Related Manuals for Omron C200H-OD212
Summary of Contents for Omron C200H-OD212
- Page 1 C200H Programmable Controllers (CPU01-E/03-E/11-E) Installation Guide Revised January 2001...
- Page 3 C200H (CPU21-E to CPU31-E) W111 Thank you for supporting OMRON products. The circuit specifications have been changed for the following I/O Units. If you are using any of these Units, please check the manufacturing number given on the Unit to confirm specifications before using the Unit.
- Page 4 ■ Special I/O Units ● C200H-OD501 ● C200H-OD215 TTL Output Unit Transistor Output Unit Units manufactured on or after November 14, 2002 Units manufactured on or after October 10, 2002 (manufacturing numbers 14Y2H or later) (manufacturing numbers 10X2H or later) ·...
- Page 5 OMRON. No patent liability is assumed with respect to the use of the information contained herein. Moreover, because OMRON is constantly striving to improve its high-quality products, the information contained in this manual is subject to change without notice.
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Page 7: Table Of Contents
TABLE OF CONTENTS PRECAUTIONS ....... . . 1 Intended Audience ............2 General Precautions . - Page 8 TABLE OF CONTENTS Appendices A Inspection and Maintenance ..........B Specifications .
- Page 9 About this Manual: This manual explains how to install a C-series C200H Programmable Controller (CPU01-E/03-E/11-E). Section 1 is an introduction to Programmable Controllers. General information about what a Programma- ble Controller can do and how a Programmable Controller works is provided. Section 2 provides a description of all the components of the C200H.
- Page 10 PRECAUTIONS This section provides general precautions for using the Programmable Controller (PC) and related devices. The information contained in this section is important for the safe and reliable application of the Programmable Con- troller. You must read this section and understand the information contained before attempting to set up or operate a PC system.
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Page 11: Intended Audience
It is extremely important that a PC and all PC Units be used for the specified purpose and under the specified conditions, especially in applications that can directly or indirectly affect human life. You must consult with your OMRON representative before applying a PC System to the above-mentioned applications. -
Page 12: Operating Environment Precautions
Application Precautions Operating Environment Precautions Caution Do not operate the control system in the following places: Locations subject to direct sunlight. Locations subject to temperatures or humidity outside the range specified in the specifications. Locations subject to condensation as the result of severe changes in tempera- ture. - Page 13 Application Precautions Interlock circuits, limit circuits, and similar safety measures in external circuits (i.e., not in the Programmable Controller) must be provided by the customer. Always use the power supply voltage specified in the operation manuals. An incorrect voltage may result in malfunction or burning. Take appropriate measures to ensure that the specified power with the rated voltage and frequency is supplied.
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Page 14: Introduction
SECTION 1 Introduction This section provides general information about Programmable Controllers (PCs) and how they fit into a Control System. What is a Control System? ..........The Role of the PC . -
Page 15: What Is A Control System
Section What is a Control System? What is a Control System? A Control System is the electronic equipment needed to control a particular process. It may include everything from a process control computer, if one is used, to the factory computer, down through the PCs (and there may be many of them networked together) and then on down through the network to the control components: the switches, stepping motors, solenoids, and sensors which monitor and control the mechanical operations. - Page 16 Section What is a Control System? A Position Control System Input Unit Position Control Unit Signal line for Servomotor driver control Hand-held Programming Console Power source Control panel Control switch DC Servomotor Power Driver source DC Servomotor DC Servomotor Driver DC Servomotor In the typical Control System example shown above, a PC controls the move- ment of the workpiece bed across two horizontal axes using Limit Switches and...
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Page 17: The Role Of The Pc
Section The Role of the PC The Role of the PC The PC is the part of the Control System that directly controls the manufacturing process. According to the program stored in its memory, the PC accepts data from the input devices connected to it, and uses this data to monitor the con- trolled system. - Page 18 Section The Role of the PC 1-2-2 Output Devices A PC can output to a myriad of devices for use in automated control. Almost any- thing that you can think of could be controlled (perhaps indirectly) by a PC. Some of the most common devices are motors, Solenoids, Servomotors, Stepping Motors, valves, switches, indicator lights, buzzers, and alarms.
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Page 19: How Does A Pc Work
Section How Does a PC Work? How Does a PC Work? PCs operate by monitoring input signals and providing output signals. When changes are detected in the signals, the PC reacts, through the user-pro- grammed internal logic, to produce output signals. The PC continually cycles the program in its memory to achieve this control. - Page 20 Section How Does a PC Work? PC Operation Flowchart Power application Clears data areas and resets System counters Initial processing on power Checks I/O Units application Resets watchdog timer Checks hardware and program memory Sets error flag and Check OK? lights indicator Common processes...
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Page 21: Description
SECTION 2 Description This section provides information about the individual Units that make up a PC. The names of all the parts of a Unit are given, followed by any details that apply to that Unit alone. For a description of how the Units fit together to become a PC, refer to Section 3 Assembly Instructions. -
Page 22: Cpu Rack
Section CPU Rack CPU Rack The following figure shows the names of all the parts of a CPU Rack. There are four models of Backplanes available with 3, 5, 8 and 10 slots for I/O Units. You can use any of these Backplanes to build a CPU or Expansion I/O Rack. Howev- er, the C200H-OC225/OD212/OD21A 16-point Output Unit and C200H-B7AO1 B7A Interface Unit must be mounted to a C200H-BC 1-V1/V2 Backplane. -
Page 23: Cpu
Section The CPU is available in three models. The C200H-CPU01-E and C200H- CPU11-E both run on 100 to 120 or 200 to 240 VAC, and the C200H-CPU03-E runs on 24 VDC. The C200H-CPU11-E is unique in that it connects the SYSMAC LINK Unit or SYSMAC NET Link Unit to the CPU. - Page 24 Section C200H-CPU11-E Indicators Power fuse MF51NR (5.2 dia. x 20 mm) 2A 250 V Memory Pack connector Battery compart- ment Bus connector Available only with the C200H-CPU11-E. Handheld Program- Used to connect this ming Console con- Unit to a SYSMAC nector LINK Unit or SYSMAC NET Link Unit.
