OPERATION MANUAL Analog I/O Units

OPERATION MANUAL Analog I/O Units
Cat. No. W368-E1-10
SYSMAC
CS Series
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CJ Series
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Analog I/O Units
OPERATION MANUAL
CS Series
[email protected]@/[email protected]@/[email protected]@/[email protected]@/
[email protected]@/[email protected]@
CJ Series
[email protected]@/[email protected]@/PH41U
Analog I/O Units
Operation Manual
Revised July 2008
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 “PLC” means Programmable Controller. “PC” is used, however, in some Programming Device displays to mean Programmable Controller.
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, 2000
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 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . xvii
1
Intended Audience . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xviii
2
General Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xviii
3
Safety Precautions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xviii
4
Operating Environment Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xix
5
Application Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xx
6
Conformance to EC Directives . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xxii
SECTION 1
Overview and Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1
1-1
Overview of Analog I/O Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2
1-2
Features and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7
1-3
System Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
24
1-4
Specifications and Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26
1-5
Operating Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
55
1-6
Error Processing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
57
1-7
Specification Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
61
SECTION 2
Individual Unit Descriptions for CS Series . . . . . . . . . . . . . . .
67
2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . .
68
2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
80
2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
97
2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
109
2-5
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100). . . . . . . . .
121
2-6
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4) . . . . . . . . . . . . . . .
132
2-7
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
142
2-8
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100) . . . . . . . . . .
157
2-9
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100) . . . . . . . . . .
167
2-10 CS1W-PTW01 2-Wire Transmitter Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
177
2-11 CS1W-PDC01 Isolated-type Direct Current Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
189
2-12 CS1W-PDC11 Isolated-type Direct Current Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
200
2-13 CS1W-PDC55 Isolated-type Direct Current Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
218
2-14 CS1W-PTR01 Power Transducer Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
229
2-15 CS1W-PTR02 Analog Input Unit (100 mV). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
238
2-16 CS1W-PPS01 Isolated-type Pulse Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
247
2-17 CS1W-PMV01 Isolated-type Analog Output Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
258
2-18 CS1W-PMV02 Isolated-type Analog Output Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
267
vii
TABLE OF CONTENTS
SECTION 3
Individual Unit Descriptions for CJ Series . . . . . . . . . . . . . . . 275
3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
276
3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
288
3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100). . . . . . . . . . .
302
3-4
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
312
3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
324
3-6
CJ1W-PH41U Isolated-type Universal Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
338
Appendices
A
Supplementary Explanation of Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
365
B
Zero/Span Adjustment Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
375
Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 379
Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 383
viii
About this Manual:
This manual describes the installation and operation of the CS/CJ-series Analog I/O Units and
includes the sections described below.
In this manual, “Analog I/O Units” is a product group name for the following groups of Units.
Name
CS-series
Isolated-type Thermocouple Input Unit
Model number
CS1W-PTS01-V1
CS1W-PTS11
CS1W-PTS51
CS1W-PTS55
Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100) CS1W-PTS02
Isolated-type Resistance Thermometer Input Unit (Ni508.4)
CS1W-PTS03
Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100,
Pt50, or Ni508.4)
Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
CS1W-PTS52
Isolated-type 2-Wire Transmitter Input Unit
CS1W-PTS56
CS1W-PTW01
Isolated-type Direct Current Input Unit
CJ-series
CS1W-PTS12
CS1W-PDC01
CS1W-PDC11
Power Transducer Input Unit
CS1W-PDC55
CS1W-PTR01
Analog Input Unit
Isolated-type Pulse Input Unit
CS1W-PTR02
CS1W-PPS01
Isolated-type Analog Output Unit
Isolated-type Thermocouple Input Unit
CS1W-PMV01/PMV02
CJ1W-PTS51/15
Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Isolated-type Resistance Thermometer input (Pt100, JPt100, Pt50
or Ni508.4)
CJ1W-PTS52
CJ1W-PTS16
Isolated-type Direct Current Input Unit
Isolated-type Universal Input Unit
CJ1W-PDC15
CJ1W-PH41U
Please read this manual carefully and be sure you understand the information provided before
attempting to install and operate the Analog I/O Units.
Precautions provides general precautions for using the CS/CJ-series Programmable Controllers
(PLCs) and related devices.
Section 1 presents an overview of the CS/CJ-series Analog I/O Units, and outlines their features.
Section 2 describes each of the CS-series Analog I/O Units in detail.
Section 3 describes each of the CJ-series Analog I/O Units in detail.
Appendix A provides a supplementary explanation of Unit functions.
Appendix B provides an example of zero/span adjustment.
!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
Related Manuals
The following table describes the CS/CJ-series manuals that are related to the Analog I/O Units.
Cat. No.
W368 (this
manual)
Model
[email protected]@/
[email protected]@/[email protected]@/
[email protected]@/[email protected]@/
[email protected]@
[email protected]@/
[email protected]@/PH41U
W339
CS1G/[email protected]@H,
SYSMAC CS-series
CS1G/[email protected]@-EV1 PLCs Operation
Manual
W405
[email protected]@H,
[email protected]@S,
CS1D-DPL01, CS1DPA207R
SYSMAC CS-series Basic information
Duplex System Oper- and procedures for
ation Manual
CS-series Duplex
Systems.
Provides an outline of and
describes the design, installation,
maintenance, and other basic operations for a Duplex System based
on CS1D CPU Units.
W393
[email protected]@H-R
CJ1G/[email protected]@H
[email protected]@P
[email protected]@
[email protected]@
CJ-series PLCs
Operation Manual
Basic CJ-series PLC
information, including an overview,
design, installation,
and maintenance.
Provides the following information
on CJ-series PLCs:
• Overview and features
• System configuration design
• Installation and wiring
• I/O memory allocations
• Troubleshooting
W394
CS1G/[email protected]@H
CS/CJ/NSJ-series
CS1G/[email protected]@-V1
PLCs Programming
[email protected]@H
Manual
[email protected]@S
[email protected]@H-R
CJ1G/[email protected]@H
[email protected]@P
[email protected]@
[email protected]@
[email protected]@@@@(B)-G5D
[email protected]@@@@(B)-M3D
Information on the
operation o f CS/CJ/
NSJ-series PLCs.
Provides the following information
on CS/CJNSJ-series PLCs:
• Programming
• Task functions
• File memory
• Various operations
W340
CS1G/[email protected]@H
CS/CJ/NSJ-series
CS1G/[email protected]@-V1
PLCs Instructions
[email protected]@H
Reference Manual
[email protected]@S
[email protected]@H-R
CJ1G/[email protected]@H
[email protected]@P
[email protected]@
[email protected]@
[email protected]@@@@(B)-G5D
[email protected]@@@@(B)-M3D
Detailed information
on instructions.
Describe all the ladder programming instructions in detail.
x
Manual name
CS/CJ-series
Analog I/O Units
Operation Manual
Application
Contents
Information on using Provides information on using the
the Analog I/O Units. CS/CJ-series Analog Input, Analog
Output, and Analog I/O Units.
Basic CS-series PLC
information, including an overview,
design, installation,
and maintenance.
Provides the following information
on CS-series PLCs:
• Overview and features
• System configuration design
• Installation and wiring
• I/O memory allocations
• Troubleshooting
Cat. No.
W446
Model
WS02-CXPC1-EV7
Manual name
CX-Programmer
Operation Manual
(Version [email protected])
W341
CQM1H-PRO01
CQM1-PRO01
C200H-PRO27
+ CS1W-KS001
CS/CJ-series Programming Console
Operation Manual
Application
Information on using
the CX-Programmer
(programming software for a personal
computer running
Windows).
Information on using
the Programming
Console.
Contents
Describes how to use the CX-Programmer.
Describes how to use the Programming Console.
xi
xii
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.
xiii
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.
xiv
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.
xv
xvi
PRECAUTIONS
This section provides general precautions for using the CS/CJ-series Programmable Controllers (PLCs) and related
devices.
The information contained in this section is important for the safe and reliable application of Programmable
Controllers. You must read this section and understand the information contained before attempting to set up
or operate a PLC system.
1
Intended Audience . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xviii
2
General Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xviii
3
Safety Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xviii
4
Operating Environment Precautions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xix
5
Application Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xx
6
Conformance to EC Directives. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xxii
6-1
Applicable Directives. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xxii
6-2
Concepts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xxii
6-3
Conformance to EC Directives . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xxiii
6-4
Conditions for Complying with EC Directives . . . . . . . . . . . . . . . .
xxiii
xvii
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 operation 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 PLC and all PLC 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 PLC 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 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 PLC or another external factor
affecting the PLC 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.
• Unless otherwise stated, the PLC will turn OFF all outputs when its selfdiagnosis function detects any error or when a severe failure alarm
(FALS) instruction is executed. (The operation of outputs from Analog
Output Units is described later in this manual.) As a countermeasure for
such errors, external safety measures must be provided to ensure safety
in the system. (The external alarm output on the CS1W-PTS51/PTS52,
CJ1W-PTS51/PTS52, however, will be ON.)
• The PLC outputs may remain ON or OFF due to deposition 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-VDC output (service power supply to the PLC) 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.
xviii
Operating Environment Precautions
4
!WARNING Always turn OFF the power supply to the PLC before attempting any of the following. Not turning OFF the power supply may result in malfunction or electric
shock.
• Mounting or dismounting the Power Supply Units, I/O Units, CPU 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.
!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 Do not apply a voltage or current outside the specified range to any Unit.
Doing so may result in malfunction or fire.
!Caution Execute online edit only after confirming that no adverse effects will be
caused by extending the cycle time. Otherwise, input signals may not be readable.
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.
Locations subject to strong electromagnetic fields.
Locations subject to possible exposure to radioactivity.
Locations close to power supplies.
!Caution The operating environment of the PLC 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 PLC
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.
xix
5
Application Precautions
!Caution When connecting a personal computers or other peripheral devices to a PLC
to which a non-insulated Power Supply Unit (CJ1W-PD022) is mounted, either
ground the 0 V side of the external power supply or do not ground the external
power supply at all ground. A short-circuit will occur in the external power supply if incorrect grounding methods are used. Never ground the 24 V side, as
shown below.
Wiring in Which the 24-V Power Supply Will Short
Non-insulated
24 V DC power supply
0V
FG
Peripheral
cable
0V
Power Supply
Unit
CPU Unit
0V
Peripheral device
(e.g., personal computer)
FG
!Caution Do not connect a Relay Contact Output Unit in the same CPU Rack or Expansion Rack as the CJ1W-PH41U Isolated-type Universal Input Unit. Doing so
may cause the process values to be abnormal, resulting in unexpected operation in machinery or equipment.
5
Application Precautions
Observe the following precautions when using the Analog I/O Unit.
• If any one of cold junction compensating elements is disconnected, no
compensation will be performed, resulting in improper temperature measurement. Do not disconnect cold junction compensating elements.
(Applicable to the CS1W-PTS01-V1, PTS11/PTS51/PTS55, CJ1WPTS51/PTS15 Isolated-type Thermocouple Input Unit or CJ1W-PH41U
Isolated-type Universal Input Unit.)
• Each cold junction compensation element is calibrated for the individual
Unit and connected circuit; do not use elements from other Units or
replace two elements of the same Unit. Doing so will result in improper
temperature measurement. Use elements attached at the time of product
delivery. (Applicable to the CS1W-PTS01-V1, PTS11/PTS51/PTS55,
CJ1W-PTS51/PTS15 Isolated-type Thermocouple Input Unit or CJ1WPH41U Isolated-type Universal Input Unit.)
• If the external 24-V power supply for the CJ1W-PTS15/PTS16 or CJ1WPDC15 drops below the specified voltage range, the Power Supply Flag
will turn OFF, the Sensor Error Flag will turn ON, and the conversion data
will be fixed at the upper limit or lower limit values. Prevent this effect on
the control system operation by using these flags in the input data read
conditions or implement other measures in the user program.
• When using the CS1W-PTS15/PTS16 or CS1W-PDC15, make sure that
the external 24-VDC power supply is isolated.
• Check the user program for proper execution before actually running it on
the Unit. Not checking the program may result in an unexpected operation.
• 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.
• Install a breaker or take other safety measures against short-circuiting of
external wiring.
• 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 PLC (including the setting of the
startup operating mode).
xx
5
Application Precautions
• Force-setting/force-resetting any bit in memory.
• Changing the present value of any word or any set value in memory.
• 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.
• Be sure that the terminal blocks, expansion cables, and other items with
locking devices are properly locked into place. Improper locking may
result in malfunction.
• Take appropriate measures to ensure that the specified power with the
rated voltage and frequency is supplied in places where the power supply
is unstable. An incorrect power supply 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.
• Use crimp terminals for wiring. Do not connect bare stranded wires
directly to terminals. Connection of bare stranded wires may result in
burning.
• Be sure to use the power supply voltage specified in this manual.
• Do not apply voltages to the input section in excess of the rated input voltage. Excess voltages may result in burning.
• Do not apply voltages or connect loads to the output section in excess of
the maximum switching capacity. Excess voltage or loads may result in
burning.
• Double-check all wiring, switch settings, and data memory (DM) settings
before turning ON the power supply. Incorrect wiring may result in burning.
• 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 drop the product or subject it to excessive vibration or shock.
• Touch a grounded piece of metal to discharge static electricity from your
body before touching a Unit.
• Check the terminal block completed before mounting it.
• Install circuit breakers or take other countermeasures against short-circuits in external wiring.
• Install Units as far as possible away from devices that generate strong,
high-frequency noise.
• Check to be sure that all switches and memory contents, such as the DIP
Switches and the contents of the DM Area) are correct before starting
operation.
• Do not pull on cables or bend them past their natural bending radius.
• Do not place any objects on top of cables.
• When wiring crossovers between terminals, the total current for both terminals will flow in the line. Check the current capacities of all wires before
wiring crossovers.
• The following precautions apply to Power Supply Units with Replacement
Notification.
• When the LED display on the front of the Power Supply Unit starts to
alternately display “0.0” and “A02” or the alarm output automatically
turns OFF, replace the Power Supply Unit within 6 months.
• Separate the alarm output cables from power lines and high-voltage
lines.
xxi
6
Conformance to EC Directives
• Do not apply a voltage or connect a load to the alarm output that exceeds the rated voltage or load.
• Maintain an ambient storage temperature of −20 to 30°C and humidity
of 25% to 70% when storing the product for longer than 3 months to
keep the replacement notification function in optimum working condition.
• Always use the standard installation method. A nonstandard installation will decrease heat dissipation, delay the replacement notification
signal, and may degrade or damage the internal elements.
• Design the system so that the power supply capacity of the Power Supply
Unit is not exceeded.
• Do not touch the terminals on the Power Supply Unit immediately after
turning OFF the power supply. Electric shock may occur due to the residual voltage.
• The product is EMC compliant when assembled in a complete PLC system of the specified PLC series. For earthing, selection of cable, and any
other conditions for EMC compliance, refer the manual for installation.
• This is a class A product. In residential areas it may cause radio interference, in which case the user may be required to take adequate measures
to reduce interference.
6
6-1
Conformance to EC Directives
Applicable Directives
• EMC Directives
• Low Voltage Directive
6-2
Concepts
EMC Directives
OMRON devices that comply with EC Directives also conform to the related
EMC standards so that they can be more easily built into other devices or the
overall machine. The actual products have been checked for conformity to
EMC standards (see the following note). Whether the products conform to the
standards in the system used by the customer, however, must be checked by
the customer.
EMC-related performance of the OMRON devices that comply with EC Directives will vary depending on the configuration, wiring, and other conditions of
the equipment or control panel on which the OMRON devices are installed.
The customer must, therefore, perform the final check to confirm that devices
and the overall machine conform to EMC standards.
Note Applicable EMC (Electromagnetic Compatibility) standards are as follows:
EMS (Electromagnetic Susceptibility): EN61000-6-2
EMI (Electromagnetic Interference): EN61000-6-4
(Radiated emission: 10-m regulations)
Low Voltage Directives
Always ensure that devices operating at voltages of 50 to 1,000 V AC and 75
to 1,500 V DC meet the required safety standards for the PLC (EN61131-2).
xxii
6
Conformance to EC Directives
6-3
Conformance to EC Directives
The CS/CJ-series PLCs comply with EC Directives. To ensure that the
machine or device in which a CS/CJ-series PLC is used complies with EC
Directives, the PLC must be installed as follows:
• The CS/CJ-series PLC must be installed within a control panel.
• You must use reinforced insulation or double insulation for the DC power
supplies used for the communications power supply and I/O power supplies.
• CS/CJ-series PLCs complying with EC Directives also conform to the
Common Emission Standard (EN61000-6-4). Radiated emission characteristics (10-m regulations) may vary depending on the configuration of
the control panel used, other devices connected to the control panel, wiring, and other conditions. You must therefore confirm that the overall
machine or equipment complies with EC Directives.
6-4
Conditions for Complying with EC Directives
The following condition was used in the immunity test of the CS1W-PTS11/
PTS12, PDC11, CJ1W-PTS15/PTS16, CJ1W-PDC15 and CJ1W-PH41U
Analog I/O Units.
• Standard accuracy: ±5%
The following conditions were used in the immunity test of the CS1W-PTS51/
PTS52/PTS55/PTS56, PDC55 and CJ1W-PTS51/PTS52.
CS1W-PTS51 R or S thermocouple
CS1W-PTS55
CJ1W-PTS51 K, J, T, or L thermocouple
±1% of PV or ±10°C, whichever is larger,
±1 digit
±1% of PV or ±4°C, whichever is larger,
±1 digit
CS1W-PTS52 ±1% of PV or ±2°C, whichever is larger, ±1 digit
CS1W-PTS56
CJ1W-PTS52
CS1W-PDC55 ±1% of FS max.
xxiii
Conformance to EC Directives
xxiv
6
SECTION 1
Overview and Features
This section presents an overview of the CS/CJ-series Analog I/O Units and outlines their features.
1-1
Overview of Analog I/O Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2
1-1-1
CS-series Analog I/O Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2
1-1-2
CJ-series Analog I/O Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5
1-2
Features and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7
1-3
System Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
24
1-4
Specifications and Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26
1-4-1
Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
26
1-4-2
Nomenclature and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
28
1-4-3
Exchanging Data with the CPU Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
34
1-4-4
Mounting the Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
48
1-4-5
Precautions when Handling Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
50
1-4-6
Connecting Crimp Terminals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
52
1-4-7
Dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
52
Operating Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
55
1-5
1-6
Error Processing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
57
1-7
Specification Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
61
1-7-1
CS1W-PTS01-V1, CS1W-PTS02/PTS03, CS1W-PTW01, CS1W-PDC01,
CS1W-PPS01, and CS1W-PMV01 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
61
1-7-2
CS1W-PTS51/PTS52 and CJ1W-PTS51/PTS52 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
63
1-7-3
CS1W-PTS55 and CS1W-PDC55 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
64
1
Section 1-1
Overview of Analog I/O Units
1-1
Overview of Analog I/O Units
1-1-1
CS-series Analog I/O Units
There are 18 Analog I/O Unit models, as shown in the following table.
Name
Model
Number Resoluof I/O
tion
Conversion
period
Isolatedtype Thermocouple
Input Unit
CS1WPTS01V1
4 inputs 1/4,096
150 ms/
4 inputs
All inputs
are isolated.
• Thermocouple: • Variable range setting
B, E, J, K, N, R, • Process value scaling
S, T, mV
• Process value alarm
• Mean value processing
• Rate-of-change calculation and
alarm
• Alarm-ON delay
• Disconnection detection
CS1WPTS11
4 inputs 1/64,000 20 ms/
4 inputs
10 ms/
2 inputs
All inputs
are isolated.
• Thermocouple:
B, E, J, K, L, N,
R, S, T, U,
WRe5-26, PL II
• DC voltage:
±100 mV
CS1WPTS51
CS1WPTS55
4 inputs ---
250 ms/
4 inputs
Field I/O
isolation
All inputs
are isolated.
8 inputs ---
250 ms/
8 inputs
All inputs
are isolated.
IsolatedCS1Wtype Resis- PTS02
tance
Thermometer Input
Unit
(Pt100,
JPt100)
4 inputs 1/4,096
100 ms/
4 inputs
All inputs
are isolated.
IsolatedCS1Wtype Resis- PTS03
tance
Thermometer Input
Unit
(Ni508.4)
4 inputs 1/4,096
2
100 ms/
4 inputs
All inputs
are isolated.
I/O type
• Thermocouple:
B, J, K, L, R, S,
T
Main functions
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
• Thermocouple: •
B, J, K, L, R, S, •
T
•
•
• Resistance ther- •
mometer:
•
Pt100 (JIS,
•
IEC), JPt100
•
•
•
•
• Resistance ther- •
mometer:
•
Ni508.4
•
•
•
•
•
Variable range setting
Process value scaling
Process value alarm
Mean value processing
Rate-of-change calculation and
alarm
Alarm-ON delay
Disconnection detection
Adjustment period control
Peak and bottom values
Top and valley values
Zero/span adjustment
Process value alarm (with
external alarm)
Sensor error detection
Alarm-ON delay
Zero/span adjustment
Process value alarm
Sensor error detection
Alarm-ON delay
Zero/span adjustment
Variable range setting
Process value scaling
Process value alarm
Mean value processing
Rate-of-change calculation and
alarm
Alarm-ON delay
Disconnection detection
Variable range setting
Process value scaling
Process value alarm
Mean value processing
Rate-of-change calculation and
alarm
Alarm-ON delay
Disconnection detection
Section 1-1
Overview of Analog I/O Units
Name
Model
Number Resoluof I/O
tion
Conversion
period
Field I/O
isolation
IsolatedCS1Wtype Resis- PTS12
tance
Thermometer Input
Unit
(Pt100,
JPt100,
Pt50,
Ni508.4)
4 inputs 1/64,000 20 ms/
4 inputs
10 ms/
2 inputs
Isolatedtype Resistance
Thermometer Input
Unit
(Pt100,
JPt100)
Isolatedtype Resistance
Thermometer Input
Unit
(Pt100,
JPt100)
Isolatedtype 2Wire
Transmitter Input
Unit
CS1WPTS52
4 inputs ---
250 ms/
4 inputs
All inputs
are isolated.
CS1WPTS56
8 inputs ---
250 ms/
8 inputs
CS1WPTW01
4 inputs 1/4,096
100 ms/
4 inputs
All inputs
are isolated.
I/O type
Main functions
•
•
•
•
•
•
• Resistance ther- •
mometer:
Pt100 (JIS,
•
IEC), JPt100
•
•
Variable range setting
Process value scaling
Process value alarm
Mean value processing
Rate-of-change calculation and
alarm
Alarm-ON delay
Disconnection detection
Adjustment period control
Peak and bottom values
Top and valley values
Zero/span adjustment
Process value alarm (with
external alarm)
Sensor error detection
Alarm-ON delay
Zero/span adjustment
All inputs
are isolated.
• Resistance thermometer:
Pt100 (JIS,
IEC), JPt100
•
•
•
•
Process value alarm
Sensor error detection
Alarm-ON delay
Zero/span adjustment
All inputs
are isolated.
4 to 20 mA from
2-wire transmitter.
• DC current:
4 to 20 mA
• DC voltage:
1 to 5 V
• Built-in power supply for 2-wire
transmitter
• Process value scaling
• Process value alarm
• Mean value processing
• Rate-of-change calculation and
alarm
• Alarm-ON delay
• Input error detection
• Resistance thermometer:
Pt100, JPt100,
Pt50, Ni508.4
•
•
•
•
•
3
Section 1-1
Overview of Analog I/O Units
Name
Model
IsolatedCS1Wtype Direct PDC01
Current
Input Unit
CS1WPDC11
CS1WPDC55
Number Resoluof I/O
tion
Conversion
period
4 inputs 1/4,096
100 ms/
4 inputs
All inputs
are isolated.
4 inputs 1/64,000 20 ms/
4 inputs
10 ms/
2 inputs
All inputs
are isolated.
Field I/O
isolation
I/O type
• DC voltage:
–10 to 10 V,
0 to 10 V,
–5 to 5 V,
0 to 5 V,
1 to 5 V, ±10 V
user-set range
• DC current:
4 to 20 mA,
0 to 20 mA
• DC voltage:
0 to 1.25 V,
–1.25 to 1.25 V,
0 to 5 V,
1 to 5 V,
–5 to 5 V,
–10 to 10 V,
0 to 10 V, ±10 V
user-set
• DC current:
0 to 20 mA
4 to 20 mA
8 inputs 1/16,000 250 ms/
8 inputs
All inputs
are isolated.
Power
CS1WTransPTR01
ducer Input
Unit
8 inputs 1/4,096
200 ms/
8 inputs
No isolation • Input from a
power transbetween
ducer:
inputs
–1 to 1 mA,
0 to 1 mA
CS1WPTR02
8 inputs 1/4,096
200 mA/
8 inputs
4 inputs ---
100 mA/
4 inputs
Analog
Input Unit
(100 mV)
IsolatedCS1Wtype Pulse PPS01
Input Unit
4
• DC voltage:
0 to 5 V,
1 to 5 V,
0 to 10 V
• DC current:
4 to 20 mA
Main functions
•
•
•
•
•
Process value scaling
Square root
Process value alarm
Mean value processing
Rate-of-change calculation and
alarm
• Alarm-ON delay
• Input error detection
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Variable range setting
Process value scaling
Square root
Mean value processing
Rate-of-change calculation and
alarm
Alarm-ON delay
Input error detection
Adjustment period control
Peak and bottom values
Top and valley values
Zero/span adjustment
Integral value calculation
Process value scaling
Square root
Process value alarm
Input error detection
• Anti-overshooting at motor
startup
• Square root
• Process value alarm
• Inrush input limit
• Alarm-ON delay
• Mean value processing
No isolation • DC voltage:
• Process value scaling
–100 to 100 mV, • Process value alarm
between
0 to 100 mV
inputs
• Inrush input limit
• Alarm-ON delay
• Mean value processing
All inputs
are isolated.
• No-voltage
semiconductor
input: 0 to
20,000 pulses/s
• Voltage input:
0 to
20,000 pulses/s
• Contact input:
0 to 20 pulses/s
• Sensor power supply:
12 V DC, built-in
• Instantaneous value scaling
• Mean value processing
• Instantaneous value alarm
• Alarm-ON delay
• Accumulated value output
Section 1-1
Overview of Analog I/O Units
Name
Model
Number Resoluof I/O
tion
Conversion
period
Field I/O
isolation
I/O type
Isolatedtype Analog Output
Unit
CS1WPMV01
4 outputs
1/4,096
100 ms/ All outputs
4 outputs are isolated.
• DC current:
4 to 20 mA
• DC voltage:
1 to 5 V
•
•
•
•
•
CS1WPMV02
4 outputs
1/16,000 40 ms/
All outputs
4 outputs are isolated.
1/8,000
• DC voltage:
−10 to 10 V,
−1 to 1 V
• Output rate-of-change limit
• Output high/low limits
• Output hold when CPU Unit
error occurs
1/4,000
1-1-2
0 to 10 V,
0 to 1 V
−5 to 5 V
Main functions
Output disconnection alarm
Answer input
Output rate-of-change limit
Output high/low limits
Output hold when CPU Unit
error occurs
• Output disconnection detection
0 to 5 V,
CJ-series Analog I/O Units
There are 6 Analog I/O Unit models, as shown in the following table.
Name
Isolatedtype Thermocouple
Input Unit
Isolatedtype Resistance
Thermometer Input
Unit
(Pt100,
JPt100)
Model
Number Resoluof I/O
tion
ConverField I/O
sion
isolation
period
250 ms/ All inputs are
4 inputs isolated.
CJ1WPTS51
4 inputs ---
CJ1WPTS15
2 inputs 1/64000
10 ms/
2 inputs
All inputs are
isolated.
CJ1WPTS52
4 inputs ---
250 ms/
4 inputs
All inputs are
isolated.
CJ1WPTS16
2 inputs 1/64000
10 ms/
2 inputs
All inputs are
isolated.
I/O type
• Thermocouple:
B, J, K, L, R, S,
T
Main functions
• Process value alarm (with
external alarm
• Sensor error detection
• Alarm-ON delay
• Zero/span adjustment
• Process value alarm (with
external alarm
• Alarm-ON delay
• Sensor error detection
• Zero/span adjustment
• External 24-VDC power supply
• Resistance ther- • Process value alarm (with
mometer:
external alarm)
Pt100 (JIS,
• Sensor error detection
IEC), JPt100
• Alarm-ON delay
• Zero/span adjustment
• Thermocouple:
B, E, J, K, L, N,
R, S, T, U,
WRe5-26, PLII
• DC voltage:
±100 mV
• Resistance thermometer:
Pt100 (JIS,
IEC), JPt100,
Pt50, Ni508.4
• Process value alarm (with
external alarm)
• Alarm-ON delay
• Sensor error detection
• Zero/span adjustment
• External 24-VDC power supply
5
Section 1-1
Overview of Analog I/O Units
Name
Model
Number Resoluof I/O
tion
Conversion
period
IsolatedCJ1Wtype Direct PDC15
Current
Input Unit
2 inputs 1/64000
10 ms/
2 inputs
Isolatedtype Universal
Input Unit
6
CJ1WPH41U
Field I/O
isolation
All inputs are
isolated.
4 inputs Select from the fol- All inputs are
lowing three modes: isolated.
Mode 1:
Resolution:
1/256,000
Conversion
period: 60 ms/
4 inputs
Mode 2:
Resolution:
1/64,000
Conversion
period: 10 ms/
4 inputs
Mode 3:
Resolution:
1/16,000
Conversion
period: 5 ms/
4 inputs
I/O type
Main functions
• DC voltage
0 to 1.25 V,
−1.25 to
+1.25 V,
0 to 5 V,
1 to 5 V,
−5 to +5 V,
0 to 10 V,
−10 to +10 V,
±10 V user set
range
• DC current
0 to 20 mA
4 to 20 mA
•
•
•
•
•
• Resistance thermometer:
Pt100 (3-wire),
JPt100, Pt1000,
Pt100 (4-wire)
• Thermocouple
K, J, T, E, L, U,
N, R, S, B,
WRe5-26, PLII
• DC voltage:
1 to 5 V,
0 to 1.25 V,
0 to 5 V,
0 to 10 V,
±100 mV,
−1.25 to 1.25 V,
−5 to 5 V,
−10 to 10 V
• DC current:
0 to 20 mA,
4 to 20 mA
• Potentiometer
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Variable range setting
Process value scaling
Square root processing
Mean value processing
Rate-of-change calculation
and alarm
Alarm-ON delay
Input error detection
Adjustment period control
Peak and bottom detection
Top and valley detection
Zero/span adjustment
Integral value calculation
External 24-VDC power supply
Variable input range setting
Process value scaling
Offset compensation
Process value alarm
Rate-of-change calculation
and alarm
Alarm ON/OFF delay
Square root extraction
Mean value processing
Input error detection
Adjustment period control
Peak and bottom detection
Top and valley detection
Zero/span adjustment
Integral value calculation
Section 1-2
Features and Functions
1-2
Features and Functions
I/O Isolation
The Analog I/O Units listed below have isolation between inputs or outputs.
Therefore sneak circuits do not occur between thermocouples or between the
power supply’s common voltage inputs, so there is no need to utilize a signal
converter to prevent sneak circuits.
Applicable Units
Isolated-type Thermocouple
Input Units
Isolated-type Resistance
Thermometer Input Units
CS1W-PTS01-V1/11/51/55,
CJ1W-PTS51/15
CS1W-PTS02/03/12/52/56,
CJ1W-PTS52/16
Isolated-type 2-Wire Transmit- CS1W-PTW01
ter Input Unit
Isolated-type Direct Current
Input Units
CS1W-PDC01/11/55,
CJ1W-PDC15
Isolated-type Pulse Input Unit CS1W-PPS01
Isolated-type Analog Output
CS1W-PMV01/PMV02
Units
Isolated-type Universal Input
Unit
CJ1W-PH41U
Analog I/O Unit
Isolation
Isolation
Isolation
Variable Input Range
Setting
For the Analog I/O Units listed below, the input range can be set by the user
according to the application. This function applies to the following Units:
Applicable Units
Note
Isolated-type Thermocouple
Input Units
CS1W-PTS01-V1/11,
CJ1W-PTS15
Isolated-type Resistance
Thermometer Input Units
Isolated-type Direct Current
Input Units
Isolated-type Universal Input
Unit
CS1W-PTS02/12,
CJ1W-PTS16
CS1W-PDC01/11,
CJ1W-PDC15
CJ1W-PH41U
The accuracy and resolution of the CS1W-PTS01-V1, CS1W-PTS02, and
CS1W-PDC01 are in respect to the internal ranges.
Measurable temperature range
−200°C
1300°C
400°C
Zero
Operating
temperature
Span
range
7
Section 1-2
Features and Functions
Process Value (or
Instantaneous Value)
Scaling in Industrial Units
This function takes the value scaled in industrial units with respect to the input
signal’s zero point and span point, and transfers it to the CPU Unit as the process value. Because of this, no ladder program is required at the CPU Unit for
scaling.
Note It also possible to set the process value scaling zero/span point in reverse to
create an inverse relationship.
Applicable Units
Isolated-type Thermocouple
Input Units
CS1W-PTS01-V1/11,
CJ1W-PTS15
Isolated-type Resistance
Thermometer Input Units
CS1W-PTS02/03/12,
CJ1W-PTS16
Isolated-type 2-Wire Transmit- CS1W-PTW01
ter Input Unit
Isolated-type Direct Current
Input Unit
Power Transducer Input Unit
CS1W-PDC01/11/55, PTR02,
CJ1W-PDC15
CS1W-PTR01
Isolated-type Pulse Input Unit CS1W-PPS01
Isolated-type Universal Input CJ1W-PH41U
Unit
4
20 mA
0
800 Pa
Input signal
Industrial unit
■
CS1W-PTS11/12, PDC11, CJ1W-PTS15/16, PDC15, PH41U
With the CS1W-PTS11/PTS12, PDC11, and CJ1W-PTS15/16, PDC15,
PH41U, the input range for thermocouple inputs, and platinum-resistance
thermometer inputs, or the user-set range for DC inputs can be set directly,
and scaling can be set for the range in industrial units. This eliminates the
need for processing scaling in the ladder program.
Note It also possible to set the process value scaling zero/span points in reverse to
create an inverse relationship.
Measured input range
−200°C
1300°C
K thermocouple
0°C
Minimum input signal value
0
Minimum scaling value
8
400°C
Maximum input signal value
Operating
temperature range
Scaling range
10000
Maximum scaling value
Section 1-2
Features and Functions
■
Offset Compensation
Offset compensation is possible for process value errors. The amount of the
error is added to the process value.
Applicable Units
Isolated-type Universal Input
Unit
CJ1W-PH41U
Upper limit (7FFF FFFF hex)
Scaling upper limit
Scaling
offset value
Scaling lower limit
Minimum input
signal value
Process Value Alarm
Maximum input
signal value
Input range
Either a 2-point alarm (H and L limits) or a 4-point alarm (HH, H, L, and LL limits) is possible for the process value (or instantaneous value).
Applicable
Units
4-point alarm
2-point alarm
Isolated-type Thermocouple Input Units
Isolated-type Resistance Thermometer
Input Units
Isolated-type 2-Wire
Transmitter Input Unit
Isolated-type Direct
Current Input Units
CS1W-PTS01-V1/11,
CJ1W-PTS15
CS1W-PTS02/03/12,
CJ1W-PTS16
Isolated-type Pulse
Input Unit
CS1W-PPS01
Isolated-type Universal Input Unit
CJ1W-PH41U
Isolated-type Thermocouple Input Units
Isolated-type Resistance Thermometer
Input Units
CS1W-PTS51/55,
CJ1W-PTS51
CS1W-PTS52/56,
CJ1W-PTS52
Analog Input Unit
(100 mV)
Power Transducer
Input Unit
CS1WPTR02,
CS1W-PDC55
CS1W-PTR01
CS1W-PTW01
CS1W-PDC01/11, PTR02,
CJ1W-PDC15
CS1W-PTS51/52 and CJ1W-PTS51/52 Units have one external alarm output
for each input. High or low outputs can be selected.
CS1W-PTS55/PTS56 and PDC55 output alarms to the Expansion Setting
Area. This enables obtaining alarm outputs without special programming.
9
Section 1-2
Features and Functions
Alarm output
Process value input
Alarm setting
LL
L
H
HH
(low low limit) (low limit) (high limit) (high high limit)
Alarm output
Process value input
Alarm setting
Rate-of-change
Calculation and Alarm
L (low limit)
H (high limit)
The Analog I/O Units listed below calculate the rate of change for the process
value, and output an alarm when the high or low limit is exceeded. The rateof-change value is derived by taking the difference each second between the
process value at that time and the process value before the comparison time
interval. The comparison time interval can be set from 1 to 16 seconds. This
allows even a small process value rate of change to be detected.
Applicable Units
Isolated-type Thermocouple
Input Units
CS1W-PTS01-V1/11,
CJ1W-PTS15
Isolated-type Resistance
Thermometer Input Units
CS1W-PTS02/03/12,
CJ1W-PTS16
Isolated-type 2-Wire Transmit- CS1W-PTW01
ter Input Unit
Isolated-type Direct Current
Input Units
Isolated-type Universal Input
Unit
Note
CS1W-PDC01/11,
CJ1W-PDC15
CJ1W-PH41U
1. With the CJ1W-PH41U, a setting can be made to enable calculating the
rate of change each conversion period.
2. CJ1W-PH41U:
When the conversion period is 60 ms: 60 to 960 ms
When the conversion period is 10 ms: 10 to 160 ms
When the conversion period is 5 ms: 5 to 80 ms
10
Section 1-2
Features and Functions
Comparison time interval
set from 1 s to 16 s
Process value
3. The rate-of-change value is derived by taking the difference each second between the process value at that time
and the process value before the comparison time interval, rather than the difference calculated at each comparison time interval. This allows even a very small process
value change to be detected.
Process value
Time
10
Rate of change
(See note 3.)
Rate-of-change high
limit alarm setting
Time
Process value (comparison time interval: 3 s)
Time
Rate-of-change high
limit alarm output
Time
Time
Note The rate of change is calculated every second (and not just once during the
comparison time interval) so that even minute changes in the process value
are detected.
Alarm Hysteresis
An hysteresis can be set for the process value (or instantaneous value) alarm
and the rate-of-change alarm. The operation is as shown in the following diagram.
Applicable Units
Isolated-type Thermocouple
Input Units
CS1W-PTS01-V1/11/51/55,
CJ1W-PTS51/15
Isolated-type Resistance
Thermometer Input Units
Isolated-type 2-Wire Transmitter Input Unit
Isolated-type Direct Current
Input Units
Power Transducer Input Unit
CS1W-PTS02/03/12/52/56,
CJ1W-PTS52/16
CS1W-PTW01
CS1W-PDC01/11/55, PTR02,
CJ1W-PDC15
CS1W-PTR01
Isolated-type Pulse Input Unit CS1W-PPS01
Isolated-type Universal Input CJ1W-PH41U
Unit
Hysteresis
Alarm output
Process value input
and rate of change
Alarm setting
11
Section 1-2
Features and Functions
Alarm-ON Delay
This function can be used to set a given time period (0 s to 60 s) for delaying
the turning ON of the alarm after the process value (or instantaneous value)
alarm status or the alarm setting is reached. One alarm-ON delay is set for
each input or output. The same setting is used for all process value alarms
(HH, H, L, LL) and rate-of-change alarms (H, L).
Applicable Units
Isolated-type Thermocouple
Input Units
Isolated-type Resistance
Thermometer Input Units
Isolated-type 2-Wire Transmitter Input Unit
Isolated-type Direct Current
Input Units
CS1W-PTS01-V1/11/51/55,
CJ1W-PTS51/15
CS1W-PTS02/03/12/52/56,
CJ1W-PTS52/16
CS1W-PTW01
CS1W-PDC01/11/55, PTR02,
CJ1W-PDC15
Power Transducer Input Unit CS1W-PTR01
Isolated-type Pulse Input Unit CS1W-PPS01
Isolated-type Universal Input
Unit
CJ1W-PH41U
Process value
Example: H alarm setting
Time
Alarm output
Time
ON delay time (0 s to 60 s)
12
Section 1-2
Features and Functions
OFF-delay Outputs
This function makes it possible to turn OFF the alarm signal after a set time
period (0 to 60 s) has elapsed after alarm status is cleared, rather than having
the alarm turned OFF immediately.
An alarm OFF-delay time can be set for each input. The process value alarms
(HH, H, L, LL) and rate-of-change alarms (H, L) will all use the same OFFdelay time.
Applicable Units
Isolated-type Universal Input
Unit
CJ1W-PH41U
Process value
Example: H (high) alarm setting
Time
Alarm output
ON
Time
OFF
ON-delay time
(0 to 60 s)
Mean Value Processing
OFF-delay time
(0 to 60 s)
The moving average of a specified number (from 1 to 16) of past process values (or instantaneous values) can be calculated and stored as the process
value. An input noise filter can be installed if erroneous process values are
obtained due to noise, or if the system has sudden voltage or current fluctuations.
Applicable Units
Isolated-type Thermocouple
Input Units
CS1W-PTS01-V1/11,
CJ1W-PTS15
Isolated-type Resistance
Thermometer Input Units
CS1W-PTS02/03/12,
CJ1W-PTS16
Isolated-type 2-Wire Transmitter Input Unit
Isolated-type Direct Current
Input Units
Power Transducer Input Unit
CS1W-PTW01
CS1W-PDC01/11, PTR02,
CJ1W-PDC15
CS1W-PTR01
Isolated-type Pulse Input Unit CS1W-PPS01
Isolated-type Universal Input CJ1W-PH41U
Unit
Note For the CS1W-PTR01 and CS1W-PTR02, four process values are always
averaged. For the CS1W-PTS11, CS1W-PTS12, CS1W-PDC11, CJ1WPTS15, CJ1W-PTS16, CJ1W-PDC15 and CJ1W-PH41U the number of values to be averaged can be set to between 1 and 128.
13
Section 1-2
Features and Functions
Analog Output Unit
CPU Unit
Calculation
of moving
average
Input Disconnection
Detection
Sensor disconnections can be detected for thermocouple input and resistance
thermometer input. Either the high (115%) or low (–15%) direction can be
specified for when a disconnection is detected.
Applicable Units
Isolated-type Thermocouple
Input Units
Isolated-type Resistance
Thermometer Input Units
Isolated-type Universal Input
Unit
CS1W-PTS01-V1/11,
CJ1W-PTS15
CS1W-PTS02/03/12,
CJ1W-PTS16
CJ1W-PH41U (See note.)
Analog Input Unit
CPU Unit
Disconnection
Detection Flag
(See note.)
Process value
High/low designation:
115% or −15%
Note For the CJ1W-PH41U, this is the Input Error Flag.
Input Error Detection
An errors resulting from exceeding the high or low limits can be detected.
Applicable Units
Isolated-type Thermocouple
Input Units
Isolated-type Resistance
Thermometer Input Units
Isolated-type 2-Wire Transmitter Input Unit
Isolated-type Direct Current
Input Units
CS1W-PTS51/55,
CJ1W-PTS51
CS1W-PTS52/56,
CJ1W-PTS52
CS1W-PTW01-V1
Isolated-type Universal Input
Unit
CJ1W-PH41U
CS1W-PDC01/11/55,
CJ1W-PDC15
Note An input error will be detected for the [email protected] or [email protected] if the
input exceeds 20 digits for the high or low limits of the sensor range.
For the CS1W-PDC55, an input error will be detected if the input exceeds
−5% or +105% for the internal range full span.
14
Section 1-2
Features and Functions
Cold Junction Sensor
Errors Detection
If a Thermocouple Input Unit or Universal Input Unit built-in cold junction sensor is disconnected, if short-circuiting occurs, or if an error occurs at the cold
junction sensor, the Cold Junction Error Flag will turn ON and the temperature
process value with no cold junction compensation will be stored in the CIO
Area.
Applicable Units
Note
Isolated-type Thermocouple
Input Units
Isolated-type Universal Input
Unit
CS1W-PTS01-V1/11/51/55,
CJ1W-PTS51/15
CJ1W-PH41U
1. If one of the two cold junction sensors is disconnected as described above,
cold junction compensation will be stopped for all inputs.
2. There is only one cold junction sensor for the CS1W-PTS51 and the
CJ1W-PH41U. There are two cold junction sensors for the CJ1W-PTS15.
Square Root
For 2-wire transmitter input and analog input, this function takes as the process value the square root of the analog input value. It is used for operations
such as calculating momentary flow based on the differential pressure input
from a differential pressure transmitter.
With linear characteristics at an output of approximately 7% or less, an on-site
differential pressure transmitter’s zero-point adjustment can be performed
with this function enabled.
Note The square root function is enabled only when the maximum scaling value is
greater than the minimum scaling value. Square root extraction will not be
possible if the minimum scaling value is greater.
Applicable Units
Note
Isolated-type Direct Current
Input Units
Isolated-type 2-Wire Transmitter Input Unit
Isolated-type Universal Input
Units
CS1W-PDC01/11/55,
CJ1W-PDC15
CS1W-PTW01
CJ1W-PH41U (See note 1.)
1. Enabled for DC input only.
2. The square root function can be used with the CS1W-PDC55 only when
using the 1 to 5 V or 4 to 40 mA range.
Process value input
100%
7%
0%
4
20 mA
Input signal
15
Section 1-2
Features and Functions
Inrush Input Limit
The inrush input limit function temporarily limits the process value input to a
given set value when it increases from a low value (2%). This function is used
for preventing a process value alarm from being generated by the inrush current, e.g., when the motor is started.
Applicable Units
Analog Input Unit (100 mA)
Power Transducer Input Unit
CS1W-PTR02
CS1W-PTR01
Analog output
High limit
Time
Inrush high limit time: 0 s to 100 s
Zero/Span Adjustment
The zero point and span point can be adjusted for a process value (or instantaneous value). The zero adjustment offsets the line plotting values before
and after adjustment parallel to the original line. The span adjustment
changes the slope of the line (i.e., the gain) around the minimum value in the
range (i.e., the minimum value is not changed). The zero adjustment value
and the span adjustment gain are set in the DM Area words allocated in the
CPU Unit. These settings are refreshed during operation, so the values can
be adjusted under normal operating conditions.
Also, with the CS1W-PTS11/PTS12, CS1W-PDC11, and CJ1WPTS15/PTS16/PDC15/PH41U, the zero point and span point can be adjusted
for a specified point (position) other than 0% or 100%. The zero adjustment
value and span adjustment gain for specified points are set in the Expansion
Setting Area allocated to the Unit.
Refer to Appendix B Zero/Span Adjustment Example for details.
Zero/Span Adjustment Only
Applicable Units
Isolated-type Thermocouple
Input Units
CS1W-PTS01-V1/11/51/55,
CJ1W-PTS51
Isolated-type Resistance
Thermometer Input Units
CS1W-PTS02/03/12/52/56,
CJ1W-PTS52
Isolated-type 2-Wire Transmit- CS1W-PTW01
ter Input Unit
Isolated-type Direct Current
Input Units
CS1W-PDC01/11/55, PTR02
Power Transducer Input Unit CS1W-PTR01
Isolated-type Pulse Input Unit CS1W-PPS01
Isolated-type Analog Output
Units
16
CS1W-PMV01/PMV02
Section 1-2
Features and Functions
Zero/Span Adjustment and Zero/Span Adjustment for Specified Points
Applicable Units
CPU Unit
Isolated-type Thermocouple
Input Unit
CS1W-PTS11, CJ1W-PTS15
Isolated-type Resistance
Thermometer Input Unit
CS1W-PTS12, CJ1W-PTS16
Isolated-type Analog Input
Unit
Isolated-type Universal Input
Unit
CS1W-PDC11, CJ1W-PDC15
Zero/Span Adjustment
Analog I/O Unit
Output data
DM Area
Span adjustment
gain B
CJ1W-PH41U
Maximum range
Always transferred
Adjustment data
Zero adjustment
value A
Gain for
span
adjustment
Expansion Memory
Area allocation
Expansion Memory
Area leading address
Expansion Setting Area
(CJ1W-PTS15/-PTS16/
-PDC15/-PH41U only)
Area for Expansion
Control/Monitor Area
First word of
Expansion
Control/Monitor Area
After adjustment
Maximum range
Before adjustment
Minimum range
Adjustment position
Power ON or
Unit restarted.
Input
Minimum range
Zero adjustment value
Span adjustment
position D
Output data
Zero adjustment
position C
Specified Point Zero/Span
Adjustment with Expansion
Setting Area Settings (CS1WPTS11/PTS12, -PDC11, CJ1WPTS15/16, PDC15, PH41U only)
Maximum range
Maximum range
After adjustment
Zero adjustment
value
Before adjustment
Gain for
span adjustment
Minimum range
Minimum range
Input
Zero adjustment
position
Stepdown
This function reduces the number of pulses by 1/10, 1/100, or 1/1,000. It only
operates for an accumulating counter (and not for instantaneous values).
Make this setting to prevent accumulating counter overflow. If the number of
pulses is 3,000, for example, setting the stepdown rate to 1/100 will reduce
the number to 30, and the totalizing will then be based on that value.
Applicable Units
Pulse Input Instantaneous
Value Conversion
Span adjustment
position
Isolated-type Pulse Input Unit CS1W-PPS01
This function counts the number of pulses per time unit and converts the number to an instantaneous value (pulses/time unit). Any of the following time
17
Section 1-2
Features and Functions
units can be selected: 1 s, 3 s, 10 s, 30 s, or 60 s. (These match the cycles for
conversion to instantaneous values.)
When the number of pulses per time unit (i.e., pulse rate) is low, lengthen the
time unit. The instantaneous value stored, however, can only be refreshed at
intervals of this time unit.
If there is fluctuation in the instantaneous values, the moving average function
can be used to even the values out through averaging. Calculate the moving
average for the specified number of values, and then convert it to the number
of pulses per time unit. To determine the number of values for averaging,
observe the operating status.
Applicable Units
Pulse Accumulation
Pulse Input Units can accumulate pulses within a range of 0 to 9,999 (0000 to
270F hex). With each accumulation conversion period, the number of input
pulses after the stepdown is added. If the accumulated value exceeds 9,999,
pulses are accumulated again from 0000. When the PLC is turned ON or the
Unit is restarted, the accumulated value is reset to 0 and the Accumulation
Reset Bit turns ON for 10 seconds.
Applicable Units
Answer Input
Isolated-type Pulse Input Unit CS1W-PPS01
Isolated-type Pulse Input Unit CS1W-PPS01
During analog output, the actual analog output (current or voltage) signal can
be checked by being read again from the analog output terminals. This function is used for checking for actual output load discrepancies due to external
load resistance, or for checking actual analog signal values when an output
rate-of-change limit is used.
Applicable Units
Isolated-type Analog Output
Unit
CS1W-PMV01
Analog Output Unit
Output value
Rate-of-change limit
High/low limit
Load
Answer input
(Actual output value)
Output Rate-of-change
Limit
With this function, the analog output value’s rate of change can be limited separately for the positive and negative directions.
Applicable Units
Analog output
Isolated-type Analog Output
Units
CS1W-PMV01/PMV02
Without rate-of-change limit
With rate-of-change limit
Negative direction rate-of-change limit
Positive direction rate-of-change limit
Time
18
Section 1-2
Features and Functions
Output Disconnection
Detection
If a current loop is disconnected during analog output, this function will detect
it.
Applicable Units
Isolated-type Analog Output
Unit
CPU Unit
Analog Output Unit
Output Disconnection Detection Flag
Output Hold When CPU
Unit Error Occurs
Load
When a fatal error (including user-defined FALS execution), or a CPU error in
the CPU Unit occurs, or all outputs are turned OFF with the Output OFF Bit,
this function can hold either a preset value or the analog output value prior to
the error. When the CPU Unit is restored to normal operation, the output value
in the CIO Area is output.
Applicable Units
Isolated-type Analog Output
Units
CPU Unit
Fatal error or
all outputs
turned OFF
with Output
OFF Bit
Adjustment Period
Control
CS1W-PMV01
CS1W-PMV01/PMV02
Analog Output Unit
Prior analog
output value or
preset value
Analog output
When zero/span adjustment is executed, the date is internally recorded at the
Unit. When the preset zero/span adjustment period and the notice of days
remaining have elapsed, this function turns ON a warning flag to give notice
that it is time for readjustment.
Applicable Units
Isolated-type Thermocouple
Input Unit
Isolated-type Resistance
Thermometer Input Unit
Isolated-type Analog Input
Unit
Isolated-type Universal Input
Unit
CS1W-PTS11, CJ1W-PTS15
CS1W-PTS12, CJ1W-PTS16
CS1W-PDC11, CJ1W-PDC15
CJ1W-PH41U
19
Section 1-2
Features and Functions
CPU Unit
Analog I/O Unit
DM Area
Span adjustment
gain B
Continuously
refreshed
Adjustment
data
Zero adjustment
value A
Expansion Memory
Area allocation
Expansion Memory
Area leading address
Expansion Memory
Area
Expansion Data Area
allocation
Final adjustment date
Example:
Zero/span adjustment period = 180 days
Notice of days remaining before zero/span
adjustment period elapses = 30 days
July 3, 2002: Zero/span adjustment executed.
Power ON or
Unit restarted
November 30, 2002: Adjustment Period Notice Flag
December 30, 2002: Adjustment Period End Flag
Expansion Data Area
leading address
Zero/span
adjustment period
Notice of days remaining
before zero/span adjustment period elapses
Present date
Expansion Control/
Monitor Area
Adjustment Update
Bit
Adjustment Period
End Flag
Continuously
refreshed
Comparison
When Adjustment Update Bit
is turned ON
Continuously
refreshed
Adjustment Period
Notice Flag
Peak and Bottom
Detection
This function detects the maximum (peak) and minimum (bottom) analog
input values, from when the Hold Start Bit (output) allocated in the Expansion
Control/Monitor Area turns ON until it turns OFF. The peak and bottom values
in the Expansion Control/Monitor Area are constantly refreshed, and they are
cleared to zero while the Hold Value Reset Bit is ON.
Applicable Units
20
Isolated-type Thermocouple
Input Unit
Isolated-type Resistance
Thermometer Input Unit
Isolated-type Analog Input
Unit
CS1W-PTS11, CJ1W-PTS15
Isolated-type Universal Input
Unit
CJ1W-PH41U
CS1W-PTS12, CJ1W-PTS16
CS1W-PDC11, CJ1W-PDC15
Section 1-2
Features and Functions
Process value
0
Hold Start Bit
Hold Value Reset Bit
Peak value
0
Bottom value
0
Note The top and valley detection function and the peak and bottom detection function cannot be used simultaneously.
Top and Valley Detection
This function detects the top and valley values of the process value from when
the Hold Start Bit (output) in the Expansion Control/Monitor Area turns ON
until it turns OFF. A detection hysteresis can be set so that minute changes
are not detected. The top and valley values in the Expansion Control/Monitor
Area are constantly refreshed, and they are cleared to zero while the Hold
Value Reset Bit is ON.
Applicable Units
Isolated-type Thermocouple
Input Unit
CS1W-PTS11, CJ1W-PTS15
Isolated-type Resistance
Thermometer Input Unit
CS1W-PTS12, CJ1W-PTS16
Isolated-type Analog Input
Unit
Isolated-type Universal Input
Unit
CS1W-PDC11, CJ1W-PDC15
CJ1W-PH41U
21
Section 1-2
Features and Functions
Analog input
0
Hold Start Bit
Hold Value Reset Bit
Top value
0
Valley value
0
Note Either peak and bottom values or top and valley values can be selected for
detection. This selection is made by using the Hold Function Selection Flag in
the Expansion Control/Monitor Area to select either the top and valley detection function or the peak and bottom detection function. These two functions
cannot be used simultaneously.
Integral Value Calculation
(CS1W-PDC11 and CJ1WPDC15/PH41U Only)
This function calculates the integral of the process value over time. The unit
can be selected as either “hour” or “minute” by a setting in the Expansion Setting Area.
The integral value can be output to the Expansion Monitor/Control Area by
turning ON the Integral Value Calculation Start Bit in the Expansion Monitor/Control Area. It can also be cleared to zero by turning ON the Integral
Value Reset Bit in the Expansion Monitor/Control Area.
In addition, with the CJ1W-PH41U, the integral value can be calculated using
an integral value coefficient to prevent integral value overflow.
Applicable Units
Isolated-type Analog Input
Unit
CS1W-PDC11, CJ1W-PDC15
Isolated-type Universal Input
Unit
CJ1W-PH41U
Integral value
Process value
Time t
Integral width
Cold Junction
Compensation Method
22
This function specifies whether cold junction compensation for thermocouple
inputs is to be performed in the Analog I/O Unit or externally. The external
method is enabled when the temperature difference is measured using two
Section 1-2
Features and Functions
thermocouples or when an external cold-junction compensator is used for
greater precision.
Applicable Units
Temperature Resistance
Thermometer
Compensation
Isolated-type Universal Input
Units
CJ1W-PH41U
This function performs compensation for resistance thermometer inputs
according to the reference resistance for a connected resistance thermometer. Set the Temperature Resistance Thermometer Compensation Enable setting in the Expansion Setting Area to Enable and then set the Reference
Resistance (i.e., the resistance at 23°C) in the Expansion Setting Area.
Applicable Units
Isolated-type Universal Input
Units
CJ1W-PH41U
23
Section 1-3
System Configuration
1-3
System Configuration
CS Series
These Analog I/O Units belong to the CS-series Special I/O Unit group.
• They can be mounted to CS-series CPU Racks or Expansion I/O Racks.
• They cannot be mounted to C200H CPU Racks, Expansion I/O Racks, or
SYSMAC BUS Remote I/O Slave Racks.
The number of Units that can be mounted to one Rack (either a CPU Rack or
Expansion I/O Rack) depends upon the maximum current supplied by the
Power Supply Unit and the current consumption by the other Units.
There are no restrictions on Rack position.
Note I/O addresses for Special I/O Units are allocated according to the unit number
set on the switches on the front panel, and not according to the slot position in
which they are mounted.
CS-series CPU Rack
I/O Unit
CPU Unit
Power Supply Unit
CS-series Expansion I/O Rack #1
I/O Unit
CS-series Expansion I/O Rack #2
I/O Unit
A maximum of 7 Expansion
I/O Racks can be mounted.
CS-series Expansion I/O Rack #7
CJ Series
I/O Unit
These Analog I/O Units belong to the CJ-series Special I/O Unit group.
• They can be mounted to CJ-series CPU Racks or Expansion I/O Racks.
The number of Units that can be mounted to one Rack (either a CPU Rack or
Expansion I/O Rack) depends upon the maximum current supplied by the
Power Supply Unit and the current consumption by the other Units.
There are no restrictions on Rack position.
Note I/O addresses for Special I/O Units are allocated according to the unit number
set on the switches on the front panel, and not according to the slot position in
which they are mounted.
24
Section 1-3
System Configuration
CPU Rack
CPU Unit
Power
Supply Unit
10 I/O Units max.
I/O Control Unit
End Cover
Power
Supply Unit
CJ-series Expansion
Rack
Expansion
Racks
3 maximum
I/O Interface Unit
I/O Interface Unit
Power
Supply Unit
CJ-series Expansion
Rack
10 I/O Units max.
25
Section 1-4
Specifications and Installation
1-4
1-4-1
Specifications and Installation
Specifications
CS Series
The specifications shown in the following table apply to all the CS-series Analog I/O Units. For specifications and installation procedures specific to each
Unit, refer to the explanations in SECTION 2 Individual Unit Descriptions for
CS Series.
Item
Unit classification
Specification
CS-series Special I/O Unit
Structure
Dimensions
Backplane-mounted, single slot size
35 × 130 × 126 mm (W × H × D)
Weight
External connection terminals
450 g max.
• CS1W-PTS55/-PTS56/-PDC55
24-point removable terminal block (with lever)
(M3 screws, Tightening torque: 0.5 N·m)
• Other Units
21-point removable terminal block
(M3 screws, Tightening torque: 0.5 N·m)
Unit number switch setting
00 to 95
Self-diagnosis function
Mountable Racks
Results of self-diagnosis shown on indicators.
CPU Rack or CS-series Expansion Rack
Maximum number of
Units
80 Units (10 Units × 8 Racks)
Confirm that the total current consumption of all the Units
(including the CPU Unit) mounted to a single CPU Rack or
Expansion Rack does not exceed the maximum power supply
capacity of the Power Supply Unit.
Ambient operating temperature
0 to 55°C
Ambient operating
humidity
10% to 90% (with no condensation)
Current consumption
Name
Current consumption (power)
CS1W-PTS01-V1
5V
0.15 A (0.75 W)
26 V
0.15 A (3.9 W)
CS1W-PTS11
0.16 A (0.60 W)
0.08 A (2.08 W)
CS1W-PTS51
CS1W-PTS55
0.25 A (1.25 W)
0.18 A (0.90 W)
Not used.
0.06 A (1.56 W)
Isolated-type ResisCS1W-PTS02
tance Thermometer
Input Unit (Pt100,
JPt100)
Isolated-type ResisCS1W-PTS03
tance Thermometer
Input Unit (Ni508.4)
Isolated-type ResisCS1W-PTS12
tance Thermometer
Input Unit (Pt100,
JPt100, Pt50, Ni508.4)
0.15 A (0.75 W)
0.15 A (3.9 W)
0.15 A (0.75 W)
0.15 A (3.9 W)
0.12 A (0.60 W)
0.07 A (1.82 W)
Isolated-type Resistance Thermometer
Input Unit (Pt100,
JPt100)
Isolated-type 2-Wire
Transmitter Input Unit
CS1W-PTS52
CS1W-PTS56
0.25 A (1.25 W)
0.18 A (0.90 W)
Not used.
0.06 A (1.56 W)
CS1W-PTW01
0.15 A (0.75 W)
0.16 A (4.2 W)
Isolated-type Thermocouple Input Unit
26
Model
Section 1-4
Specifications and Installation
Name
Model
Isolated-type Direct
Current Input Unit
Current consumption (power)
5V
26 V
CS1W-PDC01
CS1W-PDC11
0.15 A (0.75 W)
0.12 A (0.60 W)
0.16 A (4.2 W)
0.12 A (3.12 W)
CS1W-PDC55
CS1W-PTR01
0.18 A (0.90 W)
0.15 A (0.75 W)
0.06 A (1.56 W)
0.08 A (2.1 W)
Analog Input Unit (100
mV)
CS1W-PTR02
0.15 A (0.75 W)
0.08 A (2.1 W)
Isolated-type Pulse
Input Unit
CS1W-PPS01
0.20 A (1.00 W)
0.16 A (4.2 W)
Isolated-type Analog
Output Unit
CS1W-PMV01
CS1W-PMV02
0.15 A (0.75 W)
0.12 A (0.60 W)
0.16 A (4.2 W)
0.12 A (3.2 W)
Power Transducer
Input Unit
(Reference) Maximum current and total power supplied
Power Supply
Unit
CJ Series
Maximum current supplied (power)
Maximum
total power
C200HW-PA204
5V
4.6 A (23 W)
26 V
0.6 A (15.6 W)
24 V
None
30 W
C200HW-PA204C
C200HW-PA204S
4.6 A (23 W)
4.6 A (23 W)
0.6 A (15.6 W)
0.6 A (15.6 W)
None
0.8 A (19.2 W)
30 W
30 W
C200HW-PA204R
C200HW-PD024
4.6 A (23 W)
4.6 A (23 W)
0.6 A (15.6 W)
0.6 A (15.6 W)
None
None
30 W
30 W
C200HW-PA209R
C200HW-PD025
9 A (45 W)
5.3 A
1.3 A (33.8 W)
1.3 A
None
None
45 W
40 W
CS1D-PA207R
CS1D-PD024
7 A (35 W)
4.3 A (21.5 W)
1.3 A (33.8 W) None
0.56 A (14.6 W) None
35 W
28 W
CS1D-PD025
5.3 A
1.3 A
40 W
None
The specifications shown in the following table apply to all the CJ-series Analog I/O Units. For specifications and installation procedures specific to each
Unit, refer to the explanations in SECTION 3 Individual Unit Descriptions for
CJ Series.
Item
Specification
Unit classification
Dimensions
CJ-series Special I/O Unit
31 × 90 × 65 mm (W × H × D)
Weight
Maximum number
of Units
150 g max.
40 Units (10 Units × 4 Racks)
Confirm that the total current consumption of all the Units
(including the CPU Unit) mounted to a single CPU Rack or
Expansion Rack does not exceed the maximum power supplied
by the Power Supply Unit.
0 to 55°C
Ambient operating
temperature
Ambient operating
humidity
10% to 90% (with no condensation)
Current consumption
Name
Isolated-type Thermocouple Input Unit
Model
CJ1W-PTS51
CJ1W-PTS15
Current consumption (power)
5V
24-V external
0.25 A (1.25 W)
0.18 A (0.9 W)
Not used.
0.06 A
27
Section 1-4
Specifications and Installation
Name
Model
Current consumption (power)
5V
24-V external
Isolated-type Resistance
Thermometer Input Unit
(Pt100, JPt100)
CJ1W-PTS52
CJ1W-PTS16
0.25 A (1.25 W)
0.18 A (0.9 W)
Not used.
0.07 A
Isolated-type Direct Current Input Unit
CJ1W-PDC15
0.18 A (0.9 W)
0.09 A
Isolated-type Universal
Input Unit
CJ1W-PH41U
0.30 A (1.5 W)
Not used.
(Reference) Maximum current and total power supplied
Power Supply Unit
Maximum current supplied (power)
5V
1-4-2
Maximum total
power
CJ1W-PA205R/
PA205C
CJ1W-PA202
5.0 A (25 W)
24-V relay driver
current
0.8 A
2.8 A (14 W)
0.4 A
14 W
CJ1W-PD025
CJ1W-PD022
5.0 A (25 W)
2.0 A (10 W)
0.8 A
0.4 A
25 W
19.6 W
25 W
Nomenclature and Functions
CS Series
[email protected]@[email protected]/[email protected]/51/52
(Side view)
With Terminal Block mounted
Model number
Terminal Block
Unit number switch
Fastening screws
(black M3 screws)
Terminal Block
(M3 screws)
Backplane fastening screw
Terminal number/symbol
(Varies depending on the Analog I/O Unit model.)
Note
1. The Terminal Block is detachable, with connectors. It can be removed by
loosening the two black screws (on the top and bottom).
2. Always confirm that the black Terminal Block mounting screws are tightened to a torque of 0.5 N·m.
28
Section 1-4
Specifications and Installation
Screw
Screw
CS1W-PTS55/56, PDC55
(Side view)
With Terminal Block mounted
Model number
RUN
ERC
MACH
No.
Terminal Block
ERH
X101
X100
Unit number
switch
Fastening screws
(black M3 screws)
Lock lever
Terminal number/symbol
(Varies depending on the Analog I/O Unit model.)
Note The Terminal Block is detachable, with Lock lever. It can be removed by
unlocking the lock lever.
29
Section 1-4
Specifications and Installation
RUN
ERC
ERH
54321
543210
9876
DCBA
DCBA
MACH FE 1 0 FE X100
X10
No.
9876
Lock lever
Front Panel LED Indicators
■ [email protected]@[email protected]/[email protected]
RUN
ERC
LED
Meaning
CS
ERH
Indicator
RUN
(green)
Operating
Lit
Not lit
ERC
(red)
Error detected by Lit
Unit
Not lit
ERH
(red)
Error in the CPU
Unit
Lit
Not lit
Operating status
Operating normally.
Unit has stopped exchanging data
with the CPU Unit.
Data setting is out of range in the
DM Area.
Operating normally.
Error has occurred during data
exchange with the CPU Unit, or
Analog I/O Unit’s unit number is set
incorrectly, or there is a mounting
error.
Operating normally.
■ CS1W-PTS55/56, PDC55
RUN
ERC
LED
RUN
(green)
Meaning
Operating
Indicator
ERC
(red)
Error detected by Lit
Unit
Lit
Not lit
Not lit
30
CS
ERH
Operating status
Operating normally.
Unit has stopped exchanging data
with the CPU Unit.
Sensor error has occurred or data
setting is out of range in the DM
Area.
Operating normally.
Section 1-4
Specifications and Installation
LED
ERH
(red)
Meaning
Error in the CPU
Unit
Indicator
Lit
Not lit
Operating status
Error has occurred during data
exchange with the CPU Unit, or
Analog I/O Unit’s unit number is set
incorrectly, or there is a mounting
error.
Operating normally.
■ CS1W-PTS51/52
PTS51
RUN
ERC
ALM1
ALM2
LED
Meaning
Operating
ERC
(red)
Error detected by Lit
Unit
Lit
Not lit
Not lit
Error in the CPU
Unit
ALM1 to External alarm
ALM4
outputs
(yellow)
Unit Number Switches
ERH
ALM3
ALM4
Indicator
RUN
(green)
ERH
(red)
CS
Operating status
Operating normally.
Unit has stopped exchanging data
with the CPU Unit.
Sensor error has occurred or data
setting is out of range in the DM
Area.
Operating normally.
Lit
Error has occurred during data
exchange with the CPU Unit, or
Analog I/O Unit’s unit number is set
incorrectly, or there is a mounting
error.
Not lit
Lit
Operating normally.
External alarm output ON
Not lit
External alarm output OFF
The CPU Unit and Analog Input Unit exchange data via words allocated to the
Analog Input Unit as a Special I/O Unit. Words are allocated to Special I/O
Units in both the CIO Area and the DM Area.
The words that each Analog I/O Unit uses are determined by the setting of the
unit number switches on the front panel of the Unit.
Unit number switches
Unit No.
CIO Area addresses
0
CIO 2000 to CIO 2009
DM Area addresses
D20000 to D20099
1
2
CIO 2010 to CIO 2019
CIO 2020 to CIO 2029
D20100 to D20199
D20200 to D20299
3
4
CIO 2030 to CIO 2039
CIO 2040 to CIO 2049
D20300 to D20399
D20400 to D20499
5
6
CIO 2050 to CIO 2059
CIO 2060 to CIO 2069
D20500 to D20599
D20600 to D20699
7
8
CIO 2070 to CIO 2079
CIO 2080 to CIO 2089
D20700 to D20799
D20800 to D20899
9
10
CIO 2090 to CIO 2099
CIO 2100 to CIO 2109
D20900 to D20999
D21000 to D21099
to
to
to
31
Section 1-4
Specifications and Installation
Unit No.
CIO Area addresses
n
CIO 2000 + n × 10 to CIO 2000 +
n × 10 + 9
DM Area addresses
D20000 + n × 100 to D20000 +
n × 100 + 99
to
95
to
D29500 to D29599
to
CIO 2950 to CIO 2959
Note If two or more Special I/O Units are assigned the same unit number, a “UNIT
No. DPL ERR” error (in the Programming Console) will occur (A401.13 will
turn ON) and the PLC will not operate.
CJ Series
Front Panel LED Indicators
■ [email protected]
RUN
ERC
ERH
LED
Meaning
ALM
1 - 2 - 3 - 4
Indicator
RUN
(green)
Operating
Lit
Not lit
ERC
(red)
Error detected by Lit
Unit
Operating normally.
Unit has stopped exchanging data
with the CPU Unit.
Sensor error has occurred or data
setting is out of range in the DM
Area.
Operating normally.
Not lit
ERH
(red)
Error in the CPU
Unit
ALM1 to External alarm
ALM4
outputs
(yellow)
Operating status
Lit
Not lit
Error has occurred during data
exchange with the CPU Unit, or
Analog I/O Unit’s unit number is set
incorrectly, or there is a mounting
error.
Operating normally.
Lit
Not lit
External alarm output ON.
External alarm output OFF.
■ CJ1W-PTS15/PTS16/PDC15
RUN
ERC
ERH
EXT PS
LED
32
Meaning
Indicator
RUN
(green)
Operating
ERC
(red)
Error detected by Lit
Unit
ERH
(red)
Error in the CPU
Unit
EXT PS
External power
supply
Lit
Not lit
Not lit
Lit
Operating status
Operating normally.
Unit has stopped exchanging data
with the CPU Unit.
Data setting is out of range in the
DM Area.
Not lit
Operating normally.
Error has occurred during data
exchange with the CPU Unit, or
Analog I/O Unit’s unit number is set
incorrectly, or there is a mounting
error.
Operating normally.
Lit
Not lit
External 24-VDC power supply
No external power supply
Section 1-4
Specifications and Installation
■ CJ1W-PH41U
P H 41U
RUN
ERC
ERH
Meaning
Operating
Indicator
ERC
(red)
Error detected by Lit
Unit
Not lit
Data setting is out of range in the
DM Area.
Operating normally.
ERH
(red)
Error in the CPU
Unit
Lit
Error has occurred during data
exchange with the CPU Unit, or
Analog I/O Unit’s unit number is set
incorrectly, or there is a mounting
error.
Not lit
Operating normally.
Lit
Not lit
Operating status
Operating normally.
Unit has stopped exchanging data
with the CPU Unit.
The CPU Unit and Analog Input Unit exchange data via words allocated to the
Analog Input Unit as a Special I/O Unit. Words are allocated to Special I/O
Units in both the CIO Area and the DM Area.
The words that each Analog I/O Unit uses are determined by the setting of the
unit number switches on the front panel of the Unit.
Unit Number Switches
78
78
901
23
456
MACH
No.
0
X10
901
23
MACH
No.
X101
456
Unit Number Switches
LED
RUN
(green)
Unit No.
CIO Area addresses
0
CIO 2000 to CIO 2009
DM Area addresses
D20000 to D20099
1
2
CIO 2010 to CIO 2019
CIO 2020 to CIO 2029
D20100 to D20199
D20200 to D20299
3
4
CIO 2030 to CIO 2039
CIO 2040 to CIO 2049
D20300 to D20399
D20400 to D20499
5
6
CIO 2050 to CIO 2059
CIO 2060 to CIO 2069
D20500 to D20599
D20600 to D20699
7
8
CIO 2070 to CIO 2079
CIO 2080 to CIO 2089
D20700 to D20799
D20800 to D20899
9
10
CIO 2090 to CIO 2099
CIO 2100 to CIO 2109
D20900 to D20999
D21000 to D21099
to
n
to
CIO 2000 + n × 10 to CIO 2000 +
n × 10 + 9
to
D20000 + n × 100 to D20000 +
n × 100 + 99
to
95
to
CIO 2950 to CIO 2959
to
D29500 to D29599
Note If two or more Special I/O Units are assigned the same unit number, a “UNIT
No. DPL ERR” error (in the Programming Console) will occur (A401.13 will
turn ON) and the PLC will not operate.
33
Section 1-4
Specifications and Installation
1-4-3
Exchanging Data with the CPU Unit
CS1W-PTS01-V1, PTS02/03/51/52, PTW01, PDC01, PTR01/02, PMV01/02, CJ1WPTS51/52
The Analog I/O Unit exchanges data with the CPU Unit via the allocated portions of the CPU Unit’s Special I/O Unit Area and DM Area. The addresses
allocated in these areas are determined as follows, according to the value (0
to 95) set by the unit number switch on the front panel of the Analog I/O Unit.
• Special I/O Unit Area: 10 words from beginning word n
n = 2000 + unit number (0 to 95) x 10
• DM Area: 100 words from beginning word m
m = D20000 + unit number (0 to 95) x 100
The following table shows the addresses allocated according to the unit number.
Unit No.
Special I/O Unit Area
DM Area
0
1
CIO 2000 to CIO 2009
CIO 2010 to CIO 2019
D20000 to D20099
D20100 to D20199
2
3
CIO 2020 to CIO 2029
CIO 2030 to CIO 2039
D20200 to D20299
D20300 to D20399
4
5
CIO 2040 to CIO 2049
CIO 2050 to CIO 2059
D20400 to D20499
D20500 to D20599
6
7
CIO 2060 to CIO 2069
CIO 2070 to CIO 2079
D20600 to D20699
D20700 to D20799
8
9
CIO 2080 to CIO 2089
CIO 2090 to CIO 2099
D20800 to D20899
D20900 to D20999
10
to
CIO 2100 to CIO 2109
to
D21000 to D21099
to
95
CIO 2950 to CIO 2959
D29500 to D29599
Analog I/O Unit
CPU Unit
(See note 3.)
Data for Operation
Process values,
analog output values
Rates of change
Error flags
Special I/O Unit Area
n = 2000 + (unit No. x 10)
n
n+1
I/O refresh
to
n+9
DM Area
m = D20000 + (unit No. x 100)
m
Default block read command
Setting Group 1
m+1
to
Setting Group 2
m+34
to
m+93
Display Parameter
m+94
to
m+99
Note
Power ON or Unit
restarted.
(See note 1.)
I/O refresh
Power ON or Unit
restarted.
(See note 1.)
Power ON or Unit
restarted.
Unit Settings
Default transfer reception
Continuously
Refreshed Area
Alarm settings,
zero/span
Adjustment values, etc.
Area Refreshed
at Restart
Initial values for
sensor/input
signal types,
scaling, etc.
(See note 2.)
1. This applies when word m contains other than 12345 (3039 hex), e.g.,
0000 hex. When word m contains 12345 (3039 hex), the transfer direction
will be reversed.
2. The functions that can be used depend on the model.
34
Section 1-4
Specifications and Installation
3. The allocated data areas depend on the model.
These areas have the following functions for Analog I/O Units.
Special I/O
Unit Area
DM Area
The data for operation is continuously refreshed.
The following types of data are transferred from Analog Input Units to
the CPU Unit: Values scaled in industrial units for process values
and rate-of-change values; alarm contact data, Input Disconnection
Flag data, etc.
Analog output values are transferred from the CPU Unit to Analog
Output Units.
Data is set in this area. The allocated portion of the DM Area is
divided into the four areas shown below.
Note For details, refer to the explanations for the individual Units.
1) Default block read When the PLC is turned ON or the Unit is
command
restarted, the data in the Analog I/O Unit
can be transferred back to the CPU Unit.
Beginning word m is fixed.
When word m contains 12345 (3039 hex),
then the data is transferred from the Analog
I/O Unit to the CPU Unit.
When word m contains less than 12345
(3039 hex), such as 0 (0000 hex), then data
is transferred from the CPU Unit to the Analog I/O Unit as usual.
2) Setting Group 1
While the PLC is ON (even if the CPU Unit
(continuously
is operating), this area is continuously
refreshed area)
refreshed.
This area is refreshed when the PLC is
turned ON or the Unit is restarted.
The area is refreshed regardless of the
CPU Unit’s operation mode (i.e., RUN, Monitor, or Program Mode).
Alarm settings, zero/span adjustment values, and so on, are set here.
3) Setting Group 2
(initial settings area)
When word m contains anything other than
12345 (3039 hex), data is transferred once
to this area from the CPU Unit when the
PLC is turned ON or the Unit is restarted.
Sensor types, process value scaling, alarm
supplementary functions, etc., are set here.
4) Display Parameter Data range error addresses are stored
here. (See note.)
Note
1. The ERC indicator on the Unit's front panel will light if an out-of-range setting is made in either Setting Group 1 or 2. The offset from word m to the
first word containing the out-of-range error will be stored as the Data
Range Error Address in the DM Area in four digits hexadecimal. When an
error is made in Setting Group 1, the ERR indicator will light and the data
range error address will be stored immediately. When an error is made in
Setting Group 2, the ERC indicator will light when the PLC is turned ON
again or the Unit is restarted and the data range error address will be
stored at that time.
2. The functions that can be used depend on the model.
35
Section 1-4
Specifications and Installation
Transferring Analog I/O
Unit Default Settings to
the CPU Unit
When transferring the Analog I/O Unit’s default settings to the CPU Unit’s DM
Area to be used for operation, store 12345 (3039 hex) in word m and either
turn ON the power supply or restart the Unit. After the default settings have
been transferred, the value in word m will be automatically returned to 0 (0000
hex). From that point onwards, the values stored in the DM Area will be transferred to the Analog I/O Unit for operation when the PLC is turned ON or the
Unit is restarted.
Analog I/O Unit
CPU Unit
(See note 1.)
DM Area
m = D20000 + (unit No. x 100)
m
12345 (3039 Hex)
Setting Group 1
PLC turned ON or
Unit restarted.
m+1
to
Setting Group 2
When word m contains
12345 (3039 hex)
Settings
Default transfer reception
Analog I/O Unit
initial settings
m+34
to
m+93
Display Parameter
m+94
to
Analog I/O Unit
default settings are
transferred to the PLC
is turned ON or the
Unit is restarted.
m+99
Note
• Area Refreshed
when Restarted
Initial values for
sensor/input
signal types,
scaling, etc.
(See note 2.)
1. The allocated data areas depend on the model.
2. The functions that can be used depend on the model.
Restarting Special I/O
Units
To restore operation after the contents of the DM Area have been changed, or
after the cause of an error has been cleared, either turn ON the power supply
to the PLC or turn the Special I/O Unit Restart Bit ON.
Unit No.
DM Area allocation
0
1
A502.00
A502.01
to
15
to
A502.15
to
95
to
A507.15
Note If an error is not cleared when the PLC is turned ON again or the Special I/O
Unit Restart Bit is turned ON, replace the Unit.
CS1W-PTS11/12,
PDC11 and CJ1WPTS15/16, PDC15
These Units exchange data with the following CPU Unit areas:
• DM Area words allocated to the Unit as a Special I/O Unit
• CIO Area words allocated to the Unit as a Special I/O Unit
• Expansion Setting Area
• Expansion Control/Monitor Area
Set the addresses for these areas as follows:
36
Area
DM Area words allocated to the Unit as
a Special I/O Unit
Data Area allocated to the Unit as a
Special I/O Unit
Expansion Setting Area
Setting method
Set on the unit number switches (rotary
switches) on the front of the Analog I/O
Unit.
Expansion Control/Monitor Area
Set in words o and o+1 in the Expansion Setting Area.
Set in words m+98 and m+99 in the
DM Area.
Section 1-4
Specifications and Installation
Expansion Area addresses are determined as follows, according to the settings.
DM Area
A total of 100 words beginning with first word, word m (m = D20000 + unit
number (0 to 95) x 100).
Special I/O Unit Area
A total of 10 words beginning with first word, word n (n = 2000 + unit number
(0 to 95) x 100).
Expansion Setting Area
A total of 46 words (See note.) beginning with first word, word o (o = Word
specified in word m+99 in the area specified in word m+98 in the DM Area).
Note The expansion setting area for a CJ-series PLC is 24 words from word o to
word o+23.
Expansion
Control/Monitor Area
A total of 35 words beginning with first word, word p. (p = address specified in
word o+1 in the area specified in word o in the Expansion Setting Area.
Analog I/O Unit
CPU Unit
• Data for Operation
• Process values, analog
output values, rates of
change, error flags
• Special I/O Unit Area
n = 2000 + (unit No. × 10)
n
n+1
to
I/O refresh
n+9
•
Expansion Control/
Monitor Area
• Data for Operation
• Operation count, hold
function controls, hold
values, etc.
p = Address specified in o +1 in
area specified in o of
Expansion Setting Area
p
p+1
I/O refresh
to
p+34
• DM Area
m = D20000 + (unit No. × 100)
m
m+1
Default block read command
Power ON or Unit
restarted.
Points Used
Setting Group 1
m+2
to
Setting Group 2
(See note.)
I/O refresh, power
ON, or Unit restarted.
• Unit Settings
Initial setting transfer
direction reception
• Continuously
Refreshed Area
Alarm settings,
zero/span adjustment
settings, etc.
m+34
to
m+93
Display Parameter
(See note.)
Power ON or Unit
restarted.
m+94
to
• Area Refreshed
at Restart
Initial values for
sensor types,
scaling, etc.
m+97
Expansion Setting Area Allocation
Settings
m+98
m+99
Area of Expansion Setting Area
First Word in Expansion Setting Area
• Expansion Setting Area
o = Address specified in
m +99 in area specified
in m+98 of DM Area
Setting Group 3
o
o+1
o+2
to
o+45
(See note.)
Power ON or Unit
restarted.
(See note.)
Power ON or Unit
restarted.
Area of Expansion Control/Monitor Area
First word in Expansion Control/Monitor Area
(See note.)
Power ON or Unit
restarted.
Expansion Setting Area
Allocation Settings
• Settings
Expansion Control/Monitor Area
Settings
• Restart Refresh Area
Zero/span adjustment settings, operation count settings, top/valley hold settings, and number of inputs setting
37
Section 1-4
Specifications and Installation
Note
1. This applies when word m contains other than 12345 (3039 hex), e.g.,
0000 hex. When word m contains 12345 (3039 hex), the transfer direction
will be reversed.
2. The expansion setting area for a CJ-series PLC is 24 words from word o
to word o+23.
3. When specifying an expansion control/monitor area or an expansion setting area, be sure that it does not overlap with other areas that are being
used. If areas overlap, the words that are allocated may be overwritten, resulting in unexpected operation.
4. When specifying the first word in an expansion control/monitor area or an
expansion setting area, be sure that the end of the memory area is not exceeded.
These areas have the following functions for Analog I/O Units.
DM Area
Data is set in this area. The allocated portion of the DM Area
is divided into the five areas shown below.
Note For details, refer to the explanations for the individual
Units.
1) Default block read command:
When the PLC is turned ON or the Unit is restarted, the
data in the Analog I/O Unit can be transferred back to the
CPU Unit.
Beginning word m contains fixed.
When word m contains 12345 (3039 hex), then the data is
transferred from the Analog I/O Unit to the CPU Unit.
When word m contains less than 12345 (3039 hex), such
as 0 (0000 hex), then data is transferred from the CPU
Unit to the Analog I/O Unit as usual.
