OPERATION MANUAL Temperature Control Units SYSMAC C200H-TC

OPERATION MANUAL Temperature Control Units SYSMAC C200H-TC
Cat. No. W225-E1-05
SYSMAC
[email protected]@@
Temperature Control Units
OPERATION MANUAL
[email protected]@@
Temperature Control Units
Operation Manual
Revised December 2005
iv
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 heed precautions can result in injury to people or damage to property.
!DANGER
Indicates an imminently hazardous situation which, if not avoided, will result in death or
serious injury. Additionally, there may be severe property damage.
!WARNING
Indicates a potentially hazardous situation which, if not avoided, could result in death or
serious injury. Additionally, there may be severe property damage.
!Caution
Indicates a potentially hazardous situation which, if not avoided, may result in minor or
moderate injury, or property damage.
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.
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.
 OMRON, 1993
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.
v
vi
TABLE OF CONTENTS
PRECAUTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1
Intended Audience . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xv
xvi
2
General Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xvi
3
Safety Precautions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xvi
4
Operating Environment Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xvii
5
Application Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xviii
SECTION 1
System Configuration and Features . . . . . . . . . . . . . . . .
1
1-1
Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2
1-2
Basic System Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3
SECTION 2
Connections and Settings . . . . . . . . . . . . . . . . . . . . . . . . .
7
2-1
Nomenclature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8
2-2
Switch Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9
2-3
Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
13
SECTION 3
Data Setting Console Operation . . . . . . . . . . . . . . . . . . .
21
3-1
Operating Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22
3-2
Data Flow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
23
3-3
Nomenclature and Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
24
3-4
Parameter Displays and Settings. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26
SECTION 4
PC Memory Allocation and Programming. . . . . . . . . . .
35
4-1
Memory Allocation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
36
4-2
Data Flow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
44
4-3
Programming. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
44
SECTION 5
Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5-1
Error Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
61
62
Appendices
A
Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
65
B
Sensor Temperature Measurement Ranges . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
67
C
Heater Burnout Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
69
D
Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
73
Index. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
75
Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
77
vii
About this Manual:
This manual describes the installation and operation of the [email protected]@@ Temperature Control Units
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 a Temperature Control Unit or Data Setting Console.
Section 1 provides Temperature Control Unit features and describes its basic system configuration.
Section 2 provides information on the connections and settings of the Temperature Control Units.
Section 3 provides the basic operating procedures of the Data Setting Console including parameter
settings and displays.
Section 4 provides the C200H PC’s memory allocation for the Temperature Control Units. Basic programming procedures and examples are also provided.
Section 5 provides possible errors and error remedies.
The four Appendices provide references dealing with specifications, sensor temperature measurement ranges, heater burnout detection, and dimensions.
!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.
ix
Read and Understand this Manual
Please read and understand this manual before using the product. Please consult your OMRON
representative if you have any questions or comments.
Warranty and Limitations of Liability
WARRANTY
OMRON's exclusive warranty is that the products are free from defects in materials and workmanship for a
period of one year (or other period if specified) from date of sale by OMRON.
OMRON MAKES NO WARRANTY OR REPRESENTATION, EXPRESS OR IMPLIED, REGARDING NONINFRINGEMENT, MERCHANTABILITY, OR FITNESS FOR PARTICULAR PURPOSE OF THE
PRODUCTS. ANY BUYER OR USER ACKNOWLEDGES THAT THE BUYER OR USER ALONE HAS
DETERMINED THAT THE PRODUCTS WILL SUITABLY MEET THE REQUIREMENTS OF THEIR
INTENDED USE. OMRON DISCLAIMS ALL OTHER WARRANTIES, EXPRESS OR IMPLIED.
LIMITATIONS OF LIABILITY
OMRON SHALL NOT BE RESPONSIBLE FOR SPECIAL, INDIRECT, OR CONSEQUENTIAL DAMAGES,
LOSS OF PROFITS OR COMMERCIAL LOSS IN ANY WAY CONNECTED WITH THE PRODUCTS,
WHETHER SUCH CLAIM IS BASED ON CONTRACT, WARRANTY, NEGLIGENCE, OR STRICT
LIABILITY.
In no event shall the responsibility of OMRON for any act exceed the individual price of the product on which
liability is asserted.
IN NO EVENT SHALL OMRON BE RESPONSIBLE FOR WARRANTY, REPAIR, OR OTHER CLAIMS
REGARDING THE PRODUCTS UNLESS OMRON'S ANALYSIS CONFIRMS THAT THE PRODUCTS
WERE PROPERLY HANDLED, STORED, INSTALLED, AND MAINTAINED AND NOT SUBJECT TO
CONTAMINATION, ABUSE, MISUSE, OR INAPPROPRIATE MODIFICATION OR REPAIR.
xi
Application Considerations
SUITABILITY FOR USE
OMRON shall not be responsible for conformity with any standards, codes, or regulations that apply to the
combination of products in the customer's application or use of the products.
At the customer's request, OMRON will provide applicable third party certification documents identifying
ratings and limitations of use that apply to the products. This information by itself is not sufficient for a
complete determination of the suitability of the products in combination with the end product, machine,
system, or other application or use.
The following are some examples of applications for which particular attention must be given. This is not
intended to be an exhaustive list of all possible uses of the products, nor is it intended to imply that the uses
listed may be suitable for the products:
• Outdoor use, uses involving potential chemical contamination or electrical interference, or conditions or
uses not described in this manual.
• Nuclear energy control systems, combustion systems, railroad systems, aviation systems, medical
equipment, amusement machines, vehicles, safety equipment, and installations subject to separate
industry or government regulations.
• Systems, machines, and equipment that could present a risk to life or property.
Please know and observe all prohibitions of use applicable to the products.
NEVER USE THE PRODUCTS FOR AN APPLICATION INVOLVING SERIOUS RISK TO LIFE OR
PROPERTY WITHOUT ENSURING THAT THE SYSTEM AS A WHOLE HAS BEEN DESIGNED TO
ADDRESS THE RISKS, AND THAT THE OMRON PRODUCTS ARE PROPERLY RATED AND
INSTALLED FOR THE INTENDED USE WITHIN THE OVERALL EQUIPMENT OR SYSTEM.
PROGRAMMABLE PRODUCTS
OMRON shall not be responsible for the user's programming of a programmable product, or any
consequence thereof.
xii
Disclaimers
CHANGE IN SPECIFICATIONS
Product specifications and accessories may be changed at any time based on improvements and other
reasons.
It is our practice to change model numbers when published ratings or features are changed, or when
significant construction changes are made. However, some specifications of the products may be changed
without any notice. When in doubt, special model numbers may be assigned to fix or establish key
specifications for your application on your request. Please consult with your OMRON representative at any
time to confirm actual specifications of purchased products.
DIMENSIONS AND WEIGHTS
Dimensions and weights are nominal and are not to be used for manufacturing purposes, even when
tolerances are shown.
PERFORMANCE DATA
Performance data given in this manual is provided as a guide for the user in determining suitability and does
not constitute a warranty. It may represent the result of OMRON's test conditions, and the users must
correlate it to actual application requirements. Actual performance is subject to the OMRON Warranty and
Limitations of Liability.
ERRORS AND OMISSIONS
The information in this manual has been carefully checked and is believed to be accurate; however, no
responsibility is assumed for clerical, typographical, or proofreading errors, or omissions.
xiii
xiv
PRECAUTIONS
This section provides general precautions for using C200H Temperature Control Units and related devices.
The information contained in this section is important for the safe and reliable application of the C200H
Temperature Control Units. You must read this section and understand the information contained before
attempting to set up or operate a C200H Temperature Control Unit.
1
2
3
4
5
Intended Audience . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
General Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Safety Precautions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Operating Environment Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Application Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xvi
xvi
xvi
xvii
xviii
xv
1
Intended Audience
1
Intended Audience
This manual is intended for the following personnel, who must also have
knowledge of electrical systems (an electrical engineer or the equivalent).
• Personnel in charge of installing FA systems.
• Personnel in charge of designing FA systems.
• Personnel in charge of managing FA systems and facilities.
2
General Precautions
The user must operate the product according to the performance specifications described in the relevant manuals.
Before using the product under conditions which are not described in the
manual or applying the product to nuclear control systems, railroad systems,
aviation systems, vehicles, combustion systems, medical equipment, amusement machines, safety equipment, and other systems, machines, and equipment that may have a serious influence on lives and property if used
improperly, consult your OMRON representative.
Make sure that the ratings and performance characteristics of the product are
sufficient for the systems, machines, and equipment, and be sure to provide
the systems, machines, and equipment with double safety mechanisms.
This manual provides information for programming and operating the Unit. Be
sure to read this manual before attempting to use the Unit and keep this manual close at hand for reference during operation.
!WARNING It is extremely important that a PC and all PC Units be used for the specified
purpose and under the specified conditions, especially in applications that can
directly or indirectly affect human life. You must consult with your OMRON
representative before applying a PC system to the above-mentioned applications.
3
Safety Precautions
!WARNING Do not attempt to take any Unit apart while the power is being supplied. Doing
so may result in electric shock.
!WARNING Do not touch any of the terminals or terminal blocks while the power is being
supplied. Doing so may result in electric shock.
!WARNING Do not attempt to disassemble, repair, or modify any Units. Any attempt to do
so may result in malfunction, fire, or electric shock.
!WARNING Provide safety measures in external circuits (i.e., not in the Programmable
Controller), including the following items, to ensure safety in the system if an
abnormality occurs due to malfunction of the PC or another external factor
affecting the PC operation. Not doing so may result in serious accidents.
• Emergency stop circuits, interlock circuits, limit circuits, and similar safety
measures must be provided in external control circuits.
• The PC will turn OFF all outputs when its self-diagnosis function detects
any error or when a severe failure alarm (FALS) instruction is executed.
xvi
Operating Environment Precautions
4
As a countermeasure for such errors, external safety measures must be
provided to ensure safety in the system.
• The PC outputs may remain ON or OFF due to deposits on or burning of
the output relays, or destruction of the output transistors. As a countermeasure for such problems, external safety measures must be provided
to ensure safety in the system.
• When the 24-V DC output (service power supply to the PC) is overloaded
or short-circuited, the voltage may drop and result in the outputs being
turned OFF. As a countermeasure for such problems, external safety
measures must be provided to ensure safety in the system.
!WARNING Provide double safety mechanisms to handle incorrect signals that can be
generated by broken signal lines or momentary power interruptions. Faulty
operation may result in serious accidents.
!Caution The Heating and Cooling Temperature Control Unit will not operate normally if
the cycle time of the CPU Unit is less than 8 ms.
• If the cycle time is less than 8 ms (e.g., the program execution time is
short), increase it to at least 8 ms.
• For the C200H, C200HS, or C200HX/HG/HE(-Z), use the SCAN instruction to set a minimum cycle time.
• For a CS-series PC, set the cycle time in the PC Setup (Programming
Console address 208, bits 00 to 15).
• If the IORF instruction is used for a Heating and Cooling Temperature
Control Unit, allow at least 8 ms between IORF executions.
!Caution The write life for the EEPROM built into the Heating and Cooling Temperature
Control Unit is 100,000 operations. Bit corruption will occur if the memory is
written more than 100,000 times. Do not use a Unit in which memory has
been written more than 100,000 times.
4
Operating Environment Precautions
!Caution Do not operate the control system in the following locations:
• Locations subject to direct sunlight.
• Locations subject to temperatures or humidity outside the range specified
in the specifications.
• Locations subject to condensation as the result of severe changes in temperature.
• Locations subject to corrosive or flammable gases.
• Locations subject to dust (especially iron dust) or salts.
• Locations subject to exposure to water, oil, or chemicals.
• Locations subject to shock or vibration.
!Caution Take appropriate and sufficient countermeasures when installing systems in
the following locations:
• Locations subject to static electricity or other forms of noise.
xvii
5
Application Precautions
• Locations subject to strong electromagnetic fields.
• Locations subject to possible exposure to radioactivity.
• Locations close to power supplies.
!Caution The operating environment of the PC system can have a large effect on the
longevity and reliability of the system. Improper operating environments can
lead to malfunction, failure, and other unforeseeable problems with the PC
system. Be sure that the operating environment is within the specified conditions at installation and remains within the specified conditions during the life
of the system.
5
Application Precautions
Observe the following precautions when using the PC system.
!WARNING Always heed these precautions. Failure to abide by the following precautions
could lead to serious or possibly fatal injury.
• Always ground the system to 100 Ω or less when installing the Units. Not
connecting to a ground of 100 Ω or less may result in electric shock.
• Always turn OFF the power supply to the PC before attempting any of the
following. Not turning OFF the power supply may result in malfunction or
electric shock.
• Mounting or dismounting I/O Units, CPU Units, Memory Units, Power
Supply Units, or any other Units.
• Assembling the Units.
• Setting DIP switches or rotary switches.
• Connecting cables or wiring the system.
• Connecting or disconnecting the connectors.
!Caution Failure to abide by the following precautions could lead to faulty operation of
the PC or the system, or could damage the PC or PC Units. Always heed
these precautions.
• Fail-safe measures must be taken by the customer to ensure safety in the
event of incorrect, missing, or abnormal signals caused by broken signal
lines, momentary power interruptions, or other causes.
