Fluke 1521 Users Manual

1521handheldthermometerreadout cb43b660-52e7-442a-a875-3f0a8863ac0d Fluke Thermometer 1521 User Guide |

: Fluke Fluke-1521-Users-Manual-427918 fluke-1521-users-manual-427918 fluke pdf

Open the PDF directly: View PDF .
Page Count: 1

1521

Handheld Thermometer Readout

User’s Guide

Rev. 571203 ENG

Hart Scientific

Limited Warranty & Limitation of Liability

Each product from Fluke's Hart Scientific Division ("Hart") is warranted to be free from defects in mate-

rial and workmanship under normal use and service. The warranty period is one year for the Handheld

Thermometer Readout. The warranty period begins on the date of the shipment. Parts, product repairs,

and services are warranted for 90 days. The warranty extends only to the original buyer or end-user cus-

tomer of a Hart authorized reseller, and does not apply to fuses, disposable batteries or to any other prod-

uct which, in Hart's opinion, has been misused, altered, neglected, or damaged by accident or abnormal

conditions of operation or handling. Hart warrants that software will operate substantially in accordance

with its functional specifications for 90 days and that it has been properly recorded on non-defective me-

dia. Hart does not warrant that software will be error free or operate without interruption. Hart does not

warrant calibrations on Handheld Thermometer Readouts.

Hart authorized resellers shall extend this warranty on new and unused products to end-user customers

only but have no authority to extend a greater or different warranty on behalf of Hart. Warranty support is

available if product is purchased through a Hart authorized sales outlet or Buyer has paid the applicable

international price. Hart reserves the right to invoice Buyer for importation costs of repairs/replacement

parts when product purchased in one country is submitted for repair in another country.

Hart's warranty obligation is limited, at Hart's option, to refund of the purchase price, free of charge re-

pair, or replacement of a defective product which is returned to a Hart authorized service center within

the warranty period.

To obtain warranty service, contact your nearest Hart authorized service center or send the product, with

a description of the difficulty, postage, and insurance prepaid (FOB Destination), to the nearest Hart au-

thorized service center. Hart assumes no risk for damage in transit. Following warranty repair, the prod-

uct will be returned to Buyer, transportation prepaid (FOB Destination). If Hart determines that the

failure was caused by misuse, alteration, accident or abnormal condition or operation or handling, Hart

will provide an estimate or repair costs and obtain authorization before commencing the work. Following

repair, the product will be returned to the Buyer transportation prepaid and the Buyer will be billed for

the repair and return transportation charges (FOB Shipping Point).

THIS WARRANTY IS BUYER'S SOLE AND EXCULSIVE REMEDY AND IS IN LIEU OF ALL

OTHER WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY IM-

PLIED WARRANTY OF MERCHANTABLILTY OR FITNESS FOR A PARTICULAR PURPOSE.

HART SHALL NOT BE LIABLE FOR ANY SPECIAL, INDIRECT, INCIDENTAL. OR CONSE-

QUENTIAL DAMAGES OR LOSSES, INCLUDING LOSS OF DATA, WHETHER ARISING FROM

BREACH OF WARRANTY OR BASED ON CONTRACT, TORT, RELIANCE OR ANY OTHER

THEORY.

Since some countries or states do not allow limitation of the term of an implied warranty, or exclusion or

limitation of incidental or consequential damages, the limitations and exclusions of this warranty may not

apply to every buyer. If any provision of this Warranty is held invalid or unenforceable by a court of com-

petent jurisdiction, such holding will not affect the validity or enforceability of any other provision.

Rev. 571203

Fluke Corporation, Hart Scientific Division

799 E. Utah Valley Drive American Fork, UT 84003-9775 USA

Phone: +1.801.763.1600 Telefax: +1.801.763.1010

E-mail: support@hartscientific.com

www.hartscientific.com

Subject to change without notice. Copyright © 2005 Printed in USA

Table of Contents

1 Before You Start . . . . . . . . . . . . . . . . . . . . . . . . . . 1

1.1 Symbols Used . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1

1.2 Safety Information . . . . . . . . . . . . . . . . . . . . . . . . . . 2

1.2.1 Warnings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2

1.2.2 Cautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

1.3 Authorized Service Centers. . . . . . . . . . . . . . . . . . . . . . 4

2 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

3 Specifications and Environmental Conditions . . . . . . . . . . 9

3.1 Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9

3.2 Environmental Conditions. . . . . . . . . . . . . . . . . . . . . . 10

4 Quick Start . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

4.1 Unpacking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

4.2 Use Proper Care with the 1521 and Accessories . . . . . . . . . . 11

4.3 Learn About the Features and Components . . . . . . . . . . . . . 11

4.4 Connect the Probe . . . . . . . . . . . . . . . . . . . . . . . . . . 11

4.5 Connect the Power Source . . . . . . . . . . . . . . . . . . . . . 12

4.6 Switch the Power On . . . . . . . . . . . . . . . . . . . . . . . . 12

4.7 Measure Temperature . . . . . . . . . . . . . . . . . . . . . . . . 12

5 Parts and Controls . . . . . . . . . . . . . . . . . . . . . . . . 13

5.1 Front Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13

5.2 Top and Side Features . . . . . . . . . . . . . . . . . . . . . . . . 15

5.3 Back Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

5.4 Internal Features. . . . . . . . . . . . . . . . . . . . . . . . . . . 16

5.5 Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17

6 General Operation . . . . . . . . . . . . . . . . . . . . . . . . 19

6.1 Battery. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

6.2 DC Power Source . . . . . . . . . . . . . . . . . . . . . . . . . . 20

6.3 Power Button . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

6.4 Display and Backlight . . . . . . . . . . . . . . . . . . . . . . . . 21

6.5 Probe . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22

i

6.6 INFO-CON Connector . . . . . . . . . . . . . . . . . . . . . . . 23

7 Display Functions. . . . . . . . . . . . . . . . . . . . . . . . . 25

7.1 Blank Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26

7.2 Min/Max Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

7.3 Hold Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

7.4 Delta(x) Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

7.5 Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

7.6 Rate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

7.7 Resolution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

7.8 CAL MODE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29

7.8.1 Mtr Due . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30

7.8.2 Prb Due . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30

7.8.3 Time . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30

7.8.4 Passcode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30

7.8.5 Date . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

7.8.6 Probe Lock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

7.8.7 Prb #. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

7.8.8 Prb Type . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31

7.8.9 ITS-90 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32

7.8.10 IEC751 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33

7.8.11 CVD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33

7.8.12 YSI-400 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34

7.8.13 THERM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34

7.8.14 Probe Wires . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35

7.8.15 PCal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35

7.8.16 PDue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35

7.8.17 Filter. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36

7.8.18 MCal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36

7.8.19 MDue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36

7.8.20 CAL1 and CAL2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36

8 Communications Interface. . . . . . . . . . . . . . . . . . . . 37

8.1 RS-232 Connection . . . . . . . . . . . . . . . . . . . . . . . . . 37

8.2 Communication Command List . . . . . . . . . . . . . . . . . . . 38

8.2.1 Primary Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38

8.2.2 Calibration Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39

9 Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

9.1 Required Equipment. . . . . . . . . . . . . . . . . . . . . . . . . 43

9.2 Calibration Procedure . . . . . . . . . . . . . . . . . . . . . . . . 43

10 Maintenance . . . . . . . . . . . . . . . . . . . . . . . . . . . 45

ii

11 Troubleshooting. . . . . . . . . . . . . . . . . . . . . . . . . . 47

11.1 An Error Message Is Displayed . . . . . . . . . . . . . . . . . . . 47

11.2 CE Comments . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48

11.2.1 EMC Directive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48

11.2.1.1 Immunity Testing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49

11.2.1.2 Emission Testing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49

11.2.2 Low Voltage Directive (Safety) . . . . . . . . . . . . . . . . . . . . . . . . . 49

iii

iv

Figures and Tables

Table 1 International Electrical Symbols . . . . . . . . . . . . . . . . . . . . . 1

Figure 1 Front of the 1521 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13

Figure 2 Top and Side View . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15

Figure 3 INFO-CON Connector . . . . . . . . . . . . . . . . . . . . . . . . . . 17

Figure 4 Battery Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19

Figure 5 12V DC Power Source Polarity . . . . . . . . . . . . . . . . . . . . . 21

Figure 6 Probe Wiring Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . 24

Figure 7 Operating Modes Flowchart . . . . . . . . . . . . . . . . . . . . . . . 26

Figure 8 RS-232 Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37

1 Before You Start

1.1 Symbols Used

Table 1 lists the International Electrical Symbols. Some or all of these symbols

may be used on the instrument or in this manual.

Symbol Description

AC (Alternating Current)

AC-DC

Battery

CE Complies with European Union Directives

DC

Double Insulated

Electric Shock

Fuse

PE Ground

Hot Surface (Burn Hazard)

Read the User’s Manual (Important Information)

Off

On

1

1 Before You Start

Symbols Used

Table 1 International Electrical Symbols

Symbol Description

Canadian Standards Association

OVERVOLTAGE (Installation) CATEGORY II, Pollution Degree 2 per IEC1010-1 re-

fers to the level of Impulse Withstand Voltage protection provided. Equipment of

OVERVOLTAGE CATEGORY II is energy-consuming equipment to be supplied from

the fixed installation. Examples include household, office, and laboratory appliances.

C-TIC Australian EMC Mark

The European Waste Electrical and Electronic Equipment (WEEE) Directive

(2002/96/EC) mark.

1.2 Safety Information

Use this instrument only as specified in this manual. Otherwise, the protection

provided by the instrument may be impaired.

The following definitions apply to the terms “Warning” and “Caution”.

•“Warning” identifies conditions and actions that may pose hazards to the

user.

•“Caution” identifies conditions and actions that may damage the instru-

ment being used.

1.2.1 Warnings

To avoid personal injury, follow these guidelines.

•DO NOT use this unit in environments other than those listed in the

User’s Guide.

