1762-UM001 - Rockwell Automation

1762-UM001 - Rockwell Automation

MicroLogix 1200

Programmable

Controllers

Bulletin 1762 Controllers and

Expansion I/O

User Manual

Important User Information

Solid state equipment has operational characteristics differing from those of electromechanical equipment. Safety Guidelines for the Application, Installation and

Maintenance of Solid State Controls publication SGI-1.1 available from your local

Rockwell Automation sales office or online at http://www.literature.rockwellautomation.com describes some important differences between solid state equipment and hard-wired electromechanical devices. Because of this difference, and also because of the wide variety of uses for solid state equipment, all persons responsible for applying this equipment must satisfy themselves that each intended application of this equipment is acceptable.

In no event will Rockwell Automation, Inc. be responsible or liable for indirect or consequential damages resulting from the use or application of this equipment.

The examples and diagrams in this manual are included solely for illustrative purposes.

Because of the many variables and requirements associated with any particular installation, Rockwell Automation, Inc. cannot assume responsibility or liability for actual use based on the examples and diagrams.

No patent liability is assumed by Rockwell Automation, Inc. with respect to use of information, circuits, equipment, or software described in this manual.

Reproduction of the contents of this manual, in whole or in part, without written permission of Rockwell Automation, Inc. is prohibited.

Throughout this manual we use notes to make you aware of safety considerations.

WARNING

Identifies information about practices or circumstances that can cause an explosion in a hazardous environment, which may lead to personal injury or death, property damage, or economic loss.

IMPORTANT

ATTENTION

Identifies information that is critical for successful application and understanding of the product.

Identifies information about practices or circumstances that can lead to personal injury or death, property damage, or economic loss. Attentions help you:

• identify a hazard

• avoid a hazard

• recognize the consequence

SHOCK HAZARD

Labels may be located on or inside the drive to alert people that dangerous voltage may be present.

BURN HAZARD

Labels may be located on or inside the drive to alert people that surfaces may be dangerous temperatures.

Publication 1762-UM001H-EN-P - June 2015

Summary of Changes

To help you find new and updated information in this release of the manual, we have included change bars as shown to the right of this paragraph.

The table below lists the sections that document new features and additional or updated information on existing features.

For this information:

Updated list of communication cables.

Updated list of warnings for Hazardous

Location considerations

See

1-4, 2-4, 4-4

2-4

Updated list of cables for Cable Selection

Guide.

4-13

Removed catalog 1761-NET-DNI

1-4, Chapter 4

Added Relay Output life to Specifications.

A-3

Added Relay Life Chart to Specifications.

A-4

Firmware Revision History

Features are added to the controllers through firmware upgrades. See the latest release notes, 1762-RN001 , to be sure that your controller’s firmware is at the level you need. Firmware upgrades are not required, except to allow you access to the new features.

1 Publication 1762-UM001H-EN-P - June 2015

Summary of Changes 2

Notes:

Publication 1762-UM001H-EN-P - June 2015

i

Preface

Hardware Overview

Install Your Controller

Table of Contents

Important User Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-2

Firmware Revision History . . . . . . . . . . . . . . . . Summary of Changes-1

Who Should Use This Manual. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . P-1

Purpose of This Manual. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . P-1

Related Documentation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . P-2

Common Techniques Used in This Manual . . . . . . . . . . . . . . . . . . . . P-2

Chapter 1

Hardware Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1

Component Descriptions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-2

MicroLogix 1200 Memory Module and/or Real-time Clock. . . . 1-2

1762 Expansion I/O . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3

Communication Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4

Program the Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4

Communication Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-4

Chapter 2

Required Tools . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1

Agency Certifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1

Compliance to European Union Directives . . . . . . . . . . . . . . . . . . . . 2-2

EMC Directive. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2

Low Voltage Directive. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2

Installation Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-2

Safety Considerations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-3

Hazardous Location Considerations. . . . . . . . . . . . . . . . . . . . . . . 2-3

Disconnect Main Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-5

Safety Circuits. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-5

Power Distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-5

Periodic Tests of Master Control Relay Circuit . . . . . . . . . . . . . . 2-6

Power Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-6

Isolation Transformers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-6

Power Supply Inrush . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-6

Loss of Power Source . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-7

Input States on Power Down . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-7

Other Types of Line Conditions. . . . . . . . . . . . . . . . . . . . . . . . . . 2-7

Prevent Excessive Heat . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-7

Master Control Relay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-8

Use Emergency-Stop Switches . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-9

Schematic (Using IEC Symbols) . . . . . . . . . . . . . . . . . . . . . . . . . 2-10

Schematic (Using ANSI/CSA Symbols). . . . . . . . . . . . . . . . . . . 2-11

Install a Memory Module or Real-time Clock. . . . . . . . . . . . . . . . . . 2-12

Controller Mounting Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-13

Controller and

Expansion I/O Spacing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-13

Mount the Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-14

DIN Rail Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-15

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Table of Contents ii

Wire Your Controller

Communication Connections

Panel Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-16

1762 Expansion I/O Dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . 2-17

Mount 1762

Expansion I/O. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-17

DIN Rail Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-17

Mount on Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-18

Connect Expansion I/O . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-19

Chapter 3

Wire Requirements. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1

Wire without Spade Lugs. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-2

Wire with Spade Lugs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-3

Use Surge Suppressors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-3

Recommended Surge Suppressors . . . . . . . . . . . . . . . . . . . . . . . . 3-5

Ground the Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-6

Wiring Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-7

Terminal Block Layouts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-7

Terminal Groupings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-9

Sinking and Sourcing Wiring Diagrams . . . . . . . . . . . . . . . . . . . . . . 3-12

