Omron C200H-TV, C200H-TV001, C200H-TV101, C200H-TV002, C200H-TV102 Operation Manual

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Page 1

C200H-TV| W240-E3-1 Cat. No.

Temperature Control Units

OMRON

SYSMAC -SystemC200H

Presented by - MRO Electric and Supply Company, Inc.

ForProduct Needs:

Email: sales@MROELECTRIC.COM

Call: 1-800-691-8511 Fax: 919-415-1614

http://www.MROELECTRIC.com/

OMRON System C200H MRO ELECTRIC & SUPPLY Company mroelectric.com

Page 2

C200H-TV Heat/Cool Temperature Control Unit

Operation Manual

Cat. No. W240-E3-1

Page 3

Notice:

OMRON products are manufactured for use according to proper procedures by a qualified operator and only for the purposes described in this manual.

The following conventions are used to indicate and classify precautions in this manual. Always heed the information provided with them. Failure to head precautions can result in injury to people or damage to the product.

DANGER! Indicates information that, if not heeded, is likely to result in loss of life or serious

injury.

WARNING Indicates information that, if not heeded, could possibly result in loss of life or

serious injury.

Caution Indicates information that, if not heeded, could result in relative serious or minor

injury, damage to the product, or faulty operation.

OMRON Product References

All OMRON products are capitalized in this manual. The word “Unit” is also capitalized when it refers to an OMRON product, regardless of whether or not it appears in the proper name of the product.

The abbreviation “Ch,” which appears in some displays and on some OMRON products, often means “word” and is abbreviated “Wd” in documentation in this sense.

The abbreviation “PC” means Programmable Controller and is not used as an abbreviation for anything else.

Visual Aids

The following headings appear in the left column of the manual to help you locate different types of information.

 OMRON, 1998

All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form, or by any means, mechanical, electronic, photocopying, recording, or otherwise, without the prior written permission of OMRON.

No patent liability is assumed with respect to the use of the information contained herein. Moreover, because OMRON is constantly striving to improve its high-quality products, the information contained in this manual is subject to change without notice. Every precaution has been taken in the preparation of this manual. Nevertheless, OMRON assumes no responsibility for errors or omissions. Neither is any liability assumed for damages resulting from the use of the information contained in this publication.

Note Indicates information of particular interest for efficient and convenient operation

of the product.

1, 2, 3...

1. Indicates lists of one sort or another, such as procedures, checklists, etc.

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MROELECTRIC.COM

SECTION 1

System Configuration and Features 1. . . . . . . . . . . . . . . . .

1-1 Features 2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1-2 Basic System Configuration 3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

SECTION 2

Connections and Settings 5. . . . . . . . . . . . . . . . . . . . . . . . . .

2-1 Nomenclature 6. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-2 Switch Settings 7. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-3 Wiring 10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-3-1 Input Wiring 10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-3-2 Output Wiring 13. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-3-3 Data Setting Console Cables 17. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

SECTION 3

Data Setting Console Operation 19. . . . . . . . . . . . . . . . . . . .

3-1 Operating Procedure 20. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-2 Data Flow 21. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-3 Nomenclature and Features 22. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-3-1 Nomenclature 22. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-3-2 Features 23. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-4 Parameter Displays and Settings 24. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-4-1 Table of Parameters 24. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-4-2 How to Display and Set Parameter Data 26. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

SECTION 4

PC Memory Allocation and Programming 35. . . . . . . . . . .

4-1 Memory Allocation 36. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-1-1 Memory Allocation Table 37. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-1-2 Memory Contents 38. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-1-3 Table of Commands 41. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-2 Data Flow 43. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-3 Programming 43. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-3-1 Example with SW2-1 in the Fixed Position 43. . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-3-2 Example 1: Write with SW2-1 in the Normal Position 44. . . . . . . . . . . . . . . . . . . .

4-3-3 Example 2: Read with SW2-1 in the Normal Position 47. . . . . . . . . . . . . . . . . . . .

4-3-4 Operation Timing 50. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

SECTION 5

Troubleshooting 53. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Error Detection 54. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

A Specifications 57. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

B Sensor Temperature Measurement Ranges 59. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

C Heater Burnout Detection 61. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

D Parameters and Key Operations 67. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Index 69. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Revision History 71. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

vii

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About this Manual:

MROELECTRIC.COM

This manual describes the installation and operation of the C200H-TV Heat/Cool Temperature Control Unit and includes the sections described below. Also briefly described is the basic operation and installation of the C200H-DSC01 Data Setting Console.

Please read this manual carefully and be sure you understand the information provided before attempting to install and operate the Heat/Cool Temperature Control Unit and Data Setting Console.

Section 1

ration.

Section 2

Unit.

Section 3

tings and displays.

Section 4

programming procedures and examples are also provided.

Section 5

The five Appendices provide references dealing with specifications, sensor temperature measurement ranges, heater burnout detection, and dimensions, and a table of Data Setting Console key operations.

provides Heat/Cool Temperature Control Unit features and describes its basic system configu-

provides information on the connections and settings of the Heat/Cool Temperature Control

provides the basic operating procedures of the Data Setting Console including parameter set-

provides the C200H PC’s memory allocation for the Heat/Cool Temperature Control Unit. Basic

provides possible errors and error remedies.

WARNING Failure to read and understand the information provided in this manual may result in

personal injury or death, damage to the product, or product failure. Please read each section in its entirety and be sure you understand the information provided in the section and related sections before attempting any of the procedures or operations given.

Page 6

SECTION 1

MROELECTRIC.COM

System Configuration and Features

This section provides Heat/Cool Temperature Control Unit features and describes its basic system configuration.

1-1 Features 2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1-2 Basic System Configuration 3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Page 7

Features Section 1-1

MROELECTRIC.COM

1-1 Features

The Heat/Cool Temperature Control Unit measures the temperature of an object with a connected temperature sensor (thermocouple or platinum resistance thermometer) and controls the temperature according to preset parameters.

Advanced PID Control

Stable temperature control is achieved using advanced PID control and an autotuning feature. ON/OFF control can also be selected.

Units Available According to Type of Temperature Sensor

Two types of Temperature Control Unit are available, according to the temperature sensor used. The C200H-TV00 uses a thermocouple, and the C200H-TV10 uses a platinum resistance thermometer.

Two Heat/Cool Control Loops with a Single Unit

Two heating and cooling control loops are possible with one Unit.

Comprehensive Output Specifications

Three types of output specification versions are available: C200H-TV1 for transistor output, C200H-TV2 for voltage output, and C200H-TV3 for current output.

Heater Burnout Detection

A Current Transformer (with a detection current range of 0.1 to 49.9 A and a minimum detection current difference of 2.5 A) can be connected to each of the two control loops to facilitate rapid heater burnout detection and prompt correction of problems.

Eight Banks of Data Settings

Eight data values such as set point (SP) and alarm set values can be preset in eight data banks for easy selection.

Data Input and Display

The C200H-DSC01 Data Setting Console (sold separately) is used to input data and to display process values (PV) and set values (SV). The easy-to-read display can be panel-mounted.

User Programs Allow Reading and Writing of Data

Data can be set and retrieved by means of C200H user programs.

Page 8

Basic System Configuration

MROELECTRIC.COM

1-2 Basic System Configuration

C200H PC

Heat/Cool Temperature Control Unit: C200H-TV00 (for thermocouples) C200H-TV10 (for platinum resistance thermometers)

Connecting cables: C200H-CN225 (2 m) C200H-CN425 (4 m)

Recommended cable: ES1000-CA021-051 (0.5 m) ES1000-CA021-102 (1 m) ES1000-CA021-202 (2 m)

Section 1-2

Data Setting Console C200H-DSC01

24 VDC

Temperature sensor

Loop 1 Loop 2

Extruder

Heater Heater

Valve

Coolant

Current Transformer (CT)

Heat/Cool Temperature Control Unit Models

Sensor

Thermocouple C200H-TV001 C200H-TV002 C200H-TV003 Platinum resistance

thermometer

Temperature sensor

Remote I/O Terminal or Connector Terminal Block Converter Unit (Refer to page 16)

Valve

Current Transformer (CT)

Transistor

output

C200H-TV101 C200H-TV102 C200H-TV103

Relay box

Coolant

Solenoid switch

Output type

Voltage output Current output

Page 9

Basic System Configuration

MROELECTRIC.COM

Number of Units The Heat/Cool Temperature Control Unit belongs to the C200H Special I/O Unit

group. A maximum of ten Special I/O Units (including PC Link Units) can be mounted on each of the following Racks: CPU Rack, Expansion I/O Rack, and Slave Rack.

Note Configure the Units such that the maximum current supplied for each Rack is

greater than or equal to the total current consumption for the Units. Refer to the

C200H PC Operation Manuals

Section 1-2

Number of Units Mountable on Slave Rack

A B C D

High-speed Counter Units Position Control Units

(NC111/112) ASCII Units ID Sensor Units Fuzzy Logic Units

4 units max. 8 units max. 6 units max. 2 units max.

The number of Special I/O Units used with a Slave Rack is limited by data transmission considerations, as shown in the table below. The numbers in the table indicate the maximum number of Units of groups A, B, C, or D which can be used with a single Slave Rack.

High-density and Mixed I/O Units

Temperature Control Units Heat/Cool Temperature

Control Units PID Control Units Cam Positioner Units

Note 1. When a combination of Units from groups A, B, C, and D is used, the number

from each group must satisfy both the following equations: 3A + B + 2C + 6D ≤ 12

A + B + C + D ≤ 8

2. Other Units can be added until the total number of Units reaches ten. If PC Link Units are used, the number of Units including the PC Link Units must not exceed ten.

Temperature Sensor Units Voice Units

Position Control Units (NC211)

Precautions The IR area of the C200H Special I/O Unit is allocated according to the setting of

not

the unit number switch on the front panel, unit is mounted. Refer to area.

Leave the two slots next to the CPU free. It is not possible to use devices connected to the CPU (such as the Programming Console) if these slots are occupied.

If the C200H Slave Rack is connected to another SYSMAC model Remote I/O Master Unit, such as the C120, C500, C1000H, or C2000H, it is not possible to use a Special I/O Unit with the C200H Slave Rack.

WARNING Always turn the C200H power off before connecting or disconnecting a Unit,

terminal block, or output connector.

Caution Connect thermocouples with the appropriate compensating conductor.

Wire I/O leads in separate ducts from power leads to prevent noise problems.

4-1 Memory Allocation

the address of the slot where the

for the allocation of the memory

Page 10

SECTION 2

MROELECTRIC.COM

Connections and Settings

This section provides information on the connections and settings of the Heat/Cool Temperature Control Unit.

2-1 Nomenclature 6. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-2 Switch Settings 7. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-3 Wiring 10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-3-1 Input Wiring 10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-3-2 Output Wiring 13. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-3-3 Data Setting Console Cables 17. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Page 11

Nomenclature Section 2-1

MROELECTRIC.COM

2-1 Nomenclature

C200H-TV00 (For Thermocouple)

Front Panel

Model label Cover

RUN indicator SW2

(switching memory contents and setting direction under the cover)

SW1 (Unit number setting)

Data Setting Console connector

Output connector

Sensor input terminal block

Rear Panel

SW202 (input type setting)

SW203 (operation and function settings)

Rack connector

Cold junction compensator

C200H-TV10 (For Platinum Resistance Thermometer)

Front Panel Rear Panel

Model label Cover

RUN indicator SW2

(switching memory contents and setting direction under the cover)

SW1 (Unit number setting)

Data Setting Console connector

Output connector

SW202 (input type setting)

SW203 (operation and function settings)

Rack connector

Sensor input terminal block

Page 12

Switch Settings

MROELECTRIC.COM

Indicators

RUN Lit when the Heat/Cool Temperature Control Unit is operating normally.