2) Setting Group 1 (continuously refreshed area):
While the PLC is ON (even if the CPU Unit is operating),
this area is continuously refreshed.
This area is refreshed when the PLC is turned ON or the
Unit is restarted.
The area is refreshed regardless of the CPU Unit’s operation mode (i.e., RUN, Monitor, or Program Mode).
Alarm settings, zero/span adjustment values, and so on,
are set here.
3) Setting Group 2 (initial settings area):
Data is transferred once to this area from the CPU Unit
when the PLC is turned ON or the Unit is restarted,
unless word m contains 12345.
Sensor types, process value scaling, alarm supplementary functions, etc., are set here.
4) Display parameters:
Data range error addresses are stored here. (See note.)
5) Expansion Setting Area settings:
Data is transferred once to this area from the CPU Unit
when the PLC is turned ON or the Unit is restarted, as
long as word m contains other than 12345.
Expansion Setting Area settings are made here.
Special I/O Unit Area The data in for operation is continuously refreshed.
The following types of data are transferred from Analog I/O
Units to the CPU Unit: Values scaled in industrial units for process values and rate-of-change values; alarm contact data,
Input Disconnection Flag data, etc.
38
Section 1-4
Specifications and Installation
Expansion Setting
Area
Data for operation is continuously refreshed.
Note For details, refer to the explanations for the individual
Units.
3) Setting Group 3 (initial settings area):
Data is transferred once to this area from the CPU Unit
when the PLC is turned ON or the Unit is restarted, as
long as word m contains other than 12345 and the
Expansion Setting Area settings are allocated (i.e., word
m+98 contains other than 0).
Expansion Control/Monitor Area settings, zero/span
adjustment supplementary function, and so on, are set
here.
Expansion Control/Monitor Area
Data for operation is continuously refreshed. Bits for beginning or resetting the hold function selection, adjustment
period control, control bits, and so on, are transferred from the
CPU Unit to the Analog Input Unit. Adjustment period notices,
peak and bottom values, top and valley values, and so on, are
transferred from the Analog Input Unit to the CPU Unit.
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Data Range Error
Address in the DM Area in four digits hexadecimal. If the first word containing
the out-of-range error is in the Expansion Setting Area, the Data Range Error
Address offset will be 100 words or more (e.g., 100 words for an error in the
first word in the Expansion Setting Area). When an error is made in Setting
Group 1, the ERR indicator will light and the data range error address will be
stored immediately. When an error is made in Setting Group 2, the ERC indicator will light when the PLC is turned ON again or the Unit is restarted and
the data range error address will be stored at that time.
Transferring Analog I/O
Unit Default Settings to
the CPU Unit
When transferring the Analog I/O Unit’s default settings to the CPU Unit’s DM
Area and Expansion Setting Area used for operation, store 12345 (3039 hex)
in word m and either turn the power supply OFF and ON or restart the Unit.
After the default settings have been transferred, the value in word m will be
automatically returned to 0 (0000 hex). From that point onwards, the values
stored in the DM Area will be transferred to the Analog I/O Unit for operation
when the PLC is turned ON or when the Unit is restarted.
Analog I/O Unit
CPU Unit
DM Area
m = D20000 + (unit No. x 100)
m
12345 (3039 hex)
Setting Group 1
Power ON or
Unit restarted.
m+1
to
Setting Group 2
m+34
to
m+93
Display Parameters
m+94
to
When word m contains
12345 (3039 hex)
When the PLC is
turned ON or the Unit
is restarted, the
default values in the
Unit are sent to the
CPU Unit.
Unit Settings
Default transfer reception
Analog I/O Unit
initial settings
• Area Refreshed
when Restarted
Initial values for
sensor types,
scaling, etc.
m+97
Expansion Setting Area settings
m+98
m+99
Area for Expansion Memory
Area
First word in Expansion
Setting Area
Expansion Setting
Area settings
39
Section 1-4
Specifications and Installation
Restarting Special I/O
Units
To restore operation after the contents of the DM Area have been changed, or
after the cause of an error has been cleared, either turn ON the power supply
to the PLC again or turn ON the Special I/O Unit Restart Bit ON.
Unit No.
AR Area allocation
0
1
A502.00
A502.01
...
15
...
A502.15
...
95
...
A507.15
Note If an error is not cleared when the PLC is turned ON again or the Special I/O
Unit Restart Bit is turned ON, replace the Unit.
CS1W-PTS55/56,
PDC55
The Analog I/O Unit exchanges data with the CPU Unit via the allocated portions of the CPU Unit’s Special I/O Unit Area and DM Area. The addresses
allocated in these areas are determined as follows, according to the value (0
to 95) set by the unit number switch on the front panel of the Analog I/O Unit.
• Special I/O Unit Area: 10 words from beginning word n
n = 2000 + unit number (0 to 95) x 10
• DM Area: 100 words from beginning word m
m = D20000 + unit number (0 to 95) x 100
• Expansion Setting Area
• CS1W-PTS55/PTS56
Address specified in word m+60 in the area specified in word o in the
Expansion Setting Area (one word only).
• CS1W-PDC55
Address specified in word m+84 in the area specified in word o in the
Expansion Setting Area (one word only).
The following table shows the addresses allocated according to the unit number.
Unit No.
40
Special I/O Unit Area
DM Area
0
1
CIO 2000 to CIO 2009
CIO 2010 to CIO 2019
D20000 to D20099
D20100 to D20199
2
3
CIO 2020 to CIO 2029
CIO 2030 to CIO 2039
D20200 to D20299
D20300 to D20399
4
5
CIO 2040 to CIO 2049
CIO 2050 to CIO 2059
D20400 to D20499
D20500 to D20599
6
7
CIO 2060 to CIO 2069
CIO 2070 to CIO 2079
D20600 to D20699
D20700 to D20799
8
9
CIO 2080 to CIO 2089
CIO 2090 to CIO 2099
D20800 to D20899
D20900 to D20999
10
to
CIO 2100 to CIO 2109
to
D21000 to D21099
to
95
CIO 2950 to CIO 2959
D29500 to D29599
Section 1-4
Specifications and Installation
Analog I/O Unit
CPU Unit
(See note 3.)
Data for Operation
Process values,
analog output values
Rates of change
Error flags
Special I/O Unit Area
n = 2000 + (unit No. x 10)
n
n+1
I/O refresh
to
n+9
DM Area
m = D20000 + (unit No. x 100)
m
Default block read command
Setting Group 1
Power ON or Unit
restarted.
(See note 1.)
m+1
to
Setting Group 2
I/O refresh
PLC turned ON or
Unit restarted.
m+34
(See note 1.)
to
PLC turned ON or
Unit restarted.
m+58
Unit Settings
Default transfer reception
Continuously
Refreshed Area
Alarm settings,
zero/span adjustment
values, etc.
Area Refreshed at Restart
Initial values for
sensor/input signal types,
scaling, etc.
(See note 2.)
Expansion Setting Area Settings
m+59
m+60
Expansion Setting
Area Settings
Expansion Setting Area Enable
Expansion Setting Area address
Expansion Setting Area
CS1W-PTS55/56
Address specified in m+60.
CS1W-PDC55
Address specified in m+84
o
Note
Expansion Setting Area
Unit Settings
I/O refresh
Process Value Alarm
1. This applies when word m contains other than 12345 (3039 hex), e.g.,
0000 hex. When word m contains 12345 (3039 hex), the transfer direction
will be reversed.
2. The functions that can be used depend on the model.
3. The allocated data areas depend on the model.
These areas have the following functions for Analog I/O Units.
Special I/O
Unit Area
The data for operation is continuously refreshed.
The following types of data are transferred from Analog Input Units to
the CPU Unit: Values scaled in industrial units for process values
and rate-of-change values; alarm contact data, Input Disconnection
Flag data, etc.
Analog output values are transferred from the CPU Unit to Analog
Output Units.
41
Section 1-4
Specifications and Installation
DM Area
Data is set in this area. The allocated portion of the DM Area is
divided into the four areas shown below.
Note For details, refer to the explanations for the individual Units.
1) Default block read When the PLC is turned ON or the Unit is
command
restarted, the data in the Analog I/O Unit
can be transferred back to the CPU Unit.
Beginning word m is fixed.
When word m contains 12345 (3039 hex),
then the data is transferred from the Analog
I/O Unit to the CPU Unit.
When word m contains less than 12345
(3039 hex), such as 0 (0000 hex), then data
is transferred from the CPU Unit to the Analog I/O Unit as usual.
2) Setting Group 1
(continuously
refreshed area)
Expansion
Setting Area
Note
While the PLC is ON (even if the CPU Unit
is operating), this area is continuously
refreshed.
This area is refreshed when the PLC is
turned ON or the Unit is restarted.
The area is refreshed regardless of the
CPU Unit’s operation mode (i.e., RUN, Monitor, or Program Mode).
Alarm settings, zero/span adjustment values, and so on, are set here.
3) Setting Group 2
When word m contains anything other than
(initial settings area) 12345 (3039 hex), data is transferred once
to this area from the CPU Unit when the
PLC is turned ON or the Unit is restarted.
Sensor types, process value scaling, alarm
supplementary functions, etc., are set here.
4) Display Parameter Data range error addresses are stored
here. (See note.)
Data for operation is continuously refreshed.
Process Value Alarm
1. The ERC indicator on the Unit's front panel will light if an out-of-range setting is made in either Setting Group 1 or 2. The offset from word m to the
first word containing the out-of-range error will be stored as the Data
Range Error Address in the DM Area in four digits hexadecimal. When an
error is made in Setting Group 1, the ERR indicator will light and the data
range error address will be stored immediately. When an error is made in
Setting Group 2, the ERC indicator will light when the PLC is turned ON
again or the Unit is restarted and the data range error address will be
stored at that time.
2. The functions that can be used depend on the model.
42
Section 1-4
Specifications and Installation
Transferring Analog I/O
Unit Default Settings to
the CPU Unit
When transferring the Analog I/O Unit’s default settings to the CPU Unit’s DM
Area to be used for operation, store 12345 (3039 hex) in word m and either
turn the power supply OFF and ON or restart the Unit. After the default settings have been transferred, the value in word m will be automatically returned
to 0 (0000 hex). From that point onwards, the values stored in the DM Area
will be transferred to the Analog I/O Unit for operation when the PLC is turned
ON or the Unit is restarted.
CPU Unit
Analog I/O Unit
(See note 1.)
DM Area
m = D20000 + (unit No. x 100)
m
Settings
Power ON or Unit
restarted.
Default transfer reception
12345 (3039 hex)
Setting Group 1
Continuously
Refreshed Area
Alarm settings,
zero/span adjustment
values, etc.
m+1
to
Setting Group 2
When m contains 12345
(3039 Hex)
m+34
to
m+93
Display Parameters
m+94
to
m+97
Expansion Setting Area Settings
m+98
m+99
Note
Expansion Setting Area Enable
Area Refreshed when
Restarted
Initial values for
sensor/input signal types,
scaling, etc.
Analog I/O Unit default
settings are transferred
to the CPU Unit when
the PLC is turned ON
or the Unit is restarted.
(See note 2.)
Analog I/O Unit default
settings are transferred
to the CPU Unit when
the PLC is turned ON
or the Unit is restarted.
Expansion Setting
Area Settings
Expansion Setting Area address
1. The allocated data areas depend on the model.
2. The functions that can be used depend on the model.
Restarting Special I/O
Units
To restore operation after the contents of the DM Area have been changed, or
after the cause of an error has been cleared, either turn ON the power supply
to the PLC or turn ON the Special I/O Unit Restart Bit.
Unit No.
DM Area allocation
0
1
A502.00
A502.01
to
15
to
A502.15
to
95
to
A507.15
Note If an error is not cleared when the PLC is turned ON again or the Special I/O
Unit Restart Bit is turned ON, replace the Unit.
CJ1W-PH41U
These Units exchange data with the following areas in the CPU Unit:
• DM Area words allocated to the Unit as a Special I/O Unit
• Special I/O Unit Area words in CIO Area
• Expansion Setting Area
• Expansion Control/Monitor Area
Set the addresses for these areas as follows:
Area
Setting method
DM Area words allocated to the Unit as a Set on the unit number switches (rotary
Special I/O Unit
switches) on the front of the Analog I/O
Special I/O Unit Area words in CIO Area Unit.
43
Section 1-4
Specifications and Installation
Area
Expansion Setting Area
Setting method
Set in words m+98 and m+99 in the DM
Area.
Expansion Control/Monitor Area
Set in words o+32 and o+33 in the
Expansion Setting Area.
Allocated area addresses are determined as follows, according to the settings:
• DM Area: A total of 100 words beginning with first word, word m (m =
D20000 + unit number (0 to 95) x 100).
• Special I/O Unit Area: A total of 10 words beginning with first word, word n
(n = CIO 2000 + unit number (0 to 95) x 10).
• Expansion Setting Area: A total of 100 words beginning with first word,
word o (o = Word specified in word m+99 in the area specified in word
m+98, m+98 and m+99 are in the DM Area).
• Expansion Control/Monitor Area: A total of 46 words beginning with first
word, word p (p = address specified in word o+33 in the area specified in
word o+32, o+32 and o+33 are in the Expansion Setting Area).
44
Section 1-4
Specifications and Installation
CPU Unit
Analog I/O Unit
Data for Operation
Special I/O Unit Area
n = CIO 2000 + unit No. x 10
Process value, alarm
contact data, etc.
n
n+1
I/O refresh
to
n+9
Expansion Control/Monitor Area
Data for Operation
p = Address specified in o+33 in area
specified in o+32 in Expansion Setting
Area
Hold function settings,
rate-of-change values,
hold values, etc.
p
p+1
I/O refresh
p+46
DM Area
m = D20000 + unit No. x 100
m
m+1
Default block read command
Settings
Power ON or
Unit restarted.
Operation settings
Setting group 1
(See note 1.)
m+2
I/O refresh, power ON,
or Unit restarted.
to
Setting group 2
m+34
(See note 1.)
to
Power ON or
Unit restarted.
m+93
Initial setting transfer
direction reception
• Continuously Refreshed Area
Alarm settings,
zero/span adjustment
settings, etc.
• Area Refreshed at
Restart
Initial values for input
type, scaling, etc.
Display parameters
m+94
(See note 1.)
to
Power ON or
Unit restarted.
m+97
Expansion Setting Area allocations
m+98
m+99
Area of Expansion Setting Area
First word of Expansion Setting Area
(See note 1.)
Power ON or
Unit restarted.
Expansion Setting Area
Allocation Settings
Expansion Setting Area
o = Word specified in m+99 in area
specified in m+98 in DM Area
Settings
Setting group 3
o
o+1
(See note 1.)
Setting group 4
o+32
o+33
to
I/O refresh, power ON,
or Unit restarted.
Area of Expansion Control/Monitor Area
First word of Expansion Control/Monitor Area
(See note 1.)
Power ON or
Unit restarted.
(See note 1.)
o+99
Note
• Continuously Refreshed
Area
Rate of change, etc.
Expansion Control/Monitor Area Settings
• Restart Refresh Area
Rate-of-change function,
zero/span adjustment
supplementary function,
etc.
Power ON or
Unit restarted.
1. This applies when word m contains other than 12345 (3039 hex), e.g.,
0000 hex. When word m contains 12345 (3039 hex), the transfer direction
will be reversed.
2. When specifying the Expansion Control/Monitor Area or an Expansion
Setting Area, be sure that it does not overlap with other words that are being used for another purpose. If areas overlap, the words that are allocated
may be overwritten, resulting in unexpected operation.
3. When specifying the first word in the Expansion Control/Monitor Area or
the Expansion Setting Area, be sure that the end of the memory area is not
exceeded.
45
Section 1-4
Specifications and Installation
These areas have the following functions for Analog I/O Units.
DM Area
Data is set in this area. The allocated portion of the DM Area is
divided into the five areas shown below.
Note: For details, refer to the explanations for the individual Units.
1. Default block
When the power is turned ON or the Unit
read command
is restarted, the default data in the Analog
I/O Unit can be read to the CPU Unit.
• Beginning word m is fixed.
• When word m contains 12345
(3039 hex), then the data is transferred
from the Analog I/O Unit to the CPU
Unit.
• When word m contains other than
12345 (3039 hex), e.g., 0 (0000 hex),
then data is transferred from the CPU
Unit to the Analog I/O Unit as usual.
2.
3.
CIO Area
46
Setting Group 1 While the PLC is ON (even if the CPU
(continuously re- Unit is operating), this area is continufreshed area)
ously refreshed. This area is also
refreshed when the power is turned ON or
the Unit is restarted. The area is
refreshed regardless of the CPU Unit's
operation mode (i.e., RUN, Monitor, or
Program Mode). Alarm settings,
zero/span adjustment values, etc., are set
here.
Setting Group 2 When word m contains anything other
(initial settings
than 12345 (3039 hex), data is transferred
area)
once to the Analog I/O Unit from the CPU
Unit when the power is turned ON or the
Unit is restarted. Input types, process
value scaling, alarm supplementary functions, etc., are set here.
4.
Display Parame- Data range error addresses are stored
ter
here. (See note.)
5.
Expansion Setting Area settings
Data is transferred once to the Analog I/O
Unit from the CPU Unit when the power is
turned ON or the Unit is restarted, as long
as word m contains other than 12345.
Expansion Setting Area settings are
made here.
The data for operation is continuously refreshed. The following types
of data are transferred from the Analog I/O Unit to the CPU Unit: Values scaled in industrial units for the process value, alarm contact
data, Input Error Flag data, etc.
Section 1-4
Specifications and Installation
Expansion
Setting Area
Data is set in this area.
Note: For details, refer to the explanations for the individual Units.
1. Setting Group 3 While the PLC is ON (even if the CPU
(continuously re- Unit is operating), this area is continufreshed area)
ously refreshed. This area is also
refreshed when the power is turned ON or
the Unit is restarted. The area is
refreshed regardless of the CPU Unit's
operation mode (i.e., RUN, Monitor, or
Program Mode). Settings, such the as
rate-of-change alarm setting, are set
here.
2.
Expansion
Control/Monitor Area
Setting Group 4
(initial settings
area)
Data is transferred once to the Analog I/O
Unit from the CPU Unit when the power is
turned ON or the Unit is restarted, as long
as word m contains other than 12345 and
the Expansion Setting Area settings are
allocated (i.e., word m+98 contains other
than 0). Expansion Control/Monitor Area
settings, rate-of-change function,
zero/span adjustment supplementary
function, etc., are set here.
Data for operation is continuously refreshed. Bits for beginning or
resetting the hold function selection, adjustment period control, control bits, etc., are transferred from the CPU Unit to the Analog I/O
Unit. Adjustment period notice, peak and bottom values, top and valley values, and so on, are transferred from the Analog I/O Unit to the
CPU Unit.
Note The ERC indicator on the Unit's front panel will light if an out-of-range setting
is made in either Setting Group 1 (continuously refreshed area) or Setting
Group 2 (initial settings area). The offset from word m to the first word containing the out-of-range error will be stored as the Data Range Error Address in
the DM Area in four digits hexadecimal. If the first word containing the out-ofrange error is in the Expansion Setting Area, the Data Range Error Address
offset will be 100 words or more (e.g., 100 words for an error in the first word
in the Expansion Setting Area).
When an error is made in Setting Group 1, the ERC indicator will light and the
data range error address will be displayed immediately. When an error is
made in Setting Group 2, the ERC indicator will light when the power is turned
ON again or the Unit is restarted and the data range error address will be displayed at that time. For details, refer to 1-6 Error Processing.
Transferring Analog I/O
Unit Initial Settings to the
CPU Unit
When transferring the Analog I/O Unit initial settings to the CPU Unit DM Area
and Expansion Setting Area for operation, store 12345 (3039 hex) in word m
and either again turn ON the power supply or restart the Unit. After the default
settings have been transferred, the value in word m will be automatically
returned to 0 (0000 hex). From that point onwards, the values stored in the
DM Area will be transferred to the Analog I/O Unit for operation when the
power is turned ON or the Unit is restarted.
The Analog I/O Unit holds the default settings, and they cannot be overwritten.
47
Section 1-4
Specifications and Installation
CPU Unit
DM Area
m = D20000 + unit No. x 100
m
Analog I/O Unit
Power ON or
Unit restarted.
Settings
Initial setting transfer direction reception
12345 (3028 hex)
Setting group 1
m+1
Initial settings in
Analog I/O Unit
to
Setting group 2
Word m = 12345
(3039 hex)
m+34
to
m+93
Display parameters
m+94
Power ON or Unit restarted:
Initial settings in Analog
I/O Unit are transferred
to CPU Unit.
• Area Refreshed at
Restart
Initial values for input type, scaling,
etc.
to
m+97
m+98
m+99
Restarting Special I/O
Units
Expansion Setting Area allocations
Area of Expansion Setting Area
Expansion Setting Area
Allocation Settings
First word of Expansion Setting Area
To restart Unit operation after the contents of the DM Area have been
changed, or after the cause of an error has been cleared, either turn ON the
power supply to the PLC again or turn ON the Special I/O Unit Restart Bit.
Unit No.
Restart Bit
0
1
A502.00
A502.01
to
15
to
A502.15
to
95
to
A507.15
Note If an error is not cleared when the power is turned ON again or the Special I/O
Unit Restart Bit is turned ON, replace the Analog I/O Unit.
1-4-4
Mounting the Units
CS Series
Use the following procedure to mount the CS-Series Analog I/O Unit to the
Backplane.
1,2,3...
1. Mount the Unit to the Backplane by attaching it with the top and bottom
hooks.
Hook
Backplane
2. Properly insert each Unit into the Backplane connector, and tighten the
screws on the bottom of the Unit to a torque of 0.4 N·m.
48
Section 1-4
Specifications and Installation
3. To remove a Unit, loosen the screws and lift it off.
Screw
Note To allow for mounting and removal of Units, leave at least 20 mm of space
between Units, as shown in the following diagram.
20 mm min.
Backplane
20 mm min.
Phillips-head screwdriver
CJ Series
Use the following procedure to connect Analog I/O Units to a CJ-series Rack.
1,2,3...
1. Align the connectors and press in firmly on the Units to connect them completely.
Hooks
Connector
Hook holes
2. Move the sliders on the top and bottom of the Unit to the lock position to
secure the Units. The sliders should click into place.
49
Section 1-4
Specifications and Installation
Move the sliders to the back
until they click into place.
Slider
Lock
Release
3. Attach an End Cover to the Unit on the right end of the Rack.
Note The CJ-series PLC may not operate properly if the sliders are not locked
firmly into place.
1-4-5
Precautions when Handling Units
CS Series
Turn OFF the power to the PLC before mounting or removing Units, or connecting or disconnecting wiring.
To prevent adverse effects from noise, place I/O wiring in separate ducts from
high-voltage or power lines.
Always ground the GR terminal on the Power Supply Unit of the PLC.
When wiring, leave the label on the Unit’s top panel in place to prevent foreign
objects such as wire clippings from dropping into the Unit. The label must be
removed after wiring or the Unit will overheat.
Remove the label after wiring has been completed.
CJ Series
50
Be sure to turn OFF the power supply to the PLC before installing or disconnecting Units or connecting lines.
To reduce the risk of malfunctioning due to electrical noise, wire input and output lines in separate ducts from high-voltage and power lines.
When wiring a Unit, place a label over the top of the Unit to prevent wire clippings or other materials from getting inside the Unit. When the wiring has
been completed, the label must be removed to prevent heat radiation.
Section 1-4
Specifications and Installation
Remove the label after the
wiring has been completed.
N
RUC
ERH
ER
H
MAC
No. 1
x10
0
x10
• The terminal block is removable. Press the lever on the bottom of the terminal block to remove the terminal block.
• During normal use, check that the lever is raised and the terminal block is
locked in place.
Note Precautions for Terminal Blocks on Thermocouple Input Units and CJ1WPH41U Isolated-type Universal Input Units
• Thermocouple Input Units and CJ1W-PH41U Isolated-type Universal
Input Units have cold junction compensators. The specified accuracy will
be as specified only when the cold junction compensator (i.e., the terminal block) and the Unit are used as a set. Always use the terminal block
and the Unit as a set. Both the CJ1W-PTS51 Unit terminal block and this
Unit have labels on them providing the serial number.
• If repairs are required to the Unit, always return the terminal block (including the cold junction compensator) with the Unit.
Serial No.
LOT No.
23X3
SER No.
0008
8188E
RUN
ERC
ERH
54321
54321
N
RUC
ER
ERH
DCBA
DCBA
MACH 0 FE 1 0 FE X100
X10
No.
9876
9876
Precautions in Handling
Removable Terminal
Blocks
A1
B1
MACH
No. 1
X10
X10
0
51
Section 1-4
Specifications and Installation
1-4-6
Connecting Crimp Terminals
M3 screw
Fork type
6.0 mm max.
Round type
6.0 mm max.
Note Tighten the terminal screws securely to a torque of 0.5 N·m. Loose screws
may result in conversion errors.
1-4-7
Dimensions
CS Series
[email protected]@[email protected]/[email protected]/51/52
52
Unit: mm
Section 1-4
Specifications and Installation
6.4
92.66±0.1
7.62
7.62 8.23
■ Terminal Block Dimensions
4.5
CS1W-PTS55/56/PDC55
125 mm
101 mm
35 mm
RUN
ERC
ERH
X101
X100
2.4 mm
6 mm
130 mm
MACH
No.
8.4
17.8
53
Section 1-4
Specifications and Installation
96.47
6.4
7.62
■ Terminal Block Dimensions
10
18.6
CJ Series
89
2.7
65
31
PTS51
RUN
ERC
ERH
MACH
No.
×101
2.7
90
×100
54
B1
A1
Section 1-5
Operating Procedures
1-5
Operating Procedures
Use the following procedures to operate the Analog I/O Unit. The procedures
are the same for all models.
Initial Setup (Hardware)
1,2,3...
1. Set the unit number, using the rotary switches on the front panel of the
Unit.
2. Mount the Unit to either a CPU Rack or Expansion Rack.
A maximum of 80 Units for the CS Series and 40 Units for the CJ Series
can be mounted in a basic System (with no restrictions on mounting location).
3. Connect sensors or external control units.
4. Connect a Programming Device to the PLC.
5. Turn ON the power to the PLC.
6. Create the I/O tables.
7. Allow time for warmup (see note).
Note Analog I/O Units require time to warm up after the PLC is turned ON.
Warmup times differ for each Unit, as shown in the following table.
Model
CS1W-PTS01-V1/11, CJ1W-PTS15
[email protected], [email protected]
CJ1W-PH41U
Other Analog I/O Units
Warmup time
45 min
30 min
Resistance thermometer
inputs: 30 min
Thermocouple, ±100-mV
user-set range inputs: 45 min
Current and voltage inputs
(not including ±100-mV userset range inputs): 30 min
Potentiometer inputs: 10 min
10 min
Initial Software Setup
1,2,3...
1. Make the initial settings in the DM Area (m to m+99).
• When using the Unit’s default values, set word m to 12345 (3039 hex).
• When using data from the CPU Unit’s DM Area, set word m to a value
other than 12345 (3039 hex), such as 0000 hex.
2. Turn the power OFF and then back ON again, or turn ON the Special I/O
Unit Restart Bit.
55
Section 1-5
Operating Procedures
Ladder Diagram Program
Name
Model
Isolated-type Thermo- CS1W-PTS01couple Input Unit
V1
CS1WPTS11/51
Isolated-type Resistance Thermometer
Input Unit (Pt100,
JPt100)
CS1W-PTS55
CJ1W-PTS51/
15
CS1W-PTS02
Isolated-type Resistance Thermometer
Input Unit (Ni508.4)
CS1W-PTS03
Isolated-type Resistance Thermometer
Input Unit (Pt100,
JPt100, Pt50,
Ni508.4)
CS1W-PTS12
CJ1W-PTS16
Isolated-type Resistance Thermometer
Input Unit (Pt100,
JPt100)
Isolated-type 2-Wire
Transmitter Input Unit
CS1W-PTS52
CS1W-PTS56
Isolated-type Direct
Current Input Unit
CS1W-PDC01
CS1W-PDC11
CJ1W-PDC15
CS1W-PDC55
Basic ladder diagram programming
Reading the converted value using MOV(021) with the Input Disconnection
Flag's NC condition as the input condition.
Input Disconnection Flag (See note.)
MOV (021)
Bit 08 of word n+9
2009.08
2001
Input No. 1 converted value
Word n+1
D01000
Note: Bit 00 of word n +9 (CIO 2009.00 for unit number 00) is the Sensor Error
Flag for [email protected] and [email protected]
CJ1W-PTS52
CS1W-PTW01
Reading the converted value using MOV(021) with the Input Error Flag's
NC condition as the input condition.
Input Error Flag (See note)
MOV (021)
Bit 08 of word n+9
2009.08
2001
D01000
Input No. 1 converted value
Word n+1
Note: Bit 00 of word n +9 (CIO 2009.00 for unit number 00) is the Sensor Error
Flag for [email protected]
Power Transducer
Input Unit
CS1W-PTR01
Isolated-type Pulse
Input Unit
CS1W-PPS01
Analog Input Unit
(100 mW)
Isolated-type Analog
Output Unit
CS1W-PTR02
CS1W-PMV01
CS1W-PMV02
Isolated-type Universal Input Unit
CJ1W-PH41U
Reading the converted value using MOV(021).
Writing the value to convert using MOV(021). After writing, then checking of the
answer input value and output disconnection.
Writing the value to convert using MOV(021).
Reading the converted value using MOVL(498) with the Input Error Flag's
NC condition as the input condition.
Input Error Flag
MOVL (498)
Bit 08 of word n+9
2009.08
2000
D01000
56
Input No. 1 converted value
Word n
Section 1-6
Error Processing
1-6
Error Processing
The following table shows the contents of the LED indicator displays on the
front panel of the Analog I/O Unit. The contents shown here are the same for
all models. For error processing specific to each Unit, refer to the explanations
for the individual Units.
Errors Detected by the Analog I/O Unit
ERC LED
(red)
Lit
RUN LED
(green)
Lit
Not lit
Contents
Probable cause
Unit operation
Remedy
Setting Group 1 (continuously refreshed
area) error
(See note 1.)
The Analog I/O Unit
started up and was
operating properly,
but an out-of-range
setting was made in
Setting Group 1 in the
DM Area.
The Unit continues
operating with the
Setting Group 1 data
prior to the change.
Restore the set value
to within the allowable
range. (There is no
need to turn the
power supply OFF
and ON or to restart
the Unit.)
Setting Group 1 (See
note 1.), Setting
Group 2 (See note 2.)
error, or Expansion
Setting Area (See
note 3.)
An out-of-range set- The Unit will not start
ting was made for
up.
either Setting Group 1
or Setting Group 2 in
the DM Area.
Restore the set value
to within the allowable
range, and then either
turn the power supply OFF and ON or
restart the Unit.
Note
1. The following table shows the processing and results for Setting Group 1.
Processing
Result
LED indicators on
Unit
Data range error
address stored in
DM Area
When an out-ofrange setting is
made in Setting
Group 1 during
operation
The Unit continues
to operate with the
Setting Group 1
data prior to the
change.
ERC indicator is lit.
RUN indicator
remains lit.
The lowest DM
address where the
out-of-range error
occurred is stored,
in four digits hexadecimal, as the offset value from m
(i.e., the number of
added words).
↓
When the setting is
changed within the
allowable range
during operation
The Unit operates
with the Setting
Group 1 data after
the change.
ERC indicator is not If there is no other
lit. RUN indicator
error, 0000 hex is
remains lit.
stored. (If there is
another error, the
offset value for that
DM address is
stored.)
The Unit will not
start up.
ERC indicator is lit. The lowest DM
RUN indicator is not address where the
lit.
out-of-range error
occurred is stored,
in four digits hexadecimal, as the offset value from m
(i.e., the number of
added words).
The Unit starts up
normally.
ERC indicator is not If there is no other
lit. RUN indicator is error, 0000 hex is
lit.
stored. (If there is
another error, the
offset value for that
DM address is
stored.)
When the PLC is
turned ON or the
Unit is restarted
with an error still in
effect.
↓
When the setting is
made within the
allowable range,
and the PLC is
turned ON or the
Unit is restarted
57
Section 1-6
Error Processing
2. The following table shows the processing and results for Setting Group 2.
Processing
When an out-ofrange setting is
made in Setting
Group 2 during
operation
Result
The Unit operates
with the Setting
Group 2 data prior
to the change.
↓
When the PLC is
The Unit will not
turned ON or when start up.
the Unit is restarted
↓
When the setting is
made within the
allowable range,
and the PLC is
turned ON or the
Unit is restarted
58
The Unit starts up
normally.
LED indicators on
Unit
Data range error
address stored in
DM Area
ERC indicator is not If there is no other
lit. RUN indicator
setting error, 0000
remains lit.
hex remains stored.
(If there is another
setting error, the
offset value for that
DM address is
stored.)
ERC indicator is lit. The lowest DM
RUN indicator is not address where the
lit.
out-of-range error
occurred is stored,
in four digits hexadecimal, as the offset value from m
(i.e., the number of
added words).
ERC indicator is not If there is no other
lit. RUN indicator is error, 0000 hex is
lit.
stored. (If there is
another error, the
offset value for that
DM address is
stored.)
Section 1-6
Error Processing
Errors Related to the CPU Unit
The ERH indicator will be lit red for all of the following errors.
ERH RUN
LED
LED
(red) (green)
Lit
Lit
Contents
Error in
data
exchange
with the
CPU Unit
Probable
cause
During normal operation, an I/O
bus error,
CPU Unit
monitoring
error, or
WDT error
occurred at
the CPU
Unit.
Error type
I/O bus error A data transmission error
occurred
between the
CPU Unit and
the Analog
I/O Unit.
CPU Unit
monitoring
error
CPU Unit
WDT error
Not lit
Error in
Analog I/O
Unit’s unit
number or
mounting
Either the
unit number is set
incorrectly
or the Unit
is mounted
incorrectly.
Detailed
cause
WDT error
has been
generated at
CPU Unit.
The Analog
I/O Units registered in the
I/O table are
different from
the ones
actually
mounted.
Fatal error at CPU Unit after turning ON the power supply
Note
Converted
data
becomes
0000 hex.
External
alarm output:
No output.
(See note 3.)
Depending
on the output
hold status,
either the set
values prior
to the error or
preset values will be
held.
Changes to
undefined
state.
External
alarm output:
No output.
(See note 3.)
Depending
on the output
hold status,
either the set
values prior
to the error or
preset values will be
held.
Remedy
Turn OFF the
power supply
and check the
installation conditions and the
cable connections between
devices. Then
turn the power
The CPU
Maintains the Held at status back ON.
Unit did not
status exist- existing
respond
ing before the before the
within a fixed error.
error.
period of
External
time.
alarm output:
Output.
(See note 3.)
Duplicate
The same
Unit Number unit number
has been
assigned to
more than
one Unit or
the unit number was set
to a value
other than 00
to 95.
Special I/O
Unit Setting
Error
Input Unit
Output Unit
status
status
(See note 1.) (See note 2.)
Conversion
0 mA or 0 V
does not
will be output.
start.
External
alarm output:
No output.
(See note 3.)
In PROGRAM
Mode, turn the
power OFF and
then back ON.
Reset the unit
number so that it
will not duplicate
any other.
Check the
mounting positions, and either
mount the Units
according to the
I/O table or correct the I/O table.
Take measures
for CPU fatal
error.
1. Applicable Units:
CS1W-PTS01-V1/PTS11/PTS51/PTS55 and CJ1W-PTS51/15 Isolatedtype Thermocouple Input Units
CS1W-PTS02/PTS03/PTS12/PTS52/PTS56 and CJ1W-PTS52/16 Isolated-type Resistance Thermometer Input Units
CS1W-PTW01 Isolated-type 2-Wire Transmitter Input Unit
CS1W-PDC01/PDC11/PDC55, PTR02, and CJ1W-PDC15 Isolated-type
Direct Current Input Units
59
Section 1-6
Error Processing
CS1W-PTR01 Power Transducer Input Unit
CS1W-PTR02 Analog Input Unit (100 mV)
CS1W-PPS01 Isolated-type Pulse Input Unit.
CJ1W-PH41U Isolated-type Universal Input Units
2. Applicable Unit: CS1W-PMV01 Isolated-type Analog Output Unit.
3. Indicates the external alarm output status for CS1W-PTS51/PTS52 and
CJ1W-PTS51/PTS52. The alarm outputs will operate normally even if all
loads are turned OFF from the CPU Unit.
4. If either of the following changes is made for the Expansion Setting Area
for the CJ1W-PTS15/-PTS16/-PDC15/-AD04U/-PH41U, the previous data
will be left in the Expansion Setting Area even after the change has been
made.
Clear the previous data when changing either of these settings.
• The Expansion Setting Area allocation is disabled.
• The Expansion Setting Area Address setting is changed while the Expansion Setting Area allocation is enabled.
60
Section 1-7
Specification Changes
1-7
1-7-1
Specification Changes
CS1W-PTS01-V1, CS1W-PTS02/PTS03, CS1W-PTW01, CS1WPDC01, CS1W-PPS01, and CS1W-PMV01
The specifications of the following I/O Units with the lot number 000426 XXXX
or later (manufactured since April 26, 2000) have been changed as shown in
the table below.
Overview
Name
Isolated-type Thermocouple Input Unit
Model
CS1W-PTS01-V1
Main changes
• Improved effective resolution: From the equivalent of
10 bits to 1/4,096
• Improved rate-of-change calculation: Refer to
Improvement in Rate-of-change Calculation Method
below for details.
• Improved effective resolution: From the equivalent of
10 bits to 1/4,096
• Improved rate-of-change calculation: Refer to
Improvement in Rate-of-change Calculation Method
below for details.
Isolated-type Resistance Thermometer
Input Unit
CS1W-PTS02
Isolated-type Resistance Thermometer
Input Unit (Ni508.4 Ω)
CS1W-PTS03
• Improved effective resolution: From the equivalent of
11 bits to 1/4,096
• Improved rate-of-change calculation: Refer to
Improvement in Rate-of-change Calculation Method
below for details.
Isolated-type 2-Wire Transmitter Input Unit CS1W-PTW01
• Improved effective resolution: From the equivalent of
10 bits to 1/4,096
• Improved rate-of-change calculation: Refer to
Improvement in Rate-of-change Calculation Method
below for details.
• Reduced 26-V consumption current: 0.4 A to 0.16 A
Isolated-type Direct Current Input Unit
CS1W-PDC01
Isolated-type Pulse Input Unit
CS1W-PPS01
• Improved effective resolution: From the equivalent of
10 bits to 1/4,096
• Improved rate-of-change calculation: Refer to
Improvement in Rate-of-change Calculation Method
below for details.
• Added input range: 0 to 20 mA (Refer to New Input
Range (0 to 20 mA) for the CS1W-PDC01 for details.)
• Changed instantaneous value setting method and
added time unit setting function (Refer to Instantaneous Value Measurement and Measurement Time
Unit Setting for CS1W-PPS01 for details.)
• Reduction of 26 V consumption current: 0.22 A to
0.16 A
Isolated-type Analog Output Unit
CS1W-PMV01
• Improved resolution (answer back input): From the
equivalent of 9 bits to 1/2000
Details
Improvement in Rate-of-change Calculation Method
Before Change
The current process value was compared with the value before the time set by
the comparison time interval and the difference between them was divided by
the comparison time interval to find the rate-of-change per second. When the
difference was small, the calculated value turned out to be so small that it was
hard to identify the change.
61
Section 1-7
Specification Changes
After Change
The current process value is compared with the value before the time set by
the comparison time interval and the difference is output. When the difference
is small, the comparison time interval can be set longer so that the change
can be easily identified.
New Input Range (0 to 20 mA) for the CS1W-PDC01
Before Change
–10 to 10 V, 0 to 10 V, –5 to 5 V, 0 to 5 V, 1 to 5 V, 4 to 20 mA, user-set voltages
After Change
–10 to 10 V, 0 to 10 V, –5 to 5 V, 0 to 5 V, 1 to 5 V, 4 to 20 mA, user-set voltages, 0 to 20 mA (new)
The settings are shown below. (There is no need to change the setting unless
the new setting is going to be used.)
• Before Change (m = D20000 + Unit number x 100)
Input
No. 1
m+34
Offset
Input
Input
No. 2
No. 3
m+48 m+62
Input
No. 4
m+76
Setting
range
0 to 6
Setting name
Input signal
0: –10 to +10 V,
1: 0 to 10 V,
2: –5 to 5 V,
3: 0 to 5 V,
4: 1 to 5 V,
5: 4 to 20 mA,
6: User-set voltages
• After Change (m = D20000 + Unit number x 100)
Offset
Input
No. 1
m+34
Input
No. 2
m+48
Input
No. 3
m+62
Input
No. 4
m+76
Setting
range
0 to 7
Setting name
Input signal
0: –10 to +10 V,
1: 0 to 10 V,
2: –5 to 5 V,
3: 0 to 5 V,
4: 1 to 5 V,
5: 4 to 20 mA,
6: User-set voltages
7: 0 to 20 mA
Instantaneous Value Measurement and Measurement Time Unit Setting for CS1W-PPS01
Instantaneous Value Measurement
Before Change
The number of pulses per second was output as an instantaneous value. To
calculate the value, the number of pulses per 0.1 second was multiplied by 10.
For pulses less than 10 Hz, 10 pulses/second and 0 pulses/second were
alternately output due to inaccurate calculations.
After Change
The number of pulses per second is counted for that one second and output
as is. This allows calculation of pulses down to 1 Hz.
62
Section 1-7
Specification Changes
Measurement Time Unit Setting
This new function allows setting of measurement time unit to enable measuring pulses with much slower frequencies. Measurement time unit can be set
to 1, 3, 10, 30, or 60 s.
The settings are shown below. (There is no need to change the setting if the
current unit of 1 s is going to be used.)
• Before Change (m = D20000 + Unit number x 100)
Offset
Input
No. 1
m+30
Input
No. 2
m+38
Input
No. 3
m+46
Setting
range
Input
No. 4
m+54
Bits 00 to
03: 0 to 3
Bits 04 to
15: 0
Setting name
Decimal point position
from right of instantaneous value conversion
coefficient
Not used
• After Change (m = D20000 + Unit number x 100)
Input
No. 1
m+30
Offset
Input
Input
No. 2
No. 3
m+38 m+46
Input
No. 4
m+54
Setting
range
Bits 00 to
03: 0 to 3
Bits 04 to
07: 0 to 4
Bits 08 to
15: 0
1-7-2
Setting name
Decimal point from right
of instantaneous value
conversion coefficient
Instantaneous value
time unit
0: 1 s
1: 3 s
2: 10 s
3: 30 s
4: 60 s
Not used
CS1W-PTS51/PTS52 and CJ1W-PTS51/PTS52
The specifications of the following I/O Units with the lot number XX84 or later
(manufactured since August 2004) have been changed as shown in the table
below.
Model
CS1WPTS51/PTS52
CJ1WPTS51/PTS52
CS1W-PTS51/PTS52
Name
Isolated-type Thermocouple
Input Units
Main changes
• Added setting for selecting the
span adjustment resolution for
the zero/span adjustment function.
Before change: Resolution of
1/1,000
After change: Resolution of
1/1,000 or 1/10,000 selectable
• Before Change (m = D20000 + Unit number × 100)
DM address
Input No. 1 Input No. 2 Input No. 3 Input No. 4
Data range
Decimal
Hexadecimal
Default value
Data name
Span adjustment
m+4
m+8
m+12
m+16
0 to 9999
0000 to 270F
hex
1000 (03E8 hex) Set value ×
0.001
63
Section 1-7
Specification Changes
• After Change (m = D20000 + Unit number × 100)
DM address
Input No. 1 Input No. 2 Input No. 3 Input No. 4
Data range
Decimal
Hexadecimal
Default value
Data name
Span adjustment
m+4
m+8
m+12
m+16
0 to 9999
0000 to 270F
hex
0 to 32000
0000 to 7D00
hex
1000 (03E8 hex) m+35 contains
0:
Set value ×
0.001
10000
m+35 contains
(2710 hex)
1:
Set value ×
0.0001
Span adjustment mode
setting
m+35
0, 1
0000, 0001 hex 1 (See note.)
0: 1/1,000
1: 1/10,000
Note Indicates the value after transferring the default values (set when 12345 is
written to word m).
CJ1W-PTS51/PTS52
1-7-3
Settings are the same as for the CS1 models, except that the address m+35
becomes m+32.
CS1W-PTS55 and CS1W-PDC55
The specifications of the following Analog I/O Units with a lot number of
070315_XXXX or later (manufactured since March 15, 2007) have been
changed as shown in the table below.
Model
CS1W-PTS55
64
Isolated-type Thermocouple
Input Unit
CJ1W-PDC55
Isolated-type Thermocouple
Input Unit
Main changes
Added functionality for temperature data notation in units of
0.1°C or 0.1°F. (Only binary is
supported for the data format.)
Added functionality for holding
data during a sensor error.
• Before Change (m = D20000 + Unit number × 100)
Word
m+34
Name
CS1W-PTS55
Bit
Default value
Description
Settings
00
0
Temperature unit setting
0: °C
1: °F
04
0
Data format
0: Binary (Negative values are
given as 2’s complements.)
1: BCD
08
0
Minus sign display format for
BCD display
0: “F” used to indicate the minus
sign.
1: Leftmost bit used to indicate the
minus sign. The setting is disabled
if bits 04 to 07 are set to 0.
12
0
Data direction at sensor error
0: Goes to upper limit at sensor
error.
1: Goes to lower limit at sensor
error.
Section 1-7
Specification Changes
• After Change (m = D20000 + Unit number × 100)
Word
m+34
Bit
Default value
Settings
0
Temperature unit setting
0: °C
1: °F
01
0
Data unit setting
04
0
Data format
08
0
Minus sign display format for
BCD display
12
0
Data direction at sensor error
0: Follow the input type setting.
1: Use units of 0.1°C or 0.1°F as
the temperature data format. (Only
binary is supported.)
0: Binary (Negative values are
given as 2’s complements.)
1: BCD
0: “F” used to indicate the minus
sign.
1: Leftmost bit used to indicate the
minus sign. The setting is disabled
if bits 04 to 07 are set to 0.
0: Goes to upper limit at sensor
error.
1: Goes to lower limit at sensor
error.
CS1W-PDC55
• Before Change (m = D20000 + Unit number × 100)
Word
m+34
Description
00
Bit
00
Default value
Description
0
Data format
08
0
Minus sign display format for
BCD display
12
0
Data direction at sensor error
Settings
0: Binary (Negative values are
given as 2’s complements.)
1: BCD
0: “F” used to indicate the minus
sign.
1: Leftmost bit used to indicate the
minus sign. The setting is disabled
if bits 04 to 07 are set to 0.
0: Goes to upper limit at sensor
error.
1: Goes to lower limit at sensor
error.
• After Change (m = D20000 + Unit number × 100)
Word
m+34
00
Bit
Default value
Description
0
Data format
08
0
Minus sign display format for
BCD display
12
0
Data direction at sensor error
13
0
Data held at sensor error
Settings
0: Binary (Negative values are
given as 2’s complements.)
1: BCD
0: “F” used to indicate the minus
sign.
1: Leftmost bit used to indicate the
minus sign. The setting is disabled
if bits 04 to 07 are set to 0.
0: Goes to upper limit at sensor
error.
1: Goes to lower limit at sensor
error.
0: Follow the setting of bit 12.
1: If there is a sensor error when
the upper limit is exceeded, hold
the data at the upper limit. If there
is a sensor error when the lower
limit is exceeded, hold the data at
the lower limit.
65
Specification Changes
66
Section 1-7
SECTION 2
Individual Unit Descriptions for CS Series
This section describes each of the CS-series Analog I/O Units in detail.
2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
68
2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
80
2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
97
2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
109
2-5
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100) . . . . . . . . . . . . . . .
121
2-6
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4) . . . . . . . . . . . . . . . . . . . . .
132
2-7
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4) . . . .
142
2-8
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100). . . . . . . . . . . . . . . . .
157
2-9
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100). . . . . . . . . . . . . . . . .
167
2-10 CS1W-PTW01 2-Wire Transmitter Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
177
2-11 CS1W-PDC01 Isolated-type Direct Current Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
189
2-12 CS1W-PDC11 Isolated-type Direct Current Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
200
2-13 CS1W-PDC55 Isolated-type Direct Current Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
218
2-14 CS1W-PTR01 Power Transducer Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
229
2-15 CS1W-PTR02 Analog Input Unit (100 mV) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
238
2-16 CS1W-PPS01 Isolated-type Pulse Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
247
2-17 CS1W-PMV01 Isolated-type Analog Output Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
258
2-18 CS1W-PMV02 Isolated-type Analog Output Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
267
67
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
Overview
The CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit provides four
direct thermocouple inputs, and sends the data to the CPU Unit each cycle.
All inputs are isolated.
CS1W-PTS01-V1
System Configuration
CS1W-PTS01-V1
4 thermocouple inputs
(K, J, B, E, N, R, S, T, or mV)
Features
• Up to four thermocouples can be directly connected to each Unit (with
four separate settings for temperature sensors and input ranges).
• Isolation between inputs prevents sneak circuits from occurring between
thermocouple inputs.
• This Unit is suitable for a wide range of temperature specifications. K, J,
B, E, N, R, S, or T can be selected.
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal.
• Variable input range setting.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Zero/span adjustment capability during operation.
• Disconnection detection.
• Maximum or minimum process value can be specified for when a disconnection is detected.
68
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PTS01-V1
Inputs
Temperature sensor types
Thermocouple K, J, B, E, N, R, S, T, or mV.
4
Block Diagram (Order of Processing)
The processing for the four inputs is as shown in the following diagram.
CPU Unit CIO Area
HH, H, L, LL
Process value alarm
Process value
H, L
Rate-of-change value
One for all inputs
Rate-of-change alarm
Input disconnection alarm
Cold junction sensor error
Isolated-type Thermocouple Input Unit
Process value alarm
Rate-of-change alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
+115% or −15% when input disconnection is detected
Output limit: −15% to +115%
Zero/span adjustment
Input disconnection check
Process value scaling
Input calculations
Thermocouple type
Cold junction sensor error
Input range
Cold junction temperature compensation
A/D conversion, moving average
Upper cold junction sensor
Lower cold junction sensor
Thermocouple
69
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
Section 2-1
Specifications
Item
Specifications
Model number
CS1W-PTS01-V1
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data Special I/O Unit
exchange with Area
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Thermocouple Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rateof-change alarms (L, H), disconnection alarms, cold junction sensor errors
DM Area words
100 words/Unit
allocated to Spe- CPU Unit to Thermocouple Input Unit:
cial I/O Units
Temperature sensor type, input range (user set), scaling of process value data to be
stored in allocated words in CIO area, number of items for moving average, process
value alarm setting (LL, L, H, HH), rate-of-change alarm setting (L, H), zero/span
adjustment value, etc.
Number of temperature sensor
4
inputs
Temperature sensor types
Input ranges
Scaling in industrial units
Data storage in the CIO Area
Accuracy (25°C)
Thermocouple B, E, J, K, N, R, S, T or
–80 to 80 mV. (Set separately for each of
four inputs.)
Sensor type, input range, and scaling to
industrial units are separate for each of
the 4 inputs.
Note Sensor type, input range, and scaling to industrial units are set in the
DM Area.
The input range can be set within any of
Example:
the measurable input ranges shown in
Thermocouple: K; input range: 0 to
Table 1 (below).
500°C; industrial unit scaling: 0 to 500°C.
DM Area settings are as follows:
Note Internally, inputs are processed in
five ranges (refer to Table 2 below), Thermocouple: 3 (0003 hex)
so accuracy and resolution accord Input signal maximum: 5000 (1388 hex)
with these internal ranges.
Input signal minimum: 0 (0000 hex)
Data to be stored in the allocated words in Industrial unit maximum value stored: 500
(01F4 hex)
the CIO area must be scaled (with the
minimum and maximum values set). Data Industrial unit minimum value stored: 0
(0000 hex)
can be stored at 0% to 100%.
The value derived from carrying out the following processing in order of the actual process data in the input range is stored in four digits hexadecimal (binary values) in the
allocated words in the CIO Area.
1) Mean value processing → 2) Scaling → 3) Zero/span adjustment → 4) Output limits
±0.1% (of internal range full span)
As shown in the following equation, the accuracy depends on the ratio of the selected
internal range (0 to 4) span to the set input range span.
Accuracy = ±0.1% x
Internal range span (electromotive force conversion)
Set input range span (electromotive force conversion)
Temperature coefficient
±0.015% /°C, for any of internal range numbers 0 to 4.
Resolution
1/4,096 (of internal range full span)
As shown in the following equation, the resolution depends on the ratio of the selected
internal range (0 to 4) span to the set input range span.
Resolution =
1
x
4096
Cold junction compensation error ±1°C, at 20 ±10°C
Warmup time
Maximum signal input
70
45 min
–80 to 80 mV
Internal range span (electromotive force conversion)
Set input range span (electromotive force conversion)
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
Item
Input impedance
Specifications
20 kΩ min.
Input disconnection detection cur- 0.1 µA (typical)
rent
Response time
1 s (travel time from input 0% to 90%, for step input)
Conversion period
Maximum time to store data in
CPU Unit
Disconnection detection
Function
150 ms/4 inputs
Conversion period + one CPU Unit cycle
Detects disconnections at each input and turns ON the Disconnection Detection Flag.
Hardware detection time: Approx. 5 s
The process value overrange direction for when a disconnection occurs can be specified. (High: 115% of set input range; low: –15% of set input range)
Mean value pro- Calculates the moving average for the specified number of process values (1 to 16),
cessing (input fil- and stores that value in the CIO Area as the process value.
ter)
Process value
alarm
Process value 4-point alarm (HH, H, LL, L), alarm hysteresis, and ON-delay timer (0 to
60 s) are available.
Rate-of-change
calculation
Calculates the amount of change per comparison time interval (1 to 16 s).
Rate-of-change
alarm
Insulation resistance
Rate-of-change 2-point alarm (H, L), alarm hysteresis (shared with process value
alarm), and ON-delay timer (0 to 60 s, shared with process value alarm) are available.
Between temperature inputs and between input terminals and PLC signals: Isolation
by transformer
20 MΩ (at 500 V DC) between inputs
Dielectric strength
External connections
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
Terminal block (detachable)
Unit number settings
Indicators
Front panel connector
Set by rotary switches on front panel, from 0 to 95.
Three LED indicators on front panel (for normal operation, errors detected at the Thermocouple Input Unit, and errors related to the CPU Unit).
Sensor input connector terminal block (detachable)
Effect on CPU Unit cycle time
Current consumption
0.3 ms
5 V DC at 150 mA max., 26 V DC at 150 mA max.
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
Standard accessories
450 g max.
Two cold junction sensors (installed in terminal block)
Isolation
71
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
Sensor Types and Input Ranges
The temperature sensor (thermocouple) type and input range are set in the
allocated words in the DM Area for every four inputs. The input range can be
set anywhere within the measurable input ranges shown in Table 1.
Table 1: Measurable Input
Ranges
Sensor type
B
DM Area setting
Measurable input range (See note.)
0 to 1,820°C
0
E
1
–270 to 1,000°C
J
2
–210 to 1,200°C
K
3
–270 to 1,372°C
N
4
–270 to 1,300°C
R
5
–50 to 1,768°C
S
6
–50 to 1,768°C
T
7
–270 to 400°C
mV
8
–80 to 80 mV
Note Set the input range in the DM Area within this range.
Inputs are processed internally in five progressive ranges (numbers 0 to 4), as
shown in the following table.
Table 2: Internal Ranges
Internal range number
Thermocouple
electromotive force
Internal range span
0
–80 to 80 mV
160 mV
1
–40 to 40 mV
80 mV
2
–20 to 20 mV
40 mV
3
–10 to 10 mV
20 mV
4
–5 to 5 mV
10 mV
Therefore, the accuracy and resolution are determined by the ratio of the
selected internal range (0 to 4) span to the set input range span (electromotive force converted value). For the internal range, a larger number is selected
when both the minimum and maximum values of the range fall within that next
range.
For example, suppose that the thermocouple type is K and the set input range
is 0 to 800°C. The electromotive force for K 0 to 800°C is 0 to 33.277 mV.
Since both the minimum and maximum values fall within the limits for internal
range No. 1 (–40 to 40 mV), that range will be selected.
The following table shows the set input ranges corresponding to the internal
range numbers 0 to 4.
Table 3: Set Input Ranges Corresponding to Internal Ranges
Sensor
type
Measurable Input
range
Internal range
No. 0
–80 to 80 mV
Internal range
No. 1
–40 to 40 mV
Internal range
No. 2
–20 to 20 mV
Internal range
No. 3
–10 to 10 mV
Internal range
No. 4
–5 to 5 mV
B
0 to 1,820°C
Not used.
Not used.
0 to 1,820°C
0 to 1,496°C
0 to 1,030°C
E
–270 to 1,000°C
–270 to 1,000°C
–270 to 537°C
–270 to 286°C
–270 to 153°C
–94 to 80°C
J
–210 to 1,200°C
–210 to 1,200°C
–210 to 713°C
–210 to 366°C
–210 to 186°C
–100 to 95°C
K
–270 to 1,372°C
–270 to 1,372°C
–270 to 967°C
–270 to 484°C
–270 to 246°C
–153 to 121°C
N
–270 to 1,300°C
–270 to 1,300°C
–270 to 1,097°C
–270 to 584°C
–270 to 318°C
–270 to 171°C
R
–50 to 1,768°C
Not used.
–50 to 1,769°C
–50 to 1,684°C
–50 to 961°C
–50 to 548°C
S
–50 to 1,768°C
Not used.
Not used.
–50 to 1,769°C
–50 to 1,035°C
–50 to 576°C
T
–270 to 400°C
Not used.
–270 to 400°C
–270 to 385°C
–270 to 213°C
–166 to 115°C
mV
–80 to 80 mV
–80 to 80 mV
–40 to 40 mV
–20 to 20 mV
–10 to 10 mV
–5 to 5 mV
Note With Thermocouple Input Units, process values can be scaled in industrial
units for the set input range. It is possible to set the process value scaling
higher than the resolution, but it will cause the values to be unstable.
72
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
m
Decimal
12345, 0
Default
Data contents
Hexadecimal
3039, 0000 hex
0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+2 to m+93.
• 12345 (3039 hex): The data in words m+2 to
m+93 is transferred from the Thermocouple
Input Unit to the CPU Unit. When the transfer
is completed, the value will become 0000
hex.
• Other than 12345 (such as 0000 hex): The
data in the allocated words of DM Area is
transferred from the CPU Unit to the Thermocouple Input Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m + 10
m + 18
m + 26
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4200
(1068 hex)
Process value HH (high high limit) alarm setting
(Set at process value scaling value.)
m+3
m + 11
m + 19
m + 27
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m + 12
m + 20
m + 28
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m + 13
m + 21
m + 29
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
–200
(FF38 hex)
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m + 14
m + 22
m + 30
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Rate-of-change value H (high limit) alarm setting
(Set at rate-of-change scaling value.)
m+7
m + 15
m + 23
m + 31
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
Rate-of-change value alarm settings
Zero/span adjustment
m+8
m + 16
m + 24
m + 32
0 to 32000 0000 to 7D00 hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001)
m+9
m + 17
m + 25
m + 33
–32000 to
32000
0
(0000 hex)
Zero adjustment value
(Set at process value scaling value.)
8300 to FFFF hex,
0000 to 7D00 hex
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Thermocouple Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Thermocouple Input Unit is restarted.
m + 34
m + 49
m + 64
m + 79
0 to 8
0000 to 0008 hex
3
(0003 hex)
Sensor type
0: B, 1: E, 2: J, 3: K, 4: N, 5: R, 6: S, 7: T, 8: mV
m + 35
m + 50
m + 65
m + 80
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Maximum input signal value
(set value x 0.1°C/°F or mV)
m + 36
m + 51
m + 66
m + 81
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
Minimum input signal value
(set value x 0.1°C/°F or mV)
m + 37
m + 52
m + 67
m + 82
0, 1
0000, 0001 hex
0
(0000 hex)
Unit
0: °C, 1: °F
m + 38
m + 53
m + 68
m + 83
0, 1
0000, 0001 hex
0
(0000 hex)
Process value overrange direction at time of
input disconnection
0: High; 1: Low
m + 39
m + 54
m + 69
m + 84
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Value stored for maximum value in range
(span)
m + 40
m + 55
m + 70
m + 85
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
Value stored for minimum value in range (zero)
Process value input range settings
Process value scaling
73
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
DM Area address
Data range
Decimal
Default
Data contents
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Hexadecimal
m + 41
m + 56
m + 71
m + 86
0 to 32000 0000 to 7D00 hex
40
(0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared
with process value alarm and rate-of-change
alarm.)
m + 42
m + 57
m + 72
m + 87
0 to 60
0000 to 003C hex
0
(0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rate-ofchange alarm.)
m + 43
m + 58
m + 73
m + 88
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Rate-of-change
range setting
m + 44
m + 59
m + 74
m + 89
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
–4000
(F060 hex)
m + 45
m + 60
m + 75
m + 90
1 to 16
0001 to 0010 hex
1
(0001 hex)
Rate-of-change comparison time interval
(Unit: s)
m + 46
m + 61
m + 76
m + 91
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Rate-of-change
value scaling
m + 47
m + 62
m + 77
m + 92
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
m + 48
m + 63
m + 78
m + 93
1 to 16
0001 to 0010 hex
4
(0004 hex)
Number of process values for calculating moving average for mean value processing
m + 96
m + 97
0 to 93
0000 to 005D hex
0
(0000 hex)
Address of Data Range Error (See note.)
Alarm supplementary functions
Rate-of-change function
Maximum rate-of-change
value (Process value
industrial unit; comparison
time interval)
Minimum rate-of-change
value (Process value
industrial unit; comparison
time interval)
Value stored for maximum
value in range
Value stored for minimum
value in range
Mean value processing function
Storage parameter
m + 94
m + 95
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Address of Data Range
Error in the DM Area in four digits hexadecimal. For more information, refer to
1-6 Error Processing.
74
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Word
Thermocou- n
ple Input
Unit to CPU
Unit
Bit
00
Input No. 1
Name
Data range
Process value LL (low 0, 1
low limit) alarm
01
Process value L (low
limit) alarm
02
Process value H (high 0, 1
limit) alarm
03
Process value HH
0, 1
(high high limit) alarm
Process value LL (low 0, 1
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
04
Input No. 2
05
06
07
08
Input No. 3
10
11
13
0: Process value <
Set value
1: Process value ≥ Set
value
Same as for input No.
1.
Process value HH
(high high limit) alarm
09
12
0, 1
Contents
0: Process value >
Set value
1: Process value ≤ Set
value
Input No. 4
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
Process value HH
(high high limit) alarm
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
14
Process value H (high
limit) alarm
15
Process value HH
(high high limit) alarm
75
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
Direction
Word
Thermocou- n + 1
ple Input
n+2
Unit to CPU
n+3
Unit
n+4
n+5
Bit
00 to 15
Name
Input No. 1 process value
00 to 15
00 to 15
Input No. 2 process value
Input No. 3 process value
00 to 15
00 to 15
Input No. 4 process value
Input No. 1 rate-of-change value
n+6
n+7
00 to 15
00 to 15
Input No. 2 rate-of-change value
Input No. 3 rate-of-change value
n+8
00 to 15
Input No. 4 rate-of-change value
n+9
00
Input No. 1
The process value
rate of change is
stored according to
the scaling set in the
allocated words of the
DM Area.
0: Rate-of-change
value > Set value
1: Rate-of-change
value ≤ Set value
Rate-of-change value
H (high limit) alarm
0, 1
Input No. 2
Rate-of-change value
L (low limit) alarm
Rate-of-change value
H (high limit) alarm
0, 1
Input No. 3
Rate-of-change value
L (low limit) alarm
05
76
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
0, 1
03
04
Contents
The present process
value is stored
according to the scaling set in the allocated
words of the DM Area.
Rate-of-change value
L (low limit) alarm
01
02
Data range
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
0: Rate-of-change
value < Set value
1: Rate-of-change
value ≥ Set value
Same as for input No.
1.
Rate-of-change value
H (high limit) alarm
06
Input No. 4
Rate-of-change value
L (low limit) alarm
07
08
Rate-of-change value
H (high limit) alarm
Input No. 1 input disconnection
09
Input No. 2 input disconnection
10
Input No. 3 input disconnection
11
Input No. 4 input disconnection
12
Cold junction sensor error
0, 1
0: Normal
1: Disconnection
Same as for input No.
1.
Same as for input No.
1.
Same as for input No.
1.
0, 1
0: Normal
1: Error
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
Terminal Connection Diagram
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
N.C.
N.C.
N.C.
1+
2+
3+
4+
N.C.
N.C.
N.C.
Note
B1
B2
B3
B4
B5
B6
B7
B8
B9
B10
A1
A2
A3
A4
A5
A6
A7
A8
A9
A10
A11
N.C.
CJ1+
CJ1−
1−
2−
3−
4−
CJ2+
CJ2−
N.C.
N.C.
Thermocouple
Input No. 1
(See
note 4.)
Thermocouple
Input No. 4
(See note 4.)
Thermocouple
Input No. 2
Thermocouple
Input No. 3
1. Cold junction sensors are installed between A2 and A3, and between A8
and A9 when the product is shipped. Do not remove them when using the
Unit. If they are removed, temperatures cannot be measured correctly because there will be no compensation.
2. Use the same cold junction sensors that come with the Unit, and leave
them just as they are. They are provided specifically for this Unit and its circuitry, and temperatures cannot be measured correctly if they are switched
around or if another Unit’s sensors are used in their place.
3. For unused input terminals, short-circuit the positive and negative sides
(e.g., terminals A4 and B4 for input No. 1) of the thermocouple inputs with
the lead wire.
4. When connecting input No. 4, remove the cold junction sensor between
CJ2+ and CJ2−, and then reconnect it after the input is connected. Attempting to connect the input without removing the cold junction sensor
may result in damage to the sensor.
77
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
Terminal Block Diagram
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
A2
A3
B4
Thermocouples
Amplifier
Input No. 1
Isolation
circuit
Multiplexer
Amplifier
circuit
Upper cold junction sensor
−
Multi-gain
amplifier circuit
A/D converter
Amplifier
Isolation
circuit
Digital computation circuit
Input No. 2
−
A5
B6
Amplifier
Isolation
circuit
Input No. 3
+ B7
Input No. 4
Amplifier
Lower cold junction sensor
5 V DC
Isolation
circuit
− A7
Connector
− A6
To CPU Unit
Isolated power supply circuit
26 V DC
Amplifier
circuit
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
Set the gain for span adjustment to a value other than 0.
set to 0.
The minimum and maximum val- Set the minimum and maximum values correctly.
ues for process value scaling are
either the same or are set
extremely low.
The sensor type, input range, or Check and correct the settings.
process value scaling is not set
correctly.
An input device is malfunctioning, Check whether the input voltage has changed. Check for faulty or disconnected wiring.
input wiring is faulty, or wiring is
Check whether a wiring disconnection has been detected in the I/O Area.
disconnected.
Values are Not Converted as Intended.
Probable cause
Remedy
The sensor type, input range, or Check and correct the settings.
process value scaling is not set
correctly.
The zero/span adjustment data is Check and correct the zero/span adjustment settings.
incorrect.
Cold junction compensation is
Check the Cold Junction Sensor Error Flag.
not operating.
78
Section 2-1
CS1W-PTS01-V1 Isolated-type Thermocouple Input Unit
Probable cause
No compensation lead wire is
being used, or another type of
compensation lead wire is being
used.
Remedy
Use the correct compensation lead wire for thermocouples.
The input wiring is faulty. (The
thermocouple or compensation
lead wire polarity is wrong.)
Correct the input wiring.
Converted Values are Unstable.
Probable cause
Input signals are being affected
by external noise.
The process value scaling value
is greater than the Unit’s resolution.
The input signal range setting is
too small.
Remedy
Change the connection paths of the input signal lines. (Separate them from sources of
noise or use shielded cable.)
Insert 0.01-µF to 0.1-µF ceramic capacitors between the positive and negative input
terminals.
Increase the number of values for calculating the moving average in mean value processing.
Reduce the process value scaling value.
Match the input signal range to the internal ranges.
79
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Overview
The CS1W-PTS11 Isolated-type Thermocouple Input Unit provides four direct
thermocouple inputs, and sends the data to the CPU Unit each cycle. All
inputs are isolated.
CS1W-PTS11
RUN
ERC
ERH
EDCBA
9876
543210
F
X101 0 X100
54321
F
EDCBA
MACH
No.
9876
System Configuration
CS1W-PTS11
4 thermocouple
inputs (B, E, J, K, L,
N, R, S, T, U,
WRe5-26, PL II, mV)
Features
• Up to four thermocouples can be connected for each Unit (with four separate settings for temperature sensors and input ranges).
• There is isolation between channels, so unwanted circuit paths between
thermocouple inputs can be prevented.
• A variety of temperature specifications are supported. Any of the following
can be selected for thermocouple input: B, E, J, K, L, N, R, S, T, U,
WRe5-26, PL II, mV.
• Resolution of 1/64,000 for all temperature specifications.
• High-speed conversion, at 20 ms/4 inputs and 10 ms/2 inputs.
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal.
• Variable input range setting.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Zero/span adjustment capability during operation.
• Disconnection detection.
80
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
• Maximum or minimum process value can be specified for when a disconnection is detected.
• Adjustment period control.
• Peak and bottom detection.
• Top and valley detection.
Model Information
Unit
Model number
classification
CS1W-PTS11
CS-series
Special I/O
Unit
Inputs
4
Temperature sensor
types
B, E, J, K, L, N, R, S,
T, U, WRe5-26, PL II,
mV
81
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Block Diagram (Order of Processing)
The processing for the inputs is as shown in the following diagram.
CPU Unit
CPU Unit Expansion Area Allocations
Peak/top value
Bottom/valley value
CPU Unit CIO Area
HH, H, L, LL
Process value
One for all inputs
H, L
Process value alarm
Rate-of-change value
Rate-of-change alarm
Input disconnection alarm
I/O refresh
Isolated-type Thermocouple Input Unit
Process value alarm
Rate-of-change alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
+115% or −15% when input disconnection is detected
Output limit: −15% to +115%
Input disconnection check
Zero/span adjustment
Process value scaling
Input calculations
Thermocouple type
Input range
Cold junction temperature compensation
A/D conversion, moving average
Upper cold junction sensor
Lower cold junction sensor
Thermocouple
82
Cold junction sensor error
Cold junction sensor error
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Specifications
Item
Specifications
Model
CS1W-PTS11
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
Special I/O Unit
Area
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Thermocouple Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rateof-change alarms (L, H), disconnection alarms, cold junction sensor errors
DM Area words 100 words/Unit
allocated to
CPU Unit to Thermocouple Input Unit:
Special I/O Units Temperature sensor type, input range (user set), scaling of process value data to be
stored in allocated words in CIO area, rate-of-change input range, scaling of rate-ofchange data, number of items for moving average, process value alarm setting (LL, L,
H, HH), rate-of-change alarm setting (L, H), zero/span adjustment value, etc.
Expansion Con- 35 words/Unit
trol/Monitor Area CPU Unit to Thermocouple Input Unit:
Designations and flags for beginning or resetting the hold function selection, adjustment period control, etc.
Thermocouple Input Unit to CPU Unit:
Adjustment period notices (with each input), peak and bottom values, top and valley
values
Expansion Setting Area
Number of temperature sensor
inputs
Temperature sensor types
Scaling
Data storage in the CIO Area
Accuracy (25°C)
Temperature coefficient
46 words/Unit
CPU Unit to Thermocouple Input Unit:
Expansion Control/Monitor Area settings, adjustment period control, peak and bottom
detection, top and valley detection
4
The sensor type, input range, and scaling can be set individually for each of 4 inputs,
which are each selectable from B, E, J, K, L, N, R, S, T, U, WRe5-26, PL II, and mV.
Data to be stored in the allocated words in the CIO area must be scaled (individually
for each of the 4 inputs, with the minimum and maximum values set). Data can be
stored at 0% to 100%.
The value derived from carrying out the following processing in order of the actual process data in the input range is stored in four digits hexadecimal (binary values) in the
allocated words in the CIO Area.
1) Mean value processing → 2) Scaling → 3) Zero/span adjustment → 4) Output limits
±0.05% (Depends on the Sensor used and the measured temperature. Refer to Accuracy by Sensor Type and Measured Temperature Range on page 85 for details.)
±0.01% /°C (For full scale of electromotive force. See note.)
Resolution
1/64,000
Cold junction compensation error ±1°C, at 20°C±10°C
Warmup time
Maximum signal input
45 min
±120 mV
Input impedance
20 kΩ min.
Input disconnection detection cur- 0.1 µA (typical)
rent
Response time
100 ms (travel time from input 0% to 90%, for ±100 mV step input and with moving
average for 4 samples)
Conversion period
20 ms/4 inputs, 10 ms/2 inputs. Can be switched in DM Area words allocated to the
Unit as a Special I/O Unit.
83
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Item
Maximum time to store data in
CPU Unit
Section 2-2
Specifications
Conversion period + one CPU Unit cycle
Disconnection detection
Function
Detects disconnections at each input and turns ON the Disconnection Detection Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a disconnection occurs can be specified. (High: 115% of set input range; low: –15% of set input range)
Mean value pro- Calculates the moving average for the specified number of process values (1 to 128),
cessing (input
and stores that value in the CIO Area as the process value.
filter)
Process value
alarm
Rate-of-change
calculation
Rate-of-change
alarm
Adjustment
period control
Process value 4-point alarm (HH, H, LL, L), alarm hysteresis, and ON-delay timer (0 to
60 s) are available.
Calculates the amount of change per comparison time interval (1 to 16 s).
Peak and bottom detection
This function detects the maximum (peak) and minimum (bottom) analog input values,
from when the Hold Start Bit (output) allocated to the Expansion Control/Monitor Area
turns ON until it turns OFF, and stores them in the Expansion Control/Monitor Area.
Top and valley
detection
This function detects the top and valley values for analog inputs, from when the Hold
Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON until it
turns OFF, and stores them in the Expansion Control/Monitor Area.
Rate-of-change 2-point alarm (H, L), alarm hysteresis (shared with process value
alarm), and ON-delay timer (0 to 60 s, shared with process value alarm) are available.
When zero/span adjustment is executed, the date is internally recorded at the Unit.
When the preset zero/span adjustment period and number of days notice have
elapsed, this function turns ON a warning flag to give notice that it is time for readjustment.
Isolation
Between inputs and PLC signals, and between inputs: Isolation by transformer for
power supply, and by photocoupler for signals.
Insulation resistance
Dielectric strength
20 MΩ (at 500 V DC) between inputs
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Three LED indicators on front panel (for normal operation, errors detected at the Thermocouple Input Unit, and errors related to the CPU Unit).
Front panel connector
Effect on CPU Unit cycle time
Sensor input connector terminal block (detachable)
0.3 ms
Current consumption (supplied
from Power Supply Unit)
5 V DC at 120 mA max., 26 V DC at 80 mA max.
Dimensions
Weight
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
450 g max.
Standard accessories
Two cold junction sensors (mounted to terminal block)
Note The method for calculating the error in temperature measurements, including
the temperature coefficient, is given below. The “full scale of electromotive
force” is the difference between the high limit and low limit converted to electromotive force for each thermocouple.
84
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Example
Ambient temperature: 30 °C
Temperature Sensor: K thermocouple (−270 to 1,372 °C)
Measured temperature: 500 °C
From electromotive force table
−270 °C:
−6.458 mV
1,372 °C:
54.86 mV
Full scale: 61.344
Electromotive conversion of temperature coefficient:
61.344 mV × ±0.01%/°C = ±6.13 µV/°C
Error in electromotive force at 30°C:
±6.13 µV/°C x (30°C − 25°C) = 30.65 µV/°C
Temperature difference between measurement point and terminals on
Unit (ambient temperature) (based on ambient temperature of 30 °C and
Measured temperature of 500 °C):
470 °C
Electromotive force per °C at a measured temperature of 470 °C (from the
electromotive force tables for a K thermocouple):
43 µV/°C
Error in temperature coefficient: ±30.65 µV ÷ 43 µV/°C = ±0.7°C
Error in measured temperature = Accuracy ± Error from temperature coefficient + Error in cold junction compensation = ±0.8°C + ±0.7°C + ±1.0°C =
±2.5°C
Sensor Type and Input Range
The Temperature Sensor type and input range are set in the allocated words
in the DM Area for every four inputs. The input range can be set anywhere
within the measurable input ranges shown in the following table. Accuracy and
resolution, however, are not determined from the set input range, but rather
from the measurable input range shown in the following table. Therefore,
accuracy and resolution do not change even when a narrow input range is set.
Sensor type
DM Area setting
Measurable input range
B
E
0
1
0 to 1,820°C
−270 to 1,000°C
J
K
2
3
−210 to 1,200°C
−270 to 1,372°C
N
R
4
5
−270 to 1,300°C
−50 to 1,768°C
S
T
6
7
−50 to 1,768°C
−270 to 400°C
mV
L
8
9
−100 to 100 mV
−200 to 900°C
U
WRe5-26
10
11
−200 to 600°C
0 to 2,300°C
PLII
12
0 to 1,300°C
Accuracy by Sensor Type and Measured Temperature Range
Sensor type
B
Temperature range
0 to 1,820°C
Standard accuracy
±1.8°C (±0.1%)
E
−270 to 1,000°C
±0.6°C (±0.05%)
J
K
−210 to 1,200°C
−270 to 1,372°C
±0.7°C (±0.05%)
±0.8°C (±0.05%)
Details
400 to 800°C: ±3°C
Less than 400°C: Accuracy is not specified.
−250 to 200°C: ±1.2°C
Less than −250°C: Accuracy is not specified.
−250 to 200°C: ±2°C
Less than −250°C: Accuracy is not specified.
85
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
N
Sensor type
Temperature range
−270 to 1,300°C
Standard accuracy
±0.8°C (±0.05%)
Details
−200 to 150°C: ±1.6°C
Less than −200°C: Accuracy is not specified.
R
−50 to 1,769°C
±1.8°C (±0.1%)
0 to 100°C: ±2.5°C
Less than 0°C: Accuracy is not specified.
S
−50 to 1,769°C
±1.8°C (±0.1%)
0 to 100°C: ±2.5°C
Less than 0°C: 3.2°C
T
−270 to 400°C
±0.35°C (±0.05%)
−180 to 0°C: ±0.7°C
−200 to −180°C: ±1.3°C
Less than −200°C: Accuracy is not specified.
L
U
−200 to 900°C
−200 to 600°C
±0.5°C (±0.05%)
±0.4°C (±0.05%)
WRe5-26
0 to 2,315°C
±1.2°C (±0.05%)
PLII
0 to 1,395°C
±0.7°C (±0.05%)
−100 to 0°C: ±0.5°C
Less than −100°C: ±0.7°C
More than 2,200°C: ±1.4°C
DM Area Allocations
First word: m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Data range
Input No. Input No. Input No. Input No.
1
2
3
4
m
Decimal
12345, 0
Default
Data contents
Hexadecimal
3039, 0000
hex
0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+1 to m+93.
• 12345 (3039 hex): The data in words m+1
to m+93 is transferred from the Thermocouple Input Unit to the CPU Unit. When
the transfer is completed, the value will
become 0000 hex.
• Other than 12345 (3039 hex) (such as
0000 hex): The data in the allocated
words of DM Area is transferred from the
CPU Unit to the Thermocouple Input Unit.
Number of inputs setting
m+1
0, 1
0000, 0001
hex
0
(0000 hex)
0: 4 inputs, 1: 2 inputs
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m + 10
m + 18
m + 26
–32768 to
32767
8000 to FFFF 4200
hex, 0000 to (1068 hex)
7FFF hex
Process value HH (high high limit) alarm
setting
(Set at process value scaling value.)
m+3
m + 11
m + 19
m + 27
–32768 to
32767
8000 to FFFF 4000
hex, 0000 to (0FA0 hex)
7FFF hex
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m + 12
m + 20
m + 28
–32768 to
32767
8000 to FFFF 0
hex, 0000 to (0000 hex)
7FFF hex
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m + 13
m + 21
m + 29
–32768 to
32767
8000 to FFFF –200
hex, 0000 to (FF38 hex)
7FFF hex
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
Rate-of-change value alarm settings
m+6
m + 14
m + 22
m + 30
–32768 to
32767
8000 to FFFF 4000
hex, 0000 to (0FA0 hex)
7FFF hex
Rate-of-change value H (high limit) alarm
setting
(Set at rate-of-change scaling value.)
m+7
m + 15
m + 23
m + 31
–32768 to
32767
8000 to FFFF 0
hex, 0000 to (0000 hex)
7FFF hex
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
m+8
m + 16
m + 24
m + 32
0 to 32000
0000 to 7D00 10000
hex
(2710 hex)
Zero/span adjustment
86
Gain for span adjustment
(set value x 0.0001%)
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
DM Area address
Data range
Input No. Input No. Input No. Input No.
1
2
3
4
m+9
m + 17
m + 25
m + 33
Decimal
–32000 to
32000
Default
Data contents
Hexadecimal
8300 to FFFF 0
(0000 hex)
hex,
0000 to 7D00
hex
Zero adjustment value
(Set at process value scaling value.)
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Thermocouple Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Thermocouple Input Unit is restarted.
m + 34
m + 49
m + 64
m + 79
0 to 12
0000 to 000C 0
hex
(0000 hex)
Sensor type
0: B, 1: E, 2: J, 3: K, 4: N, 5: R, 6: S, 7: T,
8: mV, 9: L, 10: U, 11: Wre5-26, 12: PLII
m + 35
m + 50
m + 65
m + 80
–32000 to
32000
8300 to FFFF 4000
hex, 0000 to (0FA0 hex)
7D00 hex
Maximum input signal value
(set value x 0.1°C/°F or mV)
m + 36
m + 51
m + 66
m + 81
–32000 to
32000
8300 to FFFF 0
hex, 0000 to (0000 hex)
7D00 hex
Minimum input signal value
(set value x 0.1°C/°F or mV)
m + 37
m + 52
m + 67
m + 82
0, 1
0000, 0001
hex
0
(0000 hex)
Unit
0: °C, 1: °F
m + 38
m + 53
m + 68
m + 83
0, 1
0000, 0001
hex
0
(0000 hex)
Process value overrange direction at time of
input disconnection
0: High; 1: Low
m + 39
m + 54
m + 69
m + 84
–32000 to
32000
8300 to FFFF 4000
hex, 0000 to (0FA0 hex)
7D00 hex
Value stored for maximum value in range
(span)
m + 40
m + 55
m + 70
m + 85
–32000 to
32000
8300 to FFFF 0
hex, 0000 to (0000 hex)
7D00 hex
Value stored for minimum value in range
(zero)
m + 41
m + 56
m + 71
m + 86
0 to 32000
0000 to 7D00 40
hex
(0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared
with process value alarm and rate-ofchange alarm.)
m + 42
m + 57
m + 72
m + 87
0 to 60
0000 to 003C 0
hex
(0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rateof-change alarm.)
m + 43
m + 58
m + 73
m + 88
–32000 to
32000
8300 to FFFF 4000
hex, 0000 to (0FA0 hex)
7D00 hex
m + 44
m + 59
m + 74
m + 89
–32000 to
32000
8300 to FFFF –4000
hex, 0000 to (F060 hex)
7D00 hex
m + 45
m + 60
m + 75
m + 90
1 to 16
0001 to 0010
hex
m + 46
m + 61
m + 76
m + 91
–32000 to
32000
8300 to FFFF 4000
hex, 0000 to (0FA0 hex)
7D00 hex
m + 47
m + 62
m + 77
m + 92
–32000 to
32000
8300 to FFFF –4000
hex, 0000 to (F060 hex)
7D00 hex
Process value input range settings
Process value scaling
Alarm supplementary functions
Rate-of-change function
1
(0001 hex)
Rate-of-change
range setting
Maximum rate-of-change
value (Set value industrial
unit; comparison time
interval)
Minimum rate-of-change
value (Set value industrial
unit; comparison time
interval)
Rate-of-change comparison time interval
(Unit: s)
Rate-of-change
value scaling
Value stored for maximum value in range
Value stored for minimum
value in range
Mean value processing function
m + 48
m + 63
m + 78
m + 93
1 to 128
0001 to 0080
hex
25
(0019 hex)
Number of process values for calculating
moving average for mean value processing
m + 96
m + 97
0 to 99, 100
to 1XX
0000 to 0063
hex, 0064 to
0XXX hex
0
(0000 hex)
Address of Data Range Error (See note.)
Display parameter
m + 94
m + 95
87
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
DM Area address
Data range
Input No. Input No. Input No. Input No.
1
2
3
4
Decimal
Default
Data contents
Hexadecimal
Expansion Setting Area allocations
m+98
0 to 5
0000 to 0005
hex
m+99
0 to 32767
0000 to 7FFF --hex
Note
---
Expansion Setting Area allocations:
0: Not used; 1: DM; 2: CIO; 3: W; 4: H;
5: EM
Expansion Setting Area first word
1. The ERC indicator on the Unit’s front panel will light if an out-of-range setting is made in either Setting Group 1 (continuously refreshed area) or 2
(initial settings area), or in the Expansion Setting Area. The offset from
word m to the first word containing the out-of-range error will be stored as
the Address of Data Range Error in the DM Area in four digits hexadecimal.
If the first memory address containing the out-of-range error is in the Expansion Setting Area, the Address of Data Range Error will be over +100
(or +100 if the first word in the Expansion Setting Area is an error).
