Panasonic Air Conditioner CS TE12DKE S Te9 12dke
CS-TE9DKE to the manual 0da18d61-79c7-4a9a-a169-518849944812
User Manual: CS-TE12DKE
Open the PDF directly: View PDF 
.
Page Count: 80
1 Features 2
2 Functions 3
2.1. Remote Control 3
2.2. Indoor Unit 4
2.3. Outdoor unit 5
3 Product Specifications 6
4 Dimensions 10
4.1. Indoor Unit 10
4.2. Outdoor Unit 11
5 Refrigeration Cycle Diagram 12
6 Block Diagram 13
7 Wiring Diagram 14
7.1. CS-TE9DTE / CS-TE12DKE 14
© 2005 Matsushita Electric Industrial Co., Ltd. All
rights reserved. Unauthorized copying and
distribution is a violation of law.
CS-TE9DKE CU-TE9DKE
CS-TE12DKE CU-TE12DKE
7.2. CU-TE9DKE / CU-TE12DKE 15
8 Electronic Circuit Diagram 16
8.1. Indoor Unit / Remote Controller 16
8.2. Outdoor Unit 18
9 Operation Details 20
9.1. BASIC FUNCTION 20
9.2. Indoor Power Relay Control 21
9.3. Room Air Temperature Control (Compressor Control) 21
9.4. Airflow Direction Control 23
9.5. Quiet operation (Cooling Mode / Cooling area of Dry
Mode) 24
9.6. Indoor Fan Control 26
9.7. Powerful Operation 29
Air Conditioner
CONTENTS
Page Page
Order No. RAC0502005C2
9.8. Automatic Operation 30
9.9. Timer Operation (24H Real Timer) 31
9.10. Auto Restart Control 31
9.11. Ionizer Operation 32
9.12. Protection Control 33
10 Operating Instructions 34
11 Installation Instructions 40
11.1. SAFETY PRECAUTIONS 40
11.2. INDOOR UNIT 43
11.3. OUTDOOR UNIT 46
12 Installation and Servicing Air Conditioner Using R410A 49
12.1. OUTLINE 49
12.2. TOOLS FOR INSTALLING/SERVICING REFRIGERANT
PIPING 50
12.3. REFRIGERANT PIPING WORK 54
•
• •
• Product
−
− −
− Microcomputer-controlled compressor operating
frequency.
−
− −
− Vertical airflow direction.
−
− −
− Four modes of operation selection.
−
− −
− Air filter with function to reduce dust and smoke.
−
− −
− SUPER Alleru-buster filter inactive various harmful
airborne elements including allergens, viruses and
bacteria.
−
− −
− Ionizer control for generate negative ion in discharge air.
−
− −
− Quiet mode to provide quiet operation.
−
− −
− 24-hour timer setting.
−
− −
− Long installation piping up to 15 meters.
•
• •
• Quality Improvement
−
− −
− Random auto restart after power failure for safety restart
operation.
−
− −
− Gas leakage detection.
•
• •
• Serviceability
−
− −
− Removable and washable front panel.
−
− −
− Breakdown self diagnosis function.
•
• •
• Environmental Protection
−
− −
− Non-ozone depletion substances refrigerant (R410A).
12.4. INSTALLATION, TRANSFERRING, SERVICING 57
13 Servicing Information 61
13.1. About Lead Solder (PbF) 61
13.2. TROUBLESHOOTING 62
13.3. BREAKDOWN SELF DIAGNOSIS FUNCTION 64
13.4. DISASSEMBLY OF PARTS 66
14 Technical Data 74
14.1. Operation Characteristics 74
14.2. Sensible Capacity Chart 76
15 Exploded View and Replacement Parts List 77
15.1. Exploded View (Indoor Unit) 77
15.2. Replacement Parts List (Indoor Unit) 78
15.3. Exploded View (Outdoor Unit) 79
15.4. Replacement Parts List (Outdoor Unit) 80
1 Features
2
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
2 Functions
2.1. Remote Control
3
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
2.2. Indoor Unit
4
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
2.3. Outdoor unit
5
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
3 Product Specifications
Unit CS-TE9DKE CU-TE9DKE
Cooling Capacity kW
kcal/h
BTU/h
2.60 (0.60 - 3.00)
2,240 (520 - 2,580)
8,870 (2,050 - 10,200)
Heating Capacity kW
kcal/h
BTU/h
3.60 (0.60 - 5.30)
3,100 (520 - 4,560)
12,300 (2,050 - 18,100)
Moisture Removal l/h
Pint/h
1.5
(3.2)
Power Source Phase
V
Cycle
Single
230/240
50
Airflow Method OUTLET
INTAKE
SIDE VIEW TOP VIEW
Air Volume Indoor Air (Lo) m3/min (cfm) Cooling; 5.3 (190) —
Heating; 6.2 (220)
Indoor Air (Me) m3/min (cfm) Cooling; 7.2 (250) —
Heating; 8.4 (290)
Indoor Air (Hi) m3/min (cfm) Cooling; 9.2 (320) —
Heating; 10.5 (370)
dB (A) Cooling; High 39, Low 26 Cooling; 46
Heating; High 40, Low 27 Heating; 47
Noise Level
Power level dB Cooling; High 50 Cooling; High 59
Heating; High 51 Heating; High 60
Electrical Data Input W Cooling; 580 (120 - 720)
Heating; 845 (115 - 1,360)
Running Current ACooling; 2.7
Heating; 3.9
EER W/W (kcal/hw), BTU/hw Cooling; 4.48(3.86), 15.3
COP W/W (kcal/hw), BTU/hw Heating; 4.26 (3.67), 14.5
Starting Current A 3.9
Piping Connection Port
(Flare piping)
inch
inch
G ; Half Union 3/8”
L ; Half Union 1/4”
G ; 3-way valve 3/8”
L ; 2-way valve 1/4”
Pipe Size
(Flare piping)
inch
inch
G (gas side) ; 3/8”
L (liquid side) ; 1/4”
G (gas side) ; 3/8”
L (liquid side) ; 1/4”
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
Unit CS-TE9DKE CU-TE9DKE
Drain
Hose
Inner diameter mm 16 —
Length m 0.65 —
Power Cord Length
Number of core-wire
2.0 m
3-core wires × 1.0 mm2
—
—
Dimensions Height inch (mm) 11 - 23/32 (298) 21 - 1/4 (540)
Width inch (mm) 31 - 15/32 (799) 30 - 23/32 (780)
Depth inch (mm) 5 - 15/32 (139) 11 - 3/8 (289)
Net Weight lb (kg) 18 (8) 73 (33)
Compressor Type — Involute scroll
Motor Type —Brushless (4-poles)
Rated Output W — 750
Air Circulation Type Cross-flow Fan Propeller Fan
Material AS + Glass Fiber 30% P.P
Motor Type Transistor (8-poles) Transistor (8-poles)
Input W — —
Rate Output W 30 40
Fan Speed Lo (Cool/Heat) rpm 800 / 840 —
Me (Cool/Heat) rpm 1,000 / 1,040 —
Hi (Cool/Heat) rpm 1,200 / 1,270 790
Heat Exchanger Description Evaporator Condenser
Tube material Copper Copper
Fin material Aluminium (Pre Coat) Aluminium (Pre Coat)
Fin Type Slit Fin Corrugated Fin
Row / Stage (Plate fin configuration, forced draft)
2 rows / 11 stages,
1 row / 4 stages
2 rows / 24 stages
FPI 23 16.5
Size (W × H × L) mm 640 × 304 × 25.4 + 12.7 725.8
694.6
× 504 × 36.4
Refrigerant Control Device — Expansion valve
Refrigeration Oil (c.c) — RB68A (400)
Refrigerant (R410A) g (oz) — 960 (33.9)
Thermostat Electronic Control Electronic Control
Protection Device Electronic Control Electronic Control
Length mm — —
Capillary Tube Flow Rate l/min — —
Inner Diameter mm — —
Air Filter Material
Style
P.P.
Honeycomb
—
•
• •
• Specifications are subject to change without notice for further improvement.
7
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
Unit CS-TE12DKE CU-TE12DKE
Cooling Capacity kW
kcal/h
BTU/h
3.50 (0.60 - 4.00)
3,010 (520 - 3,440)
11,950 (2,050 - 13,600)
Heating Capacity kW
kcal/h
BTU/h
4.80 (0.60 - 6.50)
4,130 (520 - 5,590)
16,400 (2,050 - 22,200)
Moisture Removal l/h
Pint/h
2.0
(4.2)
Power Source Phase
V
Cycle
Single
230/240
50
Airflow Method OUTLET
INTAKE
SIDE VIEW TOP VIEW
Air Volume Indoor Air (Lo) m3/min (cfm) Cooling; 6.1 (210) —
Heating; 8.2 (290)
Indoor Air (Me) m3/min (cfm) Cooling; 7.9 (280) —
Heating; 9.5 (330)
Indoor Air (Hi) m3/min (cfm) Cooling; 9.9 (350) —
Heating; 10.9 (380)
dB (A) Cooling; High 42, Low 29 Cooling; 48
Heating; High 42, Low 33 Heating; 50
Noise Level
Power level dB Cooling; High 53 Cooling; High 61
Heating; High 53 Heating; High 63
Electrical Data Input W Cooling; 900 (120 - 1,160)
Heating; 1,320 (115 - 1,880)
Running Current ACooling; 4.2
Heating; 6.2
EER W/W (kcal/hw), BTU/hw Cooling; 3.89 (3.34), 13.3
COP W/W (kcal/hw), BTU/hw Heating; 3.64 (3.13), 12.4
Starting Current A 6.2
Piping Connection Port
(Flare piping)
inch
inch
G ; Half Union 1/2”
L ; Half Union 1/4”
G ; 3-way valve 1/2”
L ; 2-way valve 1/4”
Pipe Size
(Flare piping)
inch
inch
G (gas side) ; 1/2”
L (liquid side) ; 1/4”
G (gas side) ; 1/2”
L (liquid side) ; 1/4”
Drain
Hose
Inner diameter mm 16 —
Length m 0.65 —
Power Cord Length
Number of core-wire
2.0 m
3-core wires × 1.0 mm2
—
—
8
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
Unit CS-TE12DKE CU-TE12DKE
Dimensions Height inch (mm) 11 - 23/32 (298) 21 - 1/4 (540)
Width inch (mm) 31 - 15/32 (799) 30 - 23/32 (780)
Depth inch (mm) 5 - 15/32 (139) 11 - 3/8 (289)
Net Weight lb (kg) 18 (8) 75 (34)
Compressor Type — Involute scroll
Motor Type —Brushless (4-poles)
Rated Output W — 1100
Air Circulation Type Cross-flow Fan Propeller Fan
Material AS + Glass Fiber 30% P.P
Motor Type Transistor (8-poles) Transistor (8-poles)
Input W — 65.9
Rate Output W 30 40
Fan Speed Lo (Cool/Heat) rpm 880 / 1,100 —
Me (Cool/Heat) rpm 1,100 / 1,230 —
Hi (Cool/Heat) rpm 1,310 / 1,410 790
Heat Exchanger Description Evaporator Condenser
Tube material Copper Copper
Fin material Aluminium (Pre Coat) Aluminium (Pre Coat)
Fin Type Slit Fin Corrugated Fin
Row / Stage (Plate fin configuration, forced draft)
2 rows / 11 stages,
1 row / 4 stages
2 rows / 24 stages
FPI 21 16.5
Size (W × H × L) mm 640 × 304 × 25.4 + 12.7 725.8
694.6
× 504 × 36.4
Refrigerant Control Device — Expansion valve
Refrigeration Oil (c.c) — RB68A (400)
Refrigerant (R410A) g (oz) — 1,030 (36.3)
Thermostat Electronic Control Electronic Control
Protection Device Electronic Control Electronic Control
Length mm — —
Capillary Tube Flow Rate l/min — —
Inner Diameter mm — —
Air Filter Material
Style
P.P.
Honeycomb
—
•
• •
• Specifications are subject to change without notice for further improvement.
9
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
4 Dimensions
4.1. Indoor Unit
10
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
4.2. Outdoor Unit
11
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
5 Refrigeration Cycle Diagram
12
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
6 Block Diagram
13
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
7.1. CS-TE9DTE / CS-TE12DKE
7 Wiring Diagram
14
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
7.2. CU-TE9DKE / CU-TE12DKE
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
15
8 Electronic Circuit Diagram
8.1. Indoor Unit / Remote Controller
16
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
8.1.1. Printed Circuit Board
17
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
8.2. Outdoor Unit
18
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
8.2.1. Printed Circuit Board
19
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
9.1. BASIC FUNCTION
9 Operation Details
Inverter control, which equipped with a microcomputer in determining the most suitable operating mode as time passes,
automatically adjusts output power for maximum comfort always. In order to achieve the suitable operating mode, the
microcomputer maintains the set temperature by measuring the temperature of the environment and performing temperature
shifting. The compressor at outdoor unit is operating following the frequency instructed by the microcomputer at indoor unit that
judging the condition according to internal setting temperature and intake air temperature.
9.1.1. Internal Setting Temperature
Once the operation starts, remote control setting temperature will be taken as base value for temperature shifting processes.
These shifting processes are depending on the air conditioner settings and the operation environment. The final shifted value
will be used as internal setting temperature and it is updated continuously whenever the electrical power is supplied to the unit.