1762-L24AWA, 1762-L24BWA, 1762-L24BXB, 1762-L24AWAR,

1762-L24BWAR and 1762-L24BXBR Wiring Diagrams . . . . . 3-12

1762-L40AWA, 1762-L40BWA, 1762-L40BXB, 1762-L40AWAR,

1762-L40BWAR and 1762-L40BXBR Wiring Diagrams . . . . . 3-15

Controller I/O Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-17

Minimize Electrical Noise . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-17

Expansion I/O Wiring. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-18

Discrete Wiring Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-18

Analog Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-25

Chapter 4

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1

Supported Communication Protocols. . . . . . . . . . . . . . . . . . . . . . . . . 4-1

Default Communication Configuration . . . . . . . . . . . . . . . . . . . . . . . 4-2

Use the Communications Toggle Push Button . . . . . . . . . . . . . . . . . 4-3

Connect to the RS-232 Port . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-4

Make a DF1 Point-to-Point Connection . . . . . . . . . . . . . . . . . . . 4-5

Use a Modem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-5

Isolated Modem Connection. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-6

Connect to a DF1 Half-duplex Network . . . . . . . . . . . . . . . . . . . 4-8

Connect to a DH-485 Network. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9

Recommended Tools. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-9

DH-485 Communication Cable . . . . . . . . . . . . . . . . . . . . . . . . . 4-10

Connect the Communication Cable to the DH-485 Connector 4-10

Ground and Terminate the DH-485 Network. . . . . . . . . . . . . . 4-12

Connect the AIC+ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-12

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Table of Contents iii

Use Trim Pots

Cable Selection Guide . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-13

Recommended User-supplied Components. . . . . . . . . . . . . . . . 4-15

Safety Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-17

Install and Attach the AIC+ . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-17

Apply Power to the AIC+. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-17

Chapter 5

Trim Pot Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1

Trim Pot Information Function File . . . . . . . . . . . . . . . . . . . . . . 5-2

Error Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2

Use Real-time Clock and Memory

Modules

Chapter 6

Real-time Clock Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1

Removal/Insertion Under Power . . . . . . . . . . . . . . . . . . . . . . . . . 6-1

Write Data to the Real-time Clock . . . . . . . . . . . . . . . . . . . . . . . . 6-2

RTC Battery Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2

Memory Module Operation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-3

User Program and Data Back-up . . . . . . . . . . . . . . . . . . . . . . . . . 6-3

Program Compare . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-4

Data File Download Protection . . . . . . . . . . . . . . . . . . . . . . . . . . 6-4

Memory Module Write Protection . . . . . . . . . . . . . . . . . . . . . . . . 6-4

Removal/Insertion Under Power . . . . . . . . . . . . . . . . . . . . . . . . . 6-4

Specifications

1762 Replacement Parts

Troubleshoot Your System

Appendix A

Controller Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-1

Expansion I/O Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-8

Discrete I/O Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-8

Analog Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-15

Combination Module DC-Input/Relay Output. . . . . . . . . . . . A-23

Appendix B

MicroLogix 1200 RTB Replacement Kit . . . . . . . . . . . . . . . . . . . . . . B-1

Appendix C

Interpret LED Indicators. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . C-1

Normal Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . C-2

Error Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . C-2

Controller Error Recovery Model . . . . . . . . . . . . . . . . . . . . . . . . . . . . C-3

Analog Expansion I/O Diagnostics and Troubleshooting . . . . . . . . C-4

Module Operation and Channel Operation . . . . . . . . . . . . . . . . . C-4

Power-up Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . C-4

Critical and Noncritical Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . C-5

Module Error Definition Table. . . . . . . . . . . . . . . . . . . . . . . . . . . C-5

Error Codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . C-7

Publication 1762-UM001H-EN-P - June 2015

Table of Contents iv

Call Rockwell Automation for Assistance. . . . . . . . . . . . . . . . . . . . . . C-8

Use Control Flash to Upgrade Your

Operating System

Appendix D

Prepare for Upgrade. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D-1

Install ControlFlash Software . . . . . . . . . . . . . . . . . . . . . . . . . . . D-1

Prepare the Controller for Updating. . . . . . . . . . . . . . . . . . . . . . D-2

Sequence of Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D-2

Missing/Corrupt OS LED Pattern . . . . . . . . . . . . . . . . . . . . . . . . . . D-2

Connect to Networks via RS-232

Interface

Appendix E

RS-232 Communication Interface. . . . . . . . . . . . . . . . . . . . . . . . . . . . E-1

DF1 Full-duplex Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-1

DF1 Half-duplex Protocol. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-2

Use Modems with MicroLogix 1200 Programmable Controllers E-3

DH-485 Communication Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . E-5

Devices that use the DH-485 Network . . . . . . . . . . . . . . . . . . . . E-5

Important DH-485 Network Planning Considerations . . . . . . . . E-6

Example DH-485 Connections. . . . . . . . . . . . . . . . . . . . . . . . . . . E-9

Modbus Communication Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . E-12

ASCII . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E-12

System Loading and Heat

Dissipation

Appendix F

System Loading Limitations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-1

System Current Loading Example Calculations (24-point Controller)

F-1

Validate the System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-2

System Loading Worksheet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-4

Current Loading . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-4

System Current Loading Example Calculations (40-point Controller)

F-6

System Loading Worksheet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-8

Current Loading. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-8

Calculating Heat Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F-10

Glossary

Index

Publication 1762-UM001H-EN-P - June 2015

1

Who Should Use This

Manual

Preface

Read this preface to familiarize yourself with the rest of the manual. It provides information concerning:

• who should use this manual

• the purpose of this manual

• related documentation

• conventions used in this manual

Use this manual if you are responsible for designing, installing, programming, or troubleshooting control systems that use MicroLogix 1200 controllers.