2-2 Switch Settings

The function and setting of switches are identical for all models, except SW202.

Unit Number

SW1 Unit number setting

Section 2-2

Unlit when an alarm occurs, and Unit operation stops.

4 2

8 6

The addresses are allocated as shown in the following table according to the Unit number setting.

0 Wd 100 to 109 1 Wd 110 to 119 2 Wd 120 to 129 3 Wd 130 to 139 4 Wd 140 to 149 5 Wd 150 to 159 6 Wd 160 to 169 7 Wd 170 to 179 8 Wd 180 to 189 9 Wd 190 to 199

(3)

(1)

(9)

(7)

Unit no.

setting

(5)

The cut-out indicates the selected position. Negative numbers are not indicated. Turn the switch with a flat-blade screwdriver. Turn the switch until it clicks in position. Do not leave the switch between two settings.

Allocated address

The switch is factory-set to 0.

Note If the Unit number is set to an existing Unit number, an alarm occurs and the

C200H does not operate. Turn the C200H power off before setting the Unit number. If the setting is changed with the power on, the new setting is not valid until the power is turned off and back on again.

Switching Memory Contents and Setting Direction

SW2 Switching memory contents and setting direction

Remove the cover and set the switch with the tip of a ballpoint pen or a similar object.

OFF

Page 13

Switch Settings

MROELECTRIC.COM

Switch no. Pin 1 Pin 2

Function Switching memory contents Setting direction ON Normal C200H PC OFF Fixed Data Setting Console

The new setting is valid immediately after the switch setting is changed.

Removing and Attaching the Cover

Section 2-2

Removing the Cover Attaching the Cover

Insert a small flat-blade screwdriver between the case and the cover at the top of the Unit and lever off the cover.

Switching Memory Contents The methods for designating parameters differ as shown below.

Normal Parameters can be designated as required using

Fixed Parameters are allocated in advance.

Refer to

Setting Direction Selector Selects whether the data settings are made from the Data Setting Console or

from the C200H PC, using a user program or Programming Console.

Executed Bank Number

The setting of the executed bank number is made from the C200H PC, regardless of the ON/OFF setting of this switch.

4-1 Memory Allocation

commands. (Refer to

for details of the memory contents.

Place the right edge of the cover against the case and press into position.

4-1 Memory Allocation

Input Type

SW202 Input type setting

C200H-TV00

Setting 0 1 2 3 4 5 6 7 8 9 Sensor type R S K J T E B N L U

The switch is factory-set to 2. The selected position is shown by the arrow. Turn the switch with a small flat-

blade screwdriver.

Selected position

Page 14

Switch Settings

MROELECTRIC.COM

C200H-TV10

Setting Input type

OFF JPt 100 ON Pt 100

The switch is factory-set to OFF.

Appendix B Sensor Temperature Measurement Range

See temperature range.

Operation and Function Setting

SW203 Operation and Function Setting

Section 2-2

OFF

for the measurable

134562

OFF ON

Pin no. Function OFF ON

6 Loop 1

Cooling control output

5 SP write mode Write to EEPROM

4 Loop 2 Enabled Disabled or not used 3 Display unit °C °F 2 Not used. --- --1 Control method PID control ON/OFF control

The switch is factory-set to OFF.

Loop 1 Cooling Control Output

SP Write Mode

Loop 2 Set to “enabled” to use input loop 2, or to “disabled” to use only input loop 1. It is

This setting is valid when the heating output type is “current,” and input loop 2 is not used (i.e., when pin no. 4 of switch 203 is ON).

This setting selects the SP storage memory. Set it to ON if the writing is to be frequently changed.

not possible to use only input loop 2.

Pulses Current output

Write to RAM only

and RAM

Note Always set this switch to the ON (disabled) position when input loop 2 is not

used. A sensor error occurs if this switch is set to the OFF (enabled) position when no temperature sensor is connected to loop 2.

Display Unit Selects whether displays and set values are shown on the Data Setting Console

in Celsius or in Fahrenheit.

Control Method Selects the method of control.

Page 15

Wiring

MROELECTRIC.COM

2-3 Wiring

2-3-1 Input Wiring

C200H-TV00 Thermocouple

CT: Current Transformer TC:Thermocouple

Section 2-3

Loop 1

Loop 2

24 VDC

0.2 A

The 24-VDC output from the C200H CPU or the Power Supply Units is convenient.

Terminal no. Terminal name

A0 CT Loop 1 A1 CT A2 TC (–) A3 TC (+) A4 CT Loop 2 A5 CT A6 TC (–) A7 TC (+) A8 24 VDC A9 GND

A0 A1 A2 A3 A4 A5 A6 A7 A8 A9

Refer to the table below.

Page 16

Wiring

MROELECTRIC.COM

C200H-TV10 Platinum Resistance Thermometer

CT: Current Transformer Pt: Platinum resistance thermometer

Section 2-3

Heater wire

Loop 1

Loop 2

24 VDC

0.2 A

The 24-VDC output from the C200H CPU or the Power Supply Units is convenient.

Terminal no. Terminal name

A0 CT Loop 1 A1 CT/Pt (B) A2 Pt (B) A3 Pt (A) A4 CT Loop 2 A5 CT/Pt (B) A6 Pt (B) A7 Pt (A) A8 24 VDC A9 GND

A0 A1 A2 A3 A4 A5 A6 A7 A8 A9

Refer to the table below.

Screw down Pt(B) and CT together at terminals A1 and A5.

Input Wiring Precautions

1, 2, 3...

1. Set the type of temperature sensor to thermocouple or platinum resistance thermometer with SW202 on the rear of the Unit.

The Unit will not operate correctly if the switch setting does not match the type of temperature sensor connected.

Do not connect different types of temperature sensors to Loop 1 and Loop 2.

2. If no input lead is connected to Loop 2, turn SW203-4 on the rear of the Unit ON to disable Loop 2. A sensor error occurs if this switch is set to the OFF (enabled) position when no temperature sensor is connected to Loop 2.

3. Be sure to connect (+) and (–), and (A) and (B) correctly.

4. Wire I/O leads in separate ducts from power leads to prevent noise problems.

5. A voltage of 24 VDC is used for the voltage output, current output and Data Setting Console power supply.

6. The terminal block is removable. Make sure that it is attached correctly after the input wiring connections are completed.

Page 17

y y

major

Wiring

MROELECTRIC.COM

Section 2-3

Terminal Block Connections

Crimp terminals are recommended for the wiring. Take care not to overtighten the terminal screws. Tightening torque must not exceed 78 N  cm (8 kg  cm).

Crimp Terminals

The screws on the terminal block are M3.5 self-rising terminal screws. Use the following types of M3.5 crimp terminals.

7 mm max.

Soldered Lead

Strip insulation from 7 to 10 mm at the end of the wire and carefully solder the lead.

7 to 10 mm

Compensating Conductors Connect a thermocouple with the appropriate compensating conductor from the

table below.

Type of thermocouple Compensating conductor Symbol Previous

symbol

(reference)

B --- BX-G --R --- RX-G, SX-G --S --- RX-H, SX-H --- Heat-resistant,

K CA KX-G WCA-G

E CRC EX-G WCRC-G General-purpose,

J IC JX-G WIC-G General-purpose,

Symbol Previous

symbol

(reference)

KX-GS WCA-GS KX-H WCA-H Heat-resistant,

KX-HS WCA-HS Heat-resistant,

WX-G WCA-G General-purpose,

WX-H WCA-H Heat-resistant,

VX-G WCA-G General-purpose,

EX-H WCRC-H Heat-resistant,

JX-H WIC-H Heat-resistant,

Classification by

application and

tolerance

General-purpose, standard class

standard class General-purpose,

standard class

precision class

standard class

Constituent materials

+ conductor – conductor

Copper Copper

Alloy with copper or nickel as major constituent

Alloy with nickel or chrome as

ma constituent

Iron

Copper

Alloy with nickel or chrome as major constituent

Iron

Alloy with nickel as major constituent

Alloy with copper or nickel as major constituent

Page 18

Wiring

MROELECTRIC.COM

Section 2-3

Type of thermocouple Constituent materialsClassification by Symbol – conductor+ conductor

symbol

(reference)

T CC TX-G WCC-G General-purpose,

Wiring Platinum Resistance Thermometers

Current Transformer Use an E54-CT1 or E54-CT3 Current Transformer (CT). Refer to

Compensating conductor

SymbolPrevious

TX-GS --- General-purpose,

TX-H WCC-H Heat-resistant,

TX-HS --- Heat-resistant,

Connect a platinum resistance thermometer with copper wire. All three leads should have the same thickness and the same length to give them identical resistances. Do not branch the two (B) leads near the terminal block as this increases measurement errors.

Heater Burnout Detection

and installation dimensions.

symbol

(reference)

Classification by

application and

tolerance

Copper

standard class

precision class

standard class

precision class

for details of the Current Transformer specifications

Alloy with copper or nickel as major constituent

2-3-2 Output Wiring

Connection Diagrams

C200H-TV01 Transistor Output

Appendix C

HEAT1

HEAT2 COOL1 COOL2

COM

24 VDC

NC: Not connected The pairs of terminals B2 to A2 and B1 to A1 are shorted internally. Always supply power to the 24-VDC terminal (B1) as this drives the internal circuits.

24 VDC

Page 19

Wiring

MROELECTRIC.COM

C200H-TV02/TV03 Voltage/Current Output

Section 2-3

(–)

Circuit Diagrams

C200H-TV01 Transistor Output

C200H-TV02 Voltage Output

24 VDC

Internal circuits

24 VDC

OUT

COM

OUT (+)

OUT (–)

C200H-TV03 Current Output

Internal circuits

OUT (+)

OUT (–)

Applicable Connectors The following connector set manufactured by Fujitsu is included with the Unit:

FCN-361J032-AU (soldering connector) FCN-360C032-B (cover)

Page 20

Wiring

MROELECTRIC.COM

Section 2-3

Connector Wiring Precautions

Connection Precautions

After soldering the lead to each pin, insulate with heat-shrink tube to prevent shorting with the adjacent terminal.

Tighten the screws after inserting the connector into the Unit. Push the connector firmly into the Remote I/O Terminal or Connector Terminal Block Converter Unit until it fully locks.

Output Cable The output cables in the table below are recommended.

Model Cable length (L)

ES1000-CA021-051 0.5 m ES1000-CA021-102 1 m ES1000-CA021-202 2 m

32-pin connector (manufactured by Fujitsu)

FCN-361J032-AU

20-pin connector (manufactured by OMRON)

XG4M-2030

16.1

 Wiring Diagrams

32-pin connector

20-pin connector

XW2B-20G

19 17

15 13

11 9

7 5 3 1

20 18 16 12

14 10

8 6

4 2

Pin no. Wire no. Pin no. Wire no.

B16 B15 B14 B13 B12 B11 B10 B9 B8 B7 B6 B5 B4 B3 B2 B1

#1 #2 #3 #4 #5 #6 #7 #8 #9

#10

A16 A15 A14 A13 A12 A11 A10 A9 A8 A7 A6 A5 A4 A3 A2 A1

#11 #12 #13 #14 #15 #16 #17 #18 #19 #20

Pin no. Wire no. Pin no. Wire no.