Table (a): Auto Operation Mode Setting
Mode Shift: Temperature Shift (°C)
Cooling/Soft Dry →Heating -2.0
Heating →Cooling/Soft Dry +2.0
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
•
• •
• [Intake Air Temp. - Remote Controller Setting Temp.] >
[Thermostat-OFF Temp. +0.5 °C]
Operated in corresponding frequency.
•
• •
• Frequency is decided after a completion of the starting
control (in 60 seconds).
•
• •
• When Room Temp. is below [Thermostat-OFF Temp.]
continuously for 3 minutes or more, it turns to Thermostat-
OFF operation.
Cooling Power TE9DKE TE12DKE
Intake Air Temp.
Difference (°C)
Maximum 2.7kW 4.0kW
Rated 2.5kW 3.6kW
Intermediate ~ ~
Minimum 0.8kW 0.8kW
(-1.00) OFF —- —-
Table (b): Outdoor Air Temperature Shifting
Mode: Outdoor Temperature, X (°C): Temperature Shift (°C)
TE9DKE TE12DKE
Cooling/Soft Dry 38 X 0.00 0.00
30 X 38 0.00 0.00
23 X 30 0.00 0.00
X 23 0.00 0.00
Heating 21 X 0.00 0.00
17 X 21 0.00 0.00
9 X 17 0.00 0.00
5 X 9 +0.50 +1.00
1 X 5 +1.00 +1.25
X 1 +1.50 +2.00
Table (c): Fan Speed Shifting
Mode: Fan Speed: Temperature Shift (°C)
Cooling All +1.25
Soft Dry All +1.0
Heating Lo +1.0
Hi, Me-, Me, Me+, Auto +0.25 (TE9DKE), +0.50
(TE12DKE)
Table (d): Start-Up Shifting
Mode within 60 Minutes from Start-up: Temperature Shift (°C)
Cooling/Soft Dry -1.0
Heating +2.0
9.2. Indoor Power Relay Control
The Power Relay turns on under the following conditions.
1. For three minutes, when plugged in the A/C or the Error Reset button on remote controller is pressed.
2. During Installation Check Mode and following for three minutes after checking.
3. During On-timer sampling and during Preliminary operation.
4. During Operation and following for three minutes after the operation is stopped.
5. During Auto Operation, Test run, Forced Heating or Odour Removal Operation and following for three minutes after the
operation is stopped.
9.3. Room Air Temperature Control (Compressor Control)
Operating frequency of a compressor is decided according to temperature differences between remote controller setting and
room temperatures. A relative method which gives frequency changes, based on the decided frequency, will provide you with
comfortable room environment that is not affected by operating conditions.
9.3.1. Cooling Operation
9.3.1.1. Thermostat Control
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
•
• •
• [Intake Air Temp. - Remote Controller Setting Temp.] >
[Thermostat-OFF Temp. +0.5 °C]
Operated in corresponding frequency.
•
• •
• Frequency is decided after a completion of the starting
control (in 60 seconds).
•
• •
• When Room Temp. is below [Thermostat-OFF Temp.]
continuously for 3 minutes or more, it turns to Thermostat-
OFF operation.
•
• •
• When room temperature almost comes to Thermostat-OFF
Temp., the operation turns to the Minimum power & fan
speed: SSLo.
•
• •
• [Intake Air Temp. - Remote Controller Setting Temp.] >
[Thermostat-OFF Temp. +0.5 °C]
Operated in corresponding frequency.
•
• •
• Frequency is decided after a completion of starting control
(in 60 seconds).
•
• •
• When Room Temp. is below Thermostat-OFF Temp.
continuously for 3 minutes or more, it turns to Thermostat-
OFF operation.
•
• •
• When room temperature almost comes to Thermostat-OFF
Temp., the operation turns to the Maximum power.
Dry Power TE9DKE TE12DKE
Intake Air Temp.
Difference (°C)
Maximum 2.7kW 4.0kW
Rated 2.5kW 3.6kW
Intermediate ~ ~
Minimum 0.8kW 0.8kW
(-2.50) OFF — —
Heating Power TE9DKE TE12DKE
Intake Air Temp.
Difference (°C)
OFF — —
Minimum 0.8kW 0.8kW
Intermediate ~ ~
Rated 3.5kW 4.5kW
(+1.00) Maximum 4.6kW 6.2kW
9.3.2. Dry Operation
9.3.2.1. Thermostat Control
9.3.3. Heating Operation
9.3.3.1. Thermostat Control
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
9.4. Airflow Direction Control
Vertical louver is controlled with Vertical Airflow Direction button on remote controller and by operation conditions, as shown in the
table below.
9.4.1. Vertical Airflow Louver Angle
Cooling and Dry Operations
Airflow Direction Auto Airflow Direction Setting
Manual Operation Vertical Auto Operation Powerful-ON
•
• •
• It swings when airflow direction is set with
remote controller.
•
• •
• It does not swing while indoor fan is
stopped. (It is fixed at the upper limit.).
•
• •
• The louver is fixed at five-level setting
position when the airflow direction is set with
remote controller.
Heating Operation
Airflow Direction Auto Airflow Direction Setting
Fixed by Heat Exchanger Temperature Powerful Operation Remote Control
•
• •
• When Heat Exchanger Temperature is less
than 33°C
•
• •
• When Heat Exchanger Temperature is
between 33°C (, incl.) and 127°C
•
• •
• When Heat Exchanger Temperature is less
than 33°C
•
• •
• When Heat Exchanger Temperature is
between 33°C (, incl.) and 127°C
•
• •
• The louver is fixed at five-level setting
position when the airflow direction is set with
remote controller.
Airflow Direction Auto Airflow Direction Setting
Odour Removal Control
•
• •
• The vertical louver is fully opened and move to the setting position when the unit is turned on with the remote controller.
•
• •
• The vertical louver remains open position when the unit is turned off during operation.
•
• •
• The horizontal louver is manually operated.
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
9.5. Quiet operation (Cooling Mode / Cooling area of Dry Mode)
A. Purpose
To provide quiet cooling operation compare to normal operation.
B. Control condition
a. Quiet operation start condition
•
• •
• When “quiet” button at remote control is pressed.
Quiet LED illuminates.
b. Quiet operation stop condition
1. When one of the following conditions is satisfied, quiet operation stops:
a. Powerful button is pressed.
b. Stop by OFF/ON switch.
c. Timer “off” activates.
d. When change mode to ION only mode.
2. When quiet operation is stopped, operation is shifted to normal operation with previous setting.
3. When fan speed is changed, quiet operation is shifted to quiet operation of the new fan speed.
4. When operation mode is changed, quiet operation is shifted to quiet operation of the new mode, except ION only mode.
5. During quiet operation, if timer “on” activates, quiet operation maintains.
6. After off, when on back, quiet operation is not memorised.
C. Control contents
1. Fan speed is changed from normal setting to quiet setting of respective fan speed.
This is to reduce sound of Hi, Me, Lo for 3dB.
2. Fan speed for quiet operation is -100 rpm from setting fan speed.
9.5.1. Quiet operation under Soft Dry operation (Dry area at Dry Mode)
Automatic Fan Speed (Dry operation)
Manual Fan Speed (Dry operation)
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
9.5.2. Quiet operation (Heating)
A. Purpose
To provide quiet heating operation compare to normal operation.
B. Control condition
a. Quiet operation start condition
•
• •
• When “quiet” button at remote control is pressed.
Quiet LED illuminates.
b. Quiet operation stop condition
1. When one of the following conditions is satisfied, quiet operation stops:
a. Powerful button is pressed.
b. Stop by OFF/ON switch.
c. Timer “off” activates.
d. When change mode to ION only mode.
2. When quiet operation is stopped, operation is shifted to normal operation with previous setting.
3. When fan speed is changed, quiet operation is shifted to quiet operation of the new fan speed.
4. When operation mode is changed, quiet operation is shifted to quiet operation of the new mode, except ION only mode.
5. During quiet operation, if timer “on” activates, quiet operation maintains.
6. After off, when on back, quiet operation is not memorised.
C. Control contents
a. Fan Speed manual
1. Fan speed is changed from normal setting to quiet setting of respective fan speed.
This is to reduce sound of Hi, Me, Lo for 3dB.
2. Fan speed for quiet operation is -100 rpm from setting fan speed.
3. Fan Speed Auto
•
• •
• If FM Lo
-100 rpm reduce from normal Heating Auto Fan Speed
•
• •
• If FM Lo
maintain RPM
Indoor FM RPM depends on Piping temp sensor of indoor heat exchanger.
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
9.6. Indoor Fan Control
9.6.1. Fan Motor Control
•
• •
• Fan speed is controlled according to operation conditions such as fan speed setting on the remote controller as shown in the
table below.
•
• •
• There is a different speed control from setting on the remote controller.
•
• •
• When Dry operation is selected, in the Cooling area, fan speed will be switched to one at Cooling mode and in the Dry area,
it will be switched to one at Dry mode.
•
• •
• Indoor fan operates in Quiet and Quiet Control indicated in the table below by pressing the QUIET button on the remote
controller.
CS-TE9DKE
Cooling and Dry Operations
Heating Operation
26
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
CS-TE12DKE
Cooling and Dry Operations
Heating Operation
27
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
9.6.2. Cooling Operation
1. Automatic Fan Speed
Odour Cut Control is equipped with this model. Fan is temporarily stopped for 40 seconds at the beginning of unit operation or
Thermostat-ON in order to wash away odour ingredients from heat exchanger with dehumidifying water.
Conditions of Control Starting
•
• •
• When Cooling fan speed is “Auto”,
•
• •
• When conditions other than Defrost control,
•
• •
• When indoor Pipe temperature is in the area shown in the figure below,
•
• •
• When operations other than Powerful operation,
Items to be controlled
According to Intake air - Setting temperature differences, indoor fan speed is adjusted by revolution speed correction of
automatic normal fan speed as shown in the graph below.
In addition, fan speed will be reduced to MIN rpm under the following conditions:
•
• •
• Neural control stability
•
• •
• [Intake air temp. - Indoor Pipe Temp.] < 13 °C
•
• •
• Operating frequency < 25 Hz
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
•
• •
• Airflow direction, Fan speed and Setting temperature are
optimized.
•
• •
• “Intake Air temperature - Remote controller setting
temperature” is detected every 20 seconds by indication
from indoor unit and controlled to each area.
Quick Cooling →Unit forcibly turns to Quick Cooling operation
for 5 minutes after POWERFUL ON even through it is in the
stable area. If unit gets out of the Quick Cooling area, it turns
to Chilly Cooling operation.
Chilly Cooling →Discharge Air temperature is kept low by
changing fan speed according to room temperature and chilly
feeling is produced.
2. Maximum Cooling Power
When cooling load is big, if fan speed: “SHi” and temp: 16 °C are set, fan speed will be increased for 30 minutes after operation
starts in order to decrease room temperature quickly. (Refer to “Indoor fan speed control” for each model.)
3. Dew Condensation Prevention Control
Fan speed will be reduced if Dew Condensation Prevent Control is operated.
4. Forced Cooling Operation
Fan speed at Forced Cooling operation with the Emergency Operation button is “Hi”. (Refer to "Indoor fan speed control" for
each model.)
5. Emergency Operation
Fan speed when operation with the Emergency Operation button or Cooling operation with remote controller during
performance of breakdown diagnosis (breakdown that emergency operation is possible) is “ Me+”. (Refer to "Indoor fan speed
control" for each model.)
9.6.3. Dry Operation
1. Basic Fan Speed
In the cooling mode area, fan operates in the same speed as cooling operation mode. In the dry mode area, it is switched to
"SLo". (Refer to "Indoor fan speed control" for each model.) In the Thermostat-OFF mode, fan stops for 5.5 minutes and after
that, operates at a speed of level 3.
2. Automatic Fan Speed
Odour Cut Control functions and fan operates repeatedly between the 60-second stop and the 30-second “SLo” operations. In
the beginning of unit operation and Thermostat-ON, fan stops for 40 seconds.
9.6.4. Heating Operation
1. Hot Start & Cold Draft
When Indoor Exchanger Temperature is low at the beginning of the operation, fan is stopped. Cold Draft is prevented by
increased Exchanger temperature in proportion to fan speed.
2. Auto Fan Speed
In Auto Fan Speed, fan speed is controlled according to Exchanger temperature. (Refer to "Indoor fan speed control" for each
model.)
3. Forced Heating Operation
Fan speed at Forced Heating operation with the Emergency Operation button is "Hi". (Refer to "Indoor fan speed control" for
each model.)
4. Fan speed when operation with the Emergency Operation button or Heating operation with remote controller during
performance of breakdown diagnosis (breakdown that emergency operation is possible) is " Me+". (Refer to "Indoor fan speed
control" for each model.)
9.7. Powerful Operation
If the POWERFUL button is pressed during operating in Cooling, Heating, Dry or AUTO, unit always forces to operate
respectively in Quick Cooling, Dry and Quick Heating for 5 minutes, which fan speed is "SHi" even though unit is in each stable
area.
9.7.1. Cooling Operation
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•
• •
• Airflow direction, Fan speed and Setting temperature are
optimized.
•
• •
• “Intake Air temperature - Remote controller setting
temperature” is detected every 20 seconds by indication
from indoor unit and controlled to each area.
Quick Dry →Unit forcibly turns to Quick Dry operation for 5
minutes after POWERFUL ON even through it is in the stable
area. If unit gets out of the area, it turns to Chilly Dry operation.
Chilly Dry →Discharge Air temperature is kept low by
changing fan speed according to room temperature and chilly
feeling is produced.