- Page 25 Section Peripheral Device All three CPU models are equipped with two connectors for peripheral devices. Connectors One is used for the Handheld Programming Console or the Data Access Con- sole; the other is used for the CPU-Mounting Programming Console. The C200H-CPU11-E, however, has a third connector that is used for connecting the SYSMAC LINK Unit or the SYSMAC NET Link Unit to the CPU.
- Page 26 Section If you are using the C200H-CPU11-E, a SYSMAC LINK Unit or a SYSMAC LINK Unit can be mounted to either of the two slots to the left of the CPU. They are then connected to the CPU with the Bus Connector Unit. Peripheral device CPU Rack...
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Page 27: Expansion I/O Rack
Section Expansion I/O Rack Expansion I/O Rack The Backplane used to construct a CPU Rack is also used to construct an Ex- pansion I/O Rack. An Expansion I/O Rack is identical to a CPU Rack, except the CPU has been replaced with a Power Supply. The parts of an Expansion I/O Rack are shown in the following diagram. -
Page 28: Power Supply
Section Power Supply Power Supply The Power Supply used for Expansion I/O Racks is available in two models. One runs on 100 to 120 or 200 to 240 VAC, and the other runs on 24 VDC. AC Power Supply POWER Power fuse 2 A 250 V indicator (green) (5.2-dia. - Page 29 Section Power Supply DC Power Supply POWER Power fuse 5 A 125 V indicator (green) (5.2-dia. x 20) Lights when power is MF51NR supplied to Power Supply 24 VDC Terminals for external connections (See note.) Note The LG and GR terminals are connected internally.
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Page 30: I/O Units
Section I/O Units I/O Units I/O Units come in three shapes: A-shape, B-shape, and E-shape. Refer to Ap- pendix B Specifications for the dimensions of each Unit. A-shape I/O Units I/O Unit lock notch Nameplate I/O indicators Indicate ON/OFF sta- tus of points 10-terminal terminal block B-shape I/O Units... -
Page 31: Memory Units
Section Memory Units E-shape I/O Units I/O Unit lock notch Nameplate I/O indicators Indicate ON/OFF status of points 10-terminal terminal block Memory Units There are three types of Memory Units, having three different types of memory. The three types of memory are EPROM, EEPROM, and RAM. Memory Model Capacity... - Page 32 Section Memory Units EPROM Unit The data that you wish to store in an EPROM Unit must first be written to an EPROM Chip, using the PROM Writer. Then the EPROM Chip must be mounted to the inside of the EPROM Unit. Once this has been done, the data cannot be changed.
- Page 33 Section Memory Units Model Function C200H-CPU01-E/03 25308 Battery failure in RAM Unit C200H-CPU11-E 25308 Battery failure in RAM Unit or AR2404 Battery failure in CPU In the following table, the ON/OFF status of the bits indicate where battery failure took place in the C200H-CPU11-E. For example, when bit 25308 is ON the bat- tery in the CPU failed.
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Page 34: Assembly Instructions
SECTION 3 Assembly Instructions When we speak of a PC, we usually think of it as a single object. But actually even the simplest PCs are usually composed of several different devices. In fact a single PC can be physically spread throughout a building, but we still call it one PC. Mounting the Units . -
Page 35: Mounting The Units
Section Mounting the Units Mounting the Units There is no single Unit that can be said to constitute a Rack PC. To build a Rack PC, we start with a Backplane. The Backplane for the C200H is shown below. C200H Backplane The Backplane is a simple device having two functions. - Page 36 Section Mounting the Units The figure below shows one I/O Unit mounted directly to the left of the CPU. I/O Units are where the control connections are made from the PC to all the vari- ous input devices and output devices. As you can see from the figure above, there is still some space available on the left side of the Backplane.
- Page 37 Section Mounting the Units This Backplane has I/O Units mounted to it, but it has no CPU of its own. The additional Backplane must also have an Expansion I/O Power Supply mounted to its rightmost position. This configuration of additional Backplane, Expansion I/O Power Supply, and I/O Units is called an Expansion I/O Rack.
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Page 38: Memory Packs
Section Memory Packs Memory Packs The CPU has a removable Memory Pack that stores the user program. Memory Packs are available with three types of memory; EPROM, EEPROM, and RAM (refer to Section 2-6 Memory Packs ). If this is your first C200H, then you must have a RAM Pack in order to write and test the program you are going to use. - Page 39 Section Memory Packs 4. On the printed circuit board there is a socket for the EPROM Chip. On the socket you will find a notch. Align the notch on the socket with the notch on the EPROM Chip and mount the EPROM Chip to the socket as shown be- low.
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Page 40: System Configurations
Section System Configurations How to Mount the Mount the Memory Pack to the CPU by following the steps below. Memory Pack to the CPU 1, 2, 3... 1. Turn OFF the power to the PC. Caution Do not attempt to mount the Memory Pack to the CPU while the power to the PC is ON. - Page 41 Section System Configurations Host Link Unit and Special I/O Units I/O Units Memory Packs Remote I/O Master Unit Up to ten Special I/O Up to two Units can be I/O Units available with 5, 8, RAM, EPROM, or EE- Units can be mounted. mounted.
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Page 42: System Connections
SECTION 4 System Connections In the preceding sections we have covered what all the parts of a PC are and how they should be assembled. This section provides detailed information about the types of considerations involved in making all of the PC connections. Also included in this section are considerations that should be kept in mind when using the C200H-CPU11-E as the CPU. -
Page 43: Ir Word Allocation
Section IR Word Allocation IR Word Allocation Each slot of the Backplane is assigned a hardware word number. This word is accessible for I/O use only in the given slot. However, standard I/O Units are available in 5-, 8-, 12-, and 16-point models. If an I/O Unit other than a 16-point model is mounted, the unused points of that word are accessible only as “work bits”... - Page 44 Section IR Word Allocation The CPU Rack begins with word 000 at the leftmost slot. The first Expansion I/O Rack begins with word 010, and the second Expansion I/O Rack with word 020. The first word of each Rack is fixed, regardless of the model of Backplane used. As with the I/O bits unused by individual I/O Units, the bits of the I/O words un- used by a Backplane can be used as work bits.