•Follow all safety guidelines listed in the User’s Guide.

•Calibration equipment should only be used by trained personnel.

•If this equipment is used in a manner not specified by the manufacturer,

the protection provided by the equipment may be impaired.

•Before initial use, or after transport, or after storage in humid or semi-hu-

mid environments, or anytime the instrument has not been energized for

more than 10 days, the instrument needs to be energized for a "dry-out"

period of 2 hours before it can be assumed to meet all of the safety re-

quirements of the IEC 1010-1. If the product is wet or has been in a wet

environment, take necessary measures to remove moisture prior to apply-

ing power such as storage in a low humidity temperature chamber

operating at 50°C for 4 hours or more.

•This instrument can measure extreme temperatures. Precautions must be

taken to prevent personal injury or damage to objects. Probes may be ex-

tremely hot or cold. Cautiously handle probes to prevent personal injury.

1521 Handheld Thermometer Readout

User’s Guide

2

Carefully place probes on a heat/cold resistant surface or rack until they

reach room temperature.

•The AC adapter can present safety concerns if misused or damaged. To

avoid the risk of electric shock or fire, do not use the AC adapter outdoors

or in a dusty, dirty, or wet environment. If the cord, case, or plug of the

adapter is damaged in any way, discontinue its use immediately and have

it replaced. Never disassemble the AC adapter. Use only the AC adapter

provided with the instrument or equivalent adapter recommended by the

manufacturer of this instrument.

•The AC adapter has circuits with high voltage inside that could present

danger of electrical shock or fire if exposed. If the AC adapter is damaged

in any way or becomes hot, discontinue its use immediately, disconnect it

from any AC supply, and have it replaced. Do not attempt to open, repair,

or continue using a damaged or defective AC adapter.

•The instrument batteries can present danger if not handled properly. To

avoid the risk of exposure to dangerous substances or explosion, immedi-

ately remove the batteries and discontinue use if they leak or become

damaged. Never allow the batteries to be shorted, heated, punctured, or

dropped. If the instrument is physically damaged, immediately remove

the batteries to insure that they do not become shorted. While removed

from the instrument, store the batteries in a location so that they do not

come into contact with metal or fluids that might short circuit the batteries

and where they are safe from excessive temperatures. Used batteries must

be disposed of properly. Check your local regulations for additional infor-

mation. You may return the used batteries to the manufacturer. Never dis-

pose of batteries in fire which may result in explosion with the possibility

of personal injury or property damage.

•DO NOT use this instrument in combination with any probe (RTD or

thermistor) to measure the temperature or resistance of any device that is

electrically energized. Severe electric shock, personal injury, or death may

occur.

1.2.2 Cautions

To avoid possible damage to the instrument, follow these guidelines.

•If the instrument is dropped, struck, or handled in a way that causes inter-

nal or external physical damage, immediately unplug the AC adapter, re-

move the batteries, discontinue use, and contact the factory for repair. Do

not attempt to disassemble or repair the instrument, batteries, or AC

adapter. Refer repairs or replacement components to the manufacturer.

•The instrument and thermometer probes are sensitive and can be easily

damaged. Always handle these devices with care. DO NOT allow them to

be dropped, struck, stressed, or overheated.

•DO NOT leave the AC adapter plugged in for more than 24 consecutive

hours or the battery life could be degraded.

3

1 Before You Start

Safety Information

•Probes are fragile devices which can be damaged by mechanical shock,

overheating, and absorption of moisture or fluids in the wires or hub.

Damage may not be visibly apparent but nevertheless can cause drift, in-

stability, and loss of accuracy. Observe the following precautions:

•DO NOT allow probes to be dropped, struck, bent, or stressed.

•DO NOT overheat probes beyond their recommended temperature range.

•DO NOT allow any part of the probe other than the sheath to be im-

mersed in fluid.

•DO NOT allow the probe hub or wires to be exposed to excessive temper-

atures.

•Keep the probe wires clean and away from fluids.

1.3 Authorized Service Centers

Please contact one of the following authorized Service Centers to coordinate

service on your Hart product:

Fluke Corporaton, Hart Scientific Division

799 E. Utah Valley Drive

American Fork, UT 84003-9775

USA

Phone: +1.801.763.1600

Telefax: +1.801.763.1010

E-mail: support@hartscientific.com

Fluke Nederland B.V.

Customer Support Services

Science Park Eindhoven 5108

5692 EC Son

NETHERLANDS

Phone: +31-402-675300

Telefax: +31-402-675321

E-mail: ServiceDesk@fluke.nl

Fluke Int'l Corporation

Service Center - Instrimpex

Room 2301 Sciteck Tower

22 Jianguomenwai Dajie

1521 Handheld Thermometer Readout

User’s Guide

4

Chao Yang District

Beijing 100004, PRC

CHINA

Phone: +86-10-6-512-3436

Telefax: +86-10-6-512-3437

E-mail: xingye.han@fluke.com.cn

Fluke South East Asia Pte Ltd.

Fluke ASEAN Regional Office

Service Center

60 Alexandra Terrace #03-16

The Comtech (Lobby D)

118502

SINGAPORE

Phone: +65 6799-5588

Telefax: +65 6799-5588

E-mail: antng@singa.fluke.com

When contacting these Service Centers for support, please have the following

information available:

•Model Number

•Serial Number

•Voltage

•Complete description of the problem

5

1 Before You Start

Authorized Service Centers

2 Introduction

The 1521 Handheld Thermometer Readout is a low-cost, high-accuracy digital

thermometer readout designed to be used with PRTs and thermistors. The

unique combination of features makes this instrument suitable for a wide vari-

ety of applications in industry. Features and capabilities of the 1521 include the

following:

•Measures with platinum resistance thermometers (PRTs) and thermistors

•Works with Hart’s special INFO-CON probe connector (which is partially

based on U.S. Patent 5,857,777) to automatically recognize the type of

sensor and its characteristics

•Automatically alerts the operator when the probe calibration or meter cal-

ibration expires

•Measures with an accuracy of ±0.025°C at 25°C with PRTs and ±0.005°C

at 25°C with thermistors

•Accepts three- or four-wire sensors to eliminate lead resistance errors

•Is immune to thermoelectric EMF

•Measures with a fast one-second measurement cycle

•Displays maximum, minimum, and delta temperatures

•Stores up to six measurements in memory

•Uses a unique factory-assigned pass-code to protect programmed settings

•Displays measurements and settings on a high-contrast LCD display

•Communicates with other equipment using an RS-232 serial interface

•Can be powered from its AC adapter or rechargeable battery

7

2 Introduction

3 Specifications and Environmental

Conditions

3.1 Specifications

Resistance Range 0

Ω

to 500 k

Ω

Resistance Accuracy, PRT, one

year

†

0

Ω

to 25

Ω

: 0.002

Ω

25

Ω

to 400

Ω

: 0.008% (80 ppm) of reading

Resistance Accuracy, thermistor,

one year

†

0

Ω

to2k

Ω

:0.4

Ω

2k

Ω

to 200 k

Ω

: 0.02% (200 ppm) of reading

200 k

Ω

to 500 k

Ω

: 0.03% (300 ppm) of reading

Temperature Range PRT: –200°C to 962°C (–328°F to 1764°F)

Thermistor: –50°C to 150°C (–58°F to 302°F)

Temperature Accuracy, PRT

†

–200°C to 100°C: ±0.025°C (0.045°F)

100°C to 400°C: ±0.05°C (0.09°F)

400°C to 800°C: ±0.1°C (0.18°F)

800°C to 962°C: ±0.15°C (0.27°F)

Temperature Accuracy,

2.25 k

Ω

thermistor

†

–50 to 25°C: ±0.005°C (0.009°F)

25°C to 50°C: ±0.01°C (0.018°F)

50°C to 75°C: ±0.03°C (0.054°F)

75°C to 100°C: ±0.08°C (0.144°F)

Temperature Accuracy,

10 k

Ω

thermistor

†

0 to 50°C: ±0.005°C (0.009°F)

50°C to 75°C: ±0.01°C (0.018°F)

75°C to 100°C: ±0.02°C (0.036°F)

100°C to 125°C: ±0.05°C (0.09°F)

125°C to 150°C: ±0.1°C (0.18°F)

Temperature Accuracy,

100 k

Ω

thermistor

†

0 to 50°C: 0.006°C (0.011°F)

50°C to 150°C: 0.009°C (0.016°F)

Resistance Resolution 0.001

Ω

Temperature Resolution 0.001°C, F, K, R

Probe IEC-751 or DIN-43760 PRT

Callendar-Van Dusen calibrated PRT; nominal 100

Ω

ITS-90 calibrated 25

Ω

or 100

Ω

PRT

YSI-400 series or equivalent 2252

Ω

thermistor

Steinhart-Hart thermistor polynomial; nominal R(25°C) 2k

Ω

to

100k

Ω

Probe Connector Hart Scientific INFO-CON connector

Maximum Acceptable Probe Lead

Resistance

10

Ω

Probe Excitation Current PRT: 0.5 mA

Thermistor: 5

μ

A

Measurement Period 1 second

9

3 Specifications and Environmental Conditions

Specifications

Digital Filter Exponential with adjustable time constant (1 to 60 seconds)

Remote Communications RS-232 serial

Display LCD, 6-digit x 7-segment with 16-character alphanumeric

Operating Temperature Range 0 to 40°C (32 to 104°F) absolute

15 to 35°C (59 to 95°F) full accuracy

Power 12 VDC (AC adapter included)

Rechargeable NiMH batteries (included)

Safety OVERVOLTAGE (Installation) CATEGORY II, Pollution Degree 2 per

IEC1010-1 refers to the level of Impulse Withstand Voltage protec-

tion provided. Equipment of OVERVOLTAGE CATEGORY II is en-

ergy-consuming equipment to be supplied from the fixed installation.

Examples include household, office, and laboratory appliances.