•
• •
• Airflow direction, Fan speed and Setting temperature are
optimized.
•
• •
• “Intake Air temperature - Remote controller setting
temperature” is detected every 20 seconds by indication
from indoor unit and controlled to each area.
Quick Heating →Unit forcibly turns to Quick Heating operation
for 5 minutes after POWERFUL ON even through it is in the
stable area. If unit gets out of the area, it turns to Warm Heating
operation.
Warm Heating →Discharge Air temperature is kept high by
changing fan speed according to room temperature and warm
feeling is produced.
9.7.2. Dry Operation
9.7.3. Heating Operation
9.8. Automatic Operation
•
• •
• Operation mode (Cooling, Dry and Heating) is automatically selected.
•
• •
• Operation mode is selected at the beginning of unit operation and every 30 minutes. Temperature, Fan speed and Airflow
directions are set with remote controller.
9.8.1. Operation Mode Selection
Operation mode is selected according to outdoor temperature, intake air temperature and setting temperature.
1. "Heating" is selected when intake air temperature is below 16 °C.
2. "Cooling" is selected when intake air temperature is 25 °C or more. (But, when intake air temperature is 16 °C or more.)
3. Selectable range of "Heating" and "Cooling" for setting temperature on the remote controller is increased when outside air
temperature is below 25 °C.
9.8.2. Setting Temperature Shift in Automatic Operation
•
• •
• When Cooling mode is selected, setting temperature is shifted to +1 °C.
•
• •
• When Heating mode is selected, setting temperature is shifted to -1 °C.
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Preliminary operation
•
• •
• Unit operates preliminarily until room temperature
reaches setting temperature on ON-timer setting time.
Preliminary operation times are as shown in the table
below.
•
• •
• Indoor and outdoor fans operate for 30 seconds in 70
minutes before setting time and sampling of outdoor air
and intake air temperatures is performed.
•
• •
• Fan speed and airflow directions in preliminary
operation are based on remote controller setting. (Same
condition as in normal operation.)
•
• •
• In preliminary operation, deicing judgment is performed
after heating operated for 15 minutes in 50 minutes
before setting ON-time. This is because it makes start-
up time short when outdoor air temperature is extremely
low in midwinter.
Deicing Judgment: Deicing operation (Max. 12 minutes)
will be performed when outdoor air temperature is below
0°C, if outdoor heat exchanger temperature of below 0°C
continues for 14 minutes and below -8°C continues for 10
minutes or more.
Preliminary operation in Cooling or Dry mode
Outdoor Air
Temperature
Intake Air
Temperature
Warming-up Operation
Starting Time
35 °C or more — Before 15 min.
— 30 °C or more Before 15 min.
30 - 35 °C 25 - 30 °C Before 10 min.
Below 30 °C Below 25 °C Before 5 min.
Preliminary operation in Heating mode
Outdoor Air
Temperature
Intake Air
Temperature
Warming-up Operation
Starting Time
5 °C or more — Before 40 min.
— 15 °C or more Before 40 min.
0-5°C 5 - 15 °C Before 45 min.
Below 0 °C Below 5 °C Before 50 min.
9.9. Timer Operation (24H Real Timer)
•
• •
• On-timer and OFF-timer can be set simultaneously.
•
• •
• Both On-timer and OFF-timer functions operate until they are canceled. (Excluding when power supplying condition is bad.)
An example of ON-timer operation
An example of OFF-timer operation
9.10. Auto Restart Control
1. When the power supply is cut off during the operation of air conditioner, the compressor will re-operate within three to four
minutes (there are 10 patterns between 2 minutes 58 seconds and 3 minutes 52 seconds to be selected randomly) after power
supply resumes.
2. This type of control is not applicable during ON/OFF Timer setting.
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
Display and operation for the Negative Ion Generator remain
unchanged for ION only operation and simultaneous ION
operation.
Refer to the ION operation described below.
9.11. Ionizer Operation
9.11.1. Negative Ion Generator
Single blinking of the ION LED does not indicate Breakdown.
•
• •
• When unit was operated under the condition that a discharge insulation of the Ion Cleaning equipment is deteriorated (Dust,
Attached water, etc.):
1.
If the insulation deterioration of the unit discharge part is small;
When air cleaning abnormal status is detected in 1 minute or more from the unit starts operating, the unit is OFF for 10
minutes.
↑↓ (The ION LED and CLEAN monitor light up.)
The unit is ON in 5 minutes. (Repeating)
2.
If the insulation deterioration of the unit discharge part is big;
When air cleaning abnormal status is detected within 1 minute from the unit starts operating, the unit is shut OFF
immediately and the ION LED blinks.
3.
If the insulation of the Ionizer is deteriorated;
When abnormal status is detected, the unit is OFF for 30 minutes. When abnormal status is detected 25 times, the
operation stops and the ION LED blinks. (It will be reset if normal status continues for 10 minutes before reaching 25
times.)
To cancel it, stop the operation while the ION LED is blinking.
Note: Set ION Air Cleaning operation again because it is canceled when re-operated.
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9.12. Protection Control
9.12.1. Time Delay Safety Control
1. The compressor will not start for two minutes after stop of operation.
2. This control is not applicable if the power supply is cut off and on again or after 4-way valve deices condition.
9.12.2. 30 Seconds Forced Operation
1. Once the compressor starts operation, it will not stop its operation for 30 minutes.
2. However, it can be stopped by using remote control or Auto Switch at indoor unit.
* The other Protection controls are shown in “9.3.2 Protection Control from Overload Cooling & Dry Operation” and “9.3.3
Protection Control from Overload Heating Operation“.
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10 Operating Instructions
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
11 Installation Instructions
Required tools for Installation Works
1. Philips screw driver 5. Spanner 9. Gas leak detector 13. Multimeter
2. Level gauge 6. Pipe cutter 10. Measuring tape 14. Torque wrench
18 N.m (1.8 kgf.m)
42 N.m (4.2 kgf.m)
55 N.m (5.5 kgf.m)
3. Electric drill, hole core drill
(ø70 mm)
7. Reamer 11. Thermometer 15. Vacuum pump
4. Hexagonal wrench (4 mm) 8. Knife 12. Megameter 16. Gauge manifold
11.1. SAFETY PRECAUTIONS
•
• •
• Read the following “SAFETY PRECAUTIONS” carefully before installation.
•
• •
• Electrical work must be installed by a licensed electrician. Be sure to use the correct rating of the power plug and main circuit
for the model to be installed.
•
• •
• The caution items stated here must be followed because these important contents are related to safety. The meaning of each
indication used is as below. Incorrect installation due to ignoring of the instruction will cause harm or damage, and the
seriousness is classified by the following indications.
This indication shows the possibility of causing death or serious injury.
This indication shows the possibility of causing injury or damage to properties only.
The items to be followed are classified by the symbols:
Symbol with background white denotes item that is PROHIBITED from doing.
•
• •
• Carry out test running to confirm that no abnormality occurs after the installation. Then, explain to user the operation, care and
maintenance as stated in instructions. Please remind the customer to keep the operating instructions for future reference.
1. Engage dealer or specialist for installation. If installation done by the user is defective, it will cause water leakage, electrical shock or fire.
2. Install according to this installation instruction strictly. If installation is defective, it will cause water leakage, electrical shock or fire.
3. Use the attached accessories parts and specified parts for installation. Otherwise, it will cause the set to fall, water leakage, fire or
electrical shock.
4. Install at a strong and firm location which is able to withstand the set’s weight. If the strength is not enough or installation is not properly
done, the set will drop and cause injury.
5. For electrical work, follow the local national wiring standard, regulation and this installation instruction. An independent circuit and single
outlet must be used. If electrical circuit capacity is not enough or defect found in electrical work, it will cause electrical shock or fire.
6. Use the specified cable (1.5 mm2) and connect tightly for indoor/outdoor connection. Connect tightly and clamp the cable so that no
external force will be acted on the terminal. If connection or fixing is not perfect, it will cause heat-up or fire at the connection.
7. Wire routing must be properly arranged so that control board cover is fixed properly. If control board cover is not fixed perfectly, it will
cause heat-up at connection point of terminal, fire or electrical shock.
8. When carrying out piping connection, take care not to let air substances other than the specified refrigerant go into refrigeration cycle.
Otherwise, it will cause lower capacity, abnormal high pressure in the refrigeration cycle, explosion and injury.
9. Do not damage or use unspecified power supply cord. Otherwise, it will cause fire or electrical shock.
10. Do not modify the length of the power supply cord or use of the extension cord, and do not share the single outlet with
other electrical appliances. Otherwise, it will cause fire or electrical shock.
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
1. The equipment must be earthed and installed with earth leakage breaker. It may cause electrical shock if grounding is not perfect.
2. Do not install the unit at place where leakage of flammable gas may occur. In case gas leaks and accumulates at
surrounding of the unit, it may cause fire.
3. Carry out drainage piping as mentioned in installation instructions. If drainage is not perfect, water may enter the room and damage the
furniture.
1. Selection of the installation location.
Select an installation location which is rigid and strong enough to support or hold the unit, and select a location for easy maintenance.
2. Power supply connection to the room air conditioner.
Connect the power supply cord of the room air conditioner to the mains using one of the following method.
Power supply point shall be the place where there is ease for access for the power disconnection in case of emergency.
In some countries, permanent connection of this room air conditioner to the power supply is prohibited.
1. Power supply connection to the receptacle using a power plug.
Use an approved 15A/16A power plug with earth pin for the connection to the socket.
2. Power supply connection to a circuit breaker for the permanent connection. Use an approved 15A circuit breaker for the permanent
connection. It must be a double pole switch with a minimum 3 mm contact gap.
3. Do not release refrigerant.
Do not release refrigerant during piping work for installation, reinstallation and during repairing a refrigeration parts. Take care of the
liquid refrigerant, it may cause frostbite.
4. Installation work.
It may need two people to carry out the installation work.
5. Do not install this appliance in a laundry room or other location where water may drip from the ceiling, etc.
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Applicable piping kit
CZ-3F5, 7BP (CS-TE9DKE)
CZ-4F5, 7, 10BP (CS-TE12DKE)
SELECT THE BEST LOCATION
INDOOR UNIT
•
• •
• There should not be any heat source or steam near the
unit.
•
• •
• There should not be any obstacles blocking the air
circulation.
•
• •
• A place where air circulation in the room is good.
•
• •
• A place where drainage can be easily done.
•
• •
• A place where noise prevention is taken into
consideration.
•
• •
• Do not install the unit near the door way.
•
• •
• Ensure the spaces indicated by arrows from the wall,
ceiling, fence or other obstacles.
•
• •
• Recommended installation height for indoor unit shall be
at least 2.5 m.
OUTDOOR UNIT
•
• •
• If an awning is built over the unit to prevent direct
sunlight or rain, be careful that heat radiation from the
condenser is not obstructed.
•
• •
• There should not be any animal or plant which could be
affected by hot air discharged.
•
• •
• Keep the spaces indicated by arrows from wall, ceiling,
fence or other obstacles.
•
• •
• Do not place any obstacles which may cause a short
circuit of the discharged air.
•
• •
• If piping length is over the common length, additional
refrigerant should be added as shown in the table.
Indoor/Outdoor Unit Installation Diagram
•
• •
• This illustration is for explanation purposes only.
The indoor unit will actually face a different way.
Attached accessories
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11.2.1. SELECT THE BEST LOCATION
(Refer to “Select the best location”
section)
11.2.2. HOW TO FIX INSTALLATION
PLATE
The mounting wall is strong and solid enough to prevent it from
the vibration.
The centre of installation plate should be at more than 450 mm
at right of the wall.
The centre of installation plate should be at more than 450 mm
at left of the wall.
The distance from installation plate edge to ceiling should more
than 66 mm.
From installation plate left edge to unit’s left side is 20 mm.
From installation plate right edge to unit’s right is 70 mm.
:
:
:
For left side piping, piping connection for liquid should be
this line.
For left side piping, piping connection for gas should be
about 50 mm from this line.
For left side piping, piping connecting cable should be
about 750 mm from this line.
1. Mount the installation plate on the wall with 5 screws or
more.
(If mounting the unit on the concrete wall, consider using
anchor bolts.)
•
• •
• Always mount the installation plate horizontally by
aligning the marking-off line with the thread and using a
level gauge.
2. Drill the piping plate hole with ø70 mm hole-core drill.
•
• •
• The centre of the right piping hole is at the intersection
of lines extending vertically from the edge of the
installation plate and horizontally from the sideways
arrow on the installation plate. (see figure above.)
•
• •
• The centre of the left piping hole is at the intersection of
lines extending vertically from the downward arrow on
the installation plate and horizontally from the sideways
arrow on the installation plate. (see figure above.)
•
• •
• Drill the piping hole at either the right or the left and the
hole should be slightly slanted to the outdoor side.
11.2.3. TO DRILL A HOLE IN THE WALL
AND INSTALL A SLEEVE OF
PIPING
1. Insert the piping sleeve to the hole.
2. Fix the bushing to the sleeve.
3. Cut the sleeve until it extrudes about 15 mm from the wall.
Caution
When the wall is hollow, please be sure to use the
sleeve for tube ass’y to prevent dangers caused by
mice biting the connecting cable.
4. Finish by sealing the sleeve with putty or caulking
compound at the final stage.
11.2.4. INDOOR UNIT INSTALLATION
1.
For the right rear piping
2.
For the right and right bottom piping
11.2. INDOOR UNIT
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
3.