1 2 3 4 5 6 7 8 9 10

#1 #2 #3 #4 #5 #6 #7 #8 #9

#10

11 12 13 14 15 16 17 18 19 20

#11 #12 #13 #14 #15 #16 #17 #18 #19 #20

Note The pin numbers of the 20-pin con-

nector are marked for convenience. Refer to them from the ∆ mark.

Note Pins A11 through A16 and B11

through B16 are not connected.

Pin no. Terminal no.

1 2 3 4 5 6 7 8 9 10

Pin no. Terminal no.

11 12 13 14 15 16 17 18 19 20

20 18 16 14 12 10

8 6 4 2

19 17 15 13 11

9 7 5 3 1

Page 21

Wiring

MROELECTRIC.COM

Remote I/O Terminal The Remote I/O Terminal in the table below is recommended for transistor out-

put.

Model Specification Relays used

G7TC-OC08 Common (+) 8 x G7T-1112S (max. resistive load: 220 VAC, 2A)

Note One P7TF-OS08 I/O Terminal and two G7T-1112S Relays may be

purchased separately and used.

Wiring Diagram External View

24 VDC

Wiring to the heater

Section 2-3

Connector Terminal Block Converter Unit

External View

The Connector Terminal Block Converter Units in the table below are recommended for voltage output and current output type.

Model Terminal screw size

XW2B-20G4 M 2.4 XW2B-20G5 M 3.5

Page 22

Wiring

MROELECTRIC.COM

Section 2-3

2-3-3 Data Setting Console Cables

Connecting Cable Use the connecting cables in the table below (sold separately) to connect the

Unit to the Data Setting Console.

Model Cable length (L)

C200H-CN225 2 m C200H-CN425 4 m

Connection Precautions

1, 2, 3...

17.5

1. Tighten the lock screws after inserting the connector into the Unit.

2. Push the connector firmly into the Data Setting Console until the clips fully lock.

3. Power is supplied through the connecting cable from the Heat/Cool Temperature Control Unit. Nothing appears on the Data Setting Console display if no power is supplied to input terminals A8 and A9 of the Heat/Cool Temperature Control Unit.

4. Install the supplied connector cover when the Data Setting Console is not in use.

17.3

16.1

Page 23

SECTION 3

MROELECTRIC.COM

Data Setting Console Operation

This section provides the basic operating procedures of the Data Setting Console including parameter settings and displays.

3-1 Operating Procedure 20. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-2 Data Flow 21. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-3 Nomenclature and Features 22. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-3-1 Nomenclature 22. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-3-2 Features 23. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-4 Parameter Displays and Settings 24. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-4-1 Table of Parameters 24. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-4-2 How to Display and Set Parameter Data 26. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Page 24

Operating Procedure Section 3-1

MROELECTRIC.COM

3-1 Operating Procedure

After preparing the C200H PC, follow the procedure below to use the Heat/Cool Temperature Control Unit.

1, 2, 3...

1. Set the switches on the front and rear panels according to the operating conditions. (Refer to

Set SW2-2 under the display cover to the OFF position to enable data setting from the Data Setting Console.

2. Mount to Rack. Turn off the C200H power supply before mounting or dismounting the

C200H on the Rack.

3. Connect the input wiring. (Refer to The 24-VDC power supply must be connected. The Data Setting Console

will not operate unless the 24-VDC power supply is connected. The sensors can be connected immediately before the system is tested.

4. Connect the Data Setting Console. (Refer to

Cables

5. Turn on the 24-VDC and the C200H power supplies. Set the C200H to PROGRAM mode.

6. Use the Data Setting Console to make the settings for the parameters that need to be changed. (Refer to the rest of this section.)

7. Test operation and adjust data. (Refer to the rest of this section.) Connect the output wiring and turn on the heater power . To start the test op-

eration, turn ON the RUN bit of the loop that is to be controlled with a device such as the Programming Console. Monitor the control conditions and adjust the data until the required control is achieved. During operation, the “bank no.” is switched to “executed bank no.” and cannot be changed from the Data Setting Console. To change it, use a device such as the Programming Console, or use the user program.

8. Create the user programs. (Refer to

Programming.

Arrange the data for the test operation, and create the user programs for data setting, monitoring, switching the bank number, and so on. Set SW2-2 under the display cover to the ON position to enable data setting from the C200H PC.

9. Start operation.

2-2 Switch Settings.

)

2-3 Wiring.

Section 4 PC Memory Allocation and

)

2-3-3 Data Setting Console

Page 25

Data Flow

MROELECTRIC.COM

3-2 Data Flow

Section 3-2

The data flow in the Heat/Cool Temperature Control Unit is shown in the diagram below.

Read

Heating and Cooling Temperature Control Unit

Write executed bank no.

C200H PC

Write

Read

The read operation and setting the executed bank number are possible from a user program or from a device, such as the Programming Console, regardless of the ON/OFF setting of SW2-2.

Data written from the Data Setting Console and data written with write command when SW2-1 (switching memory contents) is set to Normal are written to the Heat/Cool Temperature Control Unit EEPROM and are consequently retained when the power supply is turned off.

The SP value set when SW2-1 (switching memory contents) is set to Fixed and executed bank number settings made from the C200H PC are written directly to RAM and are not saved to EEPROM. This data is lost when the power supply is turned off. The same data can be written to the RAM when the power is next turned on and executes a user program. Settings made from the Programming Console must be repeated each time the power is turned on.

SW2-2

OFF

Data Setting Console

Data Settings from Data Setting Console

Set SW2-2 under the display cover to the OFF position to enable data setting from the Data Setting Console.

The “bank no.” can be set when operation is stopped (i.e., when the RUN bit is OFF). During operation it is switched to “executed bank no.” and cannot be changed from the Data Setting Console. To change the executed bank number, use a user program or a device such as the Programming Console.

Operation begins when the RUN bit of the output relay turns ON. (For information on output relays, refer to

ming

Section 4 PC Memory Allocation and Program-

Page 26

Nomenclature and Features

MROELECTRIC.COM

3-3 Nomenclature and Features

3-3-1 Nomenclature

Section 3-3

Display Key

Front View

(With cover open)

Data display

Operation indicators

Cover

Down Key Up Key

Operation keys

Select parameters Set data Switch Loops

Side View

Panel mounting bracket (Refer to panel mounting.)

Appendix D Dimensions

Rear View

for details about

Level Key Loop Key

Heat/Cool Temperature Control Unit connector Connecting cable (sold separately) C200H-CN225 (2 m) C200H-CN425 (4 m)

The bottom row of the operation keys have upper and lower labels. The upper labels apply to Heat/Cool Temperature Control Unit operation. The lower labels are for the Cam Positioner Unit.

Two display sheets are supplied: one for the Heat/Cool Temperature Control Unit and one for the Cam Positioner Unit. If the Data Setting Console is to be used with the Temperature Control Unit only, stick on the display sheet for the Heat/Cool Temperature Control Unit.

Note The Data Setting Console will not operate unless a 24-VDC power supply is con-

nected to the Heat/Cool Temperature Control Unit input terminals.

Page 27

Nomenclature and Features

MROELECTRIC.COM

3-3-2 Features

Data Display

Note Operation begins when the RUN bit of the output relay turns ON.

Operation Indicators

Section 3-3

Name Function

PV (Process Value)

SV (Set Value) The display is as follows, according to the PV display contents.

BK (Bank Number)

Name Function

LOOP2 Indicates whether the displayed settings relate to Loop 1 or Loop

OUT (Output) Turns ON when the heating output is ON

AT (Auto-tuning)

HB (Heater Burnout)

ALM1 (Alarm) Turns ON to indicate the temperature is in

Displays the PV or the parameter symbol selected with the Level or Display Key (Refer to next page).

PV (process value): SV (set value) is displayed. Parameter symbol: Setting/monitor data is displayed.

Displays the bank number of the data presently being displayed. During operation, the executed bank number is displayed. (See note)

2. Press the Loop Key and hold down for approximately 2 seconds to switch between Loop 1 and Loop 2.

Indicator OFF: Loop 1 Indicator ON: Loop 2

These indicators for transistor output or voltage output types.

Blinks at approximately 1 second intervals during auto-tuning.

Turns ON to indicate a heater burnout alarm.

the alarm range set with Alarm SV 1 (upper- and lower-limit alarm). Refer to the following page.

relate to the

currently displayed

loop.

Display Patterns

Display Pattern 1 Display Pattern 2

Process value

Executed bank number or displayed bank number

Indicator OFF: Loop 1 Indicator ON: Loop 2

Set point

Executed bank number or displayed bank number

Indicator OFF: Loop 1 Indicator ON: Loop 2

Parameter symbol SV (Set value)

Monitored value Execution status

Page 28

999 to 9999 C

Parameter Displays and Settings

MROELECTRIC.COM

Operation Keys

Level Key The parameter items are divided into three display groups (Refer

Display Key Press this key to select the required parameter from the selected

Section 3-4

Name Function

to display levels 0 to 2 on the next page). Press this key to switch from one group to another. The display levels automatically cycle in the sequence 0 –> 1 –> 2 –> 0 when the key is held down for approximately 2 seconds.

display level 0 to 2 (Refer to table below). The parameters cycle automatically when the key is held down.

3-4 Parameter Displays and Settings

3-4-1 Table of Parameters

0 Set point

1 SP lower limit

1 SP upper limit

Display

level

Parameter Display

Bank number

Alarm SV 1 (see note 4)

Alarm SV 2 (see note 4)

Input shift value

Proportional band (see note 1)

Integral (reset) time (see note 1)

Derivative (rate) time (see note 1)

Loop Key Press this key for approximately two seconds to switch between

Up Key Press this key to increment SV.

Down Key Press this key to decrement an SV.

Write Read Loop

symbol

Yes Yes Yes Yes SP lower limit to

---

See

note 5

al-1

al-2

in-5

sl-l

sl-h

Yes Yes Yes Yes

Yes Yes Yes Yes –99.9° to

Yes Yes Yes Yes 0.0° to 999.9°C 40.0°C

Yes Yes Yes Yes 0 to 9999 s 240 s

Yes Yes Yes Yes 0 to 9999 s 40 s

Yes Yes Yes No Sensor measur-

Yes Yes Yes No (Sensor measur-

Loop 1 and Loop 2.

The SV increment continuously while the key is held down. The SV display blinks when the value reaches its upper limit.

The SV decreases continuously while the key is held down. The SV display blinks when the value reaches its lower limit.

Bank

no.

Yes Yes No 1 to 8 1 26

no.

Data range Default value Page

0°C 26

SP upper limit

Alarm mode TC 1, 4, 5:

0° to 9999°C Other TCs: –999° to 9999°C

Pt 1, 4, 5:

0.0° to 999.9°C Other Pts: –99.9° to

999.9°C

ing range lower limit to (SP upper limit – 1 digit)

ing range lower limit + 1 digit) to SP upper limit

0°C

0.0°C 27

TC: –200°C Pt: –99.9°C

TC: 1,300°C Pt: 450.0°C

Page 29

Parameter Displays and Settings

MROELECTRIC.COM

Section 3-4

Display

level

2 Heating output

Parameter

Dead band (see note 1)

Cooling coefficient (see note 1)

Heating control period (see notes 1 and 3)

Cooling control period (see notes 1 and 3)

Hysteresis (see note 2)

Alarm hysteresis (see note 4)

Heater current monitor (see note 3)

Heater burnout current (see note 3)

variable monitor Cooling output

variable monitor Auto-tuning start/

stop (see note 1) Copy bank

Input-type monitor

Alarm 1 mode Alarm 2 mode

symbol

c-db

c-sc

c-cp

hys

hysa

h-o

c-o

bcpy

in-t

alt1

alt2

ReadWriteDisplay

Yes Yes Yes No TC: –999 to

Yes Yes Yes No 0.01 to 99.99 1.00 29

Yes Yes Yes No 1 to 99 s 20 s 29

Yes Yes Yes Yes 0.0° to 999.9°C 0.8°C 29

Yes Yes Yes No 0.0° to 999.9°C 0.2°C 30

No Yes Yes No 0.0 to 55.0 A 0.0 A

Yes Yes Yes No 0.0 to 50.0

No Yes Yes No 0.0% to 100.0% 0.0 % 31

Yes Yes Yes No --- --- 31

Yes Yes Yes No --- --No Yes No No 0 to 9 Setting for

Yes Yes Yes No Yes Yes Yes No 2

Loop

no.