2. When specifying an expansion setting area, be sure that it does not overlap with other areas that are being used. If areas overlap, the words that
are allocated may be overwritten, resulting in unexpected operation.
3. When specifying the first word in an expansion setting area, be sure that
the end of the memory area is not exceeded.
Expansion Setting Area
First word: word o. (o = address specified in word m+99 in the area specified
in word m+98 in the DM Area)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
Decimal
Default
Data contents
Hexadecimal
Setting Group 3 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Thermocouple Input Unit if
word m contains other than 12345, and if Expansion Setting Area settings are allocated, when the PLC is turned ON or the Thermocouple Input Unit is restarted.
Expansion Control/Monitor Area settings
o
0 to 5
0000 to 0005
hex
---
Expansion Control/Monitor Area allocation
0: Not used. 1: DM; 2: CIO; 3: W; 4: H;
5: EM
o+1
0 to 32767
0000 to 7FFF
hex
---
Expansion Control/Monitor Area first word
Zero/span adjustment supplementary
function
o+2
o+13
o+24
o+35
0 to 32000
0000 to 7D00
hex
10000 (2710
hex)
Span adjustment position
(Input span percentage)
o+3
o+14
o+25
o+36
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Zero adjustment position
(Input span percentage)
o+4
o+15
o+26
o+37
0 to 9999
0000 to 270F
hex
365 (016D hex) Zero/span adjustment period (Unit: Days)
o+5
o+16
o+27
o+38
0 to 9999
0000 to 270F
hex
30 (001E hex)
Notice of days remaining (Unit: Days)
o+6
o+17
o+28
o+39
---
---
0 (0000 hex)
Not used.
o+7
o+18
o+29
o+40
o+8
o+19
o+30
o+41
o+9
o+20
o+31
o+42
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
Hysteresis
Not used.
Top and valley hold
Not used.
88
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
o+10
o+21
o+32
o+43
o+11
o+22
o+33
o+44
o+12
o+23
o+34
o+45
Note
Decimal
---
Default
Data contents
Hexadecimal
---
0 (0000 hex)
Not used.
1. When specifying an expansion control/monitor area be sure that it does not
overlap with other areas that are being used. If areas overlap, the words
that are allocated may be overwritten, resulting in unexpected operation.
2. When specifying the first word in an expansion control/monitor area be
sure that the end of the memory area is not exceeded.
89
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
CIO Area Allocations
First word: n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n
Bit
00
01
02
03
04
Name
Input No. 1 Process value
LL (low low
limit) alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value
HH (high high
limit) alarm
Input No. 2 Process value
LL (low low
limit) alarm
05
07
Input No. 3
0, 1
0, 1
0, 1
Process value
HH (high high
limit) alarm
0, 1
Process value
LL (low low
limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
10
Process value
H (high limit)
alarm
Process value
HH (high high
limit) alarm
Process value
LL (low low
limit) alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value
HH (high high
limit) alarm
12
13
14
15
0: Process value < Set value
1: Process value ≥ Set value
0, 1
09
11
90
0, 1
Contents
0: Process value > Set value
1: Process value ≤ Set value
Same as for input No. 1.
Process value L 0, 1
(low limit) alarm
Process value 0, 1
H (high limit)
alarm
06
08
Data range
Input No. 4
Same as for input No. 1.
0, 1
0, 1
0, 1
0, 1
0, 1
0, 1
Same as for input No. 1.
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n+1
Bit
Name
00 to 15 Input No. 1 process value
n+2
00 to 15 Input No. 2 process value
n+3
00 to 15 Input No. 3 process value
n+4
00 to 15 Input No. 4 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+5
00 to 15 Input No. 1 rate-of-change
value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+6
00 to 15 Input No. 2 rate-of-change
value
n+7
n+8
n+9
Data range
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
00 to 15 Input No. 3 rate-of-change
–32768 to 32767
value
(8000 to FFFF hex,
0000 to 7FFF hex)
00 to 15 Input No. 4 rate-of-change
–32768 to 32767
value
(8000 to FFFF hex,
0000 to 7FFF hex)
00
Input No. 1 Rate-of-change 0, 1
value L (low
limit) alarm
01
02
Input No. 2
03
04
07
08
09
10
11
The process value rate of
change is stored according
to the scaling set in the allocated words of the DM Area.
0: Rate-of-change value >
Set value
1: Rate-of-change value ≤
Set value
Rate-of-change 0, 1
value H (high
limit) alarm
0: Rate-of-change value <
Set value
1: Rate-of-change value ≥
Set value
Rate-of-change 0, 1
value L (low
limit) alarm
Same as for input No. 1.
Rate-of-change
value H (high
limit) alarm
Input No. 3
05
06
Contents
The present process value is
stored according to the scaling set in the allocated
words of the DM Area.
Input No. 4
Rate-of-change
value L (low
limit) alarm
Rate-of-change
value H (high
limit) alarm
Rate-of-change
value L (low
limit) alarm
Rate-of-change
value H (high
limit) alarm
Input No. 1 input disconnection
Input No. 2 input disconnection
Input No. 3 input disconnection
Input No. 4 input disconnection
0, 1
0: Normal
1: Disconnection
0, 1
0, 1
0, 1
91
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n+9
Bit
12
Name
Cold junction sensor error
Data range
0, 1
Contents
0: Normal
1: Error
13
Zero/span adjustment period 0, 1
end
0: Adjustment enabled
1: Adjustment ended
14
Zero/span adjustment period 0, 1
notice
0: Adjustment enabled
1: Notice period
15
Not used.
0
Expansion Control/Monitor Area Allocations
First word: word p. (p = address specified in word o+1 in the area specified in
word o in the Expansion Setting Area)
Direction
Word
CPU Unit to p
Thermocouple Input
p+1
Unit
p+2
92
Bit
00 to
15
00
Not used.
Name
Data range
0 (0000 hex)
Contents
Not used.
Input No. 1 hold function selection
0, 1
0: Peak and bottom
1: Top and valley
0
Not used.
0, 1
0: Do not hold.
1: Hold
0, 1
0: Normal operation
1: Reset hold value.
0, 1
0: Normal operation
1: Update adjustment
date
(Remains ON while
writing external
FROM.)
Not used.
01
02
Input No. 2 hold function selection
Input No. 3 hold function selection
03
04 to
07
Input No. 4 hold function selection
Not used.
08
09
Input No. 1 hold start
Input No. 2 hold start
10
11
Input No. 3 hold start
Input No. 4 hold start
12
13
Input No. 1 hold value reset
Input No. 2 hold value reset
14
Input No. 3 hold value reset
15
00
Input No. 4 hold value reset
Input No. 1 zero/span adjustment update bit
01
02
Input No. 2 zero/span adjustment update bit
Input No. 3 zero/span adjustment update bit
03
Input No. 4 zero/span adjustment update bit
04 to
15
Not used.
0
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Direction
Word
Thermocou- p+3
ple Input
Unit to CPU
Unit
Bit
00
Input No. 1
01
02
Input No. 2
03
04
Input No. 3
05
Name
Zero/span adjustment
period end
Data range
0, 1
Contents
0: Adjustment
enabled.
1: Adjustment period
end
Zero/span adjustment
period notice
0, 1
Zero/span adjustment
period end
Zero/span adjustment
period notice
Zero/span adjustment
period end
0, 1
0: Adjustment
enabled.
1: Notice period in
effect.
Remains set to 1 if the
zero/span adjustment
bit has never been
ON.
Same as for input No.
1.
Zero/span adjustment
period notice
06
Input No. 4
07
Zero/span adjustment
period notice
External FROM Error Flag
0, 1
0: Normal operation
1: External FROM
error
09 to
15
Not used.
0
Not used.
00 to
15
00 to
15
00 to
15
00 to
15
Input No. 1
p+8
00 to
15
Input No. 3
p+9
00 to
15
08
p+4
p+5
p+6
p+7
p+10
00 to
15
p+11
00 to
15
p+12 to 00 to
p+15
15
Input No. 2
Zero/span adjustment
period end
Day of final adjustment date 0100 to 3100
(BCD)
Year and month of final
0001 to 9912
adjustment date
(BCD)
Day of final adjustment date 0100 to 3100
(BCD)
Year and month of final
0001 to 9912
adjustment date
(BCD)
Day of final adjustment date 0100 to 3100
(BCD)
Year and month of final
adjustment date
Input No. 4
Not used.
Remains set to FFFF
if the zero/span
adjustment bit has
never been ON.
0001 to 9912
(BCD)
Day of final adjustment date 0100 to 3100
(BCD)
Year and month of final
0001 to 9912
adjustment date
(BCD)
0000
Not used.
93
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Direction
Word
Thermocou- p+16
ple Input
Unit to CPU
Unit
Bit
00 to
15
p+17
00 to
15
p+18
00 to
15
p+19
00 to
15
00 to
15
00 to
15
00 to
15
p+20
p+21
p+22
p+23
Input No. 1
Input No. 2
Data range
−32728 to
+32767
(8000 to FFFF
hex, 0000 to
7FFF hex)
Contents
Counts the number of
repetitions of conditional operations set
in the Expansion Setting Area.
Bottom/valley value
−32728 to
+32767
(8000 to FFFF
hex, 0000 to
7FFF hex)
The bottom or valley
value is stored
according to the scaling set in the DM
Area.
Peak/top value
−32728 to
+32767
(8000 to FFFF
hex, 0000 to
7FFF hex)
Same as for Input No.
1.
0 (0000 hex)
Not used.
Bottom/valley value
Input No. 3
Peak/top value
Bottom/valley value
Input No. 4
Peak/top value
00 to
15
p+24 to 00 to
p+34
15
Name
Peak/top value
Bottom/valley value
Not used.
Terminal Connection Diagram
N.C.
B1
N.C.
B2
N.C.
B3
1+
B4
2+
B5
3+
B6
4+
B7
N.C.
B8
N.C.
B9
N.C.
B10
A1
N.C.
A2
CJ1+
A3
CJ1−
A4
1−
A5
2−
A6
3−
A7
4−
A8
CJ2+
A9
CJ2−
A10
N.C.
A11
N.C.
*2
No. 1
thermocouple
input
No. 2
thermocouple
input
No. 4
thermocouple
input (*1)
No. 3
thermocouple
input
Note Action for Unused Input Terminals
• Short-circuit the positive (+) and negative (−) sides of the thermocouple
input section using a lead wire. For example, short terminals A4 and B4
for No. 1 thermocouple input.
• Cold junction sensors are mounted between A2 and A3, and A8 and A9
before shipment. If one of the cold junction sensors is disconnected, cold
junction compensation will stop and correct measurement of temperatures cannot be made. Always make sure the cold junction sensors are
connected when using the Units.
• Cold junction sensors are calibrated separately for each Unit and connected circuit, so correct temperatures will not be measured if a cold junc-
94
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
tion sensor from another Unit is used or if the two cold junction sensors in
a Unit are swapped. Use the cold junction sensors as they are provided,
without making any changes.
• When wiring No. 4 thermocouple input terminals (*1 in the above diagram), remove the cold junction sensor between terminals CJ2+ and
CJ2− at the bottom (*2 in the above diagram), connect the No. 4 thermocouple input, and then reconnect the cold junction sensor. Any attempt to
connect No. 4 thermocouple input without removing the cold junction sensor may result in damage to the cold junction sensor.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
Terminal Block Diagram
Thermocouples
Isolated power
supply circuit
B4
B5
No. 2 input
Photocoupler
Isolated power
supply circuit
5 VDC
A5
B6
No. 3 input
Photocoupler
Isolated power
supply circuit
A/D
converter
Amplifier
circuit
A6
B7
No. 41 input
26 VDC
A/D
converter
Amplifier
circuit
Connector
A4
A/D
converter
Amplifier
circuit
Input selector
No. 1 input
Digital
circuits
Photocoupler
Isolated power
supply circuit
A/D
converter
Amplifier
circuit
A7
Photocoupler
Amplifier
circuit
Lower
A8
A9
Amplifier
circuit
Photocoupler
A2
A3
A/D converter
Upper
Multiplexer
Cold junction
sensors
Isolated
power
supply
circuit
Error Processing
Conversion Data Does Not Change.
Probable cause
The gain for span adjustment is
set to 0.
Remedy
Set the gain for span adjustment to a value other
than 0.
The minimum and maximum values for process value scaling are
either the same or are set
extremely low.
The sensor type, input range, or
process value scaling is not set
correctly.
Set the minimum and maximum values correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring. Check whether a wiring disconnection has
been detected in the I/O Area.
Check and correct the settings.
95
Section 2-2
CS1W-PTS11 Isolated-type Thermocouple Input Unit
Values are Not Converted as Intended.
Probable cause
The sensor type, input range, or
process value scaling is not set
correctly.
The zero/span adjustment data is
incorrect.
Cold junction compensation is not
operating.
Remedy
Check and correct the settings.
A compensation conductor has
not been used or a different compensation conductor is used.
Incorrect input wiring (incorrect
thermocouple or compensation
conductor polarity.)
Use the correct compensation conductor for the
thermocouple.
Check and correct the zero/span adjustment settings.
Check the Cold Junction Error Flag.
Correct the input wiring.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
Insert a 0.01 to 0.1 µF ceramic capacitor
between the positive (+) and negative (−) input
terminals.
Increase the number of values for calculating the
moving average in mean value processing.
The process value scaling value is Reduce the process value scaling value.
greater than the Unit’s resolution.
The input signal range setting is
Match the input signal range to the internal
too small.
ranges.
96
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
Overview
The CS1W-PTS51 Isolated-type Thermocouple Input Unit provides four direct
thermocouple inputs, and sends the data to the CPU Unit each cycle. All
inputs are isolated.
CS1W-PTS51
RUN
ERC
ERH
EDCBA
9876
543210
F
X101 0 X100
54321
F
EDCBA
MACH
No.
9876
System Configuration
CS1W-PTS51
4 thermocouple
inputs (K, J, L, R, S,
T, B)
Features
• Up to four thermocouples can be connected for each Unit (with four separate settings for temperature sensors and input ranges).
• There is isolation between channels, so unwanted circuit paths between
thermocouple inputs can be prevented.
• A variety of temperature specifications are supported. Any of the following
can be selected for thermocouple input: K, J, L, R, S, T, B. (Decimal
points can be selected for K, J, and L.)
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal. (Binary or BCD can be selected for the data output format.)
• Process value alarm (with two internal alarms in memory and one external alarm output for each input).
• Alarm ON-delay timer and hysteresis for process value.
• Zero/span adjustment capability during operation.
• Sensor error detection.
• Maximum or minimum process value can be specified for when a sensor
error is detected.
97
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
Model Information
Unit
Model number
classification
CS-series
CS1W-PTS51
Special I/O
Unit
Inputs
4
Temperature sensor
types
K, J, L, R, S, T, B
Block Diagram (Order of Processing)
The processing for the inputs is as shown in the following diagram.
CPU Unit
CPU Unit Expansion Area Allocations
H, L
Process value
Process value alarm
External alarm output
Process value alarm
When input disconnection is detected
Zero/span adjustment
Thermocouple type
Input range
Cold junction temperature compensation
A/D conversion
Upper cold junction sensor
Thermocouple
98
Cold junction sensor error
I/O refresh
Isolated-type Thermocouple Input Unit
Input calculations
Sensor error
Cold junction temperature
compensation
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
Specifications
Item
Specifications
Model
CS1W-PTS51
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
Special I/O Unit
Area
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Isolated-type Thermocouple Input Unit to CPU Unit:
All process values, process value alarms (L, H), conversion data enabled flags, sensor
errors, cold junction sensor errors
DM Area words 100 words/Unit
allocated to
CPU Unit to Isolated-type Thermocouple Input Unit:
Special I/O Units Temperature sensor type, input range (user set), process value alarm setting (L, H),
zero/span adjustment value.
Number of temperature sensor
4
inputs
Temperature sensor types
The sensor type be set individually for each of 4 inputs, which are each selectable
from K, J, L, R, S, T, B.
Data storage in the CIO Area
The actual process data in the input range is stored in four digits hexadecimal (binary
or BCD values) in the allocated words in the CIO Area.
Temperature characteristic
With Celsius selected: ±0.3% of PV or ±1°C, whichever is greater, ±1 digit max.
With fahrenheit selected: ±0.3% of PV or ±2°F, whichever is greater, ±1 digit max.
However, the accuracy of K and T at −100°C or lower and L is ±2°C ±1 digit max.
The accuracy of R and S at 200°C or lower is ±3°C ±1 digit max.
The accuracy of B at 400°C or lower is not specified.
PV: Process value data
Refer to Temperature Characteristics According to Thermocouple Type on page 102.
Warmup time
Conversion period
30 min
250 ms/4 inputs.
Maximum time to store data in
CPU Unit
Conversion period + one CPU Unit cycle
Sensor error detection
Detects sensor error at each input and turns ON the Sensor error Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a sensor error occurs can be specified. (High: Set input range +20°C or +20°F; low: Set input range −20°C or −20°F)
Process value 2-point alarm (HH, H, LL, L), alarm hysteresis, and ON-delay timer (0 to
60 s) are available. External alarm outputs: One per input (H or L).
Accuracy (25°C) (See note.)
Functions
Process value
alarm
External alarm
outputs
NPN outputs (with short-circuit protection)
External power supply voltage: 20.4 to 26.4 V DC
Max. switching capacity: 100 mA (for one output)
Leakage current: 0.3 mA max.
Residual voltage: 3 V max.
Isolation
Between inputs and PLC signals: Transformer for power supply and photocoupler for
signals.
Between each input: Transformer for power supply and photocoupler for signals.
Insulation resistance
20 MΩ max. (at 500 V DC).
Between all output and NC terminals and external AC terminals (Power Supply Unit)
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and all output terminals
Between all external DC terminals (input, output, and NC terminals) and FG plate
Between all input and output terminals and all NC terminals
99
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
Item
Dielectric strength
Specifications
Between all output and NC terminals and external AC terminals (Power Supply Unit)
2,000 VAC, 50/60 Hz 1 min., detection current: 1 mA
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and all output terminals
Between all external DC terminals (input, output, and NC terminals) and FG plate
1,000 VAC, 50/60 Hz 1 min., detection current: 1 mA
Between all channels
500 VAC, 50/60 Hz 1 min., detection current: 1 mA
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Seven LED indicators on front panel (for normal operation, errors detected at the
Thermocouple Input Unit, errors related to the CPU Unit, and four indicators for external alarm outputs.)
0.4 ms
Effect on CPU Unit cycle time
Current consumption (supplied
from Power Supply Unit)
Dimensions
Weight
5 V DC at 250 mA max.
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
450 g max.
Note The heat generated by a Unit will dramatically change the accuracy specifications when more than one C200HW-PA209R or CS1W-ID291 Unit is mounted
side-by-side.
The following accuracy specifications apply under such conditions.
With Celsius selected:
±0.3% of PV or ±1.3°C, whichever is greater, ±1 digit max.
With Fahrenheit selected:
±0.3% of PV or ±3°F, whichever is greater, ±1 digit max.
However, the accuracy of K and T at −100°C or less and L is ±3°C ±1 digit
max. The accuracy of R and S at 200°C or less is ±4°C ±1 digit max.
The accuracy of B at 400°C or less is not specified.
Sensor Type and Input Range
The Temperature Sensor type and input range are set in the allocated words
in the DM Area for every four inputs.
The measurable data range is ±20 digits wider than the sensor input range.
Setting
°C
Input
16-bit binary
°F
BCD
[email protected]@@
indicates
minus sign.
F200 to 1300
(−200 to
1300)
16-bit binary
Leftmost bit
indicates
minus sign.
8200 to 1300 FED4 to FFFF to
(−200 to
08FC
1300)
(−300 to −1 to
2300)
0
K: −200 to
FF38 to FFFF to
1300°C
0514
(−300 to 2300°F) (−200 to −1 to
1300)
1
K: 0.0 to 500°C 0000 to 1388
(0.0 to 900.0°F) (0.0 to 500.0)
2
J: −100 to 850°C FF9C to FFFF to F100 to 0850 8100 to 0850 FF9C to FFFF to
(−100 to 1500°F) 0352
(−100 to 850) (−100 to 850) 05DC
(−100 to −1 to 850)
(−100 to −1 to
1500)
J: 0.0 to 400.0°C 0000 to 0FA0
0000 to 4000 0000 to 4000 0000 to 1D4C
(0.0 to 750.0°F) (0.0 to 400.0)
(0.0 to 400.0) (0.0 to 400.0) (0.0 to 750.0)
3
100
0000 to 5000 0000 to 5000 0000 to 2328
(0.0 to 500.0) (0.0 to 500.0) (0.0 to 900.0)
BCD
[email protected]@@
indicates
minus sign.
F300 to 2300
(−300 to
2300)
Leftmost bit
indicates
minus sign.
F300 to 2300
(−300 to
2300)
0000 to 9000 0000 to 7999
(0.0 to 900.0) (See note 3.)
(0.0 to 799.9)
F100 to 1500 8100 to 1500
(−100 to
(−100 to
1500)
1500)
0000 to 7500 0000 to 7500
(0.0 to 750.0) (0.0 to 750.0)
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
Setting
4
5
°C
Input
16-bit binary
°F
BCD
[email protected]@@
indicates
minus sign.
T: −200 to 400°C F830 to FFFF to
F999 to 4000
(−300 to
0FA0
(See note 3.)
700.0°F)
(−200.0 to −0.1 to (−99.9 to
400.0)
400.0)
L: −100 to 850°C FF9C to FFFF to F100 to 0850
(−100 to 1500°F) 0352
(−100 to 850)
(−100 to −1 to 850)
16-bit binary
Leftmost bit
indicates
minus sign.
A000 to 4000 F448 to FFFF to
(−200.0 to
1B58
400.0)
(−300.0 to −0.1 to
700.0)
8100 to 0850 FF9C to FFFF to
(−100 to 850) 05DC
(−100 to −1 to
1500)
BCD
[email protected]@@
Leftmost bit
indicates
indicates
minus sign. minus sign.
F999 to 7000 B000 to 7000
(See note 3.) (−300.0 to
(−99.9 to
700.0)
700.0)
F100 to 1500 8100 to 1500
(−100 to
(−100 to
1500)
1500)
6
L: 0.0 to 400.0°C 0000 to 0FA0
(0.0 to 750.0°F) (0.0 to 400.0)
0000 to 4000 0000 to 4000 0000 to 1D4C
(0.0 to 400.0) (0.0 to 400.0) (0.0 to 750.0)
0000 to 7500 0000 to 7500
(0.0 to 750.0) (0.0 to 750.0)
7
R: 0 to 1700°C
(0 to 3000°F)
S: 0 to 1700°C
(0 to 3000°F)
B: 400 to 1800°C
(See note 2.)
(750 to 3200°F)
0000 to 1700
(0 to 1700)
0000 to 1700
(0 to 1700)
0400 to 1800
(400 to 1800)
0000 to 3000
(0 to 3000)
0000 to 3000
(0 to 3000)
0750 to 3200
(750 to 3200)
8
9
0000 to 06A4
(0 to 1700)
0000 to 06A4
(0 to 1700)
0190 to 0708
(400 to 1800)
Note
0000 to 1700 0000 to 0BB8
(0 to 1700) (0 to 3000)
0000 to 1700 0000 to 0BB8
(0 to 1700) (0 to 3000)
0400 to 1800 02EE to 0C80
(400 to 1800) (750 to 3200)
0000 to 3000
(0 to 3000)
0000 to 3000
(0 to 3000)
0750 to 3200
(750 to 3200)
1. If the indication range is exceeded, a sensor error will occur and the sensor
error bit will turn ON. The process value will be clamped at the lower or upper limit of the indication range, depending on the setting for data direction
at sensor error.
2. The lower limit for B thermocouples is 0°C/°F.
3. The indicator range for BCD display will be clamped at the lower (or upper)
limit in the region between the lower (or upper) limit of the setting range
and the point where a sensor error occurs.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost 4 bits (bits
12 to 15): Lower limit = −99.9, Upper limit = 999.9.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost bit (bit 15):
Lower limit = −799.9, Upper limit = 799.9.
101
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
Temperature Characteristics According to Thermocouple Type
Thermocouple
0 to 200°C
Set value error when ambient
temperature changes by 1°C
±0.43°C
200 to 1,000°C
1,000 to 1,700°C
±0.29°C
±285 ppm of PV
0 to 200°C
200 to 1,000°C
±0.43°C
±0.29°C
1,000 to 1,700°C
400°C or less
285 ppm of PV
Not specified.
400 to 800°C
800 to 1,000°C
±0.43°C
±0.29°C
1,000 to 1,800°C
−200 to −100°C
285 ppm of PV
±0.29°C
−100 to 400°C
400 to 1,300°C
±0.11°C
±285 ppm of PV
J
−100 to 400°C
400 to 850°C
±0.11°C
±285 ppm of PV
T
−200 to −100°C
−100 to 400°C
±0.29°C
±0.11°C
L
−100 to 400°C
400 to 850°C
±0.11°C
±285 ppm of PV
R
S
B
K
Temperature range
The measured temperature error is calculated as shown in the following
example.
Item
Ambient temperature
Thermocouple type
Details
30°C
K
Measured temperature (PV) 500°C
Reference accuracy (25°C) ±0.3°C of PV or ±1°C, whichever is greater, ±1 digit.
In this example, ±1.5°C.
Temperature characteristics 400 to 1,300°C: 285 ppm of PV.
In this example, 285 ppm × 500°C = 0.143°C.
Change in ambient temper- 5°C (25 to 30°C).
ature
Overall accuracy =
Reference accuracy + Temperature characteristic × Change in ambient temperature = ±1.5°C + ±0.143°C × 5 = Approx. ±2.2°C ± 1 digit.
102
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
DM Area Allocations
First word: m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Data range
Input No. Input No. Input No. Input No.
1
2
3
4
m
Decimal
Default
Data contents
Hexadecimal
12345, 0
3039, 0000
hex
0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+1 to m+93.
• 12345 (3039 hex): The data in words m+1
to m+93 is transferred from the Thermocouple Input Unit to the CPU Unit. When
the transfer is completed, the value will
become 0000 hex.
• Other than 12345 (3039 hex) (such as
0000 hex): The data in the allocated
words of DM Area is transferred from the
CPU Unit to the Thermocouple Input Unit.
0 to 34
0000 to 0022
hex
0
(0000 hex)
Address of Data Range Error (See note 1.)
Display parameter
m+1
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m+6
m + 10
m + 14
m+3
m+7
m + 11
m + 15
m+4
m+8
m + 12
m + 16
Low to high limit for sensors.
1300
(0514 hex)
Process value H (high limit) alarm setting
−200
(FF38 hex)
Process value L (low limit) alarm setting
Span adjustment value
0 to 9999
0000 to 270F
hex
1000
(03E8 hex)
0 to 32000
0000 to 7D00 10000
hex
(2710 hex)
m+35 contains 0: Set value × 0.001
m+35 contains 1: Set value × 0.0001
Zero adjustment value
m+5
m+9
m + 13
m + 17
–9999 to
9999
D8F1 to 270F 0
hex
(0000 hex)
Set value × 0.1
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Thermocouple Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Thermocouple Input Unit is restarted.
Operation settings (See note 2.)
m + 18
(See note 2.)
(See note 2.) 0
(0000 hex)
00 to 03: Temperature unit (°C or °F)
04 to 07: Data display (binary or BCD)
08 to 11: Minus sign display format for BCD
display
12 to 15: Data direction at sensor error
Sensor type
m + 19
m + 23
m + 27
m + 31
0 to 9
0000 to 0009
hex
0
(0000 hex)
0: K, 1: K (with decimal point), 2: J, 3: J (with
decimal point), 4: T, 5: L, 6: L (with decimal
point), 7: R, 8: S, 9: B
m + 20
m + 24
m + 28
m + 32
0, 1
0000, 0001
hex
0
(0000 hex)
Select either high limit or low limit alarm output.
0: High limit alarm; 1: Low limit alarm
m + 21
m + 25
m + 29
m + 33
0 to 9999
0000 to 270F
hex
0
(0000 hex)
m + 22
m + 26
m + 30
m + 34
0 to 60
0000 to 003C 0
hex
(0000 hex)
Unit: s
0, 1
0000, 0001
hex
Span adjustment mode
0: 1/1,000
1: 1/10,000
External alarm output mode
Alarm hysteresis
Set value × 0.1
Alarm ON-delay time
m + 35
Note
1 (See note
3.)
1. The ERC indicator on the Unit's front panel will light if an out-of-range setting is made in either Setting Group 1 (continuously refreshed area) or 2
103
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
(initial settings area). The offset from word m to the first word containing
the out-of-range error will be stored as the Address of Data Range Error in
the DM Area in four digits hexadecimal.
2. The operation settings are shown in the following table.
Word
m+18
Bits
Description
Settings
00
Temperature unit setting
0: °C
1: °F
04
Data format
0: Binary (Negative values are given as 2’s complements).
1: BCD
08
Minus sign display format for BCD display 0: “F” used to indicate the minus sign.
1: Leftmost bit used to indicate the minus sign.
The setting is disabled if bits 04 to 07 are set to 0.
12
Data direction at sensor error
0: Goes to upper limit at sensor error
1: Goes to lower limit at sensor error
Example: For a temperature in degrees Celsius (°C), a binary data format,
and a data direction at sensor error of “lower limit,” word m+18 will contain
1000.
3. Indicates the value after transferring the default value (set when 12345 is
written to word m).
CIO Area Allocations
First word: n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n
Bit
00
Input No. 1
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
Name
Data range
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
0, 1
Process value
Depends on type of
input.
0, 1
Contents
0: Process value > Set value
1: Process value ≤ Set value
0: Process value < Set value
1: Process value ≥ Set value
Same as for input No. 1.
0, 1
0, 1
0, 1
0, 1
0, 1
08 to 15 Not used.
104
n+1
n+2
00 to 15 Input No. 1
00 to 15 Input No. 2
n+3
n+4
00 to 15 Input No. 3
00 to 15 Input No. 4
Stores data in the data
range specified for the input
type ±20 digits.
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n+5
Bit
Name
00 to 15 Not used.
n+6
n+7
00 to 15
00 to 15
n+8
n+9
00 to 15
00
Input No. 1
Data range
Sensor error
0, 1
01
02
Input No. 2
Input No. 3
0, 1
0, 1
03
04
Input No. 4
Not used.
0, 1
Cold junction sensor error
0, 1
Contents
0: Normal
1: Error
05
06
07
08
0: Normal
1: Error
09 to 14 Not used.
15
Conversion data enabled flag 0, 1
(See note.)
0: Data disabled
1: Data enabled
Note The Conversion Data Enabled Flag remains OFF after the PLC is turned ON
or the Unit is restarted until the AD conversion data becomes stable (approximately 2 to 4 s), then is ON during operation.
Terminal Connection Diagram
No. 2
thermocouple input
2−
B1
2+
B2
CJ
B3
CJ
B4
4−
B5
4+
B6
L
ALM2
B7
L
ALM4
B8
0V
B9
N.C.
B10
Cold junction sensor
No. 4
thermocouple input
External alarm outputs
A1
N.C
A2
1−
A3
1+
A4
N.C.
A5
N.C.
A6
3−
A7
3+
A8
ALM1
L
A9
ALM3
L
A10
24V
A11
N.C.
No. 1
thermocouple input
No. 3
thermocouple input
External alarm outputs
Note Action for Unused Input Terminals
• Short-circuit the positive (+) and negative (−) sides of the thermocouple
input section using a lead wire. For example, short terminals A3 and A2
for No. 1 thermocouple input.
• Cold junction sensors are mounted before shipment. If one of the cold
junction sensors is disconnected, cold junction compensation will stop
and correct measurement of temperatures cannot be made. Always make
sure the cold junction sensors are connected when using the Units.
• Cold junction sensors are calibrated separately for each Unit and connected circuit, so correct temperatures will not be measured if a cold junction sensor from another Unit is used or if the two cold junction sensors in
a Unit are swapped. Use the cold junction sensors as they are provided,
without making any changes.
105
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
• Do not connect anything to NC terminals. Do not use NC terminals as
relay terminals.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
Terminal Block Diagram
Amplifier
circuit
A2
B2
Amplifier
circuit
No. 2 input
B4
A7
Amplifier
circuit
No. 3 input
A6
B6
Amplifier
circuit
No. 4 input
B5
Double
integral
A/D
Double
integral
A/D
Double
integral
A/D
Double
integral
A/D
Reference
power supply
Photocoupler
Reference
power supply
Photocoupler
5 VDC
Reference
power supply
Photocoupler
Reference
power supply
Photocoupler
Cold junction
sensors
B3
Amplifier
circuit
B4
106
Double
integral
A/D
Reference
power supply
Photocoupler
Digital circuits
Connector
A3
No. 1 input
Isolation circuit
■ Input Circuits
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
■ Output Circuits
L
A8
ALM1
L
B7
ALM2
L
A9
ALM3
L
B8
ALM4
Internal Circuit
A10
24V
B9
0V
Output Display
LED
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
The sensor type, input range, or
process value scaling is not set
correctly.
Set the gain for span adjustment to a value other
than 0.
Check and correct the settings.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring. Check whether a sensor error has been
detected in the I/O Area.
107
Section 2-3
CS1W-PTS51 Isolated-type Thermocouple Input Unit
Values are Not Converted as Intended.
Probable cause
The sensor type is not set correctly.
Remedy
Check and correct the settings.
The zero/span adjustment data is
incorrect.
Check and correct the zero/span adjustment settings.
Cold junction compensation is not Check the Cold Junction Error Flag.
operating.
A compensation conductor has
not been used or a different compensation conductor is used.
Use the correct compensation conductor for the
thermocouple.
Incorrect input wiring (incorrect
thermocouple or compensation
conductor polarity.)
Correct the input wiring.
Thermocouple lead or compensating conductor is too long and measurements are being affected by
conductor resistance.
The terminal block temperature is
not uniform due to radiated heat
from peripheral devices.
Use a thicker compensating conductor.
Change the wiring position and shorten the compensating conductor.
Mount the unit in a position unaffected by radiated heat.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
Insert a 0.01 to 0.1 µF ceramic capacitor
between the positive (+) and negative (−) input
terminals.
An airflow is hitting the Unit terminal block.
108
Move the terminal block to a position unaffected
by airflow.
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
Overview
The CS1W-PTS55 Isolated-type Thermocouple Input Unit provides 8 direct
thermocouple inputs, and sends the data to the CPU Unit each cycle. All
inputs are isolated.
CS1W-PTS55
RUN
ERC
ERH
54321
EDCBA
543210
F
X101 0 X100
9876
F
EDCBA
MACH
No.
9876
System Configuration
CS1W-PTS55
8 thermocouple
inputs (K, J, L, R, S,
T, B)
Features
• Up to 8 thermocouples can be connected for each Unit (with 8 separate
settings for temperature sensors and input ranges).
• There is isolation between channels, so unwanted circuit paths between
thermocouple inputs can be prevented.
• A variety of temperature specifications are supported. Any of the following
can be selected for thermocouple input: K, J, L, R, S, T, B. (Decimal
points can be selected for K, J, and L.)
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal. (Binary or BCD can be selected for the data output format.)
• Process value alarms (Two internal alarms per input can be output to
memory and two alarms per input can be output to specified I/O memory
area addresses using indirect address specifications).
• Alarm ON-delay timer and hysteresis for process value.
• Zero/span adjustment capability during operation.
• Sensor error detection.
• Maximum or minimum process value can be specified for when a sensor
error is detected.
109
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
Model Information
Unit
Model number
classification
CS-series
CS1W-PTS55
Special I/O
Unit
Inputs
8
Temperature sensor
types
K, J, L, R, S, T, B
Block Diagram (Order of Processing)
The processing for the inputs is as shown in the following diagram.
CPU Unit
CPU Unit CIO Area
Expansion Setting Area
H, L
Process value
Process value alarm
Sensor error
Cold junction sensor error
Alarm Output
I/O refresh
Isolated-type Thermocouple Input Unit
Process value alarm
Output limit
Zero/span adjustment
Input calculations
Thermocouple type
Input range
Cold junction temperature compensation
A/D conversion
Upper cold junction sensor
Lower cold junction sensor
Thermocouple
110
Cold junction temperature
compensation
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
Specifications
Item
Specifications
Model
CS1W-PTS55
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
Special I/O Unit
Area
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Isolated-type Thermocouple Input Unit to CPU Unit:
All process values, process value alarms (L, H), conversion data enabled flags, sensor
errors, cold junction sensor errors
DM Area words 100 words/Unit
allocated to
CPU Unit to Isolated-type Thermocouple Input Unit:
Special I/O Units Temperature sensor type, input range (user set), process value alarm setting (L, H),
zero/span adjustment value.
Expansion Set- 1 word/Unit
ting Area
CPU Unit to Isolated-type Thermocouple Input Unit:
Process Value Alarm
Number of temperature sensor
inputs
Temperature sensor types
8
Temperature characteristic
The sensor type be set individually for each of 8 inputs, which are each selectable
from K, J, L, R, S, T, B (“Not used” can be selected).
The actual process data in the input range is stored in four digits hexadecimal (binary
or BCD values) in the allocated words in the CIO Area.
With Celsius selected: ±0.3% of PV or ±1°C, whichever is greater, ±1 digit max.
With fahrenheit selected: ±0.3% of PV or ±2°F, whichever is greater, ±1 digit max.
However, the accuracy of K and T at −100°C or lower and L is ±2°C ±1 digit max.
The accuracy of R and S at 200°C or lower is ±3°C ±1 digit max.
The accuracy of B at 400°C or lower is not specified.
PV: Process value data
Refer to Temperature Characteristics According to Thermocouple Type on page 113.
Warmup time
Conversion period
30 min
250 ms/8 inputs.
Maximum time to store data in
CPU Unit
Conversion period + one CPU Unit cycle
Sensor error detection
Detects sensor error at each input and turns ON the Sensor error Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a sensor error occurs can be specified. (High: Set input range +20°C or +20°F; low: Set input range −20°C or −20°F)
Process value 2-point alarm (H, L), alarm hysteresis, and ON-delay timer (0 to 60 s)
are available.
Two alarms per input (H, L) can be output to addresses in the CIO Area specified in
the Expansion Setting Area.
Data storage in the CIO Area
Accuracy (25°C)
Functions
Process value
alarm
Isolation
Between inputs and PLC signals: Transformer for power supply and photocoupler for
signals.
Between each input: Transformer for power supply and photocoupler for signals.
Insulation resistance
20 MΩ max. (at 500 V DC).
Between all input terminals and external AC terminals (Power Supply Unit)
Between all external DC terminals (input and NC terminals) and FG plate
Between all input and all NC terminals
111
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
Item
Dielectric strength
Specifications
Between NC terminals and external AC terminals (Power Supply Unit)
2,000 VAC, 50/60 Hz 1 min., detection current: 1 mA
Between all input terminals and external AC terminals (Power Supply Unit)
Between all external DC terminals (input and NC terminals) and FG plate
1000 VAC, 50/60 Hz 1 min., detection current: 1 mA
Between all channels
500 VAC, 50/60 Hz 1 min., detection current: 1 mA
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Effect on CPU Unit cycle time
Three LED indicators on front panel (for normal operation, errors detected at the Unit,
errors related to the CPU Unit)
0.4 ms
Current consumption (supplied
from Power Supply Unit)
5 V DC at 180 mA max.
26 V DC at 60 mA max.
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
450 g max.
Sensor Type and Input Range
The Temperature Sensor type and input range are set in the allocated words
in the DM Area for every four inputs.
The measurable data range is ±20 digits wider than the sensor input range.
Setting
°C
Input
16-bit binary
°F
BCD
[email protected]@@
indicates
minus sign.
F200 to 1300
(−200 to
1300)
16-bit binary
Leftmost bit
indicates
minus sign.
8200 to 1300 FED4 to FFFF to
(−200 to
08FC
1300)
(−300 to −1 to
2300)
BCD
[email protected]@@
indicates
minus sign.
F300 to 2300
(−300 to
2300)
Leftmost bit
indicates
minus sign.
F300 to 2300
(−300 to
2300)
0
K: −200 to
FF38 to FFFF to
1300°C
0514
(−300 to 2300°F) (−200 to −1 to
1300)
1
K: 0.0 to 500°C 0000 to 1388
(0.0 to 900.0°F) (0.0 to 500.0)
2
J: −100 to 850°C FF9C to FFFF to F100 to 0850 8100 to 0850 FF9C to FFFF to
(−100 to 1500°F) 0352
(−100 to 850) (−100 to 850) 05DC
(−100 to −1 to 850)
(−100 to −1 to
1500)
J: 0.0 to 400.0°C 0000 to 0FA0
0000 to 4000 0000 to 4000 0000 to 1D4C
(0.0 to 750.0°F) (0.0 to 400.0)
(0.0 to 400.0) (0.0 to 400.0) (0.0 to 750.0)
T: −200 to 400°C F830 to FFFF to
F999 to 4000 A000 to 4000 F448 to FFFF to
(−300 to
0FA0
(See note 3.) (−200.0 to
1B58
700.0°F)
(−200.0 to −0.1 to (−99.9 to
400.0)
(−300.0 to −0.1 to
400.0)
400.0)
700.0)
F100 to 1500 8100 to 1500
(−100 to
(−100 to
1500)
1500)
L: −100 to 850°C FF9C to FFFF to F100 to 0850 8100 to 0850 FF9C to FFFF to
(−100 to 1500°F) 0352
(−100 to 850) (−100 to 850) 05DC
(−100 to −1 to 850)
(−100 to −1 to
1500)
L: 0.0 to 400.0°C 0000 to 0FA0
0000 to 4000 0000 to 4000 0000 to 1D4C
(0.0 to 750.0°F) (0.0 to 400.0)
(0.0 to 400.0) (0.0 to 400.0) (0.0 to 750.0)
F100 to 1500 8100 to 1500
(−100 to
(−100 to
1500)
1500)
R: 0 to 1700°C
(0 to 3000°F)
0000 to 3000 0000 to 3000
(0 to 3000)
(0 to 3000)
3
4
5
6
7
112
0000 to 06A4
(0 to 1700)
0000 to 5000 0000 to 5000 0000 to 2328
(0.0 to 500.0) (0.0 to 500.0) (0.0 to 900.0)
0000 to 1700 0000 to 1700 0000 to 0BB8
(0 to 1700)
(0 to 1700) (0 to 3000)
0000 to 9000 0000 to 7999
(0.0 to 900.0) (See note 3.)
(0.0 to 799.9)
0000 to 7500
(0.0 to 750.0)
F999 to 7000
(See note 3.)
(−99.9 to
700.0)
0000 to 7500
(0.0 to 750.0)
B000 to 7000
(−300.0 to
700.0)
0000 to 7500 0000 to 7500
(0.0 to 750.0) (0.0 to 750.0)
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
Setting
°C
Input
16-bit binary
°F
BCD
16-bit binary
[email protected]@@
Leftmost bit
indicates
indicates
minus sign. minus sign.
BCD
[email protected]@@
Leftmost bit
indicates
indicates
minus sign. minus sign.
8
S: 0 to 1700°C
(0 to 3000°F)
0000 to 06A4
(0 to 1700)
0000 to 1700 0000 to 1700 0000 to 0BB8
(0 to 1700)
(0 to 1700) (0 to 3000)
0000 to 3000 0000 to 3000
(0 to 3000)
(0 to 3000)
9
B: 400 to 1800°C 0190 to 0708
(See note 2.)
(400 to 1800)
(750 to 3200°F)
0400 to 1800 0400 to 1800 02EE to 0C80
(400 to 1800) (400 to 1800) (750 to 3200)
0750 to 3200 0750 to 3200
(750 to 3200) (750 to 3200)
Note
1. If the indication range is exceeded, a sensor error will occur and the sensor
error bit will turn ON. The process value will be clamped at the lower or upper limit of the indication range, depending on the setting for data direction
at sensor error.
2. The lower limit for B thermocouples is 0°C/°F.
3. The indicator range for BCD display will be clamped at the lower (or upper)
limit in the region between the lower (or upper) limit of the setting range
and the point where a sensor error occurs.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost 4 bits (bits
12 to 15): Lower limit = −99.9, Upper limit = 999.9.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost bit (bit 15):
Lower limit = −799.9, Upper limit = 799.9.
Temperature Characteristics According to Thermocouple Type
Thermocouple
Temperature range
Set value error when ambient
temperature changes by 1°C
0 to 200°C
200 to 1,000°C
±0.43°C
±0.29°C
1,000 to 1,700°C
±285 ppm of PV
0 to 200°C
200 to 1,000°C
±0.43°C
±0.29°C
1,000 to 1,700°C
400°C or less
285 ppm of PV
Not specified.
400 to 800°C
800 to 1,000°C
±0.43°C
±0.29°C
1,000 to 1,800°C
−200 to −100°C
285 ppm of PV
±0.29°C
−100 to 400°C
400 to 1,300°C
±0.11°C
±285 ppm of PV
J
−100 to 400°C
400 to 850°C
±0.11°C
±285 ppm of PV
T
−200 to −100°C
−100 to 400°C
±0.29°C
±0.11°C
L
−100 to 400°C
400 to 850°C
±0.11°C
±285 ppm of PV
R
S
B
K
The measured temperature error is calculated as shown in the following
example.
Item
Ambient temperature
Details
30°C
Thermocouple type
K
Measured temperature (PV) 500°C
113
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
Item
Details
Reference accuracy (25°C) ±0.3°C of PV or ±1°C, whichever is greater, ±1 digit.
In this example, ±1.5°C.
Temperature characteristics 400 to 1,300°C: 285 ppm of PV.
In this example, 285 ppm × 500°C = 0.143°C.
Change in ambient temper- 5°C (25 to 30°C).
ature
Overall accuracy =
Reference accuracy + Temperature characteristic × Change in ambient temperature = ±1.5°C + ±0.143°C × 5 = Approx. ±2.2°C ±1 digit.
DM Area Allocations
First word: m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input Input Input Input Input Input Input Input
No. 1 No. 2 No. 3 No. 4 No. 5 No. 6 No. 7 No. 8
m
Data range
Decimal
Default
Data contents
Hexadecimal
12345, 0
3039,
0000 hex
0000 hex
Default block read command
Specifies the direction of data transfer when the PLC is turned ON or the
Unit is restarted for DM words m+1 to
m+60.
• 12345 (3039 hex): The data in
words m+1 to m+60 is transferred
from the Thermocouple Input Unit
to the CPU Unit. When the transfer
is completed, the value will become
0000 hex.
• Other than 12345 (3039 hex) (such
as 0000 hex): The data in the allocated words of DM Area is transferred from the CPU Unit to the
Thermocouple Input Unit.
0 to 59
0000 to
003B hex
0
(0000 hex)
Address of Data Range Error (See
note 1.)
Display parameter
m+1
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m+6
m+10 m+14 m+18 m+22 m+26 m+30 Low to high limit for
sensors.
1300
(0514 hex)
Process value H (high limit) alarm
setting
m+3
m+7
m+11 m+15 m+19 m+23 m+27 m+31
−200
(FF38 hex)
Process value L (low limit) alarm setting
m+4
m+8
m+12 m+16 m+20 m+24 m+28 m+32 0 to
32000
0000 to
7D00 hex
10000
(2710 hex)
Set value × 0.0001
m+5
m+9
m+13 m+17 m+21 m+25 m+29 m+33 –9999 to
9999
D8F1 to
270F hex
0
(0000 hex)
Span adjustment value
Zero adjustment value
Set value × 0.1
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Thermocouple Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Thermocouple Input Unit is restarted.
Operation settings (See note 2.)
m +34
(See
note 2.)
(See note 0
2.)
(0000 hex)
00: Temperature unit (°C or °F)
01: Data unit
04: Data display (binary or BCD)
08: Minus sign display format for
BCD display
12: Data direction at sensor error
Sensor type
m+35 m+38 m+41 m+44 m+47 m+50 m+53 m+56 0 to 9, 15
0000 to
0009 hex,
000F hex
0
(0000 hex)
0: K, 1: K (with decimal point), 2: J, 3:
J (with decimal point), 4: T, 5: L, 6: L
(with decimal point), 7: R, 8: S, 9: B,
F: Not used
Alarm hysteresis
114
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
DM Area address
Data range
Input Input Input Input Input Input Input Input
No. 1 No. 2 No. 3 No. 4 No. 5 No. 6 No. 7 No. 8
Decimal
Default
Data contents
Hexadecimal
Set value × 0.1
m+36 m+39 m+42 m+45 m+48 m+51 m+54 m+57 0 to 9999
0000 to
270F hex
0
(0000 hex)
m+37 m+40 m+43 m+46 m+49 m+52 m+55 m+58 0 to 60
0000 to
003C hex
0
(0000 hex)
m+59
0, 1
0000,
0001 hex
0
(0000 hex)
0: Disabled
1: Enabled
m+60
(See note 3)
0 to 6143
0000 to
17FF hex
0
(0000 hex)
CIO area (fixed)
Number of words.
Alarm ON-delay time
Unit: s
Expansion Setting Area enable
Expansion Setting Area address
Note
1. The ERC indicator on the Unit's front panel will light if an out-of-range setting is made in either Setting Group 1 (continuously refreshed area) or 2
(initial settings area). The offset from word m to the first word containing
the out-of-range error will be stored as the Address of Data Range Error in
the DM Area in four digits hexadecimal.
2. The operation settings are shown in the following table
3. A range check is not performed for the Expansion Setting Area address set
in word m+60. Be sure to check this address before starting actual operation.
Word
m+34
00
Bits
Description
Temperature unit setting
01
Data unit
Settings
0: °C
1: °F
0: Follow the setting of the sensor type
1: Display the temperature data to 0.1°C or 0.1°F
(Only binary is supported.)
04
Data format
08
Minus sign display format for BCD display 0: “F” used to indicate the minus sign.
1: Leftmost bit used to indicate the minus sign.
The setting is disabled if bits 04 to 07 are set to 0.
Data direction at sensor error
0: Goes to upper limit at sensor error
1: Goes to lower limit at sensor error
12
0: Binary (Negative values are given as 2’s complements).
1: BCD
Example: For a temperature in degrees Celsius (°C), a binary data format,
and a data direction at sensor error of “lower limit,” word m+18 will contain
1000.
115
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
Expansion Setting Area
First word: word o. (o = address specified in word m+60 in the DM Area)
Direction
Thermocouple
Input Unit to
CPU Unit
Word
o
Bit
00
Name
Input No. 1
01
02
Input No. 2
03
04
05
06
07
08
Input No. 5
Input No. 6
13
14
15
0, 1
0, 1
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Input No. 8
Same as for input No. 1.
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Input No. 7
0, 1
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
11
12
0: Process value < Set value
1: Process value ≥ Set value
Process value
H (high limit)
alarm
09
10
Process value
H (high limit)
alarm
Process value
H (high limit)
alarm
Input No. 4
Contents
0: Process value > Set value
1: Process value ≤ Set value
Process value
H (high limit)
alarm
Input No. 3
Data range
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
0, 1
Note If either of the following changes is made for the Expansion Setting Area for
the CS1W-PTS55/PTS56/PDC55, the previous data will be left in the Expansion Setting Area even after the change has been made.
Clear the previous data when changing either of these settings.
• The Expansion Setting Area Enable setting is changed from “enabled” to
“disabled.”
• The Expansion Setting Area Address setting is changed while the Expansion Setting Area Enable setting is set to “enabled.”
116
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
CIO Area Allocations
First word: n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n
Bit
00
Name
Data range
Input No. 1 Process value L 0, 1
(low limit) alarm
Contents
0: Process value > Set value
1: Process value ≤ Set value
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
0: Process value < Set value
1: Process value ≥ Set value
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
08
Input No. 5
09
10
Input No. 6
11
12
Input No. 7
13
14
Input No. 8
15
n+1
00 to 15 Input No. 1
n+2
n+3
00 to 15 Input No. 2
00 to 15 Input No. 3
n+4
n+5
00 to 15 Input No. 4
00 to 15 Input No. 5
n+6
n+7
00 to 15 Input No. 6
00 to 15 Input No. 7
n+8
00 to 15 Input No. 8
Same as for input No. 1.
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value
0, 1
0, 1
0, 1
0, 1
0, 1
0, 1
0, 1
Depends on type of
input.
Stores data in the data
range specified for the input
type ±20 digits.
117
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n+9
Bit
Name
Sensor error
Data range
00
Input No. 1
01
02
Input No. 2
Input No. 3
0, 1
0, 1
03
04
Input No. 4
Input No. 5
0, 1
0, 1
05
06
Input No. 6
Input No. 7
0, 1
0, 1
07
08
Input No. 8
Cold junction sensor 1 error
0, 1
0, 1
09
Cold junction sensor 2 error
10 to 14 Not used.
0, 1
15
0, 1
Contents
0: Normal
1: Error
0: Normal
1: Error
Conversion data enabled flag 0, 1
(See note.)
0: Data disabled
1: Data enabled
Note The Conversion Data Enabled Flag remains OFF after the PLC is turned ON
or the Unit is restarted until the AD conversion data becomes stable (approximately 2 to 4 s), then is ON during operation.
Terminal Connection Diagram
No. 4 thermocouple input
No. 3 thermocouple input
No. 2 thermocouple input
No. 1 thermocouple input
N.C.
B1
N.C.
B2
1+
B3
2+
B4
3+
B5
4+
B6
5+
B7
6+
B8
7+
B9
8+
B10
N.C.
B11
N.C.
B12
A1
CJ1+
A2
CJ1-
A3
1-
A4
2-
A5
3-
A6
4-
A7
5-
A8
6-
A9
7-
A10
8-
A11
CJ2+
A12
CJ2-
Cold junction sensor
Cold junction sensor
No. 8 thermocouple input
No. 7 thermocouple input
No. 6 thermocouple input
No. 5 thermocouple input
Note
118
• Set the Sensor type in Setting Group 2 in the DM Area to “Not used” for
any thermocouple inputs that are not used.
• Cold junction sensors are mounted before shipment. If one of the cold
junction sensors is disconnected, cold junction compensation will stop
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
•
•
•
•
and correct measurement of temperatures cannot be made. Always make
sure the cold junction sensors are connected when using the Units.
Cold junction sensors are calibrated separately for each Unit and connected circuit, so correct temperatures will not be measured if a cold junction sensor from another Unit is used or if the two cold junction sensors in
a Unit are swapped. Use the cold junction sensors as they are provided,
without making any changes.
Do not connect anything to NC terminals. Do not use NC terminals as
relay terminals.
Always ground the GR terminal on the Power Supply Unit of the PLC.
If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
Terminal Block Diagram
Amplifier
circuit
No. 1 input
A2
Double
integral
A/D
Reference
power supply
No.2 input Reference
power supply
Photocoupler
No.3 input Reference
power supply
B6
Amplifier
circuit
No. 4 input
A6
Double
integral
A/D
26 VDC
Reference
power supply
Photocoupler
5 VDC
Cold junction
sensors
A1
Amplifier
circuit
A2
Double
integral
A/D
Reference
power supply
No.2 input
Photocoupler
Digital circuits
Connector
B3
Isolation circuit
■ Input Circuits
No.3 input
Photocoupler
Photocoupler
No.6 input
Photocoupler
No.7 input
Photocoupler
Amplifier
circuit
No. 5 input
A7
B10
No. 8 input
Amplifier
circuit
A10
Double
integral
A/D
Double
integral
A/D
Reference
power supply
Photocoupler
Reference
power supply
Photocoupler
No.6 input Reference
power supply
Cold junction
sensors
A11
Amplifier
circuit
A12
Double
integral
A/D
Reference
power supply
No.7 input Reference
power supply
Isolation circuit
B7
Photocoupler
119
Section 2-4
CS1W-PTS55 Isolated-type Thermocouple Input Unit
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
Set the gain for span adjustment to a value other
than 0.
The sensor type, input range, or
process value scaling is not set
correctly.
Check and correct the settings.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring. Check whether a sensor error has been
detected in the I/O Area.
Values are Not Converted as Intended.
Probable cause
The sensor type is not set correctly.
Remedy
Check and correct the settings.
The zero/span adjustment data is
incorrect.
Check and correct the zero/span adjustment settings.
Cold junction compensation is not Check the Cold Junction Error Flag.
operating.
A compensation conductor has
not been used or a different compensation conductor is used.
Use the correct compensation conductor for the
thermocouple.
Incorrect input wiring (incorrect
thermocouple or compensation
conductor polarity.)
Correct the input wiring.
Thermocouple lead or compensat- Use a thicker compensating conductor.
ing conductor is too long and mea- Change the wiring position and shorten the comsurements are being affected by
pensating conductor.
conductor resistance.
The terminal block temperature is
not uniform due to radiated heat
from peripheral devices.
Mount the unit in a position unaffected by radiated heat.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
Insert a 0.01 to 0.1 µF ceramic capacitor
between the positive (+) and negative (−) input
terminals.
An airflow is hitting the Unit terminal block.
120
Move the terminal block to a position unaffected
by airflow.
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
2-5
Section 2-5
CS1W-PTS02 Isolated-type Resistance Thermometer Input
Unit (Pt100 or JPt100)
Overview
The CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit provides
four direct platinum resistance thermometer inputs, and sends the data to the
CPU Unit each cycle. All inputs are isolated.
CS1W-PTS02
System Configuration
CS1W-PTS02
Four resistance thermometer inputs
(Pt100 or JPt100)
Features
• Up to four platinum resistance thermometers can be connected for each
Unit (with four separate settings for temperature sensors and input
ranges).
• Pt100 (JIS, IEC) or JPt100 can be selected.
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal.
• Variable input range setting.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Zero/span adjustment capability during operation.
• Disconnection detection.
• Maximum or minimum process value can be specified for when a disconnection is detected.
121
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
Section 2-5
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PTS02
4
122
Inputs
Temperature sensor types
Platinum resistance thermometer Pt100 (JIS, IEC) or
JPt100.
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
Section 2-5
Block Diagram (Order of Processing)
The processing for the four inputs is as shown in the following diagram.
CPU Unit CIO Area
HH, H, L, LL
Process value
H, L
Process value alarm
Rate-of-change value
Rate-of-change alarm
I/O
refresh
Isolated-type Resistance Thermometer Input Unit
Process value alarm
Input disconnection
alarm
Rate-of-change alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
+115% or −15% when input disconnection is detected
Output limit: −15% to +115%
Zero/span adjustment
Input disconnection check
Process value scaling
Input calculations
Resistance thermometer type
Input range
A/D conversion, moving average
Resistance thermometer
123
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
Section 2-5
Specifications
Item
Specifications
Model
CS1W-PTS02
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
Special I/O Unit
Area
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Resistance Thermometer Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rateof-change alarms (L, H), disconnection alarms, cold junction sensor errors
DM Area words 100 words/Unit
allocated to
CPU Unit to Resistance Thermometer Input Unit:
Special I/O Units Temperature sensor type, input range (user set), scaling of process value data to be
stored in allocated words in CIO area, number of items for moving average, process
value alarm setting (LL, L, H, HH), rate-of-change alarm setting (L, H), zero/span
adjustment value, etc.
Number of temperature sensor
4
inputs
Temperature sensor types
Input ranges
Scaling in industrial units
Data storage in the CIO Area
Accuracy (25°C)
Pt100 (JIS, IEC) or JPt100
Sensor type, input range, and scaling to
industrial units are separate for each of
the 4 inputs.
Note Sensor type, input range, and scaling to industrial units are set in the
DM Area.
The input range can be set within any of Example:
the measurable input ranges shown in
Sensor type: Pt100; input range: 0 to
Table 1 (below).
500°C; industrial unit scaling: 0.0 to
Note Internally, inputs are processed in 500°C. DM Area settings are as follows:
five ranges (refer to Table 2 below), Sensor type: 0 (0000 hex)
so accuracy and resolution accord Input signal maximum: 5000 (1388 hex)
with these internal ranges.
Input signal minimum: 0 (0000 hex)
Data to be stored in the allocated words in Industrial unit maximum value stored: 500
the CIO area must be scaled (individually (01F4 hex)
Industrial unit minimum value stored: 0
for each of 4 inputs, with the minimum
(0000 hex)
and maximum values set). Data can be
stored at 0% to 100%.
The value derived from carrying out the following processing in order of the actual
process data in the input range is stored in four digits hexadecimal (binary values) in
the allocated words in the CIO Area.
1) Mean value processing → 2) Scaling → 3) Zero/span adjustment → 4) Output limits
The greater of the following: ±0.1% (of internal range full span) or 0.1°C
As shown in the following equation, the accuracy depends on the ratio of the selected
internal range (0 to 4) span to the set input range span.
Accuracy = ±0.1% x
Internal range span
Set input range span
or 0.1°C, whichever is greater.
Temperature coefficient
±0.015% /°C, for any of internal range numbers 0 to 4.
Resolution
1/4,096 (of internal range full span)
As shown in the following equation, the resolution depends on the ratio of the selected
internal range (0 to 4) span to the set input range span.
Resolution =
Internal range span
1
x
Set input range span
4096
Sensing method
3-wire method
Allowable lead wire resistance
20 Ω max. per wire
124
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
Item
Input detection current
0.25 mA
Warmup time
Response time
10 min
0.5 s (travel time from input 0% to 90%, for step input)
Conversion period
Maximum time to store data in
CPU Unit
100 ms/4 inputs
Conversion period + one CPU Unit cycle
Section 2-5
Specifications
Disconnection detection
Function
Detects disconnections at each input and turns ON the Disconnection Detection Flag.
Hardware detection time: Approx. 1 s
The process value overrange direction for when a disconnection occurs can be specified. (High: 115% of set input range; low: –15% of set input range)
Mean value pro- Calculates the moving average for the specified number of process values (1 to 16),
cessing (input
and stores that value in the CIO Area as the process value.
filter)
Process value
alarm
Rate-of-change
calculation
Rate-of-change
alarm
Isolation
Process value 4-point alarm (HH, H, LL, L), alarm hysteresis, and ON-delay timer (0
to 60 s) are available.
Calculates the amount of change per comparison time interval (1 to 16 s).
Rate-of-change 2-point alarm (H, L), alarm hysteresis (shared with process value
alarm), and ON-delay timer (0 to 60 s, shared with process value alarm) are available.
Between temperature inputs and between input terminals and PLC signals: Isolation
by transformer
Insulation resistance
Dielectric strength
20 MΩ (at 500 V DC) between inputs
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Three LED indicators on front panel (for normal operation, errors detected at the
Resistance Thermometer Input Unit, and errors related to the CPU Unit).
Front panel connector
Effect on CPU Unit cycle time
Sensor input connector terminal block (detachable)
0.3 ms
Current consumption
Dimensions
Weight
5 V DC at 150 mA max., 26 V DC at 150 mA max.
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
450 g max.
Standard accessories
None
Sensor Type and Input Range
The resistance thermometer type and input range are set in the allocated
words in the DM Area for every four inputs. The input range can be set anywhere within the measurable input ranges shown in Table 1.
Table 1: Measurable Input
Ranges
Sensor type
Pt100
JPt100
DM Area setting
0
1
Measurable input range (See note.)
–200 to 850°C
–200 to 500°C
Note Set the input range in the DM Area within this range.
Internally inputs are processed in five progressive ranges (numbers 0 to 4), as
shown in the following table.
Table 2: Internal Ranges
Internal range number
Temperature range
Span
0
1
–200 to 850°C
–200 to 438°C
1,050°C
638°C
2
–200 to 211°C
411°C
125
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
3
Internal range number
Temperature range
–100 to 104°C
204°C
4
–51 to 52°C
103°C
Section 2-5
Span
Therefore, the accuracy and resolution are determined by the ratio of the
selected internal range (0 to 4) span to the set input range span. For the internal range, a larger number is selected when both the minimum and maximum
values of the range fall within that next range.
For example, suppose that the sensor type is Pt100 and the set input range is
–100 to 400°C. Since both the minimum and maximum values fall within the
limits for internal range No. 1 (–200 to 438°C), that range will be selected.
Note With Resistance Thermometer Input Units, process values can be scaled
(e.g., 0% to 100%) in industrial units for the set input range. It is possible to
set the process value scaling higher than the resolution, but it will cause the
values to be unstable.
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
m
Decimal
12345, 0
Default
Data contents
Hexadecimal
3039, 0000 hex
0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+2 to m+93.
• 12345 (3039 hex): The data in words m+2 to
m+93 is transferred from the Resistance
Thermometer Input Unit to the CPU Unit.
When the transfer is completed, the value
will become 0000 hex.
• Other than 12345 (3039 hex) (such as 0000
hex): The data in the allocated words of DM
Area is transferred from the CPU Unit to the
Resistance Thermometer Input Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m + 10
m + 18
m + 26
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4200
(1068 hex)
Process value HH (high high limit) alarm setting
(Set at process value scaling value.)
m+3
m + 11
m + 19
m + 27
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m + 12
m + 20
m + 28
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m + 13
m + 21
m + 29
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
–200
(FF38 hex)
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m + 14
m + 22
m + 30
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Rate-of-change value H (high limit) alarm setting
(Set at rate-of-change scaling value.)
m+7
m + 15
m + 23
m + 31
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
m+8
m + 16
m + 24
m + 32
0 to 32000 0000 to 7D00 hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001)
m+9
m + 17
m + 25
m + 33
–32000 to
32000
0
(0000 hex)
Zero adjustment value
(Set at process value scaling value.)
Rate-of-change value alarm settings
Zero/span adjustment
8300 to FFFF hex,
0000 to 7D00 hex
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Resistance Thermometer
Input Unit if word m contains other than 12345 when the PLC is turned ON or the Resistance Thermometer Input Unit is restarted.
m + 34
m + 49
m + 64
m + 79
0, 1
0000 to 0001 hex
0
(0000 hex)
Sensor type
0: Pt100; 1: JPt100
Process value input range settings
126
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
DM Area address
Data range
Default
Section 2-5
Data contents
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Decimal
Hexadecimal
m + 35
m + 50
m + 65
m + 80
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Maximum input signal value
(set value x 0.1°C/°F)
m + 36
m + 51
m + 66
m + 81
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
Minimum input signal value
(set value x 0.1°C/°F)
m + 37
m + 52
m + 67
m + 82
0, 1
0000, 0001 hex
0
(0000 hex)
Unit
0: °C, 1: °F
m + 38
m + 53
m + 68
m + 83
0, 1
0000, 0001 hex
0
(0000 hex)
Process value overrange direction at time of
input disconnection
0: High; 1: Low
Process value scaling
m + 39
m + 54
m + 69
m + 84
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Value stored for maximum value in range
(span)
m + 40
m + 55
m + 70
m + 85
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
Value stored for minimum value in range (zero)
m + 41
m + 56
m + 71
m + 86
0 to 32000 0000 to 7D00 hex
40
(0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared
with process value alarm and rate-of-change
alarm.)
m + 42
m + 57
m + 72
m + 87
0 to 60
0000 to 003C hex
0
(0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rate-ofchange alarm.)
m + 43
m + 58
m + 73
m + 88
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Rate-of-change
range setting
m + 44
m + 59
m + 74
m + 89
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
–4000
(F060 hex)
m + 45
m + 60
m + 75
m + 90
1 to 16
0001 to 0010 hex
1
(0001 hex)
Rate-of-change comparison time interval
(Unit: s)
m + 46
m + 61
m + 76
m + 91
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Rate-of-change
value scaling
m + 47
m + 62
m + 77
m + 92
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
m + 48
m + 63
m + 78
m + 93
1 to 16
0001 to 0010 hex
4
(0004 hex)
Number of process values for calculating moving average for mean value processing
m + 96
m + 97
0 to 93
0000 to 005D hex
0
(0000 hex)
Address of Data Range Error (See note.)
Alarm supplementary functions
Rate-of-change function
Maximum rate-of-change
value (Process value
industrial unit; comparison
time interval)
Minimum rate-of-change
value (Process value
industrial unit; comparison
time interval)
Value stored for maximum
value in range
Value stored for minimum
value in range
Mean value processing function
Storage parameter
m + 94
m + 95
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Address of Data Range
Error in the DM Area in four digits hexadecimal. For more information, refer to
1-6 Error Processing.
127
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
Section 2-5
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Word
Resistance n
Thermometer Input Unit
to CPU Unit
Bit
00
Input No. 1
01
Process value L (low
limit) alarm
02
Process value H (high 0, 1
limit) alarm
03
Process value HH
(high high limit) alarm
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
04
Input No. 2
05
06
07
08
Input No. 3
10
11
12
13
0, 1
0, 1
0, 1
Contents
0: Process value >
Set value
1: Process value ≤ Set
value
0: Process value <
Set value
1: Process value ≥ Set
value
Same as for input No.
1.
0, 1
0, 1
Process value HH
0, 1
(high high limit) alarm
09
128
Name
Data range
Process value LL (low 0, 1
low limit) alarm
Input No. 4
Process value LL (low 0, 1
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
Process value HH
(high high limit) alarm
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
Same as for input No.
1.
0, 1
0, 1
0, 1
0, 1
0, 1
14
Process value H (high 0, 1
limit) alarm
15
Process value HH
0, 1
(high high limit) alarm
Same as for input No.
1.
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
Direction
Word
Resistance n + 1
Thermometer Input Unit
to CPU Unit n + 2
Bit
00 to 15
Name
Input No. 1 process value
00 to 15
Input No. 2 process value
n+3
00 to 15
Input No. 3 process value
n+4
00 to 15
Input No. 4 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+5
00 to 15
Input No. 1 rate-of-change value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+6
00 to 15
Input No. 2 rate-of-change value
n+7
00 to 15
Input No. 3 rate-of-change value
n+8
00 to 15
Input No. 4 rate-of-change value
n+9
00
Input No. 1
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
0, 1
01
02
Input No. 2
03
04
Input No. 3
05
06
07
Input No. 4
Rate-of-change value
L (low limit) alarm
Data range
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
Section 2-5
Contents
The present process
value is stored
according to the scaling set in the allocated
words of the DM Area.
The process value
rate of change is
stored according to
the scaling set in the
allocated words of the
DM Area.
0: Rate-of-change
value > Set value
1: Rate-of-change
value ≤ Set value
Rate-of-change value
H (high limit) alarm
0, 1
0: Rate-of-change
value < Set value
1: Rate-of-change
value ≥ Set value
Rate-of-change value
L (low limit) alarm
Rate-of-change value
H (high limit) alarm
Rate-of-change value
L (low limit) alarm
Rate-of-change value
H (high limit) alarm
0, 1
Same as for input No.
1.
Rate-of-change value
L (low limit) alarm
0, 1
Rate-of-change value
H (high limit) alarm
0, 1
0, 1
0, 1
Same as for input No.
1.
0, 1
08
Input No. 1 input disconnection
0, 1
09
Input No. 2 input disconnection
0, 1
10
Input No. 3 input disconnection
0, 1
11
Input No. 4 input disconnection
0, 1
Same as for input No.
1.
0: Normal
1: Disconnection
Same as for input No.
1.
Same as for input No.
1.
Same as for input No.
1.
129
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
Section 2-5
Terminal Connection Diagram
CS1W-PTS02 Isolated-type Resistance Thermometer Unit
Resistance thermometer
No. 1 input
Resistance thermometer
No. 2 input
Resistance thermometer
No. 3 input
Resistance thermometer
No. 4 input
Note
1. Wire the same length to A, B, and b, so that the impedance will be the
same. In particular, do not short circuit between B and b at the terminal
block.
2. For unused input terminals, short-circuit between A–B and B–b (e.g., A2–
A3 and A3–A4 for input No. 1) of the resistance thermometer inputs with
the lead wire.
Terminal Block Diagram
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit
Resistance thermometer
Input No. 1
470 Ω
Standard
resistance
Isolation
circuit
Amplifier
Constant current
circuit
Constant current circuit
Resistance thermometer
Input No. 2
Multiplexer
Constant current circuit
Multi-gain
amplifier
circuit
A/D converter
Isolation
circuit
470 Ω
Standard
resistance
Digital computation circuit
Amplifier
Constant current
circuit
Constant current circuit
Input No. 3
Isolation
circuit
470 Ω
Standard
resistance
Amplifier
Connector
Resistance thermometer
5 V DC
Constant current
circuit
Isolated power supply circuit
26 V DC
Constant current circuit
Resistance thermometer
Input No. 4
Isolation
circuit
470 Ω
Standard
resistance
130
Amplifier
Constant current
circuit
To CPU Unit
CS1W-PTS02 Isolated-type Resistance Thermometer Input Unit (Pt100 or JPt100)
Section 2-5
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
Set the gain for span adjustment to a value other than 0.
The minimum and maximum values for process value scaling are
either the same or are set
extremely low.
The sensor type, input range, or
process value scaling is not set
correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Set the minimum and maximum values correctly.
Check and correct the settings.
Check whether the input voltage or current has changed. Check for faulty or disconnected wiring. Check whether a wiring disconnection has been detected in the I/O
Area.
Values are Not Converted as Intended.
Probable cause
Remedy
The sensor type, input range, or Check and correct the settings.
process value scaling is not set
correctly.
The zero/span adjustment data is Check and correct the zero/span adjustment settings.
incorrect.
The resistance thermometer
Correct the input wiring.
input wiring is faulty.
Converted Values are Unstable.
Probable cause
Input signals are being affected
by external noise.
Remedy
Change the connection paths of the input signal lines. (Separate them from sources of
noise or use shielded cable.)
Increase the number of values for calculating the moving average in mean value processing.
The process value scaling value
is greater than the Unit’s resolution.
Reduce the process value scaling value.
The input signal range setting is
too small.
Match the input signal range to the internal ranges.
131
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
2-6
Section 2-6
CS1W-PTS03 Isolated-type Resistance Thermometer Input
Unit (Ni508.4)
Overview
The CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit provides
four direct Ni thermometer inputs, and sends the data to the CPU Unit each
cycle. All inputs are isolated.
CS1W-PTS03
System Configuration
CS1W-PTS03
Four resistance thermometer
inputs (Ni508.4 Ω)
Features
• Up to four Ni resistance thermometers can be connected for each Unit
(with four separate input ranges).
• Temperature sensor values are sent to the CPU Unit in four digits hexadecimal.
• Variable input range setting.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Zero/span adjustment capability during operation.
• Disconnection detection.
• Maximum or minimum process value can be specified for when a disconnection is detected.
132
Section 2-6
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PTS03
4
Inputs
Temperature sensor types
Resistance thermometer Ni508.4
Block Diagram (Order of Processing)
The processing for the four inputs is as shown in the following diagram.
CPU Unit CIO Area
HH, H, L, LL
Process value
Process value alarm
H, L
Rate-of-change value
Rate-of-change alarm
Input disconnection alarm
I/O
refresh
Isolated-type Resistance Thermometer Input Unit
Process value alarm
Rate-of-change alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
+115% or −15% when input disconnection is detected
Output limit: −15% to +115%
Zero/span adjustment
Input disconnection check
Process value scaling
Input calculations
Input range
A/D conversion, moving average
Resistance thermometer
Ni508.4
133
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
Section 2-6
Specifications
Item
Specifications
Model
CS1W-PTS03
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
Special I/O Unit
Area
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Resistance Thermometer Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rateof-change alarms (L, H), disconnection alarms
DM Area words 100 words/Unit
allocated to
CPU Unit to Resistance Thermometer Input Unit:
Special I/O Units Temperature sensor type, input range (user set), scaling of process value data to be
stored in allocated words in CIO area, number of items for moving average, process
value alarm setting (LL, L, H, HH), rate-of-change alarm setting (L, H), zero/span
adjustment value, etc.
Number of temperature sensor
4
inputs
Temperature sensor types
Ni508.4
Input range and scaling to industrial units
are separate for each of the 4 inputs.
Note Sensor type, input range, and scaling to industrial units are set in the
DM Area.
Input ranges
The input range can be set within a range
of –50 to 150°C (variable setting).
Note Internally, inputs are processed in
the above range (refer to Table 2
below), so accuracy and resolution
accord with this internal range.
Data to be stored in the allocated words in
the CIO area must be scaled (with the
minimum and maximum values set). Data
can be stored at 0% to 100%.
Example:
Input range: –50 to 100°C; industrial unit
scaling: –50.0 to 100.0°C. DM Area settings are as follows:
Input signal maximum: 1000 (03E8 hex)
Input signal minimum: –500 (FE0C hex)
Industrial unit maximum value stored:
1000 (03E8 hex)
Industrial unit minimum value stored:
–500 (FE0C hex)
Scaling in industrial units
Data storage in the CIO Area
Accuracy (25°C)
The value derived from carrying out the following processing in order of the actual
process data in the input range is stored in four digits hexadecimal (binary values) in
the allocated words in the CIO Area.
1) Mean value processing → 2) Scaling → 3) Zero/span adjustment → 4) Output limits
The greater of the following: ±0.2% (of internal range full span) or 0.2°C
As shown in the following equation, the accuracy depends on the ratio of the selected
internal range (0 to 4) span to the set input range span.
Accuracy = ±0.1% x
Internal range span
Set input range span
or 0.2°C, whichever is greater.
Temperature coefficient
±0.015% /°C, for any of internal range numbers 0 to 4.
Resolution
1/4,096 (of internal range full span)
As shown in the following equation, the resolution depends on the ratio of the internal
range span to the set input range span.
Resolution =
1
x
4096
Sensing method
3-wire method
Allowable lead wire resistance
Input detection current
20 Ω max. per wire
0.25 mA
Warmup time
10 min
134
Internal range span
Set input range span
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
Item
Response time
Specifications
0.5 s (travel time from input 0% to 90%, for step input)
Conversion period
Maximum time to store data in
CPU Unit
100 ms/4 inputs
Conversion period + one CPU Unit cycle
Section 2-6
Disconnection detection
Function
Detects disconnections at each input and turns ON the Disconnection Detection Flag.
Hardware detection time: Approx. 1 s
The process value high/low direction for when a disconnection occurs can be specified. (High: 115% of set input range; low: –15% of set input range)
Mean value pro- Calculates the moving average for the specified number of process values (1 to 16),
cessing (input
and stores that value in the CIO Area as the process value.
filter)
Process value
alarm
Rate-of-change
calculation
Rate-of-change
alarm
Isolation
Process value 4-point alarm (HH, H, LL, L), alarm hysteresis, and ON-delay timer (0
to 60 s) are available.
Calculates the amount of change per comparison time interval (1 to 16 s).
Rate-of-change 2-point alarm (H, L), alarm hysteresis (shared with process value
alarm), and ON-delay timer (0 to 60 s, shared with process value alarm) are available.
Between temperature inputs and between input terminals and PLC signals: Isolation
by transformer
Insulation resistance
Dielectric strength
20 MΩ (at 500 V DC) between inputs
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Three LED indicators on front panel (for normal operation, errors detected at the
Resistance Thermometer Input Unit, and errors related to the CPU Unit).
Front panel connector
Effect on CPU Unit cycle time
Sensor input connector terminal block (detachable)
0.3 ms
Current consumption
Dimensions
Weight
5 V DC at 150 mA max., 26 V DC at 150 mA max.
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
450 g max.
Standard accessories
None
Sensor Type and Input Range
The input range is set in the allocated words in the DM Area for every four
inputs. It can be set anywhere within the measurable input range shown in
Table 1.
Measurable Input Range
Sensor type
Ni508.4
Measurable Input range (See note.)
–50 to 150°C
Note Set the input range in the DM Area within this range.
Even if the input range is set more narrowly than the range of –50 to 150°C,
internally inputs will be processed according to the internal range shown in
the following table.
Internal range
Internal range temperatures
–50 to 150°C
Internal range span
200°C
Therefore, the accuracy and resolution are determined by the ratio of the
internal range span to the set input range span.
Example: Even if the set input range is –50 to 100°C, internally inputs will be
processed according to the internal range of –50 to 150°C.
135
Section 2-6
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
Note With Resistance Thermometer Units (Ni508.4), process values can be scaled
(e.g., 0% to 100%) in industrial units for the set input range. Generally, however, set the same values for process value scaling in industrial units as for
the set input range. It is possible to set the process value scaling higher than
the resolution, but it will cause the values to be unstable.
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
m
Decimal
12345, 0
Default
Data contents
Hexadecimal
3039, 0000 hex
0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+2 to m+93.
• 12345 (3039 hex): The data in words m+2 to
m+93 is transferred from the Resistance
Thermometer Input Unit to the CPU Unit.
When the transfer is completed, the value
will become 0000 hex.
• Other than 12345 (such as 0000 hex): The
data in the allocated words of DM Area is
transferred from the CPU Unit to the Resistance Thermometer Input Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m + 10
m + 18
m + 26
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4200
(1068 hex)
Process value HH (high high limit) alarm setting
(Set at process value scaling value.)
m+3
m + 11
m + 19
m + 27
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m + 12
m + 20
m + 28
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m + 13
m + 21
m + 29
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
–200
(FF38 hex)
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m + 14
m + 22
m + 30
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Rate-of-change value H (high limit) alarm setting
(Set at rate-of-change scaling value.)
m+7
m + 15
m + 23
m + 31
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
m+8
m + 16
m + 24
m + 32
0 to 32000 0000 to 7D00 hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001)
m+9
m + 17
m + 25
m + 33
–32000 to
32000
0
(0000 hex)
Zero adjustment value
(Set at process value scaling value.)
Rate-of-change value alarm settings
Zero/span adjustment
8300 to FFFF hex,
0000 to 7D00 hex
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Resistance Thermometer
Input Unit if word m contains other than 12345 when the PLC is turned ON or the Resistance Thermometer Input Unit is restarted.
m + 34
m + 49
m + 64
m + 79
2
0002 hex
2
(0002 hex)
Sensor type
2: Ni508.4
m + 35
m + 50
m + 65
m + 80
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
1000
(03E8 hex)
Maximum input signal value
(set value x 0.1°C/°F)
m + 36
m + 51
m + 66
m + 81
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
–500
(FE0CH hex)
Minimum input signal value
(set value x 0.1°C/°F)
m + 37
m + 52
m + 67
m + 82
0, 1
0000, 0001 hex
0
(0000 hex)
Unit
0: °C, 1: °F
m + 38
m + 53
m + 68
m + 83
0, 1
0000, 0001 hex
0
(0000 hex)
Process value overrange direction at time of
input disconnection
0: High; 1: Low
Process value input range settings
136
Section 2-6
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
DM Area address
Data range
Default
Data contents
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Decimal
Hexadecimal
m + 39
m + 54
m + 69
m + 84
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Value stored for maximum value in range
(span)
m + 40
m + 55
m + 70
m + 85
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
Value stored for minimum value in range (zero)
m + 41
m + 56
m + 71
m + 86
0 to 32000 0000 to 7D00 hex
40
(0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared
with process value alarm and rate-of-change
alarm.)
m + 42
m + 57
m + 72
m + 87
0 to 60
0000 to 003C hex
0
(0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rate-ofchange alarm.)
m + 43
m + 58
m + 73
m + 88
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
m + 44
m + 59
m + 74
m + 89
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
–4000
(F060 hex)
m + 45
m + 60
m + 75
m + 90
1 to 16
0001 to 0010 hex
1
(0001 hex)
Rate-of-change comparison time interval
(Unit: s)
m + 46
m + 61
m + 76
m + 91
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Rate-of-change
value scaling
m + 47
m + 62
m + 77
m + 92
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
Process value scaling
Alarm supplementary functions
Rate-of-change function
Rate-of-change
range setting
Maximum rate-of-change
value (Process value
industrial unit; comparison
time interval)
Minimum rate-of-change
value (Process value
industrial unit; comparison
time interval)
Value stored for maximum
value in range
Value stored for minimum
value in range
Mean value processing function
m + 48
m + 63
m + 78
m + 93
1 to 16
0001 to 0010 hex
4
(0004 hex)
Number of process values for calculating moving average for mean value processing
m + 97
0 to 93
0000 to 005D hex
0
(0000 hex)
Address of Data Range Error (See note.)
Storage parameter
m + 94
m + 95
m + 96
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Address of Data Range
Error in the DM Area in four digits hexadecimal. For more information, refer to
1-6 Error Processing.
137
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
Section 2-6
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Resistance
Thermometer Input
Unit to CPU
Unit
Word
n
Bit
00
Input No. 1
01
Process value L (low
limit) alarm
02
Process value H (high 0, 1
limit) alarm
03
Process value HH
(high high limit) alarm
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
04
Input No. 2
05
06
07
08
Input No. 3
10
11
12
13
0, 1
0, 1
0, 1
Contents
0: Process value >
Set value
1: Process value ≤ Set
value
0: Process value <
Set value
1: Process value ≥ Set
value
Same as for input No.
1.
0, 1
0, 1
Process value HH
0, 1
(high high limit) alarm
09
138
Name
Data range
Process value LL (low 0, 1
low limit) alarm
Input No. 4
Process value LL (low 0, 1
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
Process value HH
(high high limit) alarm
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
Same as for input No.
1.
0, 1
0, 1
0, 1
0, 1
0, 1
14
Process value H (high 0, 1
limit) alarm
15
Process value HH
0, 1
(high high limit) alarm
Same as for input No.
1.
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
Direction
Resistance
Thermometer Input
Unit to CPU
Unit
Word
n+1
Bit
00 to 15
Name
Input No. 1 process value
n+2
00 to 15
Input No. 2 process value
n+3
00 to 15
Input No. 3 process value
n+4
00 to 15
Input No. 4 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+5
00 to 15
Input No. 1 rate-of-change value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+6
00 to 15
Input No. 2 rate-of-change value
n+7
00 to 15
Input No. 3 rate-of-change value
n+8
00 to 15
Input No. 4 rate-of-change value
n+9
00
Input No. 1
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
0, 1
01
02
Input No. 2
03
04
Input No. 3
05
06
07
Input No. 4
Rate-of-change value
L (low limit) alarm
Data range
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
Section 2-6
Contents
The present process
value is stored
according to the scaling set in the allocated
words of the DM Area.