For the embedded piping
(This can be used for left rear piping & left bottom piping also.)
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11.2.5. CONNECT THE CABLE TO THE
INDOOR UNIT
1. The inside and outside connecting cable can be connected
without removing the front grille.
2. Connecting cable between indoor unit and outdoor unit
shall be approved polychloroprene sheathed 4 × 1.5 mm2
flexible cord, type designation 245 IEC 57 (H05RN-F) or
heavier cord.
•
• •
• Ensure the color of wires of outdoor unit and the
terminal Nos. are the same to the indoor’s respectively.
•
• •
• Earth lead wire shall be longer than the other lead wires
as shown in the figure for the electrical safety in case of
the slipping out of the cord from the anchorage.
•
• •
• Secure the cable onto the control board with the holder
(clamper).
INSTALLATION OF SUPER ALLERU-BUSTER FILTER
1. Open the front panel.
2. Remove the air filters.
3. Put Super Alleru-buster filter into place as shown in
illustration below.
HOW TO TAKE OUT FRONT GRILLE
Please follow the steps below to take out front grille if
necessary such as when servicing.
1. Set the vertical airflow direction louver to the horizontal
position.
2. Slide down the two caps on the front grille as shown in the
illustration below, and then remove the two mounting
screws.
3. Pull the lower section of the front grille towards you to
remove the front grille.
Caution
When reinstalling the front grille, first set the vertical
airflow direction louver to the horizontal position and
then carry out above steps 2 - 3 in the reverse order.
AUTO SWITCH OPERATION
The below operations will be performed by pressing the
“AUTO” switch.
1. AUTO OPERATION MODE
The Auto operation will be activated immediately once the
Auto Switch is pressed.
2. TEST RUN OPERATION (FOR PUMP DOWN/SERVICING
PURPOSE)
The Test Run operation will be activated if the Auto Switch
is pressed continuously for more than 5 sec. to below 8 sec.
A “pep” sound will occur at the fifth sec., in order to identify
the starting of Test Run operation.
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
11.3.1. SELECT THE BEST LOCATION
(Refer to “Select the best location”
section)
11.3.2. INSTALL THE OUTDOOR UNIT
•
• •
• After selecting the best location, start installation according
to Indoor/Outdoor Unit Installation Diagram.
1. Fix the unit on concrete or rigid frame firmly and horizontally
by bolt nut. (ø10 mm).
2. When installing at roof, please consider strong wind and
earthquake. Please fasten the installation stand firmly with
bolt or nails.
11.3.3. CONNECTING THE PIPING
Connecting The Piping To Indoor Unit
Please make flare after inserting flare nut (locate at joint portion
of tube assembly) onto the copper pipe. (In case of using long
piping)
Connect the piping
•
• •
• Align the center of piping and sufficiently tighten the flare
nut with fingers.
•
• •
• Further tighten the flare nut with torque wrench in specified
torque as stated in the table.
MODEL Piping size (Torque)
Gas Liquid
TE9CK 3/8” (42 N.m) 1/4” (18 N.m)
TE12CK 1/2” (55 N.m) 1/4” (18 N.m)
Connecting The Piping To Outdoor Unit
Decide piping length and then cut by using pipe cutter. Remove
burrs from cut edge. Make flare after inserting the flare nut
(located at valve) onto the copper pipe.
Align center of piping to valves and then tighten with torque
wrench to the specified torque as stated in the table.
Cutting And Flaring The Piping
1. Please cut using pipe cutter and then remove the burrs.
2. Remove the burrs by using reamer. If burrs is not
removed, gas leakage may be caused.
Turn the piping end down to avoid the metal powder
entering the pipe.
3. Please make flare after inserting the flare nut onto the
copper pipes.
11.3. OUTDOOR UNIT
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11.3.4. EVACUATION OF THE EQUIPMENT (FOR EUROPE & OCEANIA DESTINATION)
WHEN INSTALLING AN AIR CONDITIONAL, BE SURE TO EVACUTE THE AIR INSIDE THE INDOOR UNIT AND PIPES in
the following procedure.
1. Connect a charging hose with a push pin to the Low and High side of a charging set and the service port of the 3-way valve.
•
• •
• Be sure to connect the end of the charging hose with the push pin to the service port.
2. Connect the center hose of the charging set to a vacuum pump with check valve, or vacuum pump and vacuum pump adaptor.
3. Turn on the power switch of the vacuum pump and make sure that the needle in the gauge moves form 0 cmHg (0 MPa) to -
76cm Hg (-0.1 MPa). Then evacuate the air approximately 15 minutes.
4. Close the Low and High side valve of the charging set the turn off the vacuum pump. Make sure that the needle in the gauge
does not move after approximately 5 minutes.
Note: BE SURE TO FOLLOW THIS PROCEDURE INORDER IN ORDER TO AVOID REFRIGERANT GAS LEAKAGE.
5. Disconnect the charging hose from vacuum pump and from the service port of the 3-way valve.
6. Tighten the service port caps of the 3-way valve at a torque of 18 N.m with a torque wrench.
7. Remove the valve caps of both of the 2-way valve and 3-way valve. Position both of the valves to “OPEN” using a hexagonal
wrench (4 mm).
8. Mount valve caps onto the 2-way valve and the 3-way valve.
•
• •
• Be sure to check for gas leakage.
Caution
•
• •
• If gauge needle does not move from 0 cmHg (0 MPa) to -76 cmHg (-0.1 MPa), in step 3 above take the following measure:
•
• •
• If the leag stops when the piping connections are tightened further, continue working form step 3.
•
• •
• If the leak does not stop when the connections are retightened, repair the location of leak.
•
• •
• Do not release refrigerant during piping work for installation and reinstallation. Take care of the liquid refrigerant, it may cause
frostbite.
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11.3.5. CONNECT THE CABLE TO THE
OUTDOOR UNIT
1. Remove the control board cover from the unit by loosening
the screw.
2. Connecting cable between indoor unit and outdoor unit
shall be approved polychloroprene sheathed 4 × 1.5 mm2
flexible cord, type designation 245 IEC 57 (H05RN-F) or
heavier cord.
3. Secure the cable onto the control board with the holder
(clamper).
4. Attach the control board cover back in its original position
with the screw.
11.3.6. PIPE INSULATION
1. Please carry out insulation at pipe connection portion as
mentioned in Indoor/Outdoor Unit Installation Diagram.
Please wrap the insulated piping end to prevent water from
going inside the piping.
2. If drain hose or connecting piping is in the room (where dew
may form), please increase the insulation by using POLY-E
FOAM with thickness 6 mm or above.
DISPOSAL OF OUTDOOR UNIT DRAIN WATER
•
• •
• If a drain elbow is used, the unit should be placed on a
stand which is taller than 3 cm.
•
• •
• If the unit is used in an area where temperature falls below
0°C for 2 or 3 days in succession, it is recommended not to
use a drain elbow, for the drain water freezes and the fan
will not rotate.
CHECK THE DRAINAGE
•
• •
• Open front panel and remove air filters.
(Drainage checking can be carried out without removing the
front grille.)
•
• •
• Pour a glass of water into the drain tray-styrofoam.
•
• •
• Ensure that water flows out from drain hose of the indoor
unit.
EVALUATION OF THE PERFORMANCE
•
• •
• Operate the unit at cooling operation mode for fifteen
minutes or more.
•
• •
• Measure the temperature of the intake and discharge air.
•
• •
• Ensure the difference between the intake temperature and
the discharge is more than 8°C.
CHECK ITEMS
Is there any gas leakage at flare nut connection?
Has the heat insulation been carried out at flare nut
connection?
Is the connecting cable being fixed to terminal board firmly?
Is the connecting cable being clamped firmly?
Is the drainage OK?
(Refer to “Check the drainage” section)
Is the earth wire connection properly done?
Is the indoor unit properly hooked to the installation plate?
Is the power supply voltage complied with rated value?
Is there any abnormal sound?
Is the cooling operation normal?
Is the thermostat operation normal?
Is the remote control’s LCD operation normal?
Is the air purifying filter installed?
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12 Installation and Servicing Air Conditioner Using R410A
12.1. OUTLINE
12.1.1. About R410A Refrigerant
1. Converting air conditioners to R410A
Since it was declared in1974 that chlorofluorocarbons (CFC), hydro chlorofluorocarbons (HCFC) and other substances pose a
destructive danger to the ozone layer in the earth’s upper stratosphere (20 to 40 km above the earth), measures have been
taken around the world to prevent this destruction.
The R22 refrigerant which has conventionally been used in ACs is an HCFC refrigerant and, therefore, possesses this ozone-
destroying potential. International regulations (the Montreal Protocol on Ozone-Damaging Substances) and the domestic laws
of various countries call for the early substitution of R22 by a refrigerant which will not harm the ozone layer.
•
• •
• In ACs, the HFC refrigerant which has become the mainstream alternative is called R410A. Compared with R22, the
pressure of R410A is approximately 1.6 times as high at the same refrigerant temperature, but the energy efficiency is about
the same. Consisting of hydrogen (H), fluorine (F) and carbon (C), R410A is an HFC refrigerant. Another typical HFC
refrigerant is R407C. While the energy efficiency of R407C is somewhat inferior to that of R410A, it offers the advantage
of having pressure characteristics which are about the same as those of R22, and is used mainly in packaged ACs.
2. The characteristics of HFC (R410A) refrigerants
a. Chemical characteristics
The chemical characteristics of R410A are similar to those of R22 in that both are chemically stable, non-flammable
refrigerants with low toxicity.
However, just like R22, the specific gravity of R410A gas is heavier than that of air. Because of this, it can cause an oxygen
deficiency if it leaks into a closed room since it collects in the lower area of the room. It also generates toxic gas when it is
directly exposed to a flame, so it must be used in a well ventilated environment where it will not collect.
Table 1 Physical comparison of R410A and R22
R410A R22
Composition (wt%) R32/R125 (50/50) R22 (100)
Boiling point (°C) -51.4 -40.8
Vaporizing pressure (25°C) 1.56 Mpa (15.9 kgf/cm2) 0.94 Mpa (9.6 kgf/cm2)
Saturated vapor density 64.0 kg/m344.4 kg/m3
Flammability Non-flammable Non-flammable
Ozone-destroying point (ODP) 0 0.055
Global-warming point (GWP) 1730 1700
b. Compositional change (pseudo-azeotropic characteristics)
R410A is a pseudo-azeotropic mixture comprising the two components R32 and R125. Multi-component refrigerants with
these chemical characteristics exhibit little compositional change even from phase changes due to vaporization (or
condensation), which means that there is little change in the circulating refrigerant composition even when the refrigerant
leaks from the gaseous section of the piping.
Accordingly, R410A can be handled in almost the same manner as the single-component refrigerant R22. However, when
charging, because there is a slight change in composition between the gas phase and the liquid phase inside a cylinder or
other container, charging should basically begin with the liquid side.
c. Pressure characteristics
As seen in Table 2, the gas pressure of R410A is approximately 1.6 times as high as that of R22 at the same refrigerant
temperature, which means that special R410A tools and materials with high-pressure specifications must be used for all
refrigerant piping work and servicing.
Table 2 Comparison of R410A and R22 saturated vapor density
Unit: MPa
Refrigerant Temperature (°C) R410A R22
-20 0.30 0.14
0 0.70 0.40
20 1.35 0.81
40 2.32 1.43
60 3.73 2.33
65 4.15 2.60
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d. R410A refrigerating machine oil
Conventionally, mineral oil or a synthetic oil such as alkylbenzene has been used for R22 refrigerating machine oil. Because
of the poor compatibility between R410A and conventional oils like mineral oil, however, there is a tendency for the
refrigerating machine oil to collect in the refrigerating cycle. For this reason, polyester and other synthetic oils which have
a high compatibility with R410A are used as refrigerating machine oil.
Because of the high hygroscopic property of synthetic oil, more care must be taken in its handling than was necessary with
conventional refrigerating machine oils. Also, these synthetic oils will degrade if mixed with mineral oil or alkylbenzene,
causing clogging in capillary tubes or compressor malfunction. Do not mix them under any circumstances.
12.1.2. Safety Measures When Installing/Servicing Refrigerant Piping
Cause the gas pressure of R410A is approximately 1.6 times as high as that of R22, a mistake in installation or servicing could
result in a major accident. It is essential that you use R410A tools and materials, and that you observe the following precautions
to ensure safety.
1. Do not use any refrigerant other than R410A in ACs that have been used with R410A.
2. If any refrigerant gas leaks while you are working, ventilate the room. Toxic gas may be generated if refrigerant gas is exposed
to a direct flame.
3. When installing or transferring an AC, do not allow any air or substance other than R410A to mix into the refrigeration cycle. If
it does, the pressure in the refrigeration cycle can become abnormally high, possibly causing an explosion and/or injury.
4. After finishing the installation, check to make sure there is no refrigerant gas leaking.
5. When installing or transferring an AC, follow the instructions in the installation instructions carefully. Incorrect installation can
result in an abnormal refrigeration cycle or water leakage, electric shock, fire, etc.
6. Do not perform any alterations on the AC unit under any circumstances. Have all repair work done by a specialist. Incorrect
repairs can result in a water leakage, electric shock, fire, etc.
12.2. TOOLS FOR INSTALLING/SERVICING REFRIGERANT PIPING
12.2.1. Necessary Tools
In order to prevent an R410A AC from mistakenly being charged with any other refrigerant, the diameter of the 3-way valve service
port on the outdoor unit has been changed. Also, to increase its ability to withstand pressure, the opposing dimensions have been
changed for the refrigerant pipe flaring size and flare nut. Accordingly, when installing or servicing refrigerant piping, you must have
both the R410A and ordinary tools listed below.
