01;

CMC-EIP01;

EMC-COP01;
3 I/O & Relay extension card (Slot 3)
EMC-D42A;

EMC-D611A;

EMC-R6AA;

EMC-BPS01;

4 PG Card (Slot 2)
EMC-PG01L; EMC-PG02L;
EMC-PG01O; EMC-PG02O;
EMC-PG01U; EMC-PG02U;
EMC-PG01R;

8-4

Chapter 8 Optional Cards C2000 Series

8-2 Screws Specification for option card terminals:
EMC-D42A

2
Wire gauge 24~12AWG（0.205~3.31mm ）

EMC-D611A
EMC-BPS01
EMC-R6AA

Torque

5Kg-cm [4.34Ib-in]

2
Wire gauge 26~16AWG（0.128~1.31mm ）

Torque

8Kg-cm [6.94Ib-in]

EMC-PG01L
EMC-PG01O

2
Wire gauge 30~16AWG（0.0509~1.31mm ）

EMC-PG01R

Torque

2Kg-cm [1.74Ib-in]

EMC-PG01U

I/O & Relay extension card (Slot 3)
EMC-D42A

EMC-R6AA

EMC-BPS01

EMC-D611A

8-5

Chapter 8 Optional Cards C2000 Series

PG card (Slot 2)
EMC-PG01O/ EMC-PG02O

EMC-PG01U/ EMC-PG02U

EMC-PG01L/ EMC-PG02L

EMC-PG01R

8-6

Chapter 8 Optional Cards C2000 Series

Communication extension card (Slot 1)
CMC-PD01

CMC-MOD01/ CMC-EIP01

CMC-DN01

EMC-COP01

8-7

Chapter 8 Optional Cards C2000 Series

PG Card intallation

8-8

Chapter 8 Optional Cards C2000 Series

Disconneting the extension card

8-9

Chapter 8 Optional Cards C2000 Series

8-3 EMC-D42A
Terminals
COM

MI10~ MI13

I/O Extension
Card

MO10~MO11

Descriptions
Common for Multi-function input terminals
Select SINK（NPN）/SOURCE（PNP）in J1 jumper / external power
supply
Refer to parameters 02-26~02-29 to program the multi-function
inputs MI10~MI13.
Internal power is applied from terminal E24: +24Vdc±5% 200mA,
5W
External power +24VDC: max. voltage 30VDC, min. voltage
19VDC, 30W
ON: the activation current is 6.5mA
OFF: leakage current tolerance is 10μA
Multi-function output terminals (photocoupler)
The AC motor drive releases various monitor signals, such as drive
in operation, frequency attained and overload indication, via
transistor (open collector).
MO10
MO11
MXM

MXM

Common for multi-function output terminals MO10,
MO11(photocoupler)
Max 48VDC 50mA

8-4 EMC-D611A

I/O Extension
Card

Terminals
AC

Descriptions
AC power Common for multi-function input terminal (Neutral)

MI10~ MI15

Refer to Pr. 02.26~ Pr. 02.31 for multi-function input selection
Input voltage: 100~130VAC
Input frequency: 47~63Hz
Input impedance: 27Kohm
Terminal response time:
ON: 10ms
OFF: 20ms

8-5 EMC-R6AA
Terminals

Descriptions
Refer to Pr. 02.36~ Pr. 02.41 for multi-function input selection
Resistive load:
5A(N.O.) 250VAC

Relay Extension
Card

R10A~R15A
R10C~R15C

5A(N.O.) 30VDC
Inductive load (COS 0.4)
2.0A(N.O.) 250VAC
2.0A(N.O.) 30VDC
It is used to output each monitor signal, such as drive is in
operation, frequency attained or overload indication.

8-10

Chapter 8 Optional Cards C2000 Series

8-6 EMC-BPS01
Terminals

Descriptions
Input power: 24V±5%
Maximum input current:0.5A

External Power
Supply

Note:
24V
GND

1) Do not connect control terminal +24V (Digital control signal common:
SOURCE) directly to the EMC-BPS01input terminal 24V.
2) Do not connect control terminal GND directly to the EMC-BPS01 input
termina GND.

Note: Refer to I/O & Rlay extension card installation/ disconnecting method for PG Card installation/ disconnecting.

8-11

Chapter 8 Optional Cards C2000 Series

8-7 EMC-PG01L/EMC-PG02L


Terminal description
Set by Pr.10-00~10-02, 10-16~10-18
Terminals

Descriptions
Output voltage for power: +5V/+12V5% (use FSW3 to switch
+5V/+12V)
Max. output current: 200mA

VP
DCM

PG1

Common for power and signal
Encoder input signal (Line Driver or Open Collector)

A1, /A1, B1,
/B1, Z1, /Z1

A2, /A2,
B2, /B2

PG2

PG OUT

AO, /AO,
BO, /BO,
ZO, /ZO,

Open Collector input voltage: +5~+24V (Note 1)

It can be 1-phase or 2-phase input.

EMC-PG01L: Max. input frequency: 300kHz
EMC-PG02L: Max. input frequency: 30kHz(Note 2)
Pulse Input signal (Line Driver or Open Collector)
Open Collector input voltage: +5~+24V (Note1)

It can be 1-phase or 2-phase input.

EMC-PG01L: Max. input frequency: 300kHz
EMC-PG02L: Max. input frequency: 30kHz(Note 2)

PG Card Output signals. It has division frequency function: 1~255
times
Max. output voltage for Line driver: 5VDC
Max. output current: 50mA

EMC-PG01L Max. output frequency: 300kHz
EMC-PG02L Max. output frequency: 30kHz
SG is the GND of PG card. It is also the GND of position machine or
PLC to make the ouput signal to be the common pivot point.
Note 1: Open Collector application, input current 5~15mA to each set then each set needs one pull-up resistor.
If input voltage of open collector is 24V, the power of encoder needs to be connected externally. Please refer
diagram 2 of PG1.
SG,

5V
12V
24V

Recommended pull-up resistor: above100~220, 1/2W
Recommended pull-up resistor: above 510~1.35k, 1/2W
Recommended pull-up resistor, above1.8k~3.3k, 1/2W

Note 2: If the required bandwidth is not over 30kHz at the application, it is recommended to use
EMC-PG02O/L (bandwidth 30kHz) to avoid interference.

PG1 card wiring diagram (the image 1 and 2 below are wiring diagrams of Open Collector encoder)

8-12

Chapter 8 Optional Cards C2000 Series

PG2 Wiring Diagram

8-13

Chapter 8 Optional Cards C2000 Series



EMC-PG01L/EMC-PG02L Wiring Diagram


Please use a shielded cable to prevent interference. Do not run control wires parallel to any high voltage
AC power line (200 V and above).



Recommended wire size 0.21 to 0.81mm (AWG24 to AWG18).



Cable length: Less than 100m

2

8-14

Chapter 8 Optional Cards C2000 Series

8-8 EMC-PG01O/EMC-PG02O


Terminal descriptions
Set by Pr.10-00~10-02, 10-16~10-18
Terminals
VP
DCM

Descriptions
Output voltage for power: +5V/+12V5% (use FSW3 to switch +5V/+12V)
Max. output current: 200mA
Common for power and signal
Encoder Input signal (Line Driver or Open Collector)

PG1
A1, /A1, B1,
/B1, Z1, /Z1

Open Collector Input Voltage: +5V~+24V (Note 1)
It can be 1-phase or 2-phase input.
EMC-PG01O Max. input frequency: 300kHz
EMC-PG02O Max. input frequency: 30kHz(Note 2)
Pulse Input Signal (Line Driver or Open Collector)

PG2

A2, /A2,
B2, /B2

Open Collector Input Voltage: +5~+24V (Note 1)
EMC-PG01O Max. input frequency: 300kHz
EMC-PG02O Max. input frequency: 30kHz(Note 2)

V+, V+
V-

PG OUT

Needs external power source for PG OUT circuit.
Input voltage of power:+12V ~ +24V
Input voltage for the negative side

PG Card Output signals has division frequency function: 1~255 times.
On the open collector’s output signal, add a high-pull resistor on the external
power V+ ~ V- (e.g. power of PLC) to prevent the interference of the receiving
A/O, B/O, Z/O signal. Max. 。[Three pull-up resistor are included in the package (1.8kW/1W)]
(Note 1)
EMC-PG01O Max. input frequency: 300kHz

EMC-PG02O Max. input frequency: 30kHz
Note 1: Open Collector application, input current 5~15mA to each set then each set needs one pull-up resistor.
If input voltage of open collector is 24V, the power of encoder needs to be connected externally. Please refer
diagram 2 of PG1.
5V
12V
24V

Recommended pull-up resistor: above100~220, 1/2W
Recommended pull-up resistor: above 510~1.35k, 1/2W
Recommended pull-up resistor, above1.8k~3.3k, 1/2W

Note 2: If the required bandwidth is not over 30kHz at the application, it is recommended to use
EMC-PG02O/L (bandwidth 30kHz) to avoid interference.

PG1 card wiring diagram (the image 1 and 2 below are wiring diagrams of Open Collector encoder)

8-15

Chapter 8 Optional Cards C2000 Series

PG2 Wiring Diagram

8-16

Chapter 8 Optional Cards C2000 Series



EMC-PG01O/EMC-PG02O Wiring Diagram


Please use a shielded cable to prevent interference. Do not run control wires parallel to any high voltage
AC power line (200 V and above).



Recommended wire size 0.21 to 0.81mm (AWG24 to AWG18).



Cable length: Less than 30m

2

8-17

Chapter 8 Optional Cards C2000 Series

8-9 EMC-PG01U/ EMC-PG02U
 FSW1 S: Standard UVW Output Encoder; D: Delta Encoder
 When using the Delta Encoder, wait for at least 250ms after powering up to receive signals from UVW.
If a running command is received before UVW signals finish, a PGF5 error message will be given. So
wait for 250ms before sending a running command.
 EMC-PG02U has encoder disconnection detection function.
 Set by Pr.10-00~10-02, 10-16~10-18
Terminals
VP

PG1

DCM

Descriptions
Output voltage for power: +5V/+12V5% (use FSW3 to
switch +5V/+12V)
Max. output current: 200mA
Common for power and signal

Encoder input signal (Line Driver)
A1, /A1, B1, /B1, Z1, /Z1 It can be 1-phase or 2-phase input.
Max. output frequency: 300kP/sec
U1, /U1, V1, /V1, W1, /W1 Encoder input signal

PG2

A2, /A2,
B2, /B2

PG OUT

AO, /AO, BO, /BO, ZO,
/ZO, SG

Pulse Input signal (Line Driver or Open Collector)
Open Collector Input Voltage: +5~+24V (Note1)
It can be 1-phase or 2-phase input.
Max. output frequency: 300kP/sec.
PG Card Output signals.
It has division frequency function: 1~255 times
Max. output voltage for Line driver: 5Vdc
Max. output current: 50mA
Max. output frequency: 300kP/sec

SG is the GND of PG card. It is also the GND of position
machine or PLC to make the ouput signal to be the common
pivot point.
Note 1: Open Collector application, input current 5~15mA to each set then each set needs one pull-up resistor.
5V
12V
24V

Recommended pull-up resistor: above100~220, 1/2W
Recommended pull-up resistor: above 510~1.35k, 1/2W
Recommended pull-up resistor, above1.8k~3.3k, 1/2W

PG2 Wiring Diagram

8-18

Chapter 8 Optional Cards C2000 Series



EMC-PG01U Wiring Diagram


Please use a shielded cable to prevent interference. Do not run control wires parallel to any high voltage
AC power line (200 V and above).



Recommended wire size 0.21 to 0.81mm (AWG24 to AWG18).



Cable length: Less than 30m

2

8-19

Chapter 8 Optional Cards C2000 Series

8-10 EMC-PG01R


Terminal Descriptions
Set by Pr.10-00~10-02
Terminals
R1- R2

PG1

S1, /S3,
S2, /S4,

A2, /A2,
B2, /B2

PG2

PG OUT

AO, /AO,
BO, /BO,
ZO, /ZO,
SG,

Descriptions
Resolver Output Power
7Vrms, 10kHz
Resolver Input Signal (S2, /S4=Sin; S1, /S3=Cos)
3.5±0.175Vrms, 10kHz
Pulse Input signal (Line Driver or Open Collector)
Open Collector Input Voltage: +5~+24V (Note1)

It can be 1-phase or 2-phase input.
Max. output frequency: 300kP/sec.
PG Card Output signals. It has division frequency function: 1~255
times
Max. output voltage for Line driver: 5VDC
Max. output current: 50mA
Max. output frequency: 300kP/sec

SG is the GND of PG card. It is also the GND of position machine or PLC to
make the ouput signal to be the common pivot point.
Note 1: Open Collector application, input current 5~15mA to each set then each set needs one pull-up resistor.
5V
12V
24V

Recommended pull-up resistor: above100~220, 1/2W
Recommended pull-up resistor: above 510~1.35k, 1/2W
Recommended pull-up resistor, above1.8k~3.3k, 1/2W

PG2 Wiring Diagram





DOS(Degradation of Signal)：If the amplitude of the sine wave input of the S1-/S3/ S2-/S4 is lower than or higher than
the encoder IC’s specification, a red light will be on. The possible reasons which cause this problem are the following.
1.

The turns ratio of the resolver encoder is not 1:0.5 which makes the sine wave input of the S1-/S3/S2-/S4 not
equal to 3.5±0.175Vrms.

2.

While motor is running, motor creates common mode noise which makes accumulated voltage to be more than
3.5±0.175Vrms

LOT(Loss of Tracking): Compare the angle of S1-/S3/S2-/S4 sine wave input to the R1-R2 cosine wave. If their
difference is more than 5 degree, a red light will be on. Here are the possible reasons why that happens:
1.

The output frequency of the PG card is incorrect.

2.

The specification of Resolver’s encoder is not 10KHz

3.

The motor creates common mode noise while it is running. That causes a big difference, while the motor is
rotating, between main winding’s cosine wave angle and the sine wave angle of second and third windings.

8-20

Chapter 8 Optional Cards C2000 Series



EMC-PG01R Wiring Diagram


Please use a shielded cable to prevent interference. Do not run control wires parallel to any high voltage
AC power line (200 V and above).



Recommended wire size 0.21 to 0.81mm (AWG24 to AWG18).



Cable length: Less than 100m

2

8-21

Chapter 8 Optional Cards C2000 Series

8-11 CMC-MOD01


Features
1.
2.
3.
4.
5.
6.



Supports Modbus TCP protocol
MDI/MDI-X auto-detect
Baud rate: 10/100Mbps auto-detect
E-mail alarm
AC motor drive keypad/Ethernet configuration
Virtual serial port.

Product File



I/O CARD & Relay Card



PG Card



Comm. Card



RJ-45 connection port



Removable control circuit
terminal



Specifications
Network Interface
Interface
Number of ports
Transmission method

RJ-45 with Auto MDI/MDIX
1 Port
IEEE 802.3, IEEE 802.3u

Transmission cable

Category 5e shielding 100M

Transmission speed

10/100 Mbps Auto-Detect

Network protocol

ICMP, IP, TCP, UDP, DHCP, HTTP, SMTP, MODBUS OVER TCP/IP,
Delta Configuration

Electrical Specification
Power supply voltage

5VDC (supply by the AC motor drive)

Insulation voltage

2KV

Power consumption

0.8W

Weight

25g

8-22

Chapter 8 Optional Cards C2000 Series

Environment



Noise immunity

ESD (IEC 61800-5-1, IEC 61000-4-2)
EFT (IEC 61800-5-1, IEC 61000-4-4)
Surge Test (IEC 61800-5-1, IEC 61000-4-5)
Conducted Susceptibility Test (IEC 61800-5-1, IEC 61000-4-6)

Operation/storage

Operation: -10°C ~ 50°C (temperature), 90% (humidity)
Storage: -25°C ~ 70°C (temperature), 95% (humidity)

Vibration/shock immunity

International standard: IEC 61800-5-1, IEC 60068-2-6/IEC
61800-5-1, IEC 60068-2-27

Install CMC-MOD01 to VFD-C2000
1.
2.
3.

4.

Switch off the power supply of VFD-C2000.
Open the front cover of VFD-C2000.
Place the insulation spacer into the positioning pin at Slot 1 (shown in Figure 3), and aim the
two holes on the PCB at the positioning pin. Press the pin to clip the holes with the PCB (shown
in Figure 4).
Screw up at torque 6 ~ 8 kg-cm (5.21 ~ 6.94 in-lbs) after the PCB is clipped with the holes
(shown in Figure 5).
Slot 3

Slot 2 Slot 1

[Figure 3]

[Figure 4]

[Figure 5]



Communication Parameters for VFD-C2000 Connected to Ethernet
When VFD-C2000 is link to Ethernet, please set up the communication parameters base on the
table below. Ethernet master will be able to read/write the frequency word and control word of
VFD-C2000 after communication parameters setup.
Parameter
P00-20
P00-21

Function
Source of frequency
command setting
Source of operation
command setting

Set value (Dec)
8
5

8-23

Explanation
The frequency command is controlled by
communication card.
The operation command is controlled by
communication card.

Chapter 8 Optional Cards C2000 Series
Decoding method for
communication
IP setting
IP address -1
IP address -2
IP address -3
IP address -4
Netmask -1
Netmask -2
Netmask -3
Netmask -4
Default gateway -1
Default gateway -2
Default gateway -3
Default gateway -4

P09-30
P09-75
P09-76
P09-77
P09-78
P09-79
P09-80
P09-81
P09-82
P09-83
P09-84
P09-85
P09-86
P09-87



0
0
192
168
1
5
255
255
255
0
192
168
1
1

Decoding method for Delta AC motor
drive
Static IP(0) / Dynamic distribution IP(1)
IP address 192.168.1.5
IP address 192.168.1.5
IP address 192.168.1.5
IP address 192.168.1.5
Netmask 255.255.255.0
Netmask 255.255.255.0
Netmask 255.255.255.0
Netmask 255.255.255.0
Default gateway 192.168.1.1
Default gateway 192.168.1.1
Default gateway 192.168.1.1
Default gateway 192.168.1.1

Disconnecting CMC- MOD01 from VFD-C2000
1.
2.
3.
4.

Switch off the power supply of VFD-C2000.
Remove the two screws (shown in Figure 6).
Twist opens the card clip and inserts the slot type screwdriver to the hollow to prize the PCB off
the card clip (shown in Figure 7).
Twist opens the other card clip to remove the PCB (shown in Figure 8).

[Figure 6]

[Figure 7]

[Figure 8]


Basic Registers
BR#

R/W

Content

#0

R

#1

R

#2

R

#11

R/W

Modbus Timeout Pre-defined setting: 500 (ms)

#13

R/W

Keep Alive Time Pre-defined setting: 30 (s)

Model name

Explanation
Set up by the system; read only. The model code of
CMC-MOD01=H’0203

Firmware
version

Displaying the current firmware version in hex, e.g. H’0100 indicates the
firmware version V1.00.
Displaying the data in decimal form. 10,000s digit and 1,000s digit are for
Release date of
“month”; 100s digit and 10s digit are for “day”.
the version
For 1 digit: 0 = morning; 1 = afternoon.

8-24

Chapter 8 Optional Cards C2000 Series



LED Indicator & Troubleshooting
LED Indicators
LED
POWER

LINK

Status
Green

Green

How to correct it?

On

Power supply in normal status

--

Off

No power supply

Check the power supply

On

Network connection in normal status

--

Network in operation

--

Network not connected

Check if the network cable is
connected

Flashes
Off

Indication

Troubleshooting
Abnormality

Cause

How to correct it?

CMC-MOD01 not connected
to AC motor drive
CMC-MOD01 not connected
to network

Check if AC motor drive is powered, and if the
power supply is normal.
Make sure CMC-MOD01 is connected to AC motor
drive.
Make sure the network cable is correctly connected
to network.

Poor contact to RJ-45
connector

Make sure RJ-45 connector is connected to
Ethernet port.

CMC-MOD01 not connected
to network

Make sure CMC-MOD01 is connected to network.

AC motor drive not powered
POWER LED off

LINK LED off

No module found

Fail to open
CMC-MOD01 setup
page

Able to open
CMC-MOD01 setup
page but fail to
utilize webpage
monitoring
Fail to send e-mail

PC and CMC-MOD01 in
different networks and
blocked by network firewall.
CMC-MOD01 not connected
to network
Incorrect communication
setting in DCISoft
PC and CMC-MOD01 in
different networks and
blocked by network firewall.

Search by IP or set up relevant settings by AC
motor drive keypad.
Make sure CMC-MOD01 is connected to the
network.
Make sure the communication setting in DCISoft is
set to Ethernet.
Conduct the setup by AC motor drive keypad.

Incorrect network setting in
CMC-MOD01

Check if the network setting for CMC-MOD01 is
correct. For the Intranet setting in your company,
please consult your IT staff. For the Internet setting
in your home, please refer to the network setting
instruction provided by your ISP.
Check if the network setting for CMC-MOD01 is
correct.

Incorrect mail server setting

Please confirm the IP address for SMTP-Server.

Incorrect network setting in
CMC-MOD01

8-25

Chapter 8 Optional Cards C2000 Series

8-12 CMC-PD01


Features
1.
2.
3.
4.



Supports PZD control data exchange.
Supports PKW polling AC motor drive parameters.
Supports user diagnosis function.
Auto-detects baud rates; supports Max. 12Mbps.

Product Profile

1. NET indicator
2. POWER indicator
3. Positioning hole
4. AC motor drive connection
port
5. PROFIBUS DP connection
port
6. Screw fixing hole
7. Fool-proof groove



Specifications
PROFIBUS DP Connector
Interface

DB9 connector

Transmission method

High-speed RS-485

Transmission cable

Shielded twisted pair cable

Electrical isolation

500VDC

Communication
Message type

Cyclic data exchange

Module name

CMC-PD01

GSD document

DELA08DB.GSD

Company ID

08DB (HEX)

Serial transmission
speed supported
(auto-detection)

9.6kbps; 19.2kbps; 93.75kbps; 187.5kbps; 125kbps; 250kbps; 500kbps; 1.5Mbps;
3Mbps; 6Mbps; 12Mbps (bit per second)

Electrical Specification
Power supply

5VDC (supplied by AC motor drive)

Insulation voltage

500VDC

Power consumption

1W

Weight

28g

8-26

Chapter 8 Optional Cards C2000 Series

Environment



Noise immunity

ESD(IEC 61800-5-1,IEC 6100-4-2)
EFT(IEC 61800-5-1,IEC 6100-4-4)
Surge Teat(IEC 61800-5-1,IEC 6100-4-5)
Conducted Susceptibility Test(IEC 61800-5-1,IEC 6100-4-6)

Operation /storage

Operation: -10ºC ~ 50ºC (temperature), 90% (humidity)
Storage: -25ºC ~ 70ºC (temperature), 95% (humidity)

Shock / vibration
resistance

International standards: IEC61131-2, IEC68-2-6 (TEST Fc)/IEC61131-2 & IEC
68-2-27 (TEST Ea)

Installation
PROFIBUS DP Connector



PIN

PIN name

Definition

1

-

Not defined

2

-

Not defined

3

Rxd/Txd-P

Sending/receiving data P(B)

4

-

Not defined

5

DGND

Data reference ground

6

VP

Power voltage – positive

7

-

Not defined

8

Rxd/Txd-N

Sending/receiving data N(A)

9

-

Not defined

9

5

6

1

LED Indicator & Troubleshooting
There are 2 LED indicators on CMC-PD01. POWER LED displays the status of the working
power. NET LED displays the connection status of the communication.
POWER LED
LED status

How to correct it?

Indication

Green light on

Power supply in normal status.

--

Off

No power

Check if the connection between CMC-PD01 and AC
motor drive is normal.

NET LED
LED status

How to correct it?

Indication

Green light on

Normal status

--

Red light on

CMC-PD01 is not connected to
PROFIBUS DP bus.

Connect CMC-PD01 to PROFIBUS DP bus.

Red light
flashes

Invalid PROFIBUS communication
address

Set the PROFIBUS address of CMC-PD01 between 1 ~
125 (decimal)

Orange light
flashes

CMC-PD01 fails to communication
with AC motor drive.

Switch off the power and check whether CMC-PD01 is
correctly and normally connected to AC motor drive.

8-27

Chapter 8 Optional Cards C2000 Series

8-13 CMC-DN01


Functions
1.
2.
3.
4.
5.
6.
7.



Based on the high-speed communication interface of Delta HSSP protocol, able to conduct
immediate control to AC motor drive.
Supports Group 2 only connection and polling I/O data exchange.
For I/O mapping, supports Max. 32 words of input and 32 words of output.
Supports EDS file configuration in DeviceNet configuration software.
Supports all baud rates on DeviceNet bus: 125kbps, 250kbps, 500kbps and extendable serial
transmission speed mode.
Node address and serial transmission speed can be set up on AC motor drive.
Power supplied from AC motor drive.

Product Profile

1. NS indicator
2. MS indicator
3. POWER indicator
4. Positioning hole
5. DeviceNet connection port
6. Screw fixing hole
7. Fool-proof groove
8. AC motor drive connection
port


Specifications
DeviceNet Connector
Interface

5-PIN open removable connector. Of 5.08mm PIN interval

Transmission
th d
Transmission cable

CAN

Transmission speed
Network protocol

Shielded twisted pair cable (with 2 power cables)
125kbps, 250kbps, 500kbps and extendable serial transmission speed
d
DeviceNet protocol

AC Motor Drive Connection Port
Interface

50 PIN communication terminal

Transmission method

SPI communication

Terminal function

1. Communicating with AC motor drive
2. Transmitting power supply from AC motor drive

Communication
t
l

Delta HSSP protocol

8-28

Chapter 8 Optional Cards C2000 Series

Electrical Specification
Power supply voltage

5VDC (supplied by AC motor drive)

Insulation voltage

500VDC

Communication wire
power consumption

0.85W

Power consumption

1W

Weight

23g

Environment

Noise immunity

ESD (IEC 61800-5-1,IEC 6100-4-2)
EFT (IEC 61800-5-1,IEC 6100-4-4)
Surge Teat(IEC 61800-5-1,IEC 6100-4-5)
Conducted Susceptibility Test (IEC 61800-5-1,IEC 6100-4-6)

Operation /storage

Operation: -10ºC ~ 50ºC (temperature), 90% (humidity)
Storage: -25ºC ~ 70ºC (temperature), 95% (humidity)

Shock / vibration
resistance

International standards: IEC61131-2, IEC68-2-6 (TEST Fc)/IEC61131-2 &
IEC 68-2-27 (TEST Ea)

DeviceNet Connector



PIN

Signal

Color

Definition

1

V+

Red

DC24V

2

H

White

Signal+

3

S

-

Earth

4

L

Blue

Signal-

5

V-

Black

0V

1
2
3
4
5

LED Indicator & Troubleshooting
There are 3 LED indicators on CMC-DN01. POWER LED displays the status of power supply.
MS LED and NS LED are dual-color LED, displaying the connection status of the communication
and error messages.
POWER LED
LED status

Indication

How to correct it?

On

Power supply in abnormal status.

Check the power supply of CMC-DN01.

Off

Power supply in normal status

--

8-29

Chapter 8 Optional Cards C2000 Series

NS LED
LED status

Indication

How to correct it?

Off

No power supply or CMC-DN01 has
not completed MAC ID test yet.

1. Check the power of CMC-DN01 and see if the
connection is normal.
2. Make sure at least one or more nodes are on the
bus.
3. Check if the serial transmission speed of
CMC-DN01 is the same as that of other nodes.

Green light
flashes

CMC-DN01 is on-line but has not
established connection to the master.

1. Configure CMC-DN01 to the scan list of the
master.
2. Re-download the configured data to the master.

Green light on

CMC-DN01 is on-line and is normally
connected to the master

--

Red light
flashes

CMC-DN01 is on-line, but I/O
connection is timed-out.

1. Check if the network connection is normal.
2. Check if the master operates normally.

1.
2.
3.
4.

1. Make sure all the MAC IDs on the network are
not repeated.
2. Check if the network installation is normal.
3. Check if the baud rate of CMC-DN01 is
consistent with that of other nodes.
4. Check if the node address of CMC-DN01 is
illegal.
5. Check if the network power supply is normal.

Red light on

The communication is down.
MAC ID test failure.
No network power supply.
CMC-DN01 is off-line.

MS LED
LED status

Indication

How to correct it?

Off

No power supply or being off-line

Check the power supply of CMC-DN01 and see of
the connection is normal.

Green light
flashes

Waiting for I/O data

Switch the master PLC to RUN status

Green light on

I/O data are normal

--

Red light
flashes

Mapping error

1. Reconfigure CMC-DN01
2. Re-power AC motor drive

Red light on

Hardware error

1. See the error code displayed on AC motor drive.
2. Send back to the factory for repair if necessary.

Orange light
flashes

If the flashing lasts for a long time, check if
CMC-DN01 is establishing connection
CMC-DN01 and AC motor drive are correctly
with AC motor drive.
installed and normally connected to each other.

8-30

Chapter 8 Optional Cards C2000 Series

8-14 CMC-EIP01




Features
1.

Supports Modbus TCP and Ethernet/IP protocol

2.

MDI/MDI-X auto-detect

3.

Baud rate: 10/100Mbps auto-detect

4.

AC motor drive keypad/Ethernet configuration

5.

Virtual serial port

Product Profile
[Figure1]
1. Screw fixing hole
2. Positioning hole
3. AC motor drive connection
port
4. LINK indicator
5. RJ-45 connection port
6. POWER indicator
7. Fool-proof groove



Specifications
Network Interface
Interface

RJ-45 with Auto MDI/MDIX

Number of ports

1 Port

Transmission method

IEEE 802.3, IEEE 802.3u

Transmission cable

Category 5e shielding 100M

Transmission speed

10/100 Mbps Auto-Detect

Network protocol

ICMP, IP, TCP, UDP, DHCP, HTTP, SMTP, MODBUS OVER TCP/IP, EtherNet/IP, Delta
Configuration

Electrical Specification
Weight

25g

Insulation voltage

500VDC

Power consumption

0.8W

Power supply voltage

5VDC

8-31

Chapter 8 Optional Cards C2000 Series

Environment



Noise immunity

ESD (IEC 61800-5-1,IEC 61000-4-2)
EFT (IEC 61800-5-1,IEC 61000-4-4)
Surge Test (IEC 61800-5-1,IEC 61000-4-5)
Conducted Susceptibility Test (IEC 61800-5-1,IEC 61000-4-6)

Operation/storage

Operation: -10°C ~ 50°C (temperature), 90% (humidity)
Storage: -25°C ~ 70°C (temperature), 95% (humidity)

Vibration/shock
immunity

International standard: IEC 61800-5-1, IEC 60068-2-6/IEC 61800-5-1, IEC 60068-2-27

Installation
Connecting CMC-EIP01 to Network
1. Turn off the power of AC motor drive.
2. Open the cover of AC motor drive.
3. Connect CAT-5e network cable to RJ-45 port on
CMC-EIP01 (See Figure 2).
[Figure 2]
RJ-45 PIN Definition



PIN

Signal

Definition

PIN

Signal

Definition

1

Tx+

Positive pole for
data transmission

5

--

N/C

2

Tx-

Negative pole for
data transmission

6

Rx-

Negative pole for
data receiving

3

Rx+

Positive pole for
data receiving

7

--

N/C

4

--

N/C

8

--

N/C

Connecting CMC-EIP01 to VFD-C2000
1.
2.
3.

4.

Switch off the power of AC motor drive.
Open the front cover of AC motor drive.
Place the insulation spacer into the positioning pin at Slot 1 (shown in Figure 3), and aim the
two holes on the PCB at the positioning pin. Press the pin to clip the holes with the PCB (see
Figure 4).
Screw up at torque 6 ~ 8 kg-cm (5.21 ~ 6.94 in-lbs) after the PCB is clipped with the holes (see
Figure 5).

8-32

Chapter 8 Optional Cards C2000 Series

Slot 3

Slot 2 Slot 1

[Figure 3]

[Figure 4]

[Figure 5]


Communication Parameters for VFD-C2000 Connected to Ethernet
When VFD-C2000 is connected to Ethernet network, please set up the communication
parameters for it according to the table below. The Ethernet master is only able to read/write the
frequency word and control word of VFD-C2000 after the communication parameters are set.
Parameter
(Dec)

Function

Set value (Dec)

Explanation

P00-20

Source of frequency
command setting

8

The frequency command is controlled by
communication card.

P00-21

Source of operation
command setting

5

The operation command is controlled by
communication card.

P09-30

Decoding method for
communication

0

The decoding method for Delta AC motor
drive

P09-75

IP setting

0

Static IP(0) / Dynamic distribution IP(1)

P09-76

IP address -1

192

IP address 192.168.1.5

P09-77

IP address -2

168

IP address 192.168.1.5

P09-78

IP address -3

1

IP address 192.168.1.5

P09-79

IP address -4

5

IP address 192.168.1.5

P09-80

Netmask -1

255

Netmask 255.255.255.0

P09-81

Netmask -2

255

Netmask 255.255.255.0

P09-82

Netmask -3

255

Netmask 255.255.255.0

P09-83

Netmask -4

0

Netmask 255.255.255.0

P09-84

Default gateway -1

192

Default gateway 192.168.1.1

P09-85

Default gateway -2

168

Default gateway 192.168.1.1

P09-86

Default gateway -3

1

Default gateway 192.168.1.1

P09-87

Default gateway -4

1

Default gateway 192.168.1.1

8-33

Chapter 8 Optional Cards C2000 Series



Disconnecting CMC- EIP01 from VFD-C2000
1. Switch off the power supply of VFD-C2000.
2. Remove the two screws (see Figure 6).
3. Twist opens the card clip and inserts the slot type screwdriver to the hollow to prize the PCB off the
card clip (see Figure 7).
4. Twist opens the other card clip to remove the PCB (see Figure 8).

[Figure 6]

[Figure 7]

[Figure 8]


LED Indicator & Troubleshooting
There are 2 LED indicators on CMC-EIP01. The POWER LED displays the status of power
supply, and the LINK LED displays the connection status of the communication.
LED Indicators
LED
POWER

LINK

Status
Green

Green

Indication

How to correct it?

On

Power supply in normal status

--

Off

No power supply

Check the power supply.

On

Network connection in normal
status

--

Network in operation

--

Network not connected

Check if the network cable is
connected.

Cause

How to correct it?

Flashes
Off

Troubleshooting
Abnormality

CMC-EIP01 not connected to
AC motor drive

Check if AC motor drive is powered, and if the
power supply is normal.
Make sure CMC-EIP01 is connected to AC motor
drive.

CMC-EIP01 not connected to
network

Make sure the network cable is correctly connected
to network.

Poor contact to RJ-45
connector

Make sure RJ-45 connector is connected to
Ethernet port.

AC motor drive not powered
POWER LED off

LINK LED off

8-34

Chapter 8 Optional Cards C2000 Series

Abnormality

No communication
card found

Fail to open
CMC-EIP01 setup
page

Able to open
CMC-EIP01 setup
page but fail to
utilize webpage
monitoring

Fail to send e-mail

Cause

How to correct it?

CMC-EIP01 not connected to
network

Make sure CMC-EIP01 is connected to network.

PC and CMC-EIP01 in
different networks and blocked
by network firewall.

Search by IP or set up relevant settings by AC
motor drive keypad.

CMC-EIP01 not connected to
network
Incorrect communication
setting in DCISoft

Make sure CMC-EIP01 is connected to the
network.
Make sure the communication setting in DCISoft is
set to Ethernet.

PC and CMC-EIP01 in
different networks and blocked
by network firewall.

Conduct the setup by AC motor drive keypad.

Incorrect network setting in
CMC-EIP01

Check if the network setting for CMC-EIP01 is
correct. For the Intranet setting in your company,
please consult your IT staff. For the Internet setting
in your home, please refer to the network setting
instruction provided by your ISP.
Check if the network setting for CMC-EIP01 is
correct.

Incorrect mail server setting

Please confirm the IP address for SMTP-Server.

Incorrect network setting in
CMC-EIP01

8-35

Chapter 8 Optional Cards C2000 Series

8-15 EMC-COP01
Built-in EMC-COP01 card are available in VFDXXXC23E/VFDXXXC43E series.
RJ-45 Pin definition

Pin
1
2
3
7

RS485 socket



Pin name
CAN_H

Definition
CAN_H bus line (dominant
high)
CAN_L
CAN_L bus line (dominant low)
CAN_GND Ground/0V/VCAN_GND Ground/0V/V-

Specifications
Interface

RJ-45

Number of ports

1 Port

Transmission method

CAN

Transmission cable

CAN standard cable

Transmission speed

1M 500k 250k 125k 100k 50k

Communication protocol


CANopen

CANopen Communication Cable
Model: TAP-CB03, TAP-CB04



Title

Part No.

1
2

TAP-CB03
TAP-CB04

L
mm
500  10
1000 10

inch
19  0.4
39  0.4

CANopen Dimension
Model: TAP-CN03

NOTE

For more information on CANopen, please refer to Chapter 15 CANopen Overview or CANopen
user manual can also be downloaded on Delta website: http://www.delta.com.tw/industrialautomation/.

8-36

Chapter 9 Specifications C2000 Series

Chapter 9 Specification

Input Rating

007
0.4
0.75

015
0.75
1.5

022
1.5
2.2

037
2.2
3.7

055
3.7
5.5

B
075
5.5
7.5

110
7.5
11

150
11
15

C
185
15
18.5

220
18.5
22

Heavy
duty

1.9

2.8

4.0

6.4

9.6

12

19

25

28

34

4.8

7.1

10

16

24

31
2~6kHz

47

62

71

86

Normal
duty

Frame Size
Model VFD-_ _ _C_ _
Applicable Motor Output(kW)
Applicable Motor Output(HP)
Rated Output Capacity
(kVA)
Rated Output Current (A)
Carrier Frequency (kHz)
Rate Output Capacity
(kVA)
Rated Output Current (A)
Carrier Frequency (kHz)
Input Current (A) Heavy Duty
Input Current (A)
Normal Duty
Rated Voltage/Frequency
Operating Voltage Range
Frequency Tolerance
AC Drive Weight
Cooling method
Braking Chopper
DC reactor
EMC Filter
EMC-COP01

2.0

3.2

4.4

6.8

10

13

20

26

30

36

5

8

11

25

33

49

65

90

6.1

11

15

26

34

50

68

75
2~10kHz
78

95

6.4

12

16

28

36

52

72

83

99

Heavy
duty

Frame Size
Model VFD-_ _ _C_ _
Applicable Motor Output(kW)
Applicable Motor Output(HP)
Rated Output Capacity
(kVA)
Rated Output Current (A)
Carrier Frequency (kHz)
Rate Output Capacity
(kVA)
Rated Output Current (A)
Carrier Frequency (kHz)
Input Current (A) Heavy Duty
Input Current (A)
Normal Duty
Rated Voltage/Frequency
Operating Voltage Range
Frequency Tolerance

Normal
duty

Output Rating

Input Rating

Output Rating

9-1 230V Series

AC Drive Weight
Cooling method
Braking Chopper
DC reactor
EMI Filter
EMC-COP01

A

2.6± 0.3Kg
Natural cooling

370
30
37

20

3-phase AC 200V~240V (-15% ~ +10%), 50/60Hz
170~265Vac
47~63Hz
5.4± 1Kg
Fan cooling
Frame A to C (built-in); Frame D and above (optional)
Frame A to C (optional); Frame D and above (built-in)
Frame A to C (optional); Frame D and above (optional)
VFDXXC23A (optional); VFDXXXC23E (built-in)

D
300
22
30

17
2~15kHz
18.5

450
37
45

E
550
45
55

750
55
75

F
900
75
90

45

55

68

81

96

131

114

139

171

204
2~6kHz

242

329

48

58

72

86

102

138

120
146
2~10kHz
118
136

180

346

162

215
255
2~9 kHz
196
233

315

124

171

206

331

143

245

3-phase AC 200V~240V (-15% ~ +10%), 50/60Hz
170~265Vac
47~63Hz
86.5±1
38.5± 1.5Kg
64.8± 1.5Kg
.5Kg
Fan Cooling
Frame A to C (built-in); Frame D and above (optional)
Frame A to C (optional); Frame D and above (built-in)
Frame A to C (optional); Frame D and above (optional)
VFDXXC23A (optional); VFDXXXC23E (built-in)

9-1

9.8± 1.5Kg

Chapter 9 Specifications C2000 Series

9-2 460V Series
Frame Size

A

B

C

D0

Model VFD-_ _ _ C_ _

007

015

022

037

040

055

075

110

150

185

220

300

370

450

Applicable Motor Output(kW)

0.75

1.5

2.2

3.7

4.0

5.5

7.5

11

15

18.5

22

30

37

45

7.5

10

15

20

25

30

40

50

60

9.6

14

18

24

29

34

45

55

69

5.7

8.1

9.5

11

17

23

30

36

43

57

69

86

Heavy duty

5
7.6

Normal duty

5
6.5

4.8

7.2

8.4

10

14

19

25

30

36

48

58

73

6.0

9.0

10.5

12

18

24

32

38

45

60

73

91

EMI Filter
EMC-COP01
Frame Size

Input Rating

Normal duty

Heavy duty

Model VFD-_ _ _ C_ _
Applicable Motor Output(kW)
Applicable Motor Output(HP)
Rated Output Capacity
(kVA)
Rated Output Current
(A)
Carrier Frequency
(kHz)
Rate Output Capacity
(kVA)
Rated Output Current
(A)
Carrier Frequency
(kHz)
Input Current (A) Heavy Duty
Input Current (A)
Normal Duty
Rated Voltage/Frequency
Operating Voltage Range
Frequency Tolerance
AC Drive Weight
Cooling method
Braking Chopper
DC reactor

Output Rating

3
4.5

Input Rating

Output Rating

Applicable Motor Output(HP)
1
2
Rated Output Capacity
2.3
3.0
(kVA)
Rated Output Current
2.9
3.8
(A)
Carrier Frequency
(kHz)
Rate Output Capacity
2.4
3.2
(kVA)
Rated Output Current
3.0
4.0
(A)
Carrier Frequency
(kHz)
Input Current (A) Heavy
4.1
5.6
Duty
Input Current (A)
4.3
5.9
Normal Duty
Rated Voltage/Frequency
Operating Voltage Range
Frequency Tolerance
AC Drive Weight
Natural cooling
Cooling method
Braking Chopper
DC reactor

EMI Filter
EMC-COP01

2~6kHz (2kHz)

2~15kHz (8kHz)

2~10kHz (6kHz)

8.3

13

14.5

16

19

25

33

38

45

60

70

96

8.7

14

15.5

17

20

26

35

40

47

63

74

101

3-phase AC 380V~480V ( -15%~+10%), 50/60Hz
323~528Vac
47~63Hz
2.6± 0.3Kg
5.4± 1Kg
9.8± 1.5Kg
Fan cooling
Frame A to C (built-in); Frame D and above (optional)
Frame A to C (optional); Frame D and above (built-in)
VFDXXXC43A Frame A to C: No EMI Filter; VFDXXXC43E: Built-in EMI Filter
VFDXXXC43A/43E Frame D and above: EMI Filter is optional
VFDXXC43A (optional); VFDXXXC43E (built-in)

D

E

F

G

27± 1 Kg

H

550
55
75

750
75
100

900
90
125

1100
110
150

1320
132
175

1600
160
215

1850
185
250

2200
220
300

2800
280
375

3150
315
420

3550
355
475

4500
450
600

84

114

136

167

197

235

280

348

417

466

517

677

105

143

171

209

247

295

352

437

523

585

649

816

2~6kHz (2kHz)
88

120

143

175

207

247

295

367

438

491

544

720

110

150

180

220

260

310

370

460

550

616

683

866

108

149

159

197

228

285

361

380

469

527

594

816

114

157

167

207

240

300

380

400

494

555

625

866

2~10kHz (6kHz)

2~9kHz (4kHz)

3-phase AC 380V~~480V (-15% +10%), 50/60Hz
323~528Vac
47~63Hz
38.5± 1.5Kg
64.8± 1.5Kg
86.5± 1.5Kg
134± 4Kg
228Kg
Fan cooling
Frame A to C (built-in); Frame D and above (optional)
Frame A to C (optional); Frame D and above (built-in)
VFDXXXC43A Frame A to C: No EMI Filter; VFDXXXC43E: Built-in EMI Filter
VFDXXXC43A/43E Frame D and above: EMI Filter is optional
VFDXXC43A (optional); VFDXXXC43E (built-in)

NOTE






The value of the carrier frequency is a factory setting. To increase the carrier frequency, the current needs to be decreased. See derating
curve diagram of Pr06-55 for more information.
When the control mode is FOC senrorless, TQC+PG, TQC sensorless, PM+PG and PM sensorless, the current needs to be decreased. For
more information see Pr06-55.
When a load is a shock or impact load, use a higher level model.
For FRAME A, B and C, Model VFDXXXC43A the enclosure type is IP20/NEMA1/UL TYPE1.
For FRAME D and above, if the last character of the model is A then the enclosure type is IP20 but the wiring terminal is IP00; if the last
character of the model is E, the enclosure type is IP20/NEMA1/UL TYPE1.

9-2

Chapter 9 Specifications C2000 Series

General Specifications
Control Method

1: V/F, 2: SVC, 3: VF+PG, 4: FOC+PG, 5: TQC+PG,
Reach up to 150% or above at 0.5Hz.
Under FOC+PG mode, starting torque can reach 150% at 0Hz.
V/F Curve
4 point adjustable V/F curve and square curve
Speed Response Ability
5Hz (vector control can reach up to 40Hz)
Torque Limit
Max. 200% torque current
Torque Accuracy
5%
Max. Output Frequency(Hz) normal duty: 0.01~600.00Hz; Heavy duty: 0.00 ~ 300.00 Hz
Frequency Output Accuracy Digital command:0.01%, -10℃~+40℃, Analog command: 0.1%, 2510℃
Output Frequency
Digital command:0.01Hz, Analog command: 0.03 X max. output frequency/60 Hz (11 bit)
Resolution
Normal duty: rated output current is 120% for 60 seconds
Overload Tolerance
Heavy duty: rated output current is 150% for 60 seconds
Frequency Setting Signal
+10V~-10, 0~+10V, 4~20mA, 0~20mA, Pulse input
Accel./decel. Time
0.00~600.00/0.0~6000.0 seconds
Torque control, Droop control, Speed/torque control switching, Feed forward control, Zero-servo control,
Momentary power loss ride thru, Speed search, Over-torque detection, Torque limit, 17-step speed (max),
Accel/decel time switch, S-curve accel/decel, 3-wire sequence, Auto-Tuning (rotational, stationary), Dwell,
Main control function
Cooling fan on/off switch, Slip compensation, Torque compensation, JOG frequency, Frequency
upper/lower limit settings, DC injection braking at start/stop, High slip braking, PID control (with sleep
function),Energy saving control, MODOBUS communication (RS-485 RJ45, max. 115.2 kbps), Fault
restart, Parameter copy
Frame A,B is on/off control
Fan Control
Frame C and above is PWM control
Motor Protection
Electronic thermal relay protection
For drive model 230V and 440V
Over-current protection for 220% rated current
Over-current Protection
current clamp『Normal duty: 170~175%』;『Heavy duty: 180~185%』
230: drive will stop when DC-BUS voltage exceeds 410V
Over-voltage Protection
460: drive will stop when DC-BUS voltage exceeds 820V
Over-temperature
Built-in temperature sensor
Protection
Stall Prevention
Stall prevention during acceleration, deceleration and running independently
Restart After Instantaneous
Parameter setting up to 20 seconds
Power Failure
Grounding Leakage Current
Leakage current is higher than 50% of rated current of the AC motor drive
Protection

Protection Characteristics

Control Characteristics

Starting Torque

Certifications
,

,

GB/T12668-2,

9-3

(certification in progress)

Chapter 9 Specifications C2000 Series

9-3 Environment for Operation, Storage and Transportation
DO NOT expose the AC motor drive in the bad environment, such as dust, direct sunlight, corrosive/inflammable gasses, humidity, liquid and
2
vibration environment. The salt in the air must be less than 0.01mg/cm every year.
Installation
IEC60364-1/IEC60664-1 Pollution degree 2, Indoor use only
location
o
o
Storage
-25 C ~ +70 C
Surrounding
o
o
Transportation
-25 C ~ +70 C
Temperature
Non-condensation, non-frozen
Operation
Max. 95%
Storage/
Max. 95%
Rated Humidity
Transportation
No condense water
Operation/
86 to 106 kPa
Storage
Environment
Air Pressure
Transportation
70 to 106 kPa
IEC721-3-3
Operation
Class 3C2; Class 3S2
Storage
Class 2C2; Class 2S2
Pollution Level
Transportation
Class 1C2; Class 1S2
No concentrate
If AC motor drive is installed at altitude 0~1000m, follow normal operation restriction. If
it
is install at altitude 1000~2000m, decrease 2% of rated current or lower 0.5℃ of
Operation
Altitude
temeperature for every 100m increase in altitude. Maximum altitude for Corner
Grounded is 2000m.
Storage
ISTA procedure 1A(according to weight) IEC60068-2-31
Package Drop
Transportation
1.0mm, peak to peak value range from 2Hz to 13.2 Hz; 0.7G~1.0G range from 13.2Hz to 55Hz; 1.0G range from 55Hz to
Vibration
512 Hz. Comply with IEC 60068-2-6
Impact
Operation
Position

IEC/EN 60068-2-27
Max. allowed offset angle 10 (under normal installation
position)
o

9-4

10

10

Chapter 9 Specifications C2000 Series

9-4 Specification for Operation Temperature and Protection Level
Model

Frame

Top cover

Conduit Box

Frame A~C
230V: 0.75~22kW
460V: 0.75~30kW

Top cover
Removed
Standard with
top cover

Standard conduit
plate

Protection Level

Operation
Temperature

IP20/UL Open Type

-10~50℃

IP20/UL Type1/NEMA1

-10~40℃

IP00/IP20/UL Open Type
O n l y th e ci rcl e d a re a
i s IP0 0 , o th e r a re IP2 0

VFDxxxCxxA
Frame D~H
230V: >22kW
460V: >30kW

Frame A~C
460V: 0.75~30kW
VFDxxxCxxE
Frame D~H
230V: >22kW
460V: >30kW

N/A

Top cover
Removed
Standard with
top cover
N/A

-10~50℃

No conduit box

Standard conduit
plate
Standard conduit
box

9-5

IP20/UL Open Type

-10~50℃

IP20/UL Type1/NEMA1

-10~40℃

IP20/UL Type1/NEMA1

-10~40℃

Chapter 9 Specifications C2000 Series

9-5 Derating of ambient temperature and altitude
C Type Derating for Altitude
Rating (%) at Stardard Ambient Temperature*

Ta at Rating= 100%

100

50 40

90

45 35

80

40 30

60
50
40
0

500

1000

1500
2000
Altitude (m)

2500

3000

UL Open Type / IP20 Side by Side
UL Type I / IP20

UL Open Type / IP20

70

* Stardard Ambient Temperature= 50 degC for UL Open Type / IP20
Stardard Ambient Temperature= 40 degC for UL Type I /IP 20 & UL Open Type / IP20 Side by Side

Protection Level

UL Type I / IP20

UL Open Type / IP20

High Altitude

Operating Environment
When the AC motor drive is operating at the rated current and the ambient temperature
has to be between 10℃ ~ +40℃. When the temperature is over 40℃, for every
increase by 1℃, decrease 2% of the rated current. The maximum allowable
temperature is 60℃.
When the AC motor drive is operating at the rated current and the ambient temperature
has to be between -10℃ ~ +50℃. When the temperature is over 50℃, for every
increase by 1℃, decrease 2% of the rated current. The maximum allowable
temperature is 60℃.
If AC motor drive is installed at altitude 0~1000m, follow normal operation restriction. If
it is install at altitude 1000~2000m, decrease 2% of rated current or lower 0.5℃ of
temperature for every 100m increase in altitude. Maximum altitude for Corner
Grounded is 2000m. Contact Delta for more information, if you need to use this motor
drive at an altitude of 2000m or higher.

9-6

Chapter 10 Digital KeypadC2000

Chapter 10 Digital Keypad
10-1 Descriptions of Digital Keypad
10-2 Function of Digital Keypad KPC-CC01
10-3 TPEditor Installation Instruction
10-4 Fault Code Description of Digital Keypad KPC-CC01

10-1

Chapter 10 Digital KeypadC2000 Series

10-1 Descriptions of Digital Keypad
KPC-CC01

KPC-CE01(Option)
Communication Interface
RJ-45 (socket)、RS-485 interface;
Installation Method
1.
Embedded type and can be put flat on the
surface of the control box. The front cover is
water proof.
2.
Buy a MKC-KPPK model to do wall
mounting or embedded mounting. Its
protection level is IP66.
3.
The maximum RJ45 extension lead is 5 m
(16ft)
4.
This keypad can only be used on Delta’s
motor drive C2000, CH2000 and CP2000.

Descriptions of Keypad Functions
Descriptions

Key

Start Operation Key
1.
It is only valid when the source of operation command is from the keypad.
2.
It can operate the AC motor drive by the function setting and the RUN LED will be ON.
3.
It can be pressed again and again at stop process.
4.
When enabling “HAND” mode, it is only valid when the source of operation command is
from the keypad.
Stop Command Key. This key has the highest processing priority in any situation.
1.
When it receives STOP command, no matter the AC motor drive is in operation or stop
status, the AC motor drive needs to execute “STOP” command.
2.
The RESET key can be used to reset the drive after the fault occurs. For those faults that
can’t be reset by the RESET key, see the fault records after pressing MENU key for
details.
Operation Direction Key
1.
This key is only control the operation direction NOT for activate the drive. FWD: forward,
REV: reverse.
2.
Refer to the LED descriptions for more details.
ENTER Key
Press ENTER and go to the next level. If it is the last level then press ENTER to execute the command.

ESC Key
ESC key function is to leave current menu and return to the last menu. It is also functioned as a
return key in the sub-menu.
Press menu to return to main menu.
Menu content:
KPC-CE01 does not support function 5 ~13.
1. Parameter setup
7. Quick start
13. PC Link
2. Copy Parameter
8. Display Setup
3. Keypad Locked
9. Time Setup
4. PLC Function
10. Language Setup
5. Copy PLC
11. Startup Menu
6. Fault Record
12. Main Page
Direction: Left/Right/Up/Down
1.
In the numeric value setting mode, it is used to move the cursor and change the numeric
value.
2.
In the menu/text selection mode, it is used for item selection.

10-2

Chapter 10 Digital KeypadC2000
Function Key
1.
The functions keys have factory settings and can be defined by users. The factory settings
of F1 and F4 work with the function list below. For example, F1 is JOG function, F4 is a
speed setting key for adding/deleting user defined parameters.
2.
Other functions must be defined by TPEditor first. TPEditor software V1.30.6 is available
for download at:
http://www.delta.com.tw/ch/product/em/download/download_main.asp?act=3&pid=1&cid=
1&tpid=3
3.
Installation Instruction for TPEditor is on page 10-15 of this chapter.
HAND ON Key
1.
This key is executed by the parameter settings of the source of Hand frequency and hand
operation. The factory settings of both source of Hand frequency and hand operation are
the digital keypad.
2.
Press HAND ON key at stop status, the setting will switch to hand frequency source and
hand operation source. Press HAND ON key at operation status, it stops the AC motor
drive first (display AHSP warning), and switch to hand frequency source and hand
operation source.
3.
Successful mode switching for KPC-CE01, “H/A” LED will be on; for KPC-CC01, it will
display HAND mode/ AUTO mode on the screen.
1.
This key is executed by the parameter settings of the source of AUTO frequency and
AUTO operation. The factory setting is the external terminal (source of operation is
4-20mA).
2.
Press Auto key at stop status, the setting will switch to hand frequency source and hand
operation source. Press Auto key at operation status, it stops the AC motor drive first
(display AHSP warning), and switch to auto frequency source and auto operation source.
3.
Successful mode switching for KPC-CE01, “H/A” LED will be off; for KPC-CC01, it will
display HAND mode/ AUTO mode on the screen

Descriptions of LED Functions
LED

Descriptions
Steady ON: operation indicator of the AC motor drive, including DC brake, zero speed,
standby, restart after fault and speed search.
Blinking: drive is decelerating to stop or in the status of base block.
Steady OFF: drive doesn’t execute the operation command
Steady ON: stop indicator of the AC motor drive.
Blinking: drive is in the standby status.
Steady OFF: drive doesn’t execute “STOP” command.
Operation Direction LED
1. Green light is on, the drive is running forward.
2. Red light is on, the drive is running backward.
3. Twinkling light: the drive is changing direction.
(Only KPC-CE01 support this function)
Setting can be done during operation.
HAND LED: When HAND LED is on (HAND mode); when HAND LED is off (AUTO mode).
(Only KPC-CE01Support this function )
Setting can be done during operation.
AUTO LED: when AUTO LED is on (AUTO mode); when AUTO LED is off (HAND mode).

10-3

Chapter 10 Digital KeypadC2000 Series
RUN LED:
LED
status
OFF
CANopen at initial

Condition/State

No LED
Blinking CANopen at pre-operation

CANopen ~”RUN”
Single
flash

ON

CANopen at stopped

CANopen at operation status
No LED

ERR LED:
LED
status
OFF
Single One message fail
flash

CANopen ~”ERR”

Double
flash

Triple
flash

Condition/ State
No Error

Guarding fail or heartbeat fail

SYNC fail

ON

Bus off

10-4

Chapter 10 Digital KeypadC2000

10-2 Function of Digital Keypad KPC-CC01

1.
2.

NOTE
Startup page can only display pictures, no flash.
When Power ON, it will display startup page then the main page. The main page displays Delta’s default setting F/H/A/U,
the display order can be set by Pr.00.03 (Startup display). When the selected item is U page, use left key and right key to
switch between the items, the display order of U page is set by Pr.00.04 (User display).

10-5

Chapter 10 Digital KeypadC2000 Series

Display Icon

Display item

1.

Parameter Setup
For example: Setup source of master frequency command.
Once in the Group 00 Motor Drive Parameter,
Use Up/Down key to select parameter 20:
Auto Frequency Command.
When this parameter is selected, press
ENTER key to go to this parameter’s setting
menu.
Use Up/Down key to choose a setting.
For example: Choose “2 Analogue Input, then
press the ENTER key.
After pressing the ENTER key, an END will be
displayed which means that the parameter
setting is done.

2.

Copy Parameter
4 duplicates are provided
The steps are shown in the example below.
Example: Saved in the motor drive.
1 Go to Copy Parameter
2 Select the parameter group which needs to

Press ENTER key to go to 001~004:

be copied and press ENTER key.

content storage
1 Select 1: Save in the motor drive.
2. Press ENTER key to go to “Save in the
motor drive” screen.

10-6

Chapter 10 Digital KeypadC2000

Begin to copy parameters until it is done.

Once copying parameters is done, keypad
will automatically be back to this screen.
Example: Saved in the keypad.
1. Once copying parameters is done, keypad
will automatically be back to this screen.
2. Select the parameter group which needs to
be copied and press ENTER key.
Press ENTER key to go to “Save in the motor
drive” screen.

Use Up/Down key to select a symbol.
Use Left/Right key to move the cursor to
select a file name.
String & Symbol Table:
！＂＃＄％＆＇（）＊＋，－．／０１２３４５６７８９：；＜＝
＞？＠ＡＢＣＤＥＦＧＨＩＪＫＬＭＮＯＰＱＲＳＴＵＶＷＸＹＺ
［＼］＾＿｀ａｂｃｄｆｇｈｉｊｋｌｍｎｏｐｑｒｓｔｕｖｗｘ
ｙｚ｛｜｝～
Once the file name is confirmed, press
ENTER key.

To begin copying parameters until it is done.

When copying parameters is completed,
keypad will automatically be back to this
screen.

Press Right key to see the date of copying
parameters.

Press Right key to see the time of copying
parameters.

10-7

Chapter 10 Digital KeypadC2000 Series

3.

Keypad locked
Keypad Locked
This function is used to lock the keypad. The main page would not display
“keypad locked” when the keypad is locked, however it will display the
message”please press ESC and then ENTER to unlock the keypad” when any
key is pressed.
When the keypad is locked, the main screen doesn’t
display any status to show that.

Press any key on the keypad; a screen as shown in
image on the left will be displayed.

If ESC key is not pressed, the keypad will
automatically be back to this screen.
The keypad is still locked at this moment. By
pressing any key, a screen as shown in the image on
the left will still be displayed.
Press ESC for 3 seconds to unlock the keypad and
the keypad will be back to this screen. Then each key
on the keypad is functional.
Turn off the power and turn on the power again will not lock keypad.

4.

PLC Function
When activate and stop PLC function, the PLC status will be displayed on
main page of Delta default setting.
Optipn 2: Enable PLC function
Press Up/Down key to select a
PLC’s function.
Then press ENTER.

Factory setting on the main screen displays
PLC/RUN status bar.

Option 3: Disable PLC function

Factory setting on the main screen displays
PLC/STOP status bar
If the PLC program is not available in the control
board, PLFF warning will be displayed when
choosing option 2 or 3.
In this case, select option 1 : No Function to clear
PLFF warning.
The PLC function of KPC-CE01 can only displays:
1.
PLC0
2.
PLC1
3.
PLC2

10-8

Chapter 10 Digital KeypadC2000
5.

Copy PLC
4 duplicates are provided
The steps are shown in the example below.
Example: Saved in the motor drive.
1 Go to Copy PLC
2 Select a parameter group to copy then press
ENTER
1 Select 1: Save in the motor drive.
2. Press ENTER key to go to “Save in the motor
drive” screen.

Begin to copy PLC until it is done.

Once copying PLC is done, keypad will automatically
be back to this screen.
NOTE

If “Option 1: Save in the motor drive” is selected,
verify if the PLC program is built-in to KPC-CC01
keypad. If PLC program is not available in the
keypad while “Option 1: Save in the motor drive” is
selected, an “ERR8 Warning: Type not matching” will
be display on the screen.
Unplug and plug back the keypad while copying
the PLC program will have a CPLt warning.

Example: Saved in the keypad.
Once copying PLC is done, keypad will
automatically be back to this screen.
2. Select the parameter group which needs to be
copied and press ENTER key.

1.

Press ENTER key to go to “Save in the motor
drive” screen.

If WPLSoft editor is installed and password is
set, enter the password to save the file onto digital
display.
Use Up/Down key to select a symbol.
Use Left/Right key to move the cursor to select a
file name.
String & Symbol Table:
！＂＃＄％＆＇（）＊＋，－．／０１２３４５６７８９：；＜＝＞？＠Ａ
ＢＣＤＥＦＧＨＩＪＫＬＭＮＯＰＱＲＳＴＵＶＷＸＹＺ［＼］＾＿｀ａｂ
ｃｄｆｇｈｉｊｋｌｍｎｏｐｑｒｓｔｕｖｗｘｙｚ｛｜｝～

10-9

Chapter 10 Digital KeypadC2000 Series

Once the file name is confirmed, press ENTER key.

To begin copying parameters until it is done.

When copying parameters is completed, keypad will
automatically be back to this screen.

Press Right key to see the date of copying
parameters.

Press Right key to see the time of copying
parameters.

6.

Fault record
Able to store 6 error code (Keypad V1.02 and previous versions)
Able to store 20 error code(Keypad V1.0e3 and previous version)
The most recent error record is shown as the first record. Select an error
record to see its detail such as date, tme, frequency, current, voltage, DCBUs
voltage)

Press

Press Up/Down key to select an error record.
After selecting an error code, press ENTER to see
that error record’s detail

ENTER to select.

KPC-CE01 does not support
this function.

Press Up/Down key to see an error record’s detail
such as date, time, frequency, current, voltage,
DCBus voltage.

Press Up/Down key to select an error record.
After selecting an error code, press ENTER to see
that error record’s detail

Press Up/Down key to see an error record’s detail
such as date, time, frequency, current, voltage,
DCBus voltage.

NOTE

Fault actions of AC motor drive are record and save to KPC-CC01. When
KPC-CC01 is removed and apply to another AC motor drive, the previous
fault records will not be deleted. The new fault records of the present AC
motor drive will accumulate to KPC-CC01.

10-10

Chapter 10 Digital KeypadC2000
7.

Quick Start
Description:
1.

Press

ENTER to select.

Quick Start:
1. V/F Mode
2. VFPG Mode
3. SVC Mode
4. FOCPG Mode
5. TQCPG Mode
6. My Mode

2.

VF Mode
Items
1. Parameter Protection Password Input
(P00-07)
2. Parameter Protection Password Setting
(P00-08)
3. Control Mode (P00-10)
4. Control of Speed Mode (P00-11)
01:Password Decoder
5. Load Selection (P00-16)
6. Source of the Master Frequency
Command (AUTO) (P00-20)
7. Source of the Operation Command
(AUTO) (P00-21)
8. Stop Method (P00-22)
9. Digital Keypad STOP function (P00-32)
10. Max. Operation Frequency (P01-00)
11. Base Frequency of Motor 1 (P01-01)
12. Max. Output Voltage Setting of Motor 1
(P01-02)
13. Min. Output Frequency of Motor 1
(P01-07)
14. Min. Output Voltage of Motor 1 (P01-08)
15. Output Frequency Upper Limit (P01-10)
16. Output Frequency Lower Limit (P01-11)
17. Accel. Time 1 (P01-12)
18. Decel Time 1 (P01-13)
19. Over-voltage Stall Prevention (P06-01)
20. Software Brake Level (P07-00)
21. Filter Time of Torque Command
(P07-24)
22. Filter Time of Slip Compensation
(P07-25)
23. Slip Compensation Gain (P07-27)
VFPG Mode
Items
1. Parameter Protection Password Input
(P00-07)
2. Parameter Protection Password
Setting (P00-08)
3. Control Mode (P00-10)
4. Control of Speed Mode (P00-11)
01: Password Decoder
5. Load Selection (P00-16)
6. Source of the Master Frequency
Command (AUTO) (P00-20)
7. Source of the Operation Command
(AUTO) (P00-21)
8. Stop Method (P00-22)
9. Digital Keypad STOP function (P00-32)
10. Max. Operation Frequency (P01-00)
11. Base Frequency of Motor 1 (P01-01)
12. Max. Output Voltage Setting of Motor 1
(P01-02)
13. Min. Output Frequency of Motor 1
(P01-07)
14. Min. Output Voltage of Motor 1
(P01-08)
15. Output Frequency Upper Limit
(P01-10)
16. Output Frequency Lower Limit
(P01-11)
17. Accel. Time 1 (P01-12)

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Chapter 10 Digital KeypadC2000 Series
18.
19.
20.
21.
22.
23.
24.
25.
26.
27.
28.
29.
30.
31.
32.
3.

Decel Time 1 (P01-13)
Over-voltage Stall Prevention
(P06-01)
Software Brake Level (P07-00)
Filter Time of Torque Command
(P07-24)
Filter Time of Slip Compensation
(P07-25)
Slip Compensation Gain (P07-27)
Encoder Type Selection (P10-00)
Encoder Pulse (P10-01)
Encoder Input Type Setting (P10-02)
ASR Control ( P) 1 (P11-06)
ASR Control (I) 1 (P11-07)
ASR Control ( P) 2 (P11-08)
ASR Control (I) 2 (P11-09)
P Gain of Zero Speed (P11-10)
I Gain of Zero Speed (P11-11)

SVC Mode
Items
1.
Parameter Protection Password Input
(P00-07)
2.
Parameter Protection Password
Setting (P00-08)
3.
Control Mode (P00-10)
4.
Control of Speed Mode (P00-11)
01: Password Decoder
5.
Load Selection (P00-16)
6.
Carrier Frequency (P00-17)
7.
Source of the Master Frequency
Command (AUTO) (P00-20)
8.
Source of the Operation Command
(AUTO) (P00-21)
9.
Stop Method (P00-22)
10. Digital Keypad STOP function
(P00-32)
11. Max. Operation Frequency (P01-00)
12. Base Frequency of Motor 1 (P01-01)
13. Max. Output Voltage Setting of Motor
1 (P01-02)
14. Min. Output Frequency of Motor 1
(P01-07)
15. Min. Output Voltage of Motor 1
(P01-08)
16. Output Frequency Upper Limit
(P01-10)
17. Output Frequency Lower Limit
(P01-11)
18. Accel. Time 1 (P01-12)
19. Decel Time 1 (P01-13)
20. Full-load Current of Induction Motor 1
(P05-01)
21. Rated Power of Induction Motor 1
(P05-02)
22. Rated Speed of Induction Motor 1
(P05-03)
23. Pole Number of Induction Motor 1
(P05-04)
24. No-load Current of Induction Motor 1
(P05-05)
25. Over-voltage Stall Prevention
(P06-01)
26. Over-current Stall Prevention during
Acceleration (P06-03)
27. Derating Protection (P06-55)
28. Software Brake Level (P07-00)

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Chapter 10 Digital KeypadC2000
29.
30.
31.
32.
4.

Emergency Stop (EF) & Force to Stop
Selection (P07-20)
Filter Time of Torque Command
(P07-24)
Filter Time of Slip Compensation
(P07-25)
Slip Compensation Gain (P07-27)

FOCPG Mode
Items
1. Parameter Protection Password Input
(P00-07)
2. Parameter Protection Password Setting
(P00-08)
3. Control Mode (P00-10)
4. Control of Speed Mode (P00-11)
01: Password Decoder
5. Source of the Master Frequency
Command (AUTO) (P00-20)
6. Source of the Operation Command
(AUTO) (P00-21)
7. Stop Method (P00-22)
8. Max. Operation Frequency (P01-00)
9. Base Frequency of Motor 1 (P01-01)
10. Max. Output Voltage Setting of Motor 1
(P01-02)
11. Output Frequency Upper Limit (P01-10)
12. Output Frequency Lower Limit (P01-11)
13. Accel. Time 1 (P01-12)
14. Decel Time 1 (P01-13)
15. Full-load Current of Induction Motor 1
(P05-01)
16. Rated Power of Induction Motor 1
(P05-02)
17. Rated Speed of Induction Motor 1
(P05-03)
18. Pole Number of Induction Motor 1
(P05-04)
19. No-load Current of Induction Motor 1
(P05-05)
20. Over-voltage Stall Prevention (P06-01)
21. Over-current Stall Prevention during
Acceleration (P06-03)
22. Derating Protection (P06-55)
23. Software Brake Level (P07-00)
24. Emergency Stop (EF) & Force to Stop
Selection (P07-20)
25. Encoder Type Selection (P10-00)
26. Encoder Pulse (P10-01)
27. Encoder Input Type Setting (P10-02)
28. System Control (P11-00)
29. Per Unit of System Inertia (P11-01)
30. ASR1 Low-speed Bandwidth (P11-03)
31. ASR2 High-speed Bandwidth (P11-04)
32. Zero-speed Bandwidth (P11-05)

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Chapter 10 Digital KeypadC2000 Series
5.

TQCPG Mode
Items
1. Password Input (Decode) (P00-07)
2. Password Setting (P00-08)
3. Control Mode (P00-10)
4. Control of Speed Mode (P00-11)
5. Source of the Master Frequency
Command (P00-20)
01: Password Decoder
6. Source of the Operation Command
(P00-21)
7. Max. Operation Frequency (P01-00)
8. Base Frequency of Motor 1 (P01-01)
9. Max. Output Voltage Setting of Motor 1
(P01-02)
10. Full-load Current of Induction Motor 1
(P05-01)
11. Rated Power of Induction Motor 1
(P05-02)
12. Rated Speed of Induction Motor 1
(P05-03)
13. Pole Number of Induction Motor 1
(P05-04)
14. No-load Current of Induction Motor 1
(P05-05)
15. Over-voltage Stall Prevention (P06-01)
16. Software Brake Level (P07-00)
17. Encoder Type Selection (P10-00)
18. Encoder Pulse (P10-01)
19. Encoder Input Type Setting (P10-02)
20. System Control (P11-00)
21. Per Unit of System Inertia (P11-01)
22. ASR1 Low-speed Bandwidth (P11-03)
23. ASR2 High-speed Bandwidth (P11-04)
24. Zero-speed Bandwidth (P11-05)
25. Max. Torque Command (P11-27)
26. Source of Torque Offset (P11-28)
27. Torque Offset Setting (P11-29)
28. Source of Torque Command (P11-33)
29. Torque Command (P11-34)
30. Speed Limit Selection (P11-36)
31. Forward Speed Limit (torque mode)
(P11-37)
32. Reverse Speed Limit (torque mode)
(P11-38)

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Chapter 10 Digital KeypadC2000
6.

My Mode
Items

Click F4 in parameter
setting page, the
parameter will save to

It can save 01~32 sets of parameters (Pr).
Setup process
1. Go to Parameter Setup function.
Press ENTER to go to the parameter
which you need to use. There is an
ADD on the bottom right-hand corner of
the screen. Press F4 on the key pad
to add this parameter to My Mode

My Mode. To delete or
correct the parameter,
enter this parameter and
click the “DEL” on the
bottom right corner.

2. The parameter (Pr) will be displayed in
My mode if it is properly saved.
To correct or to delete this Pr. clicks
DEL.

3. To delete a parameter, go to My Mode
and select a parameter which you need
to delete.
Press ENTER to enter the parameter
setting screen. There is a DEL on the
bottom left-hand corner of the screen.
Press F4 on the keypad to delete this
parameter from My Mode.

4. After pressing ENTER to delete <01
Control Mode>, the <02 Maximum
Operating Frequency > will
automatically replace <01 Control
Mode>.

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Chapter 10 Digital KeypadC2000 Series

8.

Display setup
1. Contrast
Use Up/Down key to adjust the setting
value.

After selecting a setting value. Press
ENTER to see screen’s display after
contrast is adjusted to be +10.

When the setting value is 0 Min, the back
light will be steady on.

Then press ENTER.

After select a setting value Press ENTER to
see screen’s display result after contrast is
adjusted to be -10.
2. Back-light
Press ENTER to go to Back Light Time
Setting screnn.

Use Up/Down key to adjust the setting
value.

When the setting value is 0 Min, the back
light will be steady on.

When the setting value is 10 Min, the
backlight will be off in 10 minutes.

9.

Time setting

Time setup
Use Up/Down key to set up Year

2009/01/01
_ _ : _ _ :_ _
Use Left/Right key to select

Use Up/Down key to set up Month

Year, Month, Day, Hour, Minute
or Second to set up

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Chapter 10 Digital KeypadC2000

Use Up/Down key to set up day

Use Up/Down key to set up hour

Use Up/Down key to set up Minute

Use Up/Down key to set up Second

After setting up, press ENTER to confirm
the setup.

NOTE

When the digital keypad is removed, the time setting will be in standby status
for 7 days. After this period, the time needs to be reset.

10. Language setup
Language setting option is displayed in the language of the user’s choice.
Language setting options:

Use Up/Down key to select
language, than press ENTER.

1. English

5.

2. 繁體中文

6. Espanol

3. 简体中文

7. Portugues

4. Turkce

11. Startup-up
1. Default 1

DELTA LOGO

2. Default 2

DELTA Text

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Chapter 10 Digital KeypadC2000 Series
3. User Defined: optional accessory is require (TPEditor & USB/RS-485
Communication Interface-IFD6530)
Install an editing accessory would allow users to design their own start-up
page.If editor accessory is not installed, “user defined” option will dispay a
blank page.

USB/RS-485 Communication Interface-IFD6530
Please refer to Chapter 07 Optional Acessories for more detail.
TPEditor
Go to Delta’s website to download TPEditor V1.30.6 or later versions.
http://www.delta.com.tw/ch/product/em/download/download_main.asp?act
=3&pid=1&cid=1&tpid=3

12. Main page
1. Default page

F
H
u
Default picture and editable
picture are available upon
selection.

Press

ENTER to select.

60.00Hz
0.00Hz
540.0Vdc

F 600.00Hz >>> H >>> A >>> U (circulate)
2. User Defined: optional accessory is require (TPEditor & USB/RS-485
Communication Interface-IFD6530)
Install an editing accessory would allow users to design their own start-up
page.If editor accessory is not installed, “user defined” option will dispay a
blank page.

USB/RS-485 Communication Interface-IFD6530
Please refer to Chapter 07 Optional Acessories for more detail.
TPEditor
Go to Delta’s website to download TPEditor V1.30.6 or later versions.
http://www.delta.com.tw/ch/product/em/download/download_main.asp?act
=3&pid=1&cid=1&tpid=3

13. PC Link
1.

TPEditor: This function allows users to connect the keypad to a
computer then to download and edit user defined pages.

Click ENTER to go to 

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Chapter 10 Digital KeypadC2000
In TPEditor, choose , then choose “Write to HMI”

Choose  in the  dialogue box.

Start downloading pages to edit KPC-CC01.

Download completed

2.

VFDSoft: this function allows user to link to the VFDSoft Operating
software then to upload data
Copy parameter 1~4 in KPC-CC01
Connect KPC-CCO1 to a computer
Start downloading
KPC-CC01

pages

to

edit

to

Use Up/Down key to select a parameter
group to upload to VFDSoft.
Press ENTER

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Chapter 10 Digital KeypadC2000 Series

Waiting to connect to PC

Open VFDSoft, choose 

In Parameter Manager, choose 

Choose the right communication port and click OK

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Chapter 10 Digital KeypadC2000

Start to upload parameters to VFDSoft

Uploading parameter is completed

Before using the user defined starting screen and user defined main
screen, the starting screen setup and the main screen setup have to be
preset as user defined.
If the user defined page are not downloaded to KPC-CC01, the starting
screen and the main screen will be blank.

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Chapter 10 Digital KeypadC2000 Series

Other display
When fault occur, the menu will display:

Fault

Warning

ocA

CE01
Comm. Error 1

Oc at accel

1. Press ENTER and start RESET. If still no response, please contact local distributor or return to the factory. To
view the fault DC BUS voltage, output current and output voltage, press “MENU”“Fault Record”.
2. Press ENTER again, if the screen returns to main page, the fault is clear.
3. When fault or warning message appears, backlight LED will blinks until the fault or the warning is cleared.

Optional accessory: RJ45 Extension Lead for Digital Keypad
Part No.

Description

CBC-K3FT

RJ45 extension lead, 3 feet (approximately 0.9m)

CBC-K5FT

RJ45 extension lead, 5 feet (approximately 1.5 m)

CBC-K7FT

RJ45 extension lead, 7 feet (approximately 2.1 m)

CBC-K10FT

RJ45 extension lead, 10 feet (approximately 3 m)

CBC-K16FT

RJ45 extension lead, 16 feet (approximately 4.9 m)

Note: When you need to buy communication cables, buy non-shielded , 24 AWG, 4 twisted pair, 100 ohms
communication cables.

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Chapter 10 Digital KeypadC2000

10-3 TPEditor Installation Instruction
TPEditor can edit up to 256 HMI (Human-Machine Interface) pages with a total storage capacity of 256kb.
Each page can edit 50 normal objects and 10 communication objects.

1)

TPEditor: Setup & Basic Functions
1. Run TPEditor version 1.30

2. Go to File(F)Click on New. The Window below will pop up. At the device type, click on the drop down
menu and choose DELTA VFD-C Inverter. At the TP type, click on the drop down menu and choose VFD-C
KeyPad. As for File Name, enter TPE0. Now click on OK.

3. You are now at the designing page. Go to Edit (E)Click on Add a New Page (A) or go to the TP page on
the upper right side, right click once on TP page and choose Add to increase one more page for editing.
The current firmware of Keypad is version1.00 and can support up to 4 pages.

4. Edit Startup Page

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Chapter 10 Digital KeypadC2000 Series

5. Static Text
. Open a blank page, click once on this button
page. The following windows will pop up.

, and then double click on that blank

6. Static Bitmap
Open a blank page, then click once on this button
blank page. The following window will pop up.

and then double click on that

Please note that Static Bitmap setting support only images in BMP format. Now choose a image that
you need and click open, then that image will appear in the Static Bitmap window.
 As shown in the picture on the left side, there
7. Geometric Bitmap
are 11 kinds of geometric bitmap to choose. Open a new blank page then click once on a geometric bitmap
icon that you need. Then drag that icon and enlarge it to the size that you need on that blank page.

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Chapter 10 Digital KeypadC2000
8. Finish editing the keypad starting screen and select Communication>Input User Defined Keypad
Starting Screen.

9. Downloading setting: Go to Tool > Communication. Set up communication port and speed of IFD6530.
10. Only three speed selections are available: 9600 bps, 19200 bps and 38400 bps.

11. When a dialogue box displayed on the screen asking to confirm writing or not, press buttons on the keypad
to go to MENU, select PC LINK and then press ENTER and wait for few seconds. Then select YES on the
screen to start downloading.

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Chapter 10 Digital KeypadC2000 Series

2)

Edit Main Page & Example of Download
1.

Go to editing page, select EditàAdd one page or press the button ADD on the right hand side of the HMI
page to increase number of pages to edit. This keypad currently support up to 256 pages.

2.

On the bottom right-hand corner of the HMI, click on a page number to edit or go to VIEW >HMI page to
start editing main page. As shown in the image, the following objects are available. From left to right:
Static Text, ASCII Display, Static Bitmap, Scale, Bar Graph, Button, Clock Display, Multi-state bit map,
Units, Numeric Input and 11 geometric bitmaps and lines of different width. The application of Static Text,
Static Bitmap, and geometric bitmap is the same as the editing startup page.

3.

Numric/ASCII Display : To add a Numeric/ASCII Display object to a screen, double click on the object to
set up Related Devices, Frame Setting , Fonts and Alignment.

Related Device: Choose the VFD Communication Port that you need, if you want to read output
frequency (H), set the VFD Communication Port to $2202. For other values, please refer to ACMD
ModBus Comm Address List.

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Chapter 10 Digital KeypadC2000
4.

Scale Setting
: On the Tool Bar, click on this
for Scale Setting. You can also edit Scale Setting in
the Property Window on the right hand side of your computer screen.

a.
b.

c.
d.
e.
f.

5.

Scale Position: Click on the drop down list to choose which position that you need to place a scale.
Scale Side: Click on the drop down list to choose if you want to number your scale from smaller
number to bigger number or from big to small. Click OK to accept this setting or click Cancel to
abort.
Font Setting: Click on the drop down list to choose the Font setting that you need then click OK to
accept the setting or click Cancel to abort.
Value Length: Click on the drop down to choose 16bits or 32 bits. Then click OK to accept the
setting or click Cancel to abort.
Main Scale & Sub Scale: In order to divide the whole scale into equal parts, key in the numbers of
your choices for main scale and sub scale.
Maximum value & Minimum Value are the numbers on the two ends of a scale. They can be
negative numbers. But the values allowed to be input are limited by the length of value. For
example, when the length of value is set to be hexadecimal, the maximum and the minimum value
cannot be input as -4000.
Follow the Scale setting mentioned above; you will have a scale as shown below.

Bar Graph setting

a.
b.
c.

:

Related Device: Choose the VFD Communication Port that you need.
Direction Setting: Click on the drop down menu to choose one of the following directions: From
Bottom to Top, From Top to Bottom, From Left to Right or From Right to Left.
Maximum Value & Minimum Value: They define the range covered by the maximum value and
minimum value. If a value is smaller than or equal to the minimum value, then the bar graph will be
blank. If a value is bigger or equal to the maximum value, then the bar graph will be full. If a value is
between minimum and maximum value, then the bar graph will be filled proportionally.

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Chapter 10 Digital KeypadC2000 Series
6.

Button
: Currently this function only allows the Keypad to switch pages, other functions are not yet
available. Text input function and Image inserted functions are not yet supported.
Double click on

to open set up window.

 allows users set up buttons’ functions.  and  are the only
two currently supported functions.
A [ Page Jump ] function setting

Page Jump setting: After you choose the Page Jump function in the drop down list, you will see this
Page Jump Setting Menu

 allows you to assign functions to the following keys on the KPC-CC01 keypad: F1,
F2, F3, F4, Up, Down, Left and Right. Please note that the Up and Down keys are locked by
TPEditor. These two keys cannot be programmed. If you want to program Up and Down keys, go to
ToolFunction Key Settings (F)Re-Define Up/Down Key(R).



Button Text: This function allows user to name buttons. For example, key in  in the
empty space, a button will have the wording  displayed on it.
B [ Constant setting ] function
This function is to set up the memory address’ value of the VFD or PLC. When pressing the  set up in before, a value will be written to the memory address of the . This
function can be used as initializing a variable.

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Chapter 10 Digital KeypadC2000
7.

Clock Display Setting
: The setup window of the Clock Display is shown as the image below. Time,
Day or Date can be displayed on the keypad.
Open a new file and click once in that window, you will see the following
In the clock display setting, you can choose to display Time, Day or Date on the Keypad. To adjust time,
go to #9 on the Keypad’s menu. You can also adjust Frame Setting, Font Setting and Alignment.

8.

: The setup window of the multi-state is shown as the image below. This object
Multi-state bitmap
reads the bit’s property value of the PLC. It defines what image or wording is when this bit is 0 or when
this bit is 1. Set the initial status to be 0 or 1 to define the displayed image or wording.

9.

: Click once on this Button:
Unit Measurement
Open a new file and double click on that window, you will see the following

Choose from the drop down list the Metrology and the Unity Name that you need.
As for Metrology, you have the following choices Length, Square Measure, Volume/Solid Measure,
Weight, Speed, Time and Temperature. The unit name changes automatically when you change
metrology type.

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Chapter 10 Digital KeypadC2000 Series
10.

Numeric Input Setting

:

This menu allows you to provide parameters or communication ports and to input numbers.
Click once on this button
.
Open a new file and double click on that window, you will see the following:

a.

b.
c.

d.

e.
f.
g.

11.

Related Device: There are two blank spaces to fill in, one is  and another one is .
Input the numbers that you want to display and the corresponding numbers of a parameter and that
of a communication port. For example, input 012C to Read and Write Parameter P01-44.
OutLine Setting: The Frame setting, Font setting, Vertical Alignment and Horizontal Alignment are
the same as mentioned before. Click on the drop down menu and choose the setting that you need.
Function key: The setting here allows you to program keys on the keypad. Press the key on the
menu then the corresponding key on the keypad will start to blink, then press Enter to confirm the
setting.
Value Type & Value Length: These two factors influence the range of the Minimum and Maximum
Value of the Limit Setting. Please note that the corresponding supporting values for C2000 have to
be 16bits. The 32bits values are not supported.
Value Setting: This part is set automatically by the keypad itself.
Limit Setting: Input the range the security setting here.
For example, if you set Function Key as F1, Minimum Value as 0 and Maximum Value ias 4, then
press F1 on Keypad Then you can press Up and Down key on the keypad to increase or decrease
the value. Press Enter Key on the keypad to confirm your setting. You can also go to parameter
table 01-44 to verify if your input correctly the value.

Download TP Page : Press Up or Down key on the keypad until you reach #13 PC Link.
Then press Enter on the keypad and you will see the word “Waiting” on keypad’s screen. Now
choose a page that you have created then go to Communication (M)Write to TP(W) to start
downloading the page to the keypad
When you see the word Completed on the keypad’s screen, that means the download is done.
Then you can press ESC on the keypad to go back to the menu of the keypad.

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Chapter 10 Digital KeypadC2000

3) Edit Main Page
1. On the bottom right-hand corner of the HMI, click on a page number to edit or go to VIEW >HMI page to start
editing main page. As shown in the image, the following objects are available. From left to right: Static Text,
ASCII Display, Static Bitmap, Scale, Bar Graph, Button, Clock Display, Multi-state bit map, Units, Numeric
Input and 11 geometric bitmaps and lines of different width. The application of Static Text, Static Bitmap, and
geometric bitmap is the same as the editing startup page.

2. Numric/ASCII Display : To add a Numeric/ASCII Display object to a screen, double click on the object to set up
Related Devices, Frame Setting , Fonts and Alignment.

Related Device: Choose the VFD Communication Port that you need, if you want to read output
frequency (H), set the VFD Communication Port to $2202. For other values, please refer to ACMD
ModBus Comm Address List.

: On the Tool Bar, click on this
for Scale Setting. You can also edit Scale Setting in the
3. Scale Setting
Property Window on the right hand side of your computer screen.

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Chapter 10 Digital KeypadC2000 Series
i.
ii.

iii.
iv.
v.
vi.

Scale Position: Click on the drop down list to choose which position that you need to place a scale.
Scale Side: Click on the drop down list to choose if you want to number your scale from smaller
number to bigger number or from big to small. Click OK to accept this setting or click Cancel to
abort.
Font Setting: Click on the drop down list to choose the Font setting that you need then click OK to
accept the setting or click Cancel to abort.
Value Length: Click on the drop down to choose 16bits or 32 bits. Then click OK to accept the
setting or click Cancel to abort.
Main Scale & Sub Scale: In order to divide the whole scale into equal parts, key in the numbers of
your choices for main scale and sub scale.
Maximum value & Minimum Value are the numbers on the two ends of a scale. They can be
negative numbers. But the values allowed to be input are limited by the length of value. For example,
when the length of value is set to be hexadecimal, the maximum and the minimum value cannot be
input as -4000.
Follow the Scale setting mentioned above; you will have a scale as shown below.

4. Bar Graph setting

i.
ii.
iii.

:

Related Device: Choose the VFD Communication Port that you need.
Direction Setting: Click on the drop down menu to choose one of the following directions: From
Bottom to Top, From Top to Bottom, From Left to Right or From Right to Left.
Maximum Value & Minimum Value: They define the range covered by the maximum value and
minimum value. If a value is smaller than or equal to the minimum value, then the bar graph will be
blank. If a value is bigger or equal to the maximum value, then the bar graph will be full. If a value is
between minimum and maximum value, then the bar graph will be filled proportionally.

: Currently this function only allows the Keypad to switch pages, other functions are not yet
5. Button
available. Text input function and Image inserted functions are not yet supported.
Double click on

to open set up window.

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Chapter 10 Digital KeypadC2000
 allows users set up buttons’ functions.  and  are the only
two currently supported functions.
A [ Page Jump ] function setting

Page Jump setting: After you choose the Page Jump function in the drop down list, you will see this
Page Jump Setting Menu

 allows you to assign functions to the following keys on the KPC-CC01 keypad: F1,
F2, F3, F4, Up, Down, Left and Right. Please note that the Up and Down keys are locked by
TPEditor. These two keys cannot be programmed. If you want to program Up and Down keys, go to
ToolFunction Key Settings (F)Re-Define Up/Down Key(R).



Button Text: This function allows user to name buttons. For example, key in  in the
empty space, a button will have the wording  displayed on it.
B [ Constant setting ] function
This function is to set up the memory address’ value of the VFD or PLC. When pressing the  set up in before, a value will be written to the memory address of the . This
function can be used as initializing a variable.

6.

: The setup window of the Clock Display is shown as the image below. Time, Day or
Clock Display Setting
Date can be displayed on the keypad.
Open a new file and click once in that window, you will see the following
In the clock display setting, you can choose to display Time, Day or Date on the Keypad. To adjust time,
go to #9 on the Keypad’s menu. You can also adjust Frame Setting, Font Setting and Alignment.

10-33

Chapter 10 Digital KeypadC2000 Series

7.

Multi-state bitmap
: The setup window of the multi-state is shown as the image below. This object reads
the bit’s property value of the PLC. It defines what image or wording is when this bit is 0 or when this bit is 1.
Set the initial status to be 0 or 1 to define the displayed image or wording.

8.

Unit Measurement
: Click once on this Button:
Open a new file and double click on that window, you will see the following

Choose from the drop down list the Metrology and the Unity Name that you need.
As for Metrology, you have the following choices Length, Square Measure, Volume/Solid Measure,
Weight, Speed, Time and Temperature. The unit name changes automatically when you change
metrology type.
9.

:
Numeric Input Setting
This menu allows you to provide parameters or communication ports and to input numbers.
Click once on this button
.
Open a new file and double click on that window, you will see the following:

h.

i.
j.

k.

l.
m.

Related Device: There are two blank spaces to fill in, one is  and another one is .
Input the numbers that you want to display and the corresponding numbers of a parameter and that
of a communication port. For example, input 012C to Read and Write Parameter P01-44.
OutLine Setting: The Frame setting, Font setting, Vertical Alignment and Horizontal Alignment are
the same as mentioned before. Click on the drop down menu and choose the setting that you need.
Function key: The setting here allows you to program keys on the keypad. Press the key on the
menu then the corresponding key on the keypad will start to blink, then press Enter to confirm the
setting.
Value Type & Value Length: These two factors influence the range of the Minimum and Maximum
Value of the Limit Setting. Please note that the corresponding supporting values for C2000 have to
be 16bits. The 32bits values are not supported.
Value Setting: This part is set automatically by the keypad itself.
Limit Setting: Input the range the security setting here.

10-34

Chapter 10 Digital KeypadC2000
n.

10.

For example, if you set Function Key as F1, Minimum Value as 0 and Maximum Value ias 4, then
press F1 on Keypad Then you can press Up and Down key on the keypad to increase or decrease
the value. Press Enter Key on the keypad to confirm your setting. You can also go to parameter
table 01-44 to verify if your input correctly the value.

Download TP Page : Press Up or Down key on the keypad until you reach #13 PC Link.
Then press Enter on the keypad and you will see the word “Waiting” on keypad’s screen. Now choose a
page that you have created then go to Communication (M)Write to TP(W) to start downloading the
page to the keypad
When you see the word Completed on the keypad’s screen, that means the download is done.
Then you can press ESC on the keypad to go back to the menu of the keypad.

10-35

Chapter 10 Digital KeypadC2000 Series

10-4 Digital Keypad KPC-CC01 Fault Codes and Descriptions
Following fault codes and description are for digital keypad KPC-CC01 with version V1.01 and version
higher.
LCM Display *

Fault
FrEr
kpdFlash Read Er

Fault
FSEr
kpdFlash Save Er

Fault
FPEr
kpdFlash Pr Er

Fault
VFDr
Read VFD Info Er

Fault
CPUEr
CPU Error

Description

Corrective Actions
An error has occurred on keypad’s flash memory.
1. Press RESET on the keypad to clear errors.
2. Verify what kind of error has occurred on
keypad’s flash memory.
Keypad flash memory read error
3. Shut down the system, wait for ten minutes,
and then power on again the system.
If none of the solution above works, contact your
authorized local dealer.
An error has occurred on keypad’s flash memory.
1. Press RESET on the keypad to clear errors.
2. Press RESET on the keypad to clear errors.
Keypad flash memory save error 3. Shut down the system, wait for ten minutes,
and then power on again the system.
If none of the solution above works, contact your
authorized local dealer.
Errors occurred on parameters of factory setting.
It might be caused by firmware update.
1. Press RESET on the keypad to clear errors.
Keypad flash memory parameter 2. Verify if there’s any problem on Flash IC.
error
3. Shut down the system, wait for ten minutes,
and then power on again the system.
If none of the solution above works, contact your
local authorized dealer.
Keypad can’t read any data sent from VFD.
1. Verify if the keypad is properly connect to the
motor drive by a communication cable such as
RJ-45.
Keypad flash memory when
2. Press RESET on the keypad to clear errors.
read AC drive data error
3. Shut down the system, wait for ten minutes,
and then power on again the system.
If none of the solution above works, contact your
local authorized dealer.
A Serious error has occurred on keypad’s CPU.
1. Verify if there’s any problems on CPU clock?
2. Verify if there’s any problem on Flash IC?
3. Verify if there’s any problem on RTC IC?
and then power on again the 4. Verify if the communication quality of the
RS485 is good?
system.
5. Shut down the system, wait for ten minutes,
and then power on again the system. If none of
the solution above works, contact your local
authorized dealer.

10-36

Chapter 10 Digital KeypadC2000

Warning Code
LCM Display *

Warning

CE01
Comm Command Er

Warning

CE02
Comm Address Er

Warning

CE03
Comm Data Error

Warning

CE04
Comm Slave Error

Warning

CE10
KpdCom m Time O ut

Warning

TPNO
TP No Object

Description

Corrective Actions

Motor drive doesn’t accept the communication
command sent from keypad.
1. Verify if the keypad is properly connected to the
motor drive on the communication contact by a
Modbus function code error
communication cable such as RJ-45.
2. Press RESET on the keypad to clear errors.
If none of the solution above works, contact your local
authorized dealer.
Motor rive doesn’t accept keypad’s communication
address.
1. Verify if the keypad is properly connected to the
motor drive on the communication contact by a
Modbus data address error
communication cable such as RJ-45.
2. Press RESET on the keypad to clear errors.
If none of the solution above works, contact your local
authorized dealer.
Motor drive doesn’t accept the communication data
sent from keypad.
1. Verify if the keypad is properly connected to the
motor drive on the communication contact by a
Modbus data value error
communication cable such as RJ-45.
2. Press RESET on the keypad to clear errors.
If none of the solution above works, contact your local
authorized dealer.
Motor drive cannot process the communication
command sent from keypad.
1. Verify if the keypad is properly connected to the
motor drive on the communication contact by a
communication cable such as RJ-45.
Modbus slave drive error
2. Press RESET on the keypad to clear errors.
3. Shut down the system, wait for ten minutes, and
then power on again the system.
If none of the solution above works, contact your local
authorized dealer.
Motor drive doesn’t respond to the communication
command sent from keypad.
1. Verify if the keypad is properly connected to the
motor drive on the communication contact by a
communication cable such as RJ-45.
Modbus transmission time-Out 2. Press RESET on the keypad to clear errors.
3. Shut down the system, wait for ten minutes, and
then power on again the system.
If none of the solution above works, contact your local
authorized dealer.
Keypad’s TP Editor uses unsupported object.
1. Verify how the TP editor should use that object.
Delete unsupported object and unsupported
Object not supported by TP
setting.
Editor
2. Reedit the TP editor and then download it.
If none of the solution above works, contact your local
authorized dealer.