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Page 45: Remote I/O
Section Remote I/O The following figure shows the word allocation for a fully expanded C200H with three 8-slot Backplanes. word word word word word word word word word word word word word word word word Power Supply word word word word word word... -
Page 46: Maximum Current And Power Supplied
Section Maximum Current and Power Supplied In addition, when PC Link Units are used, a maximum of ten Special I/O Units and PC Link Units total can be mounted to one Expanded PC. When a High-den- sity I/O Unit is mounted to a Remote I/O Slave Rack, the RM001-PV1 or RM201 Remote I/O Master Unit must be used. - Page 47 C200H-IM211 C200H-IM212 Contact Output C200H-OC221 C200H-OC222 C200H-OC223 C200H-OC224 C200H-OC225 0.05 A Transistor Output C200H-OD411 0.14 A C200H-OD211 0.16 A C200H-OD212 0.18 A C200H-OD213 0.14 A C200H-OD214 C200H-OD216 0.01 A each C200H-OD217 C200H-OD21A 0.16 A Triac Output C200H-OA121-E 0.14 A C200H-OA122-E 0.18 A...
- Page 48 Section Maximum Current and Power Supplied Unit Model number Current consumption SYSMAC NET Link Unit C200HS-SNT32 1.0 A Feed Adapter C200H-APS01/ASP02 TTL Input C200H-ID501 0.13 A DC Input C200H-ID215 TTL Output C200H-OD501 0.22 A Transistor Output C200H-OD215 TTL I/O C200H-MD501 0.18 A DC Input/Transistor C200H-MD115...
- Page 49 Section Maximum Current and Power Supplied Note *With all eight bits on simultaneously. Current Drawn from 24-V Unit Model number Current Supply consumption No-Voltage Contact C200H-ID001/ID002 0.06 A Input Units Calculation Examples The total power consumption for each Rack can be obtained from the following formulas: Total power consumption for each Unit + 7 (8) CPU Rack =...
- Page 50 Section Maximum Current and Power Supplied High-density and Mixed I/O Units (MD215): Current for MD215: 0.3 A Example 4 Assume that the following Units are mounted to a rack to which is mounted the C200H-CPU11-E. The following table shows how the total power consumption is calculated.
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Page 51: I/O Connections
Section I/O Connections I/O Connections Connect the I/O Devices to the I/O Units using AWG 22 (cross-sectional area of 0.3 mm ) for 19-terminal terminal blocks and AWG 22 to 18 lead wire (cross-sec- tional area of 0.3 to 0.75 mm ) for 10 terminal terminal blocks. - Page 52 Section I/O Connections I/O Unit Cover A C200H-COV11 Cover is provided as an I/O Unit cover for Units that use 10P terminal block connectors. After the I/O wiring has been completed, slide the cover up from the bottom, as shown in the illustration below. Attach Remove I/O Unit cover...
- Page 53 Section I/O Connections DC Input Units Contact output DC input When using the configuration shown below, the sensor and Input Unit should receive their power from the same supply. NPN current output Current regulator DC input Output Sensor 7 mA Power Supply NPN open-collector output...
- Page 54 Section I/O Connections AC Input Units Contact output AC input AC Switching AC input Prox. switch main circuit Caution When using Reed switch as the input contacts for AC Input Units, be sure the allowable current of the switch is at least 1 A. Using switches with lower capaci- ties may cause the contacts to fuse due to surge current.
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Page 55: Installation Environment
SECTION 5 Installation Environment This section details the necessary environment and conditions for installation of the PC. For specific instructions on mounting Units and wiring for I/O and power, refer to Section 2-4 Power Supply and Section 3-3 System Configurations. Installation Environment . - Page 56 Section Installation Environment Installation Environment This section details the necessary environmental conditions for installing the Caution Static electricity can damage PC components. Your body can carry an electro- static charge, especially when the humidity is low. Before touching the PC, be sure to first touch a grounded metallic object, such as a metal water pipe, in order to discharge any static build-up.
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Page 57: Mounting Requirements
(refer to Appendix B Specifications ). If you want to mount the PC on DIN Rail, you can order a DIN Rail from OMRON (refer to Ap- pendix B Standard Models ). DIN Rails come in the two heights shown below. - Page 58 Section Mounting Requirements DIN Rail Mounting The DIN Rail Mounting Bracket shown below is necessary for mounting the PC Bracket to the DIN Rail. Procedure 1, 2, 3... 1. The following diagram is a view of the back of the Backplane. Attach one Mounting Bracket to the left and right sides of the Backplane as shown be- low.
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Page 59: Duct Work
Section Duct Work 3. Loosen the screws attaching the Mounting Brackets to the Backplane. Slide the Backplane upward as shown below so that the Mounting Bracket and Backplane clamp securely onto the DIN Rail. Tighten the screws. DIN Rail Mounting Bracket DIN Rail Hold-down bracket Slide this screw to the top of the... -
Page 60: Preventing Noise
Section Preventing Noise If the I/O wiring and power cables must be placed in the same duct (for example, where they are connected to the equipment), they must be shielded from each other using grounded metal plates. Metal plate (iron) 200 mm min. -
Page 61: Power Considerations
SECTION 6 Power Considerations Use a commercially available 100 to 120 VAC, 200 to 240 VAC, or 24 VDC power source, according to the model of PC you are using (refer to Appendix B Specifications). Expansion I/O Racks, if used, must also be connected to the power source. If possible, use independent power sources for the PC, input devices, and output devices. -
Page 62: Grounding
Section Emergency Stop Grounding The Line Ground (LG) terminal is a noise-filtered neutral terminal that does not normally require grounding. If electrical noise is a problem, however, this termi- nal should be connected to the Ground (GR) terminal. To avoid electrical shock, attach a grounded (earth ground) AWG 14 wire (cross- sectional area of at least 2 mm ) to the GR terminal. -
Page 63: Wiring
Section Wiring Power Failure A sequential circuit is built into the PC to handle power interruptions. This circuit prevents malfunctions due to momentary power loss or voltage drops. A timing diagram for the operation of this circuit is shown below. The PC ignores all momentary power failures if the interruption lasts no longer than 10 ms. - Page 64 Section Wiring Caution Tighten the AC Power Supply terminals on the terminal blocks to the torque of 0.8 N m. Insufficient tightening may cause short-circuiting, malfunction, or burning. C200H-CPU03-E Screw (3.5 mm head with Breaker self-raising pressure plate) Supply 24 VDC Keep voltage fluctuations within the specified range...