Table 3 Tools for installation, transferring or replacement
Type of work Ordinary tools R410A tools
Flaring Flaring tool (clutch type), pipe cutter,
reamer
Copper pipe gauge for clearance
Adjustment, flaring tool (clutch type)*1)
Bending, connecting pipes Torque wrench (nominal diameter 1/4,
3/8,1/2). Fixed spanner (opposing sides
12 mm, 17 mm, 19 mm). Adjustable
wrench, Spring bender
Air purging Vacuum pump. Hexagonal wrench
(opposing sides 4 mm)
Manifold gauge, charging hose, vacuum
pump adaptor
Gas leak inspection Gas leak inspection fluid or soapy water Electric gas leak detector for HFC
refrigerant*2)
*1) You can use the conventional (R22) flaring tool. If you need to buy a new tool, buy the R410A type.
*2) Use when it is necessary to detect small gas leaks.
For other installation work, you should have the usual tools, such as screwdrivers (+,-), a metal-cutting saw, an electrical drill, a hole
core drill (65 or 70 dia.), a tape measure, a level, a thermometer, a clamp meter, an insulation tester, a voltmeter, etc.
Table 4 Tools for serving
Type of work Ordinary tools R410A tools
Refrigerant charging Electronic scale for refrigerant charging.
Refrigerant cylinder. Charging orifice and
packing for refrigerant cylinder
Brazing (Replacing refrigerating cycle
part*1)
Nitrogen blow set (be sure to use nitrogen
blowing for all brazing), and brazing
machine
*1) Always replace the dryer of the outdoor unit at the same time. The replacement dryer is wrapped in a vacuum pack. Replace
it last among the refrigerating cycle parts. Start brazing as soon as you have opened the vacuum pack, and begin the vacuuming
operation within 2 hours.
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12.2.2. R410A Tools
1. Copper tube gauge for clearance adjustment
(used when flaring with the conventional flaring tool (clutch
type))
•
• •
• This gauge makes it easy to set the clearance for the
copper tube to 1.0-1.5 mm from the clamp bar of the
flaring tool.
2. Flaring tool (clutch type)
•
• •
• In the R410A flaring tool, the receiving hole for the
clamp bar is enlarged so the clearance from the clamp
bar can be set to 0-0.5 mm, and the spring inside the
tool is strengthened to increase the strength of the pipe-
expanding torque. This flaring tools can also be used
with R22 piping, so we recommend that you select it if
you are buying a new flaring tool.
3. Torque wrenches
4. Manifold gauge
Fig. 1 Copper tube gauge for clearance adjustment
Fig. 2 Flaring tool (clutch type)
Fig. 3 Torque wrenches
Table 5
Conventional wrenches R410A wrenches
For 1/4 (opposite side x torque) 17 mm x 18 N.m (180 kgf.cm) 17 mm x 18 N.m (180 kgf.cm)
For 3/8 (opposite side x torque) 22 mm x 42 N.m (420 kgf.cm) 22 mm x 42 N.m (420 kgf.cm)
For 1/2 (opposite side x torque) 24 mm x 55 N.m (550 kgf.cm) 26 mm x 55 N.m (550 kgf.cm)
•
• •
• Because the pressure is higher for the R410A type, the conventional type cannot be used.
Table 6 Difference between R410A and conventional high/low-pressure gauges
Conventional gauges R410A gauges
High-pressure gauge (red) -76 cmHg - 35 kgf/cm3-0.1 - 5.3 Mpa -76 cmHg - 53 kgf/cm3
Low-pressure gauge (blue) -76 cmHg - 17 kgf/cm3-0.1 - 3.8 Mpa -76 cmHg - 38 kgf/cm3
•
• •
• The shape of the manifold ports has been changed to prevent the possibility of mistakenly charging with another type of
refrigerant.
Table 7 Difference between R410A and conventional manifold port size
Conventional gauges R410A gauges
Port size 7/16 UNF 20 threads 1/2 UNF 20 threads
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5. Charging hose
•
• •
• The pressure resistance of the charging hose has been
raised to match the higher pressure of R410A. The hose
material has also been changed to suit HFC use, and
the size of the fitting has been changed to match the
manifold ports.
6. Vacuum pump adaptor
•
• •
• When using a vacuum pump for R410A, it is necessary
to install an electromagnetic valve to prevent the
vacuum pump oil from flowing back into the charging
hose. The vacuum pump adaptor is installed for that
purpose. If the vacuum pump oil (mineral oil) becomes
mixed with R410A, it will damage the unit.
7. Electric gas leak detector for HFC refrigerant
•
• •
• The leak detector and halide torch that were used with
CFC and HCFC cannot be used with R410A (because
there is no chlorine in the refrigerant).
•
• •
• The present R134a leak detector can be used, but the
detection sensitivity will be lower (setting the sensitivity
for R134a at 1, the level for R410A will drop to 0.6).
•
• •
• For detecting small amounts of gas leakage, use the
electric gas leak detector for HFC refrigerant. (Detection
sensitivity with R410A is about 23 g/year).
Fig. 4 Manifold gauge charging hose
Fig. 5 Vacuum pump adaptor
Fig. 6 Electric gas leak detector for HFC refrigerant
Table 8 Difference between R410A and conventional charging hoses
Conventional hoses R410A hoses
Pressure
resistance
Working pressure 3.4 MPa (35 kgf/cm3) 5.1 MPa (52 kgf/cm3)
Bursting pressure 17.2 MPa (175 kgf/cm3) 27.4 MPa (280 kgf/cm3)
Material NBR rubber HNBR rubber Nylon coating inside
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8. Electronic scale for refrigerant charging
•
• •
• Because of the high pressure and fast vaporizing speed
of R410A, the refrigerant cannot be held in a liquid
phase inside the charging cylinder when charging is
done using the charging cylinder method, causing
bubbles to form in the measurement scale glass and
making it difficult to see the reading. (Naturally, the
conventional R22 charging cylinder cannot be used
because of the differences in the pressure resistance,
scale gradation, connecting port size, etc.)
•
• •
• The electronic scale has been strengthened by using a
structure in which the weight detector for the refrigerant
cylinder is held by four supports. It is also equipped with
two connection ports, one for R22 (7/16 UNF, 20
threads) and one for R410A (1/2 UNF, 20 threads), so
it can also be used for conventional refrigerant charging.
•
• •
• There are two types of electronic scales, one for 10-kg
cylinders and one for 20-kg cylinders. (The 10-kg
cylinder is recommended.)
Refrigerant charging is done manually by opening and
closing the valve.
9. Refrigerant cylinders
•
• •
• The R410A cylinders are labeled with the refrigerant
name, and the coating color of the cylinder protector is
pink, which is the color stipulated by ARI of the U.S.
•
• •
• Cylinders equipped with a siphon tube are available to
allow the cylinder to stand upright for liquid refrigerant
charging.
10. Charging orifice and packing for refrigerant cylinders
•
• •
• The charging orifice must match the size of the charging
hose fitting (1/2 UNF, 20 threads).
•
• •
• The packing must also be made of an HFC-resistant
material.
Fig. 7 Electronic scale for refrigerant charging
Fig. 8 Refrigerant cylinders
Fig. 9 Charging orifice and packing
12.2.3. R410A Tools Which Are Usable for R22 Models
Table 9 R410A tools which are usable for R22 models
R410A tools Usable for R22 models
(1) Copper tube gauge for clearance adjustment OK
(2) Flaring tool (clutch type) OK
(3) Manifold gauge NG
(4) Charging hose NG
(5) Vacuum pump adaptor OK
(6) Electric gas leak detector for HFC refrigerant NG
(7) Electronic scale for refrigerant charging OK
(8) Refrigerant cylinder NG
(9) Charging orifice and packing for refrigerant cylinder NG
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12.3. REFRIGERANT PIPING WORK
When working with refrigerant piping, the following points must
be carefully observed: no moisture od dust must be allowed to
enter the piping, and there must be no refrigerant leaks.
1. Procedure and precautions for flaring work
a. Cut the pipe
Use a pipe cutter, and cut slowly so the pipe will not be
deformed.
b. Remove burrs and clean shavings from the cut surface
If the shape of the pipe end is poor after removing burrs,
or if shavings adhere to the flared area, it may lead to
refrigerant leaks.
To prevent this, turn the cut surface downward and
remove burrs, then clean the surface, carefully.
c. Insert the flare nut (be sure to use the same nut that is
used on the AC unit)
d. Flaring
Check the clamp bar and the cleanliness of the copper
pipe.
Be sure to use the clamp bar to do the flaring with
accuracy. Use either an R410A flaring tool, or a
conventional flaring tool. Flaring tools come in different
sizes, so be sure to check the size before using. When
using a conventional flaring tool, use the copper pipe
gauge for clearance adjustment, etc., to ensure the
correct A dimension (see Fig. 10)
Fig. 10 Flaring dimensions
12.3.1. Piping Materials
It is recommended that you use copper and copper alloy jointless pipes with a maximum oil adherence of 40 mg/10m. Do not use
pipes that are crushed, deformed, or discolored (especially the inside surface). If these inferior pipes are used, impurities may clog
the expansion valves or capillaries.
Because the pressure of ACs using R410A is higher than those using R22, it is essential that you select materials that are
appropriate for these standards.
The thickness of the copper tubing used for R410A is shown in Table 10. Please be aware that tubing with a thickness of only 0.7
mm is also available on the market, but this should never be used.
Table 10 Copper tube thickness (mm)
Soft pipe Thickness (mm)
Nominal diameter Outside diameter (mm) R410A (Reference) R22
1/4 6.35 0.80 0.80
3/8 9.52 0.80 0.80
1/2 12.7 0.80 0.80
12.3.2. Processing and Connecting Piping Materials
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2. Procedure and precautions for flare connection
Fig. 11 Relation between the flare nut structure and flaring tool end
Table 11 R410A flaring dimensions
Nominal
diameter
Outside
diameter
(mm)
Wall thickness
(mm)
A (mm)
R410A flaring
tool, clutch type
Conventional flaring tool
Clutch type Wing-nut type
1/4 6.35 0.8 0 - 0.5 1.0 - 1.5 1.5 - 2.0
3/8 9.52 0.8 0 - 0.5 1.0 - 1.5 1.5 - 2.0
1/2 12.70 0.8 0 - 0.5 1.0 - 1.5 2.0 - 2.5
Table 12 R22 flaring dimensions
Nominal
diameter
Outside
diameter
(mm)
Wall thickness
(mm)
A (mm)
R410A flaring
tool, clutch type
Conventional flaring tool
Clutch type Wing-nut type
1/4 6.35 0.8 0 - 0.5 0.5 - 1.0 1.0 - 1.5
3/8 9.52 0.8 0 - 0.5 0.5 - 1.0 1.0 - 1.5
1/2 12.70 0.8 0 - 0.5 0.5 - 1.0 1.5 - 2.0
Table 13 R410A flare and flare nut dimensions Unit: mm
Nominal
diameter
Outside
diameter (mm)
Wall thickness
(mm)
A +0, -0.4 B
dimension
C
dimension
D
dimension
Flare nut
width
1/4 6.35 0.8 9.1 9.2 6.5 13 17
3/8 9.52 0.8 13.2 13.5 9.7 20 22
1/2 12.70 0.8 16.6 16.0 12.9 23 26
Table 14 R22 flare and flare nut dimensions Unit: mm
Nominal
diameter
Outside
diameter (mm)
Wall thickness
(mm)
A +0, -0.4 B
dimension
C
dimension
D
dimension
Flare nut
width
1/4 6.35 0.8 9.0 9.2 6.5 13 17
3/8 9.52 0.8 13.0 13.5 9.7 20 22
1/2 12.70 0.8 16.2 16.0 12.9 20 24
a. Check to make sure there is no scratches, dust, etc., on the flare and union.
b. Align the flared surface with the axial center of the union.
c. Use a torque wrench, and tighten to the specified torque. The tightening torque for R410A is the same as the conventional
torque value for R22. Be careful, because if the torque is too weak, it may lead to a gas leak. If it is too strong, it may split
the flare nut or make it impossible to remove the flare nut.
Table 15 R410A tightening torque
Nominal
diameter
Outside
diameter (mm)
Tightening torque
N.m (kgf.cm)
Torque wrench tightening torque
N.m (kgf.cm)
1/4 6.35 14 - 18 (140 - 180) 18 (180)
3/8 9.52 33 - 42 (330 -420) 42 (420)
1/2 12.70 55 (550) 55 (550)
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12.3.3. Storing and Managing Piping Materials
1. Types of piping and their storage
The following is a general classification of the refrigerant pipe materials used for ACs.
Because the gas pressure of R410A is approximately 1.6 times as high as that of R22, copper pipes with the thickness shown
in Table 10, and with minimal impurities must be used. Care must also be taken during storage to ensure that pipes are not
crushed, deformed, or scratched, and that no dust, moisture or other substance enters the pipe interior. When storing sheathed
copper pipes or plain copper pipes, seal the openings by pinching or taping them securely.
2. Makings and management
a. Sheathed copper pipes and copper-element pipes
When using these pipes, check to make sure that they are the stipulated thickness. For flare nuts, be sure to used the same
nut that is used on the AC unit.
b. Copper pipes
Use only copper pipes with the thickness given in table 10, and with minimal impurities. Because the surface of the pipe is
exposed, you should take special care, and also take measures such as marking the pipes to make sure they are easily
distinguished from other piping materials, to prevent mistaken use.