10-37

Chapter 10 Digital KeypadC2000 Series

File Copy Setting Fault Description
LCM Display *
File 1
Err 1
Read Only

File 1
Err
Write Fail

File 1
Err
VFD Running

File 1
Err
Pr Lock

File 1
Err
Pr Changing

File 1
Err
Fault Code

File 1
Err
Warning Code

File 1
Err
Type Dismatch

File 1
Err
Password Lock

Description

Corrective Actions

The property of the parameter/file is read-only and
cannot be written to.
Parameter and rile are read only 1. Verify the specification on the user manual.
If the solution above doesn’t work, contact your local
authorized dealer.
An error occurred while write to a parameter/file.
1. Verify if there’s any problem on the Flash IC.
2. Shut down the system, wait for ten minutes, and
Fail to write parameter and file then power on again the system.
If none of the solution above work, contact your local
authorized dealer.
A setting cannot be made while motor drive is in
operation.
AC drive is in operating status 1. Verify if the drive is not in operation.
If the solution above doesn’t work, contact your local
authorized dealer.
A setting cannot be made because a parameter is
locked.
1. Verify if the parameter is locked or not. If it is locked,
AC drive parameter is locked
unlock it and try to set up the parameter again.
If the solution above doesn’t work, contact your local
authorized dealer.
A setting cannot be made because a parameter is
being modified.
1. Verify if the parameter is being modified. If it is not
AC drive parameter changing
being modified, try to set up that parameter again.
If the solution above doesn’t work, contact your local
authorized dealer.
A setting cannot be made because an error has
occurred on the motor drive.
1. Verify if there’s any error occurred on the motor
dive. If there isn’t any error, try to make the setting
Fault code
again.
If the solution above doesn’t work, contact your local
authorized dealer.
A setting cannot be made because of a warning
message given to the motor drive.
1. Verify if there’s any warning message given to the
Warning code
motor drive.
If the solution above doesn’t work, contact your local
authorized dealer.
Data need to be copied are not same type, so the
setting cannot be made.
1. Verify if the products’ serial numbers need to be
copied fall in the category. If they are in the same
File type dismatch
category, try to make the setting again.
If the solution above doesn’t work, contact your
authorized dealer.
A setting cannot be made, because some data are
locked.
1. Verify if the data are unlocked or able to be
unlocked. If the data are unlocked, try to make the
setting again.
File is locked with password
2. Shut down the system, wait for ten minutes, and
then power on again the system.
If none of the solution above works, contact your local
authorized dealer.

10-38

Chapter 10 Digital KeypadC2000
LCM Display *

File 1
Err 10
Password Fail

File 1
Err
Version Fail

File 1
Err
VFD Time Out

Description

Corrective Actions

A setting cannot be made because the password is
incorrect.
1. Verify if the password is correct. If the password is
correct, try to make the setting again.
File version dismatch
2. Shut down the system, wait for ten minutes, and
then power on again the system.
If none of the solution above works, contact your local
authorized dealer.
A setting cannot be made, because the version of the
data is incorrect.
1. Verify if the version of the data matches the motor
AC drive copy function time-out drive. If it matches, try to make the setting again.
If none of the solution above works, contact your local
authorized dealer.
A setting cannot be made, because data copying
timeout expired.
1. Redo data copying.
2. Verify if copying data is authorized. If it is
authorized, try again to copy data.
Other keypad error
3. Shut down the system, wait for ten minutes, and
then power on again the system.
If none of the solution above works, contact your local
authorized dealer.

Other AC drive error

This setting cannot be made, due to other keypad
issues. (Reserved functions)
If such error occurred, contact your local authorized
dealer.

File is locked with password

This setting cannot be made, due to other motor drive
issues. (Reserved functions).
If such error occurred, conatct your local authorized
dealer.

File 1
Err
Keypad Issue

File 1
Err
VFD Issue

※ The content in this chapter only applies on V1.01 and above of KPC-CC01 keypad.

10-39

Chapter 11 Summary of Parameter SettingsC2000 Series

Chapter 11 Summary of Parameter Settings
This chapter provides summary of parameter settings for user to gather the parameter setting ranges,
factory settings and set parameters. The parameters can be set, changed and reset by the digital keypad.
NOTE
1） : the parameter can be set during operation
2） For more detail on parameters, please refer to Ch12 Description of Parameter Settings.

00 Drive Parameters
NOTE

Pr.

IM: Induction Motor; PM: Permanent Magnet Motor
Settings

Explanation

00-00

Identity Code of the AC Motor Drive

4: 230V, 1HP
5: 460 V, 1HP
6: 230V,2HP
7: 460 V, 2HP
8: 230V, 3HP
9: 460 V, 3HP
10: 230V, 5HP
11: 460 V, 5HP
12: 230V, 7.5HP
13: 460 V, 7.5HP
14: 230V, 10HP
15: 460V, 10HP
16: 230V, 15HP
17: 460V, 15HP
18: 230V, 20HP
19: 460V, 20HP
20: 230V, 25HP
21: 460V, 25HP
22: 230V, 30HP
23: 460V, 30HP
24: 230V, 40HP
25: 460V, 40HP
26: 230V, 50HP
27: 460V, 50HP
28: 230V, 60HP
29: 460V, 60HP
30: 230V, 75HP
31: 460V, 75HP
32: 230V, 100HP
33: 460V, 100HP
34: 230V, 125HP
35: 460V, 125HP
37: 460V, 150HP
39: 460V, 175HP
41: 460V, 215HP
43: 460V, 250HP
45: 460V, 300HP
47: 460V, 375HP
49: 460V, 425HP
51: 460V, 475HP
55: 460V, 600HP
93: 460V, 5HP（4kW）

00-01

Display AC Motor Drive Rated
Current

Display by models

11-1

Factory
Setting

Read
only

Read
only

Chapter 11 Summary of Parameter SettingsC2000 Series

00-02

Parameter Reset



00-03

Start-up Display Selection



00-04

Content of Multi-function Display

0: No function
1: Read only
5: Reset KWH display to 0
6: Reset PLC (including CANopen Master Index)
7: Reset CANopen Index (Slave)
8: No function
9: All parameters are reset to factory settings(base
frequency is 50Hz)
10: All parameters are reset to factory settings (base
frequency is 60Hz
0: F (frequency command)
1: H (output frequency)
2: U (multi-function display, see Pr.00-04)
3: A (output current)
0: Display output current (A) (Unit: Amps)
1: Display counter value (c) (Unit: CNT)
2: Display actual output frequency (H.) (Unit: Hz)
3: Display DC-BUS voltage (v) (Unit: Vdc)
4: Display output voltage (E) (Unit: Vac)
5: Display output power angle (n) (Unit: deg)
6: Display output power in kW (P) (Unit: kW)
7: Display actual motor speed rpm (r) (Unit: rpm)
8: Display estimate output torque % (t) (Unit: %)
9: Display PG feedback (G) (refer to Pr.10-00,10-01)
(Unit: PLS)
10: Display PID feedback (b) (Unit: %)
11: Display AVI in % (1.) (Unit: %)
12: Display ACI in % (2.) (Unit: %)
13: Display AUI in % (3.) (Unit: %)
14: Display the temperature of IGBT in ℃ (i.) (Unit:
℃)
15: Display the temperature of capacitance in ℃
(c.) (Unit: ℃)
16: The status of digital input (ON/OFF) (i)
17: The status of digital output (ON/OFF) (o)
18: Multi-step speed (S)
19: The corresponding CPU pin status of digital
input (d)
20: The corresponding CPU pin status of digital
output (0.)
21: Actual motor position (PG1 of PG card) (P.)
22: Pulse input frequency (PG2 of PG card) (S.)
23: Pulse input position (PG2 of PG card) (q.)
24: Position command tracing error (E.)
25: Overload count (0.00~100.00%) (o.) (Unit: %)
26: Ground Fault GFF(G.) (Unit: %)
27: DC Bus voltage ripple (Unit: Vdc) (r.)
28: Display PLC data D1043 (C)
29: Display PM motor pole section (EMC-PG01U
application) (4.)
30: Display output of user defined (U)
31: Display Pr.00-05 user Gain(K)
32: Number of actual motor revolution during
operation (PG card plug in and Z phase signal
input) (Z.)
33: Motor actual position during operation (when PG
card is connected)(q)
34: Operation speed of fan (F.) (Unit: %)
35: Control Mode display: 0= Speed control mode
(SPD), 1= torque control mode (TQR) (t.)
36: Present operating carrier frequency of drive (Hz)
(J.)
37: Reserved

11-2

0

0

3

Chapter 11 Summary of Parameter SettingsC2000 Series
38: Display drive status (6.)
39: Display estimated output torque, positive and
negative, using Nt-m as unit (t 0.0: positive
torque; -0.0: negative torque (C.)
40: Torque Command (L) (Unit: %)
41: KWH display (J) (Unit: kWH)
42: PID Reference (h.) (Unit: %)
43: PID offset (o.) (Unit: %)
44: PID Output Fcmd(Hz) (b.) (Unit: Hz)
45: Hardware ID
00-05

Coefficient Gain in Actual Output
Frequency

0~160.00

1.00

00-06

Software Version

Read only

#.#



00-07

Parameter Protection Password
Input



00-08

Parameter Protection Password
Setting

0～65535
0~3: the times of password attempts
0 ~ 65535
0: No password protection / password is entered
correctly (Pr00-07)
1: Parameter is locked

00-09

Reserved





00-10

Control Mode

00-11

Control of Speed Mode

00-12

Point-to-Point Position mode

00-13

Torque Mode Control

00-14

Reserved

00-15

Reserved

00-16

Load Selection

00-17

00-18
00-19

Carrier Frequency

0: Speed mode
1: Point-to-Point position control
2: Torque mode
3: Home mode
0: VF (IM V/f control)
1: VFPG (IM V/f control+ Encoder)
2: SVC(IM Sensorless vector control)
3: FOCPG (IM FOC vector control+ encoder)
4: FOCPG（PM FOC vector control + Encoder）
5: FOC Sensorless (IM field oriented sensorless
vector control)
6: PM Sensorless (PM field oriented sensorless
vector control)
7: IPM Sensorless (IPM field oriented sensorless
vector control)
0: Relative position
1: Absolute position
0: TQCPG（IM Torque control + Encoder）
1: TQCPG (PM Torque control + Encoder)
2: TQC Sensorless (IM Sensorless torque control)

0: Normal load
1: Heavy load

0

0

0

0

0
0

0

Normal load
230V
1-15HP
20-50HP
60-125HP

460V
1-20HP
25-75HP
100-600HP

Carrier Frequency
2~15KHz
2~10KHz
2~9KHz

Heavy load
230V
1-15HP
20-50HP
60-125HP

460V
1-20HP
25-75HP
100-600HP

Carrier Frequency
2~15KHz
2~10KHz
2~9KHz

8
6
4

2

Reserved
PLC Command Mask

Bit 0: Control command by PLC force control
Bit 1: Frequency command by PLC force control
Bit 2: Position command by PLC force control
Bit 3: Torque command by PLC force control

11-3

Read
only

Chapter 11 Summary of Parameter SettingsC2000 Series
0: Digital keypad
1: RS-485 serial communication
2: External analog input (Pr.03-00)
3: External UP/DOWN terminal
4: Pulse input without direction command (Pr.10-16
without direction)
5: Pulse input with direction command (Pr.10-16)
6: CANopen communication card
7: Reserved
8: Communication card (no CANopen card)
0: Digital keypad
1: External terminals. Keypad STOP disabled.
2: RS-485 serial communication. Keypad STOP
disabled.
3: CANopen communication card
4: Reserved
5: Communication card (no CANopen card)
0: Ramp to stop
1: Coast to stop
0: Enable forward/reverse
1: Reverse disable
2: Forward disable

00-20

Source of Master Frequency
Command（AUTO）

00-21

Source of the Operation Command
（AUTO）



00-22

Stop Method



00-23

Control of Motor Direction

00-24

Memory of Frequency Command

Read only

User Defined Characteristics

Bit 0~3: user defined decimal place
0000b: no decimal place
0001b: one decimal place
0010b: two decimal place
0011b: three decimal place
Bit 4~15: user define on unit
000xh: Hz
001xh: rpm
002xh: %
003xh: kg
004xh: m/s
005xh: kW
006xh: HP
007xh: ppm
008xh: 1/m
009xh: kg/s
00Axh: kg/m
00Bxh: kg/h
00Cxh: lb/s
00Dxh: lb/m
00Exh: lb/h
00Fxh: ft/s
010xh: ft/m
011xh: m
012xh: ft
013xh: degC
014xh: degF
015xh: mbar
016xh: bar
017xh: Pa
018xh: kPa
019xh: mWG
01Axh: inWG
01Bxh: ftWG
01Cxh: psi
01Dxh: atm
01Exh: L/s
01Fxh: L/m
020xh: L/h
021xh: m3/s



00-25

11-4

0

0

0
0
Read
only

0

Chapter 11 Summary of Parameter SettingsC2000 Series





00-26

Max. User Defined Value

00-27

User Defined Value

00-28

Reserved

00-29

LOCAL/REMOTE Selection

00-30

Source of the Master Frequency
Command（HAND）

00-31

Source of the Operation Command
（HAND）

00-32

Digital Keypad STOP Function

00-33
~
00-39

Reserved

00-40

022xh: m3/h
023xh: GPM
024xh: CFM
Xxxxh: Hz
0: Disable
0~65535 (when Pr.00-25 set to no decimal place)
0.0~6553.5 (when Pr.00-25 set to 1 decimal place)
0.0~655.35 (when Pr.00-25 set to 2 decimal place)
0.0~65.535 (when Pr.00-25 set to 3 decimal place)
Read only
0: Standard HOA function
1: Switching Local/Remote, the drive stops
2: Switching Local/Remote, the drive runs as the
REMOTE setting for frequency and operation
status
3: Switching Local/Remote, the drive runs as the
LOCAL setting for frequency and operation
status
4: Switching Local/Remote, the drive runs as
LOCAL setting when switch to Local and runs as
REMOTE setting when switch to Remote for
frequency and operation status.
0: Digital keypad
1: RS-485 serial communication
2: External analog input (Pr.03-00)
3: External UP/DOWN terminal
4: Pulse input without direction command (Pr.10-16
without direction)
5: Pulse input with direction command (Pr.10-16)
6: CANopen communication card
7: Reserved
8: Communication card (no CANopen card)
0: Digital keypad
1: External terminals. Keypad STOP disabled.
2: RS-485 serial communication. Keypad STOP
disabled.
3: CANopen communication card
4: Reserved
5: Communication card (not include CANopen card)
0: STOP key disable
1: STOP key enable

Homing mode

X

Note: Forward run = closckwise (CW)
Reverse run = counterclockwise (CCW)
0: Forward run to home. Set PL forward limit as
check point.
1: Reverse run (CCW) to home. Set NL reverse
limit (CCWL) as check point.
2: Forward run to home. Set ORG : OFF→ON
as check point.
3: Reverse to home. Set ORG : OFF→ON as
check point.
11-5

0

Read
Only

0

0

0

0

0000

Chapter 11 Summary of Parameter SettingsC2000 Series
4: Forward run and search for Z-pulse as check
point.
5: Forward run and search for Z-pulse as check
point.
6: Forward run to home. Set ORG: ON→OFF
as check point.
7: Reverse run to home. Set ORG : ON→OFF
as check point.
8: Define current position as home.
Y

Set X to 0, 1, 2, 3, 6, 7 first.
0: reverse run to Z pulse
1: continue forward run to Z pulse
2: Ignore Z pulse
When home limit is reached, set X to 2, 3, 4, 5,

Z

6, 7 first.
0: display the error
1: reverse the direction



00-41

Homing by frequency 1

0.00~600.00Hz

8.00



00-42
00-43
~
00-47

Homing by frequency 2

0.00~600.00Hz

2.00



00-48

Display Filter Time (Current)

0.001~65.535 sec

0.100



00-49

Display Filter Time (Keypad)

0.001~65.535 sec

0.100

00-50

Software Version (date)

Read only

#####

00-51
~
00-61

Reserved

Reserved

11-6

Chapter 11 Summary of Parameter SettingsC2000 Series

01 Basic Parameters
Pr.

Explanation

Settings

Factory
Setting

01-00

Max. Operation Frequency

0.00~600.00Hz

01-01

Output Frequency of Motor 1

0.00~600.00Hz

60.00/
50.00
60.00/
50.00

01-02

Output Voltage of Motor 1

230V: 0.0V~255.0V
460V: 0.0V~510.0V

200.0
400.0

01-03

Mid-point Frequency 1 of Motor 1

0.00~600.00Hz
Motor drive with 250HP and above: 1.50

3.00

01-04

Mid-point Voltage 1 of Motor 1

230V: 0.0V~240.0V
460V: 0.0V~480.0V
Motor drive with 250HP and above: 10.0

11.0
22.0

01-05

Mid-point Frequency 2 of Motor 1

01-06

Mid-point Voltage 2 of Motor 1

01-07

Min. Output Frequency of Motor 1

01-08

Min. Output Voltage of Motor 1

01-09




0.00~600.00Hz
230V: 0.0V~240.0V
460V: 0.0V~480.0V

0.50

0.00~600.00Hz
230V: 0.0V~240.0V
460V: 0.0V~480.0V

0.00

Start-Up Frequency

0.00~600.00Hz

0.50

01-10

Output Frequency Upper Limit

0.00~600.00Hz

600.00



01-11

Output Frequency Lower Limit

0.00~600.00Hz

0



01-12

Accel. Time 1

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0



01-13

Decel Time 1

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0



01-14

Accel Time 2

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0



01-15

Decel Time 2

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0



01-16

Accel Time 3

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0



01-17

Decel Time 3

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0



01-18

Accel Time 4

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0



01-19

Decel Time 4

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0



01-20

JOG Acceleration Time

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0





11-7

2.0
4.0
0.0
0.0

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting



01-21

JOG Deceleration Time

Pr.01-45=0: 0.00~600.00 second
Pr.01-45=1: 0.00~6000.0 second
Motor drive with 30HP and above: 60.00/60.0

10.00
10.0



01-22

JOG Frequency

0.00~600.00Hz

6.00



01-23

1st/4th Accel/decel Frequency

0.00~600.00Hz

0.00



01-24

S-curve Acceleration Begin Time 1

Pr.01-45=0: 0.00~25.00 second
Pr.01-45=1: 0.0~250.0 second

0.20
0.2



01-25

S-curve Acceleration Arrival Time 2

Pr.01-45=0: 0.00~25.00 second
Pr.01-45=1: 0.0~250.0 second

0.20
0.2



01-26

S-curve Deceleration Begin Time 1

Pr.01-45=0: 0.00~25.00 second
Pr.01-45=1: 0.0~250.0 second

0.20
0.2



01-27

S-curve Deceleration Arrival Time 2

Pr.01-45=0: 0.00~25.00 second
Pr.01-45=1: 0.0~250.0 second

0.20
0.2

01-28

Skip Frequency 1 (upper limit)

0.00~600.00Hz

0.00

01-29

Skip Frequency 1 (lower limit)

0.00~600.00Hz

0.00

01-30

Skip Frequency 2 (upper limit)

0.00~600.00Hz

0.00

01-31

Skip Frequency 2 (lower limit)

0.00~600.00Hz

0.00

01-32

Skip Frequency 3 (upper limit)

0.00~600.00Hz

0.00

01-33

Skip Frequency 3 (lower limit)

0.00

01-34

Zero-speed Mode

0.00~600.00Hz
0: Output waiting
1: Zero-speed operation
2: Fmin (Refer to Pr.01-07, 01-41)

01-35

Output Frequency of Motor 2

0.00~600.00Hz

60.00/
50.00

01-36

Output Voltage of Motor 2

230V: 0.0V~255.0V
460V: 0.0V~510.0V

200.0
400.0

01-37

Mid-point Frequency 1 of Motor 2

0.00~600.00Hz
AC drive with power greater than 250HP: 1.50

3.00

01-38

Mid-point Voltage 1 of Motor 2

230V: 0.0V~240.0V
460V: 0.0V~480.0V
AC drive with power greater than 250HP: 10.0

11.0
22.0

01-39

Mid-point Frequency 2 of Motor 2

0.00~600.00Hz

0.50

01-40

Mid-point Voltage 2 of Motor 2

230V: 0.0V~240.0V
460V: 0.0V~480.0V

2.0
4.0

01-41

Min. Output Frequency of Motor 2

0.00~600.00Hz

0.00

01-42

Min. Output Voltage of Motor 2

230V: 0.0V~240.0V
460V: 0.0V~480.0V

0.0
0.0

01-43

V/f Curve Selection

01-44

Optimal Acceleration/Deceleration
Setting

01-45

Time Unit for Accel. /Decel. and S
Curve









0: V/f curve determined by Pr.01-00~01-08
1: Curve to the power of 1.5
2: Curve to the power of 2
0: Linear accel. /decel.
1: Auto accel.; linear decel.
2: Linear accel.; auto decel.
3: Auto accel./decel.
4: Linear, stall prevention by auto accel./decel. (limit
by Pr.01-12~01-21)
0: Unit: 0.01 sec
1: Unit: 0.1 sec

11-8

0

0

0

0

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.


01-46

Explanation
CANopen Quick Stop Time

Settings
Pr. 01-45=0: 0.00~600.00 sec
Pr. 01-45=1: 0.0~6000.0 sec

11-9

Factory
Setting
1.00

Chapter 11 Summary of Parameter SettingsC2000 Series

02 Digital Input/Output Parameters
Pr.
02-00
02-01
02-02
02-03
02-04
02-05
02-06
02-07
02-08
02-26
02-27
02-28
02-29
02-30
02-31

Explanation
2-wire/3-wire Operation Control
Multi-function Input Command 1
(MI1)
Multi-function Input Command 2
(MI2)
Multi-function Input Command 3
(MI3)
Multi-function Input Command 4
(MI4)
Multi-function Input Command 5
(MI5)
Multi-function Input Command 6
(MI6)
Multi-function Input Command 7
(MI7)
Multi-function Input Command 8
(MI8)
Input terminal of I/O
extension card (MI10)
Input terminal of I/O extension
card (MI11)
Input terminal of I/O extension
card (MI12)
Input terminal of I/O extension
card (MI13)
Input terminal of I/O extension
card (MI14)
Input terminal of I/O extension
card (MI15)

Settings

Factory
Setting

0: 2-wire mode 1, power on for operation control
1: 2-wire mode 2, power on for operation control
2: 3-wire, power on for operation control

0

0: No function

1

1: Multi-step speed command 1/multi-step position
command 1
2: Multi-step speed command 2/multi-step position
command 2
3: Multi-step speed command 3/multi-step position
command 3
4: Multi-step speed command 4/multi-step position
command 4

2
3
4
0

5: Reset

0

6: JOG command（By KPC-CC01 or external control）

0

7: Acceleration/deceleration speed inhibit

0

8: The 1st, 2nd acceleration/deceleration time selection

0

9: The 3rd, 4th acceleration/deceleration time selection

0

10: EF Input (Pr.07-20)

0

11: B.B input from external (Base Block)

0

12: Output stop

0

13: Cancel the setting of optimal accel. /decel. time

0

14: Switch between motor 1 and motor 2
15: Operation speed command from AVI
16: Operation speed command from ACI
17: Operation speed command from AUI
18: Emergency stop (Pr.07-20)
19: Digital up command
20: Digital down command
21: PID function disabled
22: Clear counter
23: Input the counter value (MI6)
24: FWD JOG command
25: REV JOG command
26: TQC/FOCmodel selection
27: ASR1/ASR2 selection
28: Emergency stop (EF1)
29: Signal confirmation for Y-connection
30: Signal confirmation for -connection
31: High torque bias (Pr.11-30)
32: Middle torque bias (Pr.11-31)
33: Low torque bias (Pr.11-32)
34: Switch between multi-step position and
multi-speed control
35: Enable single point position control
36: Enable multi-step position learning function (valid
at stop)
37: Full position control pulse command input enable
38: Disable EEPROM write function
11-10

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting

39: Torque command direction
40: Force coast to stop
41: HAND switch
42: AUTO switch
43: Enable resolution selection (Pr.02-48)
44: Reversed direction homing
45: Forward direction homing
46: Homing (ORG)
47: Homing function enable
48: Mechanical gear ratio switch
49: Drive enable
50: Master dEb action input
51: Selection for PLC mode bit0
52: Selection for PLC mode bit1
53: Trigger CANopen quick stop
54: Reserved
55: Brake release
56: Local/Remote Selection
57~70: Reserved


02-09

UP/DOWN key mode

0: up/down by the accel. /decel. time
1: up/down constant speed (Pr.02-10)



02-10

Constant speed. The Accel.
/Decel. Speed of the UP/DOWN
Key

0.01~1.00Hz/ms

0.01



02-11

Digital Input Response Time

0.000~30.000 second

0.005



02-12

Digital Input Mode Selection

0000h~FFFFh (0: N.O.; 1: N.C.）

0000



02-13

Multi-function Output 1 RY1

0: No function

11



02-14

Multi-function Output 2 RY2

1: Operation Indication

1



02-16

Multi-function Output 3 (MO1)

2: Operation speed attained

0



02-17

Multi-function Output 4 (MO2)

3: Desired frequency attained 1 (Pr.02-22)

0



02-36

4: Desired frequency attained 2 (Pr.02-24)

0



02-37

5: Zero speed (Frequency command)

0



02-38

6: Zero speed, include STOP(Frequency command)

0



02-39

7: Over torque 1(Pr.06-06~06-08)

0



02-40

8: Over torque 2(Pr.06-09~06-11)

0



02-41

9: Drive is ready

0



02-42

10: Low voltage warning（LV）(Pr.06-00)

0



02-43

11: Malfunction indication

0



02-44

12: Mechanical brake release(Pr.02-32)

0



02-45

13: Overheat warning (Pr.06-15)

0



02-46

14: Software brake signal indication(Pr.07-00)

0

Output terminal of the I/O
extension card (MO10)
Output Terminal of I/O Extension
Card (MO11)
Output Terminal of I/O Extension
Card (MO12)
Output Terminal of I/O Extension
Card (MO13)
Output Terminal of I/O Extension
Card (MO14)
Output Terminal of I/O Extension
Card (MO15)
Output Terminal of I/O Extension
Card (MO16)
Output Terminal of I/O Extension
Card (MO17)
Output Terminal of I/O Extension
Card (MO18)
Output Terminal of I/O Extension
Card (MO19)
Output Terminal of I/O Extension
Card (MO20)

15: PID feedback error (Pr.08-13, Pr.08-14)
16: Slip error (oSL)
17: Terminal count value attained, does not return to 0
(Pr.02-20)

11-11

0

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting

18: Preliminary count value attained, returns to 0
(Pr.02-19)
19: Base Block
20: Warning output
21: Over voltage warning
22: Over-current stall prevention warning
23: Over-voltage stall prevention warning
24: Operation mode indication
25: Forward command
26: Reverse command
27: Output when current >= Pr.02-33
28: Output when current < Pr.02-33
29: Output when frequency >= Pr.02-34
30: Output when frequency < Pr.02-34
31: Y-connection for the motor coil
32: △-connection for the motor coil
33: Zero speed (actual output frequency)
34: Zero speed include stop(actual output frequency)
35: Error output selection 1(Pr.06-23)
36: Error output selection 2(Pr.06-24)
37: Error output selection 3(Pr.06-25)
38: Error output selection 4(Pr.06-26)
39: Position attained (Pr.10-19)
40: Speed attained (including Stop)
41: Multi-position attained
42: Crane function
43: Actual motor speed slower than Pr.02-47
44: Low current output (use with Pr.06-71~06-73)
45: UVW Output Electromagnetic valve Switch
46: Master dEb warning output
47: Closed brake output
48: Reserved
49: Homing action complete
50: Output for CANopen control
51: Output for communication card
52: Output for RS485
53~64: Reserved
65: Output for both Can & 485 control
66: SO logic A
67: Analog input level reached
68: SO logic B


02-18



02-19



02-20



02-21

Multi-function output direction
Terminal counting value attained
(returns to 0)
Preliminary counting value
attained (not return to 0)
Digital Output Gain (DFM)

0000h~FFFFh (0: N.O.; 1: N.C.）

0000

0~65500

0

0~65500

0

1～166

1



02-22

Desired Frequency Attained 1

0.00～600.00Hz

60.00/
50.00



02-23

The Width of the Desired
Frequency Attained 1

0.00～600.00Hz

2.00



02-24

Desired Frequency Attained 2

0.00～600.00Hz

60.00/
50.00



02-25

The Width of the Desired
Frequency Attained 2

0.00～600.00Hz

2.00

02-32

Brake Delay Time

0.000~65.000 sec.

0.000

02-33

Output Current Level Setting for
Multi-function External Terminals

0~100%



11-12

0

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.


02-34



02-35



02-47



02-48



02-49
02-50
02-51
02-52
02-53
02-54

Output frequency setting
for multi-function output
terminal
External Operation Control
Selection after Reset and
Activate
Zero-speed Level of Motor
Max. Frequency of Resolution
Switch
Switch the delay time of Max.
output frequency
Status of Multi-function Input
Terminal
Status of Multi-function Output
Terminal
Display External Output terminal
occupied by PLC
Display Analog Input Terminal
occupied by PLC
Display the Frequency
Command Executed by External
Terminal

02-55

Reserved

02-56

Reserved



02-57



02-58
02-59
~
02-69

02-70

Settings

Factory
Setting

0.00~600.00Hz（Motor speed when using PG Card）

0.00

Explanation

Multi-function output terminal:
Function 42: Brake Current
Checking Point
Multi-function output terminal:
Function 42: Brake Frequency
Checking Point

0: Disable
1: Drive runs if run command exists after reset

0

0~65535 rpm

0

0.01~600.00Hz

60.00

0.000~65.000 sec.

0.000

Monitor the status of multi-function input terminals
Monitor the status of multi-function output terminals
Monitor the status of PLC input terminals
Monitor the status of PLC output terminals
Read only

0~150%

Read
only
Read
only
Read
only
Read
only
Read
only

0

0.00~655.35Hz

0.00

0：NO IO card
1：EMC-BPS01
2：NO IO card
3：NO IO card
4：EMC-D611A
5：EMC-D42A
6：EMC-R6AA
7：NO IO card

Read
only

Reserved

IO card types

11-13

Chapter 11 Summary of Parameter SettingsC2000 Series

03 Analog Input/Output Parameters
Pr.


03-00

Explanation

Settings

Factory
Setting

Analog Input Selection (AVI)

0: No function

1
0
0



03-01

Analog Input Selection (ACI)

1: Frequency command (speed limit under torque
control mode)



03-02

Analog Input Selection (AUI)

2: Torque command (torque limit under speed mode)
3: Torque offset command
4: PID target value
5: PID feedback signal
6: PTC thermistor input value
7: Positive torque limit
8: Negative torque limit
9: Regenerative torque limit
10: Positive/negative torque limit
11: PT100 thermistor input value
12: Reserved
13: PID Offset (%) (h.)
14~20: Reserved



03-03

Analog Input Bias (AVI)

-100.0~100.0%

0



03-04

Analog Input Bias (ACI)

-100.0~100.0%

0



03-05

Analog Positive Voltage Input
Bias (AUI)

-100.0~100.0%

0

03-06

Reserved



03-07



03-08



03-09

Positive/negative Bias Mode
(AVI)
Positive/negative Bias Mode
(ACI)
Positive/negative Bias Mode
(AUI)

0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: The absolute value of the bias voltage while serving
as the center
4: Serve bias as the center
0: Negative frequency is not valid. Forward and
reverse run is controlled by digital keypad or
external terminal.
1: Neagtive frequency is valid. Positive frequency =
forward run; negative frequency = reverse run.
Direction can not be switched by digital keypad or
external teriminal control.

0

03-10

Analog Frequency Command
for Reverse Run



03-11

Analog Input Gain (AVI)

-500.0~500.0%

100.0



03-12

Analog Input Gain (ACI)

-500.0~500.0%

100.0



03-13

Analog Positive Input Gain (AUI)

-500.0~500.0%

100.0



03-14

Analog Negative Input Gain
(AUI)

-500.0~500.0%

100.0



03-15

Analog Input Filter Time (AVI)

0.00~20.00 sec.

0.01



03-16

Analog Input Filter Time (ACI)

0.00~20.00 sec.

0.01



03-17

Analog Input Filter Time (AUI)

0.01



03-18

Addition Function of the Analog
Input

0.00~20.00 sec.
0: Disable (AVI, ACI, AUI)
1: Enable

11-14

0

0

Chapter 11 Summary of Parameter SettingsC2000 Series



03-19

ACI Signal Loss

0: Disable
1: Continue operation at the last frequency
2: Decelerate to 0Hz
3: Stop immediately and display ACE



03-20

Multi-function Output 1 (AFM1)

0: Output frequency (Hz)

0



03-23

Multi-function Output 2 (AFM2)

1: Frequency command (Hz)

0

0

2: Motor speed (Hz)
3: Output current (rms)
4: Output voltage
5: DC Bus voltage
6: Power factor
7: Power
8: Output torque
9: AVI
10: ACI
11: AUI
12: Iq current
13: Iq feedback value
14: Id current
15: Id feedback value
16: Vq-axis voltage
17: Vd-axis voltage
18: Torque command
19: PG2 frequency command
20: CANopen analog output
21: RS485 analog output
22: Communication card analog output
23: Constant voltage/current output
24: Reserved
25: CAN & 485 output


03-21

Gain of Analog Output 1 (AFM1)

100.0

Analog Output 1 when in REV
Direction (AFM1)

0~500.0%
0: Absolute output voltage
1: Reverse output 0V; Positive output 0-10V
2: Reverse output 5-0V; Positive output 5-10V



03-22



03-24

Gain of Analog Output 2 (AFM2)

0~500.0%

100.0

0: Absolute output voltage
1: Output 0V in REV direction; output 0-10V in FWD
direction
2: Output 5-0V in REV direction; output 5-10V in FWD
direction

0



03-25

Analog Output 2 when in REV
Direction (AFM2)



03-26

Reserved



03-27

AFM2 Output Bias

-100.00~100.00%



03-28

AVI Selection

0: 0-10V
1: 0-20mA
2: 4-20mA

0



03-29

ACI Selection

0: 4-20mA
1: 0-10V
2: 0-20mA

0

03-30

Status of PLC Output Terminal

Monitor the status of PLC output terminals



03-31

AFM2 0-20mA Output Selection

0: 0-20mA Output
1: 4-20mA Output



03-32

AFM1 DC output setting level

0.00~100.00%

0.00



03-33

AFM2 DC Output Setting Level

0.00~100.00%

0.00

11-15

0

0.00

Read
only
0

Chapter 11 Summary of Parameter SettingsC2000 Series




03-34

Reserved

03-35

AFM1 filter output time

0.00 ~ 20.00 Seconds

0.01

03-36

AFM2 filter output time

0.00 ~ 20.00 Seconds

0.01

03-37
~
03-43

Reserve



03-44

MO by source of AI level

0: AVI
1: ACI
2: AUI



03-45

AI upper level

-100%~100.00%

50%

03-46

AI lower level

-100%~100.00%

10%

03-47
~
03-49

Reserve



0



03-50

Analog Input Curve Selection

0: Regular Curve
1: 3 point curve of AVI
2: 3 point curve of ACI
3: 3 point curve of AVI & ACI
4: 3 point curve of AUI
5: 3 point curve of AVI & AUI
6: 3 point curve of ACI & AUI
7: 3 point curve of AVI & ACI & AUI



03-51

AVI Low Point

Pr.03-28=0, 0.00~10.00V
Pr.03-28≠0, 0.00~20.00mA

0.00



03-52

AVI Proportional Low Point

0.00~100.00%

0.00



03-53

AVI Mid Point

Pr.03-28=0, 0.00~10.00V
Pr.03-28≠0, 0.00~20.00mA

5.00



03-54

AVI Proportional Mid Point

0.00~100.00%

50.00



03-55

AVI High Point

Pr.03-28=0, 0.00~10.00V
Pr.03-28≠0, 0.00~20.00mA

10.00



03-56

AVI Proportional High Point

0.00~100.00%

100.00

03-57

ACI Low Point

Pr.03-29=1, 0.00~10.00V
Pr.03-29≠1, 0.00~20.00mA

4.00



03-58

ACI Proportional Low Point

0.00~100.00%

0.00



03-59

ACI Mid Point

Pr.03-29=1, 0.00~10.00V
Pr.03-29≠1, 0.00~20.00mA

12.00



03-60

ACI Proportional Mid Point

0.00~100.00%

50.00



03-61

ACI High Point

Pr.03-29=1, 0.00~10.00V
Pr.03-29≠1, 0.00~20.00mA

20.00



03-62

ACI Proportional High Point

0.00~100.00%

100.00



03-63

Positive AUI Voltage Low Point

0.00~10.00V

0.00



03-64

Positive AUI Voltage
Proportional Low Point

-100.00%~100.00%

0.00



03-65

Positive AUI Voltage Mid Point

0.00~10.00V

5.00



03-66

Positive AUI Voltage
Proportional Mid Point

-100.00%~100.00%

50.00



03-67

Positive AUI Voltage High Point

0.00~10.00V

10.00



03-68

Positive AUI Voltage
Proportional High Point

-100.00%~100.00%

100.00



03-69

Negative AUI Voltage Low Point

0.00~ -10.00V



11-16

0

0.00

Chapter 11 Summary of Parameter SettingsC2000 Series


03-70

Negative AUI Voltage
Proportional Low Point

-100.00%~100.00%

0.00



03-71

Negative AUI Voltage Mid Point

0.00~ -10.00V

-5.00



03-72

Negative AUI Voltage
Proportional Mid Point

-100.00%~100.00%

-50.00



03-73

Negative AUI Voltage High Point

0.00~ -10.00V

-10.00



03-74

Negative AUI Voltage
Proportional High Point

-100.00%~100.00%

-100.00

11-17

Chapter 11 Summary of Parameter SettingsC2000 Series

04 Multi-step Speed Parameters
Pr.

Explanation

Settings

Factory
Setting



04-00

1st Step Speed Frequency

0.00~600.00Hz

0



04-01

2nd Step Speed Frequency

0.00~600.00Hz

0



04-02

3rd Step Speed Frequency

0.00~600.00Hz

0



04-03

4th Step Speed Frequency

0.00~600.00Hz

0



04-04

5th Step Speed Frequency

0.00~600.00Hz

0



04-05

6th Step Speed Frequency

0.00~600.00Hz

0



04-06

7th Step Speed Frequency

0.00~600.00Hz

0



04-07

8th Step Speed Frequency

0.00~600.00Hz

0



04-08

9th Step Speed Frequency

0.00~600.00Hz

0



04-09

10th Step Speed Frequency

0.00~600.00Hz

0



04-10

11th Step Speed Frequency

0.00~600.00Hz

0



04-11

12th Step Speed Frequency

0.00~600.00Hz

0



04-12

13th Step Speed Frequency

0.00~600.00Hz

0



04-13

14th Step Speed Frequency

0.00~600.00Hz

0



04-14

15th Step Speed Frequency

0.00~600.00Hz

0



04-15

Position command 1 (rotation)

-30000~30000

0



04-16

Position command 1 (pulse)

-32767~32767

0



04-17

Position command 2 (rotation)

-30000~30000

0

04-18

Position command 2 (pulse)

-32767~32767

0



04-19

Position command 3 (rotation)

-30000~30000

0



04-20

Position command 3 (pulse)

-32767~32767

0



04-21

Position command 4 (rotation)

-30000~30000

0



04-22

Position command 4 (pulse)

-32767~32767

0



04-23

Position command 5 (rotation)

-30000~30000

0



04-24

Position command 5 (pulse)

-32767~32767

0



04-25

Position command 6 (rotation)

-30000~30000

0



04-26

Position command 6 (pulse)

-32767~32767

0



04-27

Position command 7 (rotation)

-30000~30000

0



04-28

Position command 7 (pulse)

-32767~32767

0



04-29

Position command 8 (rotation)

-30000~30000

0



04-30

Position command 8 (pulse)

-32767~32767

0



04-31

Position command 9 (rotation)

-30000~30000

0



04-32

Position command 9 (pulse)

-32767~32767

0



04-33

Position command 10 (rotation)

-30000~30000

0



04-34

Position command 10 (pulse)

-32767~32767

0



04-35

Position command 11 (rotation)

-30000~30000

0




11-18

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting



04-36

Position command 11 (pulse)

-32767~32767

0



04-37

Position command 12 (rotation)

-30000~30000

0



04-38

Position command 12 (pulse)

-32767~32767

0



04-39

Position command 13 (rotation)

-30000~30000

0



04-40

Position command 13 (pulse)

-32767~32767

0



04-41

Position command 14 (rotation)

-30000~30000

0



04-42

Position command 14 (pulse)

-32767~32767

0



04-43

Position command 15 (rotation)

-30000~30000

0



04-44

Position command 15 (pulse)

-32767~32767

0

04-45
~
04-49

Reserve



04-50

PLC buffer 0

0~65535

0



04-51

PLC buffer 1

0~65535

0



04-52

PLC buffer 2

0~65535

0



04-53

PLC buffer 3

0~65535

0



04-54

PLC buffer 4

0~65535

0



04-55

PLC buffer 5

0~65535

0



04-56

PLC buffer 6

0~65535

0



04-57

PLC buffer 7

0~65535

0



04-58

PLC buffer 8

0~65535

0



04-59

PLC buffer 9

0~65535

0



04-60

PLC buffer 10

0~65535

0



04-61

PLC buffer 11

0~65535

0



04-62

PLC buffer 12

0~65535

0



04-63

PLC buffer 13

0~65535

0



04-64

PLC buffer 14

0~65535

0



04-65

PLC buffer 15

0~65535

0



04-66

PLC buffer 16

0~65535

0



04-67

PLC buffer 17

0~65535

0



04-68

PLC buffer 18

0~65535

0



04-69

PLC buffer 19

0~65535

0

11-19

Chapter 11 Summary of Parameter SettingsC2000 Series

05 Motor Parameters
Pr.

05-00

05-01


05-02



05-03
05-04
05-05
05-06
05-07

Motor Auto Tuning

Full-load Current of Induction
Motor 1(A)
Rated Power of Induction Motor
1(kW)

Settings
0: No function
1: Rolling test for induction motor(IM) (Rs, Rr, Lm, Lx,
no-load current)
2: Static test for induction motor(IM)
3: No function
4: Dynamic test for PM motor magnetic pole
5: Dynamic test for PM(SPM) motor
6: Rolling test for IM motor flux curve
12: FOC Sensorless inertia estimation
13: Stacic test for PM(IPM) motor
10~120% of drive’s rated current

Factory
Setting

0

#.##

0~655.35kW

#.##

Rated Speed of Induction Motor
1 (rpm)

0~65535
1710(60Hz 4poles) ; 1410(50Hz 4 poles)

1710

Pole Number of Induction Motor
1
No-load Current of Induction
Motor 1 (A)
Stator Resistance (Rs) of
Induction Motor 1
Rotor Resistance (Rr) of
Induction Motor 1
Magnetizing Inductance (Lm) of
Induction Motor 1
Stator Inductance (Lx) of
Induction Motor 1

2~20

4

0~ Pr.05-01 factory setting

#.##

0~65.535

#.###

0~65.535

#.###

0~6553.5mH

#.#

0~6553.5mH

#.#

Full-load Current of Induction
Motor 2 (A)
Rated Power of Induction Motor
2 (kW)

10~120%

#.##

0~655.35kW

#.##

Rated Speed of Induction Motor
2 (rpm)

0~65535
1710(60Hz 4 poles) ; 1410(50Hz 4 poles)

1710

Pole Number of Induction Motor
2
No-load Current of Induction
Motor 2 (A)
Stator Resistance (Rs) of
Induction Motor 2
Rotor Resistance (Rr) of
Induction Motor 2
Magnetizing Inductance (Lm) of
Induction Motor 2
Stator Inductance (Lx) of
Induction Motor 2

2~20

05-22

Induction Motor 1/ 2 Selection

1: motor 1
2: motor 2

05-23

Frequency for
Y-connection/△-connection
Switch of Induction Motor

0.00~600.00Hz

05-24

Y-connection/△-connection
Switch of Induction Motor

0: Disable
1: Enable

05-08
05-09
05-10
~
05-12
05-13


05-14



05-15
05-16
05-17
05-18
05-19
05-20
05-21



Explanation

Reserved

4

0~ Pr.05-01 factory setting

#.##

0~65.535

#.###

0~65.535

#.###

0~6553.5mH

#.#

0~6553.5mH

#.#

11-20

1
60.00
0

Chapter 11 Summary of Parameter SettingsC2000 Series



05-25
05-26
05-27
05-28
05-29
05-30
05-31
05-32
05-33
05-34



05-35



05-36
05-37
05-38

Delay Time for
Y-connection/△-connection
Switch of Induction Motor
Accumulative Watt-second of
Motor in Low Word (W-sec)
Accumulative Watt-second of
Motor in High Word (W-sec)
Accumulative Watt-hour of Motor
(W-Hour)
Accumulative Watt-hour of Motor
in Low Word (KW-Hour)
Accumulative Watt-hour of Motor
in High Word (KW-Hour)
Accumulative Motor Operation
Time (Min)
Accumulative Motor Operation
Time (day)
Induction Motor and Permanent
Magnet Motor Selection
Full-load current of Permanent
Magnet Motor
Rated Power of Permanent
Magnet Motor
Rated speed of Permanent
Magnet Motor
Pole number of Permanent
Magnet Motor
Inertia of Permanent Magnet
Motor

0.000~60.000 sec.

0.200

Read only

#.#

Read only

#.#

Read only

#.#

Read only

#.#

Read only

#.#

00~1439

0

00~65535

0

0: Induction Motor
1: SPM Permanent Magnet Motor
2: IPM Permanent Magnet Motor
0.00~655.35Amps
0.00~655.35kW

0
#.##
0.00

0~65535rpm

2000

0~65535

10
2

0.0~6553.5 kg.cm

0.0

05-39

Stator Resistance of PM Motor

0.000~65.535

0.000

05-40

Permanent Magnet Motor Ld

0.00~655.35mH

0.000

05-41

Permanent Magnet Motor Lq

0.00~655.35mH

0.000



05-42

PG Offset angle of PM Motor

0.0~360.0°



05-43

Ke parameter of PM Motor

0~65535 (Unit: V/1000rpm)

11-21

0.0
0

Chapter 11 Summary of Parameter SettingsC2000 Series

06 Protection Parameters
Pr.



06-00

Explanation

Low Voltage Level

Settings
230V:
Frame A to D: 150.0~220.0Vdc
Frame E and frames above E: 190.0~220.0V
460V:
Frame A to D: 300.0~440.0Vdc
Frame E and frames above E: 380.0~440.0V

Factory
Setting
180.0
200.0
360.0
400.0



06-01

Over-voltage Stall Prevention



06-02

Selection for Over-voltage Stall
Prevention

0: Disabled
230V: 0.0~450.0Vdc
460V: 0.0~900.0Vdc
0: Traditional over-voltage stall prevention
1: Smart over-voltage prevention



06-03

Over-current Stall Prevention
during Acceleration

Normal Load: 0~160%(100%: drive’s rated current)
Heavy Load: 0~180%(100%: drive’s rated current)

120
150



06-04

Over-current Stall Prevention
during Operation

120
150



06-05

Accel. /Decel. Time Selection of
Stall Prevention at Constant
Speed

Normal Load: 0~160%(100%: drive’s rated current)
Heavy Load: 0~180%(100%: drive’s rated current)
0: by current accel/decel time
1: by the 1st accel/decel time
2: by the 2nd accel/decel time
3: by the 3rd accel/decel time
4: by the 4th accel/decel time
5: by auto accel/decel



06-06



06-07



06-08



06-09



06-10



06-11



Over-torque Detection Selection
(OT1)

Over-torque Detection Level
(OT1)
Over-torque Detection Time
(OT1)

Over-torque Detection Selection
(OT2)

0: No function
1: Continue operation after Over-torque detection
during constant speed operation
2: Stop after Over-torque detection during constant
speed operation
3: Continue operation after Over-torque detection
during RUN
4: Stop after Over-torque detection during RUN

380.0
760.0
0

0

0

10~250% (100%: drive’s rated current)

120

0.0~60.0 sec.

0.1

0: No function
1: Continue operation after Over-torque detection
during constant speed operation
2: Stop after Over-torque detection during constant
speed operation
3: Continue operation after Over-torque detection
during RUN
4: Stop after Over-torque detection during RUN

0

Over-torque Detection Level
(OT2)
Over-torque Detection Time
(OT2)

10~250% (100%: drive’s rated current)

120

0.0~60.0 sec.

0.1

06-12

Current Limit

0~250% (100%: drive’s rated current）

170



06-13

Electronic Thermal Relay
Selection (Motor 1)

0: Special motor (with external forced cooling)
1: Self-cooled motor (so motor with fan on the shaft)
2: Disable



06-14



06-15



06-16

Electronic Thermal Characteristic
for Motor 1
Heat Sink Over-heat (OH)
Warning
Stall Prevention Limit Level

2

30.0~600.0 sec.

60.0

0.0~110.0℃

105.0

0～100% (Pr.06-03, Pr.06-04)

11-22

50

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting

06-17

Fault Record 1 (Present Fault
Record)

0: No fault record

0

06-18

Fault Record 2

1: Over-current during acceleration (ocA)

0

06-19

Fault Record 3

2: Over-current during deceleration (ocd)

0

06-20

Fault Record 4

3: Over-current during constant speed(ocn)

0

06-21

Fault Record 5

4: Ground fault (GFF)

0

06-22

Fault Record 6

5: IGBT short-circuit (occ)

0

6: Over-current at stop (ocS)
7: Over-voltage during acceleration (ovA)
8: Over-voltage during deceleration (ovd)
9: Over-voltage during constant speed (ovn)
10: Over-voltage at stop (ovS)
11: Low-voltage during acceleration (LvA)
12: Low-voltage during deceleration (Lvd)
13: Low-voltage during constant speed (Lvn)
14: Stop mid-low voltage (LvS)
15: Phase loss protection (OrP)
16: IGBT over-heat (oH1)
17: Capacitance over-heat (oH2)
18: tH1o (TH1 open: IGBT over-heat protection error)
19: tH2o (TH2 open: capacitance over-heat protection
error)
20: Reserved
21: Drive over-load (oL)
22: Electronics thermal relay 1 (EoL1)
23: Electronics thermal relay 2 (EoL2)
24: Motor overheat (oH3) (PTC)
25: Reserved
26: Over-torque 1 (ot1)
27: Over-torque 2 (ot2)
28: Low current (uC)
29: Home limit error (LMIT)
30: Memory write-in error (cF1)
31: Memory read-out error (cF2)
32: Reserved
33: U-phase current detection error (cd1)
34: V-phase current detection error (cd2)
35: W-phase current detection error (cd3)
36: Clamp current detection error (Hd0)
37: Over-current detection error (Hd1)
38: Over-voltage detection error (Hd2)
39: Ground current detection error (Hd3)
40: Auto tuning error (AUE)
41: PID feedback loss (AFE)
42: PG feedback error (PGF1)
43: PG feedback loss (PGF2)
44: PG feedback stall (PGF3)
45: PG slip error (PGF4)
46: PG ref loss (PGr1)
47: PG ref loss (PGr2)
48: Analog current input loss (ACE)
49: External fault input (EF)
50: Emergency stop (EF1)
51: External Base Block (bb)
52: Password error (PcodE)
53: Reserved
54: Communication error (CE1)
55: Communication error (CE2)
11-23

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting

56: Communication error (CE3)
57: Communication error (CE4)
58: Communication Time-out (CE10)
59: PU Time-out (CP10)
60: Brake transistor error (bF)
61: Y-connection/△-connection switch error (ydc)
62: Decel. Energy Backup Error (dEb)
63: Slip error (oSL)
64: Electromagnet switch error (ryF)
65: PG Card Error (PGF5)
66-67: Reserved
68: Sensorless estimated speed have wrong direction
69: Sensorless estimated speed is over speed
70: Sensorless estimated speed deviated
71: Reserved
72: STO Loss 1
73: External safety gate S1
74~75: Reserved
76: STO
77: STO Loss 2
78: STO Loss 3
79: U phase over current (Uocc)
80: V phase over current (Vocc)
81: W phase over current (Wocc)
82: U phase output phase loss (OPHL)
83: V phase output phase loss (OPHL)
84: W phase output phase loss (OPHL)
85: PG-02U ABZ hardware disconnection
86: PG-02U UVW hardware disconnection
87~88: Reserved
89: Initial rotor position detection error
90: Inner PLC function is forced to stop
91~100: Reserved
101: CANopen software disconnect1 (CGdE)
102: CAN open software disconnect2 (CHbE)
103: CANopen synchronous error (CSYE)
104: CANopen hardware disconnect (CbFE)
105: CANopen index setting error (CIdE)
106: CANopen slave station number setting error
(CAdE)
107: CANopen index setting exceed limit (CFrE)
108~110: Reserved
111: Internal communication overtime error(InrCOM)
112: PM sensorless shaft Lock error
113: Software OC


06-23

Fault Output Option 1

0~65535(refer to bit table for fault code)

0



06-24

Fault Output Option 2

0~65535(refer to bit table for fault code)

0



06-25

Fault Output Option 3

0~65535(refer to bit table for fault code)

0



06-26

Fault Output Option 4

0~65535(refer to bit table for fault code)

0



06-27

Electronic Thermal Relay
Selection 2 (Motor 2)

0: Special motor (with external forced cooling)
1: Self-cooled motor (so motor with fan on the shaft)
2: Disable

2



06-28

Electronic Thermal
Characteristic for Motor 2

30.0~600.0 sec



06-29

PTC Detection Selection

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop
11-24

60.0
0

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting

3: No warning


06-30

PTC Level

0.0～100.0%

06-31

Frequency Command for
Malfunction

0.00~655.35 Hz

06-32

Output Frequency at Malfunction

0.00~655.35 Hz

06-33

Output Voltage at Malfunction

0.0~6553.5 V

06-34

DC Voltage at Malfunction

0.0~6553.5 V

06-35

Output Current at Malfunction

0.00~655.35 Amp

06-36

IGBT Temperature at Malfunction

-3276.7~3276.7 ℃

06-37
06-38
06-39
06-40
06-41

Capacitance Temperature at
Malfunction
Motor Speed in rpm at
Malfunction
Torque Command at Malfunction
Status of Multi-function Input
Terminal at Malfunction
Status of Multi-function Output
Terminal at Malfunction

-3276.7~3276.7 ℃
-3276.7~3276.7 rpm
-3276.7~3276.7
0000h~FFFFh
0000h~FFFFh

Read
only
Read
only
Read
only
Read
only
Read
only
Read
only
Read
only
Read
only
Read
only
Read
only
Read
only
Read
only

06-42

Drive Status at Malfunction

06-43

Reserved

06-44

STO Latch Selection

0：STO Latch
1：STO No Latch

0



06-45

Treatment to Output Phase Loss
Detection (OPHL)

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop
3: No warning

3



06-46



06-47



06-48



Deceleration Time of Output
Phase Loss
Current detection level of output
phase loss
DC Brake Time of Output Phase
Loss

0000h~FFFFh

50.0

0.000~65.535 sec

0.500

0.00~655.35%

1.00

0.000~65.535sec

0.000

0.00~600.00 sec

0.20

30.0 /
60.0

06-49

Reserved

06-50

Time for Input Phase Loss
Detection

06-51

Reserved



06-52

Ripple of Input Phase Loss

230V Series: 0.0~160.0 Vdc
460V Series: 0.0~320.0 Vdc



06-53

Treatment for the detected Input
Phase Loss (OrP)

0: warn and ramp to stop
1: warn and coast to stop

0

06-54

Reserved

0





06-55

Derating Protection

0: constant rated current and limit carrier wave by
load current and temperature
1: constant carrier frequency and limit load current
by setting carrier wave
2: constant rated current(same as setting 0), but
close current limit

06-56

PT100 Detected Level 1

0.000~10.000V

11-25

5.000

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting



06-57

PT100 Detected Level 2

0.000~10.000V

7.000



06-58

PT100 Level 1 Frequency
Protect

0.00~600.00Hz

0.00



06-59

PT100 activation level delay time

0~6000 sec



06-60

0.0~6553.5 %

60.0



06-61

Software Detection GFF Current
Level
Software Detection GFF Filter
Time

0.00~655.35 sec

0.10

60

06-62

Reserved

06-63

Fault Record 1 (Day)

0~65535 days

06-64

Fault Record 1 (Min)

0~1439 min

06-65

Fault Record 2 (Day)

0~65535 days

06-66

Fault Record 2 (Min)

0~1439 min

06-67

Fault Record 3 (Day)

0~65535 days

06-68

Fault Record 3 (Min)

0~1439 min

06-69

Fault Record 4 (Day)

0~65535 days

06-70

Fault Record 4 (Min)

0~1439 min



06-71

Low Current Setting Level

0.0 ~ 6553.5 %

0.0



06-72

Low Current Detection Time

0.00 ~ 655.35sec

0.00

Treatment for low current

0 : No function
1 : Warn and coast to stop
2 : Warn and ramp to stop by 2nd deceleration time
3 : Warn and operation continue



06-73

11-26

Read
only
Read
only
Read
only
Read
only
Read
only
Read
only
Read
only
Read
only

0

Chapter 11 Summary of Parameter SettingsC2000 Series

07 Special Parameters
Pr.

Explanation

Settings

Factory
Setting
380.0
760.0



07-00

Software Brake Level

230V: 350.0~450.0Vdc
460V: 700.0~900.0Vdc



07-01

DC Brake Current Level

0~100%



07-02

DC Brake Time at RUN

0.0~60.0 sec.

0.0



07-03

DC Brake Time at Stop

0.0~60.0 sec.

0.0



07-04

DC Brake frequency at Stop

0.00~600.00Hz

0.00



07-05

Voltage Incrasing Gain

1~200%

100



07-06

Restart after Momentary Power
Loss

0: Stop operation
1: Speed search for last frequency command
2: Speed search for minimum output frequency



07-07

Maximum Power Loss Duration

0.0~20.0 sec.

2.0



07-08

Base Block Time

0.1~5.0 sec.

0.5



07-09

Current Limit for Speed Search

20~200%

100



07-10

Treatment to Restart After Fault

0: Stop operation
1: Speed search starts with current speed
2: Speed search starts with minimum output frequency

0



07-11

Number of Times of Auto
Restart After Fault

0~10

0

0

0

0

0



07-12

Speed Search during Start-up

0: Disable
1: Speed search for maximum output frequency
2: Speed search for start-up motor frequency
3: Speed search for minimum output frequency



07-13

Decel. Time to Momentary
Power Loss

0: Disable
1~6: Auto decel. time



07-14

DEB Return Time

0.0~25.0sec

0.0



07-15

Dwell Time at Accel.

0.00 ~ 600.00sec

0.00



07-16

Dwell Frequency at Accel.

0.00 ~ 600.00Hz

0.00



07-17

Dwell Time at Decel.

0.00 ~ 600.00sec

0.00



07-18

Dwell Frequency at Decel.

0.00 ~ 600.00Hz

0.00

0: Fan always ON
1: 1 minute after the AC motor drive stops, fan will be
OFF
2: When the AC motor drive runs, the fan is ON. When
the AC motor drive stops, the fan is OFF
3: Fan turns ON when preliminary IGBT temperature
(around 60oC) is attained.
4: Fan always OFF
0: Coast stop
1: By deceleration Time 1
2: By deceleration Time 2
3: By deceleration Time 3
4: By deceleration Time 4
5: System Deceleration
6: Automatic Deceleration



07-19

Fan Cooling Control



07-20

Emergency Stop (EF) & Force to
Stop Selection



07-21

Auto Energy-saving Operation

0: Disable
1: Enable



07-22

Energy-saving Gain

10～1000%

11-27

0

0

0
100

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation
Auto Voltage Regulation(AVR)
Function

Settings
0: Enable AVR
1: Disable AVR
2: Disable AVR during deceleration

Factory
Setting



07-23



07-24



07-25



07-26

Torque Compensation Gain (V/F
and SVC control mode)

0~10



07-27

Slip Compensation Gain (V/F
and SVC control mode)

0.00~10.00

0.00



07-28

Reserved



07-29

Slip Deviation Level

0.0~100.0%

0



07-30

Detection Time of Slip Deviation



07-31

Over Slip Treatment

0.0~10.0 sec
0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop
3: No warning



07-32

Motor Hunting Gain

0~10000

1000



07-33

Autorestart internal of Fault

0.0~6000.0 sec

60.0

Filter Time of Torque
Compensation (V/F and SVC
control mode)
Filter Time of Slip
Compensation (V/F and SVC
control mode)

0

0.001~10.000 sec

0.020

0.001~10.000 sec

0.100

(Default: 1 in SVC mode)

11-28

0

1.0
0

Chapter 11 Summary of Parameter Settings|
|C2000 Series

08 High-function PID Parameters
Pr.

Explanation

Settings

Factory
Setting

0



08-00

Input Terminal for PID Feedback

0: No function
1: Negative PID feedback: on analogue input acc. To
setting 5 of Pr. 03-00 to Pr.03-02.
2: Negative PID feedback from PG card (Pr.10-02, skip
direction)
3: Negative PID feedback from PG card (Pr.10-02)
4: Positive PID feedback from external terminal AVI
(Pr.03-00)
5: Positive PID feedback from PG card (Pr.10-02, skip
direction)
6: Positive PID feedback from PG card (Pr.10-02)
7: Negative PID feeback from communication protocol
8: Positive PID feedback from communication protocol



08-01

Proportional Gain (P)

0.0~500.0

1.0



08-02

Integral Time (I)

0.00~100.00sec

1.00



08-03

Derivative Control (D)

0.00~1.00sec

0.00



08-04

Upper Limit of Integral Control

0.0~100.0%

100.0



08-05

PID Output Frequency Limit

0.0~110.0%

100.0



08-06

PID feedback value by
communication protocol

-200.00~200.00%

0.00



08-07

PID Delay Time

0.0~35.0 sec

0.0



08-08

Feedback Signal Detection Time

0.0~3600.0 sec

0.0



08-09

Feedback Signal Fault
Treatment

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop
3: Warn and operate at last frequency



08-10

Sleep Frequency

0.00 ~ 600.00Hz

0.00



08-11

Wake-up Frequency

0.00 ~ 600.00Hz

0.00



08-12

Sleep Time

0.0 ~ 6000.0sec

0.0



08-13

PID Deviation Level

1.0 ~ 50.0%

10.0



08-14

PID Deviation Time

0.1~300.0sec

5.0



08-15

Filter Time for PID Feedback

0.1~300.0sec

5.0



08-16

PID Compensation Selection

0: Parameter setting
1: Reserved

0



08-17

PID Compensation

-100.0~+100.0%

0

08-18

Setting of Sleep Mode Function

0: Follow PID output command
1: Follow PID feedback signal

0

08-19

Wakeup Integral Limit

0.0~200.0%

08-20

PID Mode Selection

0: Serial connection
1: Parallel connection

0

08-21

Enable PID to Change
Operation Direction

0: Operation direction can be changed
1: Operation direction can not be changed

0

08-22

Wakeup Delay Time

0.00~600.00 Seconds

PID Control Flag

Bit 0 = 1, PID reverse running must follow the setting of
Pr00-23.
Bit 0 = 0, PID reverse running follow PID’s calculated
value.







08-23

11-29

0

50.0

0.00
0

Chapter 11 Summary of Parameter SettingsC2000 Series

09 Communication Parameters
Explanation



09-00

COM1 Communication Address

1~254



09-01

COM1 Transmission Speed

4.8～115.2Kbps



09-02

COM1 Transmission Fault
Treatment

0: Warn and continue operation
1: Warn and ramp to stop
2: Warn and coast to stop
3: No warning and continue operation



09-03

COM1 Time-out Detection

0.0～100.0 sec.

0.0

09-04

COM1 Communication Protocol

1: 7N2 (ASCII)
2: 7E1 (ASCII)
3: 7O1 (ASCII)
4: 7E2 (ASCII)
5: 7O2 (ASCII)
6: 8N1 (ASCII)
7: 8N2 (ASCII)
8: 8E1 (ASCII)
9: 8O1 (ASCII)
10: 8E2 (ASCII)
11: 8O2 (ASCII)
12: 8N1 (RTU)
13: 8N2 (RTU)
14: 8E1 (RTU)
15: 8O1 (RTU)
16: 8E2 (RTU)
17: 8O2 (RTU)

1

09-05
~
09-08

Reserved

09-09

Response Delay Time

0.0~200.0ms

09-10

Main Frequency of the
Communication

0.00~600.00Hz



09-11

Block Transfer 1

0~65535

0



09-12

Block Transfer 2

0~65535

0



09-13

Block Transfer 3

0~65535

0



09-14

Block Transfer 4

0~65535

0



09-15

Block Transfer 5

0~65535

0



09-16

Block Transfer 6

0~65535

0



09-17

Block Transfer 7

0~65535

0



09-18

Block Transfer 8

0~65535

0



09-19

Block Transfer 9

0~65535

0



09-20

Block Transfer 10

0~65535

0



09-21

Block Transfer 11

0~65535

0



09-22

Block Transfer 12

0~65535

0



09-23

Block Transfer 13

0~65535

0



09-24

Block Transfer 14

0~65535

0



09-25

Block Transfer 15

0~65535

0



09-26

Block Transfer 16

0~65535

0





Settings

Factory
Setting

Pr.

11-30

1
9.6

3

2.0
60.00

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.



Explanation

09-27
~
09-29

Reserved

09-30

Communication Decoding
Method

09-31

Internal Communication
Protocol

09-32

Reserved

09-33

PLC command force to 0

09-34

Reserved

09-35
09-36

Settings

0: Decoding Method 1
1: Decoding Method 2
0: Modbus 485
-1: Internal Communication Slave 1
-2: Internal Communication Slave 2
-3: Internal Communication Slave 3
-4: Internal Communication Slave 4
-5: Internal Communication Slave 5
-6: Internal Communication Slave 6
-7: Internal Communication Slave 7
-8: Internal Communication Slave 8
-9: Reserved
-10: Internal Communication Master
-11: Reserve
-12: Internal PLC Control

Factory
Setting

1

0

0~65535

0

PLC Address

1~254

2

CANopen Slave Address

0: Disable
1~127

0

09-37

CANopen Speed

0: 1M
1: 500k
2: 250k
3: 125k
4: 100k (Delta only)
5: 50k

0

09-38

CANopen Frequency Gain

1.00 ~ 2.00

1.00

09-39

CANopen Warning Record

bit 0: CANopen Guarding Time out
bit 1: CANopen Heartbeat Time out
bit 2: CANopen SYNC Time out
bit 3: CANopen SDO Time out
bit 4: CANopen SDO buffer overflow
bit 5: Can Bus Off
bit 6: Error protocol of CANopen
bit 7: Reserved
bit 8: The setting values of CANopen indexs are fail
bit 9: The setting value of CANopen address is fail
bit10: The checksum value of CANopen indexs is fail

Read
only

09-40

CANopen Decoding Method

09-41

CANopen Communication
Status

09-42

CANopen Control Status

0: Delta defined decoding method
1: CANopen DS402 Standard
0: Node Reset State
1: Com Reset State
2: Boot up State
3: Pre Operation State
4: Operation State
5: Stop State
0: Not ready for use state
1: Inhibit start state
2: Ready to switch on state
3: Switched on state
4: Enable operation state
7: Quick Stop Active state
13: Err Reaction Activation state
14: Error state
11-31

1

Read
Only

Read
Only

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.



Explanation

Settings
bit0: reset address 20XX to 0.
bit1: reset address 264X to 0
bit2: reset address 26AX to 0
bit3: reset address 60XX to 0

Factory
Setting

09-43

Reset CANopen Index

65535

09-44

Reserved

09-45

CANopen Master Function

0: Disable
1: Enable

09-46

CANopen Master Address

1~127

100

09-47
~
09-59

Reserved

##

0

09-60

Identifications for
Communication Card

0: No communication card
1: DeviceNet Slave
2: Profibus-DP Slave
3: CANopen Slave/Master
4: Modbus-TCP Slave
5: Ethernet/IP Slave
6~8: Reserved

09-61

Firmware Version of
Communication Card

Read only

##

09-62

Product Code

Read only

##

09-63

Error Code

Read only

##

09-64
~
09-69

Reserved

09-70

Address of Communication Card

DeviceNet: 0-63
Profibus-DP: 1-125

1

Standard DeviceNet:
0: 125Kbps
1: 250Kbps
2: 500Kbps



09-71

Setting of DeviceNet Speed



09-72

Other Setting of DeviceNet
Speed

09-73

Reserved

09-74

Reserved



09-75



09-76



09-77

IP Configuration of the
Communication Card
IP Address 1 of the
Communication Card
IP Address 2 of the
Communication Card

Non standard DeviceNet: (Delta Only)
0: 10Kbps
1: 20Kbps
2: 50Kbps
3: 100Kbps
4: 125Kbps
5: 250Kbps
6: 500Kbps
7: 800Kbps
8: 1Mbps
0: Disable
In this mode, baud rate can only be 0,1,2,3 in
standard DeviceNet speed
1: Enable
In this mode, the baud rate of DeviceNet can be
same as CANopen (0-8).

2

0

0: Static IP
1: Dynamic IP (DHCP)

0

0~255

0

0~255

0

11-32

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation
IP Address 3 of the
Communication Card
IP Address 4 of the
Communication Card
Address Mask 1 of the
Communication Card
Address Mask 2 of the
Communication Card
Address Mask 3 of the
Communication Card
Address Mask 4 of the
Communication Card
Getway Address 1 of the
Communication Card
Getway Address 2 of the
Communication Card
Getway Address 3 of the
Communication Card
Getway Address 4 of the
Communication Card
Password for Communication
Card (Low word)



09-78



09-79



09-80



09-81



09-82



09-83



09-84



09-85



09-86



09-87



09-88



09-89

Password for Communication
Card (High word)



09-90

Reset Communication Card



09-91

Additional Setting for
Communication Card

09-92

Status of Communication Card

Settings

Factory
Setting

0~255

0

0~255

0

0~255

0

0~255

0

0~255

0

0~255

0

0~255

0

0~255

0

0~255

0

0~255

0

0~255

0

0~255

0

0: No function
1: Reset, return to factory setting
Bit 0: Enable IP filter
Bit 1: Enable to write internet parameters (1bit). This bit
will change to disable when it finishes saving the
internet parameter updates.
Bit 2: Enable login password (1bit). When enter login
password, this bit will be enabled. After updating
the parameters of communication card, this bit will
change to disable.
Bit 0: password enable
When the communication card is set with
password, this bit is enabled. When the password
is clear, this bit is disabled.

11-33

0

0

0

Chapter 11 Summary of Parameter SettingsC2000 Series

10 Speed Feedback Control Parameters
NOTE

Pr.

IM: Induction Motor; PM: Permanent Magnet Motor
Explanation

Settings

Factory
Setting

10-00

Encoder Type Selection

0: Disable
1: ABZ
2: ABZ (Delta Encoder for Delta servo motor)
3: Resolver
4: ABZ/UVW
5: MI8 single phase pulse input

10-01

Encoder Pulse

1~20000

Encoder Input Type Setting

0: Disable
1: Phase A leads in a forward run command and phase
B leads in a reverse run command
2: Phase B leads in a forward run command and phase
A leads in a reverse run command
3: Phase A is a pulse input and phase B is a direction
input. (low input=reverse direction, high input=forward
direction)
4: Phase A is a pulse input and phase B is a direction
input. (low input=forward direction, high input=reverse
direction)
5: Single-phase input

0

 10-03

Output Setting for Frequency
Division (denominator)

1~255

1

 10-04

Electrical Gear at Load Side A1

1~65535

100

 10-05

Electrical Gear at Motor Side B1

1~65535

100

 10-06

Electrical Gear at Load Side A2

1~65535

100

 10-07

Electrical Gear at Motor Side B2

1~65535

100

 10-08

Treatment for Encoder/ Speed
Observer Feedback Fault

10-02

 10-09
 10-10


10-11

 10-12
 10-13
 10-14

Detection Time of Encoder /
Speed Observer Feedback Fault
Encoder/ Speed Observer Stall
Level
Detection Time of Encoder/
Speed Observer Stall
Treatment for Encoder/ Speed
Observer Stall
Encoder/ Speed Observer Slip
Range
Detection Time of Encoder/
Speed Observer Slip

 10-15

Treatment for Encoder/ Speed
Observer Stall and Slip Error

 10-16

Pulse Input Type Setting

 10-17

Electrical Gear A

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop
0.0~10.0sec
0: No function
0~120%
0: No function
0.0 ~ 2.0sec

0

600

2
1.0
115
0.1

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop

2

0~50% (0: disable)

50

0.0~10.0sec

0.5

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop
0: Disable
1: Phase A leads in a forward run command and phase
B leads in a reverse run command
2: Phase B leads in a forward run command and phase
A leads in a reverse run command
3: Phase A is a pulse input and phase B is a direction
input. (L=reverse direction, H=forward direction).
4: Phase A is a pulse input and phase B is a direction
input. (L=forward direction, H=reverse direction).
1~65535

11-34

2

0

100

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting

 10-18

Electrical Gear B

1~65535

100

 10-19

Positioning for Encoder Position

0~65535pulse

0

 10-20

Range for Encoder Position
Attained

0~65535pulse

10

 10-21

Filter Time (PG2)

0~65.535 sec

0.100

10-22

Speed Mode (PG2)

0: Electronic Frequency
1: Mechanical Frequency (base on pole pair)

0

10-23

Reserved
0

 10-24

FOC&TQC Function Control

0~65535

 10-25

FOC Bandwidth of
Speed Observer

1.0~100.0Hz

40.0

 10-26

FOC Minimum Stator Frequency

0.0~10.0%fN

2.0

1~1000ms

50

33~100%Tr

100

 10-27
 10-28
 10-29

FOC Low-pass Filter Time
Constant
FOC Excitation Current Rise
Time
Top Limit of Frequency Deviation

0.00~100.00Hz

Resolver Pole Pair

1~50

1

 10-31

I/F Mode, current command

0~150%Irated (Rated current % of motor)

40

 10-32

PM Sensorless Obeserver
Bandwith for High Speed Zone

0.00~600.00Hz

5.00

10-30

10-33

20.00

Reserved

 10-34

PM Sensorless Observer
Low-pass Filter Gain

0.00~655.35 Hz

1.00

 10-35

AMR (Kp)

0.00~3.00

2.00

 10-36

AMR (Ki)

0.00~3.00

0.20

 10-37

PM Sensorless Control Word

0000~FFFFh

0000

0.00~600.00Hz

20.00

0.00~600.00Hz

20.00

10-38
 10-39
 10-40

Reserved
Frequency when switch from I/F
Mode to PM sensorless mode.
Frequency when switch from PM
sensorless observer mode to
V/F mode.

 10-41

I/F mode, low pass-filter time

0.0~6.0sec

 10-42

Initial Angle Detection Time

0~50ms

10-43

PG card version

0~655.35

10-44
~
10-48

Reserved

10-49

Zero voltage time while start up

00.000~60.000 sec

00.000

10-50

Reverse angle limit (Electrical
angle)

0.00~30.00 degree

10.00

10-51

Injection Frequency

0~2000Hz

500

10-52

Injection Magnitude

0.0~200.0V

15/30

11-35

0.2
5
Read
only

Chapter 11 Summary of Parameter SettingsC2000 Series

11 Advanced Parameters
NOTE

Pr.

IM: Induction Motor; PM: Permanent Magnet Motor
Explanation

Settings

Factory
Setting

0

11-00

System Control

bit 0: Auto tuning for ASR and APR
bit 1: Inertia estimate (only for FOCPG mode)
bit 2: Zero servo
bit 3: Dead Time compensation closed
Bit 7: Selection to save or not save the frequency
Bit 8: Maximum speed of point to point position control

11-01

Per Unit of System Inertia

1~65535（256=1PU）

400



11-02

ASR1/ASR2 Switch
Frequency

5.00~600.00Hz

7.00



11-03

ASR1 Low-speed Bandwidth

1~40Hz (IM)/ 1~100Hz (PM)

10



11-04

ASR2 High-speed Bandwidth

1~40Hz (IM)/ 1~100Hz (PM)

10



11-05

Zero-speed Bandwidth

1~40Hz (IM)/ 1~100Hz (PM)

10



11-06

ASR Control ( P) 1

0~40Hz (IM)/ 1~100Hz (PM)

10



11-07

ASR Control (I) 1

0.000~10.000 sec



11-08

ASR Control ( P) 2

0~40Hz (IM)/ 0~100Hz (PM)



11-09

ASR Control (I) 2

0.000~10.000 sec



11-10

P Gain of Zero Speed

0~40Hz (IM)/ 0~100Hz (PM)



11-11

I Gain of Zero Speed

0.000~10.000 sec



11-12

Gain for ASR Speed Feed
Forward

0~150%

0



11-13

PDFF Gain

0~200%

30



11-14

Low-pass Filter Time of ASR
Output

0.000~0.350 sec



11-15

Notch Filter Depth

0~20db



11-16

Notch Filter Frequency

0.00~200.00Hz

0.0



11-17

Forward Motor Torque Limit

0~500%

500



11-18

Forward Regenerative Torque
Limit

0~500%

500



11-19

Reverse Motor Torque Limit

0~500%

500



11-20

0~500%

500



11-21

0~200%

90



11-22

0~200%

90



11-23

0~150%

65



11-24

APR Gain

0.00~40.00Hz (IM)/ 0~100.00Hz (PM)



11-25

Gain Value of APR Feed
Forward

0~100



11-26

APR Curve Time

0.00~655.35 sec

3.00



11-27

Max. Torque Command

0~500%

100

Source of Torque Offset

0: No function
1: Analog signal input (Pr.03-00~03-02)
2: Pr.11-29
3: Control by external terminal (Pr.11-30~11-32)



11-28

Reverse Regenerative Torque
Limit
Gain Value of Flux Weakening
Curve for Motor 1
Gain Value of Flux Weakening
Curve for Motor 2
Speed Response of Flux
Weakening Area

11-36

0.100
10
0.100
10
0.100

0.008
0

10.00
30

0

Chapter 11 Summary of Parameter SettingsC2000 Series

Pr.

Explanation

Settings

Factory
Setting



11-29

Torque Offset Setting

-100%~100%

0.0



11-30

High Torque Offset

-100%~100%

30.0



11-31

Middle Torque Offset

-100%~100%

20.0



11-32

Low Torque Offset

-100%~100%

10.0

0

0



11-33

Source of Torque Command

0: Digital keypad
1: RS-485 communication (Pr.11-34)
2: Analog input (Pr.03-00)
3: CANopen
4: Reserved
5: Communication extension card



11-34

Torque Command

-100.0~+100.0% (Pr.11-27*11-34)



11-35

Filter Time of Torque
Command

0.000~1.000sec

11-36

Speed Limit Selection

0: Set by Pr.11-37 (Forward speed limit) and Pr.11-38
(Reverse speed limit)
1: Set by Pr.11-37,11-38 and Pr.00-20 (Source of
Master Frequency Command)
2: Set by Pr.00-20 (Source of Master Frequency
Command).

0



11-37

0~120%

10



11-38

Forward Speed Limit (torque
mode)
Reverse Speed Limit (torque
mode)

0~120%

10

0: Torque mode
1: Speed mode
0: External terminal
1: Reserved
2: RS485
3: CAN
4: PLC
5: Communication card

0

0.000

11-39

Zero Torque Command Mode

11-40

Command Source of
Point-to-Point Position Control

11-41

Reserved



11-42

System Control Flags

0000~FFFFh

0000



11-43

0.00~600.00Hz

10.00



11-44

0.00~655.35 sec

1.00



11-45

Max. Frequency of Pointto-Point Position Control
Accel. Time of Point-to Point
Position Control
Decel. Time of Point-to Point
Position Control

0.00~655.35 sec

3.00



11-37

0

Chapter 12 Description of Parameter SettingsC2000 Series

Chapter 12 Description of Parameter Settings
00 Drive Parameters

 This parameter can be set during operation.

Identity Code of the AC Motor Drive
Factory Setting: #.#
Settings

Read Only

Display AC Motor Drive Rated Current
Factory Setting: #.#
Settings

Read Only

 Pr. 00-00 displays the identity code of the AC motor drive. Using the following table to check if
Pr.00-01 setting is the rated current of the AC motor drive. Pr.00-01 corresponds to the identity
code Pr.00-00.
 The factory setting is the rated current for normal duty. Please set Pr.00-16 to 1 to display the rated
current for the heavy duty.
230V Series
Frame
kW
HP
Pr.00-00
Rated Current for
Heavy Duty (A)
Rated Current for
Normal Duty (A)
Frame
kW
HP
Pr.00-00
Rated Current for
Heavy Duty (A)
Rated Current for
Normal Duty (A)

A

B

C

0.75
1.0
4

1.5
2.0
6

2.2
3.0
8

3.7
5.0
10

5.5
7.5
12

7.5
10
14

11
15
16

15
20
18

18.5
25
20

22
30
22

4.8

7.1

10

16

24

31

47

62

71

86

5

8

11

17

25

33

49

65

75

90

30
40
24

37
50
26

45
60
28

E
50
75
30

75
100
32

F
90
125
34

114

139

171

204

242

329

120

146

180

215

255

346

D

460V Series
Frame
kW
0.75
HP
1
Pr.00-00
5
Rated Current for
2.9
Heavy Duty (A)
Rated Current for
3.0
Normal Duty (A)
Frame
kW
HP
Pr.00-00
Rated Current for
Heavy Duty (A)
Rated Current for
Normal Duty (A)

A

B

C

1.5
2
7

2.2
3
9

3.7
5
11

4.0
5
93

5.5
7.5
13

7. 5
10
15

11
15
17

15
20
19

18.5
25
21

22
30
23

30
40
25

3.8

5.7

8.1

9.5

11

17

23

30

36

43

57

4.0

6.0

9.0

10.5

12

18

24

32

38

45

60

D0

D

E

F

G

H

37
50
27

45
60
29

55
75
31

75
100
33

90
125
35

110
150
37

132
175
39

160
215
41

185
250
43

220
300
45

280
375
47

315
425
49

355
475
51

69

86

105

143

171

209

247

295

352

437

523

585

649

73

91

110

150

180

220

260

310

370

460

550

616

683

12-00-1

Chapter 12 Description of Parameter SettingsC2000 Series

Parameter Reset
Factory Setting: 0
Settings

0: No Function
1: Write protection for parameters
5: Reset KWH display to 0
6: Reset PLC (including CANopen Master Index)
7: Reset CANopen Index (Slave)
8: Reserve
9: All parameters are reset to factory settings(base frequency is 50Hz)
10: All parameters are reset to factory settings (base frequency is 60Hz)

 When it is set to 1, all parameters are read only except Pr.00-02~00-08 and it can be used with
password setting for password protection. It needs to set Pr.00-02 to 0 before changing other
parameter settings.
 When it is set to 9 or 10: all parameters are reset to factory settings. If password is set in Pr.00-08,
input the password set in Pr.00-07 to reset to factory settings.
 When it is set to 5, KWH display value can be reset to 0 even when the drive is operating. Pr. 05-26,
05-27, 05-28, 05-29, 05-30 reset to 0.
 When it is set to 6: clear internal PLC program (includes the related settings of PLC internal
CANopen master)
 When it is set to 7: reset the related settings of CANopen slave.
 When it is set to 6、7、9、10, please re-power the motor drive after setting.


Start-up Display Selection
Factory setting:
Settings

0

0: Display the frequency command (F)
1: Display the actual output frequency (H)
2: Display User define (U)
3: Output current ( A)

 This parameter determines the start-up display page after power is applied to the drive. User
defined choice display according to the setting in Pr.00-04.


Content of Multi-function Display
Factory setting: 3
Settings

0: Display output current (A) (Unit: Amps)
1: Display counter value (c) (Unit: CNT)
2: Display actual output frequency (H.) (Unit: Hz)
3: Display DC-BUS voltage (v) (Unit: Vdc)
4: Display output voltage (E) (Unit: Vac)
5: Display output power angle (n) (Unit: deg)
6: Display output power in kW (P) (Unit: Kw)
7: Display actual motor speed rpm (r = 00: positive speed; -00 negative
speed) (Unit: rpm)
12-00-2

Chapter 12 Description of Parameter SettingsC2000 Series

8: Display estimate output torque % (t = 00: positive torque; -00 negative
torque) (t) (Unit: %)
9: Display PG feedback (G) (refer to Note 1) (Unit: PLS)
10: Display PID feedback (b) (Unit: %)
11: Display AVI in % (1.), 0~10V/4-20mA/0-20mA corresponds to 0~100%
(Refer to Note 2) (Unit: %)
12: Display ACI in % (2.),

4~20mA/0~10V/0-20mA corresponds to

0~100%（Refer to Note 2）(Unit: %)
13: Display AUI in % (3.),

-10V~10V corresponds to -100~100%(Refer to

Note 2) (Unit: %)
14: Display the temperature of IGBT (i.) (Unit: ℃)
15: Display the temperature of capacitance (c.) (Unit: ℃)
16: The status of digital input (ON/OFF) refer to Pr.02-12 (i) (Refer to
Note3)
17: Display digital output status ON/OFF (Pr.02-18) (o) (refer to NOTE 4)
18: Display the multi-step speed that is executing (S)
19: The corresponding CPU pin status of digital input (d) (refer to NOTE 3)
20: The corresponding CPU pin status of digital output (0.) (refer to NOTE
4)
21: Actual motor position (PG1 of PG card). When the motor direction
changes or the drive stops, the counter will start from 0 (display value
restarts counting from 0) (Max. 65535) (P.)
22: Pulse input frequency (PG2 of PG card) (S.)
23: Pulse input position (PG2 of PG card) (max. 65535) (q.)
24: Position command tracing error (E.)
25: Overload counting (0.00~100.00%) (o.) (Refer to Note 6) (Unit: %)
26: GFF Ground Fault (G.) (Unit: %)
27: DC Bus voltage ripple (r.) (Unit: %)
28: Display PLC register D1043 data (C) display in hexadecimal
29: Display PM motor pole section (EMC-PG01U application) (4.)
30 : Display output of user defined (U)
31 : H page x 00-05 Display user Gain(K)
32: Number of actual motor revolution during operation (PG card plug in
and Z phase signal input) (Z.)
33: Motor actual position during operation (when PG card is connected)(q)
34: Operation speed of fan (F.) (Unit: %)
35: Control Mode display: 0= Speed control mode (SPD), 1= torque control
mode (TQR) (t.)
36: Present operating carrier frequency of drive (Hz) (J.)
37: Reserved
38: Display drive status (6.) (Refer to Note 7)

40: Torque command (L.) (Unit: %)
12-00-3

Chapter 12 Description of Parameter SettingsC2000 Series

41: KWH display (J) (Unit: KWH)
42: PID reference (h.) (Unit: %)
43: PID offset (o.) (Unit: %)
44: PID output frequency (b.) (Unit: Hz)
45: Hardware ID
NOTE

1. When Pr.10-01 is set to 1000 and Pr.10-02 is set to 1/2, the display range for PG feedback will be from 0
to 4000.
When Pr.10-01 is set to 1000 and Pr.10-02 is set to 3/4/5, the display range for PG feedback will be from
0 to 1000.
Home position: If it has Z phase, Z phase will be regarded as home position. Otherwise, home position
will be the encoder start up position.
2. It can display negative values when setting analog input bias (Pr.03-03~03-10).
Example: assume that AVI input voltage is 0V, Pr.03-03 is 10.0% and Pr.03-07 is 4 (Serve bias as the
center).
3. Example: If REV, MI1 and MI6 are ON, the following table shows the status of the terminals.
0: OFF, 1: ON
Terminal MI15 MI14 MI13 MI12 MI11 MI10 MI8 MI7 MI6 MI5 MI4 MI3 MI2 MI1 REV FWD
1
0
Status
0
0
0
0
0
0
0 0 1 0 0 0 0 1
MI10~MI15 are the terminals for extension cards (Pr.02-26~02-31).
If REV, MI1 and MI6 are ON, the value is 0000 0000 1000 0110 in binary and 0086h in HEX. When
Pr.00-04 is set to “16” or “19”, it will display “0086h” with LED U is ON on the keypad KPC-CE01. The
setting 16 is the status of digital input by Pr.02-12 setting and the setting 19 is the corresponding CPU
pin status of digital input, the FWD/REV action and the three-wire MI are not controlled by Pr.02-12. User
can set to 16 to monitor digital input status and then set to 19 to check if the wire is normal.
4. Assume that RY1: Pr.02-13 is set to 9 (Drive ready). After applying the power to the AC motor drive, if
there is no other abnormal status, the contact will be ON. The display status will be shown as follows.
N.O. switch status:
Terminal

Reserved

Reserved

Reserved

MO2 MO1 Reserved RY2 RY1

Status 0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
At the meanwhile, if Pr.00-04 is set to 17 or 20, it will display in hexadecimal “0001h” with LED U is ON
on the keypad. The setting 17 is the status of digital output by Pr.02-18 setting and the setting 20 is the
corresponding CPU pin status of digital output. User can set 17 to monitor the digital output status and
then set to 20 to check if the wire is normal.
5. Setting 8: 100% means the motor rated torque. Motor rated torque = (motor rated power x60/2π)/motor
rated speed
6. If Pr.00-04 = 25, when display value reaches 100.00%, the drive will show “oL” as an overload warning.
7. If Pr.00-04 = 38,
Bit 0: The drive is running forward.
Bit 1: The drive is running backward.
Bit 2: The drive is ready.
Bit 3: Errors occurred on the drive.
Bit 4: The drive is running.
Bit 5: Warnings on the drive.

12-00-4

Chapter 12 Description of Parameter SettingsC2000 Series



Coefficient Gain in Actual Output Frequency
Factory Setting: 0
Settings

0~160.00

 This parameter is to set coefficient gain in actual output frequency. Set Pr.00-04= 31 to display the
calculation result on the screen (calculation = output frequency * Pr.00-05).
Software Version
Factory Setting: #.#
Settings


Read only

Parameter Protection Password Input
Factory Setting: 0
Settings

1~9998, 10000~65535

Display

0~3 (the times of password attempts)

 This parameter allows user to enter their password (which is set in Pr.00-08) to unlock the
parameter protection and to make changes to the parameter.
 Pr.00-07 and Pr.00-08 are used to prevent the personal mis-operation.
 When the user have forgotten the password, clear the setting by input 9999 and press ENTER key,
then input 9999 again and press Enter within 10 seconds. After decoding, all the settings will return
to factory setting.


Parameter Protection Password Setting
Factory Setting: 0
Settings

1~9998, 10000~65535
0: No password protection / password is entered correctly (Pr00-07)
1: Password has been set

 To set a password to protect your parameter settings. In the first time, password can be set directly.
After setting, the value of 00-08 will become 1, which means password protection is activated.
When the password is set, if any parameter setting needs to be changed, be sure to enter correct
password in 00-07, and then the password will be inactivated temporarily with 00-08 changing to 0.
At this time, parameters setting can be changed. After setting, re-power the motor drive, and
password will be activated again.
 To cancel the password protection, after entering correct password in 00-07, 00-08 also needs to be
set as 0 again to inactive password protection permanently. If not, password protection will be
active after motor drive re-power.
 The keypad copy function will work normally only when the password protection is inactivated
temporarily or permanently, and password set in 00-08 will not be copied to keypad. So when
copying parameters from keypad to motor drive, the password need to be set manually again in
the motor drive to active password protection.

12-00-5

Chapter 12 Description of Parameter SettingsC2000 Series

Password Decode Flow Chart
Pass word Forgotten

Pass word Setting

Pass word Incorrect

00-07

00-08
Displays 01 after
correct password is
entered to Pr.00-08.

00-07

Enter 9999 and press ENTER,
then ente r 9999 aga in withi n 10
se cond s an d pre ss ENTER.
Then all pa ra meters will re set
to factory se ttings .

3 chan ces of p assword inpu t:
Incorre ct p ass word 1: d ispl ays "01"
Incorre ct p ass word 2: disp lays "02 "
Incorre ct p ass word 3: "Pcode "(blin king)
Keyp ad will be loc ked after 3 wrong attemp ted
pas swords. To re-activate t he k eypa d, pl ease
reboo t the drive an d in put t he c orrect
pas sword.

Decode Flow Char t

00-08
Password Set
00-07
Password Input

Pr.00-08=0

Yes

Shut down th drive
and re-app ly power

No
Re-apply power.
(The password is still valid)

Reserved


Control Mode
Factory Setting: 0
Settings

0: Speed mode
1: Point-to-Point position control
2: Torque mode
3: Home mode

 This parameter determines the control mode of C2000 series AC motor drive.
Control of Speed Mode
Factory Setting: 0
Settings

0: VF (IM V/f control)
1: VFPG (IM V/f control+ Encoder)
2: SVC(IM sensorless vector control)
3: FOCPG (IM FOC vector control+ encoder)
4: FOCPG（PM FOC vector control + Encoder）
5: FOC Sensorless (IM field oriented sensorless vector control)
6: PM Sensorless (PM field oriented sensorless vector control)
7: IPM Sensorless (Interior PM field oriented sensorless vector control)

12-00-6

Chapter 12 Description of Parameter SettingsC2000 Series

 This parameter determines the control method of the AC motor drive:
0: (IM V/f control): user can design proportion of V/f as required and can control multiple motors
simultaneously.
1: (IM V/f control + Encoder): user can use optional PG card with encoder for the closed-loop
speed control.
2: (IM Sensorless vector control): get the optimal control by the auto-tuning of motor
parameters.
3: (IM FOC vector control+ encoder): besides torque increases, the speed control will be more
accurate (1:1000).
4: (PM FOC vector control + Encoder): besides torque increases, the speed control will be more
accurate (1:1000).
5: FOC Sensorless: IM field oriented sensorless vector control
6: PM Sensorless (PM field oriented sensorless vector control)
7: IPM Sensorless (Interior PM field oriented sensorless vector control)
 When 00-10=0, and set Pr.00-11 to 0, the V/F control diagram is shown as follows.
DC BUS
Voltage
Detect

DC BUS Voltage
Pr otection

Current Detection
Fcm d
Pr 00-20

+

V/F
table
Accel / Decel tim e

+

01-00,01-01
01-02,01-03
01-04,01-05
01-06,01-07
01-08

IGBT
PWM

AVR
07- 23

X

M
01-00
01-01
01-02
05-01
05-02
05-03
05-04

Voltage
com pensation

LPF

Torque
Compensation

07-24

07-26

Irms

 When 00-10=0, and set Pr.00-11 to 1, the V/F control + encoder diagram is shown as follows.
Frequency
Inaccuracy

V/F
table

Voltage
Com mand +

Curr ent
Detection
AVR
07- 23

X
+

LPF
0 7-24

Voltage
Compensate Torque
compensation

IGBT
PWM

Power
Factor
Irm s

07-26
LPF
07-25

12-00-7

Real speed

M

Encoder

Fcm d
Pr 00-20

Chapter 12 Description of Parameter SettingsC2000 Series

 When 00-10=0, and set Pr.00-11 to 2, the sensorless vector control diagram is shown as follows.
DC BUS
DC BUS Voltage
Voltage
Det ect

Fcm d
Pr 00-20

Protection

Current Detection
+

AVR
07- 23

V/F
table

+

IGBT
PWM

M
01- 00
01- 01
01- 02
05- 01
05- 02
05- 03
05- 04

01-00,01-01
01-02

Accel / Decel time

LPF
07-25

Slip compensat ion

Slip
Com pensation

Irms

0 7-27

 When 00-10=0, and set Pr.00-11 to 3, the IM FOCPG control diagram is shown as follows.
11-12
Gain for ASR Speed
Feed Forward

Fcmd
00-20
ASR
Accel / Decel
time
01-12~01-19

+

Torque Li mi t
Pr11-17 ~11-20

ASR
11-00
Bit0=0
11-06~11-11
Bit0=1
11-03~11-05

ASR outp ut fi lter
P r11-14

TqBias
No offset
by03-00
by11-29
by mul tifun cti on inp ut
Pr11-28

DC BUS
Iq
Curr ent
control

Kt
T

C

Vd/Vq

2/ 3
e s

Id

AVR
07- 23

IGBT
PWM

M
01-00
01-01
01-02
05-01
05-02
05-03
05-04

θe

ACR

•
3/2
s e

Flux weakening
curve
11-21/11-22

current feedback

Id / Iq
fe e db ac k
ωe
ωr+ ωsl
Actual frequency + Slip

12-00-8

EN
10-00~10-02

Chapter 12 Description of Parameter SettingsC2000 Series

 When 00-10=0, and set Pr.00-11 to 4, the PM FOCPG control diagram is shown as follows.