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Page 65: Safety Considerations
SECTION 7 Safety Considerations There are certain safety requirements to be considered when installing the PC. Some of these, such as the emergency stop circuit (refer to Section 2-4 Power Supply), are part of the initial wiring. The considerations described below should be kept in mind when operating the PC and when connecting I/O devices to the PC. -
Page 66: Interlock Circuits
Section Wiring Interlock Circuits When the PC controls an operation such as the clockwise and counterclockwise operation of a motor, provide an external interlock such as the one shown below to prevent both the forward and reverse outputs from turning ON at the same time. - Page 67 Section Wiring Output Leakage Current If there is a possibility of leakage current causing a transistor or triac to malfunc- tion, connect a bleeder resistor across the output as shown below. Load power supply Bleeder resistor Determine the value and rating for the bleeder resistor using the following for- mula.
- Page 68 Section Wiring Inductive Load Surge When an inductive load is connected to an I/O Unit, it is necessary to connect a Suppressor surge suppressor or diode in parallel with the load as shown below. This is so that the back EMF generated by the load will be absorbed. Relay Output Unit Triac Output Unit Surge suppressor...
- Page 69 Fuse Specifications (5.2-dia. x 20) Model F indicator (fuse blowout Rating detection circuit) C200H-OD411 5 A 125 V C200H-OD211 C200H-OD212 8 A 125 V C200H-OD213 C200H-OA121-E 5 A 125 V C200H-OA122-E C200H-OA222V 3 A 250 V C200H-OA223 5 A 250 V C200H-OA224 3.15 A 250 V...
- Page 70 Appendix A Inspection and Maintenance 1, 2, 3... 1. Turn OFF the power to the PC. 2. Detach the terminal block by unlocking the lock levers at the top and bottom of the terminal block. 3. While pushing down the lock lever on the Backplane with a screwdriver as shown below, remove the Output Unit.
- Page 71 Appendix A Inspection and Maintenance 3. While pushing down the lock lever on the Backplane with a screwdriver as shown below, remove the Output Unit. 4. Remove the screw from the top of the Unit (Phillips screwdriver). 5. Detach the case from the Unit (flat-blade screwdriver). 6.
- Page 72 Appendix A Inspection and Maintenance OC222 OC223 OC225 7. A Relay puller is provided inside the rear of the case when the Unit is deliv- ered. Use the Relay puller to pull out the Relay as shown below. Insert a new Relay.
- Page 73 Appendix A Inspection and Maintenance Batteries Some RAM Packs use a battery (refer to Appendix B for specifications). When the battery is nearly discharged, the ALARM indicator blinks and the message “BATT FAIL” appears on the Programming Console. When this occurs, replace the battery within one week to avoid loss of data.
- Page 74 Appendix B Specifications The following series of figures and tables provides a complete set of specifications for each Unit of the C200H. Note that I/O Units may take on one of three different shapes. Thus I/O Units are sometimes referred to as A-shape I/O Units, B-shape, or E-shape I/O Units.
- Page 75 Appendix B Specifications CPU Specifications Main Control Element MPU, CMOS, LS-TTL Programming Method Ladder diagram Instruction Length 1 address/instruction, 1 to 4 words/instruction Number of Instructions 145 (12 basic instructions + 133 special instructions) C200H-CPU11 159 (12 basic instructions + 147 special instructions) Basic instructions: 0.75 to 2.25 ms Special instructions: 34 to 724 ms Execution Time...
- Page 76 Appendix B Specifications AC Input Unit C200H-IA121 Rated Input Voltage 100 to 120 VAC 50/60 Hz Operating Input Voltage 85 to 132 VAC 50/60 Hz Input Impedance 9.7 k (50 Hz), 8 k (60 Hz) Input Current 10 mA typical (at 100 VAC) ON Voltage 60 VAC min.
- Page 77 Appendix B Specifications AC Input Unit C200H-IA122/IA122V Rated Input Voltage 100 to 120 VAC 50/60 Hz Operating Input Voltage 85 to 132 VAC 50/60 Hz Input Impedance 9.7 k (50 Hz), 8 k (60 Hz) Input Current 10 mA typical (at 100 VAC) ON Voltage 60 VAC min.
- Page 78 Appendix B Specifications AC Input Unit C200H-IA221 Rated Input Voltage 200 to 240 VAC 50/60 Hz Operating Input Voltage 170 to 264 VAC 50/60 Hz Input Impedance 21 k (50 Hz), 18 k (60 Hz) Input Current 10 mA typical (at 200 VAC) ON Voltage 120 VAC min.
- Page 79 Appendix B Specifications AC Input Unit C200H-IA222/IA222V Rated Input Voltage 200 to 240 VAC 50/60 Hz Operating Input Voltage 170 to 264 VAC 50/60 Hz Input Impedance 21 k (50 Hz), 18 k (60 Hz) Input Current 10 mA typical (at 200 VAC) ON Voltage 120 VAC min.
- Page 80 Appendix B Specifications No-Voltage Contact Input Unit C200H-ID001 Input Voltage No-voltage contact/NPN output type (negative common) Input Impedance Input Current 7 mA typical ON Voltage (14.4 VDC min.) OFF Voltage (5.0 VDC max.) ON Response Time 1.5 ms max. (no-voltage contact, at 25 C) OFF Response Time 1.5 ms max.
- Page 81 Appendix B Specifications No-Voltage Contact Input Unit C200H-ID002 Input Voltage No-voltage contact/NPN output type (positive common) Input Impedance Input Current 7 mA typical ON Voltage (14.4 VDC min.) OFF Voltage (5.0 VDC max.) ON Response Time 1.5 ms max. (no-voltage contact, at 25 C) OFF Response Time 1.5 ms max.
- Page 82 Appendix B Specifications DC Input Unit C200H-ID211 Rated Input Voltage 12 to 24 VDC Operating Input Voltage 10.2 to 26.4 VDC Input Impedance Input Current 10 mA (at 24 VDC) ON Voltage 10.2 VDC min. OFF Voltage 3.0 VDC max. ON Response Time 1.5 ms max.
- Page 83 Appendix B Specifications DC Input Unit C200H-ID212 Rated Input Voltage 24 VDC Operating Input Voltage 20.4 to 26.4 VDC Input Impedance Input Current 7 mA (at 24 VDC) ON Voltage 14.4 VDC min. OFF Voltage 5.0 VDC max. ON Response Time 1.5 ms max.