The process value
rate of change is
stored according to
the scaling set in the
allocated words of the
DM Area.
0: Rate-of-change
value > Set value
1: Rate-of-change
value ≤ Set value
Rate-of-change value
H (high limit) alarm
0, 1
0: Rate-of-change
value < Set value
1: Rate-of-change
value ≥ Set value
Rate-of-change value
L (low limit) alarm
Rate-of-change value
H (high limit) alarm
Rate-of-change value
L (low limit) alarm
Rate-of-change value
H (high limit) alarm
0, 1
Same as for input No.
1.
Rate-of-change value
L (low limit) alarm
0, 1
Rate-of-change value
H (high limit) alarm
0, 1
0, 1
0, 1
Same as for input No.
1.
0, 1
08
Input No. 1 input disconnection
0, 1
09
Input No. 2 input disconnection
0, 1
10
Input No. 3 input disconnection
0, 1
11
Input No. 4 input disconnection
0, 1
Same as for input No.
1.
0: Normal
1: Disconnection
Same as for input No.
1.
Same as for input No.
1.
Same as for input No.
1.
139
Section 2-6
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
Terminal Connection Diagram
CS1W-PTS03 Isolated-type Resistance Thermometer Unit
Resistance thermometer (Ni508.4 Ω)
Input No. 1
Resistance thermometer
Input No. 2
Resistance thermometer
Input No. 3
Resistance thermometer
Input No. 4
Note
1. Wire the same length to A, B, and b, so that the impedance will be the
same. In particular, do not short circuit between B and b at the terminal
block.
2. For unused input terminals, short-circuit between A–B and B–b (e.g., A2–
A3 and A3–A4 for input No. 1) of the resistance thermometer inputs with
the lead wire.
Terminal Block Diagram
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
Resistance thermometer
Input No. 1
Isolation
circuit
470 Ω
Standard
resistance
Amplifier
Constant current
circuit
Constant current circuit
Resistance thermometer
Multiplexer
Constant current circuit
Amplifier circuit
A/D converter
Input No. 2
470 Ω
Standard
resistance
Isolation
circuit
Digital computation circuit
Amplifier
Constant current
circuit
Constant current circuit
Input No. 3
470 Ω
Standard
resistance
Isolation
circuit
Amplifier
Connector
Resistance thermometer
5 V DC
Constant current
circuit
Isolated power supply circuit
26 V DC
Constant current circuit
Resistance thermometer
Input No. 4
470 Ω
Standard
resistance
140
Isolation
circuit
Amplifier
Constant current
circuit
To CPU Unit
CS1W-PTS03 Isolated-type Resistance Thermometer Input Unit (Ni508.4)
Section 2-6
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
Set the gain for span adjustment to a value other than 0.
The minimum and maximum values for process value scaling are
either the same or are set
extremely low.
The sensor type, input range, or
process value scaling is not set
correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Set the minimum and maximum values correctly.
Check and correct the settings.
Check whether the input voltage or current has changed. Check for faulty or disconnected wiring. Check whether a wiring disconnection has been detected in the I/O
Area.
Values are Not Converted as Intended.
Probable cause
Remedy
The sensor type, input range, or Check and correct the settings.
process value scaling is not set
correctly.
The zero/span adjustment data is Check and correct the zero/span adjustment settings.
incorrect.
The resistance thermometer
Correct the input wiring.
input wiring is faulty.
Converted Values are Unstable.
Probable cause
Input signals are being affected
by external noise.
Remedy
Change the connection paths of the input signal lines. (Separate them from sources of
noise or use shielded cable.)
Increase the number of values for calculating the moving average in mean value processing.
The process value scaling value
is greater than the Unit’s resolution.
Reduce the process value scaling value.
The input signal range setting is
too small.
Match the input signal range to the internal ranges.
141
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
2-7
Section 2-7
CS1W-PTS12 Isolated-type Resistance Thermometer Input
Unit (Pt100, JPt100, Pt50, Ni508.4)
Overview
The CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit provides
four direct resistance thermometer inputs, and sends the data to the CPU Unit
each cycle. All inputs are isolated.
CS1W-PTS12
RUN
ERC
ERH
EDCBA
9876
543210
F
X101 0 X100
54321
F
EDCBA
MACH
No.
9876
System Configuration
CS1W-PTS12
Four resistance
thermometer inputs
(Pt100 (JIS, IEC),
JPt100, Pt50, or
Ni508.4)
Features
• Up to four resistance thermometers can be connected for each Unit (with
four separate settings for temperature sensors and input ranges).
• Pt100 (JIS, IEC), JPt100, Pt50, or Ni508.4 can be selected.
• 1/64,000 resolution for all temperature specifications.
• High-speed conversion of 20 ms/4 inputs and 10 ms/2 inputs.
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal.
• Variable input range setting.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Zero/span adjustment capability during operation.
• Disconnection detection.
• Maximum or minimum process value can be specified for when a disconnection is detected.
• Adjustment period control.
142
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 2-7
• Peak and bottom detection.
• Top and valley detection.
Model Information
Unit
classification
CS-series Special I/O Unit
Model number
CS1W-PTS12
Inputs
4
Input types
Resistance thermometer Pt100
(JIS, IEC), JPt100, Pt50, or
Ni508.4
143
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 2-7
Block Diagram (Order of Processing)
The processing for the inputs is as shown in the following diagram.
CPU Unit
CPU Unit Expansion Area Allocations
Top/valley value
Peak/Bottom value
CPU Unit CIO Area
HH, H, L, LL
Process value
H, L
Rate-of-change value
Process value alarm
Rate-of-change alarm
I/O refresh
Isolated-type Resistance Thermometer Input Unit
Process value alarm
Input disconnection alarm
Rate-of-change alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
+115% or −15% when input disconnection is detected
Output limit: −15% to +115%
Input disconnection check
Zero/span adjustment
Process value scaling
Input calculations
Resistance thermometer type
Input range
A/D conversion, moving average
Resistance thermometer
144
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 2-7
Specifications
Item
Specifications
Model
CS1W-PTS12
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
Special I/O Unit
Area
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Resistance Thermometer Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rateof-change alarms (L, H), disconnection alarms, adjustment period end/notices.
DM Area words 100 words/Unit
allocated to
CPU Unit to Resistance Thermometer Input Unit:
Special I/O Units Temperature sensor type, input range (user set), scaling of process value data to be
stored in allocated words in CIO area, rate-of-change input range, scaling of rate-ofchange data, number of items for moving average, process value alarm setting (LL, L,
H, HH), rate-of-change alarm setting (L, H), zero/span adjustment value.
Expansion Con- 35 words/Unit
trol/Monitor Area CPU Unit to Resistance Thermometer Input Unit:
words
Hold function selection start/reset, adjustment period control, control bits
Resistance Thermometer Input Unit to CPU Unit:
Adjustment period warnings/notices, peak and bottom values, top and valley values
Expansion Setting Area words
Number of temperature sensor
inputs
Temperature sensor type
46 words/Unit
CPU Unit to Resistance Thermometer Input Unit:
Expansion Setting Area settings, adjustment period control, peak and bottom detection, top and valley detection
4
Pt100 (JIS, IEC), JPt100, Pt50, Ni508.4
Sensor type, input range, and scaling to industrial units are separate for each of the 4
inputs.
Scaling
Data to be stored in the allocated words in the CIO area must be scaled (with the minimum and maximum values set by user) (4 inputs set separately.). Data can be stored
at 0% to 100%.
Data storage in the CIO Area
The value derived from carrying out the following processing in order of the actual process data in the input range is stored in four digits hexadecimal (binary values) in the
allocated words in the CIO Area.
1) Mean value processing → 2) Scaling → 3) Zero/span adjustment → 4) Output limits
The greater of the following: ±0.05% or ±0.1°C
Accuracy (25°C)
Temperature coefficient
Resolution
Pt100: 0.009%/°C
JPt100: 0.01%/°C
Pt50:
0.02%/°C
Ni508.4: 0.012%/°C
1/64,000
Sensing method
Allowable lead wire resistance
3-wire method
20 Ω max. per wire
Input detection current
Warmup time
0.5 mA
10 min
Response time
100 ms (travel time from input 0% to 90%, for step input and with moving average for 4
samples)
Conversion period
20 ms/4 inputs or 10 ms/2 inputs, selectable in DM Area words allocated to Unit as a
Special I/O Unit.
145
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Item
Maximum time to store data in
CPU Unit
Section 2-7
Specifications
Conversion period + one CPU Unit cycle
Disconnection detection
Function
Detects disconnections at each input and turns ON the Disconnection Detection Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a disconnection occurs can be specified. (High: 115% of set input range; low: –15% of set input range)
Mean value pro- Calculates the moving average for the specified number of process values (1 to 128),
cessing (input
and stores that value in the CIO Area as the process value.
filter)
Process value
alarm
Rate-of-change
calculation
Rate-of-change
alarm
Adjustment
period control
Process value 4-point alarm (HH, H, LL, L), alarm hysteresis, and ON-delay timer (0 to
60 s are available).
Calculates the amount of change per comparison time interval (1 to 16 s).
Peak and bottom detection
Detects the maximum (peak) and minimum (bottom) analog input values, from when
the Hold Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON
until it turns OFF. These values are stored as the peak and bottom values in the
Expansion Control/Monitor Area.
This function detects the top and valley values for analog inputs, from when the Hold
Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON until it
turns OFF. These values are stored as the top and valley values in the Expansion
Control/Monitor Area.
Top and valley
detection
Rate-of-change 2-point alarm (H, L), alarm hysteresis, and ON-delay timer (0 to 60 s
are available, shared with process value alarm).
When zero/span adjustment is executed, the date is internally recorded at the Unit.
When the preset zero/span adjustment period and the notice of days remaining have
elapsed, this function turns ON a warning flag to give notice that it is time for readjustment.
Isolation
Between temperature inputs and between input terminals and PLC signals: Power
supply isolated by transformers, signals isolated by photocouplers.
Insulation resistance
Dielectric strength
20 MΩ (at 500 V DC) between inputs
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Front panel connector
Three LED indicators on front panel (for normal operation, errors detected at the
Resistance Thermometer Input Unit, and errors detected at the CPU Unit).
Sensor input connector terminal block (detachable)
Effect on CPU Unit cycle time
Current consumption
0.3 ms
5 V DC at 120 mA max., 26 V DC at 70 mA max.
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
Standard accessories
450 g max.
None
Sensor Type and Input Range
The resistance thermometer type and input range are set in the allocated
words in the DM Area for every four inputs. The input range can be set anywhere within the measurable input ranges shown in the following table. Accuracy and resolution, however, are not determined from the set input range, but
rather from the measurable input range shown in the following table. Therefore, accuracy and resolution do not change even when a narrow input range
is set.
146
Sensor type
Pt100
DM Area setting
0
Measurable input range
−200 to 850°C
JPt100
1
−200 to 500°C
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
DM Area setting
Section 2-7
Sensor type
Pt50
2
Measurable input range
−200 to 649°C
Ni508.4
3
−50 to 150°C
DM Area Allocations
First word: word m. m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
Decimal
Default
Data contents
Hexadecimal
m
12345, 0
3039, 0000 hex 0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM Area words m+1 to m+93.
• 12345 (3039 hex): The data in words m+1
to m+93 is transferred from the Resistance Thermometer Input Unit to the CPU
Unit. When the transfer is completed, the
value will become 0000 hex.
• Other than 12345 (3039 hex) (such as
0000 hex): The data in the allocated
words of DM Area is transferred from the
CPU Unit to the Resistance Thermometer
Input Unit.
m+1
0, 1
0000, 0001 hex 0
0: 4 inputs; 1: 2 inputs
Number of inputs setting
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m + 10
m + 18
m + 26
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4200
(1068 hex)
Process value HH (high high limit) alarm
setting
(Set at process value scaling value.)
m+3
m + 11
m + 19
m + 27
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4000
(0FA0 hex)
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m + 12
m + 20
m + 28
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
0
(0000 hex)
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m + 13
m + 21
m + 29
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
–200
(FF38 hex)
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m + 14
m + 22
m + 30
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4000
(0FA0 hex)
Rate-of-change value H (high limit) alarm
setting
(Set at rate-of-change scaling value.)
m+7
m + 15
m + 23
m + 31
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
0
(0000 hex)
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
m+8
m + 16
m + 24
m + 32
0 to 32000
0000 to 7D00
hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001%)
m+9
m + 17
m + 25
m + 33
–32000 to
32000
8300 to FFFF
hex,
0000 to 7D00
hex
0
(0000 hex)
Zero adjustment value
(Set at process value scaling.)
Rate-of-change value alarm settings
Zero/span adjustment
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Resistance Thermometer
Input Unit if word m contains other than 12345 when the PLC is turned ON or the Resistance Thermometer Input Unit is restarted.
Sensor type
m+34
m+49
m+64
m+79
0 to 3
0000 to 0003
hex
0 (0000 hex)
0: Pt100; 1: JPt100: 2: Pt50: 3: Ni508.4
m+35
m+50
m+65
m+80
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Maximum input signal value
(set value x 0.1°C/°F)
m+36
m+51
m+66
m+81
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Minimum input signal value
(set value x 0.1°C/°F)
Process value input range settings
147
Section 2-7
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
DM Area address
Input
No. 1
m+37
Input
No. 2
m+52
Input
No. 3
m+67
Data range
Input
No. 4
m+82
Decimal
0, 1
Default
Data contents
Hexadecimal
0000, 0001 hex 0 (0000 hex)
Unit
0: °C, 1: °F
Process value overrange direction at
time of input disconnection
m+38
m+53
m+68
m+83
0, 1
0000, 0001 hex 0 (0000 hex)
0: High; 1: Low
Process value scaling
m+39
m+54
m+69
m+84
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Value stored for maximum value in range
(span)
m+40
m+55
m+70
m+85
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Value stored for minimum value in range
(zero)
m+41
m+56
m+71
m+86
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared
with process value alarm and rate-ofchange alarm.)
m+42
m+57
m+72
m+87
0 to 60
0000 to 003C
hex
0 (0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rateof-change alarm.)
m+43
m+58
m+73
m+88
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
m+44
m+59
m+74
m+89
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
−4000 (F060
hex)
m+45
m+60
m+75
m+90
1 to 16
0001 to 0010
hex
1 (0001 hex)
Rate-of-change comparison time interval
(Unit: s)
m+46
m+61
m+76
m+91
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Rate-of-change
value scaling
m+47
m+62
m+77
m+92
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
−4000 (F060
hex)
m+48
m+63
m+78
m+93
1 to 128
0001 to 0080
hex
25 (0019 hex)
Number of process values for calculating
moving average for mean value processing
m+96
m+97
0 to 99, 100 to
1XX
0000 to 0063
hex, 0064 to
0XXX hex
0 (0000 hex)
Address of Data Range Error (See note.)
Alarm supplementary functions
Rate-of-change function
Rate-of-change
range setting
Maximum rate-of-change
value (Set value industrial
unit; comparison time
interval)
Minimum rate-of-change
value (Set value industrial
unit; comparison time
interval)
Value stored for maximum value in range
Value stored for minimum
value in range
Mean value processing function
Display parameter
m+94
m+95
Expansion Setting Area allocation settings
m+98
0 to 5
0000 to 0005
hex
---
Expansion Setting Area allocation
0: Not used; 1: DM; 2: CIO; 3: W; 4: H;
5: EM
m+99
0 to 32767
0000 to 7FFF
hex
---
First word for Expansion Setting Area
Note
1. The ERC indicator on the Unit’s front panel will light if an out-of-range setting is made in either Setting Group 1 or 2, or in the Expansion Setting Area. The offset from word m to the first word containing the out-of-range
error will be stored as the Address of Data Range Error in the DM Area in
four digits hexadecimal. For more information, refer to 1-6 Error Processing.
If the first memory address where the out-of-range error occurred is in the
Expansion Setting Area, the Address of Data Range Area will be +100 or
later. If the first word of the Expansion Setting Area has the error, the Address of Data Range Area will be +100.
148
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 2-7
2. When specifying an expansion setting area, be sure that it does not overlap with other areas that are being used. If areas overlap, the words that
are allocated may be overwritten, resulting in unexpected operation.
3. When specifying the first word in an expansion setting area, be sure that
the end of the memory area is not exceeded.
Expansion Setting Area Allocations
First word: word o. o = address specified in word m+99 in the area specified
by word m+98 in the DM Area.
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
Decimal
Default
Data contents
Hexadecimal
Setting Group 3 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Resistance Thermometer
Input Unit if word m contains other than 12345, and if Expansion Setting Area settings are allocated, when the PLC is turned ON or the
Resistance Thermometer Input Unit is restarted.
Expansion Control/Monitor Area settings
o
0 to 5
0000 to 0005
hex
---
Expansion Control/Monitor Area allocation
0: Not used. 1: DM; 2: CIO; 3: W; 4: H;
5: EM
o+1
0 to 32767
0000 to 7FFF
hex
---
Expansion Control/Monitor Area first word
Zero/span adjustment supplementary
function
o+2
o+13
o+24
o+35
0 to 32000
0000 to 7D00
hex
1000 (2710
hex)
Span adjustment position
(Input span percentage)
o+3
o+14
o+25
o+36
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Zero adjustment position
(Input span percentage)
o+4
o+15
o+26
o+37
0 to 9999
0000 to 270F
hex
365 (016D hex) Zero/span adjustment period (Unit: Days)
o+5
o+16
o+27
o+38
0 to 9999
0000 to 270F
hex
30 (001E hex)
Notice of days remaining (Unit: Days)
o+6
o+17
o+28
o+39
---
---
0 (0000 hex)
Not used.
o+7
o+18
o+29
o+40
o+8
o+19
o+30
o+41
Not used.
Top and valley hold
o+9
o+20
o+31
o+42
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
Hysteresis
o+10
o+21
o+32
o+43
---
---
0 (0000 hex)
Not used.
o+11
o+22
o+33
o+44
o+12
o+23
o+34
o+45
Not used.
Note
1. When specifying an expansion control/monitor area be sure that it does not
overlap with other areas that are being used. If areas overlap, the words
that are allocated may be overwritten, resulting in unexpected operation.
2. When specifying the first word in an expansion control/monitor area be
sure that the end of the memory area is not exceeded.
149
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 2-7
CIO Area Allocations
First word: word n. n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Resistance Thermometer Input
Unit to CPU Unit
Word
n
Bit
00
Data range
Process value LL (low
low limit) alarm
0, 1
01
Process value L (low
limit) alarm
0, 1
02
Process value H (high
limit) alarm
0, 1
03
Process value HH (high
high limit) alarm
0, 1
Process value LL (low
low limit) alarm
0, 1
05
Process value L (low
limit) alarm
0, 1
06
Process value H (high
limit) alarm
0, 1
07
Process value HH (high
high limit) alarm
0, 1
Process value LL (low
low limit) alarm
0, 1
09
Process value L (low
limit) alarm
0, 1
10
Process value H (high
limit) alarm
0, 1
11
Process value HH (high
high limit) alarm
0, 1
Process value LL (low
low limit) alarm
0, 1
13
Process value L (low
limit) alarm
0, 1
14
Process value H (high
limit) alarm
0, 1
15
Process value HH (high
high limit) alarm
0, 1
04
08
12
150
Name
Input No. 1
Input No. 2
Input No. 3
Input No. 4
Contents
0: Process value >
Set value
1: Process value ≤
Set value
0: Process value <
Set value
1: Process value ≥
Set value
Same as for input No.
1.
Same as for input No.
1.
Same as for input No.
1.
Section 2-7
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Direction
Resistance Thermometer Input
Unit to CPU Unit
Data range
Contents
n+1
Word
00 to 15 Input No. 1 process value
Bit
Name
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+2
00 to 15 Input No. 2 process value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
The present process
value is stored
according to the scaling set in the allocated words of the
DM Area.
n+3
00 to 15 Input No. 3 process value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+4
00 to 15 Input No. 4 process value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+5
00 to 15 Input No. 1 rate-of-change value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+6
00 to 15 Input No. 2 rate-of-change value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+7
00 to 15 Input No. 3 rate-of-change value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+8
00 to 15 Input No. 4 rate-of-change value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+9
00
Rate-of-change value L
(low limit) alarm
0, 1
0: Rate-of-change
value > Set value
1: Rate-of-change
value ≤ Set value
Rate-of-change value H
(high limit) alarm
0, 1
0: Rate-of-change
value < Set value
1: Rate-of-change
value ≥ Set value
Rate-of-change value L
(low limit) alarm
0, 1
Same as for input No.
1.
Rate-of-change value H
(high limit) alarm
0, 1
Rate-of-change value L
(low limit) alarm
0, 1
Rate-of-change value H
(high limit) alarm
0, 1
Rate-of-change value L
(low limit) alarm
0, 1
Rate-of-change value H
(high limit) alarm
0, 1
Input No. 1
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
The present rate of
change is stored
according to the scaling set in the allocated words of the
DM Area.
Same as for input No.
1.
Same as for input No.
1.
08
Input No. 1 input error
0, 1
09
Input No. 2 input error
0, 1
0: Normal
1: Disconnection
10
Input No. 3 input error
0, 1
Same as for input No.
1.
11
Input No. 4 input error
0, 1
Same as for input No.
1.
12
Not used.
0
---
13
Zero/span adjustment period end
0, 1
0: Adjustment
enabled
1: Adjustment ended
14
Zero/span adjustment period notice
0, 1
0: Adjustment
enabled
1: Notice period
15
Not used.
0
---
151
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 2-7
Expansion Control/Monitor Area Allocations
First word: word p. p = address specified in word o+1 in the area specified by
word o in the Expansion Setting Area.
Direction
Word
CPU Unit to p
Resistance
Thermome- p+1
ter Input Unit
Bit
00 to
15
00
Data range
Not used.
Contents
Not used.
Input No. 1 hold function selection
Input No. 2 hold function selection
0, 1
0: Peak and bottom
1: Top and valley
02
Input No. 3 hold function selection
0, 1
03
Input No. 4 hold function selection
0, 1
04 to
07
08
Not used.
0
Not used.
Input No. 1 hold start
0, 1
09
10
Input No. 2 hold start
Input No. 3 hold start
0, 1
0, 1
0: Do not hold.
1: Hold
11
12
Input No. 4 hold start
Input No. 1 hold value reset
0, 1
0, 1
13
14
Input No. 2 hold value reset
Input No. 3 hold value reset
0, 1
0, 1
15
00
Input No. 4 hold value reset
Input No. 1 zero/span adjustment
update bit
Input No. 2 zero/span adjustment
update bit
Input No. 3 zero/span adjustment
update bit
Input No. 4 zero/span adjustment
update bit
0, 1
0, 1
Not used.
0
01
p+2
01
02
03
04 to
15
152
Name
Not used.
0, 1
0, 1
0, 1
0, 1
0: Normal operation
1: Reset hold
value.
0: Normal operation
1: Update adjustment date
(Remains ON while
writing external
FROM.)
Not used.
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Direction
Word
Resistance p+3
Thermometer Input Unit
to CPU Unit
Bit
00
Name
Input Zero/span adjustment
No. 1 period end
01
Data range
0, 1
Section 2-7
Contents
0: Adjustment
enabled.
1: Adjustment
period end
Zero/span adjustment
period notice
Zero/span adjustment
period end
Zero/span adjustment
period notice
Zero/span adjustment
period end
0, 1
05
Zero/span adjustment
period notice
0, 1
06
Input Zero/span adjustment
No. 4 period end
0, 1
07
Zero/span adjustment
period notice
External FROM Error Flag
0, 1
0, 1
0: Normal operation
1: External FROM
error
09 to
15
Not used.
0
Not used.
p+4
00 to
15
Input Day of final adjustment
No. 1 date
0100 to 3100 (BCD)
p+5
00 to
15
Year and month of final
adjustment date
0001 to 9912 (BCD)
p+6
00 to
15
00 to
15
00 to
15
00 to
15
Input Day of final adjustment
No. 2 date
Year and month of final
adjustment date
0100 to 3100 (BCD)
Remains set to
FFFF if the zero/
span adjustment
bit has never been
ON.
Input Day of final adjustment
No. 3 date
Year and month of final
adjustment date
0100 to 3100 (BCD)
p+10
00 to
15
Input Day of final adjustment
No. 4 date
0100 to 3100 (BCD)
p+11
00 to
15
Year and month of final
adjustment date
0001 to 9912 (BCD)
p+12 to
p+15
00 to
15
02
Input
No. 2
03
04
08
p+7
p+8
p+9
Input
No. 3
Not used.
0, 1
0, 1
0, 1
0: Adjustment
enabled.
1: Notice period in
effect.
Remains set to 1 if
the zero/span
adjustment bit has
never been ON.
0001 to 9912 (BCD)
0001 to 9912 (BCD)
0
Not used.
153
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Direction
Word
Resistance p+16
Thermometer Input Unit
to CPU Unit
Bit
00 to
15
p+17
00 to
15
p+18
00 to
15
p+19
00 to
15
p+20
00 to
15
p+21
00 to
15
p+22
00 to
15
p+23
00 to
15
p+24 to
p+34
00 to
15
Name
Input Peak/top value
No. 1
Data range
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
Bottom/valley value
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
Input Peak/top value
No. 2
Bottom/valley value
Input Peak/top value
No. 3
Section 2-7
Contents
Counts the number of repetitions of
conditional operations set in the
Expansion Setting
Area.
The bottom or valley value is stored
according to the
scaling set in the
DM Area.
Same as for Input
No. 1.
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
Bottom/valley value
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
Input Peak/top value
No. 4
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
0 (0000 hex)
Bottom/valley value
Not used.
Not used.
Terminal Connection Diagram
No. 2 Resistance
thermometer input
Note
154
N.C.
B1
N.C.
B2
N.C.
B3
2A
B4
2B
B5
2b
B6
N.C.
B7
N.C.
B8
N.C.
B9
N.C.
B10
A1
N.C.
A2
1A
A3
1B
A4
1b
A5
3A
A6
3B
A7
3b
A8
N.C.
A9
4A
A10
4B
A11
4b
No. 1 Resistance
thermometer input
No. 3 Resistance
thermometer input
No. 4 Resistance
thermometer input
• Wire the same length to A, B, and b, so that the impedance will be the
same. In particular, do not short circuit between B and b at the terminal
block.
• For unused input terminals, short-circuit between A–B and B–b (e.g., A2–
A3 and A3–A4 for input No. 1) of the resistance thermometer inputs with
the lead wire.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 2-7
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
Terminal Block Diagram
A
Resistance
thermometer
B
A
Resistance
thermometer
B
A
Resistance
thermometer
B
A2
1B
A3
1b
A4
2A
B4
2B
B5
2b
B6
3A
A5
Constant current circuit
510 Ω
3b
A7
4A
A9
4B
A 10
4b
A11
Photocoupler
26 VDC
Constant current circuit
Amplifier
circuit
A/D
converter
Constant current circuit
Amplifier
circuit
A/D
converter
5 VDC
Isolation
circuit
Photocoupler
Reference resistance
510 Ω
A6
A/D
converter
Reference resistance
510 Ω
3B
Amplifier
circuit
Isolation
circuit
Isolation
circuit
Connector
Resistance
thermometer
B
1A
Input selector
A
Digital
circuits
Photocoupler
Reference resistance
Constant current circuit
510 Ω
Amplifier
circuit
A/D
converter
Isolation
circuit
Photocoupler
Reference resistance
Error Processing
Conversion Data Does Not Change.
Probable cause
The gain for span adjustment is
set to 0.
Remedy
Set the gain for span adjustment to a value other
than 0.
The minimum and maximum values for process value scaling are
either the same or are set
extremely low.
The sensor type, or process value
scaling is not set correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Set the minimum and maximum process value
scaling correctly.
Check and reset the sensor type, and the process value scaling settings.
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring. Check whether a disconnection has been
detected in the I/O Area.
Values are Not Converted as Intended.
Probable cause
Remedy
The sensor type, or process value
scaling is set incorrectly.
The zero/span adjustment data is
incorrect.
The resistance thermometer input
wiring is faulty.
Check and reset the sensor type, and the process value scaling settings.
Check and correct the zero/span adjustment settings.
Check and correct the input wiring.
155
CS1W-PTS12 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 2-7
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
Increase the number of values for calculating the
moving average in mean value processing.
The scaling value is greater than
Reduce the process value scaling.
the Unit’s resolution.
The input signal range is too small. Change to match the internal range.
156
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
2-8
Section 2-8
CS1W-PTS52 Isolated-type Resistance Thermometer Input
Unit (Pt100, JPt100)
Overview
The CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit provides
four direct platinum resistance thermometer inputs, and sends the data to the
CPU Unit each cycle. All inputs are isolated.
CS1W-PTS52
RUN
ERC
ERH
EDCBA
9876
543210
F
X101 0 X100
54321
F
EDCBA
MACH
No.
9876
System Configuration
CS1W-PTS52
Four platinum
resistance
thermometer inputs
(Pt100 (JIS, IEC),
JPt100)
Features
• Up to four platinum resistance thermometers can be connected for each
Unit (with four separate settings for temperature sensors and input
ranges).
• Pt100 (JIS, IEC), JPt100 can be selected.
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal. (Either binary or BCD data output can be selected.)
• Process value alarm (two alarms in internal memory and one external
alarm output for each input).
• Alarm ON-delay timer and hysteresis for process value.
• Zero/span adjustment capability during operation.
• Sensor error detection.
• Maximum or minimum process value can be specified for when a sensor
error is detected.
Model Information
Unit
classification
CS-series Special I/O Unit
Model number
CS1W-PTS52
Inputs
4
Input types
Platinum resistance thermometer Pt100 (JIS, IEC), JPt100
157
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-8
Block Diagram (Order of Processing)
The processing for the inputs is as shown in the following diagram.
CPU Unit
CPU Unit CIO Area
Process value
H, L
H, L
Process value alarm
External alarm output
Sensor error
I/O refresh
Isolated-type Resistance Thermometer Input Unit
Process value alarm
Output limit
Zero/span adjustment
Input calculations
Resistance thermometer type
Input range
A/D conversion
Resistance thermometer
Specifications
Item
Specifications
Model
CS1W-PTS52
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
Maximum number of Units
Unit numbers
80 (within the allowable current consumption and power consumption range)
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
158
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Areas for data
exchange with
CPU Unit
Item
Special I/O Unit
Area
Section 2-8
Specifications
10 words/Unit
Resistance Thermometer Input Unit to CPU Unit:
All process values, process value alarms (L, H), conversion data enabled flag, sensor
errors.
DM Area words 100 words/Unit
allocated to
CPU Unit to Resistance Thermometer Input Unit:
Special I/O Units Temperature sensor type, input range (user set), process value alarm setting (L, H),
zero/span adjustment value.
Number of temperature sensor
4
inputs
Temperature sensor type
Data storage in the CIO Area
Accuracy (25°C)
Temperature characteristics
Sensing method
Input detection current
Pt100 (JIS, IEC), JPt100
The same sensor type, input range, and scaling to industrial units are used by all
inputs.
The actual process data in the input range is stored in four digits hexadecimal (binary
or BCD values) in the allocated words in the CIO Area.
±0.3% of PV or ±0.8°C, whichever is greater, ±1 digit max.
(±0.3% of PV or ±1.6°F, whichever is greater, ±1 digit max.)
PV: Process value data
Refer to Temperature Characteristics According to Platinum Resistance Thermometer
Type on page 161.
3-wire method
1 mA
Influence of conductor resistance 0.4°C/Ω max.
Conversion period
250 ms/4 inputs
Warmup time
Maximum time to store data in
CPU Unit
Sensor error detection
10 min
Conversion period + one CPU Unit cycle
Function
Process value
alarm
Process value 2-point alarm (H, L), alarm hysteresis, and ON-delay timer (0 to 60 s
are available).
External alarm
outputs
NPN outputs (with short-circuit protection)
External power supply voltage: 20.4 to 26.4 V DC
Max. switching capacity: 100 mA (for one output)
Leakage current: 0.3 mA max.
Residual voltage: 3 V max.
Detects sensor error at each input and turns ON the Sensor error Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a sensor error occurs can be specified. (High: +20 digit of set input range; low: –20 digit of set input range)
Isolation
Between inputs and PLC signal: Transformer for power supply and photocoupler for
signals
Between each input: Transformer for power supply and photocoupler for signals
Insulation resistance
20 MΩ max. (at 500 V DC).
Between all output and NC terminals and external AC terminals (Power Supply Unit)
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and all output terminals
Between all external DC terminals (input, output, and NC terminals) and FG plate
Between all input and output terminals and all NC terminals
159
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-8
Item
Dielectric strength
Specifications
Between all output and NC terminals and external AC terminals (Power Supply Unit)
2,000 V AC, 50/60 Hz 1 min., detection current: 1 mA
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and all output terminals
Between all external DC terminals (input, output, and NC terminals) and FG plate
1,000 V AC, 50/60 Hz 1 min., detection current: 1 mA
Between all channels
500 VAC, 50/60 Hz 1 min., detection current: 1 mA
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Seven LED indicators on front panel (for normal operation, errors detected at the Unit,
errors detected at the CPU Unit, and four indicators for external alarm outputs.)
Effect on CPU Unit cycle time
Current consumption
0.4 ms
5 V DC at 250 mA max
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
450 g max.
Sensor Type and Input Range
The Platinum Resistance Thermometer type and input range are set in the
allocated words in the DM Area for every four inputs.
The measurable data range is ±20 digits wider than the sensor input range.
Setting
0
°C
Input
Pt100:
−200.0 to
650.0°C
(−300.0 to
1200.0°F)
1
JPt100:
−200.0 to
650.0°C
(−300.0 to
1200.0°F)
2 to 9 Do not set.
16-bit binary
BCD
[email protected]@@
Leftmost bit
indicates
indicates
minus sign. minus sign.
°F
16-bit binary
F830 to FFFF to
1964
(−200.0 to
−0.1 to 650.0)
F999 to 6500 A000 to 6500 F448 to FFFF to
(See note 2.) (−200.0 to
2EE0
(−99.9 to
650.0)
(−300.0 to
650.0)
−0.1 to 1200.0)
BCD
Leftmost 4 Leftmost bit
bits (bits 12
(bit 15)
to 15)
indicates
indicate
minus sign.
minus sign.
F999 to 9999 B000 to 7999
(See note 2.) (See note 2.)
(−99.9 to
(−300.0 to
999.9)
799.9)
F830 to FFFF to
1964
(−200.0 to
−0.1 to 650.0)
F999 to 6500 A000 to 6500 F448 to FFFF to
(See note 2.) (−200.0 to
2EE0
(−99.9 to
650.0)
(−300.0 to
650.0)
−0.1 to 1200.0)
F999 to 9999
(See note 2.)
(−99.9 to
999.9)
B000 to 7999
(See note 2.)
(−300.0 to
799.9)
Do not set.
Note
1. If the indication range is exceeded, a sensor error will occur and the sensor
error bit will turn ON. The process value will be clamped at the lower or upper limit of the indication range, depending on the setting for data direction
at sensor error.
2. The indicator range for BCD display will be clamped at the lower (or upper)
limit in the region between the lower (or upper) limit of the setting range
and the point where a sensor error occurs.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost 4 bits (bits
12 to 15): Lower limit = −99.9, Upper limit = 999.9.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost bit (bit 15):
Lower limit = −799.9, Upper limit = 799.9.
160
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-8
Temperature Characteristics According to Platinum Resistance Thermometer Type
Platinum Resistance
Thermometer
Temperature range
Set value error when
ambient temperature
changes by 1°C
Pt100
−200 to 200°C
200 to 650°C
±0.06°C
285 ppm of PV
JPt100
−200 to 200°C
200 to 650°C
±0.06°C
285 ppm of PV
The measured temperature error is calculated as shown in the following
example.
Item
Details
Ambient temperature
Platinum Resistance
Thermometer
30°C
Pt100
Measured temperature
(PV)
500°C
Reference accuracy
(25°C)
±0.3°C of PV or ±0.8°C, whichever is greater, ±1 digit.
In this example, ±1.5°C.
Temperature characteris- 200 to 650°C: 285 ppm of PV.
tics
In this example, 285 ppm × 500°C = 0.143°C.
Change in ambient tem- 5°C (25 to 30°C)
perature
Overall accuracy =
Reference accuracy + Temperature characteristic × Change in ambient
temperature = ±1.5°C + ±0.143°C × 5 = Approx. ± 2.2°C ±1 digit.
DM Area Allocations
First word: word m. m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
m
Decimal
Default
Data contents
Hexadecimal
12345, 0
3039, 0000 hex 0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM Area words m+1 to m+93.
• 12345 (3039 hex): The data in words m+1
to m+93 is transferred from the Resistance Thermometer Input Unit to the CPU
Unit. When the transfer is completed, the
value will become 0000 hex.
• Other than 12345 (3039 hex) (such as
0000 hex): The data in the allocated
words of DM Area is transferred from the
CPU Unit to the Resistance Thermometer
Input Unit.
0 to 34
0000 to 0022
hex
Address of Data Range Error (See note 1.)
Display parameter
m+1
0
(0000 hex)
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m+6
m + 10
m + 14
m+3
m+7
m + 11
m + 15
Low to high limit for all sensors
6500
(1964 hex)
Process value H (high limit) alarm setting
−2000
(F830 hex)
Process value L (low limit) alarm setting
Span adjustment value
161
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
DM Area address
Input
No. 1
m+4
Input
No. 2
m+8
Data range
Input
No. 3
Input
No. 4
m + 12
m + 16
Decimal
Default
Section 2-8
Data contents
Hexadecimal
0 to 9999
0000 to 270F
hex
1000
(03E8 hex)
m+35 contains 0: Set value × 0.001
0 to 32000
0000 to 7D00
hex
10000
(2710 hex)
m+35 contains 1: Set value × 0.0001
–9999 to 9999
D8F1 to 270F
hex
0
(0000 hex)
Set value × 0.1
Zero adjustment value
m+5
m+9
m + 13
m + 17
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Resistance Thermometer
Input Unit if word m contains other than 12345 when the PLC is turned ON or the Resistance Thermometer Input Unit is restarted.
Operation settings (See note 2.)
m + 18
(See note 2.)
(See note 2.)
0
(0000 hex)
00 to 03: Temperature unit (°C or °F)
04 to 07: Data display (binary or BCD)
08 to 11: Minus sign display format for BCD
display
12 to 15: Data direction at sensor error
Sensor type
m + 19
m + 23
m + 27
m + 31
0 to 1
0000, 0001 hex 0 (0000 hex)
0: Pt100; 1: JPt100
m + 20
m + 24
m + 28
m + 32
0, 1
0000, 0001 hex 0
(0000 hex)
Select either high limit or low limit alarm output.
0: High limit alarm; 1: Low limit alarm
m + 21
m + 25
m + 29
m + 33
0 to 9999
0000 to 270F
hex
0
(0000 hex)
Set value × 0.1
m + 22
m + 26
m + 30
m + 34
0 to 60
0000 to 003C
hex
0
(0000 hex)
Unit: s
0, 1
0000, 0001 hex 1 (See note 3.)
External alarm output mode
Alarm hysteresis
Alarm ON-delay time
m + 35
Note
Span adjustment mode
0: 1/1,000
1: 1/10,000
1. The ERC indicator on the Unit’s front panel will light if an out-of-range setting is made in either Setting Group 1 or 2. The offset from word m to the
first word containing the out-of-range error will be stored as the Address of
Data Range Error in the DM Area in four digits hexadecimal.
2. The operation settings are shown in the following table.
Word
m+18
Bits
Description
Settings
00
Temperature unit setting
0: °C
1: °F
04
Data format
0: Binary (Negative values are given as 2’s complements).
1: BCD
08
Minus sign display format for BCD display 0: “F” used to indicate the minus sign.
1: Leftmost bit used to indicate the minus sign.
The setting is disabled if bits 04 to 07 are set to 0.
Data direction at sensor error
0: Goes to upper limit at sensor error
1: Goes to lower limit at sensor error
12
Example:
For a temperature in degrees Celsius (°C), a binary data format, and a data
direction at sensor error of “lower limit,” word m+18 contains 1000.
3. Indicates the value after transferring the default value (set when 12345 is
written to word m).
162
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-8
CIO Area Allocations
First word: word n. n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Resistance Thermometer Input
Unit to CPU Unit
Word
n
Bit
00
Name
Input No. 1
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
Data range
Contents
Process value L (low
limit) alarm
0, 1
0: Process value >
Set value
1: Process value ≤
Set value
Process value H (high
limit) alarm
0, 1
0: Process value <
Set value
1: Process value ≥
Set value
Process value L (low
limit) alarm
0, 1
Same as for input No.
1.
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
0, 1
Process value
Depends on type of input. Stores data in the
data range specified
for each input type
±20 digits.
Sensor error
0, 1
08 to 15 Not used.
n+1
00 to 15 Input No. 1
n+2
00 to 15 Input No. 2
n+3
00 to 15 Input No. 3
n+4
00 to 15 Input No. 4
n+5
Not used.
n+6
n+7
n+8
Resistance Thermometer Input
Unit to CPU Unit
n+9
00
Input No. 1
01
Input No. 2
0, 1
02
Input No. 3
0, 1
03
Input No. 4
0, 1
0: Normal
1: Error
04 to 14 Not used.
15
15
Conversion data
0, 1
enabled flag (See note.)
0: Data disabled
1: Data enabled
Note The Conversion Data Enabled Flag remains OFF after the PLC is turned ON
or the Unit is restarted until the AD conversion data becomes stable (approximately 2 to 4 s), then is ON during operation.
163
Section 2-8
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Terminal Connection Diagram
No. 2
Platinum-resistance
Thermometer input
No. 4
Platinum-resistance
Thermometer input
External alarm outputs
L
L
Note
2b
B1
2B
B2
2A
B3
4b
B4
4B
B5
4A
B6
ALM2
B7
ALM4
B8
0V
B9
N.C.
B10
A1
N.C
A2
1b
A3
1B
A4
1A
A5
3b
A6
3B
No. 1
Platinum-resistance
Thermometer input
No. 3
Platinum-resistance
Thermometer input
A7
3A
A8
ALM1
L
A9
ALM3
L
A10
24V
A11
N.C.
External alarm outputs
• Wire the same length to A, B, and b, so that the impedance will be the
same. In particular, do not short circuit between B and b at the terminal
block.
• For unused input terminals, connect approximately 100 Ω between the
platinum-resistance thermometer input terminals A and B and short terminals B and b with a lead wire. If resistance is not connected between terminals A and B and terminals B and b are shorted or if terminals A and B
and terminals B and b are left open, the alarm output will turn ON and the
ALM indicator will light.
• Do not connect anything to NC terminals. Do not use NC terminals as
relay terminals.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
Terminal Block Diagram
1A
A4
B
A
1B
1b
A3
A2
2A
B3
Resistance thermometer
B
A
2B
2b
B2
B1
3A
A7
Resistance thermometer
B
A
3B
3b
A6
A5
4A
B6
Resistance thermometer
B
164
4B
4b
B5
B4
Amplifier
circuit
Amplifier
circuit
Amplifier
circuit
Amplifier
circuit
Double
integral
A/D
Double
integral
A/D
Double
integral
A/D
Double
integral
A/D
Reference
power supply
Photocoupler
Reference
power supply
Photocoupler
5 V DC
Reference
power supply
Photocoupler
Reference
power supply
Photocoupler
Digital circuits
Connector
A
Resistance thermometer
Isolation circuit
■ Input Circuit
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-8
■ Output Circuit
L
A8
ALM1
L
B7
ALM2
L
A9
ALM3
L
B8
ALM4
Internal Circuit
A10
24V
B9
0V
Output Display
LED
Error Processing
Conversion Data Does Not Change.
Probable cause
The gain for span adjustment is
set to 0.
Remedy
Set the gain for span adjustment to a value other
than 0.
The sensor type is not set correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Check and reset the sensor type.
Check whether the resistance has changed.
Check for faulty or disconnected wiring. Check
whether a sensor error has been detected in the
I/O Area.
Values are Not Converted as Intended.
Probable cause
Remedy
The sensor type is set incorrectly.
The zero/span adjustment data is
incorrect.
Check and reset the sensor type.
Check and correct the zero/span adjustment settings.
165
CS1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-8
Probable cause
Remedy
The platinum-resistance thermom- Check and correct the input wiring.
eter input wiring is faulty.
The compensating conductor is
Use a thicker compensating conductor.
too long and measurements are
being affected by conductor resistance.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
166
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
2-9
Section 2-9
CS1W-PTS56 Isolated-type Resistance Thermometer Input
Unit (Pt100, JPt100)
Overview
The CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit provides
8 direct platinum resistance thermometer inputs, and sends the data to the
CPU Unit each cycle. All inputs are isolated.
CS1W-PTS56
RUN
ERC
ERH
54321
EDCBA
543210
F
X101 0 X100
9876
F
EDCBA
MACH
No.
9876
System Configuration
CS1W-PTS56
8 platinum
resistance
thermometer inputs
(Pt100 (JIS, IEC),
JPt100)
Features
• Up to 8 platinum resistance thermometers can be connected for each Unit
(with 8 separate settings for temperature sensors and input ranges).
• Pt100 (JIS, IEC), JPt100 can be selected.
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal. (Either binary or BCD data output can be selected.)
• Process value alarms (Two internal alarms per input can be output to
memory and two alarms per input can be output to specified I/O memory
area addresses using indirect address specifications).
• Alarm ON-delay timer and hysteresis for process value.
• Zero/span adjustment capability during operation.
• Sensor error detection.
• Maximum or minimum process value can be specified for when a sensor
error is detected.
Model Information
Unit
classification
CS-series Special I/O Unit
Model number
CS1W-PTS56
Inputs
8
Input types
Platinum resistance thermometer Pt100 (JIS, IEC), JPt100
167
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-9
Block Diagram (Order of Processing)
The processing for the inputs is as shown in the following diagram.
CPU Unit
Expansion Setting Area
CPU Unit CIO Area
H, L
H, L
Process value
Process value alarm
Sensor error
Alarm output
I/O refresh
Isolated-type Resistance Thermometer Input Unit
Process value alarm
When input disconnection is detected
Sensor error check
Zero/span adjustment
Input calculations
Resistance thermometer type
Input range
A/D conversion
Resistance thermometer
Specifications
Item
Specifications
Model
Applicable PLC
CS1W-PTS56
CS Series
Unit classification
Mounting position
CS-series Special I/O Unit
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
Special I/O Unit
Area
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Resistance Thermometer Input Unit to CPU Unit:
All process values, process value alarms (L, H), conversion data enabled flag, sensor
errors.
DM Area words 100 words/Unit
allocated to
CPU Unit to Resistance Thermometer Input Unit:
Special I/O Units Temperature sensor type, input range (user set), process value alarm setting (L, H),
zero/span adjustment value.
Expansion Set- 1 word/Unit
ting Area
CPU Unit to Resistance Thermometer Input Unit:
Process Value Alarm
168
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Item
Number of temperature sensor
inputs
Temperature sensor type
Data storage in the CIO Area
Accuracy (25°C)
Temperature characteristics
Section 2-9
Specifications
8
Pt100 (JIS, IEC), JPt100
The same sensor type, input range, and scaling to industrial units are used by all
inputs.
The actual process data in the input range is stored in four digits hexadecimal (binary
or BCD values) in the allocated words in the CIO Area.
±0.3% of PV or ±0.8°C, whichever is greater, ±1 digit max.
(±0.3% of PV or ±1.6°F, whichever is greater, ±1 digit max.)
PV: Process value data
Refer to Temperature Characteristics According to Platinum Resistance Thermometer
Type on page 161.
Sensing method
3-wire method
Influence of conductor resistance 0.4°C/Ω max.
Input detection current
Warmup time
0.5 mA
10 min
Conversion period
Maximum time to store data in
CPU Unit
Sensor error detection
250 ms/8 inputs
Conversion period + one CPU Unit cycle
Function
Process value 2-point alarm (H, L), alarm hysteresis, and ON-delay timer (0 to 60 s
are available).
Two alarms per input (H, L) can be output to addresses in the CIO Area specified in
the Expansion Setting Area.
Between inputs and PLC signal: Transformer for power supply and photocoupler for
signals
Between each input: Transformer for power supply and photocoupler for signals
Process value
alarm
Isolation
Detects sensor error at each input and turns ON the Sensor error Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a sensor error occurs can be specified. (High: +20 digit of set input range; low: –20 digit of set input range)
Insulation resistance
20 MΩ max. (at 500 V DC).
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and FG plate
Dielectric strength
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and FG plate
1,000 V AC, 50/60 Hz 1 min., detection current: 1 mA
Between all channels
500 VAC, 50/60 Hz 1 min., detection current: 1 mA
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Three LED indicators on front panel (for normal operation, errors detected at the Unit,
errors detected at the CPU Unit)
0.4 ms
Effect on CPU Unit cycle time
Current consumption
5 V DC at 180 mA max.
26 V DC at 60 mA max.
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
450 g max.
169
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-9
Sensor Type and Input Range
The Platinum Resistance Thermometer type and input range are set in the
allocated words in the DM Area for every four inputs.
The measurable data range is ±20 digits wider than the sensor input range.
Setting
°C
Input
16-bit binary
°F
BCD
16-bit binary
[email protected]@@
Leftmost bit
indicates
indicates
minus sign. minus sign.
0
Pt100:
−200.0 to 650.0°C
(−300.0 to
1200.0°F)
F830 to FFFF to
1964
(−200.0 to
−0.1 to 650.0)
F999 to 6500 A000 to 6500 F448 to FFFF to
(See note 2.) (−200.0 to
2EE0
(−99.9 to
650.0)
(−300.0 to
650.0)
−0.1 to 1200.0)
JPt100:
−200.0 to 650.0°C
(−300.0 to
1200.0°F)
2 to 9 Do not set.
F830 to FFFF to
1964
(−200.0 to
−0.1 to 650.0)
F999 to 6500 A000 to 6500 F448 to FFFF to
(See note 2.) (−200.0 to
2EE0
(−99.9 to
650.0)
(−300.0 to
650.0)
−0.1 to 1200.0)
Do not set.
1
Note
BCD
Leftmost 4
bits (bits 12
to 15)
indicate
minus sign.
F999 to 9999
(See note 2.)
(−99.9 to
999.9)
B000 to 7999
(See note 2.)
(−300.0 to
799.9)
F999 to 9999
(See note 2.)
(−99.9 to
999.9)
B000 to 7999
(See note 2.)
(−300.0 to
799.9)
Leftmost bit
(bit 15)
indicates
minus sign.
1. If the indication range is exceeded, a sensor error will occur and the sensor
error bit will turn ON. The process value will be clamped at the lower or upper limit of the indication range, depending on the setting for data direction
at sensor error.
2. The indicator range for BCD display will be clamped at the lower (or upper)
limit in the region between the lower (or upper) limit of the setting range
and the point where a sensor error occurs.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost 4 bits (bits
12 to 15): Lower limit = −99.9, Upper limit = 999.9.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost bit (bit 15):
Lower limit = −799.9, Upper limit = 799.9.
Temperature Characteristics According to Platinum Resistance Thermometer Type
Platinum Resistance
Thermometer
Temperature range
Set value error when
ambient temperature
changes by 1°C
Pt100
−200 to 200°C
200 to 650°C
±0.06°C
285 ppm of PV
JPt100
−200 to 200°C
200 to 650°C
±0.06°C
285 ppm of PV
The measured temperature error is calculated as shown in the following
example.
Item
Details
Ambient temperature
Platinum Resistance
Thermometer
Measured temperature
(PV)
30°C
Pt100
Reference accuracy
(25°C)
±0.3°C of PV or ±0.8°C, whichever is greater, ±1 digit.
In this example, ±1.5°C.
500°C
Temperature characteris- 200 to 650°C: 285 ppm of PV.
tics
In this example, 285 ppm × 500°C = 0.143°C.
Change in ambient temperature
170
5°C (25 to 30°C)
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-9
Overall accuracy =
Reference accuracy + Temperature characteristic × Change in ambient
temperature = ±1.5°C + ±0.143°C × 5 = Approx. ± 2.2°C ±1 digit.
DM Area Allocations
First word: word m. m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input Input Input Input Input Input Input Input
No. 1 No. 2 No. 3 No. 4 No. 5 No. 6 No. 7 No. 8
m
Data range
Decimal
Default
Data contents
Hexadecimal
12345, 0
3039,
0000 hex
0000 hex
Default block read command
Specifies the direction of data transfer
when the PLC is turned ON or the Unit
is restarted for DM Area words m+1 to
m+60.
• 12345 (3039 hex): The data in words
m+1 to m+60 is transferred from the
Resistance Thermometer Input Unit
to the CPU Unit. When the transfer is
completed, the value will become
0000 hex.
• Other than 12345 (3039 hex) (such
as 0000 hex): The data in the allocated words of DM Area is transferred from the CPU Unit to the
Resistance Thermometer Input Unit.
0 to 59
0000 to
003B hex
0
Address of Data Range Error (See
(0000 hex) note 1.)
Display parameter
m+1
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m+6
m+10 m+14 m+18 m+22 m+26 m+30 Low to high limit for all
sensors
6500
Process value H (high limit) alarm set(1964 hex) ting
m+3
m+7
m+11 m+15 m+19 m+23 m+27 m+31
−2000
(F830
hex)
m+4
m+8
m+12 m+16 m+20 m+24 m+28 m+32 0 to 32000 0000 to
7D00 hex
10000
Set value × 0.0001
(2710 hex)
m+5
m+9
m+13 m+17 m+21 m+25 m+29 m+33 –9999 to
9999
0
Set value × 0.1
(0000 hex)
Process value L (low limit) alarm setting
Span adjustment value
Zero adjustment value
D8F1 to
270F hex
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Resistance Thermometer
Input Unit if word m contains other than 12345 when the PLC is turned ON or the Resistance Thermometer Input Unit is restarted.
Operation settings (See note 2.)
(See note
2.)
0
00 to 03: Temperature unit (°C or °F)
(0000 hex) 04 to 07: Data display (binary or BCD)
08 to 11: Minus sign display format for
BCD display
12 to 15: Data direction at sensor error
m+35 m+38 m+41 m+44 m+47 m+50 m+53 m+56 0, 1, 15
0000,
0001,
000F hex
0 (0000
hex)
m+36 m+39 m+42 m+45 m+48 m+51 m+54 m+57 0 to 9999
0000 to
270F hex
0
Set value × 0.1
(0000 hex)
m+37 m+40 m+43 m+46 m+49 m+52 m+55 m+58 0 to 60
0000 to
003C hex
0
Unit: s
(0000 hex)
m +34
(See note
2.)
Sensor type
0: Pt100; 1: JPt100, F: Not used
Alarm hysteresis
Alarm ON-delay time
Expansion Setting Area enable
m+59
0, 1
0000,
0001 hex
0
0: Disabled
(0000 hex) 1: Enabled
171
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
DM Area address
Data range
Input Input Input Input Input Input Input Input
No. 1 No. 2 No. 3 No. 4 No. 5 No. 6 No. 7 No. 8
Decimal
Hexadecimal
0 to 6143
0000 to
17FF hex
Default
Section 2-9
Data contents
Expansion Setting Area address
m+60
(See note 3)
Note
0
CIO area (fixed)
(0000 hex) Number of words.
1. The ERC indicator on the Unit’s front panel will light if an out-of-range setting is made in either Setting Group 1 or 2. The offset from word m to the
first word containing the out-of-range error will be stored as the Address of
Data Range Error in the DM Area in four digits hexadecimal.
2. The operation settings are shown in the following table.
3. A range check is not performed for the Expansion Setting Area address set
in word m+60. Be sure to check this address before starting actual operation.
Word
m+34
00
Bits
Description
Temperature unit setting
04
Data format
08
12
Settings
0: °C
1: °F
0: Binary (Negative values are given as 2’s complements).
1: BCD
Minus sign display format for BCD display 0: “F” used to indicate the minus sign.
1: Leftmost bit used to indicate the minus sign.
The setting is disabled if bits 04 to 07 are set to 0.
Data direction at sensor error
0: Goes to upper limit at sensor error
1: Goes to lower limit at sensor error
Example: For a temperature in degrees Celsius (°C), a binary data format,
and a data direction at sensor error of “lower limit,” word m+18 contains 1000.
172
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-9
Expansion Setting Area
First word: word o. (o = address specified in word m+60 in the DM Area)
Direction
Resistance
Thermometer
Input Unit to
CPU Unit
Word
o
Bit
00
Name
Input No. 1
01
02
Input No. 2
03
04
05
06
07
08
Input No. 5
Input No. 6
13
14
15
0, 1
0, 1
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Input No. 8
Same as for input No. 1.
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Input No. 7
0, 1
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
11
12
0: Process value < Set value
1: Process value ≥ Set value
Process value
H (high limit)
alarm
09
10
Process value
H (high limit)
alarm
Process value
H (high limit)
alarm
Input No. 4
Contents
0: Process value > Set value
1: Process value ≤ Set value
Process value
H (high limit)
alarm
Input No. 3
Data range
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
0, 1
Note If either of the following changes is made for the Expansion Setting Area for
the CS1W-PTS55/PTS56/PDC55, the previous data will be left in the Expansion Setting Area even after the change has been made.
Clear the previous data when changing either of these settings.
• The Expansion Setting Area Enable setting is changed from “enabled” to
“disabled.”
• The Expansion Setting Area Address setting is changed while the Expansion Setting Area Enable setting is set to “enabled.”
173
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-9
CIO Area Allocations
First word: word n. n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Resistance Thermometer Input
Unit to CPU Unit
Word
n
Bit
00
Name
Input No. 1
Contents
0, 1
0: Process value >
Set value
1: Process value ≤
Set value
Process value H (high
limit) alarm
0, 1
0: Process value <
Set value
1: Process value ≥
Set value
Process value L (low
limit) alarm
0, 1
Same as for input No.
1.
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
15
Process value H (high
limit) alarm
0, 1
Process value
Depends on type of input. Stores data in the
data range specified
for each input type
±20 digits.
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
08
Input No. 5
09
10
Input No. 6
11
12
Input No. 7
13
14
Resistance Thermometer Input
Unit to CPU Unit
Data range
Process value L (low
limit) alarm
Input No. 8
n+1
00 to 15 Input No. 1
n+2
00 to 15 Input No. 2
n+3
00 to 15 Input No. 3
n+4
00 to 15 Input No. 4
n+5
00 to 15 Input No. 5
n+6
00 to 15 Input No. 6
n+7
00 to 15 Input No. 7
n+8
00 to 15 Input No. 8
n+9
00
Input No. 1
01
Input No. 2
0, 1
02
Input No. 3
0, 1
03
Input No. 4
0, 1
04
Input No. 5
0, 1
05
Input No. 6
0, 1
06
Input No. 7
0, 1
07
Input No. 8
0, 1
Sensor error
0, 1
0: Normal
1: Error
08 to 14 Not used
15
15
Conversion data
0, 1
enabled flag (See note.)
0: Data disabled
1: Data enabled
Note The Conversion Data Enabled Flag remains OFF after the PLC is turned ON
or the Unit is restarted until the AD conversion data becomes stable (approximately 2 to 4 s), then is ON during operation.
174
Section 2-9
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Terminal Connection Diagram
No. 1
Platinum-resistance
Thermometer input
1A
B1
1B
B2
1b
B3
No. 3
Platinum-resistance
Thermometer input
3A
B4
3B
B5
3b
B6
5A
B7
5B
B8
No. 5
Platinum-resistance
Thermometer input
No. 7
Platinum-resistance
Thermometer input
Note
5b
B9
7A
B10
7B
B11
7b
B12
A1
2A
A2
2B
A3
2b
A4
4A
A5
4B
A6
4b
A7
6A
A8
6B
A9
6b
A10
8A
A11
8B
A12
8b
No. 2
Platinum-resistance
Thermometer input
No. 4
Platinum-resistance
Thermometer input
No. 6
Platinum-resistance
Thermometer input
No. 8
Platinum-resistance
Thermometer input
• Wire the same length to A, B, and b, so that the impedance will be the
same. In particular, do not short circuit between B and b at the terminal
block.
• Set the Sensor type in Setting Group 2 in the DM Area to “Not used” for
any thermocouple inputs that are not used.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
Terminal Block Diagram
■ Input Circuit
1A
B1
B
1B
1b
B2
B3
Amplifier
circuit
Double
integral
A/D
Reference
power supply
No. 2 input
Reference power supply
Photocoupler
No. 3 input
Reference power supply
A
4A
A5
Resistance thermometer
B
4B
4b
A6
A7
Amplifier
circuit
Double
integral
A/D
Isolation circuit
A
Resistance thermometer
24 V DC
Reference
power supply
5 V DC
Photocoupler
No. 2 input
Photocoupler
5A
B7
Resistance thermometer
B
5B
5b
B8
B9
Amplifier
circuit
Double
integral
A/D
Reference
power supply
Photocoupler
Digital circuits
Connector
No. 3 input
Photocoupler
A
No. 6 input
Photocoupler
No. 7 input
Photocoupler
8A
A10
B
8B
8b
A11
A12
Amplifier
circuit
Double
integral
A/D
Reference
power supply
Photocoupler
No. 6 input
Reference power supply
No. 7 input
Reference power supply
Isolation circuit
A
Resistance thermometer
175
CS1W-PTS56 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Section 2-9
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
The sensor type is not set correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Set the gain for span adjustment to a value other
than 0.
Check and reset the sensor type.
Check whether the resistance has changed.
Check for faulty or disconnected wiring. Check
whether a sensor error has been detected in the
I/O Area.
Values are Not Converted as Intended.
Probable cause
The sensor type, or input range is
set incorrectly.
The zero/span adjustment data is
incorrect.
The platinum-resistance thermometer input wiring is faulty.
Remedy
Check and reset the sensor type, input range,
and the process value scaling settings.
Check and correct the zero/span adjustment settings.
Check and correct the input wiring.
The compensating conductor is
Use a thicker compensating conductor.
too long and measurements are
being affected by conductor resistance.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
176
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
2-10 CS1W-PTW01 2-Wire Transmitter Input Unit
Overview
The CS1W-PTW01 2-Wire Transmitter Input Unit provides up to four inputs for
unified signals (4 to 20 mA) from a transmitter, with no external DC power
supply, and sends the data to the CPU Unit each cycle.
CS1W-PTW01
System Configuration
CS1W-PTW01
Four 2-wire transmitter inputs
(4 to 20 mA, 1 to 5 V)
Features
• Up to four inputs can be connected per Unit for unified signals from a 2wire transmitter, such as pressure, differential pressure, etc.
• A built-in power supply (24 V DC) for a 2-wire transmitter for each input
eliminates the need for an external power supply.
• Inputs of 4 to 20 mA and 1 to 5 V, are possible with no need to provide the
usual DC power supply.
• Scaling values are sent to the CPU Unit in four digits hexadecimal.
• Square root function.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Input error detection.
• Zero/span adjustment capability during operation.
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PTW01
Inputs
4
Input types
From transmitter: unified signal (4 to 20 mA) or 4 to 20 mA,
1 to 5 V
177
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
Block Diagram (Order of Processing)
The processing for the four inputs is as shown in the following diagram.
CPU Unit CIO Area
HH, H, L, LL
Process value
Process value
alarm
H, L
Rate-of-change
value
Rate-of-change
alarm
Input error alarm
I/O refresh
Isolated-type 2-Wire Transmitter Input Unit
Process value
alarm
Rate-of-change
alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
Output limit: −15% to +115%
Square root
Input error check
Zero/span adjustment
Input error: Less than −17%
or more than 112%
Process value scaling
Input calculations
Input range
A/D conversion, moving average
4 to 20 mA, 1 to 5 V
2-wire transmitter
or DC signal sensor
Specifications
Item
Specifications
Model
Applicable PLC
CS1W-PTW01
CS Series
Unit classification
Mounting position
Maximum number of Units
CS-series Special I/O Unit
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Unit numbers
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
178
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
Item
Areas for data Special I/O Unit
exchange with Area
CPU Unit
Specifications
10 words/Unit
2-Wire Transmitter Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rate-ofchange alarms (L, H), input errors
DM Area words 100 words/Unit
allocated to
CPU Unit to 2-Wire Transmitter Input Unit:
Special I/O Units Sensor type, scaling of process value data to be stored in allocated words in CIO area,
square root function enable, rate-of-change value range, rate-of-change scaling, number of items for moving average, process value alarm setting (LL, L, H, HH), rate-ofchange alarm setting (L, H), zero/span adjustment value, etc.
Number of inputs
Sensor type
4
Unified signal from transmitter (4 to
20 mA), 4 to 20 mA, 1 to 5 V
User-defined scaling in industrial Scaling required for 4 to 20 mA or 1 to 5 V.
units
(Any minimum and maximum values can
be set.) (4 inputs set separately.)
Data storage in the CIO Area
The value derived from carrying out the
following processing in order of the process value data is stored in four digits
hexadecimal (binary values) in the allocated words in the CIO Area.
1) Mean value processing → 2) Scaling →
3) Zero/span adjustment → 4) Square root
extraction → 5) Output limits
Accuracy (25°C)
±0.2% of full scale
Temperature coefficient
Resolution
±0.015%/°C of full scale
1/4,096 of full scale
Sensor type and scaling to industrial units
are separate for each of the 4 inputs.
Note Sensor type and scaling to industrial
units are set in the DM Area.
Example:
Input signal type: 4 to 20 mA from 2-wire
transmitter; industrial unit scaling: 0 to
500 m3/h (after square root extraction).
DM Area settings are as follows:
Input signal type: 0 (0000 hex)
Industrial unit maximum value stored: 500
(01F4 hex)
Industrial unit minimum value stored:
0 (0000 hex)
Input signal range
–15 to 115%
Power supply for 2-wire transmit- Output voltage: 24 V DC ±15% for each input (without load)
ter
Current capacity: 22 mA max. for each input
Short-circuit control current: 22 to 27 mA
Allowable short-circuit time:
Ambient temperature less than 40°C: No limit
Ambient temperature 40 to 55°C: 10 min or less
Input impedance
4 to 20 mA for 2-wire transmitter: 250 Ω; 4 to 20 mA: 250 Ω; 1 to 5 V: 1 MΩ min.
Warmup time
Response time
10 min
0.5 s (travel time from input 0% to 90%, for step input)
Conversion period
Maximum time to store data in
CPU Unit
Input error detection
100 ms/4 inputs
Conversion period + one CPU Unit cycle
Input disconnection overrange
time
Approx. 1 s
Error detected when under –17.2% (4 to 20 mA: 1.25 mA; 1 to 5 V: 0.3125 V) or over
112.5% (4 to 20 mA: 22 mA; 1 to 5 V: 5.5 V).
Operation at input disconnection Process value of –15% stored.
179
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
Function
Item
Mean value processing (input
filter)
Process value
alarm
Rate-of-change
calculation
Specifications
Calculates the moving average for the specified number of process values (1 to 16),
and stores that value in the CIO Area as the process value.
Process value 4-point alarm (HH, H, LL, L), alarm hysteresis, and ON-delay timer (0 to
60 s) are available.
Calculates the amount of change per comparison time interval (1 to 16 s).
Rate-of-change
alarm
Rate-of-change 2-point alarm (H, L), alarm hysteresis (shared with process value
alarm), and ON-delay timer (0 to 60 s, shared with process value alarm) are available.
Square root
When the process value scaling maximum value is A and the minimum value is B:
Output =
(A−B) (Input−B)
+B
Dropout: Output approx. 7% maximum linear (output = input) characteristics
Note 1 The square root function is only enabled when the maximum scaling value
is greater than the minimum value.
Note 2 When square root processing is being performed, set the maximum and
minimum scaling values to the values required after square root processing
of the current or other input values.
Isolation
Insulation resistance
Between inputs and between input terminals and PLC signals: Isolation by transformer
20 MΩ (at 500 V DC) between inputs
Dielectric strength
External connections
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
Terminal block (detachable)
Unit number settings
Indicators
Front panel connector
Set by rotary switches on front panel, from 0 to 95.
Three LED indicators on front panel (for normal operation, errors detected at the 2Wire Transmitter Input Unit, and errors related to the CPU Unit).
Sensor input connector terminal block (detachable)
Effect on CPU Unit cycle time
Current consumption
0.3 ms
5 V DC at 150 mA max., 26 V DC at 160 mA max.
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
Standard accessories
450 g max.
None
180
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
m
Decimal
12345, 0
Hexadecimal
3039, 0000 hex
Default
0000 hex
Data contents
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+2 to m+81.
• 12345 (3039 hex): The data in words m+2 to
m+81 is transferred from the 2-Wire Transmitter Input Unit to the CPU Unit. When the
transfer is completed, the value will become
0000 hex.
• Other than 12345 (3039 hex) (such as 0000
hex): The data in the allocated words of DM
Area is transferred from the CPU Unit to the
2-Wire Transmitter Input Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m + 10
m + 18
m + 26
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4200
(1068 hex)
Process value HH (high high limit) alarm setting
(Set at process value scaling value.)
m+3
m + 11
m + 19
m + 27
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m + 12
m + 20
m + 28
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m + 13
m + 21
m + 29
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
–200
(FF38 hex)
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m + 14
m + 22
m + 30
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Rate-of-change value H (high limit) alarm setting
(Set at rate-of-change scaling value.)
m+7
m + 15
m + 23
m + 31
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
m+8
m + 16
m + 24
m + 32
0 to 32000 0000 to 7D00 hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001)
m+9
m + 17
m + 25
m + 33
–32000 to
32000
0
(0000 hex)
Zero adjustment value
(Set at process value scaling value.)
Rate-of-change value alarm settings
Zero/span adjustment
8300 to FFFF hex,
0000 to 7D00 hex
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the 2-Wire Transmitter Input Unit
if word m contains other than 12345 when the PLC is turned ON or the 2-Wire Transmitter Input Unit is restarted.
m + 34
m + 46
m + 58
m + 70
0, 1
0000 to 0001 hex
0
(0000 hex)
Input signal type
0: 4 to 20 mA, 1: 1 to 5 V
m + 35
m + 47
m + 59
m + 71
0, 1
0000 to 0001 hex
0
(0000 hex)
Square root extraction
0: Disable; 1: Enable
m + 36
m + 48
m + 60
m + 72
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Value stored for maximum value in range
(span)
m + 37
m +49
m + 61
m + 73
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
Value stored for minimum value in range (zero)
m + 38
m + 50
m + 62
m + 74
0 to 32000 0000 to 7D00 hex
40
(0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared
with process value alarm and rate-of-change
alarm.)
m + 39
m + 51
m + 63
m + 75
0 to 60
0
(0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rate-ofchange alarm.)
Process value scaling
Alarm supplementary functions
0000 to 003C hex
181
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Decimal
Hexadecimal
Default
Data contents
m + 40
m + 52
m + 64
m + 76
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
m + 41
m + 53
m + 65
m + 77
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
–4000
(F060 hex)
m + 42
m + 54
m + 66
m + 78
1 to 16
0001 to 0010 hex
01
(0001 hex)
Rate-of-change comparison time interval
(Unit: s)
m + 43
m + 55
m + 67
m + 79
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Rate-of-change
value scaling
m + 44
m + 56
m + 68
m + 80
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
m + 45
m + 57
m + 69
m + 81
1 to 16
0001 to 0010 hex
4
(0004 hex)
Number of process values for calculating moving average for mean value processing
m + 84
m + 85
0 to 81
0000 to 0051 hex
0
(0000 hex)
Address of Data Range Error (See note.)
Rate-of-change function
Rate-of-change
range setting
Maximum rate-of-change
value (Process value
industrial unit; comparison
time interval)
Minimum rate-of-change
value (Process value
industrial unit; comparison
time interval)
Value stored for maximum
value in range
Value stored for minimum
value in range
Mean value processing function
Storage parameter
m + 82
m + 83
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Address of Data Range
Error in the DM Area in four digits hexadecimal. For more information, refer to
1-6 Error Processing.
182
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Word
2-Wire
n
Transmitter
Input Unit to
CPU Unit
Bit
00
Input No. 1
Name
Data range
Process value LL (low 0, 1
low limit) alarm
01
Process value L (low
limit) alarm
02
Process value H (high 0, 1
limit) alarm
03
Process value HH
(high high limit) alarm
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
04
Input No. 2
05
06
07
08
Input No. 3
10
11
13
0, 1
0, 1
0: Process value <
Set value
1: Process value ≥ Set
value
Same as for input No.
1.
0, 1
0, 1
Process value HH
0, 1
(high high limit) alarm
09
12
0, 1
Contents
0: Process value >
Set value
1: Process value ≤ Set
value
Input No. 4
Process value LL (low 0, 1
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
Process value HH
(high high limit) alarm
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
Same as for input No.
1.
0, 1
0, 1
0, 1
0, 1
Same as for input No.
1.
0, 1
14
Process value H (high 0, 1
limit) alarm
15
Process value HH
0, 1
(high high limit) alarm
183
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
Direction
Word
2-Wire
n+1
Transmitter
Input Unit to
CPU Unit
n+2
Bit
00 to 15
Name
Input No. 1 process value
00 to 15
Input No. 2 process value
n+3
00 to 15
Input No. 3 process value
n+4
00 to 15
Input No. 4 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+5
00 to 15
Input No. 1 rate-of-change value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+6
00 to 15
Input No. 2 rate-of-change value
n+7
00 to 15
Input No. 3 rate-of-change value
n+8
00 to 15
Input No. 4 rate-of-change value
n+9
00
Input No. 1
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
0, 1
01
02
Input No. 2
03
04
Input No. 3
05
06
07
184
Input No. 4
Rate-of-change value
L (low limit) alarm
Data range
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
Contents
The present process
value is stored
according to the scaling set in the allocated
words of the DM Area.
The process value
rate of change is
stored according to
the scaling set in the
allocated words of the
DM Area.
0: Rate-of-change
value > Set value
1: Rate-of-change
value ≤ Set value
Rate-of-change value
H (high limit) alarm
0, 1
0: Rate-of-change
value < Set value
1: Rate-of-change
value ≥ Set value
Rate-of-change value
L (low limit) alarm
Rate-of-change value
H (high limit) alarm
Rate-of-change value
L (low limit) alarm
Rate-of-change value
H (high limit) alarm
0, 1
Same as for input No.
1.
Rate-of-change value
L (low limit) alarm
0, 1
Rate-of-change value
H (high limit) alarm
0, 1
0, 1
0, 1
Same as for input No.
1.
0, 1
Same as for input No.
1.
08
Input No. 1 input error
0, 1
0: Normal
1: Error (less than
–17.2% or greater
than 112.5%)
Same as for input No.
1.
09
Input No. 2 input error
0, 1
10
Input No. 3 input error
0, 1
Same as for input No.
1.
11
Input No. 4 input error
0, 1
Same as for input No.
1.
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
Terminal Connection Diagram
2-Wire Transmitter Input
CS1W-PTW01 Isolated-type 2-Wire Transmitter Input Unit
−
2-wire
transmitter
−
2-wire
transmitter
−
2-wire
transmitter
−
2-wire
transmitter
Current Input (No Power Supply Necessary)
CS1W-PTW01 Isolated-type
2-Wire Transmitter Input Unit
−
Current
output
device
−
Current
output
device
−
Current
output
device
−
Current
output
device
185
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
Voltage Input
CS1W-PTW01 Isolated-type
2-Wire Transmitter Input Unit
Voltage
output
device
−
Voltage
output
device
−
Voltage
output
device
−
Voltage
output
device
−
Note In all of the above cases, leave all unused terminals open (e.g., terminals A1,
A2, B1, and B2 for input No. 1).
186
Section 2-10
CS1W-PTW01 2-Wire Transmitter Input Unit
Terminal Block Diagram
CS1W-PTW01 Isolated-type 2-Wire Transmitter Input Unit
+24-V transmitter power supply
1 MΩ
250 Ω 1 MΩ
Amplifier
Isolation
circuit
Multiplexer
Input No. 1
Amplifier circuit
A/D converter
+24-V transmitter power supply
1 MΩ
Input No. 2
250 Ω 1 MΩ
Amplifier
Isolation
circuit
Digital computation circuit
+24-V transmitter power supply
Input No. 3
250 Ω 1 MΩ
Amplifier
Connector
1 MΩ
Isolation
circuit
5 V DC
To CPU Unit
Isolated power supply circuit
26 V DC
+24-V transmitter power supply
1 MΩ
Input No. 4
250 Ω 1 MΩ
Amplifier
2-Wire Transmitter Input
2-wire transmitter
Isolation
circuit
4-mA to 20-mA Input
(n: Input Nos. 1 to 4)
−
1-V to 5-V Input
(n: Input Nos. 1 to 4)
Current output
(n: Input Nos. 1 to 4)
−
Voltage output
−
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
Set the gain for span adjustment to a value other than 0.
set to 0.
The minimum and maximum val- Set the minimum and maximum values correctly.
ues for process value scaling are
either the same or are set
extremely low.
The input signal type or process Check and reset the input signal type and the process value scaling settings.
value scaling is set incorrectly.
An input device is malfunctioning, Check whether the input voltage has changed. Check for faulty or disconnected wiring.
input wiring is faulty, or wiring is
Check whether an input error has been detected in the I/O Area.
disconnected.
187
CS1W-PTW01 2-Wire Transmitter Input Unit
Section 2-10
Values are Not Converted as Intended.
Probable cause
The input signal type or process
value scaling is set incorrectly.
Remedy
Check and reset the input signal type and the process value scaling settings.
The zero/span adjustment data is Check and correct the zero/span adjustment settings.
incorrect.
The square root function is operating.
Set the square function so that it does not operate.
Converted Values are Unstable.
Probable cause
Input signals are being affected
by external noise.
Remedy
Change the connection paths of the input signal lines. (Separate them from sources of
noise or use shielded cable.)
Insert 0.01-µF to 0.1-µF ceramic capacitors between the I+ and COM, and between
the V+ and COM input terminals.
Increase the number of values for calculating the moving average in mean value processing.
The scaling value is greater than
the Unit’s resolution.
Reduce the scaling value.
188
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
2-11 CS1W-PDC01 Isolated-type Direct Current Input Unit
Overview
The CS1W-PDC01 Isolated-type Direct Current Input Unit provides four DC
signal inputs, and sends the data to the CPU Unit each cycle. All inputs are
isolated.
CS1W-PDC01
System Configuration
CS1W-PDC01
Four DC inputs (−10 to 10 V, 0 to 10 V,
−5 to 5 V, 0 to 5 V, 1 to 5 V, user-set V
range, 4 to 20 mA, 0 to 20 mA)
Features
• Up to four DC signal inputs can be connected per Unit. Any of the following can be selected separately for the four inputs: 4 to 20 mA, 0 to 20 mA,
–10 to 10 V, 0 to 10 V, –5 to 5 V, 1 to 5 V, 0 to 5 V, or ±10-V user-set range.
• Scaling values are sent to the CPU Unit in four digits hexadecimal.
• Isolation between analog inputs can prevent sneak circuits from occurring
between input signals.
• Square root function.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Input error detection.
• Zero/span adjustment capability during operation.
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PDC01
Inputs
4
Input types
The following can be selected separately: 4 to 20 mA, 0 to
20 mA, –10 to 10 V, 0 to 10 V, –5 to 5 V, 1 to 5 V, 0 to 5 V,
or ±10-V user-set range
189
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
Block Diagram (Order of Processing)
The processing for the four inputs is as shown in the following diagram.
CPU Unit CIO Area
HH, H, L, LL
Process value
Process value
alarm
H, L
Rate-of-change
value
Rate-of-change
alarm
Input error alarm
I/O refresh
Isolated-type Direct Current Input Unit
Process value
alarm
Rate-of-change
alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
Output limit: −15% to +115%
Square root
Zero/span adjustment
Input error check
Process value scaling
For 4 to 20 mA and 1 to 5 V
inputs, less than −17% or more
than 112% is an input error.
There is no check for other inputs.
Input calculations
Input range
A/D conversion, moving average
−10 to 10 V, 0 to 10 V, −5 to 5 V, 0 to 5 V, 1 to 5 V, 4 to 20 mA,
0 to 20 mA, optional DC voltage
DC signal sensor
190
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
Specifications
Item
Specifications
Model
CS1W-PDC01
Applicable PLC
Unit classification
CS-series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
Special I/O Unit
Area
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Isolated-type Direct Current Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rateof-change alarms (L, H), input errors
DM Area words 100 words/Unit
allocated to
CPU Unit to Isolated-type Direct Current Input Unit:
Special I/O Units Input signal type, scaling of process values in industrial units, square root function
enable, rate-of-change value range, rate-of-change scaling, number of items for moving average, process value alarm setting (LL, L, H, HH), rate-of-change alarm setting
(L, H), zero/span adjustment value, etc.
Number of inputs
4
Input signal type
User-defined scaling in industrial
units
Data storage in the CIO Area
Accuracy (25°C)
4 to 20 mA, 0 to 20 mA, –10 to 10 V, 0 to
10 V, –5 to 5 V, 1 to 5 V, 0 to 5 V, or ±10-V
user-set range. The ±10-V user-set range
can be specified within –10.000 to
10.000 V.
Scaling required for the above input signals, such as 4 to 20 mA or 1 to 5 V. (Any
minimum and maximum values can be
set.) (4 inputs set separately.)
Input signal type and scaling to industrial
units are separate for each of the 4 inputs.
Note Input signal type and scaling to
industrial units are set in the DM
Area.
Example:
Input signal type: 4 to 20 mA; industrial
unit scaling: 0 to 500 m3/h (after square
root extraction). DM Area settings are as
The value derived from carrying out the
follows:
following processing in order of the proInput signal type: 5 (0005 hex)
cess value data is stored in four digits
Industrial unit maximum value stored: 500
hexadecimal (binary values) in the allo(01F4 hex)
cated words in the CIO Area.
Industrial unit minimum value stored: 0
1) Mean value processing → 2) Scaling → (0000 hex)
3) Zero/span adjustment → 4) Square
root extraction → 5) Output limits
±0.1% of full scale
For the ±10-V user-set range, however, as shown in the following equation, the accuracy depends on the ratio of the selected internal range (0 to 4) span to the user-set
range span.
Accuracy = ±0.1% x
Internal range span
User-set range span
Temperature coefficient
±0.015% /°C with respect to full scale.
For the ±10-V user-set range, however: ±0.015% /°C with respect to the internal
range.
Resolution
1/4,096 of full scale
For the ±10-V user-set range, however, as shown in the following equation, the resolution depends on the ratio of the selected internal range (0 to 4) span to the user-set
range span.
1
Resolution = 4096
Internal range span
x User-set range span
Input signal range
For inputs of 4 to 20 mA, 0 to 20 mA, 0 to 10 V, 1 to 5 V, 0 to 5 V: –15 to 115%
For inputs of –10 to 10 V or –5 to 5 V: –7.5 to 107.5%
For ±10-V user-set range: –7.5 to 107.5% of internal range
Maximum input rating
Voltage: ±15 V
Current: ±30 mA
191
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
Item
Input impedance
Specifications
For current input: 250 Ω
For voltage input: 1 MΩ min.
Warmup time
Response time
10 min
0.5 s (travel time from input 0% to 90%, for step input)
Conversion period
Maximum time to store data in
CPU Unit
Input error detection
100 ms/4 inputs
Conversion period + one CPU Unit cycle
Operation at input disconnection
Checks are conducted for only 4 to 20 mA and 1 to 5 V.
Error detected when under –17.2% (1.25 mA, 0.3125 V) or over 112.5% (22 mA,
5.5 V).
4 to 20 mA, 1 to 5 V: Process value of –15% stored.
0 to 20 mA, 0 to 5 V, 0 to 10 V, –10 to 10 V: The same value is stored as when 0 V or
0 mA is input.
Input disconnection overrange
Approx. 1 s
time
Function
Mean value pro- Calculates the moving average for the specified number of past process values (1 to
cessing (input
16), and stores that value in the CIO Area as the process value.
filter)
Process value
alarm
Rate-of-change
calculation
Rate-of-change
alarm
Square root
Process value 4-point alarm (HH, H, L, LL), hysteresis, and ON-delay timer (0 to 60 s)
are available.
Calculates the amount of change per comparison time interval (1 to 16 s).
Rate-of-change 2-point alarm (H, L), alarm hysteresis (shared with process value
alarm), and ON-delay timer (0 to 60 s, shared with process value alarm) are available.
When the process value scaling maximum value is A and the minimum value is B:
Output =
(A−B) (Input−B)
+B
Dropout: Output approx. 7% maximum linear (output = input) characteristics
Note The square root function is only enabled when the maximum scaling value is
greater than the minimum value.
Note When square root processing is being performed, set the maximum and minimum scaling values to the values required after square root processing of the
current or other input values.
Isolation
Between analog inputs and between input terminals and PLC signals: Isolation by
transformer
Insulation resistance
Dielectric strength
20 MΩ (at 500 V DC) between inputs
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Front panel connector
Three LED indicators on front panel (for normal operation, errors detected at the
Direct Current Input Unit, and errors related to the CPU Unit).
Sensor input connector terminal block (detachable)
Effect on CPU Unit cycle time
Current consumption
0.3 ms
5 V DC at 150 mA max., 26 V DC at 160 mA max.
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
Standard accessories
450 g max.
None
192
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
Accuracy and Resolution for ±10 V User-set Range
With the ±10-V user-set range, the input signal zero and span can be set anywhere within the range –10.000 to 10.000 V. Internally, however, inputs are
processed in five progressive ranges (numbers 0 to 4), as shown in the following table.