• Always use the power supply voltages specified in this manual. An incorrect voltage may result in malfunction or burning.
• Take appropriate measures to ensure that the specified power with the
rated voltage and frequency is supplied. Be particularly careful in places
where the power supply is unstable. An incorrect power supply may result
in malfunction.
• Install external breakers and take other safety measures against short-circuiting in external wiring. Insufficient safety measures against short-circuiting may result in burning.
• Install Units as far as possible away from devices that generate strong,
high-frequency noise.
• Do not drop a Unit or subject it to excessive shock or vibration.
• Do not apply voltages to the Input Units in excess of the rated input voltage. Excess voltages may result in burning.
xviii
5
Application Precautions
• Do not apply voltages or connect loads to the Output Units in excess of
the maximum switching capacity. Excess voltage or loads may result in
burning.
• Disconnect the LG and GR terminal on the Power Supply Unit when performing withstand voltage tests or insulation resistance tests. Not disconnecting the functional ground terminal may result in burning.
• Be sure that all the mounting screws, terminal screws, and cable connector screws are tightened to the torque specified in this manual. Incorrect
tightening torque may result in malfunction.
• Leave the label attached to the Unit when wiring. Removing the label may
result in malfunction if foreign matter enters the Unit.
• Remove the label after the completion of wiring to ensure proper heat dissipation. Leaving the label attached may result in malfunction.
• Double-check all wiring and switch settings before turning ON the power
supply. Incorrect wiring may result in burning.
• Wire correctly. Incorrect wiring may result in burning.
• Mount Units only after checking terminal blocks and connectors completely.
• Be sure that the terminal blocks, Memory Units, expansion cables, and
other items with locking devices are properly locked into place. Improper
locking may result in malfunction.
• Check the user program for proper execution before actually running it on
the Unit. Not checking the program may result in an unexpected operation.
• Confirm that no adverse effect will occur in the system before attempting
any of the following. Not doing so may result in an unexpected operation.
• Changing the operating mode of the PC (including changing the Startup Mode).
• Force-setting/force-resetting any bit in memory.
• Changing the present value of any word or any set value in memory.
• Resume operation only after transferring to the new CPU Unit the contents of the DM Area, HR Area, and other data required for resuming
operation. Not doing so may result in an unexpected operation.
• Do not pull on the cables or bend the cables beyond their natural limit.
Doing either of these may break the cables.
• Do not place objects on top of the cables or other wiring lines. Doing so
may break the cables.
• Use crimp terminals for wiring. Do not connect bare stranded wires
directly to terminals. Connection of bare stranded wires may result in
burning.
• When replacing parts, be sure to confirm that the rating of a new part is
correct. Not doing so may result in malfunction or burning.
• Before touching a Unit, be sure to first touch a grounded metallic object in
order to discharge any static built-up. Not doing so may result in malfunction or damage.
xix
Application Precautions
xx
5
SECTION 1
System Configuration and Features
This section describes Temperature Control Unit features and describes its basic system configuration.
1-1
Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2
1-2
Basic System Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3
1
Section 1-1
Features
1-1
Features
The 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 a preset control mode.
PID with Feed-forward Circuitry (Feed-forward PID)
Stable temperature control is achieved using PID control with feed-forward circuitry and an auto-tuning feature.
ON/OFF control can also be selected.
Two Temperature Control Loops with a Single Unit
Two versions of Temperature Control Unit are available: the [email protected] for
thermocouple use and the [email protected] for platinum resistance thermometers, each offering two control loops.
Comprehensive Output Specifications
Three types of output specification versions are available: [email protected]@1 for
transistor output, [email protected]@2 for voltage output, and [email protected]@3 for
current output.
Heater Burnout Detection
Through a Current Transformer, heater burnout can be quickly detected with a
minimum current difference of 0.5 A and a heater burnout detection setting
range of 0.1 to 4.9 A, and allows for the rapid correction of problems. Heater
burnout detection is possible for each of the two control loops.
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 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
The 21 commands are used to read and set data with the C200H user programs.
2
Section 1-2
Basic System Configuration
1-2
Basic System Configuration
C200H/C200HS, C200HX/HG/HE, or CS-series PC
Temperature Control Unit:
[email protected] (for thermocouples)
[email protected] (for platinum resistance thermometers)
RUN
Connecting cables:
C200H-CN225 (2 m)
C200H-CN425 (4 m)
Data Setting Console
C200H-DSC01
Recommended cable:
[email protected]@@
(1/2 m)
24 VDC
Loop 1
Loop 2
Temperature
sensor
Temperature
sensor
Relay box
Electric
furnace
Electric
furnace
Heater
Heater
Current
Transformer
(CT)
Remote I/O Terminal or
Connector Terminal
Block Converter Unit
Current
Transformer
(CT)
Solenoid switch
3
Section 1-2
Basic System Configuration
Temperature Control Unit Models
Sensor
Thermocouple
Platinum resistance
thermometer
Output type
Transistor output
Voltage output
C200H-TC001
C200H-TC002
Current output
C200H-TC003
C200H-TC101
C200H-TC103
C200H-TC102
Applicable CPU Units
PC Series
CPU Unit
Mounting
restrictions
CS Series
[email protected]@-E
[email protected]@-E
None
C200HX/HG/HE
C200HE-CPU11/32/42-E/ZE
C200HG-CPU33/43-E/ZE
C200HX-CPU34/44-E/ZE
None
C200HG-CPU53/63-E/ZE
C200HX-CPU54/64-E/ZE
C200HX-CPU65-ZE/85-ZE
None
C200HS
C200HS-CPU01-E/01-EC/21-E/21-EC/31-E/03-E/
23-E/33-E
None
C200H
C200H-CPU01-E/03-E/11-E/21-E/22-E/23-E/31-E
Cannot be
mounted to the
two rightmost slots
on the CPU Rack.
Number of Units
The 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 the CPU Rack, Expansion I/O Rack, and Slave Rack.
Note
1. Refer to the manual for your CPU Unit for information on which Units belong to the Special I/O Unit group.
2. The Units used are limited by the maximum supply current and current
consumption. Refer to the manual for your CPU Unit for specific information.
3. The number of Units used with a Slave Rack is limited by data transmission
considerations, as described below.
Number of Units
Mountable on Slave Rack
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.
A
B
High-speed Counter Units
Position Control Units
(NC111/112)
ASCII Unit
Analog I/O Units
ID Sensor Units
Fuzzy Logic Unit
4 units max.
C
Position Control Unit
(NC211)
8 units max.
2 units max.
Note
6 units max.
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
4
D
High-density and Mixed I/O Temperature Sensor Units
Units
Voice Unit
Temperature Control Units
Heat/Cool Temperature Control Units
PID Control Units
Cam Positioner Unit
Section 1-2
Basic System Configuration
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.
Precautions
The IR area of the C200H Special I/O Unit is allocated according to the setting
of the unit number switch on the front panel, not the address of the slot where
the unit is mounted. Refer to 4-1 Memory Allocation for the allocation of the
memory 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 C500, C1000H, or C2000H, it is not possible to use a
Special I/O Unit with the C200H Slave Rack.
!WARNING Always turn the PC 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.
New Functions
Units with the following lot number or later support the following new functions.
01
Z 4 0
Year (1994): Last digit of the Christian year
Month (December): (9: September, X: October,
Y: November, X: December)
Day (1st)
Descriptions of New Functions
RUN/STOP Bits
Stop Bits have been added. These bits are supported with either fixed or normal memory allocations.
Word (n+2), bit 06
Loop 1 Stop Bit
Word (n+2), bit 04
Loop 2 Stop Bit
Turn OFF to perform temperature
control for the loop. Turn ON to
stop control.
Note These bits cannot be used when SW203-5 is set to ON to stop control in
PROGRAM mode. When SW203-5 is ON, control is always stopped.
Unit status will be as shown in the following table depending on the combination of SW203-5 settings and operating mode of the CPU Unit.
SW203-5 setting
Operating mode of CPU
Unit
Stop Bits
OFF (Run)
ON (Stop)
OFF (control continues)
RUN or
PROGRAM
MONITOR
RUN
RUN
ON (control stops)
RUN or
PROGRAM
MONITOR
RUN
STOP
STOP
STOP
STOP
STOP
• To run or stop the temperature control using the Stop Bits, set SW203-5 to
OFF.
• To run or stop the temperature control only through the operating mode of
the CPU Unit, keep the Stop Bit OFF (RUN).
5
Section 1-2
Basic System Configuration
RUN/STOP Monitor Flags
Stop Flags have been added. These flags are supported with either fixed or
normal memory allocations.
Word (n+8), bit 08
Loop 1 Stop Flag
Word (n+9), bit 08
Loop 2 Stop Flag
When OFF, temperature control is being performed for the
loop. When ON, control is not
being performed.
These Flags turn ON and OFF depending on whether temperature control is
run or stopped. Therefore, they do not necessarily have the same status as
the Stop Bits described above.
RAM Write Commands
Previously, commands could be used to read and write to the EEPROM only.
These new commands allow writing to RAM.
When various settings require frequent rewriting, write to RAM, verify the setting values, and then save the data by writing it to EEPROM. The data written
to the RAM will be deleted when the power is turned OFF.
The following commands can be used to write to RAM.
Parameter
6
Command
Write
Read
Set point
Execution bank number
4
4
0
2
Yes
Yes
No
No
Alarm SV 1
Alarm SV 2
4
4
3
4
Yes
Yes
No
No
Input shift value
Proportional band
4
4
5
6
Yes
Yes
No
No
Integral (reset) time
Derivative (rate) time
4
4
7
8
Yes
Yes
No
No
SP lower limit
SP upper limit
5
5
0
1
Yes
Yes
No
No
Control period
Hysteresis
5
5
7
8
Yes
Yes
No
No
Alarm hysteresis
Heater burnout current
5
5
9
B
Yes
Yes
No
No
Alarm 1 mode
Alarm 2 mode
6
6
4
5
Yes
Yes
No
No
SECTION 2
Connections and Settings
This section provides information on the connections and settings of the Temperature Control Unit.
2-1
Nomenclature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8
2-2
Switch Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9
2-3
Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
13
2-3-1
Input Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
13
2-3-2
Output Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
16
2-3-3
Data Setting Console Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
19
7
Section 2-1
Nomenclature
2-1
Nomenclature
[email protected] (For Thermocouple)
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
SW202
(sensor type setting)
SW203
(operation and function settings)
Rack connector
Output connector
Sensor input terminal block
Cold junction compensator
8
Section 2-2
Switch Settings
[email protected] (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
SW202
(sensor type setting)
SW203
(operation and function settings)
Rack connector
Output connector
Sensor input terminal block
Indicators
RUN
2-2
Lit when the Temperature Control Unit is operating normally. Unlit when an
alarm occurs, and Unit operation stops.
Switch Settings
The function and setting of switches are identical for all models, except
SW202.
Unit Number
SW1
Unit number setting
4
(3)
2
(1)
(5)
0
(9)
8
6
(7)
The cut-out indicates the selected position. Turn the switch with
a flat-blade screwdriver. Turn the switch until it clicks in position.
Do not leave the switch between two settings.
9
Section 2-2
Switch Settings
The addresses are allocated as shown in the following table according to the
Unit number setting.
0
Unit No. setting
Allocated address
Wd 100 to 109
1
2
Wd 110 to 119
Wd 120 to 129
3
4
Wd 130 to 139
Wd 140 to 149
5
6
Wd 150 to 159
Wd 160 to 169
7
8
Wd 170 to 179
Wd 180 to 189
9
Wd 190 to 199
The switch is factory-set to 0.
Note If the Unit number is set to an existing unit number, an alarm occurs and the
PC does not operate.
Turn the PC power OFF before setting the unit number. If the setting is
changed with the power ON, the new setting will not be valid until the power is
turned OFF and back ON again.
Switching Memory Contents and Setting Direction
SW2
Switching memory contents and setting direction
2
O
F
F
1
Remove the cover and set the switch with the tip of a ballpoint pen or similar
object.
Pin
Pin 1
ON
OFF
Pin 2
Function
ON
Switching memory contents
Normal
Setting direction
CPU Unit
OFF
Fixed
Data Setting Console
The switch is factory-set to OFF: Parameters can be set from the Data Setting
Console only.
The new setting is valid immediately after the switch setting is changed.
10
Section 2-2
Switch Settings
Removing and Attaching the Cover
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
Place the right edge of the
cover against the case and
press into position.
The contents of the allocated memory differ according to the Unit number setting.
Normal
Data can be set as required using commands (Refer to 4-1 Memory Allocation).
Fixed
Fixed data is allocated to memory. Direct reading and writing of
data is possible.
Refer to 4-1 Memory Allocation for details of the memory contents.
Setting Direction
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 reading and setting of 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 switch SW2-2.
Sensor Type
SW202
Sensor type setting
8
7
9 01
2
3
6 5 4
[email protected]
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 flatblade screwdriver.
Selected position
11
Section 2-2
Switch Settings
[email protected]
OFF
ON
Setting
OFF
ON
Sensor type
JPt
Pt
The switch is factory-set to OFF.
See Appendix B Sensor Temperature Measurement Range for the measurable temperature range.