- Page 84 Appendix B Specifications AC/DC Input Unit C200H-IM211 Rated Input Voltage 12 to 24 VDC Operating Input Voltage 10.2 to 26.4 VDC Input Impedance Input Current 10 mA typical (at 24 VDC) ON Voltage 10.2 VDC min. OFF Voltage 3.0 VDC max. ON Response Time 15 ms max.
- Page 85 Appendix B Specifications AC/DC Input Unit C200H-IM212 Rated Input Voltage 24 VDC Operating Input Voltage 20.4 to 26.4 VDC Input Impedance Input Current 7 mA typical (at 24 VDC) ON Voltage 14.4 VDC min. OFF Voltage 5.0 VDC max. ON Response Time 1.5 ms max.
- Page 86 Appendix B Specifications Triac Output Unit C200H-OA222V Max. Switching Capacity 0.3 A 250 VAC, 50/60 Hz (2 A/Unit) Min. Switching Capacity 10 mA (resistive load)/40 mA (inductive load) 10 VAC Leakage Current 3 mA (100 VAC) max./6 mA (200 VAC) max. Residual Voltage 1.2 V max.
- Page 87 Appendix B Specifications Triac Output Unit C200H-OA121-E Max. switching capacity 1 A 120 VAC, 50/60 Hz (4 A/Unit) Min. switching capacity 10 mA (resistive load)/40 mA (inductive load) 10 VAC Leakage Current 3 mA (100 VAC) max. Residual Voltage 1.2 V max. ON Response Time 1 ms max.
- Page 88 Appendix B Specifications Triac Output Unit C200H-OA122-E Max. Switching Capacity 1.2 A 120 VAC, 50/60 Hz (4 A/Unit) Max. Inrush Current 15 A (pulse width: 100 ms) 30 A (pulse width: 10 ms) Min. Switching Capacity 100 mA 10 VAC/50 mA 24 VAC/10 mA 100 VAC min.
- Page 89 Appendix B Specifications Triac Output Unit C200H-OA223 Max. Switching Capacity 1.2 A 250 VAC, 50/60 Hz (4 A/Unit) Max. Inrush Current 15 A (pulse width: 100 ms) 30 A (pulse width: 10 ms) Min. Switching Capacity 100 mA 10 VAC/50 mA 24 VAC/10 mA 100 VAC min.
- Page 90 Appendix B Specifications Triac Output Unit C200H-OA224 Max. Switching Capacity 0.5 A 250 VAC, 50/60 Hz (2 A/Unit) Max. Inrush Current 10 A (pulse width: 100ms) 20 A (pulse width: 10 ms) Min. Switching Capacity 100 mA 10 VAC/50 mA 24 VAC/10 mA 100 VAC min.
- Page 91 Appendix B Specifications Contact Output Unit C200H-OC221 Max. switching capacity 2 A 250 VAC (cos of phase angle = 1), 2 A 250 VAC (cos of phase angle = 0.4), 2 A 24 VDC 8 A/Unit Min. switching capacity 10 mA 5 VDC Relay G6B-1174P-FD-US (24 VDC) w/socket Service Life of Relay...
- Page 92 Appendix B Specifications Contact Output Unit C200H-OC222 Max. switching capacity 2 A 250 VAC (cos of phase angle = 1), 2 A 250 VAC (cos of phase angle = 0.4), 2 A 24 VDC 8 A/Unit Min. switching capacity 10 mA 5 VDC Relay G6B-1174P-FD-US (24 VDC) w/socket Service Life of Relay...
- Page 93 Appendix B Specifications Contact Output Unit C200H-OC223 Max. switching capacity 2 A 250 VAC (cos of phase angle = 1), 2 A 250 VAC (cos of phase angle = 0.4), 2 A 24 VDC 10 A/Unit Min. switching capacity relay 10 mA 5 VDC Service Life of Relay Electrical: 500,000 operations (resistive load)/...
- Page 94 Appendix B Specifications Contact Output Unit C200H-OC224 Max. switching capacity 2 A 250 VAC (cos of phase angle = 1), 2 A 250 VAC (cos of phase angle = 0.4), 2 A 24 VDC 16 A/Unit Min. switching capacity relay 10 mA 5 VDC Service Life of Relay Electrical: 500,000 operations (resistive load)/...
- Page 95 Appendix B Specifications Contact Output Unit C200H-OC225 Max. switching capacity 2 A 250 VAC (cos of phase angle = 1), 2 A 250 VAC (cos of phase angle = 0.4), 2 A 24 VDC 8 A/Unit Min. switching capacity 10 mA 5 VDC Relay G6B-1174P-FD-US (24 VDC) w/socket Service Life of Relay...
- Page 96 Appendix B Specifications Transistor Output Unit C200H-OD211 +10% Max. switching capacity 0.3 A 24 VDC (2 A/Unit) –15% Min. switching capacity None Leakage Current 0.1 mA max. Residual Voltage 1.4 V max. ON Response Time 0.2 ms max. OFF Response Time 0.3 ms max.
- Page 97 Appendix B Specifications Transistor Output Unit C200H-OD212 +10% Max. switching capacity 0.3 A 24 VDC (4.8 A/Unit) –15% Min. switching capacity None Leakage Current 0.1 mA max. Residual Voltage 1.4 V max. ON Response Time 0.2 ms max. OFF Response Time 0.3 ms max.
- Page 98 Appendix B Specifications Transistor Output Unit C200H-OD213 +10% Max. switching capacity 2.1 A 24 VDC (5.2 A/Unit) NPN output –15% Min. switching capacity None Leakage Current 0.1 mA max. Residual Voltage 1.4 V max. ON Response Time 0.2 ms max. OFF Response Time 0.3 ms max.
- Page 99 Appendix B Specifications Transistor Output Unit C200H-OD214 (Sourcing Type) +10% Max. switching capacity 24 VDC 0.8 A (2.4 A/Unit) surge current –15% 2 A (sourcing type) PNP output Min. switching capacity None Leakage Current 1 mA max. Residual Voltage 1.5 V max. ON Response Time 1 ms max.