11-12
G ainforAS RS peed
F eed F orwar d

00-20

+

+

ASR

-

+
+

11-00 Bit 0=0
11-06~11-11,
11-00 Bit 0=1
11-03~11-05,

Torque Limit
11-17~11-20

11-14

nooffset

by 03-00
by 11-29
bymultifunction
input

TqBias
11-28

Torque command

Fluxweakening
curve

Iq command

IGBT
&
PWM

Current
control

11-21/11-22
I d command

PM
motor
01-01, 01-02
01-35, 01-36
05-33~05-43

c urre nt
measure

actual frequency

EN

currentfe edbac k

10-00
~
10-02

 When 00-10=0, and set Pr.00-11 to 5, FOC sensorless (IM) control diagram is shown as follows.
-axis vo l. cmd u
S tator freq. W
DC B US vol. V dc

Id cmd

Flux
Calcu lat or

d - a xis
c urrent
regu lat or
Vd c omma nd

-axis vo l. cmd u

Acc el / Decel
calc ulation
S peed
c md

ASR

Flux cmd
D
N

q - axis
current
Vq cmd
re gulator

Iq cmd

11-01~11-14 Torque
c md

q - axis
c urrent
f eedback

I

d - axis current
feed back

S tator freq.
limit 10 - 26

dq
to


u


to
dq

i
Clarke
i
3to2

u

IGBT
&
PWM

S tato r freq.
Flux c md

Rotato r
slip calculat or

Es timated sp eed

12-00-9

Spee d
obs erv er
10-25

Current feedb ack
A phas e
B phas e
C phase

IM

Chapter 12 Description of Parameter SettingsC2000 Series

 When 00-10=0, and set Pr.00-11 to 6, PM FOC sensorless control diagram is shown as follows:
I/F mode current cmd
Pr10-31

Pr10-39
LPF
-

AMR
Pr10-35
Pr10-36

Id cmd

P r10- 41

Wr_cmd

Iq cmd

q - a xi s
cu rren t
re gul ator

ASR

Wr _est

abc
to
dq

d - axis
current
reg ula tor

Va Vb Vc

_ est

Pr11-00~Pr11-05
Iq feedback

IGBT
&
PWM

Observer
Pr10-32

MOTOR

Ia Ib Ic

dq
to
abc

Id feedback

LPF
Pr10 - 34

 When 00-10=0, and set Pr.00-11 to 7, IPM FOC sensorless control diagram is shown as follows:
High frequency signal
Frequency : Pr10- 51
Amplitude : Pr10- 52

AMR
Pr10-35
Pr10-36

LPF

Id_cmd
Id_fdb

d-axis
ACR

dq
to
abc

+

IGBT
&
PWM

MOTOR

Va Vb Vc

Speed
command

Iq_cm d
ASR

Pr 11-00~Pr11-11

Iq_fdb

q -axis
ACR

T_set O bserver
Pr10-32

abc
to
dq
Estimated speed
LPF
Pr10 - 34

12-00-10

Ia Ib Ic

Chapter 12 Description of Parameter SettingsC2000 Series

Point to Point Position control
Factory Settings: 0
Settings: 0: Incremental Type
1: Absolute Type
 Pr. 00-12 = 0 is incremental type P2P; Pr.00-12 = 1 is absolute type P2P

Control of Torque Mode
Factory Setting: 0
Settings

0: TQCPG（IM Torque control + Encoder）
1: TQCPG (PM Torque control + Encoder)
2: TQC Sensorless (IM Sensorless torque control)

 TQCPG (Pr00-13=0) control diagram is shown in the following:
11-28
Torque off se t

1 1-33

To r q ue co mm an d

n o o ffse t
b y Pr.0 3 -0 0

KPC - CC0 1
RS-485
03-00
CANOpe n

b y Pr.11 - 2 9
b y mu lt i- fu nc tio n i np u t

Co mm . c ard
+

cu r re n t lim it

T or q ue cm d
LP F

+
1 1 -3 6 o r 00 - 20
S pe e d li mi t or com ma nd
+
-

06 - 12

1 1 -3 5
sp e ed /to r qu e
mo d e swi tch

ASR
1 1 -0 0 B it 0=0
11 - 06 ~1 1 -1 1
1 1 -0 0 B it 0=1
11 - 03 ~1 1 -0 5

flu x we a ke ni n g cu rve
1 1 -2 1 /1 1- 2 2

To rq u e li mi t
11 - 17 ~1 1 -2 0

11 - 14

lq
co mm a nd

l d com ma nd

Current
control

IG B T
&
P WM

Current
measure Cu r re n t fe e db a ck

a ctu a l fre q ue n cy

12-00-11

M
Mot or 1
01-01
01-02
05-01
~
05-09

Motor2
01-35
01-36
05-13
~
05-21

EN

10-00
~
10-02

Chapter 12 Description of Parameter SettingsC2000 Series

 TQC Sensorless (Pr00-13=2) control diagram is shown in the following:
-ax is v ol. cmd
-ax is vol. cmd

u
u

Stat or f re q. W

10-28
Flux
Calculat or

Exci ting
current

Fast
Flu x
Esta bli sh

Id cmd

d - ax is
c urre nt
regulato r

DC BUS v ol.Vdc

Flux cmd

To rq ue
cmd
+

11-36 o r 0 0-20
Sp eed l imit o r co mman d

+
Estimate d
Sp eed

-

P
C ontrol ler

Iq cmd

LPF
To rq ue
Current
Low -p ass
Filte r

11-01~11-14
PI
C ontrol ler
11-01~11-14

Vd cmd

q - axis
current
re gulator

u

IGBT
&
u
PWM

IM

I
q - axis
current feed back

10-24
Sta tor freq.
limit 10- 26

d- axis current
f ee dba ck

Sta tor freq.
I* m
Lm
W* m

dq
to


Vq cmd

R otato r
sli p ca lcula tor

Sp eed
o bserver
1 0-25


to
dq

i

Clarke

i 3 to 2

Current feedb ack
A p hase
B p hase
C phase

Reserved
Reserved
Load Selection
Factory Setting: 0
Settings

0: Normal load
1: Heavy load

 Normal duty: over load ability is 160% rated output current in 3 second. Please refer to Pr.00-17 for
the setting of carrier. Refer to chapter 9 (specifications) or Pr.00-01 for the rated current.

 Heavy duty: over load ability is 180% rated output current in 3 second. Please refer to Pr.00-17 for
the setting of carrier wave. Refer to chapter 9 (specifications) or Pr.00-01 for the rated current.
 Pr.00-01 changes as the setting of Pr.00-16 changes. The default setting and maximum setting
range of Pr.06-03, 06-04 will change as the setting of Pr.00-16 changes.
 In Normal Duty, the default setting of 06-03, 06-04 is 120%, maximum setting range is 160%. When
DC voltage is higher than 700Vdc (460V series) or 350V(230V series), then the maximum setting
range will be 145%
 In Heavy Duty, the default setting of 06-03, 06-04 is 150%, maximum setting range is 180%. When
DC voltage is higher than 700Vdc (460V series) or 350V(230V series), then the maximum setting
range will be 165%

12-00-12

Chapter 12 Description of Parameter SettingsC2000 Series

Carrier Frequency
Factory setting: Table below
2～15kHz

Settings

 This parameter determinates the PWM carrier frequency of the AC motor drive.
230V Series
Models

1-15HP [0.75-11kW]

20-50HP [15-37kW]

60-125HP [45-90kW]

Setting Range

02~15kHz

02~10kHz

02~09kHz

Normal Duty Factory

8kHz

6kHz

4kHz

Setting
Heavy Duty Factory

2kHz

Setting
460V Series
Models

1-20HP [0.75-15kW]

25-75HP [18.5-55kW] 100-600HP [75-450kW]

Setting Range

02~15kHz

02~10kHz

02~09kHz

Normal Duty Factory

8kHz

6kHz

4kHz

Setting
Heavy Duty Factory

2kHz

Setting
Heat
Dissipation

Significant

Electromagnetic
Noise or Leakage
Current
Minimal

Minimal

Significant

Significant

Carrier
Frequency

Acoustic
Noise

1kH z

Current
Wave

M inimal

8kH z
15kHz

 From the table, we see that the PWM carrier frequency has a significant influence on the
electromagnetic noise, AC motor drive heat dissipation, and motor acoustic noise. Therefore, if the
surrounding noise is greater than the motor noise, lower the carrier frequency is good to reduce the
temperature rise. Although it is quiet operation in the higher carrier frequency, the entire wiring and
interference resistance should be considerate.
 When the carrier frequency is higher than the factory setting, it needs to protect by decreasing the
carrier frequency. See Pr.06-55 for the related setting and details.
Reserved
PLC Command Mask
Factory Setting: Read Only
Settings

Bit 0: Control command by PLC force control
Bit 1: Frequency command by PLC force control
Bit 2: Position command by PLC force control
Bit 3: Torque command by PLC force control

 This parameter determines if frequency command or control command is occupied by PLC

12-00-13

Chapter 12 Description of Parameter SettingsC2000 Series

Source of the Master Frequency Command（AUTO）
Factory Setting: 0
Settings

0: Digital keypad
1: RS-485 serial communication
2: External analog input (Pr.03-00)
3: External UP/DOWN terminal
4: Pulse input without direction command (Pr.10-16 without direction)
5: Pulse input with direction command (Pr.10-16)
6: CANopen communication card
7: Reserved
8: Communication card (no CANopen card)

 It is used to set the source of the master frequency in AUTO mode.
 Pr.00-20 and 00-21 are for the settings of frequency source and operation source in AUTO mode.
Pr.00-30 and 00-31 are for the settings of frequency source and operation source in HAND mode.
The AUTO/HAND mode can be switched by the keypad KPC-CC01 or multi-function input terminal
(MI).
 The factory setting of frequency source or operation source is for AUTO mode. It will return to AUTO
mode whenever power on again after power off. If there is multi-function input terminal used to
switch AUTO/HAND mode. The highest priority is the multi-function input terminal. When the
external terminal is OFF, the drive won’t receive any operation signal and can’t execute JOG.
Source of the Operation Command （AUTO）
Factory Setting: 0
Settings

0: Digital keypad
1: External terminals. Keypad STOP disabled.
2: RS-485 serial communication. Keypad STOP disabled.
3: CANopen card
4: Reserved
5: Communication card (not includes CANopen card)

 It is used to set the source of the operation frequency in AUTO mode.
 When the operation command is controlled by the keypad KPC-CC01, keys RUN, STOP and JOG
(F1) are valid.


Stop Method
Factory Setting: 0
Settings

0: Ramp to stop
1:Coast to stop

 The parameter determines how the motor is stopped when the AC motor drive receives a valid stop
command.

12-00-14

Chapter 12 Description of Parameter SettingsC2000 Series

Freq uen cy
Output
Frequenc y
Moto r
Ro tatio n
Spe ed

Oper atio n
Co mmand

RUN

Freq uen cy
Output
Frequenc y
Moto r
Ro tatio n
Spe ed

Stops according t o
deceler ation time

Fr ee r unning
to stop

Time

STOP

Oper atio n
Co mmand

RUN

Time

STOP

Ra mp to Stop and Co ast to Sto p

 Ramp to stop: the AC motor drive decelerates from the setting of deceleration time to 0 or
minimum output frequency (Pr. 01-09) and then stop (by Pr.01-07).
 Coast to stop: the AC motor drive stops the output instantly upon a STOP command and the
motor free runs until it comes to a complete standstill.
(1) It is recommended to use “ramp to stop” for safety of personnel or to prevent material from
being wasted in applications where the motor has to stop after the drive is stopped. The
deceleration time has to be set accordingly.
(2) If the motor free running is allowed or the load inertia is large, it is recommended to select
“coast to stop”. For example, blowers, punching machines and pumps


Control of Motor Direction
Factory Setting: 0
Settings

0: Enable forward/ reverse
1: Disable reverse
2: Disable forward

 This parameter enables the AC motor drives to run in the forward/reverse Direction. It may be used
to prevent a motor from running in a direction that would consequently injure the user or damage
the equipment.
Memory of Frequency Command
Factory Setting:
Settings

Read Only

Read only

 If keypad is the source of frequency command, when Lv or Fault occurs the present frequency
command will be saved in this parameter.


User Defined Characteristics
Factory Setting: 0
Settings

Bit 0~3: user defined decimal place
0000b: no decimal place
0001b: one decimal place
0010b: two decimal place
0011b: three decimal place

12-00-15

Chapter 12 Description of Parameter SettingsC2000 Series

Bit 4~15: user defined unit
000xh: Hz
001xh: rpm
002xh: %
003xh: kg
004xh: m/s
005xh: kW
006xh: HP
007xh: ppm
008xh: 1/m
009xh: kg/s
00Axh: kg/m
00Bxh: kg/h
00Cxh: lb/s
00Dxh: lb/m
00Exh: lb/h
00Fxh: ft/s
010xh: ft/m
011xh: m
012xh: ft
013xh: degC
014xh: degF
015xh: mbar
016xh: bar
017xh: Pa
018xh: kPa
019xh: mWG
01Axh: inWG
01Bxh: ftWG
01Cxh: psi
01Dxh: atm
01Exh: L/s
01Fxh: L/m
020xh: L/h
021xh: m3/s
022xh: m3/h
023xh: GPM
024xh: CFM
xxxxh: Hz
 Bit 0~3: Control F page, unit of user defined value (Pr00-04 =d10, PID feedback) and the decimal
point of Pr00-26 which supports up to 3 decimal points.
 Bit 4~15: Control F page, unit of user defined value (Pr00-04=d10, PID feedback) and the display
units of Pr00-26.
0 0 0 0 h
u se r d e fin e d d e cima l p la ce
0:no decimal place
1:one decimal place
2:two decimal place
3:three decimal place

u se r d e fin e d u n it
0: Hz
1: rpm
2: %
3: kg

12-00-16

Chapter 12 Description of Parameter SettingsC2000 Series

Max. User Defined Value
Factory Setting: 0
Settings

0: Disable
0~65535 (when Pr.00-25 set to no decimal place)
0.0~6553.5 (when Pr.00-25 set to 1 decimal place)
0.0~655.35 (when Pr.00-25 set to 2 decimal place)
0.0~65.535 (when Pr.00-25 set to 3 decimal place)

 When Pr.00-26 is NOT set to 0.

The user defined value is enabled.

The value of this parameter

should correspond to the frequency setting at Pr.01-00.
Example:
When the frequency at Pr. 01-00=60.00Hz, the max. user defined value at Pr. 00-26 is 100.0%.
That also means Pr.00-25 is set at 0021h to select % as the unit.
NOTE

The drive will display as Pr.00-25 setting when Pr.00-25 is properly set and Pr.00-26 is not 0.
User Defined Value
Factory Setting: Read only
Settings

Read only

 Pr.00-27 will show user defined value when Pr.00-26 is not set to 0.
 User defined function is valid when:
1. Pr.00-20 is set to digital keypad control
2. RS-285 communication input control.
3. PID function enable
Reserved
LOCAL/REMOTE Selection
Factory Setting: 0
Settings

0: Standard HOA function
1: Switching Local/Remote, the drive stops

2: Switching Local/Remote, the drive runs as the REMOTE setting for
frequency and operation status
3: Switching Local/Remote, the drive runs as the LOCAL setting for frequency
and operation status
4: Switching Local/Remote, the drive runs as LOCAL setting when switch to
Local and runs as REMOTE setting when switch to Remote for frequency
and operation status.
 The factory setting of Pr.00-29 is 0 (standard Hand-Off-Auto function). The AUTO frequency and
source of operation can be set by Pr.00-20 and Pr.00-21, and the HAND frequency and source of
operation can be set by Pr.00-30 and Pr.00-31. AUTO/HAND mode can be selected or switched by
using digital keypad (KPC-CC01) or setting multi-function input terminal MI= 41, 42.
 When external terminal MI is set to 41 and 42 (AUTO/HAND mode), the settings Pr.00-29=1,2,3,4
will be disabled. The external terminal has the highest priority among all command, Pr.00-29 will
always function as Pr.00-29=0, standard HOA mode.

12-00-17

Chapter 12 Description of Parameter SettingsC2000 Series

 When Pr.00-29 is not set to 0, Local/Remote function is enabled, the top right corner of digital
keypad (KPC-CC01) will display “LOC” or “REM” (the display is available when KPC-CC01 is
installed with firmware version higher than version 1.021). The LOCAL frequency and source of
operation can be set by Pr.00-20 and Pr.00-21, and the REMOTE frequency and source of
operation can be set by Pr.00-30 and Pr.00-31. Local/Remote function can be selected or switched
by using digital keypad (KPC-CC01) or setting external terminal MI=56. The AUTO key of the digital
keypad now controls for the REMOTE function and HAND key now controls for the LOCAL function.
 When MI is set to 56 for LOC/REM selection, if Pr.00-29 is set to 0, then the external terminal is
disabled.
 When MI is set to 56 for LOC/REM selection, if Pr.00-29 is not set to 0, the external terminal has the
highest priority of command and the ATUO/HAND keys will be disabled.
Source of the Master Frequency Command（HAND）
Factory Setting: 0
Settings

0: Digital keypad
1: RS-485 serial communication
2: External analog input (Pr.03-00)
3: External UP/DOWN terminal
4: Pulse input without direction command (Pr.10-16 without direction)
5: Pulse input with direction command (Pr.10-16)
6: CANopen communication card
7: Reserved
8: Communication card (no CANopen card)

 It is used to set the source of the master frequency in HAND mode.
Source of the Operation Command (HAND)
Factory Setting: 0
Settings

0: Digital keypad
1: External terminals. Keypad STOP disabled.
2: RS-485 serial communication. Keypad STOP disabled.
3: CANopen communication card
4: Reserved
5: Communication card (not include CANopen card

 It is used to set the source of the operation frequency in HAND mode.
 Pr.00-20 and 00-21 are for the settings of frequency source and operation source in AUTO mode.
Pr.00-30 and 00-31 are for the settings of frequency source and operation source in HAND mode.
The AUTO/HAND mode can be switched by the keypad KPC-CC01 or multi-function input terminal
(MI).
 The factory setting of frequency source or operation source is for AUTO mode. It will return to AUTO
mode whenever power on again after power off. If there is multi-function input terminal used to
switch AUTO/HAND mode. The highest priority is the multi-function input terminal. When the
external terminal is OFF, the drive won’t receive any operation signal and can’t execute JOG.

12-00-18

Chapter 12 Description of Parameter SettingsC2000 Series

Digital Keypad STOP Function



Factory Setting: 0
Settings

0: STOP key disable
1: STOP key enable

 This parameter works when the source of operation command is not digital keypad (Pr00-21≠0).
When Pr00-21=0, the stop key will not follow the setting of this parameter.

~


Reserved
Homing mode
Factory Setting: 0000h
Settings:

Note: Forward run = clockwise (CW)
Reverse run = counterclockwise (CCW)
X

0: Forward run to home. Set PL forward limit as check point.
1: Reverse run (CCW) to home. Set NL reverse limit (CCWL) as
check point.
2: Forward run to home. Set ORG : OFF→ON as check point.
3: Reverse to home. Set ORG : OFF→ON as check point.
4: Forward run and search for Z-pulse as check point.
5: Forward run and search for Z-pulse as check point.
6: Forward run to home. Set ORG: ON→OFF as check point.
7: Reverse run to home. Set ORG : ON→OFF as check point.
8: Define current position as home.

Y

Set X to 0, 1, 2, 3, 6, 7 .
0: reverse run to Z pulse
1: continue forward run to Z pulse
2: Ignore Z pulse

Z

When home limit is reached, set X to 2, 3, 4, 5, 6, 7 first.
0: display error
1: reverse the direction

 Homing action is control by Pr. 00-40, 00-41, 00-42 and 02-01~02-08.

12-00-19

Chapter 12 Description of Parameter SettingsC2000 Series

1. When Y=0, X=0 or Y=0, X=2
Speed

Posi tion

Z p ulse
CCWL /ORGP

2. When Y=0, X=1 or Y=0, X=3

Speed
Posi tion

Z p ulse
CWL/ORGP

3. When Y=1, X=2

Speed
Posi tion

Z p ulse
ORGP

4. When Y=1, X=3

Speed
Posi tion

Z p ulse
ORGP

12-00-20

Chapter 12 Description of Parameter SettingsC2000 Series

5. When Y=2, X=2

Speed

Posi tion

ORGP

6. When Y=2, X=3
Speed
Position

ORGP

7. When Y=2, X=4
Speed

Position
Z pulse

8. When Y=2, X=5
Speed
Position

Z pulse



Homing by Frequency 1
Factory Setting: 8.00
Settings



0.00~600.00Hz

Homing by Frequency 2
Factory Setting: 2.00
Settings

0.00~600.00Hz

 Control by Multi-function Input Terminal Pr. 02-01~02-08 (44~47).
44: Reverse direction homing
45: Forward direction homing
46: Homing (ORG)
47: Homing function enabled
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Chapter 12 Description of Parameter SettingsC2000 Series

 If the drive is not control by CAN or PLC, set Pr.00-10 =1 (Contorl mode = P2P position control) and
set external output terminal to 47 (homing function enable) for homing.
 When Pr.00-10 is set to 3, after homing is complete, user must set control mode setting Pr.00-10 to
1 in order to perform P2P position control.

~

Reserved
Display Filter Time (Current)



Factory Settings: 0.100
Settings: 0.001~65.535 sec
 Set this parameter to minimize the current fluctuation displayed by digital keypad.

Display Filter Time (Keypad)



Factory Settings: 0.100
Settings: 0.001~65.535 sec
 Set this parameter to minimize the display value fluctuation displayed by digital keypad.

Software Version (date)
Factory Settings: ####
Settings: Read only
 This parameter displays the drive’s software version by date.

~

Reserve



12-00-22

Chapter 12 Description of Parameter SettingsC2000 Series

Group 1 Basic Parameters

 This parameter can be set during operation.

Maximum Output Frequency
Factory Setting: 60.00/50.00
Settings

00.00~600.00Hz

 This parameter determines the AC motor drive’s Maximum Output Frequency. All the AC motor
drive frequency command sources (analog inputs 0 to +10V, 4 to 20mA, 0 to 20mAand ±10V) are
scaled to correspond to the output frequency range.
Output Frequency of Motor 1（base frequency and motor rated frequency）
Output Frequency of Motor 2（base frequency and motor rated frequency）
Factory Setting: 60.00/50.00
Settings

0.00~600.00Hz

 This value should be set according to the rated frequency of the motor as indicated on the motor
nameplate. If the motor is 60Hz, the setting should be 60Hz. If the motor is 50Hz, it should be set to
50Hz.
Output Voltage of Motor 1（base frequency and motor rated frequency）
Output Voltage of Motor 2（base frequency and motor rated frequency）
Factory Setting: 200.0/400.0
Settings

230V series: 0.0~255.0V
460V series: 0.0~510.0V

 This value should be set according to the rated voltage of the motor as indicated on the motor
nameplate. If the motor is 220V, the setting should be 220.0. If the motor is 200V, it should be set to
200.0.
 There are many motor types in the market and the power system for each country is also difference.
The economic and convenience method to solve this problem is to install the AC motor drive. There
is no problem to use with the different voltage and frequency and also can amplify the original
characteristic and life of the motor.
Mid-point Frequency 1 of Motor 1
Factory Setting: 3.00
Motor drive with 250HP
and above: 1.50
Settings


0.00~600.00Hz

Mid-point Voltage 1 of Motor 1
Factory Setting: 11.0/22.0
Motor drive with 250HP
and above: 10.0
Settings

230V series: 0.0~240.0V
460V series: 0.0~480.0V

12-01-1

Chapter 12 Description of Parameter SettingsC2000 Series

Mid-point Frequency 1 of Motor 2
Factory Setting: 3.00
Motor drive with 250HP
and above: 1.50
Settings


0.00~600.00Hz

Mid-point Voltage 1 of Motor 2
Factory Setting: 11.0/22.0
Motor drive with 250HP
and above: 10.0
Settings

230V series: 0.0~240.0V
460V series: 0.0~480.0V

Mid-point Frequency 2 of Motor 1
Factory Setting: 0.50
Settings


0.00~600.00Hz

Mid-point Voltage 2 of Motor 1
Factory Setting: 2.0/4.0
Motor drive with 250HP
and above: 2.0
Settings

230V series: 0.0~240.0V
460V series: 0.0~480.0V

Mid-point Frequency 2 of Motor 2
Factory Setting: 0.50
Settings


0.00~600.00Hz

Mid-point Voltage 2 of Motor 2
Factory Setting: 2.0/4.0
Motor drive with 250HP
and above: 2.0
Settings

230V series: 0.0~240.0V
460V series: 0.0~480.0V

Min. Output Frequency of Motor 1
Factory Setting: 0.00
Settings


0.00~600.00Hz

Min. Output Voltage of Motor 1
Factory Setting: 0.0/0.0
Settings

230V series: 0.0~240.0V
460V series: 0.0~480.0V

Min. Output Frequency of Motor 2
Factory Setting: 0.00
Settings

0.00~600.00Hz

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Chapter 12 Description of Parameter SettingsC2000 Series

Min. Output Voltage of Motor 2



Factory Setting: 0.0/0.0
Settings

230V series: 0.0~240.0V
460V series: 0.0~480.0V

 V/f curve setting is usually set by the motor’s allowable loading characteristics. Pay special attention
to the motor’s heat dissipation, dynamic balance, and bearing lubricity, if the loading characteristics
exceed the loading limit of the motor.
 There is no limit for the voltage setting, but a high voltage at low frequency may cause motor
damage, overheat, and stall prevention or over-current protection. Therefore, please use the low
voltage at the low frequency to prevent motor damage.
 Pr.01-35 to Pr.01-42 is the V/f curve for the motor 2. When multi-function input terminals
Pr.02-01~02-08 and Pr.02-26 ~Pr.02-31 are set to 14 and enabled, the AC motor drive will act as
the 2nd V/f curve.
 The V/f curve for the motor 1 is shown as follows. The V/f curve for the motor 2 can be deduced
from it.
Vol tage
1s t Output
Voltage Setting 01-11 Output F requency Low er Limit
01-02
F requenc y output
2nd Output
ranges limitation
Voltage Setting
01-04
3r d Output
Voltage Setting
01-06

Output F requency
01-10U pper Limi t

4th Output
Voltage Setting
01-08 01-07 01-09
01-05 01-03
01-01
2nd F req.1st F req.
4th F req. Start F req.
3rd Fr eq.

R egul ar V /f Cur ve
Special V/f C urve

F requenc y
01-00
Maximum Output
F requenc y

V/f Curve

Common settings of V/f curve:
(1) General purpose
Motor spec. 60Hz

Motor spec. 50Hz

V
220

10
1.5

60.0

F

Pr.
01-00
01-01
01-02
01-03
01-05
01-04
01-06
01-07
01-08

Setting
60.0
60.0
220.0

V
220

1.50
10.0

10

1.50
10.0

1.3

12-01-3

50.0

F

Pr.
01-00
01-01
01-02
01-03
01-05
01-04
01-06
01-07
01-08

Setting
50.0
50.0
220.0
1.30
10.0
1.30
10.0

Chapter 12 Description of Parameter SettingsC2000 Series

(2) Fan and hydraulic machinery
Motor spec. 60Hz

Motor spec. 50Hz

V
220

Pr.
01-00
01-01
01-02
01-03
01-05
01-04
01-06
01-07
01-08

50
10
1.5

30

60.0

F

V
220

Setting
60.0
60.0
220.0
30.0

50

50.0

10

1.50
10.0

1.3

25

50.0

F

Pr.
01-00
01-01
01-02
01-03
01-05
01-04
01-06
01-07
01-08

Setting
50.0
50.0
220.0
25.0
50.0
1.30
10.0

(3) High starting torque
Motor spec. 60Hz

Motor spec. 50Hz
Pr.
01-00
01-01
01-02
01-03
01-05

V
220

23
18
60.0

1.5 3

F

01-04
01-06
01-07
01-08

Setting
60.0
60.0
220.0

V
220

3.00

Pr.
01-00
01-01
01-02
01-03
01-05

23

23.0

14

1.50
18.0

1.3 2.2

50.0

F

01-04
01-06
01-07
01-08

Setting
50.0
50.0
220.0
2.20
23.0
1.30
14.0

Start-Up Frequency
Factory Setting: 0.50
Settings

0.0~600.00Hz

 When start frequency is higher than the min. output frequency, drives’ output will be from start
frequency to the setting frequency. Please refer to the following diagram for details.
 Fcmd=frequency command,
Fstart=start frequency (Pr.01-09),
fstart=actual start frequency of drive,
Fmin=4th output frequency setting (Pr.01-07/Pr.01-41),
Flow=output frequency lower limit (Pr.01-11)
 Fcmd>Fmin and Fcmd=Fcmd, drive will run with Fcmd firstly, then, accelerate to Flow according to
acceleration time.
 The drive’s output will stop immediately when output frequency has reach to Fmin during
deceleration.

12-01-4

Chapter 12 Description of Parameter SettingsC2000 Series

F cmd>Fmi n

NO

by Pr.01- 34

Y ES

F star t>Fmin

NO

fstart=F min

F low= 0

Y ES

H=Fc md
Hz
F cmd

Y ES

F min

fstart=F star t

F star t
Time

F low= 0

operation after
start-up
NO

NO

F cmd>Fl ow
NO
Y ES

by
Pr.01- 34

NO

Y ES

F cmdFmi n
NO

Y ES

Y ES

H =Fc md
Hz

H=Fc md

F star t
F min

Hz

Hz
60Hz

F cmd

H=Fl ow

F cmd1
F min
F cmd2
Time F low

60H z
H=Fc md1
F cmd1>Flow &
F cmd1>Fmin

H=Fl ow
F low> Fcmd1
>F min

F low
F cmd1
F min
F cmd2

Time
by Pr.01- 34
F min>Fc md2

Time
by Pr.01- 34
F cmd2>Flow &
F cmd2= Pr.02-33 (>= 02-33)
28: Output when current <=Pr.02-33 (<= 02-33)
29: Output when frequency >= Pr.02-34 (>= 02-34)
30: Output when frequency <= Pr.02-34 (<= 02-34)
31: Y-connection for the motor coil
32: △-connection for the motor coil
33: Zero speed (actual output frequency)
34: Zero speed include stop (actual output frequency)
35: Error output selection 1 (Pr.06-23)
36: Error output selection 2 (Pr.06-24)
37: Error output selection 3 (Pr.06-25)
38: Error output selection 4 (Pr.06-26)
39: Position attained (Pr.10-19)
40: Speed attained (including Stop)
41: Multi-position attained
42: Crane function
43: Actual motor speed slower than Pr.02-47
44: Low current output (Pr.06-71 to Pr.06-73)
45: UVW Output Electromagnetic valve On/Off Switch
46: Master dEb action output
12-02-13

Chapter 12 Description of Parameter SettingsC2000 Series

47: Closed brake output
48: Reserved
49: Homing action complete
50: Output for CANopen control
51: Output for communication card
52: Output for RS485
53~64: Reserved
65: Output for CANopen and RS485
66: SO contact A (N.O.)
67: Analog input signal level achieved
68: SO contact B (N.C.)
 This parameter is used for setting the function of multi-function terminals.
 Pr.02-36~Pr.02-41 requires additional extension cards to display the parameters, the choices of
optional cards are EMC-D42A and EMC-R6AA.
 The optional card EMC-D42A provides 2 output terminals and can be used with Pr.02-36~02-37.
 The optional card EMC-R6AA provides 6 output terminals and can be used with Pr.02-36~02-41.
 Summary of function settings (Take the normally open contact for example, ON: contact is closed,
OFF: contact is open)
Settings

Functions

0

No Function

1

Operation Indication
Master Frequency
Attained
Desired Frequency
Attained 1 (Pr.02-22)
Desired Frequency
Attained 2 (Pr.02-24)
Zero Speed (frequency
command)
Zero Speed with Stop
(frequency command)

2
3
4
5
6
7

Over Torque 1

8

Over Torque 2

9

Drive Ready

10

Low voltage warn (Lv)

11

Malfunction Indication

12

Mechanical Brake
Release (Pr.02-32)

13

Overheat

14

Software Brake Signal
Indication

Descriptions
Active when the drive is not at STOP.
Active when the AC motor drive reaches the output frequency
setting.
Active when the desired frequency (Pr.02-22) is attained.
Active when the desired frequency (Pr.02-24) is attained.
Active when frequency command =0. (the drive should be at RUN
mode)
Active when frequency command =0 or stop.
Active when detecting over-torque. Refer to Pr.06-07 (over-torque
detection level-OT1) and Pr.06-08 (over-torque detection
time-OT1). Refer to Pr.06-06~06-08.
Active when detecting over-torque. Refer to Pr.06-10 (over-torque
detection level-OT2) and Pr.06-11 (over-torque detection
time-OT2). Refer to Pr.06-09~06-11.
Active when the drive is ON and no abnormality detected.
Active when the DC Bus voltage is too low. (refer to Pr.06-00 low
voltage level)
Active when fault occurs (except Lv stop).
When drive runs after Pr.02-32, it will be ON. This function should
be used with DC brake and it is recommended to use contact “b”
(N.C).
Active when IGBT or heat sink overheats to prevent OH turn off
the drive. (refer to Pr.06-15)
Active when the soft brake function is ON. (refer to Pr.07-00)

12-02-14

Chapter 12 Description of Parameter SettingsC2000 Series

Settings

Functions

Descriptions

15

PID Feedback Error

Active when the feedback signal is abnormal.

16

Slip Error (oSL)
Terminal Count Value
Attained (Pr.02-20; not
return to 0)
Preliminary Counter
Value Attained
(Pr.02-19; returns to 0)
External Base Block
input (B.B.)
Warning Output

Active when the slip error is detected.

17
18
19
20
21
22
23
24
25
26
27
28
29
30
31

Active when the counter reaches Terminal Counter Value
(Pr.02-19). This contact won’t active when Pr.02-20>Pr.02-19.
Active when the counter reaches Preliminary Counter Value
(Pr.02-19).
Active when the output of the AC motor drive is shut off during
base block.
Active when the warning is detected.

Over-voltage Warning
Over-current Stall
Prevention Warning
Over-voltage Stall
prevention Warning
Operation Mode
Indication
Forward Command

Active when the over-voltage is detected.

Reverse Command
Output when Current >=
Pr.02-33
Output when Current <
Pr.02-33
Output when frequency
>= Pr.02-34
Output when Frequency
< Pr.02-34
Y-connection for the
Motor Coil

Active when the operation direction is reverse.

Active when the over-current stall prevention is detected.
Active when the over-voltage stall prevention is detected.
Active when the operation command is controlled by external
terminal. (Pr.00-21≠0)
Active when the operation direction is forward.
Active when current is >= Pr.02-33.
Active when current is < Pr.02-33
Active when frequency is >= Pr.02-34.
Active when frequency is  Pr.02-34 and
output current > Pr.02-33 and Time > Pr.02-32.
The example of the crane application is in the following for your
reference.
Active when motor actual speed is less than Pr.02-47.
This function needs to be used with Pr.06-71 ~ Pr.06-73
1. Under FOCPG control mode, set MI=49 (drive enable) and
MO=45 (electromagnetic contractor ON/OFF switch), then the
magnetic contactor will follow the drive status to be ON or OFF.
2. For brake control, set MO=12 (mechanical brake release),
Pr.02-31=T1 sec (mechanical brake delay time); then
enable/disable DC braking by set 07-01 (DC brake current) to any
level except 0 and set Pr.07-02 = T2 (DC brake time at start up)
and Pr.07-03 = T2 (DC brake current at stop). It is recommend to
set T2 >T1 and try to activate brake control during zero-speed
status.

En abl e
C onta cto r

AC Driver

MC

Motor

U(T1)

IM
3~

V(T2)
W(T3)

MOx=45
MIx=49

12-02-16

Chapter 12 Description of Parameter SettingsC2000 Series

Settings
46

Functions

Descriptions
When dEb arises at Master, MO will send a dEb signal to Slave. Then
Master dEb signal output Slave will follow Master’s command and decelerate to stop
simultaneously.
When drive stops, the corresponding multi-function terminal will
be ON if the frequency is less than Pr.02-34. After it is ON, it will
be OFF when brake delay time exceeds Pr.02-32.
Output Frequency

47

Output Frequency
< Pr.02-34

Brake Release at Stop

RUN

RUN

Multi-function
Output
MO=d47

02-32

48

Reserved

49

Homing Action Complete Output when homing action complete.

Time

Control multi-function output terminals through CANopen.
If to control RY2, then the Pr02-14 = 50.
The mapping table of the CANopen DO is below:
Setting of
physical
related
Attribute
Corresponding Index
terminal
parameters
RY1
P2-13 = 50
RW
The bit 0 at 2026-41

50

Output for CANopen
control

RY2

P2-14 = 50

RW

The bit 1 at 2026-41

MO1

P2-16 = 50

RW

The bit 2 at 2026-41

MO2

P2-17 = 50

RW

The bit 3 at 2026-41

P2-36 = 50

RW

P2-37 = 50

RW

RY12

P2-38 = 50

RW

The bit 8 at 2026-41

RY13

P2-39 = 50

RW

The bit 9 at 2026-41

RY14

P2-40 = 50

RW

The bit 10 at 2026-41

RY15

P2-41= 50

RW

The bit 0 at 2026-41

MO10
RY10
MO11
RY11

The bit 4 at 2026-41
The bit 5 at 2026-41
The bit 6 at 2026-41
The bit 7 at 2026-41

Refer to Chapter 15-3-5 for more information.

12-02-17

Chapter 12 Description of Parameter SettingsC2000 Series

Settings
51

Functions
Output for RS-485

Descriptions
For RS485 output.
For communication output of communication cards
(CMC-MOD01, CMC-EIP01, CMC-PN01 and CMC-DN01)
Setting of
Physical
Corresponding
related
Attribute
terminal
Address
parameters
RY1
P2-13 = 51
RW
The Bit 0 of 2640
RY2

52

Output for
communication card

P2-14 = 51

RW

The Bit 1 of 2640

P2-15 = 51

RW

The Bit 2 of 2640

MO1

P2-16 = 51

RW

The Bit 3 of 2640

MO2

P2-17 = 51

RW

The Bit 4 of 2640

MO3

P2-18 = 51

RW

The Bit 5 of 2640

MO4

P2-19 = 51

RW

The Bit 6 of 2640

MO5

P2-20 = 51

RW

The Bit 7 of 2640

MO6

P2-21 = 51

RW

The Bit 8 of 2640

MO7

P2-22 = 51

RW

The Bit 9 of 2640

MO8

P2-23 = 51

RW

The Bit 10 of 2640

53~64 Reserved
65

66

Output for CANopen and
To be control output of CANopen & RS485.
RS485
SO contact A (N.O.)

Status of drive
Normal
STO

Status of safety output
N.O. (MO=66)
N.C. (MO=68)
Broken circuit
Short circuit
(Open)
(Close)
Short circuit
Broken circuit
(Close)
(Open)
Short circuit
Broken circuit
(Close)
(Open)

68

SO contact B (N.C.)

67

Multi-function output terminals operate when analog input signal
level is between high level and low level.
03-44: Select the analog signal channel, AVI, ACI, and AUI which
is going to be compared.
Analog input signal level 03-45: The high level of analog input, factory setting is 50%.
achieved
03-46: The low level of analog input, factory setting is 10%.
If analog input > 03-45, then multi-function output terminal
operates.
If analog input < 03-46, then multi-function output terminal stops
outputting.

STL1~STL3

12-02-18

Chapter 12 Description of Parameter SettingsC2000 Series

Example: Crane Application
Out put
freque ncy

Outpu t freq uency>= Pr02-34
and out put current> =Pr02 -3 3

Multi-func tion ou tput
MO=4 2 (Ac tive whe n
Fcom>= Pr02-34, outp ut
cu rren t >P r02-33,
time>P r0 2-32)

Out put frequency< Pr02-58
or out put current = Pr0 2-33

Pr07-18
Dwe ll f requenc y
at decel.

Pr07-16
Dwell f requenc y
at acc el.
O utput frequen cy

Pr07-17
Dwell t ime
at decel.

P r0 7-15
Dwell time
at ac cel.

Multi-function ou tput
MO=4 2 (Ac tive whe n
Fcom>= Pr02-34, outp ut
cu rren t >P r02-33,
time>P r0 2-32)

Pr02-32
Brak e delay time

Pr02-32
Brak e delay time

Multi-function Output Setting



Factory Setting: 0000
Settings

0000h~FFFFh (0:N.O. ; 1:N.C.)

 The setting of this parameter is in hexadecimal.
 This parameter is set via bit setting. If a bit is 1, the corresponding multi-function output acts in the
opposite way.
Example:
If Pr02-13=1 and Pr02-18=0, Relay 1 is ON when the drive runs and is open when the drive is
stopped.
If Pr02-13=1 and Pr02-18=1, Relay 1 is open when the drive runs and is closed when the drive is
stopped.
Bit setting
bit15 bit14 bit13 bit12 bit11 bit10

bit9

bit8

bit7

bit6

bit5

bit4

bit3

bit2

bit1 bit0

MO20 MO19 MO18 MO17 MO16 MO15 MO14 MO13 MO12 MO11 MO10 MO2 MO1 Reserved RY2 RY1

12-02-19

Chapter 12 Description of Parameter SettingsC2000 Series



Terminal Counting Value Attained (return to 0)
Factory Setting: 0
Settings

0~65500

 The counter trigger can be set by the multi-function terminal MI6 (set Pr.02-06 to 23). Upon
completion of counting, the specified multi-function output terminal will be activated (Pr.02-13~02-14,
Pr.02-36, 02-37 is set to 18). Pr.02-19 can’t be set to 0.
 When the display shows c5555, the drive has counted 5,555 times. If display shows c5555, it
means that real counter value is between 55,550 to 55,559.


Preliminary Counting Value Attained (not return to 0)
Factory Setting: 0
Settings

0~65500

 When the counter value counts from 1 and reaches this value, the corresponding multi-function
output terminal will be activated, provided one of Pr. 02-13, 02-14, 02-36, 02-37 set to 17
(Preliminary Count Value Setting). This parameter can be used for the end of the counting to make
the drive runs from the low speed to stop.
1.0msec

Di spl ay va lu e
[00 -04 =0 1]
TRG [02-06=23]
Counter Trigger

1.0msec
Th e wi dth of tr ig ge r si gn al

( ou tpu t sig na l)
P re li min ar y Cou nte r V al ue
02 -20=3
RY 1 P r.0 2- 13 =17
02 -13, 02- 14, 0 2-3 6, 02 -37
Te rmi na l Co un ter Va lu e
RY 2 P r.0 2- 14 =18



02 -19=5
02 -14=1 7

Digital Output Gain（DFM）
Factory Setting: 1
Settings

1~166

 It is used to set the signal for the digital output terminals (DFM-DCM) and digital frequency output
(pulse X work period=50%). Output pulse per second = output frequency X Pr.02-21.


Desired Frequency Attained 1
Factory Setting: 60.00/50.00
Settings



0.00~600.00Hz

The Width of the Desired Frequency Attained 1
Factory Setting: 2.00
Settings



0.00~600.00Hz

Desired Frequency Attained 2
Factory Setting: 60.00/50.00
Settings



0.00~600.00Hz

The Width of the Desired Frequency Attained 2
Factory Setting: 2.00
Settings

0.00~600.00Hz
12-02-20

Chapter 12 Description of Parameter SettingsC2000 Series

 Once output frequency reaches desired frequency and the corresponding multi-function output
terminal is set to 3 or 4 (Pr.02-13, 02-14, 02-36, and 02-37), this multi-function output terminal will be
ON.
H
Fcmd=60Hz
02-24=40Hz
02-25=2Hz

42Hz
40Hz
38Hz

02-22=10Hz
02-23=2Hz

12Hz
10Hz
8Hz
T

02-13,02-14,
=3
02-36,02-37,
02-13,02-14,
02-36,02-37, =4

Brake Delay Time
Factory Setting: 0.000
Settings

0.000~65.000 sec

 When the AC motor drive runs after Pr.02-32 delay time, the corresponding multi-function output
terminal (12: mechanical brake release) will be ON. It has to use this function with DC brake.

A
frequ ency
comma nd
07 -0 2
DC b ra ke
time du ri ng
start-u p
Outp ut
freq uen cy

07 -0 3
DC b ra ke
time du ri ng
stopp ing

B=A

DC b ra ke

DC b ra ke

RUN

RUN/STOP

STOP

02 -3 2 brake de lay time
Multi -fu nctio n outp ut
(me ch an ical brake rele ase)
Pr.0 2-11 to 0 2-14=d1 2

Mechan ical b ra ke

b oun ce time of me ch ani cal brake
rele ase

braked

12-02-21

braked
Time

Chapter 12 Description of Parameter SettingsC2000 Series

 If this parameter is used without DC brake, it will be invalid. Refer to the following operation timing.

frequ ency
co mma nd

A

ze ro
sp eed

ze ro
sp eed

B=A
outp ut
frequ ency

RUN/STOP

RUN

STOP

relea se

brak e
Tim e

Mu lti-func tion output
(mec hani cal brake
relea se)
Pr.02-11 to 0 2-14=d12
me chan ical brak e



brake

Output Current Level Setting for Multi-function Output Terminals
Factory Setting: 0
Settings

0~100%

 When output current is higher or equal to Pr.02-33, it will activate multi-function output terminal
(Pr.02-13, 02-14, 02-16, and 02-17 is set to 27).
 When output current is lower or equal to Pr.02-33, it will activate multi-function output terminal
(Pr.02-13, 02-14, 02-16, and 02-17 is set to 28).


Output Boundary for Multi-function Output Terminals
Factory Setting: 3.00
Settings

0.00~600.00Hz

 When output frequency is higher or equal to Pr.02-34, it will activate the multi-function terminal
(Pr.02-13, 02-14, 02-16, 02-17 is set to 29).
 When output frequency is lower or equal to Pr.02-34, it will activate the multi-function terminal
(Pr.02-13, 02-14, 02-16, 02-17 is set to 30).


External Operation Control Selection after Reset and Activate
Factory Setting: 0
Settings

0: Disable
1: Drive runs if the run command still exists after reset or re-boots.

 Setting 1:
Status 1: After the drive is powered on and the external terminal for RUN keeps ON, the drive will run.
Status 2: After clearing fault once a fault is detected and the external terminal for RUN keeps ON,
the drive can run after pressing RESET key.

12-02-22

Chapter 12 Description of Parameter SettingsC2000 Series

Zero-speed Level of Motor



Factory Setting: 0
Settings

0~65535 rpm

 This parameter should be used with the multi-function output terminals (set to 43). It needs to be
used with PG cared and motor with encoder feedback.
 This parameter is used to set the level of motor zero-speed. When the actual speed is lower than
this setting, the corresponding multi-function output terminal 43 will be ON as shown as follows.

a ctua l mo tor
sp ee d
0 2- 47

MO =d 43

Ti me

Max. Frequency of Resolution Switch



Factory Setting: 60.00
Settings

0.00~600.00Hz

Switch the delay time of Max. output frequency



Factory Setting: 0.000
Settings

0.000~65.000 sec.

 It is used to improve the unstable speed or unstable position due to the insufficient of analog
resolution. It needs to be used with external terminal (set to 43). After setting this parameter, it needs
to adjust the analog output resolution of controller simultaneously by this setting.
AUI +10V
A UI 0V
AUI -10V

Accel./Decel. time
01-12~01-19
Max. out put frequency
01-00

Max. out put fre quency
01-00

Frequ ency
command
Out put
frequ ency
0Hz
Res olution
switch
MI =43

Delay time for max.
frequ ency switch
02-49

Resolution swit ch
f requency
0 2-4 8
ON

Forward ru nnin g

12-02-23

Re solution switch
frequency
Delay time for max .
02-48
f re quency swit ch
02-49
Reverse running

Chapter 12 Description of Parameter SettingsC2000 Series

Display the Status of Multi-function Input Terminal
Factory Setting: Read only
Weights
Bit

15

14

13

12

11

10

9

2 2 2 2 2 2 2 2
15 14 13 12 11 10 9 8

8

7

2
7

6

2 2
6 5

5

2
4

4

2
3

3

2
2

2

2
1

1

2
0

0

F WD
REV

0=O n
1=O ff

MI1
MI2
MI3
MI4
MI5
MI6
MI7
MI8
MI10
MI11
MI12

F or
option
car d

MI13
MI14
MI15

 For Example:
If Pr.02-50 displays 0034h (Hex), i.e. the value is 52, and 110100 (binary). It means MI1, MI3 and
MI4 are active.
Weights 2 5 2 4 2 3 2 2 2 1 2 0
Bit
1 1 0 1 0 0

MI1

0=O N
1=O FF

MI2
MI3

Settings
5
4
2
= bit5x 2 +bit4x2 +bit2x2

MI4
MI5

5

4

= 1x2 +1x2 + 1x2
=32+16+4 =52

2

NO TE
5

4

2 =322 =16
1

MI6

2 =2

12-02-24

3

0

2 =1

2 =8

2

2 =4

Chapter 12 Description of Parameter SettingsC2000 Series

Status of Multi-function Output Terminal
Factory Setting: Read only
 For Example:
If Pr.02-51 displays 000Bh (Hex), i.e. the value is 11, and 1011 (binary). It means RY1, RY2 and
MO1 are ON.
2 15 2 14 2

W eights
Bit

13

2

12

2

11

2

10

9

2

15 14 13 12 11 10 9

2 8 27

8

26

7

5
2

6

4

3

2

5

2

4

2

3

2

1

20 2

2

1

0

Relay 1
Relay 2
Reserved
MO1
MO2
MO10
MO11
MO12
MO13
MO14 For
MO15 option
MO16 card
MO17
MO18
MO19
MO20

0=ON
1=OFF

NOT E
7

2 =128
5

2 =32
2

2 =4

6

2 =64
4

3

1

0

2 = 16
2 =2

Display External Output terminal occupied by PLC
Factory Setting: Read only
 P.02-52 shows the external multi-function input terminal that used by PLC.
Weights
Bit

2 2 2 2 2 2
15 14 13 12 11 10
15

14

13

12

11

10

2 2
9 8
9

8

2
7

7

2 2
6 5
6

5

2
4

4

2 2
3 2
3

2

2
1

1

2
0

0

FWD
REV
MI1

0=ON
1=OFF

MI2
MI3
MI4
MI5
MI6
MI7
MI8
MI10
MI11
MI12
MI13
MI14
MI15

12-02-25

For option
card

2 =8
2 =1

Chapter 12 Description of Parameter SettingsC2000 Series

 For Example:
When Pr.02-52 displays 0034h(hex) and switching to 110100 (binary), it means MI1, MI3 and MI4
are used by PLC.
Weights
Bit

2 2 2 2
0 0 0 0
11

10

9

8

2
0

7

2 2 2
0 1 1
6

5

4

2 2
0 1
3

2

2
0

1

2
0

0: not used by P LC
1: used by PLC

0

MI1

Displays
5
4
2
= bit5x 2 +bit4x2 +bit2x2
5
4
2
= 1x2 +1x2 + 1x 2
=32+16+4 =52

MI2
MI3
MI4
MI5
MI6
MI7

NO TE

MI8
MI10

2 =20 48

14

13

12

2 =16 38 4 2 =81 92
11
8
5

10

2 =1 2 8
4

1

2 =2

2 =51 2
6

2 =64

3

2 =3 22 =16

MI12
MI13

9

2 =10 24
7

2 =2 56

MI11

2 =40 9 6

2 =8

2

2 =4

0

2 =1

Display Multi-function Output Terminal occupied by PLC
Factory Setting: Read only
 P.02-53 shows the external multi-function output terminal that used by PLC.
Weights
Bit

2

15

2

2

14

13

2

12

2

11

2

10

2

15 14 13 12 11 10 9

9

2

8

8

2

7

7

2

6

6

2

5

5

2

4

4

2

3

3

2

2

2

2

1

1

2

0

0

0=O N
1=O FF

R el ay 1
R el ay 2
R ese rve d
MO1
MO2
MO1 0
MO1 1
MO1 2
MO1 3
MO1 4
MO1 5
MO1 6
MO1 7
MO1 8
MO1 9
MO2 0

NO TE
7

2 =1 28
5

2 =3 2
2

2 =4

6

2 =6 4
2 =1 6
1

2 =2

3

2 =8
0

2 =1

12-02-26

Fo r o p tio n
card

Chapter 12 Description of Parameter SettingsC2000 Series

 For Example:
If the value of Pr.02-53 displays 0003h (Hex), it means RY1and RY2 are used by PLC.

Weights
Bit

2 7 2 6 2 5 2 4 2 3 2 2 21 2 0
0 0 0 0 0 0 1 1

0=NOT used by P LC
1=Used by PLC

R el ay 1
R el ay 2
R ese rve d
MO1
MO2
MO3
MO4
MO5

D isp la y va lu e
3 =2+1
=1x2 1 +1x2 0
=bi t 1x2 1 +b i t 0 x20

Display the Frequency Command Executed by External Terminal
Factory Setting: Read only
Settings

Read only

 When the source of frequency command comes from the external terminal, if Lv or Fault occurs at
this time, the frequency command of the external terminal will be saved in this parameter.
Reserved
Release Brake Check
Factory Setting: 0.000
Settings

0.000~65.000 sec.

 The parameter needs to be used with MI=55. This is to be set for the time difference of

mechanical brake delay time and actual brake operation.
FWD ru n
comma nd

Out put
frequ ency

MO= 63

Ou tput frequency> =Pr02 -3 4
and output curren t>= Pr0233

Pr02-32, brake delay time

Mechanical d ela y time

MI= 55

No checking signal when
brake-release che ckin g time
is reach ed.

P r02-56, brake-release ch ecking time

12-02-27

Chapter 12 Description of Parameter SettingsC2000 Series



Multi-function output terminal: Function 42: Brake Current Checking Point
Factory setting: 0
Settings



0~150%

Multi-function output terminal: Function 42: Brake Frequency Checking Point

Factory setting: 0.00
Settings

0.00~655.35Hz

 Pr02-32, Pr02-33, Pr02-34, Pr02-57 and Pr02-58 can be applied on setting up cranes. (Choose
crane action #42 to set up multi-function output Pr02-13, Pr02-14, Pr02-16, and Pr02-17)
 When output current of a drive is higher than the setting of Pr02-33 Pivot Point of the Current
(>=02-33) and when output frequency is higher than the setting of Pr02-34 Pivot Point of the
Frequency (>= 02-34), choose #42 to set up Multi-function output Pr02-13, Pr02-14, Pr02-16 and
Pr002-17 after the delay time set at Pr02-32.
 When the Pivot Point of the Current 's setting 02-57≠0 and when the output current of the drive is
lower than the setting of Pr02-57 (<02-57), or when the output frequency is lower than the setting of
Pr02-58 (<02-58), the disable the setting #42 of the multi-function output Pr02-13, Pr02-14,
Pr02-16, Pr02-17
 When Pr02-57 = 0, the output current is lower than setting of Pr02-33 Pivot Point of the current
(<02-33) or when output frequency is lower than the setting of Pr02-58(<02-58), disable the setting
of #42 of the multi-function output Pr02-13, Pr02-14, Pr02-16, Pr02-17.

IO Card Type
Factory setting: Read only
Settings

Read only

0: No IO Card
1: EMC-BPS01 Card
2: No IO Card
3: No IO Card
4: EMC-D611A Card
5: EMC-D42A Card
6: EMC-R6AA Card
7: No IO Card

12-02-28

Chapter 12 Description of Parameter SettingsC2000 Series

03 Analog Input/Output Parameter


 This parameter can be set during operation.

Analog Input Selection (AVI)
Factory Setting: 1



Analog Input Selection (ACI)
Factory Setting: 0



Analog Input Selection (AUI)
Factory Setting: 0
Settings
0: No function
1: Frequency command (speed limit under torque control mode)
2: Torque command (torque limit under speed mode)
3: Torque offset command
4: PID target value
5: PID feedback signal
6: PTC thermistor input value
7: Positive torque limit
8: Negative torque limit
9: Regenerative torque limit
10: Positive/negative torque limit
11: PT100 thermistor input value
12: Reserved
13: PID compensation value
14~20: Reserved
 When use analog input as PID reference value, Pr00-20 must set 2(analog input).
Setting method 1: Pr03-00~03-02 set 1 as PID reference input
Setting method 2: Pr03-00~03-02 set 4 as PID reference input
If the setting value 1 and set value 4 existed at the same time, AVI input has highest priority to
become PID reference input.
 When use analog input as PID compensation value, Pr08-16 must set 1(Source of PID
compensation is analog input). The compensation value can be observed via Pr08-17.
 When it is frequency command or TQC speed limit, the corresponding value for 0~±10V/4~20mA is
0 – max. output frequency(Pr.01-00)
 When it is torque command or torque limit, the corresponding value for 0~±10V/4~20mA is 0 – max.
output torque (Pr.11-27).
 When it is torque compensation, the corresponding value for 0~±10V/4~20mA is 0 – rated torque.

12-03-1

Chapter 12 Description of Parameter SettingsC2000 Series
Positive torque
03-00~02=7
Positive torque limit

03-00~02=9
Regenerative
torque limit
03-00~02=10
Positive/negative torque limit

Reverse

Forward

03-00~02=10
Positive/negative torque limit

03-00~02=8
Negative torque limit

03-00~02=9
Regenerative
torque limit

Negative Torque

 When Pr.03-00~Pr.03-02 have the same setting, then the AVI will be the prioritized selection.


Analog Input Bias (AVI)
Factory Setting: 0
Settings

-100.0~100.0%

 It is used to set the corresponding AVI voltage of the external analog input 0.


Analog Input Bias (ACI)
Factory Setting: 0
Settings

-100.0~100.0%

 It is used to set the corresponding ACI voltage of the external analog input 0.


Analog Voltage Input Bias (AUI)
Factory Setting: 0
Settings

-100.0~100.0%

 It is used to set the corresponding AUI voltage of the external analog input 0.
 The relation between external input voltage/current and setting frequency: 0~10V (4-20mA)
corresponds to 0~Pr01-00 (max. operation frequency).


Reserved



Positive/negative Bias Mode (AVI)



Positive/negative Bias Mode (ACI)



Positive/negative Bias Mode (AUI)
Factory Setting: 0
Settings

0: Zero bias
1: Lower than or equal to bias
2: Greater than or equal toe

bias

3: The absolute value of the bias voltage while serving as the center
4: Serve bias as the center
12-03-2

Chapter 12 Description of Parameter SettingsC2000 Series

 In a noisy environment, it is advantageous to use negative bias to provide a noise margin. It is
recommended NOT to use less than 1V to set the operation frequency.
In the diagram below: Black line: Curve with no bias. Gray line: curve with bias
Frequency

Pr.03-03=10%

60Hz

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

54Hz

-V

10 9 8 7 6 5 4 3 2 1

V

1 2 3 4 5 6 7 8 9 10

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI)= 100%

Pr.03-03=10%

Frequency

Pr.03-07~03-09 (Positive/Negative Bias Mode)

60Hz

0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11Analog Input Gain (AVI)=100%

Pr.03-03=10%

Frequency

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz
54Hz

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 100%

12-03-3

Chapter 12 Description of Parameter SettingsC2000 Series
Pr.03-03=10%

Frequency

Pr.03-07~03-09 (Positive/Negative Bias Mode)

60Hz

0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

54Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 100%

Pr.03-03=10%

F requency

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz
54Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI)= 100%

Pr.03-03=10%

F requency

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11Analog Input Gain (AVI)= 100%

12-03-4

Chapter 12 Description of Parameter SettingsC2000 Series
F requency

Pr.03-03=10%

60Hz

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

54Hz

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 100%

Pr.03-03=10%

F requency

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz
54Hz

-V

-6Hz

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 100%

F requency

Pr.03-03=-10%

60Hz

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI)= 100%

12-03-5

Chapter 12 Description of Parameter SettingsC2000 Series

-V

F requency

Pr.03-03=-10%

60Hz

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI)= 100%

F requency

Pr.03-03=-10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 100%

Pr.03-03=-10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

F requency
60Hz

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 100%

12-03-6

Chapter 12 Description of Parameter SettingsC2000 Series
F requency

Pr.03-03=-10%

60Hz

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI)= 100%

-V

F requency

Pr.03-03=-10%

60Hz

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI)= 100%

F requency

Pr.03-03=-10%

60Hz

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 100%

12-03-7

Chapter 12 Description of Parameter SettingsC2000 Series
F requency

Pr.03-03=-10%

60Hz

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

6Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 100%

F requency

Pr.03-03=-10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI)= 1 11.1%
10/9=111.1%

F requency

Pr.03-03=10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11Analog Input Gain (AVI)=111.1%
10/9 =111.1%

12-03-8

Chapter 12 Description of Parameter SettingsC2000 Series
F requency

Pr.03-03=10%

60Hz

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

6.66Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 111.1%
10/9 =111.1%

F requency

Pr.03-03=10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.03-11 Analog Input Gain (AVI) = 111.1%
10/9 =111.1%

Pr.03-03=10%

F requency

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr03-11 Analog Input Gain (AVI) = 111.1%
10/9 =111.1%

12-03-9

Chapter 12 Description of Parameter SettingsC2000 Series
Pr.03-03=10%

F requency

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

6.66Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr03-11Analog Input Gain (AVI) = 111.1%
10/9 =111.1%

F requency

Pr.03-03=10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

6.66Hz

-V

10 9 8 7 6 5 4 3 2 1

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr03-11 Analog Input Gain (AVI) = 111.1%
10/9 =111.1%

F requency

Pr.03-03=10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

-V
-6.66Hz

1 2 3 4 5 6 7 8 9 10

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr03-11 Analog Input Gain (AVI) = 100%
10/9 =111.1%

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Chapter 12 Description of Parameter SettingsC2000 Series

12-03-11

Chapter 12 Description of Parameter SettingsC2000 Series

12-03-12

Chapter 12 Description of Parameter SettingsC2000 Series

Pr.00-21=0 (Dgital keypad control and d run in F WD direction)
Pr.03-05 Analog Positive Voltage Input Bias (AUI) = 10%

F requency

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz
54Hz

-V

10 9 8 7 6 5 4 3 2 1
1 2 3 4 5 6 7 8 9 10

60Hz

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.00-13 Analog Positive Input Gain (AUI)= 100%
Pr.03-14 Analog Negative Input Gain (AUI)= 100%

12-03-13

Chapter 12 Description of Parameter SettingsC2000 Series
Pr.00-21=0 (Dgital keypad control and d run in F WD direction)
Pr.03-05 Analog Positive Voltage Input Bias (AUI) = 10%

F requency

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

-V

10 9 8 7 6 5 4 3 2 1
1 2 3 4 5 6 7 8 9 10

V

60Hz

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.00-13 Analog Positive Input Gain (AUI)= 100%
Pr.03-14 Analog Negative Input Gain (AUI)= 100%

Pr.00-21=0 (Dgital keypad control and d run in F WD direction)
Pr.03-05 Analog Positive Voltage Input Bias (AUI) = 10%

F requency

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz
54Hz

-V

10 9 8 7 6 5 4 3 2 1
1 2 3 4 5 6 7 8 9 10

V

60Hz

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.00-13 Analog Positive Input Gain (AUI)= 100%
Pr.03-14 Analog Negative Input Gain (AUI)= 100%

Pr.00-21=0 (Dgital keypad control and d run in F WD direction)
Pr.03-05 Analog Positive Voltage Input Bias (AUI) = 10%

F requency
60Hz
54Hz

-V

10 9 8 7 6 5 4 3 2 1
1 2 3 4 5 6 7 8 9 10

60Hz

V

Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center
Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.00-13 Analog Positive Input Gain (AUI)= 100%
Pr.03-14 Analog Negative Input Gain (AUI)= 100%

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Chapter 12 Description of Parameter SettingsC2000 Series

12-03-15

Chapter 12 Description of Parameter SettingsC2000 Series

Pr.00-21=0 (Digital keypad control and run in F WD direction )
Pr.03-05 Analog Positive Voltage Input Bias (AUI) = 10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

F requency
60Hz

-V

10 9 8 7 6 5 4 3 2 1
1 2 3 4 5 6 7 8 9 10

V

60Hz

Pr.00-13 Analog Positive Input Gain (AUI)= 111.1%
(10/9) *100% = 111.1%
Pr.00-14 Analog Negative Input Gain (AUI) = 100%

Pr.00-21=0 (Digital keypad control and run in F WD direction )

F requency

Pr.03-05 Analog Positive Voltage Input Bias (AUI) = 10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

60Hz

-V

10 9 8 7 6 5 4 3 2 1
1 2 3 4 5 6 7 8 9 10

60Hz

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.00-13 Analog Positive Input Gain (AUI)= 111.1%
(10/9) *100% = 111.1%
Pr.00-14 Analog Negative Input Gain (AUI) = 100%

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Chapter 12 Description of Parameter SettingsC2000 Series
Pr.00-21=0 (Digital keypad control and run in F WD direction )
Pr.03-05 Analog Positive Voltage Input Bias (AUI) = 10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

F requency
60Hz

-V

10 9 8 7 6 5 4 3 2 1
1 2 3 4 5 6 7 8 9 10

V

60Hz

Pr.00-13 Analog Positive Input Gain (AUI)= 111.1%
(10/9) *100% = 111.1%
Pr.00-14 Analog Negative Input Gain (AUI) = 100%

Pr.00-21=0 (Digital keypad control and run in F WD direction )
Pr.03-05 Analog Positive Voltage Input Bias (AUI) = 10%
Pr.03-07~03-09 (Positive/Negative Bias Mode)
0: No bias
1: Lower than or equal to bias
2: Greater than or equal to bias
3: T he absolute value of the bias voltage
while serving as the center
4: Serve bias as the center

F requency
60Hz

-V

10 9 8 7 6 5 4 3 2 1
1 2 3 4 5 6 7 8 9 10

60Hz

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.

V

Pr.03-10 (Analog F requency Command for Reverse Run)
0: Negative frequency is not valid.
F orward and reverse run is controlled
by digital keypad or external terminal.
1: Neagtive frequency is valid. Positive
frequency = forward run; negative
frequency = reverse run. Direction
can not be switched by digital keypad or
external teriminal control.
Pr.00-13 Analog Positive Input Gain (AUI)= 111.1%
(10/9) *100% = 111.1%
Pr.00-14 Analog Negative Input Gain (AUI) = 100%

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Chapter 12 Description of Parameter SettingsC2000 Series

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Chapter 12 Description of Parameter SettingsC2000 Series



Analog Frequency Command for Reverse Run
Factory Setting: 0
Settings 0: Negative frequency is not valid. Forward and reverse run is controlled by
digital keypad or external terminal.
1: Negative frequency is valid. Positive frequency = forward run; negative
frequency = reverse run. Run direction can not be switched by digital
keypad or the external terminal control.
 Parameter 03-10 is used to enable reverse run command when a negative frequency (negative
bias and gain) is input to AVI or ACI analog signal input (except AUI).
 Condition for negative frequency (reverse)
1. Pr03-10=1
2. Bias mode=Serve bias as center
3. Corresponded analog input gain < 0(negative), make input frequency be negative.
 In using addition function of analog input (Pr03-18=1), when analog signal is negative after adding,
this parameter can be set for allowing reverse or not. The result after adding will be restricted by
“Condition for negative frequency (reverse)”



Analog Input Gain (AVI)



Analog Input Gain (ACI)



Analog Positive Input Gain (AUI)



Analog Negative Input Gain (AUI)
Factory Setting: 100.0
Settings

-500.0~500.0%

 Parameters 03-03 to 03-14 are used when the source of frequency command is the analog
voltage/current signal.


Analog Input Filter Time (AVI)



Analog Input Filter Time (ACI)



Analog Input Filter Time (AUI)
Factory Setting: 0.01
Settings

0.00~20.00 sec

 These input delays can be used to filter noisy analog signal.
 When the setting of the time constant is too large, the control will be stable but the control response
will be slow. When the setting of time constant is too small, the control response will be faster but
the control may be unstable. To find the optimal setting, please adjust the setting according to the
control stable or response status.

12-03-19

Chapter 12 Description of Parameter SettingsC2000 Series



Addition Function of the Analog Input
Factory Setting: 0
Settings

0: Disable (AVI, ACI, AUI)
1: Enable

 When Pr03-18 is set to 1:
EX1: Pr03-00=Pr03-01=1

Frequency command= AVI+ACI

EX2: Pr03-00=Pr03-01=Pr03-02=1

Frequency command = AVI+ACI+AVI2

EX3: Pr03-00=Pr03-02=1

Frequency command = AVI+AVI2

EX4: Pr03-01=Pr03-02=1

Frequency command = ACI+AVI2

 When Pr.03-18 is set to 0 and the analog input setting is the same, the priority for AVI, ACI and AUI
are AVI>ACI>AUI.
Frequency

Voltage



Fmax( 01- 00)
Fcommand=[(ay bias)*gain]*
10V or 16mA or 20mA
Fcommand: the cor responding
frequency for 10V or 20mA
ay : 0-10V, 4-20mA, 0-20mA
bias : Pr .03-03,Pr. 03-04, Pr.03-05
gain : Pr.03-11, Pr.03-12, Pr.03-13, Pr.03-14

Treatment to 4-20mA Analog Input Signal Loss
Factory Setting: 0
Settings

0: Disable
1: Continue operation at the last frequency
2: Decelerate to stop
3: Stop immediately and display ACE

 This parameter determines the behavior when 4~20mA signal is loss, when AVIc(Pr.03-28=2) or
ACIc (03-29=0).
 When Pr.03-28 is not set to 2, it means the voltage input to AVI terminal is 0-10V or 0-20mA. At this
moment, Pr.03-19 will be invalid.
 When Pr.03-29 is set to 1, it means the voltage input to ACI terminal is for 0-10V. At this moment,
Pr.03-19 will be invalid.
 When setting is 1 or 2, it will display warning code “AnL” on the keypad. It will be blinking until the
loss of the ACI signal is recovered.
 When the motor drive stops, the condition of warning does not exist, then the warning will
disappear.

12-03-20

Chapter 12 Description of Parameter SettingsC2000 Series

Multi-function Output 1 (AFM1)



Factory Setting: 0
Multi-function Output 2 (AFM2)



Factory Setting: 0
Settings

0~25

Function Chart
Settings Functions

Descriptions

0

Output frequency (Hz)

Max. frequency Pr.01-00 is regarded as 100%.

1

Frequency command (Hz)

Max. frequency Pr.01-00 is regarded as 100%.

2

Motor speed (Hz)

600Hz is regarded as 100%

3

Output current (rms)

(2.5 X rated current) is regarded as 100%

4

Output voltage

(2 X rated voltage) is regarded as 100%

5

DC Bus Voltage

450V (900V)=100%

6

Power factor

-1.000~1.000=100%

7

Power

Rated power is regarded as 100%

8

Output torque

Full-load torque is regarded as 100%

9

AVI

0~10V=0~100%

10

ACI

0~20mA=0~100%

11

AUI

-10~10V=0~100%

12

q-axis current (Iq)

(2.5 X rated current) is regarded as 100%

13

q-axis

(2.5 X rated current) is regarded as 100%

14

d-axis current (Id)

(2.5 X rated current) is regarded as 100%

15

d-axis

(2.5 X rated current) is regarded as 100%

16

q-axis voltage (Vq)

250V (500V) =100%

17

d-axis voltage(Vd)

250V (500V) =100%

18

Torque command

Rated torque is regarded as 100%

19

PG2 frequency command

Max. frequency Pr.01-00 is regarded as 100%.

20

Output for CANopen control

21

RS485 analog output

For CANopen analog output
For communication output (CMC-MOD01, CMC-EIP01,
CMC-PN01, CMC-DN01)

22

feedback value (Iq)
feedback value (Id)

Analog output for
communication card

For communication output (CMC-MOD01, CMC-EIP01,
CMC-PN01, CMC-DN01)
Pr.03-32 and Pr.03-33 controls voltage/current output

23
24

Constant voltage/current output level
0~100% of Pr.03-32 corresponds to 0~10V of AFM1.
Reserve

25

CAN & 485 output

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Chapter 12 Description of Parameter SettingsC2000 Series

Gain of Analog Output 1 (AFM1)



Factory Setting: 100.0
Gain of Analog Output 2 (AFM2)



Factory Setting: 100.0
Settings

0~500.0%

 It is used to adjust the analog voltage level (Pr.03-20) that terminal AFM outputs.
 This parameter is set the corresponding voltage of the analog output 0.
Analog Output 1 when in REV Direction (AFM1)



Factory Setting: 0
Analog Output 2 when in REV Direction (AFM2)



Factory Setting: 0
Settings

0: Absolute value in REV direction
1: Output 0V in REV direction; output 0-10V in FWD direction
2: Output 5-0V in REV direction; output 5-10V in FWD direction
10V( 20mA)

0V
( 0mA)

10V( 20mA)

03-18
03-21
03-24

F requenc y
0V
( 0mA)

03-22=1
03-25=1

03-22=0
03-25=0

10V( 20mA)

F requenc y
5V
( 12mA)

03-22=2
03-25=2

Selections for the analog output dir ec ti on

Reserve
AFM2 Output Bias



Factory Setting: 0.00
Settings

-100.00~100.00%

 Example 1, AFM2 0-10V is set output frequency, the output equation is

10V  (

Output Frequency
)  03 - 24  10V  03 - 27
01 - 00

 Example 2, AFM2 0-20mA is set output frequency, the output equation is

20mA  (

Output Frequency
)  03 - 24  20mA  03 - 27
01 - 00

 Example 3, AFM2 4-20mA is set output frequency, the output equation is

4mA  16mA  (

Output Frequency
)  03 - 24  16mA  03 - 27
01 - 00

 This parameter can set the corresponded voltage of 0 for analog output.

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Chapter 12 Description of Parameter SettingsC2000 Series



AVI Selection
Factory Setting: 0
Settings

0: 0-10V
1: 0-20mA
2: 4-20mA



ACI Selection
Factory Setting: 0
Settings

0: 4-20mA
1: 0-10V
2: 0-20mA

 When changing the input mode, please check if the switch of external terminal (SW3, SW4)
corresponds to the setting of Pr.03-28~03-29.
Status of PLC Output Terminal
Factory Setting: ##
Settings

0~65535
Monitor the status of PLC analog output terminals

 P.03-30 shows the external multi-function output terminal that used by PLC.

Weights
Bit

2

2

15

14

2

13

2

12

2

11

2

2

10

15 14 13 12 11 10

2

9

2

8

8

9

7

7

2
6

6

2

5

2

4

4

5

2
3

3

2
2

2

2
1

1

2

0

0

0=O N
1=O FF

AFM 1
AFM 2

NO TE
7

2 =1 28

6

2 =3 2

2 =6 4
4
2 =1 6

2 =8

2 =4

2 =2

2 =1

5
2

3

1

0

 For Example:
If the value of Pr.03-30 displays 0002h(Hex), it means AFM1and AFM2 are used by PLC.
0 =N ot used by PLC
1 =U sed b y PLC
Weight s

B it

2
0

7

2
0

6

2
0

5

2
0

4

2
0

3

2
0

2

D is p la y v a lu e
1
0
2 =1x 2 + 0 x 2
1
0
= bi t 1x 2 +bi t 0 x 2



2
1

1

2
0

0

A FM 1
A FM 2

AFM2 0-20mA Output Selection
Factory Setting: 0
Settings

0: 0-20mA output
1: 4-20mA output

12-03-23

Chapter 12 Description of Parameter SettingsC2000 Series



AFM1 DC output setting level



AFM2 DC Output Setting Level
Factory Setting: 0.00
Settings

0.00~100.00%

Reserve


AFM1 Filter Output Time
AFM2 Filter Output Time



Settings
~



Factory Setting: 0.01

0.00~20.00 Seconds

Reserve
MO by AI level
Factory Setting: 0
Settings

0: AVI
1: ACI
2: AUI



AI Upper level
Factory Setting: 50%
Settings



-100%~100%

AI Lower level
Factory Setting: 50%
Settings

-100%~100%

 This function requires working with Multi-function Output item “67” Analog signal level achieved.
The MO active when AI input level is higher than Pr03-45 AI Upper level. The MO shutoffs when
the AI input is lower that Pr03-46 AI Lower level.
 AI Upper level must be higher than AI Lower level

~


Reserve
Analog Input Curve Selection
Factory Setting: 0
Settings

0: Regular Curve
1: 3 point curve of AVI
2: 3 point curve of ACI
3: 3 point curve of AVI & ACI
4: 3 point curve of AUI
5: 3 point curve of AVI & AUI
6: 3 point curve of ACI & AUI
7: 3 point curve of AVI & ACI & AUI
12-03-24

Chapter 12 Description of Parameter SettingsC2000 Series



AVI Low Point
Factory Setting: 0.00
Settings

03-28=0, 0.00~10.00V
03-28≠0, 0.00~20.00mA



AVI Proportional Low Point
Factory Setting: 0.00
Settings



0.00~100.00%

AVI Mid Point
Factory Setting: 5.00
Settings

03-28=0, 0.00~10.00V
03-28≠0, 0.00~20.00mA



AVI Proportional Mid Point
Factory Setting: 50.00
Settings



0.00~100.00%

AVI High Point
Factory Setting: 10.00
Settings

03-28=0, 0.00~10.00V
03-28≠0, 0.00~20.00mA



AVI Proportional High Point
Factory Setting: 100.00
Settings

0.00~100.00%

 When Pr.03-28 = 0, AVI setting is 0-10V and the unit is in voltage (V).
 When Pr.03-28 ≠ 0, AVI setting is 0-20mA or 4-20mA and the unit is in current (mA).
 When setting analog input AVI to frequency command, it 100% corresponds to Fmax (Pr.01-00
Max. operation frequency).
 The 3 parameters (Pr03-51, Pr03-53 and Pr03-53) must meet the following argument: P03-51 <
P03-53 < P03-55. The 3 proportional points (Pr03-52, Pr03-54 and Pr03-56) doesn’t have any limit.
Between two points is a linear calculation. The ACI and AUI are same as AVI.
 The output % will become 0% when the AVI input value is lower than low point setting.
For example:
P03-51 = 1V; P03-52 = 10%. The output will become 0% when AVI input is lower than 1V. If the AVI
input is swing between 1V and 1.1V, drive’s output frequency will beats between 0% and 10%


ACI Low Point
Factory Setting: 4.00
Settings

Pr.03-29=1, 0.00~10.00V
Pr.03-29≠1, 0.00~20.00mA



ACI Proportional Low Point
Factory Setting: 0.00
Settings

0.00~100.00%

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Chapter 12 Description of Parameter SettingsC2000 Series



ACI Mid Point
Factory Setting: 12.00
Settings

03-29=1, 0.00~10.00V
03-29≠1, 0.00~20.00mA



ACI Proportional Mid Point
Factory Setting: 50.00
Settings



0.00~100.00%

ACI High Point
Factory Setting: 20.00
Settings

03-29=1, 0.00~10.00V
03-29≠1, 0.00~20.00mA



ACI Proportional High Point
Factory Setting: 100.00
Settings

0.00~100.00%

 When Pr.03-29=1, ACI setting is 0-10V and the unit is in voltage (V).
 When Pr.03-29≠1, ACI setting is 0-20mA or 4-20mA and the unit is in current (mA).
 When setting analog input ACI to frequency command, it 100% corresponds to Fmax (Pr.01-00
Max. operation frequency).
 The 3 parameters (Pr03-57, Pr03-59 and Pr03-61) must meet the following argument: P03-57 <
P03-59 < P03-61. The 3 proportional points (Pr03-58, Pr03-60 and Pr03-62) doesn’t have any limit.
Between two points is a linear calculation.
 The output % will become 0% when the ACI input value is lower than low point setting.
For example:
P03-57 = 2mA; P03-58 = 10%. The output will become 0% when AVI input is lower than 2mA. If
the ACI input is swing between 2mA and 2.1mA, drive’s output frequency will beats between 0%
and 10%.


Positive AUI Voltage Low Point
Factory Setting: 0.00
Settings



0.00~10.00V

Positive AUI Voltage Proportional Low Point
Factory Setting: 0.00
Settings



-100.00%~100.00%

Positive AUI Voltage Mid Point
Factory Setting: 5.00
Settings



0.00~10.00V

Positive AUI Voltage Proportional Mid Point
Factory Setting: 50.00
Settings

-100.00%~100.00%

12-03-26

Chapter 12 Description of Parameter SettingsC2000 Series

Positive AUI Voltage High Point



Factory Setting: 10.00
Settings

0.00~10.00V

Positive AUI Voltage Proportional High Point



Factory Setting: 100.00
Settings

-100.00%~100.00%

 When setting positive voltage AUI to frequency command, it 100% corresponds to Fmax (Pr.01-00
Max. operation frequency) and the motor runs in forward direction.
 Three of the positive voltage AUI points can be set according to user’s demand on voltage and
proportion, there is no setting limit for AUI points.
Negative AUI Voltage Low Point



Factory Setting: 0.00
Settings

0.00~-10.00V

Negative AUI Voltage Proportional Low Point



Factory Setting: 0.00
Settings

-100.00~100.00%

Negative AUI Voltage Mid Point



Factory Setting: -5.00
Settings

0.00~-10.00V

Negative AUI Voltage Proportional Mid Point



Factory Setting: -50.00
Settings

-100.00~100.00%

Negative AUI Voltage High Point



Factory Setting: -10.00
Settings

0.00~-10.00V

Negative AUI Voltage Proportional High Point



Factory Setting: -100.00
Settings

-100.00~100.00%

 When setting negative voltage AUI to frequency command, it 100% corresponds to Fmax (Pr.01-00
Max. operation frequency) and the motor runs in reverse direction.
 Three of the negative voltage AUI points can be set according to user’s demand on voltage and
proportion, there is no setting limit for AUI points.

 The 3 parameters (Pr03-69, Pr03-71 and Pr03-73) must meet the following argument: P03-69 <
P03-71 < P03-73. The 3 proportional points (Pr03-70, Pr03-72 and Pr03-74) doesn’t have any limit.
Between two points is a linear calculation.
 The output % will become 0% when the negative AUI input value is lower than low point setting.
For example:
P03-63=-1V; P03-64 = 10%. The output will become 0% when AUI input is bigger than -1V. If the
AUI input is swing between -1V and -1.1V, drive’s output frequency will beats between 0% and
10%.
12-03-27

Chapter 12 Description of Parameter SettingsC2000 Series

04 Multi-Step Speed Parameters


1st Step Speed Frequency



2nd Step Speed Frequency



3rd Step Speed Frequency



4th Step Speed Frequency



5th Step Speed Frequency



6th Step Speed Frequency



7th Step Speed Frequency



8th Step Speed Frequency



9th Step Speed Frequency



10th Step Speed Frequency



11th Step Speed Frequency



12th Step Speed Frequency



13th Step Speed Frequency



14th Step Speed Frequency



15th Step Speed Frequency

 This parameter can be set during operation.

Factory Setting: 0.00
Settings

0.00~600.00Hz

 The Multi-function Input Terminals (refer to setting 1~4 of Pr.02-01~02-08 and 02-26~02-31) are
used to select one of the AC motor drive Multi-step speeds(max. 15 speeds). The speeds
(frequencies) are determined by Pr.04-00 to 04-14 as shown in the following.
 The run/stop command can be controlled by the external terminal/digital keypad/communication via
Pr.00-21.
 Each one of multi-step speeds can be set within 0.00~600.00Hz during operation.
 Explanation for the timing diagram for multi-step speeds and external terminals
The Related parameter settings are:
1. Pr.04-00~04-14: setting multi-step speeds (to set the frequency of each step speed)
2. Pr.02-01~02-08, 02-26~02-31: setting multi-function input terminals (multi-step speed 1~4)


Related parameters: 01-22 JOG Frequency, 02-01 Multi-function Input Command 1 (MI1),
02-02 Multi-function Input Command 2 (MI2), 02-03 Multi-function Input Command 3 (MI3),
02-04 Multi-function Input Command 4 (MI4)

12-04-1

Chapter 12 Description of Parameter SettingsC2000 Series
04-07

F requenc y

04-06

04-08

04-05
04-09
04-04
04-10
04-03
04-11
04-02
04-12

J OG Freq.

04-01
04-13
04-00

01-22

04-14

Master Spee d

1

Mul ti -functi on
terminals
MI1~MI4
02-0 1~02-08

Run/ Sto p
PU/ ext ernal t erminals
/c ommu nicat ion

3

4

5

6

7

8

9

10 11 12 13 14 15

ON

1st spee d

OFF ON

2nd sp eed

OFF

3rd spe ed

OFF

4t h speed

OFF

J og Freq.

2

ON

ON

ON

ON
ON

ON

ON

ON

ON

ON
ON

ON

ON

ON

OFF

ON
Mu lt i- speed via Ext ernal Termin als



Position command 1 (pulse)



Position command 2 (pulse)



Position command 3 (pulse)



Position command 4 (pulse)



Position command 5 (pulse)



Position command 6 (pulse)



Position command 7 (pulse)



Position command 8 (pulse)



Position command 9 (pulse)



Position command 10 (pulse)



Position command 11 (pulse)



Position command 12 (pulse)



Position command 13 (pulse)



Position command 14 (pulse)



Position command 15 (pulse)

Factory Setting: 0
Settings

-32767~32767

 Please refer to Pr.02-01~02-08 (Multi-function Input Command) for description on setting 34
(Switch between multi-step position and multi-speed control) and setting 36 (Enable multi-step
position learning function).

12-04-2

Chapter 12 Description of Parameter SettingsC2000 Series

Multi-step position corresponding MI4

MI3

MI2

MI1

Multi-step speed corresponding

10-19

0

0

0

0

Positioning for Encoder Position

04-16 Position command 1 (pulse)

0

0

0

1

04-00 1st step speed frequency

04-18 Position command 2 (pulse)

0

0

1

0

04-01 2nd step speed frequency

04-20 Position command 3 (pulse)

0

0

1

1

04-02 3rd step speed frequency

04-22 Position command 4 (pulse)

0

1

0

0

04-03 4th step speed frequency

04-24 Position command 5 (pulse)

0

1

0

1

04-04 5th step speed frequency

04-26 Position command 6 (pulse)

0

1

1

0

04-05 6th step speed frequency

04-28 Position command 7 (pulse)

0

1

1

1

04-06 7th step speed frequency

04-30 Position command 8 (pulse)

1

0

0

0

04-07 8th step speed frequency

04-32 Position command 9 (pulse)

1

0

0

1

04-08 9th step speed frequency

04-34 Position command 10 (pulse)

1

0

1

0

04-09 10th step speed frequency

04-36 Position command 11 (pulse)

1

0

1

1

04-10 11th step speed frequency

04-38 Position command 12 (pulse)

1

1

0

0

04-11 12th step speed frequency

04-40 Position command 13 (pulse)

1

1

0

1

04-12 13th step speed frequency

04-42 Position command 14 (pulse)

1

1

1

0

04-13 14th step speed frequency

04-44 Position command 15 (pulse)

1

1

1

1

04-14 15th step speed frequency



Position command 1 (rotation)



Position command 2 (rotation)



Position command 3 (rotation)



Position command 4 (rotation)



Position command 5 (rotation)



Position command 6 (rotation)



Position command 7 (rotation)



Position command 8 (rotation)



Position command 9 (rotation)



Position command 10 (rotation)



Position command 11 (rotation)



Position command 12 (rotation)



Position command 13 (rotation)



Position command 14 (rotation)



Position command 15 (rotation)
 To switch the target position of the external terminal, set multi-function input command, Pr.02-01=1,
Pr.02-02=2, Pr.02-03=3, Pr.02-04= 4 by selecting the P2P target position via multi-step speed.
Setting: Target Position = 04-15 × (10-01*4) + 04-16

12-04-3

Chapter 12 Description of Parameter SettingsC2000 Series

Multi-step
Speed Status
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111

Target Position of P2P
Position 1
Position 2
Position 3
Position 4
Position 5
Position 6
Position 7
Position 8
Position 9
Position 10
Position 11
Position 12
Position 13
Position 14
Position 15



PLC Buffer 0



PLC Buffer 1



PLC Buffer 2



PLC Buffer 3



PLC Buffer 4



PLC Buffer 5



PLC Buffer 6



PLC Buffer 7



PLC Buffer 8



PLC Buffer 9



PLC Buffer 10



PLC Buffer 11



PLC Buffer 12



PLC Buffer 13



PLC Buffer 14



PLC Buffer 15



PLC Buffer 16



PLC Buffer 17



PLC Buffer 18



PLC Buffer 19

0
04-15
04-17
04-19
04-21
04-23
04-25
04-27
04-29
04-31
04-33
04-35
04-37
04-39
04-41
04-43

04-16
04-18
04-20
04-22
04-24
04-26
04-28
04-30
04-32
04-34
04-36
04-38
04-40
04-42
04-44

Maximum Speed of P2P
11-00 bit8=0
11-43

11-43

11-00 bit8=1
04-00
04-01
04-02
04-03
04-04
04-05
04-06
04-07
04-08
04-09
04-10
04-11
04-12
04-13
04-14

Factory Setting: 0
Settings

0~65535

 The Pr 04-50~Pr04-69 can be combined with PLC or HMI programming for variety application.

12-04-4

Chapter 12 Description of Parameter SettingsC2000 Series

05 Motor Parameters

 This parameter can be set during operation.

Motor Auto Tuning
Factory Setting: 0
Settings

0: No function
1: Rolling test for induction motor(IM) (Rs, Rr, Lm, Lx, no-load current)
[motor running]
2: Static test for induction motor [motor not running]
3: No function
4: Dynamic test for PM motor magnetic pole [motor running]
5: Dynamic test for PM (SPM) motor [motor running]
6: Rolling test for IM motor flux curve [motor running]
12: FOC Sensorless inertia estimation [motor running]
13: Static test for PM(IPM) motor

Induction Motor
 This parameter can conduct motor parameters auto test. When setting as 1, motor will roll for more
than one round; setting as 4, 5, 6, and 12, motor will roll less than one round.
 Press 【Run】to begin auto tuning when the setting is done. The measured value will be written into
motor 1 (Pr.05-05 ~05-09, Rs, Rr, Lm, Lx, no-load current) and motor 2 (Pr.05-17 to Pr.05-21)
automatically.
To begin AUTO-Tuning in rolling test:
1. Make sure that all the parameters are set to factory settings (Pr00-02=9 or 10) and the motor
wiring is correct.
2. Make sure the motor has no-load before executing auto-tuning and the shaft is not connected
to any belt or gear motor. It is recommended to set to 2 if the motor can’t separate from the
load.
3. Please set motor related parameters according to motor nameplate.

4.
5.

Motor 1 Parameter

Motor 2 Parameter

Motor Rated Frequency

01-01

01-35

Motor Rated Voltage

01-02

01-36

Motor Full-load Current

05-01

05-13

Motor Rated Power

05-02

05-14

Motor Rated Speed

05-03

05-15

Motor Pole Numbers

05-04

05-16

Set Pr.05-00=1 and press【Run】, the drive will begin auto-tuning. Please be aware of the
motor that it starts spinning as【Run】 is pressed.
When auto-tuning is completed, please check if the measured values are written into motor 1
(Pr.05-05 ~05-09) and motor 2 (Pr.05-17 ~05-21) automatically.

12-05-1

Chapter 12 Description of Parameter SettingsC2000 Series

6.

Mechanical equivalent circuit

I

VS

Rs
P r.0 5- 06
P r.0 5- 18

Lx
P r.0 5- 09
P r.0 5- 21

Lm

P r.0 5- 08
P r.0 5- 20

Rr

P r.0 5- 07
P r.0 5- 19

※ If Pr.05-00 is set to 2 (static test), user needs to input the no-load current value of motor
into

Pr.05-05 for motor 1/Pr.05-17 for motor 2.

 Set Pr.05-00=6 to begin rolling test for IM motor flux curve. This function is available
when the drive is in FOC/TQC Sensorless control. User may begin auto-tuning after
setting up the motor information.


Set up Pr.01-01, 01-02, 05-01~05-04 according to the motor nameplate information。



Set Pr.05-00=6 and press【Run】, make sure no loading is applied to the motor
before setting Pr.05-00 to 6 and before performing auto-tuning.

 When Pr.05-00=12, the drive begins FOC Sensorless inertia estimation for IM motor. This
function is available when the drive is in FOC/TQC Sensorless control. User may begin
auto-tuning after setting up the motor information.


Note: Make sure the motor parameters (no-load current, Rs, Rr, Lm and Lx) of the
drive are set before performing Pr.05-00=12 (auto-tuningfor FOC Sensorless interia
estimation for IM motor).

1. Set Pr.00-10=2 (torque mode)
2. Set Pr. 00-13=2 (TQCPG, Open-loop torque mode)
3. Set Pr. 05-00=12 and press【Run】to begin FOC Sensorless inertia measure
4. When the process of inertia estimation is completed, check Pr.11-01 (unit: PU Q8) and
see if the measured value is acceptable.
Set up Sensorless FOC Mode
1. Set Pr.00-10 = 0 (speed mode)
2. Set Pr.00-11 = 5 (FOC sensorless mode)
3. Set bit0 of Pr.11-00 to 1 (use ASR gain function to automatically adjust the ASR
bandwidth in Pr.11-03,11-04,11-05)
NOTE


In torque/vector control mode, it is not recommended to have motors run in parallel.



It is not recommended to use torque/vector control mode if motor rated power exceeds
the rated power of the AC motor drive.



When auto-tuning 2 motors, it needs to set multi-function input terminals (setting 14) or
change Pr.05-22 for motor 1/motor 2 selection.



The no-load current is usually 20~50% X rated current.



The rated speed can not be greater than or equal to 120f/p (f = rated frequency
Pr.01-01/01-35; P: number of motor poles Pr.05-04/05-16).
12-05-2

Chapter 12 Description of Parameter SettingsC2000 Series

Permanent Magnet Motor (PM)


Set Pr.05-00= 5 or 13 and press 【Run】 to begin auto tuning for PM motor. The
measured values will be written into Pr.05-39（Rs）, Pr.05-40 & 41（Ld & Lq） and
Pr.05-43（PM motor’s Ke parameter）.

To begin AUTO-Tuning for PM motor in rolling test:
1.

Make sure all the parameters are reset to factory setting and the motor wiring installation is
correct.

2.

For PM motor, set Pr.05-33=1 for SPM or Pr.05-33=2 for IPM

and complete the following

settings according to your motor specifications, Pr.05-34 rated current, Pr.05-35 rated power,
Pr.05-36 rated speed and Pr. 05-37 pole number. The acceleration time and deceleration
time should be set according to your motor capacity.
3.

Set Pr.05-00 to 5 and press 【Run】 to begin auto tuning for PM motor. Please be aware of
the motor that it starts spinning as【Run】 is pressed.

4.

When auto-tuning is completed, please check if the measured values are written into
Pr.05-39~05-41 and Pr.05-43 automatically.
 Set Pr.05-00=4 and press【Run】to begin auto-tuning for PM motor PG offset angle. The
measured value will be written into Pr.05-42 automatically.


Note 1: When execute auto-tuning for PM motor PG origin, please make sure the
encoder setting are correct (Pr.10-00, 10-01, 10-02), otherwise the PG origin measure
error and motor stall may occur.



Note 2: If PM motor runs in an opposite direction of the drive’s command, switch any
two of the UVW cable and re-connect, then execute PG origin search again. It is crucial
to execute auto-tuning after the switch otherwise PG origin measure error and motor
stall may occur.

 Auto-tuning process for measuring PG offset angle of PM motor:
1.

Set Pr.05-00=5 and press RUN, or manually input the values into Pr. 01-01, 05-34~-541 and
Pr.05-43.

2.

It is strongly suggested to remove the motor and unload before beings auto-tuning.

3.

Set Pr.05-00=4 and press【Run】 to begin auto-tuning. Please be aware of the motor that it
starts spinning as 【Run】is pressed.

4.

When auto-tuning is completed, please check if the PG offset angle is written into Pr.05-42
automatically.
NOTE

When auto-tuning for PM motor is completed and the control mode setting is done, it is
recommend to turn the drive’s power off and restart again to ensure the drive operates according
to the motor parameter settings.

12-05-3

Chapter 12 Description of Parameter SettingsC2000 Series

Full-load Current of Induction Motor 1（A）
Unit: Amper
Factory Setting: #.##
Settings

10 to 120% of drive’s rated current

 This value should be set according to the rated current of the motor as indicated on the motor
nameplate. The factory setting is 90% X rated current.
Example: The rated current for 7.5HP (5.5kW) is 25 and factory setting is 22.5A. The range for
setting will be 10~30A.(25*40%=10A and 25*120%=30A)


Rated Power of Induction Motor 1(kW)
Factory Setting: #.##
Settings

0~655.35 kW

 It is used to set rated power of the motor 1. The factory setting is the power of the drive.


Rated Speed of Induction Motor 1 (rpm)
Factory Setting:
1710（60Hz 4 poles）
1410（50Hz 4 poles）
Settings

0~65535

 It is used to set the rated speed of the motor according to the motor nameplate.
 Before set up Pr05-04, this parameter must be set.
Pole Number of Induction Motor 1
Factory Setting: 4
Settings

2~20

 It is used to set the number of motor poles (must be an even number).
 Set up Pr.05-04 after setting up Pr. 01-01 and Pr.05-03 to make sure motor operate normally.
 For example: the Pr05-04 factory setting range is “2~4”. If use a 6 poles motor, to set up Pr01-01
and Pr05-03 according the motor nameplate, then the Pr05-04 setting range will become 2~6
automatically.
No-load Current of Induction Motor 1 (A)
Unit: Amper
Factory Setting: #.##
Settings

0 to the factory setting in Pr.05-01

 The factory setting is 40% motor rated current.
 For model with 110kW and above, default setting is 20% motor rated current.
Stator Resistance(Rs) of Induction Motor 1
Rotor Resistance(Rr) of Induction Motor 1
Factory Setting: #.###
Settings

0~65.535Ω

12-05-4

Chapter 12 Description of Parameter SettingsC2000 Series

Magnetizing Inductance(Lm) of Induction Motor 1
Stator inductance(Lx) of Induction Motor 1
Factory Setting: #.#
Settings
~

0~6553.5mH

Reserved
Full-load Current of Induction Motor 2（A）
Unit: Amper
Factory Setting:#.##
Settings

10~120%

 This value should be set according to the rated frequency of the motor as indicated on the motor
nameplate. The factory setting is 90% X rated current.
Example: The rated current for 7.5HP (5.5kW) is 25A and factory setting is 22.5A. The range for
setting will be 10~30A.(25*40%=10A and 25*120%=30A)


Rated Power of Induction Motor 2 (kW)
Factory Setting: #.##
Settings

0~655.35 kW

 It is used to set rated power of the motor 2. The factory setting is the power of the drive.