You should have a basic understanding of electrical circuitry and familiarity with relay logic. If you do not, obtain the proper training before using this product.

Purpose of This Manual

This manual is a reference guide for MicroLogix 1200 controllers and expansion I/O. It describes the procedures you use to install, wire, and troubleshoot your controller. This manual:

• explains how to install and wire your controllers

• gives you an overview of the MicroLogix 1200 controller system

Refer to publication 1762-RM001, MicroLogix 1200 and 1500 Programmable

Controllers Instruction Set Reference Manual, for the MicroLogix 1200 and

1500 instruction set and for application examples to show the instruction set in use. Refer to your RSLogix 500 programming software user documentation for more information on programming your MicroLogix 1200 controller.

Publication 1762-UM001H-EN-P - June 2015

P-2 Preface

Related Documentation

The following documents contain additional information concerning Rockwell

Automation products. To obtain a copy, contact your local

Rockwell Automation office or distributor.

Resource

MicroLogix 1200 and 1500 Programmable Controllers

Instruction Set Reference Manual, publication

1762-RM001

MicroLogix 1200 Programmable Controllers Installation

Instructions, publication 1762-IN006

Advanced Interface Converter (AIC+) User Manual, publication 1761-UM004

DeviceNet Interface User Manual, publication

1761-UM005

DF1 Protocol and Command Set Reference Manual, publication 1770-6.5.16

Description

Information on the MicroLogix 1200 Controllers instruction set.

Information on mounting and wiring the MicroLogix 1200 Controllers, including a mounting template for easy installation.

A description on how to install and connect an AIC+. This manual also contains information on network wiring.

Information on how to install, configure, and commission a DNI.

Information on DF1 open protocol.

Modbus Protocol Specifications available from www.modbus.org

Allen-Bradley Programmable Controller Grounding and

Wiring Guidelines, publication 1770-4.1

Application Considerations for Solid-State Controls, publication SGI-1.1

Information about the Modbus protocol.

In-depth information on grounding and wiring Allen-Bradley programmable controllers.

A description of important differences between solid-state programmable controller products and hard-wired electromechanical devices.

National Electrical Code - Published by the National Fire

Protection Association of Boston, MA.

An article on wire sizes and types for grounding electrical equipment.

Allen-Bradley Industrial Automation Glossary, publication AG-7.1

A glossary of industrial automation terms and abbreviations.

Common Techniques Used in This Manual

The following conventions are used throughout this manual:

Bulleted lists such as this one provide information, not procedural steps.

Numbered lists provide sequential steps or hierarchical information.

Publication 1762-UM001H-EN-P - June 2015

Chapter

1

Hardware Overview

1

Hardware Features

12

Side View

The Bulletin 1762, MicroLogix 1200 programmable controller contains a power supply, input and output circuits, and a processor. The controller is available in 24 I/O and 40 I/O configurations.

Figure 1.1 Hardware Features of the Controller

Top View

7

6

10

8

2

5

0

1

COM

9

7

4

3

11

1

Table 1.1 Hardware Features

3

4

Feature Description

1 Terminal Blocks

(Removable Terminal Blocks on 40-point controllers only.)

2 Bus Connector Interface to Expansion I/O

Input LEDs

Output LEDs

5

Feature Description

7 Terminal Doors and Labels

8

9

10

11

Trim Pots

Communications Toggle Push Button

Memory Module Port Cover

(1)

-or-

Memory Module and/or Real-Time Clock

(2)

DIN Rail Latches

6

Communication Port/

Channel 0

Status LEDs 12 Programmer/HMI Port

(Equipped with 1762-LxxxxxR controllers only)

(1) Shipped with controller.

(2) Optional equipment.

Publication 1762-UM001H-EN-P - June 2015

1-2 Hardware Overview

Table 1.2 Controller Input Power and Embedded I/O

Catalog Number

1762-L24AWA, 1762-L24AWAR

1762-L24BWA, 1762-L24BWAR

Description

Input Power

120/240V ac

120/240V ac

1762-L24BXB, 1762-L24BXBR

1762-L40AWA, 1762-L40AWAR

1762-L40BWA, 1762-L40BWAR

1762-L40BXB, 1762-L40BXBR

24V dc

120/240V ac

120/240V ac

24V dc

Inputs

(14) 120V ac

(10) 24V dc

(4) fast 24V dc

(10) 24V dc

(4) fast 24V dc

(24) 120V ac

(20) 24V dc

(4) fast 24V dc

(20) 24V dc

(4) fast 24V dc

Outputs

(10) relay

(10) relay

(5) relay, (4) 24V dc FET

(1) high-speed 24V dc FET

(16) relay

(16) relay

(8) relay, (7) 24V dc FET

(1) high-speed 24V dc FET

Component Descriptions

These sections provide component descriptions for:

MicroLogix 1200 Memory Module and/or Real-time Clock

1762 Expansion I/O

MicroLogix 1200 Memory Module and/or Real-time Clock

The controller is shipped with a memory module port cover in place. You can order a memory module, real-time clock, or memory module and real-time clock as an accessory.