Table 1: Internal Ranges
Internal range number
Measurable voltage
Internal range span
0
1
–10.000 to 10.000 V
–5.000 to 5.000 V
20.000 V
10.000 V
2
3
–2.500 to 2.500 V
–1.250 to 1.250 V
5.000 V
2.500 V
4
–0.625 to 0.625 V
1.250 V
Therefore, the accuracy and resolution of the set range span are determined
by the ratio of the internal range (0 to 4) span to the set input range span. For
the internal range, a larger number is selected when both the minimum and
maximum values of the range fall within that next range.
For example, suppose that the set input range is 0.000 to 3.000 V. Since both
the minimum and maximum values fall within the limits for internal range No. 1
(–5.000 to 5.000 V), that range will be selected.
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
m
Decimal
12345, 0
Hexadecimal
3039, 0000 hex
Default
0000 hex
Data contents
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+2 to m+89.
• 12345 (3039 hex): The data in words m+2 to
m+89 is transferred from the Direct Current
Input Unit to the CPU Unit. When the transfer
is completed, the value will become 0000
hex.
• Other than 12345 (3039 hex) (such as 0000
hex): The data in the allocated words of DM
Area is transferred from the CPU Unit to the
Direct Current Input Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m + 10
m + 18
m + 26
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4200
(1068 hex)
Process value HH (high high limit) alarm setting
(Set at process value scaling value.)
m+3
m + 11
m + 19
m + 27
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m + 12
m + 20
m + 28
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m + 13
m + 21
m + 29
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
–200
(FF38 hex)
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m + 14
m + 22
m + 30
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Rate-of-change value H (high limit) alarm setting
(Set at rate-of-change scaling value.)
m+7
m + 15
m + 23
m + 31
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
m+8
m + 16
m + 24
m + 32
0 to 32000 0000 to 7D00 hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001)
m+9
m + 17
m + 25
m + 33
–32000 to
32000
0
(0000 hex)
Zero adjustment value
(Set at process value scaling value.)
Rate-of-change value alarm settings
Zero/span adjustment
8300 to FFFF hex,
0000 to 7D00 hex
193
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Decimal
Hexadecimal
Default
Data contents
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Direct Current Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Direct Current Input Unit is restarted.
Input signal type
m + 34
m + 48
m + 62
m + 76
0 to 7
0000 to 0007 hex
1
(0001 hex)
Input signal type
0: –10 to 10 V, 1: 0 to 10 V, 2: –5 to 5 V, 3: 0 to
5 V, 4: 1 to 5 V, 5: 4 to 20 mA, 6: ±10-V user-set
range (set to the range below), 7: 0 to 20 mA
m + 35
m + 49
m + 63
m + 77
–10000 to
10000
D8F0 to 2710 hex
10000
(2710 hex)
±10-V user-set
range
m + 36
m + 50
m + 64
m + 78
–10000 to
10000
D8F0 to 2710 hex
0
(0 hex)
Maximum value in range
(set value × 0.001 V)
Minimum value in range
(set value × 0.001 V)
Square root function
m + 37
m + 51
m + 65
m + 79
0, 1
0000 to 0001 hex
0
(0000 hex)
Square root extraction (when maximum scaling
value > minimum scaling value)
0: Disable; 1: Enable
m + 38
m + 52
m + 66
m + 80
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Value stored for maximum value in range
(span)
m + 39
m + 53
m + 67
m + 81
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
Value stored for minimum value in range (zero)
m + 40
m + 54
m + 68
m + 82
0 to 32000 0000 to 7D00 hex
40
(0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared
with process value alarm and rate-of-change
alarm.)
m + 41
m + 55
m + 69
m + 83
0 to 60
0
(0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rate-ofchange alarm.)
Process value scaling
Alarm supplementary functions
0000 to 003C hex
Rate-of-change function
m + 42
m + 56
m + 70
m + 84
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Rate-of-change
range setting
Maximum rate-of-change
value (Process value
industrial unit; comparison
time interval)
m + 43
m + 57
m + 71
m + 85
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
–4000
(F060 hex)
m + 44
m + 58
m + 72
m + 86
1 to 16
0001 to 0010 hex
1
(0001 hex)
Rate-of-change comparison time interval
(Unit: s)
m + 45
m + 59
m + 73
m + 87
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0FA0 hex)
Rate-of-change
value scaling
m + 46
m + 60
m + 74
m + 88
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
m + 47
m + 61
m + 75
m + 89
1 to 16
0001 to 0010 hex
4
(0004 hex)
Number of process values for calculating moving average for mean value processing
m + 92
m + 93
0 to 89
0000 to 0059 hex
0
(0000 hex)
Address of Data Range Error (See note.)
Minimum rate-of-change
value (Process value
industrial unit; comparison
time interval)
Value stored for maximum
value in range
Value stored for minimum
value in range
Mean value processing function
Storage parameter
m + 90
m + 91
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Address of Data Range
Error in the DM Area in four digits hexadecimal. For more information, refer to
1-6 Error Processing.
194
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Word
Direct Cur- n
rent Input
Unit to CPU
Unit
Bit
00
Input No. 1
Name
Data range
Process value LL (low 0, 1
low limit) alarm
01
Process value L (low
limit) alarm
02
Process value H (high 0, 1
limit) alarm
03
Process value HH
(high high limit) alarm
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
04
Input No. 2
05
06
07
08
Input No. 3
10
11
13
0, 1
0, 1
0: Process value < Set
value
1: Process value ≥ Set
value
Same as for input No. 1.
0, 1
0, 1
Process value HH
0, 1
(high high limit) alarm
09
12
0, 1
Contents
0: Process value > Set
value
1: Process value ≤ Set
value
Input No. 4
Process value LL (low 0, 1
low limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
Process value HH
(high high limit) alarm
Process value LL (low
low limit) alarm
Process value L (low
limit) alarm
Same as for input No. 1.
0, 1
0, 1
0, 1
0, 1
Same as for input No. 1.
0, 1
14
Process value H (high 0, 1
limit) alarm
15
Process value HH
0, 1
(high high limit) alarm
195
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
Direction
Word
Direct Cur- n + 1
rent Input
Unit to CPU
Unit
n+2
Bit
00 to 15
Name
Input No. 1 process value
00 to 15
Input No. 2 process value
n+3
00 to 15
Input No. 3 process value
n+4
00 to 15
Input No. 4 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+5
00 to 15
Input No. 1 rate-of-change value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+6
00 to 15
Input No. 2 rate-of-change value
n+7
00 to 15
n+8
00 to 15
n+9
00
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
Input No. 3 rate-of-change value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
Input No. 4 rate-of-change value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
Input No. 1 Rate-of-change value 0, 1
L (low limit) alarm
01
02
Input No. 2
03
04
Input No. 3
05
06
07
196
Data range
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
Input No. 4
Contents
The present process
value is stored according
to the scaling set in the
allocated words of the
DM Area.
The process value rate of
change is stored according to the scaling set in
the allocated words of the
DM Area.
0: Rate-of-change value
> Set value
1: Rate-of-change value
≤ Set value
Rate-of-change value 0, 1
H (high limit) alarm
0: Rate-of-change value
< Set value
1: Rate-of-change value
≥ Set value
Rate-of-change value
L (low limit) alarm
Rate-of-change value
H (high limit) alarm
Rate-of-change value
L (low limit) alarm
Rate-of-change value
H (high limit) alarm
Same as for input No. 1.
0, 1
0, 1
0, 1
Same as for input No. 1.
0, 1
Rate-of-change value 0, 1
L (low limit) alarm
Same as for input No. 1.
Rate-of-change value 0, 1
H (high limit) alarm
08
Input No. 1 input error
0, 1
09
Input No. 2 input error
0, 1
0: Normal
1: Error (less than
–17.2% or greater than
112.5%)
Note Checks are conducted for inputs of
4 to 20 mA and 1
to 5 V.
Same as for input No. 1.
10
11
Input No. 3 input error
Input No. 4 input error
0, 1
0, 1
Same as for input No. 1.
Same as for input No. 1.
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
Terminal Connection Diagram
Voltage input
Voltage output
device
−
Voltage output
device
−
Voltage output
device
−
Voltage output
device
−
Current input
−
Current output
device
−
Current output
device
−
Current output
device
−
Current output
device
Note In both of the above cases, leave all unused inputs open between the positive
and negative terminals (e.g., between B1 and B2 for voltage input No. 1).
197
Section 2-11
CS1W-PDC01 Isolated-type Direct Current Input Unit
Terminal Block Diagram
Input No. 1
250 Ω
Isolation
circuit
1 MΩ Amplifier
Multiplexer
1 MΩ
Multi-gain amplifier
circuit
A/D converter
1 MΩ
250 Ω 1 MΩ
Input No. 2
Isolation
circuit
Digital computation circuit
Amplifier
Input No. 3
250 Ω 1 MΩ
Connector
1 MΩ
Isolation
circuit
Amplifier
5 V DC
To CPU Unit
Isolated power supply circuit
26 V DC
1 MΩ
Input No. 4
250 Ω 1 MΩ
Isolation
circuit
Amplifier
Current input
(n: Input Nos. 1 to 4)
Voltage input
(n: Input Nos. 1 to 4)
Current output
Voltage output
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
Set the gain for span adjustment to a value other than 0.
set to 0.
The minimum and maximum val- Set the minimum and maximum values correctly.
ues for process value scaling are
either the same or are set
extremely low.
The input signal type or process Check and reset the input signal type and the process value range settings.
value range is set incorrectly.
An input device is malfunctioning, Check whether the input voltage has changed. Check for faulty or disconnected wiring.
input wiring is faulty, or wiring is
Check whether an input error has been detected in the I/O Area.
disconnected.
198
CS1W-PDC01 Isolated-type Direct Current Input Unit
Section 2-11
Values are Not Converted as Intended.
Probable cause
The input signal type or process
value scaling is set incorrectly.
Remedy
Check and reset the input signal type and the process value scaling settings.
The zero/span adjustment data is Check and correct the zero/span adjustment settings.
incorrect.
The square root function is operating.
Set the square function so that it does not operate.
Converted Values are Unstable.
Probable cause
Input signals are being affected
by external noise.
Remedy
Change the connection paths of the input signal lines. (Separate them from sources of
noise or use shielded cable.)
Insert 0.01-µF to 0.1-µF ceramic capacitors between the I+ and COM, and between
the V+ and COM input terminals.
Increase the number of values for calculating the moving average in mean value processing.
The scaling value is greater than
the Unit’s resolution.
Reduce the scaling value.
199
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
2-12 CS1W-PDC11 Isolated-type Direct Current Input Unit
Overview
The CS1W-PDC11 Isolated-type Direct Current Input Unit provides four
direct-current inputs, and sends the data to the CPU Unit each cycle. All
inputs are isolated.
CS1W-PDC11
RUN
ERC
ERH
EDCBA
9876
543210
F
X101 0 X100
54321
F
EDCBA
MACH
No.
9876
System Configuration
CS1W-PDC11
4 DC inputs
(4 to 20 mA, 0 to 20 mA,
0 to 10 V, −10 to 10 V,
0 to 5 V, −5 to 5 V,
1 to 5 V, 0 to 1.25 V,
−1.25 to 1.25 V)
Features
• Up to four DC inputs can be made to each Unit.
4 to 20 mA, 0 to 20 mA, 0 to 10 V, −10 to 10 V, 0 to 5 V, −5 to 5 V, 1 to 5 V,
0 to 1.25 V, or −1.25 to 1.25 V can be selected separately for each input.
• Resolution of 1/64,000 for all input range specifications.
• High-speed conversion, at 20 ms/4 inputs and 10 ms/2 inputs.
• Scaling values are transmitted to the CPU Unit in four digits hexadecimal.
• There is isolation between channels, so unwanted signal paths between
input signals can be prevented.
• Square root function.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Input error detection.
• Zero/span adjustment capability during operation.
• Adjustment period control.
• Peak and bottom detection.
• Top and valley detection.
200
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
• Integral value calculation.
Model Information
Unit classification
Model number
CS-series Special I/O CS1W-PDC11
Unit
Inputs
4
Input types
4 to 20 mA, 0 to 20 mA, 0 to 10 V, −10 to 10 V, 0 to
5 V, −5 to 5 V, 1 to 5 V, 0 to 1.25 V, and −1.25 to
1.25 V (separate for each input)
201
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
Block Diagram
CPU Unit
CPU Unit Expansion Area Allocations
Top/valley value
Peak/Bottom value
CPU Unit CIO Area
HH, H, L, LL
Process value
H, L
Rate-of-change value
Process value alarm
Rate-of-change alarm
Input error alarm
I/O refresh
Isolated-type Direct Current Input Unit
Process value alarm
Rate-of-change alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
+115% or −15% when input disconnection is detected
Square root
Input error check
Zero/span adjustment
Process value scaling
Input calculations
Input range
For 4 to 20 mA and 1 to 5 V inputs,
less than −17% or more than 112% is
an input error.
There is no check for other inputs.
A/D conversion, moving average
DC signal sensor
202
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
Specifications
Item
Specifications
Model
CS1W-PDC11
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
Special I/O Unit 10 words/Unit
Area
Isolated-type Direct Current Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rateof-change alarms (L, H), disconnection alarms, cold junction sensor errors, adjustment period end/notice
DM Area words 100 words/Unit
allocated to
CPU Unit to Isolated-type Direct Current Input Unit:
Special I/O Units Input signal type, scaling of process value in industrial units, process value alarm setting (L, H), inrush input upper limit, inrush input upper limit time, zero/span adjustment
value, Square root function.
Temperature input signal type, input range (user set), scaling of process value data to
be stored in allocated words in CIO area, rate-of-change input range, scaling of rateof-change data, number of items for moving average, process value alarm setting (LL,
L, H, HH), rate-of-change alarm setting (L, H), zero/span adjustment value
Expansion Con- 35 words/Unit
trol/Monitor Area CPU Unit to Isolated-type Direct Current Input Unit:
Bits for beginning or resetting the hold function selection, adjustment period control,
control bits
Isolated-type Direct Current Input Unit to CPU Unit:
Adjustment period notices, peak and bottom values, top and valley values, integral values
Expansion Set- 46 words/Unit
ting Area
CPU Unit to Isolated-type Direct Current Input Unit:
Expansion Setting Area settings, adjustment period control, peak and bottom detection, top and valley detection, integral value calculation
Number of inputs
Input signal type
Accuracy (25°C)
4
4 to 20 mA, 0 to 20 mA, 0 to 10 V, −10 to 10 V, 0 to 5 V, −5 to 5 V, 1 to 5 V, 0 to 1.25 V,
−1.25 to 1.25 V (separate for each input), and ±10-V user-set range (specified range
within –10.000 V to 10.000 V)
Data to be stored in the allocated words in the CIO area must be scaled (Any minimum and maximum values can be set.) (4 inputs set separately.) Data can be converted at 0% to 100%.
The value derived from carrying out the following processing in order of the actual process data in the input range is stored in four digits hexadecimal (binary values) in the
allocated words in the CIO Area.
1) Mean value processing → 2) Scaling → 3) Zero/span adjustment → 4) Square root
calculation → 5) Output limits
±0.05%
Temperature coefficient
Resolution
±0.008%/°C
1/64,000
Input signal range
For 4 to 20 mA, 0 to 20 mA, 0 to 10 V, 0 to 5 V, 1 to 5 V, 0 to 1.25 V inputs:
−15 to 115%
Scaling
Data storage in the CIO Area
For −10 to 10 V, −5 to 5 V, −1.25 to 1.25 V inputs:
−7.5 to 107.5%
Maximum input rating
Voltage: ±15 V
Current: ±30 mA
203
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
Item
Input impedance
Warmup time
Response time
Conversion period
Maximum time to store data in
CPU Unit
Input error detection
Operation at input disconnection
Input disconnection detection
delay time
Function
Specifications
For current inputs: 250 Ω (typical)
For voltage inputs: 1 MΩ min.
10 min
100 ms (travel time from input 0% to 90%, for ±10 V step input and with moving average for 4 samples)
20 ms/4 inputs, 10 ms/2 inputs, selectable in words allocated to the Unit as a Special
I/O Unit.
Conversion period + one CPU Unit cycle
Check only for 4 to 20 mA and 1 to 5 V.
Error detected for −17.2% (1.25 mA, 0.3125 V) or less and 112.5% (22 mA, 5.5 V) or
more.
For 4 to 20 mA and 1 to 5 V: Stores −15% process value.
For all other ranges: Stores same process value as 0-V or 0-mA inputs.
Approx. 1 s.
Mean value pro- Calculates the moving average for the past specified number of process values (1 to
cessing (input
128 can be specified), and stores that value in the CIO Area as the process value.
filter)
Process value
alarm
Process value 4-point alarm (LL, L H, HH), hysteresis, and ON-delay timer (0 to 60 s)
are available.
Rate-of-change
calculation
Calculates the amount of change per comparison time interval (1 to 16 s).
Rate-of-change Rate-of-change 2-point alarm (H, L), alarm hysteresis, and ON-delay timer (0 to 60 s
alarm
are available, shared with process value alarm).
Square root cal- When the maximum value for process value scaling is A and the minimum value is B,
culation
Output = (A − B) × (input − B) + B
Drop-out: Output approx. 7% max. linear (output = input) characteristic
Note 1 The square root function can only be used when the maximum scaling value
is greater than the minimum scaling value. The square root will not be found if
the maximum is smaller than the minimum.
Note 2 When the square root function is used, set the scaling values after square root
calculation (e.g., for flow rates or other values) for the process value scaling A
and B settings.
Adjustment
period control
Peak and bottom detection
Top and valley
detection
When zero/span adjustment is executed, the date is internally recorded at the Unit.
When the preset zero/span adjustment period and the notice of days remaining set in
the Expansion Setting Area have elapsed, this function turns ON a warning flag to
give notice that it is time for readjustment.
Detects the maximum (peak) and minimum (bottom) analog input values, from when
the Hold Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON
until it turns OFF. These values are stored as the peak and bottom values in the
Expansion Control/Monitor Area.
Insulation resistance
This function detects the top and valley values for analog inputs, from when the Hold
Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON until it
turns OFF. These values are stored as the top and valley values in the Expansion
Control/Monitor Area.
This function calculates the analog input value’s time integral. The integral value is calculated and output to the Expansion Control/Monitor Area when the Integral Value
Calculation Start Bit in the Expansion Control/Monitor Area is turned ON.
Between inputs and between inputs and PLC signals: Isolation by transformer and
photocoupler.
20 MΩ (at 500 V DC) between all inputs
Dielectric strength
External connections
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
Terminal block (detachable)
Unit number settings
Set by rotary switches on front panel, from 0 to 95.
Integral value
calculation
Isolation
204
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
Indicators
Item
Specifications
Three LED indicators on front panel (for normal operation, errors detected at the
Direct Current Input Unit, and errors detected at the CPU Unit).
Front panel connector
Effect on CPU Unit cycle time
Sensor input connector terminal block (detachable)
0.3 ms
Current consumption
Dimensions
Weight
5 V DC at 120 mA max., 26 V DC at 120 mA max.
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
450 g max.
Standard accessories
Short bars (for current input)
Accuracy and Resolution in ±10-V User-set Range
The ±10-V user-set range allows the input signal’s input range to be set to any
range within –10.000 V to 10.000 V. Accuracy and resolution, however, are
not determined by the input range, but rather by the measurable input range
(–10.000 V to 10.000 V). Therefore, accuracy and resolution do not change
even if a narrow input range is set.
DM Area Allocations
First word: word m. m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
Decimal
Default
Data contents
Hexadecimal
m
12345, 0
3039, 0000 hex 0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM Area words m+1 to m+93.
• 12345 (3039 hex): The data in words m+1
to m+93 is transferred from the Direct
Current Input Unit to the CPU Unit. When
the transfer is completed, the value will
become 0000 hex.
• Other than 12345 (such as 0000 hex):
The data in the allocated words of DM
Area is transferred from the CPU Unit to
the Direct Current Input Unit.
m+1
0, 1
0000, 0001 hex 0
0: 4 inputs; 1: 2 inputs
Number of inputs setting
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m+10
m+18
m+26
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4200 (1068
hex)
Process value HH (high high limit) alarm
setting
(Set at process value scaling value.)
m+3
m+11
m+19
m+27
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4000 (0FA0
hex)
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m+12
m+20
m+28
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
0 (0000 hex)
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m+13
m+21
m+29
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
–200 (FF38
hex)
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m+14
m+22
m+30
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4000 (0FA0
hex)
Rate-of-change value H (high limit) alarm
setting
(Set at rate-of-change scaling value.)
m+7
m+15
m+23
m+31
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
0 (0000 hex)
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
Rate-of-change value alarm settings
205
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
Decimal
Default
Data contents
Hexadecimal
Zero/span adjustment
m+8
m+16
m+24
m+32
0 to 32000
0000 to 7D00
hex
10000 (2710
hex)
Gain for span adjustment
(set value × 0.0001%)
m+9
m+17
m+25
m+33
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Zero adjustment value
(Set at process value scaling value.)
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Direct Current Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Direct Current Input Unit is restarted.
Input signal type
0: ±10 V; 1: 0 to 10 V; 2: ±5 V; 3: 0 to 5 V;
4: 1 to 5 V; 5: 4 to 20 mA; 6: ±10 V user-set
range; 7: 0 to 20 mA; 8: ±1.25 V; 9: 0 to
1.25 V
m+34
m+48
m+62
m+76
0 to 9
0000 to 0009
hex
1 (0001 hex)
m+35
m+49
m+63
m+77
–1000 to 1000
D8F0 to FFFF
hex, 0000 to
2710 hex
10000 (2710
hex)
m+36
m+50
m+64
m+78
–1000 to 1000
D8F0 to FFFF
hex, 0000 to
2710 hex
0 (0000 hex)
m+37
m+51
m+65
m+79
0, 1
0000, 0001 hex 0 (0000 hex)
Square root extraction (when maximum
scaling value > minimum scaling value)
0: Disable; 1: Enable
m+38
m+52
m+66
m+80
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Value stored for maximum value in range
(span)
m+39
m+53
m+67
m+81
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Value stored for minimum value in range
(zero)
m+40
m+54
m+68
m+82
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared
with process value alarm and rate-ofchange alarm.)
m+41
m+55
m+69
m+83
0 to 60
0000 to 003C
hex
0 (0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rateof-change alarm.)
m+42
m+56
m+70
m+84
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Rate-of-change
range setting
m+43
m+57
m+71
m+85
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
–4000 (F060
hex)
m+44
m+58
m+72
m+86
1 to 16
0001 to 0010
hex
1 (0001 hex)
Rate-of-change comparison time interval
(Unit: s)
m+45
m+59
m+73
m+87
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Rate-of-change
value scaling
m+46
m+60
m+74
m+88
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
–4000 (F060
hex)
m+47
m+61
m+75
m+89
1 to 128
0001 to 0080
hex
25 (0019 hex)
Number of process values for calculating
moving average for mean value processing
m+92
m+93
0 to 99, 100 to
1XX
0000 to 0063
hex, 0064 to
0XXX hex
0 (0000 hex)
Address of Data Range Error (See note.)
Process value input range
±10-V user-set
range
Maximum value in range
(set value × 0.001 V)
Minimum value in range
(set value × 0.001 V)
Square root function
Process value scaling
Alarm supplementary functions
Rate-of-change function
Maximum rate-of-change
value (Process value
industrial unit; comparison time interval)
Minimum rate-of-change
value (Process value
industrial unit; comparison time interval)
Value stored for maximum value in range
Value stored for minimum
value in range
Mean value processing function
Display parameter
m+90
206
m+91
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
Decimal
Default
Data contents
Hexadecimal
Expansion Setting Area Allocation Settings
m+98
0 to 5
0000 to 0005
hex
---
Area of Expansion Setting Area
0: Not used; 1: DM; 2: CIO; 3: W; 4: H;
5: EM
m+99
0 to 32767
0000 to 7FFF
hex
---
First Word in Expansion Setting Area
Note
1. The ERC indicator on the Unit’s front panel will light if an out-of-range setting is made in either Setting Group 1 (continually refreshed area) or 2 (initial settings area), or in the Expansion Setting Area. The offset from word
m to the first address containing the out-of-range error will be stored as the
Address of Data Range Error in the DM Area in four digits hexadecimal.
If the first memory address where the out-of-range error occurred is in the
Expansion Setting Area, the Address of Data Range Area will be +100 or
later. If the first word of the Expansion Setting Area has the error, the Address of Data Range Area will be +100.
2. When specifying an expansion setting area be sure that it does not overlap
with other areas that are being used. If areas overlap, the words that are
allocated may be overwritten, resulting in unexpected operation.
3. When specifying the first word in an expansion setting area be sure that
the end of the memory area is not exceeded.
Expansion Setting Area Allocations
First word: word o. o = address specified in word m+99 in the area specified
by word m+98 in the DM Area.
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
Decimal
Default
Data contents
Hexadecimal
Setting Group 3 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Direct Current Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Direct Current Input Unit is restarted.
Expansion Control/Monitor Area Settings
o
0 to 5
0000 to 0005
hex
---
Expansion Control/Monitor Area allocation
0: Not used. 1: DM; 2: CIO; 3: W; 4: H;
5: EM
o+1
0 to 32767
0000 to 7FFF
hex
---
Expansion Control/Monitor Area first word
Zero/span adjustment supplementary
function
o+2
o+13
o+24
o+35
0 to 32000
0000 to 7D00
hex
10000 (2710
hex)
Span adjustment position
(Input span percentage)
o+3
o+14
o+25
o+36
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Zero adjustment position
(Input span percentage)
o+4
o+15
o+26
o+37
0 to 9999
0000 to 270F
hex
365 (016D hex) Zero/span adjustment period (Unit: Days)
o+5
o+16
o+27
o+38
0 to 9999
0000 to 270F
hex
30 (001E hex)
Notice of days remaining (Unit: Days)
o+6
o+17
o+28
o+39
---
---
0 (0000 hex)
Not used
o+7
o+18
o+29
o+40
o+8
o+19
o+30
o+41
o+9
o+20
o+31
o+42
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
Hysteresis
Not used
Top and valley hold
Integral value calculation
207
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
Decimal
Default
Data contents
Hexadecimal
o+10
o+21
o+32
o+43
0, 1
0000, 0001 hex 0 (0000 hex)
Integer unit
0: Minutes; 1: Hours
o+11
o+22
o+33
o+44
---
---
Not used.
o+12
o+23
o+34
o+45
Not used
Note
0 (0000 hex)
1. When specifying an expansion control/monitor area be sure that it does not
overlap with other areas that are being used. If areas overlap, the words
that are allocated may be overwritten, resulting in unexpected operation.
2. When specifying the first word in an expansion control/monitor area be
sure that the end of the memory area is not exceeded.
208
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
CIO Area Allocations
First word: word n. n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Direct Current
Input Unit to
CPU Unit
Word
n
Bit
00
Name
Input No. 1 Process value
LL (low low
limit) alarm
Data range
0, 1
01
Process value L 0, 1
(low limit) alarm
02
Process value
H (high limit)
alarm
03
04
05
06
07
08
Process value
HH (high high
limit) alarm
Input No. 2 Process value
LL (low low
limit) alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value
HH (high high
limit) alarm
Input No. 3 Process value
LL (low low
limit) alarm
0, 1
0, 1
0: Process value < Set
value
1: Process value ≥ Set
value
0, 1
Same as for input No. 1.
0, 1
0, 1
0, 1
0, 1
09
Process value L 0, 1
(low limit) alarm
10
Process value
H (high limit)
alarm
0, 1
11
Process value
HH (high high
limit) alarm
0, 1
12
13
14
15
Contents
0: Process value > Set
value
1: Process value ≤ Set
value
Input No. 4 Process value 0, 1
LL (low low
limit) alarm
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Process value
HH (high high
limit) alarm
0, 1
0, 1
209
CS1W-PDC11 Isolated-type Direct Current Input Unit
Direction
Direct Current
Input Unit to
CPU Unit, continued
210
Word
n+1
Bit
0 to 15
Name
Input No. 1 process value
Data range
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+2
0 to 15
Input No. 2 process value
n+3
0 to 15
Input No. 3 process value
n+4
0 to 15
Input No. 4 process value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+5
0 to 15
Input No. 1 rate-of-change
value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+6
0 to 15
Input No. 2 rate-of-change
value
n+7
0 to 15
Input No. 3 rate-of-change
value
n+8
0 to 15
Input No. 4 rate-of-change
value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
Section 2-12
Contents
The present process value
is stored according to the
scaling set in the allocated
words of the DM Area.
The present rate-of-change
value is stored according to
the scaling set in the allocated words of the DM
Area.
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
Direction
Direct Current
Input Unit to
CPU Unit, continued
Word
n+9
Bit
00
Name
Input No. 1 Rate-of-change 0, 1
value L (low
limit) alarm
01
Rate-of-change 0, 1
value H (high
limit) alarm
02
Input No. 2 Rate-of-change 0, 1
value L (low
limit) alarm
Rate-of-change 0, 1
value H (high
limit) alarm
Input No. 3 Rate-of-change 0, 1
value L (low
limit) alarm
03
04
05
Rate-of-change 0, 1
value H (high
limit) alarm
06
Input No. 4 Rate-of-change 0, 1
value L (low
limit) alarm
07
08
Rate-of-change 0, 1
value H (high
limit) alarm
Input No. 1 input error
0, 1
09
10
Input No. 2 input error
Input No. 3 input error
0, 1
0, 1
11
Input No. 4 input error
0, 1
12
13
Not used.
Zero/span adjustment
period end
0, 1
0, 1
14
Zero/span adjustment
period notice
0, 1
15
Not used.
0
Data range
Contents
0: Rate-of-change value >
set value
1: Rate-of-change value ≤
set value
0: Rate-of-change value <
set value
1: Rate-of-change value ≥
set value
Same as for input No. 1.
0: Normal
1: Error (less than –17.2%
or greater than 112.5%)
Note Checks are conducted for inputs of
4 to 20 mA and 1 to
5 V.
Not used.
0: Adjustment enabled
1: Adjustment ended
0: Adjustment enabled
1: Notice period
Not used.
211
CS1W-PDC11 Isolated-type Direct Current Input Unit
Section 2-12
Expansion Control/Monitor Area Allocations
First word: p. p = address specified in word o+1 in the area specified by word
o in the Expansion Setting Area.
Direction
Word
CPU Unit p
to Direct
Current
p+1
Input Unit,
continued
p+2
Bit
00 to
15
00
Data range
Not used.
Contents
Not used.
Input No. 1 hold function
selection
Input No. 2 hold function
selection
0, 1
0: Peak and bottom
1: Top and valley
02
Input No. 3 hold function
selection
0, 1
03
Input No. 4 hold function
selection
0, 1
04 to
07
08
Not used.
0
Not used.
Input No. 1 hold start
0, 1
09
10
Input No. 2 hold start
Input No. 3 hold start
0, 1
0, 1
0: Do not hold.
1: Hold
11
12
Input No. 4 hold start
Input No. 1 hold value reset
0, 1
0, 1
13
14
Input No. 2 hold value reset
Input No. 3 hold value reset
0, 1
0, 1
15
00
Input No. 4 hold value reset
Input No. 1 integral value calculation start
Input No. 2 integral value calculation start
Input No. 3 integral value calculation start
Input No. 4 integral value calculation start
0, 1
0, 1
01
01
02
03
p+3
0, 1
0, 1
0: Normal operation
1: Reset hold value.
0: Do not start calculation
1: Start calculation
0, 1
0, 1
04
05
Input No. 1 integral value reset 0, 1
Input No. 2 integral value reset 0, 1
06
07
Input No. 3 integral value reset 0, 1
Input No. 4 integral value reset 0, 1
08 to
15
Not used.
0
Not used.
00
Input No. 1 zero/span adjustment update bit
0, 1
01
Input No. 2 zero/span adjustment update bit
Input No. 3 zero/span adjustment update bit
Input No. 4 zero/span adjustment update bit
Not used.
0, 1
0: Normal operation
1: Update adjustment
date
(Remains ON while
writing external
FROM.)
02
03
04 to
15
212
Name
Not used.
0, 1
0: Normal operation
1: Integral value reset
0, 1
0
Not used.
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
Direction
Word
Direct Cur- p+4
rent Input
Unit to
CPU Unit
Bit
00
Name
Input Zero/span adjustment
No. 1 period end
01
0, 1
05
Zero/span adjustment
period notice
0, 1
06
Input Zero/span adjustment
No. 4 period end
0, 1
07
Zero/span adjustment
period notice
External FROM error
0, 1
0, 1
0: Normal operation.
1: External FROM
error.
Not used.
0
Not used.
Input
No. 2
03
04
08
p+6
p+7
p+8
09 to
15
00 to
15
00 to
15
00 to
15
00 to
15
Input
No. 3
0, 1
0, 1
0, 1
Input Day of final adjustment 0100 to 3100 (BCD)
No. 1 date
Year and month of final 0001 to 9912 (BCD)
adjustment date
00 to
15
Input Day of final adjustment 0100 to 3100 (BCD)
No. 3 date
p+10
00 to
15
Year and month of final 0001 to 9912 (BCD)
adjustment date
p+11
00 to
15
00 to
15
00 to
15
00 to
15
Input Day of final adjustment 0100 to 3100 (BCD)
No. 4 date
Year and month of final 0001 to 9912 (BCD)
adjustment date
p+13 to
p+16
p+17
p+18
00 to
15
0: Adjustment
enabled.
1: Notice period in
effect.
Remains set to 1 if the
zero/span adjustment
bit has never been ON.
Remains set to FFFF if
the zero/span adjustment bit has never
been ON.
Input Day of final adjustment 0100 to 3100 (BCD)
No. 2 date
Year and month of final 0001 to 9912 (BCD)
adjustment date
p+9
p+12
Contents
0: Adjustment
enabled.
1: Adjustment period
end
Zero/span adjustment
period notice
Zero/span adjustment
period end
Zero/span adjustment
period notice
Zero/span adjustment
period end
02
p+5
Data range
0, 1
Not used.
0000
Not used.
Input Peak/top value
No. 1
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
Counts the number of
repetitions of conditional operations set in
the Expansion Setting
Area.
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
The bottom or valley
value is stored according to the scaling set in
the DM Area.
Bottom/valley value
213
CS1W-PDC11 Isolated-type Direct Current Input Unit
Direction
Word
Direct Cur- p+19
rent Input
Unit to
CPU Unit
p+20
Name
Input Peak/top value
No. 2
00 to
15
Bottom/valley value
p+21
00 to
15
p+22
00 to
15
p+23
00 to
15
p+24
00 to
15
p+25
00 to
15
Input Integral value (lower
No. 1 digit)
p+26
00 to
15
Integral value (upper
digit)
p+27
00 to
15
Input Integral value (lower
No. 2 digit)
p+28
00 to
15
00 to
15
00 to
15
00 to
15
00 to
15
Integral value (upper
digit)
Integral value (lower
digit)
Integral value (upper
digit)
Integral value (lower
digit)
Integral value (upper
digit)
p+29
p+30
p+31
p+32
p+33 and
p+34
214
Bit
00 to
15
00 to
15
Input Peak/top value
No. 3
Bottom/valley value
Input Peak/top value
No. 4
Bottom/valley value
Input
No. 3
Input
No. 4
Not used.
Data range
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
Section 2-12
Contents
Same as for Input No.
1.
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−2147483648 to 2147483647 The integral value for
(80000000 to FFFFFFFF hex, the present value is
00000000 to 7FFFFFFF hex) stored according to the
scaling set in the DM
Area.
−2147483648 to 2147483647
(80000000 to FFFFFFFF hex,
00000000 to 7FFFFFFF hex)
−2147483648 to 2147483647
(80000000 to FFFFFFFF hex,
00000000 to 7FFFFFFF hex)
−2147483648 to 2147483647
(80000000 to FFFFFFFF hex,
00000000 to 7FFFFFFF hex)
0000
Not used.
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
Terminal Connection Diagram
Current inputs
Voltage Inputs
CS1W-PDC11
Voltage
output
device
Voltage
output
device
Voltage
output
device
Voltage
output
device
+
−
+
−
+
−
+
−
V1
B1
COM1
B2
V2
B3
COM2
B4
V3
B5
COM3
B6
V4
B7
COM4
B8
N.C.
B9
N.C.
B10
Note
CS1W-PDC11
A1
N.C.
A2
I1
A3
N.C.
A4
I2
A5
N.C.
A6
I3
A7
N.C.
A8
I4
A9
N.C.
A10
N.C.
A11
+
Current output
device
−
+
Current output
device
−
+
Current output
device
−
+
Current output
device
−
V1
B1
COM1
B2
V2
B3
COM2
B4
V3
B5
COM3
B6
V4
B7
COM4
B8
N.C.
B9
N.C.
B10
N.C.
A1
N.C.
A2
I1
A3
N.C.
A4
I2
A5
N.C.
A6
I3
A7
N.C.
A8
I4
A9
N.C.
A10
N.C.
A11
N.C.
• In both of the above cases, leave all unused inputs open between the
positive and negative terminals (e.g., between B1 and B2 for voltage input
No. 1).
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
• Always short-circuit the V and I terminals when using current input.
• Be sure to tighten the short bars to a torque of 0.5 N·m. Loose short bars
may result in conversion errors.
PDC11 terminal block
+
Current output
device
−
+
Current output
device
−
+
Current output
device
−
+
Current output
device
−
NC
V1+
I1+
COM1
NC
V2+
I2+
COM2
NC
V3+
I3+
COM3
NC
V4+
I4+
COM4
NC
Short bars
NC
NC
NC
NC
215
Section 2-12
CS1W-PDC11 Isolated-type Direct Current Input Unit
Terminal Block Diagram
B1
I1+
A2
COM1
B2
Isolation circuit
250 Ω
1 MΩ
Amplifier
circuit
V1+
A/D
converter
Photocoupler
26 VDC
1 MΩ
V2+
B3
Isolation circuit
I2+
A4
1 MΩ
COM2
B4
Amplifier
circuit
250 Ω
A/D
converter
Photocoupler
Input
selector
Digital
circuits
Connector
5 VDC
1 MΩ
B5
I3+
A6
Isolation circuit
250 Ω
1 MΩ
COM3
B6
Amplifier
circuit
V3+
A/D
converter
Photocoupler
1 MΩ
B7
I4+
A8
COM4
B8
Isolation circuit
250 Ω
1 MΩ
Amplifier
circuit
V4+
A/D
converter
Photocoupler
1 MΩ
Error Processing
Conversion Data Does Not Change.
Probable cause
216
Remedy
The gain for span adjustment is
set to 0.
Set the gain for span adjustment to a value other
than 0.
The minimum and maximum values for process value scaling are
either the same or are set
extremely low.
The input signal type or process
value range is set incorrectly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Set the minimum and maximum values correctly.
Check and reset the input signal type and the
process value range settings.
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring.
Check whether an input error has been detected
in the I/O Area.
CS1W-PDC11 Isolated-type Direct Current Input Unit
Section 2-12
Values are Not Converted as Intended.
Probable cause
The input signal type or process
value scaling is set incorrectly.
Remedy
Check and reset the input signal type and the
process value scaling settings.
The zero/span adjustment data is
incorrect.
Check and correct the zero/span adjustment settings.
The square root function is operat- Set the square function so that it does not opering.
ate.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
The scaling value is greater than
the Unit’s resolution.
Insert 0.01-µF to 0.1-µF ceramic capacitors
between the I+ and COM input terminals.
Increase the number of values for calculating the
moving average in mean value processing.
Reduce the scaling value.
217
Section 2-13
CS1W-PDC55 Isolated-type Direct Current Input Unit
2-13 CS1W-PDC55 Isolated-type Direct Current Input Unit
Overview
The CS1W-PDC55 Isolated-type Direct Current Input Unit provides 8 directcurrent inputs, and sends the data to the CPU Unit each cycle. All inputs are
isolated.
CS1W-PDC55
RUN
ERC
ERH
54321
EDCBA
543210
F
X101 0 X100
9876
F
EDCBA
MACH
No.
9876
System Configuration
CS1W-PDC55
8 DC inputs
(0 to 10 V, 0 to 5 V,
1 to 5 V, 4 to 20 mA)
Features
• Up to 8 DC inputs can be made to each Unit.
0 to 10 V, 0 to 5 V, 1 to 5 V, 4 to 20 mA can be selected separately for
each input.
• Scaling values are transmitted to the CPU Unit in four digits hexadecimal.
• There is isolation between channels, so unwanted signal paths between
input signals can be prevented.
• Square root function.
• Process value alarms (Two internal alarms per input can be output to
memory and two alarms per input can be output to specified I/O memory
area addresses using indirect address specifications).
• Alarm ON-delay timer and hysteresis for process value.
• Zero/span adjustment capability during operation.
• Sensor error detection.
• Maximum or minimum process value can be specified for when a sensor
error is detected.
Model Information
Unit classification
Model number
CS-series Special I/O CS1W-PDC55
Unit
218
Inputs
8
Input types
0 to 10 V, 0 to 5 V, 1 to 5 V, and 4 to 20 mA (separate
for each input)
Section 2-13
CS1W-PDC55 Isolated-type Direct Current Input Unit
Block Diagram
CPU Unit
Expansion Setting Area
CPU Unit CIO Area
H, L
Process value
Process value alarm
Input error alarm
Alarm output
I/O refresh
Isolated-type Direct Current Input Unit
Process value alarm
Output limit: -5% to +105%
Square root
Zero/span adjustment
Process value scaling
Input calculations
Input range
A/D conversion, moving average
DC signal sensor
0 to 10 V, 0 to 5 V, 1 to 5 V, 4 to 20 mA
Specifications
Item
Specifications
Model
Applicable PLC
CS1W-PDC55
CS Series
Unit classification
Mounting position
Maximum number of Units
CS-series Special I/O Unit
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Unit numbers
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
219
CS1W-PDC55 Isolated-type Direct Current Input Unit
Areas for data
exchange with
CPU Unit
Item
Special I/O Unit
Area
Section 2-13
Specifications
10 words/Unit
Isolated-type Direct Current Input Unit to CPU Unit:
All process values, process value alarms (L, H), conversion data enabled flags, input
errors
DM Area words 100 words/Unit
allocated to
CPU Unit to Isolated-type Direct Current Input Unit:
Special I/O Units Input signal type (separate for each input), process value alarm setting (L, H), zero/
span adjustment value, Square root function.
Expansion Con- 1 word/Unit
trol/Monitor Area CPU Unit to Isolated-type Direct Current Input Unit:
Process value alarms
Number of inputs
8
Input signal type
Scaling
Data storage in the CIO Area
Accuracy (25°C)
Temperature Characteristics
Resolution
Input signal range
Maximum input rating
Input impedance
Warmup time
0 to 10 V, 0 to 5 V, 1 to 5 V, 4 to 20 mA
Input signal type and scaling to industrial
(separate for each input). (“Not used” can units are separate for each of the 8 inputs.
be selected).
Note Input signal type and scaling to
industrial units are set in the DM
Data to be stored in the allocated words in
Area.
the CIO area must be scaled (Any minimum and maximum values can be set.) (8 Example:
inputs set separately.) Data can be conInput signal type: 4 to 20 mA; industrial
verted at 0% to 100%.
unit scaling: 0 to 500 m3/h (after square
The value derived from carrying out the
root extraction). DM Area settings are as
following processing in order of the actual follows:
process data in the input range is stored Input signal type: 3 (0003 hex)
in four digits hexadecimal (binary values) Industrial unit maximum value stored: 500
in the allocated words in the CIO Area.
(01F4 hex)
1) Scaling → 2) Zero/span adjustment → Industrial unit minimum value stored: 0
3) Square root calculation → 4) Output
(0000 hex)
limits
±0.3% of full scale
For voltage inputs: 100 ppm/°C of full scale.
For current inputs: 120 ppm/°C of full scale.
1/16,000 of full scale
For all inputs:
−5 to +105%
Voltage: ±15 V
Current: ±30 mA
For current inputs: 250 Ω (typical)
For voltage inputs: 1 MΩ min.
10 min
Conversion period
Maximum time to store data in
CPU Unit
250 ms/8 inputs
Conversion period + one CPU Unit cycle
Input error detection
Detects sensor error at each input and turns ON the Sensor error Flag.
The process value overrange direction for when a sensor error occurs can be specified. (High: 105% of input range; low: −5% of input range)
220
Section 2-13
CS1W-PDC55 Isolated-type Direct Current Input Unit
Function
Item
Process value
alarm
Specifications
Process value 8-point alarm (L H), hysteresis, and ON-delay timer (0 to 60 s) are
available.
Two alarms per input (L, H) can be output to addresses in the CIO Area specified in
the Expansion Setting Area.
Square root cal- When the maximum value for process value scaling is A and the minimum value is B,
culation
(Supported only Output = (A − B) × (input − B) + B
when input is 1
Drop-out: Output approx. 7% max. linear (output = input) characteristic
to 5 v or 4 to
Note 1 The square root function can only be used when the maximum scaling value
20 mA.)
is greater than the minimum scaling value. The square root will not be found if
the maximum is smaller than the minimum.
Note 2 When the square root function is used, set the scaling values after square
root calculation (e.g., for flow rates or other values) for the process value scaling A and B settings.
Isolation
Between inputs and between inputs and PLC signals: Isolation by transformer and
photocoupler.
Insulation resistance
20 MΩ max. (at 500 V DC).
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and FG plate
Dielectric strength
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and FG plate
1,000 VAC, 50/60 Hz 1 min., detection current: 1 mA
Between all channels
500 VAC, 50/60 Hz 1 min., detection current: 1 mA
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Three LED indicators on front panel (for normal operation, errors detected at the
Direct Current Input Unit, and errors detected at the CPU Unit).
Front panel connector
Effect on CPU Unit cycle time
Sensor input connector terminal block (detachable)
0.4 ms
Current consumption
Dimensions
5 V DC at 180 mA max., 26 V DC at 60 mA max.
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
450 g max.
DM Area Allocations
First word: word m. m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Data range
Default
Data contents
Input Input Input Input Input Input Input Input Decimal HexadecNo. 1 No. 2 No. 3 No. 4 No. 5 No. 6 No. 7 No. 8
imal
m
12345, 0 3039,
0000 hex
0000 hex Default block read command
Specifies the direction of data transfer
when the PLC is turned ON or the Unit is
restarted for DM Area words m+1 to
m+97.
• 12345 (3039 hex): The data in words
m+2 to m+98 is transferred from the
Direct Current Input Unit to the CPU
Unit. When the transfer is completed,
the value will become 0000 hex.
• Other than 12345 (such as 0000 hex):
The data in the allocated words of DM
Area is transferred from the CPU Unit to
the Direct Current Input Unit.
0 to 83
0
(0000
hex)
Display parameter
m+1
0000 to
0053 hex
Address of Data Range Error (See note
1.)
221
Section 2-13
CS1W-PDC55 Isolated-type Direct Current Input Unit
DM Area address
Data range
Default
Data contents
Input Input Input Input Input Input Input Input Decimal HexadecNo. 1 No. 2 No. 3 No. 4 No. 5 No. 6 No. 7 No. 8
imal
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m+6
m+10 m+14 m+18 m+22 m+26 m+30 Low to high limit for
sensors.
4200
(1068
hex)
Process value H (high limit) alarm setting
m+3
m+7
m+11 m+15 m+19 m+23 m+27 m+31
−200
(FF38
hex)
Process value L (low limit) alarm setting
Span adjustment value
m+4
m+8
m+12 m+16 m+20 m+24 m+28 m+32 0 to
32000
0000 to
10000
7D00 hex (2710
hex)
m+5
m+9
m+13 m+17 m+21 m+25 m+29 m+33 –9999 to D8F1 to
9999
270F hex
Set value × 0.0001
Zero adjustment value
0
(0000
hex)
Set value × 0.1
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Direct Current Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Direct Current Input Unit is restarted.
Operation settings (See note 2.)
m +34
(See
note 2.)
(See
note 2.)
0
(0000
hex)
04: Data display (binary or BCD)
08: Minus sign display format for BCD display
12: Data direction at sensor error
13: Data held at sensor error
m+35 m+41 m+47 m+53 m+59 m+65 m+71 m+77 0 to 3,
15
0000 to
0003,
000F hex
0 (0000
hex)
0: 0 to 10 V; 1: 0 to 5 V; 2: 1 to 5 V; 3: 4 to
20 mA; F: Not used
m+36 m+42 m+48 m+54 m+60 m+66 m+72 m+78 0 to
9999
0000 to
270F hex
0
(0000
hex)
m+37 m+43 m+49 m+55 m+61 m+67 m+73 m+79 0 to 60
0000 to
0
003C hex (0000
hex)
Input signal type
Alarm hysteresis
Set value × 0.1
Alarm ON-delay time
Unit: s
Square root function
(Supported only when input is 1 to 5 V or 4
to 20 mA.)
m+38 m+44 m+50 m+56 m+62 m+68 m+74 m+80 0, 1
0000,
0001 hex
0 (0000
hex)
Square root extraction (when maximum
scaling value > minimum scaling value)
0: Disable; 1: Enable
Process value scaling
4000
m+39 m+45 m+51 m+57 m+63 m+69 m+75 m+81 –32000 8300 to
(0FA0
to 32000 FFFF
hex, 0000 hex)
to 7D00
hex
Value stored for maximum value in range
(span)
0 (0000
m+40 m+46 m+52 m+58 m+64 m+70 m+76 m+82 –32000 8300 to
hex)
to 32000 FFFF
hex, 0000
to 7D00
hex
Value stored for minimum value in range
(zero)
Expansion Setting Area enable
m+83
0, 1
0000,
0001 hex
0
(0000
hex)
m+84
(See note 3.)
0 to
6143
0000 to
0
17FF hex (0000
hex)
0: Disabled
1: Enabled
Expansion Setting Area address
222
CIO area (fixed)
Number of words.
CS1W-PDC55 Isolated-type Direct Current Input Unit
Note
Section 2-13
1. The ERC indicator on the Unit's front panel will light if an out-of-range setting is made in either Setting Group 1 (continuously refreshed area) or 2
(initial settings area). The offset from word m to the first word containing
the out-of-range error will be stored as the Address of Data Range Error in
the DM Area in four digits hexadecimal.
2. The operation settings are shown in the following table
3. A range check is not performed for the Expansion Setting Area address set
in word m+84. Be sure to check this address before starting actual operation.
Word
m+34
Bits
04
08
12
13
Description
Settings
Data format
0: Binary (Negative values are given as 2’s complements).
1: BCD
Minus sign display format for BCD display 0: “F” used to indicate the minus sign.
1: Leftmost bit used to indicate the minus sign.
The setting is disabled if bits 04 to 07 are set to 0.
Data direction at sensor error
0: Goes to upper limit at sensor error
1: Goes to lower limit at sensor error
Data held at sensor error
0: Follow the setting of Data direction at sensor error
1: If there is a sensor error when the upper limit is
exceeded, hold the data at the upper limit. If there is a
sensor error when the lower limit is exceeded, hold
the data at the lower limit.
Example: For a binary data format and a data direction at sensor error of
“lower limit,” word m+18 contains 1000.
223
Section 2-13
CS1W-PDC55 Isolated-type Direct Current Input Unit
Expansion Setting Area
First word: word o. (o = address specified in word m+60 in the DM Area)
Direction
Direct Current
Input Unit to
CPU Unit
Word
o
Bit
00
Name
Input No. 1
01
02
Input No. 2
03
04
05
06
07
08
Input No. 5
Input No. 6
13
14
15
0, 1
0, 1
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Input No. 8
Same as for input No. 1.
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Input No. 7
0, 1
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
11
12
0: Process value < Set value
1: Process value ≥ Set value
Process value
H (high limit)
alarm
09
10
Process value
H (high limit)
alarm
Process value
H (high limit)
alarm
Input No. 4
Contents
0: Process value > Set value
1: Process value ≤ Set value
Process value
H (high limit)
alarm
Input No. 3
Data range
Process value L 0, 1
(low limit) alarm
0, 1
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
0, 1
Note If either of the following changes is made for the Expansion Setting Area for
the CS1W-PTS55/PTS56/PDC55, the previous data will be left in the Expansion Setting Area even after the change has been made.
Clear the previous data when changing either of these settings.
• The Expansion Setting Area Enable setting is changed from “enabled” to
“disabled.”
• The Expansion Setting Area Address setting is changed while the Expansion Setting Area Enable setting is set to “enabled.”
224
Section 2-13
CS1W-PDC55 Isolated-type Direct Current Input Unit
CIO Area Allocations
First word: n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Direct Current
Input Unit to
CPU Unit
Word
n
Bit
00
Name
Data range
Input No. 1 Process value L 0, 1
(low limit) alarm
Contents
0: Process value > Set value
1: Process value ≤ Set value
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
0: Process value < Set value
1: Process value ≥ Set value
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
08
Input No. 5
09
10
Input No. 6
11
12
Input No. 7
13
14
Input No. 8
15
n+1
00 to 15 Input No. 1
n+2
n+3
00 to 15 Input No. 2
00 to 15 Input No. 3
n+4
n+5
00 to 15 Input No. 4
00 to 15 Input No. 5
n+6
n+7
00 to 15 Input No. 6
00 to 15 Input No. 7
n+8
00 to 15 Input No. 8
Same as for input No. 1.
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value
0, 1
0, 1
0, 1
0, 1
0, 1
0, 1
0, 1
Depends on type of
input.
The integral value for the
present value is stored
according to the scaling set
in the DM Area.
225
Section 2-13
CS1W-PDC55 Isolated-type Direct Current Input Unit
Direction
Direct Current
Input Unit to
CPU Unit
Word
n+9
Bit
Name
Sensor error
Data range
00
Input No. 1
01
02
Input No. 2
Input No. 3
0, 1
0, 1
03
04
Input No. 4
Input No. 5
0, 1
0, 1
05
06
Input No. 6
Input No. 7
0, 1
0, 1
07
Input No. 8
08 to 14 Not used.
0, 1
15
Note
0, 1
Conversion data enabled flag 0, 1
(See note.)
Contents
0: Normal
1: Error
0: Data disabled
1: Data enabled
1. The Conversion Data Enabled Flag remains OFF after the PLC is turned
ON or the Unit is restarted until the AD conversion data becomes stable
(approximately 2 to 4 s), then is ON during operation.
2. When the default settings are transferred, the upper and lower limits for the
process value alarms will be the same as the input error detection levels.
If the upper or lower limit is exceeded in this condition, a process value
alarm will not be output and only an input error will be detected.
Terminal Connection Diagram
Voltage Inputs
CS1W-PDC55
+
Voltage
output device
Voltage
output device
Voltage
output device
Voltage
output device
+
+
+
-
V1+
I1+
COM1
V3+
I3+
COM3
V5+
I5+
COM5
V7+
I7+
COM7
B1
B2
B3
B4
B5
B6
B7
B8
B9
B10
B11
B12
A1
A2
A3
A4
A5
A6
A7
A8
A9
A10
A11
A12
V2+
I2+
COM2
V4+
I4+
COM4
V6+
I6+
COM6
V8+
I8+
COM8
+
+
+
+
-
Voltage
output device
Voltage
output device
Voltage
output device
Voltage
output device
Current inputs
CS1W-PDC55
+
Current output
device
Current output
device
Current output
device
Current output
device
226
+
+
+
-
V1+
I1+
COM1
V3+
I3+
COM3
V5+
I5+
COM5
V7+
I7+
COM7
B1
B2
B3
B4
B5
B6
B7
B8
B9
B10
B11
B12
A1
A2
A3
A4
A5
A6
A7
A8
A9
A10
A11
A12
V2+
I2+
COM2
V4+
I4+
COM4
V6+
I6+
COM6
V8+
I8+
COM8
+
+
+
+
-
Current output
device
Current output
device
Current output
device
Current output
device
Section 2-13
CS1W-PDC55 Isolated-type Direct Current Input Unit
Note
• In both of the above cases, leave all unused inputs open between the
positive and negative terminals.
• Always short-circuit the V and I terminals when using current input.
• Be sure to tighten the short bars to a torque of 0.5 N·m. Loose short bars
may result in conversion errors.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
Terminal Block Diagram
B1
B2
Amplifier
circuit
B3
Double
integral
A/D
Reference
power supply
No. 2 input
Reference power supply
Photocoupler
No. 3 input
Reference power supply
No.4 input
A5
A6
Amplifier
circuit
A7
Double
integral
A/D
Isolation circuit
No.1 input
24 V DC
Reference
power supply
5 V DC
Photocoupler
No. 2 input
Photocoupler
No.5 input
B7
B8
Amplifier
circuit
B9
Double
integral
A/D
Reference
power supply
Photocoupler
Connector
No. 3 input
Photocoupler
Digital circuits
No. 6 input
Photocoupler
No. 7 input
Photocoupler
A10
A11
A12
Amplifier
circuit
Double
integral
A/D
Reference
power supply
Photocoupler
No. 6 input
Reference power supply
No. 7 input
Reference power supply
Isolation circuit
No.8 input
227
Section 2-13
CS1W-PDC55 Isolated-type Direct Current Input Unit
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
Set the gain for span adjustment to a value other
than 0.
The minimum and maximum values for process value scaling are
either the same or are set
extremely low.
The input signal type or process
value range is set incorrectly.
Set the minimum and maximum values correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring.
Check whether an input error has been detected
in the I/O Area.
Check and reset the input signal type and the
process value range settings.
Values are Not Converted as Intended.
Probable cause
Remedy
The input signal type or process
value scaling is set incorrectly.
The zero/span adjustment data is
incorrect.
The square root function is operating.
Check and reset the input signal type and the
process value scaling settings.
Check and correct the zero/span adjustment settings.
Set the square function so that it does not operate.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
Insert 0.01-µF to 0.1-µF ceramic capacitors
between the I+ and COM input terminals.
Increase the number of values for calculating the
moving average in mean value processing.
The scaling value is greater than
the Unit’s resolution.
228
Reduce the scaling value.
Section 2-14
CS1W-PTR01 Power Transducer Input Unit
2-14 CS1W-PTR01 Power Transducer Input Unit
Overview
The CS1W-PTR01 Power Transducer Input Unit provides up to eight inputs of
0 to 1 mA or –1 to 1 mA from power transducers, and sends the data to the
CPU Unit each cycle.
CS1W-PTR01
System Configuration
CS1W-PTR01
Eight power transducer inputs
(0 to 1 mA or −1 to 1 mA)
Features
• Up to eight inputs of 0 to 1 mA or –1 to 1 mA from a power transducer can
be separately connected.
• Scaling values are sent to the CPU Unit in four digits hexadecimal.
• The inrush input limit function temporarily limits the process value input to
a given set value when it increases from a low value (2%), in order to prevent process values from being jumped up by an inrush current when the
motor is started up, and so on. (This function is available for inputs of 0 to
1 mA only.)
• Two values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing (for four values).
• Zero/span adjustment capability during operation.
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PTR01
Inputs
8
Input types
Either of the following can be selected separately:
0 to 1 mA, or –1 to 1 mA.
229
Section 2-14
CS1W-PTR01 Power Transducer Input Unit
Block Diagram (Order of Processing)
The processing for the eight inputs is as shown in the following diagram.
CPU Unit CIO Area
H, L
Process value
Process value alarm
I/O refresh
Power Transducer Input Unit
Process value alarm
Output limit: −15% to +115%
Inrush input limit
Can be used when input range is 0 to 1 mA.
Zero/span adjustment
Process value scaling
Input calculations
Input range
A/D conversion, moving average (for four values)
0 to 1 mA, −1 to 1 mA
Power transducer
Type: current, voltage, effective power, reactive power,
power rate, phase, frequency
Specifications
Item
Specifications
Model
Applicable PLC
CS1W-PTR01
CS Series
Unit classification
Mounting position
Maximum number of Units
CS-series Special I/O Unit
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Unit numbers
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
230
Section 2-14
CS1W-PTR01 Power Transducer Input Unit
Item
Specifications
Special I/O Unit 10 words/Unit
Area
Power Transducer Input Unit to CPU Unit:
All process values, process value alarms (L, H)
DM Area words 100 words/Unit
allocated to
CPU Unit to Power Transducer Input Unit:
Special I/O
Input signal type, scaling of process value in industrial units, process value alarm setUnits
ting (L, H), inrush input upper limit, inrush input upper limit time, zero/span adjustment
value, etc.
Number of inputs
8
Areas for data
exchange with
CPU Unit
Input signal type
User-defined scaling in industrial
units
Data storage in the CIO Area
Either 0 to 1 mA or –1 to 1 mA.
Scaling required for the above input signals. (Any minimum and maximum values
can be set.) (8 inputs set separately.)
The value derived from carrying out the
following processing in order of the process value data is stored in four digits
hexadecimal (binary values) in the allocated words in the CIO Area.
1) Mean value processing → 2) Scaling →
3) Zero/span adjustment → 4) Inrush input
limit → 5) Output limits
Input signal type and scaling to industrial
units are separate for each of the 8 inputs.
Note Input signal type and scaling to
industrial units are set in the DM
Area.
Example:
Input signal type: 0 to 1 mA from power
transducer; industrial unit scaling: 0 to
500 W. DM Area settings are as follows:
Input signal type: 0 (0000 hex)
Industrial unit maximum value stored: 500
(01F4 hex)
Industrial unit minimum value stored:
0 (0000 hex)
Accuracy (25°C)
±0.2% of full scale
Temperature coefficient
Resolution
±0.015%/°C of full scale
1/4,096 of full scale
Input signal range
Input impedance
For 0 to 1 mA: –15 to 115%; for –1 to 1 mA: –7.5 to 107.5%
100 Ω (typical)
Warmup time
10 min
Response time
Conversion period
1.2 s (travel time from input 0% to 90%, for step input)
200 ms/8 inputs
Maximum time to store data in
CPU Unit
Input error detection
Conversion period + one CPU Unit cycle
Operation at input disconnection
Function
Inrush input
limit
Process value
alarm
Mean value
processing
(input filter)
Isolation
Insulation resistance
None.
Process value corresponding to 0 mA stored.
When the process value is increased from 2% or less, the inrush input limit function
limits the increase for a set time. (It is available only for inputs of 0 to 1 mA.) This function can be used to prevent sudden process value increases due to inrush currents
caused by motor startup and so on.
Upper limit value: –32,000 to 32,000
Upper limit time: 0 to 100 s
Process value 2-point alarm (H, L), hysteresis, and ON-delay timer (0 to 60 s) are
available.
Calculates the moving average for the past four process values (every 200 ms), and
stores that value in the CIO Area as the process value.
Between inputs: No isolation
Between input terminals and PLC signals: Isolation by transformer and photocoupler
20 MΩ (at 500 V DC) between inputs and internal PLC signals
Dielectric strength
Between inputs and internal PLC signals: 1,000 V AC, at 50/60 Hz, for 1 min, leakage
current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Three LED indicators on front panel (for normal operation, errors detected at the
Power Transducer Input Unit, and errors related to the CPU Unit).
231
Section 2-14
CS1W-PTR01 Power Transducer Input Unit
Item
Front panel connector
Specifications
Sensor input connector terminal block (detachable)
Effect on CPU Unit cycle time
Current consumption
0.3 ms
5 V DC at 150 mA max., 26 V DC at 80 mA max.
Dimensions
Weight
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
450 g max.
Standard accessories
None
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Input
No. 5
Input
No. 6
Data range
Input
No. 7
Input
No. 8
m
Decimal
12345,
0
Default
Data contents
Hexadecimal
3039, 0000
hex
0000 hex Default block read command
Specifies the direction of data
transfer when the PLC is turned ON
or the Unit is restarted for DM
words m+2 to m+89.
• 12345 (3039 hex): The data in
words m+2 to m+89 is transferred
from the Power Transducer Input
Unit to the CPU Unit. When the
transfer is completed, the value
will become 0000 hex.
• Other than 12345 (3039 hex)
(such as 0000 hex): The data in
the allocated words of DM Area is
transferred from the CPU Unit to
the Power Transducer Input Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2 m+6 m+
10
m+
14
m+
18
m+
22
m+
26
m+
30
–32768 8000 to FFFF
to
hex, 0000 to
32767
7FFF hex
4200
(0FA0
hex)
Process value H (high limit) alarm
setting
(Set at process value scaling
value.)
m+3 m+7 m+
11
m+
15
m+
19
m+
23
m+
27
m+
31
–32768 8000 to FFFF
hex, 0000 to
to
32767
7FFF hex
0
(0000
hex)
Process value L (low limit) alarm
setting
(Set at process value scaling
value.)
Zero/span adjustment
m+4 m+8 m+
12
m+
16
m+
20
m+
24
m+
28
m+
32
0 to
32000
0000 to 7D00
hex
10000
(2710
hex)
Gain for span adjustment
(set value x 0.0001)
m+5 m+9 m+
13
m+
17
m+
21
m+
25
m+
29
m+
33
–32000 8300 to FFFF
to
hex, 0000 to
32000
7D00 hex
0
(0000
hex)
Zero adjustment value
(Set at process value scaling
value.)
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Power Transducer Input Unit
if word m contains other than 12345 when the PLC is turned ON or the Power Transducer Input Unit is restarted.
m+
34
m+
41
m+
48
m+
55
m+
62
m+
69
m+
76
m+
83
0, 1
0000 to 0001
hex
0
(0000
hex)
Input signal type
0: 0 to 1 mA
1: –1 to 1 mA
m+
35
m+
42
m+
49
m+
56
m+
63
m+
70
m+
77
m+
84
–32000 8300 to FFFF
to
hex, 0000 to
32000
7D00 hex
4000
(0FA0
hex)
Value stored for maximum value in
range (span)
m+
36
m+
43
m+
50
m+
57
m+
64
m+
71
m+
78
m+
85
–32000 8300 to FFFF
to
hex, 0000 to
32000
7D00 hex
0
(0000
hex)
Value stored for minimum value in
range (zero)
Process value scaling
Alarm supplementary functions
m+
37
m+
44
m+
51
m+
58
m+
65
m+
72
m+
79
m+
86
0 to
32000
0000 to 7D00
hex
40
(0028
hex)
Alarm hysteresis
(Set at process value scaling
value.)
m+
38
m+
45
m+
52
m+
59
m+
66
m+
73
m+
80
m+
87
0 to 60
0000 to 003C
hex
0
(0000
hex)
Alarm ON-delay time (Unit: s)
232
Section 2-14
CS1W-PTR01 Power Transducer Input Unit
DM Area address
Data range
Decimal
Default
Data contents
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Input
No. 5
Input
No. 6
Input
No. 7
Input
No. 8
Hexadecimal
m+
39
m+
46
m+
53
m+
60
m+
67
m+
74
m+
81
m+
88
0 to
100
0000 to 0064
hex
0
(0000
hex)
Inrush upper limit time (Unit: s)
0: No limit
m+
40
m+
47
m+
54
m+
61
m+
68
m+
75
m+
82
m+
89
–32000 8300 to FFFF
to
hex, 0000 to
32000
7D00 hex
4000
(0FA0
hex)
Inrush upper limit value
m+
93
m+
94
m+
95
m+
96
m+
97
0 to 89
0
(0000
hex)
Address of Data Range Error (See
note.)
Inrush input limit function
Storage parameter
m+
90
m+
91
m+
92
0000 to 0059
hex
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Address of Data Range
Error in the DM Area in four digits hexadecimal. For more information, refer to
1-6 Error Processing.
233
Section 2-14
CS1W-PTR01 Power Transducer Input Unit
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Word
Power
n
Transducer
Input Unit to
CPU Unit
Bit
00
Input No. 1
01
02
Input No. 2
Input No. 3
Input No. 4
07
08
Input No. 5
09
10
Input No. 6
15
234
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
Process value L (low
limit) alarm
0, 1
0, 1
Same as for input No.
1.
Same as for input No.
1.
0, 1
0, 1
Same as for input No.
1.
Process value L (low
limit) alarm
0, 1
Same as for input No.
1.
Process value H (high 0, 1
limit) alarm
Input No. 7
13
14
Process value L (low
limit) alarm
0: Process value <
Set value
1: Process value ≥ Set
value
Same as for input No.
1.
Process value H (high 0, 1
limit) alarm
11
12
0, 1
Contents
0: Process value >
Set value
1: Process value ≤ Set
value
Process value H (high 0, 1
limit) alarm
05
06
Data range
Process value H (high 0, 1
limit) alarm
03
04
Name
Process value L (low
limit) alarm
Input No. 8
Process value L (low
limit) alarm
Process value H (high
limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
0, 1
Same as for input No.
1.
0, 1
0, 1
0, 1
Same as for input No.
1.
Section 2-14
CS1W-PTR01 Power Transducer Input Unit
Direction
Word
Power
n+1
Transducer
Input Unit to
CPU Unit
n+2
Bit
00 to 15
Name
Input No. 1 process value
Data range
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
00 to 15
Input No. 2 process value
n+3
00 to 15
Input No. 3 process value
n+4
00 to 15
Input No. 4 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+5
00 to 15
Input No. 5 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+6
00 to 15
Input No. 6 process value
n+7
00 to 15
Input No. 7 process value
n+8
00 to 15
Input No. 8 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
Contents
The present process
value is stored
according to the scaling set in the allocated
words of the DM Area.
Terminal Connection Diagram
CS1W-PRT01 Power Transducer Input Unit
Power
transducer
Power
transducer
Power
transducer
Power
transducer
−
−
−
−
−
Power
transducer
−
Power
transducer
−
Power
transducer
−
Power
transducer
Note Leave all unused inputs open between the positive and negative terminals
(e.g., between A1, and A2 for input No. 1). (They can, however, be short-circuited with the lead wire.)
235
Section 2-14
CS1W-PTR01 Power Transducer Input Unit
Terminal Block Diagram
CS1W-PRT01 Power Transducer Input Unit
Input No. 3
Input No. 4
Input No. 5
Filter
circuit
100 Ω
Filter
circuit
100 Ω
Filter
circuit
100 Ω
Filter
circuit
100 Ω
Filter
circuit
100 Ω
Filter
circuit
−
−
−
−
Input No. 6
−
Isolation circuit
A/D converter
Digital computation circuit
Connector
Input No. 2
100 Ω
−
Multiplexer
Input No. 1
5 V DC
To CPU Unit
Isolated power supply circuit
Input No. 7
Input No. 8
100 Ω
Filter
circuit
100 Ω
Filter
circuit
−
−
26 V DC
Error Processing
Conversion Data Does Not Change.
Probable cause
The gain for span adjustment is
set to 0.
Remedy
Set the gain for span adjustment to a value other than 0.
The minimum and maximum val- Set the minimum and maximum values correctly.
ues for process value scaling are
either the same or are set
extremely low.
The input signal type or process Check and reset the input signal type and the process value range settings.
value range is set incorrectly.
An input device is malfunctioning, Check whether the input voltage or current has changed. Check for faulty or disconinput wiring is faulty, or wiring is
nected wiring.
disconnected.
Values are Not Converted as Intended.
Probable cause
The input signal type or process
value scaling is set incorrectly.
Remedy
Check and reset the input signal type and the process value scaling settings.
The zero/span adjustment data is Check and correct the zero/span adjustment settings.
incorrect.
The inrush input limit function is
operating.
236
Set the inrush input limit function so that it does not operate.
CS1W-PTR01 Power Transducer Input Unit
Section 2-14
Converted Values are Unstable.
Probable cause
Input signals are being affected
by external noise.
Remedy
Change the connection paths of the input signal lines. (Separate them from sources of
noise or use shielded cable.)
Insert 0.01-µF to 0.1-µF ceramic capacitors between the positive and negative input
terminals.
The scaling value is greater than
the Unit’s resolution.
Reduce the scaling value.
237
Section 2-15
CS1W-PTR02 Analog Input Unit (100 mV)
2-15 CS1W-PTR02 Analog Input Unit (100 mV)
Overview
The CS1W-PTR02 Analog Input Unit provides up to eight inputs of 0 to
100 mV or –100 to 100 mA, and sends the data to the CPU Unit each cycle.
CS1W-PTR02
System Configuration
CS1W-PTR02
Eight DC inputs
(0 to 100 mV or −100 to 100 mV)
Features
• Up to eight inputs of 0 to 100 mV or –100 to 100 mV can be separately
connected.
• Scaling values are sent to the CPU Unit in four digits hexadecimal.
• The inrush input limit function temporarily limits the process value input to
a given set value when it increases from a low value (2%), in order to prevent process values from being jumped up by an inrush current when the
motor is started up, and so on. (This function is available for inputs of 0 to
100 mV only.)
• Two values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing (for four values).
• Zero/span adjustment capability during operation.
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PTR02
8
238
Inputs
Input types
Either of the following can be selected separately: 0 to
100 mV, or –100 to 100 mV.
Section 2-15
CS1W-PTR02 Analog Input Unit (100 mV)
Block Diagram (Order of Processing)
The processing for the eight inputs is as shown in the following diagram.
CPU Unit CIO Area
H, L
Process value
Process value alarm
I/O refresh
Analog Input Unit
Process value alarm
Output limit: −15% to +115%
Inrush input limit
Can be used when input range is 0 to 100 mV.
Zero/span adjustment
Process value scaling
Input calculations
Input range
A/D conversion, moving average (for four values)
0 to 100 mV, −100 to 100 mV
Sensor/signal converter
239
Section 2-15
CS1W-PTR02 Analog Input Unit (100 mV)
Specifications
Item
Specifications
Model
CS1W-PTR02
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
Special I/O Unit 10 words/Unit
Area
Analog Input Unit to CPU Unit:
All process values, process value alarms (L, H)
DM Area words
allocated to
Special I/O
Units
100 words/Unit
CPU Unit to Analog Input Unit:
Input signal type, scaling of process value in industrial units, process value alarm setting (L, H), inrush input upper limit, inrush input upper limit time, zero/span adjustment
value, etc.
8
Input signal type
User-defined scaling in industrial
units
Either 0 to 100 mV or –100 to 100 mV.
Input signal type and scaling to industrial
units
are separate for each of the 8 inputs.
Scaling required for the above input signals. (Any minimum and maximum values Note Input signal type and scaling to
industrial units are set in the DM
can be set.) (8 inputs set separately.)
Area.
The value derived from carrying out the
Example:
following processing in order of the proInput signal type: 0 to 100 mV; industrial
cess value data is stored in four digits
unit scaling: 0 to 500. DM Area settings
hexadecimal (binary values) in the alloare as follows:
cated words in the CIO Area.
1) Mean value processing → 2) Scaling → Input signal type: 0 (0000 hex)
3) Zero/span adjustment → 4) Inrush input Industrial unit maximum value stored: 500
limit → 5) Output limits
(01F4 hex)
Industrial unit minimum value stored: 0
(0000 hex)
Number of inputs
Data storage in the CIO Area
Accuracy (25°C)
Temperature coefficient
±0.2% of full scale
±0.015%/°C of full scale
Resolution
Input signal range
1/4,096 of full scale
For 0 to 100 mV: –15 to 115%; for –100 to 100 mV: –7.5 to 107.5%
Input impedance
Warmup time
Balanced: 1 MΩ min. (typical); unbalanced: 20 kΩ (typical)
10 min
Response time
Conversion period
1.2 s (travel time from input 0% to 90%, for step input)
200 ms/8 inputs
Maximum time to store data in
CPU Unit
Conversion period + one CPU Unit cycle
Input error detection
Operation at input disconnection
None
Undefined
Function
Inrush input
limit
When the process value is increased from 2% or less, the inrush input limit function
limits the increase for a set time. (It is available only for inputs of 0 to 100 mV.) This
function can be used to prevent sudden process value increases due to inrush currents caused by motor startup and so on.
Upper limit value: –32,000 to 32,000
Upper limit time: 0 to 100 s
Process value
alarm
Process value 2-point alarm (H, L), hysteresis, and ON-delay timer (0 to 60 s) are
available.
Mean value
processing
(input filter)
Calculates the moving average for the past four process values (every 200 ms), and
stores that value in the CIO Area as the process value.
Isolation
240
Between inputs: No isolation
Between input terminals and PLC signals: Isolation by transformer and photocoupler.
Section 2-15
CS1W-PTR02 Analog Input Unit (100 mV)
Item
Insulation resistance
Specifications
20 MΩ (at 500 V DC) between inputs and internal PLC signals.
Dielectric strength
Between inputs and internal PLC signals: 1,000 V AC, at 50/60 Hz, for 1 min, leakage
current: 10 mA max.
Terminal block (detachable)
External connections
Unit number settings
Indicators
Front panel connector
Set by rotary switches on front panel, from 0 to 95.
Three LED indicators on front panel (for normal operation, errors detected at the Analog Input Unit, and errors related to the CPU Unit).
Sensor input connector terminal block (detachable)
Effect on CPU Unit cycle time
Current consumption
0.3 ms
5 V DC at 150 mA max., 26 V DC at 80 mA max.
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
Standard accessories
450 g max.
None
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Input
No. 5
Input
No. 6
Data range
Input
No. 7
Input
No. 8
m
Decimal
12345,
0
Default
Data contents
Hexadecimal
3039, 0000
hex
0000 hex Default block read command
Specifies the direction of data
transfer when the PLC is turned ON
or the Unit is restarted for DM
words m+2 to m+89.
• 12345 (3039 hex): The data in
words m+2 to m+89 is transferred
from the Analog Input Unit to the
CPU Unit. When the transfer is
completed, the value will become
0000 hex.
• Other than 12345 (such as 0000
hex): The data in the allocated
words of DM Area is transferred
from the CPU Unit to the Analog
Input Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2 m+6 m+
10
m+
14
m+
18
m+
22
m+
26
m+
30
–32768 8000 to FFFF
to
hex, 0000 to
32767
7FFF hex
4000
(0FA0
hex)
Process value H (high limit) alarm
setting
(Set at process value scaling
value.)
m+3 m+7 m+
11
m+
15
m+
19
m+
23
m+
27
m+
31
–32768 8000 to FFFF
hex, 0000 to
to
32767
7FFF hex
0
(0000
hex)
Process value L (low limit) alarm
setting
(Set at process value scaling
value.)
m+4 m+8 m+
12
m+
16
m+
20
m+
24
m+
28
m+
32
0 to
32000
0000 to 7D00
hex
10000
(2710
hex)
Gain for span adjustment
(set value x 0.0001)
m+5 m+9 m+
13
m+
17
m+
21
m+
25
m+
29
m+
33
–32000 8300 to FFFF
to
hex, 0000 to
32000
7D00 hex
0
(0000
hex)
Zero adjustment value
(Set at process value scaling
value.)
Zero/span adjustment
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Analog Input Unit if word m
contains other than 12345 when the PLC is turned ON or the Analog Input Unit is restarted.
m+
34
m+
41
m+
48
m+
55
m+
62
m+
69
m+
76
m+
83
0, 1
0000 to 0001
hex
0
(0000
hex)
Input signal type
0: 0 to 100 mV
1: –100 to 100 mV
241
Section 2-15
CS1W-PTR02 Analog Input Unit (100 mV)
DM Area address
Data range
Decimal
Default
Data contents
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Input
No. 5
Input
No. 6
Input
No. 7
Input
No. 8
Hexadecimal
m+
35
m+
42
m+
49
m+
56
m+
63
m+
70
m+
77
m+
84
–32000 8300 to FFFF
to
hex, 0000 to
32000
7D00 hex
4000
(0FA0
hex)
Value stored for maximum value in
range (span)
m+
36
m+
43
m+
50
m+
57
m+
64
m+
71
m+
78
m+
85
–32000 8300 to FFFF
to
hex, 0000 to
32000
7D00 hex
0
(0000
hex)
Value stored for minimum value in
range (zero)
m+
37
m+
44
m+
51
m+
58
m+
65
m+
72
m+
79
m+
86
0 to
32000
0000 to 7D00
hex
40
(0028
hex)
Alarm hysteresis
(Set at process value scaling
value.)
m+
38
m+
45
m+
52
m+
59
m+
66
m+
73
m+
80
m+
87
0 to 60
0000 to 003C
hex
0
(0000
hex)
Alarm ON-delay time (Unit: s)
m+
39
m+
46
m+
53
m+
60
m+
67
m+
74
m+
81
m+
88
0 to
100
0000 to 0064
hex
0
(0000
hex)
Inrush upper limit time (Unit: s)
0: No limit
m+
40
m+
47
m+
54
m+
61
m+
68
m+
75
m+
82
m+
89
–32000 8300 to FFFF
to
hex, 0000 to
32000
7D00 hex
4000
(0FA0
hex)
Inrush upper limit value
m+
93
m+
94
m+
95
m+
96
m+
97
0 to 89
0
(0000
hex)
Address of Data Range Error (See
note.)
Process value scaling
Alarm supplementary functions
Inrush input limit function
Storage parameter
m+
90
m+
91
m+
92
0000 to 0059
hex
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Address of Data Range
Error in the DM Area in four digits hexadecimal. For more information, refer to
1-6 Error Processing.
242
Section 2-15
CS1W-PTR02 Analog Input Unit (100 mV)
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Word
Analog Input n
Unit to CPU
Unit
Bit
00
Input No. 1
01
02
Input No. 2
Input No. 3
Input No. 4
07
08
Input No. 5
09
10
Input No. 6
15
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
Process value L (low
limit) alarm
0, 1
0, 1
Same as for input No.
1.
Same as for input No.
1.
0, 1
0, 1
Same as for input No.
1.
Process value L (low
limit) alarm
0, 1
Same as for input No.
1.
Process value H (high 0, 1
limit) alarm
Input No. 7
13
14
Process value L (low
limit) alarm
0: Process value <
Set value
1: Process value ≥ Set
value
Same as for input No.
1.
Process value H (high 0, 1
limit) alarm
11
12
0, 1
Contents
0: Process value >
Set value
1: Process value ≤ Set
value
Process value H (high 0, 1
limit) alarm
05
06
Data range
Process value H (high 0, 1
limit) alarm
03
04
Name
Process value L (low
limit) alarm
Input No. 8
Process value L (low
limit) alarm
Process value H (high
limit) alarm
Process value L (low
limit) alarm
Process value H (high
limit) alarm
0, 1
Same as for input No.
1.
0, 1
0, 1
Same as for input No.
1.
0, 1
243
Section 2-15
CS1W-PTR02 Analog Input Unit (100 mV)
Direction
Word
Analog Input n + 1
Unit to CPU
Unit
n+2
Bit
00 to 15
Name
Input No. 1 process value
Data range
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
00 to 15
Input No. 2 process value
n+3
00 to 15
Input No. 3 process value
n+4
00 to 15
Input No. 4 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+5
00 to 15
Input No. 5 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+6
00 to 15
Input No. 6 process value
n+7
00 to 15
Input No. 7 process value
n+8
00 to 15
Input No. 8 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
Contents
The present process
value is stored
according to the scaling set in the allocated
words of the DM Area.
Terminal Connection Diagram
CS1W-PRT02 Analog Input Unit
Voltage output
device
Voltage output
device
Voltage output
device
Voltage output
device
−
−
−
−
−
−
−
−
Voltage output
device
Voltage output
device
Voltage output
device
Voltage output
device
Note Short-circuit all unused inputs between the positive and negative terminals
(e.g., between A1, and A2 for input No. 1) with the lead wire.
244
Section 2-15
CS1W-PTR02 Analog Input Unit (100 mV)
Terminal Block Diagram
Input No. 1
Input No. 2
Filter
circuit
−
Isolation
circuit
Filter
circuit
−
A/D converter
Filter
circuit
Input No. 3
−
Filter
circuit
Input No. 4
−
Input No. 6
Filter
circuit
−
Filter
circuit
−
Connector
Input No. 5
Multiplexer
Digital computation circuit
5 V DC
To CPU Unit
Isolated power supply circuit
26 V DC
Filter
circuit
Input No. 7
−
Input No. 8
Filter
circuit
−
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
Set the gain for span adjustment to a value other than 0.
set to 0.
The minimum and maximum val- Set the minimum and maximum values correctly.
ues for process value scaling are
either the same or are set
extremely low.
The input signal type or process
value range is set incorrectly.
Check and reset the input signal type and the process value range settings.
An input device is malfunctioning, Check whether the input voltage or current has changed. Check for faulty or disconinput wiring is faulty, or wiring is
nected wiring.
disconnected.
Values are Not Converted as Intended.
Probable cause
Remedy
The input signal type or process Check and reset the input signal type and the process value scaling settings.
value scaling is set incorrectly.
The zero/span adjustment data is Check and correct the zero/span adjustment settings.
incorrect.
The inrush input limit function is Set the inrush input limit function so that it does not operate.
operating.
245
CS1W-PTR02 Analog Input Unit (100 mV)
Section 2-15
Converted Values are Unstable.
Probable cause
Input signals are being affected
by external noise.
Remedy
Change the connection paths of the input signal lines. (Separate them from sources of
noise or use shielded cable.)
Insert 0.01-µF to 0.1-µF ceramic capacitors between the positive and negative input
terminals.
The scaling value is greater than
the Unit’s resolution.
246
Reduce the scaling value.
Section 2-16
CS1W-PPS01 Isolated-type Pulse Input Unit
2-16 CS1W-PPS01 Isolated-type Pulse Input Unit
Overview
The CS1W-PPS01 Isolated-type Pulse Input Unit provides up to four pulses
from a device such as a displacement flowmeter, and sends scaled instantaneous values (pulses/time unit) to the CPU Unit each cycle. The accumulated
value can also be calculated at the same time and transferred to the CPU Unit
at each cycle.
CS1W-PPS01
System Configuration
CS1W-PPS01
Four pulse inputs from a device
such as a displacement flowmeter
Features
• Up to four pulse inputs can be connected per Unit.