3. Precautions during refrigerant piping work
Take the following precautions on-site when connecting pipes. (Keep in mind that the need to control the entry of moisture and
dust is even more important that in conventional piping).
a. Keep the open ends of all pipes sealed until connection with AC equipment is complete.
b. Take special care when doing piping work on rainy days. The entering of moisture will degrade the refrigerating machine oil,
and lead to malfunctions in the equipment.
c. Complete all pipe connections in as short a time as possible. If the pipe must be left standing for a long time after removing
the seal, it must be thoroughly purged with nitrogen, or dried with a vacuum pump.
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Precautions
•
• •
• Be sure to read the instructions for the vacuum pump,
vacuum pump adaptor and manifold gauge prior to use,
and follow the instructions carefully.
•
• •
• Make sure that the vacuum pump is filled with oil up to
the designated line on the oil gauge.
•
• •
• The gas pressure back flow prevention valve on the
charging hose is generally open during use. When you
are removing the charging hose from the service port, it
will come off more easily if you close this valve.
Fig. 12 Vacuum pump air purging configuration
12.4. INSTALLATION, TRANSFERRING, SERVICING
12.4.1. Inspecting Gas Leaks with a Vacuum Pump for New Installations (Using New
Refrigerant Piping)
1. From the viewpoint of protecting the global environment, please do not release refrigerant into the atmosphere.
a. Connect the projecting side (pin-pushing side) of the charging hose for the manifold gauge to the service port of the 3-way
valve. (1)
b. Fully open the handle Lo of the manifold gauge and run the vacuum pump. (2) (If the needle of the low-pressure gauge
instantly reaches vacuum, re-check step a).)
c. Continue the vacuum process for at least 15 minutes, then check to make sure the low-pressure gauge has reached -0.1
MPa (-76 cmHg). Once the vacuum process has finished, fully close the handle Lo of the manifold gauge and stop the
vacuum pump operation, then remove the charging hose that is connected to the vacuum pump adaptor. (Leave the unit in
that condition for 1-2 minutes, and make sure that the needle of the manifold gauge does not return.) (2) and (3)
d. Turn the valve stem of the 2-way valve 90° counter-clockwise to open it, then, after 10 seconds, close it and inspect for a
gas leak (4)
e. Remove the charging hose from the 3-way valve service port, then open both the 2-way valve and 3-way valve. (1) (4) (Turn
the valve stem in the counter-clockwise direction until it gently makes contact. Do not turn it forcefully).
f. Tighten the service port cap with a torque wrench (18 N.m (1.8 kgf.m)). (5) Then tighten the 2-way valve and 3-way valve
caps with a torque wrench (42 N.m (4.2 kgf.m)) or (55 N.m (5.5 kgf.m)). (6)
g. After attaching each of the caps, inspect for a gas leak around the cap area. (5) (6)
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12.4.2. Transferring (Using New Refrigerant Piping)
1. Removing the unit
a. Collecting the refrigerant into the outdoor unit by pumping down
The refrigerant can be collected into the outdoor unit (pumping down) by pressing the TEST RUN button, even when the
temperature of the room is low.
•
• •
• Check to make sure that the valve stems of the 2-way valve and 3-way valve have been opened by turning them counter-
clockwise. (Remove the valve stem caps and check to see that the valve stems are fully opened position. Always use
a hex wrench (with 4-mm opposing sides) to operate the valve stems.)
•
• •
• Press the TEST RUN button on the indoor unit, and allow preliminary operation for 5-6 minutes. (TEST RUN mode)
•
• •
• After stopping the operation, let the unit sit for about 3 minutes, then close the 2-way valve by turning the valve stem in
the clockwise direction.
•
• •
• Press the TEST RUN button on the indoor unit again, and after 2-3 minutes of operation, turn the valve stem of the 3-
way valve quickly in the clockwise direction to close it, then stop the operation.
•
• •
• Tighten the caps of the 2-way valve and 3-way valve to the stipulated torque.
•
• •
• Remove the connection pipes (liquid side and gas side).
b. Removing the indoor and outdoor units
•
• •
• Disconnect the pipes and connecting electric cables from between the indoor and outdoor units.
•
• •
• Put capped flare nuts onto all of the pipe connections of the indoor and outdoor units, to make sure no dust or other
foreign matter enters.
•
• •
• Remove the indoor and outdoor units.
2. Installing the unit
Install the unit using new refrigerant piping. Follow the instructions in section 4.1 to evacuate the pipes connecting the indoor
and outdoor units, and the pipes of the indoor unit, and check for gas leaks.
12.4.3. AC Units Replacement (Using Existing Refrigerant Piping)
When replacing an R410A AC unit with another R410A AC unit, you should re-flare the refrigerant piping. Even though the
replacement AC unit uses the R410A, problems occur when, for example, either the AC unit maker or the refrigerating machine oil
is different.
When replacing an R22 AC unit with an R410A AC unit, the following checks and cleaning procedures are necessary but are
difficult to do because of the chemical characteristics of the refrigerating machine oil (as described in items c) and d) of section
About R410A Refrigerant). In this case, you should use new refrigerant piping rather than the existing piping.
1. Piping check
Because of the different pressure characteristics of R22 and R410A, the design pressure for the equipment is 1.6 times
different. The wall thickness of the piping must comply with that shown in Table 10, but this is not easy to check. Also, even if
the thickness is correct, there may be flattened or bent portions midway through the piping due to sharp curves. Buried sections
of the piping also cannot be checked.
2. Pipe cleaning
A large quantity of refrigerating machine oil (mineral oil) adheres to existing pipes due to the refrigeration cycle circulation. If the
pipes are used just as they are for the R410A cycle, the capacity will be lowered due to the incompatibility of this oil with the
R410A, or irregularities may occur in the refrigeration cycle. For this reason, the piping must be thoroughly cleaned, but this is
difficult with the present technology.
12.4.4. Refrigerant Compatibility (Using R410A Refrigerant in R22 ACs and Vice Versa)
Do not operate an existing R22 AC with the new R410A refrigerant. Doing so would result in improper functioning of the equipment
or malfunction, and might lead to a major accident such as an explosion in the refrigeration cycle. Similarly, do not operate an
R410A AC with R22 refrigerant. The chemical reaction between the refrigerating machine oil used in R410A ACs and the chlorine
that is contained in R22 would cause the refrigerating machine oil to degrade and lead to malfunction.
12.4.5. Recharging Refrigerant During Servicing
When recharging is necessary, insert the specified amount of new refrigerant in accordance with the following procedure.
1. Connect the charging hose to the service port of the outdoor unit.
2. Connect the charging hose to the vacuum pump adaptor. At this time, fully open the 2-way valve and 3-way valve.
3. Fully open the handle Lo of the manifold gauge, turn on the power of the vacuum pump and continue the vacuum process for
at least one hour.
4. Confirm that the low pressure gauge shows a reading of -0.1 Mpa (-76 cmHg), then fully close the handle Lo, and turn off the
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vacuum pump. Wait for 1-2 minutes, then check to make sure that the needle of the Low pressure gauge has not returned. See
Fig. 13 for the remaining steps of this procedure.
5. Set the refrigerant cylinder onto the electronic scale, then connect the hose the cylinder and to the connection port for the
electronic scale. (1)(2)
Precaution:
Be sure to set up the cylinder for liquid charging. If you use a cylinder equipped with a siphon tube, you can charge the liquid
without having to turn the cylinder around
6. Remove the charging hose of the manifold gauge from the vacuum pump adaptor, and connect it to the connection port of the
electronic scale. (2)(3)
7. Open the valve of the refrigerant cylinder, then open the charging valve slightly and close it. Next, press the check valve of the
manifold gauge and purge the air. (2)(4) (Watch the liquid refrigerant closely at this point.)
8. After adjusting the electronic scale to zero, open the charging valve, then open the valve Lo of the manifold gauge and charge
with the liquid refrigerant. (2)(5) (Be sure to read the operating instructions for the electronic scale.)
9. If you cannot charge the stipulated amount, operate the unit in the cooling mode while charging a little of the liquid at a time
(about 150 g/time as a guideline). If the charging amount is insufficient from one operation, wait about one minute, then use the
same procedure to do the liquid charging again.
Precaution:
Never use the gas side to allow a larger amount of liquid refrigerant to be charged while operating the unit.
10. Close the charging valve, and after charging the liquid refrigerant inside the charging hose, fully close the valve Lo of the
manifold gauge, and stop the operation of the unit. (2)(5)
11. Quickly remove the charging hose from the service port. (6) If you stop midway through, the refrigerant that is in the cycle will
be discharged.
12. After putting on the caps for the service port and operating valve, inspect around the caps for a gas leak. (6)(7)
Fig. 13 Re-charging refrigerant
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12.4.6. Brazing
As brazing requires sophisticated techniques and experiences, it must be performed by a qualified person.
In order to prevent the oxide film from occurring in the pipe interior during brazing, it is effective to proceed with brazing while letting
dry nitrogen gas (N2) flow.
<Brazing Method for Preventing Oxidation>
1. Attach a reducing valve to the nitrogen gas cylinder.
2. Apply a seal onto the clearance between the piping and inserted pipe for the nitrogen gas in order to prevent the nitrogen gas
from flowing backward.
3. When the nitrogen gas is flowing, be sure to keep the piping end open.
4. Adjust the flow rate of nitrogen gas so that it is lower than 0.05 m3/h, or 0.02 MPa (0.2 kgf/cm2) by means of the reducing valve.
5. After taking the steps above, keep the nitrogen gas flowing until the piping cools down to a certain extent (i.e. temperature at
which pipes are touchable with finger).
6. Completely remove the flux after brazing.
Fig. 14 Prevention of Oxidation during Brazing
Cautions during brazing
1. General Cautions
a. The brazing strength should be high as required.
b. After operation, airtightness should be kept under pressurized condition.
c. During brazing do not allow component materials to become damaged due to overheating.
d. The refrigerant pipe work should not become blocked with scale or flux.
e. The brazed part should not restrict the flow in the refrigerant circuit.
f. No corrosion should occur from the brazed part.
2. Prevention of Overheating
Due to heating, the interior and exterior surfaces of treated metal may oxidize. Especially, when the interior of the refrigerant
circuit oxidizes due to overheating, scale occurs and stays in the circuit as dust, thus exerting a fatally adverse effect. So,
make brazing at adequate brazing temperature and with minimum of heating area.
3. Overheating Protection
In order to prevent components near the brazed part from overheating damage or quality deterioration due to flame or heat,
take adequate steps for protection such as (1) by shielding with a metal plate, (2) by using a wet cloth, and (3) by means
of heat absorbent.
4. Movement during Brazing
Eliminate all vibration during brazing to protect brazed joints from cracking and breakage.
5. Oxidation Preventative
In order to improve the brazing efficiency, various types of antioxidant are available on the market. However, the
constituents of these are widely varied, and some are anticipated to corrode the piping materials, or adversely affect HFC
refrigerant, lubricating oil, etc. Exercise care when using an oxidation preventive.
12.4.7. Servicing Tips
The drier must also be replaced whenever replacing the refrigerant cycle parts. Replacing the refrigerant cycle parts first
before replacing the drier. The drier is supplied in a vacuum pack. Perform brazing immediately after opening the vacuum
pack, and then start the vacuum within two hours. In addition, the drier also needs to be replaced when the refrigerant has
leaked completely. (Applicable for drier model only.)
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
13 Servicing Information
13.1. About Lead Solder (PbF)
DISTINCTION OF PbF P.C. BOARD
P.C. Boards (manufactured) using lead free solder will have a PbF stamp on the P.C. Board.
CAUTION
•
• •
• Pb free solder has a higher melting point than standard solder; Typically the melting point is 50 - 70 °F (30 - 40 °C) higher.
Please use a high temperature solder iron and set it to 700 ± 20 °F (370 ± 10 °C)
•
• •
• Pb free solder will tend to slash when heated too high (about 1100 °F/ 600°C). If you must use Pb solder, please completely
all of the Pb free solder on the pins or solder area before applying Pb solder. If this is not practical, be sure to heat the Pb
free solder until it melts, before applying Pb solder.
61
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
Refrigeration cycle system
In order to diagnose malfunctions, make sure that there are
no electrical problems before inspecting the refrigeration
cycle. Such problems include insufficient insulation,
problem with the power source, malfunction of a
compressor and a fan.
The normal outlet air temperature and pressure of the
refrigeration cycle depends on various conditions, the
standard values for them are shown in the table to the right.
13.2. TROUBLESHOOTING
1. Relationship between the condition of the air conditioner and pressure and electric current
62
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
Cooling Mode Heating Mode
Condition of the air
conditioner Low Pressure High Pressure Electric current
during operation
Low Pressure High Pressure Electric current
during operation
Insufficient refrigerant
(gas leakage)
Clogged capillary tube
or Strainer
Short circuit in the
indoor unit
Heat radiation
deficiency of the
outdoor unit
Inefficient compression
•
• •
• Carry on the measurements of pressure, electric current, and temperature fifteen minutes after an operation is started.
63
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
•
• •
• Once abnormality has been detected during operation, the
unit will immediately stop its operation. (Timer LED blinks.)
•
• •
• Although timer LED goes off when power supply is turned
off, if the unit is operated under a breakdown condition, the
LED will light up again.