Publication 1762-UM001H-EN-P - June 2015

Table 1.3 Memory Module and/or Real-time Clock

Catalog Number Description

1762-MM1

1762-RTC

1762-MM1RTC

Memory Module only

Real-time Clock only

Memory Module and Real-Time Clock

Hardware Overview 1-3

1762 Expansion I/O

1762 expansion I/O can be connected to the MicroLogix 1200 controller, as shown below.

1762 Expansion I/O 1762 Expansion I/O Connected to MicroLogix 1200 Controller

TIP

A maximum of six I/O modules, in certain combinations,

may be connected to a controller. See Appendix F, System

Loading and Heat Dissipation, to determine valid

combinations.

Table 1.4 Expansion I/O

Catalog Number

1762-IA8

1762-IQ8

1762-IQ16

1762-IQ32T

1762-OA8

1762-OB8

1762-OB16

1762-OB32T

1762-OV32T

1762-OW8

1762-OW16

1762-OX6I

1762-IF2OF2

1762-IF4

1762-OF4

1762-IR4

1762-IT4

1762-IQ8OW6

Descriptions

8-point 120V ac Input

8-point Sink/Source 24V dc Input

16-point Sink/Source 24V dc Input

32-point Sink/Source 24V dc Input Module

8-point AC Triac Output

8-point Sourcing 24V dc Output

16-point Sourcing 24V dc Output

32-point Sourcing 24V dc Output Module

32-point Sinking 24V dc Output Module

8-point AC/DC Relay Output

16-point AC/DC Relay Output

6-point Isolated Relay Output

2-channel Analog Voltage/Current Input

2-channel Analog Voltage/Current Output

4-channel Analog Voltage/Current Input

4-channel Analog Voltage/Current Output

RTD/Resistance Input

Thermocouple/mV Input

DC-input/Relay-output Combination Module

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1-4 Hardware Overview

Communication Cables

Program the Controller

Use only the following communication cables with the MicroLogix 1200 controllers.

1761-CBL-PM02 series C or later

1761-CBL-HM02 series C or later

1761-CBL-AM00 series C or later

1761-CBL-AP00 series C or later

1761-CBL-PH02 Series A or later

1761-CBL-AH02 Series A or later

2707-NC8 series A or later

2702-NC9 series B or later

2707-NC10 series B or later

2707-NC11 series B or later

You program the MicroLogix 1200 programmable controller using RSLogix

500, revision 4 or later. You must use revision 4.5 or later of RSLogix 500 in order to use the new features of the series B MicroLogix 1200 controllers, including the full ASCII instruction set. Communication cables for programming are not included with the software.

Communication Options

The MicroLogix 1200 can be connected to a personal computer. It can also be connected to a DH-485 network, or a Modbus network as an RTU Master or

RTU Slave using an Advanced Interface Converter (catalog number

1761-NET-AIC). The controller can also be connected to DF1 Half-duplex networks as an RTU Master or RTU Slave. Series B controllers may also be connected to serial devices using ASCII.

See Chapter 4 Communication Connections for more information on

connecting to the available communication options.

The 1762-LxxxxxR controllers provide an additional communication port called the Programmer/HMI Port. This port supports DF1 full-duplex protocol only. The controller cannot initiate messages through this port. It can only respond to messages sent to it. All communication parameters are fixed and cannot be changed by a user.

See Default Communication Configuration on page 4-2 for the configuration

settings.

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1

Install Your Controller

Required Tools

Agency Certifications

This chapter shows you how to install your controller.

Topics include:

• required tools

• agency certifications

• compliance to European Union Directives

• installation considerations

• safety considerations

• power considerations

• preventing excessive heat

• master control relay

• install the memory module and/or real-time clock

• controller mounting dimensions

• controller and expansion I/O spacing

• mount the controller

• mount 1762 expansion I/O

• connect 1762 expansion I/O

You need a screwdriver and a drill.

UL 508

C-UL under CSA C22.2 no. 142

Class I, Division 2, Groups A, B, C, D

(UL 1604, C-UL under CSA C22.2 no. 213)

CE compliant for all applicable directives

C-Tick compliant for all applicable acts

Chapter

2

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2-2 Install Your Controller

Compliance to European

Union Directives

This product has the CE mark and is approved for installation within the

European Union and EEA regions. It has been designed and tested to meet the following directives.

EMC Directive

This product is tested to meet Council Directive 89/336/EEC

Electromagnetic Compatibility (EMC) and the following standards, in whole or in part, documented in a technical construction file:

EN 50081-2

EMC - Generic Emission Standard, Part 2 - Industrial Environment

EN 50082-2

EMC - Generic Immunity Standard, Part 2 - Industrial Environment

This product is intended for use in an industrial environment.

Low Voltage Directive

This product is tested to meet Council Directive 73/23/EEC Low Voltage, by applying the safety requirements of EN 61131-2 Programmable Controllers,

Part 2 - Equipment Requirements and Tests.

For specific information required by EN 61131-2, see the appropriate sections in this publication, as well as the following Allen-Bradley publications:

Industrial Automation Wiring and Grounding Guidelines for Noise

Immunity, publication 1770-4.1

Guidelines for Handling Lithium Batteries, publication AG-5.4

Automation Systems Catalog, publication B113

Installation Considerations

Most applications require installation in an industrial enclosure (Pollution

Degree 2

(1)

) to reduce the effects of electrical interference (Over Voltage

Category II

(2)

) and environmental exposure. Locate your controller as far as possible from power lines, load lines, and other sources of electrical noise such as hard-contact switches, relays, and AC motor drives. For more information on proper grounding guidelines, see the Industrial Automation Wiring and

Grounding Guidelines publication 1770-4.1.