9999°C Pt: –99.9 to

999.9°C

0.0: No heater burnout detection, alarm signal OFF

50.0: No heater burnout detection, alarm signal ON

0 to 9

0°C 28

0.0 A

SW202 2

PageDefault valueData rangeBank

Yes: Possible. No: Not possible or not required.

Note 1. Only when advanced PID control is selected. (switch 203-1 = OFF)

2. Only when ON/OFF control is selected. (switch 203-1 = ON)

3. Valid only for C200H-TV03 (current output type).

4. Does not apply when Alarm Mode = 0.

5. Writing is not possible during operation (i.e., when RUN is ON).

6. Thermocouple = TC Platinum Resistance Thermometer = Pt

Page 30

Parameter Displays and Settings

MROELECTRIC.COM

3-4-2 How to Display and Set Parameter Data

Basic Operation

When not specifically explained, use the keys as described in the following.

Changing the Display Level

When the Level Key is pressed, the leading parameter for each level is displayed.

Changing Parameters

When the Display Key is pressed, the parameters are displayed in order. There may be skips depending on the model and DIP switch settings.

Changing the SV

Pressing the Up Key or the Down Key changes the SV. The SV is retrieved automatically.

Changing the Loop

The loop is switched each time the Loop Key is pressed. It can be confirmed by means of the LOOP 2 indicator.

PV and SV (Display Level 0)

Section 3-4

Bank Number (Display Level 0)

Valid SV Range

Set the set point in the range between the SV lower limit and the SV upper limit.

Error Display

When a sensor error occurs, one of the codes below and the detected temperature blink alternately in the PV display.

ser1

ser2

serr

Bank number parameter symbol

Temperature is out of the range: (sensor measurement range + 10%FS). That is, 10%FS below the lower limit or 10%FS above the upper limit. Includes broken or incorrect sensor wiring.

ser1: Loop1 or Loop1 and Loop2 simultaneously. ser2: Loop2

Abnormality in the cold junction compensating circuit. Applies to thermocouple type only .

Process temperature (monitored every 500 ms)

Set point of currently selected bank and loop (unit: °C or °F)

Settings

• The bank number can be changed.

• The changed SV is reflected in the bank number display (BK).

Bank Number and Executed Bank Number

The executed bank number cannot be changed from the Data Setting Console.

Currently set bank number. During control operation: Executed bank number Control operation interrupted: Currently displayed bank number

Page 31

Parameter Displays and Settings

MROELECTRIC.COM

When changing these parameters from the Data Setting Console, stop operation. While operation is stopped, the bank number setting can be changed.

Alarm SV 1 (Display Level 0)

Section 3-4

Alarm SV 2 (Display Level 0)

Input Shift Value (Display Level 0)

If the displayed temperature value differs from the actual temperature value due to the sensor position or some other conditions, set the input shift value such that the correct temperature is displayed.

Not valid when Alarm mode = 0.

Alarm 1 parameter symbol

Alarm SV of currently selected bank and loop (unit: °C or °F)

Alarm 2 parameter symbol

Alarm SV of currently selected bank and loop (unit: °C or °F)

Input shift value parameter symbol

Input shift value of currently selected bank and loop (unit: °C or °F)

Proportional Band (Display Level 0)

• This sets the proportional band. It is valid only when SW203-1 is set to OFF (i.e., PID control).

• This value is reflected even when auto-tuning (AT) is executed.

• If this value is set to “0.0,” ON/OFF control is executed.

Integral (Reset) Time (Display Level 0)

• This sets the integral time. It is valid only when SW203-1 is set to OFF (i.e., PID control).

• This value is reflected even when auto-tuning (AT) is executed.

Derivative (Rate) Time (Display Level 0)

Proportional band parameter symbol

Proportional band of currently selected bank and loop (unit: °C or °F)

Integral time parameter symbol

Integral time of currently selected bank and loop (unit: second)

Derivative time parameter symbol

Derivative time of currently selected bank and loop (unit: second)

Page 32

Parameter Displays and Settings

MROELECTRIC.COM

• This sets the integral time. It is valid only when SW203-1 is set to OFF (i.e., PID control).

• This value is reflected even when auto-tuning (AT) is executed.

SP Lower Limit (Display Level 1)

Section 3-4

• Settings can be made within the following range:

• When powering up or starting, the lower limit of the measuring range for sen-

SP Upper Limit (Display Level 1)

• Settings can be made within the following range:

• When powering up or starting, the upper limit of the measuring range for sen-

Sensor measuring range lower limit to (SP upper limit – 1 digit)

sors set by the rear-panel SW202 (sensor type) is set automatically. For example, if SW202 is set to “2,” the thermocouple type is set to “–200.” However, the SP lower limit will not be changed if the current SV lies inside the sensor measuring range.

(SP limit + 1 digit) to sensor measuring range upper limit

sors set by the rear-panel SW202 (sensor type) is set automatically. For example, if SW202 is set to “2,” the thermocouple type is set to “1300.” However, the SP upper limit will not be changed if the current SV lies inside the sensor measuring range.

SP lower limit parameter symbol

SP lower limit of currently selected loop (unit: °C or °F)

SP upper limit parameter symbol

SP upper limit of currently selected loop (unit: °C or °F)

Dead Band (Display Level 1)

• This sets the cooling output dead band, and it is valid when SW203-1 (PID control) is OFF.

• The relation between the dead band and the set temperature is as shown in the illustration below.

Output volume

Heating output

100%

Dead band parameter symbol

Dead band of currently selected loop (unit: °C or °F)

Dead band

Cooling output

Temperature

Set value

Page 33

Parameter Displays and Settings

MROELECTRIC.COM

Cooling Coefficient (Display Level 1)

Section 3-4

Control Period (Display Level 1)

• This sets the coefficient for finding the cooling P constant. It is valid when SW203-1 is OFF (PID control). The formula for calculating the cooling P constant is as follows:

Cooling P constant = heating P constant x cooling coefficient

• The I/D constant is the same for cooling as for heating.

• This sets the control period. It is valid when SW203-1 is OFF (PID control), and only when the heater model is not the C200H-TV03 (current output type).

• Cooling loop 1 is invalid when SW203-6 is ON (current output).

• The control period is the time required to complete one transistor output or volt-

age output ON/OFF cycle.

Cooling coefficient parameter symbol

Cooling coefficient of currently selected loop

Heating control period parameter symbol

Heating control period of currently selected loop (Unit: seconds)

Cooling control period parameter symbol

Cooling control period of currently selected loop (Unit: seconds)

Hysteresis (Display Level 1)

OFF

ON time

Control period

• Hysteresis prevents control output chattering and eliminates noise influences.

• When switching from ON to OFF, operation proceeds at the set point. When

switching from OFF to ON, operation proceeds at a lower point determined by the hysteresis SV, as shown in the following illustration.

Hysteresis parameter symbol

Hysteresis of currently selected bank and loop (Unit: °C or °F)

Hysteresis

OFF

Set point

Page 34

Parameter Displays and Settings

MROELECTRIC.COM

Hysteresis is applied in the following situations.

• When ON/OFF control is selected (i.e., when SW203-1 is ON).

• When advanced PID control is selected (i.e., when SW203-1 is OFF) and P

(proportional band) is 0.

Alarm Hysteresis (Display Level 1)

Section 3-4

• Alarm hysteresis prevents alarm output chattering and eliminates noise influences. It is invalid when both alarm mode 1 and alarm mode 2 are “0.”

• When switching from OFF to ON, operation proceeds at the set point. When switching from ON to OFF, a hysteresis SV operating band is provided which may be either higher or lower than the set point, depending on the alarm mode.

Hysteresis

OFF

The alarm output is OFF if the present temperature lies within the hysteresis band when the Unit is turned on.

Heater Current Monitor (Display Level 1)

Alarm hysteresis parameter symbol

Alarm hysteresis of currently selected loop (Unit: °C or °F)

Upper Limit Mode Lower Limit Mode

Set point Set point

Hysteresis

OFF

Note Cannot be set.

• Valid for C200H-TV03 (current output type).

Heater Burnout Detection Current (Display Level 1)

• Invalid for C200H-TV03 (current output type).

• Make the setting using one of the two values shown in the table below. Refer to

Appendix C Heater Burnout Detection

0.0 No heater burnout detection. Alarm signal OFF.

50.0 No heater burnout detection. Alarm signal ON.

Heater current monitor parameter symbol

Heater current of currently selected loop (Unit: Ampere). Monitored every 500 ms.

Heater burnout detection current parameter symbol

Heater burnout detection current of currently selected loop (Unit: Ampere) The setting can be changed from this display.

for more details about the alarm SVs.

Page 35

Parameter Displays and Settings

MROELECTRIC.COM

Control Output Variable Monitor (Display Level 2)

Section 3-4

The relationship between the control output variable and control period is defined by the formula below:

Control output variable (%) = x 100 The control output variable during ON/OFF control (when SW203-1 on the rear

panel is ON) is ON = 100% and OFF = 0%.

Auto-tuning Start/Stop (Display Level 2)

AT start/stop parameter symbol

Heating control output variable monitor parameter symbol

Heating output variable of currently selected loop (Unit: %). Monitored every 500 ms.

Cooling control output variable monitor parameter symbol

Cooling output variable of currently selected loop (Unit: %). Monitored every 500 ms.

ON time

Control period

Process temperature

Set point

AT indicator blinks

• The auto-tuning operation begins when the Up Key is pressed. The PV and SV return to the respective present temperature and set point displays. While auto-tuning is in progress the AT indicator blinks.

• To interrupt, press the Level and Display Keys again to display at. When at appears, press the Up Key. When the interrupt is executed, the A T display disappears and the process temperature is displayed.

• When auto-tuning is completed, the AT indicator stops blinking and the P, I, an d D data is written to EEPROM.

Copy Bank (Display Level 2)

Copy bank parameter symbol

Input-type Monitor (Display Level 2)

Execute bank copy

• When the Up Key is pressed, the data other than the set point is copied from bank number 1 to banks 2 through 8.

• Use this method to create data in banks 2 through 8 by slightly modifying the data in bank number 1.

Bank being copied

Input-type monitor parameter symbol

Bank copy completed

Note Cannot be set.