Rated Speed of Induction Motor 2 (rpm)
Factory Setting: 1710
Settings

0~65535

 It is used to set the rated speed of the motor according to the motor nameplate.
Pole Number of Induction Motor 2
Factory Setting: 4
Settings

2~20

 It is used to set the number of motor poles (must be an even number).
 Set up Pr.05-04 after setting up Pr. 01-35 and Pr.05-05 to make sure motor operate normally.
No-load Current of Induction Motor 2 (A)
Unit: Amper
Factory Setting: #.##
Settings

0 to the factory setting in Pr.05-13

 The factory setting is 40% motor rated current.
 For model with 110kW and above, default setting is 20% motor rated current.
Stator Resistance (Rs) of Induction Motor 2
Rotor Resistance (Rr) of Induction Motor 2
Factory Setting: #.###
Settings

0~65.535Ω
12-05-5

Chapter 12 Description of Parameter SettingsC2000 Series

Magnetizing Inductance (Lm) of Induction Motor 2
Stator Inductance (Lx) of Induction Motor 2
Factory Setting: #.#
Settings

0~6553.5 mH

Induction Motor 1/ 2 Selection
Factory Setting: 1
Settings

1: Motor 1
2: Motor 2

 It is used to set the motor that driven by the AC motor drive.



Frequency for Y-connection/△-connection Switch of Induction Motor
Factory Setting: 60.00
Settings

0.00~600.00Hz

Y-connection/△-connection Switch of Induction Motor IM
Factory Setting: 0
Settings

0: Disable
1: Enable



Delay Time for Y-connection/△-connection Switch of Induction Motor
Factory Setting: 0.200
Settings

0.000~60.000 sec

 P.05-23 and Pr.05-25 are applied in the wide range motors and the motor coil will execute the
switch of Y-connection/-connection as required. (The wide range motors has relation with the
motor design. In general, it has higher torque at low speed and Y-connection and it has higher
speed at high speed and connection.
 Pr.05-24 is used to enable/disable Y-connection/-connection Switch.
 When Pr.05-24 is set to 1, the drive will select by Pr.05-23 setting and current motor frequency to
switch motor to Y-connection or -connection. At the same time, it will also affect motor
parameters.
 Pr.05-25 is used to set the switch delay time of Y-connection/-connection.
 When output frequency reaches Y-connection/-connection switch frequency, drive will delay by
Pr.05-25 before multi-function output terminals are active.
-con necti on is fin ishe d
Pr.02-01 ~08 =30

U
MI1

V
W

Y-connec tion is finis hed
Pr.02-01 ~08 =29

MI2

RA
MRA

-con necti on c ontrol
Pr.02-13 ~14 =32

W

V

IM

Y-c onnec tion con tro l
Pr.02-11~14=31
X

Y

Yconnection switch: can be used for wide range motor
Y -connection for low speed: higher torque can be used for rigid tapping
-con necti on fo r high spe ed: h igher torque can be u sed for hig h-spee d dril ling

12-05-6

U

Z

Chapter 12 Description of Parameter SettingsC2000 Series
I f swit ch point is 60Hz,
t he accel. switc h point is 62 Hz .
Dec el. switc h po int is 58Hz.
P r05-23
Y- △switc h frequ ency
Mo tor speed/
frequency
Y-c onnec tion out put
Y-c onnection
co nfirmation inp ut

B andwid th is 2Hz.
Motor s peed will
decrea se by load in ert ia.

In this area , moto r is in free run
st atus . AC motor d riv e stops
output ting.
P r05-25 delay time for
Y-conn ect ion /△-c onnec tion swit ch
ON

Pr02-13~ Pr02-14=31

ON

ON

Pr02-01~ Pr02-08=29

ON

△-conn ect ion outpu t
Pr02-13~ Pr02-14= 32

ON

△-conne ction confirmation
in put Pr0 2-01~Pr02-08 =30

ON
: mec hanica l bounc e time

f ree run status

output
frequency
Y-c onnect ion output
Pr. 02-13~14=31
Y-c onnection
confir mation input
Pr.02-01~08=29
△-connec ti on output
Pr.02-13~14=32
△-connection
confir mation input
Pr.02-01~08=30
Y-△ s witch err or
frequency

ON
ON
ON

ON

delay ti me
Pr.05-25

2 seconds

Accumulative Watt Per Second of Motor in Low Word (W-sec)
Factory Setting: 0.0
Settings

Read only

Accumulative Watt Per Second of Motor in High Word (W-sec)
Factory Setting: 0.0
Settings

Read only

Accumulative Watt-hour of Motor (W-Hour)
Factory Setting: 0.0
Settings

Read only

Accumulative Watt-hour of Motor in Low Word (KW-Hour)
Factory Setting: 0.0
Settings

Read only
12-05-7

Chapter 12 Description of Parameter SettingsC2000 Series

Accumulative Watt-hour of Motor in High Word (KW-Hour)
Factory Setting: 0.0
Settings

Read only

 Pr.05-26~05-29 records the amount of power consumed by motors. The accumulation begins
when the drive is activated and record is saved when the drive stops or turns OFF. The amount of
consumed watts will continue to accumulate when the drive activate again. To clear the
accumulation, set Pr.00-02 to 5 then the accumulation record will return to 0.
Accumulative Motor Operation Time (Min)
Factory Setting: 0
Settings

00~1439

Accumulative Motor Operation Time (day)
Factory Setting: 0
Settings

00~65535

 Pr. 05-31 and Pr.05-32 are used to record the motor operation time. To clear the operation time, set
Pr.05-31 and Pr.05-32 to 00. Operation time shorter than 60 seconds will not be recorded.
Induction Motor (IM) and Permanent Magnet Motor Selection
Factory Setting: 0
Settings

0: Induction Motor
1: Permanent Magnet Motor (SPM)
2: Permanent Magnet Motor (IPM)

Full-load current of Permanent Magnet Motor
Factory Setting: #.##
Settings

0.00~655.35 Amps

 Set this parameter in accord to motor’s nameplate. Default setting is 90% motor drive rated current.
For example: 7.5HP（5.5kW） rated current is 25A, then Pr05-34 default is 22.5A
Setting range will be 10~30A (25*10%=2.5A 25*120%=30A)



Rated Power of Permanent Magnet Motor
Factory Setting: 0.00
Settings

0.00~655.35 kW

 Set motor rated power in accord to motor nameplate. Default setting is motor drive rated power.



Rated speed of Permanent Magnet Motor
Factory Setting: 2000
Settings

0~65535 rpm

Pole number of Permanent Magnet Motor
Factory Setting: 10
Settings

0~65535

Inertia of Permanent Magnet Motor
Factory Setting: 0.0
Settings

0.0~6553.5 kg.cm2 (0.0001kg.m2)

12-05-8

Chapter 12 Description of Parameter SettingsC2000 Series

 Default value will follow the chart
Rated Power
0.4
0.75
(kW)
Rotor inertia
1.2
3.0
(kg.cm2)
Rated Power
(kW)
Rotor inertia
(kg.cm2)
Rated Power
(kW)
Rotor inertia
(kg.cm2)

1.5

2.2

3.7

5.5

7.5

9.3

6.6

15.8

25.7

49.6

82.0

121.6

11

14.1

18.2

27

33

40

46

54

177.0

211.0

265.0

308.0

527.0

866.0

1082.0

1267.6

Above
54
1515.0

Stator Resistance of PM Motor
Factory Setting: 0.000
Settings

0.000~65.535

Permanent Magnet Motor Ld
Factory Setting: 0.00
Settings

0.00~655.35 mH

Permanent Magnet Motor Lq
Factory Setting: 0.00
Settings



0.00~655.35 mH

PG Offset angle of PM Motor
Factory Setting: 0
Settings

0.0~360.0°

 When Pr.05-00 is set to 4, the drive will detect offset angle and write into Pr.05-42.



Ke parameter of PM Motor
Unit: V/1000rpm
Factory Setting: 0
Settings

0~65535

12-05-9

Chapter 12 Description of Parameter SettingsC2000 Series

06 Protection Parameters


 This parameter can be set during operation.

Low Voltage Level
Factory Setting:
Settings 230V Series:
Frame A ~D(including D0): 150.0~ 220.0 Vdc

180.0

Frame E and above: 190.0~220.0V

200.0

Frame A ~D(including D0):
460V Series: 300.0~440.0V

360.0

Frame E and above: 380.0~440.0V

400.0

 This parameter is used to set the Low Voltage level. When the DC BUS voltage is lower than
Pr06-00, drive will stop output and free to stop.
 If the drive is triggered LV fault during the operation, drive will stop output and free to stop. There
are three LV faults, LvA (LV during acceleration), LvD (LV during deceleration), and LvN (LV in
constant speed) which will be triggered in different stage of drive operation. These faults need to be
reset manually to restart the drive, while setting restart after momentary power off function (Pr07-06,
Pr07-07), the drive will restart automatically.
 If LV is triggered when the drive is in stop status, the fault is named LvS (LV during stop), which will
not be recorded, and the drive will restart automatically when input voltage is 30Vdc (230V series)
or 60Vdc (460V series) higher than LV level.
input voltage
30V(60V)
Pr. 06-00

LV



Over-voltage Stall Prevention
Factory Setting: 380.0/760.0
Settings

230V Series: 0.0~450.0V
460V Series:0.0~900.0V
0: Disabled

 When Pr.06-01 is set to 0.0, the over-voltage stall prevention function is disabled. When braking
units or resistors are connected to the drive, this setting is suggested.
 When the setting is not 0.0, the over-voltage stall prevention is activated. This setting should refer
to power supply system and loading. If the setting is too low, then over-voltage stall prevention will
be easily activate, which may increase deceleration time.
 Related parameters: Pr01-13, Pr01-15, Pr01-17, Pr01-19 Decel. Time 1~4, Pr02-13~Pr02-14
Multiple-function output (Relay 1 and 2), Pr02-16~Pr02-17 Multiple-function output (MO1,2), and
Pr06-02 selection for over-voltage stall prevention.
12-06-1

Chapter 12 Description of Parameter SettingsC2000 Series

Selection for Over-voltage Stall Prevention
Factory Setting: 0
Settings

0: Traditional over-voltage stall prevention
1: Smart over-voltage prevention

 This function is used for the occasion that the load inertia is unsure. When it stops in the normal
load, the over-voltage won’t occur during deceleration and fulfill the setting of deceleration time.
Sometimes, it may not stop due to over-voltage during decelerating to stop when increasing the
load regenerative inertia. At this moment, the AC drive will auto add the deceleration time until
drive stop.
 Pr 06-02 is set to 0: During deceleration, the DC bus voltage may exceed its maximum allowable
value due to motor regeneration in some situation, such as loading inertia is too high or Decel.
Time is set too short. When traditional over-voltage stall prevention is enabled, the drive will not
decelerate further and keep the output frequency constant until the voltage drops below the setting
value again.
 When Pr 06-02 is set to 1, the drive will maintain DCbus voltage when decelerating and prevent OV.
High-voltage
at DC si de
Ov er-v ol tage
detec ti on
level

Time
Output
frequency
F requenc y Held

Deceleration c har acteristic
when Ov er-Voltage Stall
Pr ev ention enabled
Time
previous deceleration time
requir ed time for decelerating to 0Hz when over- voltage
stall prevention is enabled.

60Hz

Output Frequency
DCBUS Voltage
370Vdc
310Vdc

0

230V Series
12-06-2

Time

Chapter 12 Description of Parameter SettingsC2000 Series

 When the over-voltage stall prevention is enabled, drive deceleration time will be larger than the
setting.
 When there is any problem as using deceleration time, refer to the following items to solve it.
1. Add the suitable deceleration time.
2. Add brake resistor (refer to Chapter 7-1 for details) to dissipate the electrical energy that
regenerated from the motor as heat type.
 Related parameters: Pr01-13, Pr01-15, Pr01-17, Pr01-19 Decel. Time 1~4, Pr02-13~Pr02-14
Multiple-function output (Relay 1 and 2), Pr02-16~Pr02-17 Multiple-function output (MO1,2), and
Pr06-01 over-voltage stall prevention.
Over-current Stall Prevention during Acceleration



Settings

Normal duty: 0~160% (100%: drive’s rated current)

Factory Setting: 120

Heavy duty: 0~180% (100%: drive’s rated current)

Factory Setting: 150

 This parameter only works in VF, VFPG, and SVC control mode.
 If the motor load is too large or drive acceleration time is too short, the AC drive output current may
increase abruptly during acceleration and it may cause motor damage or trigger protection
functions (OL or OC). This parameter is used to prevent this situation.
 During acceleration, the AC drive output current may increase abruptly and exceed the value
specified by Pr.06-03 due to rapid acceleration or excessive load on the motor. When this function
is enabled, the AC drive will stop accelerating and keep the output frequency constant until the
current drops below the maximum value.
 When the over-current stall prevention is enabled, drive acceleration time will be larger than the
setting.
 When the Over-Current Stall Prevention occurs due to too small motor capacity or in the factory
setting, please decrease Pr.06-03 setting.
 When there is any problem by using acceleration time, refer to the following items to solve it.
 Related parameters: Pr.01-12, 01-14, 01-16, 01-18 (settings of accel. time 1~4), Pr.01-44
1. dd the suitable acceleration time.
2. Setting Pr.01-44 Optimal Acceleration/Deceleration Setting to 1, 3 or 4 (auto accel.)
 Optimal Acceleration/Deceleration Setting, Pr.02-13~02-14 (Multi-function Output 1 RY1, RY2), Pr.
02-16~02-17 Multi-function Output (MO1, 2)
Output current
06-03

Setting frequency

Over-Current
Detection
Level

Output frequency
Over-Current Stall p revention during
Acceleration,frequ ency held
Time
Original setting of acceleration time
actual acceleratio n time when over-current stall
prevention is ena bled

12-06-3

Chapter 12 Description of Parameter SettingsC2000 Series



Over-current Stall Prevention during Operation
Settings

Normal duty: 0~160% (100%: drive’s rated current)

Factory Setting: 120

Heavy duty: 0~180% (100%: drive’s rated current)

Factory Setting: 150

 This parameter only works in VF, VFPG, and SVC control mode.
 It is a protection for drive to auto decrease output frequency when the motor is over-load abruptly
during motor constant operation.
 If the output current exceeds the setting specified in Pr.06-04 when the drive is operating, the drive
will decrease its output frequency (according to Pr.06-05) to prevent the motor stall. If the output
current is lower than the setting specified in Pr.06-04, the drive will accelerate (according to
Pr.06-05) again to catch up with the set frequency command value.
Ov er-Curr ent
Detec tion Level
06-04

Current

Pr . 06-04 s etting

Ov er-Curr ent Stall P revention
during Operation, output
frequency dec reases
Decreases by
deceleration time

over- curr ent stall pr eventi on during oper ation



Pr . 06-04 s ettingrated dr ive c urrent X 5%

Output
F requenc y

T ime

Accel./Decel. Time Selection of Stall Prevention at Constant Speed
Factory Setting: 0
Settings

0: by current accel/decel time
1: by the 1st accel/decel time
2: by the 2nd accel/decel time
3: by the 3rd accel/decel time
4: by the 4th accel/decel time
5: by auto accel/decel

 It is used to set the accel./decel. time selection when stall prevention occurs at constant speed.


Over-torque Detection Selection (OT1)
Factory Setting: 0
Settings

0: No function
1: Continue operation after Over-torque detection during constant speed
operation
2: Stop after Over-torque detection during constant speed operation
3: Continue operation after Over-torque detection during RUN
4: Stop after Over-torque detection during RUN

12-06-4

Chapter 12 Description of Parameter SettingsC2000 Series

Over-torque Detection Selection (OT2)



Factory Setting: 0
Settings

0: No function
1: Continue operation after Over-torque detection during constant speed
operation
2: Stop after Over-torque detection during constant speed operation
3: Continue operation after Over-torque detection during RUN
4: Stop after Over-torque detection during RUN

 When Pr.06-06 and Pr.06-09 are set to 1 or 3, it will display a warning message and won’t have an
abnormal record.
 When Pr.06-06 and Pr.06-09 are set to 2 or 4, it will display a warning message and will have an
abnormal record.
Over-torque Detection Level (OT1)



Factory Setting: 120
Settings

10 to 250% (100%: drive’s rated current)

Over-torque Detection Level (OT1)



Factory Setting: 0.1
Settings

0.0~60.0 sec

Over-torque Detection Level (OT2)



Factory Setting: 120
Settings

10 to 250% (100%: drive’s rated current)

Over-torque Detection Time (OT2)



Factory Setting: 0.1
Settings

0.0~60.0 sec

 When the output current exceeds the over-torque detection level (Pr06-07 or Pr06-10) and also
exceeds Pr06-08 or Pr06-11, the over torque detection will follow the setting of Pr06-06 and
Pr06-09.

 When Pr06-06 or Pr06-09 is set to 1 or 3, the motor drive will have the ot1/ot2 warning after Over
Torque Detection, while the motor drive will keep running. The warning will be off only until the
output current is smaller than the 5% of the over-torque detection level (Pr06-07 and Pr06-10).

Out put current
Ov er-t orque
det ect ion level
06- 07( 0 6- 10 )
0 6- 07( 0 6- 10) * 9 5%

Multi-fu nct ion output
terminal=7 or 8

ON

Ov er-t orque
detec tion time
06-08(06-11)

12-06-5

ON

Chapter 12 Description of Parameter SettingsC2000 Series

 When Pr06-06 or Pr06-09 is set to 2 or 4, the motor drive will have the ot1/ot2 fault after Over
Torque Detection. Then the motor drive stop running until it is manually reset.

Ove r-t orque det ect ion leve l
06-07 (06-10)

Out put current
Manually reset

ON

Multi-fu nct ion outpu t
terminal=7 or 8

O ver-torqu e dete ction time
06-08 (06-11)

Current Limit



Factory Setting: 170
Settings

0~250% (100%: drive’s rated current)

 Pr.06-12 sets the maximum output current of the drive. Pr.06-12 and Pr.11-17 ~ Pr.11-20 are used
to set the drive’s output current limit. When the drive is in VF, SVC or VFPG control mode, output
frequency will decreases as the output current reaches current limit. It acts as current stall
prevention.


Electronic Thermal Relay Selection (Motor 1)



Electronic Thermal Relay Selection (Motor 2)
Factory Setting: 2
Settings

0: Special motor (with external forced cooling)
1: Self-cooled motor (so motor with fan on the shaft)
2: Disable

 It is used to prevent self-cooled motor overheats under low speed. User can use electronic thermal
relay to limit driver’s output power.
 Setting as 0 is suitable for special motor (motor fan using independent power supply). For this kind
of motor, the cooling capacity is not related to motor speed obviously. So the action of electronic
thermal relay will remain stable in low speed, which can ensure the motor’s load capability in low
speed.
 Setting as 1 is suitable for standard motor (motor fan is fixed on the rotor shaft). For this kind of
motor, the cooling capacity is low in low speed, and the action of electronic thermal relay will
reduce the action time, which ensure the life of motor.
 When the power ON/OFF is often switched, even setting as 0 or 1 can bot protect the motor well. It
is because when the power is switched off, the electronic thermal relay protection will be reset. If
there are several motors connected to one motor drive, please install electronic thermal relay in
each motor respectively.
12-06-6

Chapter 12 Description of Parameter SettingsC2000 Series



Electronic Thermal Characteristic for Motor 1



Electronic Thermal Characteristic for Motor 2
Factory Setting: 60.0
Settings

30.0~600.0 sec

 The parameter is set by the 150% of motor rated current and the setting of Pr.06-14 and Pr.06-28 to
prevent the motor damaged from overheating. When it reaches the setting, it will display
“EoL1/EoL2” and the motor will be in free running.
 This parameter is to set the action time of electronic thermal relay. It works based on the I2t
characteristic curve of electronic thermal relay, output frequency and current of motor drive, and
operation time to prevent motor from over-heat.
Motor rated
current %

Motor rated
current %

1 00

10 0

80

80

60

60

40

40
20

20
25

75

50

10 0

125

1 50

Motor rated
frequenc y %

25

50

75

10 0

125

1 50

Motor rated
frequenc y %

Mot or coo ling curv e wit h indepen dent fan

Motor c ooling curve with shaf t-fixed fan

 The action of electronic thermal relay depends on the setting of Pr06-13/Pr06-27.
1. 06-13 or 06-27 is set 0 (using special motor)：
When output current of motor drive is higher than 150% of motor current (refer to motor cooling
curve with independent fan), motor drive will start to count the time. When the accumulated
time exceeds Pr06-14 or 06-28, electronic thermal relay will act.
2. 06-13 or 06-27 is set 0 (using standard motor)：
When output current of motor drive is higher than 150% of motor current (refer to motor cooling
curve with shaft-fixed fan), motor drive will start to count the time. When the accumulated time
exceeds Pr06-14 or 06-28, electronic thermal relay will act.
The real electronic thermal relay action time will adjust with drive output current (shown as
motor loading rate). When the current is high, the action time is short; when the current is high,
the action time is short. Please refer to following chart:
Op eratio n time
(se c.)
6 00
5 50
5 00
4 50
4 00

F= 50Hz
F= 40Hz
F= 20Hz

3 50
30 0
2 50
2 00
1 50
1 00

12-06-7

1 92

1 80

1 68

1 56

1 44

1 32

1 20

1 08

96

84

72

60

48

36

24

0

12

50

Motor l oa din g ra te
(%)

Chapter 12 Description of Parameter SettingsC2000 Series



Heat Sink Over-heat (OH) Warning
Factory Setting: 105.0
Settings

0.0~110.0℃

 When using heavy duty or advanced control mode, the OH warning will be disabled if Pr06-15
remains as default. When the temperature reaches 100℃, motor drive will stop with IGBT
over-heat fault.
 When using normal duty or general control mode, the OH warning will be disabled if Pr06-15 is set
to 110℃. When the temperature reaches 110℃, motor drive will stop with IGBT over-heat fault.


Stall Prevention Limit Level (Flux weakening area current stall prevention level)
Factory Setting: 50
Settings

0~100% (Refer to Pr.06-03, Pr.06-04)

 When operation frequency is larger than Pr.01-01; e.g. Pr06-03=150%, Pr. 06-04=100% and Pr.
06-16=80%:
Calculate the Stall Prevention Level during acceleration: Pr.06-03 * Pr.06-16=150x80%=120%.
Calculate the Stall Prevention Level at constant speed: Pr.06-04 * Pr.06-16=100x80%=80%.
Fault Record 1 (Present Fault Record)
Fault Record 2
Fault Record 3
Fault Record 4
Fault Record 5
Fault Record 6
Settings
0: No fault record
1: Over-current during acceleration (ocA)
2: Over-current during deceleration (ocd)
3: Over-current during constant speed(ocn)
4: Ground fault (GFF)
5: IGBT short-circuit (occ)
6: Over-current at stop (ocS)
7: Over-voltage during acceleration (ovA)
8: Over-voltage during deceleration (ovd)
9: Over-voltage during constant speed (ovn)
10: Over-voltage at stop (ovS)
11: Low-voltage during acceleration (LvA)
12: Low-voltage during deceleration (Lvd)
13: Low-voltage during constant speed (Lvn)
14: Stop mid-low voltage (LvS)
15: Phase loss protection (OrP)
16: IGBT over-heat (oH1)
17: Capacitance over-heat (oH2) (for 40hp above)
12-06-8

Chapter 12 Description of Parameter SettingsC2000 Series

18: tH1o (TH1 open: IGBT over-heat
protection error)
19: tH2o (TH2 open: capacitance over-heat
protection error)
20: Reserved
21: Drive over-load (oL)
22: Electronics thermal relay 1 (EoL1)
23: Electronics thermal relay 2 (EoL2)
24: Motor PTC overheat (oH3) (PTC)
25: Reserved
26: Over-torque 1 (ot1)
27: Over-torque 2 (ot2)
28: Low current (uC)
29: Home limit error (LMIT)
30: Memory write-in error (cF1)
31: Memory read-out error (cF2)
32: Reserved
33: U-phase current detection error (cd1)
34: V-phase current detection error (cd2)
35: W-phase current detection error (cd3)
36: Clamp current detection error (Hd0)
37: Over-current detection error (Hd1)
38: Over-voltage detection error (Hd2)
39: occ IGBT short circuit detection error (Hd3)
40: Auto tuning error (AUE)
41: PID feedback loss (AFE)
42: PG feedback error (PGF1)
43: PG feedback loss (PGF2)
44: PG feedback stall (PGF3)
45: PG slip error (PGF4)
46: PG ref loss (PGr1)
47: PG ref loss (PGr2)
48: Analog current input loss (ACE)
49: External fault input (EF)
50: Emergency stop (EF1)
51: External Base Block (bb)
52: Password error (PcodE)
53: Reserved
54: Communication error (CE1)
55: Communication error (CE2)
56: Communication error (CE3)
57: Communication error (CE4)
12-06-9

Chapter 12 Description of Parameter SettingsC2000 Series

58: Communication Time-out (CE10)
59: PU Time-out (CP10)
60: Brake transistor error (bF)
61: Y-connection/△-connection switch error (ydc)
62: Decel. Energy Backup Error (dEb)
63: Slip error (oSL)
64: Electromagnet switch error (ryF)
65: PG Card Error (PGF5)
66~67: Reserved
68: Sensorless estimated speed have wrong direction
69: Sensorless estimated speed is over speed
70: Sensorless estimated speed deviated
71: Reserved
72: STO Loss 1
73: External safety gate S1
74~75: Reserved
76: STO
77: STO Loss 2
78: STO Loss 3
79: Uocc U phase over current (Detection begins as RUN is pressed,
software protection)
80: Vocc V phase over current (Detection begins as RUN is pressed,
software protection)
81: Wocc W phase over current (Detection begins as RUN is pressed,
software protection)
82: OPHL U phase output phase loss
83: OPHL Vphase output phase loss
84: OPHL Wphase output phase loss
85: PG-02U ABZ hardware disconnection
86: PG-02U UVW hardware disconnection
87~88: Reserved
89: Initial rotor position detection error
90: Inner PLC function is forced to stop
91~100: Reserved
101: CGdE CANopen software disconnect1
102: CHbE CANopen software disconnect2
103: CSYE CANopen synchronous error
104: CbFE CANopen hardware disconnect
105: CIdE CANopen index setting error
106: CAdE CANopen slave station number setting error
107: CFrE CANopen index setting exceed limit
108~110: Reserved
111: InrCOM Internal communication overtime error
12-06-10

Chapter 12 Description of Parameter SettingsC2000 Series

112: PM sensorless shaft Lock error
113: Software OC
 When the fault occurs and force stopping, it will record in this parameter.
 At stop with low voltage Lv (LvS warn, no record). During operation with mid-low voltage Lv (LvA,
Lvd, Lvn error, will record).
 Setting 62: when dEb function is enabled, the drive will execute dEb and record to the Pr.06-17 to
Pr.06-22 simultaneously.


Fault Output Option 1



Fault Output Option 2



Fault Output Option 3



Fault Output Option 4
Factory Setting: 0
Settings

0 to 65535 sec (refer to bit table for fault code)

 These parameters can be used with multi-function output (set to 35-38) for the specific
requirement. When the fault occurs, the corresponding terminals will be activated (It needs
to convert binary value to decimal value to fill in Pr.06-23 to Pr.06-26).
Fault Code

Bit0

Bit1

Bit2

Bit3

Bit4

Bit5

Bit6

current

Volt.

OL

SYS

FBK

EXI

CE

0: No fault
1: Over-current during acceleration (ocA)

●

2: Over-current during deceleration (ocd)

●

3: Over-current during constant speed(ocn)

●

4: Ground fault (GFF)

●

5: IGBT short-circuit (occ)

●

6: Over-current at stop (ocS)

●

7: Over-voltage during acceleration (ovA)

●

8: Over-voltage during deceleration (ovd)

●

9: Over-voltage during constant speed (ovn)

●

10: Over-voltage at stop (ovS)

●

11: Low-voltage during acceleration (LvA)

●

12: Low-voltage during deceleration (Lvd)

●

13: Low-voltage during constant speed (Lvn)

●

14: Stop mid-low voltage (LvS )

●

15: Phase loss protection (OrP)

●

16: IGBT over-heat (oH1)

●

17: Capacitance over-heat (oH2)

●

18: tH1o (TH1 open)

●

19: tH2o (TH2 open)

●

20: Reserved
21:

Drive over-load (oL)

●
12-06-11

Chapter 12 Description of Parameter SettingsC2000 Series

Fault Code

Bit0

Bit1

Bit2

Bit3

Bit4

Bit5

Bit6

current

Volt.

OL

SYS

FBK

EXI

CE

22: Electronics thermal relay 1 (EoL1)

●

23: Electronics thermal relay 2 (EoL2)

●

24: Motor PTC overheat (oH3) (PTC)

●

25: Reserved
26: Over-torque 1 (ot1)

●

27: Over-torque 2 (ot2)

●

28: Low current (uC)

●
●

29: Home limit error (LMIT)

30: Memory write-in error (cF1)

●

31: Memory read-out error (cF2)

●

32: Reserved
33: U-phase current detection error (cd1)

●

34: V-phase current detection error (cd2)

●

35: W-phase current detection error (cd3)

●

36: Clamp current detection error (Hd0)

●

37: Over-current detection error (Hd1)

●

38: Over-voltage detection error (Hd2)

●

39: occ IGBT short circuit detection error (Hd3)

●

40: Auto tuning error (AUE)

●

41: PID feedback loss (AFE)

●

42: PG feedback error (PGF1)

●

43: PG feedback loss (PGF2)

●

44: PG feedback stall (PGF3)

●

45: PG slip error (PGF4)

●

46: PG ref loss (PGr1)

●

47: PG ref loss (PGr2)

●

48: Analog current input loss (ACE)

●

49: External fault input (EF)

●

50: Emergency stop (EF1)

●

51: External Base Block (bb)

●

52: Password error (PcodE)

●

53: Reserved
54: Communication error (CE1)

●

55: Communication error (CE2)

●

56: Communication error (CE3)

●

57: Communication error (CE4)

●

58: Communication Time-out (CE10)

●

59: PU Time-out (CP10)

●
12-06-12

Chapter 12 Description of Parameter SettingsC2000 Series

Fault Code

Bit0

Bit1

Bit2

Bit3

Bit4

Bit5

Bit6

current

Volt.

OL

SYS

FBK

EXI

CE

60: Brake transistor error (bF)

●

61: Y-connection/△-connection switch error

●

(ydc)
62: Decel. Energy Backup Error (dEb)

●

63: Slip error (oSL)

●

64: Electromagnet switch error (ryF)

●

65 : PG Card Error (PGF5)

●

66~67: Reserved
68: Sensorless estimated speed have wrong
direction
69: Sensorless estimated speed is over speed
70: Sensorless estimated speed deviated
71: Reserved
72: STO Loss 1

●

73: External safety gate S1

●

74~75: Reserved
76: STO

●

77: STO Loss 2

●

78: STO Loss 3

●

79: U phase over current (Uocc)

●

80: V phase over current (Vocc)

●

81: W phase over current (Wocc)

●

82: OPHL U phase output phase loss

●

83: OPHL Vphase output phase loss

●

84: OPHL Wphase output phase loss

●

85: PG-02U ABZ hardware disconnection

●

86: PG-02U UVW hardware disconnection

●

87~88: Reserved
89: Initial rotor position detection error
90: Inner PLC function is forced to stop
91~100: Reserved
101: CGdE CANopen software disconnect1

●

102: CHbE CANopen software disconnect2

●

103: CSYE CANopen synchronous error

●

104: CbFE CANopen hardware disconnect

●

105: CIdE CANopen index setting error
106: CAdE CANopen slave station number
setting error
107: CFrE CANopen index setting exceed limit

●

12-06-13

●
●

Chapter 12 Description of Parameter SettingsC2000 Series

Fault Code

Bit0

Bit1

Bit2

Bit3

Bit4

Bit5

Bit6

current

Volt.

OL

SYS

FBK

EXI

CE

108~110: Reserved
111: InrCOM Internal communication overtime
error
112: PM sensorless shaft Lock error

●

113: Software OC
PTC (Positive Temperature Coefficient) Detection Selection



Factory Setting: 0
Settings

0: Warn and keep operating
1: Warn and ramp to stop
2: Warn and coast to stop
3: No warning

 Pr.06-29 setting defines how the will drive operate after PTC detection.
PTC Level



Factory Setting: 50.0
Settings

0.0~100.0%

 It needs to set AVI/ACI/AUI analog input function Pr.03-00~03-02 to 6 (P.T.C. thermistor input
value).
 It is used to set the PTC level, and the corresponding value for 100% is max. analog input value.
Frequency Command for Malfunction
Factory Setting: Read only
Settings

0.00~655.35Hz

 When malfunction occurs, use can check the frequency command. If it happens again, it will
overwrite the previous record.
Output Frequency at Malfunction
Factory Setting: Read only
Settings

0.00~655.35Hz

 When malfunction occurs, use can check the current frequency command. If it happens
again, it will overwrite the previous record.
Output Voltage at Malfunction
Factory Setting: Read only
Settings

0.0~6553.5V

 When malfunction occurs, user can check current output voltage. If it happens again, it will
overwrite the previous record.
DC Voltage at Malfunction
Factory Setting: Read only
Settings

0.0~6553.5V

 When malfunction occurs, user can check the current DC voltage. If it happens again, it will
overwrite the previous record.
12-06-14

Chapter 12 Description of Parameter SettingsC2000 Series

Output Current at Malfunction
Factory Setting: Read only
Settings

0.00~655.35Amp

 When malfunction occurs, user can check the current output current. If it happens again, it will
overwrite the previous record.
IGBT Temperature at Malfunction
Factory Setting: Read only
Settings

0.0~6553.5℃

 When malfunction occurs, user can check the current IGBT temperature. If it happens again, it will
overwrite the previous record.
Capacitance Temperature at Malfunction
Factory Setting: Read only
Settings

-3276.7~3276.7℃

 When malfunction occurs, user can check the current capacitance temperature. If it happens again,
it will overwrite the previous record.
Motor Speed in rpm at Malfunction
Factory Setting: Read only
Settings

-3276.7~3276.7 rpm

 When malfunction occurs, user can check the current motor speed in rpm. If it happens again, it will
overwrite the previous record.
Torque Command at Malfunction
Factory Setting: Read only
Settings

-3276.7~3276.7

 When malfunction occurs, user can check the current torque command. If it happens again, it will
overwrite the previous record.
Status of Multi-function Input Terminal at Malfunction
Factory Setting: Read only
Settings

0000h~FFFFh

Status of Multi-function Output Terminal at Malfunction
Factory Setting: Read only
Settings

0000h~FFFFh

 When malfunction occurs, user can check the status of multi-function input/output terminals. If it
happens again, it will overwrite the previous record.
Drive Status at Malfunction
Factory Setting: Read only
Settings

0000H~FFFFh

 When malfunction occurs, please check the drive status (communication address 2119H). If
malfunction happens again, the previous record will be overwritten by this parameter.
12-06-15

Chapter 12 Description of Parameter SettingsC2000 Series

Reserved


STO Alarm Latch
Factory Setting: 0
Settings

0: STO alarm Latch
1: STO alarm no Latch

 Pr06-44=0 STO Alarm Latch: after the reason of STO Alarm is cleared, a Reset command is need
to clear STO Alarm.
 Pr06-44=1 STO Alarm no Latch: after the reason of STO Alarm is cleared, the STO Alarm will be
cleared automatically.
 All of STL1~STL3 error are “Alarm latch” mode (in STL1~STL3 mode, the Pr06-44 function is no
effective).


Treatment to Output Phase Loss (OPHL)
Factory Setting: 3
Settings

0: Warn and keep operating
1: Warn and ramp to stop
2: Warn and coast to stop
3: No warning

 The OPHL protect will be active when the setting is not 3.


Deceleration Time of Output Phase Loss
Factory Setting:0.500
Settings



0.000~65.535 sec

Current detection level of output phase loss
Factory Setting:1.00
Settings



0.00~655.35%

Output phase loss detection function executing time before run
Factory Setting:0.000
Settings

0.000~65.535 sec

 When Pr06-48 is 0, OPHL detection function will be disabled

12-06-16

Chapter 12 Description of Parameter SettingsC2000 Series

 Status 1：Motor drive is in operation
Any phase is less than Pr06-47 setting level, and exceeds Pr06-46 setting time, motor drive will
perform Pr06-45 setting.

Drive’s st atus
Operation command
O PH L

OPHL detec tion
P r.06 -4 7

Outpu t current

Time
P r. 06 -46

Whe n OPHL, Pr06-45 acts

 Status 2：Motor drive is in stop; Pr06-48=0 ; Pr07-02≠0
After motor drive starts, DC brake will be applied in accord to Pr07-01 and Pr07-02. During this
period, OPHL detection will not be conducted. After DC brake, motor drive starts to run, and
conducts the OPHL protection as mentioned in status 1.
Drive’s st atus
Operation command
O P HL

OPHL detection
Pr.0 6-4 7
Pr.0 7-0 1
Outpu t current

Time
Pr.06 -46

P r. 07 -02

12-06-17

Whe n OPHL, Pr06-45 acts

Chapter 12 Description of Parameter SettingsC2000 Series

 Status 3: Motor drive is in stop; Pr06-48≠0 ; Pr07-02≠0
When motor drive starts, it will perform Pr06-48 and then Pr07-02 (DC brake). DC brake current
level in this status includes two parts, one is 20 times of Pr06-47 setting value in Pr06-48 setting
time, and Pr07-02 setting value in Pr07-01 setting time. Total DC brake time is
T=Pr06-48+Pr07-02.
In this period, if OPHL happens, motor drive starts to count until Pr06-48/2, motor drive will
perform Pr06-45 setting.
Sta tus 3-1: P r0 6-48≠0, Pr07 -0 2≠0 (No OPHL d e tected be fore ope ra tion )
Driv e’s s tat us

Operat io n co mman d
OP HL det ect ion ac tion

OPHL det ect io n ac ts
No OPHL detec ted

O PHL detec tion

20 *[ Pr0 6-4 7 ]
Pr.07-01
Pr.06-47
Out put current
Pr. 06-48

Pr. 07-02

Start to op era te

Time

Total DC brak e time

Sta tus 3-2: P r0 6-48≠0, Pr07 -0 2≠0 (OPHL d ete cte d befo re o perati on)
Drive’s st atus

O peration command
OP HL de tection action

OPHL dete ction act s

O PHL detected

OPHL det ect ion

Whe n OPHL, Pr06-45 act s

DC brake c om mand

20 *[Pr06-47]
P r.07 -01
P r.06 -47

Outp ut current

Actual output c urrent

Time

Pr. 06- 48
2

Pr.06 -48

P r.07 -02

Tota l DC brake time

12-06-18

S tart to ope ra te

Chapter 12 Description of Parameter SettingsC2000 Series

 Status 4: Motor drive is in stop; Pr06-48≠0 ; Pr07-02=0
When motor drive starts, it will perform Pr06-48 as DC brake. The DC brake current level is 20
times of Pr06-47 setting value. In this period, if OPHL happens, motor drive starts to count until
Pr06-48/2, motor drive will perform Pr06-45 setting.

Sta tus 4-1: P r0 6-48≠0, Pr07 -0 2=0 (N o OPH L d etected b efore op eratio n)
Drive ’s st atus

Operation command
O PHL detec tion acts

OP HL de tec tion action

No OPHL detected

O PHL detection

20 *[P r06-47 ]
P r. 06- 47

O utput current
Pr.06- 48

Start to operate

Time

Total DC brak e time

Sta tus 4-2: P r0 6-48≠0, Pr07 -0 2=0 (OPHL d e tected be fore ope ra tion )
Drive’s statu s

Operation command
O PHL detection acts

OP HL de tection action

OPHL det ect ed

OPHL dete ction

When OPHL, Pr06-45 acts

DC brak e c ommand

2 0 *[P r 0 6 - 47 ]
Actual output c urrent

P r.06 -47

O utput current

Pr. 06-48
2

Time

Pr.06 -48

Total DC brak e time

Reserved


Time for Input Phase Loss Detection
Factory Setting:0.20
Settings

0.00~600.00 sec

12-06-19

Chapter 12 Description of Parameter SettingsC2000 Series

Reserved


Ripple of Input Phase Loss
Factory Setting:30.0 / 60.0
Settings

230V Series: 0.0~160.0 Vdc

460V Series: 0.0~320.0 Vdc
 When the DC BUS ripple is higher than Pr06-52, and continue Pr06-50 plus 30 seconds, drive will
trip up OrP and act depending on the setting of Pr06-53 to stop.
 In the time period Pr06-50 plus 30 seconds, if the DC BUS ripple is lower than Pr06-52, the Orp
protection counter will be restart.


Treatment for the detected Input Phase Loss （OrP）
Factory Setting: 0
Settings

0: warn, ramp to stop
1: warn, coast to stop

 Over ripple protection
 When the DC BUS ripple is bigger than protection level, drive will trip up OrP and depending on
how the parameter 06-53 is set to stop.
Reserved
Derating Protection
Factory Setting: 0
Settings

0: constant rated current and limit carrier wave by load current and
temperature
1: constant carrier frequency and limit load current by setting carrier wave
2: constant rated current(same as setting 0), but close current limit

 Setting 0:
When the rated current is constant, carrier frequency (Fc) outputted by PWM will auto
decrease according to surrounding temperature, overload output current and time. If overload
situation is not frequent and only cares the carrier frequency operated with the rated current for a
long time and carrier wave changes during short overload, it is recommended to set to 0.
Refer to the following diagram for the level of carrier frequency. Take VFD007C43A in normal
duty as example, surrounding temperature 50oC with independent installation and UL open-type.
When the carrier frequency is set to 15kHz, it corresponds to 72% rated output current. When it
outputs higher than the value, it will auto decrease the carrier frequency. If the output is 83% rated
current and the carrier frequency will decrease to 12kHz. In addition, it will also decrease the
carrier frequency when overload. When the carrier frequency is 15kHz and the current is
120%*72%=86% for a minute, the carrier frequency will decrease to the factory setting.

12-06-20

Chapter 12 Description of Parameter SettingsC2000 Series

 Setting 1:
It is used for the fixed carrier frequency and prevents the carrier wave changes and motor
noise caused by the surrounding temperature and frequent overload.
Refer to the following for the derating level of rated current. Take VFD007C43A in normal
duty as example, when the carrier frequency keeps in 15kHz and the rated current is decreased to
72%, it will have OL protection when the current is 120%*72%=86% for a minute. Therefore, it
needs to operate by the curve to keep the carrier frequency.
 Setting 2:
It sets the protection method and action to 0 and disables the current limit for the Ratio*160%
of output current in the normal duty and Ratio*180% of output current in the heavy duty. The
advantage is that it can provide higher output current when the setting is higher than the factory
setting of carrier frequency. The disadvantage is that it decreases carrier wave easily when
overload.
 It should be used with Pr. 00-16 and Pr.00-17 for setting.
 Ambient temperature will also affect the derating, please refer to ambient temperature derating
curve.
General Control Derating Curve (Pr00-10=1 and Pr0011=0~3)
In Normal Duty mode (Pr.00-16=0)
Pr.06-55=1
Pr.06-55=1
Pr.06-55=0 or 2
Pr.06-55=0 or 2
(50℃: UL open-type)
(50℃: UL open-type)
(40℃:UL type1 or open type side by side)
(40℃:UL type1 or open type side by side)
460V

230V
VFD007~150C43A/E
VFD185~550C43A/E
VFD370~450C43S/U
VFD750~4500C43A/E
110
100

100

Ratio(%)

Ratio(%)

110

90
80

90
80
70

70
60
4

VFD007~110C23A
VFD150~370C23A;
VFD300~370C23E
VFD450~900C23A/E

5

6

7

8

9

60
4

10 11 12 13 14 15

5

6

7

8

9

10 11 12 13 14 15

Fc (kHz)

Fc (kHz)

12-06-21

Chapter 12 Description of Parameter SettingsC2000 Series

In Heavy Duty mode (Pr.00-16=1)
Pr.06-55=1
Pr.06-55=1
Pr.06-55=0 or 2
Pr.06-55=0 or 2
(50℃: UL open-type)
(50℃: UL open-type)
(40℃: UL type1 or open type side by side)
(40℃: UL type1 or open type side by side)
460V

230V
VFD007~110C23A
VFD150~370C23A;
VFD300~370C23E
VFD450~900C23A/E

110

110

100

100

90

90

Ratio(%)

Ratio(%)

VFD007~150C43A/E
VFD185~550C43A/E
VFD370~450C43S/U
VFD750~4500C43A/E

80
70
60

70
60
50

50
40
2

80

3 4

5

6

7

8

9 10 11 12 13 14 15

40
2

3 4

5

Fc (kHz)

Ambient Temperature derating Curve for General Control Model

12-06-22

6

7

8

9 10 11 12 13 14 15

Fc (kHz)

Chapter 12 Description of Parameter SettingsC2000 Series

Advanced Control Derating Curve (Pr00-10=1, and Pr00-11=4~7; or Pr00-10=3, and Pr00-13=1~3)
In Normal Duty mode (Pr00-16=0)

12-06-23

Chapter 12 Description of Parameter SettingsC2000 Series

In Heavy Duty mode (Pr00-16=1)

12-06-24

Chapter 12 Description of Parameter SettingsC2000 Series

Ambient Temperature derating Curve for Advanced Control Mode



PT100 Detection Level 1
Factory Setting:5.000
Settings



0.000~10.000V

PT100 Detection Level 2
Factory Setting: 7.000
Settings

0.000~10.000V

 Make sure Pr. 06-57 > Pr.06-56.


PT100 Level 1 Frequency Protection
Factory Setting: 0.00
Settings



0.00~600.00 Hz

PT100 activation level delay time
Factory Setting: 60 sec
Settings

0~6000 sec

 PT100 operation
(1) Use AVI, AUI or ACI(set to 0-10V) for analog voltage input and select PT100 mode.
(2) Choose one of the analog voltage input type: (a)AVI (Pr.03-00=11), (b) AUI (Pr.03-02=11), or
(c) ACI (Pr.03-01=11 and Pr.03-29=1).
(3) When using ACI as analog voltage input, set Pr.03-01=11 and Pr.03-29=1. Then switch SW2
to 0-10V on the I/O control terminal block.
(4) Set Pr.03-23=23 and AFM2 to constant current output. Switch AFM2 (SW2) to 0-20mA on the
I/O control terminal block and set constant current output to 9mA by setting Pr.03-33=45. The
AFM2 constant output current is 20mA * 45% = 9mA.
(5) Pr.03-33 is for adjusting the constant voltage or constant current of AFM2, the setting range is
0~100.00%.
12-06-25

Chapter 12 Description of Parameter SettingsC2000 Series
(6) There are two types of action level for PT100. The diagram of PT protecting action is shown

as below:
L e ve l 2= 0 6 -5 7
Se tti n g ra n g e: 0 .0 0 0~ 1 0 .0 0 0 V
Fa cto ry se tti n g : 7 .0 0 0 V

L e ve l 1= 0 6 -5 6
Se tti n g ra n g e : 0 .0 0 0~ 1 0 .0 0 0 V
Fa cto ry se tti n g : 5 .0 0 0 V

When voltage of PT 100 reaches level 1,
the drive passed the delay time set at Pr06-59 ,
the frequency command goes back to Pr.06-58.

Fre q u e n cy
C o mma n d

When voltage of PT 100 reaches level 2, the drive activate
protecting action by following the setting of Pr.06-29.

Pr.06- 59 D e l a y ti me

(7) PT100 wiring diagram:

0-1 0V
AF M 1

0 -1 0 V
AF M 2

-10 -10 V
A FM1 +1 0V

A VI

0 -20 mA
A CI

0 -20 m A 0-2 0m A

AVI

A FM2 -1 0V

0 -10 V

A CI

Op en

RC2 RB2 R A2RC1 RB1 RA1

48 5

0 -10 V

1 20

M O1 MO2 STO1 STO 2 +2 4V +2 4 V C OM FWD

A U I AC M MC M D FM SC M1 SC M2 D C M DC M RE V

I1
M MI3

MI2

I4
M

MI5

M I6

MI7 SGN D

MI8

S G+

SG-

PT100

Figure 1
 When Pr.06-58=0.00Hz, PT100 function is disabled.
Example:
A PT100 is installed to the drive. If motor temperature reaches 135℃ (275°F) or higher, the drive
will decrease motor frequency to the setting of Pr.06-58. Motor will operate at this frequency
(Pr.06-58) till the motor temperature decreases to 135℃(275°F) or lower. If motor temperature
exceeds 150℃(302°F), the motor will decelerate to stop and outputs an ‘OH3’ warning.
Set up process:
1. Switch AFM2 (SW2) to 0-20mA on the I/O control terminal block. (Refer to Figure 1, PT100 wiring
diagram)
2. Wiring (Refer to Figure 1, PT100 wiring diagram):
Connect external terminal AFM2 to (+)
Connect external terminal ACM to (-)
Connect external terminals AFM2 and AVI to short-circuit
3. Set Pr.03-00=11 or Pr.03-23=23 or Pr.03-33=45%(9mA)
4. Refer to RTD temperature and resistance comparison table
Temperature=135℃, resistance=151.71; Input current: 9mA, Voltage: approximately: 1.37Vdc
Temperature=150℃, resistance=157.33; Input current:9mA, Voltage: approximately: 1.42Vdc

12-06-26

Chapter 12 Description of Parameter SettingsC2000 Series

5. Set Pr.06=56=1.37 and Pr.06-58=10Hz. When RTD temperature increases to 135℃ or higher,
the drive will decelerate to the selected frequency. When Pr.06-58=0, the drive will not run.
6. Set Pr.06-57=1.42 and Pr.06-29=1 (warning and decelerate to stop). When RTD temperature
increases to 150℃ or higher, the drive will decelerate to stop and outputs an ‘OH3’ warning.


Software Detection GFF Current Level
Factory Setting: 60.0
Settings



0.0~6553.5 %

Software Detection GFF Filter Time
Factory Setting: 0.10
Settings

0.00~655.35 sec

 When the motor drive detects the unbalanced three-phase out current is higher than the setting of
Pr06-60, GFF protection will be activated. Then the motor drive will stop outputting.
 When 3-phase current output unbalance value has exceeds Pr06-60 setting, drive will trip up GFF
and stop output immediately.
Reserved
Fault Record 1 (day)
Fault Record 2 (day)
Fault Record 3 (day)
Fault Record 4 (day)
Factory Setting: Read only
Settings

0~65535 days

Fault Record 1 (min)
Fault Record 2 (min)
Fault Record 3 (min)
Fault Record 4 (min)
Factory Setting: Read only
Settings

0~1439 min

 When there is any malfunctions in motor drive operation, Pr06-17~22 will record 6 malfunctions
recently, and Pr06-63~70 can record the operation time for 4 malfunctions in sequence. It can help
to check if there is any wrong with the drive according to the recorded internal time.
For example: The first error: ocA occurs in 1000 minutes after motor drive start operation. The
second error: ocd happens after another 1000 minutes. The 4th error: ocA happens after another
1000 minutes. Then, the 5th error is ocd, happening 1000 minutes following 4th error. Last, 6th error
ocn happens 1000 minutes after 5th error.
Then Pr06-17~Pr06-22 and Pr06-63~Pr06-70 will be:

12-06-27

Chapter 12 Description of Parameter SettingsC2000 Series

1st fault

2nd fault

3rd fault

4th fault

5th fault

6th fault

06-17

ocA

ocd

ocn

ocA

ocd

ocn

06-18

0

ocA

ocd

ocn

ocA

ocd

06-19

0

0

ocA

ocd

ocn

ocA

06-20

0

0

0

ocA

ocd

ocn

06-21

0

0

0

0

ocA

ocd

06-22

0

0

0

0

0

ocA

06-63

1000

560

120

1120

680

240

06-64

0

1

2

2

3

4

06-65

0

1000

560

120

1120

680

06-66

0

0

1

2

2

3

06-67

0

0

1000

560

120

1120

06-68

0

0

0

1

2

2

06-69

0

0

0

1000

560

120

06-70

0

0

0

0

1

2

※ From time record, it can be known that the last fault (Pr06-17) happened after the drive run for
4days and 240 minutes.
Low Current Setting Level



Factory Setting: 0.0
Settings

0.0 ~ 6553.5 %

Low Current Detection Time



Factory Setting: 0.00
Settings

0.00 ~ 655.35 sec

Treatment for low current



Factory Setting: 0
0 : No function
1 : warn and coast to stop
2 : warn and ramp to stop by 2nd deceleration time
3 : warn and operation continue
 The drive will operate as the setting of Pr.06-73 when output current is lower than the setting of
Settings

Pr.06-71 and when low current continues for a period longer than the setting of Pr.06-72. This
parameter can also be used with external multi-function output terminal 44 (MO44) for low current
output.
 The low current detection function will not be executed when drive is at sleep or standby status.

12-06-28

Chapter 12 Description of Parameter SettingsC2000 Series

07 Special Parameters


 This parameter can be set during operation.

Software Brake Level
Factory Setting: 380.0/760.0
Settings

230V series: 350.0~450.0Vdc
460V series: 700.0~900.0Vdc

 This parameter sets the DC-bus voltage at which the brake chopper is activated. Users can choose
the suitable brake resistor to have the best deceleration. Refer to Chapter 7 Accessories for the
information of the brake resistor.
 It is only valid for the models below 30kW of 460 series and 22kW of 230 series.


DC Brake Current Level
Factory Setting: 0
Settings

0~100%

 This parameter sets the level of DC Brake Current output to the motor during start-up and stopping.
When setting DC Brake Current, the Rated Current is regarded as 100%. It is recommended to
start with a low DC Brake Current Level and then increase until proper holding torque has been
attained.
 When it is in FOCPG control mode, DC brake is zero-speed operation. It can enable DC brake
function by setting to any value. The drive will output an appropriate current to meet the actual
need.


DC Brake Time at RUN
Factory Setting: 0.0
Settings

0.0~60.0 sec

 The motor may be in the rotation status due to external force or itself inertia. If the drive is used with
the motor at this moment, it may cause motor damage or drive protection due to over current. This
parameter can be used to output DC current before motor operation to stop the motor and get a
stable start. This parameter determines the duration of the DC Brake current after a RUN command.
When it is set to 0.0, it is invalid.


DC Brake Time at Stop
Factory Setting: 0.0
Settings

0.0~60.0 sec

 The motor may be in the rotation status after drive stop outputting due to external force or itself
inertia and can’t stop accurately. This parameter can output DC current to force the motor drive
stop after drive stops to make sure that the motor is stop.
 This parameter determines the duration of the DC Brake current during stopping. To DC brake at
stop, this function will be valid when Pr.00-22 is set to 0 or 2. When setting to 0.0, it is invalid.
 Related parameters: Pr.00-22 Stop Method, Pr.07-04 Start-point for DC Brake

12-07-1

Chapter 12 Description of Parameter SettingsC2000 Series



DC Brake Frequency at STOP
Factory Setting: 0.00
Settings

0.00~600.00Hz

 This parameter determines the frequency when DC Brake will begin during deceleration. When
this setting is less than start frequency (Pr.01-09), the start-point for DC brake will start from the
min. frequency.
Output frequen cy

01-09
Minimum
out put
frequen cy
Run /Stop

DC Brak Time
07-04
Start-point for during St opping
DC brake
time during
stopping
OFF

ON

Time

DC Brake Time

 DC Brake at Start-up is used for loads that may move before the AC drive starts, such as fans and
pumps. Under such circumstances, DC Brake can be used to hold the load in position before
setting it in motion.
 DC Brake at stop is used to shorten the stopping time and also to hold a stopped load in position,
such as crane or cutting machine.
 DC Brake at Start-up is used for loads that may move before the AC drive starts, such as fans and
pumps. Under such circumstances, DC Brake can be used to hold the load in position before
setting it in motion.
 DC Brake at stop is used to shorten the stopping time and also to hold a stopped load in position,
such as crane or cutting machine.


Voltage Incrasing Gain
Factory Setting: 100
Settings

1~200%

 When the user is using speed tracking, adjust Pr07-05 to slow down the increasing of voltage if
there are errors such as oL or oc.


Restart after Momentary Power Loss
Factory Setting: 0
Settings

0: Stop operation
1: Speed search for last frequency command
2: Speed search for the minimum output frequency

 This parameter determines the operation mode when the AC motor drive restarts from a
momentary power loss.
 The power connected to the drive may power off momentarily due to many reasons. This function
allows the drive to keep outputting after power is on again after power off and won’t cause drive
stops.

12-07-2

Chapter 12 Description of Parameter SettingsC2000 Series

 Setting 1: Operation continues after momentary power loss, speed search starts with the Master
Frequency reference value after drive output frequency and motor rotator speed is synchronous.
The motor has the characteristics of big inertia and small obstruction. For example, in the
equipment with big inertia wheel, it doesn’t need to wait to execute operation command until
wheel is complete stop after re-start to save time.
 Setting 2: Operation continues after momentary power loss, speed search starts with the
minimum output frequency after drive output frequency and motor rotator speed is synchronous.
The motor has the characteristics of small inertia and bigger obstruction.
 In PG control mode, the AC motor drive will execute the speed search function automatically by
the PG speed when this setting isn’t set to 0.


Maximum Power Loss Duration
Factory Setting: 2.0
Settings

0.0~20.0 sec

 If the duration of a power loss is less than this parameter setting, the AC motor drive will resume
operation. If it exceeds the Maximum Allowable Power Loss Time, the AC motor drive output is
then turned off (coast stop).
 The selected operation after power loss in Pr.07-06 is only executed when the maximum
allowable power loss time is 5 seconds and the AC motor drive displays “LU”.
But if the AC motor drive is powered off due to overload, even if the maximum allowable power
loss time is 5 seconds, the operation mode as set in Pr.07-06 is not executed. In that case it
starts up normally.


Base block Time
Factory Setting: 0.5
Settings

0.1~5.0 sec

 When momentary power loss is detected, the AC drive will block its output and then wait for a
specified period of time (determined by Pr.07-08, called Base-Block Time) before resuming
operation. This parameter should be set at a value to ensure that any residual regeneration
voltage from the motor on the output has disappeared before the drive is activated again.
7

Input B.B. signal
Stop output voltage
Disable B.B. signal
Waiting time Pr.07-08
Speed search
Synchronization speed detection
7 Frequency command before B.B.

Output frequency(H)
Output voltage(V)
Output current A
07-09
Current Limit for
Speed Search

Time

FWD Run
B.B.
B.B. Search with last output frequency downward timing chart

12-07-3

Chapter 12 Description of Parameter SettingsC2000 Series

Output frequency
(H)

Input B.B. signal
Stop output voltage
Disable B.B. signal

Output voltage
(V)

Waiting time 08.07

output current A
07-09 Current Limit
for Speed Search Speed

Speed Search
Synchronization speed detection
Time

FWD Run
B.B.
B.B. Search with minimum output frequency upward timing chart

Input B.B. signal
Stop voltage output
Disable B.B. signal
Waiting time Pr.07-08
Speed search
Synchronization speed detection

Output frequency(H)
Output voltage(V)
Output current A
06-03
Over-Current Stall
Prevention
during Accel.
FWD Run

Time

B.B.

B.B. Search with minimum output frequency upward timing chart



Current Limit for Speed Search
Factory Setting: 100
Settings

20~200%

 Following a momentary power loss, the AC motor drive will start its speed search operation only if
the output current is greater than the value set by Pr.07-09.
 When executing speed search, the V/f curve is operated by group 1 setting. The maximum current
for the optimum accel./decel. and start speed search is set by Pr.07-09.
 The maximum speed search level will affect the synchronous time. It will get the synchronization
faster when this parameter is set to larger value. But too large value may activate overload
protection.

12-07-4

Chapter 12 Description of Parameter SettingsC2000 Series



Treatment after Fault
Factory Setting: 0
Settings

0: Stop operation
1: Speed search starts with current speed
2: Speed search starts with minimum output frequency

 In PG control mode, the AC motor drive will execute the speed search function automatically by
the PG speed when this setting isn’t set to 0.
 Fault includes: bb,oc,ov,occ. To restart after oc, ov, occ, Pr.07-11 can not be set to 0.


Auto Restart Time after Fault
Factory Setting: 0
Settings

0~10

 After fault (oc, ov, occ) occurs, the AC motor drive can be reset/restarted automatically up to 10
times.
 Setting this parameter to 0 will disable the reset/restart operation after any fault has occurred.
When enabled, the AC motor drive will restart with Pr07-10 setting after fault auto reset.
 If the time of reset/restart exceeds Pr.07-11 setting, the fault will not be restart /reset until user
reset manually and run the motor drive again.


Speed Search during Start-up
Factory Setting: 0
Settings

0: Disable
1: Speed search from maximum output frequency
2: Speed search from start-up motor frequency
3: Speed search from minimum output frequency

 This parameter is used for starting and stopping a motor with a high inertia. A motor with high
inertia will take 2-5 minutes or longer to stop completely. By setting this parameter, the user does
not need to wait for the motor to come to a complete stop before restarting the AC motor drive. If a
PG card and encoder is used on the drive and motor, then the speed search will start from the
speed that is detected by the encoder and accelerate quickly to the commanded frequency. The
output current is set by the Pr.07-09.
 In PG control mode, the AC motor drive will execute the speed search function automatically by
the PG speed when this setting isn’t set to 0.


Decel. Time at Momentary Power Loss (dEb function)
Factory Setting: 0
Settings

0: Disable
1~6: Auto Deceleration

 This parameter is used for the decel. time selection for momentary power loss.

12-07-5

Chapter 12 Description of Parameter SettingsC2000 Series



dEb Return Time
Factory Setting: 0.0
Settings

0.0~25.0 sec

 dEb (Deceleration Energy Backup) let motor drive decelerates to stop when momentary power loss
occurs.

dEb se tting l evel
Lv setti ng le ve l
So ft start rel ay o f p owe r side
dEb actio n
Auto de ce lerati on

Ou tput f requ ency



Dwell Time at Accel.
Factory Setting: 0.00
Settings



0.00~600.00 sec

Dwell Frequency at Accel.
Factory Setting: 0.00
Settings



0.00~600.00Hz

Dwell Time at Decel.
Factory Setting: 0.00
Settings



0.00~600.00 sec

Dwell Frequency at Decel.
Factory Setting: 0.00
Settings

0.00~600.00 Hz

 In the heavy load situation, Dwell can make stable output frequency temporarily, such as crane or
elevator.
 Pr.07-15 to Pr.07-18 is for heavy load to prevent OV or OC occurs.
Frequency

07-16
Dwell
Frequency
07-15
at Accel.
Dwell Time
at Accel.

07-17
Dwell Time
at Decel.

07-18
Dwell
Frequency
at Decel.
Time

Dwell at accel./decel.

12-07-6

Chapter 12 Description of Parameter SettingsC2000 Series



Fan Cooling Control
Factory Setting: 0
Settings

0: Fan always ON
1: 1 minute after the AC motor drive stops, fan will be OFF
2: When the AC motor drive runs, the fan is ON. When the AC motor drive
stops, the fan is OFF
3: Fan turns ON when preliminary IGBT temperature (around 60oC) is
attained.
4: Fan always OFF

 This parameter is used for the fan control.
 Setting 0: Fan will be ON as the drive’s power is turned ON.
 Setting 1: 1 minute after AC motor drive stops, fan will be OFF
 Setting 2: AC motor drive runs and fan will be ON. AC motor drive stops and fan will be OFF.
 Setting 3: Fan run according to IGBT and capacitance temperature. Fan will be ON when IGBT
temperature is higher than 60oC. Fan will be OFF, when capacitance temperature is lower than
40oC.
 Setting 4: Fan is always OFF


Emergency Stop (EF) & Force Stop
Factory Setting: 0
Settings

0: Coast to stop
1: Stop by 1st deceleration time
2: Stop by 2nd deceleration time
3: Stop by 3rd deceleration time
4: Stop by 4th deceleration time
5: System Deceleration (According to original deceleration time)
6: Automatic Deceleration ( Pr01-46)

 When the multi-function input terminal is set to 10(EF) or 18(Emergency stop) and is activated,
the drive will stop according to the setting in Pr.07-20.


Auto Energy-saving Operation
Factory Setting: 0
Settings

0: Disable
1: Enable

 When Pr.07-21 is set to 1, the acceleration and deceleration will operate with full voltage. During
constant speed operation, it will auto calculate the best voltage value by the load power for the
load. This function is not suitable for the ever-changing load or near full-load during operation.
 When the output frequency is constant, i.e. constant operation, the output voltage will auto
decrease by the load reduction. Therefore, the drive will operate with min. power, multiplication of
voltage and current.

12-07-7

Chapter 12 Description of Parameter SettingsC2000 Series



Energy-saving Gain
Factory Setting: 100
Settings

10~1000%

 When Pr. 07-21 is set to 1, this parameter can be used to adjust the gain of energy-saving. The
factory setting is 100%. If the result is not good, it can adjust by decreasing the setting. If the
motor oscillates, it should increase the setting value.
 At some special application such as High speed spindle, the motor temperature rise is been
highly concern. Thus, when the motor is not working with load, the motor current will requested to
reduce to a lower level. To Lowering this parameter setting can meet this requirement.


Auto Voltage Regulation(AVR) Function
Factory Setting: 0
Settings

0: Enable AVR
1: Disable AVR
2: Disable AVR during deceleration

 The rated voltage of the motor is usually 220V/200VAC 60Hz/50Hz and the input voltage of the
AC motor drive may vary between 180V to 264 VAC 50Hz/60Hz. Therefore, when the AC motor
drive is used without AVR function, the output voltage will be the same as the input voltage. When
the motor runs at voltages exceeding the rated voltage with 12% - 20%, its lifetime will be shorter
and it can be damaged due to higher temperature, failing insulation and unstable torque output.
 AVR function automatically regulates the AC motor drive output voltage to the motor rated voltage.
For instance, if V/f curve is set at 200 VAC/50Hz and the input voltage is at 200V to 264VAC, then
the motor Output Voltage will automatically be reduced to a maximum of 200VAC/50Hz. If the
input voltage is at 180V to 200VAC, output voltage to motor and input power will be in direct
proportion.
 Setting 0: when AVR function is enabled, the drive will calculate the output voltage by actual
DC-bus voltage. The output voltage won’t be changed by DC bus voltage.
 Setting 1: when AVR function is disabled, the drive will calculate the output voltage by DC-bus
voltage. The output voltage will be changed by DC bus voltage. It may cause insufficient/over
current.
 Setting 2: the drive will disable the AVR during deceleration, such as operated from high speed to
low speed.
 When the motor ramps to stop, the deceleration time is longer. When setting this parameter to 2
with auto acceleration/deceleration, the deceleration will be quicker.
 When it is in FOCPG or TQCPG, it is recommended to set to 0 (enable AVR).


Filter Time of Torque Command (V/F and SVC control mode)
Factory Setting: 0.020
Settings

0.001~10.000 sec

 When the setting is too long, the control will be stable but the control response will be delay. When
the setting is too short, the response will be quickly but the control may be unstable. User can
adjust the setting by the control and response situation.

12-07-8

Chapter 12 Description of Parameter SettingsC2000 Series



Filter Time of Slip Compensation (V/F and SVC control mode)
Factory Setting: 0.100
Settings

0.001~10.000 sec

 It can set Pr.07-24 and 07-25 to change the response time of compensation.
 If Pr.07-24 and 07-25 are set to 10seconds, the response time of compensation is the slowest. But
the system may be unstable when the setting is too short.


Torque Compensation Gain (V/F and SVC control mode)
Factory Setting: 0
(1 in SVC mode)
Settings

0~10

 When the motor load is large, a part of drive output voltage is absorbed by the resistor of stator
winding and causes insufficient voltage at motor induction and result in over output current and
insufficient output torque. It can auto adjust output voltage by the load and keep the air gap
magnetic fields stable to get the optimal operation.
 In the V/F control, the voltage will be decreased in direct proportion when the frequency is
decreased. It’ll cause decrease torque at low speed due to small AC resistor and the same DC
resistor. Therefore, Auto torque compensation function will increase the output voltage in the low
frequency to get higher start torque.
 When Pr.07-26 is set to large, it may cause motor overflux and result in too large output current,
motor overheat or triggers protection function.


Slip Compensation Gain (V/F and SVC control mode)
Factory Setting: 0.00
Settings

0.00~10.00

 The induction motor needs the constant slip to produce magnetic torque. It can be ignore in the
higher motor speed, such as rated speed or 2-3% slip.
 In the operation with variable frequency, the slip and the synchronous frequency will be in reverse
proportion to produce the same magnetic torque. That is the slip will be larger with the reduction
of synchronous frequency. The motor may stop when the synchronous frequency is decreased to
a specific value. Therefore, the slip serious affects the accuracy of motor speed at low speed.
 In another situation, when the drive uses with induction motor, the slip will be increased by the
increasing load. It also affects the accuracy of motor speed.
 This parameter can be used to set compensation frequency and reduce the slip to close the
synchronous speed when the motor runs in the rated current to raise the drive accuracy. When
the drive output current is larger than Pr.05-05 No-load Current of Induction Motor 1 (A), the drive
will compensation the frequency by this parameter.
 When the control method (Pr.00-11) is changed from V/f mode to vector mode, this parameter will
auto be set to 1.00. Otherwise, it will be set to 0.00. Please do the compensation of slip after
overload and acceleration. The compensation value should be increased from small to large
gradually. That is to add the output frequency with motor rated slip X Pr.07-27 Slip Compensation
Gain when the motor is rated load. If the actual speed ratio is slow than expectation, please
increase the setting. Otherwise, decrease the setting.
12-07-9

Chapter 12 Description of Parameter SettingsC2000 Series

Reserved


Slip Deviation Level
Factory Setting: 0
Settings

0~100.0%
0: No detection



Detection Time of Slip Deviation
Factory Setting:1.0
Settings



0.0~10.0 sec

Over Slip Treatment
Factory Setting:0
Settings

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop
3: No warning

 The Pr.07-29 to Pr.07-31 are to set allowable slip level/time and over slip treatment when the drive
is running.


Motor Hunting Gain
Factory Setting:1000
Settings

0~10000
0: Disable

 The motor will have current wave motion in some specific area. It can improve this situation by
setting this parameter. (When it is high frequency or run with PG, it can be set to 0. when the
current wave motion happens in the low frequency, please increase Pr.07-32.)


Autorestart internal of Fault
Factory Setting:60.0
Settings

0.0~6000.0 sec

 When a reset/restart after fault occurs, the drive will regards Pr.07-33 as a time boundary and
beging counting the numbers of faults occur within this time period. Within the period, if

numbers

of faults occurred did not exceed the setting in Pr.07-11, the counting will be cleared and starts
from 0 when next fault occurs. However, if the numbers of faults occurred within this time period
have exceed the setting in Pr.07-11, user will need to press RESET key manually for the drive to
operate again.

12-07-10

Chapter 12 Description of Parameter SettingsC2000 Series

08 High-function PID Parameters

 This parameter can be set during operation.

Input Terminal for PID Feedback



Factory Setting:0
Settings

0: No function
1: Negative PID feedback: on analogue input acc. To setting 5 of Pr. 03-00 to
Pr.03-02.
2: Negative PID feedback from PG card (Pr.10-02, skip direction)
3: Negative PID feedback from PG card (Pr.10-02)
4: Positive PID feedback from external terminal AVI (Pr.03-00)
5: Positive PID feedback from PG card (Pr.10-02, skip direction)
6: Positive PID feedback from PG card (Pr.10-02)
7: Negative PID feeback from communication protocol
8: Positive PID feedback from communication protocol

 Negative feedback means: +target value – feedback. It is used for the detection value will be
increased by increasing the output frequency.
 When Pr.03-00 to Pr.03-02 have the same setting, then the AVI will be the prioritized selection.
 Positive feedback means: -target value + feedback. It is used for the detection value will be
decreased by increasing the output frequency.
 When Pr08-00≠7 neither ≠8, input value is disabled. The value of the setting remain the same
after the derive is off.
Common applications for PID control


Flow control: A flow sensor is used to feedback the flow data and performs accurate flow
control.



Pressure control: A pressure sensor is used to feedback the pressure data and performs
precise pressure control.



Air volume control: An air volume sensor is used to feedback the air volume data to have
excellent air volume regulation.



Temperature control: A thermocouple or thermistor is used to feedback temperature data for
comfortable temperature control.



Speed control: A speed sensor or encoder is used to feedback motor shaft speed or input
another machines speed as a target value for closed loop speed control of master-slave
operation. Pr.10.00 sets the PID set point source (target value).



PID control operates with the feedback signal as set by Pr.10.01 either 0~+10V voltage or
4-20mA current.

 PID control loop:
drive execute PID control output value

¨

Setpoint +

K p (1

feedback signal
K p: Proportional gain(P)

1
 Td S )
Ti  S

¿¥

IM

sensor

Ti : Integral time(I) Td: Derivative c ontrol(D)

12-08-1

: O perator

Chapter 12 Description of Parameter SettingsC2000 Series

 Concept of PID control
1.

Proportional gain(P):
the output is proportional to input. With only proportional gain control,

there will always be

a steady-state error.
2.

Integral time(I):
the controller output

is proportional to the integral of the controller input. To eliminate the

steady-state error, an “integral part” needs to be added to the controller. The integral time
decides the relation between integral part and error. The integral part will be increased by
time even if the error is small. It gradually increases the controller output to eliminate the
error until it is 0. In this way a system can be stable without steady-state error by proportional
gain control and integral time control.
3.

Differential control(D):
the controller output

is proportional to the differential of the controller input. During

elimination of the error, oscillation or instability may occur. The differential control can be
used to suppress these effects by acting before the error. That is, when the error is near 0,
the differential control should be 0. Proportional gain(P) + differential control(D) can be used
to improve the system state during PID adjustment.
 When PID control is used in a constant pressure pump feedback application:
Set the application’s constant pressure value (bar) to be the set point of PID control. The pressure
sensor will send the actual value as PID feedback value. After comparing the PID set point and
PID feedback, there will be an error. Thus, the PID controller needs to calculate the output by
using proportional gain(P), integral time(I) and differential time(D) to control the pump. It controls
the drive to have different pump speed and achieves constant pressure control by using a 4-20mA
signal corresponding to 0-10 bar as feedback to the drive.
no fuse breaker
(NFB)

water pump

R(L1)

R(L1)

U(T 1)

S(L2)

S(L2)

V(T2)

T(L3)

T(L3)

W(T 3)

IM
3~

throttle
F eedback 4-20mA
cor responds
0-10bar
ACI/A VI
(4- 20mA /0- 10V )
ACM
analog si gnal common

pressure
sensor

DC

- +

1. Pr.00-04 is set to 10 (Display PID analog feedback signal value (b) (%))
2. Pr.01-12 Acceleration Time will be set as required
3. Pr.01-13 Deceleration Time will be set as required
4. Pr.00-21=0 to operate from the digital keypad
5. Pr.00-20=0, the set point is controlled by the digital keypad
6. Pr.08-00=1 (Negative PID feedback from analog input)
7. ACI analog input Pr. 03-01 set to 5, PID feedback signal.
12-08-2

Chapter 12 Description of Parameter SettingsC2000 Series

8. Pr.08-01-08-03 will be set as required
8.1 If there is no vibration in the system, increase Pr.08-01(Proportional Gain (P))
8.2 If there is no vibration in the system, reduce Pr.08-02(Integral Time (I))
8.3 If there is no vibration in the system, increase Pr.08-03(Differential Time(D))
 Refer to Pr.08-00 to 08-21 for PID parameters settings.


Proportional Gain (P)
Factory Setting:80.0
Settings

0.0~500.0

 When the setting is 1.0, it means Kp gain is 100%; setting is 0.5, Kp gain means 50%.
 It is used to eliminate the system error. It is usually used to decrease the error and get the faster
response speed. But if the value is set too high, it may cause the system oscillation and instability.
 If the other two gains (I and D) are set to zero, proportional control is the only one effective.


Integral Time (I)
Factory Setting:1.00
Settings

0.00~100.00 sec
0.00: Disable

 The integral controller is used to eliminate the error during stable system. The integral control
doesn’t stop working until error is 0. The integral is acted by the integral time. The smaller integral
time is set, the stronger integral action will be. It is helpful to reduce overshoot and oscillation to
make a stable system. At this moment, the decreasing error will be slow. The integral control is
often used with other two controls to become PI controller or PID controller.
 This parameter is used to set the integral time of I controller. When the integral time is long, it will
have small gain of I controller, the slower response and bad external control. When the integral
time is short, it will have large gain of I controller, the faster response and rapid external control.
 When the integral time is too small, it may cause system oscillation.
 If the integral time is set as 0.00, Pr.08-02 will be disabled.


Derivative Control (D)
Factory Setting:0.00
Settings

0.00~1.00 sec

 The differential controller is used to show the change of system error and it is helpful to preview
the change of error. So the differential controller can be used to eliminate the error to improve
system state. With the suitable differential time, it can reduce overshoot and shorten adjustment
time. However, the differential operation will increase the noise interference.

Please note that

too large differential will cause big noise interference. Besides, the differential shows the change
and the output of the differential will be 0 when there is no change. Therefore, the differential
control can’t be used independently. It needs to be used with other two controllers to make a PD
controller or PID controller.
 This parameter can be used to set the gain of D controller to decide the response of error change.
The suitable differential time can reduce the overshoot of P and I controller to decrease the
oscillation and have a stable system. But too long differential time may cause system oscillation.
 The differential controller acts for the change of error and can’t reduce the interference. It is not
recommended to use this function in the serious interference.
12-08-3

Chapter 12 Description of Parameter SettingsC2000 Series



Upper limit of Integral Control
Factory Setting:100.0
Settings

0.0~100.0%

 This parameter defines an upper bound or limit for the integral gain (I) and therefore limits the
Master Frequency. The formula is: Integral upper bound = Maximum Output Frequency (Pr.01-00)
x (Pr.08-04 %).
 Too large integral value will make the slow response due to sudden load change. In this way, it
may cause motor stall or machine damage.


PID Output Frequency Limit
Factory Setting:100.0
Settings

0.0~110.0%

 This parameter defines the percentage of output frequency limit during the PID control. The formula
is Output Frequency Limit = Maximum Output Frequency (Pr.01-00) X Pr.08-05 %.



PID feedback value by communication protocol
Factory Setting: 0.00
Settings

-200.00%~200.00%

 When PID feedback input is set as communication (Pr08-00=7 or 8), PID feedback value can be
set by this value.


PID Delay Time
Factory Setting: 0.0
Settings

0.0~35.0 sec

PID Mode Selection
Factory Setting: 0
Settings

0: Serial connection
1: Parallel connection

 When setting is 0, it uses conventional PID control structure.
 When setting is 1, proportional gain, integral gain and derivative gain are independent. The P, I
and D can be customized to fit users’ demand.
 Pr.08-07 determines the primary low pass filter time when in PID control. Setting a large time
constant may slow down the response rate of drive.
 Output frequency of PID control will filter by primary low pass function. This function could filtering
a mix frequencies. A long primary low pass time means filter degree is high and vice versa.
 Inappropriate setting of delay time may cause system error.
 PI Control: controlled by the P action only, and thus, the deviation cannot be eliminated entirely. To
eliminate residual deviations, the P + I control will generally be utilized. And when the PI control is
utilized, it could eliminate the deviation incurred by the targeted value changes and the constant
external interferences. However, if the I action is excessively powerful, it will delay the responding
toward the swift variation. The P action could be used solely on the loading system that
possesses the integral components.

12-08-4

Chapter 12 Description of Parameter SettingsC2000 Series

 PD Control: when deviation occurred, the system will immediately generate some operation load
that is greater than the load generated single handedly by the D action to restrain the increment of
the deviation. If the deviation is small, the effectiveness of the P action will be decreasing as well.
The control objects include occasions with integral component loads, which are controlled by the
P action only, and sometimes, if the integral component is functioning, the whole system will be
vibrating. On such occasions, in order to make the P action’s vibration subsiding and the system
stabilizing, the PD control could be utilized. In other words, this control is good for use with
loadings of no brake functions over the processes.
 PID Control: Utilize the I action to eliminate the deviation and the D action to restrain the vibration,
thereafter, combine with the P action to construct the PID control. Use of the PID method could
obtain a control process with no deviations, high accuracies and a stable system.
 Serial connection
Input Selection of the
PID Target Value
00-20:KPC-CC01/
RS485
03-00~02:4 PID target
value

1

PID Cancelled
08-00=0
or 02-01~06=21(disable)

Frequency
command

2

+

-

Display of the PID feedback
00-04=10 display of the
PID feedback

PID
Compensation
Selection
08-16

P
Proportion
gain

D

+

Differential
Time

08-01

PID
Delay
Time
08-07

+

+

08-03

PID
direction

I

Input Selection
of the PID Feedback
08-00:AVI/ACI
AUI/PG

+

08-05
PID Freq.
output
command
limit

08-21

08-02
08-04
Integral Time upper
limit
for
Integral

08-09
Treatment of the
Feedback Signal Fault
If Hz>08-05
time exceeds 08-08

 Parallel connection
Input Selection of the
PID Target Value
00-20:KPC-CC01/RS485
03-00~02:4 PID target value

PID Cancelled

08-00=0
or 02-01~06=21(disable)

Frequency
command

1
2

P

PID
compensation
selection
08-16

Proportion gain

08-01

+

Display of the PID feedback
00-04=10 display of the
PID feedback

-

D

+

08-03

+

Differential
Time

I

08-02
Input Selection
of the PID Feedback
08-00:AVI/ACI
AUI/PG

Integral Time

08-05

08-21

08-04
upper limit
for
Integral

+

PID Delay Time
08-07

PID F req.
output
command limit

08-09
Treatment of the Feedback Signal Fault
If Hz>08-05, time exceeds 08-08

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Chapter 12 Description of Parameter SettingsC2000 Series



Feedback Signal Detection Time
Factory Setting: 0.0
Settings

0.0~3600.0 sec

 Pr.08-08 is valid only for ACI 4-20mA.
 This parameter sets the detection time of abnormal PID derative. If detection time is set to 0.0,
detection function is disabled.


Feedback Signal Fault Treatment
Factory Setting: 0
Settings

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop
3: Warn and operate at last frequency

 This parameter is valid only for ACI 4-20mA.
 AC motor drive acts when the feedback signals analog PID feedback is abnormal.


Sleep Reference
Factory Setting: 0.00
Settings

0.00~600.00Hz

 Setting value of Pr08-10 determines if sleep reference and wake-up reference is enable or disable.
When Pr08-10 = 0, it means disable. When 08-10 ≠ 0, it means enable.


Wake-up Reference
Factory Setting: 0.00
Settings

0.00~600.00Hz

 When Pr08-18 = 0, the unit of Pr08-10 and that of Pr08-11 become frequency. The settings then
become 0 ~ 600.0 Hz.
 When Pr08-18=1, the unit of Pr08-10 and that of Pr08-11 switch to percentage. The settings then
switch to 0~200.00%.
 And the percentage is based on the input command not maximum. E.g. If the maximum is 100 Kg,
the command now is 30kg, if 08-11=40%, it is 12kg.
 The same to 08-10.


Sleep Time
Factory Setting: 0.0
Settings

0.00~6000.0 sec

 When the frequency command is smaller than the sleep frequency and less than the sleep time,
the frequency command is equal to the sleep frequency. However the frequency command
remains at 0.00Hz until the frequency command becomes equal to or bigger than the wake-up
frequency.


PID Deviation Level
Factory Setting: 10.0
Settings

1.0~50.0%
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Chapter 12 Description of Parameter SettingsC2000 Series



PID Deviation Time
Factory Setting: 5.0
Settings



0.1~300.0 sec

Filter Time for PID Feedback
Factory Setting: 5.0
Settings

0.1~300.0 sec

 When the PID control function is normal, it should calculate within a period of time and close to the
target value.
 Refer to the PID control diagram for details. When executing PID feedback control, if |PID
reference target value – detection value| > Pr.08-13 PID Deviation Level and exceeds Pr.08-14
setting, it will be judged as the PID control fault. Multiple-funtion output MO=15 (PID feedback
error) will activate.


PID Compensation Selection
Factory Setting: 0
Settings

0: Parameter setting (Pr.08-17)

1: Reserved
 Pr08-16=0: PID compensation value is given via Pr08-17 setting.
 Pr08-16=1: The PID compensation value is given via analog input(Pr03-00~03-02=13) and display
at Pr08-17(at this moment, Pr08-17 become read only).


PID Compensation
Factory Setting: 0
Settings

-100.0~+100.0%

 The PID compensation value=Max. PID target value×Pr08-17. For example, the max. output
frequency Pr01-00=60Hz, Pr08-17=10.0%, PID compensation value will increase output
frequency 6.00Hz. 60.00Hz × 100.00% × 10.0% = 6.00Hz
Setting of Sleep Mode Function
Factory Setting: 0
Settings

0: Follow PID output command
1: Follow PID feedback signal

 When Pr08-18=0, the unit of Pr08-10 and that of Pr08-11 becomes frequency. The settings then
become 0~600.00Hz.

 When Pr08-18=1, the unit of Pr08-10 and that of Pr08-11 switches to percentage. The settings
then switch to 0~200.00%.


Wake-up Integral Limit
Factory Setting: 50.0
Settings

0.0~200.0%

 The wake-up integral limit of the VFD is to prevent sudden high speed running when the VFD
wakes up.
 The wake-up integral frequency limit=(01-00×08-19%)
 The Pr08-19 is used to reduce the reaction time from sleep to wake-up.
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Chapter 12 Description of Parameter SettingsC2000 Series

Enable PID to Change the Operation Direction
Factory Setting: 0
Settings

0: Disable change of direction
1: Enable change of direction



Wake-up delay time
Factory Setting: 0.00
Settings

0.00~600.00 sec.

 Refer to Pr08-18 for more information.


PID Control Bit
Factory Setting: 0
Settings

Bit0 =1, PID reverse running must follow the setting of Pr00-23
Bit0 = 0, PID reverse running follows PID’s calculated value

 Bit0, When Pr08-21 = 1, PID reverse running is enable..
 Bit0 = 0, if the PID calculated value is positive, it will be forward running. If the PID calculated value
is negative, it will be reverse running.
There are three scenarios for sleep and wake-up frequency.
1) Frequency Command (PID is not in use, Pr08-=00. Only works in VF mode)
When the output frequency ≦ the sleep frequency, and the VFD reaches the preset sleep time,
then the VFD will be at the sleep mode.
When the frequency command reaches the wake-up frequency, the VFD will start to count the
wake-up delay time. Then when the VFD reaches the wake-up delay time, the VFD will begin
acceleration time to reach the frequency command.
frequency command
actual output frequency

Pr08-11
Wake -up
R eference Point

Frequency
Command

ActualOutputFrequency

Pr08-10
Sleep
Reference Point
Pr08-12
Sleep Time

0Hz

Pr08-22
Wake-up
Delay
Time

2) Frequency Command Calculation of the Internal PID
When the PID calculation reaches the sleep frequency, the VFD will start to count the sleep
time and the output frequency will start to decrease. If the VFD exceeds the preset sleep time, it will
directly go to sleep mode which is 0 Hz. But if the VFD doesn’t reach the sleep time, it will remain at
the lower limit (if there is a preset of lower limit.). Or it will remain at the lowest output frequency set
at Pr01-07 and wait to reach the sleep time then go to sleep mode (0 Hz).

12-08-8

Chapter 12 Description of Parameter SettingsC2000 Series

When the calculated frequency command reaches the wake-up frequency, the VFD will start to
count the wake-up delay time. Once reaching the wake-up delay time, the VFD will start the
acceleration time to reach the PID frequency command.
frequency command
output frequency

Acceleration
Time Limit

Pr08-22
Wake-up
Delay Time

3) PID Feedback Rate Percentage ( Use PID, Pr08-00 ≠ 0 and Pr08-18=1)
When the PID feedback rate reaches the sleep level percentage, the VFD starts to count the
sleep time. The output frequency will also decrease. If the VFD exceeds the preset sleep time, it will
go to sleep mode which is 0 Hz. But if the VFD doesn’t reach the sleep time, it will remain at the
lower limit (if there is a preset of lower limit.). Or it will remain at the lowest output frequency set at
Pr01-07 and wait to reach the sleep time then go to sleep mode (0 Hz).
When PID feedback value reaches the wake up percentagethe motor drive will start to count
the wake up delay time. Once reaches the wake up delay time, the motor drives starts the
accelerating time to reach PID frequency command
Output
Frequency

PID
Feedback

Setpoint

Pr08-10
Sleep Reference Point
Pr08-11
Wake-up Reference Point

Pr01-11
Output Frequency
Lower Limit
Pr01-07/Pr01-41

Pr08-12
Sleep Time

12-08-9

Pr08-22
Wake-up
Delay Time

Chapter 12 Description of Parameter SettingsC2000 Series

09 Communication Parameters

 The parameter can be set during the operation.
8

1

When us ing communication devi ces,
connects AC dr ive with P C by us ing
Delta IFD6530 or IFD6500.
RS-485



Modbus RS- 485
Pin
Pin
Pin
Pin

1~2,7,8: Reserv ed
3, 6: GND
4: SG5: SG+

COM1 Communication Address
Factory Setting: 1
Settings

1~254

 If the AC motor drive is controlled by RS-485 serial communication, the communication address
for this drive must be set via this parameter and each AC motor drive’s communication address
must be different.


COM1 Transmission Speed
Factory Setting: 9.6
Settings

4.8~115.2Kbits/s

 This parameter is for set up the RS485 communication transmission speed.


COM1 Transmission Fault Treatment
Factory Setting: 3
Settings

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop
3: No warning and continue operation

 This parameter is to set the reaction of MODBUS transmission errors with the host. Detection time
can be set in Pr09-03.


COM1 Time-out Detection
Factory Setting: 0.0
Settings

0.0~100.0 sec
0.0: Disable

 It is used to set the communication transmission time-out..


COM1 Communication Protocol
Factory Setting: 1
Settings

1: 7, N, 2 for ASCII
2: 7, E, 1 for ASCII
3: 7, O, 1 for ASCII
4: 7, E, 2 for ASCII
5: 7, O, 2 for ASCII
6: 8, N, 1 for ASCII
7: 8, N, 2 for ASCII
8: 8, E, 1 for ASCII
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Chapter 12 Description of Parameter SettingsC2000 Series

9: 8, O, 1 for ASCII
10: 8, E, 2 for ASCII
11: 8, O, 2 for ASCII
12: 8, N, 1 for RTU
13: 8, N, 2 for RTU
14: 8, E, 1 for RTU
15: 8, O, 1 for RTU
16: 8, E, 2 for RTU
17: 8, O, 2 for RTU
 Control by PC or PLC (Computer Link)
 A VFD-C2000 can be set up to communicate on Modbus networks using one of the following
modes: ASCII (American Standard Code for Information Interchange) or RTU (Remote Terminal
Unit).Users can select the desired mode along with the RS-485 serial port communication
protocol in Pr.09-00.
 MODBUS ASCII（American Standard Code for Information Interchange）: Each byte data is the
combination of two ASCII characters. For example, a 1-byte data: 64 Hex, shown as ‘64’ in ASCII,
consists of ‘6’ (36Hex) and ‘4’ (34Hex).
1. Code Description
Communication protocol is in hexadecimal, ASCII: ”0”, “9”, “A”, “F”, every 16 hexadecimal
represent ASCII code. For example:
Character

‘0’

‘1’

‘2’

‘3’

‘4’

‘5’

‘6’

‘7’

ASCII code

30H

31H

32H

33H

34H

35H

36H

37H

Character

‘8’

‘9’

‘A’

‘B’

‘C’

‘D’

‘E’

‘F’

ASCII code

38H

39H

41H

42H

43H

44H

45H

46H

2. Data Format
10-bit character frame (For ASCII):
（7, N , 2）
Start
bit

0

1

2

3

4

5

6

5

6

Stop
bit

Stop
bit

7-data bits
10-bits character frame

（7 , E , 1）
Start
bit

0

1

2

3

4

7-data bits
10-bits character frame
12-09-2

Even
parity

Stop
bit

Chapter 12 Description of Parameter SettingsC2000 Series

（7 , O , 1）
Start
bit

0

1

2

3

4

5

6

Odd
parity

Stop
bit

5

6

7

Stop
bit

Stop
bit

6

7

Even
parity

Stop
bit

6

7

Odd
parity

Stop
bit

7-data bits
10-bits character frame

11-bit character frame (For RTU):
（8 , N , 2）
Start
bit

0

1

2

3

4

8-data bits
11-bits character frame

（8 , E , 1）
Start
bit

0

1

2

3

4

5

8-data bits
11-bits character frame

（8 , O , 1）
Start
bit

0

1

2

3

4

5

8-data bits
11-bits character frame

3. Communication Protocol
Communication Data Frame: ASCII mode
STX
Address Hi
Address Lo
Function Hi
Function Lo
DATA (n-1)
…….

Start character = ‘:’ (3AH)
Communication address:
8-bit address consists of 2 ASCII codes
Command code:
8-bit command consists of 2 ASCII codes
Contents of data:
Nx8-bit data consist of 2n ASCII codes
n<=16, maximum of 32 ASCII codes

DATA 0
LRC CHK Hi
LRC CHK Lo
END Hi
END Lo

LRC check sum:
8-bit check sum consists of 2 ASCII codes
End characters:
END1= CR (0DH), END0= LF(0AH)

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Chapter 12 Description of Parameter SettingsC2000 Series

Communication Data Frame: RTU mode
START

A silent interval of more than 10 ms

Address

Communication address: 8-bit address

Function

Command code: 8-bit command
Contents of data:
n×8-bit data, n<=16

DATA (n-1)
…….
DATA 0
CRC CHK Low
CRC CHK High
END

CRC check sum:
16-bit check sum consists of 2 8-bit characters
A silent interval of more than 10 ms

Address (Communication Address)
Valid communication addresses are in the range of 0 to 254. A communication address equal to
0, means broadcast to all AC drives (AMD). In this case, the AMD will not reply any message to the
master device.
00H: broadcast to all AC drives
01H: AC drive of address 01
0FH: AC drive of address 15
10H: AC drive of address 16
:
FEH: AC drive of address 254
Function (Function code) and DATA (data characters)
The format of data characters depends on the function code.
03H: read data from register
06H: write single register
Example: reading continuous 2 data from register address 2102H, AMD address is 01H.
ASCII mode:
Command Message:
STX
Address
Function

Starting register

Number of register
(count by word)
LRC Check
END

Response Message
STX

‘:’
‘0’
‘1’
‘0’
‘3’
‘2’
‘1’
‘0’
‘2’
‘0’
‘0’
‘0’
‘2’
‘D’
‘7’
CR
LF

Address
Function
Number of register
(count by byte)
Content of starting
register 2102H

Content of register 2103H

LRC Check
END

12-09-4

‘:’
‘0’
‘1’
‘0’
‘3’
‘0’
‘4’
‘1’
‘7’
‘7’
‘0’
‘0’
‘0’
‘0’
‘0’
‘7’
‘1’
CR
LF

Chapter 12 Description of Parameter SettingsC2000 Series

RTU mode:
Command Message:
Address
01H
Function
03H
21H
Starting data register
02H
00H
Number of register
(count by world)
02H
CRC CHK Low
6FH
CRC CHK High
F7H

Response Message
Address
Function
Number of register
(count by byte)
Content of register
address 2102H
Content of register
address 2103H
CRC CHK Low
CRC CHK High

17H
70H
00H
00H
FEH
5CH

06H: single write, write single data to register.
Example: writing data 6000(1770H) to register 0100H. AMD address is 01H.
ASCII mode:
Command Message:
Response Message
STX
‘:’
STX
‘0’
Address
Address
‘1’
‘0’
Function
Function
‘6’
‘0’
‘1’
Target register
Target register
‘0’
‘0’
‘1’
‘7’
Register content
Register content
‘7’
‘0’
‘7’
LRC Check
LRC Check
‘1’
CR
END
END
LF

‘:’
‘0’
‘1’
‘0’
‘6’
‘0’
‘1’
‘0’
‘0’
‘1’
‘7’
‘7’
‘0’
‘7’
‘1’
CR
LF

RTU mode:
Command Message:
Address
01H
Function
06H
01H
Target register
00H
17H
Register content
70H
CRC CHK Low
86H
CRC CHK High
22H

01H
03H
04H

Response Message
Address
01H
Function
06H
01H
Target register
00H
17H
Register content
70H
86H
CRC CHK Low
CRC CHK High
22H

10H: write multiple registers (write multiple data to registers) (at most 20 sets of data can be written
simultaneously)
Example: Set the multi-step speed,
Pr.04-00=50.00 (1388H), Pr.04-01=40.00 (0FA0H). AC drive address is 01H.