Size 7.75"H x4.2"Wx1.5"D (20 cm H x 11 cm W x 4 cm D)

Weight 0.4 kg (1.0 lb.)

†

Accuracy specifications apply from 15 to 35°C. Accuracy specifications over the entire absolute operating

range are 1.5 times the stated values. Temperature accuracy does not include probe uncertainty or probe

characterization errors. The practical measurement range may be limited by the sensor.

3.2 Environmental Conditions

Although the instrument has been designed for optimum durability and trou-

ble-free operation, it must be handled with care. The instrument should not be

operated in an excessively dusty, dirty, or wet environment. Maintenance and

cleaning recommendations can be found in the Maintenance section of this

manual.

For full accuracy, operate the instrument in ambient temperatures between

15-35°C (59-95°F). Do not operate the instrument in an environment colder

than 5°C (41°F) or warmer than 50°C (122°F).

The instrument operates safely under the following conditions:

•Operating temperature range: absolute 5–50°C (41–122°F);

full accuracy15-35°C (59-95°F)

•ambient relative humidity: maximum 80% for temperature <31°C, de-

creasing linearly to 50% at 40°C

•Pressure: 75kPa-106kPa

•Vibration should be minimized

•Altitude less than 2,000 meters

•Indoor use only

1521 Handheld Thermometer Readout

User’s Guide

10

4 Quick Start

This section briefly explains the basics of setting up and operating your 1521

Thermometer.

4.1 Unpacking

Carefully unpack the 1521 and accessories and inspect them to make sure all

components are present and in satisfactory condition. Verify that the following

items are present:

•1521 Thermometer

•AC Adapter (clamp-on ferrite installed)

•Serial Cable

•User’s Guide

•Report of Calibration

•Calibration Label

•Pass-code Notice

•INFO-CON Connector

•Clamp-on ferrite with instructions for probe

•Probe (optional—must be purchased separately)

If all items are not present, call an Authorized Service Center (see Section 1.3).

4.2 Use Proper Care with the 1521 and Accessories

First and most important is to understand the safety issues related to the 1521

and its accessories. Be aware that potential hazards exist due to high tempera-

tures, high voltages, and battery chemicals. Carefully read Section .

CAUTION: The 1521 and any thermometer probes are sensitive instru-

ments that can be easily damaged. Always handle these devices with care.

DO NOT allow them to be dropped, struck, stressed, or overheated.

4.3 Learn About the Features and Components

Familiarize yourself with the features and accessories of the 1521 by reading

Section 5.

4.4 Connect the Probe

The PRT or thermistor probe connects to the top of the 1521 using Hart’s

unique INFO-CON probe connector. The probe connector is inserted into the

11

4 Quick Start

Unpacking

top of the instrument with the ridged side down. It will fit snugly and lock into

place when it is fully inserted.

The INFO-CON probe connector includes a memory device that stores the

unique characteristics of the probe, allowing the 1521 to measure tempera-

ture accurately. If your probe was purchased from Hart for use with the 1521 it

should already have the connector attached and properly programmed. You can

use your own probe with the 1521, but you must attach it with an INFO-CON

connector. See Section 6.6 for more information on the INFO-CON connector.

4.5 Connect the Power Source

The 1521 draws power from either a DC power supply (the included AC

adapter) connected to the DC input or the internal rechargeable battery pack. To

use the AC adapter, plug it into a wall outlet of the appropriate voltage and in-

sert the DC plug into the DC power input of the 1521 (see Figure 2.) To use the

battery pack it must first be fully charged using the AC adapter (see Section

6.1).

4.6 Switch the Power On

Power is switched on and off with the power button located below and to the

left of the display. To switch the power on, hold the power button down for at

least two seconds. (To switch power off, momentarily press the power button

again.) The instrument takes a few seconds to power up, initialize itself, and be-

gin normal operation. During initialization the lower line of the display shows

the manufacturer, model number, firmware version, and the state of battery

charge or the message “External power” if the AC adapter is attached. The

1521 reads important information about the attached probe from the

INFO-CON connector that it subsequently uses to calculate temperature.

The 1521 then performs a memory check of critical parameters, such as the cal-

ibration parameters CAL1 and CAL2. During this check the lower line of the

display reads “Checking Memory”. If a “Memory Error” or “Memory Recover”

message is displayed, see Section 12.1, Troubleshooting, for additional infor-

mation and instructions.

4.7 Measure Temperature

After initialization the upper line of the display will begin to show temperature

measurements sensed at the tip of the probe. Place the tip of the probe into the

object that you want to measure the temperature. DO NOT force the probe or

otherwise allow it to be bent, stressed, or overheated. It can be easily damaged

if misused. For further suggestions on handling the probe and using the 1521

and probe to measure temperature accurately, see Section 6.5. For information

on the various modes of operation of the 1521see Section 7.

1521 Handheld Thermometer Readout

User’s Guide

12

5 Parts and Controls

The functions of the various features of the 1521 are described below.

5.1 Front Features

The front of the 1521 features the LCD display and control buttons.

13

5 Parts and Controls

Front Features

Display-The display shows the current temperature (or resistance) measure-

ment on the large numeric upper portion of the display. It can also show a vari-

ety of information on the smaller alphanumeric lower portion such as

minimum, maximum, hold temperatures, delta(x), and other instrument

settings.

Power and Backlight button-This button turns the instrument on or off. If the

power is on, pressing the button for three seconds toggles the backlight on or

off (see Section 6.3). Note: using the backlight drains the battery more

quickly.

ENT (enter) button-This button is pressed to accept changes to a setting and,

in some modes, to store the most recent measurement.

CLR (clear) button-This button cancels changes to a setting and in the

MIN/MAX mode resets the minimum and maximum to the last measurement.

UpandDownbuttons-These buttons are used to change values and settings.

MODE button-This button advances through operating modes and program-

ming functions (see Section 7).

1521 Handheld Thermometer Readout

User’s Guide

14

5.2 Top and Side Features

The top and side of the 1521 feature the probe connector, DC power input, se-

rial port, and infrared window.

Probe Connector - At the top of the thermometer is the opening where the

probe connector is inserted. The probe must be connected using an INFO-CON

probe connector to measure temperature (see Section 6.6).

DC Power Input-The AC adapter plugs into the DC power input to recharge

the battery and to power the instrument while the battery is being charged (see

Section 6.2).

Serial Port-The RS-232 serial port provides a means of connecting the 1521 to

a computer or a printer using the included serial cable (see Section 8). The

baud rate is fixed at 2400 baud, the linefeed is fixed to ON (all carriage returns

are followed by a linefeed (ASCII decimal 10), and the duplex is fixed to Half

disabling the echo.

Infrared Window-The infrared window has no functionality.

15

5 Parts and Controls

Top and Side Features

DC Power Input Stand

Probe Connector

Top View

Side View

Serial Port Infrared Window

(not used)

Figure 2 Top and Side View

5.3 Back Features

See Figure 4 on page 19.

Stand-The stand at the back of the 1521 can be flipped down to prop up the in-

strument for better viewing.

Battery Compartment- Behind the stand is the compartment that contains the

battery pack. The battery pack can be accessed if necessary by opening the bat-

tery cover with a small Philips screwdriver (see Section 6.1).

Serial Number Label-Also behind the stand is the serial number label that

uniquely identifies the instrument.

5.4 Internal Features

The significant components inside the 1521 are described here.

Battery-The 1521 has an internal rechargeable battery pack that can be re-

charged by the AC adapter without removing the battery. It can be used and re-

charged many times. If necessary, it can be easily removed and replaced (see

Section 6.1).

Micro-controller-The 1521 uses a micro-controller to control all its functions.

The micro-controller manages the measurement process, retrieves measurement

data from the analog-to-digital converter (ADC), places measurements and

other information on the display, senses button actions, reads battery status in-

formation from the power control circuit, and handles communications through

the serial port.

Power Control Circuit-The power control circuit manages the electrical power

that drives all the circuits. It handles switching between the two sources of

power (DC input and battery pack), regulates voltages, monitors the state of

battery charge, and manages battery charging.

Analog-to-Digital Converter and Measurement Circuit-The ADC takes an

analog signal produced by the probe and converts it to a digital value that can

be read by the micro-controller. The ADC used in the 1521 was selected for its

excellent resolution, linearity, and stability. The measurement circuit built

around the ADC was carefully designed for accuracy and stability to match the

ADC. The measurement circuit allows complete rejection of probe wire resis-

tance effects that would otherwise seriously limit accuracy. Offsets from

sources such as thermoelectric EMF are also completely rejected. This is done

using a current reversal technique with the probe current alternating at a rate of

one cycle per second. Self-heating is minimized by using low sensing currents.

For PRTs the current is only 0.5 mA. For thermistors the current is only 0.005

mA.

1521 Handheld Thermometer Readout

User’s Guide

16

5.5 Accessories

The 1521's accessories and their features are described here.

AC Adapter-The AC adapter recharges the internal battery pack and can also

be used to supply power to operate the 1521 while the battery is being charged

(see Section 6.2).

Serial Cable-The serial cable can be used to connect a computer or a printer to

the 1521 through its serial port (see Section 8).

INFO-CON Connector-Hart’s unique INFO-CON connector allows the probe

to be easily attached and detached from the 1521. It also contains a memory de-

vice that stores information about the probe and automatically transfers

this data to the 1521 when the probe is attached. This ensures that the set-

tings used to measure and calculate temperature always match the probe being

used (see Section 6.6).

Probe-The probe acts as the temperature sensor. Its resistance depends on its

temperature. The 1521 precisely measures the resistance of the probe and uses

the coefficients stored in the INFO-CON connector to calculate its temperature

(see Section 6.5). The following probe options are available.