(1) Pollution Degree 2 is an environment where normally only non-conductive pollution occurs except that occasionally temporary conductivity caused by condensation shall be expected.

(2) Overvoltage Category II is the load level section of the electrical distribution system. At this level, transient voltages are controlled and do not exceed the impulse voltage capability of the products insulation.

Publication 1762-UM001H-EN-P - June 2015

Install Your Controller 2-3

ATTENTION

Vertical mounting of the controller is not recommended due to heat build-up considerations.

Safety Considerations

ATTENTION

Be careful of metal chips when drilling mounting holes for your controller or other equipment within the enclosure or panel. Drilled fragments that fall into the controller or I/O modules could cause damage. Do not drill holes above a mounted controller if the protective debris shields are removed or the processor is installed.

Safety considerations are an important element of proper system installation.

Actively thinking about the safety of yourself and others, as well as the condition of your equipment, is of primary importance. We recommend reviewing the following safety considerations.

Hazardous Location Considerations

This equipment is suitable for use in Class I, Division 2, Groups A, B, C, D or non-hazardous locations only. The following WARNING statement applies to use in hazardous locations.

Publication 1762-UM001H-EN-P - June 2015

2-4 Install Your Controller

WARNING

EXPLOSION HAZARD

Substitution of components may impair suitability for Class I, Division 2.

Do not replace components or disconnect equipment unless power has been switched off.

Do not connect or disconnect components unless power has been switched off.

This product must be installed in an enclosure.

All cables connected to the product must remain in the enclosure or be protected by conduit or other means.

All wiring must comply with N.E.C. article 501-4(b).

The interior of the enclosure must be accessible only by the use of a tool.

For applicable equipment (for example, relay modules), exposure to some chemicals may degrade the sealing properties of the materials used in these devices:

Relays, epoxy

It is recommended that you periodically inspect these devices for any degradation of properties and replace the module if degradation is found.

Use only the following communication cables in Class I, Division 2 hazardous locations.

Communication Cables for Class I, Division 2 Hazardous Locations

1761-CBL-PM02 series C or later

1761-CBL-HM02 series C or later

1761-CBL-AM00 series C or later

1761-CBL-AP00 series C or later

1761-CBL-PH02 series A or later

1761-CBL-AH02 series A or later

2707-NC8 series A or later

2707-NC9 series B or later

2707-NC10 series B or later

2707-NC11 series B or later

Publication 1762-UM001H-EN-P - June 2015

Install Your Controller 2-5

Disconnect Main Power

WARNING

Explosion Hazard

Do not replace components or disconnect equipment unless power has been switched off.

The main power disconnect switch should be located where operators and maintenance personnel have quick and easy access to it. In addition to disconnecting electrical power, all other sources of power (pneumatic and hydraulic) should be de-energized before working on a machine or process controlled by a controller.

Safety Circuits

WARNING

Explosion Hazard

Do not connect or disconnect connectors while circuit is live.

Circuits installed on the machine for safety reasons, like overtravel limit switches, stop push buttons, and interlocks, should always be hard-wired directly to the master control relay. These devices must be wired in series so that when any one device opens, the master control relay is de-energized, thereby removing power to the machine. Never alter these circuits to defeat their function. Serious injury or machine damage could result.

Power Distribution

There are some points about power distribution that you should know:

The master control relay must be able to inhibit all machine motion by removing power to the machine I/O devices when the relay is de-energized. It is recommended that the controller remain powered even when the master control relay is de-energized.

If you are using a dc power supply, interrupt the load side rather than the ac line power. This avoids the additional delay of power supply turn-off. The dc power supply should be powered directly from the fused secondary of the transformer. Power to the dc input and output circuits should be connected through a set of master control relay contacts.

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2-6 Install Your Controller

Power Considerations

Periodic Tests of Master Control Relay Circuit

Any part can fail, including the switches in a master control relay circuit. The failure of one of these switches would most likely cause an open circuit, which would be a safe power-off failure. However, if one of these switches shorts out, it no longer provides any safety protection. These switches should be tested periodically to assure they will stop machine motion when needed.

The following explains power considerations for the micro controllers.

Isolation Transformers

You may want to use an isolation transformer in the ac line to the controller.

This type of transformer provides isolation from your power distribution system to reduce the electrical noise that enters the controller and is often used as a step-down transformer to reduce line voltage. Any transformer used with the controller must have a sufficient power rating for its load. The power rating is expressed in volt-amperes (VA).

Power Supply Inrush

During power-up, the MicroLogix 1200 power supply allows a brief inrush current to charge internal capacitors. Many power lines and control transformers can supply inrush current for a brief time. If the power source cannot supply this inrush current, the source voltage may sag momentarily.

The only effect of limited inrush current and voltage sag on the MicroLogix

1200 is that the power supply capacitors charge more slowly. However, the effect of a voltage sag on other equipment should be considered. For example, a deep voltage sag may reset a computer connected to the same power source.

The following considerations determine whether the power source must be required to supply high inrush current:

The power-up sequence of devices in a system.

The amount of the power source voltage sag if the inrush current cannot be supplied.

The effect of voltage sag on other equipment in the system.

If the entire system is powered-up at the same time, a brief sag in the power source voltage typically will not affect any equipment.

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Install Your Controller 2-7

Loss of Power Source

The power supply is designed to withstand brief power losses without affecting the operation of the system. The time the system is operational during power loss is called ‘program scan hold-up time after loss of power’.