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Chapter 12 Description of Parameter SettingsC2000 Series

ASCII Mode
Command Message:
STX
ADR 1
ADR 0
CMD 1
CMD 0
Target register

Number of register
(count by word)
Number of register
(count by Byte)
The first data content

The second data content

LRC Check
END

Response Message
STX
ADR 1
ADR 0
CMD 1
CMD 0

‘:’
‘0’
‘1’
‘1’
‘0’
‘0’
‘5’
‘0’
‘0’
‘0’
‘0’
‘0’
‘2’
‘0’
‘4’
‘1’
‘3’
‘8’
‘8’
‘0’
‘F’
‘A’
‘0’
‘9’
‘A’
CR
LF

Target register

Number of register
(count by word)
LRC Check
END

RTU mode:
Command Message:
ADR
01H
CMD
10H
05H
Target register
00H
00H
Number of register
(Count by word)
02H
Quantity of data (Byte)
04
13H
The first data content
88H
0FH
The second data content
A0H
CRC Check Low
‘9’
CRC Check High
‘A’

‘:’
‘0’
‘1’
‘1’
‘0’
‘0’
‘5’
‘0’
‘0’
‘0’
‘0’
‘0’
‘2’
‘E’
‘8’
CR
LF

Response Message:
ADR
01H
CMD 1
10H
05H
Target register
00H
Number of register
00H
(Count by word)
02H
CRC Check Low
41H
CRC Check High
04H

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Chapter 12 Description of Parameter SettingsC2000 Series

Check sum
ASCII mode:
LRC (Longitudinal Redundancy Check) is calculated by summing up, module 256, and the values
of the bytes from ADR1 to last data character then calculating the hexadecimal representation of the
2’s-complement negation of the sum.
For example,
01H+03H+21H+02H+00H+02H=29H, the 2’s-complement negation of 29H is D7H.
RTU mode:
CRC (Cyclical Redundancy Check) is calculated by the following steps:
Step 1:
Load a 16-bit register (called CRC register) with FFFFH.
Step 2:
Exclusive OR the first 8-bit byte of the command message with the low order byte of the 16-bit CRC
register, putting the result in the CRC register.
Step 3:
Examine the LSB of CRC register.
Step 4:
If the LSB of CRC register is 0, shift the CRC register one bit to the right with MSB zero filling, then
repeat step 3. If the LSB of CRC register is 1, shift the CRC register one bit to the right with MSB
zero filling, Exclusive OR the CRC register with the polynomial value A001H, then repeat step 3.
Step 5:
Repeat step 3 and 4 until eight shifts have been performed. When this is done, a complete 8-bit
byte will have been processed.
Step 6:
Repeat step 2 to 5 for the next 8-bit byte of the command message. Continue doing this until all
bytes have been processed. The final contents of the CRC register are the CRC value. When
transmitting the CRC value in the message, the upper and lower bytes of the CRC value must be
swapped, i.e. the lower order byte will be transmitted first.
The following is an example of CRC generation using C language. The function takes two
arguments:
Unsigned char* data  a pointer to the message buffer
Unsigned char length  the quantity of bytes in the message buffer
The function returns the CRC value as a type of unsigned integer.
Unsigned int crc_chk(unsigned char* data, unsigned char length)

12-09-7

Chapter 12 Description of Parameter SettingsC2000 Series

{
int j;
unsigned int reg_crc=0Xffff;
while(length--){
reg_crc ^= *data++;
for(j=0;j<8;j++){
if(reg_crc & 0x01){

/* LSB(b0)=1 */

reg_crc=(reg_crc>>1) ^ 0Xa001;
}else{
reg_crc=reg_crc >>1;
}
}
}
return reg_crc;

// return register CRC

}

4. Address list
Content
Register
Function
AC drive parameters GGnnH GG means parameter group, nn means parameter number, for
example, the address of Pr 4-01 is 0401H.
Command write only 2000H
Bit1~0 00B：No function
01B：Stop
10B：Run
11B：JOG+RUN
Bit3~2 Reserved
Bit5~4 00B：No function
01B：FWD
10B：REV
11B：Change direction
Bit7~6 00B：1st accel/decel.
01B：2nd accel/decel
10B：3rd accel/decel
11B：4th accel/decel
Bit11~8 000B: master speed
0001B: 1st Step Speed Frequency
0010B: 2nd Step Speed Frequency
0011B: 3rd Step Speed Frequency
0100B: 4th Step Speed Frequency
0101B: 5th Step Speed Frequency
0110B: 6th Step Speed Frequency
0111B: 7th Step Speed Frequency
1000B: 8th Step Speed Frequency
1001B: 9th Step Speed Frequency
1010B: 10th Step Speed Frequency
1011B: 11th Step Speed Frequency
1100B: 12th Step Speed Frequency
1101B: 13th Step Speed Frequency
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Chapter 12 Description of Parameter SettingsC2000 Series

Content

Register

2001H
2002H

Status monitor read
only

2100H
2101H

2102H
2103H
2104H

2105H
2106H
2107H
2108H
2109H
210AH

Function
1110B: 14th Step Speed Frequency
1111B: 15th Step Speed Frequency
Bit12 1: Enable bit06-11 function
Bit14~13 00B：No function
01B：Operated by digital keypad
10B：Operated by Pr.00-21 setting
11B：Change operation source
Bit15 Reserved
Frequency command(XXX.XXHz)
1：EF (external fault) on
Bit0
1：Reset
Bit1
1：B.B ON
Bit2
Bit15~3 Reserved
High byte: Warn Code
Low Byte: Error Code
Bit1~0 AC Drive Operation Status
00B: Drive stops
01B: Drive decelerating
10B: Drive standby
11B: Drive operating
Bit2
1：JOG Command
Bit4~3 Operation Direction
00B: FWD run
01B: From REV run to FWD run
10B: REV run
11B: From FWD run to REV run
Bit8
1：Master frequency controlled by communication
interface
Bit9
1：Master frequency controlled by analog signal
Bit10 1：Operation command controlled by
communication interface
Bit11 1：Parameter locked
Bit12 1：Enable to copy parameters from keypad
Bit15~13 Reserved
Frequency command （XXX.XX Hz）
Output frequency （XXX.XX Hz）
Output current（XX.XXA）. When current is higher than
655.35,it will shift decimal as（XXX.XA）. The decimal can refer
to High byte of 211F.
DC-BUS Voltage （XXX.XV）
Output voltage（XXX.XV）
Current step number of Multi-Step Speed Operation
Reserved
Counter value
Power Factor Angle (XXX.X)

210BH Output Torque （XXX.X%）
210CH Actual motor speed（XXXXXrpm)
210DH Number of PG feed back pulses（0~65535）
210EH Number of PG2 pulse commands（0~65535）
210FH Power output （X.XXX KWH）
2116H Multi-function display (Pr.00-04)

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Chapter 12 Description of Parameter SettingsC2000 Series

Content

Register

211BH

211FH
2200H
2201H
2202H
2203H
2204H
2205H
2206H
2207H
2208H
2209H
220AH
220BH
220CH
220DH
220EH
220FH
2210H
2211H
2212H
2213H
2214H
2215H
2216H
2217H
2218H
2219H
221AH
221BH
221CH
221DH
221EH
221FH

Function
Max. opeartion frequency (Pr.01-00) or Max. user defined
value (Pr.00-26)
When Pr00-26 is 0, this value is equal to Pr01-00 setting
When Pr00-26 is not 0, and the command source is Keypad,
this value = Pr00-24 * Pr00-26 / Pr01-00
When Pr00-26 is not 0, and the command source is 485, this
value = Pr09-10 * Pr00-26 / Pr01-00
High byte: decimal of current value (display)
Display output current (A). When current is higher than
655.35,it will shift decimal as（XXX.XA）. The decimal can refer
to High byte of 211F.
Display counter value (c)
Actual output frequency（XXXXXHz）
DC-BUS voltage（XXX.XV）
Output voltage（XXX.XV）
Power angle（XXX.X）
Display actual motor speed kW of U, V, W（XXXXXkW）
Display motor speed in rpm estimated by the drive or encoder
feedback（XXXXXrpm）
Display positive/negative output torque in %, estimated by the
drive (t0.0: positive torque, -0.0: negative torque)（XXX.X%）
Display PG feedback (as Pr. 00-04 NOTE 1)
PID feedback value after enabling PID function（XXX.XX%）
Display signal of AVI analog input terminal, 0-10V corresponds
to 0.00~100.00% (1.) (as Pr. 00-04 NOTE 2)
Display signal of ACI analog input terminal, 4-V20mA/0-10V
corresponds to 0.00~100.00% (2.) (as Pr. 00-04 NOTE 2)
Display signal of AUI analog input terminal, -10V~10V
corresponds to -100.00~100% (3.) (as Pr. 00-04 NOTE 2)
IGBT temperature of drive power module （XXX.X℃）
The temperature of capacitance （XXX.X℃）
The status of digital input (ON/OFF), refer to Pr.02-12 (as Pr.
00-04 NOTE 3)
The status of digital output (ON/OFF), refer to Pr.02-18 (as Pr.
00-04 NOTE 4)
The multi-step speed that is executing (S)
The corresponding CPU pin status of digital input (d.) (as Pr.
00-04 NOTE 3)
The corresponding CPU pin status of digital output (O.) (as Pr.
00-04 NOTE 4)
Number of actual motor revolution (PG1 of PG card) (P.) it will
start from 9 when the actual operation direction is changed or
keypad display at stop is 0. Max. is 65535
Pulse input frequency (PG2 of PG card)（XXX.XXHz）
Pulse input position (PG card PG2), maximum setting is
65535.
Position command tracing error
Display times of counter overload（XXX.XX%）
GFF（XXX.XX%）
DCbus voltage ripples（XXX.XV）
PLC register D1043 data (C)
Pole of Permanent Magnet Motor
User page displays the value in physical measure
Output Value of Pr.00-05（XXX.XXHz）

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Chapter 12 Description of Parameter SettingsC2000 Series

Content

Register
2220H
2221H
2222H
2223H
2224H
2225H

2226H

2227H
2228H
2229H
222AH
222BH
222CH
222DH
222EH
222FH
2230H

Function
Number of motor tunrns when drive operates (keeping when
drive stops, and reset to zero when operation)
Opeartion position of motor (keeping when drive stops, and
reset to zero when operation)
Fan speed of the drive（XXX%）
Control mode of the drive 0: speed mode 1: torque mode
Carrier frequency of the drive（XXKHZ）
Reserve
Drive status
bit 1~0
00b: No direction
01b: Forward
10b: Reverse
bit 3~2
01b: Driver ready
10b: Error
bit 4
0b: Motor drive did not output
1b: Motor drive did output
bit 5
0b: No alarm
1b: Have Alarm
Drive’s estimated output torque(positive or negative direction)
（XXXX Nt-m）
Torque command（XXX.X%）
KWH display（XXXX.X）
PG2 pulse input in Low Word
PG2 pulse input in High Word
Motor actual position in Low Word
Motor actual position in High Word
PID reference（XXX.XX%）
PID offset（XXX.XX%）
PID output frequency（XXX.XXHz）

5. Exception response:
The AC motor drive is expected to return a normal response after receiving command messages
from the master device. The following depicts the conditions when no normal response is replied to
the master device.
The AC motor drive does not receive the messages due to a communication error; thus, the AC
motor drive has no response. The master device will eventually process a timeout condition.
The AC motor drive receives the messages without a communication error, but cannot handle
them. An exception response will be returned to the master device and an error message “CExx”
will be displayed on the keypad of AC motor drive. The xx of “CExx” is a decimal code equal to the
exception code that is described below.
In the exception response, the most significant bit of the original command code is set to 1, and
an exception code which explains the condition that caused the exception is returned.
Example:
ASCII mode:
STX
Address
Function
Exception code
LRC CHK
END

RTU mode:
Address
Function
Exception code
CRC CHK Low
CRC CHK High

‘:’
‘0’
‘1’
‘8’
‘6’
‘0’
‘2’
‘7’
‘7’
CR
LF
12-09-11

01H
86H
02H
C3H
A1H

Chapter 12 Description of Parameter SettingsC2000 Series

The explanation of exception codes:
Exception
code
1
2
3
4

~


Explanation
Function code is not supported or unrecognized.
Address is not supported or unrecognized.
Data is not correct or unrecognized.
Fail to execute this function code

Reserved
Response Delay Time
Factory Setting: 2.0
Settings

0.0~200.0ms

 This parameter is the response delay time after AC drive receives communication command as
shown in the following.
RS-485 BUS
PC or PLC command
Handling time
of the AC drive

Response Delay Time
Pr.09-09

Response Message
of the AC Drive

Main Frequency of the Communication
Factory Setting: 60.00
Settings

0.00~600.00Hz

 When Pr.00-20 is set to 1 (RS485 communication). The AC motor drive will save the last
frequency command into Pr.09-10 when abnormal turn-off or momentary power loss. After reboots
the power, it will regard the frequency set in Pr.09-10 if no new frequency command is inputted.
When frequence command of 485 is changed (the source of frequence command needs to be set
as MODBUS), this parameter is also be changed.


Block Transfer 1



Block Transfer 2



Block Transfer 3



Block Transfer 4



Block Transfer 5



Block Transfer 6



Block Transfer 7



Block Transfer 8



Block Transfer 9



Block Transfer 10



Block Transfer 11



Block Transfer 12



Block Transfer 13



Block Transfer 14

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Chapter 12 Description of Parameter SettingsC2000 Series



Block Transfer 15



Block Transfer 16
Factory Setting: 0
Settings

0~65535

 There is a group of block transfer parameter available in the AC motor drive (Pr.09-11 to Pr.09-26).
Through communication code 03H, user can use them (Pr.09-11 to Pr.09-26) to save those
parameters that you want to read.

~

Reserved
Communication Decoding Method
Factory Setting: 1
Settings

0: Decoding Method 1
1: Decoding Method 2

Source of
Digital Keypd
Operation External Terminal
Control
RS-485
CANopen
Communication
Card
PLC

Decoding Method 1
Decoding Method 2
Digital keypad controls the drive action regardless decoding method 1 or 2.
External terminal controls the drive action regardless decoding method 1 or 2.
Refer to address: 2000h~20FFh
Refer to address: 6000h ~ 60FFh
Refer to index: 2020-01h~2020-FFh
Refer to index:2060-01h ~ 2060-FFh
Refer to address: 2000h ~ 20FFh

Refer to address: 6000h ~ 60FFh

PLC commands the drive action regardless decoding method 1 or 2.

Internal Communication Protocol
Factory Setting: 0
Settings

0: Modbus 485
-1: Internal Communication Slave 1
-2: Internal Communication Slave 2
-3: Internal Communication Slave 3
-4: Internal Communication Slave 4
-5: Internal Communication Slave 5
-6: Internal Communication Slave 6
-7: Internal Communication Slave 7
-8: Internal Communication Slave 8
-9: Reserve
-10: Internal Communication Master
-11: Reserve
-12: Internal PLC Control

 When it is defined as internal communication, see CH16-10 for information on Main Control
Terminal of Internal Communication.
 When it is defined as internal PLC control, see CH16-12 for Remote IO control application ( by
using MODRW).
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Chapter 12 Description of Parameter SettingsC2000 Series

Reserved


PLC command force to 0
Factory Setting：0
Setting

0~65535

 It defines the action that before PLC scans time sequence, the frequence command or speed
command needs to be cleared as 0 or not.
Bit
Explanation
Bit0
Before PLC scan, set up PLC target frequency=0
Bit1
Before PLC scan, set up the PLC target torque=0
Bit2
Before PLC scan, set up the speed limit of torque control mode=0
PLC Address
Factory Setting: 2
Settings

1~254

CANopen Slave Address
Factory Setting: 0
Settings

0: Disable
1~127

CANopen Speed
Factory Setting: 0
Settings

0: 1M
1: 500k
2: 250k
3: 125k
4: 100k (Delta only)
5: 50k

Reserved
CANopen Warning Record
Factory Setting: Read only
Settings

bit 0: CANopen Guarding Time out
bit 1: CANopen Heartbeat Time out
bit 2: CANopen SYNC Time out
bit 3: CANopen SDO Time out
bit 4: CANopen SDO buffer overflow
bit 5: Can Bus Off
bit 6: Error protocol of CANOPEN
bit 7: Reserved
bit 8: The setting values of CANopen indexs are fail
bit 9: The setting value of CANopen address is fail
bit10: The checksum value of CANopen indexs is fail

12-09-14

Chapter 12 Description of Parameter SettingsC2000 Series

CANopen Decoding Method
Factory Setting: 1
Settings

0: Delta defined decoding method
1: CANopen Standard DS402 protocol

CANopen Status
Factory Setting: 0
Settings

0: Node Reset State
1: Com Reset State
2: Boot up State
3: Pre Operation State
4: Operation State
5: Stop State

CANopen Control Status
Factory Setting: Read Only
Settings

0: Not ready for use state
1: Inhibit start state
2: Ready to switch on state
3: Switched on state
4: Enable operation state
7: Quick stop active state
13: Err reaction activation state
14: Error state

Reset CANopen Index
Factory Setting: 65535
Settings: bit0: reset address 20XX to 0
bit1: reset address 264X to 0
bit2: reset address 26AX to 0
bit3: reset address 60XX to 0
Reserved
CANopen Master Function
Factory Setting: 0
Settings

0: Disable
1: Enable

CANopen Master Address
Factory Setting: 100
Settings
~

1~127

Reserved

12-09-15

Chapter 12 Description of Parameter SettingsC2000 Series

Identifications for Communication Card
Factory Setting: ##
Settings

0: No communication card
1: DeviceNet Slave
2: Profibus-DP Slave
3: CANopen Slave/Master
4: Modbus-TCP Slave
5: EtherNet/IP Slave
6~8: Reserved

Firmware Version of Communication Card
Factory Setting: ##
Settings

Read only

Product Code
Factory Setting: ##
Settings

Read only

 Different communication cards have their own product codes with different value.
DeviceNet: As it connects to different kind of motor drive, it will have different product code.
Profibus: ID number of a communication card. Each Profibus selling in the market must apply for
an ID number at the Profibus International to be a unique product.
Fault Code
Factory Setting: ##
Settings

Read only

 For more information about Fault codes, refer to Pr. 06-17~06-22 and Chapter 14.

~


Reserved
Address of Communication Card
Factory Setting: 1
Settings

DeviceNet: 0-63
Profibus-DP: 1-125



Setting of DeviceNet Speed (according to Pr.09-72)
Factory Setting: 2
Settings

Standard DeviceNet:
0: 125Kbps
1: 250Kbps
2: 500Kbps
Non standard DeviceNet:

(Delta only)

0: 10Kbps
1: 20Kbps
2: 50Kbps
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Chapter 12 Description of Parameter SettingsC2000 Series

3: 100Kbps
4: 125Kbps
5: 250Kbps
6: 500Kbps
7: 800Kbps
8: 1Mbps


Other Setting of DeviceNet Speed
Factory Setting: 0
Settings

0: Standard DeviceNet
1: Non standard DeviceNet

 It needs to use with Pr.09-71.
 Setting 0: the baud rate can only be set to 0, 1, 2 or 3.
 Setting 1: setting of DeviceNet communication rate can be the same as CANopen (setting 0-8).
Reserved
Reserved


IP Configuration of the Communication Card
Factory Setting: 0
Settings

0: Static IP
1: DynamicIP (DHCP)

 Setting 0: it needs to set IP address manually.
 Setting 1: IP address will be auto set by host controller.


IP Address 1 of the Communication Card



IP Address 2 of the Communication Card



IP Address 3 of the Communication Card



IP Address 4 of the Communication Card
Factory Setting: 0
Settings

0~255

 Pr.09-76~09-79 needs to use with communication card.


Address Mask 1 of the Communication Card



Address Mask 2 of the Communication Card



Address Mask 3 of the Communication Card



Address Mask 4 of the Communication Card
Factory Setting: 0
Settings

0~255

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Chapter 12 Description of Parameter SettingsC2000 Series



Getway Address 1 of the Communication Card



Getway Address 2 of the Communication Card



Getway Address 3 of the Communication Card



Getway Address 4 of the Communication Card
Factory Setting: 0
Settings

0~255



Password for Communication Card (Low word)



Password for Communication Card (High word)
Factory Setting: 0
Settings



0~255

Reset Communication Card
Factory Setting: 0
Settings

0: Disable
1: Reset, return to factory setting



Additional Setting for Communication Card
Factory Setting: 1
Settings

Bit 0: Enable IP Filter
Bit 1: Internet parameters enable(1bit)
When IP address is set up, this bit need to be enabled to write down the
parameters. This bit will change to disable when it finishes saving the
update of internet parameters.
Bit 2: Login password enable(1bit)
When enter login password, this bit will be enabled. After updating the
parameters of communication card, this bit will change to disable.

Status of Communication Card
Factory Setting: 0
Settings

Bit 0: password enable
When the communication card is set with password, this bit is enabled.
When the password is clear, this bit is disabled.

12-09-18

Chapter 12 Description of Parameter SettingsC2000 Series

10 PID Control

 This parameter can be set during operation.

In this parameter group, ASR is the abbreviation for Adjust Speed Regulator and PG is the
abbreviation for Pulse Generator.
Encoder Type Selection
Factory Setting: 0
Settings

0: Disable
1: ABZ
2: ABZ (Delta encoder for Delta Servo motor)
3: Resolver
4: ABZ/UVW
5. MI8 single phase pulse input

 For PG extension card EMC-PG01L and EMC-PG01O, set Pr.10-00=1. These extension cards
are for IM motor only.
 For EMC-PG01U, when setting Pr.10-00=2 (Delta encoder) make sure SW1 is switched to D
(Delta type). If the setting for Pr.10-00, 10-01 and 10-02 has changed, please turn off the drive’s
power and reboots to prevent PM motor stall. This mode is suggested for PM motor.
 For EMC-PG01R, when setting Pr.10-00=3 please also input 1024 ppr.
 For EMC-PG01U, when setting Pr.10-00=4 (Standard ABZ/UVW Encoder) make sure SW1 is
switched to S (Standard Type). This mode is applicable for both IM and PM motor.
 When using MI8 single phase pulse input as frequency command, the Pr10-02 must set “5:
Single-phase input”. This only can be use with VF, VFPG, SVC, IM/PM FOC Sensor-less, IM/PM
TQC Sensor-less control mode.
 When using MI8 single phase pulse as speed feedback, the drive must at VFPG control mode
only.
Encoder Pulse
Factory Setting: 600
Settings

1~20000

 A Pulse Generator (PG) or encoder is used as a sensor that provides a feedback signal of the
motor speed. This parameter defines the number of pulses for each cycle of the PG control, i.e.
the number of pulses for a cycle of A phase/B phase.
 This setting is also the encoder resolution. With the higher resolution, the speed control will be
more accurate.
 An incorrect input to Pr.10-00 may result drive over current, motor stall, PM motor magnetic pole
origin detection error. If Pr.10-00 setting has changed, please trace the magnetic pole again, set
Pr.05-00=4 (static test for PM motor magnetic pole and PG origin again).

12-10-1

Chapter 12 Description of Parameter SettingsC2000 Series

Encoder Input Type Setting
Factory Setting: 0
Settings

0: Disable
1: Phase A leads in a forward run command and phase B leads in a reverse
run command

FWD

REV

A
B

2: Phase B leads in a forward run command and phase A leads in a reverse
run command
FWD
REV
A
B

3: Phase A is a pulse input and phase B is a direction input. (L =reverse
direction, H=forward direction)

FWD

REV

A
B

4: Phase A is a pulse input and phase B is a direction input. (L=forward
direction, H=reverse direction)
REV
FWD
A
B
5:

Single-phase input

A



Output Setting for Frequency Division (denominator)
Factory Setting: 1
Settings

1~255

 This parameter is used to set the denominator for frequency division (for PG card EMC-PG01L or
EMC-PG01O). For example, when it is set to 2 with feedback 1024ppr, PG output will be
1024/2=512ppr.


Electrical Gear at Load Side A1



Electrical Gear at Motor Side B1



Electrical Gear at Load Side A2



Electrical Gear at Motor Side B2
Factory Setting: 100
Settings

1~65535

 Parameters 10-04 to 10-07 can be used with the multi-function input terminal (set to 48) to switch
to Pr.10-04~10-05 or Pr.10-06~10-07 as shown as follows

12-10-2

Chapter 12 Description of Parameter SettingsC2000 Series

PG
car d

load
encoder is us ed
at load side

Gear
B1 or B2

Gear
A1 or A2

Driv er

Motor

gear ratio
MI=48 ON = A2: B2

OFF=A 1:B 1



Treatment for Encoder/ Speed Observer Feedback Fault
Factory Setting: 2
Settings

0: Warn and keep operating
1: Warn and RAMP to stop
2: Warn and COAST to stop



Detection Time of Encoder/ Speed Observer Feedback Fault
Factory Setting: 1.0
Settings

0.0~10.0 sec
0: No function

 When encoder loss, encoder signal error, pulse signal setting error or signal error, if time exceeds
the detection time for encoder feedback fault (Pr.10-09), the encoder signal error will occur. Refer
to the Pr.10-08 for encoder feedback fault treatment.
 When speed controller signal is abnormal, if time exceeds the detection time for encoder speed
controller fault (Pr.10-09), the feedback fault will occur. Refer to the Pr.10-08 for encoder feedback
fault treatment.


Encoder/ Speed Observer Stall Level
Factory Setting: 115
Settings

0~120%
0: No function

 This parameter determines the maximum encoder feedback signal allowed before a fault occurs.
(Max. output frequency Pr.01-00 =100%)


Detection Time of Encoder/ Speed Observer Stall
Factory Setting: 0.1
Settings



0.0~2.0 sec

Treatment for Encoder/ Speed Observer Stall
Factory Setting: 2
Settings

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop

 When the motor drive output frequency exceeds Pr.1

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Chapter 12 Description of Parameter SettingsC2000 Series



Encoder/ Speed Observer Slip Range
Factory Setting: 50
Settings

0~50%
0: Disable



Detection Time of Encoder/ Speed Observer Slip
Factory Setting: 0.5
Settings



0.0~10.0 sec

Treatment for Encoder/ Speed Observer Stall and Slip Error
Factory Setting: 2
Settings

0: Warn and keep operation
1: Warn and ramp to stop
2: Warn and coast to stop

 Action principle of Pr10-13~Pr10-15:
When the value of (rotation speed – motor frequency) exceeds Pr.10-13 setting, detection time
exceeds Pr.10-14; it will start to accumulate time. If detection time exceeds Pr.10-14, the encoder
feedback signal error will occur. Refer to Pr.10-15 encoder stall and slip error treatment.


Pulse Input Type Setting (PG card: PG2)
Factory Setting: 0
Settings

0: Disable
1: Phase A leads in a forward run command and phase B leads in a reverse
run command
FW D

REV

A
B

2: Phase B leads in a forward run command and phase A leads in a reverse
run command

FW D

REV

A
B

3: Phase A is a pulse input and phase B is a direction input. (L=reverse
direction, H=forward direction)
F WD

REV

A
B

4: Phase A is a pulse input and phase B is a direction input. (L=forward
direction, H=reverse direction)
REV

FWD
A
B

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Chapter 12 Description of Parameter SettingsC2000 Series

 When this setting is different from Pr.10-02 setting and the source of the frequency command is
pulse input (Pr.00-20 is set to 4 or 5), it may have 4 times frequency problem.
Example: Assume that Pr.10-01=1024, Pr.10-02=1, Pr.10-16=3, Pr.00-20=5, MI=37 and ON, it
needs 4096 pulses to rotate the motor a revolution.
 Assume that Pr.10-01=1024, Pr.10-02=1, Pr.10-16=1, Pr.00-20=5, MI=37 and ON, it needs 1024
pulses to rotate the motor a revolution.
 Position control diagram

Position
command

d
dt
A
B
Electr ical
gear
10- 17
10- 18



Electrical Gear A



Electrical Gear B

kd
10- 21

+

kp

Position
feedbac k

11-25
+

+

Speed
command

11-00 bi t 0=0
11-24
11-00 bi t 0=1
11-05

Factory Setting: 100
Settings

1~65535

 Rotation speed = pulse frequency/encoder pulse (Pr.10-01) * PG Electrical Gear A / PG Electrical
Gear B.


Positioning for Encoder Position
Factory Setting: 0
Settings

0~65535 pulse

 This parameter determines the internal position in the position mode.
 It needs to be used with multi-function input terminal setting =35 (enable position control).
 When it is set to 0, it is the Z-phase position of encoder.


Range for Encoder Position Attained
Factory Setting: 10
Settings

0~65535 pulse

 This parameter determines the range for internal positioning position attained.
For example:
When the position is set by Pr.10-19 Positioning for Encoder Position and Pr.10-20 is set to 1000, it
reaches the position if the position is within 990-1010 after finishing the positioning.


Filter Time (PG2)
Factory Setting: 0.100
Settings

0.000~65.535 sec

 When Pr.00-20 is set to 5 and multi-function input terminal is set to 37 (OFF), the pulse command
will be regarded as frequency command. This parameter can be used to suppress the jump of
speed command.
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Chapter 12 Description of Parameter SettingsC2000 Series

Speed Mode (PG2)
Factory Setting: 0
Settings

0: Electronic Frequency
1: Mechanical Frequency (base on pole pair)

Reserved
FOC&TQC Function Control



Factory Setting: 0
Settings

0~65535

Bit#
0

Description
ASR control at sensorless torque
0:use PI as ASR; 1:use P as ASR
1~10
NA
11
Activate DC braking when executing zero torque command
0:ON , 1:OFF
12
FOC Sensorless mode, cross zero means speed goes from negative to
positive or positive to negative (forward to reverse direction or reverse to
forward direction). 0: determine by stator frequency , 1: determine by speed
command
13
NA
14
NA
15
Direction control at open loop status
0: Switch ON direction control 1: Switch OFF direction control
 Except Bit=0 set to be used in closed loop, other Bit settings are for open loop.


FOC Bandwidth of Speed Observer
Factory Setting:40.0
Settings

20.0~100.0Hz

 Setting speed observer to higher bandwidth could shorten the speed response time but will create
greater noise interference during the speed observation.


.

FOC Minimum Stator Frequency
Factory Setting:2.0
Settings

0.0~10.0%fN

 This parameter is used to set the minimum level of stator frequency at operation status. This
setting ensures the stability and accuracy of observer and avoid interferences from voltage,
current and motor parameter. fN is motor rated frequency.


FOC Low-pass Filter Time Constant
Factory Setting:50
Settings

1~1000ms

 This parameter sets the low-pass filter time constant of a flux observer at start up. If the motor can
not be activated during the high-speed operation, please lower the setting in this parameter.

12-10-6

Chapter 12 Description of Parameter SettingsC2000 Series



FOC Gain of Excitation Current Rise Time
Factory Setting:100
Settings

33~100% Tr

(Tr: rotor time constant)

 This parameter sets the drive’s excitation current rise time when activates at senslorless torque
mode. When the drive’s activation time is too long at torque mode, please adjust this parameter to
a shorter time constant.


Top Limit of Frequency Deviation
Factory Setting: 20.00
Settings

0.00~200.00Hz

 Pr.10-29 is for setting the maximum of frequency deviation.
 When this parameter is set too large, resulting in abnormal PG feedback malfunction.
 If the application need higher setting of Pr10-29, please note that: Higher setting of Pr10-29 value
will result in larger motor slip, which will cause PG Error (PGF3, PGF4) easily. In this case, set
Pr10-10 and Pr10-13 as 0 will disable PGF3 and PGF4 detection, but it needs to make sure the
PG wiring and application is correct. Or it may lose the instant PG protection. Too Higher Pr10-29
setting is not a common setting.
Resolver Pole Pair
Factory Setting: 1
Settings

1~50

 To use Pr.10-30 function, user must set Pr.10-00=3(Resolver Encoder) first.
Reserved
Reserved


I/F Mode, current command
Factory Setting: 40
Settings



0~150% Irated

(Rated current % of the motor)

PM Sensorless Obeserver Bandwith for High Speed Zone
Factory Setting: 5.00
Settings



0.00~600.00Hz

PM Sensorless Observer Low-pass Filter Gain
Factory Setting: 1.00
Settings



0.00~655.35Hz

ARM (Kp)
Factory Setting: 1.00
Settings



0.00~3.00

ARM (Ki)
Factory Setting: 0.20
Settings



0.00~3.00

PM Sensorless Control Word
Factory Setting: 0000
Settings

0000~FFFFh

12-10-7

Chapter 12 Description of Parameter SettingsC2000 Series

Bit No.
Function
0
Reserved
1
Reserved
2
Choose a control mode to
statrt.
3
Choose a mode to stop .
4
5

Description
0 :Start by IF mode
1: Start by VF mode
0 :Stop by IF mode
1 :Stop by VF mode

Reserved
Choose a control mode to stop 0 : When lower than Pr10-40, coast to stop
1 : When lower than Pr10-40, ramp to stop
Reserved
Reserved

6
7

Frequency Point when switch from I/F mode to PM Sensorless mode



Factory Setting: 20.00
Settings

0.00~600.00Hz

Frequency Point when switch from PM Sensorless Observation mde to I/F mode



Factory Setting: 20.00
Settings

0.00~600.00Hz

I/F mode, low pass-filter time



Factory Setting: 0.2
Settings

0.0~6.0 sec

Initial Angle Detection Time



Factory Setting: 5
Settings

0~20 ms

 PM Sensorless (I/f + FOC) Adjustment Procedure
1. When executing Static test for PM(IPM) (05-00=13), VFD software can be used to monitor
adjustment procedure. To download VFD Sotware go to:
http://www.delta.com.tw/product/em/download/download_main.asp?act=3&pid=1&cid=1&tpid=3
2. Testing PM High Frequency Standstill VFD (calculating of Rs, Ld, Lg)
Procedures:
A.

Set control mode as VF mode (Pr00-10=0, Pr00-11=0)

B.

Output Frequency of Motor 1 (Pr01-01)

C.

Output Voltage of Motor 1 (Pr01-02)

D.

Induction Motor and Permanent Magnet Motor Selection (Pr05-33=1 or 2)

E.

Full-load current of Permanent Magnet Motor(Pr05-34

F.

Set Static test for PM(IPM) (05-00=13), then run the drive.

3. Set control mode as PM sensorless Mode (Parameters 00-10=0, 00-11=6)
4. Set VFD Prameters






Pr05-35 Rated Power of Permanent Magnet Motor
Pr05-36 Rated speed of Permanent Magnet Motor
Pr05-37 Pole number of Permanent Magnet Motor
Pr05-38 Inertia of Permanent Magnet Motor

12-10-8

Chapter 12 Description of Parameter SettingsC2000 Series

5. Set ASR Parameters




Pr11-00 bit0=1: Auto tuning for ASR and APR
Pr11-02：ASR1/ASR2 Switch Frequency, it is recommended to set Pr10-39 higher than
10Hz.



Pr11-03: ASR1 Low-speed Bandwidth and Pr11-03, ASR2 High-speed Bandwidth. Do not set
Low-speed Bandwith too high to avoid dissipation of the estimator.

6. Set speed estimator and speed control’s parameter.




Pr10-39 Frequency when switch from I/F Mode to PM sensorless mode.
Pr10-32 PM Sensorless Obeserver Bandwith for High Speed Zone

7. Zero-load test



Refer to switch point prodcedure of I/F and FOC as shown in the image below.
Set frequency command
(Higher than switching command)
Big variation of current or
OC while switching
Lower Per Unit of System
Inertia (Pr.11-01)/
Lower ASR1 Low-speed
Bandwidth (Pr.11-03)
NO

Big variation of output
frequency or dissipation
IncreasePM Sensorless
Observer Bandwidth for
High Speed Zone (Pr.10-32)/
Decrease Per Unit of
System Inertia (Pr.11-01)

NO

Perform RUN command

Can the drive run
normally until switching
to higher frequency?

Yes

Observe output current/
fequency via
commnucation intreface

When running at high
frequency, is the frequency
stable?
Observe output current/
fequency via
Yes
commnucation intreface
Increase load and Test
Procedure for switching between I/
F mode and FOC mode

12-10-9

Chapter 12 Description of Parameter SettingsC2000 Series

IPM control method SOP
1. Set up IPM motor
Pr05-33=2
2. Set up motor parameter according to the motor Nameplate
Pr01-01 Output Frequency of Motor 1（base frequency and motor rated frequency
Pr01-02 Output Voltage of Motor 1（base frequency and motor rated frequency）
Pr05-34 Full-load current of Permanent Magnet Motor
Pr05-35 Rated Power of Permanent Magnet Motor
Pr05-36 Rated speed of Permanent Magnet Motor
Pr05-37 Pole number of Permanent Magnet Motor
3. Execute Auto-tuning
Set upPr05-00=13 for IPM motor tuning and press Run(static-tuning). When the tuning
is done, the following parameters will be obtained.
Pr05-39 Stator Resistance of PM Motor
Pr05-40 Permanent Magnet Motor Ld
Pr05-41 Permanent Magnet Motor Lq
4. Set up control mode: Pr00-10=0 velocity mode, Pr00-11=7 IPM sensor-less
5. Turn OFF the power and power ON again.
6. Modify the ASR Kp and Ki according to system need.
PG Card Version
Factory Setting: Read only
Settings

0~655.35

 Version reference:
PG02U
PG01U
PG01O/PG01L
PG02O/PG02L
PG01R
~


21.XX
31.XX
11.XX
14.XX
41.XX

Reserve
Zero voltage time while start up
Factory Setting: 00.000
sec
Settings

00.000~60.000 sec

 When the motor is in static status at the startup, the accuracy to estimate angles will be increased.
In order to make the motor in “static status”, the drive 3 phase U, V, W output 0V to motor to reach
this goal. The Pr10-49 setting time is the length of time when three-phase output 0V.
 It is possible that even when this parameter is being applied but the motor at the installation site
cannot go in to the “static status” caused by the inertia or by any external force. So, if the motor
doesn’t go into a completer “static status” in 0.2 sec, increase appropriately this setting value.
 This parameter is functional only when the setting of Pr07-12 Speed Search during Startup ≠0.
12-10-10

Chapter 12 Description of Parameter SettingsC2000 Series



Reverse angle limit (Electrical angle)
Factory Setting: 10.00
degree
Settings

0.00~30.00 degree

 While forward run is starting, if there is a sudden reverse run and the reverse angle is bigger than
the Pr10-50 setting, then, drive will has a ScRv error.
 This parameter is valid only when Pr07-28 =11 Enable textile machine’s function.


Injection Frequency
Factory Setting: 500 Hz
Settings

0~2000Hz

 This parameter is a High Frequency Injection Command when the motor drive is under IPM HFI
sensor-less control mode and it doesn’t often need to be adjusted. But, if a motor’s rated
frequency (i.e. 400Hz) is too close to the frequency setting of this parameter (i.e. 500Hz), the
accuracy of angles detected will be affected. Therefore, refer to the setting of Pr01-01 before
adjusting this parameter.


Injection Magnitude
Factory Setting:15/30V
Settings 0.0~200.0V
 This parameter is the High Frequency Injection Command’s amplitude when the motor drive is
under IPM HFI sensor-less control mode.
 By increase the setting value of this parameter, the accuracy of angles detected will also be
increased. However, if the setting value is too big, it will cause a louder electromagnetic noise.

12-10-11

Chapter 12 Description of Parameter SettingsC2000 Series

11 Advanced Parameters

 This parameter can be set during operation.

In this parameter group, ASR is the abbreviation for Adjust Speed Regulator
System Control
Factory Setting: 0
Settings

0: Auto tuning for ASR and APR
1: Inertia estimate (only in FOCPG mode)
2: Zero servo
3: Dead time compensation closed
7: Selection to save or not save the freqeuncy
8: Maximum speed of point to point position control

 Bit 0=0: Pr.11-06 to 11-11 will be valid and Pr.11-03~11-05 are invalid.
Bit 0=1: system will generate an ASR setting. At this moment, Pr.11-06~11-11 will be invalid and
Pr.11-03~11-05 are valid.
Bit 1=0: no function.
Bit 1=1: Inertia estimate function is enabled. (Bit 1 setting would not activate the estimation
process, please set Pr.05-00=12 to begin FOC/TQC Sensorless inertia estimating)
Bit 2=0: no function.
Bit 2=1: when frequency command is less than Fmin (Pr.01-07), it will use zero servo function.
NO

Estimate i ner tia value

YES

Setting auto gain adjustment
Pr.11-00=1
Adjust Pr.11- 03, 11-04 and 11-05
separately by speed response
Adjust by r equi rement
Pr.11-13 ( PDFF function)

Adjust gai n value by manual
Pr.11-00=0 ( factor y setting)
Adjust Pr.11- 06, 11-07, 11- 08,
11-09, 11- 10 and 11- 11
separately by speed response
Adjust by r equi rement
Pr.11-14 ( for general,
no need to adj us t)

Adjust by r equi rement
Pr.11-02
(A SR1/ASR2 switch frequency)
Adjust by r equi rement
Pr.11-17~20 ( tor que limit)

12-11-1

Chapter 12 Description of Parameter SettingsC2000 Series
PI

PI
P r .11 - 05
u se to ad j ust the
s tre n gth o f ze ro s er vo lo ck

1 1- 1 0
1 1- 1 1
1 1- 0 6

1. Pr . 11 - 01 va lu e
2. set Pr .11 - 00 to bi t 0=1

11 -0 3

11-07
11 -0 8
11 -0 9

5 Hz

0 Hz

11 - 04

5Hz

11 - 02

Hz

0 Hz

P I adj us tme nt- ma nu a l ga in

5H z

5 Hz

1 1 -0 2
P I adj us tme nt- au to g ai n

Hz

 Bit 7=0: frequency is saved before power turns off. When power turns on again, the display
frequency will be the memorized frequency.
Bit 7=1: frequency is not saved before power turns off. When power turns ON again, the display
frequency will be 0.00Hz.
Bit 8=0: maximum speed for point-to-point position control is control by the setting of Pr.11-43.
Bit 8=1: maximum speed for point-to-point position control is control by the multi-step speed
setting of the external terminal device. When multi-step speed of the external device is set to 0,
the maximum operation speed will bet the setting of Pr.11-43.
Per Unit of System Inertia
Factory Setting: 400
Settings

1~65535（256=1PU）

 To get the system inertia from Pr.11-01, user needs to set Pr.11-00 to bit1=1 and execute
continuous forward/reverse running.
Unit of induction motor system inertia is 0.001kg-m^2:
Power
Setting
Power
Setting
Power
Setting
1HP
2.3
20HP
95.3
100HP
1056.5
2HP
4.3
25HP
142.8
125HP
1275.3
3HP
8.3
30HP
176.5
150HP
1900.0
5HP
14.8
40HP
202.5
175HP
2150.0
7.5HP
26.0
50HP
355.5
215HP
2800.0
10HP
35.8
60HP
410.8
300HP
3550.0
15HP
74.3
75HP
494.8
The base value for induction motor system inertia is set by Pr.05-38 and the unit is in 0.001kg-m^2.


ASR1/ASR2 Switch Frequency
Factory Setting: 7.00
Settings



5.00~600.00Hz

ASR1 Low-speed Bandwidth
Factory Setting: 10
Settings

1~40Hz (IM)/ 1~100Hz (PM)

12-11-2

Chapter 12 Description of Parameter SettingsC2000 Series



ASR2 High-speed Bandwidth
Factory Setting: 10
Settings



1~40Hz (IM)/ 1~100Hz (PM)

Zero-speed Bandwidth
Factory Setting: 10
Settings

1~40Hz (IM)/ 1~100Hz (PM)

 After estimating inertia and set Pr.11-00 to bit 0=1 (auto tuning), user can adjust parameters
Pr.11-03, 11-04 and 11-05 separately by speed response. The larger number you set, the faster
response you will get. Pr.11-02 is the switch frequency for low-speed/high-speed bandwidth.
 Position control pulse command (MIx=37) and P2P position control Kp gain can adjust Pr11-05.
The higher the value, the lower the steady-state error.


ASR (Auto Speed Regulation) control (P) 1
Factory Setting: 10
Settings



0~40 Hz (IM)/ 1~100Hz (PM)

ASR (Auto Speed Regulation) control (I) 1
Factory Setting: 0.100
Settings



0.000~10.000 sec

ASR (Auto Speed Regulation) control (PI) 2
Factory Setting: 10
Settings



0~40 Hz (IM)/ 0~100Hz (PM)

ASR (Auto Speed Regulation) control (I) 2
Factory Setting: 0.100
Settings



0.000~10.000 sec

ASR(Auto Speed Regulation) Control (P) of Zero Speed
Factory Setting: 10
Settings



0~40 Hz (IM)/ 0~100Hz (PM)

ASR(Auto Speed Regulation) Control (I) of Zero Speed
Factory Setting: 0.100
Settings



0.000~10.000 sec

Gain for ASR Speed Feed Forward
Factory Setting: 0
Settings

0~150%

 This parameter is used to improve speed response.
11- 12
G ain for ASR
speed feed for war d
00- 20

+

ASR
-

Speed feedback

+

+
+

Tq B ias

12-11-3

Tor que
command
Tor que limit
11- 17~11- 20

11- 14

Chapter 12 Description of Parameter SettingsC2000 Series



PDFF Gain Value
Factory Setting: 30
Settings

0~200%

 After finishing estimating and set Pr.11-00 to bit 0=1 (auto tuning), using Pr.11-13 to reduce
overshoot. Please adjust PDFF gain value by actual situation.
 This parameter will be invalid when Pr.05-24 is set to 1.
frequency

PI

PDFF

T ime



Low-pass Filter Time of ASR Output
Factory Setting: 0.008
Settings

0.000~0.350 sec

 It is used to set the filter time of ASR command.


Notch Filter Depth
Factory Setting: 0
Settings



0~20db

Notch Filter Frequency
Factory Setting: 0.00
Settings

0.00~200.00Hz

 This parameter is used to set resonance frequency of mechanical system. It can be used to
suppress the resonance of mechanical system.
 The larger number you set Pr.11-15, the better suppression resonance function you will get.
 The notch filter frequency is the resonance of mechanical frequency.


Forward Motor Torque Limit



Forward Regenerative Torque Limit



Reverse Motor Torque Limit



Reverse Regenerative Torque Limit
Factory Setting: 500
Settings

0~500%

 The motor drive rated current is 100%. The settings for Pr.11-17 to Pr.11-20 will compare with
Pr.03-00=7, 8, 9, 10. The minimum of the comparison result will be torque limit. Please refer the
chart as below.

12-11-4

Chapter 12 Description of Parameter SettingsC2000 Series

 Calculation equation for motor rated torque:

T ( N .M ) 
Motor rated torque=

P(W )
 (rad / s) ; P(W) value= Pr.05-02;

RPM  2
 rad / s
60
ω(rad/s) value= Pr.05-03。

 . FOCPG and FOC sensor-less control mode
The drive rated current=100%. The setting value of parameters Pr11-17~Pr11-20 will compare to
Pr03-00=7, 8, 9 and 10. The smallest value will become the torque limit value. Please refer to the
torque limit diagram.
 TQCPG and TQC Sensor-less control mode
The drive rated current=100%. The setting value of parameters Pr11-17~Pr11-20 will compare to
Pr06-12. The smallest value will become the torque limit value.
 VF, VFPG and SVC control mode
The Pr11-17~Pr11-20 are output current limit and its 100%=drive rated current. The smallest value
between the Pr11-17~Pr11-20 and Pr06-12 will become output current limit. If the output current
has reach this limit during acceleration or normal running, drive will enable “Over current Stall”
function. Until the output frequence drops to limit value, drive can run normally.
Po sitiv e
to rque

Rev ers e mot or mode
06-1 2 c urrent limit

Ex te rnal ana lo g t ermin als
Pr. 03-00~ 02
7: pos itiv e to rque limit
10: pos itiv e/n egat iv e torque limit
9: regen erativ e t orque limit
Pr. 11-19
Rev ers e rege nerat ive
to rque limit

s peed

E xt ernal an alog t erminals
P r. 03-00 ~02
7: po sitiv e t orque limit
10: pos itive/ne gativ e t orque limit

The level o f t orque limit will b e
th e min. va lu e of fo llowing thre e v alues

Pr. 11-17
Fo rwa rd moto r
t orque limit

s peed

Q ua dr an t II Q ua dr an t I
Q ua dr an t III Q ua dr an t IV

Pr. 11-20
Rev ers e mot or
to rque limit

Ex te rnal ana lo g t ermin als
Pr. 03-00~ 03-0 2
8: nega tiv e to rque limit
10: pos itiv e/n egat iv e torque limit
06-1 2 c urrent limit
Rev ers e mot or mode



Forward mo tor mo de
06-1 2 c urrent limit

Pr. 11-18
Forward re genera tive
t orque limit

E xt ernal an alog t erminals
Pr. 03-00~ 03-02
8 : ne gativ e t orque limit
10: pos itiv e/ne gativ e t orque limit
06-1 2 c urrent limit
Forward mo tor mo de

Nega tive
to rque

Gain Value of Flux Weakening Curve for Motor 1
Factory Setting: 90
Settings



0~200%

Gain Value of Flux Weakening Curve for Motor 2
Factory Setting: 90
Settings

0~200%

 Pr.11-21 and 11-22 are used to adjust the output voltage of flux weakening curve.
12-11-5

Chapter 12 Description of Parameter SettingsC2000 Series

 For the spindle application, the adjustment method is
1. It is used to adjust the output voltage when exceeding rated frequency.
2. Monitor the output voltage
3. Adjust Pr.11-21 (motor 1) or Pr.11-22 (motor 2) setting to make the output voltage reach motor
rated voltage.
4. The larger number it is set, the larger output voltage you will get.
output tor que

Fl ux w eakening cur ve
11-21
or
11-22
100%
90%
01-01
or
01-35



frequency

Speed Response of Flux Weakening Area
Factory Setting: 65
Settings

0: Disable
0~150%

 It is used to control the speed in the flux weakening area. The larger value is set in Pr.11-23, the
faster acceleration/deceleration will generate. In general, it is not necessary to adjust this
parameter.


APR Gain
Factory Setting: 10.00
Settings

0.00~40.00 (IM)/ 0~100.00Hz (PM)

 Kip gain of internal position (MI=35)


Gain Value of APR Feed Forward
Factory Setting: 30
Settings

0~100

 It works only for internal position (MI=35) and position control pulse command (MI=37). To set a
larger value in Pr.11-25, it can shorten the pulse differential and speed up the position response.
But it may cause overshoot.


APR Curve Time
Factory Setting: 3.00
Settings

0.00~655.35 sec

 It is valid when the multi-function input terminal is set to 35(ON). The larger it is set, the longer the
position time will be.

12-11-6

Chapter 12 Description of Parameter SettingsC2000 Series

Max. Torque Command



Factory Setting: 100
Settings

0~500%

 The upper limit of torque command is 100%.
 Calculation equation for motor rated torque:
motor rated torque: T ( N .M ) 
ω(rad/s) value= Pr.05-03。

P(W )
; P(W) value= Pr.05-02;
 (rad / s)

RPM  2
 rad / s
60

Source of Torque Offset



Factory Setting: 0
Settings

0: Disable
1: Analog input

(Pr.03-00~Pr.03-02)

2: Torque offset setting (Pr.11-29)
3: Control by external terminal (by Pr.11-30 to Pr.11-32)
 This parameter is the source of torque offset.
 When it is set to 3, source of torque offset would determine to follow Pr.11-30, Pr.11-31 or Pr.11-32
as command by the combination of MI setting as 31, 32 or 33. Please refer following char:
N.O. switch status:

ON= contact closed, OFF= contact open

Pr. 11-32



Pr. 11-31

Pr. 11-30

MI=33(Low)

MI=32(Mid)

MI=31(High)

Torque Offset

OFF
OFF
OFF
OFF
ON
ON
ON
ON

OFF
OFF
ON
ON
OFF
OFF
ON
ON

OFF
ON
OFF
ON
OFF
ON
OFF
ON

None
11-30
11-31
11-30+11-31
11-32
11-30+11-32
11-31+11-32
11-30+11-31+11-32

Torque Offset Setting
Factory Setting: 0.0
Settings

-100.0%~100.0%

 This parameter is torque offset. The motor rated torque is 100%.
 Calculation equation for motor rated torque:
motor rated torque: T ( N .M ) 
ω(rad/s) value= Pr.05-03。


P(W )
; P(W) value= Pr.05-02;
 (rad / s)

RPM  2
 rad / s
60

High Torque Offset
Factory Setting: 30.0
Settings

-100.0%~100.0%

12-11-7

Chapter 12 Description of Parameter SettingsC2000 Series



Middle Torque Offset
Factory Setting: 20.0
Settings



-100.0%~100.0%

Low Torque Offset
Factory Setting: 10.0
Settings

-100.0%~100.0%

 When Pr.11-28 is set to 3, the source of torque offset will regard Pr.11-30, Pr.11-31 and Pr.11-32
by the multi-function input terminals setting (31, 32 or 33). The motor rated torque is 100%.
 Calculation equation for motor rated torque:
motor rated torque: T ( N .M ) 
ω(rad/s) value= Pr.05-03。


P(W )
; P(W) value= Pr.05-02;
 (rad / s)

RPM  2
 rad / s
60

Source of Torque Command
Factory Setting: 0
Settings

0: Digital Keypad (Pr.11-34)
1: RS485 serial communication
2: Analog signal (Pr.03-00)
3: CANopen
4: Reserved
5: Communication card

 When Pr.11-33 is set to 0 or 1, torque command can be set in Pr.11-34.
 When Pr.11-33 is set to 2, 3, and 5, Pr.11-34 would only display the torque command


Torque Command
Factory Setting: 0.0
Settings

-100.0~100.0%(Pr.11-27=100%)

 This parameter is for the torque command. When Pr.11-27 is set to 250% and Pr.11-34 is set to
100%, actual torque command=250X100%=250% motor rated torque.
 The drive will save the setting to the record before power turns off.


Low-pass Filter Time of Torque Command
Factory Setting: 0.000
Settings

0.000~1.000 sec

 When the setting is too long, the control will be stable but the control response will be delay. When
the setting is too short, the response will be quickly but the control maybe unstable. User can
adjust the setting by the control and response situation.

12-11-8

Chapter 12 Description of Parameter SettingsC2000 Series

Speed Limit Selection
Factory Setting: 0
Settings

0: Set by Pr.11-37 (Forward speed limit) and Pr.11-38 (Reverse speed limit)
1: Set by Pr.11-37,11-38 and Pr.00-20 (Source of Master Frequency
Command)
2: Set by Pr.00-20 (Source of Master Frequency Command).

 Speed limit function: in TQCPG, when the motor speed is accelerated to speed limit value
(Pr.11-36, 11-37 and 11-38), it will switch to speed control mode to stop acceleration.
 Pr11-36=1:
When the torque command is positive, the forward speed limit is Pr00-20 and reverse speed limit
is Pr11-38.
When the torque command is negative, the forward speed limit is Pr11-37 and reverse speed limit
is Pr00-20.
 Unwind application, Torque command direction is different to motor operating direction, this
indicates that the motor is being load dragging. At this moment, the speed limit must be Pr11-37 or
Pr11-38. When the torque command direction and speed limit have same direction, the speed
limit will refer to the setting of Pr00-20
 About the keypad display, please refer to the “LED function Descriptions ” in User manual
chapter10 “Digital Keypad’. In torque control, F page of keypad display the present speed limit
value.
Pr . 11-3 6= 0
Fo rwa rd /reve r se ru nn ing
sp eed a re limite d

Pr.1 1- 36 =2
F o rw ard/ reverse r un nin g
spe ed ar e lim ited

b y Pr . 11-3 7 and P r. 11 -3 8.

by Pr.0 0- 20 .
T or q ue

T orqu e

Mot or
spe ed

M ot or
spee d

0 0- 20

11 -3 7
1 1- 38

0 0- 20

Pr . 11-3 6= 1

Pr . 11-3 6= 1

Wh en t orqu e is positive ,
f orwa rd ru nn ing spe ed

Wh en t orqu e is nega tive ,
f orwa rd ru nn ing spe ed

is limit ed by Pr.0 0-20 ;
reve r se ru nn ing spe ed

is limit ed by Pr.1 1-37 ;
reve rse ru nn ing spe ed

is limit ed by Pr.1 1-38 .

is limit ed by Pr.0 0-20 .

T o rq ue

T o rq ue

M oto r
sp ee d

M oto r
sp eed

00 -2 0

11 -3 7

11 -3 8

00 -2 0

12-11-9

Chapter 12 Description of Parameter SettingsC2000 Series

Forward Speed Limit (torque mode)



Factory Setting: 10
Settings

0~120%

Reverse Speed Limit (torque mode)



Factory Setting: 10
Settings

0~120%

 These parameters are used in the torque mode to limit the running direction and opposite
direction. (Pr.01-00 max. output frequency=100%)
Zero Torque Command Mode
Factory Setting: 0
Settings

0: Torque mode
1: Speed mode

 This parameter only works in TQCPG IM and TQCPG PM, and it defines the mode when speed
limit is 0% or 0Hz.
 When Pr.11-39 is set as 0 (the torque mode), and speed limit is 0% or 0Hz, the motor will generate
excitation current but no torque current.
 When Pr.11-39 is set as 1 (the speed mode), if torque command is 0% and speed limit is 0Hz, the
AC motor drive can still produce torque current through speed controller (at this moment, the
torque limit is Pr06-12) and the control mode will change from TQCPG to FOCPG mode. The
motor will have a holding torque. If the speed command is not 0, motor drive will change to be 0.
Command Source of Point-to-Point Position Control



Factory Settings:0
Settings

0: External terminal
1: Reserved
2: RS485
3: CAN
4: PLC
5: Communication card

Reserved

System control flag



Factory Settings: 0000
Settings

0000~FFFFh

Bit No.
Function
0
Current limit selection of speed
control at torque mode
1

FWD/REV action control

Description

0:Speed control at torque mode, the highest current
limit is torque command.
1: Speed control at torque mode, the highest current
limit is Pr06-12
0: FWD/REV cannot be controlled by 02-12 bit 0 & 1
1: FWD/REV can be controlled by 02-12 bit 0&1

2~15 Reserved

12-11-10

Chapter 12 Description of Parameter SettingsC2000 Series



Max. Frequency of Point- to-Point Position Control
Factory Settings:10.00
Settings



0.00~600.00Hz

Accel. Time of Point-to Point Position Control
Factory Settings:1.00
Settings



0.00~655.35sec

Decel. Time of Point-to Point Position Control
Factory Settings:3.00
Settings

0.00~655.35sec

Position
Max. Frequency
11-43

Speed

11-44
Accel. time

11-45
Decel. time

12-11-11

Chapter 13 Warning CodesC2000 Series

Chapter 13 Warning Codes
Di s p la y e rr o r si g n al

Warning

A b b r ev i a te e rr o r c o d e
T h e co d e is d is p l a y e d as s h ow n on K P C- C E 01 .

CE01
Comm. Error 1
ID No.
1

D i s p la y er r o r d e s c r i p ti o n

Display on LCM Keypad

Descriptions

Warning

CE01

Modbus function code error

Comm. Error 1

2
Warning

CE02

Address of Modbus data is error

Comm. Error 2

3
Warning

CE03

Modbus data error

Comm. Error 3

4
Warning

CE04

Modbus communication error

Comm. Error 4

5
Warning

CE10

Modbus transmission time-out

Comm. Error 10

6
Warning

CP10

Keypad transmission time-out

Keypad time out

7
Warning

SE1
Save Error 1

Keypad COPY error 1
Keypad simulation error, including communication delays,
communication error (keypad recived error FF86) and
parameter value error.

8
Warning

SE2

Keypad COPY error 2
Keypad simulation done, parameter write error

Save Error 2

9
Warning

oH1

IGBT over-heating warning

Over heat 1 warn

13-1

Chapter 13 Warning CodesC2000 Series

ID No.
10

Display on LCM Keypad

Descriptions

Warning

oH2

Capacity over-heating warning

Over heat 2 warn

11
Warning

PID

PID feedback error

PID FBK Error

12
Warning

ANL

ACI signal error
When Pr03-19 is set to 1 and 2.

Analog loss

13
Warning

uC

Low current

Under Current

14
Warning

AUE

Auto tuning error

Auto-tune error

15
Warning

PGFB

PG feedback error

PG FBK Warn

16
Warning

PGL

PG feedback loss

PG Loss Warn

17
Warning

oSPD

Over-speed warning

Over Speed Warn

18
Warning

DAvE

Over speed deviation warning

Deviation Warn

19
Warning

PHL

Phase loss

Phase Loss

20
Warning

ot1

Over torque 1

Over Torque 1

21
Warning

ot2

Over torque 2

Over Torque 2

13-2

Chapter 13 Warning CodesC2000 Series

ID No.
22

Display on LCM Keypad

Descriptions

Warning

oH3

Motor over-heating

Motor Over Heat

24
Warning

oSL

Over slip

Over Slip Warn

25
Warning

tUn

Auto tuning processing

Auto tuning

28
Wa r ni n g

O PHL

Output phase loss

O u tp ut PH L Wa r n

30
Warning

SE3

Keypad COPY error 3
Keypad copy between different power range drive

Copy Model Err 3

36
Warning

CGdn

CAN guarding time-out 1

Guarding T-out

37
Warning

CHbn

CAN heartbeat time-out 2

Heartbeat T-out

38
Warning

CSYn

CAN synchrony time-out

SYNC T-out

39
Warning

CbFn

CAN bus off

Can Bus Off

40
Warning

CIdn

CAN index error

CAN/S Idx exceed

41
Warning

CAdn

CAN station address error

CAN/S Addres set

42
Warning

CFrn

CAN memory error

CAN/S FRAM fail

13-3

Chapter 13 Warning CodesC2000 Series

ID No.
43

Display on LCM Keypad

Descriptions

Warning

CSdn

CAN SDO transmission time-out

SDO T-out

44
Warning

CSbn

CAN SDO received register overflow

Buf Overflow

45
Warning

Cbtn

CAN boot up error

Boot up fault

46
Warning

CPtn

CAN format error

Error Protocol

47
Warning

Plra

Adjust RTC

RTC Adjust

50
Warning

PLod

PLC download error

Opposite Defect

51
Warning

PLSv

Save error of PLC download

Save mem defect

52
Warning

PLdA

Data error during PLC operation

Data defect

53
Warning

PLFn

Function code of PLC download error

Function defect

54
Warning

PLor

PLC register overflow

Buf overflow

55
Warning

PLFF

Function code of PLC operation error

Function defect

56
Warning

PLSn

PLC checksum error

Check sum error

13-4

Chapter 13 Warning CodesC2000 Series

ID No.
57

Display on LCM Keypad

Descriptions

Warning

PLEd

PLC end command is missing

No end command

58
Warning

PLCr

PLC MCR command error

PLC MCR error

59

Warning

PLdF

PLC download fail

Download fail

60

Warning

PLSF

PLC scan time exceed

Scane time fail

61

Warning

PCGd

CAN Master guarding error

CAN/M Guard err

62

Warning

PCbF

CAN Master bus off

CAN/M bus off

63

Warning

PCnL

CAN Master node error

CAN/M Node Lack

64

Warning

PCCt

65

CAN/M cycle time-out

Warning

PCSF

CAN/M SDOover

CAN/M SDO over

66

Warning

PCSd

CAN/M SDO time-out

CAN/M Sdo Tout

67

Warning

PCAd

CAN/M station address error

CAN/M Addres set

68

Wa r ni n g

P CTo

PLC/CAN Master Slave communication time out

CA N /M T-O u t

13-5

Chapter 13 Warning CodesC2000 Series

ID No.
70

Display on LCM Keypad
Warning

ECid

Descriptions
Duplicate MAC ID error
Node address setting error

ExCom ID failed

71
Warning

ECLv

Low voltage of communication card

ExCom pwr loss

72
Warning

ECtt

Communication card in test mode

ExCom Test Mode

73
Warning

ECbF

DeviceNet bus-off

ExCom Bus off

74
Warning

ECnP

DeviceNet no power

ExCom No power

75
Warning

ECFF

Factory default setting error

ExCom Facty def

76
Warning

ECiF

Serious internal error

ExCom Inner err

77
Warning

ECio

IO connection break off

ExCom IONet brk

78
Warning

ECPP

Profibus parameter data error

ExCom Pr data

79
Warning

ECPi

Profibus configuration data error

ExCom Conf data

80
Warning

ECEF

Ethernet Link fail

ExCom Link fail

81
Warning

ECto

Communication time-out for communication card
and drive

ExCom Inr T-out

13-6

Chapter 13 Warning CodesC2000 Series

ID No.
82

Display on LCM Keypad

Descriptions

Warning

ECCS

Check sum error for Communication card and drive

ExCom Inr CRC

83
Warning

ECrF

Communication card returns to default setting

ExCom Rtn def

84
Warning

ECo0

Modbus TCP exceed maximum communication
value

ExCom MTC P over

85
Warning

ECo1

EtherNet/IP exceed maximum communication value

ExCom EIP over

86
Warning

ECiP

IP fail

ExCom IP fail

87
Warning

EC3F

Mail fail

ExCom Mail fail

88
Warning

Ecby

Communication card busy

ExCom Busy

90
Wa r ni n g

CP LP

Copy PLC password error

Cop y P LC P ass W d

91
Wa r ni n g

CP L0

Copy PLC Read mode error

Cop y P LC M o de Rd

92
Wa r ni n g

CP L1

Copy PLC Write mode error

Cop y P LC M o de Wt

93
Wa r ni n g

CP Lv

Copy PLC Version error

Cop y P LC V e rsi on

94
Wa r ni n g

CP LS

Copy PLC Capacity size error

Cop y P LC S ize

13-7

Chapter 13 Warning CodesC2000 Series

ID No.
96

Display on LCM Keypad

Descriptions

Wa r ni n g

CP Lt

Copy PLC time out

Cop y P LC T ime Out

101
Warning

ictn

Internal communication is off

InrCOM Tim e Out

13-8

Chapter 14 Fault Codes and Descriptions C2000 Series

Chapter 14 Fault Codes and Descriptions
Dis p la y e rro r sig n a l

Warning

A b b re v ia te e rro r c o d e
T h e co d e is d isp la ye d a s s h o wn o n K P C-CE 0 1 .

CE01
Comm. Error 1

Dis p la y e rro r d e s c rip tio n

* Refer to setting of Pr06-17~Pr06~22.
ID*

1

Fault Name

Fault

ocA
Oc at accel

2

Fault

ocd
Oc at decel

Fault

3

ocn
Oc at normal SPD

4

Fault

GFF

Fault Descriptions

Corrective Actions

Over-current during
acceleration
(Output current exceeds
triple rated current during
acceleration.)

1. Short-circuit at motor output: Check for possible
poor insulation at the output.
2. Acceleration Time too short: Increase the
Acceleration Time.
3. AC motor drive output power is too small: Replace
the AC motor drive with the next higher power
model.

Over-current during
deceleration
(Output current exceeds
triple rated current during
deceleration.)

1. Short-circuit at motor output: Check for possible
poor insulation at the output.
2. Deceleration Time too short: Increase the
Deceleration Time.
3. AC motor drive output power is too small: Replace
the AC motor drive with the next higher power
model.

Over-current during
steady state operation
(Output current exceeds
triple rated current during
constant speed.)

1. Short-circuit at motor output: Check for possible
poor insulation at the output.
2. Sudden increase in motor loading: Check for
possible motor stall.
3. AC motor drive output power is too small: Replace
the AC motor drive with the next higher power
model.

Ground fault

When (one of) the output terminal(s) is grounded,
short circuit current is more than 50% of AC motor
drive rated current, the AC motor drive power module
may be damaged.
NOTE: The short circuit protection is provided for AC
motor drive protection, not for protecting the user.
1. Check the wiring connections between the AC
motor drive and motor for possible short circuits,
also to ground.
2. Check whether the IGBT power module is
damaged.
3. Check for possible poor insulation at the output.

Short-circuit is detected
between upper bridge
and lower bridge of the
IGBT module

Return to the factory

Ground fault

5

Fault

occ
Short Circuit

14-1

Chapter 14 Fault Codes and Descriptions C2000 Series
ID*

6

Fault Name
Fault

ocS

Fault Descriptions

Corrective Actions

Hardware failure in
current detection

Return to the factory

DC BUS over-voltage
during acceleration
(230V: DC 450V; 460V:
DC 900V)

1. Check if the input voltage falls within the rated AC
motor drive input voltage range.
2. Check for possible voltage transients.
3. If DC BUS over-voltage due to regenerative
voltage, please increase the acceleration time or
add an optional brake resistor.

DC BUS over-voltage
during deceleration
(230V: DC 450V; 460V:
DC 900V)

1. Check if the input voltage falls within the rated AC
motor drive input voltage range.
2. Check for possible voltage transients.
3. If DC BUS over-voltage due to regenerative
voltage, please increase the Deceleration Time or
add an optional brake resistor.

DC BUS over-voltage at
constant speed (230V: DC
450V; 460V: DC 900V)

1. Check if the input voltage falls within the rated AC
motor drive input voltage range.
2. Check for possible voltage transients.
3. If DC BUS over-voltage due to regenerative
voltage, please increase the Deceleration Time or
add an optional brake resistor.

Hardware failure in
voltage detection

1. Check if the input voltage falls within the rated AC
motor drive input voltage range.
2. Check for possible voltage transients.

DC BUS voltage is less
than Pr.06-00 during
acceleration

1.
2.

Check if the input voltage is normal
Check for possible sudden load

DC BUS voltage is less
than Pr.06-00 during
deceleration

1.
2.

Check if the input voltage is normal
Check for possible sudden load

DC BUS voltage is less
than Pr.06-00 in constant
speed

1.
2.

Check if the input voltage is normal
Check for possible sudden load

DC BUS voltage is less
than Pr.06-00 at stop

1.
2.

Check if the input voltage is normal
Check for possible sudden load

Oc at stop

7

Fault

ovA
Ov at accel

8

Fault

ovd
Ov at decel

9

Fault

ovn
Ov at normal SPD

10

Fault

ovS
Ov at stop

11

Fault

LvA
Lv at accel

12

Fault

Lvd
Lv at decel

13

Fault

Lvn
Lv at normal SPD

Fault

14

LvS
Lv at stop

14-2

Chapter 14 Fault Codes and Descriptions C2000 Series
ID*

15

Fault Name
Fault

OrP

Fault Descriptions

Corrective Actions
Check Power Source Input if all 3 input phases are
connected without loose contacts.
For models 40hp and above, please check if the fuse
for the AC input circuit is blown.

Phase Loss

Phase lacked

1.

16

Fault

oH1

2.
IGBT overheating
IGBT temperature exceeds
3.
protection level

IGBT over heat

4.
5.
1.

17

Fault

oH2
Heat Sink oH

18

Fault

tH1o

Heatsink overheating
Capacitance temperature
exceeds cause heatsink
overheating.

2.
3.

Ensure that the ambient temperature falls within
the specified temperature range.
Make sure that the ventilation holes are not
obstructed.
Remove any foreign objects from the heatsinks
and check for possible dirty heat sink fins.
Check the fan and clean it.
Provide enough spacing for adequate ventilation.
Ensure that the ambient temperature falls within
the specified temperature range.
Make sure heat sink is not obstructed. Check if
the fan is operating
Check if there is enough ventilation clearance for
AC motor drive.

IGBT Hardware Error

Return to the factory

Capacitor Hardware Error

Return to the factory

Overload
The AC motor drive
detects excessive drive
output current.

1.
2.

Thermo 1 open

19

Fault

tH2o
Thermo 2 open

21

Fault

oL
Over load

22

Fault

EoL1
Thermal relay 1

23

Fault

EoL2

Check if the motor is overloaded.
Take the next higher power AC motor drive
model.

1. Check the setting of electronics thermal relay
Electronics thermal relay 1
(Pr.06-14)
protection
Take the next higher power AC motor drive model

Electronics thermal relay
2 protection

Thermal relay 2

14-3

1. Check the setting of electronics thermal relay
(Pr.06-28)
2. Take the next higher power AC motor drive model

Chapter 14 Fault Codes and Descriptions C2000 Series
ID*

24

Fault Name

Fault

oH3
Motor over heat

26

Fault

ot1
Over torque 1

27

Fault

ot2
Over torque 2

28

Fault

uC

Fault Descriptions
Motor overheating
The AC motor drive
detecting internal
temperature exceeds the
setting of Pr.06-30 (PTC
level) or Pr.06-57 (PT100
level 2).

Corrective Actions
1.
2.
3.

Make sure that the motor is not obstructed.
Ensure that the ambient temperature falls within
the specified temperature range.
Change to a higher power motor.

These two fault codes will
be displayed when output
current exceeds the
1. Check whether the motor is overloaded.
over-torque detection
2. Check whether motor rated current setting
level (Pr.06-07 or
(Pr.05-01) is suitable
Pr.06-10) and exceeds
3. Take the next higher power AC motor drive
over-torque detection
model.
(Pr.06-08 or Pr.06-11)
and it is set to 2 or 4 in
Pr.06-06 or Pr.06-09.

Check Pr.06-71, Pr.06-72, Pr.06-73.

Low current detection

Under torque

29

Fault

LMIT

Limit error

Limit Error

30

Fault

cF1

Internal EEPROM can not 1. Press “RESET” key to the factory setting
be programmed.
2. Return to the factory.

EEPROM write err

31

Fault

cF2

Internal EEPROM can not 1. Press “RESET” key to the factory setting
be read.
2. Return to the factory.

EEPROM read err

33

Fault

cd1

U-phase error

Reboots the power. If fault code is still displayed on the
keypad please return to the factory

V-phase error

Reboots the power. If fault code is still displayed on the
keypad please return to the factory

W-phase error

Reboots the power. If fault code is still displayed on the
keypad please return to the factory

Ias sensor err

34

Fault

cd2
Ibs sensor err

35

Fault

cd3
Ics sensor err

14-4

Chapter 14 Fault Codes and Descriptions C2000 Series
ID*

36

Fault Name
Fault

Hd0

Fault Descriptions

Corrective Actions

CC (current clamp)

Reboots the power. If fault code is still displayed on the
keypad please return to the factory

OC hardware error

Reboots the power. If fault code is still displayed on the
keypad please return to the factory

OV hardware error

Reboots the power. If fault code is still displayed on the
keypad please return to the factory

Occ hardware error

Reboots the power. If fault code is still displayed on the
keypad please return to the factory

Auto tuning error

1. Check cabling between drive and motor
2. Try again.

PID loss (ACI)

1.
2.

cc HW error

37

Fault

Hd1
Oc HW error

38

Fault

Hd2
Ov HW error

Fault

39

Hd3
occ HW error

40

Fault

AUE
Auto tuning err

41

Fault

AFE

Check the wiring of the PID feedback
Check the PID parameters settings

PID Fbk error

42

Fault

PG feedback error

Check if encoder parameter setting is accurate when
it is PG feedback control.

PG feedback loss

Check the wiring of the PG feedback

PG feedback stall

1.
2.

PGF1
PG Fbk error

43

Fault

PGF2
PG Fbk loss

44

45

Fault

PGF3
PG Fbk over SPD

3.

Fault

1.
2.

PGF4

PG slip error

3.

PG Fbk deviate

14-5

Check the wiring of the PG feedback
Check if the setting of PI gain and deceleration is
suitable
Return to the factory

Check the wiring of the PG feedback
Check if the setting of PI gain and deceleration is
suitable
Return to the factory

Chapter 14 Fault Codes and Descriptions C2000 Series
ID*

46

Fault Name
Fault

PGr1

Fault Descriptions

Corrective Actions

Pulse input error

1.
2.

Check the pulse wiring
Return to the factory

Pulse input loss

1.
2.

Check the pulse wiring
Return to the factory

ACI loss

1.
2.

Check the ACI wiring
Check if the ACI signal is less than 4mA

External Fault

1. Input EF (N.O.) on external terminal is closed to
GND. Output U, V, W will be turned off.
2. Give RESET command after fault has been
cleared.

Emergency stop

1. When the multi-function input terminals MI1 to
MI6 are set to emergency stop, the AC motor
drive stops output U, V, W and the motor coasts
to stop.
2. Press RESET after fault has been cleared.

External Base Block

1. When the external input terminal (B.B) is active,
the AC motor drive output will be turned off.
2. Deactivate the external input terminal (B.B) to
operate the AC motor drive again.

Password is locked.

Keypad will be locked. Turn the power ON after power
OFF to re-enter the correct password. See Pr.00-07
and 00-08.

Illegal function code

Check if the function code is correct (function code
must be 03, 06, 10, 63)

Illegal data address (00H
to 254H)

Check if the communication address is correct

Illegal data value

Check if the data value exceeds max./min. value

PG Ref error

47

Fault

PGr2
PG Ref loss

48

Fault

ACE
ACI loss

49

Fault

EF
External fault

50

Fault

EF1
Emergency stop

51

Fault

bb
Base block

52

Fault

Pcod
Password error

54

Fault

CE1
PC err command

55

Fault

CE2
PC err address

56

Fault

CE3
PC err data

14-6

Chapter 14 Fault Codes and Descriptions C2000 Series
ID*

57

Fault Name
Fault

CE4

Fault Descriptions

Corrective Actions

Data is written to read-only
address

Check if the communication address is correct

PC slave fault

58

Fault

CE10

Modbus transmission time-out

PC time out

59

Fault

CP10

Keypad transmission time-out

PU time out

60

Fault

bF

If the fault code is still displayed on the keypad after
pressing “RESET” key, please return to the factory.

Brake resistor fault

Braking fault

61

Fault

ydc

Y-connection/∆-connectio 1.
n switch error
2.

Check the wiring of the Y-connection/∆-connection
Check the parameters settings

When Pr.07-13 is not set
to 0 and momentary
power off or power cut, it
will display dEb during
accel./decel. stop.

1.
2.

Set Pr.07-13 to 0
Check if input power is stable

1.

Check if motor parameter is correct (please
decrease the load if overload
Check the settings of Pr.05-26 and Pr.05-27

Y-delta connect

62

Fault

dEb
Dec. Energy back

Over slip error

It will be displayed when
slip exceeds Pr.05-26
setting and time exceeds
Pr.05-27 setting.

Fault

Electric valve switch error when executing Soft Start.
(This warning is for frame E and higher frame of AC drives)

Fault

63

64

65

oSL

ryF
MC Fault

Do not disconnect RST when drive is still operating.

Fault

Hardware error of PG Card
Check if PG Card is insert to the right slot and parameter settings for encoder are
accurate.

PGF5
PG HW Error

68

2.

Fault

SdRv
SpdFbk Dir Rev

Rotaing direction is different from the commanding direction deteced by the
sensorless.
Solution
Verify if the parameter setting of the motor drive is correct
Increase the estimator's bandwidth and verify if parameters relating to the sensorless
are correct.

14-7

Chapter 14 Fault Codes and Descriptions C2000 Series
ID*

69

Fault Name
Fault

SdOr
SpdFbk over SPD

70

Fault

SdDe
SpdFbk deviate

72

F au l t

STOL

Fault Descriptions
Corrective Actions
Overspeed rotation detected by the sensorless
Solution
Verify if the parameter setting of the motor drive is correct
Increase the estimator's bandwidth and verify if parameters relating to the sensorless
are correct.
Verify if the gains of the speed circuit is reasonable.
Big difference between the rotating speed and the command deteced by the
sensorless
Solution
Verify if the parameter setting of the motor drive is correct
Increase the estimator's bandwidth and verify if parameters relating to the sensorless
are correct.
Verify if the gains of the speed circuit is reasonable.

STO1~SCM1 internal hardware detect error

S TO L o ss 1

73

Fault

S1

Emergency stop for external safety

S1-emergy stop

76

Fa u l t

STO

Safety Torque Off function active

STOL

STO2~SCM2 internal hardware detect error

S TO

77

F au l t
S TO L o ss 2

78

F au l t

STOL

STO1~SCM1 and STO2~SCM2 internal hardware detect error

S TO L o ss 3

79

Fault

Uoc

Phase U short circuit

U phase oc

80

Fault

Voc

Phase V short circuit

V phase oc

14-8

Chapter 14 Fault Codes and Descriptions C2000 Series
ID*

81

Fault Name
Fault

Woc

Fault Descriptions

Corrective Actions

W phase short circuit

W phase oc

82

Fault

OPHL

Output phase loss (Phase U)

U phase lacked

83

Fault

OPHL

Output phase loss (Phase V)

V phase lacked

84

Fault

OPHL

Output phase loss (Phase W)

W phase lacked

85

F au l t

Ab oF
P G A B Z L in e o ff

86

F au l t

Uv oF
P G UV W L in e o ff

89

F au l t

RoPd
R ot or P o s. Er r or

90

Fault

Fstp

PG card ABZ signal loss
Solution
Verify if the parameter setting of PG card and PG card cable is correct.

PG card UVW signal loss
Solution
Verify if the parameter setting of PG card and PG card cable is correct.

Rotor position detection error
Solution
Verify if the UVW output cable are loss.
Verify if the motor internal coil is broken.
Verify if the drive UVW output are normal.

Internal PLC forced to stop
Verify the setting of Pr.00-32

For ce Stop

101

Fault

CGdE

CANopen guarding error

Guarding T-out

102

Fault

CHbE

CANopen heartbeat error

Heartbeat T-out

14-9

Chapter 14 Fault Codes and Descriptions C2000 Series
ID*

103

Fault Name
Fault

CSYE

Fault Descriptions

Corrective Actions

CANopen synchronous error

SYNC T-out

104

Fault

CbFE

CANopen bus off error

Can bus off

105

Fault

CIdE

CANopen index error

Can bus Index Err

106

Fault

CAdE

CANopen station address error

Can bus Add. Err

107

Fault

CFrE

CANopen memory error

Can bus off

111

Internal communication time-out

Fault

ictE
InrCom Time Out

112

F au l t

Sf LK
P ML ess Sh aftL o ck

113

F au l t

SwO c

Motor Shaft lock error(Motor does not turn but the output frequency is not
zero)
Solution
Verify if the motor parameter setting is correct.

Software OC protection

S o ftw ar e O C

14-10

Chapter 15 CANopen Overview C2000 Series

Chapter 15 CANopen Overview
Newest version is available at http://www.delta.com.tw/industrialautomation/
15.1 CANopen Overview
15.2 Wiring for CANopen
15.3 CANopen Communication Interface Description
15.3.1 CANopen Control Mode Selection
15.3.2 DS402 Standard Control Mode
15.3.3 By using Delta Standard (Old definition, only support speed mode)
15.3.4 By using Delta Standard (New definition)
15.3.5 DI/DO AI AO are controlled via CANopen
15.4 CANopen Supporting Index
15.5 CANopen Fault Code
15.6 CANopen LED Function

15-1

Chapter 15 CANopen Overview C2000 Series

Built-in EMC-COP01 card is included in VFDXXXC23E/VFDXXXC43E models.
The built-in CANopen function is a kind of remote control. Master can control the AC motor drive by using
CANopen protocol. CANopen is a CAN-based higher layer protocol. It provides standardized communication objects,
including real-time data (Process Data Objects, PDO), configuration data (Service Data Objects, SDO), and special
functions (Time Stamp, Sync message, and Emergency message). And it also has network management data,
including Boot-up message, NMT message, and Error Control message. Refer to CiA website
http://www.can-cia.org/ for details. The content of this instruction sheet may be revised without prior notice. Please
consult our distributors or download the most updated version at http://www.delta.com.tw/industrialautomation
Delta CANopen supporting functions:
 Support CAN2.0A Protocol;
 Support CANopen DS301 V4.02;
 Support DSP-402 V2.0.
Delta CANopen supporting services:
 PDO (Process Data Objects): PDO1~ PDO4
 SDO (Service Data Object):
Initiate SDO Download;
Initiate SDO Upload;
Abort SDO;
SDO message can be used to configure the slave node and access the Object Dictionary in every node.
 SOP (Special Object Protocol):
Support default COB-ID in Predefined Master/Slave Connection Set in DS301 V4.02;
Support SYNC service;
Support Emergency service.
 NMT (Network Management):
Support NMT module control;
Support NMT Error control;
Support Boot-up.
Delta CANopen not supporting service:
 Time Stamp service

15-2

Chapter 15 CANopen Overview C2000 Series

15.1 CANopen Overview
CANopen Protocol
CANopen is a CAN-based higher layer protocol, and was designed for motion-oriented machine
control networks, such as handling systems. Version 4.02 of CANopen (CiA DS301) is standardized
as EN50325-4. The CANopen specifications cover application layer and communication profile (CiA
DS301), as well as a framework for programmable devices (CiA 302), recommendations for cables
and connectors (CiA 303-1) and SI units and prefix representations (CiA 303-2).

Device Profile CiA
DSP-401

OSI Layer 7
Application

OSI Layer 2
Data Link Layer

OSI Layer 1
Physical Layer

Device Profile CiA
DSP-404

Device Profile CiA
DSP-XXX

Communication Profile CiA DS-301

CAN Controller

CAN 2.0A

+ + -

ISO 11898

CAN bus
RJ-45 Pin Definition

8~1
plug

PIN
1
2
3
6

Signal
CAN_H
CAN_L
CAN_GND
CAN_GND

Description
CAN_H bus line (dominant high)
CAN_L bus line (dominant low)
Ground / 0V /VGround / 0V /V-

15-3

Chapter 15 CANopen Overview C2000 Series

CANopen Communication Protocol
It has services as follows:


NMT (Network Management Object)



SDO (Service Data Objects)



PDO (Process Data Object)



EMCY (Emergency Object)

NMT (Network Management Object)
The Network Management (NMT) follows a Master/Slave structure for executing
NMT service. Only one NMT master is in a network, and other nodes are regarded as
slaves. All CANopen nodes have a present NMT state, and NMT master can control the
state of the slave nodes. The state diagram of a node is shown as follows:

(1)
Initializing
(15)
Reset Application

(10)

(11)

(9)

(16)
Reset Communication

(14)

(2)F
Pre-Operation ABCD
(3)

(4)

(13)
(12)

Stopped AB
(8)

(6)
Operation ABCD

(1) After power is applied, it is auto in initialization state
(2) Enter pre-operational state automatically
(3) (6) Start remote node
(4) (7) Enter pre-operational state
(5) (8) Stop remote node
(9) (10) (11) Reset node
(12) (13) (14) Reset communication
(15) Enter reset application state automatically
(16) Enter reset communication state automatically
PDO
SDO
SYNC
Time Stamp
EMCY
Boot-up
NMT

(7)

(5)

Initializing Pre-Operational Operational
○
○
○
○
○
○
○
○
○
○
○
○

15-4

A: NMT
B: Node Guard
C: SDO
D: Emergency
E: PDO
F: Boot-up

Stopped

○

Chapter 15 CANopen Overview C2000 Series

SDO (Service Data Objects)
SDO is used to access the Object Dictionary in every CANopen node by
Client/Server model. One SDO has two COB-ID (request SDO and response SDO) to
upload or download data between two nodes. No data limit for SDOs to transfer data. But it
needs to transfer by segment when data exceeds 4 bytes with an end signal in the last
segment.
The Object Dictionary (OD) is a group of objects in CANopen node. Every node has
an OD in the system, and OD contains all parameters describing the device and its network
behavior. The access path of OD is the index and sub-index, each object has a unique
index in OD, and has sub-index if necessary. The request and response frame structure of
SDO communication is shown as follows:
PDO (Process Data Object)
PDO communication can be described by the producer/consumer model. Each node
of the network will listen to the messages of the transmission node and distinguish if the
message has to be processed or not after receiving the message. PDO can be transmitted
from one device to one another device or to many other devices. Every PDO has two PDO
services: a TxPDO and a RxPDO. PDOs are transmitted in a non-confirmed mode.
PDO Transmission type is defined in the PDO communication parameter index
(1400h for the 1st RxPDO or 1800h for the 1st TxPDO), and all transmission types are
listed in the following table:
Type Number

PDO
Cyclic

0
1-240

Acyclic

Synchronous

○

○

○

Asynchronous

RTR only

○

241-251

Reserved

252

○

○

253

○

254

○

255

○

○

Type number 1-240 indicates the number of SYNC message between two PDO
transmissions.
Type number 252 indicates the data is updated (but not sent) immediately after receiving
SYNC.
Type number 253 indicates the data is updated immediately after receiving RTR.
Type number 254: Delta CANopen doesn’t support this transmission format.
Type number 255 indicates the data is asynchronous transmission.
All PDO transmission data must be mapped to index via Object Dictionary.

EMCY (Emergency Object)
When errors occurred inside the hardware, an emergency object will be triggered an
emergency object will only be sent when an error is occurred. As long as there is nothing wrong with
the hardware, there will be no emergency object to be served as a warning of an error message.

15-5

Chapter 15 CANopen Overview C2000 Series

15.2 Wiring for CANopen
An external adapter card: EMC-COP01 is used for CANopen wiring to connect
CANopen to VFD C2000. The link is enabled by using RJ45 cable. The two farthest ends must
be terminated with 120Ω terminating resistors.

15-6

Chapter 15 CANopen Overview C2000 Series

15.3 CANopen Communication Interface
Description
15.3.1 CANopen Control Mode Selection
There are two control modes for CANopen; Pr.09-40 set to 1 is the factory setting mode
DS402 standard and Pr.09-40 set to 0 is Delta’s standard setting mode.
Actually, there are two control modes according to Delta’s standard, one is the old control
mode (Pr09-30=0).
This control mode can only control the motor drive under frequency control. Another mode is a
new standard (Pr09-30=1)
This new control mode allows the motor drive to be controlled under all sorts of mode.
Currently, C2000 support speed, torque, position and home mode.
The definition of relating control mode are:
CANopen
Control
Mode
Selection
DS402
standard
Pr. 09-40=1

Speed
Index
Description
6042-00

-----

Target
rotating
speed
(RPM)
-----

Control Mode
Torque
Position
Home
Index
Description
Index Description Index Description
6071-00 Target Torque 607A-00
(%)
6072-00

Max. Torque
Limit(%)
-----

-----

Delta Standard 2020-02 Target rotating --------(Old definition)
speed (Hz)
P09-40=1,
P09-30=0
Delta Standard 2060-03 Target rotating 2060-07 Target Torque 2060-05
(New definition)
speed (Hz)
(%)
P09-40=0,
2060-04 Torque Limit 2060-08 Speed Limit (Hz) ----P09-30=1
(%)
CANopen Control Mode
Selection
DS402 standard
Pr. 09-40=1
Delta Standard (Old definition)
P09-40=1, P09-30=0
Delta Standard (New
definition)
P09-40=0, P09-30=1

Operation Control
Index
Description
6040-00
Operation Command
--------2020-01
Operation Command
2060-01

Operation Command

-----

-----

CANopen Control Mode
Selection
Index
DS402 standard
605A-00
Pr. 09-40=1
605C-00
Delta Standard (Old definition)
----P09-40=1, P09-30=0
Delta Standard (New
----definition)
----P09-40=0, P09-30=1

Other
Description
Quick stop processing mode
Disable operation processing mode
-------------

15-7

Target
Position

-----

-----

-----

-----

-----

-----

-----

-----

Target
Position
-----

-----

-----

-----

-----

Chapter 15 CANopen Overview C2000 Series

However, you can use some index regardless DS402 or Delta’s standard.
For example:
1. Index which are defined as RO attributes.
2. Index correspond to parameters such as (2000 ~200B-XX)
3. Accelerating/Decelerating Index: 604F 6050

15-8

Chapter 15 CANopen Overview C2000 Series

15.3.2 DS402 Standard Control Mode
15.3.2.1 Related set up of ac motor drive (by following DS402 standard)
If you want to use DS402 standard to control the motor drive, please follow the steps below:
1.

Wiring for hardware (refer to chapter 15-2 Wiring for CANopen)

2.

Operation source setting: set Pr.00-21 to 3 for CANopen communication card control.

3.

Frequency source setting: set Pr.00.20 to 6. (Choose source of frequency commend from
CANopen setting.)

4.

Source of torque setting is set by Pr.11-33.

(Choose source of torque commend from

CANopen setting.)
5.

CANopen station setting: set Pr.09-36 (Choose source of position commend from CANopen
setting.)

6.

Set DS402 as control mode: Pr09-40=1

7.

CANopen station setting: set Pr.09-36 (Range of setting is 1~127. When Pr.09-36=0,
CANopen slave function is disabled. ) (Note: If error arise (CAdE or CANopen memory error)
as station setting is completed, press Pr.00-02=7 for reset.)

8.

CANopen baud rate setting: set Pr.09.37 (CANBUS Baud Rate: 1M(0), 500K(1), 250K(2),
125K(3), 100K(4) and50K(5))

9.

Set multiple input functions to Quick Stop (it can also be enable or disable, default setting is
disable). If it is necessary to enable the function, set MI terminal to 53 in one of the following
parameter: Pr.02.01 ~Pr.02.08 or Pr.02.26 ~ Pr.02.31. (Note: This function is available in
DS402 only.)

15.3.2.1 The status of the motor drive (by following DS402 standard)
According to the DS402 definition, the motor drive is divided into 3 blocks and 9 status
as described below.
3 blocks
Power Disable: That means without PWM output
Power Enable: That means with PWM output
Fault: One or more than one error has occurred.
9 status
Start: Power On
Not ready to switch on: The motor drive is initiating.
Switch On Disable: When the motor drive finishes the initiation, it will be at this mode.
Ready to switch on: Warming up before running.
Switch On: The motor derive has the PWM output now, but the reference commend is not
effective.
Operate Enable: Able to control normally.
Quick Stop Active: When there is a Quick Stop request, you have to stop running the motor
drive.
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Chapter 15 CANopen Overview C2000 Series

Fault Reaction Active: The motor drive detects conditions which might trigger error(s).
Fault: One or more than errors has occurred to the motor drive.
Therefore, when the motor drive is turned on and finishes the initiation, it will remain at Ready to
Switch on status.

To control the operation of the motor drive, you need to change this status to

Operate Enable status. The way to change it is to commend the control word's bit0 ~ bit3 and
bit7 of the Index 6040H and to pair with Index Status Word (Status Word 0X6041).

The control

steps and index definition are described as below:
Index 6040
15~9

8

7

6~4

Reserved

Halt

Fault Reset

Operation

3
Enable
operation

2

1
Enable
Voltage

Quick Stop

0
Switch On

Index 6041
15~14

13~12

11
10
9
8
7
6
Internal
Switch on
Target
Reserved Operation limit
Remote Reserved Warning
disabled
reached
active

Power
Disable

Start

5

4

3

Quick
stop

Voltage
enabled

Fault

2

1

0

Ready to
Operation
Switch on
enable
switch on

Fault Reaction Active
X0XX1111

Not Ready to Switch On
Fault

X0XX0000

X0XX1000
XXXXXXX

Switch On Disable
X1XX0000

0XXXXX0X

0XXXX110
and
Disable QStop=1

0XXXXX0X
or
0XXXX01X
or
Disable QStop=0

Ready to Switch On

0XXXXX0X
or
0XXXX01X
or
Disable QStop=0

X01X0001
0XXXX111

0XXXX110

Switch On
X01X0011
0XXX1111
0XXXX110

0XXXX111

Operation Enable
X01X0111

0XXXX01X
or
Disable QStop=0
0XXXX01X
and
Disable QStop=1

Fault
Power
Enable
0XXXXX0X
or
Fout=0

Quick Stop Active
X00X0111

Set command 6040 =0xE, then set another command 6040 =0xF. Then the motor drive can be
switched to Operation Enable. The Index 605A decides the dashed line of Operation Enable when
15-10

Chapter 15 CANopen Overview C2000 Series

the control mode changes from Quick Stop Active. (When the setting value is 1~3, this dashed line is
active. But when the setting value of 605A is not 1~3, once he motor derive is switched to Quick Stop
Active, it will not be able to switch back to Operation Enable.)
Index

605Ah

Sub

0

Definition

Factory Setting

Quick stop option code

R/W

RW

2

Size

Unit

PDO
Map

S16

Mode

note
0 : disable drive function
1 :slow down on slow down ramp
2: slow down on quick stop ramp
5 slow down on slow down ramp and
stay in QUICK STOP
6 slow down on quick stop ramp and
stay in QUICK STOP
7 slow down on the current limit and
stay in Quick stop

No

Besides, when the control section switches from Power Enable to Power Disable, use 605C to define
parking method.
Index

Sub

605Ch

0

Definition
Disable operation option code

Factory Setting

R/W

Size

1

RW

S16

Unit

PDO
Map

Mode

note
0: Disable drive function
1: Slow down with slow down ramp;
disable of the drive function

No

15-3-2-3 Various mode control method (by following DS402 standard)
Control mode of C2000, supporting speed, torque, position and home control are described as
below:
Speed mode
1. Let Ac Motor Drive be at the speed control mode: Set Index6060 to 2.
2. Switch to Operation Enable mode: Set 6040=0xE, then set 6040 = 0xF.
3. To set target frequency: Set target frequency of 6042, since the operation unit of 6042 is rpm, there
is a transformation:

nf

120
p

n: rotation speed (rpm) (rounds/minute)

P: motor’s pole number (Pole)

f: rotation frequency (Hz)
For example:
Set 6042H = 1500 (rpm), if the motor drive's pole number is 4 (Pr05-04 or Pr05-16), then the
motor drive's operation frequency is 1500(120/4)=50Hz.
Besides, the 6042 is defined as a signed operation. The plus or minus sign means to rotate
clockwise or counter clockwise
4. To set acceleration and deceleration: Use 604F(Acceleration) and 6050(Deceleration).
5. Trigger an ACK signal: In the speed control mode, the bit 6~4 of Index 6040 needs to be controlled.
It is defined as below:
Speed mode
(Index 6060=2)

Bit 6
1
1

Index 6040
Bit 5
0
1
Other

15-11

Bit 4
1
1

SUM
Locked at the current signal.
Run to reach targeting signal.
Decelerate to 0Hz.

Chapter 15 CANopen Overview C2000 Series

NOTE 01: To know the current rotation speed, read 6043. (unit: rpm)
NOTE 02: To know if the rotation speed can reach the targeting value; read bit 10 of 6041. (0: Not
reached; 1: Reached)
Torque mode
1. Let Ac Motor Drive be at the torque control mode: Set Index6060 = 4.
2. Switch the current mode to Operation Enable, set 6040 = 0xE, then set 6040 = 0xF.
3. To set targeting torque: Set 6071 as targeting torque and 6072 as the largest output torque.
Index 6040
SUM
Torque mode
Bit 6
Bit 5
Bit 4
(Index 6060=4)
X
X
X
RUN to reach the targeting torque.

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Chapter 15 CANopen Overview C2000 Series

NOTE: The standard DS402 doesn’t regulate the highest speed limit. Therefore if the motor drive
defines the control mode of DS402, the highest speed will go with the setting of Pr11-36 to
Pr11-38.
NOTE 01: To know the current torque, read 6077 (unit: 0.1%).
NOTE02: To know if reaching the targeting torque, read bit 10 of 6041. (0: Not reached; 1: Reached)
Position mode
1. Set the parameter of a trapezium curve to define position control (Pr11-43 Max. Frequency of
Point- to-Point Position Control, Pr11-44 Accel. Time of Point-to Point Position Control and
Pr11-45 Decel. Time of Point-to Point Position Control)
2. Let Ac Motor Drive be at the position control mode: Then set Index 6060 = 1.
3. Switch the current mode to Operation Enable, set 6040 = 0xE and then set 6040 = 0xF.
4. To set targeting position: set 607A as the targeting position.
5. Trigger an ACK signal: Set 6040 = 0x0F then set 6040 = 0x1F. (Bit4 changes from 0 to 1).