17

5 Parts and Controls

Accessories

INFO-CON

Figure 3 INFO-CON Connector

Ordering Information

Model Type Range Size

Cal Uncertainty and

Repeatability

Typical Drift

(1 year)

5626 Pt-100 Ohm, 4-wire –200 to 660°C 1/4” x 12” or 15”

(6.35 x 305 or 381 mm)

±0.015°C ±0.03°C

5628 Pt-25 Ohm, 4-wire –200 to 660°C 1/4” x 12” or 15”

(6.35 x 305 or 381 mm)

±0.015°C ±0.03°C

5614 Pt-100 Ohm, 4-wire –200 to 450°C 1/4” x 12” (6.35 x 305 mm) ±0.025°C ±0.01°C

5613 Pt-100 Ohm, 4-wire –200 to 300°C 3/16” x 6” (4.76 x 152 mm) ±0.025°C ±0.01°C

5612 Pt-100 Ohm, 4-wire –200 to 450°C 3/16” x 9” (4.76 x 229 mm) ±0.025°C ±0.01°C

5627–6 Pt-100 Ohm, 4-wire –200 to 300°C 3/16” x 6” (4.76 x 152 mm) ±0.035°C ±0.13°C

5627–9 Pt-100 Ohm, 4-wire –200 to 450°C 3/16” x 9” (4.76 x 229 mm) ±0.035°C ±0.13°C

5627–12 Pt-100 Ohm, 4-wire –200 to 450°C 1/4” x 12” (6.35 x 305 mm) ±0.035°C ±0.13°C

5610-6 10K-ohm Thermistor 0 to 110°C 1/8” x 6” (3.2 x 152 mm) ±0.02°C ±0.01°C

5610-9 10K-ohm Thermistor 0 to 110°C 1/8” x 9” (3.2 x 229 mm) ±0.02°C ±0.01°C

5611 10K-ohm Thermistor 0 to 110°C 0.07” x 0.55” (1.8 x 14 mm) ±0.02°C ±0.01°C

5611T 10K-ohm Thermistor 0 to 110°C 0.11” x 1.1” (2.8 x 28 mm) ±0.02°C ±0.01°C

5640 4K-ohm Thermistor 0 to 60°C 1/4” x 9” (6.35 x 229 mm) ±0.0015°C ±0.005°C

LogWa r e Software - The Model 9934 LogWare software is a one channel data

acquisition software. This software can be used with your 1521 thermometer to

collect and graph data.

Carrying Cases - There are two types of cases available for your 1521 ther-

mometer. The Model 9318 case is a hard case for carrying the thermometer and

a 12" probe. The Model 9321 case is a soft case with a belt clip and a probe

slot.

1521 Handheld Thermometer Readout

User’s Guide

18

6 General Operation

This section explains the details of the operation of the 1521 with its compo-

nents and accessories.

6.1 Battery

The 1521 has a built-in nickel-metal-hydride battery pack that can power the

instrument for about 18 hours before needing to be recharged. The battery will

discharge much more quickly if the display backlight is used often. The battery

charge remaining or the message “External Power” is shown on the display

when the instrument is switched on. The battery percentages are approximate

and should be used as general guidelines when determining the length of

charge remaining.

The battery is recharged in situ (while in place) using the AC adapter that’s

provided. Plug the AC adapter into an AC socket of the appropriate voltage as

noted on the AC adapter (normally 115V, optionally 230V). Connect the DC

plug of the adapter into the DC input of the 1521 located on the right side. The

battery will be charged as necessary whether or not the instrument is switched

19

6 General Operation

Battery

Battery cover

Battery

Battery plug

Battery connector

Battery installed and connected

Battery removed

Stand in vertical position

MODEL:

SERIAL NO:

1521

941234

FLUKE CORPORATION

HART SCIENTIFIC DIVISION

MADE IN USA

MODEL:

SERIAL NO:

1521

941234

FLUKE CORPORATION

HART SCIENTIFIC DIVISION

MADE IN USA

Figure 4 Battery Installation

on. The power control circuit inside the instrument manages battery charging

and will stop charging the battery automatically when it’s fully charged. It nor-

mally takes about four hours to fully charge the battery. The instrument can be

operated while the battery is being charged.

CAUTION: DO NOT leave the AC adapter plugged in for more than 24

consecutive hours or, the battery life could be degraded.

The battery pack can be used for a minimum of 500 charge-discharge cycles

before needing to be replaced. Replacement battery packs are available from

the manufacturer. The battery pack can be easily removed and replaced in the

field by following this procedure:

1. Power the 1521 off and unplug the AC adapter from the unit.

2. With the 1521 facing down, lift the stand to expose the battery cover (see

Figure 4). Remove the battery cover screw with a small Philip’s screw-

driver. Place the screw in a safe place so it won’t get lost. Remove the

battery cover to access the battery pack.

3. Pull the battery pack out. Note the orientation of the battery plug on

the connector. The new battery pack will be plugged in the same direc-

tion. Gently pull the battery plug off the connector.

4. Attach the polarized plug of the new battery pack onto the connector in

the same direction as before (see Figure 4 on page 19). Place the battery

pack in the battery compartment.

5. Close the battery cover and replace the screw.

6. Plug in the AC adapter and charge for a minimum of four hours for its

initial charge.

WARNING: Used batteries must be disposed of properly. Check your lo-

cal regulations for additional information. You may return used batteries

to the manufacturer. Never dispose of batteries in fire as this may result in

explosion with the possibility of personal injury or property damage.

6.2 DC Power Source

The DC power source provides power to charge the battery. It can also be used

to power the 1521 while the battery is being charged. The AC adapter provided

with the 1521 is intended to be used for these purposes. Use only the AC

1521 Handheld Thermometer Readout

User’s Guide

20

adapter supplied with the instrument. The DC power source plugs into the DC

power input on the right side of the 1521.

WARNING: The AC adapter has circuits with high voltages inside that

could present danger of electric shock or fire if exposed. If the AC adapter

is damaged in any way or becomes hot, discontinue its use immediately,

disconnect it from any AC supply, and have it replaced. Do not attempt to

open, repair, or continue using a damaged or defective AC adapter.

6.3 Power Button

The power button controls power to the instrument and operates the backlight.

The following table summarizes the power button functions.

Function Action

Power on Press the power button for at least two seconds when the power is off

Power off Press the power button momentarily (1/2 second or less) when the power is on

Backlight on Press the power button for three seconds or more when the power is on and

the backlight is off

Backlight off Press the power button for three seconds or more when the backlight is on

6.4 Display and Backlight

The display shows measurement data and other information depending on the

selected mode.

The upper part of the display continually shows the most recent measurement.

It uses large digits for easy viewing. A new measurement is produced and dis-

played every second. The unit associated with the measurement is shown in

21

6 General Operation

Power Button

+

–

Figure 5 12V DC Power Source Polarity

smaller type to the right of the measurement. The possible units are degrees

Celsius (C), resistance in ohms (Ω), degrees Fahrenheit (F), Kelvin (K), and

degrees Rankine (R). The units can be easily changed by placing the display in

the units setting mode using the MODE button (see Section 7.5).

The lower part of the display has various functions depending on the selected

mode. It has smaller alphanumeric characters. It can be used to display mini-

mum and maximum measurements, delta(x) measurements, or measurements

stored in memory. It is also used to view and set various operating parameters.

The mode is easily changed using the MODE button. (See details on the vari-

ous modes beginning with Section 7.)

The display has a backlight that can be switched on for better viewing in dim

light. The backlight is switched on and off by pressing and holding the power

button for three seconds (see Section 6.3 above). Note: The battery dis-

charges more quickly when the backlight is used.

6.5 Probe

The probe is used to sense temperature. The probe attaches to the 1521 using a

Hart INFO-CON probe connector that plugs into the top of the instrument. The

probe connector must be properly programmed with the correct charac-

teristics of the probe for measurements to be accurate (see Section 6.6).

The 1521 can be used with various types of PRT and thermistor probes:

•ITS-90 calibrated 25Ωor 100ΩPRT

•IEC-751 or DIN-43760 PRT (RTD)

•Callendar-Van Dusen calibrated 100ΩPRT

•YSI-400 series or equivalent 2252Ωthermistor

•Steinhart-Hart thermistor polynomial; nominal R(25°C) 2kΩto 100kΩ

See Section 7.8.8 for details on the various probe types and their programming.

The 1521 cannot be used with thermocouples.

The 1521 can be used with probes having two, three, or four wires. Three wires

allow partial compensation for wire resistance. The 1521 measures three-wire

probes using the following algorithm. It measures the sensor resistance, includ-

ing the lead resistance in C2. The 1521 then directly measures the resistance in

the C1 lead of the sensor. The 1521 then subtracts the measured C1 lead resis-

tance from the measured sensor resistance (including the C2 lead resistance) to

obtain the sensor resistance used to calculate temperature. Note: This algorithm

assumes that the lead resistance of C1 and C2 are equal. If C1 and C2 have dif-

ferent resistance there will be an error in the calculated sensor resistance equal

to this difference. Four wires allow complete rejection of wire resistance and

should be used when the best accuracy is desired. The 1521 wire setting must

be set to match the actual number of wires of the probe (see Section 7.8.14).

1521 Handheld Thermometer Readout

User’s Guide

22

Temperature is generally sensed at the tip of the probe. To get an accurate tem-

perature measurement the probe sheath should be well immersed, with ade-

quate depth and fit, into the medium to be measured.

CAUTION: Probes are fragile devices that can be easily damaged by me-

chanical shock, overheating, and absorption of moisture or fluids in the

wires or hub. Damage may not be visibly apparent but nevertheless can

cause drift, instability, and loss of accuracy. Observe the following pre-

cautions:

Do not allow probes to be dropped, struck, bent, or stressed.

Do not overheat probes beyond their recommended temperature range.

Do not allow any part of the probe other than the sheath to be immersed in

fluid.

Do not allow the probe hub or wires to be exposed to excessive temperatures.

Keep the probe wires clean and away from fluids.