The duration of the power supply hold-up time depends on the type and state of the I/O, but is typically between 10 milliseconds and 3 seconds. When the duration of power loss reaches this limit, the power supply signals the processor that it can no longer provide adequate dc power to the system. This is referred to as a power supply shutdown. The processor then performs an orderly shutdown of the controller.

Input States on Power Down

The power supply hold-up time as described above is generally longer than the turn-on and turn-off times of the inputs. Because of this, the input state change from ‘On’ to ‘Off ’ that occurs when power is removed may be recorded by the processor before the power supply shuts down the system.

Understanding this concept is important. The user program should be written to take this effect into account.

Other Types of Line Conditions

Occasionally the power source to the system can be temporarily interrupted. It is also possible that the voltage level may drop substantially below the normal line voltage range for a period of time. Both of these conditions are considered to be a loss of power for the system.

Prevent Excessive Heat

For most applications, normal convective cooling keeps the controller within the specified operating range. Ensure that the specified temperature range is maintained. Proper spacing of components within an enclosure is usually sufficient for heat dissipation.

In some applications, a substantial amount of heat is produced by other equipment inside or outside the enclosure. In this case, place blower fans inside the enclosure to assist in air circulation and to reduce “hot spots” near the controller.

Additional cooling provisions might be necessary when high ambient temperatures are encountered.

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2-8 Install Your Controller

Master Control Relay

TIP

Do not bring in unfiltered outside air. Place the controller in an enclosure to protect it from a corrosive atmosphere. Harmful contaminants or dirt could cause improper operation or damage to components. In extreme cases, you may need to use air conditioning to protect against heat build-up within the enclosure.

A hard-wired master control relay (MCR) provides a reliable means for emergency machine shutdown. Since the master control relay allows the placement of several emergency-stop switches in different locations, its installation is important from a safety standpoint. Overtravel limit switches or mushroom-head push buttons are wired in series so that when any of them opens, the master control relay is de-energized. This removes power to input

and output device circuits. Refer to the figures on pages 2-10 and 2-11.

ATTENTION

Never alter these circuits to defeat their function since serious injury and/or machine damage could result.

TIP

If you are using an external dc power supply, interrupt the dc output side rather than the ac line side of the supply to avoid the additional delay of power supply turn-off.

The ac line of the dc output power supply should be fused.

Connect a set of master control relays in series with the dc power supplying the input and output circuits.

Place the main power disconnect switch where operators and maintenance personnel have quick and easy access to it. If you mount a disconnect switch inside the controller enclosure, place the switch operating handle on the outside of the enclosure, so that you can disconnect power without opening the enclosure.

Whenever any of the emergency-stop switches are opened, power to input and output devices should be removed.

When you use the master control relay to remove power from the external I/O circuits, power continues to be provided to the controller’s power supply so that diagnostic indicators on the processor can still be observed.

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Install Your Controller 2-9

The master control relay is not a substitute for a disconnect to the controller. It is intended for any situation where the operator must quickly de-energize I/O devices only. When inspecting or installing terminal connections, replacing output fuses, or working on equipment within the enclosure, use the disconnect to shut off power to the rest of the system.

TIP

Do not control the master control relay with the controller. Provide the operator with the safety of a direct connection between an emergency-stop switch and the master control relay.

Use Emergency-Stop Switches

When using emergency-stop switches, adhere to the following points:

Do not program emergency-stop switches in the controller program.

Any emergency-stop switch should turn off all machine power by turning off the master control relay.

Observe all applicable local codes concerning the placement and labeling of emergency-stop switches.

Install emergency-stop switches and the master control relay in your system. Make certain that relay contacts have a sufficient rating for your application. Emergency-stop switches must be easy to reach.

In the following illustration, input and output circuits are shown with

MCR protection. However, in most applications, only output circuits require MCR protection.

The following illustrations show the Master Control Relay wired in a grounded system.

TIP

In most applications input circuits do not require

MCR protection; however, if you need to remove power from all field devices, you must include MCR contacts in series with input power wiring.

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2-10 Install Your Controller

Schematic (Using IEC Symbols)

L1

230V ac

L2

Disconnect

Fuse

MCR

230V ac

I/O

Circuits

X1

Isolation

Transformer

115V ac

or 230V ac

Fuse

X2

Operation of either of these contacts will remove power from the external I/O circuits, stopping machine motion.

Emergency-Stop

Push Button

Overtravel

Limit Switch

Stop

(Lo) (Hi)

Line Terminals: Connect to terminals of Power

Supply (1762-L24AWA, 1762-L24BWA,

1762-L40AWA, 1762-L40BWA,

1762-L24AWAR, 1762-L24BWAR,

1762-L40AWAR, and 1762-L40BWAR).

Start

Master Control Relay (MCR)

Cat. No. 700-PK400A1

Suppressor

Cat. No. 700-N24

MCR

Suppr.

MCR

MCR

115V ac or

230V ac

I/O Circuits dc Power Supply.

Use IEC 950/EN 60950

_

+

MCR

Line Terminals: Connect to 24V dc terminals of

Power Supply (1762-L24BXB, 1762-L40BXB,

1762-L24BXBR, and 1762-L40BXBR).

24V dc

I/O

Circuits

Publication 1762-UM001H-EN-P - June 2015

Install Your Controller 2-11

Schematic (Using ANSI/CSA Symbols)

L1

230V ac

L2

Disconnect

X1

Isolation

Transformer

115V ac or

230V ac

X2

Fuse

Fuse

MCR

230V ac

Output

Circuits

Operation of either of these contacts will remove power from the external I/O circuits, stopping machine motion.

