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Cat. No. W479-E1-10 SYSMAC CP Series CP1E-E SD - CP1E-N S D - CP1E-E CP1E-N CP1E-NA CP1E CPU Unit Hardware USER’S MANUAL...
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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. Neverthe- less, OMRON assumes no responsibility for errors or omissions.
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SYSMAC CP Series CP1E-E SD - CP1E-N S D - CP1E-E CP1E-N CP1E-NA CP1E CPU Unit Hardware User’s Manual Revised July 2017...
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Introduction Thank you for purchasing a SYSMAC CP-series CP1E Programmable Controller. This manual contains information required to use the CP1E. Read this manual completely and be sure you understand the contents before attempting to use the CP1E. Intended Audience This manual is intended for the following personnel, who must also have knowledge of electrical sys- tems (an electrical engineer or the equivalent).
CP1E CPU Unit Manuals Information on the CP1E CPU Units is provided in the following manuals. Refer to the appropriate manual for the information that is required. This Manual CP1E CPU Unit Hardware CP1E CPU Unit Instructions CP1E CPU Unit Software User’s Manual(Cat.
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Manual Configuration The CP1E CPU manuals are organized in the sections listed in the following tables. Refer to the appro- priate section in the manuals as required. CP1E CPU Unit Hardware User’s Manual (Cat. No. W479) (This Manual) Section Contents Section 1 Overview and Specifica- This section gives an overview of the CP1E, describes its features, and tions...
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Section Contents Section 11 High-speed Counters This section describes the high-speed counter inputs, high-speed counter interrupts, and the frequency measurement function. Section 12 Pulse Outputs This section describes positioning functions such as trapezoidal control, jogging, and origin searches. Section 13 PWM Outputs This section describes the variable-duty-factor pulse (PWM) outputs.
Manual Structure Page Structure and Icons The following page structure and icons are used in this manual. Level 1 heading 5 Installation and wiring Level 2 heading Level 3 heading Installation Level 2 heading Gives the current headings. Level 3 heading 5-2-1 Installation Location DIN Track Installation...
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Terminology and Notation Term Description E-type CPU Unit A basic model of CPU Unit that support basic control applications using instructions such as basic, movement, arithmetic, and comparison instructions. Basic models of CPU Units are called “E(S)-type CPU Units” in this manual. The models of E(S)-type CPU Units are shown below.
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Sections in this Manual Overview and Specifications Basic System Configuration and Devices Part Names and Functions Programming Device Installation and Wiring Troubleshooting Maintenance and Inspection Using Expansion Units and Expansion I/O Units Appendices CP1E CPU Unit Hardware User’s Manual(W479)
CONTENTS Introduction ....................... 1 CP1E CPU Unit Manuals ................... 2 Manual Structure ....................... 5 Terms and Conditions Agreement................. 12 Safety Precautions ....................14 Precautions for Safe Use..................19 Operating Environment Precautions..............22 Regulations and Standards..................23 Related Manuals ...................... 24 Section 1 Overview and Specifications CP1E Overview ........................
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Section 3 Part Names and Functions CPU Units ..........................3-2 3-1-1 E10/14/20(S) or N14/20 CPU Units ..................3-2 3-1-2 E30/40/60(S), N30/40/60(S) or NA20 CPU Units ..............3-7 3-1-3 Common I/O Specifications....................... 3-13 3-1-4 Optional Serial Communications Port for N/NA(S)-type CPU Units ........ 3-19 3-1-5 Analog Option Board for N/NA-type CPU Units..............
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Troubleshooting Unit Errors....................6-15 6-2-1 Inputs ............................6-15 6-2-2 Outputs............................6-16 6-2-3 Built-in Analog ........................... 6-17 6-2-4 CX-Programmer Connection..................... 6-18 Section 7 Maintenance and Inspection Periodic Maintenance and Inspection ................... 7-2 7-1-1 Tools Required for Inspections ....................7-2 7-1-2 Periodic Inspection........................7-2 7-1-3 Inspection and Maintenance .......................
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A-3 Wiring for Serial Communications..................A-44 A-3-1 Recommended RS-232C Wiring ....................A-44 A-3-2 Recommended RS-422A/485 Wiring..................A-47 A-3-3 Converting the Built-in RS-232C Port to RS-422A/485 ............A-50 A-3-4 Reducing Electrical Noise for External Wiring ................A-53 Index ..........................Index-1 Revision History................Revision-1 CP1E CPU Unit Hardware User’s Manual(W479)
Omron’s exclusive warranty is that the Products will be free from defects in materials and workman- ship for a period of twelve months from the date of sale by Omron (or such other period expressed in writing by Omron). Omron disclaims all other warranties, express or implied.
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Disclaimers Performance Data Data presented in Omron Company websites, catalogs and other materials 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 user must correlate it to actual application requirements. Actual perfor- mance is subject to the Omron’s Warranty and Limitations of Liability.
Safety Precautions Definition of Precautionary Information The following notation is used in this manual to provide precautions required to ensure safe usage of a CP-series PLC. The safety precautions that are provided are extremely important to safety. Always read and heed the information provided in all safety precautions. Indicates an imminently hazardous situation which, WARNING if not avoided, will result in death or serious injury.
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WARNING Do not attempt to take any Unit apart while the power is being supplied. Doing so may result in electric shock. Do not touch any of the terminals or terminal blocks while the power is being supplied. Doing so may result in electric shock. Provide safety measures in external circuits (i.e., not in the Programmable Con- troller), including the following items, to ensure safety in the system if an abnormality occurs due to malfunction of the PLC or another external factor...
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Caution Caution Be sure to sufficiently confirm the safety at the destination when you transfer the program or I/O memory or perform procedures to change the I/O memory. Devices connected to PLC outputs may incorrectly operate regardless of the operat- ing mode of the CPU Unit.
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Caution Pay careful attention to the polarities (+/-) when wiring the DC power supply. A wrong connection may cause malfunction of the system. When connecting the PLC to a computer or other peripheral device, either ground the 0-V side of the external power supply or do not ground the external power supply at all.
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Caution Set the temperature range according to the type of temperature sensor con- nected to the Unit. Temperature data will not be converted correctly if the temperature range does not match the sensor. Do not set the temperature range to any values other than those for which tem- perature ranges are given in the following table.
Precautions for Safe Use Observe the following precautions when using a CP-series PLC. Power Supply • Always use the power supply voltages specified in the user’s manuals. An incorrect voltage may result in malfunction or burning. • Take appropriate measures to ensure that the specified power with the rated voltage and fre- quency is supplied.
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• Do not apply voltages or connect loads to the output terminals in excess of the maximum switch- ing capacity. Excess voltage or loads may result in burning. • Disconnect the functional ground terminal when performing withstand voltage tests. Not discon- necting the functional ground terminal may result in burning.
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• Force-setting/force-resetting any bit in memory. • Changing the present value of any word or any set value in memory. • When replacing parts, be sure to confirm that the rating of a new part is correct. Not doing so may result in malfunction or burning.
Operating Environment Precautions Perform installation following the instructions in this manual Follow the instructions in this manual to correctly perform installation. 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 •...
Concepts EMC Directives OMRON devices are electrical components that are designed to be built into equipment and manu- facturing systems. OMRON devices that comply with EMC Directives also conform to the related EMC standards*, so that they can be more easily built into other devices or the overall machine.
Related Manuals The following manuals are related to the CP1E. Use them together with this manual. Manual name Cat. No. Model numbers Application Contents SYSMAC CP Series W479 CP1E-ESD- To learn the hard- Describes the following information for CP1E CP1E CPU Unit Hard- ware specifications PLCs.
Overview and Specifications This section gives an overview of the CP1E, describes its features, and provides its specifications. 1-1 CP1E Overview ..........1-2 1-1-1 Overview of Features .
1-1-1 Overview of Features The SYSMAC CP1E Programmable Controller is a package-type PLC made by OMRON that is designed for easy application. The CP1E includes E(S)-type CPU Units (basic models) for standard control operations using basic, movement, arithmetic, and comparison instructions, and N/NA(S)-type CPU Units (application models) that supports connections to Programmable Terminals, Inverters, and Servo Drives.
1 Overview and Specifications Precautions for Correct Use Precautions for Correct Use For CP1E CPU Units, the following I/O memory area will be unstable after a power interruption. • DM Area (D) (excluding words backed up to the EEPROM using the DM function) •...
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1 Overview and Specifications Programming, Setting, and Monitoring with the CX-Programmer The CX-Programmer is used as the Programming Device for the CP1E. Easy Connection with Computers Using Commercially Available USB Cables The CX-Programmer is connected using a commercially available USB cable between the computer’s USB port and the built-in peripheral USB port of the CP1E.
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1 Overview and Specifications Input Interrupts An interrupt task can be started when a built-in input turns ON or turns OFF . Up to six interrupt inputs can be used. Interrupt input Built-in input Interrupt task Ladder program Interrupt occurs Note The user setting in the PLC Setup determines if each input is a quick-response input, normal input, interrupt input, or high-speed counter input.
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1 Overview and Specifications Versatile Pulse Control for Transistor Output CPU Units Fixed duty ratio pulse outputs can be output from the CPU Unit’s built-in outputs and used to perform positioning or speed control with a servomotor or a stepping motor that accepts pulse inputs. Two pulse outputs at 100 kHz are provided as standard features.
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1 Overview and Specifications Mounting Serial Option Boards to N30/40/60 or NA20 CPU Units One Serial Communications Option Board with one RS-232C port or one RS-422A/485 port can be added to an N30/40/60 or NA20 CPU Unit. With the serial communications port, it is easy to connect to general components, such as barcode readers, and other components such as PTs, other CP-series PLCs, and Inverters.
1 Overview and Specifications Basic Operating Procedure In general, use the following procedure. 1. Setting Devices and Hardware Connect the CPU Unit, Expansion I/O Units, and Expansion Units. Set the DIP switches on the Option Board and Expansion Units as required. Refer to Section 3 Part Names and Functions and Section 5 Installation and Wiring in the CP1E CPU Unit Hardware User’s Manual (Cat.
1 Overview and Specifications Specifications 1-3-1 General Specifications The following table lists the general specifications of CP1E CPU Units. Item AC power supply DC power supply CP1E-D-A CP1E-D-D Model CP1E-S(1)D-A CP1E-S(1)D-D Enclosure Mounted in a panel Dimensions (H × D × W) E/N/NA-type CPU Unit with 10 I/O points (CP1E-E10D-): 90mm ×85mm...
1 Overview and Specifications 1-3-2 Characteristics The following table gives the characteristics of CP1E CPU Units. CP1E-ND- CP1E-ED- Item CP1E-NAD- CP1E-ESD- CP1E-NS(1)D- Program capacity 2K steps (8 KB) including the symbol table, comments, 8K steps (32 KB) including the symbol table, com- and program indices of the CX-Programmer ments, and program indices of the CX-Programmer Control method...
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1 Overview and Specifications CP1E-ND- CP1E-ED- Item CP1E-NAD- CP1E-ESD- CP1E-NS(1)D- Built-in RS-232C port No built-in RS-232C port Interface: Conforms to EIA RS-232C. Communica Communica- Half duplex tions tions method Synchronization Start-stop Baud rate 1.2, 2.4, 4.8, 9.6, 19.2, 38.4, 57.6, or 115.2 kbps Transmission 15 m max.
1 Overview and Specifications 1-3-3 Functional Specifications The following table gives the functional specifications of CP1E CPU Units. Function Description Cycle time Minimum cycle time Makes the cycle time consistent. manage- Cycle time monitoring Monitors the cycle time. ment CPU Unit Inputs High- High-speed pulse...
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1 Overview and Specifications Function Description Power Memory protection Holding Area data, DM Area data, Counter Completion Flags, and Counter supply Present Values are held even when power is turned OFF. manage- This function is valid only when an optional battery is mounted. ment Number of power interruptions counter The number of times power has been interrupted is counted.
1 Overview and Specifications Difference between E/N/NA-type and E/NS(1)-type The differences among functions other than appearances of E/N/NA-type CPU Units and E/NS(1)-type CPU Units are as follows. Refer to A-1 Dimensions for the dimensions. E-type CPU Units Difference in Characteristics and Functions Function E-type ES-type...
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1 Overview and Specifications N-type CPU Units Difference in Characteristics and Functions Function N/NA-type NS(1) -type Analog adjusters 2 adjusters None (Setting range: 0 to 255) The analog adjuster PV in A642/A643 is fixed on 0000. Built-in RS-232C port 6 signals are supported: SD, RD, RS, CS, 4 signals are supported: SD, RD, RS and DR and ER.