Operation and Function Setting
Operation and Function Setting
1 2 3 4 5 6
SW203
NO
OFF
Pin
6
Function
Not used
ON
OFF
---
ON
---
5
Operation in C200H Continue control
program mode
Interrupt control
4
3
Loop 2
Display units
Enabled
°C
Disabled (not used)
°F
2
1
Control action
Control method
Reverse (heating control)
Feed-forward PID
Normal (cooling control)
ON/OFF control
The switch is factory-set to OFF.
Operation in CPU Unit
Program Mode
Selects if the temperature control is continued or interrupted when the CPU
Unit is set to PROGRAM mode.
Note Units with a lot number of 01Z40 or later are provided with Stop Bits for loops
1 and 2 in bits 06 and 04 of word (n+2). For further information, refer to
page 5.
Loop 2
Selects if input Loop 2 is used or not.
Note
1. 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.
2. Use input Loop 1 when only one loop is used.
It is not possible to use Loop 2 if Loop 1 is not used.
Display Units
12
Selects whether setting and SVs displayed on the Data Setting Console are in
Celsius or Fahrenheit.
Section 2-3
Wiring
Control Action
Reverse:
For heating control with a heater. The heater output is increased when the
measured temperature is below the SP (i.e., a negative temperature difference).
Normal:
For cooling control of overheated objects using cooling water or some other
method. The cooling water output is increased when the measured temperature is above the SP (i.e., a positive temperature difference).
Control Method
2-3
2-3-1
Selects the method of control.
Wiring
Input Wiring
[email protected] Thermocouple
CT: Current Transformer
TC: Thermocouple
Heater wire
A0
CT
A1
Loop 1
A2
TC
A3
A4
CT
A5
Loop 2
Refer to the
table below.
A6
TC
A7
A8
24 VDC
0.2 A
A9
The 24-VDC output from the
C200H CPU or the Power
Supply Units is convenient.
Terminal No.
Terminal name
A0
A1
CT
CT
A2
A3
TC (–)
TC (+)
A4
A5
CT
CT
A6
A7
TC (–)
TC (+)
A8
A9
24 VDC
0V
Loop 1
Loop 2
13
Section 2-3
Wiring
[email protected] Platinum Resistance Thermometer
CT: Current Transformer
Pt: Platinum resistance thermometer
Heater wire
A0
CT
A1
Loop 1
A2
Pt
A3
A4
CT
A5
Loop 2
Refer to the
table below.
A6
Pt
A7
A8
24 VDC
0.2 A
A9
The 24-VDC output from the
C200H CPU or the Power
Supply Units is convenient.
Terminal No.
Terminal name
A0
A1
CT
CT/Pt (B)
A2
A3
Pt (B)
Pt (A)
A4
A5
CT
CT/Pt (B)
A6
A7
Pt (B)
Pt (A)
A8
A9
24 VDC
0V
Loop 1
Loop 2
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. (The power for the transistor output is supplied from the output connector.)
14
Section 2-3
Wiring
6. The terminal block is removable. Make sure that it is attached correctly after the input wiring connections are completed.
Terminal Block
Connections
Tighten the terminal block screws to a torque of 0.8 N • m.
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.
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
Type of thermocouple
Symbol
Previous
symbol
(reference)
10
Connect a thermocouple with the appropriate compensating conductor from
the table below.
Compensating conductor
Symbol
Previous
symbol
(reference)
Classification by
application and
tolerance
Constituent materials
+ conductor
B
R
-----
BX-G
--RX-G, SX-G ---
General-purpose,
standard class
S
---
RX-H, SX-H
---
Heat-resistant, standard class
K
CA
KX-G
KX-GS
WCA-G
WCA-GS
General-purpose,
standard class
KX-H
WCA-H
Heat-resistant, standard class
KX-HS
WCA-HS
WX-G
WCA-G
WX-H
WCA-H
VX-G
WCA-G
Heat-resistant, precision class
General-purpose,
Iron
standard class
Heat-resistant, standard class
General-purpose,
Copper
standard class
EX-G
WCRC-G
General-purpose,
standard class
EX-H
WCRC-H
Heat-resistant, standard class
JX-G
WIC-G
JX-H
WIC-H
General-purpose,
standard class
Heat-resistant, standard class
E
J
CRC
IC
– conductor
Copper
Copper
Alloy with copper or
nickel as major constituent
Alloy with nickel
or chrome as
major constituent
Alloy with nickel as
major constituent
Alloy with copper or
nickel as major constituent
Alloy with nickel
or chrome as
major constituent
Iron
15
Section 2-3
Wiring
Type of thermocouple
Symbol
Previous
symbol
(reference)
T
CC
Compensating conductor
Classification by
application and
Symbol
Previous
tolerance
symbol
(reference)
TX-G
WCC-G
General-purpose,
standard class
TX-GS
--General-purpose,
precision class
Constituent materials
+ conductor
– conductor
Copper
TX-H
WCC-H
Heat-resistant, standard class
TX-HS
---
Heat-resistant, precision class
Alloy with copper or
nickel as major constituent
Wiring Platinum
Resistance Thermometers
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.
Current Transformer
Use an E54-CT1 or E54-CT3 Current Transformer (CT). Refer to Appendix C
Heater Burnout Detection for details of the Current Transformer specifications
and installation dimensions.
2-3-2
Output Wiring
Connection Diagrams
[email protected] Transistor Output
B
OUT1
OUT2
24 VDC
COM
24 VDC
A
NC
NC
10
NC
9
NC
NC
NC
2
2
COM
1
1
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.
[email protected]/[email protected] Voltage/Current Output
OUT1 (+)
OUT2 (+)
16
A
B
NC
NC
10
10
9
9
NC
NC
OUT1 (−)
OUT2 (−)
Section 2-3
Wiring
Circuit Diagrams
[email protected] Transistor Output
Internal circuits
24 VDC
OUT
COM
Internal circuits
[email protected] Voltage Output
OUT (+)
OUT (−)
Internal circuits
[email protected] Current Output
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)
Connector Wiring
Precautions
After soldering the lead to each pin, insulate with heat-shrink tube to prevent
shorting with the adjacent terminal.
Connection Precautions
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.
17
Section 2-3
Wiring
Output Cable
The output cables in the table below are recommended.
Model
ES1000-CA021-102
1m
Cable length (L)
ES1000-CA021-202
2m
32-pin connector
(manufactured by Fujitsu)
FCN-361J032-AU
20-pin connector
(manufactured by OMRON)
L
XG4M-2030
63
30
28
16.1
46
Wiring Diagrams
32-pin connector
B
20-pin connector
A
16 16
10 10
9 9
1 11
2 12
2
1
9 19
10 20
2
1
1
B10
11
A10
2
B9
12
A9
9
B2
19
A2
10
B1
A1
18
Note The pin numbers of the 20-pin connector are marked for convenience.
Refer to them from the ∆ mark.
20
Section 2-3
Wiring
Remote I/O Terminal
Remote I/O Terminal in the table below is recommended for transistor output.
Model
G7TC-OC08
Specification
Relays used
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
OUT1 OUT2
Wiring to the heater
24 VDC
Connector Terminal Block
Converter Unit
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
XW2B-20G5
M 2.4
M 3.5
External View
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
C200H-CN225
C200H-CN425
Cable length (L)
2m
4m
L
39
17.3
17.5
16.1
10
19
Section 2-3
Wiring
Connection Precautions
1,2,3...
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 Temperature
Control Unit. Nothing appears on the Data Setting Console display if no
power is supplied to input terminals A8 and A9 of the Temperature Control
Unit.
4. Install the supplied connector cover when the cable is not connected.
20
SECTION 3
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 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22
3-2
Data Flow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
23
3-3
Nomenclature and Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
24
3-3-1
Nomenclature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
24
3-3-2
3-4
Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
25
Parameter Displays and Settings. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26
3-4-1
Table of Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26
3-4-2
How to Display and Set Parameter Data . . . . . . . . . . . . . . . . . . . . .
28
21
Section 3-1
Operating Procedure
3-1
Operating Procedure
After preparing the CPU Unit, follow the procedure below to use the Temperature Control Unit.
1,2,3...
1. Set the switches on the front and rear panels according to the operating
conditions. (Refer to 2-2 Switch Settings.)
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 PC power supply before mounting or dismounting the C200H
on the Rack.
3. Connect the input wiring. (Refer to 2-3 Wiring.)
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 2-3-3 Data Setting Console
Cables.)
5. Turn ON the 24-VDC power supply and the PC power supply.
Set the CPU Unit to PROGRAM mode.
6. Set data from the Data Setting Console. (Refer to the rest of this section.)
Under either one of the following conditions (i.e., when control is stopped),
the bank number can be changed to set data using the Data Setting Console.
• When SW203-5 on the rear panel is set to ON (to stop temperature
control in PROGRAM mode) and the CPU Unit is set to PROGRAM
mode.
• When the Stop Bit (word n+2, bit 06 for loop 1 and bit 04 for loop 2) is
ON.
In all other cases, the executed bank number (default value = 1) is displayed and the bank number cannot be changed from the Data Setting
Console. Change the executed bank number with a user program or with
a device, such as the Programming Console.
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 operation. Monitor the control conditions and adjust the data until the required
control is achieved.
8. Create the user programs. (Refer to SECTION 4 PC Memory Allocation
and Programming.)
Create the user programs for data setting, monitoring, and switching the
bank number, as required. Set SW2-2 under the display cover to the ON
position to enable data setting from the CPU Unit.
9. Start operation.
22
Section 3-2
Data Flow
3-2
Data Flow
The data flow in the Temperature Control Unit is shown in the diagram below.
If SW2-2 is ON
Write
I/O bus
CS-series or
C200H CPU
Unit
Temperature
Control Unit
Read
Read
Write
If SW2-2 is OFF
Data Setting
Console
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 the
EEPROM write commands when SW2-1 (switching memory contents) is set
to Normal are written to the Temperature Control Unit EEPROM and are consequently retained when the power supply is turned OFF.
Data written with RAM write commands when SW2-1 (switching memory contents) is set to Normal, the SP value set when SW2-1 (switching memory contents) is set to Fixed and executed bank number settings made from the CPU
Unit are written directly to RAM and are not saved to EEPROM. This data is
lost when the power supply is turned OFF.
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.
While Temperature Control Unit is in control operation, all data can be set
using the specified executed bank number (default value = 1).
Change the executed bank number with a user program or with a device, such
as the Programming Console. The executed bank number cannot be changed
from the Data Setting Console.
Under either one of the following conditions (i.e., when control is stopped), the
bank number can be changed to set data using the Data Setting Console.
• When SW203-5 on the rear panel is set to ON (to stop temperature control in the PROGRAM mode) and the CPU Unit is set to PROGRAM
mode.
23
Section 3-3
Nomenclature and Features
• When the Stop Bit (word n+2, bit 06 for Loop 1 and bit 04 for Loop 2) is
ON.
3-3
3-3-1
Nomenclature and Features
Nomenclature
Front View
Side View
Data display
Operation indicators
Display for Cam
Positioner
Cover
Down Key
Up Key
(With cover open)
Display Key
Panel mounting bracket
(Refer to Appendix D Dimensions for details about
panel mounting.)
Rear View
Operation keys
Select parameters
Set data
Switch Loops
Level Key
Loop Key
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 Temperature Control Unit operation. The lower labels are for
the Cam Positioner Unit.
Two display sheets are supplied: one for the 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 the display sheet for the Temperature
Control Unit.
24
Section 3-3
Nomenclature and Features
Note The Data Setting Console will not operate unless a 24-VDC power supply is
connected to the Temperature Control Unit input terminals.
3-3-2
Features
Data Display
Name
PV (Process Value)
SV (Set Value)
BK (Bank Number)
Function
Displays the PV or the parameter symbol selected with the
Level or Display Key (Refer to next page).
Displays the SV or setting/monitored data corresponding to
the parameter symbol selected with the Level, Display or Loop
Keys and indicated in the PV display. Displays the SP when
the PV is indicated in the PV display.
Displays the executed bank number. Displays the bank number of the displayed data when temperature control is interrupted. (See note.)
Note Temperature control is interrupted when SW203-5 on the rear panel is set to
ON and also the CPU Unit is set to PROGRAM mode, or when the Stop Bit
(word n+2, bit 06 for loop 1 and bit 04 for loop 2) is ON.
Operation Indicators
Name
LOOP2
OUT (Output)
AT (Auto-tuning)
HB (Heater
Burnout)
ALM1 (Alarm)
Function
Indicates whether the displayed settings relate to Loop 1 or Loop
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
Turns ON when the output is ON for tran- These indicators relate
sistor output or voltage output types.
to the currently displayed loop.
Blinks at approximately 1 second intervals during auto-tuning.
Turns ON to indicate a heater burnout
alarm.
Turns ON to indicate the temperature is
in the alarm range set with Alarm SV 1
(upper- and lower-limit alarm). Refer to
the following page.
Display Patterns
Display Pattern 1
Executed bank
number or displayed
bank number
Indicator OFF: Loop 1
Indicator ON: Loop 2
Display Pattern 2
Process
value
Parameter symbol
Set point
SV (Set value)
Monitored value
Execution status
Executed
bank number
or displayed
bank number
Indicator OFF: Loop 1
Indicator ON: Loop 2
25
Section 3-4
Parameter Displays and Settings
Operation Keys
Name
3-4
3-4-1
Display
level
0
26
Level Key
The parameter items are divided into three display groups (Refer
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 Key
Press this key to select the required parameter from the selected
display level 0 to 2 (Refer to table below).