- Page 100 Appendix B Specifications C200H-OD214 Short-Circuit Protection The C200H-OD214 Output Unit is equipped with two types of short-circuit pro- tection. One is overcurrent protection, and the other is thermal protection. The short-circuit should be eliminated immediately in order to avoid damage to the Unit.
- Page 101 Appendix B Specifications Programming Example If there is a short-circuit in an output, we want the pro- gram to turn that output OFF. Assume that the Unit is mounted at word 000. A program to turn OFF output bits 00 and 01 is shown below. 00008 00000 00008...
- Page 102 Appendix B Specifications Transistor Output Unit C200H-OD216 Max. switching capacity 0.3 A 5 to 24 VDC Min. switching capacity 10 mA 5 VDC Leakage Current 0.1 mA max. Residual Voltage 1.5 V max. ON Response Time 1.5 ms max. OFF Response Time 2 ms max.
- Page 103 Appendix B Specifications Transistor Output Unit C200H-OD217 Max. switching capacity 0.3 A 5 to 24 VDC Min. switching capacity 10 mA 5 VDC Leakage Current 0.1 mA max. Residual Voltage 1.5 V max. ON Response Time 1.5 ms max. OFF Response Time 2 ms max.
- Page 104 Appendix B Specifications Transistor Output Unit C200H-OD411 Max. switching capacity 12 to 48 VDC 1 A (3 A/Unit) Min. switching capacity None Leakage Current 0.1 mA max. Residual Voltage 1.4 V max. ON Response Time 0.2 ms max. OFF Response Time 0.3 ms max.
- Page 105 Appendix B Specifications Transistor Output Unit C200H-OD21A (Sourcing Type with Load Circuit Protection) +10% Max. switching 24 VDC , 1.0 A (4 A/Unit) No. of Circuits 1 (16 points/common) –15% capacity surge current 1.6 A (sourcing type) PNP output Min. switching None Internal Current 160 mA, 5 VDC max.
- Page 106 Appendix B Specifications Terminal Connections +24 VDC 24 VDC Note 1. When the ALARM output turns ON, remove the cause of the high current and then shut off the external power supply for approx. 1 second. After confirming that the cause has been removed, turn ON the pow- er supply again to reset the output.
- Page 107 Appendix B Specifications Analog Timer Unit Item Specifications Oscillation Method RC oscillation Time Setting Range Use the DIP switch to set any of the following four ranges, according to the chart shown on the next page. 0.1 to 1 second (typical) 1 to 10 seconds (typical) 10 to 60 seconds (typical) 1 to 10 minutes (typical)
- Page 108 Appendix B Specifications Internal variable resistors TM001 Indicators These variable re- The SET indicators in the top row light when the cor- sistors are used to responding timer is operating. The TIME UP indica- set the timers. The tors in the bottom row light when the corresponding settings of these re- timer (T0 through T3) turns ON.
- Page 109 Appendix B Specifications Caution Ensure that the external variable resistor connectors are open when using the internal variable resistor. External variable resistor connector External variable resistor B7A Interface Unit C200H-B7A 1 (Basic I/O Unit Type) The B7A Interface Unit used with the B7A Link Terminal allows the transmission and reception of 16-point I/O data over two wires.
- Page 110 Appendix B Specifications Connection Terminals SIG: Connects to the SIG terminal of the B7A Link Terminal. V–: Connects to the negative power terminal of the B7A Link Terminal. Caution If the terminals are not connected correctly, the internal circuitry of the B7A Link Terminal will be damaged.
- Page 111 Appendix B Specifications Dimensions Racks The dimensions shown below are for both the CPU Rack and Expansion I/O Rack. The C dimension for the Pro- gramming Console will increase by 30mm when the Programming Console Adapter C200H-BP001 is used, and will increase by 50 mm when the Programming Console Adapter C200H-BP002 is used.
- Page 112 Appendix B Specifications Mounted Unit CPU01/03 CPU11 Programming Console Other peripheral devices B-shape I/O Units E-shape I/O Units I/O Units The dimensions shown below are for the three shapes of I/O Units mentioned throughout these specifications. A-shape I/O Units Back- plane B-shape I/O Units Back-...
- Page 113 Appendix B Specifications E-shape I/O Units Backplane Insulation Plates The dimensions shown below are for Backplane Insulation Plates. PC mounting screws Insulation plate mounting screws Four screws with 4-mm diameter Four screws with 5-mm diameter heads are provided. shafts are provided. 118 110 5 dia 12 dia...
- Page 114 Appendix B Specifications I/O Connecting Cables The dimensions shown below are for I/O Connecting Cables. Cable Length (L) C200H-CN311 30 cm C200H-CN711 70 cm C200H-CN221 C200H-CN521 C200H-CN131 10 m...
- Page 115 Appendix C Standard Models The C200H is a Rack-type PC that can be configured many different ways. Here is a series of tables listing the Units available for the C200H, along with a brief description of the Unit and its model number. C200H Racks Name Specifications...
- Page 116 1 A, 12 to 48 VDC C200H-OD411 Unit 12 pts 0.3 A, 24 VDC C200H-OD211 16 pts 0.3 A, 24 VDC C200H-OD212 8 pts 2.1 A, 24 VDC C200H-OD213 8 pts 0.8 A, 24 VDC; sourcing type (PNP); with C200H-OD214 load short protection 8 pts 5 to 24 VDC;...
- Page 117 Appendix C Standard Models C200H Special I/O Units All of the following are classified as Special I/O Units except for the ASCII Unit, which is an Intelligent I/O Unit. Name Specifications Model number High-den- DC Input 32 pts 5 VDC (TTL inputs); with high-speed input function C200H-ID501 sity I/O Units Units...
- Page 118 Appendix C Standard Models Name Specifications Model number Position Control Units 1 axis Pulse output; speeds: 1 to 99,990 pps C200H-NC111 1 axis Directly connectable to servomotor driver; compat- C200H-NC112 ible with line driver; speeds: 1 to 250,000 pps 2 axis 1 to 250000.
- Page 119 Appendix C Standard Models Optional Products Name Specifications Model number I/O Unit Cover Cover for 10-pin terminal block C200H-COV11 Terminal Block Cover Short protection for 10-pin terminal block C200H-COV02 Short protection for 19-pin terminal block C200H-COV03 Connector Cover Protective cover for unused I/O Connecting Cable connectors C500-COV01 Space Unit Used for vacant slots...