Emergency-Stop

Push Button

Overtravel

Limit Switch

Stop

(Lo)

(Hi)

Line Terminals: Connect to terminals of Power

Supply (1762-L24AWA, 1762-L24BWA,

1762-L40AWA, 1762-L40BWA, 1762-L24AWAR,

1762-L24BWAR, 1762-L40AWAR, and

1762-L40BWAR).

Start

Master Control Relay (MCR)

Cat. No. 700-PK400A1

Suppressor

Cat. No. 700-N24

MCR

Suppr.

MCR

MCR

115V ac or

230V ac

I/O Circuits dc Power Supply. Use

NEC Class 2 for UL

Listing

.

_

+

MCR

24 V dc

I/O

Circuits

Line Terminals: Connect to 24V dc terminals of

Power Supply (1762-L24BXB, 1762-L40BXB,

1762-L24BXBR, and 1762-L40BXBR).

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2-12 Install Your Controller

Install a Memory Module or

Real-time Clock

1. Remove the memory module port cover.

2. Align the connector on the memory module with the connector pins on the controller.

3. Firmly seat the memory module into the controller.

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Install Your Controller 2-13

Controller Mounting

Dimensions

C

C

A

A

B B

1762-L24AWA, 1762-L24BWA, 1762-L24BXB

1762-L24AWAR, 1762-L24BWAR, 1762-L24BXBR

1762-L40AWA, 1762-L40BWA, 1762-L40BXB

1762-L40AWAR, 1762-L40BWAR, 1762-L40BXBR

Table 2.1 Controller Dimensions

Dimension 1762-L24AWA

1762-L24AWAR

A

B

C

1762-L24BWA

1762-L24BWAR

90 mm (3.5 in.)

110 mm (4.33 in.)

87 mm (3.43 in.)

1762-L24BXB

1762-L24BXBR

1762-L40AWA

1762-L40AWAR

1762-L40BWA

1762-L40BWAR

90 mm (3.5 in.)

160 mm (6.30 in.)

87 mm (3.43 in.)

1762-L40BXB

1762-L40BXBR

Controller and

Expansion I/O Spacing

The controller mounts horizontally, with the expansion I/O extending to the right of the controller. Allow 50 mm (2 in.) of space on all sides of the controller system for adequate ventilation. Maintain spacing from enclosure walls, wireways, and adjacent equipment, as shown below.

Top

Side

MicroLogix

1200

Side

Bottom

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2-14 Install Your Controller

Mount the Controller

MicroLogix 1200 controllers are suitable for use in an industrial environment when installed in accordance with these instructions. Specifically, this equipment is intended for use in clean, dry environments (Pollution degree

2

(1)

) and to circuits not exceeding Over Voltage Category II

(2)

(IEC

60664-1).

(3)

ATTENTION

Do not remove the protective debris shield until after the controller and all other equipment in the panel near the controller are mounted and wiring is complete. Once wiring is complete, remove protective debris shield. Failure to remove shield before operating can cause overheating.

debris shield

ATTENTION

Electrostatic discharge can damage semiconductor devices inside the controller. Do not touch the connector pins or other sensitive areas.

TIP

For environments with greater vibration and shock concerns, use the panel mounting method described

on page 2-16, rather than DIN rail mounting.

Publication 1762-UM001H-EN-P - June 2015

(1) Pollution Degree 2 is an environment where, normally, only non-conductive pollution occurs except that occasionally a temporary conductivity caused by condensation shall be expected.

(2) Over Voltage Category II is the load level section of the electrical distribution system. At this level transient voltages are controlled and do not exceed the impulse voltage capability of the product’s insulation.

(3) Pollution Degree 2 and Over Voltage Category II are International Electrotechnical Commission (IEC) designations.

Install Your Controller 2-15

DIN Rail Mounting

The maximum extension of the latch is 14 mm (0.55 in.) in the open position.

A flat-blade screwdriver is required for removal of the controller. The controller can be mounted to EN50022-35x7.5 or EN50022-35x15 DIN rails.

DIN rail mounting dimensions are shown below.

27.5 mm

(1.08 in.)

90 mm

(3.5 in.)

27.5 mm

(1.08 in.)

To install your controller on the DIN rail:

1. Mount your DIN rail. (Make sure that the placement of the controller on the DIN rail meets the recommended spacing requirements,

see Controller and Expansion I/O Spacing on page 2-13. Refer to the

mounting template inside the back cover of this document.)

2. Close the DIN latch, if it is open.

3. Hook the top slot over the DIN rail.

4. While pressing the controller down against the top of the rail, snap the bottom of the controller into position.

5. Leave the protective debris shield attached until you are finished wiring the controller and any other devices.

To remove your controller from the DIN rail:

1. Place a flat-blade screwdriver in the DIN rail latch at the bottom of the controller.

2. Holding the controller, pry downward on the latch until the latch locks in the open position.

3. Repeat steps 1 and 2 for the second DIN rail latch.

4. Unhook the top of the DIN rail slot from the rail.

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2-16 Install Your Controller

Publication 1762-UM001H-EN-P - June 2015 open closed

Panel Mounting

Mount to panel using #8 or M4 screws. To install your controller using mounting screws:

1. Remove the mounting template from inside the back cover of the

MicroLogix 1200 Programmable Controllers Installation Instructions, publication 1762-IN006.

2. Secure the template to the mounting surface. (Make sure your controller

is spaced properly. See Controller and Expansion I/O Spacing on page

2-13.)