The parameters cycle automatically when the key is held down.
Loop Key
Press this key for approximately two seconds to switch between
Loop 1 and Loop 2.
Up Key
Press this key to increment SV.
The SV increment continuously while the key is held down. The
SV display blinks when the value reaches its maximum limit.
Down Key
Press this key to decrement an SV.
The SV decreases continuously while the key is held down. The
SV display blinks when the value reaches its minimum limit.
Parameter Displays and Settings
Table of Parameters
Parameter
Display
symbol
Write
Read
Loop
no.
Bank
no.
Set point
---
Yes
Yes
Yes
Yes
Bank number
bk
Yes
Yes
No
Yes
Yes
Yes
Alarm SV 1 (see
note 4)
Alarm SV 2 (see
note 4)
al-1
See
note 5
Yes
al-2
Yes
Yes
Yes
Yes
Input shift value
in-5
p
Yes
Yes
Yes
Yes
Yes
Integral (reset)
time (see note 1)
i
Yes
Derivative (rate)
time (see note 1)
SP lower limit
d
SP upper limit
Proportional band
(see note 1)
1
Function
Data range
SP lower limit to
SP upper limit
1 to 8
Default value
Page
0°C
28
1
32
29
Yes
Alarm mode
0°C
TC 1, 4, 5:
0° to 9999°C
0°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
–99.9° to 999.9°C 0.0°C
Yes
Yes
0.0° to 999.9°C
40.0°C
33
Yes
Yes
Yes
0 to 9999 s
240 s
Yes
Yes
Yes
Yes
0 to 9999 s
40 s
sl-l
Yes
Yes
Yes
No
Sensor measurTC: –200°C
ing range lower
Pt: –99.9°C
limit to (SP upper
limit – 1 digit)
28
sl-h
Yes
Yes
Yes
No
(Sensor measuring range lower
limit + 1 digit) to
SP upper limit
28
TC: 1,300°C
Pt: 450.0°C
31
Section 3-4
Parameter Displays and Settings
Display
Parameter
level
1
Control period
(see note 1 and 3)
Hysteresis (see
note 2)
Alarm hysteresis
(see note 4)
Heater current
monitor (see
note 3)
Heater burnout
current (see
note 3)
2
Control output
variable monitor
Auto-tuning start/
stop (see note 1)
Copy bank
Sensor-type monitor
Alarm 1 mode
Alarm 2 mode
Display
symbol
Write
cp
Yes
Yes
Loop
no.
Yes
hys
Yes
Yes
Yes
Yes
0.0° to 999.9°C
0.8°C
hysa
Yes
Yes
Yes
No
0.0° to 999.9°C
0.2°C
30
ct
No
Yes
Yes
No
0.0 to 5.5 A
---
31
hb
Yes
Yes
Yes
No
0.0 to 5.0
0.0 A
0.0: No heater
burnout detection,
alarm signal OFF
5.0: No heater
burnout detection,
alarm signal ON
No
Yes
Yes
No
0.0% to 100.0%
---
31
at
Yes
Yes
Yes
No
---
---
33
bcpy
in-t
Yes
Yes
Yes
No
---
---
32
No
Yes
No
No
0 to 9
Setting for
SW202
alt1
alt2
Yes
Yes
Yes
No
2
Yes
Yes
Yes
No
0 to 9
Mode for Alarm
SV 1/2 (0: no
alarm)
o
Read
Bank
no.
No
Data range
Default value
Page
1 to 99 s
20 s
31
29
2
Yes: Possible.
No: Not possible or not required.
Note
1. Only when PID control with feed-forward circuitry is selected
2. Only when ON/OFF control is selected.
3. Does not apply to current output.
4. Does not apply when Alarm Mode = 0
5. Under either one of the following conditions (i.e., when control is stopped),
the bank number can be changed to set data using the Data Setting Console.
• When SW203-5 on the rear panel is set to ON (to stop temperature
control in the PROGRAM mode) and the CPU Unit is set to PROGRAM mode.
• When the Stop Bit (word n+2, bit 06 for loop 1 and bit 04 for loop 2) is
ON.
In all other cases, the executed bank number (default value = 1) is displayed and the bank number cannot be changed from the Data Setting
Console. Change the executed bank number with a user program or with
a device, such as the Programming Console.
6. Thermocouple = TC
Platinum Resistance Thermometer = Pt
27
Section 3-4
Parameter Displays and Settings
3-4-2
How to Display and Set Parameter Data
PV and SV (Display Level 0)
PV
Process value (monitored every 500 ms)
SV
Currently set set value. Units: °C or °F. The SV can be
changed from this display.
Valid SV Range
Set the SV 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
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 : Loop 1; ser2 : Loop 2
serr
Abnormality in the cold junction compensating circuit. Applies to thermocouple type only.
SP Lower Limit (Display Level 1)
PV
SP lower limit parameter symbol
SV
Currently set SV lower limit. Units: °C or °F.
The SV lower limit can be changed from this display.
When the sensor type is set with SW202 on the rear of the Unit, the SV lower
limit is automatically set to the measuring range lower limit of the selected
sensor, as shown below. However, the SP lower limit cannot be changed if the
current SV lies inside the sensor measuring range.
Default values TC: –200 °C
Pt: –99.9 °C
Change the set limit, if required. Set the lower limit in the following range:
Sensor measuring range lower limit to (SP upper limit – 1 digit)
The SV and “----” blink alternately on the display if the SP lower limit is set outside the limit defined above to indicate that the value is out-of-range. Reset
the SP lower limit inside the permitted range.
SP Upper Limit (Display Level 1)
PV
SP upper limit parameter symbol
SV
Currently set SV upper limit. Units: °C or °F.
The SV upper limit can be changed from this display.
When the sensor type is set with SW202 on the rear of the Unit, the SV upper
limit is automatically set to the measuring range upper limit of the selected
sensor, as shown below. However, the SP upper limit cannot be changed if the
current SV lies inside the sensor measuring range.
Default values TC: 1300 °C
Pt: 450.0 °C
Change the set limit, if required. Set the upper limit in the following range:
(Sensor measuring range lower limit + 1 digit) to SP upper limit
28
Section 3-4
Parameter Displays and Settings
The SV and “----” blink alternately on the display if the SP upper limit is set
outside the limit defined above to indicate that the value is out-of-range. Reset
the SP upper limit inside the permitted range.
Alarms SV 1 and SV 2 (Display Level 0)
PV
Alarm 1/2 parameter symbol
SV
Currently set alarm value. Units: C or F. The
setting can be changed from this display. The
alarm mode is set with the Alarm 1/2 Mode
parameter described on the following page.
Two alarm SVs can be set for each loop and bank.
Alarm 1 and Alarm 2 Modes (Display Level 2)
PV
Alarm 1/2 Mode parameter symbol
SV
Currently set alarm mode.
The setting can be changed from this display.
Two alarm modes can be set for each loop.
Alarm
Mode
Alarm Type
Alarm Range
SP
0
0
No alarm
1
Upper- and lower-limit alarm
2
Upper-limit alarm
3
Lower-limit alarm
x
4
Upper- and lower-limit range alarm
x
x
5
Upper- and lower-limit alarm with
standby sequence
x
x
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
x
x
x
x
x
x
x
29
Section 3-4
Parameter Displays and Settings
About the Standby Sequence
Select the standby sequence to avoid an alarm output immediately after
power is turned ON where the value is in the alarm range. 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.
Lower Limit Alarm with Standby Sequence
Standby sequence
cancel point
Hysteresis
OFF point
Alarm SV
0°C
Alarm output
The standby sequence is restarted in the following situations.
• When SV is changed.
• When executed bank number is changed.
• When alarm mode is changed.
• When PC power supply is turned ON.
• When restart flag is set ON.
• When PROGRAM mode is switched to MONITOR or RUN while the control interrupt is set (SW203-5 is ON).
• When the Stop Bit (word n+2, bit 06 or 04) goes OFF.
Alarm Hysteresis (Display Level 1)
PV
Alarm hysteresis parameter symbol
SV
Current setting. Units: °C or °F.
The setting can be changed from this display.
A hysteresis band is provided to prevent chattering of the alarm output when
the alarm output is turned from ON to OFF.
Hysteresis bandwidth
ON
Hysteresis bandwidth
ON
OFF
Input
Alarm SV
OFF
Input
Alarm SV
The alarm output is OFF if the process value lies within the hysteresis band
when the Unit is turned on.
Heater Burnout Current (Display Level 1)
PV
SV
30
Heater burnout current parameter symbol
Currently set heater burnout current value. Units:
Amperes (A).
The setting can be changed from this display.
Section 3-4
Parameter Displays and Settings
Set the heater burnout current value in the range shown in the table below.
Refer to Appendix C Heater Burnout Detection for more details about the
alarm SVs.
0.0
0.1 to 4.9
No heater burnout detection. Alarm signal OFF.
Within heater burnout current SV range.
5.0
No heater burnout detection. Alarm signal ON.
Heater Current Monitor (Display Level 1)
PV
Heater current monitor parameter symbol
SV
Currently set heater current value. Units: Amperes (A).
If the current exceeds 5.5 A, a CT Input Overflow error
occurs and BBBB is displayed.
Input Shift Value (Display Level 0)
PV
Input shift value parameter symbol
SV
Currently set input shift value. Units: °C or °F. The setting
can be changed from this display.
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.
Control Period (Display Level 1)
PV
Control period parameter symbol
SV
Currently set control period. Units: Seconds (s). The setting can be changed from this display.
The control period is the time required to complete one transistor output or
voltage output ON/OFF cycle.
ON
OFF
ON time
Control period
Control Output Variable Monitor (Display Level 2)
PV
Control output variable monitor parameter symbol
SV
Current control output variable. Units: percentage (%).
The relationship between the control output variable and control period is
defined by the formula below:
Control output variable (%) =
ON time
Control period
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%.
31
Section 3-4
Parameter Displays and Settings
Hysteresis (Display Level 1)
PV
Hysteresis parameter symbol
SV
Currently set hysteresis value. Units: °C or °F. The
setting can be changed from this display.
Hysteresis is an operating band provided for ON/OFF operation to prevent
output chattering (repeated ON/OFF switching) and eliminate noise influences.
Hysteresis
ON
OFF
SV
Hysteresis is applied in the following situations.
• When ON/OFF control is selected (SW203-1 is ON).
• When PID control with feed-forward circuitry (SW203-1 is OFF) and P
(proportional band) is 0.
Bank Number (Display Level 0)
PV
Bank number parameter symbol
SV
Currently set bank number.
During control operation: Executed bank number (default value = 1)
Control operation interrupted: Currently displayed bank number
Changing the Settings
The bank number can be changed from the Data Setting Console in the following situations.
• When the CPU Unit is set to PROGRAM mode and SW203-5 on the rear
panel is set to ON to interrupt temperature control.
• When the Stop Bit (word n+2, bit 06 for loop 1 or bit 04 for loop 2) is ON.
When the above conditions are not met, the executed bank number cannot be
changed from the Data Setting Console and the executed bank number
(default value = 1) is displayed. Change the executed bank number with a
user program or with a device, such as the Programming Console.
Copy Bank (Display Level 2)
Copies the data, except for the SV (set value) data, from bank number 1 to
banks 2 to 8.
PV
SV
Execute bank copy
32
Bank being copied
Bank copy completed
Section 3-4
Parameter Displays and Settings
Sensor-type Monitor (Display Level 2)
PV
Sensor-type monitor parameter symbol
SV
Sensor type currently set with SW202 on the rear panel. Number refers to the following if a platinum resistance thermometer
is used:
0: JPt (OFF), 1: Pt (ON)
Auto-tuning Start/Stop (Display Level 2)
PV
AT
AT indicator
blinks
SV
AT start
Process value (PV)
Set point (SP)
AT executing
To interrupt, press the Level and Display Keys again to display at. When at
appears, press the Up Key. On interrupt, the at display disappears and the
process value is displayed.
Auto-tuning operates only when SW203-1 on the rear panel is set to OFF to
enable PID control with feed-forward circuitry. When auto-tuning is completed,
the AT indicator stops blinking and the P, I, and D data is written to EEPROM.
If necessary, the P, I, and D data can be changed as described in the following.
Proportional Band (Display Level 0)
PV
Proportional Band parameter symbol
SV
Currently set Proportional Band. Units: °C or °F. The
setting can be changed from this display.
Integral (Reset) Time (Display Level 0)
PV
Integral time parameter symbol
SV
Currently set integral time. Units: second. The
setting can be changed from this display.
Derivative (Rate) Time (Display Level 0)
PV
Derivative time parameter symbol
SV
Currently set derivative time. Units: second. The
setting can be changed from this display.
33
SECTION 4
PC Memory Allocation and Programming
This section provides the C200H PC’s memory allocation for the Temperature Control Unit. Basic programming
procedures and examples are also provided.