- Page 120 Appendix C Standard Models Link Adapters Name Specifications Model no. Link Adapter 3 RS-422 connectors 3G2A9-AL001 3 optical connectors (APF/PCF) 3G2A9-AL002-PE 3 optical connectors (PCF) 3G2A9-AL002-E 1 connector for RS-232C; 2 for RS-422 3G2A9-AL003 1 connector each for APF/PCF, RS-422, and RS-232C 3G2A9-AL004-PE 1 connector each for PCF, RS-422, and RS-232C 3G2A9-AL004-E...
- Page 121 (Must not be subjected to direct sunlight) Crystal Optical Fiber Cable (AGF) AGF stands for “All-Glass Fiber”. Crystal optical fiber cable is not available from OMRON. Cable Length The connectors may be difficult to attach to the cables. Therefore, always leave a little extra length when cutting the cable.
- Page 122 Appendix C Standard Models Peripheral Devices Product Description Model no. Programming Console Vertical, w/backlight 3G2A5-PRO13-E Horizontal, w/backlight 3G2A6-PRO15-E Vertical type, w/backlight (Connecting cable required) C200H-PRO27-E Data Access Console Connecting cable required C200H-DAC01 Programming Console and For vertical type C200H-CN222 Data Access Console Data Access Console C200H-CN422 Connecting Cables...
- Page 123 Appendix C Standard Models SYSMAC LINK Unit/SYSMAC NET Link Unit If you are using any of the Units listed in the table below, they must be mounted to a CPU Rack that uses model C200H-CPU11-E as the CPU. Otherwise, these Units will not operate properly.
- Page 124 Appendix D Programming Console Operation System Operations Operation Mode Key Sequence MON. PROG. Data All PLAY All Clear MONTR Clear RESET [Address] Partial Clear Retained if pressed I/O Table SHIFT Register WRITE I/O Table SHIFT Verify I/O Table SHIFT Read [0-7] [0-7] MONTR...
- Page 125 Appendix D Programming Console Operation Programming Operations Operation Mode Key Sequence MON. PROG. Setting Address [Address] Program Address Read currently displayed Search [Instruction] SRCH SRCH CONT [Address] SHIFT SHIFT SRCH SRCH (AR) Instruction Locate [Instruction] Insert and position in program Instruction then enter Delete...
- Page 126 Appendix D Programming Console Operation Monitoring and Data Change Operations Operation Mode Key Sequence MON. PROG. Monitor CONT [Address] SHIFT SHIFT MONTR SHIFT SHIFT (Monitor Clear) 3 Word Bit/Hex Monitor monitor in progress Forced PLAY Set/Reset MONTR RESET PLAY SHIFT SHIFT RESET Change or Timer/Counter...
- Page 127 Appendix D Programming Console Operation Operation Mode Key Sequence MON. PROG. SV Incre- Timer/Counter ment/ currently displayed Decre- ment, SV Reset [New SW] WRITE 3-Word 3 Word Monitor Change [Data] in progress WRITE Cycle MONTR MONTR Time Read HEX-AS- Word currently CII Display displayed Convert...
- Page 128 Appendix D Programming Console Operation Cassette Tape Operations Mode Operation Key Sequence MON. PROG. [File no.] [Start address] WRITE Cassette Tape Start recording with the [Stop address] SHIFT WRITE Write tape recorder. RESET Wait for about 5 seconds. (Cancel with the CLR key.) [File no.] [Start address] WRITE...
- Page 129 Appendix E Programming Instructions Basic Instructions Name Symbol Function Operand Data Areas Mnemonic Logically ANDs the status of the desig- nated bit with the current execution condi- tion. AND LOAD Logically ANDs the resultant execution None AND LD conditions of the preceding logic blocks. AND NOT Logically ANDs the inverse of the desig- AND NOT...
- Page 130 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic Logically ORs the status of the designated bit with the current execution condition. OR LOAD Logically ORs the resultant execution con- None OR LD ditions of the preceding logic blocks. OR NOT Logically ORs the inverse of the desig- OR NOT...
- Page 131 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic Required at the end of each program. In- None END(01) structions located after END(01) will not be END(01) executed. INTERLOCK If an interlock condition is OFF, all outputs None IL(02) and all timer PVs between the current IL(02)
- Page 132 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic SHIFT REGISTER Creates a bit shift register for data from the St/E: SFT(10) starting word (St) through to the ending word (E). I: input bit; P: shift pulse; R: reset SFT(10) input.
- Page 133 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic REVERSIBLE WORD Creates controls reversible St/E: SHIFT non-synchronous word shift register be- RWS(17) (@)RWS(17) tween St and E. Exchanges the content of (CPU11) a word containing zero with the content of either the preceding or following word, de- pending on the shift direction.
- Page 134 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic MOVE NOT Transfers the inverse of the data in the (@)MVN(22) source word (S) to destination word (D). MVN(22) BCD-TO-BINARY Converts 4-digit, BCD data in source word (@)BIN(23) (S) into 16-bit binary data, and outputs converted data to result word (R).
- Page 135 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic ROTATE RIGHT Each bit within a single word of data (Wd) (@)ROR(28) is moved one bit to the right, with bit 00 moving to carry (CY), and CY moving to bit ROR(28) COMPLEMENT Inverts bit status of one word (Wd) of data,...
- Page 136 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic LOGICAL OR Logically ORs two 16-bit input words (I1 I1/I2: (@)ORW(35) and I2) and sets the bits in the result word ORW(35) (R) when one or both of the corresponding bits in the input words is/are ON.
- Page 137 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic DISPLAY MESSAGE Displays eight words of ASCII code, start- (@)MSG(46) ing from FM, on the Programming Console or GPC. All eight words must be in the same data area. MSG(46) FM+ 7 ABCD..DP...
- Page 138 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic BINARY ADD Adds the 4-digit augend (Au), 4-digit ad- Au/Ad: (@)ADB(50) dend (Ad), and content of CY and outputs the result to the specified result word (R). ADB(50) BINARY SUBTRACT Subtracts the 4-digit hexadecimal subtra- Mi/Su: (@)SBB(51)
- Page 139 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic DOUBLE BCD ADD Adds two 8-digit values (2 words each) and Au/Ad: (@)ADDL(54) the content of CY, and outputs the result to ADDL(54) the specified result words. All words for any one operand must be in the same data area.