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1 Overview and Specifications Function N/NA-type NS(1) -type Power supply for tran- Not needed Needed sistor outputs Do not connect an external power supply. It is necessary to connect a DC24V exter- nal power supply when using terminals 00 (Transistor outputs and 01 on terminal block CIO 100.
Ü Basic System Configuration and Devices This section describes the basic system configuration and device models of the CP1E. 2-1 Basic System Configuration ........2-2 2-1-1 Basic System Configuration Using an E(S)-type CPU Unit .
2 Basic System Configuration and Devices Basic System Configuration This section describes the system configurations using E (S)-type and N/NA (S )-type CP1E CPU Units. 2-1-1 Basic System Configuration Using an E (S)-type CPU Unit The system configuration when using a CP1E E (S)-type CPU Unit is shown below.
2 Basic System Configuration and Devices 2-1-2 Basic System Configuration Using an N/NA(S)-type CPU Unit The system configuration when using a CP1E N/NA(S)-type CPU Unit is shown below. Battery CP1W-BAT01 CP1E CPU Unit Expansion I/O Units Expansion Units DIN Track CP1E-N30D - 20 or 40 I/O Points Analog I/O...
2 Basic System Configuration and Devices CPU Units This section describes the models of CP1E CPU Units. 2-2-1 CPU Unit Models The CP1E CPU Unit model numbers are configured as shown below. Power supply A: AC power supply CP1E- D: DC power supply Output type R: Relays outputs T: Transistor outputs, sinking...
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2 Basic System Configuration and Devices ES-type CPU Units Number of built-in I/O Current Power Pro- points consumption supply Output gram DM Area Name and appearance Model number Weight Num- Num- specifica- type capac- capacity Total ber of ber of 5 VDC tions inputs...
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2 Basic System Configuration and Devices E-type CPU Units Number of built-in I/O Current Power points consumption Pro- supply DM Area Name and appearance Model number Output type gram Weight Number Number specifica- capacity capacity Total 5 VDC 24 VDC tions inputs outputs...
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2 Basic System Configuration and Devices NS(1)-type CPU Units Number of built-in I/O Current Power points consumption Pro- supply DM Area Name and appearance Model number Output type gram Weight Number Number specifica- capacity capacity Total 5 VDC 24 VDC tions inputs outputs...
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2 Basic System Configuration and Devices N-type CPU Units Number of built-in I/O Current Power points consumption Pro- supply DM Area Name and appearance Model number Output type gram Weight Number Number specifica- capacity capacity Total 5 VDC 24 VDC tions inputs outputs...
2 Basic System Configuration and Devices NA-type CPU Units Number of built-in I/O Built-in Current Power points analog consumption supply Output Program DM Area Name and appearance Model number Weight Number Number specifica- type capacity capacity Total AD DA tions inputs outputs CPU Unit with 20 I/O...
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2 Basic System Configuration and Devices Current consumption Name and appearance Model number Applications Weight 5 VDC 24 VDC − Analog Input/Output Option CP1W-MAB221 Mounted in the option slot of an N30/40/60 or 0.080A Board NA20 CPU Unit (version 1.2 or higher) and can be used as an analog input/output mod- ule.
CP1E CPU Unit Product nameplate CP1E-N40DR-A CPU UNIT Lot No. 28705 0000 Ver.1.0 OMRON Corporation MADE IN CHINA Lot No. Unit version (example for unit version 1.0) Confirming Unit Versions with Support Software CX-Programmer can be used to confirm the unit version of the CP1E CPU Units.
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2 Basic System Configuration and Devices Unit Versions and Support Software The relationship between the unit versions of CP1E CPU Units and versions of Support Software is shown below. Relationship between Unit Versions and Support Software Required Support Software (see note.) CX-Pro- CX-Programmer CX-Programmer Micro PLC...
2 Basic System Configuration and Devices Expansion I/O Unit or Expansion Unit This section describes the connection of Expansion I/O Units or Expansion Units to a CP1E CPU Unit. 2-3-1 Expandable CPU Units • Expansion I/O Units and Expansion Units cannot be connected to E10/14/20(S) or N14/20 CPU Units. •...
2 Basic System Configuration and Devices 2-3-4 Expansion I/O Units and Expansion Units Expansion I/O Units Current Specifications consumption Name and appearance Model number Weight Outputs Inputs − 8-point Input Unit CP1W-8ED Not provided. 8 inputs, 24 VDC 0.018A 200g 8-point Output Unit CP1W-8ER 8 relay outputs...
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2 Basic System Configuration and Devices Expansion Units Current consumption Name and appearance Model number Specifications Weight Analog I/O Unit CP1W-MAD11 2 analog inputs 0.083A 0.110A 250g 0 to 5 V, 1 to 5 V, 0 to 10 V, -10 to 10 V, 0 to 20 mA, and 4 to 20 mA 1 analog output 1 to 5 V, 0 to 10 V, -10 to 10 V, 0 to 20 mA, 4...
2 Basic System Configuration and Devices Current consumption Name and appearance Model number Specifications Weight Temperature Sensor Unit CP1W-TS004 Thermocouple inputs K or J, 12 inputs 0.080A 0.050A 380g − CompoBus/S I/O Link Unit CP1W-SRT21 Can perform communications as a Compo- 0.029A 200g Bus/S slave via 8 inputs and 8 outputs.
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2 Basic System Configuration and Devices Restrictions by ambient temperature According to the ambient temperature, there are restrictions on power supply voltage and output load current for the DC-power-supply CPU Units. Refer to Output Specifications for Relay Outputs in 3-1-3 Common I/O Specifications and in 3-2-4 I/O Specifications for details.
2 Basic System Configuration and Devices Unit Current Consumption and External Power Supply Capacity This section describes the current consumption and external power supply capacity of units used by the CP1E. 2-4-1 External Power Supply Capacity When Expansion I/O Units or Expansion Units are Connected Power of 24 VDC can be supplied to external devices from E30/40/60(S), N30/40/60(S) or NA20 CPU Units.
2 Basic System Configuration and Devices 2-4-2 Current Consumption CPU Units E(S)-type CPU Units Current consumption I/O capacity Model number 5 VDC 24 VDC 10 I/O points CP1E-E10DR-A 0.08A 0.04A CP1E-E10DT-A 0.11A 0.00A CP1E-E10DT1-A 0.11A 0.00A CP1E-E10DR-D 0.08A 0.04A CP1E-E10DT-D 0.11A 0.00A...
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2 Basic System Configuration and Devices NA-type CPU Units Current consumption I/O capacity Model number 5 VDC 24 VDC 20 I/O points CP1E-NA20DR-A 0.18A 0.11A and built-in CP1E-NA20DT-D 0.23A 0.09A analog CP1E-NA20DT1-D 0.23A 0.09A Note 1 The current consumption of CP1W-CIF01/11 Option Boards is included in the CPU Unit’s current con- sumption.
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2 Basic System Configuration and Devices Other Devices Using PLC Internal Power Supply Current consumption Unit name Model number 5 VDC 24 VDC − Conversion Adapter CJ1W-CIF11 0.04A NT-AL001 0.15A − Programmable Backlight NV3W-MG20L 0.2A − Terminal Green/Orange/Red Backlight NV3W-MR20L 0.2A −...
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2 Basic System Configuration and Devices 2-22 CP1E CPU Unit Hardware User’s Manual(W479)
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Part Names and Functions This section describes the part names, function specifications and terminal arrange- ments of the CP1E CPU Unit and other Units. 3-1 CPU Units ........... . 3-2 3-1-1 E10/14/20(S) or N14/20 CPU Units .
3 Part Names and Functions CPU Units This section describes the names of the CPU Unit parts and provides the I/O specifications and termi- nal arrangements. Refer to A-1 Dimensions for the dimensions, A-2 Wiring Diagrams for the wiring dia- grams.
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3 Part Names and Functions Number Name Function Input terminal block This is the terminal block for inputs such as the power supply input and 24 VDC inputs. Input indicators (yellow) Input status is displayed. An indicator will be ON when the input is ON. Peripheral USB port Used to connect to a personal computer for programming and monitoring by the CX-Programmer for CP1E.
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3 Part Names and Functions CPU Unit Status Indicators : Not lit : Flashing : Lit Indicator Color Status Description POWER Green Power is ON. POWER Power is OFF. Not lit Green The CP1E is executing a program in either RUN or MONITOR mode.
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3 Part Names and Functions Terminal Arrangements Input Arrangement AC Power Supply CP1E-E10D -A CIO 0 L1,L2/N : Power supply terminal L1 L2/N COM 01 : Protective ground terminal : Common terminal 00 to 05 : Input terminal : No connection CP1E- 14 D -A CIO 0 L1,L2/N : Power supply terminal...
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3 Part Names and Functions Output Arrangement AC Power Supply and DC Power Supply CP1E-E10D - : Common terminal 00 to 03 : Output terminal COM COM NC COM NC : No connection CIO 100 CP1E- 14 D - : Common terminal 00 to 05 : Output terminal COM COM NC COM...
3 Part Names and Functions 3-1-2 E30/40/60(S), N30/40/60(S) or NA20 CPU Units Part Names and Functions N/NA-type CPU Unit E-type CPU Unit CP1E-N30/40/60D- CP1E-E30/40DR-A CP1E-NA20D- (6) Operation (14) Battery (15) Built-in RS-232C communications (7) Input terminals indicators cover status indicator (1) Input terminal block (20) Analog input...
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3 Part Names and Functions Number Name Function Input terminal block This is the terminal block for inputs such as the power supply input and 24-VDC inputs. Input indicators (yellow) Input status is displayed. An indicator will be ON when the input is ON. Peripheral USB port Used to connect to a personal computer for programming and monitor- ing by the CX-Programmer for CP1E.
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3 Part Names and Functions CPU Unit Status Indicators : Not lit : Flashing : Lit Indicator Color Status Description POWER Green Power is ON. POWER Power is OFF. Not lit Green The CP1E is executing a program in either RUN or MONITOR mode. ERR/ALM Operation is stopped in PROGRAM mode or due to a fatal error.
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3 Part Names and Functions Terminal Arrangements Input Arrangement AC Power Supply CP1E-30D-A L1, L2/N : Power supply terminal CIO 0 CIO 1 : Common terminal L1 L2/N COM 00 to 11 : Input terminal : Functional ground terminal : Protective ground terminal CP1E-40D-A : No connection...
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3 Part Names and Functions Output Arrangement AC Power Supply CP1E-30D-A : External supply terminal : Common terminal 00 to 07 : Output terminal CIO 100 CIO 101 VOUT0 : Analog voltage Output I OUT0 : Analog current Output CP1E-40D-A COM0 : Common terminal for analog...
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3 Part Names and Functions CP1E-N30S(1)DT-D COM :Common terminal 00~07 :Output terminal COM(V-) COM :External supply terminal (DC24V) :External supply terminal (0V) Note COM(V-) has been connected with V- in an inner circuit. CP1E-N30S(1)DT1-D COM(V+) COM CIO 100 CIO 101 Note COM(V+) has been connected with V+ in an inner circuit.
3 Part Names and Functions 3-1-3 Common I/O Specifications The following table gives the specifications that apply to the built-in I/O on a CP1E CPU Unit. Specifications Item Specification High-speed counter inputs, High-speed counter inputs interrupt inputs, quick- Input type Normal inputs or normal inputs response inputs...
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3 Part Names and Functions *1 The bits that can be used depend on the model of CPU Unit. *2 The response time is the delay caused by hardware. The delay set in the PLC Setup (0 to 32 ms, default: 8 ms) for a normal input must be added to this value.
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3 Part Names and Functions Estimating the Service Life of Relays Under normal conditions, the service life of output contacts is as shown above. The service life of relays is as shown in the following diagram as a guideline. CP1E-DR-...
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3 Part Names and Functions Output Specifications for Transistor Outputs (Sinking or Sourcing) CP1E- N14/20/30/40/60DT(1)-, CP1E-E10DT(1)-, CP1E-NA20DT(1)- Normal Outputs Specification Item N/NA(S)-type: CIO 100.00 and CIO 100.01 N/NA(S)-type: CIO 100.02 to CIO 102.07 E10-type: CIO 100.00 to CIO 100.03 Maximum 0.3 A/output, 0.9 A/common switching...
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3 Part Names and Functions *2 The bits that can be used depend on the model of CPU Unit. Precautions for Correct Use Precautions for Correct Use Do not connect a load to an output terminal or apply a voltage in excess of the maximum switch- ing capacity.