6.6 INFO-CON Connector

The probe connects to the top of the 1521 using a Hart INFO-CON connector

(see Figure 3 on page 17). The probe connector will fit snugly and lock into

place when it is fully inserted. The connector includes a memory device that

stores the unique characteristics of the probe, allowing the instrument to mea-

sure temperature accurately. Generally, the probe will be purchased with the

connector attached and programmed by the factory. Connectors can be pur-

chased separately and installed onto probes by the user. The INFO-CON can be

programmed directly from the 1521 by authorized personnel.

If it is necessary to install the INFO-CON onto a probe in the field follow the

diagram below for connecting the wires of the probe to the connector terminals.

Before opening the INFO-CON case, be sure to be grounded with an ESD strap

to avoid damaging the memory chip. For four-wire probes, one pair of wires at-

taches to terminals C1 and P1 and the other pair attaches to terminals C2 and

P2. (C1 and C2 source current and P1 and P2 sense the potential.) If a shield

wire is present it should be connected to the GND terminal (see Figure 6).

A three-wire or two-wire probe can also be used with the 1521. A three-wire

probe is connected by attaching the common wires to the C1 and P1 terminals

and the other wire to the C2 and P2 terminals. The two-wire probe is connected

by one wire to the C1 and P1 terminals and the other wire to C2 and P2. Again,

any shield wire should be connected to the GND terminal (see Figure 6). Rec-

23

6 General Operation

INFO-CON Connector

ognize that accuracy may be significantly degraded using a two-wire connec-

tion because of wire resistance.

1521 Handheld Thermometer Readout

User’s Guide

24

GND

P1

C2

P2

C1

J1 J2

Four-wire Connection

GND

P1

C2

P2

C1

J1 J2

Three-wire Connection

GND

P1

C2

P2

C1

J1 J2

Two-wire Connection

Short

Short

Figure 6 Probe Wiring Diagrams

7 Display Functions

The 1521 operates in any of several modes which determine what information

is visible in the lower alphanumeric portion of the display. The MODE button

changes the mode. This button can be pressed repeatedly until a desired mode

is set. The various modes are listed below in the order they appear. (See Figure

7).

Blank - No data shown

Min/Max - Minimum and maximum measurements (CLR to reset)

Hold - Data stored in the hold registers

Delta(x) - Delta from reference measurement (ENT to set reference)

Units: C/Ω/F/K/R - Set the units of measurement

Rate: 00000 - Set the period for serial transmission

Resol: XXX.XXX - Set the display resolution

CAL MODE - Set probe and instrument calibration parameters (MODE

button must be held for three seconds) See Section 7.8.

Note: Units, Rate, and Resol are temporary modes. The instrument will return

to Delta(x) mode if left in one of these modes when the power is cycled.

25

7 Display Functions

Each of these operating modes is described in the sections that follow.

7.1 Blank Mode

This mode is identified by “Blank” that temporarily appears on the display.

1521 Handheld Thermometer Readout

User’s Guide

26

Blank Mode

Set Units

Min/Max Mode

Set Rate

Hold Mode

Set Resolution

Cal Mode

button

button

button

button

button

button

button (3 seconds)

any mode

MODE

MODE

MODE

MODE

MODE

MODE

MODE

Delta(x) Mode

button

MODE

Figure 7 Operating Modes Flowchart

In this mode nothing appears on the alphanumeric portion of the display. Use

this mode if you are only interested in the latest measurements and want to sim-

plify the appearance of the display.

The message “Prb cal expired”, “Mtr cal expired”, “Recharge Needed”, or

“Probe is locked” may be displayed. See Section 11.1.

7.2 Min/Max Mode

This mode is identified by “Min/Max” that temporarily appears on the display.

In this mode the maximum and minimum measurements taken since the last

time the function was cleared appears on the display. The minimum appears on

the left and the maximum appears on the right. The resolution of the displayed

values may be changed using the Resolution mode (see Section 7.7). Pressing

the CLR button at anytime while in this mode clears the minimum and maxi-

mum values setting them to the last measurement. Both the minimum and max-

imum are reset to 0°C (32°F) when the instrument is powered up.

The message “Prb cal expired”, “Mtr cal expired”, “Recharge Needed”, or

“Probe is locked” may be displayed. See Section 11.1.

7.3 Hold Mode

This mode is identified by “Hold” that temporarily appears on the display.

In this mode the data stored in one of the hold registers appears on the display.

There are six hold registers. The resolution of the Hold register values may be

changed using the Resolution Mode (see Section 7.7). The Up and Down but-

tons are used to select a desired hold register for viewing. The ENT button is

used to store a measurement in the next available register.

The message “Prb cal expired”, “Mtr cal expired”, “Recharge Needed” , or

“Probe is locked” may be displayed. See Section 11.1.

7.4 Delta(x) Mode

This mode is identified by “Delta(x)” that temporarily appears on the display.

In this mode the delta between the measurement and a previously stored refer-

ence value appears on the right side of the display. The reference value appears

on the left. The resolution of the reference value may be changed using the

Resolution mode (see Section 7.7) if necessary. The ENT button stores the

present measurement as the reference value.

The message “Prb cal expired”, “Mtr cal expired”, “Recharge Needed” , or

“Probe is locked” may be displayed. See Section 11.1.

27

7 Display Functions

Min/Max Mode

7.5 Units

This mode is identified by “Units: C/Ω/F/K/R” that appears on the display.

This mode allows you to select the unit of measurement: C for degrees Celsius,

Ωfor resistance in ohms, F for degrees Fahrenheit, K for Kelvin, and R for

Rankine. The Up and Down buttons are used to select one of the displayed

units. The underline cursor indicates which of the units is selected. The ENT

button stores the selection. If the MODE button or CLR button is pressed with-

out pressing ENT the unit remains unchanged. Once the unit is selected, subse-

quent measurements appear in that unit. The Min/Max and Delta(x) values

are automatically converted when changing to C, K, F, or R units.

When measuring in units of ohms, make sure that the appropriate probe type

has been selected in the Cal Mode menu. For example, to measure a sensor be-

tween 0 and 400 ohms, set the units to ohms and select the probe type "CVD".

To measure a sensor between 400 and 500K ohms, set the units to ohms and se-

lect the probe type "THERM".

7.6 Rate

This mode is identified by “Rate: 00000" that appears on the display.

This mode allows you to set the samples that are transmitted through the serial

port. The sample for a 2-wire and a 4-wire probe is approximately one second

and for a 3-wire probe is approximately two seconds. For example, if the rate is

set to 2, every other sample is sent through the serial interface. Note: If the

probe wire is set to 3, the time between samples is twice as long. A value of 0

disables transmission. The Up and Down buttons are used to increase or de-

crease the value for the underlined digit. The ENT button moves to the next

digit. If the ENT button is pushed when the last digit is underlined, the setting

is stored. If the MODE button or CLR button is pressed, the value remains un-

changed. Once the value is set, measurements are transmitted through the serial

port at the given interval.

7.7 Resolution

This mode is identified by “Resol: XXX.XXX” that appears on the display.

This mode allows you to set the resolution of measurements to one, two, or

three digits after the decimal point. The Up and Down buttonsareusedtoin

-

crease or decrease the resolution setting. The ENT button stores the setting. If

the MODE button or CLR button is pressed, the setting remains unchanged.

Once the resolution is set, measurements are displayed and transmitted from

the serial port at the given resolution if possible. The resolution may be reduced

if necessary for large values of temperature or resistance.

1521 Handheld Thermometer Readout

User’s Guide

28

7.8 CAL MODE

The calibration menu contains functions for setting probe and instrument cali-

bration parameters. If a probe parameter is changed, the probe parameter is up-

loaded into the INFO-CON probe connector when the CAL MODE is exited or

after scrolling through the entire menu. Always check to insure that the param-

eters have been written to the INFO-CON connector by disconnecting the

probe or by turning the 1521 off and on.

The calibration menu is entered by pressing and holding the MODE button for

three seconds. “CAL MODE” appears on the display. Press the ENT button to

advance. Press the MODE button while in the calibration menu to exit and to

advance to the display mode that follows the display mode that was active be-

fore the CAL Mode was entered.

The functions contained in the CAL Mode are listed below in the order they ap-

pear. In any of the functions the ENT button stores the displayed value or se-

lection and advances to the next function. The CLR button can be used to

cancel changes to a value or selection and skip to the next function. Use the

ENT button to move from Mtr Due to Prb Due and then to Time. Use the CLR

button to quickly advance through the remaining functions. Many of the func-

tions are in the passcode protected part of the CAL Mode. You must enter the

correct passcode to reach them.

Mtr Due - View the date the instrument is due for calibration

Prb Due - View the date the probe is due for calibration

Time - View and set the real-time clock time-of-day

Passcode - Enter the passcode to advance to the protected functions

Date - View and set the real-time clock date

Probe Lock - Lock or unlock operation of the unit with the current probe

only

Prb # - Set the probe serial number

Prb Type - Select the probe type and temperature calculation

R(.01) [ITS-90 only] - Sets the R(273.16K) probe coefficient

a[ITS-90 only] - Set the a5, a6, a7, a8, a9, a10, or a11 probe coefficient

b[ITS-90 only] - Set the b5, b6, b7, b8, or b9 probe coefficient

c[ITS-90 only] - Set the c6, or c7 probe coefficient

d[ITS-90 only] - Set the d probe coefficient

a4 [ITS-90 only] - Set the a4 or a5 probe coefficient

b4 [ITS-90 only] - Set the b4 or b5 probe coefficient

R(0) [CVD only] - Set the R0 probe coefficient

Alpha [CVD only] - Set the alpha probe coefficient

Delta [CVD only] - Set the delta probe coefficient

29

7 Display Functions

CAL MODE

Beta [CVD only] - Set the beta probe coefficient

b0 [Therm only] - Set the b0 probe coefficient

b1 [Therm only] - Set the b1 probe coefficient

b2 [Therm only] - Set the b2 probe coefficient

b3 [Therm only] - Set the b3 probe coefficient

Probe Wires - Set the number of wires of the probe

PCal - Set the probe calibration date

PDue - Set the probe calibration due date

Filter - Set the digital filter time constant

MCal - Set the instrument calibration date

MDue - Set the instrument recalibration due date

CAL1 - Set the 0 to 400Ωinstrument calibration parameter

CAL2 - Set the 400Ωto 500 kΩinstrument calibration parameter

The calibration functions are described in detail in the following subsections.