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Chapter 15 CANopen Overview C2000 Series

NOTE 01: To know the current position, read 6064.
NOTE 02: To know if the position reaches the targeting position, read bit 10 of 6041. (0: reached, 1:
Not reached)
NOTE 03: To know if the position is over the limited area, read bit 11 of 6041 (0: in the limit, 1: over
the limit)
Home mode
1. Set Pr00-12 to choose a home method.
2. Set the left and right limits correspond to the position of MI terminal.
3. To switch Ac Motor Drive control mode to Home mode: Set Index 6060 = 6.
4. To switch from current mode to Operation Enable: Set 6040 = 0xE, then set 6040 = 0xF.
5. To trigger an ACK signal: Set 6040 = 0x0F, then set 6040 = 0x1F (Bit4 changes from 0 to 1 and the
motor drive will be back to home.)
Note 01: To know if the home mode is completed, read bit 12 of 6041.

(0: reached, 1: Not reached)

15.3.3 By using Delta Standard (Old definition, only support speed mode)
15-3.3.1 Various mode control method (by following DS402 standard)
If you want to use DS402 standard to control the motor drive, please follow the steps below:
1.

Wiring for hardware (Refer to chapter 15.2 Wiring for CANopen)

2.

Operation source setting: set Pr.00-21 to 3 for CANopen communication card control.

3.

Frequency source setting: set Pr.00.20 to 6. (Choose source of frequency commend from
CANopen setting.)

15-14

Chapter 15 CANopen Overview C2000 Series

4.

Set Delta Standard (Old definition, only support speed mode) as control mode: Pr. 09-40 = 0 and
09-30 = 0.
CANopen station setting: set Pr.09-36 (Range of setting is 1~127. When Pr.09-36=0, CANopen
slave function is disabled. ) (Note: If error arised (CAdE or CANopen memory error) as station
setting is completed, press Pr.00-02=7 for reset.)

5.

CANopen baud rate setting: set Pr.09.37 (CANBUS Baud Rate: 1M(0), 500K(1), 250K(2),
125K(3), 100K(4) and50K(5))

15-3-3-2 By speed mode
1. Set the target frequency: Set 2020-02, the unit is Hz, with a number of 2 decimal places. For
example 1000 is 10.00.
2. Operation control: Set 2020-01 = 0002H for Running, and set 2020-01 = 0001H for Stopping.

15.3.4 By using Delta Standard (New definition)
15-3-4-1 Related set up of ac motor drive (Delta New Standard)
If you want to use DS402 standard to control the motor drive, please follow the steps below:
1.

Wiring for hardware (Refer to chapter 15.2 Wiring for CANopen)

2.

Operation source setting: set Pr.00-21 to 3 for CANopen communication card control.

3.

Frequency source setting: set Pr.00.20 to 6. (Choose source of frequency commend from
CANopen setting.)

4.

Source of torque setting is set by Pr.11-33.
CANopen setting.)

15-15

(Choose source of torque commend from

Chapter 15 CANopen Overview C2000 Series

5.

CANopen station setting: set Pr.09-36 (Choose source of position commend from CANopen
setting.)

6.

Set Delta Standard (Old definition, only support speed mode) as control mode: Pr. 09-40 = 0 and
09-30 = 0.

7.

CANopen station setting: set Pr.09-36 (Range of setting is 1~127. When Pr.09-36=0, CANopen
slave function is disabled. ) (Note: If error arised (CAdE or CANopen memory error) as station
setting is completed, press Pr.00-02=7 for reset.)

8.

CANopen baud rate setting: set Pr.09.37 (CANBUS Baud Rate: 1M(0), 500K(1), 250K(2),
125K(3), 100K(4) and50K(5))

15-3-4-2 Various mode control method (Delta New Standard)
Speed Mode
1. Let Ac Motor Drive be at the speed control mode: Set Index6060 = 2.
2. Set the target frequency: set 2060-03, unit is Hz, with a number of 2 decimal places. For example
1000 is 10.00Hz.
3. Operation control: set 2060-01 = 008H for Server on, and set 2060-01 = 0081H for Running.

Torque Mode
1. Let Ac Motor Drive be at torque control mode: set Index 6060 = 4.
2. Set target torque: set 2060-07, unit is %, a number of 1 decimal place. For example 100 is 10.0%.
3. Operation control: Set 2060-01 = 0080H for Server on, then the motor drive will start to run to
reach target torque.

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Chapter 15 CANopen Overview C2000 Series

Note01 To know what the current torque is, read 2061-07 (unit is 0.1%).
Note02 To know if the torque can reach the setting value, read the bit 0 of 2061-01 (0: Not reached, 1:
Reached).
Note 03: When doing torque output and if the motor drive’s speed reaches the speed limit, the output
torque will decrease to ensure the speed is under the limit.
Position Mode
1. Set the parameter of a trapezium curve to define position control (Pr11-43 Max. Position Control
Frequency), Pr11-44 Accel. Time of Position Control, Pr11-45 Decel. Time of Position Control)
2. Let Ac motor drive be at the position control mode, set Index 6060 = 1.
3. Set 2060-01 = 0080h, then motor drive will have server on.
4. Set target position: set 2060-05 = target position.
5. Set 2060-01 =0081h to trigger the motor drive to run to the target position.
6. To move to another position, simply repeat step 3 to 5.

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Chapter 15 CANopen Overview C2000 Series

NOTE01: To know the current position, read 2061-05.
NOTE02: To know if reaching the target position, read bit 0 of 2061 (0: Not reached, 1: Reached).
Home Mode
1. Set Pr00-12 to choose how to return home.
2. Set the left and right limits correspond to the position of MI terminal.
3. To switch C2000 control mode to Home mode: Set Index 6060 = 6.
4. Set 2060-01 = 0080h, then motor drive will have server on.
5. Set the ACK signal: set 2060-01 = 0081h, then the motor drive will start to go back home.
NOTE 01: To know if returning home is completed, read bit12 of 6041 ( 0: Not reached, 1: Reached).

15-18

Chapter 15 CANopen Overview C2000 Series

15-3-5 DI/DO AI AO are controlled via CANopen
To control the DO AO of the motor drive through CANopen, follow the steps below:
1. To set the DO to be controlled, define this DO to be controlled by CANopen. For example, set
Pr02-14 to control RY2.
2. To set the DO to be controlled, define this AO to be controlled by CANopen. For example, set
Pr03-23 to control AFM2.
3. To control the mapping index of CANopen. If you want to control DO, then you will need to control
Index2026-41. If you want to control AO, then you will need to control 2026-AX. If you want to set
RY2 as ON, set the bit 1 of Index 2026-41 =1, then RY2 will output 1. If you want to control AFM2
output = 50.00%, then you will need to set Index 2026-A2 =5000, then AFM2 will output 50%.
Mapping table of CANopen DI DO AI AO:
DI:
Terminal
FWD

Related Parameters
==

R/W
RO

Mapping Index
2026-01 bit 0

REV

==

RO

2026-01 bit 1

MI 1

==

RO

2026-01 bit 2

MI 2

==

RO

2026-01 bit 3

MI 3

==

RO

2026-01 bit 4

MI 4

==

RO

2026-01 bit 5

MI 5

==

RO

2026-01 bit 6

MI 6

==

RO

2026-01 bit 7

MI 7

==

RO

2026-01 bit 8

MI 8

==

RO

2026-01 bit 9

MI 10

==

RO

2026-01 bit 10

MI 11

==

RO

2026-01 bit 11

MI 12

==

RO

2026-01 bit 12

MI 13

==

RO

2026-01 bit 13

MI 14

==

RO

2026-01 bit 14

MI 15

==

RO

2026-01 bit 15

Related Parameters
P2-13 = 50

R/W
RW

Mapping Index
2026-41 bit 0

P2-14 = 50

RW

2026-41 bit 1

P2-15 = 50

RW

2026-41 bit 2

MO1

P2-16 = 50

RW

2026-41 bit 3

MO2

P2-17 = 50

RW

2026-41 bit 4

MO3

P2-18 = 50

RW

2026-41 bit 5

MO4

P2-19 = 50

RW

2026-41 bit 6

DO：
Terminal
RY1
RY2

15-19

Chapter 15 CANopen Overview C2000 Series

MO5

P2-20 = 50

RW

2026-41 bit 7

MO6

P2-21 = 50

RW

2026-41 bit 8

MO7

P2-22 = 50

RW

2026-41 bit 9

MO8

P2-23 = 50

RW

2026-41 bit 10

Related Parameters
==

R/W
RO

Mapping Index
Value of 2026-61

ACI

==

RO

Value of 2026-62

AUI

==

RO

Value of 2026-63

Related Parameters
P3-20 = 20

R/W
RW

Mapping Index
Value of 2026-A1

P3-23 = 20

RW

Value of 2026-A2

AI：
Terminal
AVI

AO：
Terminal
AFM1
AFM2

15-20

Chapter 15 CANopen Overview C2000 Series

15.4 CANopen Supporting Index
C2000 Index:
Parameter index corresponds to each other as following:
Index

sub-Index

2000H + Group

member+1

For example:
Pr.10.15 (Encoder Slip Error Treatment)
Group

member

10(0 A H)

-

15(0FH)

Index = 2000H + 0AH = 200A
Sub Index = 0FH + 1H = 10H
C2000 Control Index:
Delta Standard Mode (Old definition)
Index Sub

Definition

0 Number

2020H

1 Control word

Factory
Setting
3

0

R/W

Size

R

U8

RW

15-21

U16

Note
Bit 1~0 00B:disable
01B:stop
10B:disable
11B: JOG Enable
Bit3~2 Reserved
Bit5~4 00B:disable
01B: Direction forward
10B: Reverse
11B: Switch Direction
Bit7~6 00B: 1st step Accel. /Decel.
01B: 2nd step Accel. /Decel.
10B: 3rd step Accel. /Decel.
11B: 4th step Accel. /Decel.
Bit11~8 0000B: Master speed
0001B: 1st step speed
0010B: 2nd step speed
0011B: 3rd step speed
0100B: 4th step speed
0101B: 5th step speed
0110B: 6th step speed
0111B: 7th step speed
1000B: 8th step speed
1001B: 9th step speed
1010B: 10th step speed
1011B: 11th step speed
1100B: 12th step speed
1101B: 13th step speed
1110B: 14th step speed
1111B: 15th step speed
Bit12 1: Enable the function of
Bit6-11
Bit14~13 00B: no function
01B: Operation command by
the digital keypad

Chapter 15 CANopen Overview C2000 Series
Index Sub

Definition

Factory
Setting

R/W

Size

Note

Bit 15

2021H

Freq. command
2
(XXX.XXHz)

0

RW

U16

3 Other trigger

0

RW

U16

DH
0
0

R
R
R

U8
U16
U16

0

R

U16

0
0
0
0

R
R
R
R

U16
U16
U16
U16

0

R

U16

0
0

R
R

U16
U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0
0
0

R
R
R

U16
U16
U16

0 Number
1 Error code
2 AC motor drive status

3
4
5
6
7
8
9
A
B
C
D
E
F
2022H

10
0
1

Freq. command
(XXX.XXHz)
Output freq. (XXX.XXHz)
Output current (XX.XA)
DC bus voltage (XXX.XV)
Output voltage (XXX.XV)
the current segment run by
the multi-segment speed
commend
Reserved
Display counter value（c）
Display output power angle
(XX.X°)
Display output torque
(XXX.X%)
Display actual motor speed
(rpm)
Number of PG feed back
pulses (0~65535)
Number of PG2 pulse
commands (0~65535)
power output (X.XXXKWH)
Reserved
Display output current

15-22

10B: Operation command by
Pr. 00-21 setting
11B: Switch the source of
operation command
Reserved

Bit0
1: E.F. ON
Bit1
1: Reset
Bit15~2 Reserved

Bit 1~0 00B: stop
01B: decelerate to stop
10B: waiting for operation
command
11B: in operation
Bit 2
1: JOG command
Bit 4~3 00B: forward running
01B: switch from reverse
running to forward running
10B: switch from forward
running to reverse running
11B: reverse running
Bit 7~5 Reserved
Bit 8
1: master frequency command
controlled by communication
interface
Bit 9
1: master frequency command
controlled by analog signal
input
Bit 10 1: operation command
controlled by communication
interface
Bit 15~11 Reserved

Chapter 15 CANopen Overview C2000 Series
Index Sub

Definition

2 Display counter value
Display actual output
3
frequency (XXX.XXHz)
Display DC-BUS voltage
4
(XXX.XV)
Display output voltage
5
(XXX.XV)
Display output power angle
6
(XX.X°)
7 Display output power in kW
Display actual motor speed
8
(rpm)
Display estimate output
9
torque (XXX.X%)
A Display PG feedback
Display PID feedback value
B after enabling PID function
in % (To 2 decimal places)
Display signal of AVI analog
C input terminal, 0-10V
corresponds to 0-100% (To 2

Factory
Setting
0

R/W

Size

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

decimal places)

Display signal of ACI analog
input terminal,
D 4-V20mA/0-10V
corresponds to 0-100% (To 2
decimal places)

Display signal of AUI analog
E input terminal, -10V~10V
corresponds to -100~100%
(To 2 decimal places)

F
10
11
12
13
14
15

16

17
18
19
1A

Display the IGBT
temperature of drive power
module in oC
Display the temperature of
capacitance in oC
The status of digital input
(ON/OFF), refer to Pr.02-12
The status of digital output
(ON/OFF), refer to Pr.02-18
Display the multi-step
speed that is executing
The corresponding CPU pin
status of digital input
The corresponding CPU pin
status of digital output
Number of actual motor
revolution (PG1 of PG
card). it will start from 9
when the actual operation
direction is changed or
keypad display at stop is 0.
Max. is 65535
Pulse input frequency (PG2
of PG card)
Pulse input position (PG
card PG2), maximum
setting is 65535.
Position command tracing
error
Display times of counter
overload (0.00~100.00%)

15-23

Note

Chapter 15 CANopen Overview C2000 Series
Index Sub

Factory
Setting
0

Definition

1B Display GFF in %
Display DCbus voltage
1C
ripples (Unit: Vdc)
Display PLC register D1043
1D
data
Display Pole of Permanent
1E
Magnet Motor
User page displays the
1F
value in physical measure
20 Output Value of Pr.00-05
Number of motor turns
21
when drive operates
22 Operation position of motor
23 Fan speed of the drive
Control mode of the drive 0:
24
speed mode 1: torque mode
Carrier frequency of the
25
drive

R/W

Size

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0

R

U16

0
0

R
R

U16
U16

0

R

U16

0

R

U16

Note

CANopen Remote IO mapping
Index
2026H

Sub
01h
02h
03h~40h
41h
42h~60h
61h
62h
63h
64h~A0h
A1h
A2h

R/W
R
R
R
RW
R
R
R
R
R
RW
RW

Definition
Each bit corresponds to the different input terminals
Each bit corresponds to the different input terminals
Reserved
Each bit corresponds to the different output terminals
Reserved
AVI (%)
ACI (%)
AUI (%)
Reserved
AFM1 (%)
AFM2 (%)

Delta Standard Mode (New definition)
Index sub R/W Size
00h R

Descriptions
bit DefinitionPriority

Speed Mode

Home Mode

U8
0

Ack

4

1

Dir

4

Pulse 1: Position
0:fcmd =0
1:fcmd = Fset(Fpid) control
0: FWD run
command
1: REV run
command

2
2060h

Position Mode

01h RW U16

3

Halt

4

Hold

5

JOG

6

QStop

0: drive run till target
speed is attained
1: drive stop by
declaration setting
0: drive run till target
speed is attained
1: frequency
stop at current
frequency
0:JOG OFF
Pulse 1:JOG RUN
Quick Stop

15-24

Pulse 1: Return to
home

Torque Mode

Chapter 15 CANopen Overview C2000 Series

Index sub R/W Size

Descriptions
bit DefinitionPriority
7

Power

14~8

Cmd
SW

15

Speed Mode

Position Mode

0:Power OFF
1:Power ON
Multi-step
frequency
switching
Pulse 1: Fault code
cleared

0:Power OFF
1:Power ON

Home Mode
0:Power OFF
1:Power ON

Torque Mode
0:Power OFF
1:Power ON

Multi-step position
switching
Pulse 1: Fault
code cleared

Pulse 1: Fault code Pulse 1: Fault
cleared
code cleared

02h RW U16
Speed command
(unsigned decimal)

03h RW U16
04h RW U16
05h RW S32
06h RW

Position command
Torque command
(signed decimal)
Speed limit
(unsigned decimal)

07h RW U16
08h RW U16

01h R U16

2061h

0

Arrive

1

Dir

2
Warn
3
Error
4
5
JOG
6
QStop
7 Power On
15~8

Frequency attained Position attained

Homing complete

Torque attained

0: Motor FWD run
1: Motor REV run
Warning
Error detected

0: Motor FWD run
1: Motor REV run
Warning
Error detected

0: Motor FWD run
1: Motor REV run
Warning
Error detected

0: Motor FWD run
1: Motor REV run
Warning
Error detected

JOG
Quick stop
Switch ON

JOG
Quick stop
Switch ON

JOG
Quick stop
Switch ON

JOG
Quick stop
Switch ON

Actual output
frequency

Actual output
frequency

Actual output
frequency

Actual output
frequency

Actual position
(absolute)

Actual position
(absolute)

Actual position
(absolute)

Actual position
(absolute)

Actual torque

Actual torque

Actual torque

Actual torque

02h R
03h R U16
04h R
05h R S32
06h R
07h R S16

DS402 Standard
Index Sub

Definition

Factory
Setting

6007h

0 Abort connection option code

2

603Fh
6040h
6041h
6042h
6043h
6044h
604Fh
6050h
6051h

0
0
0
0
0
0
0
0
0

Error code
Control word
Status word
vl target velocity
vl velocity demand
vl control effort
vl ramp function time
vl slow down time
vl quick stop time

0
0
0
0
0
0
10000
10000
1000

605Ah

0 Quick stop option code

2

R/W Size Unit

PDO
Mode
Map

RW S16

Yes

R0
RW
R0
RW
RO
RO
RW
RW
RW

Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes

U16
U16
U16
S16
S16
S16
U32
U32
U32

RW S16

15-25

rpm
rpm
rpm
1ms
1ms
1ms

No

Note
0: No action
2: Disable Voltage,
3: quick stop

vl
vl
vl
vl
vl
vl

Unit must be: 100ms, and
check if the setting is set to
0.
0 : disable drive function
1 :slow down on slow down
ramp
2: slow down on quick stop
ramp

Chapter 15 CANopen Overview C2000 Series

Index Sub

605Ch

0

6060h

Definition

Disable operation option

Factory
Setting

R/W Size Unit

PDO
Mode
Map

Note
5 slow down on slow down
ramp and stay in QUICK
STOP
6 slow down on quick stop
ramp and stay in QUICK
STOP
0: Disable drive function
1: Slow down with slow
down ramp; disable of the
drive function
1: Profile Position Mode
2: Velocity Mode
4: Torque Profile Mode
6: Homing Mode

1

RW S16

No

0 Mode of operation

2

RW

S8

Yes

6061h

0 Mode of operation display

2

RO

S8

Yes

6064h

0 pp Position actual value

0

RO S32

Yes

pp

6071h

0 tq Target torque

0

RW S16 0.1% Yes

tq

Valid unit: 1%

6072h

0 tq Max torque

150

RW U16 0.1% No

tq

Valid unit: 1%

6075h

0 tq Motor rated current

0

RO U32 mA No

tq

6077h

0 tq torque actual value

0

RO S16 0.1% Yes

tq

6078h

0 tq current actual value

0

RO S16 0.1% Yes

tq

6079h

0 tq DC link circuit voltage

0

RO U32 mV Yes

tq

607Ah

0 pp Target position

0

RW S32

pp

code

15-26

1

Yes

Same as above

Chapter 15 CANopen Overview C2000 Series

15.5 CANopen Fault Code
Display

Fault

ocA

Fault code

Description

CANopen
fault code

CANopen
fault
register
(bit 0~7)

0001H

Over-current during acceleration

2213 H

1

0002H

Over-current during deceleration

2213 H

1

2214H

1

2240H

1

2250H

1

2314H

1

3210H

2

3210H

2

3210H

2

3210H

2

Oc at accel
Fault

ocd
Oc at decel

Fault

ocn

0003H

Oc at normal SPD

Over-current during steady status
operation
Ground fault. When (one of) the output
terminal(s) is grounded, short circuit

Fault

GFF

0004H

Ground fault

current is more than 50% of AC motor
drive rated current.
NOTE: The short circuit protection is provided for
AC motor drive protection, not for protection of the
user.

Short-circuit is detected between upper

Fault

occ

0005H

IGBT module.

Short Circuit
Fault

ocS

0006H

Oc at stop
Fault

ovA

0007H

Ov at accel
Fault

ovd

0008H

Ov at decel
Fault

ovn

0009H

Ov at normal SPD
Fault

ovS
Ov at stop

bridge and lower bridge of the

000AH

Over-current at stop. Hardware failure in
current detection

Over-current during acceleration.
Hardware failure in current detection

Over-current during deceleration.
Hardware failure in current detection.

Over-current during steady speed.
Hardware failure in current detection.

Over-voltage at stop. Hardware failure in
current detection

15-27

Chapter 15 CANopen Overview C2000 Series

Display

Fault

LvA

Fault code

000BH

Lv at accel
Fault

Lvd

000CH

Lv at decel

Fault

Lvn

000DH

Lv at normal SPD
Fault

LvS

000EH

Lv at stop
Fault

OrP

000FH

Description

DC BUS voltage is less than Pr.06.00
during acceleration.

DC BUS voltage is less than Pr.06.00
during deceleration.

DC BUS voltage is less than Pr.06.00 in
constant speed.

DC BUS voltage is less than Pr.06-00 at
stop

Phase Loss Protection

CANopen
fault code

CANopen
fault
register
(bit 0~7)

3220H

2

3220H

2

3220H

2

3220H

2

3130H

2

4310H

3

4310H

3

FF00H

3

FF01H

3

FF02H

2

Phase Lacked

IGBT overheat
IGBT temperature exceeds protection

Fault

oH1

0010H

level.
1~15HP: 90℃

IGBT over heat

20~100HP: 100℃
Fault

oH2

0011H

Hear Sink oH

Heat sink overheat
Heat sink temperature exceeds 90oC
Temperature detection circuit error

Fault

tH1o

0012H

(IGBT)
IGBT NTC

Thermo 1 open

Temperature detection circuit error

Fault

tH2o

0013H

CAP NTC

Thermo 2 open
Fault

PWR

(capacity module)

0014H

Power RST off

Power RST OFF

15-28

Chapter 15 CANopen Overview C2000 Series

Display

Fault code

Description

CANopen
fault code

CANopen
fault
register
(bit 0~7)

2310H

1

Overload. The AC motor drive detects
Fault

oL

0015H

Inverter oL
Fault

EoL2
EoL1

excessive drive output current.
NOTE: The AC motor drive can withstand up to
150% of the rated current for a maximum of 60
seconds.

0016H

Electronics thermal relay 1 protection

2310H

1

0017H

Electronics thermal relay 2 protection

2310H

1

8311H

3

8311H

3

8321H

1

5530H

5

Thermal relay 1
2
Fault

EoL2
Thermal relay 2

These two fault codes will be displayed

Fault

EoL2
ot1

001AH

Thermal
Over
torque
relay
12

when output current exceeds the
over-torque detection level (Pr.06.07 or
Pr.06.10) and exceeds over-torque

Fault

EoL2
ot2

001BH

set 2 or 4 in Pr.06-06 or Pr.06-09.

Thermal
Over
torque
relay
22
Fault

EoL2
uC

detection (Pr.06.08 or Pr.06.11) and it is

001CH

Low current

Thermal
Under
torque
relay12
Fault

EoL2
cF1

001EH

Thermal relay
EEPROM
write2Err
Fault

EoL2
cF2

Internal EEPROM can not be
programmed.

001FH

Internal EEPROM can not be read.

5530H

5

0021H

U-phase error

FF04H

1

0022H

V-phase error

FF05H

1

0023H

W-phase error

FF06H

1

Thermal relay
EEPROM
read2Err
Fault

EoL2
cd1
Thermal
Ias
sensor
relay
Err 2
Fault

EoL2
cd2
Thermal
Ibs
sensor
relay
Err 2

Fault

EoL2
cd3
Thermal
Ics
sensor
relay
Err 2

15-29

Chapter 15 CANopen Overview C2000 Series

CANopen
fault
register
(bit 0~7)

Display

Fault code

EoL2
Hd0

0024H

cc (current clamp) hardware error

FF07H

5

0025H

oc hardware error

FF08H

5

0026H

ov hardware error

FF09H

5

0027H

GFF hardware error

FF0AH

5

0028H

Auto tuning error

FF21H

1

0029H

PID loss (ACI)

FF22H

7

002AH

PG feedback error

7301H

7

002BH

PG feedback loss

7301H

7

002BH

PG feedback stall

7301H

7

002CH

PG slip error

7301H

7

0030H

ACI loss

FF25H

1

Fault

Description

CANopen
fault code

Thermal
cc
HW Error
relay 2
Fault

EoL2
Hd1
Thermal
oc
HW Error
relay 2

Fault

EoL2
Hd2
Thermal
ov
HW Error
relay 2
Fault

EoL2
Hd3
Thermal
GFF
HW relay
Error 2
Fault

EoL2
AUE
Thermal
Auto
tuning
relay
Err2
Fault

EoL2
AFE
Thermal
PID
Fbk Error
relay 2
Fault

EoL2
PGF1
Thermal
PG
Fbk Error
relay 2
Fault

EoL2
PGF2
Thermal
PG
Fbk Loss
relay 2

Fault

EoL2
PGF3
Thermal
PG
Fbk Over
relaySPD
2
Fault

EoL2
PGF4
Thermal
PG
Fbk deviate
relay 2
Fault

EoL2
ACE
Thermal
ACI
loss relay 2

15-30

Chapter 15 CANopen Overview C2000 Series

Display

Fault code

Description

CANopen
fault code

CANopen
fault
register
(bit 0~7)

9000H

5

9000H

5

9000H

5

FF26H

5

External Fault
Fault

EoL2
EF

0031H

Thermal relay
External
Fault 2

When input EF (N.O.) on external
terminal is closed to GND, AC motor
drive stops output U, V, and W.
Emergency stop
When the multi-function input terminals

Fault

EoL2
EF1

0032H

MI1 to MI6 are set to emergency stop,
the AC motor drive stops output U, V, W

Thermal relay
Emergency
stop
2

and the motor coasts to stop.
External Base Block
Fault

EoL2
bb

0033H

Thermal
Base
block
relay 2
Fault

EoL2
Pcod

EoL2
ccod

MI16 are set as bb and active, the AC
motor drive output will be turned off

0034H

Thermal relay
Password
Error
2
Fault

When the external input terminals MI1 to

Password will be locked if three fault
passwords are entered

0035H

Software error

6100H

5

0036H

Illegal function code

7500H

4

0037H

Illegal data address (00H to 254H)

7500H

4

0038H

Illegal data value

7500H

4

0039H

Data is written to read-only address

7500H

4

003AH

Modbus transmission timeout.

7500H

5

Thermal
SW
coderelay
Error2

Fault

EoL2
cE1
Thermal CMD
Modbus
relay err
2
Fault

cE2
Thermal ADDR
Modbus
relay 2err
Fault

cE3
Thermal DATA
Modbus
relay 2err
Fault

cE4
Thermal slave
Modbus
relay FLT
2
Fault

cE10
Thermal time
Modbus
relayout
2

15-31

Chapter 15 CANopen Overview C2000 Series

CANopen
fault
register
(bit 0~7)

Display

Fault code

cP10

003BH

Keypad transmission timeout.

7500H

4

003CH

Brake resistor fault

7110H

4

003DH

Motor Y-∆ switch error

3330H

2

003EH

Energy regeneration when decelerating

FF27H

2

FF28H

7

Fault

Description

CANopen
fault code

Thermaltime
Keypad
relayout
2
Fault

bF
Thermalfault
Braking
relay 2

Fault

ydc
Thermalconnect
Y-delta
relay 2
Fault

dEb
Thermal
Dec.
Energy
relayback
2

Over slip error. Slip exceeds Pr.05.26

Fault

oSL

003FH

setting.

Thermal
Over
sliprelay
Error2
Fault

PGF5

limit and slip duration exceeds Pr.05.27

0041H

PG Card Error

FF29H

5

0042H

over current caused by unknown reason

2310H

1

0043H

over voltage caused by unknown reason

3210H

2

0049H

external safety emergency stop

FF2AH

5

0052H

U phase output phase loss

2331H

2

0053H

V phase output phase loss

2332H

2

Thermal
PG
HW Error
relay 2
Fault

ovU
ocU
Over volt.
Thermal
Unknow
Over
relay
Unknow
Apm
2
Fault

ovU
Thermal Over
Unknow
relay volt.
2

Fault

S1
Thermal relay
S1-Emergy
stop
2
Fault

OPHL
Thermal
U
phase lacked
relay 2
Fault

OPHL
Thermal
U
phase lacked
relay 2

15-32

Chapter 15 CANopen Overview C2000 Series

Display

Fault code

OPHL

0054H

Fault

Description

W phase output phase loss

CANopen
fault code

CANopen
fault
register
(bit 0~7)

2333H

2

Thermal
U
phase lacked
relay 2
Fault

aocc

004FH

A phase short

FF2BH

1

0050H

B phase short

FF2CH

1

0051H

C phase short

FF2DH

1

0065H

Guarding time-out 1

8130H

4

0066H

Heartbeat time-out

8130H

4

0067H

CAN synchrony error

8700H

4

0068H

CAN bus off

8140H

4

0069H

Can index exceed

8110H

4

006AH

CAN address error

0x8100

4

006BH

CAN frame fail

0x8100

4

Thermal
A
phase short
relay 2

Fault

bocc
Thermal
B
phase short
relay 2
Fault

cocc
Thermal
C
phase short
relay 2
Fault

CGdE
Thermal relay
Guarding
T-out2
Fault

CHbE
Thermal relay
Heartbeat
T-out
2
Fault

CSyE
Thermal
SYNC
T-out
relay 2
Fault

CbFE
Thermalbus
CAN/S
relay
off 2

Fault

CIdE
Thermal relay 2
Fault

CAdE
Thermal relay 2
Fault

CFdE
Thermal relay 2

15-33

Chapter 15 CANopen Overview C2000 Series

15.6 CANopen LED Function
There are two CANopen flash signs: RUN and ERR.
RUN LED:
LED status

Condition

CANopen State

OFF

Initial

Blinking

Pre-Operation

Single flash

Stopped

ON

Operation

ERR LED:
LED status

Condition/ State

OFF

No Error

Single

One Message fail

flash

Double

Guarding fail or heartbeat fail

flash

Triple flash SYNC fail

ON

Bus off

15-34

PLC Function Applications

16 PLC Function Applications
16-1

PLC Summary

16-2

Notes before PLC use

16-3

Turn on

16-4

16-3-1

Connect to PC

16-3-2

I/O device explanation

16-3-3

Installation WPLSoft

16-3-4

Program writing

16-3-5

Program download

16-3-6

Program monitoring

Basic principles of PLC ladder diagrams
16-4-1

Schematic diagram of PLC ladder diagram program

scanning

16-5

16-6

16-4-2

Introduction to ladder diagrams

16-4-3

Overview of PLC ladder diagram editing

16-4-4

Commonly-used basic program design examples

Various PLC device functions
16-5-1

Introduction to device functions

16-5-2

Introduction to special relay functions (special M)

16-5-3

Introduction to special register functions (special D)

16-5-4

PLC Communication address

Introduction to the Command Window
16-6-1

Overview of basic commands

16-6-2

Detailed explanation of basic commands

16-6-3

Overview of application commands

16-6-4

Detailed explanation of applications commands

16-6-5

Detailed explanation of driver special applications

commands

16-7

Error display and handling

16-8

CANopen Master control applications

16-9

Explanation of various PLC mode controls (speed, torque,

homing, and position)
16-10 Internal communications main node control
16-11 Count function using MI8
16-11-1 High-speed count function
16-11-2 Frequency calculation function

16-12 Modbus remote IO control applications (use MODRW)
16-13 Calendar

16-1

16-1 PLC Summary
16-1-1 Introduction
The commands provided by the C2000's built-in PLC functions, including the ladder diagram editing
tool WPLSoft, as well as the usage of basic commands and applications commands, chiefly retain
the operating methods of Delta's PLC DVP series.

16-1-2 WPLSoft ladder diagram editing tool
WPLSoft is Delta's program editing software for the DVP and C2000 programmable controllers in the
Windows operating system environment. Apart from general PLC program design general Windows
editing functions (such as cut, paste, copy, multiple windows, etc.), WPLSoft also provides many
Chinese/English annotation editing and other convenience functions (such as registry editing,
settings, file reading, saving, and contact graphic monitoring and settings, etc.).
The following basic requirements that need to install WPLSoft editing software:
Item
Operating system
CPU
Memory
Hard drive
Display

System requirements
Windows 95/98/2000/NT/ME/XP
At least Pentium 90
At least 16MB (we recommend at least 32MB)
Hard drive capacity: at least 100MB free space
One optical drive (for use in installing this software)
Resolution: 640×480, at least 16 colors; it is recommended that the screen
area be set at 800×600 pixels

Mouse

Ordinary mouse or Windows-compatible device

Printer

Printer with a Windows driver program

RS-485 port
Suitable PLC
models

Must have at least an RS-485 port to link to the PLC
Delta's full DVP-PLC series, VFD-C2000 series

16-2

PLC Function Applications

16-2
1.

Notes before PLC use

The PLC has a preset communications format of 7,N,2,9600, with node 2; the PLC node can be
changed in parameter 09-35, but this address may not be the same as the converter's address
setting of 09-00.

2.

The C2000 provides 2 communications serial ports that can be used to download PLC programs
(see figure below). Channel 1 has a fixed communications format of 19200,8,N,2 RTU.

3.

The client can simultaneously access data from the converter and internal PLC, which is
performed through identification of the node. For instance, if the converter node is 1 and the
internal PLC node is 2, then the client command will be
01 (node) 03 (read) 0400 (address) 0001 (1 data item), indicating that it must read the data in
converter parameter 04-00
02 (node) 03 (read) 0400 (address) 0001 (1 data item), indicating that it must read the data in
internal PLC X0

4.

The PLC program will be disabled when uploading/downloading programs.

5.

Please note when using WPR commands to write in parameters, values may be modified up to
a maximum of 109 times, otherwise a memory write error will occur. The calculation of
modifications is based on whether the entered value has been changed. If the entered value is
left unchanged, the modifications will not increase afterwards. But if the entered value is
different from before, the number of modifications will increase by one.

6.

When parameter 00-04 is set as 28, the displayed value will be the value of PLC register D1043
(see figure below):
Digital Keypad KPC-CC01

Digital Keypad KPC-CE01

Can display 0~65535

0~9999

16-3

When more than 9999

H 0.00Hz
A 0.00Hz
C _____
7.

In the PLC Run and PLC Stop mode, the content 9 and 10 of parameter 00-02 cannot be set
and cannot be reset to the default value.

8.

The PLC can be reset to the default value when parameter 00-02 is set as 6.

9.

The corresponding MI function will be disabled when the PLC writes to input contact X.

10. When the PLC controls converter operation, control commands will be entirely controlled by the
PLC and will not be affected by the setting of parameter 00-21.
11. When the PLC controls converter frequency commands (FREQ commands), frequency
commands will be entirely controlled by the PLC, and will not be affected by the setting of
parameter 00-20 or the Hand ON/OFF configuration.
12. When the PLC controls converter frequency (TORQ commands), torque commands will be
entirely controlled by the PLC, and will not be affected by the setting of parameter 11-33 or the
Hand ON/OFF configuration.
13. When the PLC controls converter frequency (POS commands), position commands will be
entirely controlled by the PLC, and will not be affected by the setting of parameter 11-40 or the
Hand ON/OFF configuration.
14. When the PLC controls converter operation, if the keypad Stop setting is valid, this will trigger
an FStP error and cause stoppage.

16-4

PLC Function Applications

16-3 Turn on
16-3-1 Connect to PC
Start operation of PLC functions in accordance with the following four steps
1.

After pressing the Menu key and selecting 4: PLC on the KPC-CC01 digital keypad, press
the Enter key (see figure below).

NOTE
If the optional KPC-CE01 digital keypad is used, employ the following method:
Switch to the main PLC2 screen: After powering up the drivers, press the

switch to the function screen, which will then display "PrSET." After using the
"PLC" screen, and then press

key on the KPC-CE01 once to

up or down button to switch to the

to enter PLC function settings. Afterwards, press the Up key to switch to

"PLC2," and then press
. The screen will now display "PLSn" and flash, indicating that the internal PLC
currently has no program, and this error message can be ignored. If the PLC has an editing program, the screen will
display "End," and will jump back to "PLC2" after 1 to 2 seconds. When no program has been downloaded to the
drivers, the program can continue to run even if a PLC warning message appears.

2.

Wiring: Connect the driver's RJ-45 communications interface to a PC via the RS485

16-5

3.

PLC function usage

PLC
1.Disable
2.PLC Run
3.PLC Stop




PLC functions are as shown in the figure on the left; select
item 2 and implement PLC functions.

1: No function (Disable)
2: Enable PLC (PLC Run)
3: Stop PLC functions (PLC Stop)

Optional product: PLC function display

PLC 0 : Do not implement PLC functions

method on KPC-CE01 digital keypad

PLC 1 : Initiate PLC Run
PLC 2 : Initiate PLC Stop




When the external multifunctional input terminals (MI1 to MI8) are in PLC Mode select bit0
(51) or PLC Mode select bit1 (52), and the terminal contact is closed or open, it will
compulsorily switch to the PLC mode, and keypad switching will be ineffective.
Corresponding actions are as follows:
PLC mode
Using KPC-CC01 Using KPC-CE01
Disable
PLC 0
PLC Run
PLC 1
PLC Stop
PLC 2
Maintain previous Maintain previous
state
state

PLC Mode select bit1(52)

PLC Mode select bit0 (51)

OFF
OFF
ON

OFF
ON
OFF

ON

ON

Use of KPC-CE01 digital keypad to implement PLC functions


When the PLC screen switches to the PLC1 screen, this will trigger one PLC action,
and the PLC program start/stop can be controlled by communications via the WPL.



When the PLC screen switches to the PLC2 screen, this will trigger one PLC stop, and
the PLC program start/stop can be controlled by communications via the WPL.



The external terminal control method is the same as shown in the table above.
NOTE




When input/output terminals (FWD REV MI1 to MI8 MI10 to 15, Relay1, Relay2 RY10 to RY15, MO1 to MO2
MO10 to MO11,) are included in the PLC program, these input/output terminals will only be used by the PLC. As
an example, when the PLC program controls Y0 during PLC operation (PLC1 or PLC2), the corresponding
output terminal relay(RA/RB/RC) will operate in accordance with the program. At this time, the multifunctional
input/output terminal setting will be ineffective. Because these terminal functions are already being used by the
PLC, the DI DO AO in use by the PLC can be determined by looking at parameter 02-52, 02-53, and 03-30.




When the PLC's procedures use special register D1040, the corresponding AO contact AFM1 will be occupied,
and AFM2 corresponding to special register D1045 will have the same situation.




Parameter 03-30 monitors the state of action of the PLC function analog output terminal; Bit0 corresponds to the
AFM1 action state, and Bit1 corresponds to the AFM2 action state.

16-6

PLC Function Applications

16-3-2 I/O device explanation
Input devices:
Serial X0
X1
No.
1
FWD REV
2
3

X2

X3

X4

X5

X6

X7

X10

X11

MI1

MI2

MI3

MI4

MI5

MI6

MI7

MI8

X12

X13

X14

X15

X16

X17

MI10 MI11 MI12 MI13 MI14 MI15
MI10 MI11 MI12 MI13

1: Control I/O |
2: Expansion card EMC-D611A (D1022=4)
3: Expansion card EMC-D42A (D1022=5)

Output devices:
Serial
Y0
No.
1
RY1
2
3

Y1
RY2

Y2

Y3

Y4

MO1

MO2

Y5

Y6

Y7

Y10

Y11

Y12

Y13

Y14

Y15

Y16

Y17

MO10 MO11
RY10 RY11 RY12 RY13 RY14 RY15

1: Control I/O |
2: Expansion card EMC-D42A (D1022=5)
3: Expansion card EMC-R6AA (D1022=6)

16-3-3 Installation WPLSoft
See Delta's website for WPLSoft editing software:
http://www.delta.com.tw/industrialautomation/download.

16-3-4 Program writing
After completing installation, the WPLSoft program will be installed in the designated subfolder
"C:\Program Files\Delta Industrial Automation\WPLSoft x.xx." The editing software can now be run
by clicking on the WPL icon using the mouse.

16-7

The WPL editing window will appear after 3 seconds (see figure below). When running WPLSoft for
the first time, before "New file" has been used, only the "File (F)," "Communications (C)," View (V),"
"Options (O)," and "Help (H)" columns will appear on the function toolbar.

After running WPLSoft for the second time, the last file edited will open and be displayed in the
editing window. The following figure provides an explanation of the WPLSoft editing software window:

Click on the

icon on the toolbar in the upper left part of the screen: opens new file (Ctrl+N)

16-8

PLC Function Applications

You can also use "File (F)"=> New file (N) (Ctrl+N)

The "Device settings" window will appear after clicking. You can now enter the project title and
filename, and select the device and communication settings to be used

Communications settings: Perform settings in accordance with the desired communications method

16-9

Press Confirm after completing settings and begin program editing. There are two program editing
methods; you can choose whether to perform editing in the command mode or the ladder diagram
mode.

In ladder diagram mode, you can perform program editing using the buttons on the function icon row

Basic Operation
Example: Input the ladder diagram in the following figure

16-10

PLC Function Applications

Mouse operation and keyboard function key (F1 to F12) operation
1. The following screen will appear after a new file has been established:

2. Use the mouse to click on the always-open switch icon

or press the function key F1:

3. After the name of the input device and the comment dialog box have appeared, the device name
(such as "M"), device number (such as "10"), and input comments (such as "auxiliary contact")
can be selected; press the Confirm button when finished.

16-11

4. Click on the output coil icon

or press function key F7. After the name of the input device and

the comment dialog box have appeared, the device name (such as "Y"), device number (such as
"0"), and input comments (such as "output coil") can be selected; press the Confirm button when
finished.

5. Click on application command icon

or press function key F6. Click on "All application

commands" in the function classification field, and click on the End command in the application
command pull-down menu, or use the keyboard to key in "End" in that field, and press the confirm
button.

16-12

PLC Function Applications

6. Click on the

icon, which will compile the edited ladder diagram as a command program.

After compiling, the number of steps will appear on the left side of the busbar.

16-3-5 Program download
After inputting a program using WPLSoft, select compile
the

. After completing compilation, select

to download a program. WPLSoft will perform program download with the online PLC in the

communications format specified in communications settings.

16-3-6 Program monitoring
While confirming that the PLC is in the Run mode, after downloading a program, click on
communications menu and select start ladder diagram control (see figure below)

16-13

in the

16-4 Basic principles of PLC ladder diagrams
16-4-1 Schematic diagram of PLC ladder diagram program scanning

Output results are
calculated on the basis of
the ladder diagram
configuration

Repeated

(internal devices will have

implementation

real-time output
before results are sent to
an external output point)

16-4-2 Introduction to ladder diagrams
Ladder diagrams comprise a graphic language widely applied in automatic control, and employs
common electrical control circuit symbols. After a ladder diagram editor has been used to create a
ladder pattern, PLC program designed is completed. The use of a graphic format to control
processes is very intuitive, and is readily accepted by personnel who are familiar with electrical
control circuit technology. Many of the basic symbols and actions in a ladder diagram comprise
commonly-seen electrical devices in conventional automatic control power distribution panels, such
as buttons, switches, relays, timers, and counters.
Internal PLC devices: The types and quantities of internal PLC devices vary in different brands of
products. Although these internal devices use the same names as conventional electrical control
circuit elements such as relays, coils, and contacts, a PLC does not actually contain these physical
devices, and they instead correspond to basic elements in the PLC's internal memory (bits). For
instance, if a bit is 1, this may indicate that a coil is electrified, and if that bit is 0, it will indicate that
the coil is not electrified. An NO contact (Normal Open, or contact a) can be used to directly read the
value of the corresponding bit, and an NC contact (Normal Close, or contact b) can be used to obtain
the inverse of the bit's value. Multiple relays occupy multiple bits, and 8 bits comprise one byte; two
16-14

PLC Function Applications

bytes comprise one word, and two words comprise a double word. When multiple relays are
processing at the same time (such as addition/subtraction or displacement, etc.), a byte, word, or
double word can be used. Furthermore, a PLC contains two types of internal devices: a timer and a
counter. It not only has a coil, but can count time and numerical values. Because of this, when it is
necessary to process some numerical values, these values are usually in the form of bytes, words, or
double words.
The various internal devices in a PLC all account for a certain quantity of storage units in the PLC's
storage area. When these devices are used, the content of the corresponding storage area is red in
the form of bits, bytes, or words.
Introduction to the basic internal devices in a PLC
Device type

Input Relay

Description of Function
An input relay constitutes the basic unit of storage in a PLC's internal memory
corresponding to an external input point (which serves as a terminal connecting
with an external input switch and receiving external input signals). It is driven by
external input signals, to which it assigns values of 0 or 1. A program design
method cannot change the input relay status, and therefore cannot rewrite the
corresponding basic units of an input relay, and WPLSoft cannot be used to
perform compulsory On/Off actions. A relay's contacts (contacts a and b) can be
used an unlimited number of times. An input relay with no input signal must be left
idle and cannot be used for some other purpose.
 Device indicated as: X0, X1, X7, X10, X11, etc. This device is expressed
with the symbol "X," and a device's order is indicated with an octal number.
Input point numbers are indicated in the main computer and in expansion
devices.

Output Relay

An output relay constitutes the basic unit of storage in a PLC's internal memory
corresponding to an external output point (which connects with an external load).
It may be driven by an input relay contact, a contact on another internal device, or
its own contacts. It uses one NO contact to connect with external loads or other
contacts, and, like input contacts, can use the contact an unlimited number of
times. An output relay with no input signal will be idle, but may be used an internal
relay if needed.
Device indicated as: Y0, Y1, Y7, Y10, Y11, etc. This device is expressed
with the symbol "Y," and a device's order is indicated with an octal number.
Output point numbers are indicated in the main computer and in expansion
devices.

Internal Relay

Internal relays have no direct connection with the outside. These relays are
auxiliary relays inside a PLC. Their function is the same as that of an auxiliary
(central) relay in an electrical control circuit: Each auxiliary relay corresponding to
a basic unit of internal storage; they can be driven by input relay contacts, output
relay contacts, and the contacts of other internal devices. An internal auxiliary
relay's contact can also be used an unlimited number of times. Internal relays
have no outputs to outside, and must output via an output point.
 Device indicated as: M0, M1 to M799, etc. This device is expressed as the
symbol "M," expressed, and its order is expressed as a decimal number.

Counter

A counter is used to perform counting operations. A count setting value (such as
the number of pulses to be counted) must be assigned when a counter is used. A
counter contains a coil, contact, and a counting storage device. When the coil
goes from Off to On, this indicates that the counter has an input pulse, and one
is added to its count. There are 16 bits that can be employed by the user.
 Device indicated as: C0, C1 to C79, etc. This device is expressed as the
symbol "C," expressed, and its order is expressed as a decimal number.

16-15

Device type

Description of Function

Timer

A timer is used to complete control of timing. The timer contains a coil, contact,
and a time value register. When the coil is electrified, if the preset time is reached,
the contact will be actuated (contact a will close, contact b will open), and the
timer's fixed value be given by the set value. Timer has a regulated clock cycle
(timing units: 100 ms). As soon as power to the coil is cut off, the contact will no
longer be actuated (contact a will open, contact b will close), and the original
timing value will return to zero.
 Device indicated as: T0, T1 to T159, etc. The device is expressed as the
symbol "T," and its order is expressed as a decimal number.

Data register

When a PLC is used to perform various types of sequence control and set time
value and count value control, it most commonly perform data processing and
numerical operations, and data registers are used exclusively for storage of data
and various parameters. Each data register contains 16 bits of binary data, which
means that it can store one word. Two data registers with adjacent numbers can
be used to process double words.
 Device indicated as: D0, D1 to D399, etc. The device is expressed as the
symbol "D," and its order is expressed as a decimal number.

Ladder diagram images and their explanation
Ladder diagram
structures

Explanation of commands

Command

NO switch, contact a

LD

NC switch, contact b

LDI

Series NO

AND

Series NC

ANI

、Y、M、T、C
X、Y、M、T、C
X、Y、M、T、C
X、Y、M、T、C

Parallel NO

OR

X

、Y、M、T、C

Parallel NC

ORI

X

、Y、M、T、C

Positive edge-triggered
switch

LDP

Negative edge-triggered
switch

LDF

Positive edge-triggered
series

ANDP

Negative edge-triggered
series

ANDF

、Y、M、T、C
X、Y、M、T、C
X、Y、M、T、C
X、Y、M、T、C

Positive edge-triggered
parallel

ORP

X

、Y、M、T、C

Negative edge-triggered
parallel

ORF

X

、Y、M、T、C

Block series

ANB

16-16

Using Device
X

X

N/A

PLC Function Applications

Ladder diagram
structures

Explanation of commands

Command

Using Device

Block parallel

ORB

N/A

Multiple outputs

MPS
MRD
MPP

N/A

Coil driven output
commands

OUT

Y M

Some basic
commands
Applications
commands
INV

N/A

Some basic commands,
applications commands
Inverted logic

、

16-4-3 Overview of PLC ladder diagram editing
The program editing method begins from the left busbar and proceeds to the right busbar (the right
busbar is omitted when editing using WPLSoft). Continue to the next row after completing each row;
there is a maximum of 11 contacts on each row. If this is not sufficient, a continuous line will be will be
generated to indicate the continued connection and more devices can be added. A continuous series
of numbers will be generated automatically and identical input points can be used repeatedly. See
figure below:
X0

X1

X2

X3

X4

X5

X6

X7

X10 C0

C1
00000

X11 X12 X13

Y0

00000

Row Number
The ladder diagram programming method involves scanning from the upper left corner to the lower
right corner. The coils and applications command computing box are handled in the output, and the
ladder diagram is placed on the farthest right. Taking the figure below as an example, we can
gradually analyze the procedural sequence of the ladder diagram. The number in the upper right
corner gives the sequential order.
Explanation of
command
sequence
1

LD

X0

2

OR

M0

3

AND

X1

4

LD

X3

AND

M1

X0

X1

Y1

Y1
M0

T0

LD

Y1

AND

X4

M3
TMR

X3

M1

ORB
5

X4

16-17

T0

K10

6

LD

T0

AND

M3

ORB
7

ANB

8

OUT

Y1

TMR T0

K10

Explanation of basic structure of ladder diagrams
LD (LDI) command: An LD or LDI command is given at the start of a block.
LD command

AND Block

LD command

OR Block

LDP and LDF have this command structure, but there are differences in their action state. LDP, LDF
only act at the rising or falling edge of a conducting contact. (see figure below):
Rising-edge

Falling-edge

X0

X0
Time
OFF

ON

OFF

Time
OFF

ON

OFF

AND (ANI) command: A series configuration in which a single device is connected with one device
or a block.
AND command

AND command

ANDP, ANDF also have structures like this, but their action occurs at the rising and falling edge.
OR (ORI) command: A single device is connected with one device or a block.

OR command

OR command

OR command

ORP, ORF also have identical structures, but their action occurs at the rising and falling edge.
ANB command: A configuration in which one block is in series with one device or block.

16-18

PLC Function Applications

ANB command

ORB command: A configuration in which one block is in parallel with one device or block.

ORB command

In the case of ANB and ORB operations, if a number of blocks are connected, they should be
combined to form a block or network from the top down or from left to right.
MPS, MRD, MPP commands: Branching point memory for multiple outputs, enabling multiple,
different outputs. The MPS command begins at a branching point, where the so-called branching
point refers to the intersection of horizontal and vertical lines. We have to rely on the contact status
along a single vertical line to determine whether the next contact can give a memory command.
While each contact is basically able to give memory commands, in view of convenience and the
PLC's capacity restrictions, this can be omitted from some places when converting a ladder diagram.
The structure of the ladder diagram can be used to judge what kinds of contact memory commands
are used.
MPS can be distinguished by use of the "┬" symbol; this command can be used consecutively for up
to 8 times. The MRD command is read from branching point memory; because logic states along any
one vertical line must be the same, in order to continue analysis of other ladder diagrams, the original
contact status must be read.
MRD can be distinguished by use of the "├" symbol. The MPP command is read from the starting
state of the uppermost branching point, and it is read from the stack (pop); because it is the final
command along a vertical line, it indicates that the state of the vertical line can be concluded.
MPP can be distinguished by use of the "└" symbol. Although there should basically be no errors
when using the foregoing analytical approach, the compiling program may sometimes omit identical
state output, as shown in the following figure:

16-19

MPS

MRD
MPP

(

)

(

)

(

)

(

)

(

)

(

)

(

)

16-4-4 Commonly-used basic program design examples
Start, stop, and protection
Some applications may require a brief close or brief break using the buttons to start and stop
equipment. A protective circuit must therefore be designed to maintain continued operation in these
situations; this protective circuit may employ one of the following methods:
Example 1: Priority stop protective circuit

＝

When the start NO contact X1=On, and the stop NC contact X2 Off, Y1=On; if X2=On at
this time, coil Y1 will no longer be electrified, and this is therefore referred to as priority stop.
X2

Y1

Y1
STOP

X1
START

Example 2: Priority start protective circuit

＝

When start NO contact X1=On, and the stop NC contact X2 Off, Y1=On, and coil Y1 will be
electrified and protected. At this time, if X2=On, coil Y1 will still protect the contact and
continue to be electrified, and this is therefore priority start.
X1

X2
Y1

START

STOP

Y1

Example 3: Setting (SET) and reset (RST) command protective circuit
The following figure shows a protective circuit composed of RST and SET commands.
Priority stop occurs when the RST command is placed after the SET command. Because the
PLC executes programs from the top down, at the end of the program, the state of Y1 will
indicate whether coil Y1 is electrified. When X1 and X2 are both actuated, Y1 will lose power,
and this is therefore priority stop.
Priority start occurs when the SET command is placed after the RST command. When X1
and X2 are both actuated, Y1 will be electrified, and this is therefore priority start.

16-20

PLC Function Applications

Top priority of start

Top priority of stop

X2

X1
SET

Y1

RST

Y1

RST

Y1

SET

Y1

X1

X2

Commonly-used control circuits
Example 4: Conditional control
X1, X3 are respectively start/stop Y1, and X2, X4 are respectively start/stop Y2; all have
protective circuits. Because Y1's NO contact is in series with Y2's circuit, it becomes an
AND condition for the actuation of Y2. The action of Y1 is therefore a condition for the action
of Y2, and Y1 must be actuated before Y2 can be actuated.
X1

X3
X1

Y1
Y1

X3
X2

X2

X4

Y1
Y2

X4

Y2

Y1
Y2

Example 5: Interlocking control
The figure below shows an interlocking control circuit. Depending on which of the start
contacts X1, X2 is valid first, the corresponding output Y1 or Y2 will be actuated, and when
one is actuated, the other will not be actuated. This implies that Y1 and Y2 cannot be
actuated at the same time (interlocking effect). Even if both X1 and X2 are valid at the same
time, because the ladder diagram program is scanned from the top down, it is impossible for
Y1 and Y2 to be actuated at same time. This ladder diagram assigns priority only to Y1.
X1

X3

Y2
Y1

Y1

X1
X3
X2

X2

X4

Y1
Y2

Y2

X4
Y1
Y2

16-21

Example 6: Sequence control
If the NC contact of Y2 in the interlocking control configuration of example 5 is put in series
with the Y1 circuit, so that it is an AND condition for actuation of Y1 (see figure below), not
only is Y1 a condition for the actuation of Y2 in this circuit, the actuation of Y2 will also stop
the actuation of Y1. This configuration confirms the actuation order of Y1 and Y2.
X3

X1

Y2
Y1

Y1

X4

X2

Y1
Y2

Y2

Example 7: Oscillating circuit
Oscillating circuit with a period of ∆T+∆T
The figure below shows a very simple ladder diagram. When starting to scan the Y1 NC
contact, because the Y1 coil has lost power, the Y1 NC contact will be closed. When the Y1
coil is then scanned, it will be electrified, and the output will be 1. When the Y1 NC contact is
scanned in the scanning cycle, because Y1 coil is electrified, the Y1 NC contact will be open,
the Y1 coil will then lose power, and the output will be 0. Following repeated scanning, the
output of Y1 coil will have an oscillating waveform with a period of ∆T(On)+∆T(Off).
Y1
Y1

Y1
T

T

Oscillating circuit with a period of nT+∆T
The program of the ladder diagram shown below uses timer T0 to control coil Y1's electrified
time. After Y1 is electrified, it causes timer T0 to close during the next scanning cycle, which
will cause the output from Y1 to have the oscillating waveform shown in the figure below.
Here n is the timer's decimal setting value, and T is the clock cycle of the timer.
X0

Y1
TMR

T0

Kn

T0

X0

Y1

Y1

nT

T

Example 8: Flashing circuit
The following figure shows an oscillating circuit of a type commonly used to cause an
indicator light to flash or a buzzers to buzz. It uses two timers to control the On and Off time
of Y1 coil. Here n1, n2 are the timing set values of T1 and T2, and T is the clock cycle of the
timer.

16-22

PLC Function Applications

X0

T2
TMR

T1

Kn1

TMR

T2

Kn2

X0

n2*T

T1
X0

Y1

T1

n1*T

Y1

Example 9: Triggering circuit
In the figure below, a command consisting of the differential of the rising edge of X0 causes
coil M0 to generate a single pulse for ∆T (length of one scanning cycle), and coil Y1 is
electrified during this scanning cycle. Coil M0 loses power during the next scanning cycle,
and NC contact M0 and NC contact Y1 are both closed. This causes coil Y1 to stay in an
electrified state until there is another rising edge in input X0, which again causes the
electrification of coil M0 and the start of another scanning cycle, while also causing coil Y1 to
lose power, etc. The sequence of these actions can be seen in the figure below. This type of
circuit is commonly used to enable one input to perform two actions in alternation. It can be
seen from the time sequence in the figure below that when input X0 is a square wave signal
with a period of T, the output of coil Y1 will be a square wave signal with a period of 2T.
X0
M0
M0

T

Y1
Y1

M0

X0

M0

Y1
Y1

Example 10: Delay circuit
When input X0 is On, because the corresponding NC contact will be Off, the timer T10 will
be in no power status, and output coil Y1 will be electrified. T10 will receive power and
begin timing only after input X0 is Off, and output coil Y1 will be delayed for 100 sec.
(K1000*0.1 sec. =100 sec.) before losing power; please refer to the sequence of actions in
the figure below.

Example 11: The open/close delay circuit is composed of two timers; output Y4 will have a delay
whether input X0 is On or Off.
Example 12: Extended timing circuit
In the circuit in the figure on the left, the total delay time from the moment input X0 closes to
the time output Y1 is electrified is (n1+n2)*T, where T is the clock cycle. Timers: T11, T12;
clock cycle: T.

16-23

X0
TMR

T11 Kn1

TMR

T12 Kn2

X0
n1*T

T11
T11

n2*T

T12
Y1

T12
Y1
(n1+n2)*T

16-24

PLC Function Applications

16-5 Various PLC device functions
Item
Specifications
Algorithmic control Program stored internally, alternating
method
back-and-forth scanning method
When it starts again after ending (after
Input/output control execution to the END command), the
method
input/output has an immediate refresh
command
Algorithmic
Basic commands (several us);
processing speed
Programming
Command + ladder diagram
language
Program capacity 10000 steps
Input/output
terminal

Type

Device

Input (X): 10, output (Y): 4

Item

Relay bit form

X

External input relay

Y

External output relay

M

General
Auxiliary Use
Relay
Special
purpose

T

C

T
Register word data

C

D

K
Constant
H

Notes

Applications command
(1-several tens of us)

This number of contacts
constitutes C2000 input/output
contacts; other devices have
different correspondences

Range
Function
X0~X17, 16 points, octal
Corresponds to external
Total
number
input point
32
Y0~Y17, 16 points, octal
Corresponds to external
points
number
output point
Contact can switch
M0~M799, 800 points
Total
On/Off within the
880
program
M1000~M1079, 80 points points

Timers referred to by the
Total TMR command; contact
100ms
Timer
T0~T159, 160 points
160 of the T with the same
timer
points number will go On when
the time is reached
Counter referred to by
the CNT command;
16-bit
Total
contact of the C with the
Counter counter,
C0~C79, 80 points
80
same number will go On
general use
points
when the count is
reached
The contact will be On
Current timer value
T0~T159, 160 points
when the time is reached
The counter contact will
C0~C79, 16-bit counter 80
Current counter value
come On when the count
points
is reached
Used
to
maintain
D0~D399, 400 points
power Off
Total
Data
Used as data storage
D1000~D1199,
200 1400
memory area
Register
points
Special
points
purpose
D2000~D2799,
800
points
Single-byte Setting Range: K-32,768 ~ K32,767
Decimal
Double-byte Setting Range: K-2,147,483,648~K2,147,483,647
Single-byte Setting Range:H0000 ~ HFFFF
Hexadecimal
Double-byte Setting Range: H00000000 ~ HFFFFFFFF

16-25

Serial communications port (program
RS-485/keypad port
write/read)
Input/output
Built-in three analog inputs and two analog outputs
Function expansion module
Optional
EMC-D42A; EMC-R6AA; EMCD611A
Accessories
Communication Expansion
Optional
EMC-COP01,(CANopen)
Module
Accessories

16-5-1 Introduction to device functions
Input/output contact functions
Input contact X functions: Input contact X is connected with an input device, and reads input signals
entering the PLC. The number of times that contact a or b of input contact X is used in the program is
not subject to restrictions. The On/Off state of input contact X will change as the input device
switches On and Off; a peripheral device (WPLSoft) cannot be used to force contact X On or Off.

Output contact Y functions
The job of output contact Y is to send an On/Off signal to drive the load connected with output contact
Y. Output contacts consist of two types: relays and transistors. While number of times that contact a
or b of each output contact Y is used in the program is not subject to restrictions, it is recommended
that the number of output coil Y be used only once in a program, otherwise the right to determine the
output state when the PLC performs program scanning will be assigned to the program's final output
Y circuit.

Numerical value, constant [K]/[H]
Single-byte
Double-byte
Constant
Single-byte
Double-byte

K

Decimal

H

Hexadecimal

K-32,768 ~ K32,767
K-2,147,483,648~K2,147,483,647
H0000 ~ HFFFF
H00000000 ~ HFFFFFFFF

The PLC can use five types of numerical values to implement calculations based on its control tasks;
the following is an explanation of the missions and functions of different numerical values.
Binary Number, BIN
The PLC's numerical operations and memory employ binary numbers. Binary nibbles and relevant
terms are explained as follows:
Bit
Bits are the fundamental units of binary values, and have a state of either 1 or 0
Comprised of a series of 4 bits (such as b3-b0); can be used to express a
Nibble
one-nibble decimal number 0-9 or hexadecimal number: 0-F.
Comprised of a series of two nibbles (i.e. 8 bits, b7-b0); can express a
Byte
hexadecimal number: 00-FF.
Comprised of a series of two bytes (i.e. 16 bits, b15-b0); can express a
Word
hexadecimal number with four nibbles: 0000-FFFF.

16-26

PLC Function Applications

Double Word

Comprised of a series of two words (i.e. 32 bits, b31-b0); can express a
hexadecimal number with eight nibbles: 00000000-FFFFFFFF

Relationship between bits, digits, nibbles, words, and double words in a binary system (see figure
below):
DW

Double Word

W1

W0

BY3

BY2

NB7

NB6

NB5

Word

BY1
NB4

NB3

BY0
NB2

NB1

Byte
NB0

Nibble
Bit

Octal Number, OCT
The external input and output terminals of a DVP-PLC are numbered using octal numbers
Example:

External input:

External output:

，

，

X0~X7 X10~X17…(Device number table);

Y0~Y7 Y10~Y17…(Device number table)

Decimal Number, DEC
Decimal numbers are used for the following purposes in a PLC system:
The setting values of timer T or counter C, such as TMR C0 K50. (K constant)
The numbers of devices including M, T, C, or D, such as M10 or T30. (device number)
Used as a operand in an application command, such as MOV K123 D0. (K constant)
Binary Code Decimal, BCD
Uses one nibble or 4 bits to express the data in a decimal number; a series of 16 bits can therefore
express a decimal number with 4 nibbles. Chiefly used to read the input value of a fingerwheel
numerical switch input or output a numerical value to a seven-segment display driver.
Hexadecimal Number, HEX
Applications of hexadecimal numbers in a PLC system: Used as operands in application commands,
such as MOV H1A2B D0. (H constant)
Constant K
Decimal numbers are usually prefixed with a "K" in a PLC system, such as K100. This indicates that it
is a decimal number with a numerical value of 100.
Exceptions: K can be combined with bit device X, Y, M, or S to produce data in the form of a nibble,
byte, word, or double word, such as in the case of K2Y10 or K4M100. Here K1 represents a
4-bit combination, and K2-K4 variously represent 8-, 12-, and 16-bit combinations.
Constant H
Hexadecimal numbers are usually prefixed with the letter "H" in a PLC system, such as in the case of
H100, which indicates a hexadecimal number with a numerical value of 100.

Functions of auxiliary relays
Like an output relay Y, an auxiliary relay M has an output coil and contacts a and b, and the number

16-27

of times they can be used in a program is unrestricted. Users can use an auxiliary relay M to
configure the control circuit, but cannot use it to directly drive an external load. Auxiliary relays have
the following two types of characteristics:
Ordinary auxiliary relays: Ordinary auxiliary relays will all revert to the Off state if a power outage
occurs while the PLC is running, and will remain in the Off state if power is again
turned down.
Special purpose auxiliary relays: Each special purpose auxiliary relay has its own specific use. Do not
use any undefined special purpose auxiliary relays.

Timer functions
Timers take 100 ms as their timing units. When the timing method is an upper time limit, when the
current timer value = set value, power will be sent to the output coil. Timer setting values consist of
decimal K values, and the data register D can also serve as a setting value.
Actual timer setting time = timing units * set value
Counter features
Item
16-bit counter
Type
General Type
CT Direction:
Score:
Setting
0~32,767
Designation of Constant K or data register D
set value
Change in current When the count reaches the set value, there is no
value
longer a count
When the count reaches the set value, the contact
Output contact
comes On and stays On
Reset
The current value reverts to 0 when an RST
command is executed, and the contact reverts to Off
Contact actuation All are actuated after the end of scanning

Counter functions
When a counter's counting pulse input signal goes Off→On, if the counter's current value is equal to
the set value, the output coil will come On. The setting value will be a decimal K values, and the data
register D can also serve as a setting value.
16-bit counter C0-C79:


16-bit counter setting range: K0-K32,767. (when K0 and K1 are identical, the output contact will
immediately be On during the first count.)



The current counter value will be cleared from an ordinary counter when power is shut off to the
PLC.



If the MOV command or WPLSoft is used to transmit a value greater than the set value to the
C0 current value register, when the next X1 goes from Off→On, the C0 counter contact will
change to On, and the current value will change to the set value.



A counter's setting value may be directly set using a constant K or indirectly set using the value
in register D (not including special data registers D1000- D1199



或 D2000 ~ D2799).

If the set value employs a constant K, it may only be a positive number; the set value may be
either a positive or negative number if the value in data register D is used. The current counter
value will change from 32,767 to -32,768 as the count continues to accumulate.

16-28

PLC Function Applications

Example
LD

X0

RST

C0

LD

X1

CNT

C0 K5

LD

C0

OUT

Y0

X0
RST C0
X1
CNT

C0

K5

C0
Y0

1. When X0=On and the RST command is

X0

executed, the current value of C0 will
revert to 0, and the output contact will

X1
5

revert to Off.

4

2. When X1 changes from Off→On, the
current value of the counter will execute

C0
present
value

3
2
1
0

an increase (add one).
3. When the count of counter C0 reaches the

settings

0

Contacts Y0, C0

set value K5, the contact C0 will come On,

＝ set value

and the current value of C0

=K5. Afterwards, signal C0 triggered by X1
cannot be received, and the current value
of C0 will remain K5.

16-5-2 Introduction to special relay functions (special M)
R/W items: RO: read only function; RW: read and write function
Special
Description of Function
R/W *
M
M1000 Operates monitor NO contact (contact a). NO while RUN, contact a. This contact
RO
is On while in the RUN state.
M1001 Operates monitor NC contact (contact b). NC while RUN, contact b. This contact is
RO
Off while in the RUN state.
M1002 Initiates a forward (the instant RUN is On) pulse. Initial pulse, contact a. Produces
RO
a forward pulse the moment RUN begins; its width = scan cycle
M1003 Initiates a reverse (the instant RUN is Off) pulse. Initial pulse, contact a. Produces
RO
a reverse pulse the moment RUN ends; the pulse width = scan cycle
M1004 Reserved
RO
M1005 Driver malfunction instructions
RO
M1006 Converter has no output
RO
M1007 Driver direction FWD(0)/REV(1)
RO
M1008
~
--M1010
M1011 10 ms clock pulse 5ms On/5ms Off
RO
M1012 100 ms clock pulse 50ms On / 50ms Off
RO
M1013 1 sec. clock pulse 0.5s On / 0.5s Off
RO
M1014 1 min. clock pulse 30s On / 30s Off
RO
M1015 Frequency attained (when used together with M1025)
RO

，
，
，
，

16-29

Special
M
M1016
M1017
M1018
M1019
M1020
M1021
M1022
M1023
M1024
M1025
M1026
M1027
M1028
M1029
M1030
M1031
M1032
M1033
M1034
M1035
M1036
M1037
M1038
M1039
M1040
M1041
M1042
M1043
M1044
M1045
~
M1047
M1048
M1049
M1050
M1051
M1052
M1053
M1054
M1055
M1056
M1057
M1058
M1059
M1060
M1061
M1062
M1063
M1064
M1065
M1066
M1067
M1068

Description of Function

R/W *

Parameter read/write error
Parameter write successful
--Zero flag
Borrow flag
Carry flag
Divisor is 0
-Driver frequency = set frequency (ON)
Driver frequency =0(OFF)
Driver operating direction FWD(OFF)/REV(ON)
Driver Reset
---Compulsory setting of the current PID integral value equal to D1019 (0 change, 1
valid)
Compulsory definition of FREQ command after PID control
-Initiates CANopen real-time control
Initiates internal communications control
Ignore calendar error
-MI8 count begins
Reset MI8 count value
Hardware power (Servo On)
-Quick stop
-Pause

RO
RO
--RO
RO
RO
RO
--

--

RW
RW
RW
---RW
RW
-RW
RW
RW
-RW
RW
RW
-RW
-RW
--

Move to new position
-Absolute position/relative position (0: relative/1: absolute)
-Lock frequency (lock, frequency locked at the current operating frequency)
-Compulsory reset of absolute position
Search Origin
Hardware already has power (Servo On Ready)
-On Quick Stopping
CANopen Master setting complete
CANopen Currently initializing slave station
CANopen Slave station initialization failure
-Torque attained
Target reached
Read/write CANOpen data time out
Read/write CANopen data complete
Read/write CANopen data successful
Calendar calculation error

16-30

RW
-RW
-RW
-RW
RW
RO
-RO
RO
RO
RO
-RO
RO
RO
RO
RO
RO

PLC Function Applications

Special
M
M1069
M1070
M1071
M1072
~
M1075
M1076
M1077
M1078
M1079

Description of Function
-Return home complete
Homing error

R/W *
-RO
RO

--

--

Calendar time error or refresh time out
485 Read/write complete
485 Read-write error
485 Communications time out

RO
RO
RO
RO

16-5-3 Introduction to special register functions (special D)
Special
D
D1000
D1001
D1002
D1003
D1004
~
D1009
D1010
D1011
D1012
D1013
~
D1017
D1018
D1019
D1020
D1021

Description of Function
-Device system program version
Program capacity
Total program memory content

R/W *
--

RO
RO
RO

--

--

Current scan time (units: 0.1 ms)
Minimum scan time
(units: 0.1 ms)
Maximum scan time
(units: 0.1 ms)
--

RO
RO
RO
--

Current integral value
Compulsory setting of PID I integral
Output frequency (0.000~600.00Hz)
Output current (####.#A)
AI AO DI DO Expansion card number
0 No expansion card
D1022 4 AC input card ( 6 in ) (EMC-D611A)
5 I/O Card ( 4 in 2 out ) (EMC-D42A)
6 Relay card( 6 out ) (EMC-R6AA)
Communication expansion card number
0 No expansion card
1 DeviceNet Slave
D1023 2 Profibus-DP Slave
3 CANopen Slave
4 Modbus-TCP Slave
5 EtherNet/IP Slave
D1024
~
-D1026
D1027 PID calculation frequency command (frequency command after PID calculation)
D1028 AVI value (0.00~100.00%)
D1029 ACI value (0.0~100.00%)
D1030 AUI value (-100.0~100.00%)
D1031 --

：
：
：
：
：
：
：
：
：
：

16-31

RO
RW
RO
RO

RO

RO

--

RO
RO
RO
RO
--

Special
D
~
D1035
D1036
D1037
D1038
D1039
D1040
D1041
~
D1042

Description of Function

Servo error bit
Driver output frequency
DC BUS voltage
Output voltage
Analog output value AFM1(-100.00~100.00%)
--

R/W *

RO
RO
RO
RO
RW
--

Can be user-defined (will be displayed on panel when parameter 00-04 is set as
28; display method is C xxx)
D1044 -D1045 Analog output value AFM2(-100.00~100.00%)
D1046
~
-D1049
Actual Operation Mode
0 Speed
1
Position
D1050
2 Torque
3 Homing Origin
D1051 Actual position (Low word)
D1052 Actual position (High word)
D1053 Actual torque
D1054 MI8 current calculated count value (L Word)
D1055 MI8 current calculated count value (H Word)
D1056 Rotational speed corresponding to MI8
D1057 MI8's rotational speed ratio
D1058 MI8 refresh rate (ms) corresponding to rotational speed
D1059 Number of nibbles of rotational speed corresponding to MI8 (0-3)
Operation Mode setting
0 Speed
1
Position
D1060
2 Torque
3 Homing Origin
D1061 485 COM1 communications time out time (ms)
D1062 Torque command (torque limit in speed mode)
Year (Western calendar) (display range 2000-2099)
(must
use
D1063
KPC-CC01)
D1064 Week (display range 1-7)
(must use KPC-CC01)
D1065 Month (display range 1-12)
(must use KPC-CC01)
D1066 Day (display range 1-31)
(must use KPC-CC01)
D1067 Hour (display range 0-23)
(must use KPC-CC01)
D1068 Minute (display range 0-59) (must use KPC-CC01)
D1069 Second (display range 0-59) (must use KPC-CC01)
D1100 Target frequency
D1101 Target frequency (must be operating)
D1102 Reference frequency
D1103 Target L
D1104 Target H
D1105 Target torque
D1106 -D1107 π(Pi) Low word
D1108 π(Pi) High word
D1043

：
：
：
：

：
：
：
：

16-32

RW
-

RW
--

RO

RO
RO
RO
RO
RO
RO
RW
RW
RW

RW

RW
RW
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
RO
-RO
RO

PLC Function Applications

Special
Description of Function
R/W *
D
D1109 Random number
RO
Internal node communications number (set number of slave stations to be
D1110
RW
controlled)
D1111 Encoder Pulses L
RO
D1112 Encoder Pulses H
RO
D1113 -RO
D1114 --D1115 Internal node synchronizing cycle (ms)
RO
D1116 Internal node error (bit0 = Node 0, bit1 = Node 1,…bit7 = Node 7)
RO
Internal node online correspondence (bit0 = Node 0, bit1 = Node 1,…bit7 = Node
RO
D1117
7)
D1118 --D1119 --D1120 Internal node 0 control command
RW
D1121 Internal node 0 mode
RW
D1122 Internal node 0 reference command L
RW
D1123 Internal node 0 reference command H
RW
D1124 --D1125 --D1126 Internal node 0 status
RO
D1127 Internal node 0 reference status L
RO
D1128 Internal node 0 reference status H
RO
D1129 --D1130 Internal node 1 control command
RW
D1131 Internal node 1 mode
RW
D1132 Internal node 1 reference command L
RW
D1133 Internal node 1 reference command H
RW
D1134 ---D1135 -D1136 Internal node 1 status
RO
D1137 Internal node 1 reference status L
RO
D1138 Internal node 1 reference status H
RO
D1139 --D1140 Internal node 2 control command
RW
D1141 Internal node 2 mode
RW
D1142 Internal node 2 reference command L
RW
D1143 Internal node 2 reference command H
RW
D1144 --D1145 --D1146 Internal node 2 status
RO
D1147 Internal node 2 reference status L
RO
D1148 Internal node 2 reference status H
RO
-D1149 -D1150 Internal node 3 control command
RW
D1151 Internal node 3 mode
RW
D1152 Internal node 3 reference command L
RW
D1153 Internal node 3 reference command H
RW
D1154 --D1155 --D1156 Internal node 3 status
RO
D1157 Internal node 3 reference status L
RO
D1158 Internal node 3 reference status H
RO
D1159 --D1160 Internal node 4 control command
RW

16-33

Special
D
D1161
D1162
D1163
D1164
D1165
D1166
D1167
D1168
D1169
D1170
D1171
D1172
D1173
D1174
D1175
D1176
D1177
D1178
D1179
D1180
D1181
D1182
D1183
D1184
D1185
D1186
D1187
D1188
D1189
D1190
D1191
D1192
D1193
D1194
D1195
D1196
D1197
D1198
D1199

Description of Function

R/W *

Internal node 4 mode
Internal node 4 reference command L
Internal node 4 reference command H

RW
RW
RW
--RO
RO
RO
-RW
RW
RW
RW
RW
--RO
RO
-RW
RW
RW
RW
--RO
RO
RO
-RW
RW
RW
RW
--RO
RO
RO
--

--Internal node 4 status
Internal node 4 reference status L
Internal node 4 reference status H

-Internal node 5 control command
Internal node 5 mode
Internal node 5 reference command L
Internal node 5 reference command H

--Internal node 5 status
Internal node 5 reference status L
Internal node 5 reference status H

-Internal node 6 control command
Internal node 6 mode
Internal node 6 reference command L
Internal node 6 reference command H

--Internal node 6 status
Internal node 6 reference status L
Internal node 6 reference status H

-Internal node 7 control command
Internal node 7 mode
Internal node 7 reference command L
Internal node 7 reference command H

--Internal node 7 status
Internal node 7 reference status L
Internal node 7 reference status H

--

The following is CANopen Master's special D (can be written in only
with PLC in Stop state)
n=0~7
Special D
D1070
D1071
D1072
D1073

Description of Function
Channel opened by CANopen initialization
(bit0=Machine code0 …….)
Error channel occurring in CANopen initialization
process (bit0=Machine code0 …….)
Reserved
CANopen break channel (bit0=Machine code0 …….)

16-34

PDO
Map

Power
off
Default:
Memory

R/W

NO

NO

0

R

NO

NO

0

R

NO

NO

R

PLC Function Applications

Special D

D1074
D1075
D1076
D1077
D1078
D1079
D1080
D1081
~
D1086
D1087
~
D1089
D1090
D1091
D1092
D1093
D1094
D1095
~
D1096

PDO
Map

Description of Function
Error code of master error
0: No error
1: Slave station setting error
2: Synchronizing cycle setting error (too small)
Reserved
SDO error message (main index value)
SDO error message (secondary index value)
SDO error message (error code)
SDO error message (error code)
Reserved

Power
off
Default:
Memory

NO

NO

NO
NO
NO
NO
-

NO
NO
NO
NO
-

Reserved

-

-

Reserved

-

-

NO

YES

4

NO

YES

FFFFH

NO
NO
NO

YES
YES
YES

0
1000ms
3

-

-

NO

YES

1

NO

YES

1

NO

YES

15 sec.

NO

YES

0

Synchronizing cycle setting
Sets slave station On or Off (bit 0-bit 7 correspond to
slave stations number 0-7)
Delay before start of initialization
Break time detection
Break number detection
Reserved

Corresponding real-time transmission type (PDO)
Setting range: 1~240
Corresponding real-time receiving type (PDO)
D1098
Setting range: 1~240
Initialization completion delay time
D1099
Setting range: 1 to 60000 sec
Station number n of slave station
D2000+100*n Setting range: 0~127
0: No CANopen function
D1097

R/W

0

R
R
R
R
R
-

RW
RW
RW
RW
RW
RW
RW
RW
RW

The C2000 supports 8 slave stations under the CANopen protocol; each slave station
occupies 100 special D locations; stations are numbered 1-8, total of 8 stations.
Explanation of
slave station
number and

Slave station no.
1

D2000
D2001
~
D2099

Slave station no.
2

D2100
D2101
~
D2199

Slave station no.
3

D2200
D2201
~
D2299

Slave station no.
8


D2700
D2701
~
D2799

16-35

Node ID
Slave station no. 1 torque restrictions
~
Address 4(H) corresponding to receiving
channel 4
Node ID
Slave station no. 2 torque restrictions
~
Address 4(H) corresponding to receiving
channel 4
Node ID
Slave station no. 3 torque restrictions
~
Address 4(H) corresponding to receiving
channel 4
Node ID
Slave station no. 8 torque restrictions
~
Address 4(H) corresponding to receiving
channel 4

1. The range of n is 0-7
2. ●Indicates PDOTX, ▲Indicates PDORX; unmarked special D can be refreshed using the
CANFLS command
Special D

D2000+100*n
D2002+100*n
D2003+100*n
D2004+100*n
D2005+100*n

Description of Function
Station number n of slave station
Setting range: 0~127
0: No CANopen function
Manufacturer code of slave station number n (L)
Manufacturer code of slave station number n (H)
Manufacturer's product code of slave station number n
Manufacturer's product code of slave station number n

Default:

R/W

0

RW

0
0
0
0

R
R
R
R

(L)
(H)

Basic definitions
Special D
D2006+100*n
D2007+100*n
D2008+100*n
D2009+100*n
D2010+100*n
D2011+100*n

Description of Function
Communications break handling method of
slave station number n
Error code of slave station number n error
Control word of slave station number n
Status word of slave station number n
Control mode of slave station number n
Actual mode of slave station number n

PDO Default:
R/W
1 2 3 4

Default:

CAN
Index

0

6007H-0010H

0
0
0
2
2

603FH-0010H
6040H-0010H ●
6041H-0010H ▲
6060H-0008H
6061H-0008H

RW
●

●

▲ ▲

R
RW
R
RW
R

Velocity Control
Slave station number n=0-7
Special D

Description of Function

Default:

D2001+100*n
D2012+100*n
D2013+100*n
D2014+100*n
D2015+100*n
D2016+100*n

Torque restriction on slave station number n
Target speed of slave station number n
Actual speed of slave station number n
Error speed of slave station number n
Acceleration time of slave station number n
Deceleration time of slave station number n

0
0
0
0
1000
1000

CAN
Index
6072H-0010H
6042H-0010H
6043H-0010H
6044H-0010H
604FH-0020H
6050H-0020H

PDO Default:
R/W
1 2 3 4
RW
●
RW
R
▲
R
R
RW

Torque control
Slave station number n=0-7
Special D
D2017+100*n
D2018+100*n
D2019+100*n

Description of Function
Target torque of slave station number n
Actual torque of slave station number n
Actual current of slave station number n

Default:
0
0
0

PDO Default:
CAN
R/W
Index
1 2 3 4
6071H-0010H
● RW
6077H-0010H
▲ R
6078H-0010H
R

Position control
Slave station number n=0-7
Special D

Description of Function

Default:

D2020+100*n
D2021+100*n

Target of slave station number n (L)
Target of slave station number n (H)
Actual position of slave station number n
(L)
Actual position of slave station number n
(H)
Speed chart of slave station number n (L)
Speed chart of slave station number n (H)

0
0

D2022+100*n
D2023+100*n
D2024+100*n
D2025+100*n

16-36

PDO Default:
R/W
1 2 3 4
RW
607AH-0020H
●
RW
CAN
Index

0
6064H-0020H
0
10000
0

▲

R
R

6081H-0020H

RW
RW

PLC Function Applications

20XXH correspondences: MI MO AI AO
Slave station number n=0-7
Special D
D2026+100*n
D2027+100*n
D2028+100*n
D2029+100*n
D2030+100*n
D2031+100*n
D2032+100*n
D2033+100*n

Description of Function

Default:

MI status of slave station number n
MO setting of slave station number n
AI1 status of slave station number n
AI2 status of slave station number n
AI3 status of slave station number n
AO1 status of slave station number n
AO2 status of slave station number n
AO3 status of slave station number n

0
0
0
0
0
0
0
0

PDO Default:
CAN
Index
1 2 3 4
2026H-0110H
▲
2026H-4110H
●
2026H-6110H
▲
2026H-6210H
▲
2026H-6310H
▲
2026H-A110H
●
2026H-A210H
●
2026H-A310H
●

R/W
RW
RW
RW
RW
RW
RW
RW
RW

PDO reflection length setting:
Special D
D2034+100*n
D2067+100*n

Description of Function
Real-time transmission setting of slave station number n
Real-time reception setting of slave station number n

Default:

R/W

000AH
0000H

RW
RW

16-5-4 PLC Communication address
Device
X
Y
T
M
M
C
D
D
D

Range
00~37 (Octal)
00~37 (Octal)
00~159
000~799
1000~1079
0~79
00~399
1000~1099
2000~2799

Type
bit
bit
bit/word
bit
bit
bit/word
word
word
word

Address (Hex)
0400~041F
0500~051F
0600~069F
0800~0B1F
0BE8~0C37
0E00~0E47
1000~118F
13E8~144B
17D0~1AEF

Command code that can be used
Function Code
Description of Function
01
Coil status read
02
Input status read
03
Read single unit of data
05
Compulsory single coil status change
06
Write single unit of data
0F
Compulsory multiple coil status change
10
Write multiple units of data

Function target
Y,M,T,C
X,Y,M,T,C
T,C,D
Y,M,T,C
T,C,D
Y,M,T,C
T,C,D

NOTE
When PLC functions have been activated, the C2000 can match PLC and driver parameters; this method employs different
addresses, drivers (default station number is 1, PLC sets station number as 2)

16-37

16-6 Introduction to the Command Window
16-6-1 Overview of basic commands
Ordinary commands
Command
code
LD
LDI
AND
ANI
OR
ORI
ANB
ORB
MPS
MRD
MPP

Function

OPERAND

Load contact a
Load contact b
Connect contact a in series
Connect contact b in series
Connect contact a in parallel
Connect contact b in parallel
Series circuit block
Parallel circuit block
Save to stack
Stack read (pointer does not change)
Read stack

X
X
X
X
X
X

、Y、M、T、C
、Y、M、T、C
、Y、M、T、C
、Y、M、T、C
、Y、M、T、C
、Y、M、T、C
N/A
N/A
N/A
N/A
N/A

Execution
speed (us)
0.8
0.8
0.8
0.8
0.8
0.8
0.3
0.3
0.3
0.3
0.3

Output command
Command
code
OUT
SET
RST

Function

OPERAND

、
、
、 、、、

Y M
Y M
Y M T C D

Drive coil
Action continues (ON)
Clear contact or register

Execution
speed (us)
1
1
1.2

Timer, counter
Command
code
TMR
CNT

Function

OPERAND

16-bit timer
16-bit counter

T-K or T-D commands
C-K or C-D (16-bit)

Execution
speed (us)
1.1
0.5

Main control command
Command
code
MC
MCR

Function

OPERAND

Common series contact connection
Common series contact release

N0~N7
N0~N7

Execution
speed (us)
0.4
0.4

Contact rising edge/falling edge detection command
Command
code
LDP
LDF
ANDP
ANDF
ORP
ORF

Function

OPERAND

Start of forward edge detection action
Start of reverse edge detection action
Forward edge detection series connection
Reverse edge detection series connection
Forward edge detection parallel connection
Reverse edge detection parallel connection

16-38

X
X
X
X
X
X

、Y、M、T、C
、Y、M、T、C
、Y、M、T、C
、Y、M、T、C
、Y、M、T、C
、Y、M、T、C

Execution
speed (us)
1.1
1.1
1.1
1.1
1.1
1.1

PLC Function Applications

Upper/lower differential output commands
Command
code
PLS
PLF

Function

OPERAND

、
、

Y M
Y M

Upper differential output
Lower differential output

Execution
speed (us)
1.2
1.2

Stop command
Command
code
END

Function

OPERAND

Program conclusion

N/A

Execution
speed (us)
0.2

Other commands
Command
code
NOP
INV
P

Function

OPERAND

No action
Inverse of operation results
Index

N/A
N/A
P

Execution
speed (us)
0.2
0.2
0.3

16-6-2 Detailed explanation of basic commands
Command
Function
LD
Load contact a
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand





The LD command is used for contact a starting at the left busbar or contact a starting
at a contact circuit block; its function is to save current content and save the acquired
contact status in the cumulative register.
Ladder diagram:
Command code:
Description:

－

X0

X1
Y1

LD

X0

AND

X1

OUT

Y1

Load Contact a of X0
Create
series
connection to contact a
of X1
Drive Y1 coil

Command
Function
LDI
Load contact b
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand





The LDI command is used for contact b starting at the left busbar or contact b starting
at a contact circuit block; its function is to save current content and save the acquired
contact status in the cumulative register.
Ladder diagram:
Command code:
Description:

－

X0

X1
Y1

16-39

LDI

X0

AND

X1

OUT

Y1

Load Contact b of X0
Create
series
connection to contact a
of X1
Drive Y1 coil

Command
Function
AND
Connect contact a in series
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand





The AND command is used to create a series connection to contact a; first reads
current status of the designated series contact and logical operation results before
contact in order to perform "AND" operation; saves results in cumulative register.

－

Ladder diagram:

Command code:
Description:
LDI
X1
Load Contact b of X1
Create
series
AND
X0
connection to contact a
of X0
OUT
Y1
Drive Y1 coil

X0

X1

Y1

Command
Function
ANI
Connect contact b in series
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand





The ANI command is used to create a series connection to contact b; its function is to
first read current status of the designated series contact and logical operation results
before contact in order to perform "AND" operation; saves results in cumulative
register.
Ladder diagram:
Command code:
Description:

－

X1

X0
Y1

LD

X1

ANI

X0

OUT

Y1

Load Contact a of X1
Create
series
connection to contact b
of X0
Drive Y1 coil

Command
Function
OR
Connect contact a in parallel
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand





The OR command is used to establish a parallel connection to contact a; its function is
to first read current status of the designated series contact and logical operation
results before contact in order to perform "OR" operation; saves results in cumulative
register.
Ladder diagram:
Command code:
Description:

－

X0
Y1

LD

X0

OR

X1

OUT

Y1

X1

Load Contact a of X0
Create
series
connection to contact a
of X1
Drive Y1 coil

Command
Function
ORI
Connect contact b in parallel
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand





The ORI command is used to establish a parallel connection to contact a; its function
is to first read current status of the designated series contact and logical operation
results before contact in order to perform "OR" operation; saves results in cumulative
register.
Ladder diagram:
Command code:
Description:

－

LD

16-40

X0

Load Contact a of X0

PLC Function Applications

X0
Y1

ORI

X1

OUT

Y1

X1

Create
series
connection to contact b
of X1
Drive Y1 coil

Command
Function
ANB
Series circuit block
Operand
N/A
ANB performs an "AND" operation on the previously saved logic results and the
current cumulative register content.
Ladder diagram:
Command code:
Description:
LD
X0
Load Contact a of X0
X0
X1
ANB
Y1
Establish parallel
ORI
X2
connection to contact b
X2
X3
of X2
LDI
X1
Load Contact b of X1
Block A
Block B
Establish parallel
OR
X3
connection to contact a
of X3
ANB
Series circuit block
OUT
Y1
Drive Y1 coil
Command
Function
ORB
Parallel circuit block
Operand
N/A
ORB performs an "OR" operation on the previously saved logic results and the current
cumulative register content.
Ladder diagram:
Command code:
Description:
X0
X1 Block A
LD
X0
Load Contact a of X0
Establish parallel
Y1
ANI
X1
connection to contact b
X2
X3
of X1
ORB
LDI
X2
Load Contact b of X2
Block B
Establish parallel
AND
X3
connection to contact a
of X3
ORB
Parallel circuit block
OUT
Y1
Drive Y1 coil
Command
MPS
Save to stack
Operand

Function
N/A

Save current content of cumulative register to the stack. (Add one to stack pointer)
Command
Function
MRD
Read stack (pointer does not change)
Operand
N/A
Reads stack content and saves to cumulative register. (Stack pointer does not
change)
Command
Function
MPP
Read stack
Operand
N/A
Retrieves result of previously-save logical operation from the stack, and saves to
cumulative register. (Subtract one from stack pointer)
Command code:
Description:
Ladder diagram:

16-41

MPS

X0

X1
Y1
X2
M0

MRD

X0

AND

X1

OUT

Y1

MRD

Y2
MPP

END

Command
OUT
Drive coil
X0~X17
Operand

LD
MPS

AND

X2

OUT
MPP
OUT
END

M0
Y2

Load Contact a of X0
Save to stack
Create series connection
to contact a of X1
Drive Y1 coil
Read stack (pointer does
not change)
Create series connection
to contact a of X2
Drive M0 coil
Read stack
Drive Y2 coil
Program conclusion

Function
Y0~Y17


－

M0~M799


T0~159

－

C0~C79

－

D0~D399

Outputs result of logical operation before OUT command to the designated element.
Coil contact action:

Result:

Coil

FALSE
TRUE

Off
On

Out command
Access Point:
Contact a (NO) Contact b (NC)
Not conducting
Conducting
Conducting
Not conducting
Command code:
Description:
LD
X0
Load Contact b of X0
Establish parallel
AND
X1
connection to contact a
of X1
OUT
Y1
Drive Y1 coil

Ladder diagram:
X0

－

X1
Y1

Command
Function
SET
Action continues (ON)
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand


When the SET command is driven, the designated element will be set as On, and will
be maintained in an On state, regardless of whether the SET command is still driven.
The RST command can be used to set the element as Off.
Ladder diagram:
Command code:
Description:
X0
Y0
LD
X0
Load Contact a of X0
SET Y1
Establish parallel
AN
Y0
connection to contact b
of Y0
SET
Y1
Action continues (ON)

－

－

－

－

Command
Function
RST
Clear contact or register
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand





When the RST command is driven, the action of the designated element will be as
follows:
Element
Mode
Y, M Both coil and contact will be set as Off.
The current timing or count value will be set as 0, and both the coil
T, C
and contact ill be set as Off.
D
The content value will be set as 0.

－

16-42

PLC Function Applications

If the RST command has not been executed, the status of the designated element will
remain unchanged.
Ladder diagram:
Command code:
Description:
X0
LD
X0
Load Contact a of X0
RST Y5
Clear
contact
or
RST
Y5
register
Command
Function
TMR
16-bit timer
T0~T159 K0~K32,767
T-K
Operand
T0~T159 D0~D399
T-D
When the TMR command is executed, the designated timer coil will be electrified, and
the timer will begin timing. The contact's action will be as follows when the timing
value reaches the designated set value (timing value >= set value):

，
，

NO (Normally Open) contact
NC (Normally Close) contact

Closed
Open

If the RST command has not been executed, the status of the designated element will
remain unchanged.
Ladder diagram:
Command code:
Description:
X0

LD

TMR

T5

K1000

TMR

Command
CNT
Operand

X0

Load Contact a of X0
T5 timer
T5 K1000
Set value as K1000

Function
16-bit counter
C-K
C-D

，
C0~C79，D0~D399

C0~C79 K0~K32,767

When the CNT command is executed from Off→On, this indicates that the designated
counter coil goes from no power → electrified, and 1 will be added to the counter's
count value; when the count reaches the designated value (count value = set value),
the contact will have the following action:
NO (Normally Open) contact

Closed

NC (Normally Close) contact

Open

After the count value has been reached, the contact and count value will both remain
unchanged even if there is continued count pulse input. Please use the RST
command if you wish to restart or clear the count.
Ladder diagram:

Command code:

X0

LD

CNT

C2

K100

CNT

Description:

X0

Load Contact a of X0
C2counter
C2 K100
Set value as K100

Command
Function
MC/MCR Connect/release a common series contact
Operand
N0~N7
MC is the main control initiation command, and any commands between MC and
MCR will be executed normally. When the MC command is Off, any commands
between MC and MCR will act as follows:
Determination of commands
Description
The timing value will revert to 0, the coil will lose
Ordinary timer
power, and the contact will not operate
The coil will lose power, and the count value and
Counter
contact will stay in their current state
Coil driven by OUT command None receive power
16-43

Elements driven by SET, RST
Will remain in their current state
commands
Applications commands
None are actuated
MCR is the main control stop command, and is placed at the end of the main control
program. There may not be any contact commands before the MCR command.
The MC-MCR main control program commands support a nested program structure
with a maximum only 8 levels; use in the order N0-N7, please refer to the following
program:
Command
Description:
Ladder diagram:
code:
X0

MC
X1
Y0
X2
MC

N1

X3
Y1
MCR

N1

MCR

N0

MC

N0

X10
X11
Y10
MCR

LD

X0

MC

N0

LD
OUT
:
LD

X1
Y0
X2

MC

N1

LD
OUT
:
MCR
:
MCR
:
LD

X3
Y1

Load Contact a of X2
Connection of N1 common series
contact
Load Contact a of X3
Drive Y1 coil

N1

Release N1 common series contact

N0

Release N0 common series contact

X10

MC

N0

LD
OUT
:
MCR

X11
Y10

Load Contact a of X10
Connection of N0 common series
contact
Load Contact a of X11
Drive Y10 coil

N0

Release N0 common series contact

N0

N0

Load Contact a of X0
Connection of N0 common series
contact
Load Contact a of X1
Drive Y0 coil

Command
Function
LDP
Start of forward edge detection action
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand





The LDP command has the same usage as LD, but its action is different; its function is
to save current content, while also saving the detected state of the rising edge of the
contact to the cumulative register.
Command
Description:
Ladder diagram:
code:
X0
X1
Start of X0 forward edge detection
Y1
LDP
X0
action
Create series connection to
AND
X1
contact a of X1
OUT
Y1 Drive Y1 coil
Please refer to the function specifications table for each device in series for the scope
of usage of each operand.
A rising edge contact will be TRUE after power is turned on if the rising edge contact is
On before power is turned on to the PLC.