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 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
44
4-3
Programming. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
44
4-3-1
C200HX/HG/HE, C200HS, C200H . . . . . . . . . . . . . . . . . . . . . . . . .
44
4-3-2
CS Series. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
51
4-3-3
Operation Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
58
4-3-4
I/O Refresh . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
59
35
Section 4-1
Memory Allocation
4-1
Memory Allocation
Memory Allocation
The Temperature Control Unit is allocated 10 words in the IR or CIO Area
according to the unit number switch setting on the front of the Unit. These
words are used as an I/O refresh data area. The IR or CIO Area words used
by the Temperature Control Unit are refreshed each I/O refresh scan of the
CPU Unit.
CS Series
Temperature Control Unit
CIO area
I/O refresh data area
Unit#0 CIO 2000 to CIO 2009
Unit#1 CIO 2010 to CIO 2019
Unit#2 CIO 2020 to CIO 2029
Unit#3 CIO 2030 to CIO 2039
Unit#4 CIO 2040 to CIO 2049
Unit#5 CIO 2050 to CIO 2059
Unit#6 CIO 2060 to CIO 2069
During PC I/O refresh,
each scan is executed for
the outputs (PC to Temperature Control Unit) followed
by the inputs (Temperature
Control Unit to PC).
Wd (n)
to
Wd (n+2)
Output refresh
Wd (n+3)
to
Wd (n+9)
Input refresh
(n=2000 + 10 x Unit number)
The terms "output" and 'input" are defined
from the CPU Unit.
Unit#7 CIO 2070 to CIO 2079
Unit#8 CIO 2080 to CIO 2089
Unit#9 CIO 2090 to CIO 2099
Temperature Control Unit
C200HX/HG/HE, C200HS, or C200H
IR area
I/O refresh data area
Unit#0 IR 100 to IR 109
Unit#1 IR 110 to IR 119
Unit#2 IR 120 to IR 129
Unit#3 IR 130 to IR 139
Unit#4 IR 140 to IR 149
Unit#5 IR 150 to IR 159
During PC I/O refresh, each
scan is executed for the outputs
(PC to Temperature Control Unit)
followed by the inputs (Temperature Control Unit to PC).
Unit#6 IR 160 to IR 169
Wd (n)
to
Wd (n+2)
Output refresh
Wd (n+3)
to
Wd (n+9)
Input refresh
(n=100 + 10 x Unit number)
The terms "output" and "input" are defined
from the CPU Unit.
Unit#7 IR 170 to IR 179
Unit#8 IR 180 to IR 189
Unit#9 IR 190 to IR 199
Note A Duplicate I/O Unit error occurs if the set Unit number corresponds to the
number of an existing Special I/O Unit.
Selecting Allocated Data
The data allocated to each IR word due to the Unit number setting is determined by the setting of SW2-1 on the front of the Unit.
ON
OFF
Normal
Fixed
All data can be set using commands.
Fixed data is allocated to memory. Direct reading and writing of
data is possible.
This setting becomes valid immediately after the switch is set.
36
Section 4-1
Memory Allocation
4-1-1
Memory Allocation Table
SW2-1 Set for Fixed Memory Allocations
(CS Series: n=2000+10 x Unit number)
(C200HX/HG/HE, C200HS, C200H: n=100 + 10 x Unit number)
I/O
Output
Word
n
n+1
n+2
Input
Bit
15
14
13
12
Loop 1 SP (see note)
Loop 2 SP (see note)
Loop 1 executed bank
number
n+3
Loop 1 PV (see note)
n+4
n+5
Loop 2 PV (see note)
Loop 1 SP (see note)
n+6
n+7
Loop 2 SP (see note)
Loop 1 executed bank
number
n+8
10
09
08
07
06
05
04
Loop 2 executed bank
number
Loop 1
Loop 2 executed bank
number
0
0
0
0
STOP
0
0
0
Con- AT
trol
output
0
0
0
STOP
0
0
0
Con- AT
trol
output
0
Loop 2
03
Stop 0
02
01
00
0
Stop
0
0
SW data
2-2
2-1
HB
AL1
AL2
HB
AL1
AL2
Loop 1 status data
0
n+9
11
Sensor
error
CT
0
overflow
Loop 2 status data
0
Sensor
error
CT
0
overflow
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 Set for Normal Memory Allocations
(CS Series: n=2000+10 x Unit number)
(C200HX/HG/HE, C200HS, C200H: n=100 + 10 x Unit number)
I/O
Word
Bit
15
Output
n
n+1
n+2
14
13
12
11
10
09
08
07
06
05
04
Read/write instruction
Read/write Loop no.
Bank no.
Instruction
Write data (see note)
Loop 1 executed bank
number
Loop 2 executed bank
number
Loop 1
Loop 2
0
0
STOP
STOP
03
0
02
0
01
0
00
Write
request
37
Section 4-1
Memory Allocation
I/O
Word
Bit
15
Input
14
13
12
n+3
n+4
Loop 1 PV (see note)
Loop 2 PV (see note)
n+5
n+6
Read data
0
n+7
Loop 1 executed bank
number
n+8
Loop 1 status data
0
n+9
11
10
Write 0
error
Sensor
error
09
08
07
06
05
04
Write 0
complete
Loop 2 executed bank
0
number
CT
0
overflow
0
03
02
0
0
0
0
01
00
0
Read
complete
SW data
2-2
2-1
0
0
0
STOP 0
0
0
Control
output
AT
HB
AL1
AL2
0
0
0
STOP 0
0
0
Control
output
AT
HB
AL1
AL2
Loop 2 status data
0
Sensor
error
CT
0
overflow
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 Set for Fixed Memory Allocations
(CS Series: n=2000+10 x Unit number)
(C200HX/HG/HE, C200HS, C200H: n=100 + 10 x Unit number)
I/O
Output
Address
Word
Bit
Data contents
n
n+1
15 to 00
15 to 00
Loop 1 SP
Loop 2 SP
n+2
15 to 12
Loop 1 exe- Sets the bank number executed for Loop 1 and Loop 2 as 1-digit
cuted bank BCD data. Set executed bank numbers from 1 to 8. If the value is
number
set out of this range, the bank number reverts to the previous value
Loop 2 exe- (default value = 1).
cuted bank
number
--Not used. Set to 0.
11 to 08
07
38
Data item
Sets the Loop 1 and Loop 2 SP (set point) 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 (–).
These specified values apply to the bank number set with Wd
(n+2) and can only be changed in RAM. (Refer page 44)
06
Loop 1
STOP
Bit set to 0 during temperature control of Loop 1 and set to 1 when
the control stop is executed. This bit will not be available under the
program mode with SW203-5 set to ON (same as the control stop).
05
04
--Loop 2
STOP
03 to 00
---
Not used. Set to 0.
Bit set to 0 during temperature control of Loop 2 and set to 1 when
the control stop is executed. This bit will not be available under the
program mode with SW203-5 set to ON (same as the control stop).
Not used. Set each bit to 0.
Section 4-1
Memory Allocation
I/O
Input
Address
Word
Bit
Data item
Data contents
n+3
n+4
15 to 00
15 to 00
Loop 1 PV
Loop 2 PV
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. The most significant digit is F for minus (–).
n+5
n+6
15 to 00
15 to 00
Loop 1 SP
Loop 2 SP
Outputs the Loop 1 and Loop 2 SP (set point) as 4-digit BCD data.
For platinum resistance thermometer data, the least significant
digit is 0.1. The most significant digit is F for minus (–).
n+7
15 to 12
07 to 02
Loop 1 exe- Outputs the bank number currently executed for Loop 1 and Loop
cuted bank 2 as 1-digit BCD data. Executed bank numbers are from 1 to 8.
number
Loop 2 executed bank
number
--Not used. Each bit is set to 0.
01
SW2-2
00
SW2-1
11 to 08
n+8 Loop 1 15
n+9 Loop 2 14
13
Outputs the ON/OFF status of SW2-2 (setting direction).
0: Data Setting Console
1: CPU Unit
Outputs the ON/OFF status of SW2-1 (switching memory contents).
0: Fixed
1: Normal
--Not used. Set to 0.
Loop 1/2
status data
Sensor
Bit set to 1 if the sensor is not connected, a sensor
error
wire is broken, or the input data exceeds the operational temperature range.
CT overflow Bit set to 1 when the detected heater current
exceeds 5.5 A.
12 to 09
---
Not used. Each bit is set to 0.
08
STOP
07 to 05
---
Bit set to 0 during temperature control and set to 1
when the control stop is executed.
Not used. Each bit is set to 0.
04
03
Control out- Bit set to 1 when the control output (transistor or voltput
age output) is ON. The bit is always 0 for current output.
AT
Bit set to 1 during auto-tuning (AT).
02
HB
Bit set to 1 if the detected heater current drops below
the set heater burnout current value. (HB: heater
burnout)
01
00
AL1
AL2
Bit set to 1 when the temperature enters the set
alarm range (Refer to page 25).
Note If the setting direction of the Temperature Control Unit is set to the CPU Unit
and the CPU Unit is in PROGRAM mode, all word data will be 0. Therefore, if
the CPU Unit is in PROGRAM mode and has been set for continuous control,
the Temperature Control Unit will continue executing temperature control even
when the CPU Unit stops operating and will assume that the SP has been
changed to 0°C. To prevent this, set SW2-2 on the Temperature Control Unit
to OFF (i.e., the setting direction is set to the Data Setting Console) before the
CPU Unit stops operating and reset SW2-2 after the CPU Unit restarts.
39
Section 4-1
Memory Allocation
SW2-1 Set for Normal Memory Allocations
(CS Series: n=2000+10 x Unit number)
(C200HX/HG/HE, C200HS, C200H: n=100 + 10 x Unit number)
I/O
Output
Address
Word
Bit
n
15 and 14
40
Data contents
13 and 12
Read/Write The data bit sets operation to read or write.
Read/Write
Write = 01 Read = 00
command
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
n+2
15 to 12
11 to 08
Input
Data item
Set the SP for a write operation as 4-digit BCD data. For data
including 0.1 units, the least significant digit represents 0.1. Set the
most significant digit to F for minus (–). The write operation commences on the ON rising-edge of the write request flag (Wd (n+2),
bit 00).
Loop 1 exe- Set the bank number currently executed for Loop 1 and Loop 2 as
cuted bank 1-digit BCD data. Executed bank numbers are from 1 to 8. If the
number
value is set out of this range, the bank number reverts to the previLoop 2 exe- ous value (default value = 1).
cuted bank
number
07
06
--Loop 1
STOP
Not used. Set to 0.
Bit set to 0 during temperature control of Loop 1 and set to 1 when
the control stop is executed. This bit will not be available under the
program mode with SW203-5 set to ON (same as the control stop).
05
04
--Loop 2
STOP
03 to 01
---
Not used. Set to 0.
Bit set to 0 during temperature control of Loop 2 and set to 1 when
the control stop is executed. This bit will not be available under the
program mode with SW203-5 set to ON (same as the control stop).
Not used. Set each bit to 0.
00
Write
request
n+3
15 to 00
Loop 1 PV
n+4
15 to 00
Loop 2 PV
n+5
15 to 00
Read data
n+6
15 to 12
11
--Write error
10 to 09
---
08
Write complete
Turn this bit ON when writing the write data set with Wd (n+1) with
the commands set to Wd (n).
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 (–).
Outputs the data read with the commands set with Wd (n). For
data including 0.1 Units, the least significant digit represents 0.1.
Set the most significant digit to F for minus (–).
Not used. Each bit is set to 0.
Bit set to 1 when the write data exceeds the set permissible range.
The bit is automatically set to 0 on the OFF falling-edge of the write
request flag (Wd (n+2), bit 00).
Not used. Each bit is set to 0.
Bit set to 1 when the write operation due to the instructions set with
Wd (n) ends normally. The bit is automatically set to 0 on the OFF
falling-edge of the write request flag (Wd (n+2), bit 00).
Section 4-1
Memory Allocation
I/O
Input
Address
Word
Bit
n+6
07 to 01
00
n+7
15 to 12
Data item
--Read complete
Not used. Each bit is set to 0.
Bit set to 1 when the read operation due to the commands set with
Wd (n) ends normally. The bit is set to 0 when the command is
changed.
Loop 1 exe- Outputs the bank number currently executed for Loop 1 and Loop
cuted bank 2 as 1-digit BCD data. Executed bank numbers are from 1 to 8.
number
Loop 2 executed bank
number
11 to 08
07 to 02
01
--SW2-2
00
SW2-1
n+8 Loop 1 15
n+9 Loop 2 14
--Sensor
error
Not used. Each bit is set to 0.
Outputs the ON/OFF status of SW2-2 (setting direction).
0: Data Setting Console
1: CPU Unit
Outputs the ON/OFF status of SW2-1 (switching memory contents).
0: Fixed
1: Normal
12 to 09
Not used. Set to 0.
Bit set to 1 if the sensor is not connected, a sensor
wire is broken, or the input data exceeds the operational temperature range.
CT overflow Bit set to 1 when the detected heater current
exceeds 5.5 A.
--Not used. Each bit is set to 0.
08
STOP
07 to 05
04
03
--Not used. Each bit is set to 0.
Control out- Bit set to 1 when the control output (transistor or voltput
age output) is ON. The bit is always 0 for current output.