Input type currently set with SW202 on the rear panel. Thermocouple: Setting no. Platinum resistance thermometer: 0: JPt (OFF), 1: Pt (ON)

Page 36

Parameter Displays and Settings

MROELECTRIC.COM

Alarm 1 and Alarm 2 Modes (Display Level 2)

Section 3-4

Select the desired alarm type from the following chart and set the number (X: set value)

Alarm

Mode

0No alarm 1 Upper- and lower-limit alarm

2 Upper-limit alarm

Alarm Type Alarm Range

Alarm 1 Mode parameter symbol

Alarm 1 Mode of currently selected loop

Alarm 2 Mode parameter symbol

Alarm 2 Mode of currently selected loop

0SP

x x

3 Lower-limit alarm

4 Upper- and lower-limit range alarm

5 Upper- and lower-limit alarm with

standby sequence

6 Upper-limit alarm with standby

sequence

7 Lower-limit alarm with standby

sequence

8 Absolute-value upper-limit alarm

9 Absolute-value lower-limit alarm

Standby Sequence

When the power is turned on, the temperature is below the set point, so alarm output status occurs with regard to the lower limit alarm. In this situation, if “lower limit alarm with standby sequence” is selected, the standby sequence recognizes that the value is out of the alarm range and then outputs an alarm when the value enters the alarm range once more.

x x

Page 37

Parameter Displays and Settings

MROELECTRIC.COM

Lower Limit Alarm with Standby Sequence

The standby sequence is restarted in the following situations.

• When the power is turned on.

• When the set point is changed.

• When the executed bank number is changed.

• When the alarm mode is changed.

• When changing from stop to run.

Hysteresis OFF point

Alarm SV

0°C

Alarm output

Standby sequence cancel point

Section 3-4

Page 38

SECTION 4

MROELECTRIC.COM

PC Memory Allocation and Programming

This section provides the C200H PC’s memory allocation for the Heat/Cool Temperature Control Unit. Basic programming procedures and examples are also provided.

4-1 Memory Allocation 36. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-1-1 Memory Allocation T able 37. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-1-2 Memory Contents 38. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-1-3 Table of Commands 41. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-2 Data Flow 43. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-3 Programming 43. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-3-1 Example with SW2-1 in the Fixed Position 43. . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-3-2 Example 1: Write with SW2-1 in the Normal Position 44. . . . . . . . . . . . . . . . . . . . .

4-3-3 Example 2: Read with SW2-1 in the Normal Position 47. . . . . . . . . . . . . . . . . . . . .

4-3-4 Operation Timing 50. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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Memory Allocation Section 4-1

MROELECTRIC.COM

4-1 Memory Allocation

Memory Allocation According to the Unit number switch setting on the front of the C200H Heat/Cool

Temperature Control Unit, 10 words are allocated for each Unit number in the Special I/O Unit IR area between IR100 to IR199, which is used as the I/O refresh data area. The IR area used by the C200H Temperature Control Unit is refreshed on each C200H PC I/O refresh cycle.

C200H PC

IR area Unit#0 IR100 to IR109

Unit#1 IR110 to IR119 Unit#2 IR120 to IR129 Unit#3 IR130 to IR139 Unit#4 IR140 to IR149 Unit#5 Unit#6 IR160 to IR169 Unit#7 IR170 to IR179 Unit#8 IR180 to IR189 Unit#9 IR190 to IR199

Selecting Allocated Data The data allocated to each IR word due to the Unit number setting is determined

IR150 to IR159

Note A Duplicate I/O Unit error occurs if the set Unit number corresponds to the num-

During the PC’s I/O refresh, each cycle is executed for the outputs (PC to Heat/Cool Temperature Control Unit) followed by the inputs (Heat/ Cool Temperature Control Unit to PC).

ber of an existing Special I/O Unit.

by the setting of SW2-1 on the front of the Unit.

ON Normal All data can be set using commands. OFF Fixed Parameters are fixed for the set point (SP).

OUT

Heat/Cool Temperature Control Unit

I/O refresh data area

Wd (n) to Wd (n+2)

Wd (n+3) to Wd (n+9)

(n=100 + 10 x Unit number)

The terms “output” and “input” are defined from the C200H PC side.

Output refresh

Input refresh

This setting becomes valid immediately when the switch is set.

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Memory Allocation Section 4-1

MROELECTRIC.COM

4-1-1 Memory Allocation Table

SW2-1 in Fixed Position

(n=100 + 10 x Unit number)

I/O Word

Output n

n+1

n+2 Loop 1 executed bank

Input n+3

n+4

n+5

n+6

n+7

n+8 Loop 1 status data

n+9 Loop 2 status data

Bit

15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00

Loop 1 SP (see note) 0 to 9, F 0 to 9 0 to 9 0 to 9 Loop 2 SP (see note) 0 to 9, F 0 to 9 0 to 9 0 to 9

Loop 2 executed bank

number number Loop 1 PV (see note)

0 to 9, F 0 to 9 0 to 9 0 to 9 Loop 2 PV (see note) 0 to 9, F 0 to 9 0 to 9 0 to 9 Loop 1 SP (see note) 0 to 9, F 0 to 9 0 to 9 0 to 9 Loop 2 SP (see note) 0 to 9, F 0 to 9 0 to 9 0 to 9 Loop 1 executed bank

number number

0 Sen-

sor error

CT overflow

Loop 2 executed bank

0 0

Loop 1 Loop 2 0

RUN

0 0 0

RUN

0 0 Coo

RUN

0 0 Coo

ling output

RUN

Hea

AT HB AL1 AL2 ting output

Hea

AT HB AL1 AL2 ting output

SW2 2 1

Note For four-digit BCD and platinum resistance thermometer data, the least

significant digit = 0.1, and the most significant digit (F) = minus (–). For example, “F200” represents –20.0°C for a platinum resistance thermometer.

SW2-1 in Normal Position

(n=100 + 10 x Unit number)

I/O Word

15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00

Output

Input n+3

n Read/write instruction

Read/write Loop no. Bank no. Instruction

n+1

n+2 Loop 1 executed bank

Write data (see note) 0 to 9, F 0 to 9 0 to 9 0 to 9

number

Loop 1 PV (see note) 0 to 9, F 0 to 9 0 to 9 0 to 9

Loop 2 executed bank number

Bit

Loop

1 RUN

0 Loop 2

RUN

0 0 0 Write

request

Page 41

digit is 0.1. S

ifi

Memory Allocation Section 4-1

MROELECTRIC.COM

I/O BitWordI/O

Input n+4

Word

n+5

n+6 0 Write

n+7

n+8 Loop 1 status data

n+9 Loop 2 status data

Loop 2 PV (see note) 0 to 9, F 0 to 9 0 to 9 0 to 9 Read data (see note) 0 to 9, F 0 to 9 0 to 9 0 to 9

error

Loop 1 executed bank number number

0 Sen-

sor error

CT overflow

Loop 2 executed bank

0 0

0 0 Write

0 0 0 0 Read complete

0 0 0

RUN

0 0 Co

oling output

Heat-

AT HB AL1 AL2 ing output

Heat-

AT HB AL1 AL2 ing output

00010203040506070809101112131415

com-

plete SW2 2 1

Note For four-digit BCD and platinum resistance thermometer data, the least

significant digit = 0.1, and the most significant digit (F) = minus (–). For example, “1000” represents 100.0°C for a platinum resistance thermometer.

4-1-2 Memory Contents

SW2-1 in Fixed Position

I/O Address Data item Data contents

Word Bit

Output n 15 to 00 Loop 1 SP

n+1 15 to 00 Loop 2 SP

n+2 15 to 12 Loop 1

executed bank number

11 to 08 Loop 2

executed bank

number 07 --- Not used. Set to 0. 06 Loop 1

RUN 05 --- Not used. Set to 0. 04 Loop 2

RUN 03 to 00 --- Not used. Set to 0.

Sets the Loop 1 and Loop 2 SP (set point) as 4-digit BCD data. For platinum resistance thermometer data, the least significant

et the most sign

Note These specified values apply to the bank number set with Wd

(n+2) and can are written directly to RAM. (Refer

Sets the bank number executed for Loop 1 and Loop 2 as 1-digit BCD data. Set executed bank numbers from 1 to 8. If the value is set out of this range, the bank number reverts to the previous value.

This the Loop 1 Run/Stop bit. When it is set to 1, operation starts; when it is set to 0, operation stops.

This the Loop 2 Run/Stop bit. When it is set to 1, operation starts; when it is set to 0, operation stops.

(n=100 + 10 x Unit number)

cant digit to F for minus (–).

page 43

)

Page 42

BCD dat

dat

Memory Allocation Section 4-1

MROELECTRIC.COM

I/O Data contentsData itemAddress

BitWord

Input n+3 15 to 00 Loop 1 PV

n+4 15 to 00 Loop 2 PV n+5 15 to 00 Loop 1 SP n+6 15 to 00 Loop 2 SP n+7 15 to 12 Loop 1

executed

bank

number 11 to 08 Loop 2

executed

bank

number 07 to 02 --- Not used. Each bit is set to 0. 01 SW2-2 Outputs the ON/OFF status of SW2-2 (setting direction).

00 SW2-1 Outputs the ON/OFF status of SW2-1 (switching memory

n+8 Loop 1 n+9 Loop 2

15 --- Not used. Set to 0.

14 Sensor

error

13 CT

overflow 12 to 09 --- Not used. Each bit is set to 0. 08 RUN Bit set to 1 during operation. 07 and 06 --- Not used. Each bit is set to 0. 05 Cooling

control

output 04 Heating

control

output 03 AT Bit set to 1 during auto-tuning (AT). 02 HB Bit set to 1 if the detected heater current drops

01 AL1 00 AL2

Outputs the Loop 1 and Loop 2 PV (process value) as 4-digit

a. For platinum resistance thermometer data, the leas

significant digit is 0.1. The most significant digit is F for minus (–). Outputs the Loop 1 and Loop 2 SP (set point) as 4-digit BCD

a. For platinum resistance thermometer data, the leas

significant digit is 0.1. The most significant digit is F for minus (–). Outputs the bank number currently executed for Loop 1 and Loop

2 as 1-digit BCD data.

0: Data Setting Console 1: C200H PC

contents).

0: Fixed 1: Normal

Loop 1/2 status data

Bit set to 1 if the sensor is not connected, a sensor wire is broken, or the input data exceeds the operational temperature range.

Bit set to 1 when the detected heater current exceeds 55.0 A.

Bit set to 1 when the control output (transistor or voltage output) is ON.

below the set heater burnout current value. (HB: heater burnout)

Bit set to 1 when the temperature enters the set alarm range (Refer to page 23).

Note If the setting direction of the Temperature Control Unit is set to the C200H PC

and the C200H is in program mode, all word data will be 0. Therefore, if the C200H in program mode has been set to continuous control, the Temperature Control Unit executes temperature control when the C200H stops operating, judging that the SP has been changed to 0°C. To prevent this, set SW2-2 of the Temperature Control Unit to OFF (i.e., the setting direction is set to the Data Setting Console) before the C200H stops operating and reset SW2-2 after the C200H restarts.

Page 43

BCD data. For latinum resistance thermometer data, the least

Memory Allocation Section 4-1

MROELECTRIC.COM

SW2-1 in Normal Position

(n=100 + 10 x Unit number)

I/O Address Data item Data contents

Word Bit

Output n 15 and 14 Read/Write The data bit sets operation to read or write.

Write = 01 Read = 00

13 and 12 Loop no. The data bit sets the Loop Number to which the

read or write operation applies. Loop 1 = 01, Loop 2 = 10

11 to 08 Bank no. Sets the bank number to which the read or write

operation applies as 1-digit BCD data. Set executed bank numbers from 1 to 8.