•
• •
• In operation after breakdown repair, error code is not
displayed. The last error code (abnormality) will be saved in
IC memory.
•
• •
• Timer LED Blinking in Abnormal Operation:
1. Automatically stops the operation.
2. Timer LED on display of the indoor unit blinks.
3. The LED will be off if the unit is turned off or the Error
RESET button on the remote controller is pressed.
•
• •
• To display memorized error (Protective operation)
status:
1. Turn the unit on.
2. Slide the remote controller cover down to appear the
operating buttons.
3. Press the CHECK button on the remote controller for
continuously 5 seconds or more to appear “--” on the
display.
4. Press the “TEMP” or button on the remote
controller to appear “H00” on the display. Signal is
transmitted to the main unit.
5. Press the “TEMP” button (When button is
pressed, the display goes back.) repeatedly and slowly
until Beep sound (about 5 seconds intermittently) is
heard from main unit.
6. Then, displayed error code matches to the error code
saved in unit memory. The power LED on the main unit
also lights up.
Mote: When the CHECK button is pressed
continuously for 5 seconds again, or when no
operation continues for 30 seconds, or when the
RESET button on remote controller is pressed with
a pointed object, the display is cancelled.
•
• •
• To clear memorized error (Protective operation) status
after repair:
1. Press the AUTO button in main unit continuously for 5
seconds or more and release it. (Test run / Pump down
operation: Beep sound)
2. Press the CHECK button on remote controller for about
1 second to transmit signal to main unit. A beep sound
is heard from main unit and the data is cleared.
•
• •
• Temporary Operation (Depending on breakdown
status)
1. Press the ON/OFF button after selecting Cooling or
Heating operation. (Receiving Beep sound is heard and
the TIMER LED blinks.)
2. The unit can temporarily be used until repaired.
Error Code Operation Temporary items
H23 Cooling Emergency Operation
with limited power
H27, H28 Cooling, Heating
13.3. BREAKDOWN SELF DIAGNOSIS FUNCTION
13.3.1. Self Diagnosis Function (Three Digits Alphanumeric Code)
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
13.3.2. Error Code Table
Diagnosis
display
Abnormality / Protection control Abnormality
Judgement
Emergency
operation
Primary location to verify
H11 Indoor / outdoor abnormal
communication
> 1 min after starting
operation
Indoor fan operation
only
•
• •
• Internal / external cable connections
•
• •
• Indoor / Outdoor PCB
H14 Indoor intake air temperature sensor
abnormality
— —
•
• •
• Intake air temperature sensor
(defective or disconnected)
H15 Outdoor compressor temperature sensor
abnormality
Continue for 5 sec. —
•
• •
• Compressor temperature sensor
(defective or disconnected)
H16 Outdoor Current Transformer open
circuit
— —
•
• •
• Outdoor PCB
•
• •
• IPM (Power transistor) module
H19 Indoor fan motor mechanism lock — —
•
• •
• Indoor PCB
•
• •
• Fan motor
H23 Indoor heat exchanger temperature
sensor abnormality
Continue for 5 sec. O
(Cooling only)
•
• •
• Heat exchanger temperature sensor
(defective or disconnected)
H26 Ionizer abnormality — —
•
• •
• Indoor PCB
•
• •
• Ionizer
H27 Outdoor air temperature sensor
abnormality
Continue for 5 sec. O
•
• •
• Outdoor temperature sensor
(defective or disconnected)
H28 Outdoor heat exchanger temperature
sensor abnormality
Continue for 5 sec. O
•
• •
• Outdoor heat exchanger
temperature sensor (defective or
disconnected)
H33 Indoor/Outdoor wrong connection — —
•
• •
• Indoor/Outdoor supply voltage
H97 Outdoor Fan Motor lock abnormality — —
•
• •
• Outdoor PCB
•
• •
• Outdoor Fan Motor
H98 Indoor high pressure protection — —
•
• •
• Air filter dirty
•
• •
• Air circulation short circuit
H99 Indoor heat exchanger anti-freezing
protection
— —
•
• •
• Insufficient refrigerant
•
• •
• Air filter dirty
F11 Cooling / Heating cycle changeover
abnormality
4 times occurrence
within 30 minutes
—
•
• •
• 4-way valve
•
• •
• V-coil
F91 Refrigeration cycle abnormality 2 times occurrence
within 20 minutes
—
•
• •
• No refrigerant
(3-way valve is closed)
F93 Outdoor compressor abnormal revolution 4 times occurrence
within 20 minutes
—
•
• •
• Outdoor compressor
F95 Cool high pressure protection 4 times occurrence
within 20 minutes
—
•
• •
• Outdoor refrigerant circuit
F96 IPM (power transistor) overheating
protection
— —
•
• •
• Excess refrigerant
•
• •
• Improper heat radiation
•
• •
• IPM (Power transistor)
F97 Outdoor compressor overheating
protection
4 times occurrence
within 10 minutes
—
•
• •
• Insufficient refrigerant
•
• •
• Compressor
F98 Total running current protection 3 times occurrence
within 20 minutes
—
•
• •
• Excess refrigerant
•
• •
• Improper heat radiation
F99 Outdoor Direct Current (DC) peak
detection
7 times occurrence
continuously
—
•
• •
• Outdoor PCB
•
• •
• IPM (Power transistor)
•
• •
• Compressor
Note:
“O” - Frequency measured and fan speed fixed.
The memory data of error code is erased when the power supply is cut off, or press the Auto Switch until “beep” sound heard
following by pressing the “RESET” button at remote controller.
Although operation forced to stop when abnormality detected, emergency operation is possible for certain errors (refer to Error
Codes Table) by using remote controller or Auto Switch at indoor unit. However, the remote controller signal receiving sound is
changed from one “beep” to four “beep” sounds.
65
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
13.4.1.1. Removal of the Front Panel
1. Push the Front Panel up toward upper side from the
horizontal line a little by hand.
Fig. 1
2. Pull it out by pressing each arm located on left and right
sides toward outside.
Fig. 2
Note for Reassembly:
Put each axis into Bearing Ass’y up to the bottom one
side by one while keeping the Front Panel horizontal.
Fig. 3
Note for Reassembly:
Insert protruding parts on the reverse side of the panel
(both left and right sides), for right side, between the
PCB Control Box the Open/Close Motor, and for left
side, into the left side of the Heat Exchanger
respectively.
Fig. 4
13.4.1.2. Removal of Front Grille
1. Remove the Front Panel according to the item 13.5.1.1.
2. Keep the Vertical Louver horizontal.
3. Pull the Screw Caps (two in left and right sides) toward the
front side and unscrew the screws inside (one each left and
right), and finally unscrew the screw on the right side of the
Front Grille (one).
Fig. 5
Note for Disassembly:
Removing the Front Panel in advance before removal of
Air Filters (two) can make reassembly of the Grille easy.
4. Remove the Front Grille to upside by holding the lower part
up a little.
Note for Disassembly:
There are three hooks on the top. Holding the Grille up
while holding these hooks down makes its removal
easy. Be careful of the hooks that might be hard.
Fig. 6
Note for Reassembly:
Put the Grille back securely until you hear click sound
of all the hooks (three) on the top. Or, it may cause
breakdown such as “Front Panel does not open” due to
out of gear of the Front Panel Open/Close Motor.
13.4. DISASSEMBLY OF PARTS
13.4.1. Disassembly of Indoor Unit
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
13.4.1.3. Removal of Control Board
1. Remove the Front Panel according to the item 13.5.1.1.
2. Remove the Front Grille according to the item 13.5.1.2.
Fig. 7
3. Remove the Control Cover.
Note for Disassembly:
There are hooks on both sides (left and right).
Fig. 8
4. Pull out the Control Board.
Fig. 9
5. Remove a variety of Connectors and Terminals.
Wiring parts from the upper side
•
• •
• CN-STM2 (blue) ...... Front Panel Open/Close Motor
•
• •
• CN-TH (yellow) ...... Intake Air / Pipe Temp. Sensor
Note for Disassembly:
The CN-TH (yellow) can not be disconnected.
Disconnect thermosensitive part of the Pipe Temp.
Sensor from the holder (Board-in). The Intake Air
Temp. Sensor can be easily disconnected.
Wiring cables from lower side
•
• •
• CN-STM1 (White) ...... Air Swing Motor for Vertical
Louver
•
• •
• CN-FM (White) ...... Indoor Fan Motor
•
• •
• CN-ION (White) ...... Ionizer
•
• •
• CN-DISP (green or yellow) ...... Control Board
(Receiver & Display Unit)
Note for Disassembly:
The CN-TH (yellow) can not be disconnected
from Control Board. Remove whole plastic part
by releasing the hooks (two) for the Receiver &
Display Unit (Board-in).
Fig. 10
Note for Disassembly:
Disconnect the connectors while holding the
hooks down. Do not pull it out directly.
Wiring cables from the Terminal Board
•
• •
• TAB1 terminal (brown) ...... Disconnect the terminal.
•
• •
• TAB2 terminal (white) ...... Disconnect the terminal.
Note for Disassembly:
Disconnect the terminals while holding the
convexity down in the center of each terminal.
•
• •
• H1 (black), H3 (red) are soldered on PCB. .........
Remove it from the PCB by desoldering.
Fig. 11
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
13.4.1.4. Removal of Control Board Box
1. Remove the Front Panel according to the item 15.5.1.1.
2. Remove the Front Grille according to the item 15.5.1.2.
3. Remove the Control Board according to the item 15.5.1.3.
Note for Disassembly:
The Control Board Box can be removed without pulling
out the Board. (Disconnect a variety of connectors and
the Receiver & Display Unit first.)
4. Remove a fixing screw for interconnecting cables and a
screw for earth wire.
5. Remove the screws (three) for Terminal Board and release
the hook (one).
Fig. 12
6. Pull out the Control Board Box from the main unit.
Fig. 13
13.4.1.5. Removal of Fan Motor and
Cross-Flow Fan
1. Remove the Front Panel according to the item 13.5.1.1.
2. Remove the Front Grille according to the item 13.5.1.2.
3. Remove the Control Board Box according to the item
13.5.1.4.
4. Remove the Drain Hose and Discharge Grille.
Note for Disassembly:
Be careful of Drain Hose that will be hard to pulled out.
5. Unscrew the Screws (two) on the left side of the Heat
Exchanger.
Fig. 14
6. Loosen the Screw (one) between the Cross-Flow Fan and
Fan Motor.
Fig. 15
7. Pull out the Cross-Flow Fan by holding up the left side of
the Heat Exchanger.
Fig. 16
68
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
8. Pull out the Indoor Fan Motor.
Fig. 17
Fig. 18
13.4.1.6. Removal of Air Swing Motor for
Vertical and Horizontal Louvers
1. Remove the Front Panel according to the item 13.5.1.1.
2. Remove the Front Grille according to the item 13.5.1.2.
Note for Disassembly:
The Air Swing Motor for Vertical Louver can be
removed by only removal of the Front Grille.
Fig. 19
3. Remove it by unscrewing screws (two).
Fig. 20
13.4.1.7. Removal of Front Panel
Open/Close Motor
1. Remove the Front Panel according to the item 13.5.1.1.
2. Remove the Front Grille according to the item 13.5.1.2.
Note for Disassembly:
The Front Panel Open/Close Motor for Vertical Louver
can be removed by only removal of the Front Grille.
Fig. 21
3. Remove the Front Panel Open/Close Motor by unscrewing
the screw and disconnecting the connector.
Note for Disassembly:
Replace the Motor together with the Gear (Plastic)
when replacement. If further disassembly of the Gear is
performed, the reassembly will become impossible due
to out of gears inside.
Fig. 22
69
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
13.4.2.1. Removal of Cabinet Top Plate
and Cabinet Front Plate
1. Unscrew the screws (three: two on the right side and one on
the left side as you faces) and the Cabinet Top Plate.
2. Unscrew the screws (six: three on the upper side and
another three on the lower side) on the Cabinet Top Plate.
Fig. 1
3. Release the hooks (four: two on the right and another two
on the left as you faces) for the Cabinet Front Plate and
remove the Front Plate by holding it up a little.
Fig. 2
13.4.2.2. Removal of Control Cover (2- / 3-
way valve Covers and Terminal
Cover)
1. Remove the Front Grille according to the item 13.5.1.2.
2. Remove the screw (one) on the Control Cover and remove
it by sliding it downward.
Fig. 3
3. Remove the Terminal Cover by removing the screws (two)
and releasing the hooks (two).
Fig. 4
13.4.2. Disassembly of Outdoor Unit
70
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
13.4.2.3. Removal of Control Plate Casing
1. Remove the Cabinet Top Plate and Cabinet Front Plate
according to the item 13.5.2.1.
2. Remove the Control Cover (2- / 3-way valve Covers and
Terminal Cover) according to the item 13.5.2.2.
3. Remove the Control Plate Casing by releasing hooks (four:
two each on the right and left).
Fig. 5
4. Remove the screw (one) fixing the Control Plate Casing.
Fig. 6
5. Disconnect a variety of connectors and Terminals.
Wiring cables from lower side
•
• •
• Compressor cables (red, blue and yellow)
...... Disconnect the connector (white).
•
• •
• CN-HOT (white) ...... Electromagnetic Coil (4-way
valve) Cable: Yellow
•
• •
• Terminals connecting Reactor (two) Cable: Gray
•
• •
• CN-TANK (white) ...... Compressor Temp. Sensor
Wiring cables from left side
•
• •
• CN-FM1 ...... Outdoor Fan Motor
Wiring cables from right side
•
• •
• CN-STM (white) ...... Electromagnetic Coil
(Expansion Valve)
•
• •
• CN-TH (white) ...... Outdoor Air Temp. / Pipe Temp.