AT
Bit set to 1 during auto-tuning (AT).
02
HB
01
AL1
00
AL2
13
4-1-3
Data contents
Loop 1/2
status data
Bit set to 0 during temperature control and set to 1
when the control stop is executed.
Bit set to 1 if the detected heater current drops 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 25).
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 for normal memory allocations.
EEPROM Write/Read Command
Parameter
Command
Write
Read
Loop
no.
Bank
no.
Set point
0
0
Yes
Yes
Yes
Yes
Executed bank number
0
2
Yes
Yes
Yes
No
Actual data
range
Write/Read
data range
SV lower limit to SV upper
limit
1 to 8
Default value
0°C
1
41
Section 4-1
Memory Allocation
Parameter
Alarm SV 1 (see note 4)
Alarm SV 2 (see note 4)
Command
0
3
0
4
Write
Read
Yes
Yes
Yes
Yes
Loop
no.
Yes
Yes
Bank
no.
Yes
Yes
Actual data
range
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
Write/Read
data range
Default value
0°C
0000 to
9999
F999 to
9999
0°C
0000 to
9999
F999 to
9999
Input shift value
0
5
Yes
Yes
Yes
Yes
–99.9° to
999.9°C
F999 to
9999
0.0°C
Proportional band (see
note 1)
Integral (reset) time (see
note 1)
Derivative (rate) time
(see note 1)
SP lower limit
0
6
Yes
Yes
Yes
Yes
0000 to
9999
40.0°C
0
7
Yes
Yes
Yes
Yes
0.0° to
999.9°C
0 to 9999 s
0
8
Yes
Yes
Yes
Yes
0 to 9999 s
40 s
1
0
Yes
Yes
Yes
No
TC: –200°C
Pt: –99.9°C
1
1
Yes
Yes
Yes
No
Control period (see note 1
1 and 3)
Hysteresis (see note 2) 1
7
Yes
Yes
Yes
No
Sensor measuring range
lower limit to (SP upper limit
value – 1 digit)
(SP lower limit + 1 digit) to
sensor measuring range
upper limit
1 to 99 s
8
Yes
Yes
Yes
Yes
1
9
Yes
Yes
Yes
No
1
A
No
Yes
Yes
1
B
Yes
Yes
Yes
SP upper limit
Alarm hysteresis (see
note 4)
Heater current monitor
(see note 3)
Heater burnout current
(see note 3)
240 s
No
0.0° to
999.9°C
0.0° to
999.9°C
0.0 to 5.6 A
0000 to
9999
0000 to
9999
0000 to
0056
No
0.0 to 5.0 A
0000 to
0050
TC: 1,300°C
Pt: 450.0°C
20 s
0.8°C
0.2°C
--0.0 A
0.0: No heater burnout detection, alarm signal OFF
5.0: No heater burnout detection, alarm signal ON
0.0% to
0000 to
--100.0%
1000
AT start = 0001
--AT stop = 0000
Control output variable
monitor
Auto-tuning start/stop
(see note 1)
2
0
No
Yes
Yes
No
2
1
Yes
No
Yes
No
Copy bank
Sensor-type monitor
2
2
2
3
Yes
No
No
Yes
Yes
Yes
No
No
Run = 0001
0 to 9
Alarm 1 mode
2
4
Yes
Yes
Yes
No
Alarm 2 mode
2
5
Yes
Yes
Yes
No
0 to 9
Mode for Alarm SV 1/2 (0: no 2
alarm)
Yes: Possible.
No: Not possible or not required.
Note
1. Only when advanced PID control is selected.
2. Only when ON/OFF control is selected.
42
--Setting for
SW202
2
Section 4-1
Memory Allocation
3. Does not apply to current output. A value of 5.6 (0056) for the heater current monitor indicates that the heater current value exceeds 5.6 A.
4. Does not apply when Alarm Mode = 0
5. Refer to 3-4 Parameter Displays and Settings for details of the parameters.
6. Thermocouple = TC
Platinum Resistance Thermometer = Pt
RAM Write Command
Parameter
Command
Write
Read
Loop
no.
Bank
no.
Actual data
range
Write/Read
data range
Default value
Set point
4
0
Yes
No
Yes
Yes
SV lower limit to SV upper
limit
0°C
Executed bank number
Alarm SV 1 (see note 4)
4
4
2
3
Yes
Yes
No
No
Yes
Yes
No
Yes
1 to 8
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
–99.9° to
999.9°C
0.0° to
999.9°C
1
0°C
Alarm SV 2 (see note 4)
4
4
Yes
No
Yes
Yes
0000 to
9999
F999 to
9999
0°C
0000 to
9999
F999 to
9999
F999 to
9999
0000 to
9999
Input shift value
4
5
Yes
No
Yes
Yes
0.0°C
Proportional band (see
note 1)
4
6
Yes
No
Yes
Yes
Integral (reset) time (see 4
note 1)
7
Yes
No
Yes
Yes
0 to 9999 s
240 s
Derivative (rate) time
(see note 1)
4
8
Yes
No
Yes
Yes
0 to 9999 s
40 s
SP lower limit
5
0
Yes
No
Yes
No
Sensor measuring range
lower limit to (SP upper limit
value – 1 digit)
TC: –200°C
Pt: –99.9°C
SP upper limit
5
1
Yes
No
Yes
No
TC: 1,300°C
Pt: 450.0°C
Control period (see note 5
1 and 3)
7
Yes
No
Yes
No
(SP lower limit + 1 digit) to
sensor measuring range
upper limit
1 to 99 s
Hysteresis (see note 2)
5
8
Yes
No
Yes
Yes
0.0° to
999.9°C
0000 to
9999
0.8°C
Alarm hysteresis (see
note 4)
5
9
Yes
No
Yes
No
0.0° to
999.9°C
0000 to
9999
0.2°C
Heater burnout current
(see note 3)
5
B
Yes
No
Yes
No
0.0 to 5.0 A
Alarm 1 mode
Alarm 2 mode
6
6
4
5
Yes
Yes
No
No
Yes
Yes
No
No
2
0 to 9
Mode for Alarm SV 1/2 (0: no 2
alarm)
40.0°C
20 s
0000 to
0.0 A
0050
0.0: No heater burnout detection, alarm signal OFF
5.0: No heater burnout detection, alarm signal ON
Yes: Possible.
No: Not possible or not required.
43
Section 4-2
Data Flow
Note
1. Only when advanced PID control is selected.
2. Only when ON/OFF control is selected.
3. Does not apply to current output.
4. Does not apply when Alarm Mode = 0
5. Data written by the RAM write command will disappear when the power is
turned OFF.
6. Data cannot be read using the RAM write command.
7. Refer to 3-4 Parameter Displays and Settings for details of the parameters.
4-2
Data Flow
Refer to 3-2 Data Flow for the data flow in the Temperature Control 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 CPU Unit. 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.
4-3
4-3-1
Programming
C200HX/HG/HE, C200HS, C200H
Example with SW2-1 with Fixed Memory Allocations
Description and Conditions
Example:
The user program makes the following settings:
Loop 1 SP = 80°C
Loop 2 SP = 200°C
Loop 1 executed bank number = 1
Loop 2 executed bank number = 3
Conditions: C200H-TC001 (thermocouple)
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).
Sample Program
25315
10701
10700
(C200H)
Fixed
Set #0080 for word 100 (Loop 1 SP).
MOV (21)
1 cycle ON
#0080
100
Set #0200 for word 101 (Loop 2 SP).
MOV (21)
#0200
101
Set #1300 for word 102 (executed bank number).
MOV (21)
#1300
102
END (01)
#1300
Loop 2 executed bank number
Loop 1 executed bank number
Be sure to set the correct values for the Loop 1 and Loop 2 SP.
44
Section 4-3
Programming
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).
Example 1: Write with SW2-1 Set for Normal Memory Allocations
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-TC001 (thermocouple)
SW202 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).
45
Section 4-3
Programming
Sample Program
10701
10700
DIFU (13)
(C200H) Normal
25315
10701
1 cycle ON
(C200H)
23200
10700
23201
SW2-2 (10701) switch ON detection
(C200H PC)
Program runs when operation is started or
SW2-2 turned ON.
Normal
23200
23201
MOV (21)
#1200
#1200
Loop 2 executed bank number
Loop 1 executed bank number
102
MOV (21)
#5100
100
MOV (21)
#0200
101
23202
#5100
SP setting instruction
Bank number
Bit data: 0101
Loop 1
Write
Write data (200°C)
DIFD (14)
23203
To start next data
23201
10608
S
Write complete
KEEP(11)
23202
R
23203
#6200
MOV (21)
SP setting instruction
Bank number
Bit data: 0110
Loop 2
Write
#6200
100
MOV (21)
#0250
101
23204
Write data (250°C)
DIFD (14)
23205
23203
10608
S
Write complete
KEEP(11)
23204
To start next data
R
23205
#501B
MOV (21)
#501B
100
MOV (21)
#0020
Next page
46
101
Write data (2A)
Heater burnout current
value command
Bank number not required
Bit data: 0101
Loop 1
Write
Section 4-3
Programming
23206
DIFD (14)
23207
23205
10608
S
Write complete
KEEP(11)
23206
To start next data
R
23207
#601B
MOV (21)
#601B
100
Heater burnout current
value command
Bank number not required
Bit data: 0101
Loop 2
Write
MOV (21)
#0025
101
23208
10608
S
Write complete
KEEP(11)
10200
Write data (2.5A)
Write request
R
23201
DIFD (14)
23203
23208
23205
23207
END (01)
47
Section 4-3
Programming
Timing Chart
1 cycle
25315
(1 cycle ON)
23201
23202
23203
23204
23205
23206
23207
10200
(Write request)
10608
(Write complete)
↑: Point of Write command execution
In addition to the above, IR 23201 will turn ON for one cycle on the rising edge
of SW2-2 (IR 10701). One cycle after IR 23208 turns ON, IR 10200 (write
request) will turn ON.
Example 2: Read with SW2-1 Set for Normal Memory Allocations
Description and Conditions
Example:
The following data is read from the indicated addresses:
Loop 1 PV: DM0000
Loop 1 control output variable: DM0001
Loop 2 heater current: DM0002
This read program is to be executed after writing the data with program
example 1.
Conditions: C200H-TC001 (thermocouple)
SW202 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).
48
Section 4-3
Programming
Sample Program
Insert the program below before the END instruction in the program on
page 47.
25313
MOV (21)
Normally ON
103
Read Loop 1 PV from IR103 to DM 0000.
Read operation is not affected by SW2-1
and SW2-2 settings.
DM0000
23209
DIFD (14)
23300
23207
S
(A)
10608
Write complete
23300
10701
KEEP(11)
23209
R
10700
23301
(C200H)
Runs next Read command
when final write complete is
detected.
Normal
23307 repeatedly executes the Read
command when each Read Complete
is detected.
23307
23301
MOV (21)
#1020
100
DIFD (14)
23302
23302
Control output variable
monitor command
Bank number not required
Bit data: 0001
Loop 1
Read
S
KEEP(11)
23303
10600
#1020
Read complete
Wait for Read Complete
to read data
R
23303
DIFD (14)
23304
Next page
49
Section 4-3
Programming
23304
Read data from IR105 to DM 0001.
MOV (21)
105
DM0001
MOV (21)
#201A
100
DIFD (14)
23305
23305
Execute next Read command.
#201A
Heater Current
Monitor command
Bank number not required
Bit data 0010
Loop 2
Read
S
KEEP(11)
23306
10600
Read complete
Wait for Read Complete
to read data
R
23306
DIFD (14)
23307
23307
MOV (21)
105
Read data from IR105 to DM 0002.
DM0002
(B)
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.
10701
10700
DIFU (13)
(C200H)
Normal
25315
10701
1 cycle
ON
(C200H)
23200
SW2-2 (10701) switch ON
detection (C200H PC)
10700
23301
Normal
Program runs when operation is
started or SW2-2 turned ON
23200
Add an END instruction (01) at position (B) of the program.
50
Section 4-3
Programming
Timing Chart
1 cycle
23301
23302
23303
23304
23305
23306
23307
Wd 105
(Read data)
10600
(Read complete)
: Point of Read command execution
1 : Point where data (1) is read.
2 : Point where data (2) is read.
4-3-2
CS Series
Example with Fixed Memory Allocations
Description and Conditions
Example:
The user program makes the following settings:
Loop 1 SP = 80°C
Loop 2 SP = 200°C
Loop 1 executed bank number = 1
Loop 2 executed bank number = 3
Conditions: C200H-TC001 (thermocouple)
SW203 set to 2 (K).
Unit number set to 0 (allocated memory: CIO 2000 to CIO 2009).
SW2-1 set OFF (Fixed) and SW2-2 set ON (CPU Unit).
51
Section 4-3
Programming
Sample Program
A20011
200701
200700
MOV (021)
1 cycle ON CPU Unit
Fixed
Set #0080 for word 2000 (Loop 1 SP).
#0080
2000
MOV (021)
Set #0200 for word 2001 (Loop 2 SP).
#0200
2001
MOV (021)
Set #1300 for word 2002 (executed bank number).