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3 Part Names and Functions Analog I/O (NA-type CPU Units) The NA-type CPU Units of the CP1E CPU Units are equipped with 2 built-in analog inputs and 1 built-in analog output. Analog Input Specifications Item Voltage input Current input Number of inputs 2 inputs (Allocated 2 words: CIO 90 to CIO 91.) Input signal range...
3 Part Names and Functions 3-1-4 Optional Serial Communications Port for N/NA(S)-type CPU Units The Serial Communication Port can be used for a CP1E N/NA(S)-type CPU Unit. N/NA-type CPU Units CP1E N30/40/60 or NA20 CPU Unit Built-in RS-232C port 10BASE-T 100BASE-TX CP1W-CIF01 CP1W-CIF11/12...
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3 Part Names and Functions N/NAS(1) -type CPU Units CP1E N30/40/60S(1) CPU Unit Built-in RS-232C port Built-in RS-485 port S1-type CPU Unit only) Built-in RS-232C Port and CP1W-CIF01 RS-232C Option Board Front Rear Communications status indicator CPU Unit connector COMM RS-232C connector ...
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3 Part Names and Functions Built-in RS-485 Port (2-wire) for N30/40/60S1 CPU Units RS-485 Terminal Block A- B+ FG DIP switch DIP switch for terminating resistance settings Setting ON (both ends) Terminating resistance selection Resistance value: 220Ω typical CP1W-CIF11 or CP1W-CIF12 RS-422A/485 Option Board Front Rear...
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3 Part Names and Functions DIP switch for operation settings CP1W-CIF11/12 CP1W-CIF12-V1 Setting ON (both ends) Terminating resistance selection Resistance value:220Ω typical 2-wire connections 2-wire or 4-wire selection 4-wire connections 2-wire connections 2-wire or 4-wire selection 4-wire connections − − Not used.
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3 Part Names and Functions Connector structure: RJ45 8-pin Modular Connector (conforming to ISO8877) Connector Pin Signal Name Abbr. Signal Direction Transmission data + Output Transmission data - Output Reception data + Input Not used Not used Reception data - Input Not used Not used...
3 Part Names and Functions 3-1-5 Analog Option Board for N/NA-type CPU Units The Analog Option Board can be used for a CP1E N30/40/60 or NA20 CPU Unit. N/NA-type CPU Units CP1E N30/40/60 or NA20 CPU Unit Built-in RS-232C port CP1W-ADB21 CP1W-DAB21V CP1W-MAB221...
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3 Part Names and Functions Analog Input Option Board Analog Input Terminal Arrangement Voltage Input 1 Current Input 1 Voltage Input 2 Current Input 2 Input Common Note When using current inputs, voltage input terminals must be short-circuited with current input terminals. ...
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3 Part Names and Functions Analog Output Option Board Analog Output Terminal Arrangement Voltage Output 1 Voltage Output 2 Output Common Main Specifications Specifications Item Voltage Output Current Output Output signal range 0 V to 10 V External output allowable load resistance 2 kΩ...
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3 Part Names and Functions Analog I/O Option Board Analog I/O Terminal Arrangement Voltage Input 1 Current Input 1 Voltage Input 2 Current Input 2 Analog I/O Common Voltage Output 1 Voltage Output 2 Analog I/O Common Note When using current inputs, voltage input terminals must be short-circuited with current input terminals. ...
3 Part Names and Functions Expansion I/O Units This section describes the names of the Expansion I/O Unit parts and provides the input specifications and terminal arrangement. Refer to A-1 Dimensions for the dimensions, A-2 Wiring Diagrams for the wiring diagrams. 3-2-1 Expansion Input Unit Part Names and Functions...
3 Part Names and Functions 3-2-2 Expansion Output Units Part Names and Functions 8-point Output Units 16-point Output Units CP1W-8ER/8ET/8ET1 CP1W-16ER/ET/ET1 Output terminals Output terminals Expansion I/O Expansion I/O connecting cable connecting cable Output indicators Output indicators 00 01 02 03 04 05 06 07 Expansion connector 16ER Expansion connector...
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3 Part Names and Functions Terminal Arrangements The first word of output words allocated to the Expansion Output Unit is indicated by CIO n. 8-point Output Units (CP1W-8E) Unit Upper Terminal Block Unit Lower Terminal Block : Common terminal 00 to 07 : Output terminal CIO n...
3 Part Names and Functions 3-2-3 Expansion I/O Units Part Names and Functions Units with 20 I/O Points Units with 40 I/O Points CP1W-20EDR1/EDT/EDT1 CP1W-40 EDR/EDT/EDT1 Input indicators Input indicators Input terminals Input terminals Expansion I/O Expansion I/O connecting cable connecting cable Expansion connector...
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3 Part Names and Functions Terminal Arrangements The first word of input words allocated to the Expansion I/O Unit is indicated by CIO m and the first word of the output words by CIO n. 20-point I/O Units (CP1W-20ED) •...
3 Part Names and Functions 3-2-4 I/O Specifications This section describes the I/O specifications common to all Expansion I/O Units. I/O Specifications Input Specifications (CP1W-8ED/20EDR1/20EDT/20EDT1/40EDR/40EDT/40EDT1) Item Specification Input voltage 24 VDC, +10%, -15% Input impedance 4.7 kΩ Input current 5 mA typical ON voltage 14.4 VDC min.
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3 Part Names and Functions Output Specifications for Relay Outputs (CP1W-8ER/16ER/20EDR1/32ER/40EDR) Item Specification Maximum switching capacity 2 A 250 VAC (cosφ = 1), 2 A 24 VDC (4 A/common) Minimum switching capacity 10 mA 5 VDC Service Electrical Resistive 150,000 operations (24 VDC) life of load...
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3 Part Names and Functions • CP1W-32ER’s maximum number of simultaneously ON output points is 24 (75%). Relation between Number of ON Outputs and Ambient Temperature (CP1W-32ER) Number of inputs ON simultaneously (%) Ambient temperature (˚C) According to the ambient temperature, there are restrictions on power supply voltage and output load current for the CPU Units connected with the Expansion I/O Units (CP1W-8ER/16ER/20EDR1/ 32ER/40EDR).
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3 Part Names and Functions Output Specifications for Transistor Outputs (Sinking or Sourcing) Specification Item CP1W-32ET CP1W-20EDT CP1W-16ET CP1W-8ET CP1W-40EDT CP1W-32ET1 CP1W-20EDT1 CP1W-16ET1 CP1W-8ET1 Maximum 4.5 to 30 VDC 4.5 to 30 VDC 24 VDC +10%/-5% 4.5 to 30 VDC 4.5 to 30 VDC switching 0.3 A/output...
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Programming Device This section describes the features of the CX-Programmer used for programming and debugging PLCs, as well as how to connect the PLC with the Programming Device. 4-1 Applicable Programming Devices for CP1E ......4-2 4-1-1 Applicable Programming Devices .
4 Programming Device Applicable Programming Devices for CP1E A programming device is a software application for initializing, programming, monitoring, and debug- ging PLCs. This section describes the programming device used by CP1E. 4-1-1 Applicable Programming Devices The programming devices in the following table are used to program and monitor the CP1E Unit. IBM PC/AT or equivalent CX-Programmer...
4 Programming Device Precautions for Correct Use Precautions for Correct Use • This section describes the unique applications and functions of the Micro PLC Edition CX- Programmer version 9.03 or higher/CX-Programmer for CP1E. In the remainder of this sec- tion, “CX-Programmer” refers to the Micro PLC Edition CX-Programmer version 9.03 or higher/CX-Programmer for CP1E.
4 Programming Device 4-1-3 Operating Environment and System Configuration The following system is required to operate the CX-Programmer. Make sure your system provides the following conditions and has the necessary components. Item Description Supported computer IBM PC/AT or equivalent CD-ROM or DVD-ROM drive One or more Supported operating systems Windows XP (Service Pack 3 or higher), Vista, 7 or 8...
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4 Programming Device Automatic Address Increment Function The addresses are automatically incremented to the addresses input last time by 1. The addresses of inputs and outputs are incremented by 1 respectively. • +1 bit for a bit address • +1 word for a word address Example: When the previous address was W0.01.
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4 Programming Device Instructions Can Be Copied with Automatic Address Incrementing Automatic Address Incrementing A copied group of ladder instructions can be pasted with a specified address offset (e.g., 16 bits). Instructions can be reused with automatic address incrementing Bit address + n (e.g., 16) Word address + m (e.g., 10) ...
4 Programming Device 4-1-5 Installing the Software This section provides a simple description of how to install the CX-Programmer on the hard disk of a computer. Preparing for Installation Check the following items before beginning with the installation. Available Hard Disk Space The CX-Programmer can be installed on the hard disk only.
4 Programming Device Connecting by USB This section describes how to connect a computer running the CX-Programmer and the CP1E CPU Unit. 4-2-1 Connecting by USB Preparations for Connection The USB driver must be installed in the computer to connect the PLC to the computer using the USB port.
4 Programming Device Restrictions on Connecting by USB The following restrictions apply to the connection of the CP1E to a computer due to the USB specifica- tions. Keep these restrictions in mind when using the USB port. • Only one CP1E CPU Unit can be connected by USB to a single personal computer. It is not possible to connect multiple CP1E CPU Units simultaneously.
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4 Programming Device The USB driver will be automatically installed when the cable is connected. Additional Information If the software is not automatically installed, refer to Installing a Specified USB Driver later in this section. Windows XP Turn ON the power supply to the PLC and connect the peripheral USB port on the PLC to the personal computer using a USB cable.
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4 Programming Device Additional Information • If the software cannot be installed automatically, refer to Installing a Specified USB Driver later in this section. • If the installation media is not inserted or the USB device driver is installed for another port, a Driver List Dialog Box will be displayed.
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Select I don’t have the disc. Show me other options. The following dialog box will be dis- played. Click the Browse Button, specify the following location, and then click the Next Button. C:\Program Files\OMRON\CX- Server\USB\wind2000_XP\Inf 4-12 CP1E CPU Unit Hardware User’s Manual(W479)
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4 Programming Device Ignore the following dialog box if it is displayed and select Install this driver software anyway. The following dialog box will be dis- played when the driver software has been installed successfully. CP1E CPU Unit Hardware User’s Manual(W479) 4-13...
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The Device Manager Dialog Box will be displayed. Double-click the USB (Universal Serial Bus) Controller Device. Check that OMRON SYSMAC PLC Device is displayed. If it appears, then the USB driver has been installed correctly. Close the Device Manager Dialog Box and System Properties Dialog Box.
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4 Programming Device Re-installing the USB Driver Right-click OMRON-PLC under Uni- versal Serial Bus controllers and select Properties. The properties will be displayed. Click the Reinstall Driver Button. The Hardware Update Wizard Dialog Box will be displayed. Install the driver software using the procedure...
4 Programming Device Connection Method with a Serial Port Using a built-in RS-232C port makes it possible to connect Support Software with serial communica- tions. Personal computer CX-One (e.g., CX-Programmer) D-Sub connector (9-pin, female) Recommended cable XW2Z-200S-CV (2 m) or D-Sub connector XW2Z-500S-CV (5 m) (9-pin, male)
5 Installation and Wiring Fail-safe Circuits This section describes the fail-safe circuits that must be set up outside the CP1E. Always set up safety circuits outside of the PLC to prevent dangerous conditions in the event of errors in the CP1E CPU Unit or external power supply. In particular, be careful of the following points.
5 Installation and Wiring Installation This section describes the environmental factors that must be considered and the installation location of each Unit. 5-2-1 Installation Location Installation Environment Do not install the Unit in the following locations. • Locations subject to ambient temperatures lower than 0ºC or higher than 55ºC. •...
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5 Installation and Wiring Not possible Accessibility for Operation and Maintenance • To ensure safe access for operation and maintenance, separate the PLC as much as possible from high-voltage equipment and moving machinery. • The PLC will be easiest to install and operate if it is mounted at a height of 1.0 to 1.6 m above the floor.
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5 Installation and Wiring Improving Noise Resistance Leave space between the CP1E and control panel or other devices to allow adequate dissipation of heat generated by the power supply. • Do not mount the PLC in a control panel containing high-voltage equipment. •...
5 Installation and Wiring 5-2-2 Unit Arrangement This section describes how to arrange the CP1E Units. As shown in the following diagrams, Units can be arranged in one or two rows when Expansion I/O Units or Expansion Units are used. Arrangement in One Row Expansion I/O Units and Expansion Units can be installed in a side-by-side arrangement.