- Page 140 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic DOUBLE BCD DIVIDE Divides the 8-digit BCD dividend by an Dd/Dr: (@)DIVL(57) 8-digit BCD divisor, and outputs the result DIVL(57) to the specified result words. All words for any one operand must be in the same data area.
- Page 141 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic Fetches data from the same numbered bit COLUMN-TO-WORD (C) in 16 consecutive words (where S is the (@)CTW(63) CTW(63) address of the first source word), and (CPU11) creates a 4-digit word by consecutively placing the data in the bits of the destina- tion word, D.
- Page 142 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic BIT COUNTER Counts the number of ON bits in one or (@)BCNT(67) more words (SB is the beginning source BCNT(67) word) and outputs the result to the speci- fied result word (R). N gives the number of words to be counted.
- Page 143 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic Calculates the cosine, or sine of the given VALUE CALCULATE degree value, or determines the y-coordi- (@)VCAL(69) VCAL(69) nate of the given x value in a previously es- (CPU11) tablished line graph.
- Page 144 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic BLOCK TRANSFER Moves the content of several consecutive (@)XFER(70) source words (S gives the address of the XFER(70) starting source word) to consecutive desti- nation words (D is the starting destination word).
- Page 145 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic ONE DIGIT SHIFT LEFT Shifts all data, between the starting word St/E: (@)SLD(74) (St) and ending word (E), one digit (four bits) to the left, writing zero into the right- SLD(74) most digit of the starting word.
- Page 146 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic 7-SEGMENT DECODER Converts hexadecimal values from the (@)SDEC(78) source word (S) into 7-segment display SDEC(78) data. Results are placed in consecutive half-words, starting at the first destination word (D). Di gives digit and destination de- tails.
- Page 147 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic DATA COLLECT Extracts data from the source word and SBs: (@)COLL(81) writes it to the destination word (D). The COLL(81) source word is determined by adding the offset (Of) to the address of the source base word (SBs).
- Page 148 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic REVERSIBLE SHIFT Shifts bits in the specified word or series of St/E/C: REGISTER words either left or right. Starting (St) and SFTR(84) (@)SFTR(84) ending words (E) must be specified. Con- trol word (C) contains shift direction, reset input, and data input.
- Page 149 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic ASCII CONVERT Converts hexadecimal digits from the (@)ASC(86) source word (S) into 8-bit ASCII values, ASC(86) starting at leftmost or rightmost half of the starting destination word (D). The right- most digit of Di designates the first source digit.
- Page 150 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic NETWORK SEND Transfers data from n source words (S is D/C: (@)SEND(90) the starting word) to the destination words (CPU11) SEND(90) (D is the first address) in node N of the spe- cified network (in a SYSMAC LINK or NET Link System).
- Page 151 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic SUBROUTINE START Marks the start of subroutine N. SBN(92) 00 to 99 SBN(92) RETURN Marks the end of a subroutine and returns None RET(93) control to the main program. RET(93) WATCHDOG TIMER Sets the maximum and minimum limits for...
- Page 152 Appendix E Programming Instructions Name Symbol Function Operand Data Areas Mnemonic NETWORK RECEIVE Transfers data from the source words (S is C/D: (@)RECV(98) the first word) from node N of the specified (CPU11) RECV(98) network (in a SYSMAC LINK or NET Link System) to the destination words starting at D.
- Page 153 Glossary ASCII code [A(merican) S(tandard) C(ode for) I(nformation) I(nterchange)] A standard computer code used to facilitate the interchange of information among vari- ous types of data-processing equipment. ASCII Unit An Intelligent I/O Unit. The ASCII Unit has its own CPU and 16 kilobytes of memory.
- Page 154 Glossary data disk Floppy disk used to store information such as programs or I/O tables. The data disk should be used in drive B of the FIT. data link Allows for the connection of up to 32 PCs in a Net Link System where each is contributing information to a common memory area.
- Page 155 Glossary interface An interface is the conceptual boundary between systems or devices and usually involves changes in the way the communicated data is represented. Interface devices such as NSBs perform operations such as changing the coding, format, or speed of data. I/O devices The devices which are connected to the terminals on I/O Units, Special I/O Units, or Intelligent I/O Units.
- Page 156 The arrangement in which Units in a System are connected. This term refers to the conceptual arrangement and wiring together of all the devices needed to comprise the System. In OMRON terminology, system configuration is used to describe the arrangement and connection of the Units comprising a...
- Page 157 Glossary Unit In OMRON PC terminology, the word Unit is capitalized to indicate any prod- uct sold for a PC System. though most of the names of these products end with the word Unit, not all do, e.g., a Remote Terminal is referred to in a col- lective sense as a Unit.
- Page 158 Index Assembly factory computer, backplane, , Fuse connecting cable, CPU and power supply, replacement, CPU, Output, replacement, Expansion I/O Unit, Output Units, I/O Units, mounting the Units, Grounding ground terminal, Backplane, line ground terminal, IR word allocation, , wire, Backplane Insulating Plates, humidity, Battery, Memory Packs, replacement, I/O Devices, connections,...
- Page 159 Index Sequential circuit (for power failure), Noise cables, Servomotor, I/O wiring, servomotor drivers, output devices, servomotors, Output Units, external fuse, Solenoid, Special I/O Units, Remote I/O Slave Rack, static electricity, preventing, stepping motor, system configuration, block diagram, System Configurations, flow chart, Expansion I/O Racks, operation, Host Link Unit,...
- Page 160 October 1990 Revision of text and inclusion of new product information (C200H-CPU11-E, SYS- MAC NET, SYSMAC LINK, C200H-OC225, and C200H-OD212) Corrections to pages: 7, 10, 12, 13, 15, 16, 23, 27, 28, 34 to 39, 61, 63, 64, 82, 85, 94, 97 to 100, 103, 104.
- Page 161 Pages 73 to 76: Specifications for C200H-ID218 and C200H-ID219 DC Input Units added. Page 77: Circuit configuration corrected for C200H-OA121-E. Pages 84, 85: Circuit configurations changed for C200H-OD212 and C200H-OD213. Pages 95, 96: B7A Interface Unit information modified. Page 99: Insulation plate mounting dimensions corrected.