07 to 00 Command Sets the command code (Refer to page 41) for the

read or write operation as 2-digit BCD data.

n+1 15 to 00 Write data Set the SP for a write operation as 4-digit BCD data. The least

significant digit of the actual data matches the least significant digit of the set value. Set the most significant digit to F for minus (–) values. The write operation commences when the write request flag (Wd (n+2), bit 00) turns ON.

n+2 15 to 12 Loop 1

executed

bank

number 11 to 08 Loop 2

executed

bank

number 07 --- Not used. Set to 0. 06 Loop 1

RUN 05 --- Not used. Set to 0. 04 Loop 2

RUN 03 to 01 --- Not used. Set to 0. 00 Write

request

Input n+3 15 to 00 Loop 1 PV

n+4 15 to 00 Loop 2 PV

n+5 15 to 00 Read data Outputs the data read with the commands set with Wd (n). The

n+6 15 to 12 --- Not used. Each bit is set to 0.

11 Write error Bit set to 1 when the write data exceeds the set permissible

10 and 09 --- Not used. Each bit is set to 0. 08 Write

complete

Set the bank number currently executed for Loop 1 and Loop 2 as 1-digit BCD data. Executed bank numbers are from 1 to 8. If the value is set out of this range, the bank number reverts to the previous value.

This the Loop 1 Run/Stop bit. When it is set to 1, operation starts; when it is set to 0, operation stops.

This the Loop 2 Run/Stop bit. When it is set to 1, operation starts; when it is set to 0, operation stops.

Turn this bit ON to write the data in Wd (n+1), by means of this command. Turn this bit OFF after the Write Complete Flag (Wd (n+6), bit 08) turns ON.

Outputs the Loop 1 and Loop 2 PV (process value) as 4-digit BCD data. For platinum resistance thermometer data, the least significant digit is 0.1. Set the most significant digit to F for minus (–) values.

least significant digit of the actual data matches the least significant digit of the set value. Set the most significant digit to F for minus (–) values.

range. The bit is automatically set to 0 when the Write Request Flag (Wd (n+2), bit 00) turns OFF.

Bit set to 1 when the write operation executed by means of the command set with Wd (n) ends normally. The bit is automatically set to 0 when the Write Request Flag (Wd (n+2), bit 00) turns OFF.

Read/Write command

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Memory Allocation Section 4-1

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I/O Data contentsData itemAddress

BitWord

Input n+6 07 to 01 --- Not used. Each bit is set to 0.

n+7

n+8 Loop 1 n+9 Loop 2

00 Read

complete

15 to 12 Loop 1

executed

bank

number 11 to 08 Loop 2

executed

bank

number 07 to 02 --- Not used. Each bit is set to 0. 01 SW2-2 Outputs the ON/OFF status of SW2-2 (setting direction).

00 SW2-1 Outputs the ON/OFF status of SW2-1 (switching memory

15 --- Not used. Set to 0. 14 Sensor

error

13 CT

overflow 12 to 09 --- Not used. Each bit is set to 0. 08 RUN Bit set to 1 during operation. 07 and 06 --- Not used. Each bit is set to 0. 05 Cooling

control

output 04 Heating

control

output 03 AT Bit set to 1 during auto-tuning (AT). 02 HB Bit set to 1 if the detected heater current drops

01 AL1 00 AL2

Bit set to 1 when the read operation executed by means of the command set with Wd (n) ends normally. The bit is automatically set to 0 when the next command is set.

Outputs the bank number currently executed for Loop 1 and Loop 2 as 1-digit BCD data.

0: Data Setting Console 1: C200H PC

contents).

0: Fixed 1: Normal

Loop 1/2

Bit set to 1 if the sensor is not connected, a sensor wire is broken, or the input data exceeds the operational temperature range.

Bit set to 1 when the detected heater current exceeds 55.0 A.

Bit set to 1 when the control output (transistor or voltage output) is ON.

below the set heater burnout current value. (HB: heater burnout)

Bit set to 1 when the temperature enters the set alarm range (Refer to page 23).

status data

4-1-3 Table of Commands

The command codes shown below are set in bits (n Wd) 07 to 00 when the SW2-1 (switching memory contents) on the front panel is set in the Normal position.

Parameter Com-

mand

Set point 0 0 Yes Yes Yes Yes SV lower limit to SV upper

Executed bank number 0 2 Yes Yes Yes No 1 to 8 0001 to

Write Read Loop

no.

Bank

no.

Actual data

range

limit

Write/Read data range

0008

Default value

0°C

Page 45

9999°C ()

Memory Allocation Section 4-1

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Alarm SV 1 (see note 4) 0 3 Yes Yes Yes Yes

Alarm SV 2 (see note 4) 0 4 Yes Yes Yes Yes

Input shift value 0 5 Yes Yes Yes Yes –99.9 to

Proportional band (see note 1)

Integral (reset) time (see note 1)

Derivative (rate) time (see note 1)

SP lower limit 1 0 Yes Yes Yes No Sensor measuring range

SP upper limit 1 1 Yes Yes Yes No (SP lower limit + 1 digit) to

Dead band (see note 1) 1 C Yes Yes Yes No

Cooling coefficient (see note 1)

Heating control period (see notes 1 and 3)

Cooling control period (see notes 1 and 3)

Hysteresis (see note 2) 1 8 Yes Yes Yes Yes 0.0 to 999.9°C 0000 to

Alarm hysteresis (see note 4)

Heater current monitor (see note 3)

Heater burnout current (see note 3)

Heating control output variable monitor

Cooling control output variable monitor

Auto-tuning start/stop (see note 1)

Copy bank 2 2 Yes No Yes No --- 0001 --Input-type monitor 2 3 No Yes No No 0 to 9 0000 to

Parameter Default valueWrite/Read

mand

0 6 Yes Yes Yes Yes 0.0 to 999.9°C 0000 to

0 7 Yes Yes Yes Yes 0 to 9999 s 0000 to

0 8 Yes Yes Yes Yes 0 to 9999 s 0000 to

1 D Yes Yes Yes No 0.01 to 99.99 0001 to

1 7 Yes Yes Yes No 1 to 99 s 0001 to

1 6 Yes Yes Yes No 1 to 99 s 0001 to

1 9 Yes Yes Yes No 0.0 to 999.9°C 0000 to

1 A No Yes Yes No 0.0 to 55.0 A 0000 to

1 B Yes Yes Yes No 0.0 to 50.0 A 0000 to

2 0 No Yes Yes No 0.0 to 100.0% 0000 to

2 6 No Yes Yes No 0.0 to 100.0% 0000 to

2 1 Yes No Yes No ---

ReadWriteCom-

Loop

no.

Bank

no.

Actual data

range

Alarm mode TC 1, 4, 5:

0 to 9999°C Other TCs: –999 to

Pt 1, 4, 5:

0.0 to 999.9°C Other Pts: –99.9 to

999.9°C

lower limit to (SP upper limit value – 1 digit)

sensor measuring range upper limit

TC: –999 to 9999°C Pt: –99.9 to 999.9°C

0.0: No heater burnout detection, alarm signal OFF

50.0: No heater burnout detection, alarm signal ON

data range

0000 to 9999 F999 to 9999

F999 to 9999

9999

F999 to 9999

9999

0550

0050

1000

Start = 0001 Stop = 0000

0009

0°C

0.0°C

40.0°C

240 s

40 s

TC: –200°C Pt: –99.9°C

TC: 1,300°C Pt: 450.0°C

0°C

1.00

20 s

0.8°C

0.2°C

0.0 A

0.0%

---

Setting for SW202

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Section 4-3

Parameter Default valueWrite/Read

mand

Alarm 1 mode 2 4 Alarm 2 mode 2 5

Note 1. Only when advanced PID control is selected. (switch 203-1 = OFF)

Yes Yes Yes No 0 to 9 0000 to

Yes: Possible. No: Not possible or not required.

2. Only when ON/OFF control is selected. (switch 203-1 = ON)

3. Invalid only for C200H-TV03 (current output type).

4. Does not apply when Alarm Mode = 0.

5. Thermocouple = TC

ReadWriteCom-

Platinum Resistance Thermometer = Pt

Loop

no.

Bank

no.

Actual data

range

data range

0009

4-2 Data Flow

Refer to Unit.

Data Settings Before setting data with a user program or the Programming Console, turn ON

SW2-2 of the Unit to enable data setting from the C200H PC. However, the executed bank number can be set with a user program or from the Programming Console regardless of the ON/OFF setting of SW2-2.

SW2-1 (switching memory contents) may be set in either the OFF (Fixed) or ON (Normal) position, but care is required as the setting of this switch changes the stored data contents.

3-2 Data Flow

for the data flow in the Heat/Cool Temperature Control

4-3 Programming

4-3-1 Example with SW2-1 in the Fixed Position

Description and Conditions

Sample Program

1 cycle ON

(C200H)

Example: The user program makes the following settings:

Conditions:C200H-TV001 (thermocouple)

1070023515 10701

Fixed

Loop 1 SP = 80°C Loop 2 SP = 200°C Loop 1 executed bank number = 1 Loop 2 executed bank number = 3

SW203 set to 2 (K). Unit number set to 0 (allocated memory: IR100 to IR109). SW2-1 set OFF (Fixed) and SW2-2 set ON (C200H PC).

MOV (21)

END (01)

Set #0080 for word 100 (Loop 1 SP).

#0080

100

Set #0200 for word 101 (Loop 2 SP).

#0200

101

Set #1350 for word 102 (executed bank number).

#1350

102

#1350 run bit ON

Loop 1, loop 2 begin operation

Loop 2 executed bank number Loop 1 executed bank number

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Be sure to set the correct values for the Loop 1 and Loop 2 SP. The SV value is #0000 (0°C) if no data is set. If the executed bank number is set

to a value out of the range from 1 to 8 the bank number reverts to the previous value (default value = 1).

Reading Monitored Data Read monitored data into the program using Wd (n+3) to (n+9).

4-3-2 Example 1: Write with SW2-1 in the Normal Position

Description and Conditions

Example The user program makes the following settings:

Loop 1 SP = 200°C (Bank no. = 1) Loop 2 SP = 250°C (Bank no. = 2) Loop 1 executed bank number = 1 Loop 2 executed bank number = 2 Loop 1 heater burnout current value = 2.0 A Loop 2 heater burnout current value = 2.5 A

Conditions C200H-TV001 (thermocouple)

SW203 set to 2 (K). Unit number set to 0 (allocated memory: IR100 to IR109). SW2-1 set ON (Normal) and SW2-2 set ON (C200H PC).

Section 4-3

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Programming

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Sample Program

10701

10700

(C200H)

Normal

DIFU (13)

SW2-2 (10701) switch ON detection (C200H PC)

23200

Section 4-3

25315 10701

1 cycle ON Normal

23200

23201

23202

23201

10608

(C200H)

Write complete

10700

MOV (21)

DIFD (14)

23201

#1250

102

#5100

100

#0200

101

23203

KEEP(11)

23202

Program runs when operation is started or SW2-2 turned ON

#1250

Loop 1, loop 2 begin operation Loop 2 executed bank number

Loop 1 executed bank number

#5100

SP setting instruction Bank number

Bit data : 0101

Loop 1

Write data (200°C)

Write

Waits for write completion, then proceeds to next step.

23203

23204

23203

10608

23205

Write complete

MOV (21)

DIFD (14)

MOV (21)

#6200

100

#0250

101

23205

KEEP(11)

23204

#501B

100

#0020

101

#6200

SP setting instruction Bank number Bit data:

Write data (250°C)

Waits for write completion, then proceeds to next step.