5 Installation and Wiring 5-2-3 Installation This section describes how to install the CP1E. Dimensions and Installation Height Dimensions • E-type and N/NA-type CPU Units 110 100 90 4- φ 4.5 Model number CP1E-E10D- CP1E-14D- CP1E-20D- CP1E-30D- CP1E-40D- CP1E-N60D- CP1E-NA20D-...
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5 Installation and Wiring Installation Height The installation height is approximately 90 mm. When a cable is connected to an Option Board, however, the additional height must be included. Always allow for the additional height when considering the depth of the control panel in which the PLC is to be mounted.
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5 Installation and Wiring Fit the back of the Units onto the DIN Track by catching (1) the top of the Units on the Track and then pressing (2) in at the bottom of the Units, as shown below. DIN Track Press in all of the DIN Track mounting pins to securely lock the Units in place.
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5 Installation and Wiring End Plate Use the PFP-M End Plates to secure the Units so that they do not move towards one end or the other of the DIN Track. Surface Installation Surface Installation • Create the mounting holes in the mounting surface as shown in the dimensions diagrams. •...
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5 Installation and Wiring Using Wiring Ducts Whenever possible, route I/O wiring through wiring ducts. Install the ducts so that it is easy to wire the I/O Units through the ducts. It is handy to have the ducts at the same height as the Racks. Use mount- ing bases if necessary to adjust the heights.
5 Installation and Wiring 5-2-4 Connecting Expansion I/O Units and Expansion Units This section describes how to connect Expansion I/O Units and Expansion Units. Connection Methods Remove the cover from the CPU Unit’s or the Expansion I/O Unit’s expansion connector. Use a flat-head screwdriver to remove the cover from the Expansion I/O Connector.
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5 Installation and Wiring Precautions on Connecting Units The following restrictions apply to the CP-series Expansion Units and Expansion I/O Units that can be connected to CP1E CPU Units. Maximum Number of Connectable Units With an E30/40/60(S), N30/40/60(S) or NA20 CPU Unit, a total of up to three Expansion I/O Units and Expansion Units can be connected to one CPU Unit.
5 Installation and Wiring Wiring This section describes wiring methods for the CPU Unit. 5-3-1 Wiring Procedure Make sure that the power supply is OFF before beginning wiring. − 1. Prepare the parts required for wiring. Prepare crimp terminals and cables for wiring.
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5 Installation and Wiring AC Power Supply Wiring • Use twisted-pair power supply cables to prevent noise from the power supply lines. Adding a 1:1 isolating transformer reduces electrical noise even further. • Consider the possibility of voltage drops and the allowable current, and always use thick power lines.
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5 Installation and Wiring Wiring DC Power Supply and Ground 24VDC MCCB Upper Terminal Block GR:Protective ground terminal Ground to 100Ω or less • Wire a separate circuit for the power supply circuit so that there is no voltage drop from the inrush current or startup current that flows when other equipment is turned ON.
5 Installation and Wiring Precautions for Correct Use Precautions for Correct Use • Loose pieces of wires may fall in the area when wiring. To prevent these pieces from entering into the Unit, leave the label on the top of the Unit while wiring. •...
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5 Installation and Wiring Unit type Terminal width Terminal pitch CPU Units 6.4mm 7.6mm Expansion I/O Units 6.4mm 7.7mm 40ED/32E/20EDT Expansion I/O Units 6.8mm 8.4mm AD04/DA0/MAD/TS0/ SRT21/20EDR1/16E/8E Terminal Terminal width pitch Example of Input Device Connections Use the following information for reference when selecting or connecting input devices. ...
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5 Installation and Wiring Precautions When Connecting a Two-wire DC Sensor When using a two-wire sensor with a 24-VDC input device, check that the following conditions have been met. Failure to meet these conditions may result in operating errors. (1) Relation between voltage when the PLC is ON and the sensor residual voltage: ≤V −V (2) Relation between current when the PLC is ON and sensor control output (load cur-...
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Programming Example In this example, the sensor’s power supply voltage is used as the input to CIO 0.00. A 100-ms timer delay (the time required for an OMRON Proximity Sensor to stabilize) is created in the program. After the Completion Flag for the timer turns ON, the sensor input on input bit CIO 0.01 will cause output bit CIO 100.00 to turn ON.
5 Installation and Wiring 5-3-4 Wiring Safety and Noise Controls I/O Signal Wiring Whenever possible, place I/O signal lines and power lines in separate ducts or conduits both inside and outside of the control panel. (1):I/O cables (2):Power lines Floor ducts Conduit Suspended ducts When wiring in the same duct, use shielded cables and connect the shields to the GR terminal to...
5 Installation and Wiring Reducing Electrical Noise for External Wiring Take the following points into account when externally wiring I/O, power supply, and power lines. • When multi-conductor signal cable is being used, do not combine I/O wires and other control wires in the same cable.
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5 Installation and Wiring Countermeasure Examples • When switching an inductive load, connect a surge protector, diodes, etc., in parallel with the load or contact as shown below. Current Circuit Characteristic Required element CR method If the load is a relay or solenoid, there is The capacitance of the capacitor must be 1 to 0.5 μF per contact current of 1 A and a time lag between the moment the cir-...
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5 Installation and Wiring Conditions for Meeting EMC Directives when Using CP-series Relay Expansion I/O Units EN61131-2 immunity testing conditions when using the CP1W-40EDR, CP1W-32ER, or CP1W- 16ER with a CP1W-CN811 I/O Connecting Cable are given below. • Recommended Ferrite Core Ferrite Core (Data Line Filter): 0443-164151 manufactured by Nisshin Electric Minimum impedance: 90 Ω...
Troubleshooting This section describes how to troubleshoot problems that may occur with a CP1E PLC. 6-1 Troubleshooting CPU Unit Errors ....... . 6-2 6-1-1 Errors and Remedies .
6 Troubleshooting Troubleshooting CPU Unit Errors This section describes how to troubleshoot errors that occur in the CP1E CPU Units. 6-1-1 Errors and Remedies Use the following procedure when an error occurs. Error occurs Check the indicators on the front of the CPU Unit or use the CX- ·...
6 Troubleshooting Checking Error Status with the CX-Programmer Use the following procedure to read the error status. Place the CX-Programmer online with the CPU Unit. Double-click Error Log in the project tree in the main window. The PLC Errors Window will be displayed. Click the Errors Tab. The current errors will be dis- played on the Errors Tab Page.
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6 Troubleshooting Error Log Information A maximum of 20 error records will be stored in the error log. If more than 20 errors occur, the oldest error record (in A100 to A104) will be deleted and the 19 records stored in A105 to A199 will be shifted by one, with the newest record being stored in A195 to A199.
6 Troubleshooting Directly Monitoring the Area where Error Log Information is Stored Connect the CX-Programmer online. Read words A100 to A199. Check the error status from the registered data. 6-1-5 Types of Errors The type of error that has occurred can be identified by checking the indicators on the front of the CPU Unit, or by using the CX-Programmer to check the error status.
6 Troubleshooting 6-1-7 No Operation When Power Is Supplied First confirm that the POWER indicator (green) is lit. POWER Indicator Not Lit The power supply may not match the Unit rating, wiring may not be correct, or the Unit may be faulty. •...
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6 Troubleshooting Memory Errors Cause Remedy An error has occurred in memory. See below. One or more bits in A403 will turn ON to indicate where the error has occurred. See below for details. • Memory Error Location A403.00 is ON A checksum error has occurred in the Transfer the ladder program again.
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6 Troubleshooting Reference Error flag Too Many I/O Points Flag, A401.11 Error code (A400) 80E1 Error information Too Many I/O Points Details, A407 Program Errors A program error indicates a problem with the user program. Refer to the error information, check the program, and correct the mistakes.
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6 Troubleshooting Reference Error flag Program Error Flag, A401.09 Error code (A400) 80F0 Error information Program Error Details, A294 to A299 Cycle Time Exceeded Error Cause Remedy This error occurs when the cycle time • Change the program to reduce the cycle time. PV exceeds the maximum cycle time •...
CPU Unit Errors Cause Remedy A WDT (watchdog) error occurred in the CPU Cycle the power supply. Unit. The Unit may be faulty. Consult your OMRON representa- (This does not occur in normal use.) tive. Reference − Error flag −...
6 Troubleshooting 6-1-10 Non-fatal Errors A non-fatal error has occurred if both the RUN indicator is lit and the ERR/ALM indicator is flashing during operation (i.e., in RUN or MONITOR mode). CPU Unit Indicators : Not lit : Flashing : Lit POWER POWER...
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6 Troubleshooting Reference Error flag Backup Memory Error Flag, A315.15 Error code (A400) 00F1 − Error information PLC Setup Errors Cause Remedy A set value error occurred in the PLC Setup. Correct the PLC Setup with correct values. Reference Error flag PLC Setup Error Flag, A402.10 Error code (A400)
6 Troubleshooting Built-in Analog Errors (Only for NA-type) Cause Remedy For NA-type, when a built-in analog I/O error occurs. Restart the PLC .If this error still exists, please change unit. Reference Built-in analog error, A315.14 Error flag Other error flag, A402.00 Error code 008A Error information...
6 Troubleshooting Troubleshooting Unit Errors This section describes how to troubleshoot errors that occur in devices other than the CP1E CPU Unit. 6-2-1 Inputs Symptom Cause Remedy Not all inputs turn ON or 1. External power is not supplied for the Supply power.
6 Troubleshooting 6-2-2 Outputs Symptom Cause Remedy Not all outputs turn ON 1. Load is not supplied with power. Supply power. 2. Load voltage is low. Adjust voltage to within rated range. 3. Terminal block screws are loose. Tighten screws. 4.
6 Troubleshooting 6-2-3 Built-in Analog Symptom Cause Remedy ERR/ALM indicator is lit. A non-fatal error has occurred. Refer to 6-1-10 . Analog Input Symptom Cause Remedy Conversion data does not 1. The input is not set for being Check PLC setup,set analog input to change.
6 Troubleshooting 6-2-4 CX-Programmer Connection Use the following procedure if the CX-Programmer cannot connect to the PLC. Connecting via the Peripheral USB Port The CX-Programmer cannot connect. Is the USB cable Insert the cable all the way in at both the securely connected? personal computer and at the CPU Unit.
Maintenance and Inspection This section describes periodic inspections, the service life of the Battery, and how to replace the Battery. 7-1 Periodic Maintenance and Inspection ......7-2 7-1-1 Tools Required for Inspections .
7 Maintenance and Inspection Periodic Maintenance and Inspection This section describes periodic inspections and maintenance of CP1E PLCs. Daily or periodic inspections are required in order to maintain the PLC’s functions in peak operating condition. 7-1-1 Tools Required for Inspections ...
7 Maintenance and Inspection 7-1-3 Inspection and Maintenance Inspection Inspection Criteria Remedy points Power sup- Check for voltage fluctua- Allowable voltage Use a voltage tester to check the ply voltage tions at the power supply ter- range power supply at the terminals. Take minals.
• If a faulty Unit is being returned for repair, describe the problem in as much detail as possible, enclose this description with the Unit, and return the Unit to your OMRON representative. • For poor contact, take a clean cotton cloth, soak the cloth in industrial alcohol, and carefully wipe the contacts clean.
7 Maintenance and Inspection Replacing the Battery in N/NA(S)- type CPU Units For CP1E N/NA(S)-type CPU Units, the data in the following areas may be unstable when the power is turned ON. Mount the CP1W-BAT01 Battery (sold separately) to an N/NA(S)-type CPU Unit if data in the following areas need to be retained after a power interruption.
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7 Maintenance and Inspection Low Battery Indications The ERR/ALM indicator on the front of the CPU Unit will flash when the Battery is nearly discharged. Flashing When the ERR/ALM indicator flashes, connect the CX-Programmer to the peripheral USB port and read the error messages.
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7 Maintenance and Inspection Replacing the Battery Use the following procedure to replace the Battery when the previous Battery has become completely discharged. Precautions for Safe Use We recommend replacing the Battery with the power OFF to prevent the CPU Unit’s sensitive internal components from being damaged by static electricity.
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7 Maintenance and Inspection Precautions for Safe Use • You must complete this procedure within 5 minutes after turning OFF the power to the CPU Unit to ensure memory backup. If the Battery is removed for more than 5 minutes, data retained by the I/O memory (excluding the DM Area words saved to the backup memory) may be unstable.