• Instantaneous values (pulses × pulse weight/time unit) are scaled and
sent to the CPU Unit in four digits hexadecimal.
• Four values for each instantaneous value alarm input
• ON-delay timer for instantaneous value alarm
• Mean value processing
• Zero/span adjustment capability during operation
• Accumulated value output
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PPS01
4
Inputs
Input types
Pulse inputs of 0 to 20,000 pulses/s or 0 to 20 pulses/s
247
Section 2-16
CS1W-PPS01 Isolated-type Pulse Input Unit
Block Diagram (Order of Processing)
The processing for the four inputs is as shown in the following diagram.
CPU Unit CIO Area
HH, H, L, LL
Instantaneous value
Instantaneous value alarm
For each input
Accumulated value
For all inputs
Accumulation Reset Flag
I/O refresh
Pulse Input Unit
ON for 10 s
at reset.
Instantaneous value alarm
Accumulation reset for
all inputs at restart.
Output limit: −15% to +115%
Differential accumulation
Zero/span adjustment
Stepdown
Instantaneous value
(pulse × pulse weight per
time unit) scaling
Instantaneous value (pulses
× pulse weight per time unit)
conversion
Instantaneous value
(pulses × pulse weight per
time unit) average
Pulse weight conversion
(pulse scaling)
Pulse generator
248
Use when the weight/pulse (pulse weight) from the Sensor
is a fraction (not an exponent of 10), and the accumulated
value from the Pulse Input Unit in the CPU Unit is used as is
(without scaling). Do not use at any other time.
Flow, mass, power, rotation pulses, etc.
Section 2-16
CS1W-PPS01 Isolated-type Pulse Input Unit
Specifications
Item
Specifications
Model
CS1W-PPS01
Applicable PLC
Unit classification
CS-series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
Special I/O Unit 10 words/Unit
Area
Pulse Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), accumulated values, Accumulation Reset Bit
DM Area words
allocated to
Special I/O
Units
Number of pulse inputs
Pulse input type
100 words/Unit
CPU Unit to Pulse Input Unit:
Instantaneous value conversion coefficient, instantaneous value scaling, pulse
weight, number of values for moving average, instantaneous value alarm settings (LL,
L, H, HH), zero/span adjustment, etc.
4
Voltage input, no-voltage semiconductor input, contact input (selected individually for
each of 4 inputs, according to connection terminals)
No-voltage semiconductor input: Connected to voltage input terminals (between Fn+
and COMn).
Maximum coefficient speed: 20,000 pulses/s (duty ratio: 50%)
Detection voltage: 4 V DC
Short-circuit current between terminals: 1.2 mA DC
ON resistance: 0.8 kΩ max.
OFF resistance: 5.0 kΩ min.
Voltage input: Connected to voltage input terminals (between Fn+ and COMn).
Waveform: Square wave
Maximum coefficient speed: 20,000 pulses/s (duty ratio: 50%)
ON voltage: 0 to 1 V
OFF voltage: 3 to 30 V
Contact input: Connected to contact input terminals (between Sn+ and COMn).
Maximum coefficient speed: 20 pulses/s (duty ratio: 50%)
Detection voltage: 8 V DC
Short-circuit current between terminals: 2.4 mA DC
ON resistance: 0.8 kΩ max.
OFF resistance: 5.0 kΩ min.
Sensor power supply
For no-voltage semiconductor inputs, etc., a 12-V DC power supply can be provided
for the sensors that are the pulse sources.
Output voltage: 12 V DC ±15%
Current capacity: 30 mA max.
Limit current when short-circuited: 31 to 55 mA
Allowable short-circuit time: No limit
Accumulation conversion period
Maximum time to store data in
CPU Unit
100 ms/4 inputs
Conversion period + one CPU Unit cycle
249
CS1W-PPS01 Isolated-type Pulse Input Unit
Function
Item
Instantaneous
value output
Conversion to
instantaneous
values
Instantaneous
value scaling
Data storage in
the CIO Area
Section 2-16
Specifications
This function can be used to count the number of pulses per time
unit, and to convert the values to instantaneous values (pulses x
pulse weight / time unit). Any of the following can be selected as
the time unit: 1 s, 3 s, 10 s, 30 s, or 60 s. (The time unit is set in the
DM Area.)
Note 1 Errors and fluctuations will increase when the input signal
pulse rate is low, so specify a longer time unit.
Note 2 The instantaneous value is only refreshed at intervals of
the time unit set. Therefore, when the Unit is restarted,
the instantaneous value will be 0000 until the time set as
the time unit has elapsed.
Note 3 When pulse weight conversion is used for accumulated
values, the number of pulses obtained by multiplying the
actual number of input pulses by the pulse weight (0.1000
to 3.2000) for one time unit is used.
This function can be used for
Example 1:
scaling instantaneous values
To obtain a pulse input of 0 to
(pulses x pulse weight/time unit), 2,000 pulses/s for a flow of 0 to
i.e., setting data with respect to 300.0 ml/s:
a maximum value, and storing
Time unit: 1 s
them in the allocated words of
Instantaneous value 100% input:
the CIO Area.
2,000
• When instantaneous value
Maximum value for instanta(pulses x pulse weight/time
neous value scaling (industrial
unit) is 100% input:
units): 3,000
Can be set from 0.001 pulses/
time unit to 32,000 pulses/
Example 2:
time unit.
When pulse inputs at 0 to 2,000
• Maximum value for Instanta- pulses/s are obtained for a flowneous value scaling (industrial rate of 0 to 300.0 ml/s, and the
units):
pulse weight function is used for
Scaling of the above instanta- totaling:
neous value (100% input) is
There are 0.15 ml per pulse, so
possible from
the pulse weight = 0.15.
–32,000 to 32,000 (8300 to
For a flowrate of 0 to 300.0 ml/s,
FFFF, 0000 to 7D00 hex).
0 to 2,000 x 0.15 = 300 pulses/s.
Note When pulse weight conversion is used for accu- Therefore,
mulated values, scaling is Time unit: 1 s
Instantaneous value 100% input:
already performed for
300
each pulse, so an exponent of 10 of the industrial Maximum value for instantaunit is set in the instanta- neous value scaling (industrial
units): 3,000
neous value (pulses x
pulse weight per time unit)
for a 100% input.
The value derived from carrying
out the following processing in
order of the instantaneous value
(pulses x pulse weight/time unit)
is stored in four digits hexadecimal (binary values) in the allocated words in the CIO Area.
1) Mean value processing →
2) Instantaneous value scaling
→ 3) Scaling → 4) Zero/span
adjustment → 5) Output limits
Mean value pro- Calculates the moving average for the specified number of past
cessing (input fil- instantaneous values (1 to 16), and stores that value in the CIO
ter)
Area as the instantaneous value.
Instantaneous
value alarm
250
Instantaneous value 4-point alarm (HH, H, L, LL), hysteresis, and
ON-delay timer (0 to 60 s) are available.
CS1W-PPS01 Isolated-type Pulse Input Unit
Function
Item
Accumulated
output
Pulse weight
conversion
Section 2-16
Specifications
Performs scaling for a single pulse.
Use for the accumulated value when the pulse weight (weight/
pulse) is a fraction (not an exponent of 10). (See note.)
The pulse weight (0.1 to 3.2) is multiplied by the actual number of
pulses input. This number of pulses is used as the input for conversion to instantaneous values (pulses x pulse weight per time unit)
and the input for totaling prior to stepdown.
Example: When the pulse weight from the flowmeter is 0.26 ml/
pulse, the pulse weight is set to 0.26. When one pulse (0.26 ml) is
input, it is treated as a 0.26 pulse, and when two pulses (0.52 ml)
are input, they are treated as a 0.52 pulse.
The weight per pulse becomes 1 ml, so to calculate in the CPU
Unit the simple (unscaled) value in industrial units (ml) based on
the accumulated value from the Pulse Input Unit (value in words
n+5 to n+8), the value can be calculated simply using 1 ml/pulse.
Note When the accumulated value from the Pulse Input Unit in the
CPU Unit is not used (i.e., when only the instantaneous
value is used), pulse weight conversion is not required. Use
instantaneousness value scaling to convert to industrial
units.
Accumulated
value
Isolation
The accumulated number of pulses (0 to 9,999 pulses) for each
input is stored in the allocated words of the CIO Area. When 9,999
is exceeded, the value returns to 0 and starts counting again.
Note When pulse weight conversion is used, the accumulated
value for the number of pulses obtained by multiplying the
actual number of input pulses by the pulse weight (0.1000 to
3.2000) is used.
Stepdown
When the accumulated value is used, this function prevents accumulated value overflow by reducing the number of input pulses.
The actual number of input pulses is multiplied by one of four factors (x1, x0.1, x0.01, or x0.001), and the number of input pulses
accumulated is then based on that value.
Note This stepdown function operates only for accumulated values, and not for instantaneous values. When the pulse
weight conversion function is used, it uses for the number of
pulses obtained by multiplying the actual number of input
pulses by the pulse weight (0.1000 to 3.2000).
Between inputs and between input terminals and PLC signals: Isolation by transformer and photocoupler
Insulation resistance
Dielectric strength
20 MΩ (at 500 V DC) between inputs
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Three LED indicators on front panel (for normal operation, errors detected at the
Pulse Input Unit, and errors related to the CPU Unit).
Front panel connector
Effect on CPU Unit cycle time
Sensor input connector terminal block (detachable)
0.3 ms
Current consumption
Warmup time
5 V DC at 200 mA max., 26 V DC at 160 mA max.
10 min
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
Standard accessories
450 g max.
None
251
Section 2-16
CS1W-PPS01 Isolated-type Pulse Input Unit
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
m
Decimal
12345, 0
Hexadecimal
3039, 0000 hex
Default
0000 hex
Data contents
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+2 to m+57.
• 12345 (3039 hex): The data in words m+2 to
m+57 is transferred from the Pulse Input Unit
to the CPU Unit. When the transfer is completed, the value will become 0000 hex.
• Other than 12345 (3039 hex) (such as 0000
hex): The data in the allocated words of DM
Area is transferred from the CPU Unit to the
Pulse Input Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Instantaneous value alarm settings
m+2
m+8
m + 14
m + 20
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4200
(1068 hex)
Instantaneous value HH (high high limit) alarm
setting
(Set at instantaneous value scaling value.)
m+3
m+9
m + 15
m + 21
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
4000
(0FA0 hex)
Instantaneous value H (high limit) alarm setting
(Set at instantaneous value scaling value.)
m+4
m + 10
m + 16
m + 22
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
0
(0000 hex)
Instantaneous value L (low limit) alarm setting
(Set at instantaneous value scaling value.)
m+5
m + 11
m + 17
m + 23
–32768 to
32767
8000 to FFFF hex,
0000 to 7FFF hex
–200
(FF38 hex)
Instantaneous value LL (low low limit) alarm
setting
(Set at instantaneous value scaling value.)
m+6
m + 12
m + 18
m + 24
0 to 32000 0000 to 7D00 hex
10000
(2710 hex)
Gain for span adjustment
(Set value x 0.0001)
m+7
m + 13
m + 19
m + 25
–32000 to
32000
0
(0000 hex)
Zero adjustment value
(Set at instantaneous value scaling value.)
Zero/span adjustment
8300 to FFFF hex,
0000 to 7D00 hex
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Pulse Input Unit if word m
contains other than 12345 when the PLC is turned ON or the Pulse Input Unit is restarted.
m + 26
m + 34
m + 42
m + 50
1000 to
32000
03E8 to 7D00 hex
10000
(2710 hex)
Pulse weight
Set value x 0.0001 (0.1 to 3.2)
The result of multiplying the actual number of
pulses input by the value set here is input as
the instantaneous value (pulses x pulse weight
per time unit) for conversion and the input for
totaling prior to stepdown.
m + 27
m + 35
m + 43
m + 51
0 to 3
0000 to 0003 hex
0
(0000 hex)
Accumulated value stepdown
0: x1; 1: x0.1; 2: x0.01; 3: x0.001
The product of multiplying the actual number of
pulses input x the pulse weight x the stepdown
ratio set here is input as the accumulated
value.
m + 28
m + 36
m + 44
m + 52
1 to 16
0001 to 0010 hex
1
(0001 hex)
Number of process values for calculating moving average for mean value processing
m + 29
m + 37
m + 45
m + 53
0 to 32000 0000 to 7D00 hex
1000
(03E8 hex)
Instantaneous value when 100% input
Note When pulse weight conversion is used,
the value set here is the number of
pulses x pulse weight per time unit.
m + 30
m + 38
m + 46
m + 54
---
Bit 00 to 03: 0 to 3
hex
0
(0 hex)
Decimal point position (from right) for instantaneous value when 100% input
---
Bit 04 to 07: 0 to 4
hex
0
(0 hex)
Instantaneous value time unit (matching conversion period)
0: 1 s; 1: 3 s: 2: 10 s; 3: 30 s; 4: 60 s
Instantaneous value conversion function
---
Bit 08 to 15: 00 hex 00 hex
Not used.
m + 31
m + 39
m + 47
m + 55
–32000 to
32000
8300 to FFFF hex
0000 to 7D00 hex
4000
(0FA0 hex)
Maximum instantaneous value scaling value
Data stored in allocated words of CIO Area
when instantaneous value is 100% input as
above
m + 32
m + 40
m + 48
m + 56
0 to 32000 0000 to 7D00 hex
40
(0028 hex)
Alarm hysteresis
(Set at instantaneous value scaling value.)
Alarm supplementary functions
252
Section 2-16
CS1W-PPS01 Isolated-type Pulse Input Unit
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
Decimal
Hexadecimal
Default
Data contents
m + 33
m + 41
m + 49
m + 57
0 to 60
0000 to 003C hex
0
(0000 hex)
Alarm ON-delay time (Unit: s)
m + 60
m + 61
0 to 57
0000 to 0039 hex
0
(0000 hex)
Address of Data Range Error (See note.)
Storage parameter
m + 58
m + 59
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Address of Data Range
Error in the DM Area in four digits hexadecimal. For more information, refer to
1-6 Error Processing.
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Pulse Input
Unit to CPU
Unit
Word
n
Bit
00
Input No. 1
01
02
03
04
Input No. 2
05
06
07
08
Input No. 3
09
10
11
12
13
14
15
Input No. 4
Name
Data range
Instantaneous value
0, 1
LL (low low limit)
alarm
Instantaneous value L 0, 1
(low limit) alarm
Instantaneous value H 0, 1
(high limit) alarm
Instantaneous value
HH (high high limit)
alarm
Instantaneous value
LL (low low limit)
alarm
Instantaneous value L
(low limit) alarm
Instantaneous value H
(high limit) alarm
Instantaneous value
HH (high high limit)
alarm
Instantaneous value
LL (low low limit)
alarm
Instantaneous value L
(low limit) alarm
Instantaneous value H
(high limit) alarm
Instantaneous value
HH (high high limit)
alarm
Instantaneous value
LL (low low limit)
alarm
Instantaneous value L
(low limit) alarm
Instantaneous value H
(high limit) alarm
Instantaneous value
HH (high high limit)
alarm
0, 1
0, 1
Contents
0: Instantaneous
value > Set value
1: Instantaneous
value ≤ Set value
0: Instantaneous
value < Set value
1: Instantaneous
value ≥ Set value
Same as for input No.
1.
0, 1
0, 1
0, 1
0, 1
Same as for input No.
1.
0, 1
0, 1
0, 1
0, 1
Same as for input No.
1.
0, 1
0, 1
0, 1
253
Section 2-16
CS1W-PPS01 Isolated-type Pulse Input Unit
Direction
Pulse Input
Unit to CPU
Unit
Word
n+1
Bit
00 to 15
Name
Input No. 1 instantaneous value
Data range
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+2
00 to 15
Input No. 2 instantaneous value
n+3
00 to 15
Input No. 3 instantaneous value
n+4
00 to 15
Input No. 4 instantaneous value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+5
00 to 15
Input No. 1 accumulated value
0 to 9999
(0000 to 270F hex)
n+6
00 to 15
Input No. 2 accumulated value
n+7
00 to 15
Input No. 3 accumulated value
n+8
00 to 15
Input No. 4 accumulated value
n+9
00
Accumulation Reset Bit
0 to 9999
(0000 to 270F hex)
0 to 9999
(0000 to 270F hex)
0 to 9999
(0000 to 270F hex)
0, 1
Contents
The present instantaneous value is stored
according to the scaling set in the allocated
words of the DM Area.
The accumulated
value for the number
of pulses (after stepdown) is stored here.
When the accumulated value is reset,
this flag turns ON for
10 s. (See note.)
Note The accumulated value is reset when the PLC is turned ON or when the Pulse
Input Unit is restarted.
254
Section 2-16
CS1W-PPS01 Isolated-type Pulse Input Unit
Terminal Connection Diagram
Voltage Input
No-voltage Semiconductor Input
CS1W-PPS01 Isolated-type Pulse Input Unit
CS1W-PPS01 Isolated-type Pulse Input Unit
Voltage pulse generation
−
−
−
−
Contact Input
3-wire Sensor Input
CS1W-PPS01 Isolated-type Pulse Input Unit
CS1W-PPS01 Isolated-type Pulse Input Unit
Internal
power
supply
Internal
power
supply
Internal
power
supply
Internal
power
supply
Note In all of the above cases, leave all unused inputs open between the terminals
(e.g., between B1 and B2 for no-voltage semiconductor input No. 1).
255
Section 2-16
CS1W-PPS01 Isolated-type Pulse Input Unit
Terminal Block Diagram
P1+
+12-V sensor
power supply
A1
4.7 kΩ
S1+
A2
F1+
B1
Input No. 1
4.7 kΩ
Pulse
4.7 kΩ
COM1
B2
P2+
A3
Isolation
circuit
Pulse counter
+12-V sensor
power supply
4.7 kΩ
S2+
A4
F2+
B3
Input No. 2
4.7 kΩ
Pulse
4.7 kΩ
COM2
B4
P3+
A5
Digital computation circuit
Isolation
circuit
+12-V sensor
power supply
4.7 kΩ
S3+
A6
F3+
B5
Input No. 3
Pulse
4.7 kΩ
COM3
Isolation
circuit
Connector
4.7 kΩ
5 V DC
B6
To CPU Unit
Isolated power
supply circuit
26 V DC
P4+
A7
S4+
A8
F4+
B7
+12-V sensor
power supply
4.7 kΩ
Input No. 4
4.7 kΩ
Pulse
4.7 kΩ
COM4
Isolation
circuit
B8
Contact Input (for Metal Contacts)
Voltage Pulse Input
Sensor Power Supply
(Connected to 3-wire Sensor)
(n: Input Nos. 1 to 4)
(n: Input Nos. 1 to 4)
Contact
(n: Input Nos. 1 to 4)
Pulse output
Pulse output
−
−
Error Processing
Accumulated Values Do Not Change.
Probable cause
Remedy
An input device is malfunctioning, Check whether the input voltage has changed to exceed the minimum OFF voltage or
input wiring is faulty, or wiring is
the maximum ON voltage.
disconnected.
Check for faulty or disconnected wiring.
256
CS1W-PPS01 Isolated-type Pulse Input Unit
Section 2-16
Accumulation Data is Different from the Number of Pulses Input.
Probable cause
Input signals are being affected
by external noise.
Remedy
Change the connection paths of the input signal lines. (Separate them from sources of
noise or use shielded cable.)
Insert 0.01-µF to 0.1-µF ceramic capacitors between the positive and negative input
terminals.
The pulse weight or accumulation Check the pulse weight and accumulation stepdown settings.
stepdown settings are incorrect.
Pulses exceeding the allowable
Check the input signal waveform and correct them for the entire system.
frequency are being input.
Pulses with defects such as chat- Check the input signal waveform and remove chattering from external circuitry.
tering are being input.
Instantaneous Values Do Not Change.
Probable cause
The gain for span adjustment is
set to 0.
Remedy
Set the gain for span adjustment to a value other than 0.
The instantaneous value when
Set the instantaneous value when input 100%, and the maximum instantaneous value
input 100%, or the maximum
in the range, to a value other than 0.
instantaneous value in the range,
is set to 0.
Instantaneous Values are Not Converted as Intended.
Probable cause
The instantaneous value when
input 100%, or the maximum
instantaneous value scaling
value, is incorrect.
Remedy
Check the instantaneous value when input 100%, the decimal point position, and the
maximum instantaneous value scaling value.
The zero/span adjustment data is Check and correct the zero/span adjustment settings.
incorrect.
Input pulses are too slow (i.e., the Lengthen the instantaneous value time unit (conversion period).
pulse rate is to low).
There is pulsating in the instanta- Set the number of values for moving average processing.
neous value.
When using pulse weight conver- Set the instantaneous value for 100% input as pulses x pulse weight/time unit.
sion for accumulated values, the
value obtained from pulses x
pulse weight per time unit is not
set for the instantaneous value
for 100% input.
257
Section 2-17
CS1W-PMV01 Isolated-type Analog Output Unit
2-17 CS1W-PMV01 Isolated-type Analog Output Unit
Overview
Each cycle, the CS1W-PMV01 Isolated-type Analog Output Unit converts up
to four analog output set values from the CPU Unit to either 4 to 20 mA or 1 to
5 V, and outputs them. It can also provide answer back for checking actual
output values.
CS1W-PMV01
System Configuration
CS1W-PMV01
Control terminal
Control terminal
Four analog outputs (4 to 20 mA, 1 to 5 V)
Control terminal
Control terminal
Features
• Outputs in either 4 to 20 mA or 1 to 5 V (set separately for each of the four
outputs) the analog output values set in the allocated words of the CPU
Unit’s CIO Area.
• Answer input function.
Actual output signals of 4 to 20 mA or 1 to 5 V are checked by being read
again from the output circuit, and are stored in the allocated words in the
CIO Area. Mean value processing is also possible.
• Output disconnection detection function (current output only).
• Output high/low limit function.
• Rate-of-change limit function.
• Output hold function when CPU Unit errors occur.
When a CPU Unit fatal error (including FALS execution), or a CPU error in
the CPU Unit occurs, or all outputs are turned OFF with the Output OFF
Bit, this function can hold either a preset value or the analog output value
prior to the error.
• Zero/span adjustment capability during operation.
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PMV01
258
Outputs
4
Outputs
4 to 20 mA, 1 to 5 V (separate for each of four outputs)
Section 2-17
CS1W-PMV01 Isolated-type Analog Output Unit
Block Diagram (Order of Processing)
The processing for the four outputs is as shown in the following diagram.
CPU Unit CIO Area
Range: 0 to 4,000
Control output values
Range: 0 to 4,000
Disconnection alarm
Answer input values
I/O refresh
Analog Output Unit
Output when CPU Unit error occurs
(Previous value or specified preset value)
Rate-of-change limit
Zero/span adjustment
Disconnection when
−22% max.
High/low limits
Disconnection check
Zero/span adjustment
D/A conversion
A/D conversion, moving average
Control terminal
Control valves, inverter motor, etc.
259
Section 2-17
CS1W-PMV01 Isolated-type Analog Output Unit
Specifications
Item
Specifications
Model
CS1W-PMV01
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
Special I/O Unit 10 words/Unit
Area
CPU Unit to Analog Output Unit:
Analog output values for each output
Analog Output Unit to CPU Unit:
Answer input values for each output, output disconnection
DM Area words 100 words/Unit
allocated to
CPU Unit to Analog Output Unit:
Special I/O Units Output hold for when CPU Unit error occurs, high/low limit values, rate-of-change limit
values (positive and negative directions), number of values for answer input moving
average, zero/span adjustment for control outputs and answer inputs, etc.
Number of outputs
4
Output signal types
User-defined scaling in industrial
units
Data storage in the CIO Area
Either 4 to 20 mA or 1 to 5 V (separate for each of the four outputs).
Switched according to the connection terminals.
None
0 to 4,000 (0000 to 0FA0 hex), fixed
0: 4 mA or 1 V; 4,000: 20 mA or 5 V
The values derived from carrying out the following processing in order of the values in
the allocated words in the CIO Area are output in analog.
1) Output hold → 2) Rate-of-change limit → 3) Zero/span adjustment → 4) High/low
limits
Therefore, the values after processing are confirmed by analog inputs.
Accuracy (25°C)
When 4 to 20 mA: ±0.1% of full scale
When 1 to 5 V: ±0.2% of full scale
Temperature coefficient
Resolution
±0.015%/°C of full scale
1/4,000 of full scale
Warmup time
Output response time
10 min
0.2 s (travel time from output 0% to 100%, for step output)
D/A conversion period
Maximum time to store data in
CPU Unit
Output signal range
100 ms/4 outputs
Conversion period + one CPU Unit cycle
Approx. –20 to 115%
Allowable load resistance
When 4 to 20 mA: 404 Ω max. (when output range is –20 to 115%) or 458 Ω max.
(when output range is –20 to 100%) (Refer to note.)
When 1 to 5 V: 250 kΩ max.
Output impedance
Voltage when open between terminals
Answer input function
When 1 to 5 V: 250 Ω (typical)
Approx. 15 V
260
The actual analog output values (4 to 20 mA or 1 to 5 V) from the Unit’s output terminals can be read.
Data stored to allocated words of CIO Area:
0 to 4,000 (0000 to 0FA0 hex), fixed. (When 4 mA or 1 V: 0; when 20 mA or 5 V:
4,000)
Accuracy: ±0.2% of full scale
Resolution: 1/2000
Temperature coefficient: ±0.015%/°C
Section 2-17
CS1W-PMV01 Isolated-type Analog Output Unit
Item
Current output disconnection
detection function
Function
Rate-of-change
limit
Output high/low
limits
Output hold
Specifications
When the actual output of 4 to 20 mA from the Analog Output Unit’s output terminals
is 0.5 mA or less, it is regarded as an external output circuit current loop disconnection, and the Output Disconnection Flag turns ON.
This function can be used to control the speed of up and down changes in analog output values.
This function can be used to place high and low limits on analog output values.
This function holds the analog output value to the previous value or to a specified preset value when any of the following CPU Unit errors occurs, and outputs the analog
output value in the CIO Area when the error is cleared.
• CPU Unit fatal error (including FALS execution)
• CPU error in CPU Unit
• All outputs turned OFF with Output OFF Bit
Isolation
Between outputs and between output terminals and PLC signals: Isolation by transformer and photocoupler
Insulation resistance
Dielectric strength
20 MΩ (at 500 V DC) between outputs
Between outputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Front panel connector
Three LED indicators on front panel (for normal operation, errors detected at the Analog Output Unit, and errors related to the CPU Unit).
Output connector terminal block (detachable)
Effect on CPU Unit cycle time
Current consumption
0.3 ms
5 V DC at 150 mA max., 26 V DC at 160 mA max.
Dimensions
35 × 130 × 126 mm (W × H × D)
Note The height including the Backplane is 145 mm.
Weight
Standard accessories
450 g max.
None
Note The following diagram shows the relationship between the allowable load
resistance and the current output.
Current output
22.4 mA (115%)
20 mA (100%)
0.8 mA (−20%)
Allowable load resistance (Ω)
261
Section 2-17
CS1W-PMV01 Isolated-type Analog Output Unit
Output Values According to CPU Unit Status
Analog output values from the Analog Output Unit will be as shown in the following table, depending on the status of the CPU Unit.
CPU Unit status
Fatal error (including
FALS(007) execution)
CPU error
Analog output values from Unit
The output hold function holds the previous value or a
specified preset value.
All outputs turned OFF
with Output OFF Bit
Change of operation
mode from RUN or
Monitor to Program
(See note.)
When the CPU Unit’s I/O
Memory Hold Flag
(A500.12) is OFF.
When the CPU Unit’s I/O
Memory Hold Flag
(A500.12) is ON.
Fatal error or CPU
standby after turning
ON the power supply
Special I/O Unit cyclic
refresh disabled
The output value in the CIO
Area is cleared, and that
value (0000 hex) is output
refreshed.
The output value in the CIO
Area is held at the value
prior to the operation mode
change, and that is output
refreshed.
Either 0 mA or 0 V is output.
Outputs can be refreshed by means of IORF(097) in the
ladder diagram program.
Note Regardless of the CPU Unit’s operation mode (including Program Mode), the
analog output value in the allocated words of the CIO Area is always output
refreshed. As shown in the above table, however, when the operation mode is
changed to Program Mode, the analog output value in the CIO Area is either
cleared or held depending on the status of the CPU Unit’s I/O Memory Hold
Flag (A500.12). In particular, be careful when this flag is ON, because the
value prior to the mode change will be held and that value will be output
refreshed.
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
Output
No. 1
Output
No. 2
Output
No. 3
Output
No. 4
m
Decimal
12345, 0
Hexadecimal
3039, 0000 hex
Default
0000 hex
Data contents
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+2 to m+45.
• 12345 (3039 hex): The data in words m+2 to
m+45 is transferred from the Analog Output
Unit to the CPU Unit. When the transfer is
completed, the value will become 0000 hex.
• Other than 12345 (3039 hex) (such as 0000
hex): The data in the allocated words of DM
Area is transferred from the CPU Unit to the
Analog Output Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Analog output zero/span adjustment
m+2
m+6
m + 10
m + 14
0 to 32000 0000 to 7D00 hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001)
m+3
m+7
m + 11
m + 15
–4000 to
4000
0
(0000 hex)
Zero adjustment value
(Set in units of analog output value resolution.)
F060 to FFFF hex,
0000 to 0FA0 hex
Answer input zero/span adjustment
m+4
m+8
m + 12
m + 16
0 to 32000 0000 to 7D00 hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001)
m+5
m+9
m + 13
m + 17
–4000 to
4000
0
(0000 hex)
Zero adjustment value
(Set in units of analog output value resolution.)
262
F060 to FFFF hex,
0000 to 0FA0 hex
Section 2-17
CS1W-PMV01 Isolated-type Analog Output Unit
Output
No. 1
Output
No. 2
Output
No. 3
Output
No. 4
Decimal
Hexadecimal
Default
Data contents
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Analog Output Unit if word m
contains other than 12345 when the PLC is turned ON or the Analog Output Unit is restarted.
Output hold function
m + 18
m + 25
m + 32
m + 39
0, 1
0000 to 0001 hex
1
(0001 hex)
Output hold value
0: Hold at previous value.
1: Hold at specified preset value (below).
m + 19
m + 26
m + 33
m + 40
–800 to
4600
FCE0 to FFFF hex,
0000 to 11F8 hex
–800
(FCE0 hex)
Preset output value for output hold function
m + 20
m + 27
m + 34
m + 41
–800 to
4600
FCE0 to FFFF hex,
0000 to 11F8 hex
4600
(11F8 hex)
High limit
m + 21
m + 28
m + 35
m + 42
–800 to
4600
FCE0 to FFFF hex,
0000 to 11F8 hex
–800
(FCE0 hex)
Low limit
m + 22
m + 29
m + 36
m + 43
0 to 32000 0000 to 7D00 hex
32000
(7D00 hex)
Positive rate-of-change limit (unit: 1 s)
m + 23
m + 30
m + 37
m + 44
0 to 32000 0000 to 7D00 hex
32000
(7D00 hex)
Negative rate-of-change limit (unit: 1 s)
m + 24
m + 31
m + 38
m + 45
1 to 16
0001 to 0010 hex
4
(0004 hex)
Number of values for answer input moving
average
m + 48
m + 49
0 to 45
0000 to 002D hex
0
(0000 hex)
Address of Data Range Error (See note.)
High/low limit function
Rate-of-change limit function
Answer input mean value processing
Storage parameter
m + 46
m + 47
Note The ERC indicator on the Unit’s front panel will light if an out-of-range setting
is made in either Setting Group 1 or 2. The offset from word m to the first word
containing the out-of-range error will be stored as the Address of Data Range
Error in the DM Area in four digits hexadecimal. For more information, refer to
1-6 Error Processing.
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Wd
CPU Unit to
n
Analog Output n + 1
Unit
Bit
00 to 15
Not used.
Name
---
Data range
---
00 to 15
No. 1 analog output value
–800 to 4600
(FCE0 to 11F8 hex)
n+2
00 to 15
No. 2 analog output value
–800 to 4600
(FCE0 to 11F8 hex)
n+3
00 to 15
No. 3 analog output value
n+4
00 to 15
No. 4 analog output value
–800 to 4600
(FCE0 to 11F8 hex)
–800 to 4600
(FCE0 to 11F8 hex)
Analog Output n + 5
Unit to CPU
Unit
n+6
00 to 15
No. 1 answer input value
00 to 15
No. 2 answer input value
n+7
00 to 15
No. 3 answer input value
Set from 0 to 4,000 (0000
to 0FA0 hex).
This value is processed
as follows: Output hold →
rate-of-change limit →
zero/span adjustment →
high/low limit. Then an
analog signal is output as
either 4 to 20 mA or 1 to
5 V.
The actual analog output
signal is input and stored
as a value from 0 to 4,000
(0000 to 0FA0 hex), for
either 4 to 20 mA or 1 to
5 V.
n+8
00 to 15
No. 4 answer input value
n+9
00
01
No. 1 output disconnection 0, 1
No. 2 output disconnection 0, 1
02
03
No. 3 output disconnection
No. 4 output disconnection
–800 to 4600
(FCE0 to 11F8 hex)
–800 to 4600
(FCE0 to 11F8 hex)
–800 to 4600
(FCE0 to 11F8 hex)
Contents
–800 to 4600
(FCE0 to 11F8 hex)
0: Normal
1: Disconnection
0, 1
0, 1
263
Section 2-17
CS1W-PMV01 Isolated-type Analog Output Unit
Terminal Block Diagram
Voltage Output
Current Output
CS1W-PMV01 Isolated-type Analog Output Unit
−
CS1W-PMV01 Isolated-type Analog Output Unit
Load
Load resistance
Load
Load resistance
−
−
−
−
−
−
−
−
−
−
−
−
−
−
−
Load
Load resistance
Load
Load resistance
Note In both of the above cases, short-circuit all unused inputs between [email protected] and
[email protected] (e.g., between terminals B1 and B2 for output No. 1) with the lead
wire.
264
Section 2-17
CS1W-PMV01 Isolated-type Analog Output Unit
Terminal Block Diagram
CS1W-PMV01 Analog Output Unit
Output multiplexer
Isolated output circuit
250 Ω
−
Output No. 1
Isolated input circuit
D/A converter
Isolated output circuit
250 Ω
−
Output No. 2
Isolated input circuit
To CPU Unit
Connector
A/D converter
Input multiplexer
Digital computation circuit
Isolated output circuit
250 Ω
−
Output No. 3
Isolated input circuit
5 V DC
Isolated output circuit
250 Ω
−
Isolated power supply circuit
Isolated input circuit
26 V DC
Output No. 4
1- to 5-V output
4- to 20-mA output
Short-circuit between terminals Vn− and COMn−.
(n: Input Nos. 1 to 4)
(n: Input Nos. 1 to 4)
Voltage input
Current input
−
−
Short-circuit wiring
Error Processing
Outputs Do Not Change.
Probable cause
Remedy
The span adjustment value in the Set the span adjustment to the Unit’s default value.
output zero/span adjustment is
set to 0.
The high/low limit is operating.
The output data is set out of
range.
All outputs have been turned
OFF with the Output OFF Bit.
Set the high/low limit to the Unit’s default value.
Correct the data so that it falls within the range.
Turn OFF the Output OFF Bit.
265
Section 2-17
CS1W-PMV01 Isolated-type Analog Output Unit
Outputs are Not Converted as Intended.
Probable cause
The span adjustment value in the
output zero/span adjustment is
set to 0.
An output device’s I/O specifications do not conform.
The rate-of-change limit is too
low, and the change is too slow.
Remedy
Set the span adjustment to the Unit’s default value.
Check the load impedance.
Change the remote device.
Correct the rate-of-change limit setting.
Outputs are Unstable.
Probable cause
Remedy
Output signals are being affected Change the connection paths of the output signal lines. (Separate them from sources
by external noise.
of noise or use shielded cable.)
Answer Input Data Does Not Change.
Probable cause
The gain for span adjustment is
set to 0.
An output device is malfunctioning, output wiring is faulty, or wiring is disconnected.
Remedy
Set the gain for span adjustment to a value other than 0.
Check whether the output voltage or current has changed. Check for faulty or disconnected wiring. Check whether a disconnection has been detected in the I/O Area.
Values are Not Converted as Intended.
Probable cause
The zero/span adjustment, high/
low limit, or rate-of-change value
is incorrect.
An output device’s I/O specifications do not conform.
Remedy
Check and correct the settings.
Check the load impedance.
Change the remote device.
Converted Values are Unstable.
Probable cause
Remedy
Output signals are being affected Change the connection paths of the output signal lines. (Separate them from sources
by external noise.
of noise or use shielded cable.)
Increase the number of values for calculating the moving average in mean value processing.
266
Section 2-18
CS1W-PMV02 Isolated-type Analog Output Unit
2-18 CS1W-PMV02 Isolated-type Analog Output Unit
Overview
Each cycle, the CS1W-PMV02 Isolated-type Analog Output Unit converts up
to four analog output set values from the CPU Unit to analog voltage signals
and outputs them.
CS1W-PMV02
System Configuration
CS1W-PMV02
Control terminal
Control terminal
Control terminal
Four analog outputs
(0 to 10 V, ±10 V, 0 to 5 V,
±5 V, 0 to 1 V, ±1 V)
Control terminal
Features
• Outputs the analog output values set in the allocated words of the CPU
Unit’s CIO Area. (Supported output ranges: −10 to 10 V, 0 to 10 V, −5 to
5 V, 0 to 5 V, −1 to 1 V, 0 to 1 V.)
• Output high/low limit function.
• Rate-of-change limit function.
• Output hold function when CPU Unit errors occur.
When a CPU Unit fatal error (including FALS execution), or a CPU error in
the CPU Unit occurs, or all outputs are turned OFF with the Output OFF
Bit, this function can hold either a preset value or the analog output value
prior to the error.
• Zero/span adjustment capability during operation.
Model Information
Unit classification
Model number
CS-series Special I/O Unit CS1W-PMV02
Outputs
4
Outputs
−10 to 10 V, 0 to 10 V, −5 to 5 V, 0 to 5 V, −1 to 1 V, 0 to 1 V
267
Section 2-18
CS1W-PMV02 Isolated-type Analog Output Unit
Block Diagram (Order of Processing)
The processing for the four outputs is as shown in the following diagram.
CPU Unit CIO Area
Control output values
Analog Output Unit
I/O refresh
Output when CPU Unit error occurs
(Previous value or specified preset
value)
Rate-of-change limit
Zero/span adjustment
High/low limits
D/A conversion
Control terminal
268
Control valves, inverter motor, etc.
Section 2-18
CS1W-PMV02 Isolated-type Analog Output Unit
Specifications
Item
Specifications
Model
CS1W-PMV02
Applicable PLC
Unit classification
CS Series
CS-series Special I/O Unit
Mounting position
CS-series CPU Rack or CS-series Expansion Rack (Cannot be mounted to C200H
Expansion I/O Rack or SYSMAC BUS Remote I/O Slave Rack.)
80 (within the allowable current consumption and power consumption range)
Maximum number of Units
Unit numbers
Areas for data
exchange with
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
Special I/O Unit 10 words/Unit
Area
CPU Unit to Analog Output Unit:
Analog output values for each output
Analog Output Unit to CPU Unit:
None
DM Area words 100 words/Unit
allocated to
CPU Unit to Analog Output Unit:
Special I/O Units Output hold for when CPU Unit error occurs, high/low limit values, rate-of-change limit
values, zero/span adjustment for control outputs, etc.
Number of outputs
Output signal types
Data storage in the CIO Area
4
0 to 10 V, 0 to 5 V, 0 to 1 V, −10 to 10 V, −5 to 5 V, −1 to 1 V
(Each output point can be set individually.)
Scaling is possible for each of the above signal types individually.
(The data corresponding to the minimum and maximum output values can be set
freely.)
±32,000 (8300 to FFFF hex, 0000 to 7D00 hex)
Accuracy (25°C)
Temperature coefficient
±0.1% of full scale
±0.015%/°C of full scale
Resolution
Warmup time
−10 to 10 V, −1 to 1 V:
1/16,000 of full scale
0 to 10 V, 0 to 1 V, −5 to 5 V: 1/8,000 of full scale
0 to 5 V:
1/4,000 of full scale
10 min
Output response time
D/A conversion period
50 ms max. (travel time from output 0% to 90%, for step output)
40 ms/4 outputs
Maximum output delay time
Output signal range
Output response time + conversion period + one CPU Unit cycle
–15 to 115% (–7.5 to 107.5% for ±10-V and ±1-V ranges)
Allowable load resistance
Output impedance
10 kΩ min.
0.5 Ω max.
Voltage when open between terminals
Answer input function
---
Current output disconnection
detection function
None
Function
Rate-of-change
limit
This function can be used to control the speed of up and down changes in analog output values.
Output high/low
limits
Output hold
This function can be used to place high and low limits on analog output values.
User-defined scaling in industrial
units
Isolation
None
This function holds the analog output value to the previous value or to a specified preset value when any of the following CPU Unit errors occurs. Normal operation is
restored when the CPU Unit error is cleared.
• CPU Unit fatal error (including FALS execution)
• CPU error in CPU Unit
• CPU Unit’s load interrupted
Between outputs and between output terminals and PLC signals: Isolation by transformer and photocoupler
269
Section 2-18
CS1W-PMV02 Isolated-type Analog Output Unit
Item
Insulation resistance
Specifications
20 MΩ (at 500 V DC) between outputs
Dielectric strength
External connections
Between outputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
Terminal block (detachable)
Unit number settings
Indicators
Set by rotary switches on front panel, from 0 to 95.
Three LED indicators on front panel (for normal operation, errors detected at the Analog Output Unit, and errors related to the CPU Unit).
Front panel connector
Effect on CPU Unit cycle time
Output connector terminal block (detachable)
0.3 ms
Current consumption
Dimensions
5 V DC at 120 mA max., 26 V DC at 120 mA max.
35 × 130 × 126 mm (W × H × D)
Weight
Note The height including the Backplane is 145 mm.
450 g max.
Standard accessories
None
Output Values According to CPU Unit Status
Analog output values from the Analog Output Unit will be as shown in the following table, depending on the status of the CPU Unit.
CPU Unit status
Fatal error (including
FALS(007) execution)
CPU error
Analog output values from Unit
The output hold function holds the previous value or a
specified preset value.
All outputs turned OFF
with Output OFF Bit
Change of operation
mode from RUN or
Monitor to Program
(See note.)
When the CPU Unit’s I/O
Memory Hold Flag
(A500.12) is OFF.
When the CPU Unit’s I/O
Memory Hold Flag
(A500.12) is ON.
Fatal error or CPU
standby after turning
ON the power supply
Special I/O Unit cyclic
refresh disabled
The output value in the CIO
Area is cleared, and that
value (0000 hex) is output
refreshed.
The output value in the CIO
Area is held at the value
prior to the operation mode
change, and that is output
refreshed.
0 V is output.
Outputs can be refreshed by means of IORF(097) in the
ladder diagram program.
Note Regardless of the CPU Unit’s operation mode (including Program Mode), the
analog output value in the allocated words of the CIO Area is always output
refreshed. As shown in the above table, however, when the operation mode is
changed to Program Mode, the analog output value in the CIO Area is either
cleared or held depending on the status of the I/O Memory Hold Flag
(A500.12). In particular, be careful when this flag is ON, because the value
prior to the mode change will be held and that value will be output refreshed.
270
Section 2-18
CS1W-PMV02 Isolated-type Analog Output Unit
DM Area Allocations
m = D20000 + unit number × 100 (unit number: 0 to 95)
Input
No. 1
Input
No. 2
Input
No. 3
Input
No. 4
m
Decimal
12345, 0
Hexadecimal
3039, 0000 hex
Default
0000 hex
Data contents
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+2 to m+61.
• 12345 (3039 hex): The data in words m+2 to
m+61 is transferred from the Analog Output
Unit to the CPU Unit. When the transfer is
completed, the value will become 0000 hex.
• Other than 12345 (such as 0000 hex): The
data in the allocated words of DM Area is
transferred from the CPU Unit to the Analog
Output Unit.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Analog output zero/span adjustment
m+2
m+6
m + 10
m + 14
1 to 32000 0001 to 7D00 hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001)
m+3
m+7
m + 11
m + 15
–16000 to
16000
0
(0000 hex)
Zero adjustment value
(Set in units of analog output value resolution.)
C180 to FFFF hex,
0000 to 3E80 hex
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Analog Output Unit if word m
contains other than 12345 when the PLC is turned ON or the Analog Output Unit is restarted.
Output hold function
m + 18
m + 25
m + 32
m + 39
0, 1
0000 to 0001 hex
1
(0001 hex)
Output hold value
0: Hold at previous value.
1: Hold at specified preset value (below).
m + 19
m + 26
m + 33
m + 40
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
–600
(FDA8 hex)
Preset output value for output hold function
High/low limit function
m + 20
m + 27
m + 34
m + 41
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4600
(11F8 hex)
High limit
m + 21
m + 28
m + 35
m + 42
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
–600
(FDA8 hex)
Low limit
m + 22
m + 29
m + 36
m + 43
0 to 32000 0000 to 7D00 hex
32000
(7D00 hex)
Positive rate-of-change limit (unit: 1 s)
m + 23
m + 30
m + 37
m + 44
0 to 32000 0000 to 7D00 hex
32000
(7D00 hex)
Negative rate-of-change limit (unit: 1 s)
m + 48
m + 49
0 to 61
0
(0000 hex)
Address display for data range error
Rate-of-change limit function
Display Parameter
m + 46
m + 47
0000 to 003D
Expansion Settings (initial settings area): Parameters that are transferred one time from the CPU Unit to the Analog Output Unit if
word m contains other than 12345 when the PLC is turned ON or the Analog Output Unit is restarted.
Output signal type
m + 50
m + 53
m + 56
m + 59
0, 1, 2, 3,
8, 9
0000 hex
0001 hex
0002 hex
0003 hex
0008 hex
0009 hex
1
(0001 hex)
0: –10 to 10 V
1: 0 to 10 V
2: –5 to 5 V
3: 0 to 5 V
8: –1 to 1 V
9: 0 to 1 V
m + 51
m + 54
m + 57
m + 60
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
4000
(0000 hex)
Setting data that corresponds to maximum output value (span)
m + 52
m + 55
m + 58
m + 61
–32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
Setting data that corresponds to minimum output value (zero)
Output data scaling
271
Section 2-18
CS1W-PMV02 Isolated-type Analog Output Unit
CIO Area Allocations
n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Wd
CPU Unit to
n
Analog Output n + 1
Unit
Bit
00 to 15
Name
Data range
Contents
Not used.
---
---
00 to 15
No. 1 analog output value
–32000 to 32000
(8300 to FFFF hex, 0000
to 7D00 hex)
n+2
00 to 15
No. 2 analog output value
–32000 to 32000
(8300 to FFFF hex, 0000
to 7D00 hex)
n+3
00 to 15
No. 3 analog output value
n+4
00 to 15
No. 4 analog output value
Analog Output n + 5
Unit to CPU
n+6
Unit
n+7
00 to 15
Not used.
–32000 to 32000
(8300 to FFFF hex, 0000
to 7D00 hex)
–32000 to 32000
(8300 to FFFF hex, 0000
to 7D00 hex)
---
Set from –32000 to 32000
(8300 to FFFF hex, 0000
to 7D00 hex).
This value is processed
as follows: Output hold →
rate-of-change limit →
zero/span adjustment →
high/low limit. Then an
analog signal is output.
n+8
n+9
00 to 15
00 to 15
---
00 to 15
00 to 15
Terminal Connection Diagram
CS1W-PMV02
Isolated-type Analog Output Unit
+
+
Load
−
V1L
B1
COM1
B2
V2L
B3
COM2
B4
V3L
B5
COM3
B6
V4L
B7
COM4
B8
N.C.
B9
N.C.
B10
A1
V1H
A2
COM1
A3
V2H
A4
COM2
A5
V3H
A6
COM3
A7
V4H
A8
COM4
A9
N.C.
A10
N.C.
A11
N.C.
Load
−
B terminals: 0 to 1 V, ±1 V; A terminals: 0 to 10 V, 0 to 5 V, ±10 V, ±5 V
Note
1. Although signals 1/10 of the size of the A-row terminal output signals are
output to the B terminals, simultaneous use of A (L) and B (H) terminals of
the same number is prohibited.
2. Do not connect [email protected]@ and [email protected]@ for all unused output numbers.
272
Section 2-18
CS1W-PMV02 Isolated-type Analog Output Unit
Terminal Block Diagram
Isolated power
supply circuit
Amplifier
circuit
A1 V1H
Amplifier
circuit
B1 V1L
Amplifier
circuit
A3 V2H
Amplifier
circuit
B3 V2L
Amplifier
circuit
A5 V3H
Amplifier
circuit
B5 V3L
Amplifier
circuit
A7 V4H
Amplifier
circuit
B7 V4L
A2 COM1
Output No. 1
Photocoupler
D/A converter
Isolated power
supply circuit
B2 COM1
A4 COM2
Output No. 2
Photocoupler
D/A converter
Isolated power
supply circuit
B4 COM2
A6 COM3
Output No. 3
Photocoupler
26 V DC
5 V DC
D/A converter
Isolated power
supply circuit
B6 COM3
A8 COM4
Connector
Output No. 4
Photocoupler
D/A converter
Digital
computation
circuit
B8 COM4
Error Processing
Outputs Do Not Change.
Probable cause
The span adjustment value in the output zero/
span adjustment is set to 0.
The high/low limit is operating.
Remedy
Set the span adjustment to the Unit’s default value.
Set the high/low limit to the Unit’s default value.
The output data is set out of range.
Correct the data so that it falls within the range.
All outputs have been turned OFF with the Out- Turn OFF the Output OFF Bit.
put OFF Bit.
Outputs are Not Converted as Intended.
Probable cause
The zero/span adjustment or high/low limit
value is incorrect.
Remedy
Check and correct the settings.
An output device’s I/O specifications do not
conform.
Check the load impedance.
Change the remote device.
The rate-of-change limit is too low, and the
change is too slow.
Correct the rate-of-change limit setting.
273
CS1W-PMV02 Isolated-type Analog Output Unit
Section 2-18
Outputs are Unstable.
Probable cause
Output signals are being affected by external
noise.
274
Remedy
Change the connection paths of the output signal lines. (Separate them
from sources of noise or use shielded cable.)
SECTION 3
Individual Unit Descriptions for CJ Series
This section describes each of the CJ-series Analog I/O Units in detail.
3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
276
3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
288
3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100) . . . . . . . . . . . . . . . . .
302
3-4
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4) . . . . .
312
3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
324
3-6
CJ1W-PH41U Isolated-type Universal Input Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
338
275
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
Overview
The CJ1W-PTS51 Isolated-type Thermocouple Input Unit provides four direct
thermocouple inputs, and sends the data to the CPU Unit each cycle. All
inputs are isolated.
CJ1W-PTS51
51
PTS RUCN
4
ALM
3 2 1 -
ERH
ER
H
MAC
No. 1
X10
X10
0
System Configuration
CJ1W-PTS51
4 thermocouple
inputs (K, J, L, R, S,
T, B)
Features
• Up to four Thermocouples can be connected for each Unit. (The temperature sensor and input range settings are the same for all four inputs.)
• There is isolation between channels, so unwanted circuit paths between
thermocouple inputs can be prevented.
• A variety of temperature specifications are supported. Any of the following
can be selected for thermocouple input: K, J, L, R, S, T, B (Decimal points
can be selected for K, J, and L.)
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal. (Binary or BCD can be selected for the data output format.)
• Process value alarm (with two internal alarms in memory and one external alarm output for each input)
• Alarm ON-delay timer and hysteresis for process value
• Zero/span adjustment capability during operation
• Sensor error detection
• Maximum or minimum process value can be specified for when a sensor
error is detected.
276
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
Model Information
Unit
Model number
classification
CJ-series Spe- CJ1W-PTS51
cial I/O Unit
Inputs
4
Temperature sensor types
K, J, L, R, S, T, B
(The same sensor type is
used for all four inputs.)
Block Diagram (Order of Processing)
The processing for the inputs is as shown in the following diagram.
CPU Unit
CPU Unit Expansion Area Allocations
H, L
Process value
Process value alarm
External alarm outputs
Sensor error
Cold junction sensor error
I/O refresh
Isolated-type Thermocouple Input Unit
Process value alarm
Output limit
Zero/span adjustment
Input calculations
Cold junction temperature
compensation
Thermocouple type
Input range
Cold junction temperature compensation
A/D conversion
Cold junction sensor
Thermocouple
277
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
Specifications
Item
Specifications
Model
CJ1W-PTS51
Applicable PLC
Unit classification
CJ Series
CJ-series Special I/O Unit
Mounting position
Maximum number of Units
CJ-series CPU Rack or CJ-series Expansion Rack
40 (within the allowable current consumption and power consumption range)
Unit numbers
Areas for data
exchange with
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Thermocouple Input Unit to CPU Unit:
All process values, process value alarms (L, H), conversion data enabled flag, sensor
errors, cold junction sensor errors
Special I/O Unit
Area
DM Area words 100 words/Unit
allocated to
CPU Unit to Thermocouple Input Unit:
Special I/O Units Temperature sensor type, input range (same for all I/O), process value alarm setting
(L, H), zero/span adjustment value.
Number of temperature sensor
4
inputs
Temperature sensor types
Data storage in the CIO Area
Accuracy (25°C) (See note.)
Selectable from K, J, L, R, S, T, B. (Same setting for all inputs.)
The actual process data in the input range is stored in four digits hexadecimal (binary
or BCD values) in the allocated words in the CIO Area.
With Celsius selected: ±0.3% of PV or ±1°C, whichever is greater, ±1 digit max.
With fahrenheit selected: ±0.3% of PV or ±2°F, whichever is greater, ±1 digit max.
However, the accuracy of K and T at −100°C or lower and L is ±2°C ±1 digit max.
The accuracy of R and S at 200°C or lower is ±3°C ±1 digit max.
The accuracy of B at 400°C or lower is not specified.
PV: Process value data
Temperature characteristics
Warmup time
Refer to Temperature Characteristics According to Thermocouple Type on page 280.
30 min
Conversion period
Maximum time to store data in
CPU Unit
250 ms/4 inputs.
Conversion period + one CPU Unit cycle
Sensor error detection
Detects sensor error at each input and turns ON the Sensor error Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a sensor error occurs can be specified. (High: Set input range +20°C or +20°F; low: Set input range −20°C or −20°F)
Process value 2-point alarm (HH, H, LL, L), alarm hysteresis, and ON-delay timer (0 to
60 s) are available. External alarm outputs: One per input (H or L).
NPN outputs (with short-circuit protection)
External power supply voltage: 20.4 to 26.4 V DC
Max. switching capacity: 100 mA (for one output)
Leakage current: 0.3 mA max.
Residual voltage: 3 V max.
Between inputs and PLC signal: Transformer for power supply and photocoupler for
signals
Between each input: Transformer for power supply and photocoupler for signals.
20 MΩ max. (at 500 V DC).
Between all output and NC terminals and external AC terminals (Power Supply Unit)
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and all output terminals
Between all external DC terminals (input, output, and NC terminals) and FG plate
Between all input and output terminals and all NC terminals
Function
Process value
alarm
External alarm
outputs
Isolation
Insulation resistance
278
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
Item
Dielectric strength
Specifications
Between all output and NC terminals and external AC terminals (Power Supply Unit)
2,000 VAC, 50/60 Hz 1 min., detection current: 1 mA
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and all output terminals
Between all external DC terminals (input, output, and NC terminals) and FG plate
1,000 VAC, 50/60 Hz 1 min., detection current: 1 mA
Between all channels
500 VAC, 50/60 Hz 1 min., detection current: 1 mA
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Seven LED indicators on front panel (for normal operation, errors detected at the
Thermocouple Input Unit, errors related to the CPU Unit, and four indicators for external alarm outputs.)
0.4 ms
Effect on CPU Unit cycle time
Current consumption (supplied
from Power Supply Unit)
Dimensions
5 V DC at 250 mA max.
31 × 90 × 65 mm (W × H × D)
Weight
150 g max.
Sensor Type and Input Range
The Temperature Sensor type and input range are set in the allocated words
in the DM Area for every four inputs.
The measurable data range is ±20 digits wider than the sensor input range.
Setting
°C
Input
16-bit binary
°F
BCD
[email protected]@@
indicates
minus sign.
F200 to 1300
(−200 to
1300)
16-bit binary
Leftmost bit
indicates
minus sign.
8200 to 1300 FED4 to FFFF to
(−200 to
08FC
1300)
(−300 to −1 to
2300)
BCD
[email protected]@@
indicates
minus sign.
F300 to 2300
(−300 to
2300)
Leftmost bit
indicates
minus sign.
F300 to 2300
(−300 to
2300)
0
K: −200 to
FF38 to FFFF to
1300°C
0514
(−300 to 2300°F) (−200 to −1 to
1300)
1
K: 0.0 to 500°C 0000 to 1388
(0.0 to 900.0°F) (0.0 to 500.0)
2
J: −100 to 850°C FF9C to FFFF to F100 to 0850 8100 to 0850 FF9C to FFFF to
(−100 to 1500°F) 0352
(−100 to 850) (−100 to 850) 05DC
(−100 to −1 to 850)
(−100 to −1 to
1500)
J: 0.0 to 400.0°C 0000 to 0FA0
0000 to 4000 0000 to 4000 0000 to 1D4C
(0.0 to 750.0°F) (0.0 to 400.0)
(0.0 to 400.0) (0.0 to 400.0) (0.0 to 750.0)
T: −200 to 400°C F830 to FFFF to
F999 to 4000 A000 to 4000 F448 to FFFF to
(−300 to
0FA0
(See note 3.) (−200.0 to
1B58
700.0°F)
(−200.0 to −0.1 to (−99.9 to
400.0)
(−300.0 to −0.1 to
400.0)
400.0)
700.0)
F100 to 1500 8100 to 1500
(−100 to
(−100 to
1500)
1500)
L: −100 to 850°C FF9C to FFFF to F100 to 0850 8100 to 0850 FF9C to FFFF to
(−100 to 1500°F) 0352
(−100 to 850) (−100 to 850) 05DC
(−100 to −1 to 850)
(−100 to −1 to
1500)
L: 0.0 to 400.0°C 0000 to 0FA0
0000 to 4000 0000 to 4000 0000 to 1D4C
(0.0 to 750.0°F) (0.0 to 400.0)
(0.0 to 400.0) (0.0 to 400.0) (0.0 to 750.0)
F100 to 1500 8100 to 1500
(−100 to
(−100 to
1500)
1500)
R: 0 to 1700°C
(0 to 3000°F)
0000 to 3000 0000 to 3000
(0 to 3000)
(0 to 3000)
3
4
5
6
7
0000 to 06A4
(0 to 1700)
0000 to 5000 0000 to 5000 0000 to 2328
(0.0 to 500.0) (0.0 to 500.0) (0.0 to 900.0)
0000 to 1700 0000 to 1700 0000 to 0BB8
(0 to 1700)
(0 to 1700) (0 to 3000)
0000 to 9000 0000 to 7999
(0.0 to 900.0) (See note 3.)
(0.0 to 799.9)
0000 to 7500
(0.0 to 750.0)
F999 to 7000
(See note 3.)
(−99.9 to
700.0)
0000 to 7500
(0.0 to 750.0)
B000 to 7000
(−300.0 to
700.0)
0000 to 7500 0000 to 7500
(0.0 to 750.0) (0.0 to 750.0)
279
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
Setting
°C
Input
16-bit binary
°F
BCD
16-bit binary
[email protected]@@
Leftmost bit
indicates
indicates
minus sign. minus sign.
BCD
[email protected]@@
Leftmost bit
indicates
indicates
minus sign. minus sign.
8
S: 0 to 1700°C
(0 to 3000°F)
0000 to 06A4
(0 to 1700)
0000 to 1700 0000 to 1700 0000 to 0BB8
(0 to 1700)
(0 to 1700) (0 to 3000)
0000 to 3000 0000 to 3000
(0 to 3000)
(0 to 3000)
9
B: 400 to 1800°C 0190 to 0708
(See note 2.)
(400 to 1800)
(750 to 3200°F)
0400 to 1800 0400 to 1800 02EE to 0C80
(400 to 1800) (400 to 1800) (750 to 3200)
0750 to 3200 0750 to 3200
(750 to 3200) (750 to 3200)
Note
1. If the indication range is exceeded, a sensor error will occur and the sensor
error bit will turn ON. The process value will be clamped at the lower or upper limit of the indication range, depending on the setting for data direction
at sensor error.
2. The lower limit for B thermocouples is 0°C/°F.
3. The indicator range for BCD display will be clamped at the lower (or upper)
limit in the region between the lower (or upper) limit of the setting range
and the point where a sensor error occurs.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost 4 bits (bits
12 to 15): Lower limit = −99.9, Upper limit = 999.9.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost bit (bit 15):
Lower limit = −799.9, Upper limit = 799.9.
Temperature Characteristics According to Thermocouple Type
Thermocouple
Temperature range
Set value error when ambient
temperature changes by 1°C
0 to 200 °C
200 to 1,000°C
±0.43°C
±0.29°C
1,000 to 1,700°C
±285 ppm of PV
0 to 200 °C
200 to 1,000°C
±0.43°C
±0.29°C
1,000 to 1,700°C
400°C or less
285 ppm of PV
Not specified.
400 to 800°C
800 to 1,000°C
±0.43°C
±0.29°C
1,000 to 1,800°C
−200 to −100°C
285 ppm of PV
±0.29°C
−100 to 400°C
400 to 1,300°C
±0.11°C
±285 ppm of PV
J
−100 to 400°C
400 to 850°C
±0.11°C
±285 ppm of PV
T
−200 to −100°C
−100 to 400°C
±0.29°C
±0.11°C
L
−100 to 400°C
400 to 850°C
±0.11°C
±285 ppm of PV
R
S
B
K
The measured temperature error is calculated as shown in the following
example.
Item
Ambient temperature
Details
30°C
Thermocouple type
K
Measured temperature (PV) 500°C
280
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
Item
Details
Reference accuracy (25°C) ±0.3°C of PV or ±1°C, whichever is greater, ±1 digit.
In this example, ±1.5°C.
Temperature characteristics 400 to 1,300°C: 285 ppm of PV.
In this example, 285 ppm × 500°C = 0.143°C.
Change in ambient temper- 5°C (25 to 30°C).
ature
Overall accuracy =
Reference accuracy + Temperature characteristic x Change in ambient temperature = ±1.5°C + ±0.143°C × 5 = Approx. ±2.2°C ±1 digit.
DM Area Allocations
First word: m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Data range
Input No. Input No. Input No. Input No.
1
2
3
4
m
Decimal
Default
Data contents
Hexadecimal
12345, 0
3039, 0000
hex
0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM words m+1 to m+31.
• 12345 (3039 hex): The data in words m+1
to m+31 is transferred from the Thermocouple Input Unit to the CPU Unit. When
the transfer is completed, the value will
become 0000 hex.
• Other than 12345 (3039 hex) (such as
0000 hex): The data in the allocated
words of DM Area is transferred from the
CPU Unit to the Thermocouple Input Unit.
0 to 34
0000 to 0022
hex
0
(0000 hex)
Address of Data Range Error (See note 1.)
Display parameter
m+1
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m+6
m + 10
m + 14
m+3
m+7
m + 11
m + 15
m+4
m+8
m + 12
m + 16
Low to high limit for sensors
1300
(0514 hex)
Process value H (high limit) alarm setting
−200
(FF38 hex)
Process value L (low limit) alarm setting
Span adjustment value
0 to 9999
0000 to 270F
hex
1000
(03E8 hex)
0 to 32000
0000 to 7D00 10000
hex
(2710 hex)
m+32 contains 0: Set value × 0.001
m+32 contains 1: Set value × 0.0001
Zero adjustment value
m+5
m+9
m + 13
m + 17
–9999 to
9999
D8F1 to 270F 0
hex
(0000 hex)
Set value × 0.1
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Thermocouple Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Thermocouple Input Unit is restarted.
Operation settings (See note 2.)
m + 18
(See note 2.)
(See note 2.) 0
(0000 hex)
00 to 03: Temperature unit (°C or °F)
04 to 07: Data display (binary or BCD)
08 to 11: Minus sign display format for BCD
display
12 to 15: Data direction at sensor error
Sensor type
m + 19
0 to 9
0000 to 0009
hex
0
(0000 hex)
0: K, 1: K (with decimal point), 2: J, 3: J (with
decimal point), 4: T, 5: L, 6: L (with decimal
point), 7: R, 8: S, 9: B
281
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
DM Area address
Data range
Input No. Input No. Input No. Input No.
1
2
3
4
Decimal
Default
Data contents
Hexadecimal
External alarm output mode
m + 20
m + 23
m + 26
m + 29
0, 1
0000, 0001
hex
0
(0000 hex)
Select either high limit or low limit alarm output.
0: High limit alarm; 1: Low limit alarm
m + 21
m + 24
m + 27
m + 30
0 to 9999
0000 to 270F
hex
0
(0000 hex)
m + 22
m + 25
m + 28
m + 31
0 to 60
0000 to 003C 0
hex
(0000 hex)
Unit: s
0, 1
0000, 0001
hex
Span adjustment mode
0: 1/1,000
1: 1/10,000
Alarm hysteresis
set value × 0.1
Alarm ON-delay time
m+32
Note
1 (See note
3.)
1. The ERC indicator on the Unit's front panel will light if an out-of-range setting is made in either Setting Group 1 (continuously refreshed area) or 2
(initial settings area). The offset from word m to the first word containing
the out-of-range error will be stored as the Address of Data Range Error in
the DM Area in four digits hexadecimal.
2. The operation settings are shown in the following table.
Word
m+18
Bits
Description
Settings
00
Temperature unit setting
0: °C
1: °F
04
Data format
0: Binary (Negative values are given as 2’s complements).
1: BCD
08
Minus sign display format for BCD display 0: “F” used to indicate the minus sign.
1: Leftmost bit used to indicate the minus sign.
The setting is disabled if bits 04 to 07 are set to 0.
Data direction at sensor error
0: Goes to upper limit at sensor error
1: Goes to lower limit at sensor error
12
Example: For a temperature in degrees Celsius (°C), a binary data format,
and a data direction at sensor error of “lower limit,” word m+18 contains 1000.
3. Indicates the value after transferring the default value (set when 12345 is
written to word m).
282
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
CIO Area Allocations
First word: n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n
Bit
00
Name
Data range
Input No. 1 Process value L 0, 1
(low limit) alarm
Contents
0: Process value > Set value
1: Process value ≤ Set value
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
0: Process value < Set value
1: Process value ≥ Set value
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
Same as for input No. 1.
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
Process value 0, 1
H (high limit)
alarm
Process value L 0, 1
(low limit) alarm
Process value
H (high limit)
alarm
0, 1
Process value
Depends on type of
input.
Stores data in the data
range specified for each
input type ±20 digits.
Sensor error
0, 1
0, 1
0: Normal
1: Error
08 to 15 Not used.
Thermocouple
Input Unit to
CPU Unit
n+1
n+2
00 to 15 Input No. 1
00 to 15 Input No. 2
n+3
n+4
00 to 15 Input No. 3
00 to 15 Input No. 4
n+5
n+6
00 to 15 Not used.
00 to 15
n+7
n+8
00 to 15
00 to 15
n+9
00
01
Input No. 1
Input No. 2
02
03
Input No. 3
Input No. 4
04 to 07 Not used.
08
Cold junction sensor error
0, 1
0, 1
0, 1
0: Normal
1: Error
09 to 14 Not used.
15
Conversion data enabled flag 0, 1
(See note.)
0: Data disabled
1: Data enabled
Note The Conversion Data Enabled Flag remains OFF after the PLC is turned ON
or the Unit is restarted until the AD conversion data becomes stable (approximately 2 to 4 s), then is ON during operation.
283
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
Terminal Connection Diagram
No. 2
thermocouple input
2−
B1
2+
B2
CJ
B3
CJ
B4
4−
B5
4+
B6
L
ALM2
B7
L
ALM4
B8
0V
B9
Cold junction sensors
No. 4
thermocouple input
External alarm outputs
A1
1−
A2
1+
A3
N.C.
A4
N.C.
A5
3−
A6
3+
A7
ALM1
L
A8
ALM3
L
A9
24V
No. 1
thermocouple input
No. 3
thermocouple input
External alarm outputs
Note Action for Unused Input Terminals
• Short-circuit the positive (+) and negative (−) sides of the thermocouple
input section using a lead wire. For example, short terminals A3 and A2
for No. 1 thermocouple input.
• Cold junction sensors are mounted before shipment. If one of the cold
junction sensors is disconnected, cold junction compensation will stop
and correct measurement of temperatures cannot be made. Always make
sure the cold junction sensors are connected when using the Units.
• Cold junction sensors are calibrated separately for each Unit and connected circuit, so correct temperatures will not be measured if a cold junction sensor from another Unit is used or if the two cold junction sensors in
a Unit are swapped. Use the cold junction sensors as they are provided,
without making any changes.
• Do not connect anything to NC terminals. Do not use NC terminals as
relay terminals.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
284
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
Terminal Block Diagram
Reference
power supply
A2
A1
Double
integral
A/D
Photocoupler
Reference
power supply
B2
Amplifier
circuit
No. 2 input
B1
Double
integral
A/D
Photocoupler
Reference
power supply
A6
Amplifier
circuit
No. 3 input
A5
Double
integral
A/D
No. 4 input
B5
Double
integral
A/D
Digital circuits
Photocoupler
Reference
power supply
B6
Amplifier
circuit
5 V DC
Connector
Amplifier
circuit
No. 1 input
Isolation circuit
■ Input Circuit
Photocoupler
Cold junction
sensors
Reference
power supply
B3
Amplifier
circuit
B4
Double
integral
A/D
Photocoupler
285
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
■ Output Circuit
L
A7
ALM1
L
B7
ALM2
L
A8
ALM3
L
B8
ALM4
Internal Circuit
A9
24V
B9
0V
Output Display
LED
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
The sensor type is not set correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Set the gain for span adjustment to a value other
than 0.
Check and correct the settings.
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring. Check whether a sensor error has been
detected in the I/O Area.
Values are Not Converted as Intended.
Probable cause
286
Remedy
The sensor type is not set correctly.
Check and correct the settings.
The zero/span adjustment data is
incorrect.
Check and correct the zero/span adjustment settings.
Section 3-1
CJ1W-PTS51 Isolated-type Thermocouple Input Unit
Probable cause
Remedy
Cold junction compensation is not Check the Cold Junction Error Flag.
operating.
A compensation conductor has
not been used or a different compensation conductor is used.
Incorrect input wiring (incorrect
thermocouple or compensation
conductor polarity.)
Thermocouple lead or compensating conductor is too long and measurements are being affected by
conductor resistance.
Use the correct compensation conductor for the
thermocouple.
The terminal block temperature is
not uniform due to radiated heat
from peripheral devices.
Mount the unit in a position unaffected by radiated heat.
Correct the input wiring.
Use a thicker compensating conductor.
Change the wiring position and shorten the compensating conductor.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
An airflow is hitting the Unit terminal block.
Insert a 0.01 to 0.1 µF ceramic capacitor
between the positive (+) and negative (−) input
terminals.
Move the terminal block to a position unaffected
by airflow.
287
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Overview
The CJ1W-PTS15 Isolated-type Thermocouple Input Unit provides two direct
thermocouple inputs, and sends the data to the CPU Unit each cycle. All
inputs are isolated.
CJ1W-PTS15
15
PTS RUCN
ERH
ER PS
EXT
H
MAC
No. 1
0
System Configuration
CJ1W-PTS15
Two thermocouple inputs
(B, E, J, K, L, N, R, S, T, U,
WRe5-26, PLII, mV)
Features
• Up to two Thermocouples can be connected for each Unit. (The temperature sensor and input range settings can be made separately for each of
the two inputs.)
• There is isolation between channels, so unwanted circuit paths between
thermocouple inputs can be prevented.
• A variety of temperature specifications are supported. Any of the following
can be selected for thermocouple input: B, E, J, K, L, N, R, S, T, U,
WRe5-26, PLII, mV.
• 1/64,000 resolution for all temperature specifications.
• High-speed conversion of 10 ms/2 inputs.
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal.
• Variable input range setting (input range set by user).
• Four values for each process value alarm input.
• Alarm ON-delay timer for process value
• Mean value processing.
• Rate-of-change calculation.
288
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
•
•
•
•
Two values for each rate-of-change alarm input.
Zero/span adjustment capability during operation.
Disconnection detection.
Maximum or minimum process value can be specified for when a disconnection is detected.
• Adjustment period control.
• Peak and bottom detection.
• Top and valley detection.
Model Information
Unit
Model number
classification
CJ-series Special CJ1W-PTS15
I/O Unit
Inputs
2
Input types
B, E, J, K, L, N, R, S, T, U,
WRe5-26, PLII, or mV selectable for each input
Block Diagram (Order of Processing)
CPU Unit
CPU Unit Expansion Area Allocations
Peak/bottom value
Top/valley value
CPU Unit CIO Area
HH, H, L, LL
Process value
One for all inputs
H, L
Rate-of-change value
Process value alarm
Rate-of-change alarm
Input disconnection alarm
Cold junction sensor error
External power
supply used/not used
I/O refresh
Isolated-type Thermocouple Input Unit
Process value alarm
Rate-of-change alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
+115% or −15% when input disconnection is detected
Output limit: −15% to +115%
Input disconnection check
Zero/span adjustment
Process value scaling
Input calculations
Cold junction temperature compensation
· Thermocouple type
· Input range
· Cold junction temperature compensation
A/D conversion, moving average
Upper cold junction sensor
24-V external power supply
Lower cold junction sensor
Thermocouple
289
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Specifications
Item
Specifications
Model
CJ1W-PTS15
Applicable PLC
Unit classification
CJ Series
CJ-series Special I/O Unit
Mounting position
Maximum number of Units
CJ-series CPU Rack or CJ-series Expansion Rack
40 (within the allowable current consumption and power consumption range)
Unit numbers
Areas for data
exchange with
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Thermocouple Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), conversion data enabled
flags, sensor errors.
Special I/O Unit
Area
DM Area words 100 words/Unit
allocated to
CPU Unit to Thermocouple Input Unit:
Special I/O Units Temperature sensor type, input range (user set), process value alarm setting (L, H),
zero/span adjustment value.
Expansion Con- 35 words/Unit
trol/Monitor Area CPU Unit to Thermocouple Input Unit:
words
Hold function selection start/reset, adjustment period control, control bits
Thermocouple Input Unit to CPU Unit:
Adjustment period warnings/notices (for each input), peak and bottom values, top and
valley values
Expansion Set- 46 words/Unit
ting Area words CPU Unit to Thermocouple Input Unit:
Expansion Setting Area settings, adjustment period control, peak and bottom detection, top and valley detection
Number of temperature sensor
inputs
2
Temperature sensor type
The sensor type, input range, and scaling can be set individually for each of 2 inputs,
which are each selectable from B, E, J, K, L, N, R, S, T, U, WRe5-26, PL II, and mV.
Scaling
Data to be stored in the allocated words in the CIO area must be scaled (with the minimum and maximum values set by user) (2 inputs set separately). For example, data
can be stored at 0% to 100%.
Data storage in the CIO Area
The value derived from carrying out the following processing in order of the actual process data in the input range is stored in four digits hexadecimal (binary values) in the
allocated words in the CIO Area.
1) Mean value processing → 2) Scaling → 3) Zero/span adjustment → 4) Output limits
±0.05% (Depends on the Sensor used and the measured temperature. Refer to Accuracy by Sensor Type and Measured Temperature Range on page 292 for details.)
±0.01%/°C (For full scale of electromotive force. See note.)
Accuracy (25°C)
Temperature coefficient
Resolution
1/64000
Cold junction compensation error ±1°C, at 20 ±10°C
Maximum signal input
Input impedance
±120 mV
20 kΩ min.
Input disconnection detection cur- 0.1 µA (typical)
rent
Warmup time
45 min
Response time
100 ms (travel time from input 0% to 90%, for ±100 mV step input and with moving
average for 4 samples)
Conversion period
Maximum time to store data in
CPU Unit
Disconnection detection
10 ms/2 inputs
Conversion period + one CPU Unit cycle
290
Detects disconnections at each input and turns ON the Disconnection Detection Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a disconnection occurs can be specified. (High: 115% of set input range; low: –15% of set input range)
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Function
Item
Mean value processing (input
filter)
Process value
alarm
Rate-of-change
calculation
Section 3-2
Specifications
Calculates the moving average for the specified number of process values (1 to 128),
and stores that value in the CIO Area as the process value.
Process value 4-point alarm (LL, L, H, HH), alarm hysteresis, and ON-delay timer (0 to
60 s) are available.
Calculates the amount of change per comparison time interval (1 to 16 s).
Rate-of-change
alarm
Rate-of-change 2-point alarm (L, H), alarm hysteresis (shared with process value
alarm), and ON-delay timer (0 to 60 s, shared with process value alarm) are available.
Adjustment
period control
When zero/span adjustment is executed, the date is internally recorded at the Unit.
When the preset zero/span adjustment period and number of days notice have
elapsed (allocated in Expansion Setting Area), this function turns ON a warning flag to
give notice that it is time for readjustment.
This function detects the maximum (peak) and minimum (bottom) analog input values,
from when the Hold Start Bit (output) allocated to the Expansion Control/Monitor Area
turns ON until it turns OFF, and stores them in the Expansion Control/Monitor Area.
This function detects the top and valley values for analog inputs, from when the Hold
Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON until it
turns OFF, and stores them in the Expansion Control/Monitor Area.
Peak and bottom detection
Top and valley
detection
Isolation
Between inputs and PLC signals, and between inputs: Isolation by transformer for
power supply, and by photocoupler for signals.
Cold junction compensation circuit: No isolation from input 2
Insulation resistance
Dielectric strength
20 MΩ (at 500 V DC) between inputs
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Front panel connector
Four LED indicators on front panel (for normal operation, errors detected at the Thermocouple Input Unit, errors related to the CPU Unit, and use of external power supply).
Sensor input connector terminal block (detachable)
Effect on CPU Unit cycle time
Current consumption
0.3 ms
5 V DC at 180 mA max.
External power supply
Dimensions
24 VDC +10%/−15% 60 mA max., inrush current: 20 A for 1 ms max.
(The external 24-VDC power supply must be isolated.)
31 × 90 × 65 mm (W × H × D)
Weight
Standard accessories
150 g max.
Two cold junction sensors (installed in terminal block)
Note The method for calculating the error in temperature measurements, including
the temperature coefficient, is given below. The “full scale of electromotive
force” is the difference between the high limit and low limit converted to electromotive force for each thermocouple.
Example
Ambient temperature: 30 °C
Temperature Sensor: K thermocouple (−270 to 1,372 °C)
Measured temperature: 500 °C
From electromotive force table
−270 °C:
−6.458 mV
1,372 °C:
54.86 mV
Full scale: 61.344
291
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Electromotive conversion of temperature coefficient:
61.344 mV × ±0.01%/°C = ±6.13 µV/°C
Error in electromotive force at 30°C:
±6.13 µV/°C x (30°C − 25°C) = 30.65 µV/°C
Temperature difference between measurement point and terminals on
Unit (ambient temperature) (based on ambient temperature of 30 °C and
Measured temperature of 500 °C):
470 °C
Electromotive force per °C at a measured temperature of 470 °C (from the
electromotive force tables for a K thermocouple):
43 µV/°C
Error in temperature coefficient: ±30.65 µV ÷ 43 µV/°C = ±0.7°C
Error in measured temperature = Accuracy ± Error from temperature coefficient + Error in cold junction compensation = ±0.8°C + ±0.7°C + ±1.0°C =
±2.5°C
Sensor Type and Input Range
The Temperature Sensor type and input range are set in the allocated words
in the DM Area for every four inputs. The input range can be set anywhere
within the measurable input ranges shown in the following table. Accuracy and
resolution, however, are not determined from the set input range, but rather
from the measurable input range shown in the following table. Therefore,
accuracy and resolution do not change even when a narrow input range is set.
Sensor type
DM Area setting
B
0
Measurable input range
0 to 1,820°C
E
J
1
2
−270 to 1,000°C
−210 to 1,200°C
K
N
3
4
−270 to 1,372°C
−270 to 1,300°C
R
5
−50 to 1,768°C
S
T
6
7
−50 to 1,768°C
−270 to 400°C
mV
L
8
9
−100 to 100 mV
−200 to 900°C
U
WRe5-26
10
11
−200 to 600°C
0 to 2,300°C
PLII
12
0 to 1,300°C
Accuracy by Sensor Type and Measured Temperature Range
Sensor type
Temperature range
Standard accuracy
Details
B
0 to 1,820°C
±1.8°C (±0.1%)
400 to 800°C: ±3°C
Less than 400°C: Accuracy is not specified.
E
−270 to 1,000°C
±0.6°C (±0.05%)
−250 to 200°C: ±1.2°C
Less than −250°C: Accuracy is not specified.
J
K
−210 to 1,200°C
−270 to 1,372°C
±0.7°C (±0.05%)
±0.8°C (±0.05%)
N
−270 to 1,300°C
±0.8°C (±0.05%)
−200 to 150°C: ±1.6°C
Less than −200°C: Accuracy is not specified.
R
−50 to 1,769°C
±1.8°C (±0.1%)
0 to 100°C: ±2.5°C
Less than 0°C: Accuracy is not specified.
S
−50 to 1,769°C
±1.8°C (±0.1%)
T
−270 to 400°C
±0.35°C (±0.05%)
0 to 100°C: ±2.5°C
Less than 0°C: 3.2°C
−180 to 0°C: ±0.7°C
−200 to −180°C: ±1.3°C
Less than −200°C: Accuracy is not specified.
292
−250 to 200°C: ±2°C
Less than −250°C: Accuracy is not specified.
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
L
Sensor type
Temperature range
−200 to 900°C
Standard accuracy
±0.5°C (±0.05%)
U
−200 to 600°C
±0.4°C (±0.05%)
WRe5-26
0 to 2,315°C
±1.2°C (±0.05%)
PLII
0 to 1,395°C
±0.7°C (±0.05%)
Details
−100 to 0°C: ±0.5°C
Less than −100°C: ±0.7°C
More than 2,200°C: ±1.4°C
DM Area Allocations
First word: m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Data range
Input No. 1 Input No. 2
Decimal
Default
Data contents
Hexadecimal
m
12345, 0
3039, 0000
hex
0000 hex
Default block read command
Specifies the direction of data transfer when the PLC is turned
ON or the Unit is restarted for DM words m+1 to m+93.
• 12345 (3039 hex): The data in words m+1 to m+93 is transferred from the Thermocouple Input Unit to the CPU Unit.
When the transfer is completed, the value will become 0000
hex.
• Other than 12345 (3039 hex) (such as 0000 hex): The data
in the allocated words of DM Area is transferred from the
CPU Unit to the Thermocouple Input Unit.
m+1
---
---
0 (0000 hex)
Not used.
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m + 10
–32768 to
32767
8000 to FFFF 4200
hex, 0000 to (1068 hex)
7FFF hex
Process value HH (high high limit) alarm setting
(Set at process value scaling value.)
m+3
m + 11
–32768 to
32767
8000 to FFFF 4000
hex, 0000 to (0FA0 hex)
7FFF hex
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m + 12
–32768 to
32767
8000 to FFFF 0
hex, 0000 to (0000 hex)
7FFF hex
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m + 13
–32768 to
32767
8000 to FFFF –200
hex, 0000 to (FF38 hex)
7FFF hex
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m + 14
–32768 to
32767
8000 to FFFF 4000
hex, 0000 to (0FA0 hex)
7FFF hex
Rate-of-change value H (high limit) alarm setting
(Set at rate-of-change scaling value.)
m+7
m + 15
–32768 to
32767
8000 to FFFF 0
hex, 0000 to (0000 hex)
7FFF hex
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
m+8
m + 16
0 to 32000
0000 to 7D00 10000
hex
(2710 hex)
Gain for span adjustment
(set value x 0.0001%)
m+9
m + 17
–32000 to
32000
8300 to FFFF 0
(0000 hex)
hex,
0000 to 7D00
hex
Zero adjustment value
(Set at process value scaling value.)