#1300
2002
#1300
Loop 2 executed bank number
END (001)
Loop 1 executed bank number
• Be sure to set the correct values for the Loop 1 and Loop 2 SP. The 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).
Example 1: Write Set for Normal Memory Allocations
Description and Conditions
Example
The user program makes the following settings.
This example writes to EEPROM. To write to RAM, add 4 to the leftmost
digit of the command.
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-TC001 (thermocouple)
SW202 set to 2 (K).
Unit number set to 0 (allocated memory: CIO 2000 to CIO 2009).
SW2-1 set ON (Normal) and SW2-2 set ON (CPU Unit).
52
Section 4-3
Programming
Sample Program
20701
200700
DIFU (013)
CPU Unit
Normal
2320
SW2-2 (200701) switch ON
detection (CPU Unit)
0
A20011
200701
200700
23201
1 cycle ON CPU Unit
Normal
Program runs when operation
is started or SW2-2 turned ON.
23200
23201
MOV (021)
#1200
#1200
Loop 2 executed bank number
2002
Loop 1 executed bank number
MOV (021)
#5100
#5100
2000
MOV (021)
#0200
2001
SP setting instruction
Bank number
Bit data: 0101
Loop 1
Write
Write data (200°C)
23202
DIFU (014)
23203
To start next data
23201
KEEP(011)
23202
200608 Write complete
Next page
53
Section 4-3
Programming
23203
#6200
MOV (021)
SP setting instruction
Bank number
Bit data: 0110
Loop 2
Write
#6200
2000
MOV (021)
#0250
2001
Write data (250°C)
23204
DIFD (014)
23205
To start next data
23203
200608
S
Write complete
KEEP(011)
23204
R
23205
#501B
MOV (021)
#501B
2000
MOV (021)
#0020
2001
Heater burnout current
value command
Bank number not required
Bit data: 0101
Loop 1
Write
Write data (2A)
23206
DIFD (014)
23207
23205
200608
S
Write complete
KEEP(011)
23206
To start next data
R
23207
#601B
MOV (021)
#601B
2000
MOV (021)
#0025
2001
23208
200608
S
Write complete
KEEP(011)
200200
R
23201
DIFD (014)
23203
23208
23205
23207
END (001)
54
Heater burnout current
value command
Bank number not required
Bit data: 0101
Loop 2
Write
Write data (2.5A)
Write request
Section 4-3
Programming
Timing Chart
1 cycle
A20011
(1 cycle ON)
23201
23202
23203
23204
23205
23206
23207
200200
(Write request)
200608
(Write complete)
↑: Point of Write command execution
In addition to the above, CIO 23201 will turn ON for one cycle on the rising
edge of SW2-2 (CIO 200701). One cycle after CIO 23208 turns ON, CIO
200200 (write request) will turn ON.
Example 2: Read Set for Normal Memory Allocations
Description and Conditions
Example:
The following data is read from the indicated addresses:
Loop 1 PV: D0000
Loop 1 control output variable: D0001
Loop 2 heater current: D0002
This read program is to be executed after writing the data with program
example 1.
Conditions: C200H-TC001 (thermocouple)
SW202 set to 2 (K).
Unit number set to 0 (allocated memory: CIO 2000 to CIO 2009.
SW2-1 set ON (Normal) and SW2-2 set ON (CPU Unit).
55
Section 4-3
Programming
Sample Program
Insert the program below before the END instruction in the program on
page 54.
CF113
MOV (021)
Always ON
2003
Read Loop 1 PV from CIO 2003 to D0000.
Read operation is not affected by SW2-1
and SW2-2 settings.
D0000
23209
DIFD (014)
23300
23207
S
(A)
200608
Write complete
23300
200701
KEEP(011)
23209
R
200700
23301
CPU Unit
Runs next Read command
when final write complete is
detected.
Normal
23307 repeatedly executes the Read
command when each Read Complete
is detected.
23307
23301
MOV (021)
#1020
2000
DIFD (014)
23302
23302
Read complete
R
23303
DIFD (014)
23304
Next page
56
Control output variable
monitor command
Bank number not required
Bit data: 0001
Loop 1
Read
S
KEEP(011)
23303
200600
#1020
Wait for Read Complete
to read data.
Section 4-3
Programming
23304
Read data from CIO 2005 to D0001.
MOV (021)
2005
D0001
MOV (021)
#201A
2000
DIFD (014)
23305
23305
Execute next Read command.
#201A
Heater Current
Monitor command
Bank number not required
Bit data 0010
Loop 2
Read
S
KEEP(011)
23306
200600
Read complete
Wait for Read Complete
to read data.
R
23306
DIFD (014)
23307
23307
MOV (021)
2005
Read data from CIO 2005 to D0002.
D0002
(B)
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.
200701
200700
DIFU (013)
23200
CPU Unit Normal
A20011 200701
200700
23300
1 cycle
ON
SW2-2 (200701) switch
ON detection (CPU Unit)
CPU Unit Normal
Program runs when operation is
started or SW2-2 turned ON
23200
Add an END instruction (001) at position (B) of the program.
57
Section 4-3
Programming
Timing Chart
1 cycle
23301
23302
23303
23304
23305
23306
23307
Wd 2005
(Read data)
200600
(Read complete)
: Point of Read command execution
1 : Point where data (1) is read.
2 : Point where data (2) is read.
4-3-3
Operation Timing
The following descriptions apply to the C200HX/HG/HE, C200HS, C200H,
and CS-series PCs.
Write Operation Timing
Command (Wd n)
Write data (Wd n+1)
Write request
(Wd n+2), bit 00
Write complete
(Wd n+6), bit 08
Data (1)
Data (2)
Data (3)
Data (4)
ON
OFF
ON
OFF
Approx.
140 ms
1,2,3...
1. The data is written to the Temperature Control Unit EEPROM when the
Write Request Flag turns ON.
2. The Write Complete Flag turns ON when the data writing operation is completed. It takes approximately 140 ms to write the data.
3. The Write Complete Flag automatically turns OFF when the Write Request
Flag turns OFF.
Check the Write Complete Flag is ON before turning OFF the Write Request Flag. If the Write Request Flag is set to OFF before the Write Com-
58
Section 4-3
Programming
plete 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.
The Loop 1 and 2 executed bank number (Wd n+2) sets data directly. The
data is written to the Temperature Control Unit RAM. If the value is set out
of this range, the bank number reverts to the previous value (default value
= 1).
Timing for a Read Operation
Command (n)
Command (A)
Read complete ON
(Wd n+6),
OFF
bit 00
Approx.
140 ms
Read data
(Wd n+5)
1,2,3...
Command (B)
Read data (A)
Read data (B)
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.
4-3-4
I/O Refresh
The following descriptions apply to the C200HX/HG/HE, C200HS, C200H,
and CS-series PCs.
Temperature control cannot be performed properly unless the I/O refresh
interval is at least 8 ms. Therefore, create programs that satisfy all of the following conditions.
• Set the cycle time to 8 ms min.
If the program processing time is short for the C200HX/HG/HE, C200HS,
and C200H, use the CYCLE TIME instruction SCAN(18) to set a minimum
cycle time.
If the program processing time is short for the CS-series PC, set the cycle
time to a minimum value in the PC Setup.
• When using the I/O Refresh instruction IORF with the Unit, provide an
interval of at least 8 ms between the end refreshes.
• Provide an interval of at least 8 ms between the I/O Refresh instructions.
Normal I/O refresh
End refresh
8 ms min. (Cycle time)
Normal I/O refresh
End refresh
8 ms min.
IORF
I/O Refresh instruction
IORF
I/O Refresh instruction
8 ms min.
8 ms min.
Normal I/O refresh
End refresh
59
SECTION 5
Troubleshooting
This section provides possible errors and error remedies.
5-1
Error Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
62
61
Section 5-1
Error Detection
5-1
Error Detection
When an error occurs in an input or in the Unit, details of the error are
reported to the Data Setting Console and input relays.
Sensor Input Errors
Display
ser1
ser2
serr
Error name
Output status after
error
Cause
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 sensor wiring
Defective sensor
Loop 2 sensor error
Defective Unit
SW203-4 is OFF (Loop 2
enabled) but no sensor
connected to Loop 2
Cold junction compensat- Control output:
Abnormality in cold juncing circuit error
The transistor output or
tion compensating cirvoltage output turns OFF cuit. Applies to
or the current output falls thermocouple type only.
below 2 mA.
Alarm output turns OFF.
Loop 1 sensor error
Data Setting Console
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.
Remedy
Check the sensor wiring.
Replace the sensor.
Replace the Unit.
Correctly set switch
SW203-4.
Replace the Unit.
When a sensor error occurs, one of the codes above and the detected temperature 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.
The bits shown in the table below are set to 1 when a relay input error occurs.
Wd (n+8), bit 14
Loop 1 sensor error
Wd (n+9), bit 14
Loop 2 sensor error
Both bits = 1 after a
cold junction compensating circuit error.
CT Input Overflow
Display
ffff
Error name
CT input overflow
Cause
The detected heater
current exceeds 5.5 A.
Remedy
Check the CT and heater
wiring.
The display shown in the table above will appear if the CT overflow error
occurs when the heater current monitor is selected. The display returns to
normal after the cause of the error is removed.
The bits shown in the table below are set to 1 when the CT overflow error
occurs.
Wd (n+8), bit 13
Wd (n+9), bit 13
Loop 1 CT overflow
Loop 2 CT overflow
Heater Burnout Alarm
Display
HB indicator
lit
62
Error name
Heater burnout
Cause
The detected heater current is below the heater
burnout current value.
Remedy
Check the heater and
heater wiring. Replace
heater if necessary.
Section 5-1
Error Detection
Error displayed when an abnormality occurs in the loop currently being displayed.
The bits shown in the table below are set to 1 when a heater burnout alarm
occurs.
Wd (n+8), bit 02
Wd (n+9), bit 02
Loop 1 heater burnout alarm
Loop 2 heater burnout alarm
Use one of the methods below to reset a heater burnout alarm.
• Turn ON the Special I/O Unit Restart Bit (AR 0100 to AR 0109 for the
C200HX/HG/HE, C200HS, C200H and A50200 to A50209 for a CS-series
PC) and then turn it OFF.
• Turn the PC power supply OFF then back ON.
• Set the heater burnout current limit to 00 then back to its original value.
Temperature Alarm
Display
ALM1
indicator
lit
Error name
Temperature alarm 1
Cause
The temperature is in
the alarm range set
with Alarm SV 1.
Remedy
Check the temperature
of the measured body.
Check the set SP value.
Error displayed when an abnormality occurs in the loop currently being displayed. 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
Temperature alarm 1
Loop 1
Wd (n+9)
Bit 00
Bit 01
Temperature alarm 2
Temperature alarm 1
Loop 2
Bit 00
Temperature alarm 2
EEPROM Error
Display
e111
Error name
EEPROM
error
Output status after error
Cause
Control output:
Defective
The transistor output or volt- EEPROM
age output is OFF or the current output is less than 2 mA.
Alarm output is OFF.
Remedy
Replace
the Unit
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. SR 25415
(for C200HX/HG/HE, C200HS, C200H) or A40113 (for CS-series PC) will turn
ON when an Duplicate I/O Unit error occurs. Refer to AR0000 to AR0009 for
the C200HX/HG/HE, C200HS, C200H or to A41100 to A41109 for the CSseries PC for the duplicated unit number. The CPU Unit will not operate during
a duplicate I/O error.
Set the Unit number to a separate number.
Special I/O Unit Error
I/O refresh not operating correctly between the CPU Unit and Temperature
Control Unit. Operation is not interrupted when a Special I/O Unit error
occurs. Refer to AR 0000 to AR 0009 for the C200HX/HG/HE, C200HS,
C200H or to A41100 to A41109 for a CS-series PC for the unit number where
the error occurred. After correcting the cause of the error, turn ON the Special
I/O Unit Restart Bit (AR 0100 to AR0109 for the C200HX/HG/HE, C200HS,
C200H; A50200 to A50209 for a CS-series PC) to restart operation.
63
Section 5-1
Error Detection
RUN Indicator Unlit
The PC 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 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 Temperature Control Unit is defective.
After determining the cause of the error, correct the problem or replace the
Unit.
Temperature Control Not
Performed
Temperature control will not be performed in either one of the following cases.
• SW203-5 on the rear panel is set to ON and the CPU Unit is in PROGRAM mode.
• The Stop Bit (word n+2, bit 06 for loop 1 and bit 04 for loop 2) is ON.
Change to proper settings.
64
Appendix A
Specifications
General Specifications
Conforms to the CPU Unit specifications.
Item
[email protected]
Connectable temperature sen- Thermocouple (R, S, K, J, T, E, B, N, L, U)
sor (see note 1)
[email protected]
Platinum resistance thermometer (JPt100,
Pt100)
Current Transformer detection
current
0.1 to 4.9 A (with a heater burnout detecting current difference of 0.5 A min.)
Indication accuracy: ±5% FS ±1 digit max.
No. of input points (loops)
Temperature control mode
Two points (two loops, each of which consists of a temperature sensor and a CT)
PID, ON/OFF (selectable with a switch on the rear panel)
(PID control with feed-forward circuitry with auto-tuning)
±0.5% of set (designated) value or ±2°C
±0.5% of set (designated) value or ±1°C
whichever larger ±1 digit max.
whichever larger ±1 digit max.