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Using Expansion Units and Expansion I/O Units This section describes the Analog Input Unit, Analog Output Unit, Temperature Sensor Units, CompoBus/S I/O Link Unit, and Expansion I/O Units. 8-1 Analog Input Units ..........8-2 8-1-1 Overview .
8 Using Expansion Units and Expansion I/O Units Analog Input Units 8-1-1 Overview Each CP1W-AD041/CP1W-AD042 Analog Input Unit provides four analog inputs. • The analog input signal ranges are 0 to 5 V, 1 to 5 V, 0 to 10 V, -10 to +10 V, 0 to 20 mA, and 4 to 20 mA.
8 Using Expansion Units and Expansion I/O Units Precautions for Safe Use Do not touch the cables during operation. Static electricity may cause operating errors. (3)Expansion Connector Connected to the next Expansion Unit or Expansion I/O Unit to enable expansion. 8-1-3 Specifications CP1W-AD041/AD042 Analog Input Units are connected to a CP1E CPU Unit.
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8 Using Expansion Units and Expansion I/O Units Additional Information When the input exceeds the specified range, the A/D conversion data will be fixed at either the lower limit or upper limit. -10 to 10 V Inputs When the resolution is 1/6,000, the -10 to 10 V Converted data range correspond to hexadecimal values F448 to Hexadecimal (Decimal)
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8 Using Expansion Units and Expansion I/O Units 0 to 5 V Inputs When the resolution is 1/6,000, the 0 to 5 V range Converted data correspond to hexadecimal values 0000 to 1770 (0 Hexadecimal (Decimal) to 6,000). The range of data that can be converted 189C (6300) is FED4 to 189C hex (-300 to 6,300).
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8 Using Expansion Units and Expansion I/O Units When the resolution is 1/12,000, the 0 to 20 mA Converted Data Hexadecimal (Decimal) range correspond to hexadecimal values 0000 to 2EE0 (0 to 12,000). The entire data range is FDA8 3138 (12600) to 3138 hex (-600 to 12,600).
8 Using Expansion Units and Expansion I/O Units 8-1-4 Flow of Operation • Connect Analog Input Units. Connect and wire Units. • Wire to analog output devices. • Write set data to output words (n+1, n+2). Create a ladder program. •...
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8 Using Expansion Units and Expansion I/O Units Wire to analog output devices. (1) Wiring internal circuits of the CPU Unit V IN1 510 kΩ 250 Ω I IN1 Analog input 1 COM1(−) 510 kΩ V IN4 510 kΩ 250 Ω I IN4 Analog input 4 COM4(−)
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8 Using Expansion Units and Expansion I/O Units Additional Information Refer to the following information on open circuits when using voltage inputs. Analog output device Analog output device 24 VDC For example, if connected device 2 is outputting 5 V and the same power supply is being used for both devices as shown above, approximately 1/3, or 1.6 V, will be applied to the input for input device If a wiring disconnection occurs when voltage input is being used, the situation described below will result.
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8 Using Expansion Units and Expansion I/O Units Create the ladder program. (1) Allocating I/O Words Four input words and two output words are allocated from the next words following the last I/O words allocated to the CPU Unit or an existing Expansion Unit or Expansion I/O Unit. Words (m+1) to (m+4) Analog Input Unit Words (n+1), (n+2)
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8 Using Expansion Units and Expansion I/O Units (4) Reading Analog Input Conversion Values The ladder program can be used to read the memory area words where the converted val- ues are stored. With word m as the last input word allocated to the CPU Unit or an already-connected Expansion Unit, the A/D conversion data will be output to the following words m+1 to m+4.
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8 Using Expansion Units and Expansion I/O Units (7) Program Example Destination Analog input Input range Range code Averaging Set data word Input 1 0 to 10 V 1101 (D hex) Input 2 4 to 20 mA 1110 (E hex) Input 3 -10 to +10 V 1000 (8 hex)
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8 Using Expansion Units and Expansion I/O Units • Example: Scaling analog input values When a 0 to 10V voltage is input to the analog input word (CIO 3) of CP1W-AD042 as 0 to 12,000, convert the value into a value between 0 and 24,000 and output the result to D200. 24,000 Scaled value...
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8 Using Expansion Units and Expansion I/O Units C: Control word Set for “Signed Integer Data (Binary)”. Control word setting #0800: Binary numeral (0000 1000 0000 0000) The number of coordinates is 1 (m=1), so 14 13 12 11 10 9 set bit 0 to 7 to “0”...
8 Using Expansion Units and Expansion I/O Units Analog Output Units 8-2-1 Overview Each CP1W-DA021 Analog Output Unit provides two analog outputs. Each CP1W-DA041/CP1W-DA042 Analog Output Unit provides four analog outputs. • The analog output signal ranges are 1 to 5 V, 0 to 10 V, -10 to +10 V, 0 to 20 mA, and 4 to 20 mA. The resolution of CP1W-DA021/DA041 is 1/6,000.
8 Using Expansion Units and Expansion I/O Units • I/O Terminal Arrangement for CP1W-DA041/DA042 V OUT1 Voltage output 1 I OUT1 Current output 1 I OUT1 VOUT2 COM2 I OUT3 VOUT4 COM4 VOUT1 COM1 I OUT2 VOUT3 COM3 I OUT4 COM1 Output common 1 V OUT2...
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8 Using Expansion Units and Expansion I/O Units Model CP1W-DA021/CP1W-DA041 CP1W-DA042 Item Voltage output Current output Voltage output Current output Analog Number of analog CP1W-DA021: 4 outputs (4 words allocated) output outputs 2 outputs (2 words allocated) section CP1W-DA041: 4 outputs (4 words allocated) Output signal range 1 to 5 V, 0 to 20 mA...
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8 Using Expansion Units and Expansion I/O Units -10 to 10 V When the resolution is 1/6,000, the hexadecimal values F448 to 0BB8 (-3000 to 3000) correspond to an analog voltage range of -10 to 10 V. The entire output range is -11 to 11 V. Specify the DA conversion data as the two’s complement if it is a negative value.
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8 Using Expansion Units and Expansion I/O Units When the resolution is 1/12,000, the hexadecimal values 0000 to 2EE0 (0 to 12000) correspond to an analog voltage range of 0 to 10 V. The entire output range is -0.5 to 10.5 V. Specify the DA conversion data as the two's complement if it is a negative value.
8 Using Expansion Units and Expansion I/O Units When the resolution is 1/12,000, the hexadecimal values 0000 to 2EE0 (0 to 12000) correspond to an analog voltage range of 0 to 20 mA. The entire output range is 0 to 21 mA. 21 mA 20 mA 8000...
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8 Using Expansion Units and Expansion I/O Units Writing Set Data and Writing D/A Conversion Data CP1W-DA021 Analog Output Unit CPU Unit Word (n+1) Set data (outputs 1, 2) Ladder program Word (n+1) Analog output 1 conversion value Analog devices Word (n+2) Analog output 2 conversion value •...
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8 Using Expansion Units and Expansion I/O Units Wire to analog input devices. (1) Wiring internal circuits of the CPU Unit The following diagram shows the internal circuit using CP1W-DA041/DA042 as an exam- ple, which wires analog outputs 1 to 4. In the case of CP1W-DA021, analog outputs 1 to 2 can be used.
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8 Using Expansion Units and Expansion I/O Units Create the ladder program. (1) Allocating Output Words Four output words (n+1 to n+4) are allocated to the Analog Output Unit starting from the next word following the last word allocated to the CPU Unit or previous Expansion Unit or Expansion I/O Unit.
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8 Using Expansion Units and Expansion I/O Units (3) Writing Analog Output Conversion Values The ladder program can be used to write conversion data to the output words. When “n” is the last output word allocated to the CPU Unit, or previous Expansion Unit or Expansion I/O Unit, the output words will be n+1 to n+2 for CP1W-DA021 and n+1 to n+4 for CP1W-DA041/DA042.
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8 Using Expansion Units and Expansion I/O Units (6) Program Example (CP1W-DA041/DA042) Analog output Output range Range code Set data Destination word Output 1 0 to 10 V 1001 (9 hex) Output 2 4 to 20 mA 1100 (C hex) Output 3 -10 to 10 V 1000 (8 hex)
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8 Using Expansion Units and Expansion I/O Units • Example: Scaling analog output values Convert a value between 200 and 500 in D300 into 2 to 5 V to output the voltage from the analog output word (CIO 102) of CP1W-DA042. Unscaled data (200 to...
8 Using Expansion Units and Expansion I/O Units Analog I/O Units 8-3-1 CP1W-MAD11 Analog I/O Units Overview Each CP1W-MAD11 Analog I/O Unit provides 2 analog inputs and 1 analog output. • The analog input range can be set to 0 to 5 V, 1 to 5 V, 0 to 10 V, -10 to 10 V, 0 to 20 mA, or 4 to 20 mA.
8 Using Expansion Units and Expansion I/O Units Precautions for Safe Use Do not touch the cables during operation. Static electricity may cause operating errors. (3)Expansion Connector Used for connecting Expansion Units or Expansion I/O Units. (4)DIP Switch Used to enable or disable averaging. Pin 1: Average processing for analog input 0 (OFF: Average processing not performed;...
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8 Using Expansion Units and Expansion I/O Units Model CP1W-MAD11 Item Voltage I/O Current I/O Analog Number of analog inputs 2 inputs (2 words allocated) Input Input signal range 0 to 5 V, 1 to 5 V, 0 to 10 V, 0 to 20 mA or 4 to 20 mA Section or -10 to 10 V...
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8 Using Expansion Units and Expansion I/O Units Analog Input Signal Ranges -10 to 10 V Voltages in the -10 to 10 V range corre- Converted Data spond to hexadecimal values F448 to 0BB8 Hexadecimal (Decimal) (-3,000 to 3,000). The range of data that 0CE4 (3300) can be converted is F31C to 0CE4 hex (- 3,300 to 3,300).
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8 Using Expansion Units and Expansion I/O Units 1 to 5 V Voltages in the 1 to 5 V range correspond to Converted Data hexadecimal values 0000 to 1770 (0 to Hexadecimal (Decimal) 6,000). The range of data that can be con- verted is FED4 to 189C hex (-300 to 6,300).
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8 Using Expansion Units and Expansion I/O Units Analog Output Signal Ranges -10 to 10 V The hexadecimal values F448 to 0BB8 (-3000 to 3000) correspond to an analog voltage range of -10 to 10 V. The entire output range is -11 to 11V. Specify the DA conversion data as the two’s complement if it is a negative value.
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8 Using Expansion Units and Expansion I/O Units 0 to 20 mA The hexadecimal values 0000 to 1770 (0 to 6000) correspond to an analog current range of 0 to 20 mA. The entire output range is 0 to 21 mA. 21 mA 20 mA 8000...
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8 Using Expansion Units and Expansion I/O Units Flow of Operation • Connect the Analog I/O Unit. Connect the Unit. • Set analog inputs as voltage or current inputs and set the aver- aging function. • Connect analog I/O devices. Wire the analog I/O.
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8 Using Expansion Units and Expansion I/O Units Connect the Analog I/O Unit to the CPU Unit. CP1W-MAD11 CP1E CPU Unit Analog I/O Unit • Setting the Averaging Function DIP switch pins 1 and 2 are used to set the averaging function. When averaging is enabled, a moving average of the last eight input values is output as the converted value.
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8 Using Expansion Units and Expansion I/O Units (3) Wiring analog input devices to the Analog I/O Unit 2-core shielded 2-core shielded twisted-pair cable twisted-pair cable V OUT Analog V OUT Analog device device Analog Analog I OUT I OUT with with Output...
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8 Using Expansion Units and Expansion I/O Units • If the same power supply is being used by the connected devices and a disconnection occurs at points A or B in the above diagram, an unwanted circuit path will occur as shown along the dotted line in the diagram.
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8 Using Expansion Units and Expansion I/O Units 7 6 5 4 3 2 1 0 0 0 0 0 0 word n+1 Analog Analog Analog output input 1 input 0 Example: The following instructions set analog input 0 to 4 to 20 mA, analog input 1 to 0 to 10 V, and the analog output to -10 to 10 V.
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8 Using Expansion Units and Expansion I/O Units (6) Handling Unit Errors • When an error occurs in the Analog I/O Unit, analog input data will be 0000 and 0 V or 0 mA will be output as the analog output. If a CPU error or an I/O bus error (fatal errors) occurs at the CPU Unit and the analog output is set to 1 to 5 V or 4 to 20 mA, 0 V or 0 mA will be output.