Sensor
6. Disconnect the interconnect cables and the Earth Wire (one
screw).
•
• •
• Remove the screws (two) fixing the Terminal part and
the Cabinet Side Plate (right).
Fig. 7
7. Remove the Control Plate Casing from the main unit by
holding it up.
Fig. 8
71
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
13.4.2.4. Removal of Control Board
1. Remove the Cabinet Top Plate and Cabinet Front Plate
according to the item 13.5.2.1.
2. Remove the Power Supply Cover (2- / 3-way valve Covers
and Terminal Cover) according to the item 13.5.2.2.
3. Remove the Control Plate Casing according to 13.5.2.3.
4. Remove Outdoor Air Temp. Sensor and its fitting by
releasing the hooks (two) the fitting.
Fig. 9
5. Place the Control Box reversely and remove the Screws
(Two) on the both sides of the Control Box (for Terminal
Plate).
Fig. 10
6. Remove the Control Plate Casing (Terminal Plate) from the
Control Plate Casing.
Note for Disassembly:
Remove Power supply terminal (red, white and black)
from the Terminal Plate.
Fig. 11
7. Remove the Control Box by releasing the hooks (four) the
Box (Control Board Lower Cover).
Note for Disassembly:
Be careful of hanging-up of connectors or wiring cables
such as the earth wire when the Box (Control Board
Lower Cover) is removed.
Fig. 12
8. Replace the Control Plate Casing (Black plastic part)
together when the Control Board needs to be replaced.
Fig. 13
Note for Disassembly:
Replacement of the Outdoor Control Board should be
made as a whole unit due to silicon pasting, etc.
although it can be separated PCB part from Control Box
part by removing the screws (six) on the soldering side.
72
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
13.4.2.5. Removal of Propeller Fan and
Fan Motor
1. Remove the Cabinet Top Plate and Cabinet Front Plate
according to the item 13.5.2.1.
2. Remove the Control Cover (Control Board Upper Cover) by
releasing the hooks (four: two each on the both sides).
Fig. 14
3. Remove only the Connector for the CN-MTR1 and CN-
MTR2 (Outdoor Fan Motor).
4. Remove the Propeller Fan by turning the nut in the center
of the fan clockwise.
Fig. 15
5. Remove the Fan Motor by loosening the screws (four).
Fig. 16
Note for Reassembly:
Adjust each position of the Boss in the center of the
Propeller and the groove on the shaft of the Motor when
putting them together.
Fig. 17
73
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
14 Technical Data
14.1. Operation Characteristics
CS-TE9DKE / CU-TE9DKE
74
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
CS-TE12DKE / CU-TE12DKE
75
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
14.2. Sensible Capacity Chart
CS-TE9DKE / CU-TE9DKE
230V Outdoor Temp. (°C)
Indoor wet
bulb temp.
30 35 40 46
TC SHC IP TC SHC IP TC SHC IP TC SHC IP
17.0°C 2.58 2.33 0.53 2.41 2.24 0.57 2.24 2.14 0.61 2.04 2.03 0.66
19.0°C 2.60 0.58
19.5°C 2.83 2.44 0.54 2.65 2.34 0.58 2.46 2.25 0.62 2.24 2.14 0.67
22.0°C 3.09 2.52 0.56 2.88 2.43 0.60 2.68 2.34 0.64 2.44 2.24 0.69
CS-TE12DKE / CU-TE12DKE
230V Outdoor Temp. (°C)
Indoor wet
bulb temp.
30 35 40 46
TC SHC IP TC SHC IP TC SHC IP TC SHC IP
17.0°C 3.42 2.86 0.82 3.20 2.75 0.89 2.97 2.64 0.95 2.70 2.51 1.02
19.0°C 3.45 0.95
19.5°C 3.76 3.01 0.84 3.51 2.89 0.90 3.27 2.78 0.97 2.97 2.64 1.04
22.0°C 4.10 3.12 0.85 3.83 3.06 0.92 3.56 2.89 0.99 3.24 2.75 1.06
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CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
15 Exploded View and Replacement Parts List
15.1. Exploded View (Indoor Unit)
Note:
The above exploded view is for the purpose of parts disassembly and replacement.
77
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
The non-numbered parts are not kept as standard service parts.
15.2. Replacement Parts List (Indoor Unit)
<Models: CS-TE9DKE CS-TE12DKE>
REF. NO. PART NAME & DESCRIPTION QTY. CS-TE9DKE CS-TE12DKE REMARKS
D1 CHASSY COMPLETE 1CWD50C1418 ←
←←
←
D2 INSTALLATION PLATE 1CWH361074 ←
←←
←
D3 PIPE HOLDING PLATE 1CWD911465 ←
←←
←
D4 FAN MOTOR 1ARW41E8P30AC ←
←←
←0
D5 CROSS FLOW FAN COMPLETE 1CWH02K1029 ←
←←
←
D5-1 SCREW - CROSS FLOW FAN 1CWH4580304 ←
←←
←
D6 BEARING ASS’Y 1CWH64K1005 ←
←←
←
D7 DISCHARGE GRILLE COMPLETE 1CWE20C2423 ←
←←
←
D7-1 VERTICAL VANE 1CWE24C1115 ←
←←
←
D7-2 HORIZONTAL VANE COMPLETE (R) 1CWE24C1106 ←
←←
←
D7-3 HORIZONTAL VANE COMPLETE (L) 1CWE24C1107 ←
←←
←
D7-4 FULCRUM 1CWH621050 ←
←←
←
D7-5 CAP (DRAIN CAP) 1CWH521091 ←
←←
←
D7-6 AIR SWING MOTOR 1CWA981106 ←
←←
←0
D8 DRAIN HOSE 1CWH851107 ←
←←
←
E1 CONTROL BOARD CASING 1CWH102280 ←
←←
←
E2 TERMINAL BOARD COMPLETE 1CWA28C2233 ←
←←
←0
E4 DISPLAY PCB HOLDER 1CWD932475 ←
←←
←
E5 ELECTRONIC CONTROLLER - RECEIVER, INDICATOR 1CWA743634 ←
←←
←0
E7 POWER SUPPLY CORD 1CWA20C2432 ←
←←
←
E8 ELECTRONIC CONTROLLER - MAIN 1CWA73C1810 ←
←←
←0
E9 CONTROL COVER (LOWER) 1CWH131229 ←
←←
←
E10 CONTROL COVER (PLASTIC PLATE - UPPER) 1CWH131232 ←
←←
←
E11 CONTROL COVER (STEEL PLATE - UPPER) 1CWH131230 ←
←←
←
E12 GEAR (FRONT PANEL OPEN/CLOSE MOTOR) 1CWH68C1022 ←
←←
←
E12-1 FRONT PANEL OPEN/CLODE MOTOR 1CWA981126 ←
←←
←
E13 SENSOR HOLDER (PIPE TEMP) 1CWH32137 ←
←←
←
E14 ELECTRONIC CONTROLLER - IONIZER 1CWA73C1791 ←
←←
←
E15 ION GENERATOR 1CWH94C0005 ←
←←
←
F1 FRONT GRILLE COMPLETE 1CWE11C3206XA ←
←←
←
F1-1 FRONT PANEL (INTALE GRILLE) 1CWE22C1184XA ←
←←
←
F1-2 DOOR (INTERCONNECT CABLE) 1CWE141087A ←
←←
←
F1-3 INDICATOR 1CWE312539 ←
←←
←
F2 CAP 2 CWH521121 ←
←←
←
F3 AIR FILTER 2CWD001149 ←
←←
←
R1 EVAPORATOR COMPLETE (WITH PIPE) 1CWB30C1608X CWB30C1706X
R1-1C FLARE NUT (1/4”) 1CWT25086 ←
←←
←
R1-2 EVAPORATOR HOLDER 1CWD61048 ←
←←
←
R3 FLARE NUT (3/8”) 1CWT25087
R3 FLARE NUT (1/2”) 1CWT25096
Z1 REMOTE CONTROL COMPLETE 1CWA75C2686X ←
←←
←
Z2-1 OPERATION INSTRUCTION 1CWF564718 ←
←←
←
Z2-2 OPERATION INSTRUCTION 1CWF564719 ←
←←
←
Z2-3 INSTALLATION INSTRUCTION 1CWF612743 ←
←←
←
(Note)
•
• •
• All parts are supplied from ACD, Japan.
•
• •
• “O” marked parts are recommended to be kept in stock.
78
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
15.3. Exploded View (Outdoor Unit)
Note:
The above exploded view is for the purpose of parts disassembly and replacement.
The non-numbered parts are not kept as standard service parts.
79
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
15.4. Replacement Parts List (Outdoor Unit)
<Models: CU-TE9DKE CU-TE12DKE>
REF NO. DESCRIPTION & NAME QTY. CU-TE9DKE CU-TE12DKE REMARKS
D1 CHASSY ASSY 1CWD50K2126X ←
←←
←
D2 FAN MOTOR BRACKET 1CWD541021 ←
←←
←
D3 FAN MOTOR 1ARW44W8P40AC ←
←←
←O
D5 PROPELLER FAN 1CWH03K1014 ←
←←
←
D6 NUT - PROPELLER FAN 1CWH561034J ←
←←
←
D7 FAN MOTOR MOUNT PLATE (UPPER) 1CWMD910001X2 ←
←←
←
D8 SOUND PROOF BOARD 1CWH151067RX ←
←←
←
D9 REACTOR 1G0A193M00003 G0A193M00002
D10 COUPLING MOUNT PLATE 1CWMH350001 ←
←←
←
E1 CONTROL COVER (TERMINAL PLATE COVER) 1CWH131244X ←
←←
←
E2 CONTROL PLATE CASING (TERMINAL BOARD) 1CWH102284 ←
←←
←
E3 TERMINAL BOARD 1CWA38K1121 ←
←←
←
E4 CONTROL BOARD COVER (ELECTRONIC CONTROLLER - LOWER) 1CWH102247 ←
←←
←
E5 ELECTRONIC CONTROLLER - MAIN 1CWA73C1821R CWA73C1822R 0
E6 SENSOR COMPLETE 1CWA50C2281 ←
←←
←
E7 SENSOR HOLDER (OUTDOOR TEMP.) 1CWH321046 ←
←←
←
E8 SENSOR COMPLETE 1CWA50C2241 ←
←←
←
E14 CONTROL BOARD COVER (ELECTRONIC CONTROLLER - UPPER) 1CWH131206XD ←
←←
←
F1 CABINET FRONT PLATE 1CWE06C1115 ←
←←
←
F2 CABINET SIDE PLATE (RIGHT) 1CWE04C1052 ←
←←
←
F3 CABINET SIDE PLATE (LEFT) 1CWE041054 ←
←←
←
F4 HANDLE 1CWE161001 ←
←←
←
F5 CABINET TOP PLATE 1CWE031053 ←
←←
←
F6 CONTROL BOARD COVER (2-, 3-WAY VALVE COVER) 1CWMH13C0002 ←
←←
←
R1 COMPRESSOR 1CWB092330 ←
←←
←0
R2 ANTI-VIBRATION BUSHING 3CWH501022 ←
←←
←
R3 NUT - COMPRESSOR MOUNT 3CWH56000J ←
←←
←
R4 TERMINAL COVER 1CWH17006 ←
←←
←
R5 NUT - TERMINAL COVER 1CWH7080300J ←
←←
←
R6 SOUND PROOF MATERIAL 1CWMG300001 ←
←←
←
R7 WIRE NET 1 CWD041046 ←
←←
←
R8 LIQUID RECEIVER (MULTI BEND TUBE - MULTI BEND TUBE) 1CWB14011 ←
←←
←
R10 4-WAY VALVE 1CWB001037J ←
←←
←
R11 V-COIL COMPLETE (4-WAY VALVE) 1CWA43C2144J ←
←←
←
R13 CONDENSER 1CWB32C1471XA ←
←←
←
R14 TUBE ASS’Y (WITH EXPANSION VALVE) 1CWT01C3271 ←
←←
←
R14-1 EXPANSION VALVE 1CWB051016J ←
←←
←
R15 BUSHING (EXPANSION VALVE) 1CWMH510005 ←
←←
←
R16 V-COIL COMPLETE (EXPANSION VALVE) 1CWA43C2058J ←
←←
←
R17 DRYER 1CWB101016 ←
←←
←
R20 2-WAY VALVE 1CWB021180J ←
←←
←0
R22 FLARE NUT (1/4”) 1CWT25086 ←
←←
←
R23 3-WAY VALVE COMPLETE (GAS) 1CWB011165J CWB011316J 0
R23-1 CAP (VALVE ROD) 1CWH521098 ←
←←
←
R23-2 CAP (SERVICE PORT) 1CWH521099
R25 FLARE NUT (3/8”) 1CWT25087
R25 FLARE NUT (1/2”) 1CWY25096
R27 STRAINER (MULTI BEND TUBE - U-TUBE) 1CWB111004 ←
←←
←
Z1 L-TUBE (DRAIN ELBOW) 1CWT20C022 ←
←←
←
(Note)
•
• •
• All parts are supplied from ACD, Japan.
•
• •
• “O” marked parts are recommended to be kept in stock.
80
CS-TE9DKE CU-TE9DKE / CS-TE12DKE CU-TE12DKE
[ACD] Printed in Japan