#501B

Heater burnout current value command

Bank number not required Bit data:

Write data (2A)

0110

Loop 2 Write

0101

Loop 1 Write

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Section 4-3

23206

23205

10608

Write complete

23207

23201

23203

23205

23207

10608

Write complete

DIFD (14)

MOV (21)

23207

KEEP(11)

23206

#601B

100

#0025

101

KEEP(11)

10200

Waits for write completion, then proceeds to next step.

#601B

Write data (2.5A)

Write request

Heater burnout current value command

Bank number not required Bit data:

0110

Loop 2 Write

END (01)

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Timing Chart

Section 4-3

1 cycle

25315

(1 cycle ON)

23201

23202

23203

23204

23205

23206

23207

10200

(Write request)

(Write complete)

In addition to the timing above, 23201 turns ON for one cycle on the ON rising edge of SW2-2 (10701).

10608

j: Point of Write command execution

4-3-3 Example 2: Read with SW2-1 in the Normal Position

Description and Conditions

Example: The following data is read from the indicated addresses:

Conditions:C200H-TV001 (thermocouple)

Loop 1 PV: DM0000 Loop 1 heating control output variable: DM0001 Loop 2 heater current: DM0002 This read program is to be executed after writing the data with program example 1.

SW203 set to 2 (K). Unit number set to 0 (allocated memory: IR100 to IR109. SW2-1 set ON (Normal) and SW2-2 set ON (C200H PC).

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Sample Program

Section 4-3

Insert the program below before the END instruction in the program on page 46.

(A)

25313

Normally ON

23208

23207

Write complete

10608

23300

23307

23301

23302

10701

(C200H)

10700

Normal

MOV (21)

DIFD (14)

MOV (21)

DIFD (14)

103

DM0000

23300

KEEP(11)

23208

23301

#1020

100

23302

KEEP(11)

23303

Read Loop 1 PV from IR103 to DM 0000. Read operation is not affected by SW2-1 and SW2-2 settings.

Runs next Read command when final write complete is detected.

23307 repeatedly executes the Read command when each Read Complete is detected.

#1020

Wait for Read Complete to read data

Heating control output variable monitor command Bank number not required

Bit data:

0001

Loop 1 Read

10600

Read complete

23303

DIFD (14)

23304

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Section 4-3

23304

23305

10600

23306

23307

Read complete

MOV (21)

DIFD (14)

MOV (21)

105

DM0001

#201A

100

23305

KEEP(11)

23306

23307

105

DM0002

Read data from IR105 to DM 0001.

Execute next Read command.

#201A

Wait for Read Complete to read data

Read data from IR105 to DM 0002.

Heater Current Monitor command

Bank number not required Bit data

0010

Loop 2 Read

(B)

(C200H)

25315

1 cycle ON

23200

1070010701

Normal

10701

(C200H)

10700

Normal

Change the above program as shown below if only reading is to be carried out. Replace part (A) of the program with the following program.

DIFU (13)

23200

23300

SW2-2 (10701) switch ON detection (C200H PC)

Program runs when operation is started or SW2-2 turned ON

Add an END instruction (01) at position (B) of the program.

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Timing Chart

23301

23302

23303

23304

23305

23306

23307

Wd 105

(Read data)

10600

(Read complete)

Section 4-3

1 cycle

4-3-4 Operation Timing

Write Operation Timing

Command (Wd n) Write data (Wd n+1)

Write request (Wd n+2), bit 00

Write complete (Wd n+2), bit 08

1, 2, 3...

ON OFF

1. The data is written to the Heat/Cool Temperature Control Unit EEPROM

2. The Write Complete Flag turns ON when the data writing operation is com-

3. The Write Complete Flag automatically turns OFF when the Write Request

: Point of Read command execution

: Point where data (1) is read. : Point where data (2) is read.

Data (1) Data (2) Data (3) Data (4)

Approx. 140 ms

when the Write Request Flag turns ON.

pleted. It takes approximately 140 ms to write the data.

Flag turns OFF. Check the Write Complete Flag is ON before turning OFF the W rite Request

Flag. If the W rite Request Flag is set to OFF before the W rite Complete Flag turns ON the Write Complete Flag will not subsequently turn ON.

Temporarily turn the Write Request Flag OFF before executing the second and subsequent write operations. Writing is enabled on the ON rising edge of the Write Request Flag.

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Timing for a Read Operation

Section 4-3

The Loop 1 and 2 executed bank number (Wd n+2) sets data directly . The data is written to the Heat/Cool Temperature Control Unit RAM. If the value is set out of this range, the bank number reverts to the previous value (default value = 1).

I/O Refresh

1, 2, 3...

Command (n)

Read complete (Wd n+6), bit 00

Read data (Wd n+5)

1. The read data is output to Wd (n+5) approximately 140 ms after the Read command is executed.

2. The read data is updated every 100 ms.

3. When the Read command is modified, turn OFF the Read Complete Flag to execute the next read operation.

Heating and cooling control will not be executed properly unless there are at least 8 ms between I/O refresh operations. When creating the program, be sure that all of the conditions described below are satisfied.

• The cycle time must be a minimum of 8 ms. If the program processing time is short, it is recommended that the fixed cycle time instruction, SCAN(18), be used.

• When IORF(97) is executed for the Temperature Control Unit, there must be an interval of at least 8 ms between prior and subsequent end refreshes.

• The time interval for executing IORF(97) must be a minimum of 8 ms.

ON OFF

Command (A) Command (B)

Approx. 140 ms

Read data (A) Read data (B)

Normal I/O refresh

IORF(97)

Normal I/O refresh

(End refresh)

8 ms min. (cycle time)

(End refresh)

8 ms min.

(I/O refresh instruction)

8 ms min.

(I/O refresh instruction)

8 ms min.

(End refresh)

Page 55

This section provides possible errors and error remedies.

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Error Detection 54. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

SECTION 5

Troubleshooting

Page 56

The alarm is out ut

Broken or incorrect in ut

Error Detection Section 5

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Error Detection

When an error occurs in an input or in the Unit, details of the error are output to the Data Setting Console and input relays (words n+8 and n+9).

Sensor Input Errors

The following table shows the Data Setting Console display and error contents.

Display Error name Output status after

error

ser1

ser2

serr

Data Setting Console When a sensor error occurs, one of the codes above and the detected tempera-

Loop 1 sensor error

Loop 2 sensor error

Cold junction compensating circuit error (C200H-TC00)

Control output: The transistor output or voltage output turns OFF or the current output falls below 2 mA.

Alarm output: The alarm is output assuming the input is +10%FS.

Control output: The transistor output or voltage output turns OFF or the current output falls below 2 mA.

ture are displayed alternately. If a Loop 1 sensor error ser1 and a Loop 2 sensor error ser2 occur simultaneously,

ser1 is displayed preferentially. Even if a sensor error is detected in one Loop, the other Loop continues to operate normally. Control operation restarts automatically five seconds after the cause of the error is corrected. If a cold junction compensating circuit error occurs, reset the power supply.

The following bits are set when a sensor input error occurs.

Reading is + 10%FS out of sensor measurement range (i.e., 10%FS below the lower limit or 10%FS above the upper limit).

Broken or incorrect input wiring

Defective input sensor Defective Unit SW203-4 is OFF (Loop

2 enabled) but no sensor connected to Loop 2

Abnormality in cold junction compensating circuit.

Cause Remedy

Check the sensor wiring. Replace the sensor. Replace the Unit. Correctly set switch

SW203-4.

Replace the Unit.

CT Input Overflow

Loop 1 sensor error Wd. n+8, bit 14 = 1; Wd. n+9, bit 14 = 0 Loop 2 sensor error Wd. n+8, bit 14 = 0; Wd. n+9, bit 14 = 1 Cold junction

compensating circuit error

Display Error name Cause Remedy

ct ffff

The information is displayed as heater current monitor data. It cannot be checked while other parameter data is being displayed. The display returns to normal after the cause of the error is removed.

The following bits are set when a CT overflow error occurs.

Wd (n+8), bit 13 = 1 Loop 1 CT overflow Wd (n+9), bit 13 = 1 Loop 2 CT overflow

CT input overflow The detected heater

Wd. n+8, bit 14 = 1; Wd. n+9, bit 14 = 1

Check the CT and

current exceeds 55.0 A.

heater wiring.

Page 57

Error Detection Section 5

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Heater Burnout Alarm

Display Error name Cause Remedy

HB indicator lit

Error displayed when an abnormality occurs in the loop currently being displayed.

The following bits are set when a heater burnout alarm occurs.

Wd (n+8), bit 02 = 1 Loop 1 heater burnout alarm Wd (n+9), bit 02 = 1 Loop 2 heater burnout alarm

Use one of the methods below to reset a heater burnout alarm.

a) Turn the Special I/O Unit restart flag (AR0100 to AR0109) ON and then

b) Turn the C200H power supply OFF then back ON. c) Set the heater burnout current limit to 00 then back to its original value.

Temperature Alarm

Display Error name Cause Remedy

ALM1 indicator lit

––– Temperature alarm 2 The temperature is in

Heater burnout The detected heater

current is below the heater burnout current value.

back OFF.

Temperature alarm 1 The temperature is in

the alarm range set with Alarm 1 SV.

the alarm range set with Alarm 2 SV.

Check the heater and heater wiring. Replace heater if necessary.

Check the controlled conditions

“ALM1” displays the temperature alarm 1 for the loop current selected. No indicator is provided to show an ALM2 alarm.

The bits shown in the table below are set to 1 when a temperature alarm occurs.

Wd (n+8) Bit 01 =1 Temperature alarm 1 Loop 1

Bit 00 =1 Temperature alarm 2

Wd (n+9) Bit 01 =1 Temperature alarm 1 Loop 2

Bit 00 =1 Temperature alarm 2

EEPROM Error

Display Error

name

e111

The RUN indicator turns off when an EEPROM error occurs.

Duplicate I/O Unit The Unit number duplicates the number of another Special I/O Unit. The SR bit

25415 turns ON when an Duplicate I/O Unit error occurs. Refer to AR0000 to AR0011 for the duplicated Unit number. The C200H PC will not operate during a duplicate I/O error.

Set the Unit number to a separate number.

EEPROM error

Output status after error Cause Remedy

Control output: The transistor output or voltage output is OFF or the current output is less than 2 mA.

Alarm output is OFF.

Defective EEPROM

Replace the Unit

Special I/O Unit Error I/O refresh not operating correctly between the CPU Unit and Temperature Con-

trol Unit. The Heat/Cool Temperature Control Unit is operating based on the con-

Page 58

Error Detection Section 5

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tents of the previous refresh. Refer to AR0000 to AR0015 for the Unit number where the error occurred. After correcting the cause of the error , set the Special I/O Unit Restart Flag (AR0100 to AR0109) to restart operation.

RUN Indicator Unlit The C200H power supply is turned on but the RUN indicator is not lit. None of the

errors described previously are detected. Replace the Unit.

No Data Setting Console Display

• No 24 VDC power supply is connected to the Heat/Cool Temperature Control Unit input terminals A8 and A9.

• The connecting cable is disconnected.

• The connecting cable is broken.

• A circuit in the Data Setting Console is defective.

• A circuit in the Heat/Cool Temperature Control Unit is defective.

After determining the cause of the error , correct the problem or replace the Unit.

Page 59

General Specifications

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Conforms to the C200H PC specifications.

Appendix A

Specifications

Item

Connectable temperature sensor (see note 1)

Current Transformer detection current

No. of input points (loops) Two points (two loops, each of which consists of a temperature sensor and a CT) Temperature control mode PID, ON/OFF (selectable with a switch on the rear panel)

Setting/designation accuracy (See notes 2 and 3.)