8 Using Expansion Units and Expansion I/O Units 8-3-2 CP1W-MAD42/CP1W-MAD44 Analog I/O Units Overview Each CP1W-MAD42 Analog I/O Unit provides 4 analog inputs and 2 analog outputs. Each CP1W-MAD44 Analog I/O Unit provides 4 analog inputs and 4 analog outputs. •...
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8 Using Expansion Units and Expansion I/O Units • Output Terminal Arrangement for CP1W-MAD42 V OUT1 Voltage output 1 I OUT1 Current output 1 COM1 Output common 1 V OUT2 Voltage output 2 I OUT2 Current output 2 COM2 Output common 2 •...
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8 Using Expansion Units and Expansion I/O Units Model CP1W-MAD042/CP1W-MAD044 Item Voltage I/O Current I/O Analog Number of inputs 4 inputs (4 words allocated) Input Input signal range 0 to 5 VDC, 1 to 5 VDC, 0 to 20 mA or 4 to 20 mA Section 0 to 10 VDC, or −10 to 10 VDC ±15 V...
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8 Using Expansion Units and Expansion I/O Units Analog Input Signal Ranges −10 to 10 V The −10 to 10 V range corresponds to the hexadecimal values E890 to 1770 (−6000 to 6000). The entire data range is E638 to 19C8 (−6600 to 6600). A negative voltage is expressed as a two’s complement.
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8 Using Expansion Units and Expansion I/O Units 1 to 5 V The 1 to 5 V range corresponds to the hexadecimal values 0000 to 2EE0 (0 to 12000). The entire data range is FDA8 to 3138 (−600 to 12600). Inputs between 0.8 and 1 V are expressed as two’s complements.
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8 Using Expansion Units and Expansion I/O Units Analog Output Signal Ranges −10 to 10 V The hexadecimal values E890 to 1770 (−6000 to 6000) correspond to an analog voltage range of −10 to 10 V. The entire output range is −11 to 11 V. Specify a negative voltage as a two’s complement. 11 V 10 V E638...
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8 Using Expansion Units and Expansion I/O Units 0 to 20 mA The hexadecimal values 0000 to 2EE0 (0 to 12000) correspond to an analog current range of 0 to 20 mA. The entire output range is 0 to 21 mA. 21 mA 20 mA 8000...
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8 Using Expansion Units and Expansion I/O Units Flow of Operation • Connect the Analog I/O Unit. Connect the Unit. • Set analog inputs as voltage or current inputs and set the aver- aging function. • Connect analog I/O devices. Wire the analog I/O.
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8 Using Expansion Units and Expansion I/O Units Writing D/A Conversion Data CPU Unit CP1W-MAD42 Ladder program Analog output 1 Word (n+1) conversion value Analog output 2 Word (n+2) conversion value Writes the conversion values. Analog devices • Adjustment equipment “n”...
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8 Using Expansion Units and Expansion I/O Units Wire to analog I/O devices. (1) Wiring internal circuits of the CPU Unit Analog Inputs V IN1 250 Ω 510 kΩ I IN1 Analog input 1 COM1 (−) 510 kΩ V IN4 250 Ω...
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8 Using Expansion Units and Expansion I/O Units Precautions for Correct Use Precautions for Correct Use • Do not connect the shield when using shielded twisted-pair cables. • When an input is not being used, short V IN and I IN to COM terminals. •...
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8 Using Expansion Units and Expansion I/O Units Additional Information When external power is supplied (when setting the range code), or when there is a power inter- ruption, a pulse-form analog output may be generated. If this causes problems with operation, take countermeasures such as those suggested below. (1) Countermeasure 1 •...
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8 Using Expansion Units and Expansion I/O Units (b) CP1W-MAD44 Write the set data to words (n+1 to n+4). A/D or D/A conversion begins when the set data is transferred from the CPU Unit to the Analog I/O Unit. Setting contents are shown as the following table.
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8 Using Expansion Units and Expansion I/O Units (3) Averaging Set whether averaging is to be used for set data. When the averaging bit is set to 1, the average (moving average) for the past eight inputs is output as conversion data. (4) Reading Analog Input Converted Values Read the conversion value storage area with the ladder program.
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8 Using Expansion Units and Expansion I/O Units This programming example uses these ranges: (a) CP1W-MAD42 Analog Input Range Averaging Set data Destination input range code word Input 1 4 to 20 mA 1110 (E hex) Input 2 0 to 10 V 1101 (D hex) Input 3 0 to 5 V...
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8 Using Expansion Units and Expansion I/O Units Always ON Flag P_On 0005 #0002 Execution T0005 condition ← Reads analog input 1’s of CP1W-MAD42 converted value. Execution T0005 condition ← Reads analog input 2’s of CP1W-MAD42 converted value. Execution T0005 condition ←...
8 Using Expansion Units and Expansion I/O Units Temperature Sensor Units 8-4-1 CP1W-TS1/TS2 Temperature Sensor Units Overview CP1W-TS002/TS102 Temperature Sensor Units each provide up to four input points, and CP1W- TS001/TS101 Temperature Sensor Units each provide up to two input points. The inputs can be from thermocouples or platinum resistance thermometers.
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8 Using Expansion Units and Expansion I/O Units Specifications A CP1W-TS01/TS02 Temperature Sensor Unit can be connected to a CP1E CPU Unit. CP1W-20EDR1 CP1W-8ED CP1W-TS 01/TS CP1E CPU Unit Expansion I/O Unit Expansion I/O Unit Temperature Sensor Unit C OM C OM 00 01 02 03 04 05 06 07 C H 00 01 02 03...
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8 Using Expansion Units and Expansion I/O Units Connect the Temperature Sensor Unit to the CPU Unit. CP1W-20EDR1 CP1W-8ED CP1W-TS001/101 Expansion I/O Unit Expansion I/O Unit Temperature Sensor Unit CP1E CPU Unit 0 30 00 01 02 03 04 05 06 07 CH 00 01 02 03 08 09 10 11 08 09 10 11...
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8 Using Expansion Units and Expansion I/O Units (2) Rotary Switch Setting Caution Set the temperature range according to the type of temperature sensor connected to the Unit. Temperature data will not be converted correctly if the temperature range does not match the sensor. Do not set the temperature range to any values other than those for which temperature ranges are given in the following table.
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8 Using Expansion Units and Expansion I/O Units (b) CP1W-TS002 Up to four K or J thermocouples can be connected to the CP1W-TS002, but all four thermocouples must be the same type and the same input range. Input 0 Input 1 Input 2 Input 3 Input 0...
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8 Using Expansion Units and Expansion I/O Units (b) CP1W-TS102 Up to four Pt100 or JPt100 platinum resistance thermometers can be connected to the CP1W-TS102, but all four of the thermometers must be of the same type and the same input range must be used for each.
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8 Using Expansion Units and Expansion I/O Units (2) Reading Temperature Data The temperature data will be stored in the input words allocated to the Temperature Sensor Unit in 4-digit hexadecimal. CP1W-TS002/TS102 CP1W-TS001/TS101 Converted temperature Converted temperature data from input 0 data from input 0 Converted temperature Converted temperature...
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8 Using Expansion Units and Expansion I/O Units (3) Startup Operation After power is turned ON, approximately 1 s is required for the first conversion data to be stored in the input word. During that period, the data will be 7FFE. Therefore, create a pro- gram as shown below, so that when operation begins simultaneously with startup it will wait for valid conversion data.
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8 Using Expansion Units and Expansion I/O Units Always ON P_On Detects completion of input 0 initialization. #7FFE P_EQ ON when input 0 has been initialized W0.00 Always ON P_On Detects completion of input 1 initialization. #7FFE P_EQ W0.01 ON when input 1 has been initialized W0.00 Execution condition Detects an open-circuit alarm or Unit...
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8 Using Expansion Units and Expansion I/O Units (b) The following programming example shows how to convert the data for temper- ature input 0 to BCD and store the result in D0 and D1. “#0001” is stored in D1 when the input data is a negative value. The following system configuration is used.
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8 Using Expansion Units and Expansion I/O Units (7) Programming with SCL2 Instruction Always ON P_On Detects completion of input 0 initialization. #7FFE P_EQ W0.00 ON when initialization complete. Execution W0.00 condition Detects an open-circuit alarm or Unit error by checking whether the error code 7FFF has been output #7FFF P_EQ...
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8 Using Expansion Units and Expansion I/O Units Temperature Data Partitioning and Structure Temperature Data (Actual Temperature x 100 Binary) @ @ @ @ @ @ Leftmost 3 Digits and Flags Temperature Open-circuit Leftmost/ Not used. Temperature data Unit Flag Flag Rightmost Flag 0: °C...
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8 Using Expansion Units and Expansion I/O Units Example 2 Temperature: -100.12°C ×100: -10012 Temperature Data: FFD8E4 (hexadecimal for -10012) Leftmost 3 Digits and Flags ×16 ×16 ×16 Flags Bits 11 to 08 07 to 04 03 to 00 Data Normal Temperature Flags...
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8 Using Expansion Units and Expansion I/O Units Additional Information • Leftmost digits are stored in the lower memory addresses. Treat the data in the lower memory address as the leftmost digits when programming. • Be sure that the data is read at least once every 125 ms to allow for the CPU Unit’s cycle time and communications time.
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8 Using Expansion Units and Expansion I/O Units A200.11 (First Scan Flag) Sets D103 and D102 to #0100 and #0000 #0000, respectively. D102 #0100 D103 P_On (Always ON Flag) Detects completion of input 0 initialization. #7FFE P_EQ W0.00 ON when input 0 has been initialized. W0.00 2.13 (open-circuit detected)
8 Using Expansion Units and Expansion I/O Units Description of Operation CIO 2: Leftmost 3 digits of temperature data CIO 2: Rightmost 3 digits of temperature data W100 W102 0 16 W101 If the temperature data is non-negative, binary data is converted to BCD data.
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8 Using Expansion Units and Expansion I/O Units (3)Expansion I/O Connecting Cable Connected to the expansion connector of a CP1E CPU Unit or an Expansion Unit or Expansion I/O Unit.The cable is included with the Temperature Sensor Unit and cannot be removed. Precautions for Safe Use Do not touch the cables during operation.
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8 Using Expansion Units and Expansion I/O Units Analog Input Signal Ranges Analog input data is digitally converted according to the input signal range as shown below. Additional Information When the input exceeds the specified range, the A/D conversion data will be fixed at either the lower limit or upper limit.
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8 Using Expansion Units and Expansion I/O Units 4 to 20 mA The 4 to 20 mA range corresponds to the hexadecimal values 0000 to 2EE0 (0 to 12000). The entire data range is FDA8 to 3138 (−600 to 12600). Inputs between 3.2 and 4 mA are expressed as two’s complements.
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8 Using Expansion Units and Expansion I/O Units Connect the Temperature Sensor Unit to the CPU Unit. CP1E CPU Unit CP1W-20EDR1 CP1W-8ED CP1W-TS003 Expansion I/O Unit Expansion I/O Unit Temperature Sensor Unit C O M C O M 00 01 02 03 04 05 06 07 C H 00 01 02 03 08 09 10 11 08 09 10 11...
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8 Using Expansion Units and Expansion I/O Units With the Temperature Sensor Unit’s DIP switch, set the input type (temperature or analog input), the input thermocouple type (K or J) and the temperature unit (°C or °F). SW 1 Setting Thermocouple type of temperature sensor Temperature unit...
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8 Using Expansion Units and Expansion I/O Units Precautions for Correct Use Precautions for Correct Use When connecting a thermocouple input, observe the following precautions: • Do not remove the cold junction compensator attached at the time of delivery. If the cold junc- tion compensator is removed, the Unit will not be able to measure temperatures correctly.
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8 Using Expansion Units and Expansion I/O Units Create the ladder program. (1) Word Allocations Temperature Sensor Units are allocated words in the same way as other CP-series Expan- sion Units or Expansion I/O Units, in order of connection. A Temperature Sensor Unit is allocated the next input words following the input words of the CPU Unit or previous Expan- sion Unit or Expansion I/O Unit.
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8 Using Expansion Units and Expansion I/O Units (4) Programming Example The following programming example shows how to store the input data of CP1W-TS003 (4 inputs) in D0 to D3, and W10.00 to W10.03 turn ON at the time of open-circuit detection. CP1E CP1W-TS003 Temperature Sensor Unit...