7.8.1 Mtr Due

This function displays the date the 1521 is due for calibration. The date cannot

be changed with this function.

7.8.2 Prb Due

This function displays the date the probe is due for calibration. The date is

stored in the INFO-CON probe connector. The date cannot be changed with

this function.

7.8.3 Time

This function displays and sets the time of day. The time is always set, dis-

played, or printed in 24-hour format. To set each time segment use the Up and

Down buttons. Use the ENT button to move between time segments and to

save the changed values. The CLR button moves to the next function.

7.8.4 Passcode

All functions below this function are protected by a pass-code so that only au-

thorized users can access them. The passcode must be entered correctly to con-

tinue. If the passcode is entered incorrectly or the MODE or CLR buttons are

pressed, the message “Invalid Passcode” is displayed and the instrument is re-

turned to the next display mode after the display mode that was active before

the CAL Mode was entered.

Each individual instrument has its own unique passcode. The passcode number

is given on a notice provided with this instrument. The equipment manager is

responsible for keeping the passcode number stored in a proper location and

1521 Handheld Thermometer Readout

User’s Guide

30

ensuring that it is not lost or forgotten. If necessary the passcode can be re-

stored by contacting the manufacturer. To enter the passcode use the Up and

Down buttons to set each digit of the passcode and the ENT button to move to

the next digit on the right. Press ENT twice when all digits are entered to move

to the next function. If the passcode is entered correctly the next function in the

CAL Mode will appear.

7.8.5 Date

This function displays the present date and allows it to be changed. This func-

tion is placed in the passcode protected part of the CAL Mode since the calibra-

tion due warning messages depend on the present date as well as the stored due

dates. Use the Up and Down buttons to set each date segment and the ENT

button to move between the date segments. Press ENT when all digits are en-

tered to save the changed values. The CLR button moves to the next function.

7.8.6 Probe Lock

This function locks or unlocks operation of the unit with the presently con-

nected probe only. If probe lock is set to ON, the instrument can only be used

to display temperature with the probe attached when probe lock was set ON. If

probe lock is ON and a different probe is attached the instrument will display

the serial number of the connected probe, ‘PRT: xxxxxxxxxx’, and then the

message “Probe is locked”. Measuring will be disabled. If probe lock is OFF

the instrument can be used with any probe. To lock the instrument with a new

probe, set probe lock OFF, attach the new probe, and then set probe lock ON

again. Probe lock ON also disables access to the probe parameters that follow

in the menu. The probe parameters, beginning with the probe serial number,

will only appear in the menu if probe lock is OFF. To set probe lock use the Up

and Down buttons to select ON or OFF and press the ENT button to store and

continue.

7.8.7 Prb #

This function displays the serial number of the probe and allows it to be set.

The probe serial number is stored in the INFO-CON probe connector. Use

the Up and Down buttons to set each digit and the ENT button to move to the

next digit on the right. Press ENT when all digits are entered.

7.8.8 Prb Type

This function specifies the type of probe and its characterization. It allows the

1521 to use the appropriate algorithm to calculate temperature from the mea-

sured resistance of the probe. The functions that follow the probe conversion

function for setting probe characterization coefficients depend on the selected

probe type. The table below lists the probe types and the corresponding

coefficients.

Probe Type Description Coefficients

31

7 Display Functions

CAL MODE

ITS-90 PRTs calibrated to ITS-90 R(.01), a, b, c, d, a4, and b4

IEC751 PRTs (RTDs) conforming to IEC-751 none

CVD PRTs characterized by the Callendar-Van Dusen

equation

R0, Alpha, Delta, and Beta

YSI400 Thermistors matching the YSI-400 series none

THERM Thermistors characterized by the thermistor

polynomial

b0, b1, b2, and b3

Each of the conversion options is explained in the following sections along

with their associated coefficients, if they have any. The probe type and associ-

ated coefficients are stored in the INFO-CON probe connector. Use the Up and

Down buttons to select the probe type and the ENT button to store and

continue.

Each of the coefficients that follow the probe type, if there are any, are set in

theusualway.UsetheUp and Down buttons to set each digit and the ENT but-

ton to move to the next digit to the right. Press ENT when all digits are entered.

7.8.9 ITS-90

The ITS-90 type is for PRTs calibrated and characterized using the Interna-

tional Temperature Scale of 1990 equations. This type of probe generally has

excellent accuracy (0.005 to 0.025°C), a wide operating range (–180°C to

420°C or higher), but may be rather expensive. The coefficients that appear

when ITS-90 is selected are “R(.01)”, “a”, “b”, “c”, “d”, “a4", and ”b4".These

should be set to the coefficient values that appear on the PRT calibration certifi-

cate according to the following table.

Unused coefficients must be set to 0.

1521 Coefficients Certificate Value

R(.01) Rtpw

a a5, a6, a7, a8, a9, a10, or a11

b b5, b6, b7, b8 or b9

cc6orc7

dd

a4 a4 or a5

b4 b4 or b5

Consider the following examples.

Example 1:

1521 Handheld Thermometer Readout

User’s Guide

32

A PRT was calibrated to ITS-90 and its calibration certificate states values for

coefficients R(273.16K), a4, b4, a8, and b8. Set the 1521 coefficients to the

certificate values as follows.

1521 Coefficients Certificate Value

R(.01) R(273.16K)

aa8

bb8

c0.0

d0.0

a4 a4

b4 b4

Example 2:

A PRT was calibrated to ITS-90 and its calibration certificate states values for

coefficients R(273.16K), a5, and b5. Set the 1521 coefficients to the certificate

values as follows.

1521 Coefficients Certificate Value

R(.01) R(273.16K)

aa5

bb5

c0.0

d0.0

a4 a5

b4 b5

7.8.10 IEC751

The IEC-751 probe type is for standard PRTs (RTDs) conforming to the

IEC-751 or DIN-43760 standards. This type of probe is generally low cost and

has a wide operating range (–180°C to 420°C or higher), but has limited accu-

racy (0.15°C to 4°C). There are no user programmable coefficients associated

with this probe type.

7.8.11 CVD

The CVD (Callendar-Van-Dusen) type is used with PRTs that have unique cal-

ibration coefficients or do not match the IEC-751 specification. This type of

higher), and has moderate accuracy (0.05°C to 1°C). This type uses the

Callendar-Van Dusen equation to calculate temperature from resistance:

rt C

Rt tt

R

([ ])°=

+− −

⎛

⎝

⎜⎞

⎠

⎟

⎡

⎣

⎢⎤

⎦

⎥

⎧

⎨

⎩

⎫

⎬

⎭≥

0

0

11

100 100 10αδ

1100 100 1100 1100

3

+− −

⎛

⎝

⎜⎞

⎠

⎟−−

⎛

⎝

⎜⎞

⎠

⎟⎛

⎝

⎜⎞

⎠

⎟

⎡

⎣

⎢

αδ βttt t t

⎢

⎤

⎦

⎥

⎥

⎧

⎨

⎩

⎪

⎫

⎬

⎭

<

⎧

⎨

⎪

⎪

⎩

⎪

⎪t0

The coefficients R0, α,δ,andβcan be set by the user using the functions

“R0", ”Alpha", “Delta”, and “Beta” respectively. When editing “Alpha”, there

is an assumed exponent of 10–3 (i.e. 3.8500 is actually 0.0038500).

7.8.12 YSI-400

The YSI-400 type is for 2252Ωthermistors matching the characteristics of the

YSI-400 series of thermistors. This type of probe generally is low cost, has a

limited operating range (–40°C to 150°C), good accuracy (0.1°C to 0.4°C), and

excellent resolution (0.002°C). There are no user programmable coefficients as-

sociated with this probe type. Temperature is converted from resistance based

upon a standard YSI-400 table resident in the instrument.

7.8.13 THERM

The THERM thermistor type is for thermistors that have unique calibration co-

efficients or do not match the YSI-400 specification. This type of probe gener-

ally has moderate cost, a limited operating range (–40°C to 100°C), excellent

accuracy (0.005°C to 0.02°C) and excellent resolution (0.002°C). This type

uses the Steinhart-Hart equation in the following form:

RT K b bT bT bT( [ ])[ ] exp[ ]Ω= +++

−−−

01

1

2

2

3

3

The coefficients b0 through b3 are usually found on the calibration certificate

of the probe. These coefficients are set with the functions “b0", ”b1", “b2", and

”b3". In some cases the equation is used without the b2 term. For this case, the

“b2" coefficient should be set to 0. Consider the following examples.

Example 1:

A thermistor has coefficients for the equation ln(R) as a function of T given as

a, b, c, and d. Set the 1521 coefficients to the certificate values as follows:

1521 Coefficients Certificate Value

b0 a

b1 b

b2 c

b3 d

1521 Handheld Thermometer Readout

User’s Guide

34

Example 2:

A thermistor has coefficients for the equation ln(R) as a function of T given as

a, b, and c. Set the 1521 coefficients to the certificate values as follows:

1521 Coefficients Certificate Value

b0 a

b1 b

b2 0.0

b3 c

7.8.14 Probe Wires

This function sets the number of connecting wires in the probe. The probe

wires setting is stored in the INFO-CON connector. The 1521 can be used with

probes that have two, three, or four wires. Three wires connecting the probe

sensor instead of two allows the 1521 to partially cancel measurement error due

to the resistance of the wires. With four wires the 1521 can completely cancel

the error. The internal measurement circuit is configured differently depending

on the number of wires. Important—The 1521 will try to calculate a mea-

surement even if the wire settings are incorrect. Therefore, the Probe

Wires setting must match the actual number of wires or loss of accuracy

will result. Use the Up and Down buttons to set the value and press the ENT

button to store and continue.