Hysteresis 0.0 to 999.9°C/°F (in units of 0.1 °C/°F) (during ON/OFF control action) Proportional band 0.0 to 999.9°C/°F (in units of 0.1 °C/°F) Integral (reset) time 0 to 9999 s (in units of 1 s) Derivative (rate) time 0 to 9999 s (in units of 1 s) Control period 1 to 99 s (in units of 1 s) Sampling period 500 ms Output refresh period 500 ms Display refresh period 500 ms Input shift range –99.9 to 999.9°C/°F (in units of 0.1 °C/°F) Alarm output setting range –999 to 9,999°C/°F (in units of 1 °C/°F) –99.9 to 999.9°C/°F (in units of 0.1 °C/°F) No. of banks 8 banks Internal current consumption 5 VDC, 0.33 A max. External supply voltage 24 VDC Dimensions (see note 4) 34.5 mm (W) x 130 mm (H) x 120.5 mm (D) Weight 360 g

Thermocouple (R, S, K, J, T, E, B, N, L, U) Platinum resistance thermometer (JPt100,

0.1 to 49.9 A (with a heater burnout detecting current difference of 2.5 A min.) Indication accuracy: ±5% FS ±1 digit max.

(advanced PID control with auto-tuning) ±0.5% of set (designated) value or ±2°C

(whichever is larger) ±1 digit max.

C200H-TV00 C200H-TV10

Pt100)

±0.5% of set (designated) value or ±1°C (whichever is larger) ±1 digit max.

+10%

, 0.2 A min.

–15%

Note 1. Set with the switch on the rear panel. See

measurable temperature range.

2. The set value and designated value coincide with each other.

3. The indication accuracy of thermocouples R and S at a temperature of 200°C max., that of thermocouples K and T at a temperature of –100°C max, and that of thermocouple U are all ±4°C, ±1 digit max. The indication accuracy of thermocouple B at a temperature of 400°C or below is not guaranteed.

4. See

Appendix D Dimensions

Appendix B Sensor Temperature Measurement Range

for the

Page 60

Output Characteristics

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Transistor Output (Pulse) C200H-TV01

Appendix ASpecifications

External supply voltage 24 VDC Max. load voltage 24 VDC ( collector supplied voltage) max. Max. load current 100 mA max. Residual voltage when ON 3 V max. Leakage current when OFF 0.3 mA max.

Voltage Output (Pulse) C200H-TV02

Output voltage 12 VDC Max. load current 40 mA (with short-protective circuit)

Current Output (Linear) C200H-TV03

Output current 4 to 20 mA Permissible load impedance 600 Ω max. Current value accuracy 4±0.3 to 20±1 mA

+10%

–15%

Page 61

Appendix B

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Sensor Temperature Measurement Ranges

C200H-TV00 Thermocouple

Set the thermocouple type with the switch on the rear panel. This switch is factory-set to 2 (K). The Data Setting Console can display the range from 10%FS below the lower limit to 10%FS above the upper limit.

Input R

Range °C 0 to 1,700 0 to 1,700 –200 to

Switch setting

Platinum

vs. platinum rhodium

13%

°F 0 to 3,000 0 to 3,000 –300 to

0 1 2 3/8 4/9 5 6 7

Platinum

vs.

platinum

rhodium

10%

K (CA)

Chromel vs.

alumel

1,300

2,300

J/L (IC)

Iron vs.

constantan

–100 to 850

–100 to 1,500

T/U (CC)

Copper vs.

constantan

–200 to 400

–300 to 700

E (CRC)

Chromel vs.

constantan

0 to 600 100 to

0 to 1,100 300 to

Platinum

rhodium

30% vs.

platinum

rhodium 6%

1,800

3,200

Nichrosil

vs. nisil

0 to 1,300

0 to 2,300

C200H-TV10 Platinum Resistance Thermometer

OFF

Set the platinum resistance thermometer type with the switch on the rear panel. This switch is factory-set to OFF (JPt100). The Data Setting Console can display the range from 10%FS below the lower limit to 10%FS above the upper limit.

Input JPt100 Pt100

Range °C –99.9 to 450.0 –99.9 to 450.0

°F –99.9 to 800.0 –99.9 to 800.0

Switch setting

OFF ON

Page 62

Appendix C

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Heater Burnout Detection

Heater Burnout Detection System

The heater wiring is connected through the Current Transformer (CT). As a current flows through the heater wiring, an alternating current is induced in the CT which is dependent on the size of the current flowing. This induced current drops to zero if the heater burns out. The heater burnout alarm signal is output when the induced current is compared to the set current value.

Heater Burnout Alarm Precautions

• Turn on the heater power supply and the input terminal 24-VDC power supply at the same time as or before the C200H PC power supply. The heater burnout signal is output if the heater power supply or the input terminal 24-VDC power supply is turned on after the C200H PC power supply.

• Temperature Control Unit operation continues if a burned-out heater causes a heater burnout alarm. Control signal output continues according to the control parameters. Take measures to detect the heater burnout alarm signal to allow early repair.

• The heater burnout alarm is output when the control output is ON. Once the heater burnout alarm is output, it remains ON. Use one of the methods below to reset a heater burnout alarm.

1. Turn the Special I/O Unit Restart Flag (AR0100 to AR0109) ON and then back OFF.

2. Turn the C200H PC power supply OFF then back ON.

3. Set the heater burnout current limit to 0.0 then back to its original value.

• Make sure that the current difference between normal operation and heater burnout is at least 2.5 A. Stable detection is difficult with a current difference less than 2.5 A.

• Heater burnout detection is not possible with the current output type (C200HTV03) or with 3-phase heaters.

• Set the heater burnout current to 0.0 when heater burnout detection is not required because the CT input wiring is not detected.

Determining the Heater Burnout Detection Current

• Determine the SV from the following equation:

SV =

• If more than one heater is connected through the CT, take the heater burnout current as the value when the heater with the smallest current consumption is burned out. If all heaters consume equal current, take the heater burnout current as the value when any one heater is burned out.

• Make sure that the current difference between normal operation and heater burnout is at least 2.5 A. Stable detection is difficult with a current difference less than 2.5 A.

• Set the SV in the range between 0.1 A and 49.9 A. Heater burnout detection is not carried out if the SV is set to 0.0 A or 50.0 A. The alarm signal is always OFF if the SV is set to 0.0 or always ON if the SV is set to 50.0.

• The total heater current during normal operation should not exceed 50 A. If the current exceeds 55.0 A, a CT Input Overflow error occurs and ffff is displayed if the heater current monitor is selected.

Normal current value + heater burnout current

Page 63

Measure each current with the heater current monitor . In some cases the calcu-

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lated current may differ from the actual measured value.

Sample SV Calculations

Example 1 Using one 200 VAC, 1 kW heater

Normal current = = 5 A

Burnout current = 0 A

1000

200

Appendix CHeater Burnout Detection

SV = = 2.5 A (≤ 49.9 A)

Example 2 Using three 200 VAC, 1 kW heaters

Normal current = x 3 = 15 A

Burnout current with one heater burned out = x 2 = 10 A

SV = = 12.5 A (≤ 49.9 A)

Difference between normal and burnout current = 15 – 10 = 5 A (≥ 2.5 A)

5 + 0

1000

200

1000

200

15 + 10

Specifications

Heater Burnout Detection Characteristics

Heater burnout detection setting range 0.1 to 49.9 A (in units of 0.1 A) (see note 1) Current difference required for heater

burnout detection Heater current monitor range 0.0 to 55.0 A Monitor accuracy of input current +5% of FS +1 digit max. Min. detectable ON time 200 ms (see note 2)

Note 1. If the heater burnout detection setting value is set to 0.0 or 50.0 A, no heater burnout detection is pos-

sible. The alarm signal is turned OFF if the heater burnout detection setting value is set to 0.0 A and turned ON if it is set to 50.0 A.

2. If the heating control output is turned ON for less than 200 ms, no heater burnout detection or heater current measurement is possible.

2.5 A min. (normal time – burnout time)

E54-CT1/CT3 Current Transformer

Max. continuous heater current 50 A Dielectric strength 1,000 VAC (1 min) Vibration resistance 50 Hz (approx. 10G) Weight E54-CT1: approx. 11.5 g; E54-CT3: approx. 50 g Accessories (E54-CT3 only) Contact: 2; Plug: 2

Page 64

Current Transformer Dimensions

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Appendix CHeater Burnout Detection

E54-CT1

E54-CT3

7.5

10.5

5.8 dia.

30 40

12 dia.

2.8

Two 3.5-dia. holes

2.36 dia.

Two M3 holes with a depth of 4 mm

Page 65

Current Transformer Circuit Diagram

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Control output

Heater

To Temperature Control Unit CT input terminal

To Temperature Control Unit CT input terminal (no polarity)

Appendix CHeater Burnout Detection

AC power supply

Heater cable

Current Transformer

Page 66

Appendix D

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Dimensions

Heat/Cool Temperature Control Unit

Unit Dimensions

130

Mounting Dimensions

Data Setting Console

Unit Dimensions

34.5

Approx. 200

100.5

120.5

131.5

Base unit

Weight: 360 g

45 57

Weight: 120 g

Page 67

Mounting Dimensions

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Panel Cutout Clearance

Appendix DDimensions

+0.8

+0.6 0

Panel thickness 1 to 4 mm

Clearance of at least 150 mm

Allow a clearance of at least 150 mm behind the Data Setting Console when it is installed in the panel to allow cable connectors to be inserted. A clearance of 50 mm is sufficient if the rear panel can be opened.

Page 68

Appendix E

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Parameters and Key Operations

The Data Setting Console key operations and their relation to parameters are shown in the following table.

Power on

Display Level 0 Display Level 1

LVL LVL LVL

PV SP

Bank number

al-1

Alarm 1 SV

al-2

Alarm 2 SV

in-s

Input shift value

Proportional band

sl-l

SP lower limit

sl-h

SP upper limit

c-db

Dead band

c-sc

Cooling coefficient

Heating control period

c-cp

Cooling control period

Display Level 2

h-o

Heating output monitor

c-o

Cooling output monitor

Auto-tuning start/stop

bcpy

Copy bank

in-t

Input-type monitor

alt1

Alarm 1 mode

Integral time

Derivative time

hys

Hysteresis

hysa

Alarm hysteresis

Heater current monitor

Heater burnout current

alt2

Alarm 2 mode

Page 69

Index

MROELECTRIC.COM

AB

advanced PID control, 2 alarm hysteresis setting, 30 alarm mode setting. See settings alarm SV 1 setting, 27 alarm SV 2 setting, 27 allocating memory, 36 auto-tuning start/stop setting, 31

Revision History

MROELECTRIC.COM

C200H-TV

Heat/Cool

Temperature Control Unit

Operation Manual

A manual revision code appears as a suffix to the catalog number on the front cover of the manual.

Cat. No. W240-E3-1

Revision

code

The following table outlines the changes made to the manual during each revision.

Revision code Date Revised content

W240-E1-1 November 1993 Original production W240-E3-1 February 1998 Page 15: Table added to Secton 2–3

Page 42: Write/Read data range correcton in Heating and Cooling Control Period rows in the Table of Commands.

Omron C200H-TV, C200H-TV001, C200H-TV101, C200H-TV002, C200H-TV102 Operation Manual

Specifications and Main Features

Frequently Asked Questions

User Manual

TABLE OF CONTENTS

System Configuration and Features

Connections and Settings

Data Setting Console Operation

PC Memory Allocation and Programming

Troubleshooting

Index

Revision History