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8 Using Expansion Units and Expansion I/O Units Detects initialization complete <>(305) MOV(021) Stores input 0’s data in D0. #7FFE ON when an open-circuit alarm has been W10.00 =(300) detected for thermocouples input 2. #7FFF <>(305) MOV(021) Stores input 1’s data in D1. #7FFE ON when an open-circuit alarm has been W10.01...
8 Using Expansion Units and Expansion I/O Units 8-4-3 TS004 Temperature Sensor Units Overview CP1W-TS004 Temperature Sensor Unit provide up to twelve input points. The inputs can be from thermocouples. CP1W-TS004 Temperature Sensor Unit is allocated two input words and one output word, so no more than seven Units can be connected.
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8 Using Expansion Units and Expansion I/O Units Specifications Item CP1W-TS004 Temperature sensors Thermocouples Switchable between K and J, but same type must be used for all inputs. Number of inputs Allocated input words Allocated output words Accuracy 25°C (The larger of ±0.5% of converted value or ±2°C) ±1 digit max. *1 0 to 55°C (The larger of ±1% of converted value or ±4°C) ±1 digit max.
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8 Using Expansion Units and Expansion I/O Units Set temperature ranges. Precautions for Safe Use Do not touch the DIP switch while power is being supplied. Static electricity may cause operating errors. Precautions for Correct Use Precautions for Correct Use Always turn OFF the power supply before setting the temperature range.
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8 Using Expansion Units and Expansion I/O Units Connecte Temperature Sensors. (1) Thermocouples Either K or J thermocouples can be connected, but all twelve thermocouples must be the same type and the same input range. Temperature input 1 Cold junction Temperature input 11 compensator Temperature input 0...
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8 Using Expansion Units and Expansion I/O Units (2) Reading Temperature Data There are 12 temperature input data to be read, but only two input words are allocated to CP1W-TS004. The operation is shown as the following. • Input Word Response.
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8 Using Expansion Units and Expansion I/O Units (3) Creating Ladder Program (1) Write temperature data command Write temperature data command which read temperature data from input word to CIO n+1. (2) Response confirmation After CP1W-TS004 receives CIO n+1 read command and CP1W-TS004’s internally specified input temperature data is ready, the value which is the same as the read command will be stored in CIO m+1.
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8 Using Expansion Units and Expansion I/O Units (4) Programming Example The temperature data of CP1W-TS004 (12 inputs, input type is J type and temperature unit is °C) is stored in D0 to D11. When it occurs open-circuit alarm, W10.00 to W10.11 is ON. CP1E CP1W-TS004 Temperature Sensor Unit...
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8 Using Expansion Units and Expansion I/O Units First Cycle ON Flag Start to read temperature data. W0.00 W0.00 MOV(021) Write input 0’s read command (#9901) to CIO 102 (CIO n+1). #9901 If CIO 2 (CIO m+1) and read MOV(021) =(300) command are matched, store #9901...
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8 Using Expansion Units and Expansion I/O Units W0.03 MOV(021) #9904 MOV(021) =(300) #9904 Read Input 3’s temperature data W10.03 =(300) #7FFF W0.04 RSET W0.03 W0.04 MOV(021) #9905 MOV(021) =(300) #9905 Read Input 4’s temperature data W10.04 =(300) #7FFF W0.05 RSET W0.04 W0.05...
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8 Using Expansion Units and Expansion I/O Units W0.06 MOV(021) #9907 MOV(021) =(300) #9907 Read Input 6’s temperature data W10.06 =(300) #7FFF W0.07 RSET W0.06 W0.07 MOV(021) #9908 MOV(021) =(300) #9908 Read Input 7’s temperature data W10.07 =(300) #7FFF W0.08 RSET W0.07 W0.08...
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8 Using Expansion Units and Expansion I/O Units W0.09 MOV(021) #990A MOV(021) =(300) #990A Read Input 9’s temperature data W10.09 =(300) #7FFF W0.10 RSET W0.09 W0.10 MOV(021) #990B MOV(021) =(300) #990B Read Input 10’s temperature data W10.10 =(300) #7FFF W0.11 RSET W0.10 W0.11...
8 Using Expansion Units and Expansion I/O Units CompoBus/S I/O Link Units 8-5-1 Overview The CP1E CPU Unit can function as a slave to a CompoBus/S Master Unit when a CP1W-SRT21 Com- poBus/S I/O Link Unit is connected. The CompoBus/S I/O Link Unit establishes an I/O link of 8 inputs and 8 outputs between the Master Unit and the PLC.
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8 Using Expansion Units and Expansion I/O Units (1)CompoBus/S Terminals The following CompoBus/S terminals are provided: CompoBus/S communications data high/low terminals, NC terminals for communications power supply plus (+) and minus (-), and an NC ter- minal. (Power is supplied internally for this Unit, so the NC terminals for communications power supply can be used as relay terminals.) (2)DIP Switch Used to specify the node number for the CompoBus/S I/O Link Unit.
8 Using Expansion Units and Expansion I/O Units 8-5-3 Specifications Model CP1W-SRT21 Master/slave CompoBus/S Slave Number of I/O points 8 input points, 8 output points Number of words allocated in 1 input word, 1 output word CPU Unit I/O memory Node number setting Set using the DIP switch (Set before turning on the CPU Unit’s power supply.)
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8 Using Expansion Units and Expansion I/O Units I/O Words Allocation I/O words are allocated to the CompoBus/S I/O Link Unit in the same way as to other Expansion Units and Expansion I/O Units, i.e., the next available input and output words are allocated. As shown below, when “m”...
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8 Using Expansion Units and Expansion I/O Units Additional Information • Unused bits in the CompoBus/S I/O Link Unit’s output words can be used as work bits. • Unused bits in input word cannot be used as work bits. Determine the node number and make DIP switch settings. (1) Determining Node Number •...
Appendices Dimensions A-1-1 CPU Units CPU Units with 10 I/O Points CP1E-E10D- Unit: mm 4-φ4.5 CPU Units with 14 or 20 I/O Points CP1E-14D-/20D- Unit: mm 110 100 90 2-φ4.5 CP1E CPU Unit Hardware User’s Manual(W479)
Appendices CP1E-E14/20SD- Unit: mm 78.6 110 100 90 2-φ4.5 CPU Units with 30 I/O Points CPU Units with Built-in Analog and 20 I/O Points CP1E-30D-, CP1E-NA20D- Unit: mm 110 100 90 4-φ4.5 CP1E-30S(1)D- Unit: mm 78.6 110100 90 4-φ4.5 CP1E CPU Unit Hardware User’s Manual(W479)
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Appendices CPU Units with 40 I/O Points CP1E-40D- Unit: mm 110 100 90 4-φ4.5 CP1E-40S(1)D- Unit: mm 78.6 110 100 90 4-φ4.5 CPU Units with 60 I/O Points CP1E-N60D- Unit: mm 4-φ4.5 CP1E CPU Unit Hardware User’s Manual(W479)
Appendices CP1E-60S(1)D- Unit: mm 78.6 4-φ4.5 A-1-2 Option Boards CP1W-CIF01 RS-232C Option Board Unit: mm 0.15 16.5 35.9 13.5 16.5 19.7 CP1E CPU Unit Hardware User’s Manual(W479)
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Appendices CP1W-CIF11/CIF12-V1 RS-422A/485 Option Board Unit: mm 0.15 16.5 35.9 13.5 15.7 16.5 CP1W-CIF12 RS-422A/485 Option Board (Not include CP1W-CIF12-V1) Unit: mm 0.15 30.3 36.4 28.2 CP1W-CIF41 Ethernet Option Board Unit: mm 36.4 28.2 14.7 10BASE-T 100BASE-TX CP1E CPU Unit Hardware User’s Manual(W479)
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Appendices CP1W-MAB221 Analog Input/Output Option Board Unit: mm 0.15 36.4 CP1W-ADB21 Analog Input Option Board Unit: mm 0.15 36.4 CP1W-DAB21V Analog Output Option Board Unit: mm 0.15 36.4 CP1E CPU Unit Hardware User’s Manual(W479)
Appendices A-1-3 Expansion I/O Units CP1W-8ED Expansion I/O Unit with 8 Input Points Unit: mm 100±0.2 56±0.2 2-φ4.5 CP1W-8E Expansion I/O Units with 8 Output Points Unit: mm 90 100±0.2 56±0.2 2-φ4.5 CP1W-16E Expansion I/O Units with 16 Output Points Unit: mm 90 100±0.2 76±0.2...
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Appendices CP1W-32ER/ET/ET1 Expansion I/O Units with 32 Output Points Unit: mm 110 100 90 4-φ4.5 CP1W-20ED Expansion I/O Units with 20 I/O Points Unit: mm 90 100±0.2 76±0.2 2-φ4.5 CP1W-40ED Expansion I/O Units with 40 I/O Points Unit: mm 110 100 90 4-φ4.5 CP1E CPU Unit Hardware User’s Manual(W479)
Appendices A-1-4 Expansion Units CP1W-MAD11/MAD42/MAD44 Analog I/O Units Unit: mm 90 100±0.2 76±0.2 2-φ4.5 CP1W-AD041/AD042 Analog Input Unit Unit: mm 90 100±0.2 76±0.2 2-φ4.5 CP1W-DA021/DA041/DA042 Analog Output Unit Unit: mm 90 100±0.2 76±0.2 2-φ4.5 A-10 CP1E CPU Unit Hardware User’s Manual(W479)
Appendices CP1W-TS1/2/3 Temperature Sensor Units Unit: mm 100±0.2 76±0.2 CP1W-TS004 Temperature Sensor Units Unit: mm 90 100±0.2 Two,4.5 dia. 140 ± 0.2 140 ± 0.2 holes CP1W-SRT21 CompoBus/S I/O Link Unit Unit: mm 90 100±0.2 56±0.2 2-φ4.5 CP1E CPU Unit Hardware User’s Manual(W479) A-11...
Appendices Wiring Diagrams A-2-1 CPU Units CPU Unit with 10 I/O Points (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram All Models Relay Outputs AC Power Supply CP1E-E10DR- CP1E-E10D-A CIO 100 DC Power Supply CP1E-E10D-D CIO 0 COM COM NC COM NC 24V DC...
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Appendices CPU Unit with 14 I/O Points (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram All Models Relay Outputs AC Power Supply CP1E-E14DR-A/E14SDR-A CP1E-E14DR-A/E14SDR-A CP1E-N14DR- CP1E-N14D-A CIO 100 DC Power Supply CP1E-N14D-D CIO 0 COM COM NC COM NC COM NC 24V DC L1 L2/N COM 01 CIO 100...
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Appendices CPU Unit with 20 I/O Points (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram All Models Relay Outputs AC Power Supply CP1E-E20DR-A/E20SDR-A CP1E-E20DR-A/E20SDR-A CP1E-N20DR- CP1E-N20D-A CIO 100 DC Power Supply CP1E-N20D-D CIO 0 COM COM NC COM NC COM 06 24V DC L1 L2/N COM 01 CIO 100...
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Appendices CPU Units with 30 I/O Points (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram All Models Relay Outputs AC Power Supply CP1E-30DR-/30SDR-A CP1E-E30DR-A/E30SDR-A CIO 100 CIO 101 CP1E-N30D-A/N30S(1)D-A DC Power Supply CP1E-N30D-D/N30S(1)D-D CIO 0 CIO 1 COM COM COM 03 COM 06 COM 01...
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Appendices CPU Units with 40 I/O Points (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram All Models Relay Outputs AC Power Supply CP1E-40DR-/40SDR-A CP1E-E40DR-A/E40SDR-A CIO 100 CIO 101 CP1E-N40D-A/N40S(1)D-A DC Power Supply CP1E-N40D-D/N40S(1)D-D CIO 0 CIO 1 COM COM COM COM 05 07 COM 02 COM 05...
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Appendices CPU Units with 60 I/O Points (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram All Models Relay Outputs AC Power Supply CP1E-N60DR-/60SDR-A CIO 100 CIO 101 CIO 102 CP1E-E60SDR-A CP1E-N60D-A/N60S(1)D-A DC Power Supply COM COM COM COM 06 CP1E-N60D-D/N60S(1)D-D CIO 0...
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Appendices CPU Units with Built-in Analog and 20 I/O Points (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram All Models Relay Outputs AC Power Supply CP1E-NA20DR-A CP1E-NA20D-A CIO 100 DC Power Supply CIO 190 CP1E-NA20D-D Analog Output CIO 0 NC I OUT0...