Rate-of-change value alarm settings
Zero/span adjustment
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Thermocouple Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Thermocouple Input Unit is restarted.
m + 34
m + 49
0 to 12
0000 to 000C 0
hex
(0000 hex)
Sensor type
0: B, 1: E, 2: J, 3: K, 4: N, 5: R, 6: S, 7: T, 8: mV, 9: L, 10: U, 11:
Wre5-26, 12: PLII
m + 35
m + 50
–32000 to
32000
8300 to FFFF 4000
hex, 0000 to (0FA0 hex)
7D00 hex
Maximum input signal value
(set value x 0.1°C/°F or mV)
m + 36
m + 51
–32000 to
32000
8300 to FFFF 0
hex, 0000 to (0000 hex)
7D00 hex
Minimum input signal value
(set value x 0.1°C/°F or mV)
m + 37
m + 52
0, 1
0000, 0001
hex
Unit
0: °C, 1: °F
Process value input range settings
0
(0000 hex)
293
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
DM Area address
Input No. 1 Input No. 2
Data range
Decimal
Default
Data contents
Hexadecimal
m + 38
m + 53
0, 1
0000, 0001
hex
0
(0000 hex)
Process value overrange direction at time of input disconnection
0: High; 1: Low
m + 39
m + 54
–32000 to
32000
8300 to FFFF 4000
hex, 0000 to (0FA0 hex)
7D00 hex
Value stored for maximum value in range (span)
m + 40
m + 55
–32000 to
32000
8300 to FFFF 0
hex, 0000 to (0000 hex)
7D00 hex
Value stored for minimum value in range (zero)
Process value scaling
Alarm supplementary functions
m + 41
m + 56
0 to 32000
0000 to 7D00 40
hex
(0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared with process value
alarm and rate-of-change alarm.)
m + 42
m + 57
0 to 60
0000 to 003C 0
hex
(0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rate-of-change alarm.)
m + 43
m + 58
–32000 to
32000
8300 to FFFF 4000
hex, 0000 to (0FA0 hex)
7D00 hex
m + 44
m + 59
–32000 to
32000
8300 to FFFF –4000
hex, 0000 to (F060 hex)
7D00 hex
m + 45
m + 60
1 to 16
0001 to 0010
hex
m + 46
m + 61
–32000 to
32000
8300 to FFFF 4000
hex, 0000 to (0FA0 hex)
7D00 hex
m + 47
m + 62
–32000 to
32000
8300 to FFFF –4000
hex, 0000 to (F060 hex)
7D00 hex
m + 48
m + 63
1 to 128
0001 to 0080
hex
25
(0019 hex)
Number of process values for calculating moving average for
mean value processing
0 to 99, 100
to 1XX
0000 to 0063
hex, 0064 to
0XXX hex
0
(0000 hex)
Address of Data Range Error (See note.)
---
Expansion Setting Area allocations:
0: Not used; 1: DM; 2: CIO; 3: W; 4: H; 5: EM
Rate-of-change function
1
(0001 hex)
Rate-of-change
range setting
Maximum rate-of-change value (Set value
industrial unit; comparison time interval)
Minimum rate-of-change value (Set value
industrial unit; comparison time interval)
Rate-of-change comparison time interval (Unit: s)
Rate-of-change
value scaling
Value stored for maximum value in range
Value stored for minimum value in range
Mean value processing function
Display parameter
m + 94
m + 95
Expansion Setting Area allocations
m+98
0 to 5
0000 to 0005
hex
m+99
0 to 32767
0000 to 7FFF --hex
Note
Expansion Setting Area first word
1. The ERC indicator on the Unit’s front panel will light if an out-of-range setting is made in either Setting Group 1 (continuously refreshed area) or 2
(initial settings area), or in the Expansion Setting Area. The offset from
word m to the first word containing the out-of-range error will be stored as
the Address of Data Range Error in the DM Area in four digits hexadecimal.
If the first memory address containing the out-of-range error is in the Expansion Setting Area, the Address of Data Range Error will be over +100
(or +100 if the first word in the Expansion Setting Area is an error).]
2. When specifying an expansion setting area, be sure that it does not overlap with other areas that are being used. If areas overlap, the words that
are allocated may be overwritten, resulting in unexpected operation.
3. When specifying the first word in an expansion setting area, be sure that
the end of the memory area is not exceeded.
294
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Expansion Setting Area
First word: word o. (o = address specified in word m+99 in the area specified
in word m+98 in the DM Area)
DM Area address
Input No. 1
Data range
Input No. 2
Decimal
Default
Data contents
Hexadecimal
Setting Group 3 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Thermocouple Input Unit if
word m contains other than 12345, and if Expansion Setting Area settings are allocated, when the PLC is turned ON or the Thermocouple Input Unit is restarted.
Expansion Control/Monitor Area settings
o
0 to 5
0000 to 0005
hex
---
Expansion Control/Monitor Area allocation
0: Not used. 1: DM; 2: CIO; 3: W; 4: H; 5: EM
o+1
0 to 32767
0000 to 7FFF
hex
---
Expansion Control/Monitor Area first word
Zero/span adjustment supplementary function
o+2
o+13
0 to 32000
0000 to 7D00
hex
10000 (2710
hex)
Span adjustment position
(Input span percentage)
o+3
o+14
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Zero adjustment position
(Input span percentage)
o+4
o+15
0 to 9999
0000 to 270F
hex
365 (016D hex) Zero/span adjustment period (Unit: Days)
o+5
o+16
0 to 9999
0000 to 270F
hex
30 (001E hex)
o+6 to o+8
o+17 to
o+19
---
---
0 (0000 hex)
Not used.
o+9
o+20
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
Hysteresis
o+10
o+21
---
---
0 (0000 hex)
Not used.
o+11
o+22
o+12
o+23
Notice of days remaining (Unit: Days)
Not used.
Top and valley hold
Not used.
Note
1. When specifying an expansion control/monitor area be sure that it does not
overlap with other areas that are being used. If areas overlap, the words
that are allocated may be overwritten, resulting in unexpected operation.
2. When specifying the first word in an expansion control/monitor area be
sure that the end of the memory area is not exceeded.
295
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
CIO Area Allocations
First word: n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n
Bit
00
01
02
03
04
Name
Input No. 1 Process value
LL (low low
limit) alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value
HH (high high
limit) alarm
Input No. 2 Process value
LL (low low
limit) alarm
05
0, 1
Contents
0: Process value > Set value
1: Process value ≤ Set value
0, 1
0, 1
0: Process value < Set value
1: Process value ≥ Set value
0, 1
0, 1
Same as for input No. 1.
Process value L 0, 1
(low limit) alarm
Process value 0, 1
H (high limit)
alarm
06
07
296
Data range
Process value
HH (high high
limit) alarm
0, 1
n+1
08 to 15 Not used.
00 to 15 Input No. 1 process value
0
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+2
00 to 15 Input No. 2 process value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n + 3,
n+4
---
0000
----
n+5
00 to 15 Input No. 1 rate-of-change
value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
n+6
00 to 15 Input No. 2 rate-of-change
value
–32768 to 32767
(8000 to FFFF hex,
0000 to 7FFF hex)
The process value rate of
change is stored according
to the scaling set in the allocated words of the DM Area.
n + 7,
n+8
---
---
Not used.
Not used.
--The present process value is
stored according to the scaling set in the allocated
words of the DM Area.
---
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Direction
Thermocouple
Input Unit to
CPU Unit
Word
n+9
Bit
00
Input No. 1
01
02
Name
Data range
Rate-of-change 0, 1
value L (low
limit) alarm
Rate-of-change 0, 1
value H (high
limit) alarm
Input No. 2
03
04 to 07 Not used.
Rate-of-change 0, 1
value L (low
limit) alarm
Rate-of-change 0, 1
value H (high
limit) alarm
0
Contents
0: Rate-of-change value >
Set value
1: Rate-of-change value ≤
Set value
0: Rate-of-change value <
Set value
1: Rate-of-change value ≥
Set value
Same as for input No. 1.
---
08
Input No. 1 input disconnection
0, 1
09
Input No. 2 input disconnection
0, 1
10, 11
12
Not used.
Cold junction sensor error
0
0, 1
13
Zero/span adjustment period 0, 1
end
0: Adjustment enabled
1: Adjustment ended
14
Zero/span adjustment period 0, 1
notice
0: Adjustment enabled
1: Notice period
15
External power supply
0: External power supply not
used
1: External power supply
used
0, 1
0: Normal
1: Disconnection
--0: Normal
1: Error
Note The External Power Supply Flag turns ON after external power is supplied
and the internal voltage stabilizes (which requires approximately 2 s). The
indicator on the front of the Unit will turn ON as soon as external power is supplied.
297
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Expansion Control/Monitor Area Allocations
First word: word p. (p = address specified in word o+1 in the area specified in
word o in the Expansion Setting Area)
Direction
Word
CPU Unit to p
Thermocouple Input
p+1
Unit
Bit
00 to
15
00
01
02 to
07
08
Not used.
Name
Data range
Not used.
Contents
Not used.
Input No. 1 hold function selection
0, 1
Input No. 2 hold function selection
Not used.
0: Peak and bottom
1: Top and valley
0
Not used.
Input No. 1 hold start
0, 1
0: Do not hold.
1: Hold
0
Not used.
0, 1
0: Normal operation
1: Reset hold value.
0
0, 1
Not used.
0: Normal operation
1: Update adjustment
date
(Remains ON while
writing external
FROM.)
Not used.
09
Input No. 2 hold start
10, 11 Not used.
12
13
p+2
298
Input No. 1 hold value reset
Input No. 2 hold value reset
14, 15 Not used.
00
Input No. 1 zero/span adjustment update bit
01
Input No. 2 zero/span adjustment update bit
02 to
15
Not used.
0
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Direction
Word
Thermocou- p+3
ple Input
Unit to CPU
Unit
Bit
00
Input No. 1
01
02
Input No. 2
03
04 to
07
08
Name
Zero/span adjustment
period end
Data range
0, 1
Contents
0: Adjustment
enabled.
1: Adjustment period
end
Zero/span adjustment
period notice
Zero/span adjustment
period end
Zero/span adjustment
period notice
0, 1
0: Adjustment
enabled.
1: Notice period in
effect.
Remains set to 1 if the
zero/span adjustment
bit has never been
ON.
Not used.
0, 1
0, 1
Not used.
0
External FROM Error Flag
0, 1
09 to
15
00 to
15
00 to
15
Not used.
0
Input No. 1
Day of final adjustment date 0100 to 3100
(BCD)
Year and month of final
0001 to 9912
adjustment date
(BCD)
p+6
00 to
15
Input No. 2
Day of final adjustment date 0100 to 3100
(BCD)
p+7
00 to
15
p+8 to
p+15
---
Not used.
p+16
00 to
15
Input No. 1
p+17
00 to
15
p+18
00 to
15
p+19
00 to
15
p+4
p+5
p+20 to --p+34
Year and month of final
adjustment date
Peak/top value
Bottom/valley value
Input No. 2
Peak/top value
Bottom/valley value
Not used.
0: Normal operation
1: External FROM
error
Not used.
Remains set to FFFF
if the zero/span
adjustment bit has
never been ON.
0001 to 9912
(BCD)
0000
Not used.
−32728 to
+32767
(8000 to FFFF
hex, 0000 to
7FFF hex)
−32728 to
+32767
(8000 to FFFF
hex, 0000 to
7FFF hex)
−32728 to
+32767
(8000 to FFFF
hex, 0000 to
7FFF hex)
−32728 to
+32767
(8000 to FFFF
hex, 0000 to
7FFF hex)
Counts the number of
repetitions of conditional operations set
in the Expansion Setting Area.
The bottom or valley
value is stored
according to the scaling set in the DM
Area.
Same as for Input No.
1.
0000
Not used.
299
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Terminal Connection Diagram
Thermocouple
input 1
Thermocouple input 2
NC
B1 (10)
NC
B2 (11)
NC
B3 (12)
1+
B4 (13)
2+
B5 (14)
NC
B6 (15)
NC
B7 (16)
NC
B8 (17)
0V
B9 (18)
A1 (1)
CJ1+
A2 (2)
CJ1−
A3 (3)
1−
A4 (4)
2−
A5 (5)
NC
A6 (6)
CJ2+
A7 (7)
CJ2−
A8 (8)
NC
A9 (9)
24V
Cold
junction
sensor 1
Cold junction sensor 2
24 VDC
Note Action for Unused Input Terminals
• Short-circuit the positive (+) and negative (−) sides of the thermocouple
input section using a lead wire. For example, short terminals A4 and B5
for No. 2 thermocouple input.
• Cold junction sensors are mounted between A1 and A2, and A6 and A7
before shipment. If one of the cold junction sensors is disconnected, cold
junction compensation will stop and correct measurement of temperatures cannot be made. Always make sure the cold junction sensors are
connected when using the Units.
• Cold junction sensors are calibrated separately for each Unit and connected circuit, so correct temperatures will not be measured if a cold junction sensor from another Unit is used or if the two cold junction sensors in
a Unit are swapped. Use the cold junction sensors as they are provided,
without making any changes.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
Terminal Block Diagram
Thermocouples
Isolation circuit
B4
Amplifier
circuit
5 VDC
A/D
converter
Photocoupler
A3
No. 2 input
Isolation circuit
B5
Amplifier
circuit
A/D
converter
A4
Photocoupler
Amplifier
circuit
Lower
A6
A7
Amplifier
circuit
24-V
power
supply
300
A9
B9
Power supply circuit
Photocoupler
A1
A2
A/D converter
Upper
Multiplexer
Cold junction sensors
Digital
circuits
Connector
No. 1 input
Section 3-2
CJ1W-PTS15 Isolated-type Thermocouple Input Unit
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
Set the gain for span adjustment to a value other
than 0.
The minimum and maximum values for process value scaling are
either the same or are set
extremely low.
The sensor type, input range, or
process value scaling is not set
correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Set the minimum and maximum values correctly.
Check and correct the settings.
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring. Check whether a wiring disconnection has
been detected in the I/O Area.
Values are Not Converted as Intended.
Probable cause
Remedy
The sensor type, input range, or
process value scaling is not set
correctly.
Check and correct the settings.
The zero/span adjustment data is
incorrect.
Check and correct the zero/span adjustment settings.
Cold junction compensation is not Check the Cold Junction Error Flag.
operating.
A compensation conductor has
Use the correct compensation conductor for the
not been used or a different com- thermocouple.
pensation conductor is used.
Incorrect input wiring (incorrect
thermocouple or compensation
conductor polarity.)
Correct the input wiring.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
Insert a 0.01 to 0.1 µF ceramic capacitor
between the positive (+) and negative (−) input
terminals.
Increase the number of values for calculating the
moving average in mean value processing.
The process value scaling value is Reduce the process value scaling value.
greater than the Unit’s resolution.
The input signal range setting is
too small.
Match the input signal range to the internal
ranges.
301
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
3-3
Section 3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input
Unit (Pt100, JPt100)
Overview
The CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit provides
four direct platinum resistance thermometer inputs, and sends the data to the
CPU Unit each cycle. All inputs are isolated.
CJ1W-PTS52
52
PTS RUCN
4
ALM
3 2 1 -
ER
ERH
H
MAC
No. 1
X10
0
X10
System Configuration
CJ1W-PTS52
Four platinum
resistance
thermometer inputs
(Pt100 (JIS, IEC),
JPt100)
Features
• Up to four platinum resistance thermometers can be connected for each
Unit. (The temperature sensor and input range settings are the same for
all four inputs.)
• Pt100 (JIS, IEC), JPt100 can be selected.
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal. (Either binary or BCD data output can be selected.)
• Process value alarm (two alarms in internal memory and one external
alarm output for each input).
• Alarm ON-delay timer and hysteresis for process value.
• Zero/span adjustment capability during operation.
• Sensor error detection.
• Maximum or minimum process value can be specified for when a sensor
error is detected.
302
Section 3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Model Information
Unit
Model number
classification
CJ-series Special CJ1W-PTS52
I/O Unit
Inputs
4
Input types
Platinum resistance thermometer Pt100 (JIS, IEC), JPt100
Block Diagram (Order of Processing)
The processing for the inputs is as shown in the following diagram.
CPU Unit
CPU Unit CIO Area
H, L
Process value
H, L
Process value alarm
External alarm outputs
Isolated-type Resistance Thermometer Input Unit
Sensor error
I/O refresh
Process value alarm
Output limit
Zero/span adjustment
Input calculations
Resistance thermometer type
Input range
A/D conversion
Resistance thermometer
Specifications
Item
Specifications
Model
CJ1W-PTS52
Applicable PLC
Unit classification
CJ Series
CJ-series Special I/O Unit
Mounting position
Maximum number of Units
CJ-series CPU Rack or CJ-series Expansion Rack
40 (within the allowable current consumption and power consumption range)
Unit numbers
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
303
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Areas for data
exchange with
CPU Unit
Item
Special I/O Unit
Area
Section 3-3
Specifications
10 words/Unit
Resistance Thermometer Input Unit to CPU Unit:
All process values, process value alarms (L, H), conversion data enabled flags, sensor
errors.
DM Area words 100 words/Unit
allocated to
CPU Unit to Resistance Thermometer Input Unit:
Special I/O Units Temperature sensor type, input range (user set), process value alarm setting (L, H),
zero/span adjustment value.
Number of temperature sensor
4
inputs
Temperature sensor type
Pt100 (JIS, IEC), JPt100
Sensor type, input range, and scaling to industrial units are the same for all I/O.
Data storage in the CIO Area
The actual process data in the input range is stored in four digits hexadecimal (binary
or BCD values) in the allocated words in the CIO Area.
Accuracy (25°C)
±0.3% of PV or ±0.8°C, whichever is greater, ±1 digit max.
±0.3% of PV or ±1.6°F, whichever is greater, ±1 digit max.
PV: Process value data
Temperature characteristics
Refer to Temperature Characteristics According to Platinum Resistance Thermometer
Type on page 305.
Sensing method
3-wire method
Influence of conductor resistance 0.4°C/Ω max.
Input detection current
Warmup time
1 mA
10 min
Conversion period
Maximum time to store data in
CPU Unit
250 ms/4 inputs
Conversion period + one CPU Unit cycle
Sensor error detection
Detects sensor error at each input and turns ON the Sensor error Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a sensor error occurs can be specified. (High: +20 digit of set input range; low: –20 digit of set input range)
Function
Process value 2-point alarm (H, L), alarm hysteresis, and ON-delay timer (0 to 60 s
are available).
NPN outputs (with short-circuit protection)
External power supply voltage: 20.4 to 26.4 V DC
Max. switching capacity: 100 mA (for one output)
Leakage current: 0.3 mA max.
Residual voltage: 3 V max.
Between inputs and PLC signal: Transformer for power supply and photocoupler for
signals
Between each input: Transformer for power supply and photocoupler for signals
20 MΩ max. (at 500 V DC).
Between all output and NC terminals and external AC terminals (Power Supply Unit)
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and all output terminals
Between all external DC terminals (input, output, and NC terminals) and FG plate
Between all input and output terminals and all NC terminals
Process value
alarm
External alarm
outputs
Isolation
Insulation resistance
Dielectric strength
304
Between all output and NC terminals and external AC terminals (Power Supply Unit)
2,000 V AC, 50/60 Hz 1 min., detection current: 1 mA
Between all input terminals and external AC terminals (Power Supply Unit)
Between all input terminals and all output terminals
Between all external DC terminals (input, output, and NC terminals) and FG plate
1,000 V AC, 50/60 Hz 1 min., detection current: 1 mA
Between all channels
500 VAC, 50/60 Hz 1 min., detection current: 1 mA
Section 3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Item
External connections
Specifications
Terminal block (detachable)
Unit number settings
Indicators
Effect on CPU Unit cycle time
Current consumption
Dimensions
Set by rotary switches on front panel, from 0 to 95.
Seven LED indicators on front panel (for normal operation, errors detected at the
Resistance Thermometer Input Unit, errors detected at the CPU Unit, and four indicators for external alarm outputs.)
0.4 ms
5 V DC at 250 mA max
31 × 90 × 65 mm (W × H × D)
Note The height including the Backplane is 145 mm.
150 g max.
Weight
Sensor Type and Input Range
The Platinum Resistance Thermometer type and input range are set in the
allocated words in the DM Area for every four inputs.
The measurable data range is ±20 digits wider than the sensor input range.
Setting
°C
Input
16-bit binary
°F
BCD
16-bit binary
[email protected]@@
Leftmost bit
indicates
indicates
minus sign. minus sign.
0
1
Pt100: −200.0 to
650.0°C
(−300.0 to
1200.0°F)
JPt100: −200.0
to 650.0°C
(−300.0 to
1200.0°F)
F830 to FFFF to
1964
(−200.0 to −0.1 to
650.0)
F830 to FFFF to
1964
(−200.0 to −0.1 to
650.0)
F999 to 6500
(See note 2.)
(−99.9 to
650.0)
F999 to 6500
(See note 2.)
(−99.9 to
650.0)
Leftmost 4 Leftmost bit
bits (bits 15
(bit 15)
to 12)
indicates
indicate
minus sign.
minus sign.
A000 to 6500 F448 to FFFF to
(−200.0 to
2EE0
650.0)
(−300.0 to −0.1 to
1200.0)
A000 to 6500 F448 to FFFF to
(−200.0 to
2EE0
650.0)
(−300.0 to −0.1 to
1200.0)
2 to 9 Do not set.
BCD
F999 to 9999
(See note 2.)
(−99.9 to
999.9)
F999 to 9999
(See note 2.)
(−99.9 to
999.9)
B000 to 7999
(See note 2.)
(−300.0 to
799.9)
B000 to 7999
(See note 2.)
(−300.0 to
799.9)
Do not set.
Note
1. If the indication range is exceeded, a sensor error will occur and the sensor
error bit will turn ON. The process value will be clamped at the lower or upper limit of the indication range, depending on the setting for data direction
at sensor error.
2. The indicator range for BCD display will be clamped at the lower (or upper)
limit in the region between the lower (or upper) limit of the setting range
and the point where a sensor error occurs.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost 4 bits (bits
12 to 15): Lower limit = −99.9, Upper limit = 999.9.
For 0.1°C/0.1°F indication with minus sign indicated by leftmost bit (bit 15):
Lower limit = −799.9, Upper limit = 799.9.
Temperature Characteristics According to Platinum Resistance Thermometer Type
Platinum Resistance
Thermometer
Temperature range
Pt100
−200 to 200°C
Set value error when
ambient temperature
changes by 1°C
±0.06°C
JPt100
200 to 650°C
−200 to 200°C
285 ppm of PV
±0.06°C
200 to 650°C
285 ppm of PV
305
Section 3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
The measured temperature error is calculated as shown in the following
example.
Item
Ambient temperature
Details
30°C
Platinum Resistance
Thermometer
Measured temperature
(PV)
Reference accuracy
(25°C)
Pt100
Change in ambient temperature
5°C (25 to 30°C)
500°C
±0.3°C of PV or ±0.8°C, whichever is greater, ±1 digit.
In this example, ±1.5°C.
Temperature characteris- 200 to 650°C: 285 ppm of PV.
tics
In this example, 285 ppm × 500°C = 0.143°C.
Overall accuracy =
Reference accuracy + Temperature characteristic × Change in ambient
temperature = ±1.5°C + ±0.143°C × 5 = Approx. ±2.2°C ±1 digit.
306
Section 3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
DM Area Allocations
First word: word m. m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input
No. 1
Input
No. 2
Input
No. 3
Data range
Input
No. 4
m
Decimal
Default
Data contents
Hexadecimal
12345, 0
3039, 0000 hex 0000 hex
Default block read command
Specifies the direction of data transfer when
the PLC is turned ON or the Unit is restarted
for DM Area words m+1 to m+31.
• 12345 (3039 hex): The data in words m+1
to m+31 is transferred from the Resistance Thermometer Input Unit to the CPU
Unit. When the transfer is completed, the
value will become 0000 hex.
• Other than 12345 (3039 hex) (such as
0000 hex): The data in the allocated
words of DM Area is transferred from the
CPU Unit to the Resistance Thermometer
Input Unit.
0 to 31
0000 to 001F
hex
Address of Data Range Error (See note 1.)
Display parameter
m+1
0
(0000 hex)
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m+6
m + 10
m + 14
m+3
m+7
m + 11
m + 15
m+4
m+8
m + 12
m + 16
Low to high limit for all sensors
6500
(1964 hex)
Process value H (high limit) alarm setting
−2000
(F830 hex)
Process value L (low limit) alarm setting
Span adjustment value
0 to 9999
0000 to 270F
hex
1000
(03E8 hex)
m+32 contains 0: Set value × 0.001
0 to 32000
0000 to 7D00
hex
10000
(2710 hex)
m+32 contains 1: Set value × 0.0001
–9999 to 9999
D8F1 to 270F
hex
0
(0000 hex)
Set value × 0.1
Zero adjustment value
m+5
m+9
m + 13
m + 17
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Resistance Thermometer
Input Unit if word m contains other than 12345 when the PLC is turned ON or the Resistance Thermometer Input Unit is restarted.
Operation settings (See note 2.)
m + 18
(See note 2.)
(See note 2.)
0
(0000 hex)
00 to 03: Temperature unit (°C or °F)
04 to 07: Data display (binary or BCD)
08 to 11: Minus sign display format for BCD
display
12 to 15: Data direction at sensor error
Sensor type
m + 19
0, 1
0000, 0001 hex 0 (0000 hex)
0: Pt100; 1: JPt100
External alarm output mode
m + 20
m + 23
m + 26
m + 29
0, 1
0000, 0001 hex 0
(0000 hex)
Select either high limit or low limit alarm output.
0: High limit alarm; 1: Low limit alarm
m + 21
m + 24
m + 27
m + 30
0 to 9999
0000 to 270F
hex
0
(0000 hex)
Set value × 0.1
m + 22
m + 25
m + 28
m + 31
0 to 60
0000 to 003C
hex
0
(0000 hex)
Unit: s
0, 1
0000, 0001 hex 1 (See note 3.)
Alarm hysteresis
Alarm ON-delay time
m + 32
Note
Span adjustment mode
0: 1/1,000
1: 1/10,000
1. The ERC indicator on the Unit’s front panel will light if an out-of-range setting is made in either Setting Group 1 or 2. The offset from word m to the
307
Section 3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
first word containing the out-of-range error will be stored as the Address of
Data Range Error in the DM Area in four digits hexadecimal.
2. The operation settings are shown in the following table.
Word
m+18
Bits
00
Description
Temperature unit setting
04
Data format
Settings
0: °C
1: °F
0: Binary (Negative values are given as 2’s complements).
1: BCD
Minus sign display format for BCD display 0: “F” used to indicate the minus sign.
1: Leftmost bit used to indicate the minus sign.
The setting is disabled if bits 04 to 07 are set to 0.
Data direction at sensor error
0: Goes to upper limit at sensor error
1: Goes to lower limit at sensor error
08
12
Example: For a temperature in degrees Celsius (°C), a binary data format,
and a data direction at sensor error of “lower limit,” word m+18 contains 1000.
3. Indicates the value after transferring the default value (set when 12345 is
written to word m).
CIO Area Allocations
First word: word n. n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Resistance Thermometer Input
Unit to CPU Unit
Word
n
Bit
00
Name
Input No. 1
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
Data range
Contents
Process value L (low
limit) alarm
0, 1
0: Process value >
Set value
1: Process value ≤
Set value
Process value H (high
limit) alarm
0, 1
0: Process value <
Set value
1: Process value ≥
Set value
Process value L (low
limit) alarm
0, 1
Same as for input No.
1.
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
0, 1
Process value L (low
limit) alarm
0, 1
Process value H (high
limit) alarm
0, 1
Process value
Depends on type of input. Stores data in the
data range specified
for each input type
±20 digits.
08 to 15 Not used.
n+1
00 to 15 Input No. 1
n+2
00 to 15 Input No. 2
n+3
00 to 15 Input No. 3
n+4
00 to 15 Input No. 4
n+5
Not used.
n+6
n+7
n+8
308
Section 3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Direction
Resistance Thermometer Input
Unit to CPU Unit
Word
n+9
Bit
Name
00
Input No. 1
Data range
Sensor error
Contents
0, 1
01
Input No. 2
0, 1
02
Input No. 3
0, 1
03
Input No. 4
0, 1
0: Normal
1: Error
04 to 14 Not used.
15
15
Conversion data
0, 1
enabled flag. (See note.)
0: Data disabled
1: Data enabled
Note The Conversion Data Enabled Flag remains OFF after the PLC is turned ON
or the Unit is restarted until the AD conversion data becomes stable (approximately 2 to 4 s), then is ON during operation.
Terminal Connection Diagram
No. 2
Platinum-resistance
Thermometer input
No. 4
Platinum-resistance
Thermometer input
External alarm outputs
L
L
Note
2b
B1
2B
B2
2A
B3
4b
B4
4B
B5
4A
B6
ALM2
B7
ALM4
B8
0V
B9
A1
1b
A2
1B
A3
1A
A4
3b
A5
3B
No. 1
Platinum-resistance
Thermometer input
No. 3
Platinum-resistance
Thermometer input
A6
3A
A7
ALM1
L
A8
ALM3
L
A9
24V
External alarm outputs
• Wire the same length to A, B, and b, so that the impedance will be the
same. In particular, do not short circuit between B and b at the terminal
block.
• For unused input terminals, connect approximately 100 Ω between the
platinum-resistance thermometer input terminals A and B and short terminals B and b with a lead wire. If resistance is not connected between terminals A and B and terminals B and b are shorted or if terminals A and B
and terminals B and b are left open, the alarm output will turn ON and the
ALM indicator will light.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
309
Section 3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Terminal Block Diagram
■ Input Circuit
B
A
1B
1b
A2
A1
2A
B3
Resistance thermometer
B
A
2B
2b
B2
B1
3A
A6
Resistance thermometer
B
A
3B
3b
A5
A4
4A
B6
Resistance thermometer
B
4B
4b
Reference
power supply
A3
B5
B4
Double
integral
A/D
Amplifier
circuit
Double
integral
A/D
Amplifier
circuit
Double
integral
A/D
Amplifier
circuit
Double
integral
A/D
Amplifier
circuit
Photocoupler
Reference
power supply
Photocoupler
5 V DC
Reference
power supply
Digital circuits
Photocoupler
Reference
power supply
Photocoupler
■ Output Circuit
L
A7
ALM1
L
B7
ALM2
L
A8
ALM3
L
B8
ALM4
Internal Circuit
A9
24V
B9
0V
Output Display
LED
310
Connector
1A
Isolation circuit
A
Resistance thermometer
Section 3-3
CJ1W-PTS52 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100)
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
The sensor type is not set correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Set the gain for span adjustment to a value other
than 0.
Check and reset the sensor type.
Check whether the resistance has changed.
Check for faulty or disconnected wiring. Check
whether a sensor error has been detected in the
I/O Area.
Values are Not Converted as Intended.
Probable cause
The sensor type is set incorrectly.
Remedy
Check and reset the sensor type settings.
The zero/span adjustment data is
incorrect.
Check and correct the zero/span adjustment settings.
The platinum-resistance thermom- Check and correct the input wiring.
eter input wiring is faulty.
The compensating conductor is
Use a thicker compensating conductor.
too long and measurements are
being affected by conductor resistance.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
311
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
3-4
Section 3-4
CJ1W-PTS16 Isolated-type Resistance Thermometer Input
Unit (Pt100, JPt100, Pt50, Ni508.4)
Overview
The CS1W-PTS16 Isolated-type Resistance Thermometer Input Unit provides
two direct resistance thermometer inputs, and sends the data to the CPU Unit
each cycle. All inputs are isolated.
CS1W-PTS16
16
PTS RUCN
ERH
ERT PS
EX
H
MAC
No. 1
0
System Configuration
CS1W-PTS16
Two resistance
thermometer inputs
(Pt100 (JIS, IEC),
JPt100, Pt50, or
Ni508.4)
Features
• Up to two resistance thermometers can be connected for each Unit (with
two separate settings for temperature sensors and input ranges).
• Pt100 (JIS, IEC), JPt100, Pt50, or Ni508.4 can be selected.
• 1/64,000 resolution for all temperature specifications.
• High-speed conversion of 10 ms/2 inputs.
• Temperature sensor values are transmitted to the CPU Unit in four digits
hexadecimal.
• Variable input range setting.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Zero/span adjustment capability during operation.
• Disconnection detection.
• Maximum or minimum process value can be specified for when a disconnection is detected.
• Adjustment period control.
312
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 3-4
• Peak and bottom detection.
• Top and valley detection.
Model Information
Unit
Model number
classification
CJ-series Special CJ1W-PTS16
I/O Unit
Inputs
2
Input types
Resistance thermometer Pt100
(JIS, IEC), JPt100, Pt50, or
Ni508.4
Block Diagram (Order of Processing)
The processing for the inputs is as shown in the following diagram.
CPU Unit
CPU Unit Expansion Area Allocations
Top/valley value
Peak/Bottom value
CPU Unit CIO Area
HH, H, L, LL
Process value
H, L
Process value alarm
Rate-of-change value
Rate-of-change alarm
Isolated-type Resistance Thermometer Input Unit
Process value alarm
External power
supply used/not used
Input disconnection alarm
I/O refresh
Rate-of-change alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
+115% or −15% when input disconnection is detected
Output limit: −15% to +115%
Input disconnection check
Zero/span adjustment
Process value scaling
Input calculations
Resistance thermometer type
Input range
A/D conversion, moving average
Resistance thermometer
24-V external power supply
313
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 3-4
Specifications
Item
Specifications
Model
CJ1W-PTS16
Applicable PLC
Unit classification
CJ Series
CJ-series Special I/O Unit
Mounting position
Maximum number of Units
CJ-series CPU Rack or CJ-series Expansion Rack
40 (within the allowable current consumption and power consumption range)
Unit numbers
Areas for data
exchange with
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Resistance Thermometer Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rateof-change alarms (L, H), disconnection alarms, adjustment period end/notices.
Special I/O Unit
Area
DM Area words 100 words/Unit
allocated to
CPU Unit to Resistance Thermometer Input Unit:
Special I/O Units Temperature sensor type, input range (user set), scaling of process value data to be
stored in allocated words in CIO area, rate-of-change input range, scaling of rate-ofchange data, number of items for moving average, process value alarm setting (LL, L,
H, HH), rate-of-change alarm setting (L, H), zero/span adjustment value.
Expansion Con- 35 words/Unit
trol/Monitor Area CPU Unit to Resistance Thermometer Input Unit:
words
Hold function selection start/reset, adjustment period control, control bits
Resistance Thermometer Input Unit to CPU Unit:
Adjustment period warnings/notices, peak and bottom values, top and valley values
Expansion Setting Area words
Number of temperature sensor
inputs
Temperature sensor type
Scaling
Data storage in the CIO Area
46 words/Unit
CPU Unit to Resistance Thermometer Input Unit:
Expansion Setting Area settings, adjustment period control, peak and bottom detection, top and valley detection
2
Pt100 (JIS, IEC), JPt100, Pt50, Ni508.4
Sensor type, input range, and scaling to industrial units are separate for each of the 2
inputs.
Data to be stored in the allocated words in the CIO area must be scaled (with the minimum and maximum values set by user) (2 inputs set separately.). Data can be stored
at 0% to 100%.
The value derived from carrying out the following processing in order of the actual process data in the input range is stored in four digits hexadecimal (binary values) in the
allocated words in the CIO Area.
1) Mean value processing → 2) Scaling → 3) Zero/span adjustment → 4) Output limits
Accuracy (25°C)
Temperature coefficient
The greater of the following: ±0.05% or ±0.1°C
Pt100: 0.009%/°C
JPt100: 0.01%/°C
Pt50:
0.02%/°C
Ni508.4: 0.012%/°C
Resolution
Sensing method
1/64,000
3-wire method
Allowable lead wire resistance
Input detection current
20 Ω max. per wire
0.5 mA
Warmup time
Response time
10 min
100 ms (travel time from input 0% to 90%, for step input and with moving average for 4
samples)
10 ms/2 inputs
Conversion period
Maximum time to store data in
CPU Unit
314
Conversion period + one CPU Unit cycle
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Item
Disconnection detection
Function
Section 3-4
Specifications
Detects disconnections at each input and turns ON the Disconnection Detection Flag.
Hardware detection time: Approx. 0.5 s max.
The process value overrange direction for when a disconnection occurs can be specified. (High: 115% of set input range; low: –15% of set input range)
Mean value pro- Calculates the moving average for the specified number of process values (1 to 128),
cessing (input
and stores that value in the CIO Area as the process value.
filter)
Process value
alarm
Process value 4-point alarm (HH, H, LL, L), alarm hysteresis, and ON-delay timer (0 to
60 s are available).
Rate-of-change
calculation
Rate-of-change
alarm
Adjustment
period control
Calculates the amount of change per comparison time interval (1 to 16 s).
Peak and bottom detection
Detects the maximum (peak) and minimum (bottom) analog input values, from when
the Hold Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON
until it turns OFF. These values are stored as the peak and bottom values in the
Expansion Control/Monitor Area.
This function detects the top and valley values for analog inputs, from when the Hold
Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON until it
turns OFF. These values are stored as the top and valley values in the Expansion
Control/Monitor Area.
Top and valley
detection
Rate-of-change 2-point alarm (H, L), alarm hysteresis, and ON-delay timer (0 to 60 s
are available, shared with process value alarm).
When zero/span adjustment is executed, the date is internally recorded at the Unit.
When the preset zero/span adjustment period and the notice of days remaining have
elapsed, this function turns ON a warning flag to give notice that it is time for readjustment.
Isolation
Between temperature inputs and between input terminals and PLC signals: Power
supply isolated by transformers, signals isolated by photocouplers.
Insulation resistance
Dielectric strength
20 MΩ (at 500 V DC) between inputs
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
External connections
Unit number settings
Terminal block (detachable)
Set by rotary switches on front panel, from 0 to 95.
Indicators
Four LED indicators on front panel (for normal operation, errors detected at the Resistance Thermometer Input Unit, errors detected at the CPU Unit, and use of external
power supply).
Front panel connector
Effect on CPU Unit cycle time
Sensor input connector terminal block (detachable)
0.3 ms
Current consumption
External power supply
Dimensions
5 V DC at 180 mA max.
24 VDC +10%/−15% 70 mA max., inrush current: 20 A for 1 ms max.
(The external 24-VDC power supply must be isolated.)
31 × 90 × 65 mm (W × H × D)
Weight
Standard accessories
150 g max.
None
Sensor Type and Input Range
The resistance thermometer type and input range are set in the allocated
words in the DM Area for every four inputs. The input range can be set anywhere within the measurable input ranges shown in the following table. Accuracy and resolution, however, are not determined from the set input range, but
rather from the measurable input range shown in the following table. Therefore, accuracy and resolution do not change even when a narrow input range
is set.
Sensor type
Pt100
0
DM Area setting
Measurable input range
−200 to 850°C
JPt100
1
−200 to 500°C
315
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
DM Area setting
Section 3-4
Sensor type
Pt50
2
Measurable input range
−200 to 649°C
Ni508.4
3
−50 to 150°C
DM Area Allocations
First word: word m. m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input No. 1
Data range
Input No. 2
Decimal
Default
Data contents
Hexadecimal
m
12345, 0
3039, 0000 hex 0000 hex
Default block read command
Specifies the direction of data transfer when the PLC is
turned ON or the Unit is restarted for DM Area words
m+1 to m+93.
• 12345 (3039 hex): The data in words m+1 to m+93 is
transferred from the Resistance Thermometer Input
Unit to the CPU Unit. When the transfer is completed,
the value will become 0000 hex.
• Other than 12345 (3039 hex) (such as 0000 hex): The
data in the allocated words of DM Area is transferred
from the CPU Unit to the Resistance Thermometer
Input Unit.
m+1
---
---
Not used.
0 (0000 hex)
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m + 10
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4200
(1068 hex)
Process value HH (high high limit) alarm setting
(Set at process value scaling value.)
m+3
m + 11
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4000
(0FA0 hex)
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m + 12
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
0
(0000 hex)
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m + 13
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
–200
(FF38 hex)
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m + 14
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4000
(0FA0 hex)
Rate-of-change value H (high limit) alarm setting
(Set at rate-of-change scaling value.)
m+7
m + 15
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
0
(0000 hex)
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
Rate-of-change value alarm settings
Zero/span adjustment
m+8
m + 16
0 to 32000
0000 to 7D00
hex
10000
(2710 hex)
Gain for span adjustment
(set value x 0.0001%)
m+9
m + 17
–32000 to
32000
8300 to FFFF
hex,
0000 to 7D00
hex
0
(0000 hex)
Zero adjustment value
(Set at process value scaling.)
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Resistance Thermometer
Input Unit if word m contains other than 12345 when the PLC is turned ON or the Resistance Thermometer Input Unit is restarted.
Sensor type
m+34
m+49
0 to 3
0000 to 0003
hex
0 (0000 hex)
0: Pt100; 1: JPt100: 2: Pt50: 3: Ni508.4
m+35
m+50
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Maximum input signal value
(set value x 0.1°C/°F)
m+36
m+51
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Minimum input signal value
(set value x 0.1°C/°F)
m+37
m+52
0, 1
0000, 0001 hex 0 (0000 hex)
Process value input range settings
316
Unit
0: °C, 1: °F
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
DM Area address
Input No. 1
Input No. 2
Data range
Decimal
Default
Section 3-4
Data contents
Hexadecimal
Process value overrange direction at time of input
disconnection
m+38
m+53
0, 1
0000, 0001 hex 0 (0000 hex)
0: High; 1: Low
m+39
m+54
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Value stored for maximum value in range (span)
m+40
m+55
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Value stored for minimum value in range (zero)
m+41
m+56
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared with process value alarm and rate-of-change alarm.)
m+42
m+57
0 to 60
0000 to 003C
hex
0 (0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rate-of-change
alarm.)
m+43
m+58
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
m+44
m+59
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
−4000 (F060
hex)
m+45
m+60
1 to 16
0001 to 0010
hex
1 (0001 hex)
Rate-of-change comparison time interval
(Unit: s)
m+46
m+61
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Rate-of-change
value scaling
m+47
m+62
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
−4000 (F060
hex)
m+48
m+63
1 to 128
0001 to 0080
hex
25 (0019 hex)
Number of process values for calculating moving average for mean value processing
0 to 99, 100 to
1XX
0000 to 0063
hex, 0064 to
0XXX hex
0 (0000 hex)
Address of Data Range Error (See note.)
Process value scaling
Alarm supplementary functions
Rate-of-change function
Rate-of-change
range setting
Maximum rate-of-change value (Set
value industrial unit; comparison time
interval)
Minimum rate-of-change value (Set
value industrial unit; comparison time
interval)
Value stored for maximum value in
range
Value stored for minimum value in
range
Mean value processing function
Display parameter
m+94
m+95
Expansion Setting Area allocation settings
m+98
0 to 5
0000 to 0005
hex
---
Expansion Setting Area allocation
0: Not used; 1: DM; 2: CIO; 3: W; 4: H; 5: EM
m+99
0 to 32767
0000 to 7FFF
hex
---
First word for Expansion Setting Area
Note
1. The ERC indicator on the Unit’s front panel will light if an out-of-range setting is made in either Setting Group 1 or 2, or in the Expansion Setting Area. The offset from word m to the first word containing the out-of-range
error will be stored as the Address of Data Range Error in the DM Area in
four digits hexadecimal. For more information, refer to 1-6 Error Processing.
If the first memory address where the out-of-range error occurred is in the
Expansion Setting Area, the Address of Data Range Area will be +100 or
later. If the first word of the Expansion Setting Area has the error, the Address of Data Range Area will be +100.
2. When specifying an expansion setting area, be sure that it does not overlap with other areas that are being used. If areas overlap, the words that
are allocated may be overwritten, resulting in unexpected operation.
3. When specifying the first word in an expansion setting area, be sure that
the end of the memory area is not exceeded.
317
Section 3-4
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Expansion Setting Area Allocations
First word: word o. o = address specified in word m+99 in the area specified
by word m+98 in the DM Area.
DM Area address
Input No. 1
Data range
Input No. 2
Decimal
Default
Data contents
Hexadecimal
Setting Group 3 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Resistance Thermometer
Input Unit if word m contains other than 12345, and if Expansion Setting Area settings are allocated, when the PLC is turned ON or the
Resistance Thermometer Input Unit is restarted.
Expansion Control/Monitor Area settings
o
0 to 5
0000 to 0005
hex
---
Expansion Control/Monitor Area allocation
0: Not used. 1: DM; 2: CIO; 3: W; 4: H; 5: EM
o+1
0 to 32767
0000 to 7FFF
hex
---
Expansion Control/Monitor Area first word
Zero/span adjustment supplementary function
o+2
o+13
0 to 32000
0000 to 7D00
hex
1000 (2710
hex)
Span adjustment position
(Input span percentage)
o+3
o+14
−32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Zero adjustment position
(Input span percentage)
o+4
o+15
0 to 9999
0000 to 270F
hex
365 (016D hex) Zero/span adjustment period (Unit: Days)
o+5
o+16
0 to 9999
0000 to 270F
hex
30 (001E hex)
o+6 to o+8
o+17 to
o+19
---
---
0 (0000 hex)
Not used.
o+9
o+20
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
Hysteresis
o+10 to
o+12
o+21 to
o+23
---
---
0 (0000 hex)
Notice of days remaining (Unit: Days)
Not used.
Top and valley hold
Not used.
Note
Not used.
1. When specifying an expansion control/monitor area be sure that it does not
overlap with other areas that are being used. If areas overlap, the words
that are allocated may be overwritten, resulting in unexpected operation.
2. When specifying the first word in an expansion control/monitor area be
sure that the end of the memory area is not exceeded.
CIO Area Allocations
First word: word n. n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Resistance Thermometer Input
Unit to CPU Unit
Word
n
Bit
00
Name
0, 1
01
Process value L (low
limit) alarm
0, 1
02
Process value H (high
limit) alarm
0, 1
03
Process value HH (high
high limit) alarm
0, 1
Process value LL (low
low limit) alarm
0, 1
05
Process value L (low
limit) alarm
0, 1
06
Process value H (high
limit) alarm
0, 1
07
Process value HH (high
high limit) alarm
0, 1
Input No. 2
08 to 15 Not used.
318
Data range
Process value LL (low
low limit) alarm
04
Input No. 1
0
Contents
0: Process value >
Set value
1: Process value ≤
Set value
0: Process value <
Set value
1: Process value ≥
Set value
Same as for input No.
1.
---
Section 3-4
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Direction
Resistance Thermometer Input
Unit to CPU Unit
Data range
Contents
n+1
Word
00 to 15 Input No. 1 process value
Bit
Name
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+2
00 to 15 Input No. 2 process value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
The present process
value is stored
according to the scaling set in the allocated words of the
DM Area.
n + 3,
n+4
---
0000
---
n+5
00 to 15 Input No. 1 rate-of-change value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+6
00 to 15 Input No. 2 rate-of-change value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
The present rate of
change is stored
according to the scaling set in the allocated words of the
DM Area.
n + 7,
n+8
---
Not used.
0000
---
n+9
00
Input No. 1
Rate-of-change value L
(low limit) alarm
0, 1
0: Rate-of-change
value > Set value
1: Rate-of-change
value ≤ Set value
Rate-of-change value H
(high limit) alarm
0, 1
0: Rate-of-change
value < Set value
1: Rate-of-change
value ≥ Set value
Rate-of-change value L
(low limit) alarm
0, 1
Same as for input No.
1.
Rate-of-change value H
(high limit) alarm
0, 1
Not used.
01
02
Input No. 2
03
04 to 07 Not used.
0
---
08
Input No. 1 input error
0, 1
09
Input No. 2 input error
0: Normal
1: Disconnection
0, 1
10 to 12 Not used.
0
---
13
Zero/span adjustment period end
0, 1
0: Adjustment
enabled
1: Adjustment ended
14
Zero/span adjustment period notice
0, 1
0: Adjustment
enabled
1: Notice period
15
External power supply
0, 1
0: External power
supply not used
1: External power
supply used
Note The External Power Supply Flag turns ON after external power is supplied
and the internal voltage stabilizes (which requires approximately 2 s). The
indicator on the front of the Unit will turn ON as soon as external power is supplied.
319
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 3-4
Expansion Control/Monitor Area Allocations
First word: word p. p = address specified in word o+1 in the area specified by
word o in the Expansion Setting Area.
Direction
Word
CPU Unit to p
Resistance
Thermome- p+1
ter Input Unit
Bit
00 to
15
00
Data range
Not used.
Contents
Not used.
Input No. 1 hold function selection
Input No. 2 hold function selection
0, 1
0: Peak and bottom
1: Top and valley
02 to
07
Not used.
0
Not used.
08
09
Input No. 1 hold start
Input No. 2 hold start
0, 1
0, 1
0: Do not hold.
1: Hold
10, 11
12
Not used.
Input No. 1 hold value reset
0
0, 1
13
Input No. 2 hold value reset
0, 1
Not used.
0: Normal operation
1: Reset hold
value.
14, 15
00
Not used.
0
Input No. 1 zero/span adjustment 0, 1
update bit
Input No. 2 zero/span adjustment 0, 1
update bit
Not used.
0: Normal operation
1: Update adjustment date
(Remains ON while
writing external
FROM.)
Not used.
Not used.
01
p+2
01
02 to
15
320
Name
Not used.
0, 1
0
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Direction
Word
Resistance p+3
Thermometer Input Unit
to CPU Unit
Bit
00
Name
Input Zero/span adjustment
No. 1 period end
01
Zero/span adjustment
period notice
Input Zero/span adjustment
No. 2 period end
Zero/span adjustment
period notice
0, 1
Not used.
0
External FROM Error Flag
0, 1
0: Normal operation
1: External FROM
error
09 to
15
Not used.
0
Not used.
00 to
15
00 to
15
00 to
15
00 to
15
Input Day of final adjustment
No. 1 date
Year and month of final
adjustment date
0100 to 3100 (BCD)
Input Day of final adjustment
No. 2 date
Year and month of final
adjustment date
0100 to 3100 (BCD)
Remains set to
FFFF if the zero/
span adjustment
bit has never been
ON.
p+8 to
p+15
---
Not used.
0
Not used.
p+16
00 to
15
Input Peak/top value
No. 1
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
p+17
00 to
15
Counts the number of repetitions of
conditional operations set in the
Expansion Setting
Area.
The bottom or valley value is stored
according to the
scaling set in the
DM Area.
p+18
00 to
15
p+19
00 to
15
p+20 to
p+34
---
02
03
04 to
07
08
p+4
p+5
p+6
p+7
Bottom/valley value
Input Peak/top value
No. 2
Bottom/valley value
Not used.
Data range
Section 3-4
0, 1
0, 1
0, 1
0001 to 9912 (BCD)
Contents
0: Adjustment
enabled.
1: Adjustment
period end
0: Adjustment
enabled.
1: Notice period in
effect.
Remains set to 1 if
the zero/span
adjustment bit has
never been ON.
Not used.
0001 to 9912 (BCD)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
0 (0000 hex)
Same as for Input
No. 1.
Not used.
321
Section 3-4
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Terminal Connection Diagram
Resistance
thermometer input 2
NC
B1 (10)
NC
B2 (11)
NC
B3 (12)
2A
B4 (13)
2B
B5 (14)
2b
B6 (15)
NC
B7 (16)
NC
B8 (17)
0V
B9 (18)
A1 (1)
NC
A2 (2)
1A
A3 (3)
1B
A4 (4)
1b
A5 (5)
NC
A6 (6)
NC
A7 (7)
NC
A8 (8)
NC
A9 (9)
24V
Resistance
thermometer input 1
24 VDC
Note
• Wire the same length to A, B, and b, so that the impedance will be the
same. In particular, do not short circuit between B and b at the terminal
block.
• For unused input terminals, short-circuit between A–B and B–b (e.g., B4–
B5 and B5–B6 for input No. 2) of the resistance thermometer inputs with
the lead wire.
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
Terminal Block Diagram
1A
A2
Constant current circuit
Isolation
circuit
A
Am510 Ω plifier
circuit
A/D
converter
1B
A3
1b
A4
Constant current circuit
2A
B4
Constant current circuit
Isolation
circuit
A
Reference
resistance
Resistance
thermometer
B
2B
B5
2b
B6
A9
24-VDC
circuit
B9
Am510 Ω plifier
circuit
A/D
converter
5 VDC
Photocoupler
Digital
circuits
Connector
B
Input selector
Reference
resistance
Resistance
thermometer
Photocoupler
Constant current circuit
Power
supply circuit
Error Processing
Conversion Data Does Not Change.
Probable cause
The gain for span adjustment is
set to 0.
The minimum and maximum values for process value scaling are
either the same or are set
extremely low.
Remedy
Set the gain for span adjustment to a value other
than 0.
Set the minimum and maximum process value
scaling correctly.
The sensor type, or process value Check and reset the sensor type, and the process value scaling settings.
scaling is not set correctly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
322
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring. Check whether a disconnection has been
detected in the I/O Area.
CJ1W-PTS16 Isolated-type Resistance Thermometer Input Unit (Pt100, JPt100, Pt50, Ni508.4)
Section 3-4
Values are Not Converted as Intended.
Probable cause
Remedy
The sensor type, or process value Check and reset the sensor type, and the proscaling is set incorrectly.
cess value scaling settings.
The zero/span adjustment data is
incorrect.
Check and correct the zero/span adjustment settings.
The resistance thermometer input Check and correct the input wiring.
wiring is faulty.
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
Increase the number of values for calculating the
moving average in mean value processing.
Reduce the process value scaling.
The scaling value is greater than
the Unit’s resolution.
The input signal range is too small. Change to match the internal range.
323
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Overview
The CJ1W-PDC15 Isolated-type Direct Current Input Unit provides two directcurrent inputs, and sends the data to the CPU Unit each cycle. All inputs are
isolated.
CJ1W-PDC15
15
PDCRUCN
ERH
ER PS
EXT
H
MAC
No. 1
0
System Configuration
CJ1W-PDC15
2 DC inputs
(4 to 20 mA, 0 to 20 mA,
0 to 10 V, −10 to 10 V,
0 to 5 V, −5 to 5 V,
1 to 5 V, 0 to 1 V,
−1.25 to 1.25 V)
Features
• Up to two DC inputs can be made to each Unit.
4 to 20 mA, 0 to 20 mA, 0 to 10 V, −10 to 10 V, 0 to 5 V, −5 to 5 V, 1 to 5 V,
0 to 1.25 V, or −1.25 to 1.25 V can be selected separately for each input.
• Resolution of 1/64,000 for all input range specifications.
• High-speed conversion, at 10 ms/2 inputs.
• Scaling values are transmitted to the CPU Unit in four digits hexadecimal.
• There is isolation between channels, so unwanted signal paths between
input signals can be prevented.
• Square root function.
• Four values for each process value alarm input.
• ON-delay timer for process value alarm.
• Mean value processing.
• Rate-of-change calculation.
• Two values for each rate-of-change alarm input.
• Input error detection.
• Zero/span adjustment capability during operation.
• Adjustment period control.
• Peak and bottom detection.
• Top and valley detection.
324
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
• Integral value calculation.
Model Information
Unit classification
CJ-series Special I/O
Unit
Model number
CJ1W-PDC15
Inputs
Input types
4 to 20 mA, 0 to 20 mA, 0 to 10 V, −10 to 10 V, 0 to
5 V, −5 to 5 V, 1 to 5 V, 0 to 1.25 V, and −1.25 to
1.25 V (separate for each input)
2
Block Diagram
CPU Unit
CPU Unit Expansion Area Allocations
Top/valley value
Peak/Bottom value
CPU Unit CIO Area
HH, H, L, LL
Process value
H, L
Process value alarm
Rate-of-change value
Rate-of-change alarm
External power supply
used/not used
Input error alarm
Isolated-type Direct Current Input Unit
I/O refresh
Process value alarm
Rate-of-change alarm
Output limit: −15% to +115%
Rate-of-change calculation and scaling
+115% or −15% when input disconnection is detected
Square root
Input error check
Zero/span adjustment
Process value scaling
For 4 to 20 mA and 1 to 5 V inputs,
less than −17% or more than 112% is
an input error.
Input calculations
Input range
There is no check for other inputs.
A/D conversion, moving average
24-V external power supply
DC signal sensor
Specifications
Item
Specifications
Model
CJ1W-PDC15
Applicable PLC
Unit classification
CJ Series
CJ-series Special I/O Unit
325
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Section 3-5
Item
Mounting position
Specifications
CJ-series CPU Rack or CJ-series Expansion Rack
Maximum number of Units
Unit numbers
40 (within the allowable current consumption and power consumption range)
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
Areas for data
exchange with
CPU Unit
Special I/O Unit
Area
10 words/Unit
Direct Current Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate-of-change values, rateof-change alarms (L, H), disconnection alarms, cold junction sensor errors, adjustment period end/notice
DM Area words 100 words/Unit
allocated to
CPU Unit to Direct Current Input Unit:
Special I/O Units Input signal type, scaling of process value in industrial units, process value alarm setting (L, H), inrush input upper limit, inrush input upper limit time, zero/span adjustment
value, Square root function.
Temperature input signal type, input range (user set), scaling of process value data to
be stored in allocated words in CIO area, rate-of-change input range, scaling of rateof-change data, number of items for moving average, process value alarm setting (LL,
L, H, HH), rate-of-change alarm setting (L, H), zero/span adjustment value
Expansion Con- 35 words/Unit
trol/Monitor Area CPU Unit to Direct Current Input Unit:
Bits for beginning or resetting the hold function selection, adjustment period control,
control bits
Direct Current Input Unit to CPU Unit:
Adjustment period notices, peak and bottom values, top and valley values, integral values
Expansion Set- 46 words/Unit
ting Area
CPU Unit to Direct Current Input Unit:
Expansion Setting Area settings, adjustment period control, peak and bottom detection, top and valley detection, integral value calculation
Number of inputs
Input signal type
Scaling
Data storage in the CIO Area
2
4 to 20 mA, 0 to 20 mA, 0 to 10 V, −10 to 10 V, 0 to 5 V, −5 to 5 V, 1 to 5 V, 0 to 1.25 V,
−1.25 to 1.25 V (separate for each input), and ±10-V user-set range (specified range
within –10.000 V to 10.000 V)
Data to be stored in the allocated words in the CIO area must be scaled (Any minimum and maximum values can be set.) (2 inputs set separately.) Data can be converted at 0% to 100%.
Accuracy (25°C)
The value derived from carrying out the following processing in order of the actual process data in the input range is stored in four digits hexadecimal (binary values) in the
allocated words in the CIO Area.
1) Mean value processing → 2) Scaling → 3) Zero/span adjustment → 4) Square root
calculation → 5) Output limits
±0.05%
Temperature coefficient
Resolution
±0.008%/°C
1/64,000
Input signal range
For 4 to 20 mA, 0 to 20 mA, 0 to 10 V, 0 to 5 V, 1 to 5 V, 0 to 1.25 V inputs:
−15 to 115%
For −10 to 10 V, −5 to 5 V, −1.25 to 1.25 V inputs: −7.5 to 107.5%
Voltage: ±15 V
Current: ±30 mA
Maximum input rating
Input impedance
For current inputs: 250 Ω (typical)
For voltage inputs: 1 MΩ min.
Warmup time
Conversion period
10 min
10 ms/2 inputs
Maximum time to store data in
CPU Unit
Conversion period + one CPU Unit cycle
326
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Item
Input error detection
Operation at input disconnection
Input disconnection detection
delay time
Function
Section 3-5
Specifications
Check only for 4 to 20 mA and 1 to 5 V.
Error detected for −17.2% (1.25 mA, 0.3125 V) or less and 112.5% (22 mA, 5.5 V) or
more.
For 4 to 20 mA and 1 to 5 V: Stores −15% process value.
For all other ranges: Stores same process value as 0-V or 0-mA inputs.
Approx. 1 s.
Mean value processing (input
filter)
Process value
alarm
Calculates the moving average for the past specified number of process values (1 to
128 can be specified), and stores that value in the CIO Area as the process value.
Rate-of-change
calculation
Calculates the amount of change per comparison time interval (1 to 16 s).
Rate-of-change
alarm
Rate-of-change 2-point alarm (H, L), alarm hysteresis, and ON-delay timer (0 to 60 s
are available, shared with process value alarm).
Process value 4-point alarm (LL, L H, HH), hysteresis, and ON-delay timer (0 to 60 s)
are available.
Square root cal- When the maximum value for process value scaling is A and the minimum value is B,
culation
Output = (A − B) × (input − B) + B
Drop-out: Output approx. 7% max. linear (output = input) characteristic
Note 1 The square root function can only be used when the maximum scaling value
is greater than the minimum scaling value. The square root will not be found if
the maximum is smaller than the minimum.
Note 2 When the square root function is used, set the scaling values after square root
calculation (e.g., for flow rates or other values) for the process value scaling A
and B settings.
Adjustment
period control
Peak and bottom detection
Top and valley
detection
Integral value
calculation
Isolation
When zero/span adjustment is executed, the date is internally recorded at the Unit.
When the preset zero/span adjustment period and the notice of days remaining set in
the Expansion Setting Area have elapsed, this function turns ON a warning flag to
give notice that it is time for readjustment.
Detects the maximum (peak) and minimum (bottom) analog input values, from when
the Hold Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON
until it turns OFF. These values are stored as the peak and bottom values in the
Expansion Control/Monitor Area.
This function detects the top and valley values for analog inputs, from when the Hold
Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON until it
turns OFF. These values are stored as the top and valley values in the Expansion
Control/Monitor Area.
This function calculates the analog input value’s time integral. The integral value is calculated and output to the Expansion Control/Monitor Area when the Integral Value
Calculation Start Bit in the Expansion Control/Monitor Area is turned ON.
Insulation resistance
Between inputs and between inputs and PLC signals: Isolation by transformer and
photocoupler.
20 MΩ (at 500 V DC) between all inputs
Dielectric strength
External connections
Between inputs: 1,000 V AC, at 50/60 Hz, for 1 min, leakage current 10 mA max.
Terminal block (detachable)
Unit number settings
Indicators
Front panel connector
Set by rotary switches on front panel, from 0 to 95.
Four LED indicators on front panel (for normal operation, errors detected at the Direct
Current Input Unit, and errors detected at the CPU Unit).
Sensor input connector terminal block (detachable)
Effect on CPU Unit cycle time
Current consumption
0.3 ms
5 V DC at 180 mA max.
External power supply
24 V DC +10%/−15% 90 mA max., inrush current: 20 A for 1 ms max.
(The external 24-VDC power supply must be isolated.)
Dimensions
31 × 130 × 65 mm (W × H × D)
327
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Item
Specifications
Weight
150 g max.
Standard accessories
Short bars (for current input)
Accuracy and Resolution in ±10-V User-set Range
The ±10-V user-set range allows the input signal’s input range to be set to any
range within –10.000 V to 10.000 V. Accuracy and resolution, however, are
not determined by the input range, but rather by the measurable input range
(–10.000 V to 10.000 V). Therefore, accuracy and resolution do not change
even if a narrow input range is set.
DM Area Allocations
First word: word m. m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input No. 1
Data range
Input No. 2
Decimal
Default
Data contents
Hexadecimal
m
12345, 0
3039, 0000 hex 0000 hex
Default block read command
Specifies the direction of data transfer when the PLC is
turned ON or the Unit is restarted for DM Area words
m+1 to m+93.
• 12345 (3039 hex): The data in words m+1 to m+93 is
transferred from the Direct Current Input Unit to the
CPU Unit. When the transfer is completed, the value
will become 0000 hex.
• Other than 12345 (such as 0000 hex): The data in the
allocated words of DM Area is transferred from the
CPU Unit to the Direct Current Input Unit.
m+1
---
---
Not used.
0 (0000 hex)
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (regardless of the
CPU Unit’s operation mode)
Process value alarm settings
m+2
m+10
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4200 (1068
hex)
Process value HH (high high limit) alarm setting
(Set at process value scaling value.)
m+3
m+11
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4000 (0FA0
hex)
Process value H (high limit) alarm setting
(Set at process value scaling value.)
m+4
m+12
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
0 (0000 hex)
Process value L (low limit) alarm setting
(Set at process value scaling value.)
m+5
m+13
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
–200 (FF38
hex)
Process value LL (low low limit) alarm setting
(Set at process value scaling value.)
m+6
m+14
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
4000 (0FA0
hex)
Rate-of-change value H (high limit) alarm setting
(Set at rate-of-change scaling value.)
m+7
m+15
–32768 to
32767
8000 to FFFF
hex, 0000 to
7FFF hex
0 (0000 hex)
Rate-of-change value L (low limit) alarm setting
(Set at rate-of-change scaling value.)
m+8
m+16
0 to 32000
0000 to 7D00
hex
10000 (2710
hex)
Gain for span adjustment
(set value × 0.0001%)
m+9
m+17
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Zero adjustment value
(Set at process value scaling value.)
Rate-of-change value alarm settings
Zero/span adjustment
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Direct Current Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Direct Current Input Unit is restarted.
Input signal type
m+34
328
m+48
0 to 9
0000 to 0009
hex
1 (0001 hex)
0: ±10 V; 1: 0 to 10 V; 2: ±5 V; 3: 0 to 5 V; 4: 1 to 5 V;
5: 4 to 20 mA; 6: ±10 V user-set range; 7: 0 to 20 mA;
8: ±1.25 V; 9: 0 to 1.25 V
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
DM Area address
Input No. 1
Input No. 2
m+35
Data range
Default
Data contents
Decimal
Hexadecimal
m+49
–1000 to 1000
D8F0 to FFFF
hex, 0000 to
2710 hex
10000 (2710
hex)
m+36
m+50
–1000 to 1000
D8F0 to FFFF
hex, 0000 to
2710 hex
0 (0000 hex)
Minimum value in range (set value ×
0.001 V)
m+37
m+51
0, 1
0000, 0001 hex 0 (0000 hex)
Square root extraction (when maximum scaling value >
minimum scaling value)
0: Disable; 1: Enable
m+38
m+52
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Value stored for maximum value in range (span)
m+39
m+53
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Value stored for minimum value in range (zero)
m+40
m+54
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
Alarm hysteresis
(Set at process value scaling value. Shared with process value alarm and rate-of-change alarm.)
m+41
m+55
0 to 60
0000 to 003C
hex
0 (0000 hex)
Alarm ON-delay time (Unit: s)
(Shared with process value alarm and rate-of-change
alarm.)
m+42
m+56
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Rate-of-change
range setting
m+43
m+57
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
–4000 (F060
hex)
m+44
m+58
1 to 16
0001 to 0010
hex
1 (0001 hex)
Rate-of-change comparison time interval (Unit: s)
m+45
m+59
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
4000 (0FA0
hex)
Rate-of-change
value scaling
m+46
m+60
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
–4000 (F060
hex)
m+47
m+61
1 to 128
0001 to 0080
hex
25 (0019 hex)
Number of process values for calculating moving average for mean value processing
0 to 99, 100 to
1XX
0000 to 0063
hex, 0064 to
0XXX hex
0 (0000 hex)
Address of Data Range Error (See note.)
Process value input range
±10-V user-set
range
Maximum value in range (set value ×
0.001 V)
Square root function
Process value scaling
Alarm supplementary functions
Rate-of-change function
Maximum rate-of-change value (Process value industrial unit; comparison
time interval)
Minimum rate-of-change value (Process value industrial unit; comparison
time interval)
Value stored for maximum value in
range
Value stored for minimum value in
range
Mean value processing function
Display parameter
m+90
m+91
Expansion Setting Area Allocation Settings
m+98
0 to 5
0000 to 0005
hex
---
Area of Expansion Setting Area
0: Not used; 1: DM; 2: CIO; 3: W; 4: H; 5: EM
m+99
0 to 32767
0000 to 7FFF
hex
---
First Word in Expansion Setting Area
Note
1. The ERC indicator on the Unit’s front panel will light if an out-of-range setting is made in either Setting Group 1 (continually refreshed area) or 2 (initial settings area), or in the Expansion Setting Area. The offset from word
m to the first address containing the out-of-range error will be stored as the
Address of Data Range Error in the DM Area in four digits hexadecimal.
If the first memory address where the out-of-range error occurred is in the
Expansion Setting Area, the Address of Data Range Area will be +100 or
later. If the first word of the Expansion Setting Area has the error, the Address of Data Range Area will be +100.
329
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
2. When specifying an expansion setting area, be sure that it does not overlap with other areas that are being used. If areas overlap, the words that
are allocated may be overwritten, resulting in unexpected operation.
3. When specifying the first word in an expansion setting area, be sure that
the end of the memory area is not exceeded.
Expansion Setting Area Allocations
First word: word o. o = address specified in word m+99 in the area specified
by word m+98 in the DM Area.
DM Area address
Input No. 1
Data range
Input No. 2
Decimal
Default
Data contents
Hexadecimal
Setting Group 3 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Direct Current Input Unit if
word m contains other than 12345 when the PLC is turned ON or the Direct Current Input Unit is restarted.
Expansion Control/Monitor Area Settings
o
0 to 5
0000 to 0005
hex
---
Expansion Control/Monitor Area allocation
0: Not used. 1: DM; 2: CIO; 3: W; 4: H; 5: EM
o+1
0 to 32767
0000 to 7FFF
hex
---
Expansion Control/Monitor Area first word
Zero/span adjustment supplementary function
o+2
o+13
0 to 32000
0000 to 7D00
hex
10000 (2710
hex)
Span adjustment position
(Input span percentage)
o+3
o+14
–32000 to
32000
8300 to FFFF
hex, 0000 to
7D00 hex
0 (0000 hex)
Zero adjustment position
(Input span percentage)
o+4
o+15
0 to 9999
0000 to 270F
hex
365 (016D hex) Zero/span adjustment period (Unit: Days)
o+5
o+16
0 to 9999
0000 to 270F
hex
30 (001E hex)
Notice of days remaining (Unit: Days)
o+6
o+17
---
---
0 (0000 hex)
Not used
o+7
o+18
o+8
o+19
Not used
Top and valley hold
o+9
o+20
0 to 32000
0000 to 7D00
hex
40 (0028 hex)
o+10
o+21
0, 1
0000, 0001 hex 0 (0000 hex)
Hysteresis
Integral value calculation
Integer unit
0: Minutes; 1: Hours
Not used
o+11
o+22
o+12
o+23
---
Note
---
0 (0000 hex)
Not used.
1. When specifying an expansion control/monitor area be sure that it does not
overlap with other areas that are being used. If areas overlap, the words
that are allocated may be overwritten, resulting in unexpected operation.
2. When specifying the first word in an expansion control/monitor area be
sure that the end of the memory area is not exceeded.
330
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
CIO Area Allocations
First word: word n. n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Direct Current
Input Unit to
CPU Unit
Word
n
Bit
00
Name
Input No. 1 Process value
LL (low low
limit) alarm
Data range
0, 1
01
Process value L 0, 1
(low limit) alarm
02
Process value
H (high limit)
alarm
03
04
05
06
07
0, 1
Contents
0: Process value > Set
value
1: Process value ≤ Set
value
Process value
HH (high high
limit) alarm
Input No. 2 Process value
LL (low low
limit) alarm
Process value L
(low limit) alarm
Process value
H (high limit)
alarm
Process value
HH (high high
limit) alarm
Not used.
0, 1
0: Process value < Set
value
1: Process value ≥ Set
value
0, 1
Same as for input No. 1.
0
Not used.
Input No. 1 process value
The present process value
is stored according to the
scaling set in the allocated
words of the DM Area.
0, 1
0, 1
0, 1
n+1
08 to
15
0 to 15
n+2
0 to 15
Input No. 2 process value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
n+3,
n+4
---
Not used.
0000
Not used.
n+5
0 to 15
Input No. 1 rate-of-change
value
n+6
0 to 15
Input No. 2 rate-of-change
value
–32768 to 32767
(8000 to FFFF hex, 0000
to 7FFF hex)
The present rate-of-change
value is stored according to
the scaling set in the allocated words of the DM
Area.
n+7,
n+8
---
Not used.
0000
Not used.
331
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Direction
Direct Current
Input Unit to
CPU Unit, continued
Word
n+9
Bit
00
Name
Input No. 1 Rate-of-change 0, 1
value L (low
limit) alarm
01
Rate-of-change 0, 1
value H (high
limit) alarm
02
Input No. 2 Rate-of-change 0, 1
value L (low
limit) alarm
Rate-of-change
value H (high
limit) alarm
Not used.
0
03
04 to
07
08
Data range
Contents
0: Rate-of-change value >
set value
1: Rate-of-change value ≤
set value
0: Rate-of-change value <
set value
1: Rate-of-change value ≥
set value
Same as for input No. 1.
Not used.
Input No. 1 input error
0, 1
0: Normal
1: Error (less than –17.2%
or greater than 112.5%)
Note Checks are conducted for inputs of
4 to 20 mA and 1 to
5 V.
09
Input No. 2 input error
0, 1
10 to
12
Not used.
0
Not used.
13
Zero/span adjustment
period end
0, 1
14
Zero/span adjustment
period notice
0, 1
15
External power supply
0, 1
0: Adjustment enabled
1: Adjustment ended
0: Adjustment enabled
1: Notice period
0: External power supply
not used
1: External power supply
used
Note The External Power Supply Flag turns ON after external power is supplied
and the internal voltage stabilizes (which requires approximately 2 s). The
indicator on the front of the Unit will turn ON as soon as external power is supplied.
332
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Expansion Control/Monitor Area Allocations
First word: p. p = address specified in word o+1 in the area specified by word
o in the Expansion Setting Area.
Direction
Word
CPU Unit p
to Direct
Current
p+1
Input Unit,
continued
p+2
p+3
Bit
00 to
15
00
Name
Data range
Contents
Not used.
Not used.
0000
Input No. 1 hold function
selection
Input No. 2 hold function
selection
0, 1
02 to
07
Not used.
0
Not used.
08
09
Input No. 1 hold start
Input No. 2 hold start
0, 1
0, 1
0: Do not hold.
1: Hold
10, 11
12
Not used.
Input No. 1 hold value reset
0
0, 1
13
14, 15
Input No. 2 hold value reset
Not used.
0, 1
0
Not used.
0: Normal operation
1: Reset hold value.
00
Input No. 1 integral value calculation start
0, 1
01
0, 1
02, 03
Input No. 2 integral value calculation start
Not used.
0: Do not start calculation
1: Start calculation
0
Not used.
04
05
Input No. 1 integral value reset 0, 1
Input No. 2 integral value reset 0, 1
0: Normal operation
1: Integral value reset
06 to
15
Not used.
0
Not used.
00
Input No. 1 zero/span adjustment update bit
0, 1
01
Input No. 2 zero/span adjustment update bit
0, 1
02 to
15
Not used.
0
0: Normal operation
1: Update adjustment
date
(Remains ON while
writing external
FROM.)
Not used.
01
0: Peak and bottom
1: Top and valley
0, 1
Not used.
333
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Direction
Word
Direct Cur- p+4
rent Input
Unit to
CPU Unit
Bit
00
Name
Input Zero/span adjustment
No. 1 period end
01
Zero/span adjustment
period notice
Input Zero/span adjustment
No. 2 period end
Zero/span adjustment
period notice
0, 1
04 to
07
Not used.
0
08
External FROM error
0, 1
09 to
15
Not used.
0
p+5
00 to
15
Input Day of final adjustment 0100 to 3100 (BCD)
No. 1 date
p+6
00 to
15
Year and month of final 0001 to 9912 (BCD)
adjustment date
p+7
00 to
15
00 to
15
00 to
15
00 to
15
Input Day of final adjustment 0100 to 3100 (BCD)
No. 2 date
Year and month of final 0001 to 9912 (BCD)
adjustment date
02
03
p+8
p+9 to
p+16
p+17
0, 1
0, 1
Contents
0: Adjustment
enabled.
1: Adjustment period
end
0: Adjustment
enabled.
1: Notice period in
effect.
Remains set to 1 if the
zero/span adjustment
bit has never been ON.
Not used.
0: Normal operation.
1: External FROM
error.
Not used.
Remains set to FFFF if
the zero/span adjustment bit has never
been ON.
Not used.
0000
Not used.
Input Peak/top value
No. 1
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
Counts the number of
repetitions of conditional operations set in
the Expansion Setting
Area.
The bottom or valley
value is stored according to the scaling set in
the DM Area.
00 to
15
p+19
00 to
15
p+20
00 to
15
p+21 to
p+24
---
Not used.
0
p+25
00 to
15
Input Integral value (lower
No. 1 digit)
p+26
00 to
15
00 to
15
00 to
15
00 to
15
Integral value (upper
digit)
Input Integral value (lower
No. 2 digit)
Integral value (upper
digit)
Not used.
−2147483648 to 2147483647 The integral value for
(80000000 to FFFFFFFF hex, the present value is
00000000 to 7FFFFFFF hex) stored according to the
scaling set in the DM
Area.
−2147483648 to 2147483647
(80000000 to FFFFFFFF hex,
00000000 to 7FFFFFFF hex)
p+28
p+29 to
p+34
Bottom/valley value
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
p+18
p+27
334
Data range
0, 1
Input Peak/top value
No. 2
Bottom/valley value
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
Same as for Input No.
1.
−32728 to +32767
(8000 to FFFF hex, 0000 to
7FFF hex)
0000
Not used.
Not used.
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Terminal Connection Diagram
Voltage Inputs
NC
B1 (10)
V1
B2 (11)
COM1
B3 (12)
+
V2
B4 (13)
−
COM2
B5 (14)
NC
B6 (15)
NC
B7 (16)
NC
B8 (17)
0V
B9 (18)
+
Voltage output
device
−
Voltage output
device
A1 (1)
NC
A2 (2)
I1
A3 (3)
NC
A4 (4)
I2
A5 (5)
NC
A6 (6)
NC
A7 (7)
NC
A8 (8)
NC
A9 (9)
24V
Current inputs
+
Current output
device
−
+
−
Current output
device
NC
V1
COM1
V2
COM2
NC
NC
NC
0V
Note
B1 (10)
A1 (1)
B2 (11)
A2 (2)
B3 (12)
A3 (3)
B4 (13)
A4 (4)
B5 (14)
A5 (5)
B6 (15)
A6 (6)
B7 (16)
A7 (7)
B8 (17)
A8 (8)
B9 (18)
A9 (9)
NC
I1
NC
I2
NC
NC
NC
NC
24V
• In both of the above cases, leave all unused inputs open between the
positive and negative terminals (e.g., between B2 and B3 for voltage input
No. 1).
• Always ground the GR terminal on the Power Supply Unit of the PLC.
• If the input device uses a voltage generator, temperature compensator, or
similar device, then ground the input device if it has a ground terminal.
• Always short-circuit the V and I terminals when using current input.
PDC15 terminal block
Short bars
NC
Current output
device
+
−
+
Current output
device
−
NC
V1
I1
COM1
NC
V2
I2
COM2
NC
NC
I3+
NC
NC
NC
I4+
0V
24
335
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Terminal Block Diagram
I1+
A2
Isolation circuit
250 Ω
1 MΩ
COM1
B3
A/D
converter
5 VDC
Photocoupler
Connector
B2
Amplifier
circuit
V1+
1 MΩ
B4
I2+
A4
250 Ω
1 MΩ
COM2
B5
Amplifier
circuit
V2+
Isolation circuit
A/D
converter
Input
selector
Digital
circuits
Photocoupler
1 MΩ
24-VDC
circuit
A9
B9
Power
supply circuit
Error Processing
Conversion Data Does Not Change.
Probable cause
Remedy
The gain for span adjustment is
set to 0.
Set the gain for span adjustment to a value other
than 0.
The minimum and maximum values for process value scaling are
either the same or are set
extremely low.
The input signal type or process
value range is set incorrectly.
An input device is malfunctioning,
input wiring is faulty, or wiring is
disconnected.
Set the minimum and maximum values correctly.
Check and reset the input signal type and the
process value range settings.
Check whether the input voltage or current has
changed. Check for faulty or disconnected wiring.
Check whether an input error has been detected
in the I/O Area.
Values are Not Converted as Intended.
Probable cause
Remedy
The input signal type or process
value scaling is set incorrectly.
Check and reset the input signal type and the
process value scaling settings.
The zero/span adjustment data is
incorrect.
Check and correct the zero/span adjustment settings.
The square root function is operat- Set the square function so that it does not opering.
ate.
336
Section 3-5
CJ1W-PDC15 Isolated-type Direct Current Input Unit
Converted Values are Unstable.
Probable cause
Remedy
Input signals are being affected by Change the connection paths of the input signal
external noise.
lines. (Separate them from sources of noise or
use shielded cable.)
Insert 0.01-µF to 0.1-µF ceramic capacitors
between the I+ and COM input terminals.
Increase the number of values for calculating the
moving average in mean value processing.
The scaling value is greater than
the Unit’s resolution.
Reduce the scaling value.
337
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Overview
The CJ1W-PH41U Isolated-type Universal Input Unit supports four input
channels, each of which can be set to a resistance thermometer, thermocouple, DC signal, or potentiometer input. All inputs are isolated.
CJ1W-PH41U
1U
PH4 RUCN
ERH
ER
H
MAC
No. 1
10
0
10
System Configuration
CJ1W-PH41U
Resistance thermometer input:
Pt100 (3-wire), JPt100 (3-wire)
Pt1000 (3-wire), Pt100 (4-wire)
Thermocouple input:
K, J, T, E, L, U, N, R, S, B,
WRe5-26, PLII
Channel 1
Isolation
Channel 2
Isolation
Channel 3
DC input:
4 to 20 mA,
0 to 20 mA
mA
DC voltage input:
1 to 5 V, 0 to 1.25 V, 0 to 5 V,
0 to 10 V, ±100 mV, −1.25 to 1.25 V,
−5 to 5 V, −10 to 10 V
V
±100 mV
Potentiometer input
Isolation
Channel 4
O
W
C
Features
• A single Unit supports a maximum of four inputs: resistance thermometer,
thermocouple, DC current/voltage, and potentiometer. The input type is
set separately for each input.
Resistance thermometer input Pt100 (JIS, IEC 3-wire), JPt100 (3-wire),
Pt1000 (3-wire), or Pt100 (JIS, IEC 4-wire) can be selected.
Thermocouple input K, J, T, E, L, U, N, R, S, B, WRe5-26, or PLII can be
selected.
For DC signal, 4 to 20 mA, 0 to 20 mA, 1 to 5 V, 0 to 1.25 V, 0 to 5 V, 0 to
10 V, ±100 mV, −1.25 to 1.25 V, −5 to 5 V, or −10 to 10 V can be selected.
In addition, a potentiometer input can be selected.
• Isolation between input channels prevents unwanted current paths
between input channels.
• A minimum resolution of 1/256,000 is achieved.
• The conversion period is 60 ms/4 points at a resolution of 1/256,000,
10 ms/4 points at 1/64,000 (Pt1000 or a potentiometer input cannot be
338
CJ1W-PH41U Isolated-type Universal Input Unit
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Section 3-6
selected), and 5 ms/4 points at 1/16,000 (K and E thermocouple inputs
only can be selected). The fastest conversion period is automatically set
for the resolution.
Scaled values are transferred to the CPU Unit in eight or four digits hexadecimal.
Input ranges can be set to any values.
Process value alarms (four alarms for each point) are provided.
Alarm ON/OFF delay timer and hysteresis are provided for process values.
Averaging function is provided.
Rate-of-change function is provided.
Rate-of-change alarms (two alarms for each point) are provided.
Zero/span adjustment during operation is supported.
Input error detection is supported.
Process value clamp direction is supported for input burnout.
Adjustment period control is provided.
Peak and bottom value detection is supported.
Top and valley value detection is supported.
Square root extraction (DC input only) is supported.
Integral value calculation is supported.
Model Information
Type of
Unit
CJ-series
Special I/O
Unit
Model
CJ1W-PH41U
Number of
Input types
inputs
4
Resistance thermometer: Pt100 (JIS, IEC 3-wire), JPt100 (3-wire), Pt1000
(3-wire), Pt100 (JIS, IEC 4-wire)
Thermocouple:
K, J, T, E, L, U, N, R, S, B, WRe5-26, PLII
Current:
4 to 20 mA, 0 to 20 mA
Voltage:
1 to 5 V, 0 to 1.25 V, 0 to 5 V, 0 to 10 V, ±100 mV,
−1.25 to 1.25 V, −5 to 5 V, −10 to 10 V
Potentiometer:
The input type is set separately for each input.
339
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Block Diagram (Order of Processing)
● CPU Unit
Expansion Control/Monitor Area
Peak/bottom value
Top/valley value
Rate-of-change value
CIO Area
Process value
HH, H, L, LL
H, L
Process value alarm
Rate-of-change alarm
Input error alarm
I/O refresh
● Isolated-type Universal Input Unit
Rate-of-change
alarm
Process value alarm
Output limit: −15% to 115%
Rate-of-change
calculation and scaling
Input error: 115% or −15%
Output limit: −15% to 115%
Offset compensation
Input error check
Square root (DC input only)
Zero/span adjustment
Process value scaling
Input calculations:
Thermocouple input only
• Input range
• Cold junction temperature compensation
(thermocouple input only)
A/D conversion, moving average
Cold junction sensor
Resistance thermometer, thermocouple, DC
input, or potentiometer
340
Cold junction
sensor error
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Specifications
Item
Specifications
Model
CJ1W-PH41U
Applicable PLC
Type of Unit
CJ Series
CJ-series Special I/O Unit
Mounting position
Maximum number of Units
CPU Rack or CJ-series Expansion Rack
40 (within the allowable current consumption and power consumption range)
Unit numbers
Areas for
exchanging
data with the
CPU Unit
00 to 95 (Cannot duplicate Special I/O Unit numbers.)
10 words/Unit
Special I/O Unit
Area words in
the CIO Area
Isolated-type Universal Input Unit to CPU Unit:
All process values, process value alarms (LL, L, H, HH), rate- of-change alarms (L, H),
input errors (such as disconnection alarms), cold junction sensor errors, and zero/
span adjustment period end/notices.
100 words/Unit
Special I/O Unit
words in the DM CPU Unit to Isolated-type Universal Input Unit:
Area
Operation settings, input type, input range (user set), temperature unit, process value
clamp direction for input burnout, scaling upper and lower limits, scaling offset value,
alarm hysteresis, alarm ON/OFF delay time, number of items for moving average,
Expansion Setting Area settings, process value alarm setting (L, H), zero/span adjustment value.
Expansion Con- 46 words/Unit
trol/Monitor Area CPU Unit to Isolated-type Universal Input Unit:
Hold function selection start/reset, integral value calculation start/reset, zero/span
adjustment period flag
Isolated-type Universal Input Unit to CPU Unit:
All rate-of-change values, zero/span adjustment period notices (all inputs), EEPROM
errors, day of final adjustment date, top and valley detection flags, peak and bottom
values, top and valley values, integral value.