7.8.15 PCal

This function shows the date the probe was calibrated and allows it to be set.

The date is stored in the INFO-CON connector and is used simply for refer-

ence. Use the Up and Down buttons to set each date segment and the ENT but-

ton to move to the next date segment to the right. Press ENT when the date is

correctly entered. Press CLR to move to the next function without changing the

date.

7.8.16 PDue

This function shows the date the probe is due for calibration and allows it to be

set. The date is stored in the INFO-CON connector. The probe due date is regu-

larly checked against the present date and if the calibration has expired the user

is alerted with the message “Prb cal expired”. This message only disappears

when the probe is recalibrated and the probe calibration due date is set to a fu-

ture date. To set the date, use the Up and Down buttons to set each date seg-

ment and the ENT button to move to the next date segment to the right. Press

ENT when the date is correctly entered. Press CLR to move to the next func-

tion without changing the date.

35

7 Display Functions

CAL MODE

Note: Probe parameters are uploaded to the INFO-CON connector at this point.

7.8.17 Filter

The digital filter helps to smooth variations in the measurements and improve

resolution. A negative effect of filtering is that it tends to slow the response to

changes in temperature. You can increase the filter time constant to further im-

prove accuracy and resolution or decrease the time constant to reduce the re-

sponse time. Valid values are any number between 0.0 and 60.0 seconds. A

value of 0.0 disables the filter. The default is 0.0. Use the Up and Down but-

tons to set the value and press the ENT button to store and continue. Press

CLR to move to the next function without changing the filter.

7.8.18 MCal

This function shows the date the 1521 was calibrated and allows it to be set.

The date is used simply for reference. Use the Up and Down buttons to set

each date segment and the ENT button to move to the next date segment on the

right. Press ENT when the date is correctly entered. Press CLR to move to the

next function without changing the date.

7.8.19 MDue

This function shows the date the 1521 is due for calibration and allows it to be

set. The meter calibration due date is regularly checked against the present date

and if the calibration has expired the user is alerted with the message “Mtr cal

expired”. The message will only disappear when the 1521 is recalibrated and

the meter calibration due date is set to a future date. To set the meter calibration

due date use the Up and Down buttons to set each date segment and the ENT

button to move to the next date segment to the right. Press ENT when the date

is correctly entered. Press CLR to move to the next function without changing

the date.

7.8.20 CAL1 and CAL2

The CAL1 and CAL2 meter calibration parameters calibrate the 0 to 500Ω

measurement range and the 0 to 500 kΩmeasurement range respectively. These

parameters directly affect the accuracy of the 1521 and are only to be altered by

an authorized, qualified technician as part of a regular instrument calibration

operation. Refer to the calibration procedure in Section 9. Use the Up and

Down buttons to set the value and press the ENT button to store and continue.

Press CLR to move to the next function without changing the date.

1521 Handheld Thermometer Readout

User’s Guide

36

8 Communications Interface

Remote communications allows an external device, such as a computer, to com-

municate with the 1521 to obtain measurement data and control its operation.

Communication is accomplished with various commands issued to the 1521

through the RS-232 serial port.

8.1 RS-232 Connection

The three-conductor jack for the serial port is located on the top of the 1521

near the probe connector. One serial cable is included with the 1521. Additional

or longer cables, of three meters or less, can be constructed by following the

wiring diagram shown in Figure 8. Note: The TxD line on one side connects

to the RxD line on the other and vice-versa. To reduce the possibility of elec-

trical interference, the serial cable should be shielded with low resistance be-

tween the connector and the shield. It should not be much longer than is

necessary. The protocol for serial communications is 8 data bits, 1 stop bit, and

no parity. Use no flow control. The baud rate is fixed at 2400, the linefeed to

37

8 Communications Interface

RS-232 Connection

1

2

3

4

5

6

7

8

9

RxD

TxD

GND

RxD

TxD

GND

Figure 8 RS-232 Wiring

ON (all carriage returns are followed by a linefeed (ASCII decimal 10)), and

the duplex to HALF disabling echo.

The serial port can be used to transmit measurements to a computer or printer.

It can also be used to change settings of the 1521 from a computer or interface

with software. A full list of commands follows in Section 8.2.

Commands sent to the 1521 must end with an EOS character which is a car-

riage return (ASCII decimal 13) or linefeed character (ASCII decimal 10).

Commands can be sent with upper or lower case letters. Data returned from the

1521 ends with a carriage return and a linefeed.

8.2 Communication Command List

8.2.1 Primary Commands

The following group of commands read or set various functions.

Description Command Example

Response

Format

Response

Example Range

Read measurement, extended

format

t[emperature] t t: 999.999

{C,O,F,R,orK}

mm-dd-yyyy

hh:mm:ss

t: 125.745 C

03-01-1999

15:49:15

Read measurement, simple format f[etch?]

rea[d?]

me[asure?]

fetch?

read?

meas?

t: 999.999

{C,O,F,R,orK}

t: 25.587 C

Read minimum m[inimum] min min: 999.999

{C,O,F,R,orK}

min: -14.653 C

Read maximum ma[ximum] max max: 999.999

{C,O,F,R,orK}

max: 416.781 C

Clear minimum and maximum cl[ear] clear

Read a hold register h[ld]<n> hld6 hld<n>: 999.999 {C, O, F,

R, or K}

hld6: 26.553 C <n> can be 1 to

6

Description Command Example

Response

Format

Response

Example Range

Set resolution digits re[solution]=n res=1 1 to 3

Read time ti[me] time ti: hh:mm:ss ti: 16:23:45

Set time

Note: You must set hours, min-

utes, and seconds for the time to

be set correctly.

ti[me]=hh:mm:s

s

ti=08:15:0

0

00:00:00 to

23:59:59

Read identification information *i[dn?] *idn? <manufacturer>,

<model>,

<serial number>,

<firmware version>

Hart,

1521,

95001,

2.11

Read model and firmware version *v[ersion] *ver ver.<model>,

<firmware version>

ver.1521,

2.11

Legend: [] Optional Command data

{} Returns either information

n Numeric data supplied by user

9 Numeric data returned to user

x Character data returned to user

8.2.2 Calibration Commands

The following group of commands directly or indirectly affect the accuracy of

the instrument. These commands should only be used by qualified, authorized

personnel. Calibration parameters can only be changed if protection is dis-

abled by entering the proper pass-code using the command *pas= ddddd.

Entering an invalid passcode or cycling the power re-establishes protection of

the calibration parameters. The parameters can be read without disabling the

passcode protection.

Description Command Example

Response

Format

Response

Example Range

Unprotect calibration parame-

ters with the pass-code

*pas[scode]=nnnnn *pas=12345

Read date da[te] date da: yyyy-mm-dd da: 1999-03-28

Read passcode protection

state

*pas *pas ps:9 ps:0 0 or 1

Set date da[te]=yyyy-mm-dd da=1999-03-28 1999-01-01 to

2100-12-31

Read probe serial number se[rial] ser ser: xxxxxxxxxx ser: 100231A

Set probe serial number se[rial]=xxxxxxxxxx ser=001 0 to 9, A to Z,

., -, /

Read probe type p[robe] pr pr: {ITS-90, IEC751,

CVD, YSI400, THERM}

pr: ITS-90

39

8 Communications Interface

Communication Command List

Description Command Example

Response

Format

Response

Example Range

Set probe type p[robe]=IT[S-90]/

IE[C751]/ C[VD]/

Y[SI400]/ T[HR]

pr ITS-90,

IEC751,

CVD, YSI400,

THERM

Read ITS-90 R(.01) or CVD R0 r[0] r0 r0: 9999.999 r0: 100.035

Set ITS-90 R(.01) or CVD R0 r[0]=n r0=100.106 1 to 900

Read ITS-90 coefficient a/b/c/d/a4/b4 a {a/b/c/d/a4/b4}:

-9.999999E-99

a: -2.8644101E-5

Set ITS-90 coefficient a/b/c/d/a4/b4=n a=-2.8644E-5 1.0 to 9.9e-18

Read CVD coefficient al[pha]/de[lta]/be[ta] al {al/de/be}: 9.99999999 al: 0.0038123

Set CVD coefficient al[pha]/de[lta]/be[ta]=n al=0.0038512 E+/-18

Read THERM thermistor

coefficient

b0/b1/b2/b3 b3 {b0/b1/b2/b3}:

9.999999e-99

b3: -9.944070e-12

Set THERM thermistor

coefficient

b0/b1/b2/b3=n b3=-9.944E-12 E+/-18

Read probe wires wi[res] wi wi: 9 wi: 4

Set probe wires wi[res]=2/3/4 wi=4 2,3,4

Read probe calibration date pc[al] pcal pc: yyyy-mm-dd pc: 1999-03-28

Set probe calibration date pc[al]=yyyy-mm-dd pc=1999-03-28 1999-01-01 to

2100-12-31

Read probe due date pd[ue] pdue pd: yyyy-mm-dd pd: 1999-03-28

Set probe due date pd[ue]=yyyy-mm-dd pd=1999-03-28 1999-01-01 to

2100-12-31

Read filter fi[lter] fi fi: 99.99999 fi: 0.5

Set filter fi[lter]=n fi=0 0.0 to 60.0

Read low range calibration *c1 *c1 c1: 99.999 c1: -0.0121

Set low range calibration *c1=n *c1=-0.012 -1.999 to 1.999

Read high range calibration *c2 *c2 c2: 9999.9 c2: -0.9

Set high range calibration *c2=n *c2=-0.9 -1980.0 to

1980.0

Read meter calibration date mc[al] mcal mc: yyyy-mm-dd mc: 1999-03-28

Set meter calibration date mc[al]=yyyy-mm-dd mc=1999-03-28 1999-01-01 to

2100-12-31

Read meter due date md[ue] mdue md: yyyy-mm-dd : 1999-03-28

Set meter due date md[ue]=yyyy-mm-dd md=1999-03-28 1999-01-01 to

2100-12-31

Legend: [] Optional Command data

{} Returns either information

1521 Handheld Thermometer Readout

User’s Guide

40

Description Command Example

Response

Format

Response

Example Range

n Numeric data supplied by user

9 Numeric data returned to user

x Character data returned to user

41

8 Communications Interface

Communication Command List

9 Calibration

The 1521 should be calibrated at regular intervals to ensure that it continues to

measure with proper accuracy. Calibration should only be done by qualified,

authorized personnel.