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Appendices Analog Input Wiring Diagram Analog Output Wiring Diagram Analog Analog V IN V OUT Analog Analog input output Output Input I OUT device device Terminal Terminal − − (voltage (voltage Block Block input) output) Voltage Input Voltage Output Analog Analog V IN V OUT...
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Appendices Input Wiring Example When Using External Power Supply AC-power-supply E30/40/60(S), N30/40/60(S) or NA20 CPU Units have an external power supply (DC24V 0.3A), and can be used as a service power supply for input devices. DC-power-supply E10/14/20(S) or N14/20 CPU Units have no external power supply. Wiring Example: AC-power-supply CPU Units with 40 I/O Points Input device L2/N...
Appendices A-2-2 Expansion I/O Units The first input word allocated to the Expansion I/O Unit is shown as CIO m and the first output word is shown as CIO n. 8-point Input Unit (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram Outputs not provided.
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Appendices Input Wiring Diagram Output Wiring Diagram Transistor Outputs (Sinking) Inputs not provided. CP1W-8ET Unit Upper Terminal Block Unit Lower Terminal Block 4.5 to 30 VDC CIO n 4.5 to 30 VDC Transistor Outputs (Sourcing) CP1W-8ET1 Unit Upper Terminal Block Unit Lower Terminal Block 4.5 to 30 VDC CIO n...
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Appendices Input Wiring Diagram Output Wiring Diagram Inputs not provided. Unit Lower Terminal Block CIO n+1 Transistor Outputs (Sinking) CP1W-16ET Unit Upper Terminal Block COM COM COM CIO n Unit Lower Terminal Block CIO n+1 Transistor Outputs (Sourcing) CP1W-16ET1 Unit Upper Terminal Block COM COM COM...
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Appendices Input Wiring Diagram Output Wiring Diagram Inputs not provided. Unit Lower Terminal Block CIO n+1 32-point Output Units (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram Relay Outputs Inputs not provided. CP1W-32ER Unit Upper Terminal Block CIO n+1 CIO n COM COM...
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Appendices Input Wiring Diagram Output Wiring Diagram Transistor Outputs (Sinking) Inputs not provided. CP1W-32ET Unit Upper Terminal Block CIO n CIO n+1 COM COM COM COM CIO n CIO n+1 Unit Lower Terminal Block CIO n+2 CIO n+3 COM COM COM CIO n+2 CIO n+3 ...
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Appendices Input Wiring Diagram Output Wiring Diagram Inputs not provided. Unit Lower Terminal Block CIO n+2 CIO n+3 CIO n+2 CIO n+3 20-point I/O Units (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram All Models Relay Outputs CP1W-20EDR1 CIO m 24V DC...
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Appendices Input Wiring Diagram Output Wiring Diagram Transistor Outputs (Sourcing) CP1W-20EDT1 CIO n 40-point I/O Units (Terminal Block is not removable) Input Wiring Diagram Output Wiring Diagram All Models Relay Outputs CP1W-40EDR CIO m CIO m+1 CIO n CIO n+1 24V DC NC 00...
Appendices A-2-3 Expansion Units CP1W-AD041/AD042 Analog Input Unit (Terminal Block is not removable) Wiring Diagrams Input Terminal Arrangement V IN1 Voltage input 1 I IN1 Current input 1 COM1 Input common 1 V IN2 Voltage input 2 I IN2 Current input 2 COM2 Input common 2...
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Appendices CP1W-DA021 Analog Output Unit (Terminal Block is not removable) Wiring Diagrams Output Terminal Arrangement V OUT1 Voltage output 1 I OUT1 Current output 1 I OUT1 VOUT2 COM2 COM1 Output common 1 VOUT1 COM1 I OUT2 V OUT2 Voltage output 2 I OUT2 Current output 2...
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Appendices CP1W-DA041/DA042 Analog Output Unit (Terminal Block is not removable) Wiring Diagrams Output Terminal Arrangement V OUT1 Voltage output 1 I OUT1 Current output 1 COM1 Output common 1 V OUT2 Voltage output 2 I OUT2 Current output 2 COM2 Output common 2 V OUT3...
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Appendices CP1W-MAD11 Analog I/O Unit (Terminal Block is not removable) Wiring Diagrams I/O Terminal Arrangement V OUT Voltage output I OUT Current output Output common V IN0 Voltage input 0 I IN0 Current input 0 COM0 Input common 0 V IN1 Voltage input 1 I IN1...
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Appendices Wiring Diagrams Example: I OUT V IN0 COM0 IIN1 VOUT I IN0 V IN1 COM1 Connection to input for voltage output Voltage input – Connection to input 0 for voltage input Voltage output – Connection to input 1 for current input Current output –...
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Appendices CP1W-MAD42 Analog I/O Unit (Terminal Block is not removable) Wiring Diagrams I/O Terminal Arrangement • Input Terminal Arrangement V IN1 Voltage input 1 I IN1 Current input 1 COM1 Input common 1 V IN2 Voltage input 2 I IN2 Current input 2 COM2 Input common 2...
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Appendices CP1W-MAD44 Analog I/O Unit (Terminal Block is not removable) Wiring Diagrams I/O Terminal Arrangement • Input Terminal Arrangement V IN1 Voltage input 1 I IN1 Current input 1 COM1 Input common 1 V IN2 Voltage input 2 I IN2 Current input 2 COM2 Input common 2...
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Appendices CP1W-TS001/TS002/TS101/TS102 Temperature Sensor Units (Terminal Block is not removable) Wiring Diagrams Connecting a Thermocouple • CP1W-TS001 One or two K or J thermocouples can be connected to the CP1W-TS001. Both of the thermocouples must be of the same type and the same input range must be used for each.
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Appendices Wiring Diagrams Connecting a Platinum Resistance Thermometer • CP1W-TS101 One or two Pt or JPt platinum resistance thermometers can be connected to the CP1W-TS101. Both of the thermometers must be of the same type and the same input range must be used for each.
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Appendices CP1W-TS003 Temperature Sensor Units (Terminal Block is not removable) Wiring Diagrams Connecting a Thermocouple Either K or J thermocouples can be connected, but all four of the thermocouples must be of the same type and the same input range must be used for each. Only last two channels can be used as analog inputs.
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Appendices CP1W-TS004 Temperature Sensor Units (Terminal Block is not removable) Wiring Diagrams Connecting a Thermocouple Either K or J thermocouples can be connected, but all twelve of the thermocouples must be of the same type and the same input range must be used for each. Example: Temperature input 1 Cold junction...
Wiring Examples for PTs Using NT Link Connecting a PT and a PLC 1:1 with RS-232C Ports • Communications Mode: 1:N NT Link, N = 1 only • OMRON Cables with Connectors: XW2Z-200T (2 m) XW2Z-500T (5 m) CP1E N/NA-type CPU Unit...
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No-protocol Communications Connecting RS-232C Ports 1:1 • Communications Mode: No-protocol Example: Connections to E5CK Controller CP1E N/NA (S)-type CPU Unit Built-in RS-232C Port or RS-232C Example: OMRON E5CK Controller Option Board RS-232C RS-232C: Terminal block Signal shielded cable Terminal...
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Appendices Connecting RS-422A/485 Ports 1:1 with 4-wire Connections • Communications Mode: No-protocol Device supporting RS-422A/485 communications CP1E N/NA -type CPU Unit Signal Signal SDA- RS-422A/485 RS-422A/485 Option Board SDB+ interface RDA- RDB+ Terminal block 4-wire Terminating resistance: Device supporting RS-422A/485 communications NT-AL001...
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Appendices Serial PLC Links • Communications mode: Serial PLC Link (Master) or Serial PLC Link (Slave) Connection with RS-232C Ports RS-232C connection is also possible when using a Serial PLC Link to connect two CP1E N/NA(S)- type CPU Units. CP1E N/NA (S)-type CPU Unit CP1E N/NA...
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Appendices • Wiring Example Using RS-422A/485 Ports with RS-485, 2-wire Connections CP1E N/NA -type CPU Unit CP1E N/NA -type CPU Unit (Polled Unit No. 0) CJ1M CPU Unit (Polled Unit No. 1) Built-in RS-232C port CJ1W-CIF11 RS-422A Conversion Unit CP1W-CIF11 RS-422A/485 Option Board CJ1W-CIF11 RS-422A Conversion Unit DIP SW DIP SW...
Appendices Wiring for Serial Communications A-3-1 Recommended RS-232C Wiring Recommended RS-232C Wiring We recommend the following wiring method for the RS-232C, especially in environments prone to noise. Use shielded twisted-pair cables for the communications cables. • Recommended RS-232C Cables Model numbers Manufacturer UL2464 AWG28x5P IFS-RVV-SB (UL product) Fujikura Ltd.
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Appendices Note The hood (FG) is internally connected to the ground terminal (GR) on the CPU Unit. Therefore, the FG is grounded by grounding the power supply ground terminal (GR). Although there is con- ductivity between the hood (FG) and pin 1 (FG), connect the shield to both the hood and pin 1 to reduce the contact resistance between the shield and FG and thus provide better noise resistance.
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Appendices Shield Not Connected to Hood (FG) Cut the cable to the required length. Remove the specified length of the sheath from the cable using a knife. Be careful not to scratch the braided shield. 25mm (RS-422A) 40mm(RS-232C) Trim off all the braided shield using scissors. Remove the insulation from each conductor using a stripper.
Appendices Return the heat-shrinking tube to the soldered portion, then heat the tube to shrink it in place. Heat-shrinking tube Assembling Connector Hood Assemble the connector hood as shown below. End connected to FG End not connected to FG Aluminum foil tape Grounding plate A-3-2...
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Appendices Terminal Wiring When wiring the Rs-485 terminal block, treat either solid or stranded wires directly. 2-conductor shielded twisted-pair cable Release button • To make the connection, press the release button in with a small flat blade screwdriver and push the line in while the lock is released.
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Appendices Connection Examples 2-Wire and 4-Wire Transmission Circuits The transmission circuits for 2-wire and 4-wire connections are different, as shown in the following diagram. • CP1W-CIF11/12 Example of 4-Wire Connections Example of 2-Wire Connections 2/4-wire switch 2/4-wire switch (DPDT) (DPDT) Other Unit Other Unit...
Appendices • Four-wire Connections CP1E N/NA -type CPU Unit Remote device RS-422A/485 Option Board Signal Signal SDA- SDB+ RDA- RDB+ Shield Ground the shield at one end when using CP1W-CIF12. A-3-3 Converting the Built-in RS-232C Port to RS-422A/485 Use one of the following Conversion Units to convert a built-in RS-232C port to an RS-422A port for a CP1E N/NA-type CPU Unit.
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Appendices * The hood and the connector hood to which it is connected will have the same electrical potential. DIP Switch for Operation Settings Setting Terminating resistance Terminating resistance connected Terminating resistance selection (both ends of transmission path) not connected 2-wire connections 4-wire connections 2-wire or 4-wire selection*...
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Appendices DIP Switch Setting The NT-AL001 RS-232C/RS-422A Conversion Unit has a DIP switch for setting RS-422A/485 communications conditions. When connecting the Serial Communications Option Board, refer to the DIP switch settings shown in the following table. Function Factory setting Not used.
Appendices Wiring for the Recommended Cables (XW2Z-070T-1 or XW2Z-200T-1) Wiring with XW2Z- 0T -1 (10 conductors) SYSMAC PLC NT-AL001 end (inside NT-AL001) Signal Signal *Arrows indicate Not used. signal directions Loopback Loopback Hood Hood Shield * DR and ER signals are not supported by the NS(1)-type CPU Unit. Note The hood (FG) is internally connected to the ground terminal (GR) on the CPU Unit.
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Appendices A-54 CP1E CPU Unit Hardware User’s Manual(W479)
Index Analog Output Unit ..........8-17 CPU Unit ......2-5, 2-6, 2-7, 2-8, 2-9, 2-19 Analog adjuster ............3-3, 3-8 Expansion I/O Unit ..........2-20 Analog adjusters ............3-3 Expansion Unit ............2-20 Analog I/O Unit............2-15, 8-27 Temperature Sensor Unit ........8-57 Dimensions ............A-10 CX-Programmer.............4-2 DIP Switch settings ..........
Revision History A manual revision code appears as a suffix to the catalog number on the front cover of the manual. Cat. No. W479-E1-10 Revision code Revision code Date Revised content March 2009 Original production June 2009 • Information added on CX-Programmer Micro PLC Edition version 8.2 upgrading to version 9.0.
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Revision-2 CP1E CPU Unit Hardware User’s Manual(W479)
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