Expansion Setting Area
Number of inputs
Input type
Resolution:
1/256,000 (Conversion period:
60 ms)
Resolution:
1/64,000 (Conversion period:
10 ms)
Resolution:
1/16,000 (Conversion period:
5 ms)
100 words/Unit
CPU Unit to Isolated-type Universal Input Unit:
Expansion Control/Monitor Area settings, square root calculation enable, rate-ofchange input range, rate-of-change comparison time interval, rate-of-change scaling
upper and lower limits, zero/span adjustment position, zero/span adjustment period
and notice of days remaining, top and valley hysteresis, integral value calculation integer unit and integer coefficient, temperature resistance thermometer compensation
enable, temperature resistance thermometer reference resistance, cold junction compensation method, process value alarm settings (LL, HH), rate-of-change alarm settings (L, H).
4
Pt100 (JIS, IEC 3-wire), JPt100 (3-wire), Pt1000 (3-wire), Pt100 (JIS, IEC 4-wire), K,
J, T, E, L, U, N, R, S, B, WRe5-26, PLII, 4 to 20 mA, 0 to 20 mA, 1 to 5 V, 0 to 1.25 V,
0 to 5 V, 0 to 10 V, ±100 mV user-set range, −1.25 to 1.25 V, −5 to 5 V, −10 to 10 V,
±10 V user-set range, potentiometer (all inputs). The input type, input range, and scaling can be set for individual inputs. The input range for DC inputs, however, can be set
only for input types with user-set input ranges.
Pt100 (JIS, IEC 3-wire), JPt100 (3-wire), Pt100 (JIS, IEC 4-wire), K, J, T, E, L, U, N, R,
S, B, WRe5-26, PLII, 4 to 20 mA, 0 to 20 mA, 1 to 5 V, 0 to 1.25 V, 0 to 5 V, 0 to 10 V,
±100 mV user-set range, −1.25 to 1.25 V, −5 to 5 V, −10 to 10 V, ±10 V user-set range
(all inputs). The input type, input range, and scaling can be set for individual inputs.
The input range for DC inputs, however, can be set only for input types with user-set
input ranges.
K, E
341
CJ1W-PH41U Isolated-type Universal Input Unit
Item
Applicable standards for resistance thermometer and thermocouple inputs
Scaling
Data storage in the Special I/O
Unit Area in the CIO Area
Accuracy (25°C)
Section 3-6
Specifications
Pt100: JIS C1604-1997, IEC 60751-95
JPt100: JIS C1604-1989
K, J, T, E, N, R, S, B: JIS C1602-1995
L, U: DIN 43710-1985
WRe5-26: ASTM E988-96
PLII: ASTM E1751-00
Data to be stored in the allocated words in the CIO area must be scaled (with user-set
minimum and maximum values for data and offsets). The inputs are set individually.
Data can be converted at 0% to 100%.
The values derived from carrying out the following processing in order of the actual
process data in the input range are stored in four digits hexadecimal (binary values) in
the allocated words in the Special I/O Unit Area.
1) Averaging → 2) Scaling → 3) Zero/span adjustment → 4) Square root calculation →
5) Offset compensation → 6) Output limits
Resistance thermometer or thermocouple input:
±0.05% (The accuracy depends on the input type and the measured temperature. For details, refer to the Accuracy and Temperature Coefficient According to
Resistance Thermometer and Thermocouple Input Types and Measured Temperatures on page 347.
Current or voltage input: ±0.05%
Potentiometer input: ±1%
Temperature coefficient
Resistance thermometer or thermocouple input:
The temperature coefficient depends on the input type and the measured temperature. For details, refer to the Accuracy and Temperature Coefficient According to
Resistance Thermometer and Thermocouple Input Types and Measured Temperatures on page 347.
Current or voltage input: ±80 ppm/°C (for full scale)
Potentiometer input: ±100 ppm/°C (for full scale)
Cold junction compensation error Thermocouple input: ±1.2°C
Resolution
Input signal range
1/256,000 (Conversion period: 60 ms) (See note.), 1/64,000 (Conversion period:
10 ms), 1/16,000 (Conversion period: 5 ms)
Note: The resolution for a potentiometer input is 1/4,000.
Resistance thermometer, thermocouple, ±100 mV user-set input:
−15% to 115% of measurable input range
4 to 20 mA, 1 to 5 V, 0 to 1.25 V, 0 to 5 V, 0 to 10 V input:
−15% to 115%
0 to 20 mA input:
0% to 115%
−1.25 to 1.25 V, −5 to 5 V, −10 to 10 V, ±10 V user-set range input:
−7.5% to 107.5%
Potentiometer input:
−15% to 115% of 0 to 2,500 Ω
Influence of lead wire resistance
Resistance thermometer input:
0.06°C/Ω (20 Ω max.) (3-wire)
0.006°C/Ω (20 Ω max.) (4-wire)
Input detection current
Resistance thermometer input: Approx. 0.21 mA (3-wire), approx. 0.42 mA (4-wire)
Potentiometer input: Approx. 0.21 mA
Absolute maximum ratings
Thermocouple, ±100 mV user-set range input: ±130 mV
Current input: 30 mA
Voltage input (excluding ±100 mV user-set range): ±15 V
Input impedance
Thermocouple, ±100 mV user-set range input: 20 kΩ min.
Current input: 150 Ω max.
Voltage input (excluding ±100 mV user-set range): 1 MΩ min.
Input disconnection detection cur- Thermocouple, ±100 mV user-set range input: Approx. 0.1 µA
rent
342
CJ1W-PH41U Isolated-type Universal Input Unit
Item
Warmup time
Section 3-6
Specifications
Resistance thermometer input: 30 min
Thermocouple, ±100 mV user-set range input: 45 min
Current or voltage input (excluding ±100 mV user-set range): 30 min
Potentiometer input: 10 min
Response time
1/256,000 resolution:
Resistance thermometer input:
180 ms max. (travel time from input 0% to 90%, for step input and with moving average for 1 sample)
Thermocouple, ±100 mV user-set range input:
180 ms max. (travel time from input 0% to 90%, for ±100 mV step input and
with moving average for 1 sample)
Current or voltage input:
180 ms max. (travel time from input 0% to 90%, for ±10 V step input and with
moving average for 1 sample)
Potentiometer input:
180 ms max. (travel time from input 0% to 90%, for step input and with moving average for 1 sample)
1/64,000 resolution:
Resistance thermometer input:
100 ms max. (travel time from input 0% to 90%, for step input and with moving average for 4 samples)
Thermocouple, ±100 mV user-set range input:
100 ms max. (travel time from input 0% to 90%, for ±100 mV step input and
with moving average for 4 samples)
Current or voltage input:
100 ms max. (travel time from input 0% to 90%, for ±10 V step input and with
moving average for 4 samples)
1/16,000 resolution:
Thermocouple input:
100 ms max. (travel time from input 0% to 90%, for ±100 mV step input and
with moving average for 4 samples)
Conversion period
60 ms/4 inputs (1/256,000 resolution), 10 ms/4 inputs (1/64,000 resolution, 5 ms/
4 inputs (1/16,000 resolution)
Maximum time to store data in
CPU Unit
Conversion period + one CPU Unit cycle
343
CJ1W-PH41U Isolated-type Universal Input Unit
Item
Input disconnection and input
error detection
344
Section 3-6
Specifications
Resistance thermometer, thermocouple, ±100 mV user-set range, potentiometer
input:
Input Error Flag turns ON when a disconnection occurs or when 115% or −15% of
the measurable input range is exceeded.
The process value clamp direct direction for when a disconnection occurs can be
specified. (High: 115% of set input range. Low: −15% of set input range.)
Disconnection detection time:
Approx. 5 s max. (4-wire Pt100)
Approx. 1 s max. (±100 mV user-set range)
Approx. 0.5 s max. (not 4-wire Pt100 or ±100 mV user-set range)
4 to 20 mA, 1 to 5 V, 0 to 1.25 V, 0 to 5 V, 0 to 10 V input:
An error is detected and the Input Error Flag turns ON when a disconnection
occurs or when 115% or −15% of the measurable input range is exceeded.
When a disconnection occurs in the 4 to 20 mA/1 to 5 V range, the −15% process
value is stored. When a disconnection occurs in any other range, a process value
the same as for a 0 V input is stored.
0 to 20 mA input:
An error is detected and the Input Error Flag turns ON when 115% of the measurable input range is exceeded. When a disconnection occurs, a process value the
same as for a 0 mA input is stored.
−1.25 to 1.25 V, −5 to 5 V,−10 to 10 V, ±10 V user-set range input:
An error is detected and the Input Error Flag turns ON when 107.5% or −7.5% of
the measurable input range is exceeded. When a disconnection occurs, a process
value the same as for a 0 V input is stored.
CJ1W-PH41U Isolated-type Universal Input Unit
Function
Item
Process value
alarm
Section 3-6
Specifications
Four process value alarms (HH, H, LL, L), hysteresis, and ON/OFF-delay timer (0 to
60 s) can be set.
Rate-of-change
calculation
Calculates the amount of change per process value comparison time interval (Either 1
to 16 s or the conversion period can be set.)
Rate-of-change
alarm
Two rate-of-change alarms (H, L), hysteresis, and ON/OFF-delay timer (0 to 60 s) can
be set (shared with process value alarm).
Process value
Calculates the moving average for the specified number of past process values (1 to
averaging (input 128), and stores that value in the CIO Area as the process value.
filter)
Square root
extraction
Adjustment
period control
Peak and bottom detection
Top and valley
detection
Integral value
calculation
When the process value scaling maximum value is A and the minimum value is B:
Output = 〈 A – B〉 × 〈 Input – B〉 + B
Dropout: Output approx. 7% maximum linear (output = input) characteristics
Note 1: The square root function is enabled for DC inputs only. It is not performed for
temperature inputs.
Note 2: The square root function is enabled only when the maximum scaling value is
greater than the minimum value. It is not performed when the minimum value
is greater.
Note 3: When performing square root calculation, set the maximum and minimum
scaling values to the scaling values following square root extraction of the
flowrate or other input value.
When zero/span adjustment is executed, the date is internally recorded at the Unit.
When the preset zero/span adjustment period and the notice of days remaining set in
the Expansion Setting Area have elapsed, this function turns ON a warning flag to
give notice that it is time for readjustment.
Detects the maximum (peak) and minimum (bottom) process values, from when the
Hold Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON until
it turns OFF. These values are stored as the peak and bottom values in the Expansion
Control/Monitor Area.
This function detects the top and valley values for process values, from when the Hold
Start Bit (output) allocated to the Expansion Control/Monitor Area turns ON until it
turns OFF. These values are stored as the top and valley values in the Expansion
Control/Monitor Area.
This function calculates the process value's time integral. The integral value is calculated and the result is output to the Expansion Control/Monitor Area when the Integral
Value Calculation Start Bit in the Expansion Control/Monitor Area is turned ON.
Specifies whether cold junction compensation is to be executed internally or externally.
Note: This function is supported only for thermocouple inputs.
Resistance ther- Compensation is enabled for a connected resistance thermometer by setting the
resistance for 23°C.
mometer input
compensation
Note: This function is supported only for resistance thermometer inputs.
Isolation
Between inputs and PLC signals, and between inputs: Power supply = Transformer,
Signal = Digital isolator
Insulation resistance
20 MΩ (at 500 V DC) between all inputs
Cold junction
compensation
method
Dielectric strength
External connections
Between all inputs: 500 V AC, at 50 or 60 Hz, for 1 min, leakage current 10 mA max.
Terminal block (detachable)
Unit number settings
Indicators
Set by rotary switches on front panel, from 0 to 95.
Three LED indicators on front panel (for normal operation, errors detected at the Universal Input Unit, and errors detected at the CPU Unit).
Front panel connector
Input connector terminal block (detachable)
Effect on CPU Unit cycle time
0.4 ms
Current consumption (supplied by 5 VDC at 300 mA max.
Power Supply Unit)
Dimensions
31 × 90 × 65 mm (W × H × D)
345
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Item
Specifications
Weight
150 g max.
Standard accessories
One cold junction sensor (mounted to terminal block)
Input Types and Input
Ranges
The input type and range are set in the DM Area for each input. Each input
range can be set within the measurable input range shown in the following
table. (DC input ranges are user-set.) The accuracy and resolution are determined by the measurable input ranges shown in the table, and not by the set
input ranges. The accuracy and resolution are not changed by narrowing the
input range.
■
Resolution: 1/256,000
Input type
DM Area settings
0
3
−200.00 to 850.00°C
−200.00 to 500.00°C
Pt1000 (3-wire)
Pt100 (4-wire)
7
9
−200.00 to 850.00°C
−200.00 to 850.00°C
K
10
15
0.000 to 50.000°C
−200.0 to 1300.0°C
J
16
17
−20.00 to 600.00°C
−200.0 to 1200.0°C
T
18
19
−20.00 to 600.00°C
−200.00 to 400.00°C
E
L
20
21
−200.0 to 1000.0°C
−200.0 to 900.0°C
U
N
22
23
−200.0 to 600.0°C
−200.0 to 1300.0°C
R
S
24
25
−50.0 to 1700.0°C
−50.0 to 1700.0°C
B
WRe5-26
26
27
0.0 to 1800.0°C
0.0 to 2300.0°C
PLII
4 to 20 mA
28
30
0.0 to 1300.0°C
4 to 20 mA
0 to 20 mA
1 to 5 V
31
32
0 to 20 mA
1 to 5 V
0 to 1.25 V
0 to 5 V
34
35
0 to 1.25 V
0 to 5 V
0 to 10 V
±100 mV user-set
range
±1.25 V
36
37
0 to 10 V
−100 to 100 mV
38
−1.25 to 1.25 V
±5 V
±10 V
39
40
−5 to 5 V
−10 to 10 V
±10 V user-set range 41
Potentiometer
50
346
Measurable input range
Pt100 (3-wire)
JPt100 (3-wire)
−10 to 10 V
0 to (100 to 2500) Ω
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
■
Resolution: 1/64,000
Input type
Pt100 (3-wire)
0
DM Area settings
Measurable input range
−200.00 to 850.00°C
JPt100 (3-wire)
Pt100 (4-wire)
3
9
−200.00 to 500.00°C
−200.00 to 850.00°C
K
J
15
17
−200.0 to 1300.0°C
−200.0 to 1200.0°C
T
E
19
20
−200.00 to 400.00°C
−200.0 to 1000.0°C
L
U
21
22
−200.0 to 900.0°C
−200.0 to 600.0°C
N
R
23
24
−200.0 to 1300.0°C
−50.0 to 1700.0°C
S
B
25
26
−50.0 to 1700.0°C
0.0 to 1800.0°C
WRe5-26
PLII
27
28
0.0 to 2300.0°C
0.0 to 1300.0°C
4 to 20 mA
0 to 20 mA
30
31
4 to 20 mA
0 to 20 mA
1 to 5 V
0 to 1.25 V
32
34
1 to 5 V
0 to 1.25 V
0o5V
0 to 10 V
35
36
0 to 5 V
0 to 10 V
±100 mV user-set
range
37
−100 to 100 mV
±1.25 V
±5 V
38
39
−1.25 to 1.25 V
−5 to 5 V
±10 V
40
±10 V user-set range 41
■
−10 to 10 V
−10 to 10 V
Resolution: 1/16,000
Input type
K
E
DM Area settings
Measurable input range
−200.0 to 1300.0°C
−200.0 to 1000.0°C
15
20
Accuracy and Temperature Coefficient According to Resistance Thermometer and Thermocouple Input
Types and Measured Temperatures
Input classification
Temperature
sensor type
Pt100 (3-wire)
Measured
temperature (°C)
Temperature range
(°C)
−200.00 to 850.00
−200.00 to −50.00
Standard accuracy
°C (%)
Temperature coefficient (See
note 1.)
°C/°C (ppm/°C) (See note 2.)
±0.5°C (±0.05%)
±0.08°C/°C (±78ppm/°C)
−50.00 to 150.00
150.00 to 850.00
±0.21°C (±0.02%)
±0.5°C (±0.05%)
±0.03°C/°C (±29ppm/°C)
±0.08°C/°C (±78ppm/°C)
JPt100 (3-wire)
Pt1000 (3-wire)
−200.00 to 500.00
−200.00 to 850.00
Same as on the left.
Same as on the left.
±0.4°C (±0.05%)
±0.5°C (±0.05%)
±0.07°C/°C (±96ppm/°C)
±0.09°C/°C (±85ppm/°C)
Pt100 (4-wire)
−200.00 to 850.00
0.000 to 50.000
Same as on the left.
Same as on the left.
±0.5°C (±0.05%)
±0.025°C (±0.05%)
±0.02°C/°C (±17ppm/°C)
±0.005°C/°C (±90ppm/°C)
K
−200.0 to 1300.0
−20.00 to 600.00
Same as on the left.
Same as on the left.
±0.75°C (±0.05%)
±0.3°C (±0.05%)
±0.08°C/°C (±50ppm/°C)
±0.03°C/°C (±48ppm/°C)
347
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Input classification
Temperature
Temperature range
sensor type
(°C)
Measured
temperature (°C)
Standard accuracy
°C (%)
Temperature coefficient (See
note 1.)
°C/°C (ppm/°C) (See note 2.)
J
−200.0 to 1200.0
−200.0 to 0.0
0.0 to 1200.0
±0.7°C (±0.05%)
±0.13°C/°C (±96ppm/°C)
±0.06°C/°C (±42ppm/°C)
T
−20.00 to 600.00
−200.00 to 400.00
Same as on the left.
−200.00 to −180.00
±0.3°C (±0.05%)
±1.3°C (±0.22%)
±0.04°C/°C (±72ppm/°C)
±0.05°C/°C (±75ppm/°C)
−180.00 to 0.00
0.00 to 400.00
±0.7°C (±0.12%)
±0.33°C (±0.055%)
E
−200.0 to 1000.0
−200.0 to 0.0
0.0 to 1000.0
±0.6°C (±0.05%)
±0.12°C/°C (±100ppm/°C)
±0.06°C/°C (±50ppm/°C)
L
U
−200.0 to 900.0
−200.0 to 600.0
Same as on the left.
−200.0 to −100.0
±0.5°C (±0.05%)
±0.7°C (±0.09%)
±0.04°C/°C (±40ppm/°C)
±0.06°C/°C (±75ppm/°C)
−100.0 to 0.0
0.0 to 600.0
±0.5°C (±0.07%)
±0.4°C (±0.05%)
−200.0 to −150.0
−150.0 to −100.0
±1.6°C (±0.11%)
±0.75°C (±0.05%)
N
R
−200.0 to 1300.0
−50.0 to 1700.0
S
−50.0 to 1700.0
B
0.0 to 1800.0
WRe5-26
PLII
0.0 to 2300.0
0.0 to 1300.0
Note
−100.0 to 1300.0
−50.0 to 0.0
±3.2°C (±0.19%)
0.0 to 100.0
100.0 to 1700.0
±2.5°C (±0.15%)
±1.75°C (±0.1%)
±0.11°C/°C (±60ppm/°C)
−50.0 to 0.0
0.0 to 100.0
±3.2°C (±0.19%)
±2.5°C (±0.15%)
±0.13°C/°C (±77ppm/°C)
±0.11°C/°C (±60ppm/°C)
100.0 to 1700.0
0.0 to 400.0
±1.75°C (±0.1%)
May not be accurate.
May not be accurate.
400.0 to 800.0
±3°C (±0.17%)
±0.12°C/°C (±66ppm/°C)
800.0 to 1800.0
0.0 to 1500.0
±1.8°C (±0.1%)
±1.15°C (±0.05%)
±0.13°C/°C (±58ppm/°C)
1500.0 to 2200.0
2200.0 to 2300.0
±1.4°C (±0.07%)
Same as on the left.
±0.65°C (±0.05%)
±0.08°C/°C (±50ppm/°C)
±0.13°C/°C (±77ppm/°C)
±0.21°C/°C (±91ppm/°C)
±0.07°C/°C (±57ppm/°C)
1. Error in process value when ambient temperature changes by 1°C.
2. For full-scale.
348
±0.11°C/°C (±70ppm/°C)
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
DM Area Allocations
First word: word m. m = D20000 + unit number × 100 (unit number: 0 to 95)
DM Area address
Input Input Input Input
No. 1 No. 2 No. 3 No. 4
m
m+1
Data range
Decimal
Hexadecimal
Default
Data contents
12345, 0
3039 hex, 0000 hex 0 (0000 hex)
Default Block Read Command
Specifies the direction of data transfer when the PLC is turned ON or
the Unit is restarted.
• 12345 (3039 hex): The initial settings for the Analog I/O Unit are
transferred from the Analog I/O
Unit to words m+1 to m+93 in the
CPU Unit. When the transfer is
completed, the value will become
0000 hex.
• Other than 12345 (3039 hex),
such as 0 (0000 hex): The data in
the allocated words of DM Area is
transferred from the CPU Unit to
the Analog Input Unit.
Operation Settings (See note 1.)
(See note 1.)
(See note 1.)
0 (0000 hex)
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
Process value alarm settings
Lower
Process Value H (High
40000
(00009C40 hex) Upper
Limit) Alarm Setting (Set
to process value scaling value.)
0
Lower
Process Value L (Low
(00000000 hex) Upper
Limit) Alarm Setting (Set
to process value scaling value.)
Bits 00 to 03: Resolution Switch
Bits 04 to 07: Process Value Data
Length
Setting Group 1 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (can
be set regardless of the CPU Unit's operation mode)
m+2 m+10 m+18 m+26 −2147483648
m+3 m+11 m+19 m+27 to
2147483647
m+4 m+12 m+20 m+28 −2147483648
m+5 m+13 m+21 m+29 to
2147483647
m+6 m+14 m+22 m+30 1 to
m+7 m+15 m+23 m+31 100000000
00000001 to
05F5E100 hex
m+8 m+16 m+24 m+32 −2147483648
m+9 m+17 m+25 m+33 to
2147483647
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
Zero/span adjustment
10000000
Lower
Gain for Span Adjust(00989680 hex) Upper
ment (set value ×
0.0000001% (10−7)%)
0
Lower
Zero Adjustment Value
(00000000 hex) Upper
(Set to process value
scaling value.)
349
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
DM Area address
Input Input Input Input
No. 1 No. 2 No. 3 No. 4
Decimal
Data range
Hexadecimal
Default
Data contents
Setting Group 2 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Analog Input
Unit if word m contains other than 12345 when the PLC is turned ON or the Analog Input Unit is restarted.
Input Signal Type
• When the Resolution Switch Is Set
to 0 (1/256,000)
0: Pt100, 3-wire,
3: JPt100, 3-wire,
7: Pt1000, 3-wire,
9: Pt100, 4-wire (1),
10: Pt100, 4-wire (2),
15: K (1), 16: K (2), 17: J (1),
18: J (2), 19: T, 20: E, 21: L,
22: U, 23: N, 24: R, 25: S, 26: B,
27: WRe5-26, 28: PLII,
30: 4 to 20 mA, 31: 0 to 20 mA,
32: 1 to 5 V, 34: 0 to 1.25 V,
35: 0 to 5 V, 36: 0 to 10 V,
37: ±100 mV user-set range,
38: ±1.25 V, 39: ±5 V, 40: ±10 V,
41: ±10 V user-set range,
50: Potentiometer
• When the Resolution Switch Is Set
to 1 (1/64,000)
0: Pt100, 3-wire,
3: JPt100, 3-wire,
9: Pt100, 4-wire (1),
15: K (1), 17: J (1), 19: T, 20: E,
21: L, 22: U, 23: N, 24: R, 25: S,
26: B, 27: WRe5-26, 28: PLII,
30: 4 to 20 mA, 31: 0 to 20 mA,
32: 1 to 5 V, 34: 0 to 1.25 V,
35: 0 to 5 V, 36: 0 to 10 V,
37: ±100 mV user-set range,
38: ±1.25 V, 39: ±5 V, 40: ±10 V,
41: ±10 V user-set range
• When the Resolution Switch Is Set
to 2 (1/16,000)
15: K (1), 20: E
Process Value Input Range
m+34 m+49 m+64 m+79 0 to 50
0 to 32 hex
36 (0024 hex)
m+35 m+50 m+65 m+80 −32000 to
32000
8300 to FFFF hex
0000 to 7D00 hex
10000
(2710 hex)
Maximum Input Signal Value
(Set value × 0.1°C for °C, set value ×
0.1°F for °F, set value × 0.1 mV for
±100 mV user-set range, set value ×
0.001 V for ±10 V user-set range,
set value × 1 Ω for potentiometer)
Note: Only for a temperature input
user-set range for a DC input,
or a potentiometer input.
m+36 m+51 m+66 m+81 −32000 to
32000
8300 to FFFF hex
0000 to 7D00 hex
0
(0000 hex)
m+37 m+52 m+67 m+82 0, 1
0000, 0001 hex
0
(0000 hex)
Minimum Input Signal Value
(Set value × 0.1°C for °C, set value ×
0.1°F for °F, set value × 0.1 mV for
±100 mV user-set range, set value ×
0.001 V for ±10 V user-set range,
set value × 1 Ω for potentiometer)
Note: Only for a temperature input
user-set range for a DC input,
or a potentiometer input.
Unit
0: °C, 1: °F
Process Value Clamp Direction
for Input Burnout
m+38 m+53 m+68 m+83 0, 1
350
0000, 0001 hex
0
(0000 hex)
0: Upper limit, 1: Lower limit
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
DM Area address
Input Input Input Input
No. 1 No. 2 No. 3 No. 4
Decimal
Data range
Hexadecimal
Default
Data contents
Process Value Scaling
10000
Lower
Value Stored for Maxi(00002710 hex) Upper
mum Value in Range
(Span)
m+39 m+54 m+69 m+84 −2147483648
m+40 m+55 m+70 m+85 to
2147483647
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
m+41 m+56 m+71 m+86 −2147483648
m+42 m+57 m+72 m+87 to
2147483647
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
0
Lower
(00000000 hex) Upper
Value Stored for Minimum Value in Range
(Zero)
0
Lower
(00000000 hex) Upper
Scaling Offset
m+45 m+60 m+75 m+90 0 to 32767
0000 to 7FFF hex
40
(0028 hex)
m+46 m+61 m+76 m+91 0 to 60
0000 to 003C hex
0
(0000 hex)
m+47 m+62 m+77 m+92 0 to 60
0000 to 003C hex
0
(0000 hex)
m+48 m+63 m+78 m+93 0 to 128
0000 to 0080 hex
0
(0000 hex)
Number of Process Values for Calculating Moving Average for Mean
Value Processing
0: 4 values for a resolution of
1/256,000, 25 values for a resolution of 1/64,000 or 1/16,000
1 to 128: Number of process values
m+94 m+95 m+96 m+97 0 to 99, 100 to 0000 to 0063 hex,
1XX
0064 to 0XXX hex
0
(0000 hex)
Address of Data Range Error (See
note 2.)
Expansion Setting Area Allocation Settings
m+98
0 to 5
0000 to 0005 hex
---
Area of Expansion Setting Area
0: Not used; 1: DM; 2: CIO; 3: W;
4: H; 5: EM
First Word in Expansion Setting
Area
m+43 m+58 m+73 m+88 −2147483648
m+44 m+59 m+74 m+89 to
2147483647
Alarm Supplementary Functions
Alarm Hysteresis
(Set to process value scaling value.
Shared with process value alarm
and rate-of-change alarm.)
Alarm ON-delay Time (Unit: s)
(Shared with process value alarm
and rate-of-change alarm.)
Alarm OFF-delay Time (Unit: s)
(Shared with process value alarm
and rate-of-change alarm.)
Mean Value Processing Function
Display parameter
m+99
0 to 32767
0000 to 7FFF hex
---
351
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Note
1. The operation settings are as follows:
Address
Bits
m+1
00 to 03
04 to 07
Descriptions
Resolution Switch
Settings
0: 1/256,000 (conversion period:
60 ms)
1: 1/64,000 (conversion period:
10 ms)
2: 1/16,000 (conversion period:
5 ms)
Process Value Data
Length
(Sets the data length
for the process value,
rate of change, peak
value, top value, bottom value, and valley
value.)
0: 2 words (signed double word
binary data)
1: 1 word (Restricted to the following range: −32768 to 32767
(8000 to FFFF hex, 0000 to
7FFF hex).)
2. The ERC indicator on the front of the Analog Input Unit will light if a setting
in the Set Group 1 (continuously refreshed area), Setting Group 2 (initial
settings area), or Expansion Setting Area Allocation Settings Area is out of
range. The offset from word m to the first address containing the out-ofrange error will be stored as the Address of Data Range Error in the DM
Area in four digits hexadecimal. If the first memory address where the outof-range error occurred is in the Expansion Setting Area, the Address of
Data Range Area will be +100 or later. If the first word of the Expansion
Setting Area has the error, the Address of Data Range Area will be +100.
3. When specifying an Expansion Setting Area, be sure that it does not overlap with other areas that are being used. If areas overlap, the words that
are allocated may be overwritten, resulting in unexpected operation.
4. When specifying the first word in an Expansion Setting Area, be sure that
the end of the memory area is not exceeded.
5. Set the first word in an Expansion Setting Area to an even-numbered address.
Expansion Setting Area Allocations
First word: word o. o = address specified in word m+99 in the area specified
by word m+98 in the DM Area.
DM Area address
Input Input Input Input
No. 1 No. 2 No. 3 No. 4
Decimal
Data range
Hexadecimal
Default
Data contents
Setting Group 3 (continuously refreshed area): Parameters that are continuously refreshed during PLC operation (can
be set regardless of the CPU Unit's operation mode)
o+1
o+9
o+16 o+24 −2147483648
o+17 o+25 to
2147483647
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
o+2
o+3
o+10 o+18 o+26 −2147483648
o+11 o+19 o+27 to
2147483647
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
o+4
o+12 o+20 o+28 −2147483648
o+13 o+21 o+29 to
2147483647
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
o
o+8
o+5
352
Process Value Alarm Set Value
Lower
Process Value HH
42000
(0000A410 hex) Upper
(High High Limit) Alarm
Setting (Set to process
value scaling value.)
−2000
Lower
(FFFFF830 hex) Upper
Process Value LL
(Low Low Limit) Alarm
Setting (Set to process
value scaling value.)
Rate-of-change Value Alarm Settings
40000
Lower
Rate-of-change Value H
(00009C40 hex) Upper
(High Limit) Alarm Setting (Set to rate-ofchange scaling value.)
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
DM Area address
Data range
Default
Data contents
Input Input Input Input
Decimal
Hexadecimal
No. 1 No. 2 No. 3 No. 4
o+6 o+14 o+22 o+30 −2147483648 80000000 to
0
Lower
Rate-of-change Value L
FFFFFFFF hex,
(00000000 hex) Upper
(Low Limit) Alarm Seto+7 o+15 o+23 o+31 to
2147483647
00000000 to
ting (Set at rate-of7FFFFFFF hex
change scaling value.)
Setting Group 4 (initial settings area): Parameters that are transferred one time from the CPU Unit to the Analog Input
Unit when an Expansion Setting Area is allocated if word m contains other than 12345 when the PLC is turned ON or the
Analog Input Unit is restarted.
o+32
0 to 5
0000 to 0005 hex
o+33
0 to 32767
0000 to 7FFFF hex ---
First Address in the Expansion Allocation Area
Square Root Calculations
o+34 o+48 o+62 o+76 0, 1
0000, 0001 hex
0
(0000 hex)
Square Root Extraction
(Valid when max. scaling value ≥
minimum scaling value.)
0: Disable, 1: Enable
Rate-of-change Function
o+35 o+49 o+63 o+77 −32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
10000
(2710 hex)
o+36 o+50 o+64 o+78 −32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
−10000
(D810 hex)
Minimum Rate-of-change Value
(Process value industrial unit/comparison time interval)
o+37 o+51 o+65 o+79 1 to 16
0001 to 0010 hex
1
(0001 hex)
Rate-of-change Comparison Time
Interval (See note 1.)
Bits 00 to 07: Comparison time
Bits 08 to 15: Unit
Rate-of-change Value Scaling
o+38 o+52 o+66 o+80 −2147483648
o+39 o+53 o+67 o+81 to
2147483647
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
10000
Lower
(00002710 hex) Upper
Value Stored for Maximum Value in Range
−10000
Lower
(FFFFD810 hex) Upper
Value Stored for Minimum Value in Range
o+40 o+54 o+68 o+82 −2147483648
o+41 o+55 o+69 o+83 to
2147483647
---
Expansion Allocation Area Settings
Area for Expansion Allocation Area
0: Not used. , 1: DM, 2: CIO, 3: W,
4: H, 5: EM
Rate-of-change Range Settings
Maximum Rate-of-change Value
(Process value industrial unit/ comparison time interval)
Zero/Span Adjustment Supplementary Function
o+42 o+56 o+70 o+84 0 to 32000
0000 to 7D00 hex
10000
(2710 hex)
Span Adjustment Position
(Set value x 0.01%, percentage of
input span)
o+43 o+57 o+71 o+85 −32000 to
32000
8300 to FFFF hex,
0000 to 7D00 hex
0
(0000 hex)
o+44 o+58 o+72 o+86 0 to 9999
0000 to 270F hex
365
(016D hex)
Zero Adjustment Position
(Set value x 0.01%, percentage of
input span)
Zero/Span Adjustment Period (Unit:
Days)
o+45 o+59 o+73 o+87 0 to 9999
0000 to 270F hex
30
(001E hex)
Notice of Days Remaining (Unit:
Days)
o+46 o+60 o+74 o+88 0 to 32767
0000 to 7FFF hex
40
(0028 hex)
Top and Valley Hold
Hysteresis
353
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
DM Area address
Input Input Input Input
No. 1 No. 2 No. 3 No. 4
Decimal
Data range
Hexadecimal
Default
Data contents
Integral Value Calculation
(See note 1.)
o+47 o+61 o+75 o+89 (See note.)
o+90
(See note.)
o+91 o+93 o+95 o+97 −2147483648
o+92 o+94 o+96 o+98 to
2147483647
o+99
(See note.)
(See note.)
0 (0000 hex)
Bits 00 to 07: Integer Unit
Bits 08 to 15: Integer Coefficient
Temperature Resistance Thermometer Compensation
Temperature Resistance Thermometer Compensation Enable (See
note 1.)
(See note.)
0 (0000 hex)
80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex
1089585403
Lower
(40F1C0FB hex) Upper
(See note.)
0 (0000 hex)
Reference Resistance
(resistance at 23°C)
(Set value ×
0.0000001(10−7) Ω for
Pt100 or JPt100,
or Set value ×
0.000001(10−6) Ω for
Pt1000)
Cold Junction Compensation
Method Settings
Cold Junction Compensation
Method (See note 1.)
Note The settings for the Rate-of-change Comparison Time Interval, Integral Value
Calculation, Temperature Resistance Thermometer Compensation, and Cold
Junction Compensation Method are as follows:
Address
o+37
o+51
o+65
o+79
Bits
00 to 07
o+47
o+61
o+75
o+89
00 to 07
Integral Unit
0: Minutes
1: Hours
08 to 15
Integer Coefficient
0: 1
1: 1/10
2: 1/100
3: 1/1,000
4: 1/10,000
o+90
00
Input No. 1 Temperature Resistance
Thermometer Compensation
0: Disabled
1: Enabled
01
Input No. 2 Temperature Resistance
Thermometer Compensation
Input No. 3 Temperature Resistance
Thermometer Compensation
Input No. 4 Temperature Resistance
Thermometer Compensation
Not used.
08 to 15
02
03
04 to 15
o+99
00
01
02
03
04 to 15
354
Description
Settings
Rate-of-change Comparison Time Inter- Decimal
Hexadecimal
val
1 to 16
0001 to 0010 hex
Unit
0: s
1: Conversion period
Input No. 1 Cold Junction Compensation 0: Internal (Use the Unit's cold junction sensor.)
Method
1: External (Do not use the Unit's cold junction
Input No. 2 Cold Junction Compensation sensor.)
Method
Input No. 3 Cold Junction Compensation
Method
Input No. 4 Cold Junction Compensation
Method
Not used.
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Note
1. When specifying an Expansion Allocation Area, be sure that it does not
overlap with other areas that are being used. If areas overlap, the words
that are allocated may be overwritten, resulting in unexpected operation.
2. When specifying the first word in an Expansion Allocation Area, be sure
that the end of the memory area is not exceeded.
3. Set the first word in an Expansion Allocation Area to an even-numbered
address.
CIO Area Allocations
First word: word n. n = 2000 + unit number × 10 (unit number: 0 to 95)
Direction
Analog Input
Unit to CPU
Unit
Word
n
Bits
00 to 15
Input No. 1
Name
Lower
Process Value
(See
note 1.)
Upper
n+1
n+2
00 to 15
00 to 15
Input No. 2
Lower
n+3
n+4
00 to 15
00 to 15
Input No. 3
Upper
Lower
n+5
n+6
00 to 15
00 to 15
Input No. 4
Upper
Lower
n+7
n+8
00 to 15
00
Input No. 1
Upper
Process Value LL (Low
Low Limit) Alarm
Data range
−2147483648 to
+2147483647
(80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex)
Contents
The present process
value is stored according to the scaling set in
the allocated words of
the DM Area.
0, 1
0: Process value > Set
value
1: Process value ≤ Set
value (See note 2.)
01
Process Value L (Low
Limit) Alarm
0, 1
02
Process Value H (High
Limit) Alarm
0, 1
03
Process Value HH (High
High Limit) Alarm
0, 1
Input No. 2
Process Value LL (Low
Low Limit) Alarm
Process Value L (Low
Limit) Alarm
Process Value H (High
Limit) Alarm
Process Value HH (High
High Limit) Alarm
0, 1
Input No. 3
Process Value LL (Low
Low Limit) Alarm
04
05
06
07
08
09
Process Value L (Low
Limit) Alarm
10
Process Value H (High
Limit) Alarm
Process Value HH (High
High Limit) Alarm
Process Value LL (Low
Low Limit) Alarm
Process Value L (Low
Limit) Alarm
11
12
13
Input No. 4
14
Process Value H (High
Limit) Alarm
15
Process Value HH (High
High Limit) Alarm
0: Process value < Set
value
1: Process value ≥ Set
value (See note 2.)
Same as for input No. 1.
(See note 2.)
355
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Direction
Analog Input
Unit to CPU
Unit
Word
n+9
Bits
00
Input No. 1
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
08
Input No. 1
09
10
Input No. 2
Input No. 3
11
12
Name
Rate-of-change Value L
(Low Limit) Alarm
Data range
0, 1
Contents
0: Rate of change > Set
value
1: Rate of change ≤ Set
value (See note 3.)
Rate-of-change Value H
(High Limit) Alarm
0, 1
Rate-of-change Value L
(Low Limit) Alarm
0, 1
0: Rate of change < Set
value
1: Rate of change ≥ Set
value (See note 3.)
Same as for input No. 1.
(See note 3.)
Rate-of-change Value H
(High Limit) Alarm
0, 1
Rate-of-change Value L
(Low Limit) Alarm
0, 1
Rate-of-change Value H
(High Limit) Alarm
Rate-of-change Value L
(Low Limit) Alarm
Rate-of-change Value H
(High Limit) Alarm
Input Error
0, 1
0, 1
0, 1
0, 1
0: Normal
1: Error
Input No. 4
Cold Junction Sensor Error
0, 1
0: Normal
1: Error
13
Zero/Span Adjustment Period End
0, 1
14
Zero/span Adjustment Period Notice
0, 1
15
A/D Conversion Error (See note 4.)
0, 1
0: Adjustment enabled.
1: Adjustment ended.
(See note 3.)
Remains set to 1 if the
zero/span adjustment
bit has never been ON.
0: Adjustment enabled.
1: Notice period in
effect. (See note 3.)
Remains set to 1 if the
zero/span adjustment
bit has never been ON.
0: Normal
1: Error
Note
1. To indicate the process value in one word of data, set scaling in the range
of −32,768 to 32,767 (8000 to FFFF hex or 0000 to 7FFF hex), and set the
process value data length to 1 (one word).
2. If an Expansion Allocation Area is not set, the Process Value HH (High
High Limit) Alarm and Process Value LL (Low Low Limit) Alarm will be 0.
3. This value will be 0 if neither the Expansion Setting Area nor the Expansion
Control/Monitor Area is used.
4. This value will be 1 if an error occurs in the A/D conversion. If the error is
not cleared by turning the power OFF and back ON or restarting the Unit,
check whether there is a source of noise nearby. For details, refer to Error
Processing on page 363.
356
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Expansion Allocation Area
First word: word p. p = address specified in word o+33 in the area specified by
word o+32 in the Expansion Setting Area.
Direction
CPU Unit to
Analog Input
Unit
Word
p
p+1
p+2
p+3
Bits
00 to 15
Not used.
Name
00
01
Input No. 1
Input No. 2
02
03
Input No. 3
Input No. 4
04 to 07
08
Not used.
Input No. 1
09
10
Input No. 2
Input No. 3
11
12
Input No. 4
Input No. 1
13
14
Input No. 2
Input No. 3
15
00
Input No. 4
Input No. 1
01
02
Input No. 2
Input No. 3
03
04
Input No. 4
Input No. 1
05
06
Input No. 2
Input No. 3
07
Input No. 4
08 to 15
00
Not used.
Input No. 1
01
02
Input No. 2
Input No. 3
03
04 to 15
Input No. 4
Not used.
Data range
0000
Contents
---
Hold Function Selection
0, 1
0: Peak and bottom
1: Top and valley
Hold Start
0
0, 1
--0: Do not hold.
1: Hold.
Hold Value Reset
0, 1
0: Normal operation
1: Reset hold value
Integral Value Calculation Start
0, 1
0: Do not start calculation
1: Start calculation
Integral Value Reset
0, 1
0: Normal operation
1: Reset integral
value
0
0, 1
--0: Normal operation
1: Update adjustment date (Remains
ON while writing
external EEPROM.)
0
---
Zero/Span Adjustment
Update Bit
357
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Direction
Analog Input
Unit to CPU
Unit
Word
p+4
Bits
00 to 15
Input No. 1
p+5
p+6
00 to 15
00 to 15
Input No. 2
Name
Lower
Rate of
Change
(See
Upper
note.)
Lower
Data range
−2147483648 to
2147483647
(80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex)
Contents
The present rate-ofchange value is
stored according to
the scaling set in the
Expansion Setting
Area.
p+7
p+8
00 to 15
00 to 15
Input No. 3
Upper
Lower
p+9
p+10
00 to 15
00 to 15
Input No. 4
Upper
Lower
p+11
p+12
00 to 15
00
Input No. 1
0, 1
0: Adjustment
enabled.
1: Adjustment
ended. Remains set
to 1 if the Zero/Span
Adjustment Bit has
never been ON.
Zero/Span Adjustment
Period Notice
0, 1
Zero/Span Adjustment
Period End
0, 1
0: Adjustment
enabled.
1: Notice period in
effect.Remains set to
1 if the Zero/Span
Adjustment Bit has
never been ON.
Same as input No. 1.
Zero/Span Adjustment
Period Notice
0, 1
Zero/Span Adjustment
Period End
0, 1
Zero/Span Adjustment
Period Notice
0, 1
0, 1
08
Zero/Span Adjustment
Period End
Zero/Span Adjustment
Period Notice
EEPROM Error
09 to 15
Not used.
0
p+13
00 to 15
Input No. 1
p+14
00 to 15
p+15
00 to 15
p+16
00 to 15
p+17
00 to 15
p+18
00 to 15
p+19
00 to 15
p+20
00 to 15
01
02
Input No. 2
03
04
Input No. 3
05
06
07
358
Upper
Zero/Span Adjustment
Period End
Input No. 4
Input No. 2
Input No. 3
Input No. 4
Day of Final Adjustment
Date
Year and Month of Final
Adjustment Date
Day of Final Adjustment
Date
Year and Month of Final
Adjustment Date
0, 1
0, 1
0100 to 3100(BCD)
0001 to 9912(BCD)
0100 to 3100(BCD)
0001 to 9912(BCD)
Day of Final Adjustment
Date
0100 to 3100(BCD)
Year and Month of Final
Adjustment Date
0001 to 9912(BCD)
Day of Final Adjustment
Date
Year and Month of Final
Adjustment Date
0100 to 3100(BCD)
0001 to 9912(BCD)
0: Normal
1: Error
--Records the last
date when the Zero/
Span Adjustment
Update Bit was
turned ON. Remains
set to FFFF if the
Zero/Span Adjustment Update Bit has
never been ON.
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Direction
Analog Input
Unit to CPU
Unit
Word
p+21
Bits
00
Input No. 1
01
02
Input No. 2
03
04
Input No. 3
05
06
Input No. 4
07
Not used.
Input No. 1
Name
Valley Detection Timing
Flag
Data range
0, 1
Top Detection Timing
Flag
0, 1
Turns ON when a top
is detected for the
top hold function.
Turns OFF the next
cycle.
Valley Detection Timing
Flag
0, 1
Same as input No. 1.
Top Detection Timing
Flag
Valley Detection Timing
Flag
Top Detection Timing
Flag
Valley Detection Timing
Flag
0, 1
Top Detection Timing
Flag
0, 1
0
Lower
0, 1
0, 1
0, 1
p+22
08 to 15
00 to 15
p+23
00 to 15
Upper
p+24
p+25
00 to 15
00 to 15
Lower
Upper
Bottom/Valley
Value (See
note.)
p+26
p+27
00 to 15
00 to 15
Lower
Upper
p+28
p+29
00 to 15
00 to 15
p+30
p+31
00 to 15
00 to 15
Peak/Top Value −2147483648 to
(See note.)
2147483647
(80000000 to
Bottom/Valley
FFFFFFFF hex,
Value (See
00000000 to
note.)
7FFFFFFF hex)
Peak/Top Value
(See note.)
p+32
p+33
00 to 15
00 to 15
p+34
00 to 15
p+35
p+36
00 to 15
00 to 15
Upper
Lower
p+37
00 to 15
Upper
Input No. 2
Lower
Upper
Input No. 3
Lower
Upper
Lower
Upper
Input No. 4
Contents
Turns ON when a
valley is detected for
the valley hold function. Turns OFF the
next cycle.
Lower
--Peak/Top Value −2147483648 to
(See note.)
2147483647
(80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex)
The peak or top
value is stored
according to the
scaling set in the DM
Area.
−2147483648 to
2147483647
(80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex)
The bottom or valley
value is stored
according to the
scaling set in the DM
Area.
Same as for input
No. 1.
Bottom/Valley
Value (See
note.)
Peak/Top Value
(See note.)
Bottom/Valley
Value (See
note.)
359
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Direction
Analog Input
Unit to CPU
Unit
Word
p+38
Bits
00 to 15
Input No. 1
Name
Lower
Integral Value
p+39
p+40
00 to 15
00 to 15
Input No. 2
Upper
Lower
Integral Value
p+41
p+42
00 to 15
00 to 15
Input No. 3
Upper
Lower
Integral Value
p+43
p+44
00 to 15
00 to 15
Input No. 4
Upper
Lower
Integral Value
p+45
00 to 15
Data range
−2147483648 to
+2147483647
(80000000 to
FFFFFFFF hex,
00000000 to
7FFFFFFF hex)
Contents
The integral value for
the present value is
stored according to
the scaling set in the
DM Area.
Upper
Note To indicate the value in one word of data, set scaling in the range of −32,768
to 32,767 (8000 to FFFF hex or 0000 to 7FFF hex), and set the process value
data length to 1 (one word).
Terminal Connection Diagram
Input 1
Input 2
A
+
O
W
+
±100 mV
−
C
+
mA
−
V
Voltage
−
−
C
+
mA
±100 mV
−
V
Voltage
B
b
b
A
+
W
B
Thermocouple
Resistance
thermometer
+
+
A
−
Current
Potentiometer
O
a
+
2-B
B2(11)
2-C
2-D
A1(1)
1- A
A2(2)
1- B
A3(3)
A4(4)
A
A
a
1- C
B
B
1- D
b
B3(12)
CJ−
B5(14)
4-A
B6(15)
4-B
B7(16)
B
B
4-C
B8(17)
b
b
4-D
B9(18)
A5(5)
CJ+
A6(6)
3-A
A7(7)
3-B
A8(8)
A9(9)
3-C
3-D
+
+
b
Resistance
thermometer
B
a
+
b
O
+
mA
−
Thermo- Current
couple
Input 4
Note
C
Voltage
±100 mV
−
−
b
V
+
W
−
+
B
Resistance
thermometer
±100 mV
Potentiometer
A
A
−
Thermo- Current
couple
O
+
mA
−
−
B4(13)
A
Thermocouple
Resistance
thermometer
Potentiometer
B1(10)
a
−
−
Current
2-A
V
W
−
C
+
Voltage
Potentiometer
Input 3
1. When wiring voltage inputs, be careful not to connect the wrong terminals.
Incorrect wiring may damage the Unit.
2. Do not remove the cold junction sensors that are connected to the CJ+ and
CJ− terminals. If they are removed, compensation will not be executed and
temperatures will not be correctly measured.
3. Use the cold junction sensors that are included with the product. Cold junction sensors are calibrated for particular Units and connection circuits. If a
sensor from another Unit is used, temperatures cannot be correctly measured.
4. Use shielded cable when the resolution selection is set to 2 (1/16,000).
5. Use the same wiring length for connecting to A, B, a, and b, so that the impedance will be the same. In particular (for resistance thermometers), do
not connect the A-a and B-b terminals.
6. Do not connect anything to unused terminals.
7. Be sure to ground the GR terminal at the Power Supply Unit for the PLC.
8. Be sure to ground all input devices (such as voltage generators, temperature calibrators, and resistors) that have ground terminals.
9. Do not mount an Isolated-type Universal Input Unit on the same CPU Rack
or the same Expansion Rack as a [email protected]@@ Contact Output Unit.
The Universal Input Unit measures process values at high resolution, and
360
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
the noise that is generated from relay output switching can adversely affect
these operations.
10. If the CPU Rack and an Expansion Rack are lined up horizontally on the
control panel and a Relay Output Unit is mounted in the same Rack as the
CJ1W-PH41U, keep the Racks separated by at least 70 mm.
11. If for some reason it is not possible to avoid mounting them on the same
Rack, then mount them as far apart as possible and take measures such
as installing a surge suppressor in the relay output circuit wiring.
Shielded Cable
For 1/16,000 resolution, connect shielded cable as shown below.
■
Thermocouple Input
+
−
Input 1
Input 2
Input 3
Input 4
1 to 4-A
A1(1)
B1(10)
A6(6)
B6(15)
1 to 4-B
A2(2)
B2(11)
A7(7)
B7(16)
1 to 4-C
A3(3)
B3(12)
A8(8)
B8(17)
1 to 4-D
A4(4)
B4(13)
A9(9)
B9(18)
361
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
CH4 input
CH3 input
Isolated
circuit
Input circuit
A/D converter
Digital isolator
Isolated
circuit
Input circuit
A/D converter
Input circuit
A/D converter
Digital isolator
Connector
Cold junction
sensor
CH2 input
CH1 input
Block Diagram
Isolated
circuit
Input circuit
A/D converter
Digital isolator
Isolated
circuit
Input circuit
A/D converter
Digital isolator
Power supply
circuit
362
5 VDC
Section 3-6
CJ1W-PH41U Isolated-type Universal Input Unit
Error Processing
Conversion data does not change.
Probable cause
The gain for span adjustment is set to
0.
Remedy
Set the span adjustment gain to a value other than 0.
The maximum and minimum values set Set suitable maximum and minimum values for process value scaling.
for process value scaling are identical
or extremely close.
The input type, input range, or process Check and correct the settings.
value scaling is not set correctly.
An input device is malfunctioning or
input wiring is faulty or disconnected.
Check whether input values have changed. Check for faulty or disconnected wiring. Check whether an input error has been detected.
Values are not converted as intended.
Probable cause
Remedy
The input type, input range, or process Check and correct the settings.
value scaling is not set correctly.
The zero/span adjustment data is
Check and correct the zero adjustment value and the span adjustment gain setincorrect.
tings.
The resistance thermometer input wiring is incorrect.
Correct the input wiring.
Thermocouple or compensation conductor polarity is incorrect.
DC input polarity is incorrect.
Potentiometer input wiring is incorrect.
Cold junction compensation is not
operating.
A compensation conductor has not
been used, or the wrong type of compensation conductor is used.
Check the Cold Junction Error Flag.
The offset compensation function is
operating.
Set the scaling offset value to an appropriate value.
The square root calculation is operating.
Disable the square root calculation.
Use the correct compensation conductor for the thermocouple.
Conversion values are unstable.
Probable cause
Input signals are being affected by
external noise.
Process values greater than the resolution are being scaled.
Remedy
Change the connection paths of the input signal lines. (Separate them from
sources of noise or use shielded twisted-pair cable.)
Increase the number of items for moving average processing.
Set the resolution to 1/256,000 (conversion period: 60 ms).
Reduce the process value scaling value.
An A/D conversion error occurred.
Probable cause
Remedy
There is influence from ambient noise. Install surge suppressors and noise filters for noise-generating devices.
Separate the Unit from the noise source.
The ERC indicator is lit.
Probable cause
Remedy
A setting in the DM Area or the Expan- Set the value within the optimum range. For Setting Group 2 or 4 (Initial Settings
sion Setting Area is out of range.
Area), turn the power OFF and back ON or restart the Unit.
Set even addresses for the Expansion Setting Area and Expansion Control/Monitor Area beginning addresses.
363
CJ1W-PH41U Isolated-type Universal Input Unit
364
Section 3-6
Appendix A
Supplementary Explanation of Functions
The following supplements the explanation given in 1-2 Features and Functions.
Changing Set Values during Output of Process Value (or
Instantaneous Value) Alarm or Rate-of-change Alarm
HH (High High Limit) and H (High Limit) Alarms
When the alarm set value is raised while the alarm output is ON, the alarm output will be turned OFF when the
following condition is satisfied.
Input value < (alarm set value after change – hysteresis)
The alarm output will first turn OFF when the input value falls below the set value (with the hysteresis included).
LL (Low Low Limit) and L (Low Limit) Alarms
When the alarm set value is lowered while the alarm output is ON, the alarm output will be turned OFF when
the following condition is satisfied.
Input value > (alarm set value after change + hysteresis)
When the hysteresis part alone of the input value is greater than the set value, the alarm output will turn OFF
for the first time.
Example: HH and H Limit Alarms
Hysteresis
Input value (Process value,
rate-of-change value,
instantaneous value)
H, HH alarm set value
With present value at this point, alarm output turns ON.
Alarm set value raised.
Hysteresis
Input value (Process value, rate-ofchange value, instantaneous value)
H, HH
alarm set value
With present value at this point, alarm output remains ON.
Alarm set value further raised.
Hysteresis
Input value (Process value,
rate-of-change value,
instantaneous value)
H, HH alarm set value
With present value at this point, alarm output turns OFF.
365
Appendix A
Supplementary Explanation of Functions
Applicable Units
Isolated-type Thermocouple Input Units
CS1W-PTS01-V1/11/51/55, CJ1W-PTS51/15
Isolated-type Resistance Thermometer Input
Units
CS1W-PTS02/03/12/52/56, CJ1W-PTS52/16
Isolated-type 2-Wire Transmitter Input Unit
Isolated-type Direct Current Input Units
CS1W-PTW01
CS1W-PDC01/11/55,
CJ1W-PDC15
Isolated-type Pulse Input Unit
Power Transducer Input Unit
CS1W-PPS01
CS1W-PTR01
Analog Input Unit (100 mV)
Isolated-type Universal Input Units
CS1W-PTR02
CS1W-PH41U
Alarm Operation when Upper Limit Is Less Than Lower Limit
Process value (instantaneous value) and rate-of-change value alarm set values can be set freely regardless of
the relative sizes of HH > H > L > LL.
Example: H < L, or HH < H.
The alarm output operation is determined purely by the relative sizes of the input value (screening value) and
alarm set value, as shown below.
HH and H Limit Alarms
When the input value is greater than the alarm set value, the alarm output is turned ON.
LL and L Limit Alarms
When the input value is less than the alarm set value, the alarm output is turned ON.
Process value or rate-of-change value
Hysteresis
Low limit (L) set value
High limit (H) set value
Time
Low limit (L) alarm output
Time
High limit (H) alarm output
Time
Applicable Units
Isolated-type Thermocouple Input Units
Isolated-type Resistance Thermometer Input
Units
Isolated-type 2-Wire Transmitter Input Unit
CS1W-PTS01-V1/11/51/55, CJ1W-PTS51/15
CS1W-PTS02/03/12/52/56, CJ1W-PTS52/16
CS1W-PTW01
Isolated-type Direct Current Input Units
CS1W-PDC01/11/55,
CJ1W-PDC15
Isolated-type Pulse Input Unit
Power Transducer Input Unit
CS1W-PPS01
CS1W-PTR01
Analog Input Unit (100 mV)
Isolated-type Universal Input Units
CS1W-PTR02
CJ1W-PH41U
Note Rate-of-change value alarm is not available for [email protected]/PDC55, and CJ1W-PTS51/PTS52. Process value alarm only.
366
Appendix A
Supplementary Explanation of Functions
Alarm Output Operation when Falling Back from Alarm
Condition Before Alarm-ON Delay Time Elapses
If inputs fall back from the alarm-ON condition (including hysteresis) before the alarm-ON delay time has
elapsed, the alarm output will not turn ON.
Process value or rate-of-change value
Falling back from ON condition
Set value
Hysteresis
Time
Will not turn ON
Alarm output
Time
Alarm-ON delay time
Applicable Units
Isolated-type Thermocouple Input Units
CS1WPTS01-V1/11/51/55, CJ1W-PTS51/15
Isolated-type Resistance Thermometer Input
Units
Isolated-type 2-Wire Transmitter Input Unit
CS1W-PTS02/03/12/52/56, CJ1W-PTS52/16
CS1W-PTW01
Isolated-type Direct Current Input Units
CS1W-PDC01/11/55,
CJ1W-PDC15
Isolated-type Pulse Input Unit
Power Transducer Input Unit
CS1W-PPS01
CS1W-PTR01
Analog Input Unit (100 mV)
Isolated-type Universal Input Units
CS1W-PTR02
CJ1W-PH41U (See note.)
Note The alarm will not be turned OFF even if the alarm OFF condition is no longer met before the alarm
OFF-delay time expires.
Setting Process Value Scaling with Negative Bias
With process value scaling in industrial units, a negative bias can be set by reversing the maximum and minimum values in the range.
Example: CS1W-PDC01 Isolated-type Direct Current Input Unit
The following values can be set for an input signal of 4 to 20 mA: Maximum process value in range = 0, minimum process value in range = 4000.
367
Appendix A
Supplementary Explanation of Functions
Process value (stored data)
4600 (115%)
4000 (100%)
Process value scaling with negative bias
0 (0%)
Input signal
−600 (−15%)
3.2 mA
Applicable Units
4 mA
20 mA
20.8 mA
Isolated-type Thermocouple Input Unit
CS1W-PTS01-V1/11, CJ1W-PTS15
Isolated-type Resistance Thermometer Input
Unit
Isolated-type 2-Wire Transmitter Input Unit
CS1W-PTS02/03/12, CJ1W-PTS16
CS1W-PTW01
Isolated-type Direct Current Input Unit
Isolated-type Pulse Input Unit
CS1W-PDC01/11/55, CJ1W-PDC15
CS1W-PPS01
Power Transducer Input Unit
Analog Input Unit (100 mV)
CS1W-PTR01
CS1W-PTR02
Isolated-type Universal Input Units
CJ1W-PH41U
Alarm Operation during Process Value Scaling with Negative
Bias
During process value scaling with negative bias, the alarm operates on the process value after scaling, and not
on the input signal. Consequently, the operation is the same as for normal bias, as shown below.
HH and H Limit Alarms
When the input value is greater than the alarm set value, the alarm output is turned ON.
368
Appendix A
Supplementary Explanation of Functions
LL and L Limit Alarms
When the input value is less than the alarm set value, the alarm output is turned ON.
Example: If the maximum process value in the range is 0 and minimum process value in the range is 4,000 for
an input signal of 4 to 20 mA, and if the H (high limit) alarm set value is 3,000, the alarm output will turn ON
when the process value is greater than 3,000 (when the input signal is less than 8 mA).
Process value (stored data)
4600 (115%)
4000 (100%)
When process value is greater than 3,000, output turns ON.
3000 (75%)
Process value scaling with negative bias
Input signal
0 (0%)
−600 (−15%)
3.2 mA
4 mA
20 mA
20.8 mA
When input signal is less than 8 mA, output turns ON.
Applicable Units
Isolated-type Thermocouple Input Unit
CS1W-PTS01-V1/11, CJ1W-PTS15
Isolated-type Resistance Thermometer Input
Unit
Isolated-type 2-Wire Transmitter Input Unit
CS1W-PTS02/03/12, CJ1W-PTS16
CS1W-PTW01
Isolated-type Direct Current Input Unit
Isolated-type Pulse Input Unit
CS1W-PDC01/11/55, CJ1W-PDC15
CS1W-PPS01
Power Transducer Input Unit
Analog Input Unit (100 mV)
CS1W-PTR01
CS1W-PTR02
Isolated-type Universal Input Units
CJ1W-PH41U
369
Appendix A
Supplementary Explanation of Functions
Maximum/Minimum Value for when Input Disconnection Occurs
during Process Value Scaling with Negative Bias
If an input is disconnected during process value scaling with negative bias, either the maximum or minimum
process value will be specified.
If the process value overrange direction is high, the maximum process value will be specified.
If the process value overrange direction is low, the minimum process value will be specified.
Process value (stored data)
If the high value is set, the maximum
value of 4600 will be specified when an
input is disconnected.
4600 (115%)
4000 (100%)
Process value scaling with negative bias
Input signal
0 (0%)
If the low value is set, the minimum value
of −600 will be specified when an input is
disconnected.
−600 (−15%)
3.2 mA
Applicable Units
370
4 mA
20 mA
20.8 mA
Isolated-type Thermocouple Input Unit
Isolated-type Resistance Thermometer Input
Unit
Isolated-type Universal Input Units
CS1W-PTS01-V1/11, CJ1W-PTS15
CS1W-PTS02/03/12, CJ1W-PTS16
CJ1W-PH41U
Appendix A
Supplementary Explanation of Functions
Output Hold when CPU Unit Error Occurs
In the following cases, the CS1W-PMV01/PMV02 Isolated-type Analog Output Unit will hold either a specified
preset value or the analog output value prior to the error for output when the CPU Unit is restored to normal
operation.
• A fatal error (including user-defined FALS execution) occurs
• A CPU error occurs
• A load break occurs
When the CPU Unit is restored to normal operation, the output value in the CIO Area will be output.
Note If a CPU error occurs while the output rate-of-change limit function is operating, the output hold function
will operate as follows:
• If previous value hold has been specified, then the value prior to the CPU error will be held for output.
Analog output value
No output rate-of-change limit
No CPU error occurs.
Previous value held
when CPU error occurs
Rate-of-change
limit in effect
CPU error occurs here.
Time
• When preset value hold has been specified, the output rate-of-change limit will remain in effect even during
the change to the preset value, and the rate of change will be limited.
Analog output value
Preset value
No rate-of-change limit
Previous value held
when CPU error occurs
Rate-of-change
limit enabled
No CPU error occurs.
Rate-of-change limit still enabled.
CPU error occurs.
Time
Applicable Units
Isolated-type Analog Output Units
CS1W-PMV01/PMV02
Inrush Input Limit Function
The inrush input limit function will not operate if the process value is already greater than 2% when the power
supply to the PLC is turned ON. The inrush input limit function will operate only when the process value rises
above 2% from less than 2% at startup.
Process value
Operation of inrush input limit function
Time
371
Appendix A
Supplementary Explanation of Functions
Applicable Units
Analog Input Unit (100 mV)
CS1W-PTR02
Power Transducer Input Unit
CS1W-PTR01
Hysteresis during Square Root Calculations
During square root calculations, outputs of approximately 7% or less have linear characteristics (i.e., output =
input). Hysteresis exists, however, when switching between square root characteristics and linear characteristics, as shown below.
During input rise: Switching from linear characteristics to square root characteristics at 0.5% input (output of
approximately 7%).
During input fall: Switching from square root characteristics to linear characteristics at 0.3% input (output of
approximately 5.5%).
Output
Square root calculation
7%
5.5%
2%
Linear
Input
0.5%
0.3%
Applicable Units
Isolated-type 2-Wire Transmitter Input Unit
CS1W-PTW01
Isolated-type Direct Current Input Unit
Isolated-type Universal Input Units
CS1W-PDC01/11/55, CJ1W-PDC15
CS1W-PH41U
Adjustment Period Control
Final Adjustment Date Not Stored in the Unit’s External FROM (Initial
Status)
The set values are as follows:
• The 4-byte area (2 words) for the final adjustment date is set to FFFF.
• The Zero/span Adjustment Period Notice Bit is set to 1 (notice period).
• The Zero/span Adjustment Period End Bit is set to 1 (adjustment ended).
Error in Final Adjustment Date Stored in Unit’s External FROM when
Power is Turned ON
The ERC indicator is ON and the adjustment period control function does not operate properly.
Restart the Unit. The set values are as follows.
• The External FROM Error Flag is set to 1 (external FROM error).
• The 4-byte area (2 words) for the final adjustment date is set to FFFF.
• The Zero/span Adjustment Period Notice Bit is set to 1 (notice period).
• The Zero/span Adjustment Period End Bit is set to 1 (adjustment ended).
372
Appendix A
Supplementary Explanation of Functions
Error in Unit’s External FROM when Updating Final Adjustment Date
The ERC indicator is ON and the adjustment period control function does not operate properly when the Unit is
restarted. Update the final adjustment date again.
The set values are as follows.
• The External FROM Error Flag is set to 1 (external FROM error).
Note If the CPU Unit’s internal clock information is refreshed after updating the final adjustment date, the
warning will not be accurate. The Zero/span Adjustment Update Bit remains ON (1: Update adjustment
date) while writing external FROM, so do not turn OFF the PLC.
Applicable Units
Isolated-type Thermocouple Input Unit
Isolated-type Resistance Thermometer Input
Unit
Isolated-type Direct Current Input Unit
CS1W-PTS11, CJ1W-PTS15
CS1W-PTS12, CJ1W-PTS16
Isolated-type Universal Input Units
CJ1W-PH41U (See note.)
CS1W-PDC11, CJ1W-PDC15
Note For the CJ1W-PH41U, the “external FROM” is an external EEPROM.
Integral Value Calculation
Integral Value Unit: Hour
The process value is calculated using an integral width of 3.6 s (1/1,000th of an hour), and the total is output to
4 bytes (2 words) of memory.
An integral value of 1,000 indicates that a process value of 1,000 has continued for one hour.
Integral Value Unit: Minute
The process value is calculated using an integral width of 60 ms (1/1,000th of a minute), and the total is output
to 4 bytes (2 words) of memory.
An integral value of 1,000 indicates that a process value of 1,000 has continued for one minute.
Example:
Process value: 1,000 (constant)
Integral unit: hour
Time lapsed (hours)
Integral value
0.5
500
1
2
1,000
2,000
3
3,000
373
Appendix A
Supplementary Explanation of Functions
Integral width
(See note.)
Integral value
Process value
Time
Integral value
Time
Integral Value
Calculation
Start Bit
ON
OFF
Time
Integral Value
Reset Bit
ON
Time
OFF
Note The integral width for one integral value is as follows:
Unit
Integral width
Hour
Minute
3.6 s (1/1,000th of an hour)
60 ms (1/1,000th of a minute)
Integral Value Overflow
The integral value will become undefined if the integral value exceeds the data range (–2147483648 to
2147483647) during integral calculation. For the CJ1W-PDC15, an integral value overflow will occur after a
minimum of 45 days has lapsed from the start of integral calculation.
Example: Integral value overflow (minimum conditions). The table shows the integral values for the following
minimum conditions.
• Process value: –32768 (constant)
• Integral unit: Minute
Number of days lapsed
(days)
0
0
Integral value
1
2
−47185920
−94371840
to
45
to
−2123366400
46
Undefined
Note Use the Integral Value Calculation Start Bit, the Integral Value Reset Bits, and (for the CJ1W-PH41U
only) the integral coefficient so that an integral value overflow does not occur.
Applicable Units
374
Isolated-type Direct Current Input Unit
CS1W-PDC11, CJ1W-PDC15
Isolated-type Universal Input Units
CJ1W-PH41U
Appendix B
Zero/Span Adjustment Example
The Analog I/O Unit’s zero/span adjustment can be performed as described below using a calibration device.
1,2,3...
1. Connect the Programming Device to the CPU Unit.
2. Connect a suitable calibration device as shown in the following table to the Analog I/O Unit.
Name
Isolated-type Thermocouple Input Unit
Model
Calibration device
CS1W-PTS01-V1 Voltage and current generator
CS1W-PTS11
CS1W-PTS51
CS1W-PTS55
CJ1W-PTS51
CJ1W-PTS15
Isolated-type Universal Input Unit (thermocouple inputs)
CJ1W-PH41U
Isolated-type Resistance Thermocouple
Input Unit (Pt100, JPt100)
CS1W-PTS02
Isolated-type Resistance Thermocouple
Input Unit (Ni508.4)
Isolated-type Resistance Thermocouple
Input Unit (Pt100, JPt100, JPt50, Ni508.4)
CS1W-PTS03
Isolated-type Resistance Thermocouple
Input Unit (Pt100, JPt100)
Isolated-type Resistance Thermocouple
Input Unit (Pt100, JPt100)
Isolated-type Universal Input Unit (Pt100,
JPt100, Pt1000)
Isolated-type 2-Wire Transmitter Input Unit
Isolated-type Direct Current Input Unit
Variable resistor
CS1W-PTS12
CJ1W-PTS16
CS1W-PTS52
CS1W-PTS56
CJ1W-PTS52
CJ1W-PH41U
CS1W-PTW01
Voltage and current generator
CS1W-PDC01
CS1W-PDC11
Voltage and current generator
CS1W-PDC55
CJ1W-PDC15
Isolated-type Universal Input Units (direct
current inputs)
Analog Input Unit (100 mV)
CJ1W-PH41U
CS1W-PTR02
Voltage generator
Power Transducer Input Unit
Isolated-type Pulse Input Unit
CS1W-PTR01
CS1W-PPS01
Voltage generator
Pulse generator
Isolated-type Analog Output Unit
CS1W-PMV01
CS1W-PMV02
Voltage and current meter
Voltage meter
3. Turn ON the power to the PLC, and wait approximately 10 minutes for the Unit to warm up.
The [email protected] and [email protected] require approximately 30 minutes to warm up.
The CS1W-PTS01-V1, CS1W-PTS11, and CJ1W-PTS15/PH41U require approximately 45 minutes to warm up.
4. Make the adjustments.
375
Appendix B
Zero/Span Adjustment Example
Input Units
1,2,3...
1. Input a signal equivalent to 0% from the calibration device, and check the process value in the CPU
Unit’s CIO Area using the Programming Device. If the value is abnormal, change the zero adjustment value in the DM Area, and adjust the offset (parallel movement) value.
2. Input a signal equivalent to 100% from the calibration device, and check the process value in the
CPU Unit’s CIO Area using the Programming Device. If the value is abnormal, change the span
adjustment gain value in the DM Area, and adjust the gain (bias).
Note For the CJ1W-PTS15 Isolated-type Thermocouple Input Unit or CJ1W-PH41U Universal Input Unit, connect the terminals of the cold junction sensor. For the CJ1W-PTS15 Isolated-type Thermocouple Input
Unit, connect the terminals for the cold junction sensor on the top. This will make the Isolated-type Thermocouple Input Unit or Universal Input Unit discontinue cold junction compensation. Then input a standard thermocouple value of 0°C (standard thermal power generation value, IEC 60584-1) to the
calibration mV signal.
Output Units
1,2,3...
1. Set an analog output value equivalent to 0% in the CPU Unit’s CIO Area. Check the signal using
the calibration device. If the value is abnormal, change the zero adjustment value in the DM Area,
and adjust the offset (parallel movement) value.
2. Set an analog output value equivalent to 100% in the CPU Unit’s CIO Area. Check the signal using
the calibration device. If the value is abnormal, change the span adjustment gain value in the DM
Area, and adjust the gain (bias).
Adjust the zero/span according to the following equation.
Process value after adjustment = (input value – minimum process value in range) x DM Area span adjustment
gain value + minimum process value in range + DM Area zero adjustment value
Example: Minimum process value in range = 0; maximum process value in range = 4,000; span adjustment
gain = 10060 x 0.0001 = 1.0060; zero adjustment value = 5
If the input value is 500, the process value after adjustment will be as follows:
Process value after adjustment = (500 – 0) x 1.0060 + 0 + 5 = 508.
Process value (after adjustment = stored data)
Span adjustment gain (example: 1.006)
Zero adjustment value (example: 5)
4600 (115%)
4000 (100%)
508
5
0 (0%)
Process value (before adjustment)
−600 (−15%)
−600
376
0
500
4000
4600
Appendix B
Zero/Span Adjustment Example
Zero/span Adjustment Example for Any Points (CS1W-PTS11/12,
PDC11, CJ1W-PTS15/16, PDC15, PH41U)
Use the following adjustment equation to perform zero/span adjustment for any points.
Process value after adjustment = (X − B) × ((C − A) × E − B + A)/(C − B) + D + B
X: Input value
A: Zero point of allocated DM Area
B: Zero adjustment position (process value range)
C: Span adjustment position (process value range)
D: Zero adjustment value for allocated DM Area
E: Span adjustment gain for allocated DM Area
Note The zero adjustment position and span adjustment position are percentages of the input span in the
Expansion Setting Area settings, so they can be obtained using the following equations.
Zero adjustment position = (Span point set in the allocated DM Area – Zero point set in the allocated DM
Area) × Zero adjustment position set in the Expansion Setting Area + Zero point set in the allocated DM
Area
Span adjustment position = (Span point set in the allocated DM Area – Zero point set in the allocated
DM Area) × Span adjustment position set in the Expansion Setting Area + Zero point set in the allocated
DM Area
Example: The values are calculated for the conditions in the following table.
Item
Value
Zero point set in the Allocated DM Area
Span point set in the Allocated DM Area
0
4000
Span adjustment gain set in the Allocated DM Area
10060 (10060 × 0.0001 = 1.0060)
(See note.)
Zero adjustment position set in the Allocated DM Area
Zero adjustment position set in the Expansion Setting Area
5
500 (500 × 0.0001 = 5%)
Span adjustment position set in the Expansion Setting Area
Input value
9500 (9500 × 0.0001 = 95%)
500
Note For the CJ1W-PH41U, the space adjustment gain setting is 10060000 (10060000 × 0.0000001 =
1.0060000).
After adjustment, the process value is as follows:
Zero adjustment position = (4000 − 0) × 0.0500 + 0 = 200
Span adjustment position = (4000 − 0) × 0.9500 + 0 = 3800
Process value after adjustment = (500 − 200) × ((3800 − 0) × 1.0060 − 200 + 0)/(3800 − 200) + 5 + 200
= 506.9
377
Appendix B
Zero/Span Adjustment Example
Process value
(after adjustment = stored data)
After adjustment
Before adjustment
4600 (115%)
4000 (100%)
Span
adjustment gain
(e.g., 1.006)
507
Zero
adjustment
value (e.g., 5)
Process value (before adjustment)
0 (0%)
−600 (−15%)
−600
0
500
Zero
adjustment
position (e.g., 5%)
378
4000 4600
Span
adjustment
position (e.g., 95%)
Index
A
alarm
alarm-ON delay, 12, 13, 367
HH and H limits, 9, 365
hysteresis, 11, 372
LL and L limits, 9, 365
process value alarm, 9, 365
rate-of-change alarm, 10, 365
allocation, 34
answer input, 18
applications
precautions, xx
available models, 2
average
mean value processing, 13
C
CJ1W-PDC15
detailed description, 324
CJ1W-PH41U
detailed description, 338
CJ1W-PTS15
detailed description, 288
CJ1W-PTS16
detailed description, 312
CJ1W-PTS51
detailed description, 276, 338
CJ1W-PTS52
detailed description, 302
cold junction sensor
errors, 15
CS1W-PDC01
detailed description, 189
CS1W-PDC11
detailed description, 200
CS1W-PDC55
detailed description, 218
CS1W-PMV01
detailed description, 258
CS1W-PMV02
detailed description, 267
CS1W-PPS01
detailed description, 247
detailed description, 238
CS1W-PTS01-V1
detailed description, 68
CS1W-PTS02
detailed description, 121
CS1W-PTS03
detailed description, 132
CS1W-PTS11
detailed description, 80
CS1W-PTS12
detailed description, 142
CS1W-PTS51
detailed description, 97
CS1W-PTS52
detailed description, 157
CS1W-PTS55
detailed description, 109
CS1W-PTS56
detailed description, 167
CS1W-PTW01
detailed description, 177
D
default settings
transferring, 36, 39, 43
delay
alarm-ON delay, 12, 13, 367
detection
input disconnection detection, 14, 370
input error detection, 14
output disconnection detection, 19
dimensions, 52
disconnection
input disconnection detection, 14, 370
output disconnection detection, 19
E
ERH indicator, 59
error
cold junction sensor error, 15
error processing, 57
input error detection, 14
error processing, 57
CS1W-PTR01
detailed description, 229
CS1W-PTR02
379
Index
F
features
CJ1W-PDC15, 324
CJ1W-PH41U, 338
CJ1W-PTS15, 288
CJ1W-PTS16, 312
CJ1W-PTS51, 276, 338
CJ1W-PTS52, 302
CS1W-PDC01, 189
CS1W-PDC11, 200
CS1W-PDC55, 218
CS1W-PMV01, 258
CS1W-PMV02, 267
CS1W-PPS01, 247
CS1W-PTR01, 229
CS1W-PTR02, 238
CS1W-PTS01-V1, 68
CS1W-PTS02, 121
CS1W-PTS03, 132
CS1W-PTS11, 80
CS1W-PTS12, 142
CS1W-PTS51, 97
CS1W-PTS52, 157
CS1W-PTS55, 109
CS1W-PTS56, 167
CS1W-PTW01, 177
H
hysteresis, 11, 372
I
M
mean value processing, 13
models
available models, 2
mounting Units, 48
N
nomenclature, 28
O
operating environment
precautions, xix
operating procedures, 55
output disconnection detection, 19
output hold, 19, 371
output rate-of-change limit, 18
P
precautions
applications, xx
general, xviii
handling precautions, 50
operating environment, xix
safety, xviii
process value
automatic scaling, 8, 367
averaging, 13
process value alarm, 9, 365
I/O Isolation, 7
pulse accumulation, 18
input disconnection detection, 14, 370
pulse input instantaneous value conversion, 17
input error detection, 14
input range
variable input range setting, 7
R
inrush input limit, 16, 371
rate-of-change alarm, 10, 365
installation, 26
precautions, xx
Restart Bits, 36, 40, 43
isolation
I/O isolation, 7
L
LED Indicators, 30, 32
rate-of-change limit, 18
restarting Special I/O Units, 36, 43
S
safety precautions
See also precautions
scaling, 8, 367
380
Index
setup
initial hardware setup, 55
initial software setup, 55
span adjustment gain, 16
example, 375
specifications, 26
CJ1W-PDC15, 325
CJ1W-PH41U, 341
CJ1W-PTS15, 290
CJ1W-PTS16, 314
CJ1W-PTS51, 278, 341
CJ1W-PTS52, 303
CS1W-PDC01, 191
CS1W-PDC11, 203
CS1W-PDC55, 219
CS1W-PMV01, 260
CS1W-PMV02, 269
CS1W-PPS01, 249
CS1W-PTR01, 230
CS1W-PTR02, 240
CS1W-PTS01-V1, 70
CS1W-PTS02, 124
CS1W-PTS03, 134
CS1W-PTS11, 83
CS1W-PTS12, 145
CS1W-PTS51, 99
CS1W-PTS52, 158
CS1W-PTS55, 111
CS1W-PTS56, 168
CS1W-PTW01, 178
square root, 15, 372
stepdown rate, 17
system configuration, 24
CJ1W-PDC15, 324
CJ1W-PH41U, 338
CJ1W-PTS15, 288, 338
CJ1W-PTS16, 312
CJ1W-PTS51, 276
CJ1W-PTS52, 302
CS1W-PDC01, 189
CS1W-PDC11, 200
CS1W-PDC55, 218
CS1W-PMV01, 258
CS1W-PMV02, 267
CS1W-PPS01, 247
CS1W-PTR01, 229
CS1W-PTR02, 238
CS1W-PTS01-V1, 68
CS1W-PTS02, 121
CS1W-PTS03, 132
CS1W-PTS11, 80
CS1W-PTS12, 142
CS1W-PTS51, 97
CS1W-PTS52, 157
CS1W-PTS55, 109
CS1W-PTS56, 167
CS1W-PTW01, 177
T
terminals
connecting, 52
U
unit number switches, 31, 33
V
variable input range setting, 7
W
word allocation, 34
CJ1W-PDC15, 328, 331
CJ1W-PH41U, 349, 355
CJ1W-PTS15, 293, 296
CJ1W-PTS16, 316, 318
CJ1W-PTS51, 281, 283
CJ1W-PTS52, 307, 308
CS1W-PDC01, 193, 195
CS1W-PDC11, 205, 209
CS1W-PDC55, 221, 225
CS1W-PMV01, 262, 263
CS1W-PMV02, 271, 272
CS1W-PPS01, 252, 253
CS1W-PTR01, 232, 234
CS1W-PTR02, 241, 243
CS1W-PTS01-V1, 73, 75
CS1W-PTS02, 126, 128
CS1W-PTS03, 136, 138
CS1W-PTS11, 86, 90
CS1W-PTS12, 147, 150
CS1W-PTS51, 103, 104
CS1W-PTS52, 161, 163
CS1W-PTS55, 114, 117
CS1W-PTS56, 171, 174
CS1W-PTW01, 181, 183
381
Index
Z
zero adjustment offset, 16
example, 375
382
Revision History
A manual revision code appears as a suffix to the catalog number on the front cover of the manual.
Cat. No. W368-E1-10
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
1
02
April 2000
January 2002
03
04
05
06
07
08
Revised content
Original production
“CS1 Series” was changed to “CS Series” and “-V1” was added to the model number
CS1W-PTS01 throughout the manual. In addition, the following changes were made.
Page 39: Changes made to diagram and notes 1 and 2, and another note added.
Page 40: Terminal numbers changed
Page 128: Changes made to equations in 3 places.
May 2002
Information on the CS1W-PMV02 Isolated-type Analog Output Unit was added throughout
the manual.
August 2003 “PC” was changed to “PLC” throughout the manual.
Changes and additions were made to add the CS1W-PTS11, CS1W-PTS12, and CS1WPDC11.
February 2004 Changes and additions were made to add the CS1W-PTS51/PTS52 and
CJ1W-PTS51/PTS52.
June 2004
Changes and additions were made to add the CS1W-PTS55/PTS56 and PDC55.
March 2005 Changes and additions were made to add the CJ1W-PTS15/PTS16 and PDC15.
February 2007 Page v: Added information on notation for general precautions.
Page x: Added information on liability and warranty.
Page 13: Added a note below the bottom table.
Page 23: Added maximum current and total power supplied for the C200HW-PD025 and
CS1D-PD025.
Pages 55, 93, 152, 271, and 297: Changed the default values for m+4 to m+16.
Page 162: Changed word to m+34 in bottom table.
Pages 194 and 317: Added “output =” to formula and added “for” to note 2.
Pages 196 and 319: Changed the decimal data range for m+38, m+39, m+42, and m+43.
Page 210: Added information on input range to square root calculation and modified the
equation.
Page 211: Changed values for m+4 to m+32.
Page 212: Added information on input range for the square root function, changed the
decimal data range for m+39 and m+40, and removed setting of 00 to 03 from m+34.
Page 213: Modified the description below the table.
Page 283: Added “8: mV” to the sensor type for m+34 and m+49.
Pages 290 and 312: Added 24-VDC circuit to the top diagram.
09
March 2008
10
July 2008
Changes and additions were made to add the CJ1W-PH41U Isolated-type Universal Input
Unit.
Pages 191, 203, 220, and 326: Added maximum input ratings.
Page 304: Added input detection current.
383
Revision History
384
OMRON Corporation
Industrial Automation Company
Control Devices Division H.Q.
Analog Controller Division
Shiokoji Horikawa, Shimogyo-ku,
Kyoto, 600-8530 Japan
Tel: (81) 75-344-7080/Fax: (81) 75-344-7149
2-2-1 Nishikusatsu, Kusatsu-shi,
Shiga, 525-0035 Japan
Tel: (81) 77-565-5216/Fax: (81) 77-565-5568
Regional Headquarters
OMRON EUROPE B.V.
Wegalaan 67-69-2132 JD Hoofddorp
The Netherlands
Tel: (31)2356-81-300/Fax: (31)2356-81-388
OMRON ELECTRONICS LLC
One Commerce Drive Schaumburg,
IL 60173-5302 U.S.A.
Tel: (1) 847-843-7900/Fax: (1) 847-843-7787
Authorized Distributor:
OMRON ASIA PACIFIC PTE. LTD.
No. 438A Alexandra Road # 05-05/08 (Lobby 2),
Alexandra Technopark, Singapore 119967
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
OMRON Industrial Automation Global: www.ia.omron.com
© OMRON Corporation 2000 All Rights Reserved.
In the interest of product improvement,
specifications are subject to change without notice.
Printed in Japan
Cat. No. W368-E1-10
0708
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