9.1 Required Equipment

The following items are required to test and calibrate the 1521:

•0Ωfour-wire resistor (short)

•25Ωfour-wire resistor, uncertainty within 20 ppm (±0.0005Ω)

•100Ωfour-wire resistor, uncertainty within 20 ppm (±0.002Ω)

•400Ωfour-wire resistor, uncertainty within 20 ppm (±0.008Ω)

•4 kΩfour-wire resistor, uncertainty within 50 ppm (±0.2Ω)

•10 kΩfour-wire resistor, uncertainty within 50 ppm (±0.5Ω)

•40 kΩfour-wire resistor, uncertainty within 50 ppm (±2Ω)

•100 kΩfour-wire resistor, uncertainty within 50 ppm (±5Ω)

•500 kΩfour-wire resistor, uncertainty within 75 ppm (±37.5Ω)

Each resistor must be attached with an INFO-CON probe connector. The 25Ω,

100Ω, and 400Ωresistors must be programmed with the CVD probe type with

units set to ohms. The 4 kΩ,10kΩ,40kΩ, 100 kΩ, and 500 kΩresistors must

be programmed with the THERM probe type with units set to ohms.

9.2 Calibration Procedure

Calibration requires adjustment of the CAL1 and CAL2 parameters at 100Ω

and10kΩrespectively (see Section 7.8.20). The calibration parameters can be

accessed from the front panel by pressing the MODE button and holding it for

three seconds, releasing it, then pressing the ENT button (see Section 7.8). You

must enter the pass-code to continue (see Section 7.8.4). The step-by-step pro-

cedureisasfollows:

1. Connect the 100Ωresistor. Adjust the CAL1 parameter by subtracting the

measured error. For example, if the resistor is exactly 100.000Ωand the 1521

measures 100.029Ω, CAL1 should be adjusted by subtracting 0.029 from the

current value of CAL1.

2. Verify the accuracy at 0Ω, 25Ω, 100Ω, and 400Ω.

3. Connect the 10 kΩresistor. Adjust the CAL2 parameter by subtracting the

measured error. For example, if the resistor is exactly 10.0000 kΩand the 1521

measures 10.0029 kΩ, CAL2 should be adjusted by subtracting 2.9 from the

current value of CAL2.

43

9 Calibration

Required Equipment

4. Verify the accuracy at 0Ω, 4kΩ,10kΩ,40kΩ, 100 kΩ, and 500 kΩ.

5. Set the meter calibration date to the present date (see Section 7.8.18).

6. Set the meter due date to one year from the present date (see Section 7.8.19).

1521 Handheld Thermometer Readout

User’s Guide

44

10 Maintenance

•This instrument has been designed with the utmost care. Ease of operation

and simplicity of maintenance have been a central theme in the product

development. Therefore, with proper care the instrument should require

very little maintenance. Avoid operating the instrument in oily, wet, dirty,

or dusty environments.

•If the outside of the instrument becomes soiled, it may be wiped clean

with a damp cloth and mild detergent. Do not use harsh chemicals on the

surface which may damage the LCD or the plastic outside shell.

•If a hazardous material is spilt on or inside the equipment, the user is re-

sponsible for taking the appropriate decontamination steps as outlined by

the national safety council with respect to the material.

•Before using any cleaning or decontamination method except those rec-

ommended by Hart, users should check with an Authorized Service

Center to be sure that the proposed method will not damage the equip-

ment.

•If the AC adapter becomes damaged, have it replaced immediately. Never

disassemble the AC adapter or attempt to repair it.

•If the instrument is used in a manner not in accordance with the equip-

ment design, the operation of the thermometer may be impaired or safety

hazards may arise.

45

10 Maintenance

11 Troubleshooting

In case you run into difficulty while operating the 1521, this section provides

some suggestions that may help you solve the problem. Below are several situa-

tions that may arise followed by possible causes of the problem and suggested

actions you might take.

11.1 An Error Message Is Displayed

The following table lists possible error messages, their causes, and suggested

actions.

Problem Solution

“Recharge Needed”

The battery is low and needs to be recharged.

When this message first

appears the user has approximately 30 minutes of charge left. If the

battery is not recharged, the 1521 continues to operate until the bat-

tery drops below 0% and then automatically shuts itself off after dis-

playing the error message.

“No Probe” The display shows ‘ - - - ----‘.The instrument is unable to detect

that a probe is connected. Check that a probe with a properly pro-

grammed INFO-CON connector is attached.

“Probe is locked” The incorrect probe is attached. The meter is set to accept only the

probe with the given serial number. Attach the correct probe or have

the instrument properly programmed for the new probe.

“Prb cal expired” The probe calibration has expired. Have the probe calibrated and

the calibration due date reset.

“Mtr cal expired” The meter calibration has expired. Have the instrument calibrated

and the calibration due date reset.

“Invalid Passcode” The passcode entered was not correct. Check the passcode on the

Pass-code Notice sent with the instrument.

The instrument display is blank

when normally it should show

measurements.

Make sure the instrument has power, either from the batteries or

the AC adapter. Verify that the initialization information appears on

the display when the power is switched on. Check to make sure that a

probe is properly connected. Check to make sure that the probe is

programmed properly.

47

11 Troubleshooting

An Error Message Is Displayed

Problem Solution

While attempting to measure re-

sistance the display shows an in-

correct value.

Poor or incorrect connection of the probe. A common mistake is to

connect the wires of the probe to the wrong terminals. Check the wir-

ing carefully (see Figure 6).

Open, shorted, or damaged sensor or lead wires. Check the resis-

tance across the sensor using a handheld DMM. Also check the resis-

tance between common pairs of leads. Check to make sure there is

no conductivity between any of the leads and the probe sheath. Use a

good-quality sensor to avoid errors caused by drift, hysteresis, or in-

sulation leakage.

Stem conduction error. Make sure the stem of the probe is im-

mersed in the medium with adequate depth and a tight fit.

Electrical interference. Intense radio-frequency radiation near the

1521 or the probe can induce noise into the measurement circuits re-

sulting in erratic readings. Try eliminating the source of interference or

moving the 1521 to a different location. A well-grounded, shielded ca-

ble should be used for the probe.

Memory Check Error Memory Error.

A non-critical parameter is corrupt in memory. The non-critical

praameters are Units, Rate, Resolution, Filter, and serial port settings.

Press any key and the display reads “Check Settings”. Press any key

again to resume normal operation. Check your current settings for the

specific parameters that were set.

Memory Recover X.

A critical parameter is corrupt and the 1521 can recover the correct

value for that parameter. The critical parameters are CAL1, CAL2,

Passcode, Meter Due Date, Meter Cal Date, and Serial Number.

Press any key and the display reads “Check Settings”. Press any key

again to resume normal operation. Also, check non-critical settings as

in the Memory Error above. The number following the message is

used by authorized technicians.

Memory Invalid!

A critical parameter is corrupt and the 1521 cannot recover the cor-

rect value for the parameter. The critical parameters are CAL1, CAL2,

Passcode, Meter Due Date, Meter Cal Date, and Serial Number.

Press any key and the display reads “Contact Factory”. Contact an

Authorized Service Center (see Section 1.3) for assistance in guiding

you through the process of reentering critical parameters.

Note: The parameters stored in the INFO-CON, Probe Wires, Probe

Type, Probe Parameters, are not checked by the meter during mem-

ory testing.

11.2 CE Comments

11.2.1 EMC Directive

Hart Scientific’s equipment has been tested to meet the European Electromag-

netic Compatibility Directive (EMC Directive, 89/336/EEC). The Declaration

of Conformity for your instrument lists the specific standards to which the unit

was tested.

1521 Handheld Thermometer Readout

User’s Guide

48

The instrument was designed specifically as a test and measuring device. Com-

pliance to the EMC directive is through IEC 61326-1 Electrical equipment for

measurement, control and laboratory use – EMC requirements (1998).

As noted in the IEC 61326-1, the instrument can have varying configurations.

The instrument was tested in a typical configuration with shielded, grounded

probe and RS-232 cables. Emissions may, in non-typical applications, exceed

the levels required by the standard. It is not practical to test all configurations,

as the manufacturer has no control over the probes the user may connect to the

instrument.

11.2.1.1 Immunity Testing

The instrument was tested to the requirements for industrial locations. This al-

lows the instrument to be used in all types of locations from the laboratory to

the factory floor. Criterion B was used for Radiated RF (IEC 61000-4-3) and

Conducted RF (IEC 61000-4-6). Therefore, the operation of the instrument

may be affected by excessive electromagnetic interference and the instrument

may not perform within the normal specification limits in such an environment.

Criterion C was used for Electrostatic Discharge (ESD, IEC 61000-4-2) and

Electric Fast Transit (EFT, Burst, IEC 61000-4-4). If the instrument is sub-

jected to EFT conditions at 2kV, the instrument may require the user to cycle

the power to return to normal operation.

11.2.1.2 Emission Testing

The instrument fulfills the limit requirements for Class A equipment but does

not fulfill the limit requirements for Class B equipment. The instrument was

not designed to be used in domestic establishments.

11.2.2 Low Voltage Directive (Safety)

In order to comply with the European Low Voltage Directive (73/23/EEC),

Hart Scientific equipment has been designed to meet the IEC 1010-1 (EN

61010-1) and the IEC 1010-2-010 (EN 61010-2-010) standards.

49

11 Troubleshooting

CE Comments