－

Command
Function
LDF
Start of reverse edge detection action
X0~X17
Y0~Y17
M0~M799
T0~159
Operand





16-44

C0~C79


D0~D399

－

PLC Function Applications

The LDF command has the same usage as LD, but its action is different; its function is
to save current content while also saving the detected state of the falling edge of the
contact to the cumulative register.
Command code:
Description:
Ladder diagram:
Start of X0 reverse
X0
X1
LDF
X0
Y1
edge detection action
Create
series
AND
X1
connection to contact a
of X1
OUT
Y1
Drive Y1 coil
Command
Function
ANDP
Forward edge detection series connection
X0~X17
Y0~Y17
M0~M799
T0~159
Operand





C0~C79


D0~D399

－

The ANDP command used for a contact rising edge detection series connection.
Ladder diagram:
X0

Command code:
Description:
LD
X0
Load Contact a of X0
X1 Forward edge
X1
ANDP
detection series
connection
OUT
Y1
Drive Y1 coil

X1
Y1

Command
Function
ANDF
Reverse edge detection series connection
X0~X17
Y0~Y17
M0~M799
T0~159
Operand





C0~C79


D0~D399

－

The ANDF command is used for a contact falling edge detection series connection.
Ladder diagram:
X0

Command code:
Description:
LD
X0
Load Contact a of X0
X1 Reverse edge
X1
ANDF
detection series
connection
OUT
Y1
Drive Y1 coil

X1
Y1

Command
Function
ORP
Forward edge detection parallel connection
X0~X17
Y0~Y17
M0~M799
T0~159
Operand





C0~C79


D0~D399

－

The ORP command is used for a contact rising edge detection parallel connection.
Ladder diagram:
X0

Command code:
Y1

LD

X0

ORP

X1

OUT

Y1

X1

16-45

Description:
Load Contact a of X0
X1 Forward edge
detection parallel
connection
Drive Y1 coil

Command
Function
ORF
Reverse edge detection parallel connection
X0~X17
Y0~Y17
M0~M799
T0~159
Operand





C0~C79


D0~D399

－

The ORF command is used for contact falling edge detection parallel connection.
Ladder diagram:

Command code:

X0
Y1
X1

LD

X0

ORF

X1

OUT

Y1

Description:
Load Contact a of X0
X1 Reverse edge
detection parallel
connection
Drive Y1 coil

Command
Function
PLS
Upper differential output
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand


Upper differential output commands. When X0=Off→On (positive edge-triggered), the
PLS command will be executed, and M0 will send one pulse, with a pulse length
consisting of one scanning period.
Ladder diagram:
Command code:
Description:

－

－

－

－

X0
PLS

M0

SET

Y0

M0

Time sequence diagram:
X0

LD

X0

PLS

M0

LD

M0

SET

Y0

Load Contact a of X0
M0 Upper differential
output
Load Contact a of M0
Y0 Action continues
(ON)

Time for one scan cycle

M0
Y0

Command
Function
PLF
Lower differential output
X0~X17
Y0~Y17
M0~M799
T0~159
C0~C79
D0~D399
Operand


Lower differential output command. When X0= On→Off (negative edge-triggered), the
PLF command will be executed, and M0 will send one pulse, with pulse length
consisting of one scanning period.
Ladder diagram:
Command code:
Description:

－

－

－

－

X0
PLF

M0

SET

Y0

M0

Time sequence diagram:
X0

M0

Time for one scan cycle

Y0

16-46

LD

X0

PLF

M0

LD

M0

SET

Y0

Load Contact a of X0
M0 Lower differential
output
Load Contact a of M0
Y0 Action continues
(ON)

PLC Function Applications

Command
Function
END
Program conclusion
Operand
N/A
An END command must be added to the end of a ladder diagram program or
command program. The PLC will scan from address 0 to the END command, and will
return to address 0 and begins scanning again after execution.
Command
Function
NOP
No action
Operand
N/A
The command NOP does not perform any operation in the program. Because
execution of this command will retain the original logical operation results, it can be
used in the following situation: the NOP command can be used instead of a command
that is deleted without changing the program length.
Command code:
Ladder diagram:
Description:

NOP command will be simplified and not
displayed when the ladder diagram is
displayed.
X0
Y1

NOP

LD

X0

NOP
OUT

Load Contact b of X0
No action

Y1

Drive Y1 coil

Command
Function
INV
Inverse of operation results
Operand
N/A
Saves the result of the logic inversion operation prior to the INV command in the
cumulative register.
Ladder diagram:
Command code:
Description:
X0

LD

Y1

X0

INV
OUT

Y1

Load Contact a of X0
Inverse of operation
results
Drive Y1 coil

Command
Function
P
Index
Operand
P0~P255
Pointer P is used to subprogram call command API 01 CALL. Use does not require
starting from zero, but the number cannot be used repeatedly, otherwise an
unpredictable error will occur.
Command code:
Description:
Ladder diagram:
X0
LD
X0
Load Contact a of X0
P10
CALL
CALL
P10 Call command CALL to
P10

：

X1

P10

Y1

P10

16-47

Pointer P10

LD

X1

Load Contact a of X1

OUT

Y1

Drive Y1 coil

16-6-3 Overview of application commands
Classification
Circuit control

Send
comparison

Four logical
operations

Rotational
displacement
Data Process

API

Command code
16 bit
32 bit

P
command

Function

STEPS
16bit 32bit

01
2
06
10
11
12
15
20
21
22
23
24
25
30
31

CALL
SRET
FEND
CMP
ZCP
MOV
BMOV
ADD
SUB
MUL
DIV
INC
DEC
ROR
ROL

DCMP
DZCP
DMOV
–
DADD
DSUB
DMUL
DDIV
DINC
DDEC
DROR
DROL















Call subprogram
Conclusion of subprogram
Conclusion a main program
Compares set output
Range comparison
Data movement
Send all
BIN addition
BIN subtraction
BIN multiplication
BIN division
BIN add one
BIN subtract one
Right rotation
Left rotation

3
1
1
7
9
5
7
7
7
7
7
3
3
5
5

13
17
9
–
13
13
13
13
5
5
–
–

40

ZRST

–



Clear range

5

-


49

–

DFLT

BIN whole number → binary
floating point number
transformation

-

9

MODBUS read/write

7

–

–

13

–

17

–
–

9
9

–

13

–

13

–

13

–

13

–

9

–

9

–

9

–

9

–

9

–

9

–

9

–

9

–

9



communication
150

110
111
116
117
120
121
122
Floating point operation

123
124
125
127

MODRW

–
–
–
–
–
–
–
–
–
–
–

–


DECMP



DEZCP





DRAD
DDEG
DEADD



DESUB



DEMUL



DEDIV



DEXP



DLN



DESQR



–
129
130
131
132
133
134

DINT
–
–
–
–
–



DSIN



DCOS



DTAN



DASIN



DACOS

16-48

Comparison of binary floating
point numbers
Comparison of binary floating
point number range
Angle → Diameter
Diameter → angle
Binary floating point number
addition
Binary floating point number
subtraction
Binary floating point number
multiplication
Binary floating point number
division
Binary floating point number
obtain exponent
Binary floating point number
obtain logarithm
Binary floating point number
find square root
Binary floating point number →
BIN whole number
transformation
Binary floating point number
SIN operation
Binary floating point number
COS operation
Binary floating point number
TAN operation
Binary floating point number
ASIN operation
Binary floating point number
ACOS operation

PLC Function Applications

Classification

API
135

Floating
point
operation
Calendar

GRAY code

136
137
138

Command code
16 bit
32 bit
–
–
–
–

P
command


DATAN



DSINH



DCOSH



DTANH









Contact form logical operation

160
161
162
163
166
170

TCMP
TZCP
TADD
TSUB
TRD
GRY

–
–
–
–
–
DGRY

171

GBIN

DGBIN

215

LD&

DLD&

-

216

LD|

DLD|

-

217

LD^

DLD^

-

218

AND&

DAND&

-

219

ANDl

DANDl

-

220

AND^

DAND^

-

221

OR&

DOR&

-

222

OR|

DOR|

-

223

OR^

DOR^

-

Contact form compare command

224
225
226
228
229
230
232
233
234
236
237
238
240
241
242
244
245
246

＝
＞
＜
＜＞
＜＝
＞＝
＝
＞
＜
＜＞
＜＝
＞＝
＝
＞
＜
＜＞
＜＝
＞＝

LD
LD
LD
LD
LD
LD
AND
AND
AND
AND
AND
AND
OR
OR
OR
OR
OR
OR

＝
＞
＜
＜＞
＜＝
＞＝
＝
＞
＜
＜＞
＜＝
＞＝
＝
＞
＜
＜＞
＜＝
＞＝

DLD
DLD
DLD
DLD
DLD
DLD
DAND
DAND
DAND
DAND
DAND
DAND
DOR
DOR
DOR
DOR
DOR
DOR

-

16-49

Function
Binary floating point number
ATAN operation
Binary floating point number
SINH operation
Binary floating point number
COSH operation
Binary floating point number
TANH operation
Compare calendar data
Compare calendar data range
Calendar data addition
Calendar data subtraction
Calendar data read
BIN→GRY code transformation
GRY code →BIN
transformation
Contact form logical operation
LD#
Contact form logical operation
LD#
Contact form logical operation
LD#
Contact form logical operation
AND#
Contact form logical operation
AND#
Contact form logical operation
AND#
Contact form logical operation
OR#
Contact form logical operation
OR#
Contact form logical operation
OR#
Contact form compare LD*
Contact form compare LD*
Contact form compare LD*
Contact form compare LD*
Contact form compare LD*
Contact form compare LD*
Contact form compare AND*
Contact form compare AND*
Contact form compare AND*
Contact form compare AND*
Contact form compare AND*
Contact form compare AND*
Contact form compare OR*
Contact form compare OR*
Contact form compare OR*
Contact form compare OR*
Contact form compare OR*
Contact form compare OR*

STEPS
16bit 32bit
–

9

–

9

–

9

–

9

11
9
7
7
3
5

–
–
–
–
–
9

5

9

5

9

5

9

5

9

5

9

5

9

5

9

5

9

5

9

5

9

5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5
5

9
9
9
9
9
9
9
9
9
9
9
9
9
9
9
9
9
9

275

-

276

-

277

-

278

-

279

-

280

-

281

-

282

-

283

-

284

-

285

-

286

-

287

-

288

-

289

-

290

-

291

-

292

-

＝
FLD＞
FLD＜
FLD＜＞
FLD＜＝
FLD＞＝
FAND＝
FAND＞
FAND＜
FAND＜＞
FAND＜＝
FAND＞＝
FOR＝
FOR＞
FOR＜
FOR＜＞
FOR＜＝
FOR＞＝

139
140
141
142
262
263

RPR
WPR
FPID
FREQ
–
TORQ

–
–
–
–
DPOS
–

261

CANRX

–

264

CANTX

–

265

CANFLS

–

320
321

ICOMR
ICOMW

DICOMR
DICOMW

Compare command

API

Floating
point contact
form

Command code
16 bit
32 bit

Classification

P
command

FLD

-

Driver special command













16-50

Function
Floating point number contact
form compare LD*
Floating point number contact
form compare LD*
Floating point number contact
form compare LD*
Floating point number contact
form compare LD*
Floating point number contact
form compare LD*
Floating point number contact
form compare LD*
Floating point number contact
form compare AND*
Floating point number contact
form compare AND*
Floating point number contact
form compare AND*
Floating point number contact
form compare AND*
Floating point number contact
form compare AND*
Floating point number contact
form compare AND*
Floating point number contact
form compare OR*
Floating point number contact
form compare OR*
Floating point number contact
form compare OR*
Floating point number contact
form compare OR*
Floating point number contact
form compare OR*
Floating point number contact
form compare OR*
Read servo parameter
Write servo parameter
Driver PID control mode
Driver torque control mode
Set target
Set target torque
Read CANopen slave station
data
Write CANopen slave station
data
Refresh
special
D corresponding to CANopen
Internal communications read
Internal communications write

STEPS
16bit 32bit
-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

-

9

5
5
9
7
5

–
–
–
–
5
-

9

-

9

-

3

-

9
9

17
17

PLC Function Applications

16-6-4 Detailed explanation of applications commands
API

CALL

01

Bit device
X

Y

Call subprogram

S

P

Word device

M

K

H

KnX KnY KnM

T

C

D

32-bit command

－

Notes on operand usage:
The S operand can designate P
C2000 series device: The S operand can designate P0-P63

API

Y

－

－

Flag signal: none

：

S Call subprogram pointer.




Write the subprogram after the FEND command.




The subprogram must end after the SRET command.




Refer to the FEND command explanation and sample content for detailed
command functions.

－

P

Bit device
X

－




SRET

02

16-bit command (3 STEP)
CALL
Continuous
CALLP
Pulse
execution type
execution type

Conclusion of subprogram

Word device

M

K

H

KnX KnY KnM

16-bit command
T

C

D

FEND

32-bit command

－

Notes on operand usage:
No operand
A contact-driven command is not needed

(1 STEP)

Continuous
execution type

－

－

－

－

－

Flag signal: none




A contact-driven command is not needed. Automatically returns next
command after CALL command




Indicates end of subprogram. After end of subprogram, SRET returns to main
program, and executes next command after the original call subprogram CALL
command.
Refer to the FEND command explanation and sample content for detailed
command functions.




16-51

API

－

FEND

06

Bit device
X

Y

Conclusion a main program

Word device
M

K

H

KnX KnY KnM

16-bit command
T

C






FEND

32-bit command

－

Notes on operand usage:
No operand
A contact-driven command is not needed




D

(1 STEP)

Continuous
execution type

－

－

－

－

－

Flag signal: none

This command indicates the end of the main program. It is the same as
the END command when the PLC executes this command.
The CALL command program must be written after the FEND command,
and the SRET command added to the end of the subprogram.
When using the FEND command, an END command is also needed.
However, the END command must be placed at the end, after the main
program and subprogram.

16-52

PLC Function Applications

API

10

CMP

D

S1

P

Bit device
X
S1
S2
D

Y

M

＊ ＊

S2

Compares set output

D

Word device
K

H

KnX KnY KnM

T

C

Notes on operand usage:
The operand D occupies three consecutive points
















D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊

16-bit command (7 STEP)
CMP
Continuous
CMPP
execution type

32-bit command (13 STEP)
DCMP
Continuous DCMPP
Pulse
execution type
execution type
Flag signal: none

S1 : Compare value 1.

S2 : Compare value 2.

D : Results of comparison.
S1 and S2 ; the results of

Compares the size of the content of operand
comparison are expressed in D .
Size comparison is performed algebraically. All data is compared in the form of
numerical binary values. Because this is a 16-bit command, when b15 is 1, this
indicates a negative number.
When the designated device is Y0, it automatically occupies Y0, Y1 and Y2.
When X10=On, the CMP command executes, and Y0, Y1 or Y2 will be On. When
X10=Off, the CMP command will not execute, and the state of Y0, Y1 and Y2 will
remain in the state prior to X10=Off.
If ≥, ≤, or ≠ results are needed, they can be obtained via series/parallel
connections of Y0-Y2.
X10

CMP

K10

D10

Y0

Y0
If K10>D10, Y0 = On
Y1
If K10=D10, Y1 = On
Y2
If K10 upper limit S2 , the command will use the lower limit
S1 to perform comparison with the upper and lower limit.

upper limit





Size comparison is performed algebraically. All data is compared in the form of
numerical binary values. Because this is a 16-bit command, when b15 is 1, this
indicates a negative number.






When the designated device is M0, it automatically occupies M0, M1 and M2.
When X0=On, the ZCP command executes, and M0, M1 or M2 will be On. When
X0=Off, the ZCP command will not execute, and the state of M0, M1 or M2 will
remain in the state prior to X0=Off.
If ≥, ≤, or ≠ results are needed, they can be obtained via series/parallel
connections of M0-M2.




X0

ZCP

K10

K100

C10

M0

M0
If C10 < K10, M0 = On
M1
If

K10 <
= C10 <
= K100, M1 = On

M2
If C10 > K100, M2 = On




To clear results of comparison, use the RST or ZRST command.
X0

X0
RST

M0

RST

M1

RST

M2

ZRST

16-54

M0

M2

PLC Function Applications

API

12

D

MOV

P

Bit device

S

Data movement

D

Word device

X
Y
M
K
H KnX KnY KnM
S
D
Notes on operand usage: none

T

C

D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊

16-bit command (5 STEP)
MOV
Continuous
MOVP
execution type

Pulse
execution type

32-bit command (9 STEP)
DMOV
Continuous DMOVP
Pulse
execution type
execution type
Flag signal:






S : Data source.

D : Destination of data movement.
When this command is executed, the content of S content will be directly
moved to D . When the command is not executed, the content of D will not

change.





When X0=Off, the content of D10 will not change; if X0=On, the value K10 will be
sent to data register D10.
When X1=Off, the content of D10 will not change; if X1=On, the current value of
T0 will be sent to data register D10.
X0
MOV

K10

D0

MOV

T0

D10

X1

16-55

API

BMOV

15

S

P

Bit device
X

Y

M

D

n

Send all

Word device
K

H

KnX KnY KnM

T

C

16-bit command (7 STEP)
BMOV
Continuous BMOVP
Pulse
execution type
execution type

D

＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊
＊ ＊
＊ ＊
＝

S
D
n
Notes on operand usage:
n operand scope n
1 to 512






S : Initiate source device.

32-bit command

－

－

－

－

Flag signal: none

D : Initiate destination device.

n : Send block

length.
The content of n registers starting from the initial number of the device designated
by

S

will be sent to the n registers starting from the initial number of the

device designated by n ; if the number of points referred to by n exceeds the
range used by that device, only points within the valid range will be sent.



When X10=On, the content of registers D0-D3 will be sent to the four registers
D20 to D23.




D must
If the designated bit devices KnX, KnY, and KnM are sent, S and
have the same number of nibbles, which implies that n must be identical.




In order to prevent overlap between the transmission addresses of two operands,
which would cause confusion, make sure that the addresses designated by the
two operands have different sizes, as shown below:
When

S >

D , send in the order

X10
BMOV D20

When

S

<

D19

1→2 →3.

K3

D , send in the order

X11
BMOV D10

D11

K3

16-56

D20
D21
D22

1
2
3

D19
D20
D21

3→2 →1.
D10
D11
D12

3
2
1

D11
D12
D13

PLC Function Applications

API

20

D

ADD

S1

P

Bit device

S2

BIN addition

D

Word device

X
Y
M
K
H KnX KnY KnM
S1
S2
D
Notes on operand usage: none

T

C

16-bit command (7 STEP)
ADD
Continuous
ADDP
execution type

D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊

Pulse
execution type

32-bit command (13 STEP)
DADD
Continuous DADDP
Pulse
execution type
execution type
Flag signal: M1020 Zero flag
M1021 Borrow flag
M1022 Carry flag
Please refer to the following
supplementary explanation






S1 : Augend.

S2 : Addend.

D : Sum.

Using two data sources: The result of adding

S1

S2

and

using the BIN

D .







method will be stored in
The highest bit of any data is symbolized as bit 0 indicating (positive) 1 indicating
(negative), enabling the use of algebraic addition operations. (for instance:
3+(-9)=-6)
Flag changes connected with the addition.
1. When calculation results are 0, the zero flag M1020 will be On.
2. When calculation results are less than –32,768, the borrow flag M1021 will be
On.
3. When calculation results are greater than 32,767, the carry flag M1022 will be
On.




16-bit BIN addition: When X0=On, the result of the content of addend D0 plus the
content of augend D10 will exist in the content of D20.
X0

ADD




D0

D10

D20

Relationship between flag actions and negative/positive numbers:
Zero flag

16 bit: Zero flag
-2, -1, 0

-32,768

Borrow flag

-1, 0

The highest bit
of the data
= 1 (negative)

32 bit: Zero flag

1

32,767

The highest bit
of the data
= 0 (positive)

Zero flag

-2, -1, 0 -2,147,483,648

Borrow flag

Zero flag

-1, 0

The highest bit
of the data
= 1 (negative)

16-57

1

0

1 2

Carry flag

Zero flag
2,147,483,647 0 1 2

The highest bit
of the data
= 0 (positive)

Carry flag

API

21

D

SUB

S1

P

Bit device

S2

BIN subtraction

D

Word device

X
Y
M
K
H KnX KnY KnM
S1
S2
D
Notes on operand usage: none

T

C

16-bit command (7 STEP)
SUB
Continuous
SUBP
execution type

D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊

Pulse
execution type

32-bit command (13 STEP)
Continuous
Pulse
DSUB
DSUBP
execution type
execution type
Flag signal: M1020 Zero flag
M1021 Borrow flag
M1022 Carry flag
Please refer to the following
supplementary explanation






S1 : Minuend.

S2 : Subtrahend.

D : Difference.

Using two data sources: The result of subtraction of

S1

and

S2

using the

D .






BIN method is stored in
The highest bit of any data is symbolized as bit 0 indicating (positive) 1 indicating
(negative), enabling the use of algebraic subtraction operations.
Flag changes connected with subtraction.
1. When calculation results are 0, the zero flag M1020 will be On.
2. When calculation results are less than –32,768, the borrow flag M1021 will be
On.
3. When calculation results are greater than 32,767, the carry flag M1022 will be
On.




16-bit BIN subtraction: When X0=On, the content of D10 is subtracted from the
content of D0, and the difference is stored in D20.
X0

SUB

D0

16-58

D10

D20

PLC Function Applications

API

22

D

MUL

S1

P

Bit device

S2

BIN multiplication

D

Word device

16-bit command (7 STEP)
MUL
Continuous
MULP
execution type

X
Y
M
K
H KnX KnY KnM T
C
D
S1
S2
D
Notes on operand usage:
The 16-bit command operand D will occupy 2 consecutive points

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊

Pulse
execution type

32-bit command (13 STEP)
DMUL
Continuous DMULP
Pulse
execution type
execution type
Flag signal: none






S1 : Multiplicand.

S2 : Multiplier. D : Product.
Using two data sources: When S1 and S2 are multiplied using the BIN
method, the product is stored in D .

16-bit BIN multiplication operation:
S1

S2

b15..........b0

b15..........b0

D

D

b31..........b16b15..............b0

X
b15 is a symbol bit

+1

=
b31 is a symbol bit (b15 of D+1)

b15 is a symbol bit

Symbol bit = 0 refers to a positive value.
Symbol bit = 1 refers to a negative value.

When D is a bit device, K1-K4 can be designated as a hexadecimal number,
which will occupy 2 consecutive units.



When 16-bit DO is multiplied by 16-bit D10, the result will be a 32-bit product; the
upper 16 bits will be stored in D21, and the lower 16 bits will be stored in D20.
Whether the bit at the farthest left is Off or On will indicate the sign of the result.
X0

MUL

D0

D10

MUL

D0

D10 K8M0

16-59

D20

API

23

D

DIV

S1

P

Bit device

S2

BIN division

D

Word device

X
Y
M
K
H KnX KnY KnM T
C
D
S1
S2
D
Notes on operand usage:
The 16-bit command operand D will occupy 2 consecutive points

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊

16-bit command (7 STEP)
DIV
Continuous
DIVP
execution type

Pulse
execution type

32-bit command (13 STEP)
DDIV
Continuous
DDIVP
Pulse
execution type
execution type
Flag signal: none






S1 : Dividend.

S2 : Divisor.

D : Quotient and remainder.

Using two data sources: The quotient and remainder will be stored in
S1

and

S1 ,

S2

S2

D

when

are subjected to division using the BIN method. The sign bit for

and

D

must be kept in mind when performing a 16-bit operation.

16-bit BIN division:

Quotient

Remainder
+1

/

=

If D is a bit device, K1-K4 can be designated 16 bits, which will occupy 2
consecutive units and yield the quotient and remainder.



When X0=On, the quotient resulting from division of dividend D0 by divisor D10
will be placed in D20, and the remainder will be placed in D21. Whether the
highest bit is Off or On will indicate the sign of the result.
X0

DIV

D0

D10

DIV

D0

D10 K4Y0

16-60

D20

PLC Function Applications

API

24

D

INC

BIN add one

D

P

Bit device

Word device

X
Y
M
K
H KnX KnY KnM
D
Notes on operand usage: none

T

C

D

＊ ＊ ＊ ＊ ＊

16-bit command (3 STEP)
INC
Continuous
INCP
execution type

Pulse
execution type

32-bit command (5 STEP)
DINC
Continuous
DINCP
Pulse
execution type
execution type
Flag signal: none

D : Destination device.






If a command is not the pulse execution type, when the command is executed, the




program will add 1 to the content of device D for each scanning cycle.
This command is ordinarily used as a pulse execution type command (INCP).




During 16-bit operation, 32,767 +1 will change the value to -32,768. During 32 bit
operation, 2,147,483,647 +1 will change the value to -2,147,483,648.




When X0=Off→On, 1 is automatically added to the content of D0.
X0
INCP

D0

16-61

API

25

D

DEC

BIN subtract one

D

P

Bit device

Word device

X
Y
M
K
H KnX KnY KnM
D
Notes on operand usage: none

＊ ＊ ＊ ＊ ＊

T

C

D

16-bit command (3 STEP)
DEC
Continuous
DECP
execution type

Pulse
execution type

32-bit command (5 STEP)
DDEC
Continuous DDECP
Pulse
execution type
execution type
Flag signal: none

D : Destination device.






If a command is not the pulse execution type, when the command is executed, the




program will add 1 to the content of device D for each scanning cycle.
This command is ordinarily used as a pulse execution type command (DECP).




During 16-bit operation, -32,768 -1 will change the value to 32,767. During 32 bit
operation, -2,147,483,648 -1 will change the value to -2,147,483,647.




When X0=Off→On, 1 is automatically subtracted from the content of D0.
X0
DECP

D0

16-62

PLC Function Applications

API

30

ROR

D

D

P

Bit device
X

Y

M

D
n

Right rotation

n

Word device
K

H

KnX KnY KnM

T

C

D

＊ ＊ ＊ ＊ ＊

＊ ＊

16-bit command (5 STEP)
ROR
Continuous
RORP
execution type

Pulse
execution type

32-bit command (9 STEP)
DROR
Continuous DRORP
Pulse
Notes on operand usage:
execution type
execution type
Only K4 (16-bit) will be valid if the operand D is designated as KnY
or KnM.
Flag signal: M1022
Carry flag
n operand n=K1-K16 (16-bit)








D : Device to be rotated.

n : Number of bits for one rotation.
Rotates the device designated by D to the right n bits.




When X0=Off→On, 4 of the 16 bits in D10 specify a right rotation; the content of
the bit indicated with * (see figure below) will be sent to the carry flag signal
M1022.
X0

This command is ordinarily used as a pulse execution type command (RORP).

RORP D10

K4

Rotate to the right
upper bit

lower bit
Carry
flag

D10 0 1 1 1 1 0 1 1 0 1 0 0 0 1 0 1

upper bit

16 bits
After one rotation
to the right

lower bit

D10 0 1 0 1 0 1 1 1 1 0 1 1 0 1 0 0
*

16-63

0

Carry
flag

API

31

D

ROL

D

P

Bit device

Left rotation

n

Word device

16-bit command (5 STEP)
ROL
Continuous
ROLP
execution type

Pulse
X
Y
M
K
H KnX KnY KnM T
C
D
execution type
D
n
32-bit command (9 STEP)
Notes on operand usage:
DROL
Continuous DROLP
Pulse
Only K4 (16-bit) will be valid if the operand D is designated as KnY
execution type
execution type
or KnM.
n operand n=1 to 16 (16-bit)
Flag signal: M1022
Carry flag

＊ ＊ ＊ ＊ ＊

＊ ＊








D : Device to be rotated.

n : Number of bits for one rotation.
Rotates the device designated by D to the left n bits.




When X0=Off→On, 4 of the 16 bits in D10 specify a left rotation; the content of the
bit indicated with * (see figure below) will be sent to the carry flag signal M1022.

This command is ordinarily used as a pulse execution type command (ROLP).

X0

D10

K4

Rotate to the left
upper bit

lower bit

1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0
Carry
flag

16 bits
After one rotation
to the left
lower bit

upper bit
1

D10

1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1

Carry
flag

16-64

D10

PLC Function Applications

API

ZRST

40

D1

P

Bit device
X

Y

M

＊ ＊
＊ ＊

Clear range

D2

Word device
K

H

KnX KnY KnM

T

C

D

＊ ＊ ＊
＊ ＊ ＊

16-bit command (5 STEP)
ZRST
Continuous
ZRSTP
Pulse
execution type
execution type

D1
D2
32-bit command
Notes on operand usage:
Number of operand D1 operand ≤ number of operand D2
Operands D1, D2 must designate the same type of device
Please refer to the function specifications table for each device in Flag signal: none
series for the scope of device usage

－

－

－

－




D1: Clear range's initial device. D2: Clear range's final device.




When the number of operand D1 > number of operand D2, only the operand
designated by D2 will be cleared.






When X0 is On, auxiliary relays M300 - M399 will be cleared and changed to Off.
When X1 is On, 16-bit counters C0 - C127 will all be cleared. (Writes 0, and clears
and changes contact and coil to Off).
When X10 is On, timer T0 - T127 will all be cleared. (Writes 0, and clears and
changes contact and coil to Off).
When X3 is On, the data in data registers D0 - D100 will be cleared and set as 0.






X0
ZRST

M300

M399

ZRST

C0

C127

ZRST

T0

T127

ZRST

D0

D100

X1
X10
X3




Devices can independently use the clear command (RST), such as bit device Y, M
and word device T, C, D.
X0

16-65

RST

M0

RST

T0

RST

Y0

API

49

D

FLT

Bit device

BIN whole number
transformation

P
Word device

16-bit command

－

→

－

binary

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9steps)
D
Continuous
DFLTP
Notes on operand usage: Please refer to the function specifications DFLT
execution
type
table for each device in series for the scope of device usage
The operand D will occupy 2 consecutive points
Flag signal: none

＊ ＊
＊ ＊

＊ ＊ ＊
＊ ＊ ＊

decimal

－
Pulse
execution type




S: Transformation source device. D: Device storing transformation results.




Transforms BIN whole number into a binary decimal value.




When X11 is On, converts the whole number of values corresponding to D0 and
D1 into floating point numbers, which are placed in D20 and D21.

16-66

PLC Function Applications

API

MODRW

150

MODBUS data read/write

P

Bit device
X
S1
S2
S3
S
n

Y

M

Word device
K

H

＊
＊
＊
＊

＊
＊
＊
＊

KnX KnY KnM

T

C

D

＊
＊
＊
＊
＊

16-bit command (5 STEP)
MODRW Continuous MODRW
execution type P
32-bit command

－

－

Pulse
execution type

－

－

Flag signal: M1077 M1078 M1079


 S1: online device address. S2: communications function code. S3: address of
data to read/write. S: register for data to be read/written is stored. N: length of data
to be read/written.

 COM1 must be defined as controlled by the PLC (set P9-31 = -12) before using
this command, and the corresponding communications speed and format must
also be set (set P09-01 and P09-04). S2: communications function code.
Currently only supports the following function code; the remaining function code
cannot be executed.
Function
H 02

Description
Input read

H 03

Read word

H 06

Write single word

H 0F

Write multiple coils

H10
Write single word

 After executing this command, M1077, M1078 and M1079 will be immediately
changed to 0.

 As an example, when C2000 must control another converter and PLC, if the
converter has a station number of 10 and the PLC has a station number of 20, see
the following example:
Control slave device converter
MODRW command
Seria
l No.

1

2

3

4

S1
S2
S3
S4
n
Node Function Addres
Leng
Register
ID
code
s
th:

Example

Reads 4 sets of data comprising the
converter slave device parameters
P01-00 to P01-03, and saves the read
data in D0 to D3
Reads 3 sets of data comprising the
converter slave device addresses
H2100 to H2102, and saves the read
data in D5 to D7
Reads 3 sets of data comprising the
converter slave device parameters
P05-00 to P05-03, and writes the
values as D10 to D12
Writes 2 sets of data comprising the
converter slave device addresses
H2000 to H2001, and writes the values
as D15 to D16

16-67

K10

H3

H100

D0

K4

K10

H3

H2100

D5

K3

K10

H10

H500

D10

K3

K10

H10

H2000

D15

K2

PLC controlling slave device
Serial
No.

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

MODRW command
S1
S2
S3
S4
n
Node Functio Addres Registe
Length:
ID
n code
s
r

Example

Reads 4 sets of data comprising the
PLC slave device's X0 to X3 state, and
saves the read data in bits 0 to 3 of D0
Reads 4 sets of data comprising the
PLC slave device's Y0 to Y3 state, and
saves the read data in bits 0 to 3 of D1
Reads 4 sets of data comprising the
PLC slave device's M0 to M3 state, and
saves the read data in bits 0 to 3 of D2
Reads 4 sets of data comprising the
PLC slave device's T0 to T3 state, and
saves the read data in bits 0 to 3 of D3
Reads 4 sets of data comprising the
PLC slave device's C0 to C3 state, and
saves the read data in bits 0 to 3 of D4
Reads 4 sets of data comprising the
PLC slave device's T0 to T3 count
value, and saves the read data of D10
to D13
Reads 4 sets of data comprising the
PLC slave device's C0 to C3 count
value, and saves the read data of D20
to D23
Reads 4 sets of data comprising the
PLC slave device's D0 to D3 count
value, and saves the read data of D30
to D33
Writes 4 sets of the PLC slave device's
Y0 to Y3 state, and writes the values as
bits 0 to 3 of D1
Writes 4 sets of the PLC slave device's
M0 to M3 state, and writes the values
as bits 0 to 3 of D2
Writes 4 sets of the PLC slave device's
T0 to T3 state, and writes the values as
bits 0 to 3 of D3
Writes 4 sets of the PLC slave device's
C0 to C3 state, and writes the values
as bits 0 to 3 of D4
Writes 4 sets of the PLC slave device's
T0 to T3 state, and writes the values of
D10 to D13
Writes 4 sets of the PLC slave device's
C0 to C3 state, and writes the values of
D20 to D23
Writes 4 sets of the PLC slave device's
D0 to D3 state, and writes the values of
D30 to D33

16-68

K20

H2

H400

D0

K4

K20

H2

H500

D1

K4

K20

H2

H800

D2

K4

K20

H2

H600

D3

K4

K20

H2

HE00

D4

K4

K20

H3

H600

D10

K4

K20

H3

HE00

D20

K4

K20

H3

H1000

D30

K4

K20

HF

H500

D1

K4

K20

HF

H800

D2

K4

K20

HF

H600

D3

K4

K20

HF

HE00

D4

K4

K20

H10

H600

D10

K4

K20

H10

HE00

D20

K4

K20

H10

H1000

D30

K4

PLC Function Applications










Will trigger M0 On when the PLC begins to operate, and sends instruction to
execute one MODRW command.
After receiving the slave device's response, if the command is correct, it will
execute one ROL command, which will cause M1 to be On.
After receiving the slave device's response, will trigger M50 = 1 after a delay of 10
PLC scanning cycles, and then execute one MODRW command.
After again receiving the slave device's response, if the command is correct, it will
execute one ROL command, and M2 will change to On at this time (and M2 can
be defined as a repeat of M); K4M0 will change to K1, and only M0 will remain 1.
Transmission can proceed in a continuous cycle. If you wish to add a command,
merely add the desired command in the empty frame, and change repeat M to
Mn+1.

16-69

API

110 D

ECMP

Comparison of binary floating point numbers

P

Bit device
X

Y

M

Word device
K

H

＊ ＊
＊ ＊
＊ ＊

KnX KnY KnM

T

C

D

＊
＊
＊

16-bit command

－

－

－

－

S1
S2
32-bit command (13 STEP)
DECMP Continuous DECMPP
Pulse
D
execution type
execution type
Notes on operand usage:
The operand D occupies three consecutive points
Please refer to the function specifications table for each device in Flag signal: none
series for the scope of device usage




S1: Comparison of binary floating point numbers value 1. S2: Comparison of
binary floating point numbers value 2. D: Results of comparison, occupies 3
consecutive points.




When binary floating point number 1 is compared with comparative binary
floating point number 2, the result of comparison (>, =, <) will be expressed in D.




If the source operand S1 or S2 designates a constant K or H, the command will
transform the constant to a binary floating-point number for the purpose of
comparison.




When the designated device is M10, it will automatically occupy M10-M12.




When X0=On, the DECMP command executes, and one of M10-M12 will be On.
When X0=Off, the DECMP command will not execute, and M10-M12 will remain
in the X0=Off state.




If results in the form of ≥, ≤, or ≠ are needed, they can be obtained by series and
parallel connection of M10-M12.




Please use the RST or ZRST command to clear the result.

16-70

PLC Function Applications

API

EZCP

111 D

Comparison of binary floating point number range

P

Bit device
X

Y

M

Word device

T
C
D
S1
S2
S
D
Notes on operand usage:
The operand D occupies three consecutive points
Please refer to the function specifications table for each device in
series for the scope of device usage

＊ ＊

K

H

＊ ＊
＊ ＊
＊ ＊

KnX KnY KnM

＊
＊
＊

16-bit command

－

－

－

－

32-bit command (17 STEP)
DEZCP
Continuous DEZCPP
Pulse
execution type
execution type
Flag signal: none




S1: Lower limit of binary floating point number in range comparison. S2: Upper
limit of binary floating point number in range comparison. S: Comparison of
binary floating point numerical values. D: Results of comparison, occupies 3
consecutive points.




Comparison of binary floating point numerical value S with binary floating point
number lower limit value S1 and binary floating point number upper limit value S2;
the results of comparison are expressed in D.




If the source operand S1 or S2 designates a constant K or H, the command will
transform the constant to a binary floating-point number for the purpose of
comparison.




When the lower limit binary floating point number S1 is greater than the upper
limit binary floating point number S2, a command will be issued to perform
comparison with the upper and lower limits using the binary floating point number
lower limit value S1.




When the designated device is M0, it will automatically occupy M0- M2.




When X0=On, the DEZCP command will be executed, and one of M0-M2 will be
On. When X0=Off, the EZCP command will not execute, and M0-M2 will continue
in the X0=Off state.




Please use the RST or ZRST command to clear the result.

16-71

API

116 D

RAD

Angle → Diameter

P

Bit device

Word device

16-bit command

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DRAD
Continuous DRADP
Notes on operand usage:
execution
type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊

－
脈波執行型




S: data source (angle). D: result of transformation (diameter).




Uses the following formula to convert angles to radians.




Diameter




When X0=On, the angle of the designated binary floating point number (D1, D0)
will be converted to radians and stored in (D11, D10), with the content consisting
of a binary floating point number.

＝Angle

× (π/180)

X0
DRAD

D0

D10

16-72

PLC Function Applications

API

117 D

DEG

Diameter → angle

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DDEG
Continuous DDEGP
Pulse
Notes on operand usage:
execution type
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: data source (diameter). D: results of transformation (angle).




Uses the following formula to convert radians to an angle.




Angle




When X0=On, angle of the designated binary floating point number (D1, D0) in
radians will be converted to an angle and stored in (D11, D10), with the content
consisting of a binary floating point number.

＝Diameter × (180/π)

X0
DDEG

D0

D1

D0

D 11

D 10

D10

徑度值
2 進小數點
角度值 (徑度值
2 進小數點

16-73

X

180/ π )

API

120 D

EADD

Adding binary floating point numbers

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S1
32-bit command (9 STEP)
S2
DEADD
Continuous DEADDP
Pulse
D
execution type
execution type
Notes on operand usage:
Please refer to the function specifications table for each device in
Flag signal: none
series for the scope of device usage

＊ ＊
＊ ＊

＊
＊
＊




S1: addend. S2: augend. D: sum.




When the content of the register designated by S2 is added to the content of the
register designated by S1, and the result is stored in the register designated by D.
Addition is performed entirely using binary floating-point numbers.




If the source operand S1 or S2 designates a constant K or H, the command will
transform that constant into a binary floating point number for use in addition.




In the situation when S1 and S2 designate identical register numbers, if a
"continuous execution" command is employed, when conditional contact is On,
the register will perform addition once during each scan. Pulse execution type
commands (DEADDP) are generally used under ordinary circumstances.




When X0=On, a binary floating point number (D1, D0) will be added to a binary
floating point number (D3, D2), and the results stored in (D11, D10).
X0
DEADD




D0

D2

D10

When X2 =On, a binary floating point number (D11, D10) will be added to K1234
(which has been automatically converted to a binary floating-point number), and
the results stored in (D21, D20).
X2
DEADD

D10

K1234

16-74

D20

PLC Function Applications

API

121 D

ESUB

Subtraction of binary floating point numbers

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S1
32-bit command (13 STEP)
S2
DESUB
Continuous DESUBP
Pulse
D
execution type
execution type
Notes on operand usage:
Please refer to the function specifications table for each device in
Flag signal: none
series for the scope of device usage

＊ ＊
＊ ＊

＊
＊
＊




S1: minuend. S2: subtrahend. D: difference.




When the content of the register designated by S2 is subtracted from the content
of the register designated by S1, the difference will be stored in the register
designated by D; subtraction is performed entirely using binary floating-point
numbers.




If the source operand S1 or S2 designates a constant K or H, the command will
transform that constant into a binary floating point number for use in subtraction.




In the situation when S1 and S2 designate identical register numbers, if a
"continuous execution" command is employed, when conditional contact is On,
the register will perform addition once during each scan. Pulse execution type
commands (DESUBP) are generally used under ordinary circumstances.




When X0=On, a binary floating point number (D1, D0) will be subtracted to a
binary floating point number (D3, D2), and the results stored in (D11, D10).
X0
DESUB




D0

D2

D10

When X2 =On, the binary floating point number (D1, D0) will be subtracted from
K1234 (which has been automatically converted to a binary floating-point
number), and the results stored in (D11, D10).
X2
DESUB

K1234

D0

16-75

D10

API

122 D

EMUL

Multiplication of binary floating point numbers

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S1
32-bit command (13 STEP)
S2
DEMUL
Continuous DEMULP
Pulse
D
execution type
execution type
Notes on operand usage:
Please refer to the function specifications table for each device in
Flag signal: none
series for the scope of device usage

＊ ＊
＊ ＊

＊
＊
＊




S1: multiplicand. S2: multiplier.




When the content of the register designated by S1 is multiplied by the content of
the register designated by S2, the product will be stored in the register
designated by D; multiplication is performed entirely using binary floating-point
numbers.




If the source operand S1 or S2 designates a constant K or H, the command will
transform that constant into a binary floating point number for use in
multiplication.




In the situation when S1 and S2 designate identical register numbers, if a
"continuous execution" command is employed, when conditional contact is On,
the register will perform multiplication once during each scan. Pulse execution
type commands (DEMULP) are generally used under ordinary circumstances.




When X1=On, the binary floating point number (D1, D0) will be multiplied by the
binary floating point number (D11, D10), and the product will be stored in the
register designated by (D21, D20).

D: product.

X1
DEMUL




D0

D10

D20

When X2 =On, the binary floating point number (D1, D0) will be multiplied from
K1234 (which has been automatically converted to a binary floating-point
number), and the results stored in (D11, D10).
X2
DEMUL

K1234

D0

16-76

D10

PLC Function Applications

API

123 D

EDIV

Division of binary floating point numbers

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S1
32-bit command (13 STEP)
S2
DEDIV
Continuous DEDIVP
Pulse
D
execution type
execution type
Notes on operand usage:
Please refer to the function specifications table for each device in
Flag signal: none
series for the scope of device usage

＊ ＊
＊ ＊

＊
＊
＊



S1: dividend. S2: divisor. D: quotient and remainder.



When the content of the register designated by S1 is divided by the content of the
register designated by S2, the quotient will be stored in the register designated
by D; division is performed entirely using binary floating-point numbers.




If the source operand S1 or S2 designates a constant K or H, the command will
transform that constant into a binary floating point number for use in division.


When X1=On, the binary floating point number (D1, D0) will
be divided by the binary floating point number (D11, D10),
and the quotient stored in the register designated by (D21,
D20).

X1
DEDIV



D0

D10

D20

When X2 =On, the binary floating point number (D1, D0) will be divided by
K1,234 (which has been automatically converted to a binary floating-point
number), and the results stored in (D11, D10).
X2
DEDIV

D0

K1234

16-77

D10

API

124 D

EXP

Binary floating point number obtain exponent

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DEXP
Continuous
DEXPP
Pulse
Notes on operand usage:
execution type
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: operation source device. D: operation results device.




Taking e =2.71828 as a base, S is the exponent in the EXP operation.




[ D +1 D ]=EXP [ S +1 S ]




Valid regardless of whether the content of S has a positive or negative
value. The designated register D must have a 32-bit data format. This
operation is performed using floating-point numbers, and S must therefore
be converted to a floating point number.




Content of operand D =e S ; e=2.71828, S is the designated source data




When M0 is On, the value of (D1, D0) will be converted to a binary floating
point number, which will be stored in register (D11, D10).




When M1 is On, the EXP operation is performed on the exponent of (D11,
D10); its value is a binary floating point number stored in register (D21,
D20).
M0
DFLT D0
D10

，

，

M1
DEXP

16-78

D10

D20

PLC Function Applications

API

125 D

LN

Binary floating point number obtain logarithm

P

Bit device

Word device

16-bit command

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DLN
Continuous
DLNP
Notes on operand usage:
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊

－
Pulse
execution type




S: operation source device. D: operation results device.




Taking e =2.71828 as a base, S is the exponent in the EXP operation.




[ D +1 D ]=EXP [ S +1 S ]




Valid regardless of whether the content of S has a positive or negative
value. The designated register D must have a 32-bit data format. This
operation is performed using floating-point numbers, and S must therefore
be converted to a floating point number.




Content of operand D =e S ; e=2.71828




When M0 is On, the value of (D1, D0) will be converted to a binary floating
point number, which will be stored in register (D11, D10).




When M1 is On, the EXP operation is performed on the exponent of (D11,
D10); its value is a binary floating point number stored in register (D21,
D20).
M0
DFLT D0
D10

，

，

， S is the designated source data

M1
DLN

16-79

D10

D20

API

127

D

ESQR

Binary floating point number find square root

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DESQR Continuous DESQR
Pulse
Notes on operand usage:
execution type
P
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊




＊
＊




S: source device for which square root is desired D: result of finding square
root.




When the square root is taken of the content of the register designated by
S, the result is temporarily stored in the register designated by D. Taking
square roots is performed entirely using binary floating-point numbers.




If the source operand S refers to a constant K or H, the command will
transform that constant into a binary floating point number for use in the
operation.

When X0=On, the square root is taken of the binary floating point number (D1,
D0), and the result is stored in the register designated by (D11, D10).
X0
DESQR




D0

(D1, D0)

(D11, D10)

Binary floating
point

Binary floating
point

D10

When X2 =On, the square root is taken of K1,234 (which has been automatically
converted to a binary floating-point number), and the results stored in (D11,
D10).
X2
DESQR

K1234

16-80

D10

PLC Function Applications

API

129

D

INT

Binary floating point number → BIN whole
number transformation

P

Bit device

Word device

16-bit command

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DINT
Continuous
DINTP
Notes on operand usage:
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊
＊




－
Pulse
execution type




S: the source device to be transformed. D: results of transformation.




The content of the register designated by S is transformed from a binary
floating point number format into a BIN whole number, and is temporarily
stored in D. The BIN whole number floating point number will be discarded.




The action of this command is the opposite of that of command API 49
(FLT).

When X0=On, the binary floating point number (D1, D0) is transformed into a
BIN whole number, and the result is stored in (D10); the BIN whole number
floating point number will be discarded.
X0
DINT

16-81

D0

D10

API

130

SIN

D

Binary floating point number SIN operation

P

Bit device

Word device

16-bit command

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DSIN
Continuous
DSINP
Notes on operand usage:
execution type
Please refer to the function specifications table for each device in series
for the scope of device usage
Flag signal: none

＊ ＊

＊
＊



S: the designated source value. D: the SIN value result.



S is the designated source in radians.



The value in radians (RAD) is equal to (angle ×π/180).



The SIN obtained from the source value designated by S is stored in D.

－
Pulse
execution type

The following figure displays the relationship between the arc and SIN results:
S: Radian
R: Result (SIN value)

R
1

-2

- 32

-2

0

-2

3
2

2

2

S

-1



When X0=On, the SIN value of the designated binary floating point number (D1,
D0) in radians (RAD) will be stored in (D11, D10), with the content consisting of a
binary floating point number.
X0
DSIN

D0

D10

16-82

PLC Function Applications

API

131

D

COS

Binary floating point number COS operation

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DCOS
Continuous DCOSP
Pulse
Notes on operand usage:
execution type
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: the designated source value. D: the COS value result.




The source designated by S can be given as radians or an angle; this is
decided by flag M1018.




When M1018=Off, the operation is in radians mode, where the radians (RAD)
value is equal to (angle ×π/180).




When M1018=On, the operation is in the angle mode, where the angular range is
0°≤ angle <360°.




When calculation results yield 0, M1020=On.




The COS obtained from the source value designated by S is stored in D.
The following figure displays the relationship between the arc and SIN results:
S: Radian
R: Result (COS value)

R
1

-2

- 32

-2

0

-2

2

3
2

2

S

-1




When X0=On, the COS value of the designated binary floating point number (D1,
D0) in radians will be stored in (D11, D10), with the content consisting of a binary
floating point number.
X0
DCOS

D0

D10

D1

D0

RAD value ( x π/ 180)
binary floating point

D1

D 10

COS value
binary floating point

16-83

API

132 D

TAN

Binary floating point number TAN operation

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DTAN
Continuous
DTANP
Pulse
Notes on operand usage:
execution type
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: the designated source value. D: the TAN value result.




The source designated by S can be given as radians or an angle; this is decided by
flag M1018.




When M1018=Off, the operation is in radians mode, where the radians (RAD) value
is equal to (angle ×π/180).




When M1018=On, the operation is in the angle mode, where the angular range is
0°≤ angle <360°.




When calculation results yield 0, M1020=On.




The TAN obtained from the source value designated by S is stored in D.
The following figure displays the relationship between the arc and SIN results:



When X0=On, the TAN value of the designated binary floating point number (D1,
D0) in radians (RAD) will be stored in (D11, D10), with the content consisting of a
binary floating point number.
X0
DTAN
D1

D0

D 11

D 10

D0

D10

RAD value (degree x π / 180)
binary floating point
TAN value
binary floating point

16-84

PLC Function Applications

API

133

D

ASIN

Binary floating point number ASIN operation

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DASIN
Continuous DASINP
Pulse
Notes on operand usage:
execution type
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: the designated source (binary floating point number). D: the ASIN value result.




ASIN value =sin-1
The figure below shows the relationship between input data and result:
R

S: Input (SIN value)
R: Result (ASIN value)
2

-1,0

0

-



1,0

S

2

When X0=On, the ASIN value obtained from the designated binary floating point
number (D1, D0) will be stored in (D11, D10), with the content consisting of a
binary floating point number.
X0
DASIN

D0

D10

D1

D0

Binary floating point

D 11

D 10

ASIN value
binary floating point

16-85

API

134

D

ACOS

Binary floating point number ACOS operation

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DACOS
Continuous DACOS
Pulse
Notes on operand usage:
execution type
P
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: the designated source (binary floating point number). D: the ACOS value result.




ACOS value =cos-1
The figure below shows the relationship between input data and result:
R
S: Input (COS value)
R: Result (ACOS value)

2

-1,0



0

1,0

S

When X0=On, the ACOS value obtained from the designated binary floating point
number (D1, D0) will be stored in (D11, D10), with the content consisting of a
binary floating point number.
X0
DACOS

D0

D1

D0

D 11

D 10

D10

Binary floating point

ACOS value

16-86

PLC Function Applications

API

135

D

ATAN

Binary floating point number ATAN operation

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DATAN
Continuous DATANP
Pulse
Notes on operand usage:
execution type
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: the designated source (binary floating point number). D: the ATAN value result.




ATAN value =tan-1
The figure below shows the relationship between input data and result:
R

S: Input (TAN value)
R: Result (ATAN value)

2

S

0

-2



When X0=On, the TAN value obtained from the designated binary floating point
number (D1, D0) will be stored in (D11, D10), with the content consisting of a
binary floating point number.
X0
D0

DATAN

D10

D1

D0

Binary floating point

D 11

D 10

ATAN value
binary floating point

16-87

API

136

D

SINH

Binary floating point number SINH operation

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DSINH
Continuous DSINHP
Pulse
Notes on operand usage:
execution type
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: the designated source (binary floating point number). D: the SINH value result.




SINH value =(es-e-s)/2




When X0=On, the SINH value obtained from the designated binary floating point
number (D1, D0) will be stored in (D11, D10), with the content consisting of a
binary floating point number.
X0
DSINH

D0

D1

D0

D 11

D 10

D10

binary floating point

SINH value
binary floating point

16-88

PLC Function Applications

API

137 D

COSH

Binary floating point number COSH operation

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DCOSH Continuous DCOSHP
Pulse
Notes on operand usage:
execution type
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: the designated source (binary floating point number). D: the COSH value result.




COSH value =(es+e-s)/2




When X0=On, the COSH value obtained from the designated binary floating point
number (D1, D0) will be stored in (D11, D10), with the content consisting of a
binary floating point number.
X0
DCOSH

D0

D10

D1

D0

binary floating point

D 11

D 10

COSH value
binary floating point

16-89

API

138 D

TANH

Binary floating point number TANH operation

P

Bit device

Word device

16-bit command

－

－

－

－

X
Y
M
K
H KnX KnY KnM T
C
D
S
32-bit command (9 STEP)
D
DTANH
Continuous DTANHP
Pulse
Notes on operand usage:
execution type
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＊ ＊

＊
＊




S: the designated source (binary floating point number). D: the TANH value result.




tanh value =(es-e-s)/(es+e-s)




When X0=On, the TANH value obtained from the designated binary floating point
number (D1, D0) will be stored in (D11, D10), with the content consisting of a binary
floating point number.
X0
DTANH

D0

D10

D1

D0

binary floating point

D 11

D 10

TANH value
binary floating point

16-90

PLC Function Applications

API

TCMP

160

Comparison of calendar data

P

Bit device

Word device

T
C
D 16-bit command (11 STEP)
TCMP
Continuous TCMPP
Pulse
S1
execution type
execution type
S2
S3
32-bit command
S
D
Notes on operand usage:
Flag signal: none
Please refer to the function specifications table for each device in
series for the scope of device usage
X

Y

M

＊ ＊

K

H

KnX KnY KnM

＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊

＊
＊
＊
＊

－

－

－

－




S1: Sets the hours of the comparison time, setting range is "K0-K23." S2: Sets the
minutes of the comparison time, setting range is "K0-K59." S3: Sets the seconds of
the comparison time, setting range is "K0-K59." S: current calendar time. D:
Results of comparison.




Compares the time in hours, minutes, and seconds set in S1 - S3 with the current
calendar time in hours, minutes, and seconds, with the results of comparison
expressed in D.




S The hour content of the current calendar time is "K0-K23." S +1 comprises the
minutes of the current calendar time, and consists of "K0-K59." S +2 comprises the
seconds of the current calendar time, and consists of "K0-K59."




The current calendar time designated by S is usually compared using the TCMP
command after using the TRD command to read the current calendar time. If the
content value of S exceeds the range, this is considered an operating error, the
command will not execute, and M1068=On.




When X10=On, the command will execute, and the current calendar time in
D20-D22 will be compared with the preset value of 12:20:45; the results will be
displayed in M10-M12. When X10 On→Off, the command will not be executed, but
the On/Off status prior to M10-M12 will be maintained.




If results in the form of ≥, ≤, or ≠ are needed, they can be obtained by series and
parallel connection of M10-M12.
X10
TCMP

K12

K20

>

D20 (hr )
D21(min )
D22

=

D20
D21 (m in)
D22 (s ec)

<

D20 ( hr)
D21 ( min )
D22

M10
ON when12: 20: 45

M11
ON when 12: 20: 45

M12
ON when12: 20: 45

16-91

K45

D20

M10

API

TZCP

161

Comparison of calendar data

P

Bit device
X

Y

M

Word device
K

H

KnX KnY KnM

T

C

D

＊ ＊ ＊
＊ ＊ ＊
＊ ＊ ＊

16-bit command (9 STEP)
TZCP
Continuous
TZCPP
Pulse
execution type
execution type

S1
S2
32-bit command
S
D
Notes on operand usage:
Please refer to the function specifications table for each device in Flag signal: none
series for the scope of device usage

＊ ＊

－

－

－

－




S1: Sets the lower limit of the comparison time. S2: Sets the upper limit of the
comparison time. S: current calendar time. D: Results of comparison.




Performs range comparison by comparing the hours, minutes, and seconds of the
current calendar time designated by S with the lower limit of the comparison time
set as S1 and the upper limit of the comparison time set as S2, and expresses the
results of comparison in D.




S1 S1 +1 S1 +2: Sets the hours, minutes, and seconds of the lower limit of the
comparison time.




S2 S2 +1 S2 +2: Sets the hours, minutes, and seconds of the upper limit of the
comparison time.




S S +1 S +2: The hours, minutes, and seconds of the current calendar time




The D0 designated by the S listed in this program is usually obtained by
comparison using the TZCP command after using the TRD command in advance to
read the current calendar time. If the value of S1, S2, or S exceeds the range, this is
considered an operating error, the command will not execute, and M1068=On.




When the current time S is less than the lower limit value S1 and S is less than the
upper limit value S2, D will be On. When the current time S is greater than the lower
limit value S1 and S is greater than the upper limit value S2, D +2 will be On; D +1
will be On under other conditions.

、

、

、

、

、




、

When X10=On, the TZCP command executes, and one of M10-M12 will be
On. When X10=Off, the TZCP command will not execute, and M10-M12 will
remain in the X10=Off state.
X10
TZCP
M10

M11
ON when

D0

D20

D10

M10

D0 (hr)
D1 (min)
D2 (sec)

>

D10 (hr)
D11 (min)
D12 (sec)

D0 (hr)
D1 (min)
D2 (sec)

<
=

D10 (hr)
D11 (min)
D12 (sec)

<
=

D20 (hr)
D21 (min)
D22 (sec)

D10 (hr)
D11 (min)
D12 (sec)

>

D20 (hr)
D21(min)
D22 (sec)

M12
ON when

16-92

PLC Function Applications

API

162

TADD

Calendar data addition

P

Bit device

Word device

16-bit command (7 STEP)
TADD
Continuous
TADDP
Pulse
execution type
execution type

X
Y
M
K
H KnX KnY KnM T
C
D
S1
S2
32-bit command
D
Notes on operand usage:
Please refer to the function specifications table for each device in
 Flag signal: M1020 Zero flag
series for the scope of device usage

＊ ＊ ＊
＊ ＊ ＊
＊ ＊ ＊

－

－

－

－

M1022 Carry flag
M1068 Calendar error




S1: time addend. S2: time augend. D: time sum.




The calendar data in hours, minutes, and seconds designated by S2 is added to the
calendar data in hours, minutes, and seconds designated by S1, and the result is
stored as hours, minutes, and seconds in the register designated by D.




If the value of S1 or S2 exceeds the range, this is considered an operating error, the
command will not execute, M1067, M1068=On, and D1067 will record the error
code 0E1A(HEX).




If the results of addition are greater than or equal to 24 hours, carry flag
M1022=On, and D will display the results of addition minus 24 hours.




If the results of addition are equal to 0 (0 hours, 0 minutes, 0 seconds), zero flag
M1020=On.



When X10=On, the TADD command will be executed, and the calendar data
in hours, minutes, and seconds designated by D0 to D2 will be added to the
calendar data in hours, minutes, and seconds designated by D10 to D12, and
the results are stored as a total number of hours, minutes, and seconds in the
registers designated by D20 to D22.
X10
TADD

D0 8(hr )
D1
min )
D2 20(sec )

8 : 10 : 20

D0

+

D10

D20

6(hr)
D11 40( min)
D12 6(sec)

D20 14(hr )
D21 50(min)
D22 26(sec)

6 : 40 : 6

14: 50: 26

16-93

API

163

TSUB

Calendar data subtraction

P

Bit device

Word device

16-bit command (7 STEP)
TSUB
Continuous
TSUBP
Pulse
execution type
execution type

X
Y
M
K
H KnX KnY KnM T
C
D
S1
S2
32-bit command
D
Notes on operand usage:
Please refer to the function specifications table for each device in
 Flag signal: M1020 Zero flag
series for the scope of device usage

＊ ＊ ＊
＊ ＊ ＊
＊ ＊ ＊

－

－

－

－

M1022 Carry flag
M1068 Calendar error




S1: time minuend. S2: time augend. D: time sum.




Subtracts the calendar data in hours, minutes, and seconds designated by S2 from
the calendar data in hours, minutes, and seconds designated by S1, and the result
is temporarily stored as hours, minutes, and seconds in the register designated by
D.




If the value of S1 or S2 exceeds the range, this is considered an operating error, the
command will not execute, M1067, M1068=On, and D1067 will record the error
code 0E1A(HEX).




If subtraction results in a negative number, borrow flag M1021=On, and the result of
that negative number plus 24 hours will be displayed in the register designated by
D.




If the results of subtraction are equal to 0 (0 hours, 0 minutes, 0 seconds), zero flag
M1020=On.



When X10=On, the TADD command will be executed, and the calendar data in
hours, minutes, and seconds designated by D10 to D12 will be subtracted from
the calendar data in hours, minutes, and seconds designated by D0 to D2, and
the results are stored as a total number of hours, minutes, and seconds in the
registers designated by D20 to D22.
X10
TSUB

D0

D10

D20

D0 20(
D1 20(min)
D2 5( sec)

hr)
D11
min)
D12 8(sec)

D20 5(hr)
D21 49(min)
D22 57( sec)

20: 20: 5

14: 30: 8

5: 49: 57

16-94

PLC Function Applications

API

166

TRD

Calendar data read

P

Bit device

Word device

16-bit command (3 STEP)
TRD
Continuous
120
execution type

X
Y
M
K
H KnX KnY KnM T
C
D
D
Notes on operand usage:
Please refer to the function specifications table for each device in 32-bit command
series for the scope of device usage

＊ ＊ ＊

－



－

－

Pulse
execution type

－

Flag signal: none




S1: time minuend. S2: time augend. D: time sum.




D: device used to store the current calendar time after reading.




The EH/EH2/SV/EH3/SV2/SA/SX/SC main units have a built-in calendar clock, and
the clock provides seven sets of data comprising year, week, month, day, hour,
minute, and second stored in D1063 to D1069. The TRD command function allows
program designers to directly read the current calendar time into the designated
seven registers.




D1063 only reads the two right digits of the Western calendar year.



When X0=On, the current calendar time is read into the designated registers
D0 to D6.




In D1064, 1 indicates Monday, 2 indicates Tuesday, and so on, with and 7
indicating Sunday.
X0
TRD

D0

Special
D

Item

Content

General
D

Item

D1063

Year
(Western)

00~99

D0

Year
(Western)

D1064

Weeks

1~7

D1

Weeks

D1065

Month

1~12

D2

Month

D1066

Day

1~31

D3

Day

D1067

Hour

0~23

D4

Hour

D1068

Minute

0~59

D5

Minute

D1069

Second

0~59

D6

Second

16-95

API

170 D

GRY

BIN→GRAY code transformation

P

Bit device

Word device

16-bit command (5 STEP)
GRY
Continuous
GRYP
execution type

Pulse
X
Y
M
K
H KnX KnY KnM T
C
D
execution type
S
D
32-bit command (9 STEP)
Notes on operand usage:
Continuous DGRYP
Pulse
Please refer to the function specifications table for each device in DGRY
execution
type
execution
type
series for the scope of device usage

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊



Flag signal: none




S: source device. D: device storing GRAY code.




Transforms the content value (BIN value) of the device designated by S to GRAY
code, which is stored in the device designated by D.




The valid range of S is as shown below; if this range is exceeded, it will be
considered an error, and the command will not execute.
16-bit command: 0~32,767




32-bit command: 0~2,147,483,647


When X0=On, the constant K6513 will be transformed to GRAY code and
stored in D0.

16-96

PLC Function Applications

API

171 D

GBIN

GRAY code →BIN transformation

P

Bit device

Word device

16-bit command (5 STEP)
GBIN
Continuous
GBINP
execution type

Pulse
X
Y
M
K
H KnX KnY KnM T
C
D
execution type
S
D
32-bit command (9 STEP)
Notes on operand usage:
Continuous DGBINP
Pulse
Please refer to the function specifications table for each device in DGBIN
execution
type
execution
type
series for the scope of device usage

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
＊ ＊ ＊ ＊ ＊



Flag signal: none




S: source device used to store GRAY code. D: device used to store BIN value after
transformation.




The GRAY code corresponding to the value of the device designated by S is
transformed into a BIN value, which is stored in the device designated by D.




This command will transform the value of the absolute position encoder connected
with the PLC's input and (this encoder usually has an output value in the form of
GRAY code) into a BIN value, which is stored in the designated register.




The valid range of S is as shown below; if this range is exceeded, it will be
considered an error, and the command will not execute.
16-bit command: 0~32,767




32-bit command: 0~2,147,483,647


When X20=On, the GRAY code of the absolute position encoder connected
with input points X0 to X17 will be transformed into BIN value and stored in
D10.
X20
GBIN

K4X0

D10
K4X0

X17

X0

GRAY CODE 6513 0 0 0 1 0 1 0 1 1 1 0 0 1 0 0 1

b0

b15

H1971=K6513 0 0 0 1 1 0 0 1 0 1 1 1 0 0 0 1

16-97

API
215~
217

LD#

D

S1

Bit device

Contact form logical operation LD#

S2

Word device

16-bit command (5 STEP)
LD#
Continuous
execution type

－

－

32-bit command (9 STEP)
DLD#
Continuous
Please refer to the function specifications table for each device in
execution type
series for the range of device usage

－

－

X

Y

M

K

H

KnX KnY KnM

T

C

D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S1
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S2
Notes on operand usage: ＃：&、|、^

Flag signal: none




S1: data source device 1. S2: data source device 2.




This command performs comparison of the content of S1 and S2; when the result
of comparison is not 0, this command will be activated, but this command will not
be activated when the result of comparison is 0.




The LD#This command can be used while directly connected with the busbar
API No.









16-bit
32-bit
commands commands

Conditions for
activation

215

LD&

DLD&

S1

&

S2

216

LD|

DLD|

S1

|

S2

217

LD^

DLD^

S1

^

S2

≠0
≠0
≠0

Conditions for inactivation

S1

&

S2

S1

|

S2

S1

^

S2

=0
=0
=0

&: logical AND operation.
|: logical OR operation.
^: logical XOR operation.

When the content of C0 and C10 is subjected to the logical AND operation, and
the result is not equal to 0, Y10=On.
When the content of D200 and D300 is subjected to the logical OR operation, and
the result is not equal to 0, and X1=On, Y11=On and remains in that state.
LD &

C0

C10

LD I

D200

D300

Y10
X1

16-98

SET

Y11

PLC Function Applications

API
218~
220

D

AND#

S1

Bit device

Contact form logical operation AND#

S2

Word device

16-bit command (5 STEP)
AND#
Continuous
execution type

－

－

32-bit command (9 STEP)
DAND#
Continuous
Please refer to the function specifications table for each device in
execution type
series for the scope of device usage
Flag signal: none

－

－

X

Y

M

K

H

KnX KnY KnM

T

C

D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S1
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S2
Notes on operand usage:
＃：&、|、^



S1: data source device 1. S2: data source device 2.




This command performs comparison of the content of S1 and S2; when the result
of comparison is not 0, this command will be activated, but this command will not
be activated when the result of comparison is 0.




The AND# command is an operation command in series with the contact.
API No.











16-bit
32-bit
commands commands

Conditions for
activation

218

AND&

DAND&

S1

&

S2

219

AND|

DAND|

AND^

S1
S1

|

DAND^

S2
S2

220

^

≠0
≠0
≠0

Conditions for inactivation

S1

&

S2

S1
S1

|

S2
S2

^

=0
=0
=0

&: logical AND operation.
|: logical OR operation.
^: logical XOR operation.
When X0=On and the content of C0 and C10 is subjected to the logical
AND operation, and the result is not equal to 0, Y10=On.
When X1=Off and D10 and D0 is subjected to the logical OR operation, and the
result is not equal to 0, Y11=On and remains in that state.
When X2 =On and the content of the 32-bit register D200(D201) and 32-bit
register D100(D101) is subjected to the logical XOR operation, and the result is
not equal to 0 or M3=On, M50=On.
X0
AND &

C0

C10

Y10

AND I

D10

D0

SET

DAND ^

D200

D100

M50

X1
X2
M3

16-99

Y11

API
221~
223

OR#

D

S1

Bit device

Contact form logical operation OR#

S2

Word device

16-bit command (5 STEP)
OR#
Continuous
execution type

－

－

32-bit command (9 STEP)
DOR#
Continuous
Please refer to the function specifications table for each device in
execution type
series for the scope of device usage
Flag signal: none

－

－

X

Y

M

K

H

KnX KnY KnM

T

C

D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S1
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S2
Notes on operand usage:
＃：&、|、^



S1: data source device 1. S2: data source device 2.




This command performs comparison of the content of S1 and S2; when the result
of comparison is not 0, this command will be activated, but this command will not
be activated when the result of comparison is 0.




The OR# command is an operation command in series with the contact.
API No.









16-bit
32-bit
commands commands

Conditions for
activation

221

OR&

DOR&

S1

&

S2

222

OR|

DOR|

OR^

S1
S1

|

DOR^

S2
S2

223

^

≠0
≠0
≠0

Conditions for inactivation

S1

&

S2

S1
S1

|

S2
S2

^

=0
=0
=0

&: logical AND operation.
|: logical OR operation.
^: logical XOR operation.
When X1=On or the content of C0 and C10 is subjected to the logical
AND operation, and the result is not equal to 0, Y0=On.
When X2 and M30 are both equal to On, or the content of 32-bit register D10
(D11) and 32-bit register D20 (D21) is subjected to the logical OR operation, and
the result is not equal to 0, or the content of the 32-bit counter C235 and the 32-bit
register D200 (D201) is subjected to the logical XOR operation, and the result is
not equal to 0, M60=On.
X1
Y0
OR &
X2

C0

C10

M30
M60

DOR I

D10

D20

DOR ^

D25

D200

16-100

PLC Function Applications

API
224~
230

LD※
※

D

S1

Bit device

Contact form compare LD*

S2

Word device

16-bit command (5 STEP)
Continuous
LD
execution type

－

－

32-bit command (9 STEP)
Continuous
DLD
Please refer to the function specifications table for each device in
execution type
series for the scope of device usage
Flag signal: none

－

－

X

Y

M

K

H

KnX KnY KnM

T

C

D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S1
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S2
Notes on operand usage:
※：=、>、<、<>、≦、≧

※

※




S1: data source device 1. S2: data source device 2.




This command compares the content of S1 and S2. Taking API 224 (LD=) as an
example, this command will be activated when the result of comparison is
"equal," and will not be activated when the result is "unequal."




The LD* can be used while directly connected with the busbar
API No.
224
225
226
228
229

＝
LD＞
LD＜
LD＜＞
LD＜＝
LD＞＝

＝
DLD＞
DLD＜
DLD＜＞
DLD＜＝
DLD＞＝
DLD

LD

Conditions for
activation

S1
S1
S1

＝S
＞S
＜S

2

S1 ≠ S2

2

S1

2

S1

S1 ≠ S2
S1

Conditions for
inactivation

≦S
≧S

2

S1
S1

≦S
≧S
＝S
＞S
＜S

2
2

2
2

S1
S1
2
2
When the content of C10 is equal to K200, Y10=On.
When the content of D200 is greater than K-30, and X1=On, Y11=On and remains
in that state.
230






16-bit commands 32-bit commands

Y10

LD=

K200

C10

LD>

D200

K-30

SET

C20

M50

X1

DLD>

K678493

M3

16-101

Y11

API
232~
238

D

AND※
※

S1

Bit device

Contact form compare AND*

S2

Word device

16-bit command (5 STEP)
Continuous
AND
execution type

－

－

32-bit command (9 STEP)
Continuous
DAND
Please refer to the function specifications table for each device in
execution type
series for the scope of device usage
Flag signal: none

－

－

X

Y

M

K

H

KnX KnY KnM

T

C

※

D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S1
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S2
Notes on operand usage:
※：=、>、<、<>、≦、≧

※




S1: data source device 1. S2: data source device 2.




This command compares the content of S1 and S2. Taking API 232 (AND=) as an
example, when the result of comparison is equal, this command will be activated;
when the result of comparison is unequal, this command will not be activated.




The AND* command is a comparison command in series with a contact.
API No.
232
233
234
236
237




＝
AND＞
AND＜
AND＜＞
AND＜＝
AND＞＝

＝
DAND＞
DAND＜
DAND＜＞
DAND＜＝
DAND＞＝
DAND

AND

Conditions for
activation

S1
S1
S1

＝S
＞S
＜S

2

S1 ≠ S2

2

S1

2

S1

S1 ≠ S2
S1

Conditions for
inactivation

≦S
≧S

2

S1
S1

≦S
≧S
＝S
＞S
＜S

2
2

2
2

S1
S1
2
2
When X0=On and the current value of C10 is also equal to K200, Y10=On.
When X1=Off and the content of register D0 is not equal to K-10, Y11=On and
remains in that state.
When X2 =On and the content of the 32-bit register D0(D11)is less than 678,493,
or M3=On, M50=On.
238






16-bit commands 32-bit commands

X0
AND=

K200

C10

Y10

AND<>

K-10

D0

SET

X1
X2
DAND>

K678493

M3

16-102

D10

M50

Y11

PLC Function Applications

API
240~
246

OR※
※

D

S1

Bit device

Contact form compare OR*

S2

Word device

16-bit command (5 STEP)
Continuous
OR
execution type

－

－

32-bit command (9 STEP)
Continuous
DOR
Please refer to the function specifications table for each device in
execution type
series for the scope of device usage
Flag signal: none

－

－

X

Y

M

K

H

KnX KnY KnM

T

C

D

＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S1
＊ ＊ ＊ ＊ ＊ ＊ ＊ ＊
S2
Notes on operand usage:
※：=、>、<、<>、≦、≧

※

※




S1: data source device 1. S2: data source device 2.




This command compares the content of S1 and S2. Taking API 240 (OR=) as an
example, when the result of comparison is equal, this command will be activated;
when the result of comparison is unequal, this command will not be activated.




The OR* command is a compare command in parallel with a contact.
API No.




＝
＞
＜
＜＞
＜＝
＞＝

＝
＞
＜
＜＞
＜＝
＞＝

Conditions for
activation

Conditions for
inactivation
S1 ≠ S2

＝
＞
＜
≦
≧

S1
S2
S1
S2
S1
S2
S1
S2
S1
S2
S1
S2
S1 ≠ S2
S1
S2
S1
S2
S1
S2
S1
S2
When X0=On and the current value of C10 is also equal to K200, Y10=On.
When X1=Off and the content of register D0 is not equal to K-10, Y11=On and
remains in that state.
When X2 =On and the content of the 32-bit register D0(D11)is less than 678,493,
or M3=On, M50=On.
240
241
242
244
245
246






16-bit commands 32-bit commands
OR
OR
OR
OR
OR
OR

DOR
DOR
DOR
DOR
DOR
DOR

≦
≧
＝
＞
＜

X1
Y0
OR>=
X2

K200

C10

M30
M60
DOR>=

D100

K100000

16-103

API

FLD※
※

275~
280

S1

Bit device
X

Y

M

Floating point number contact form compare LD*

S2

Word device
K

H

KnX KnY KnM

16-bit command
T

C

D

＊ ＊ ＊
＊ ＊ ＊

－

－

S1
32-bit command (9 STEP)
S2
Continuous
FLD
Notes on operand usage:
& | ^
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＃： 、 、

※

－

－

－

－



S1: data source device 1. S2: data source device 2.



This command compares the content of S1 and S2. Taking "FLD=" as an example,
if the result of comparison is "equal," this command will be activated; but it will not
be activated when the result is "unequal."



The FLD* command can directly input floating point numerical values (for
instance: F1.2) to the S1, S2 operands, or store floating-point numbers in register
D for use in operations.



This command can be used while directly connected with the busbar
API No.
275
276
277
278
279




280

32-bit commands

＝
FLD＞
FLD＜
FLD＜＞
FLD＜＝
FLD＞＝

Conditions for
activation

S1

FLD

S1
S1

＝S
＞S
＜S

Conditions for
inactivation

S1 ≠ S2

2
2

S1

2

S1

S1 ≠ S2
S1
S1

S1

≦S
≧S

2

S1

2

S1

≦S
≧S
＝S
＞S
＜S

2
2

2
2
2

When the floating point number of register D200 (D201) is less than or equal
to F1.2, and X1 activated, contact Y21 will be activated and remain in that state.
X1
FLD<=

D200

F1.2

16-104

SET

Y21

PLC Function Applications

API

FAND※
※

281~
286

S1

Bit device
X

Y

M

Floating point number contact form compare AND*

S2

Word device
K

H

KnX KnY KnM

16-bit command
T

C

－

D

＊ ＊ ＊
＊ ＊ ＊

－

S1
32-bit command (9 STEP)
S2
Continuous
FAND
Notes on operand usage:
& | ^
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＃： 、 、

※

－

－

－

－



S1: data source device 1. S2: data source device 2.



This command compares the content of S1 and S2. Taking "FAND=" as an
example, if the result of comparison is "equal," this command will be activated;
but it will not be activated when the result is "unequal."



The FAND* command can directly input floating point numerical values (for
instance: F1.2) to the S1, S2 operands, or store floating-point numbers in register
D for use in operations.



This command can be used while directly connected with the busbar
API No.
281
282
283
284
285




286

32-bit commands

Conditions for
activation

FAND

S1

FAND

S1

＞
FAND＜
FAND＜＞
FAND＜＝
FAND＞＝

S1

＝S
＞S
＜S

S1

S1 ≠ S2

2
2

S1

2

S1

S1 ≠ S2
S1

Conditions for
inactivation

≦S
≧S

S1

2

S1

2

S1

≦S
≧S
＝S
＞S
＜S

2
2

2
2
2

When X1=Off, and the floating point number in register D100 (D101) is not equal
to F1.2, Y21=On and remains in that state.
X1
FAND<>

F1.2

16-105

D0

SET

Y21

API

FOR※
※

287~
292

S1

Bit device
X

Y

M

Floating point number contact form compare OR*

S2

Word device
K

H

KnX KnY KnM

16-bit command
T

C

－

D

＊ ＊ ＊
＊ ＊ ＊

－

S1
32-bit command (9 STEP)
S2
Continuous
FOR
Notes on operand usage:
& | ^
execution type
Please refer to the function specifications table for each device in
series for the scope of device usage
Flag signal: none

＃： 、 、

※

－

－

－

－



S1: data source device 1. S2: data source device 2.



This command compares the content of S1 and S2. Taking "FOR=" as an
example, if the result of comparison is "equal," this command will be activated;
but it will not be activated when the result is "unequal."



The FOR* command can directly input floating point numerical values (for
instance: F1.2) to the S1, S2 operands, or store floating-point numbers in register
D for use in operations.



This command can be used while directly connected with the busbar
API No.

＝
FOR＞
FOR＜
FOR＜＞
FOR＜＝
FOR＞＝

288
289
290
291



S1

FOR

287



Conditions for
activation

32-bit commands

292

S1
S1

＝S
＞S
＜S

2

S1

S1 ≠ S2

2

S1

2

S1

S1 ≠ S2
S1

Conditions for
inactivation

≦S
≧S

S1

2

S1

2

S1

≦S
≧S
＝S
＞S
＜S

2
2

2
2
2

When X2 and M30 are both equal to "On," or the floating point number in register
D100 (D101) is greater than or equal to F1.234, M60=On.
X2

M30
M60

FOR>=

D100

F1.234

16-106

PLC Function Applications

16-6-5 Detailed explanation of driver special applications commands
API

RPR

139

S1

P

Bit device
X

Y

Read servo parameter

S2

Word device

M

K

H

＊ ＊

KnX KnY KnM

T

C

S1
S2
Notes on operand usage: none

D

＊
＊

16-bit command (5 STEP)
RPR
Continuous
RPRP
execution type
32-bit command

－

－

－

Flag signal: none

S1 : Parameter address of data to be read.




Pulse
execution type

－

S2 : Register where data to be

read is stored.
API

WPR

140

S1

P

Bit device
X

Y

Write servo parameter

S2

Word device
M

K

H

＊ ＊
＊ ＊

KnX KnY KnM

T

S1
S2
Notes on operand usage: none

C

D

＊
＊

16-bit command (5 STEP)
WPR
Continuous
WPRP
Pulse
execution type
execution type
32-bit command

－

－

Flag signal: none












S1 : Data to write to specified page.

－

－

S2 : Parameter address of data to be

written.
When the data in the C2000 driver's parameter H01.00 is read and written to
D0, data from H01.01 will be read and written to D1.
When M0=On, the content of D10 will be written to the C2000 driver parameter
04.00 (first speed of multiple speed levels).
When the parameter has been written successfully, M1017=On.
The C2000's WPR command does not support writing to the 20XX address,
but the RPR command supports reading of 21XX, 22XX.

Recommendation Take care when using the WPR command. When writing parameters, because
most parameters are recorded as they are written, these parameters may only be
revised 109 times; a memory write error may occur if parameters are written more
than 109 times.
Because the following commonly-used parameters have special processing, there are
no restrictions on the number of times they may be written.
P00-10: Control method
P00-11: Speed mode selection
P00-12: P2P position mode
P00-13: Torque mode select
P00-27: User-defined value

16-107

P01-12: Acceleration time 1
P01-13: Deceleration time 1
P01-14: Acceleration time 2
P01-15: Deceleration time 2
P01-16: Acceleration time 3
P01-17: Deceleration time 3
P01-18: Acceleration time 4
P01-19: Deceleration time 4
P02-12: Select MI Conversion Time mode:
P02-18: Select MO Conversion Time mode:
P04-50 ~ P04-69: PLC register parameter 0 - 19
P08-04: Upper limit of integral
P08-05: PID output upper limit
P10-17: Electronic gear A
P10-18: Electronic gear B
P11-34: Torque command
P11-43: P2P highest frequency
P11-44: Position control acceleration time
P11-45: Position control deceleration time

Calculation of the number of times written is based on whether the written value is
modified. For instance, writing the same value 100 times at the same time counts as
writing only once.
When writing a PLC program, if unsure of usage of the WPR command, we
recommend that you use the WPRP command.

16-108

PLC Function Applications

API

141

FPID

S1

P

Bit device

S2

S3

＊
＊
＊
＊
















Driver PID control mode

Word device

X
Y
M
K
H KnX KnY KnM
S1
S2
S3
S4
Notes on operand usage: none




S4

＊
＊
＊
＊

T

C

D

＊
＊
＊
＊

16-bit command (9 STEP)
FPID
Continuous
FPIDP
execution type
32-bit command

－

－

Pulse
execution type

－

－

Flag signal: none

S1 : PID reference target value input terminal select.
proportional gain P. S3 : PID function integral time I.

S2 : PID function
S4 : PID function

differential time D.
The FPID command can directly control the driver's feedback control of
PID parameter 08-00 PID reference target value input terminal selection, 08-01
proposal gain P, 08-02 integral time I, and 08-03 differential time D.
When M0=On, the set PID reference target value input terminal selection is 0 (no
PID function), the PID function proportional gain P is 0, the PID function integral
time I is 1 (units: 0.01 sec.), and the PID function differential time D is 1 (units:
0.01 sec.).
When M1=On, the set PID reference target value input terminal selection is 0 (no
PID function), the PID function proportional gain P is 1 (units: 0.01), the
PID function integral time I is 0, and the PID function differential time D is 0.
When M2=On, the set PID reference target value input terminal selection is 1
(target frequency input is controlled from the digital keypad), the PID function
proportional gain P is 1 (units: 0.01), the PID function integral time I is 0, and the
PID function differential time D is 0.
D1027: Frequency command after PID operation.
M0
FPID

H0

H0

H1

H1

FPID

H0

H1

H0

H0

FPID

H1

H1

H0

H0

MOV

D1027

D1

M1
M2
M1000

END

16-109

API

142

FREQ

P

S1

Bit device

S2

Driver speed control mode

S3

Word device

X
Y
M
K
H KnX KnY KnM
S1
S2
S3
Notes on operand usage: none

＊ ＊
＊ ＊
＊ ＊

T

C

D

＊
＊
＊

16-bit command (7 STEP)
FREQ
Continuous FREQP
Pulse
execution type
execution type
32-bit command

－

－

－

－

Flag signal: M1015

S1 : Frequency command. S2 : Acceleration time. S3 : Deceleration time
S2,S3: In acceleration/deceleration time settings, the number of decimal places is
determined by the definitions of Pr01-45.
Example
When 01-45=0: units of 0.01 sec.
The setting of 50 for S2 (acceleration time) in the ladder diagram below implies 0.5 sec,
and the S3 (deceleration time) setting of 60 implies 0.6 sec

 The FREQ command can control driver frequency commands, and acceleration and
deceleration time; it also uses special register control actions, such as:
M1025: Control driver RUN(On)/STOP(Off) (RUN requires Servo On (M1040 On) to be
effective)
M1026: Control driver operating direction FWD(Off)/REV(On)
M1040: Control Servo On/Servo Off.
M1042: Trigger quick stop (ON)/does not trigger quick stop (Off).
M1044: Pause (On)/release pause (Off)
M1052: Lock frequency (On)/release lock frequency (Off)














M1025:
Driver
RUN(On)/STOP(Off),
M1026:
driver
operating
direction FWD(Off)/REV(On). M1015: frequency reached.
When M10=On, sets the driver frequency command K300(3.00Hz), with an
acceleration/deceleration time of 0.
When M11=On, sets the driver frequency command K3000 (30.00Hz), with an
acceleration time of 50 (0.5 sec.) and deceleration time of 60 (0.6 sec.). (When 01-45=0)
When M11=Off, the driver frequency command will now change to 0
M1000
M1025
M11
M1026
M1000
M1040
M12
M1042
M13
M1044
M14
M1052
M10 M11
FREQP K300
K0
K0
M11
M10
K50
K60
FREQ K3000

END




Parameter 09-33 are defined on the basis of whether reference commands have
been cleared before PLC operation
Bit 0 : Prior to PLC scanning procedures, whether the target frequency has been
cleared is 0. (This will be written to the FREQ command when the PLC is
On)

16-110

PLC Function Applications

Bit 1 : Prior to PLC scanning procedures, whether the target torque has been
cleared is 0. (This will be written to the TORQ command when the PLC is
On)
Bit 2 : Prior to PLC scanning procedures, whether speed limits in the torque mode
have been cleared is 0. (This will be written to the TORQ command when
the PLC is On)
Example: When using r to write a program,
M0
FREQ

K2000

K1000

K1000
END

if we force M0 to be 1, the frequency command will be 20.00 Hz; but when M0 is set
as 0, there will be a different situation.
Case 1: When the 09-33 bit 0 is 0, and M0 is set as 0, the frequency command will
remain at 20.00Hz.
Case 2: When the 09-33 bit 0 is 1, and M0 is set as 0, the frequency command will
change to 0.00Hz
The reason for this is that when the 09-33 bit 0 is 1 prior to PLC scanning
procedures, the frequency will first revert to 0.
When the 09-33 bit 0 is 0, the frequency will not revert to 0.

16-111

API

263

TORQ

S1

P

Bit device

Driver torque control mode

S2

Word device

X
Y
M
K
H KnX KnY KnM
S1
S2
Notes on operand usage: none

＊ ＊
＊ ＊

T

C

D

＊
＊

16-bit command (5 STEP)
TORQ
Continuous TORQ P
Pulse
execution type
execution type
32-bit command

－

－

Flag signal: M1063




















－

－

S1 : Torque command (numbered, no more than one digit). S2 : Speed limit.
The TORQ command can control the driver torque command and speed limits; it also
uses special register control actions, such as:
M1040: Controls Servo On/Servo Off. When Servo is ON, if a TORQ command is
executed, the torque will output the torque defined by the TORQ command, and the
frequency restrictions will similarly be controlled by the TORQ command.
M1040: Control Servo On/Servo Off. M1063: set torque attained. D1060 is the mode
controls. D1053 is the actual torque.
When M0=Off, set the driver torque command K+500 (+50.0%), rotational speed
restrictions is 3000 (30Hz).
When M0=On, sets the driver torque command K-300 (-30.0%), rotational speed
restrictions is 3000 (30Hz).
When M10=On, driver began output torque command.
When set torque is attained, M1063 will go On; this flag usually jumps continuously,
however.

Parameter 09-33 are defined on the basis of whether reference commands have been
cleared before PLC operation
Bit 0 : Prior to PLC scanning procedures, whether the target frequency has been cleared
is 0. (This will be written to the FREQ command when the PLC is On)
Bit 1 : Prior to PLC scanning procedures, whether the target torque has been cleared is 0.
(This will be written to the TORQ command when the PLC is On)
Bit 2 : Prior to PLC scanning procedures, whether speed limits in the torque mode have
been cleared is 0. (This will be written to the TORQ command when the PLC is On)
Example:

M1
TORQ

K300

K400
END

If we now force M1 to be 1, the torque command will be K+300 (+30%), and the speed limit
will be 400 (40Hz). But when M1 is set as 0, there will be a different situation

16-112

PLC Function Applications

Case 1: When bit 1 and bit 2 of 09-33 are both set as 0, and M1 is set as 0, the torque
command will remain at +30%, and the speed limit will be set as 40Hz.
Case 2: When bit 1 and bit 2 of 09-33 are both 1, and M1 is set as 0, the torque command will
revert 0%, and the speed limit will be set as 0Hz.

16-113

API

DPOS

262

Bit device
X

Y

M

Driver point-to-point control

S1

P

Word device
K

H

＊ ＊

KnX KnY KnM

16-bit command
T

C

D

＊

Notes on operand usage: none

－

－

－

－

32-bit command (5 STEP)
DPOS
Continuous DPOSP
Pulse
execution type
execution type
Flag signal: M1064, M1070













S1 : Target (must have a number).

The DPOS command can control the driver's position commands, and employs
special register control actions, such as:
M1040: Control Servo On/Servo Off. M1055 search for origin. M1048 move to
new position. If the control mode is position mode (D1060 = 1), and the converter
is in the Servo ON state (M1040 = 1), if the DPOS command is executed, the
driver will move to a new position in conjunction with activation of M1048 once
(OFF to ON).
M1040: Control Servo On/Servo Off. M1064: set position attained. D1060 is the
mode control. D1051(L) and D1052(H) are the actual position points.
When X0=On, M1040 will be On (Servo On).
When X1=On, sets DPOS position as +300000, and M1048 will change to On
(move to new position) after a delay of 1 sec. Check whether the value of D1051
has changed at this time; after the set position point has been reached, M1064
will go On, and Y0 will output On.

16-114

PLC Function Applications

API

261

CANRX

P

S1

Bit device

S2

S3

Word device

X
Y
M
K
H KnX KnY KnM
S1
S2
S3
D
Notes on operand usage: none

＊ ＊
＊ ＊
＊ ＊






Read CANopen slave station data

D

T

C

D

＊ ＊ ＊

16-bit command (9 STEP)
CANRX
Continuous CANRXP
Pulse
execution type
execution type
32-bit command

－

－

－

－

Flag signal

S1 : Slave station number.
D : Preset address.

S2 : Main index..

S3 : Subindex+bit length.

The CANRX command can read the index of the corresponding slave station.
When it is executed, it will send the SDO message format to the slave station.
M1066 and M1067 will both be 0 at that time, and M1066 will be set as 1 after
reading. If the slave station gives the correct response, it will write the value to the
preset register, and set M1067 as 1. If the slave station has a response error,
M1067 will be set as 0, and an error message will be recorded to D1076 to
D1079.
M1002: When the PLC runs, the command will be triggered once and will set
K4M400 = K1
Afterwards, each time M1066 is 1, it will switch to a different message.

16-115

API

264

CANTX

P

S1

Bit device

＊
＊
＊
＊




S3

S4

Write CANopen slave station data

Word device

X
Y
M
K
H
S1
S2
S3
S4
Notes on operand usage: none




S2

＊
＊
＊
＊

KnX KnY KnM

T

C

D

＊ ＊ ＊

16-bit command (9 STEP)
CANTX Continuous CANTXP
Pulse
execution type
execution type
32-bit command

－

－

－

－

Flag signal

S1 : Slave station number.
S4 : Subindex+bit length.

S2 : Address to be written.

S3 : Main index.

The CANTX command can write a value to the index of the corresponding slave
station. When it is executed, it will send the SDO message format to the slave
station. M1066 and M1067 will both be 0 at that time, and M1066 will be set as 1
after reading. If the slave station gives the correct response, it will write the value
to the preset register, and set M1067 as 1. If the slave station has a response
error, M1067 will be set as 0, and an error message will be recorded to D1076 to
D1079.

16-116

PLC Function Applications

API

CANFLS

265

Refresh special D corresponding to CANopen

D

P

Bit device

Word device

X
Y
M
K
H
D
Notes on operand usage: none

＊ ＊

KnX KnY KnM

T

C

D

16-bit command (3 STEP)
CANFLS Continuous CANFLSP
Pulse
execution type
execution type
32-bit command

－

－

－

－

Flag signal









API

320 D

D : Special D to be refreshed.

The CANFLS command can refresh special D commands. When is a read only
attribute, executing this command will send a message equivalent to that of
CANRX to the slave station, and the number of the slave station will be
transmitted back and refreshed to this special D. When there is a read/write
attribute, executing this command will send a message equivalent to that of
CANTX to the slave station, and the value of this special D will be written to the
corresponding slave station.
When M1066 and M1067 are both 0, and M1066 is set as 1 after reading, if the
slave station gives a correct response, the value will be written to the designated
register, and M1067 will be set as 1. If the slave station's response contains an
error, then M1067 will be set as 0, and an error message will be recorded to
D1076-D1079.

ICOMR

D

P

Word device

Bit device
X

Y

M

Internal communications read

K

＊
＊
＊
＊

H

＊
＊
＊
＊

KnX KnY KnM

T

C

S1
S2
S3
D
Notes on operand usage: none

D

＊
＊
＊
＊

16-bit command (9 STEP)
ICOMR
Continuous ICOMRP
Pulse
execution type
execution type
32-bit command (17 STEP)
DICOMR Continuous DICOMRP
execution type
Flag signal: M1077

Pulse
execution
type

M1078 M1079

S1 : Selection of slave device. S2 : Device selection (0: converter, 1: internal
PLC). S3 : Read address. D : Saving target.




The ICOMR command can obtain the slave station's converter and the internal
PLC's register value.

16-117

API

321 D

ICOMW

D

P

Bit device

Internal communications write

Word device

X
Y
M
K
H
S1
S2
S3
D
Notes on operand usage: none

＊
＊
＊
＊

＊
＊
＊
＊

KnX KnY KnM

T

C

D

＊
＊
＊
＊

16-bit command (9 STEP)
ICOMW Continuous ICOMWP
Pulse
execution type
execution type
32-bit command (17 STEP)
DICOMW Continuous DICOMWP
execution
type
Flag signal: M1077

Pulse
execution
type

M1078 M1079

S1 : Selection of slave device. S2 : Device selection (0: converter, 1: internal
PLC). S3 : Read address. D : Saving target.




The ICOMW command write a value to the slave station's converter and the
internal PLC's register.

Please refer to the following example:

16-118

PLC Function Applications

16-7 Error display and handling
Code
PLrA

ID
47

PLrt

49

PLod

50

PLSv

51

PLdA

52

PLFn

53

PLor

54

PLFF

55

PLSn

56

PLEd

57

PLCr

58

PLdF

59

PLSF

60

Descript
RTC time check

Recommended handling approach
Turn power on and off when resetting the
keypad time
(incorrect RTC mode)
Turn power on and off after making sure
that the keypad is securely connected
Data writing memory error
Check whether the program has an error
and download the program again
Data write memory error during
Restart power and download the program
program execution
again
Program transmission error
Try uploading again; if the error persists,
sent to the manufacturer for service
Command error while downloading Check whether the program has an error
program
and download the program again
Program exceeds memory capacity Restart power and download the program
again
or no program
Check whether the program has an error
Command error during program
and download the program again
execution
Check code error
Check whether the program has an error
and download the program again
Program has no END stop
Check whether the program has an error
command
and download the program again
MC command has been used
Check whether the program has an error
continuously more than nine times and download the program again
Download program error
Check whether the program has an error
and download again
PLC scan time excessively long
Check whether the program code has a
writing error and download again

16-119

16- 8 CANopen Master control applications
Control of a simple multi-axis application is required in certain situations. If the device supports the
CANopen protocol, a C2000 can serve as the master in implementing simple control (position, speed,
homing, and torque control). The setting method comprises the following seven steps:

Step 1: Activating CANopen Master functions
1.

Parameter 09-45=1 (initiates Master functions); restart power after completing setting, the status bar
on the KPC-CC01 digital keypad will display "CAN Master".

2.

Parameter 00-02=6 reset PLC (please note that this action will reset the program and PLC registers
to the default values)

3.

Turn power off and on again.

4.