Setting/Indication accuracy
(see note 2, 3 and 4)
Influence of temperature:
For ambient temperature
change from 0 to 23 to 55°C
Influence of voltage:
For change from −15% lower to
10% higher than rated voltage
Thermocouples R and S
±1% of set (designated) value or ±10°C,
whichever is larger, ±1 digit max.
Other Thermocouples
±1% of set (designated) value or ±4°C,
whichever is larger, ± 1 digit max.
CT Input
±0.25 A ±1 digit max.
Hysteresis
Proportional band
0.0° to 999.9°C/°F (in units of 0.1°C/°F) (during ON/OFF control action)
0.0° to 999.9°C/°F (in units of 0.1°C/°F)
Integral (reset) time
Derivative (rate) time
0 to 9999 s (in units of 1 s)
0 to 9999 s (in units of 1 s)
Control period
Sampling period
1 to 99 s (in units of 1 s)
500 ms
Output refresh period
Display refresh period
500 ms
500 ms
Input shift range
Alarm output setting range
–99.9° to 999.9°C/°F (in units of 0.1°C/°F)
–999° to 9,999°C/°F (in units of 1°C/°F)
No. of banks
Internal current consumption
8 banks
5 VDC, 0.33 A max.
External supply voltage
24 VDC +10%/–15%, 0.2 A min.
Dimensions (see note 4)
34.5 mm (W) x 130 mm (H) x 120.5 mm (D)
Weight
360 g
Platinum Resistance Thermometer
±1% of set (designated) value or ±2°C,
whichever is larger, ±1 digit max.
CT Input
±0.25 A ±1 digit max.
–99.9° to 999.9°C/°F (in units of 0.1°C/°F)
Note 1. Set with the switch on the rear panel. See Appendix B Sensor Temperature Measurement Range for
the 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. At an ambient temperature of 23°C.
5. See Appendix D Dimensions.
65
Appendix A
Specifications
Output Characteristics
Open-collector Output (Pulse) [email protected]
External supply voltage
24 VDC +10%/–15%
Max. load voltage
Max. load current
24 VDC max.
100 mA max.
Residual voltage when ON
Leakage current when OFF
3 V max.
0.3 mA max.
Voltage Output (Pulse) [email protected]
Output voltage
12 VDC
Max. load current
40 mA (with short-protective circuit)
Current Output (Linear) [email protected]
66
Output current
Permissible load impedance
4 to 20 mA
600 Ω max.
Current value accuracy
4±0.3 to 20±1 mA
Appendix B
Sensor Temperature Measurement Ranges
8
7
9 01
2
3
6 5 4
[email protected] 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
Range
R
Platinum vs.
platinum
rhodium
13%
S
Platinum
vs.
platinum
rhodium
10%
°C 0 to 1,700
0 to 1,700
°F
0 to 3,000
0 to 3,000
Switch set- 0
ting
1
K (CA)
Chromel vs.
alumel
–200 to
1,300
–300 to
2,300
2
J/L (IC)
Iron vs.
constantan
T/U (CC)
Copper vs.
constantan
E (CRC)
Chromel vs.
constantan
–100 to 850 –200 to 400 0 to 600
–100 to
1,500
3/8
–300 to 700 0 to 1,100
4/9
5
B
Platinum
rhodium
30% vs.
platinum
rhodium 6%
100 to
1,800
300 to
3,200
6
N
Nichrosil
vs. nisil
0 to 1,300
0 to 2,300
7
[email protected] Platinum Resistance Thermometer
OFF
ON
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
Range
JPt100
°C
°F
Switch setting
Pt100
–99.9 to 450.0
–99.9 to 800.0
–99.9 to 450.0
–99.9 to 800.0
OFF
ON
67
Appendix C
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 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 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.
• Turn ON the Special I/O Unit Restart Bit (AR 0100 to AR 0109 for the C200HX/HG/HE, C200HS, C200H
and A50200 to A50209 for the CS1) and then turn it OFF.
• Turn the PC power supply OFF then back ON.
• 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 0.5 A. Stable detection is difficult with a current difference less than 0.5 A.
• Heater burnout detection is not possible with the current output type ([email protected]) 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 =
Normal current value + heater burnout current
2
• 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 0.5 A. Stable detection is difficult with a current difference less than 0.5 A.
• Set the SV in the range between 0.1 A and 4.9 A. Heater burnout detection is not carried out if the SV is
set to 0.0 A or 5.0 A. The alarm signal is always OFF if the SV is set to 0.0 or always ON if the SV is set to
5.0.
• The total heater current during normal operation should not exceed 5 A. If the current exceeds 5.5 A, a CT
Input Overflow error occurs and ffff is displayed if the heater current monitor is selected.
Measure each current with the heater current monitor. In some cases the calculated current may differ from the
actual measured value.
69
Appendix C
Heater Burnout Detection
Sample SV Calculations
Example 1 Using one 200 VAC, 800 W heater
800
=4A
200
Normal current =
Burnout current = 0 A
SV =
4+0
= 2 A (≤ 4.9 A)
2
Example 2 Using three 100 VAC, 100 W heaters
Normal current =
100
x3=3A
100
Burnout current with one heater burned out =
SV =
100
x2=2A
100
3+2
= 2.5 A (≤ 4.9 A)
2
Difference between normal and burnout current = 3 − 2 = 1 A (≤ 0.5 A)
Specifications
Heater Burnout Detection Characteristics
Heater burnout detection setting range
0.1 to 4.9 A (in units of 0.1 A) (see note 1)
Current difference required for heater
burnout detection
0.5 A min. (normal time – burnout time)
Heater current monitor range
Monitor accuracy of input current
0.0 to 5.5 A
±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 5.0 A, no heater burnout detection is possible. 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 5.0 A.
2. If the control output is turned ON for less than 200 ms, no heater burnout detection or heater current
measurement is possible.
E54-CT1/CT3 Current Transformer
Max. continuous heater current
50 A
Dielectric strength
Vibration resistance
1,000 VAC (1 min)
50 Hz (approx. 10G)
Weight
Accessories (E54-CT3 only)
E54-CT1: approx. 11.5 g; E54-CT3: approx. 50 g
Contact: 2; Plug: 2
70
Appendix C
Heater Burnout Detection
Current Transformer Dimensions
21
E54-CT1
2.8
15
7.5
5.8 dia.
25
10.5
3
10
30
40
Two 3.5-dia. holes
2.36 dia.
30
E54-CT3
12 dia.
9
40
15
30
Two M3 holes with a depth of 4 mm
40
71
Appendix C
Heater Burnout Detection
Current Transformer Circuit Diagram
Control output
AC power supply
CT
Heater
To Temperature Control Unit
CT input terminal
To Temperature Control
Unit CT input terminal
(no polarity)
Heater cable
Current Transformer
72
Appendix D
Dimensions
Temperature Control Unit
Weight: 360 g
Unit Dimensions
130
34.5
20
100.5
11
120.5
131.5
Base unit
Mounting Dimensions
Approx. 200
17
73
Appendix D
Dimensions
Data Setting Console
Weight: 120 g
Unit Dimensions
96
91
12
48
3
45
44
57
Mounting Dimensions
Panel Cutout
Clearance
92 +0.8
0
45 +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.
74
Index
A–B
command codes
settings, 41
alarm hysteresis, 30
error display, 28
alarm mode setting, 29
errors
data setting, 62
allocating memory, 36
applications
precautions, xviii
auto-tuning start/stop setting, 33
bank number setting, 32
features, 2
F–H
Heater Burnout Alarm, 62
C
command codes
settings, 41
EEPROM write/read command, 41
RAM write command, 43
compensating conductors
specifications, 15
Connector Terminal Block Converter Unit, 19
control output variable monitor setting, 31
control period setting, 31
copy bank setting, 32
cover
removal and replacement, 11
CT input overflow error, 62
Current Transformer, 16
D
heater burnout current
See also settings
heater burnout detection
precautions and current ranges, 69
hysteresis setting, 32
I
I/O refresh, 59
indicators, 9
input shift value setting, 31
input wiring
Platinum Resistance Thermometer, 14, 16
precautions, 14
thermocouple, 13
installation
precautions, xviii
integral time setting, 33
memory contents, 38
data flow, 23
data setting, 23
operating procedure, 22
Data Setting Console
connecting cable and precautions, 19
features, 25
mounting, 74
parameter and setting tables, 26
physical features, 24
data settings, 44
derivative time setting, 33
detecting errors, 62
Duplicate I/O Unit, 63
E
M–O
operating environment
precautions, xvii
operating in PROGRAM mode, 12
Operation and Function Setting, 12
operation timing, 58
output wiring, 16
circuit diagrams, 17
connectors and cable, 18
diagrams, 17
precautions, 18
P
EEPROM error alarm, 63
PID control with feed-forward circuitry, 2
EEPROM write/read command
precautions, xv, 5
75
Index
applications, xviii
general, xvi
operating environment, xvii
safety, xvi
programming
examples, 44, 48
proportional band setting, 33
R
RAM write command
command codes
settings, 43
read operation timing, 59
refresh
I/O, 59
Remote I/O Terminal, 19
S
safety precautions, xvi
selecting allocated memory, 36
sensors
setting type, 11
sensor-type setting, 33
Set Value display
upper and lower limits, 28
setting and displaying parameters
method, 28
settings
heater burnout current, 30
source, 11
Slave Rack
number of mountable Units, 4
Special I/O Unit error, 63
specifications
general, table, 65
standby sequence, 30
switch settings, 9, 10
switching memory contents, 11
switching memory contents and setting direction, 10
system configuration, 4
T
temperature alarm, 63
temperature measurements
76
ranges, 67
troubleshooting
CT input overflow error, 62
data setting errors, 62
duplicate I/O unit, 63
EEPROM error, 63
power supply, 64
RUN Indicator Unlit, 64
Special I/O Unit error, 63
temperature alarm, 63
U
Unit
models, 4
Unit components
dimensions, 74
Unit nomenclature, 8
Revision History
A manual revision code appears as a suffix to the catalog number on the front cover of the manual.
Cat. No. W225-E1-05
Revision code
The following table outlines the changes made to the manual during each revision. Page numbers refer to the
previous version.
Revision code
Date
Revised content
1
1A
August 1993
July 1995
2
September 1996
Pages 35 to 39: Loop 1 STOP, Loop 2 STOP, and STOP data items added to
the tables.
Pages 39 and 40: EEPROM Write/Read Command title added to table and the
RAM Write Command table added.
Page 48: 4-3-5 I/O Refresh added.
3
March 2000
04
December 2001
Added precautions to beginning of manual and changed “C200H PC” to either
“PC” or “CPU Unit” throughout the manual.
Page 3: Added a table of applicable CPU Units.
Page 4: Modified number of units mountable on Slave Rack in the table.
Page 4: Added information on new functions.
Page 9: Added information on Stop Bits and Stop Flags.
Page 11: Changed screw tightening torque.
Pages 20, 21, 25: Changed descriptions of data setting.
Page 23: Added Stop Bit information to the Data Display note.
Page 30: Added Stop Bit information to Changing the Settings.
Page 34: Added memory allocation information for the CS1.
Page 45: Modified sample program for write request.
Page 49: Added programming examples for the CS1.
Page 53, 59: Changed SR bit and restart bit.
Page 53: Added information on cases where temperature control is not performed.
Page xiii: Added Power Supply Units to WARNING sub-item.
Page 4: Added C200H-CPU-22-E to Applicable CPU Units table.
Page 15: Reversed A and B in Voltage/Current Output figure.
Pages 49 and 56: Changed 23208 to 23209.
05
December 2005
Original production
Page 40: Note 1 corrected.
"CS1" changed to "CS" throughout manual in reference to OMRON PC Series.
Page xii: Safety precautions added.
Page xiv: Two precautions added toward top of page and three corrections/
additions made to existing precautions.
Page 65: Influence of temperature and influence of voltage specifications
added, and note added.
77
OMRON Corporation
Control Devices Division H.Q.
Shiokoji Horikawa, Shimogyo-ku,
Kyoto, 600-8530 Japan
Tel: (81)75-344-7109/Fax: (81)75-344-7149
Regional Headquarters
OMRON EUROPE B.V.
Wegalaan 67-69, NL-2132 JD Hoofddorp
The Netherlands
Tel: (31)2356-81-300/Fax: (31)2356-81-388
OMRON ELECTRONICS LLC
1 East Commerce Drive, Schaumburg, IL 60173
U.S.A.
Tel: (1)847-843-7900/Fax: (1)847-843-8568
OMRON ASIA PACIFIC PTE. LTD.
83 Clemenceau Avenue,
#11-01, UE Square,
Singapore 239920
Tel: (65)6835-3011/Fax: (65)6835-2711
OMRON (CHINA) CO., LTD.
Room 2211, Bank of China Tower,
200 Yin Cheng Zhong Road,
PuDong New Area, Shanghai, 200120 China
Tel: (86)21-5037-2222/Fax: (86)21-5037-2200
Authorized Distributor:
Cat. No. W225-E1-05
Note: Specifications subject to change without notice.
This manual is printed on 100% recycled paper.
Printed in Japan
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