Use the KPC-CC01 digital keypad to set the PLC control mode as "PLC Stop" (if the KPC-CE01
digital keypad is used, set as "PLC 2"; if a newly-introduced driver is used, the blank internal PLC
program will cause a PLFF warning code to be issued).

Step 2: Master memory settings
1.

After connecting the 485 communications cable, use WPL Soft to set the PLC status as Stop (if the
PLC mode has been switched to the "PLC Stop" mode, the PLC status should already be Stop)

2.

Set the address and corresponding station number of the slave station to be controlled. For instance,
if it is wished to control two slave stations (a maximum of 8 stations can be controlled simultaneously),
and the station numbers are 21 and 22, it is only necessary to set D2000 and D2100 as 20 and 21,
and then set D2200, D2300, D2400, D2500, D2600, and D2700 as 0. The setting method involves
use of the PLC's WPL editing software WPL as follows:




Open WPL and implement communications > register edit (T C D) function

16-120

PLC Function Applications




After leaving the PLC register window, the register setting screen will appear, as shown below:

If there is a new PLC program and no settings have yet been made, you can read default data from the
converter, and merely edit it to suit the current application. If settings have already been made, however,
the special D in the CANopen area will display the saved status (the CANopen D area is located at D1090
to D1099 and D2000 to D2799). Assuming it is a new program, we will first read the default data from the
converter; check the communications format if there is no communications link (the default PLC station
number is 2, 9600, 7N2, ASCII). Perform the following steps: 1. Switch the PLC to Stop status; 2. Press
the transmit button; 3. click on read memory after exiting the window; 4. Ignore D0-D399; and 5. click on
the confirm button.)

16-121

After reading the data, it is necessary to perform some special D settings. Before proceeding, we will first
introduce the special D implications and setting range. The CANopen Master's special D range is currently
D1070 to D1099 and D2000 to D2799; this range is divided into 3 blocks:
The first block is used to display CANopen's current status, and has a range of D1070 to D1089;
the second block is used for CANopen's basic settings, and has a range of D1090 to D1099;
the third block is the slave station mapping and control area, and has a range of D2000 to D2799;
These areas are therefore introduced as follows:
The first contains the current CANopen status display:
When the master initializes a slave station, we can from find out from D1070 whether configuration of the
slave device has been completed; we can find out whether an error occurred in the configuration process
from D1071 and whether the configuration is inappropriate from D1074.
After entering normal control, we can find out whether the slave device is offline from D1073. In addition,
we can check the slave device's read/write information using the CANRX, CANTX, and CANFLS
commands; error information can be obtained from D1076 to D1079 if there has been a read/write failure.
Special D
D1070
D1071
D1072
D1073

Description of Function
Channel opened by CANopen initialization (bit0=Machine
code0 …….)
Error channel occurring in CANopen initialization process
(bit0=Machine code0 …….)
Reserved
CANopen break channel (bit0=Machine code0 …….)

16-122

R/W
R
R
R

PLC Function Applications

Special D
D1074
D1075
D1076
D1077
D1078
D1079

Description of Function
Error code of master error
0: No error
1: Slave station setting error
2: Synchronizing cycle setting error (too small)
Reserved
SDO error message (main index value)
SDO error message (secondary index value)
SDO error message (error code L)
SDO error message (error code H)

The second area is for basic CANopen settings: (the PLC must have

R/W
R
R
R
R
R

stopped when this area is used

to make settings)
We must set the information exchange time for the master and slave station,
Special D
D1090

Description of Function
Synchronizing cycle setting

Default:
4

R/W
RW

Use D1090 to perform settings; setting time relationships include:

For instance, when communications speed is 500K, TXPDO + RXPDO have 8 sets, and synchronizing
time will require more than 4 ms
We must also define how many slave stations will be open. D1091 is the channel for defining station
opening, and D2000+100*n is the station number defining this channel. See the detailed explanation
below.
Slave station number n=0-7
Special D

Description of Function

Sets slave station On or Off (bit 0-bit 7 correspond to
slave stations number 0-7)
D2000+100*n Slave station number
D1091

16-123

R/W
RW
RW

If slave devices have a slow start-up, the master can delay for a short time before performing slave station
configuration; this time delay can be set via D1092.
Special D
D1092

Description of Function
Delay before start of initialization

Default:

R/W

0

RW

With regard to slave device initialization, a delay time can be set to judge whether failure has occurred. If
the communications speed is relatively slow, the delay time can be adjusted to judge whether initialization
has been completed, which will ensure that there is time to perform slave device initialization.
Special D
D1099

Description of Function
Initialization completion delay time
Setting range: 1 to 60000 sec

Default:
15 sec.

R/W
RW

After communication is successful, the system must detect whether there is a break in communications
with the slave station. D1093 is used to set detection time, and D1094 sets the number of consecutive
errors that will trigger a break error.
Special D
D1093
D1094

Description of Function
Break time detection
Break number detection

Default:

R/W

1000ms
3

RW
RW

The packet type transmitted by PDO is set before establishing normal communications and generally does
not require adjustment.
Special D

Description of Function

16-124

Default:

R/W

PLC Function Applications

Special D
D1097
D1098

Description of Function

Default:

Corresponding real-time transmission type
(PDO)
Setting range: 1~240
Corresponding real-time receiving type (PDO)
Setting range: 1~240

R/W
RW

1
1

RW

The third block is the slave station mapping and control area.
CANopen provides a PDO method to perform mapping of the master and slave station memory, and
enables the master to directly access read/write data in a certain memory area. The master will
automatically perform data exchange with the corresponding slave device, and the read/write values can
be seen directly from the special D area after real-time exchange (M1034 = 1 time) has been established.
The C2000 currently supports real-time mapping of four PDOs, and there are two types of PDO RXPDO
(reads slave device information) and TXPDO (writes to slave device). In addition, in order to facilitate
control, the C2000 cannot perform mapping of commonly-used registers; the following is an overview of
the current PDO mapping situation:

TX PDO
PDO4 (Torque)
Descriptio
Special D
n
Controller
D2008+1
Word
00*n
Target
D2017+1
torque
00*n
Control
method

D2010+1
00*n

PDO3 (Position)
Descriptio
Special D
n
Controller
D2008+1
Word
00*n
Target
D2020+1
00*n
D2021+1
00*n
Control
D2010+1
method
00*n

PDO2 (Remote I/O)
Description
Special D
Slave
device DO
Slave
device AO1

D2027+1
00*n
D2031+1
00*n

Slave
device AO2
Slave device
AO3

D2032+1
00*n
D2033+100
*n

PDO1 (Speed)
Descriptio
Special D
n
Controller
D2008+1
Word
00*n
Target
D2012+1
speed
00*n

RXPDO
PDO4 (Torque)
PDO3 (Position)
Description Special D
Description
Special D
D2009+100*
D2009+100*
Mode word
Mode word
n
n
D2022+100*
Actual
D2018+100* Actual
n
torque
n
position
D2023+100*
n
Actual
D2011+100*
D2011+100*
Actual mode
mode
n
n

PDO2 (Remote I/O)
PDO1 (Speed)
Description
Special D
Description
Special D
D2026+100*
D2009+100*
Slave device DI
Mode word
n
n
Slave device
AI1

D2028+100*
n

Slave device
AI2
Slave device
AI3

D2029+100*
n
D2030+100*
n

Actual
frequency

D2013+100*
n

Because usage requires only simple to open the corresponding PDO, where TXPDO employs
D2034+100*n settings and RXPDO employs D2067+100*n settings.
These two special D areas are defined as follows:
Default
definition
bit
Definition

PDO4
Torque
15
En

14 ~ 12
Length:

PDO3
Position
11
En

10 ~ 8
Length:

PDO2
Remote I/O
7
En

6~4
Length:

PDO1
Speed
3
En

2~0
Length:

En: indicates whether PDO is used
Length:

indicates mapping of several variables

In a simple example, if we wish to control a C2000 slave device and cause it to operate in speed mode, we
only have to make the following settings:

16-125

D2034+100*n =000Ah
Lengt
h:
1
2

3

TX PDO
PDO4
Descriptio
Special D
n
Controller
D2008+100*
Word
n
Target
D2017+100*
torque
n
Control
method

PDO3
Descriptio
Special D
n
Controller
D2008+100*
Word
n
Target
D2020+100*
n
D2021+100*
n
Control
D2010+100*
method
n

D2010+100*
n

4

Definition
bit
Definition

15
0

PDO4
Torque
14 ~ 12
0

11
0

PDO2
Descriptio
Special D
n
Slave
D2027+10
device DO 0*n
Slave
D2031+10
device
0*n
AO1
Slave
device
AO2
Slave device
AO3

PDO3
Position
10 ~ 8
0

Descriptio
n
Controller
Word
Target
speed

PDO1
Special D
D2008+100*
n
D2012+100*
n

D2032+10
0*n
D2033+100*
n

PDO2
Remote I/O
7
6~4
0
0

3
1

PDO1
Speed
2~0
2

D2067+100*n =000Ah
Lengt
h:
1
2

3

TX PDO
PDO4
Description
Special D
Controller
D2009+100
Word
*n
Actual torque D2018+100
*n
Actual mode

PDO3
Description
Special D
Controller
D2009+100
Word
*n
Actual
D2022+100
position
*n
D2023+100
*n
Actual mode
D2011+100
*n

D2011+100
*n

4

Definition
bit
Definition

15
0

PDO4
Torque
14 ~ 12
0

11
0

PDO2
Description
Special D
Slave device
D2026+100
DI
*n
Slave device
D2028+100
AI1
*n
Slave device
AI2
Slave device
AI3

PDO3
Position
10 ~ 8
0

PDO1
Description
Special D
Controller
D2009+100
Word
*n
Actual
D2013+100
frequency
*n

D2029+100
*n
D2030+100*n

PDO2
Remote I/O
7
6~4
0
0

3
1

PDO1
Speed
2~0
2

Switch the PLC to Run after completing settings. Now wait for successful initialization of CANopen (M1059 =
1 and M1061 = 0), and then initiate CANopen memory mapping (M1034 = 1). The control word and
frequency command will now automatically refresh to the corresponding slave device (D2008+n*100 and
D2012+n*100), and the slave device's status word and currently frequency will also be automatically sent
back to the master station (D2009+n*100 and D2013+n*100). This also illustrates how the master can
handle these tasks through read/write operations in the special D area.
Furthermore, it should be noted that the remote I/O of PDO2 can obtain the slave device's current DI and AI
status, and can also control the slave device's DO and AO status. Nevertheless, after introducing a fully
automatic mapping special D, the C2000 CANopen master also provides additional information
refreshes. For instance, while in speed mode, acceleration/deceleration settings may have been refreshed.
The special D therefore also stores some seldom-used real-time information, and these commands can be
refreshed using the CANFLS command. The following is the C2000's current CANopen master data
conversion area, which has a range of D2001+100*n - D2033+100*n, as shown below:

1. The range of n is 0-7
2. ●Indicates PDOTX, ▲Indicates PDORX; unmarked special D can be refreshed using the
CANFLS command
Special D

Description of Function

16-126

Default
:

1

PDO Default:
2
3
4

R/W

PLC Function Applications

D2000+100*n
D2002+100*n
D2003+100*n
D2004+100*n
D2005+100*n

Station number n of slave station
Setting range: 0~127
0: No CANopen function
Manufacturer code of slave station
number n (L)
Manufacturer code of slave station
number n (H)
Manufacturer's product code of slave
station number n (L)
Manufacturer's product code of slave
station number n (H)

0

RW

0

R

0

R

0

R

0

R

Basic definitions
Special D
D2006+100*n
D2007+100*n
D2008+100*n
D2009+100*n
D2010+100*n
D2011+100*n

Description of Function
Communications break handling
method of slave station number n
Error code of slave station number
n error
Control word of slave station
number n
Status word of slave station
number n
Control mode of slave station
number n
Actual mode of slave station
number n

Default:

1

PDO Default:
2
3

4

R/W

0

RW

0

R

0

●

●

●

RW

0

▲

▲

▲

R

2

RW

2

R

Velocity Control
Special D

Description of Function

D2001+100*n Torque restriction on slave station
number n
Target speed of slave station
D2012+100*n
number n (rpm)
Actual speed of slave station
D2013+100*n
number n (rpm)
Error speed of slave station
D2014+100*n
number n (rpm)
Acceleration time of slave station
D2015+100*n
number n (ms)
Deceleration time of slave station
D2016+100*n
number n (ms)

Default
:

PDO Default:
2
3

1

4

0

R/W
RW

0

●

RW

0

▲

R

0

R

1000

RW

1000

RW

Torque control
Special D

Description of Function

Target torque of slave station
number n(-100.0%~+100.0%)
Actual torque of slave station
D2018+100*n
number n(XX.X%)
Actual current of slave station
D2019+100*n
number n(XX.XA)
D2017+100*n

PDO Default:
2
3
4

R/W

0

●

RW

0

▲

R

Default:

1

0

R

Position control
Special D

Description of Function

D2020+100*n Target of slave station number n (L)
Target of slave station number n
D2021+100*n
(H)
Actual position of slave station
D2022+100*n
number n (L)
Actual position of slave station
D2023+100*n
number n (H)

16-127

Default:

1

PDO Default:
2
3
4

0
0

R/W
RW

●

0

RW
R

▲
0

R

Speed chart
number n (L)
Speed chart
D2025+100*n
number n (H)
D2024+100*n

of

slave

station

of

slave

station

RW

10000

RW

0

Remote I/O
Special D

Description of Function

D2026+100*n MI status of slave station number n
MO setting of slave station number
D2027+100*n
n
AI1 status of slave station number
D2028+100*n
n
AI2 status of slave station number
D2029+100*n
n
AI3 status of slave station number
D2030+100*n
n
AO1 setting of slave station
D2031+100*n
number n
AO2 setting of slave station
D2032+100*n
number n
AO3 setting of slave station
D2033+100*n
number n

Default:
0

1

PDO Default:
2
3
4
▲

R/W
R
RW

0

●

0

▲

R

0

▲

R

0

▲

R

0

●

RW

0

●

RW

0

●

RW

After gaining an understanding of special D definitions, we return to setting steps. After entering the values
corresponding to D1090 to D1099, D2000+100*n, D2034+100*n and D2067+100*n, we cannot begin to
perform downloading, which is performed in accordance with the following steps: (1. D2000 and D2100 are
set as 20 and 21, and D2200, D2300, D2400, D2500, D2600, and D2700 are set as 0; if a setting of 0 causes
problems, D1091 can be set as 3, and slave stations 2 to 7 can be closed. 2. Switch PLC to Stop status. 3.
Press the transmit button. 4. click on write memory after exiting the window. 5. Ignore D0-D399. 6. Change
the second range to D1090-D1099. 7. Click on Confirm.)

16-128

PLC Function Applications




Another method can be used to set D1091: Determine which of slave stations 0 to 7 will not be needed,
and set the corresponding bits to 0. For instance, if it is not necessary to control slave stations 2, 6 and 7,
merely set D1091 = 003B, and the setting method is the same as described above: Use WPL to initiate

communications > use register edit (T C D) function to perform settings.

Step 3: Set the master's communications station number and communications
speed


When setting the master's station number (parameter 09-46, default is set as 100), make sure
not to use the same number as a slave station.



Set the CANopen communications speed (parameter 09-37); regardless of whether the driver is
defined as a master or slave station, the communications speed is set via this parameter.

Step 4: Write program code
Real-time access: Can directly read/write to or from the corresponding D area.
Non real-time access:

16-129

Read command:

Use the CANRX command for reading. M1066 will be 1 when reading is

complete; M1067 will be 1 if reading is successful, and M1067 will be 0 if an error has
occurred.

Write command:

Use the CANTX command for writing. M1066 will be 1 when writing is

complete; M1067 will be 1 if writing is successful, and M1067 will be 0 if an error has
occurred.

Refresh command:

Use CANFLS command to refresh (if there are RW attributes, the master will

write to the slave station; if there are RO attributes, the slave station will return the read
values to the master); M1066 will be 1 if refresh has been completed; M1067 will be 1 if
refresh is successful, and M1067 will be 0 if an error has occurred.
NOTE

When using CANRX, CANTX or CANFLS, internal implementation commands will wait until M1066 is
completed before executing the next CANRX, CANTX or CANFLS.
Afterwards, download program to the driver (Please note that the PLC's default communications format is
ASCII 7N2 9600, and the station number is 2. The WPL must therefore be modified, and the WPL setting
pathway is settings > communications settings)

Step 5: Set the slave stations' station numbers, communications speed, control
source, and command source
Delta's C2000 and EC series devices currently support the CANopen communications interface driver,
and the corresponding slave station numbers and communications speed parameters are as follows:
Corresponding device
parameters
C2000
E-C
Slave station
address

09-36

09-20

Communication
speed

09-37

09-21

00-21
00-20
11-33
11-40
-

02-01
02-00
-

Control source
Frequency source
Torque source
Position source

Value
0
1~127
0
1
2
3
4
5
3
5
6
5
3
3
-

Definition
Disable CANopen hardware interface
CANopen Communication address
1M
500K
250K
125K
100K
50K

Delta's A2 Servo currently supports the CANopen communications interface, and the corresponding slave
station numbers and communications speed parameters are as follows:
Corresponding device
parameters
A2

Value

Slave station
address

03-00

1~127

Communication
speed

03-01 bit 8-11 XRXX

R= 0
R= 1
R= 2
16-130

Definition
CANopen Communication address
125K
250K
500K

PLC Function Applications

R= 3
R= 4
Control/command
source

01-01

750K
1M

B

Step 6: Connect hardware wiring
When performing wiring, note the head and tail terminal resistance; connection methods are as
follows:

Step 7: Initiate control
After a program has been written and downloaded, switch the PLC mode to Run. Merely turn power
to master and slave stations off and then on again.
Refer to CANMasterTest 1 vs. 2 driver.dvp
Example
C2000 driver one-to-two control
Step 1: Activating CANopen Master functions


Parameter 09-45=1 (initiates Master functions); restart power after completing setting,
the status bar on the KPC-CC01 digital keypad will display "CAN Master".



Parameter 00-02=6 reset PLC (please note that this action will reset the program and
PLC registers to the default values)



Turn power off and on again.



Use the KPC-CC01 digital keypad to set the PLC control mode as "PLC Stop" (if
the KPC-CE01 digital keypad is used, set as "PLC 2"; if a newly-introduced driver is
used, the blank internal PLC program will cause a PLFF warning code to be issued).

Step 2: Master memory correspondences


Enable WPL



Use keypad set PLC mode as Stop (PLC 2)



WPL read D1070 to D1099 D2000 to D2799



Set D2000=10 D2100=11

16-131



Set D2100 2200 2300 2400 2500 2600 2700=0



Download D2000 to D2799 settings

Step 3: Set the master's communications station number and communications speed


When setting the master's station number (parameter 09-46, default is set as 100),
make sure not to use the same number as a slave station.



Set the CANopen communications speed as 1M (parameter 09-37=0); regardless of
whether the driver is defined as a master or slave station, the communications speed
is set via this parameter.

Step 4: Write program code
Real-time access: Can directly read/write to or from the corresponding D area.
Non real-time access:
Read command: Use the CANRX command for reading. M1066 will be 1 when reading
is complete; M1067 will be 1 if reading is successful, and M1067 will be 0 if
an error has occurred.
Write command: Use the CANTX command for writing. M1066 will be 1 when writing is
complete; M1067 will be 1 if writing is successful, and M1067 will be 0 if an
error has occurred.
Refresh command: Use CANFLS command to refresh (if there are RW attributes, the
master will write to the slave station; if there are RO attributes, the slave
station will return the read values to the master); M1066 will be 1 if refresh
has been completed; M1067 will be 1 if refresh is successful, and M1067
will be 0 if an error has occurred.
NOTE

When using CANRX, CANTX or CANFLS, internal implementation commands will wait until M1066 is
completed before executing the next CANRX, CANTX or CANFLS.

Afterwards, download program to the driver (Please note that the PLC's default
communications format is ASCII 7N2 9600, and the station number is 2. The WPL must
therefore be modified, and the WPL setting pathway is settings > communications
settings)
Step 5: Set the slave stations' station numbers and communications speed
Slave station no. 1: 09-37 = 0(Speed 1M)

09-36=10(Node ID 10 )

Slave station no. 2: 09-37 = 0(Speed 1M)

09-36=10(Node ID 11 )

16-132

PLC Function Applications

Step 6: Connect hardware wiring
When performing wiring, note the head and tail terminal resistance; connection methods are
as follows:

Terminal
resistor

Terminal
resistor

Step 7: Initiate control
After a program has been written and downloaded, switch the PLC mode to Run. Merely
turn power to master and slave stations off and then on again.
Refer to CANMasterTest 1 vs. 2 driver.dvp

16-133

16-9 Explanation of various PLC mode controls (speed, torque,
homing, and position)
The torque mode and position mode are based on FOC vector control and speed mode also
supports FOC vector control. Control therefore cannot be performed successfully unless you study
motor parameters ahead of time for the torque mode and position mode, and the speed mode based
on FOC.
In addition, motors are classified as two types: IM and PM. You therefore need to study IM motor
parameters. For PM motors, after completing motor parameter study, you must also complete study
of motor origin angle of deviation. Please refer to parameters 12-58 Pr.

05-00 detailed explanation.

※ If a PM motor belongs to Delta's ECMA series, motor parameters can be directly input from
data in the servo motor catalog, and parameter study will not be needed.
Control methods and settings are explained as follows:
Speed control:

Register table for speed mode:
Control special M
Special
M
M1025
M1026
M1040
M1042
M1044
M1052

Description of Function

Attributes

Driver frequency = set frequency (ON)/driver frequency =0 (OFF)
Driver operating direction FWD(OFF)/REV(ON)
Hardware power (Servo On)
Quick stop
Pause (Halt)
Lock frequency (lock, frequency locked at the current operating frequency)

RW
RW
RW
RW
RW
RW

Status special M
Special
Description of Function
M
M1015 Frequency attained (when used together with M1025)
M1056 Servo On Ready
M1058 On Quick Stopping

Attributes
RO
RO
RO

Control special D
Special
Description of Function
D
D1060 Mode setting (speed mode is 0)

Attributes
RW

Status special D
Special
Description of Function
D
D1037 Converter output frequency (0.00~600.00)
D1050 Actual operating mode (speed mode is 0)

Attributes
RO
RO

Speed mode control commands:
FREQ(P)

S1

S2

S3

16-134

PLC Function Applications

Target speed

The first acceleration time setting

The

first

deceleration time setting
Example of speed mode control:
Before performing speed control, if the FOC (magnetic field orientation) control method is used,
setting of electromechanical parameters must first be completed.
1.

Setting D1060 = 0 will shift the converter to the speed mode (default).

2.

Use the FREQ command to control frequency, acceleration time, and deceleration time.

3.

Set M1040 = 1, the driver will now be excited, but the frequency will be 0.

4.

Set M1025 = 1, the driver frequency command will now jump to the frequency designated
by FREQ, and acceleration/deceleration will be controlled on the basis of the acceleration
time and deceleration time specified by FREQ.

5.

M1052 can be used to lock the current operating frequency.

6.

M1044 can be used to temporarily pause operation, and the deceleration method will comply
with deceleration settings.

7.

M1042 can be used to perform quick stop, and deceleration will be as quick as possible
without giving rise to an error. (There may still be a jump error if the load is too large.)

8.

Control user rights:

M1040(Servo ON) > M1042(Quick Stop) >M1044(Halt) >M1052(LOCK)

16-135

Torque control:
Register table for torque mode:
Control special M
Special
M
M1040 Servo On

Description of Function

Attributes
RW

Status special M
Special
M
M1056 Servo On Ready
M1063 Torque attained

Description of Function

Attributes
RO
RO

Control special D
Special
Description of Function
D
D1060 Operating mode setting (torque mode is 2)
Status special D
Special
Description of Function
D
D1050 Actual operating mode (speed mode is 0)
D1053 Actual torque

Attributes
RW

Attributes
RO
RO

Torque mode control commands:
TORQ(P)

S1

S2

Target torque (with numbers)

Frequency restrictions

Example of torque mode control:
The setting of electromechanical parameters involved in torque control must be completed before
implementing torque control.
1.

Set D1060 = 2 to change the converted to the torque mode.

2.

Use the TORQ command to implement torque control and speed limits.

3.

Set M1040 = 1; the driver will now be excited, and immediately jump to the target torque or
speed limit. D1053 can be used to find out the current torque.

16-136

PLC Function Applications

0

M1002
MOV

K2

ON only for 1scan a
6

D1060
Set control mode (0:V)

M1000
TMR
Normally open contact

K30
T0
Power on delay

T0
Power on delay
13

Ready

X1
TORQ K100

19

K1000

Set Torque
X1
TORQ K-200 K1000
Set Torque

25

M0

X4

Ready

Power on

28
END
9999

16-137

Homing control/position control:
Register table in homing mode/position mode:
Control special M
Special
Description of Function
Attributes
M
RW
M1040 Servo On
Move to new position, must use control mode as position mode (D1060 = 1) and
RW
M1048
M1040 = 1
RW
M1050 Absolute position/relative position (0: relative/1: absolute)
Search for origin (home start), must use control mode as position mode (D1060
RW
M1055
= 3) and M1040 = 1
Status special M
Special
M
M1064 Target reached
M1070 Return home complete
M1071 Homing error

Description of Function

Attributes
RO
RO
RO

Control special D
Special
Description of Function
D
D1060 Operating mode setting (position mode is 1, homing mode is 3)

Attributes
RW

Status special D
Special
Description of Function
Attributes
D
RO
D1050 Actual operating mode (speed mode is 0)
RO
D1051 Actual position (Low word)
RO
D1052 Actual position (High word)
D1051 and D1052 must be combined to give the actual location, and it has a serial number.

※

Position mode control commands:
DPOS(P)

S1
Target (with numbers)

Example of homing mode/position mode control:
First complete setting of electromechanical parameters connected with position before
implementing homing control or position control.
1.

Set 00-40 to select the homing method and the corresponding limit sensors and origin.
(Setting the MI function gives a reverse rotation limit of 44, a forward rotation limit of 45, and
an origin proximity of 46. Because the C2000 current only supports a Z-phase origin, the
encoder card must a provide Z-phase.)

2.

Set D1060 = 3 to change the converter to the homing mode.

16-138

PLC Function Applications

3.

Set M1040 = 1
In the VF/SVC/VFPG mode, will enter the STANDBY mode (01-34 can be used to access the
STANDBY mode's action options).
In the FOC+PG mode, zero speed holding will occur

4.

Set M1055 = 1, and the driver will now start to search for the origin.

5.

When homing is complete, M1070 will change to ON. If you now set D1060 = 1, the control
mode will switch to position mode (please note that M1040 will not change to off; this
mechanical origin move).

6.

The DPOS command can now be used to designate the driver's target location. M1050 or
parameter 00-12 can be used to set a change in absolute or relative position.

7.

Implement M1048 Pulse ON once (must be more than 1 ms in duration), and the converter
will begin to move toward the target (M1040 must be 1 to be effective). The current position
can be obtained from D1051 and D1052.

Part 1: The initialization mode is defined as the "homing" mode from the beginning (set D1060 = 3).
X2 is used to implement converter excitation.
Initial condition
0

M1002
MOV

K3

ON only for 1scan a

10

D1060
Set control mode (0:V)

SET

M100
Home mode

RST

M101
P2P mode

X2
Servo on req

Power on

Part 2—homing: Use X3 to trigger homing action; will automatically switch to position mode after
completion.
Home mode
12

M100 X3
Home Home
mode req

Home
M1070
RST

M100

RST

M100

Home
finish

16-139

Part 3—point-to-point movement: Switch to position mode (set D1060 = 1), and move back and
forth between position points. (+300000 ~ -300000 )
P2P mode
20

M101
MOV

K1

MOV

K1

D1060
Set control mode (0:V)

P2P mode

33

K4M200
+300000

M200
DPOS K300000
+300000

43

TMR

T100

K10

TMR

T101

K10

M201 M1064
Ack

Target Position atta

49
M202
DPOS K300000
-400000
T102

K10

TMR

T103

K10

M1064

59
Ack
65

TMR

Target Position atta

M200 T100
ROLP K4M200
+300000

+300000
M200 T100

K1

+300000
M200 T100
+300000
M200 T100
+300000
81

M202
(M1048)
Ack
M203

84

Ack

END

※ If homing is not needed in an application, the first and second parts can be skipped. However,
the M1040 condition from Part 1 must be included, and the writing method in Part 1 involve the
use of X2 to achieve direct access. In addition, when M101 is used at the beginning of Part 3 to
set the control mode, it can be rewritten as M1002, which will put the PLC immediately into the
position mode when it starts running.

16-140

PLC Function Applications

16-10 Internal communications main node control
The protocol has been developed in order to facilitate the use of 485 instead of CANopen in certain
application situations. The 485 protocol offers similar real-time characteristics as CANopen; this
protocol can only be used on the C2000 and CT2000 devices. The maximum number of slave
devices is 8.
Internal communications have a master-slave structure. The initiation method is very simple:
Slave device:
Set parameter 09-31 = -1 to -8 in order to access 8 nodes, and set parameter 00-20 = 1 to define the
control source as 485 and access the reference sources that must be controlled, namely speed
command (00-21 = 2), torque command (11-33 = 1), and position command (11-40=2). This will
complete slave device settings. (PLC functions do not need to be activated)
System
Setting the master is even simpler; it is only necessary to set parameter 09-31 = -10, and enable the
PLC.
Hardware wiring: The master and slave stations are connected via the 485 serial port. The C2000
provide two types of 485 serial port interfaces, see the figure below: (please refer to 06 Control
terminals concerning detailed terminal connections)

16-141

Master programming: In a program, D1110 can be used to define a slave station to be controlled (1-8,
if set as 0, can jump between 8 stations). Afterwards, M1035 is set as 1, and the memory positions of
the master and slave stations will correspond. At this time, it is only necessary to send commands to
the correlation slave station address to control that station. The following is a register table connected
with internal communications:
Control special M
Attributes

Special M
Description of Function
M1035 Initiates internal communications control
Control special D
Special D
D1110

RW

Attributes

Description of Function

Internal node communications number 1-8 (set the station number of
the slave station to be controlled)

RW

Description of Function
Special D

Definition

D1120 + 10*N

Internal node N control
command

D1121 + 10*N

Internal node N control
mode

Attributes
User
Location
bit
Speed mode
Torque mode Homing mode
rights
mode
Command
Homing
0
4
functions
Origin
Reverse
Immediate
1
4
rotation
change
requirements
2
4
Temporary
Temporary
3
3
pause
pause
Frequency
Temporary
4
4
locking
pause
5
4
JOG
RW
6
2
Quick Stop
Quick Stop
Quick Stop
Quick Stop
7
1
Servo ON
Servo ON
Servo ON
Servo ON
Speed interval Speed interval
11~8 4
switching
switching
Deceleration
13~12 4
time change
Enable Bit 13 Enable Bit 13
14
4
~8
~8
Clear error
Clear error
Clear error
Clear error
15
4
code
code
code
code
0

1

2

3

RW

Position
command
(with
numbers)

Torque
command
(with
numbers)

-

RW

Speed limit

-

RW

D1122 + 10*N

Internal node N
reference command L

Speed
command
(no number)

D1123 + 10*N

Internal node N
reference command H

-

※ N=0~7

Status special D
Attributes
Special D
Description of Function
RO
D1115
Internal node synchronizing cycle (ms)
Internal node error (bit0 = slave device 1, bit1 = slave device 2,…bit7 = slave
RO
D1116
device 8)
Internal node online correspondence (bit0 = slave device 1, bit1 = slave device
RO
D1117
2,…bit7 = slave device 8)

16-142

PLC Function Applications

Description of Function

Special D

bit

Speed mode
Frequency command
arrival
Clockwise
Counterclockwise:
Warning
Error
JOG
Quick Stop
Servo ON

Location mode
Position command
attained
Clockwise
Counterclockwise:
Warning
Error

Torque mode
Torque command
attained
Clockwise
Counterclockwise:
Warning
Error

Homing mode
Zero command
completed
Clockwise
Counterclockwise:
Warning
Error

Quick Stop
Servo ON

Quick Stop
Servo ON

D1127 + 10*N

Actual frequency

D1128 + 10*N

-

Actual position
(with numbers)

Quick Stop
Servo ON
Actual torque
(with numbers)
-

0
1
D1126 + 10*N

2
3
5
6
7

※ N=0~7

-

Attributes

RO

RO

-

Example: Assume it is desired to control slave station 1 operation at frequencies of 30.00Hz and
60.00 Hz, status, and online node correspondences:
0

M1000
MOV
Normally open contact of
operation monitoring (a)

D1117

K1M700

Internal node
online mapping

MOV

D1126

Node 0 online

K4M250
Node 0 arrive

MOV K4M200
Node 0 ack

D1120
Control command of
internal node 0

(M1035)
Enable internal
communication
control

When it is judged that slave station 1 is online, delay 3 sec. and begin control
17

M700
MOVP

K0

Node 0 online
TMR
T0

K30
T0
Enable Control Delay
( M100 )
Enable Control

Enable Control Delay
T0

( M215 )
Reset

Enable Control Delay
33

D1121
Control mode of
internal node 0

M100
MOVP
Enable Control

K0

D1121
Control mode of
internal node 0

( M207 )
Node 0 Servo On
( M200 )
Node 0 Ack

16-143

It is required slave station 1 maintain forward rotation at 30.00Hz for 1 sec., and maintain reverse
rotation at 60.00 Hz for 1 sec., and repeat this cycle continuously.
41

M300
MOV K3000 D1122
+30.00Hz
M250
TMR

Node 0 arrive
52

M301
( M200 )
Rev

-60.00Hz
MOV

K6000

D1122
Reference command L
of the internal node 0

M250
TMR

Node 0 arrive
64

K10

T10

K10

T11

M302
MOV

Repeat

K1

K1M300
+30.00Hz

M100

73

Enable control
M300 T10
M100
+30.00Hz

ROLP K4M300
+30.00Hz

Enable control

K1

M301 T11
-60.00Hz
84

END

16-144

PLC Function Applications

16-11 Count function using MI8
16-11-1

High-speed count function

The C2000's MI8 supports one-way pulse counting, and the maximum speed is 100K. The starting
method is very simple, and only requires setting M1038 to begin counting. The 32 bit count value is
stored on D1054 and D1055 in non-numerical form. M1039 can reset the count value to 0.

Current count value
of MI8(H word)

※ When the PLC program defines MI8 for use as a high-speed counter, and also for use in PLC
procedures, it must be written to M1038 or M1039, and the original MI8 functions will be disabled.

16-11-2

Frequency calculation function

Apart from high-speed counting, the C2000's MI8 can also convert a received pulse to frequency.
The following figure shows that there is no conflict between frequency conversion and count
calculations, which can be performed simultaneously.
PLC speed calculation formula
D1057 Speed
D1058 Interval between calculations
D1059 Decimal places
Assuming that there are 5 input pulses each second, (see figure below) we set D1058=1000ms=1.0
sec. as the calculation interval. This enables five pulses to be sent to the converter each second.

Assuming that each 5 pulses correspond to 1Hz, we set D1057=5.
Assuming that we wish to display numbers to two decimal places, we set D1059=2, which is also
1.00Hz. The numerical value displayed at D1056 is 100. For simplicity, the D1059 conversion formula
can be expressed as in the following table:

16-145

16-12 Modbus remote IO control applications (use MODRW)
The C2000's internal PLC supports 485 read/write functions, which can be realized using the
MODRW command. However, the 485 serial port must be defined as available for the PLC's 485 use
before writing a program, and the parameter 09-31 must be set as -12. After completing settings, the
standard functions defined by 485 can be used to implement read/write commands at other stations.
Communications speed is defined by parameter 09-01, the communications format is defined by
parameter 09-04, and the PLC's current station number is defined by parameter 09-35. The C2000
currently supports the functions
read coil (0x01), read input (0x02), read register (0x03), write to single register (0x06), write to
several coils (0x0F), and write to several registers (0x10). Explanations and the usage of these
functions are provided as follows:
MODRW command
S1
S2
S3
S4
S5
Node Comman
Return: Length
Address
d
D area
:
ID
K3

H01

H500

D0

K3

H02

H400

D10

K3

H03

H600

D20

K3

H06

H610

D30

K3

H0F

H509

D40

K3

H10

H602

D50

General
meaning

Slave device is Delta's PLC
meaning

Slave device is Delta's
converter meaning

Read 18 bits of data corresponding to
slave station 3 PLC Y0 to Y21. This
Does not support this function
data is stored by bit 0 to 15 of the this
station's D0 and bit 0 to bit 3 of D1.
Read 10 bits of data corresponding to
Read input
slave station 3 PLC X0 to X11. This
K10
Does not support this function
(Bit)
data is stored by bit 0 to 9 of this
station's D10.
Read 3 words of data
Read 3 words of data corresponding corresponding to slave station
Read register
K3
to slave station 3 PLC T0 to T2. This 3 converter parameters 06-00
(word)
data is stored by D20 to D22.
to 06-02. This data is stored by
D20 to D22
Write slave station 3 converter
Write to single Write slave station 3 PLC's T16 to this
XX
06 to 16 parameter to this
register (word) station's D30 value
station's D30 value
Write to
Write slave station 3 PLC's Y11 to
K10 multiple coils
Does not support this function
Y22 to bit 0 to 9 of D40.
(Bit)
Write to
Write slave station 3 converter
Write slave station 3 PLC's T2 to T5 to
K4 multiple
06-02 to 06-05 parameters to
D50 to D53
registers (word)
this station's D50 to D53

Read coil
K18
(Bit)

※ XX indicates doesn't matter

After implementing MODRW, the status will be displayed in M1077 (485 read/write complete), M1078
(485 read/write error), and M1079 (485 read/write time out). M1077 is defined so as to immediately
revert to 0 after the MODRW command has been implemented. However, any of three situations—a
report of no error, a data error report, or time out with no report—will cause the status of M1077 to
change to On.
Example program: Testing of various functions
At the start, will cause the transmitted time sequence to switch to the first data unit.
0

M1002
MOV
On only for 1 scan a

16-146

K1

K4M0

PLC Function Applications

When the reported message indicates no error, it will switch to the next transmitted command
6

M1077 M1078 M1079
ROLP

K4M0

K1

485 R/W 485 R/W 485 R/W
rite is co rite is fail rite is time 0

If time out occurs or an error is reported, the M1077 will change to On. At this time, after a delay of 30
scanning cycles, it will re-issue the original command once
14

M1077
ADD

D30

K1 D30

485 R/W rite is co
D30 K40

33

MOV K0 D30
( M200 )
Delay cycle

M1002
( M100 )
ReqTXOnce

ON only for 1 scan a
M200
Delay cycle
36

M100
ReqTXOnce

M0
MODRW K2

H1 H500 D200

MODRW K2

HF H500 D100

MODRW K2

H2 H410 D201

MODRW K3

H3 H2100 D300

MODRW K2

H2 H410 D201

M1
M2
M3
M4

It will repeat after sending all commands
102

M5
MOV K1 K4M0
INC
D30 K40

D1

MOV K1 K4M0

121

END

Practical applications:
Actual use to control the RTU-485 module.
Step 1: Set the communications format. Assume that the communications format is 115200, 8,N,2,
RTU

：

C2000 The default PLC station number is set as 2 (09-35)
09-31=-12(COM1 is controlled by the PLC ), 09-01=115.2(The communications speed is 115200 )
09-04=13(The format is 8,N,2, RTU)
RTU485: The station number = 8 (give example)
ID7 ID6 ID5 ID4 ID3 ID2 ID1 ID0

PA3 PA2 PA1 PA0 DR2 DR1 DR0 A/R

16-147

0

0

0

0

1

0

0

0

1

0

0

0

1

1

1

0

Communication station #:
ID0~ ID7 are defined as 2 0 , 2 1, 2 2 ...2 6, 27

Communication protocol
Communication Protocol

Communicaton Speed

Step 2: Install control equipment. We sequentially connect a DVP16-SP (8 IN 8 OUT), DVP-04AD (4
channels AD), DVP02DA (2 channels DA), and DVP-08ST (8 switches) to the RTU485.
The following corresponding locations can be obtained from the RTU485's configuration definitions:

Module
DVP16-SP

Terminals 485 Address
X0 ~ X7

0400H ~ 0407H

Y0 ~ Y7

0500H ~ 0507H

DVP-04AD AD0 ~ AD3

1600H ~ 1603H

DVP02DA

1640H ~ 1641H

DA0 ~ DA1

DVP-08ST Switch 0 ~ 7 0408H ~ 040FH

16-148

PLC Function Applications

Step 3: Physical configuration

Step 4: Write to PLC program

16-149

16-150

PLC Function Applications

Step 5: Actual testing situation:
I/O testing: When the switch is activated, it can be discovered that the display corresponds to M115 M108. Furthermore, it can be seen that one output point light is added every 1 sec. (the
display uses a binary format)

This light signal increase
by 1number per second.

WPL will be modified
when pressing this Switch

AD DA testing: It can be discovered that D200 and D201 are roughly twice the D300, and continue to
increase progressively. For their part, the D202 and D203 are roughly twice the D301,
and continue to decrease progressively.

16-151

16-152

PLC Function Applications

16-13 Calendar functions
The C2000's internal PLC includes calendar functions, but these may only be used when a keypad
(KPC-CC01) is connected, and otherwise cannot be used. Currently-support commands include TCMP
(comparison of calendar data), TZCP (calendar data range comparison), TADD (calendar data addition),
TSUB (calendar data subtraction), and TRD (calendar reading). Please refer to the explanation of
relevant commands and functions for the usage of these commands.
In real applications, the internal PLC can judge whether calendar function have been activated; if they
have been activated, calendar warning codes may be displayed in some situations. The basis for whether
a calendar function has been activated is whether the program has written the calendar time (D1063 to
D1069) in connection with the foregoing calendar commands or programs.
The calendar's time display is currently assigned to D1063 to D1069, and is defined as follows:
Special
D

Item

Year
(Western)
D1064 Weeks
D1063

Content

Attributes

20xx (2000~2099)

RO

1~7

RO

D1065

Month

1~12

RO

D1066

Day

1~31

RO

D1067

Hour

0~23

RO

D1068

Minute

0~59

RO

D1069

Second

0~59

RO

Calendar-related special M items are defined as follows:
Special
Item
D
M1068 Calendar time error
Calendar time error or refresh time
M1076
out
M1036 Ignore calendar warning

Attributes
RO
RO
RW

*When a program writes to the commands TCMP, TZCP, TADD, or TSUB, if it is discovered that a
value exceeds the reasonable range, M1026 will be 1.
*When the keypad display is PLra (RTC correction warning) or PLrt (RTC time out warning), M1076
will be ON.
*When M1036 is 1, the PLC will ignore the calendar warning.
Calendar trigger warning code is defined as follows:
Warning

Description

PLra

Calendar time correction

PLrt

Calendar time refresh time out

Reset
approach
Requires
power restart
Requires
power restart

Whether it affects PLC
operation
Will not have any effect
Will not have any effect

*When the PLC's calendar functions are operating, if the keypad is replaced with another keypad, it
will jump to PLra.
*When it is discovered at startup that the keypad has not been powered for more than 7 days, or the
time is wrong, PLra will be triggered.

16-153

*When it is discovered that the C2000 has no keypad 10 sec. after startup, PLrt will be triggered.
*If the keypad is suddenly pulled out while the calendar is operating normally, and is not reconnected
for more than 1 minute, PLrt will be triggered.
Practical applications:
We will perform a demo of simple applications.
We first correct the keypad time. After pressing Menu on the keypad, select the 9th time setting
option. After selection, set the current time.

Menu
7.Quick Start
8.Displ Setup
9.Time Setup

Time Setup
2020/09/01
02:16:21

We set converter on during the period of 8:00-17:20, which allows us to write the following example
At K16

Normally open
contact of
operation
monitoring (a)

At K16

Servo on

Motor drive
Run (ON)/ Stop(OFF)

Normally open
contact of
operation
monitoring (a)

16-154

Chapter 12 Description of Parameter SettingsC2000 Series

Chapter 17 How to Select the Right
AC Motor Drive
17-1 Capacity formula
17-2 General Precautions
17-3 How to choose a suitable motor
The choice of the right AC motor drive for the application is very important and has great influence on its
lifetime. If the capacity of AC motor drive is too large, it cannot offer complete protection to the motor and
motor maybe damaged. If the capacity of AC motor drive is too small, it cannot offer the required
performance and the AC motor drive maybe damaged due to overloading.
But by simply selecting the AC motor drive of the same capacity as the motor, user application
requirements cannot be met completely. Therefore, a designer should consider all the conditions,
including load type, load speed, load characteristic, operation method, rated output, rated speed, power
and the change of load capacity. The following table lists the factors you need to consider, depending on
your requirements.

Item

Related Specification
Speed and torque
Time
Overload
characteristics
ratings
capacity

Friction load and weight
load
Liquid (viscous) load
Load type
Inertia load
Load with power
transmission
Constant torque
Load speed and
Constant output
torque
Decreasing torque
characteristics
Decreasing output
Constant load
Shock load
Load
Repetitive load
characteristics
High starting torque
Low starting torque
Continuous operation, Short-time operation
Long-time operation at medium/low speeds
Maximum output current (instantaneous)
Constant output current (continuous)
Maximum frequency, Base frequency
Power supply transformer capacity or
percentage impedance
Voltage fluctuations and unbalance
Number of phases, single phase protection
Frequency
Mechanical friction, losses in wiring
Duty cycle modification

●

Starting
torque

●

●

●

●

●

●

●

●

●

●

●

●

●

17-1

●

●

●

●

Chapter 12 Description of Parameter SettingsC2000 Series

17-1 Capacity Formulas
1.
When one AC motor drive operates one motor
The starting capacity should be less than 1.5x rated capacity of AC motor drive
The starting capacity=

kN
GD 2 N 
 TL 
   1.5  the _ capacity _ of _ AC _ motor _ drive ( kVA)
973    cos  
375 t A 

2.
When one AC motor drive operates more than one motor
2.1 The starting capacity should be less than the rated capacity of AC motor drive
 Acceleration time ≦60 seconds
The starting capacity=


kN
nT  nsks  1  PC11  ns ks  1  1.5  the _ capacity _ of _ AC _ motor _ drive(kVA)
  cos 
nT



 Acceleration time ≧60 seconds
The starting capacity=


kN
nT  nsks  1  PC11  ns ks  1  the _ capacity _ of _ AC _ motor _ drive(kVA)


  cos
nT

2.2 The current should be less than the rated current of AC motor drive(A)
 Acceleration time ≦60 seconds

nT  IM 1 nnTS  kS 1   1.5  the _ rated _ current _ of _ AC _ motor _ drive( A)
 Acceleration time ≧60 seconds

nT  IM 1 nnTS  kS 1   the _ rated _ current _ of _ AC _ motor _ drive( A)

17-2

Chapter 12 Description of Parameter SettingsC2000 Series

2.3 When it is running continuously
 The requirement of load capacity should be less than the capacity of AC motor drive(kVA)
The requirement of load capacity=

k  PM
 the _ capacity _ of _ AC _ motor _ drive(kVA)
  cos
 The motor capacity should be less than the capacity of AC motor drive

k  3  VM  IM 103  the _ capacity_ of _ AC _ motor _ drive(kVA)
 The current should be less than the rated current of AC motor drive(A)

k  IM  the _ rated _ current _ of _ AC _ motor _ drive( A)
Symbol explanation

PM

: Motor shaft output for load (kW)

η

: Motor efficiency (normally, approx. 0.85)

cos 

: Motor power factor (normally, approx. 0.75)

VM

: Motor rated voltage(V)

IM
k

: Motor rated current(A), for commercial power
: Correction factor calculated from current distortion factor (1.05-1.1, depending on PWM
method)

PC1

: Continuous motor capacity (kVA)

kS

: Starting current/rated current of motor

nT

: Number of motors in parallel

nS
GD

: Number of simultaneously started motors
2

: Total inertia (GD2) calculated back to motor shaft (kg m2)

TL

: Load torque

tA

: Motor acceleration time

N

: Motor speed

17-3

Chapter 12 Description of Parameter SettingsC2000 Series

17-2 General Precaution
Selection Note
1. When the AC Motor Drive is connected directly to a large-capacity power transformer (600kVA or
above) or when a phase lead capacitor is switched, excess peak currents may occur in the power
input circuit and the converter section may be damaged. To avoid this, use an AC input reactor
(optional) before AC Motor Drive mains input to reduce the current and improve the input power
efficiency.
2. When a special motor is used or more than one motor is driven in parallel with a single AC Motor
Drive, select the AC Motor Drive current 1.25x(Sum of the motor rated currents).
3. The starting and accel./decel. characteristics of a motor are limited by the rated current and the
overload protection of the AC Motor Drive. Compared to running the motor D.O.L. (Direct On-Line),
a lower starting torque output with AC Motor Drive can be expected. If higher starting torque is
required (such as for elevators, mixers, tooling machines, etc.) use an AC Motor Drive of higher
capacity or increase the capacities for both the motor and the AC Motor Drive.
4. When an error occurs on the drive, a protective circuit will be activated and the AC Motor Drive
output is turned off. Then the motor will coast to stop. For an emergency stop, an external
mechanical brake is needed to quickly stop the motor.

Parameter Settings Note
1. The AC Motor Drive can be driven at an output frequency up to 400Hz (less for some models) with
the digital keypad. Setting errors may create a dangerous situation. For safety, the use of the
upper limit frequency function is strongly recommended.
2. High DC brake operating voltages and long operation time (at low frequencies) may cause
overheating of the motor. In that case, forced external motor cooling is recommended.
3. Motor accel./decel. time is determined by motor rated torque, load torque, and load inertia.
4. If the stall prevention function is activated, the accel./decel. time is automatically extended to a
length that the AC Motor Drive can handle. If the motor needs to decelerate within a certain time
with high load inertia that can’t be handled by the AC Motor Drive in the required time, either use
an external brake resistor and/or brake unit, depending on the model, (to shorten deceleration
time only) or increase the capacity for both the motor and the AC Motor Drive.

17-4

Chapter 12 Description of Parameter SettingsC2000 Series

17-3 How to Choose a Suitable Motor
Standard motor
When using the AC Motor Drive to operate a standard 3-phase induction motor, take the following
precautions:
1. The energy loss is greater than for an inverter duty motor.
2. Avoid running motor at low speed for a long time. Under this condition, the motor temperature may
rise above the motor rating due to limited airflow produced by the motor’s fan. Consider external
forced motor cooling.
3. When the standard motor operates at low speed for long time, the output load must be decreased.
4. The load tolerance of a standard motor is as follows:
Load duty-cycle

25%

40% 60%

100
torque(%)

82
70
60
50

0

continuous

3 6

20
Frequency (Hz)

60

5. If 100% continuous torque is required at low speed, it may be necessary to use a special inverter
duty motor.
6. Motor dynamic balance and rotor endurance should be considered once the operating speed
exceeds the rated speed (60Hz) of a standard motor.
7. Motor torque characteristics vary when an AC Motor Drive instead of commercial power supply
drives the motor. Check the load torque characteristics of the machine to be connected.
8. Because of the high carrier frequency PWM control of the VFD series, pay attention to the
following motor vibration problems:
 Resonant mechanical vibration: anti-vibration (damping) rubbers should be used to mount
equipment that runs at varying speed.
 Motor imbalance: special care is required for operation at 50 or 60 Hz and higher
frequency.
 To avoid resonances, use the Skip frequencies.
9. The motor fan will be very noisy when the motor speed exceeds 50 or 60Hz.
Special motors:
1. Pole-changing (Dahlander) motor:
The rated current is differs from that of a standard motor. Please check before operation and
select the capacity of the AC motor drive carefully. When changing the pole number the motor
needs to be stopped first. If over current occurs during operation or regenerative voltage is too
high, please let the motor free run to stop (coast).

17-5

Chapter 12 Description of Parameter SettingsC2000 Series

2. Submersible motor:
The rated current is higher than that of a standard motor. Please check before operation and
choose the capacity of the AC motor drive carefully. With long motor cable between AC motor
drive and motor, available motor torque is reduced.
3. Explosion-proof (Ex) motor:
Needs to be installed in a safe place and the wiring should comply with the (Ex) requirements.
Delta AC Motor Drives are not suitable for (Ex) areas with special precautions.
4. Gear reduction motor:
The lubricating method of reduction gearbox and speed range for continuous operation will be
different and depending on brand. The lubricating function for operating long time at low speed
and for high-speed operation needs to be considered carefully.
5. Synchronous motor:
The rated current and starting current are higher than for standard motors. Please check before
operation and choose the capacity of the AC motor drive carefully. When the AC motor drive
operates more than one motor, please pay attention to starting and changing the motor.
Power Transmission Mechanism
Pay attention to reduced lubrication when operating gear reduction motors, gearboxes, belts and
chains, etc. over longer periods at low speeds. At high speeds of 50/60Hz and above, lifetime
reducing noises and vibrations may occur.
Motor torque
The torque characteristics of a motor operated by an AC motor drive and commercial mains power
are different.
Below you’ll find the torque-speed characteristics of a standard motor (4-pole, 15kW):
AC motor drive

Motor
180

60 seconds

100
80
55
38
03 20

55
38
60
120
Frequency (Hz)
Base freq.: 60Hz
V/F for 220V/60Hz

180
150

60 seconds
torque (%)

torque (%)

100

0 3 20

60
120
Frequency (Hz)
Base freq.: 60Hz
V/F for 220V/60Hz

140
130

60 seconds

155
torque (%)

torque (%)

180
155
140

100
85
68
45
35

60 seconds

100
80
45
35
0 3 20 50
120
Frequency (Hz)
Base freq.: 50Hz
V/F for 220V/50Hz

03 20

50
120
Frequency (Hz)
Base freq.: 50Hz
V/F for 220V/50Hz

17-6

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

Chapter 18 Suggestions and Error
Corrections for Standard AC Motor Drives
18-1 Maintenance and Inspections
18-2 Greasy Dirt Problem
18-3 Fiber Dust Problem
18-4 Erosion Problem
18-5 Industrial Dust Problem
18-6 Wiring and Installation Problem
18-7 Multi-function Input/Output Terminals Problem

The AC motor drive has a comprehensive fault diagnostic system that includes several different
alarms and fault messages. Once a fault is detected, the corresponding protective functions will be
activated. The following faults are displayed as shown on the AC motor drive digital keypad display. The
six most recent faults can be read from the digital keypad or communication.

The AC motor drive is made up by numerous components, such as electronic components,
including IC, resistor, capacity, transistor, and cooling fan, relay, etc. These components can’t be used
permanently. They have limited-life even under normal operation. Preventive maintenance is required to
operate this AC motor drive in its optimal condition, and to ensure a long life.

Check your AC motor drive regularly to ensure there are no abnormalities during operation and
follows the precautions:
 Wait 5 seconds after a fault has been cleared before performing reset via keypad of
input terminal.
 When the power is off after 5 minutes for ≦ 22kW models and 10 minutes for ≧
30kW models, please confirm that the capacitors have fully discharged by
measuring the voltage between + and -. The voltage between + and - should be less
than 25VDC.
 Only qualified personnel can install, wire and maintain drives. Please take off any
metal objects, such as watches and rings, before operation. And only insulated tools
are allowed.
 Never reassemble internal components or wiring.
 Make sure that installation environment comply with regulations without abnormal
noise, vibration and smell.

18-1

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

18-1 Maintenance and Inspections
Before the check-up, always turn off the AC input power and remove the cover. Wait at least 10
minutes after all display lamps have gone out, and then confirm that the capacitors have fully
discharged by measuring the voltage between DC+ and DC-. The voltage between DC+ and
DC-should be less than 25VDC.
Ambient environment
Maintenance
Check Items

Methods and Criterion

Check the ambient temperature, humidity,

Visual inspection and

vibration and see if there are any dust, gas,

measurement with equipment

oil or water drops

with standard specification

If there are any dangerous objects

Visual inspection

Period
Half One
Daily
Year Year
○
○

Voltage
Maintenance

Check if the voltage of main circuit and

Period
Half One
Daily
Year Year
Measure with multimeter with ○

control circuit is correct

standard specification

Check Items

Methods and Criterion

Digital Keypad Display
Maintenance
Check Items

Methods and Criterion

Is the display clear for reading

Visual inspection

Any missing characters

Visual inspection

Period
Half One
Daily
Year Year
○
○

Mechanical parts
Maintenance
Check Items

Methods and Criterion

Period
Half One
Daily
Year Year
○

If there is any abnormal sound or vibration

Visual and aural inspection

If there are any loose screws

Tighten the screws

○

If any part is deformed or damaged

Visual inspection

○

If there is any color change by overheating

Visual inspection

○

If there is any dust or dirt

Visual inspection

○

18-2

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

Main circuit
Maintenance
Check Items

If there are any loose or missing screws
If machine or insulator is deformed, cracked,
damaged or with color change due to
overheating or ageing
If there is any dust or dirt

Methods and Criterion

Tighten or replace the screw

Period
Half One
Daily
Year Year
○

Visual inspection
NOTE: Please ignore the

○

color change of copper
plate

○

Visual inspection

Terminals and wiring of main circuit
Maintenance
Check Items

If the terminal or the plate is color change or
deformation due to overheat
If the insulator of wiring is damaged or color
change
If there is any damage

Methods and Criterion

Visual inspection

Period
Half One
Daily
Year Year
○
○

Visual inspection
Visual inspection

○

DC capacity of main circuit
Maintenance
Check Items

If there is any leak of liquid, color change,
crack or deformation
If the safety valve is not removed? If valve is
inflated?

Methods and Criterion

Visual inspection
Visual inspection

Period
Half One
Daily
Year Year
○
○
○

Measure static capacity when required
Resistor of main circuit

Maintenance
Check Items

If there is any peculiar smell or insulator
cracks due to overheat
If there is any disconnection
If connection is damaged?

Methods and Criterion

Visual inspection, smell

Period
Half One
Daily
Year Year
○

Visual inspection

○

Measure with multimeter with

○

standard specification

18-3

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

Transformer and reactor of main circuit
Maintenance
Check Items

Methods and Criterion

If there is any abnormal vibration or peculiar

Visual, aural inspection and

smell

smell

Period
Half One
Daily
Year Year
○

Magnetic contactor and relay of main circuit
Maintenance
Check Items

Methods and Criterion

If there are any loose screws

Visual and aural inspection

If the contact works correctly

Visual inspection

Period
Half One
Daily
Year Year
○
○

Printed circuit board and connector of main circuit
Maintenance
Check Items

Methods and Criterion

Tighten the screws and
If there are any loose screws and connectors

Period
Half One
Daily
Year Year
○

press the connectors firmly
in place.

If there is any peculiar smell and color change Visual and smell inspection

○

If there is any crack, damage, deformation or

○

Visual inspection

corrosion
If there is any liquid is leaked or deformation in
capacity

Visual inspection

○

Cooling fan of cooling system
Maintenance
Check Items

Methods and Criterion

Period
Half One
Daily
Year Year

Visual, aural inspection and
turn the fan with hand (turn
If there is any abnormal sound or vibration

off the power before

○

operation) to see if it rotates
smoothly
If there is any loose screw

Tighten the screw

○

If there is any color change due to overheat

Change fan

○

18-4

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

Ventilation channel of cooling system
Maintenance
Check Items

If there is any obstruction in the heat sink, air
intake or air outlet

Methods and Criterion

Visual inspection

Period
Half One
Daily
Year Year
○

NOTE

Please use the neutral cloth for clean and use dust cleaner to remove dust when necessary.

18-5

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

18-2 Greasy Dirt Problem
Serious greasy dirt problems generally occur in processing industries such as machine tools,
punching machines and so on. Please be aware of the possible damages that greasy oil may cause
to your drive:
1.

Electronic components that silt up with greasy oil may cause the drive to burn out or even
explode.

2.

Most greasy dirt contains corrosive substances that may damage the drive.

Solution:
Install the AC motor drive in a standard cabinet to keep it away from dirt. Clean and remove greasy
dirt regularly to prevent damage of the drive.

18-6

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

18-3 Fiber Dust Problem
Serious fiber dust problems generally occur in the textile industry. Please be aware of the
possible damages that fiber may cause to your drives:
1.

Fiber that accumulates or adheres to the fans will lead to poor ventilation and cause
overheating problems.

2.

Plant environments in the textile industry have higher degrees of humidity that may cause the
drive to burn out, become damaged or explode due to wet fiber dust adhering to the devices.

Solution:
Install the AC motor drive in a standard cabinet to keep it away from fiber dust. Clean and remove
fiber dust regularly to prevent damage to the drive.

18-7

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

18-4 Erosion Problem
Erosion problems may occur if any fluids flow into the drives. Please be aware of the damages
that erosion may cause to your drive.
1.

Erosion of internal components may cause the drive to malfunction and possibility to explode.

Solution:
Install the AC motor drive in a standard cabinet to keep it away from fluids. Clean the drive
regularly to prevent erosion.

18-8

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

18-5 Industrial Dust Problem
Serious industrial dust pollution frequently occurs in stone processing plants, flour mills, cement
plants, and so on. Please be aware of the possible damage that industrial dust may cause to your
drives:
1.

Dust accumulating on electronic components may cause overheating problem and shorten the
service life of the drive.

2.

Conductive dust may damage the circuit board and may even cause the drive to explode.

Solution:
Install the AC motor drive in a standard cabinet and cover the drive with a dust cover. Clean the
cabinet and ventilation hole regularly for good ventilation.

18-9

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

18-6 Wiring and Installation Problem
When wiring the drive, the most common problem is wrong wire installation or poor wiring.
Please be aware of the possible damages that poor wiring may cause to your drives:
1.

Screws are not fully fastened. Occurrence of sparks as impedance increases.

2.

If a customer has opened the drive and modified the internal circuit board, the internal
components may have been damaged.

Solution:
Ensure all screws are fastened when installing the AC motor drive. If the AC motor drive functions
abnormally, send it back to the repair station. DO NOT try to reassemble the internal components or
wire.

18-10

Chapter 18 Suggestions and Error Corrections for Standard AC Motor Drives C2000 Series

18-7 Multi-function Input/Output Terminals Problem
Multi-function input/output terminal errors are generally caused by over usage of terminals and
not following specifications. Please be aware of the possible damages that errors on multi-function
input/output terminals may cause to your drives:
1.

Input/output circuit may burns out when the terminal usage exceeds its limit.

Solution:
Refer to the user manual for multi-function input output terminals usage and follow the specified
voltage and current. DO NOT exceed the specification limits.

18-11

http://www.delta.com.tw/industrialautomation/

AC Motor Drives

EMC Standard Installation Guide
EMC Compliance Practice

i

Preface
When an AC motor drive is installed in a noisy environment, radiated and/or conducted
noise via signal and power cables can interfere with the correct functioning, cause errors or even
damage to the drive. To prevent this, some AC motor drives have an enhanced noise resistance
but the results are limited and it is not economical. Therefore, an effective method would be finding
the cause of the noise and use the right solution to achieve “no emission, no transmission and no
reception of noise”. All three solutions should be applied.

Finding the Noise




Ascertain whether the error is caused by noise.
Find the source of the noise and its transmission path.
Confirm the signal and the source of noise

Solutions




Grounding
Shielding
Filtering

ii

Table of Contents
Preface .................................................................................................................... i
Table of Contents .................................................................................................... ii
Chapter 1 Introduction ............................................................................................ 1
1.1 What is EMC ............................................................................................. 1
1.2 EMC for AC Motor Drive ........................................................................... 1
Chapter 2 How to prevent EMI ............................................................................... 2
2.1 Types of EMI: common-mode and differential mode noise ....................... 2
2.2 How does EMI transmit? (Noise transmission) ......................................... 2
Chapter 3 Solution to EMI: Grounding ................................................................... 4
3.1 Protective Grounding & Functional Grounding .......................................... 4
3.2 Ground Loops ........................................................................................... 5
3.3 Earthing Systems ...................................................................................... 5
Chapter 4 Solution to EMI: Shielding ..................................................................... 9
4.1 What is Shielding? .................................................................................... 9
4.2 How to Reduce EMI by Shielding? .......................................................... 10
Chapter 5 Solution to EMI: Filter .......................................................................... 12
5.1 Filter ........................................................................................................ 12
5.2 Harmonic Interference............................................................................. 14

iii

Chapter 1 Introduction
1.1 What is EMC?
Electromagnetic Compatibility (EMC) is the ability of an electrical device to function properly in
electromagnetic environments. It does not emit electromagnetic noise to surrounding equipment and is
immune to interference from surrounding equipment. The goal is to achieve high immunity and low
emission; these two properties define the quality of EMC. In general, electrical devices react to high and
low frequency phenomena. High frequency phenomena are electrostatic discharge (ESD); pulse
interference; radiated electromagnetic field; and conducted high frequency electrical surge. Low
frequency phenomena refer to mains power harmonics and imbalance.
The standard emission and immunity levels for compliance depend on the installation location of
the drive. A Power Drive System (PDS) is installed in an industrial or domestic environment. A PDS in a
domestic environment must have lower emission levels and is allowed to have lower immunity levels. A
PDS in an industrial environment is allowed to have higher emission levels but must have more severe
immunity levels.

1.2 EMC for AC Motor Drive
When an AC motor drive is put into operation, harmonic signal will occur at the AC drive’s power
input and output side. It creates a certain level of electromagnetic interference to the surrounding
electrical devices and the mains power network. An AC motor dive is usually applied in industrial
environments with a strong electromagnetic interference. Under such conditions, an AC drive could
disturb or be disturbed.
Delta’s AC motor drives are designed for EMC and comply with EMC standard EN61800-3 2004.
Installing the AC motor drive accurately will decrease EMI influences and ensure long term stability of the
electricity system. It is strongly suggested to follow Delta’s user manual for wiring and grounding. If any
difficulties or problems arise, please follow the instructions and measures as indicated in this EMC
Standard Installation Guide.

1

Chapter 2 How to prevent EMI
2.1 Types of EMI: Common-mode and differential-mode noise
The electromagnetic noise of an AC motor drive can be distinguished into common-mode and
differential-mode noise. Differential-mode noise is caused by the stray capacitance between the
conducting wires and common-mode noise is caused by the common-mode coupling current path created
by the stray capacitance between the conducting wires and ground.
Basically, differential-mode noise has a greater impact to the AC motor drive and common-mode
noise has a greater impact to high-sensitivity electronic devices. An excessive amount of differentialmode noise may trigger the circuit protection system of the AC motor drive. Common-mode noise affects
peripheral electronic devices via the common ground connection.
EMC problems can be more serious when the following conditions apply:
 When a large horsepower AC motor drive is connected to a large horsepower motor.
 The AC motor drive’s operation voltage increases.
 Fast switching of the IGBTs.
 When a long cable is used to connect the motor to the AC motor drive.

2.2

How does EMI transmit? (Noise transmission path)

Noise disturbs peripheral high-sensitivity electrical devices/systems via conduction and radiation, their
transmission paths are shown hereafter:
1. Noise current in the unshielded power cable is conducted to ground via stray capacitances into a
common-mode voltage. Whether or not other modules are capable to resist this common-mode noise
depends on their Common-Mode Rejection Ratio (CMRR), as shown in the following figure.

Noise

Unshielded cable

Receive

Send

Load

Cstray

Ground

2. Common-mode noise in the power cable is transmitted through the stray capacitance and coupled
into the adjacent signal cable, as shown in Figure 2. Several methods can be applied to reduce the
effect of this common-mode noise; for example, shield the power cable and/or the signal cables,
separate the power and signal cables, take the input and output side of the signal cable and twist
them together to balance out the stray capacitance, let power cables and signal cables cross at 90°,
etc.

2

Unshielded cable
Noise

Cstray

Power
supply

System

Cable

Ground

3. Common-mode noise is coupled via the power cable to other power systems then the cable of such a
power system is coupled to the transmission system, as shown in Figure 3.
Unshielded cable
Noise
Cstray
Receive

Send

Load

Ground

4. The common-mode noise of an unshielded power cable is transmitted to the ground via the stray
capacitance. Since both shielded wire and unshielded wire are connected to a common ground, other
systems can be interfered with by the common-mode noise that is transmitted from the ground back
to the system via the shield. See Figure 4.
Noise
Unshielded cable

Send

Receive
Cstray
Load
Cstray

Ground
5. When excessive pulse modulated currents pass through an un-grounded AC drive cable, it acts as an
antenna and creates radiated interference.

3

Chapter 3 Solution to EMI: Grounding
The leakage current of an electronic equipment is conducted to ground via the grounding wire and
the ground electrode. According to Ohm's law, potential differences may arise when the electrode’s
ground and the ground’s ground resistance are different.

According to Ohm's law, the earth resistance for electrode and the ground are different,
in this case potential differences may arise.
3.1 Protective Grounding & Functional Grounding
Please carefully read the following instruction if two types of grounding are applied at the same
time.
Protective grounding is applied outside buildings and must have low resistance. On the other hand,
functional grounding can be applied inside buildings and must have low impedance.
The goal of EMC is to avoid any interference effects. Grounding for EMC can be distinguished by
frequency. For frequencies lower than 10kHz, a single-point ground system should be used and for
frequencies higher than 10 kHz, a multiple point ground system should be used.






Single Point Grounding: all signal grounds of all IT equipment are connected in series to form a single
reference point. This point can be grounded directly to earth; to the designated grounding point or to
the safety point that is already grounded.
Multiple Point Grounding: all signals of all IT equipment are grounded independently.
Hybrid Grounding: this type of grounding behaves differently for low and high frequencies. When two
pieces of IT equipment (A and B) are connected via a shielded cable, one end is connected directly to
ground while the other end is connected to ground via a capacitor. This type of grounding system
fulfils the criteria for high and low frequency grounding.
Floating grounding: the signals of all IT equipment are isolated from each other and are not grounded.

DC current flows evenly throughout the conductor section. But AC current flows towards the
conductor’s surface as frequency increases; this is called the “skin effect”. It causes the effective crosssection area to be reduced with increasing frequency. Therefore it is suggested to increase the effective
ground cross-section area for high frequencies by replacing pigtail grounding by braided conductors or
strip conductors. Refer to the following figure.
Pigtail
HF

1
LF-HF

2
1
Braided
strapl

3

This is why a thick short ground wire must be implemented for connecting to the common
grounding path or the ground busbar. Especially when a controller (e.g. PLC) is connected to an AC
motor drive, it must be grounded by a short and thick conducting wire. It is suggested to use a flat braided
conductor (ex: metal mesh) with a lower impedance at high frequencies.

4

If the grounding wire is too long, its inductance may interfere structure of the building or the control
cabinet and form mutual inductance and stray capacitance. As shown in the following figure, a long
grounding wire could become a vertical antenna and turn into a source of noise.

Long PE

Painted
sheet metal

HF

3.2 Ground Loops
A ground loop occurs when the pieces of equipment are connected to more than one grounding path.
In this case, the ground current may return to the grounding electrode via more than one path. There are
three methods to prevent ground loops
1. Use a common power circuit
2. Single point grounding
3. Isolate signals, e.g. by photocouplers
Good

Cable

Cable

Equipment

Equipment

Equipment

A

B

A

Accompanying cable

Equipment

B
Very good
Cable
Earth plane

Earth plane

In order to avoid “Common Mode Noise”, please use parallel wires or twisted pair wiring. Follow
this rule and also avoid long wires, it is suggested to place the two wires as close to each other as
possible.

3.3 Earthing Systems
The international standard IEC60364 distinguishes three different earthing system categories, using the
two-letter codes TN, TT, IT.






The first letter indicates the type of earthing for the power supply equipment (generator or
transformer).
T: One or more points of the power supply equipment are connected directly to the same earthing
point.
I: Either no point is connected to earth (isolated) or it is connected to earth via a high impedance.
The second letter indicates the connection between earth and the power supply equipment.
T: Connected directly to earth (This earthing point is separate from other earthing points in the power
supply system.)
N: Connected to earth via the conductor that is provided by the power supply system
The third and forth letter indicate the location of the earth conductor.
S: Neutral and earth conductors are separate
C: Neutral and earth are combined into a single conductor
5

TN system
TN: The neutral point of the low voltage transformer or generator is earthed, usually the star point in a
three-phase system. The body of the electrical device is connected to earth via this earth connection at
the transformer.
protective earth (PE): The conductor that connects the exposed metallic parts of the consumer.
neutral (N): The conductor that connects to the start point in a 3-phase system or that carries the return
current in a single phase system.

L1
L2
L3
N
PE

TN-S system
TN-S: PE and N are two separate conductors that are combined together only near the power source
(transformer or generator). It is the same as a three-phase 5-wire system.

6

TN-C system
TN-C: PE and N are two separate conductors in an electrical installation similar to a three-phase 5wire
system, but near the power side, PE and N are combined into a PEN conductor similar to a three-phase 4
wire system.
Generator or
transformer
L1
L2
L3
PEN

Earth

Consumer

TN-C-S system
TN-C-S: A combined earth and neutral system (PEN conductor) is used in certain systems but eventually
split up into two separate conductors PE and N. A typical application of combined PEN conductor is from
the substation to the building but within the building PEN is separated into the PE and N conductors.
Direct connection of PE and N conductors to many earthing points at different locations in the field will
reduce the risk of broken neutrals. Therefore this application is also known as protective multiple earthing
(PME) in the UK or as multiple earthed neutral (MEN )in Australia
Generator or
transformer
L1
L2
L3
N
PE

Earth

Consumer

7

TT system
TT: The neutral point (N) of the low voltage transformer and the equipment frames (PE) are connected to
a separate earthing point. The Neutral (N) of the transformer and electrical equipment are connected.

IT system
IT: The neutral point of the transformer and electrical equipment are not earthed, only the equipment
frames PE are earthed.
In the IT network, the power distribution system Neutral is either not connected to earth or is earthed via a
high impedance. In such a system, an insulated monitoring device is used for impedance monitoring.
A built-in filter should be disconnected by the RFI-jumper and an external filter should not be installed

when the AC motor drive or the AC servo motor drive is connected to an IT system.

Criteria for earthing system and EMC
Safety of
Personnel

Safety of property

TN-S
Good

TN-C
Good

Continuity of the PE
conductor must be
ensured throughout
the installation
Poor

Continuity of the PE
conductor must be
ensured throughout
the installation
Poor

RCD is mandatory

High fault current
(around 1kA)

High fault current
(around 1kA)

Medium fault current
(< a few dozen
amperes)

8

TT
Good

Good

IT
Good
Continuity of the PE
conductor must be
ensured throughout
the installation
Good
Low current at the
first fault (< a few
dozen mA) but high
current at the
second fault

Availability of
energy
EMC behavior

Good

Good

Good

Excellent

Excellent

Poor
(prohibited)

Good

Poor
(should be avoided)

Few equipotential
Problems:
- Need to handle
the high leaking
currents problem of
the device
- High fault current
(transient
disturbances)

- Neutral and PE are
the same

- Over-voltage risk
- Equipotential

- Circulation of
disturbance
currents in exposed
conductive parts
(high magnetic-field
radiation)

Problems:
- Need to handle the
high leaking
currents problem of
the device

- High fault currents
(transient
disturbances)

- RCD (Residualcurrent device)

- Over-voltage risk
- Common–mode
filters and surge
arrestors must
handle the phase
to phase voltage.
- RCDs subject to
nuisance tripping
when commonmode capacitors
are present
- Equivalent to TN
system for second
fault

9

Chapter 4 Solution to EMI: Shielding
4.1 What is Shielding?
Electrostatic shielding is used to isolate equipment so that it will not create electromagnetic field
interference or be influenced by an external electromagnetic field. A conductive material is used for
electrostatic shielding to achieve this isolation.
A Faraday cage can be made from a mesh of metal or a conductive material.
One characteristic of metal is that it is highly conductive and not electrostatic,, which offers shielding and
prevents interference by external electrical fields. Metal with its high conductivity protects the internal
devices from high voltages—no voltage will enter the cage even when the cage is experiencing a high
current. In addition, electromagnetic fields can also pass through the Faraday cage without causing any
disturbance.
Electromagnetic shielding is applied to some electrical devices and measurement equipment for the
purpose of blocking interference. Examples of shielding include:
 earth high-voltage indoor equipment using a metal frame or a high-density metal mesh
 shielding a power transformer is achieved by wrapping a metal sheet between the primary and
secondary windings or by adding an enamel wire to the winding wire which is then earthed.
 a shielding coating, which is made of metal mesh or conductive fibres to provide effective protection
for the workers who work in a high-voltage environment.
In the picture below, the radio appears to be not fully covered by metal but if the conductivity of the
metal is high, radio waves are completely blocked and the radio will not receive any signal.

Mobile phone connections are also established through the transmission of radio waves. This is
why the mobile phone reception is often cut off when we walk into an elevator. The metal walls of the
elevator create the same shielding effect just as if we had entered a metal cage. Another example is a
microwave oven. The microwave door may seem transparent in visible light, but the density of the metal
mesh in the microwave door blocks the electromagnetic waves. A higher density of the metal mesh offers
better shielding.

10

Electromagnetic fields

Wall of
shielded
enclosure

Greater leakage
form bigger
apertures
G=gap
( ap er tu re d im en sio n)
d=depth
( distan ce that f ields
have to travel)

Shield in g ef fectiveness
(SE)in dB
80
d=18"
g=6"
60

20
0
0.05

0.2

0.5

"Waveguide below cut-off"
doesn't leak very much
(does not have to be a tube)

d=4"
g=2"

d=6"
g=6"
0.1

d
(depth)

d=6"
g=2"

d=12"
g=6"

40

g
(gap)

d=2"
g=2"
1

GHz
2

F<0.5Fcutoff SE is approximately 27d/g

5

4.2 How to reduce EMI by Shielding?
Iron and other metals are high conductivity materials that provide effective shielding at extremely low
frequencies. But conductivity will decrease as:
1. High frequency signals are applied to the conductor.
2. Equipment is located in a strong magnetic field
3. The shielding frame is forced into a specific form by machines.
It is difficult to select a suitable high-conductivity material for shielding without the help from a shielding
material supplier or a related EMI institution.

Metallic Shielding Effectiveness
Shielding Effectiveness (SE) is used to assess the applicability of the shielding shell. The formula
is:
SEdB=A+R+B (Measures in dB)

where A= Absorption loss (dB)
R= Reflection loss (dB)
B= Correction factor (dB) (for multiple reflections in thin
shields)

The absorption loss refers to the amount of energy loss as the electromagnetic wave travels
through the shield. The formula is:
AdB=1.314(fσμ)1/2t

where f= frequency (MHz)
μ= permeability relative to copper
σ= conductivity relative to copper
t= thickness of the shield in centimetres

The reflection loss depends on the source of the electromagnetic wave and the distance from that
source. For a rod or straight wire antenna, the wave impedance increases as it moves closer to the
source and decreases as it moves away from the source until it reaches the plane wave impedance (377)
and shows no change. If the wave source is a small wire loop, the magnetic field is dominant and the
wave impedance decreases as it moves closer to the source and increases as it moves away from the
source; but it levels out at 377 when the distance exceeds one-sixth of the wavelength.

11

Electrical Cabinet Design
In a high frequency electric field, shielding can be achieved by painting a thin layer of conductive
metal on the enclosure or on the internal lining material. However, the coating must be thorough and all
parts should be properly covered without any seams or gaps (just like a Faraday cage). That is only the
ideal. Making a seamless shielding shell is practically impossible since the cage is composed of metal
parts. In some conditions, it is necessary to drill holes in the shielding enclosure for installation of
accessories (like optional cards and other devices).
1. If the metallic components are properly welded using sophisticated welding technology to form an
electrical cabinet, deformation during usage is unlikely to occur. But if the electrical cabinet is
assembled with screws, the protective insulating layer under the screw must be properly removed
before assembly to achieve the greatest conductivity and best shielding.
2. Drilling holes for the installation of wires in the electrical cabinet lowers the shielding effectiveness
and increases the chance of electric waves leaking through the openings and emitting interference.
We recommend that the drilled holes are as narrow as possible. When the wiring holes are not used,
properly cover the holes with metal plates or metal covers. The paint or the coating of the metal plate
and metal cover should be thoroughly removed to ensure a metal-to-metal contact or a conductive
gasket should be installed.
3. Install industrial conductive gaskets to completely seal the electrical cabinet and the cabinet door
without gaps. If conductive gaskets are too costly, please screw the cabinet door to the electrical
cabinet with a short distance between the screws.
4. Reserve a grounding terminal on the electrical cabinet door. This grounding terminal shall not be
painted. If the paint already exists, please remove the paint before grounding.

Electrical wires and cables
Shielded Twisted Pair (STP) is a type of cable where two insulated copper wires are twisted
together with a metal mesh surrounding the twisted pair that forms the electromagnetic shielding and can
also be used for grounding.
The individual electrical wires and complete cable are surrounded by (synthetic) rubber, that
provides insulation and also protects against damage.
There are two types of electrical cables: high voltage and low voltage. The high voltage cable
differs from the low voltage cable in that it has an additional insulation layer called the dielectric insulator
within the plastic sleeve. The dielectric insulator is the most important component in insulation. The low
voltage cable is usually only filled with a soft polymer material for keeping the internal copper wire in
place.
The shield has two functions.
1. To shield the electrical wire and cable.
A. Electric currents increase as power flows through the power cable and generate an electrical field.
Such interference can be suppressed inside the cable by shielding the power cables or the electrical
wires.
B. To form a protective earthing. When the cable core is damaged, the leakage current will flow via
the shield to ground
2. To protect the cable. A power cable used for the computer control purpose generates only relatively
low amount of current inside the cable. Such power cable will not become the source of interferences
but has great possibility to be interfered by the surrounding electrical devices.

Plastic jacket

Dielectric insulator

Metallic shield

Centre core

12

Chapter 5 Solution to EMI: Filter
5.1 Filter
Electromagnetic interference is transmitted in two ways, by radiation and by conduction. The most
effective and economical method of reducing radiated interference is to use shielding and of reducing
conducted interference is to use an electromagnetic filter.
Noise interference can be divided into two categories: high frequency (150kHz~300MHz) and low
frequency (100Hz~3000Hz). High-frequency noise fades more over distance and has a shorter wavelength, while low-frequency noise fades less over distance and has a longer wave-length.. Both types of
interference are transmitted through power cables and power leads, affecting the power supply side.
High-frequency interference at the power side can be eliminated or attenuated by mounting a filter.
The filter consists of coils and capacitors. Some drives do not have a built-in filter, in which case the
installation of an external option filter is required. The drawing below shows a standard filter diagram:

A filter is composed of a Differential Mode section (to eliminate noise below 150kHz) and a
Common Mode section (to eliminate noise above 150kHz). For high-frequency noise , the inductor acts
as a high impedance to form an open circuit and the capacitor acts as a low impedance to form a short
circuit. Proper design and dimensioning of inductors and capacitors give a resonant circuit to absorb
harmonic currents. Capacitor Cy is earthed to lead the harmonic currents to the ground.

External Filter
The filter and the AC drive should be installed in the control cabinet or on the mounting plate that is
earthed to ground. The motor cable must be shielded and as short as possible. Please use the filters
recommended by Delta to ensure compliance with EMC standards.
The Shielded
Chassis
IP20/NEMA 1/UL Type 1
Option Kit

Metal Conduits
EMI Filter
L1
L1'
L2
L2'
L3
L3'

R/L1
S/L2
T/L3

U/T1
V/T2
W/T3

Chassis Grounding

Shielded Motor Cable

Connect to the steel
structure of the building

13

AC Motor Drives with Built-in Filter
1. Since interferences are suppressed by installing an earthed capacitor in the filter, the amount of
current to ground (leakage current) could result in electric shocks to personnel or the power system.
Please be aware of this problem.
2. Since the leakage current to ground can be high, it is crucial to implement protective earthing to
prevent electrical shocks.

Filter Installation (With and Without)

Zero Phase Reactor (Choke)
Interferences can also be suppressed by installing a zero phase reactor at the power supply side
and/or the AC Motor Drive’s output, depending on where the interference is. Since currents are large at
the power input and the AC Motor Drive’s output, please carefully select the magnetic core with suitable
current handling capability. An ideal magnetic material for large currents is compound magnetic powder. It
has a higher current handling capability and higher impedance compared to pure metallic magnetic cores.
It is therefore suitable to implement in a high frequency environment. The impedance can also be
enhanced by increasing the turn ratio.

Zero Phase Reactor Installation
There are two installation methods, depending on the size of the zero phase reactor and the motor
cable length.
1. Wind the motor cable through the middle of a zero-phase reactor 4 times. Place the reactor and the
AC Motor Drive as close to each other as possible.

Zero Phase Reactor
Power
Supply

R/L1

U/T1

S/L2

V/T2

T/L3

W/T3

MOTOR

2. Place all wires through the middle of four zero-phase reactors without winding.

Zero Phase Reactor
Power
Supply

R/L1
S/L2
T/L3

U/T1
V/T2
W/T3

MOTOR

14

Analog Input Signals
If the analog input signals are affected by noise from the AC motor drive, please connect a
capacitor and a ferrite core as indicated in the following diagram.
Wind the wires around the core in same direction for 3 times or more.

AVI/ACI/AUI
C
ACM

Ferrite core

5.2

Harmonic Interference

The AC motor drive’s input current is non-linear, the input rectifier generates harmonics.
Harmonics must be limited to within a certain range to avoid impact the mains power and to avoid current
distortion to ensure surrounding devices are not influenced. An AC Motor Drive with built-in DC reactor
suppresses harmonic currents (Total Harmonic Current Distortion THID) effectively and therefore reduces
the harmonic voltage peaks (Total Harmonic Voltage Distortion).

Harmonic Current at the Power Supply Side

(A) Fund amen tal Sin e Wa ve
(6 0Hz)

(A) Fund amen tal Sin e Wa ve
(6 0Hz)

(B) 3 r d Ha rmo nic
(1 80H z)

(B) 5 th Ha rmon ic
(3 00H z)

(C) H armo nica lly
Di sto rte d Wa ve

(C) H armo ni ca lly
Di sto rted Wa ve

Suppression of Harmonic Currents
When a large portion of lower order harmonic currents (5th, 7th, 11th ,etc) occur at the power input,
surrounding devices will be disturbed and the power factor will be low as a result of reactive power.
Installing a reactor at the AC Motor Drive’s input effectively suppresses lower order harmonic currents.

AC Reactor
Installed in series with the power supply and is effective in reducing low order current harmonics.
Features of an AC reactor include:
1. Reduces the harmonic currents to the AC Motor Drive and increases the impedance of the power
supply.
2. Absorbs interferences generated by surrounding devices (such as surge voltages, currents, and
mains surge voltages) and reduce their effect on the AC Motor Drive.
3. Increases the power factor.

15

DC Reactor
A DC-Reactor is installed between the rectifier and the DC-bus capacitor to suppress harmonic
currents and to achieve a higher power factor.

Current Wave Diagrams
Without Reactor
150

150

100

100

50

50

0

0

-50

-50

-100

-100

With Reactor

-150

-150
0

50

100

150

200

250 300

350

400 450

500

0

50

16

100

150

200

250 300

350

400 450

500

Chapter 20 Safety Torque Off Function
20-1 The drive safety function failure rate
20-2 Safety torque off terminal function description
20-3 Wiring diagram
20-4 Parameter
20-5 Operating sequence description
20-6 New error code for STO function

Page 1/8

20-1 The drive safety function failure rate
Item

Definition
Safe Torque Off

SFF
HFT (Type A
subsystem)
SIL
PFH
PFDav
Category
PL
MTTFd
DC

Standard
IEC61508

Hardware Fault Tolerance
Safety Integrity Level
Average frequency of dangerous
failure [h-1]
Probability of Dangerous Failure on
Demand
Category
Performance level
Mean time to dangerous failure
Diagnostic coverage

Performance
Channel 1: 80.08%
Channel 2: 68.91%

IEC61508

1

IEC61508
IEC62061

SIL 2
SILCL 2

IEC61508

9.56×10-10

IEC61508

4.18×10-6

ISO13849-1
ISO13849-1
ISO13849-1
ISO13849-1

Category 3
d
High
Low

20-2 Safety Torque Off terminal function description
The safety Torque Off function is to cut off the power supply to motor through the hardware,
thereby the motor couldn’t produce torque.
The safety Torque Off function is respectively by two independent hardware to control the motor
current drive signal, and thus cut off the inverter power module output in order to achieve the
status of safety stop.
Operation principle Description as below table 1:
Table 1: Terminal operation description
Channel
Signal
STO
signal

STO1~SCM1

ON(High)

ON(High)

OFF(Low)

OFF(Low)

STO2~SCM2

ON(High)

OFF(Low)

ON(Low)

OFF(Low)

Ready

STL2 mode
(Torque
output off)

STL1 mode
(torque
output off)

STO mode
(Torque output
off)

Driver Output status








Photo-coupler status

STO means Safe Torque Off
STL1~STL3 means Safety Torque Off hardware abnormal.
STL3 means STO1~SCM1 and STO2~SCM2 internal circuit detected abnormal.
STO1~SCM1 ON(High): means STO1~SCM1has connect to a +24VDC power supply.
STO2~SCM2 ON(High): means STO2~SCM2 has connect to a +24V power supply.
STO1~SCM1 OFF(Low): means STO1~SCM1hasn’t connect to a +24VDC power supply.
STO2~SCM2 OFF(Low): means STO2~SCM2hasn’t connect to a +24VDC power supply.

Page 2/8

20-3 Wiring diagram
20-3-1Internal STO circuit as below:

I /O C a rd
+ 24 V

C2000
V+

ST O1
SCM1

Li ne
drive

C PU
S TO2

Gat e
drive

M

S CM2

M CM

M O1

DC M

C OM

20-3-2 In the figure below, the factory setting for +24V-STO1-STO2 and SCM1-SCM2-DCM is short circuit:

I/O Card
+ 24 V

C2000
V+

STO 1
SCM1

CP U
S TO2

Lin e
drive

Gate
dr ive

M

S CM2

M CM

M O1

DC M

C OM

Page 3/8

20-3-3 The control loop wiring diagram:
1. Remove the shot-circuit of +24V-STO1-STO2 and DCM-SCM1-SCM2.
2. The wiring as below diagram. The ESTOP switch must at Close status in normal situation and
drive will be able to Run.
3. STO mode, switch ESTOP open. Drive output stop and keypad display STO.
MO2( f ac tory s ett ing =66)
MCM

C2000

+ 24VDC

E STO P

*1

DCM
SCM1
Saf ety PLC

SCM2
*2

+2 4V
STO1
STO2

N OTE

*1: factory sho rt circu it of DCM-SCM1-SC M2. To use the Safety f un cti on , p lea se re move thi s short c ircu it
*2: factory sho rt circu it of +2 4V-STO1 -STO2 . to u se the Safe ty fu nction , pl ease remove thi s short ci rcui t .

20-4 Parameter


STO Alarm Latch
Factory setting: 0
Settings

0：STO Alarm Latch
1：STO Alarm no Latch

 Pr06-44=0 STO Alarm Latch: after the reason of STO Alarm is cleared, a Reset command is
need to clear STO Alarm.
 Pr06-44=1 STO Alarm no Latch: after the reason of STO Alarm is cleared, the STO Alarm will
be cleared automatically.
 All of STL1~STL3 error are “Alarm latch” mode (in STL1~STL3 mode, the Pr06-44 function is
no effective).


Multi-function Output 1 (Relay1)
Factory Setting:11



Multi-function Output 2 (Relay2)
Factory Setting:1



Multi-function Output 3 (MO1)
Factory Setting:0



Multi-function Output 4 (MO2)
Factory Setting:66
Settings
66: SO N.O. output
68: SO N.C. output
Page 4/8

Settings

66
68

Functions
SO Logic A output
SO Logic B output

Descriptions
Safety Output Normal Open
Safety Output Normal Close

 C2000 factory setting Pr02-17(MO2)=66(N.O.) and Multi-function Output setting item has add
2 new function: 66 and 68.
Safety Output status
N.O.
N.C.
(MO=66)
(MO=68)
Open
Close
Close
Open
Close
Open

Drive status
Normal run
STO
STL1~STL3


Content of Multi-function Display

Factory setting: 3
Settings

45: Hardware version

00-04=45

Hardware version

20-5 Operating sequence description
20-5-1Normal operation status
As shown in Figure 3: When the STO1~SCM1 and STO2~SCM2=ON (no STO function is need),
the drive will execute “Operating” or “Output Stop” according to RUN/STOP command.

RUN c ommand
STO1~ SCM1
s tatu s
STO2 ~SCM2
s tatu s
Driv e out put

RUN

STOP

ON(no S TO f unct ion n eed , Pr0 6-44=0 )
ON(no S TO f unct ion n eed , Pr0 6-44=0 )
Operat ing

Out put Stop

Figure 3

Page 5/8

20-5-2-1 STO，Pr06-44=0，Pr02-35=0
As shown in Figure 4: When both of STO1~SCM1 and STO2~SCM2 channel has turn off during
operating, the STO function enabling and the drive will stop output regardless of Run command is
ON or OFF status.
RUN co mmand

STOP

RUN

STO1~ SCM1
st atus

ON

O FF

ON

STO2~ SCM2
st atus

ON

O FF

ON

Drive out put

RUN

Operat ing O utp ut S top

Figure 4
20-5-2-2 STO，Pr06-44=0，Pr02-35=1
As shown in Figure 5: As same as the figure 4. But, because the Pr02-35=1, therefore, after the
Reset command, if the operating command still exists, then the drive will immediately execute the
run command again.
RUN co mmand

RUN

STO1~ SCM1
st atus

ON

O FF

ON

STO2~ SCM2
st atus

ON

O FF

ON

Drive o utput

Operating O utpu t St op

O perating

Res et

Reset

Figure 5
20-5-3 STO，Pr06-44=1

S TO P

RUN co mmand

RUN

STO1~ SCM1
st atus

ON

OFF

ON

STO2~ SCM2
st atus

ON

OFF

ON

Drive out put

Operating Ou tput Sto p

RUN

O perat ing

Figure 6
Page 6/8

20-5-4 STL1
RUN co mmand
STO1~ SCM1
st atus

ON

STO2~ SCM2
st atus

ON

Drive out put

STOP

RUN
OFF

RUN

ON

Operat ing Ou tput Sto p

Figure 7
20-5-4 STL2
RUN co mmand

RUN

STO1~ SCM1
st atus

ON

STO2~ SCM2
st atus

ON

S TO P

RUN

O FF ON

Drive out put
Operating O utp ut St op

Figure 8

20-6 New Error code for STO function
Present Fault Record
Second Most Recent Fault Record
Third Most Recent Fault Record
Fourth Most Recent Fault Record
Fifth Most Recent Fault Record
Sixth Most Recent Fault Record
Settings
72：Channel 1(STO1~SCM1)internal hardware error
76：STO(Safety Torque Off
77：Channel 2(STO2~SCM2)internal hardware error
78：Channel 1 and Channel 2 internal hardware error

Page 7/8

Error code

Name

76

STO
STL1
(STO1~SCM1)

72
77

STL2
(STO2~SCM2)

78

STL3

Description
Safety Torque Off function active
STO1~SCM1 internal hardware detect error
STO2~SCM2 internal hardware detect error
STO1~SCM1 and STO2~SCM2 internal
hardware detect error

The Old/New control board and Old/New I/O card: :
C2000
v1.12 control board + old I/O card(no STO function)
v1.12 control board + new I/O card(with STO function)
v1.20 control board + old I/O card(no STO function)
v1.20 control board + new I/O card(with STO function)

v1.12 firmware v1.20 firmware
OK
OK
Error
Error
Error
Error
Error

OK

Page 8/8

Appendix A. Publication History

Appendix A. Publication History
V1.12→V1.20
Explanations

Coverage
Add

STO (Safety Torque Off) Function

Chapter 4 – Wiring
Chapter 5 – Main Circuit Terminals
Chapter 6 – Control Terminals
Group 02 Parameters
Group 06 Parameters
Chapter 14 – Fault Codes and Descriptions
Chapter 20 – Safety Torque Off Function --- NEW

Parameters of PM Sensorless & Tuning Process

Group 00 Parameters (00-10),
Group 05 Parameters (05-00, 05-33),
Group 10 Parameters (10-42)

Mechanical Brake Check

Group 02 Parameters (MI=55; 02-56)

EMC-PG02L, EMC-PG02O, EMC-PG02U

Chapter 8

PLC Buffer

Group 04 Parameters (04-50~04-69)

Electronic Thermal Relay

Group 06 Parameters (06-13, 06-14, 06-27, 06-28)

Output Phase Loss

Group 06 Parameters (06-46, 06-47, 06-48)

Command of PLC as 0

Group 09 Parameters (09-33)

Revise
Ambient Temperature and Control Derating Curve

Chapter 2, Chapter 9, Group 06 Parameters

Block Diagrams of Different Speed Mode Control

Group 00 Parameters (00-10, 00-13)

Protection Password Parameter

Group 00 Parameters (00-08)

Mid-point Voltage & Frequency Factory Setting of High

Group 01 Parameters (01-03, 01-04, 01-06, 01-37,

Power Models (above 185kW)

01-38, 01-40)

Upper/Lower Limit of Output Frequency Curve Diagram

Group 01 Parameters (01-10, 01-11)

st

th

1 /4 Accel./Decel. Time Curve Diagram

Group 01 Parameters (01-23)

UP/DOWN Key Function Sequence Diagram

Group 02 Parameters (02-09, 02-10)

The Factory Setting of Induction Motor with No-load

Group 05 Parameters (05-05, 05-17)

Current and above 110kW.
Y-connection Switch Delay Diagram of Induction Motor

Group 05 Parameters (05-25)

Over-torque Detection TiME Diagram

Group 06 Parameters (06-07, 06-08, 06-10, 06-11)

IGBT OH Setting

Group 06 Parameters (06-15)

dEB Function

Group 06 Parametes (06-62), Group 07 Parameters
(07-13, 07-14)

PLC Functions

Chapter 16

A-1



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