3. Drill holes through the template.

4. Remove the mounting template.

5. Mount the controller.

6. Leave the protective debris shield in place until you are finished wiring the controller and any other devices.

Debris Shield

Mounting Template

Install Your Controller 2-17

1762 Expansion I/O

Dimensions

A

Mount 1762

Expansion I/O

C

B

Dimension

A

B

C

Expansion I/O Module

90 mm (3.5 in.)

40 mm (1.57 in.)

87 mm (3.43 in.)

ATTENTION

During panel or DIN rail mounting of all devices, be sure that all debris (metal chips, wire stands) is kept from falling into the module. Debris that falls into the module could cause damage when the module is under power.

DIN Rail Mounting

The module can be mounted using the following DIN rails:

35 x 7.5 mm (EN 50 022 - 35 x 7.5), or

35 x 15 mm (EN 50 022 - 35 x 15).

Before mounting the module on a DIN rail, close the DIN rail latch. Press the

DIN rail mounting area of the module against the DIN rail. The latch momentarily opens and locks into place.

Publication 1762-UM001H-EN-P - June 2015

2-18 Install Your Controller

Use DIN rail end anchors (Allen-Bradley part number 1492-EA35 or

1492-EAH35) for vibration or shock environments. The following illustration shows the location of the end anchors.

End Anchor

End Anchor

Publication 1762-UM001H-EN-P - June 2015

TIP

TIP

1762 expansion I/O must be mounted horizontally as illustrated.

For environments with greater vibration and shock concerns, use the panel mounting method described below, instead of DIN rail mounting.

Mount on Panel

Use the dimensional template shown below to mount the module. The preferred mounting method is to use two M4 or #8 panhead screws per module. Mounting screws are required on every module.

For more than 2 modules: (number of modules - 1) x 40 mm (1.58 in.)

14.5

(0.57)

40.4

(1.59)

100 90

(3.94) (3.54)

MicroLogix

1200

A = 95.86mm (3.774 in.)

1762-L24AWA, 1762-L24BWA, 1762-L24BXB

1762-L24AWAR, 1762-L24BWAR, 1762-L24BXBR

B = 145.8 mm (5.739 in.)

1762-L40AWA, 1762-L40BWA, 1762-L40BXB

1762-L40AWAR, 1762-L40BWAR, 1762-L40BXBR

A

B

40.4

(1.59)

NOTE: All dimensions are in mm (inches).

Hole spacing tolerance: ±0.4 mm (0.016 in.).

Connect Expansion I/O

Install Your Controller 2-19

The expansion I/O module is attached to the controller or another I/O module by means of a flat ribbon cable after mounting, as shown below.

Pull Loop

TIP

Use the pull loop on the connector to disconnect modules. Do not pull on the ribbon cable.

TIP

ATTENTION

Up to six expansion I/O modules can be connected to a controller depending upon the power supply loading.

Remove power before removing or inserting an I/O module. When you remove or insert a module with power applied, an electrical arc may occur. An electrical arc can cause personal injury or property damage by:

• sending an erroneous signal to your system’s field devices, causing the controller to fault

• causing an explosion in a hazardous environment

Electrical arcing causes excessive wear to contacts on both the module and its mating connector. Worn contacts may create electrical resistance, reducing product reliability.

Publication 1762-UM001H-EN-P - June 2015

2-20 Install Your Controller

WARNING

EXPLOSION HAZARD

In Class I, Division 2 applications, the bus connector must be fully seated and the bus connector cover must be snapped in place.

In Class I, Division 2 applications, all modules must be mounted in direct contact with each other as

shown on page 2-19. If DIN rail mounting is used, an end

stop must be installed ahead of the controller and after the last 1762 I/O module.

Publication 1762-UM001H-EN-P - June 2015

1

Wire Requirements

Chapter

3

Wire Your Controller

This chapter describes how to wire your controller and expansion I/O. Topics include:

• wire requirements

• using surge suppressors

• grounding the controller

• wiring diagrams

• sinking and sourcing wiring diagrams

• controller I/O wiring

• expansion I/O wiring

ATTENTION

Before you install and wire any device, disconnect power to the controller system.

ATTENTION

Calculate the maximum possible current in each power and common wire. Observe all electrical codes dictating the maximum current allowable for each wire size. Current above the maximum ratings may cause wiring to overheat, which can cause damage.

United States Only: If the controller is installed within a potentially hazardous environment, all wiring must comply with the requirements stated in the National Electrical Code 501-4 (b).

Allow for at least 50 mm (2 in) between I/O wiring ducts or terminal strips and the controller.

Route incoming power to the controller by a path separate from the device wiring. Where paths must cross, their intersection should be perpendicular.

Publication 1762-UM001H-EN-P - June 2015

3-2 Wire Your Controller

TIP

Do not run signal or communication wiring and power wiring in the same conduit. Wires with different signal characteristics should be routed by separate paths.

Separate wiring by signal type. Bundle wiring with similar electrical characteristics together.

Separate input wiring from output wiring.

Label wiring to all devices in the system. Use tape, shrink-tubing, or other dependable means for labeling purposes. In addition to labeling, use colored insulation to identify wiring based on signal characteristics.

For example, you may use blue for dc wiring and red for ac wiring.

Table 3.1 Wire Requirements

Wire Type

Solid

Stranded

Wire Size (2 wire maximum per terminal screw)

(1)

Cu-90 °C (194 °F) #14 to #22 AWG

Cu-90 °C (194 °F) #16 to #22 AWG

(1) Wiring torque = 0.791 Nm (7 lb-in) rated

Wire without Spade Lugs

When wiring without spade lugs, it is recommended to keep the finger-safe covers in place. Loosen the terminal screw and route the wires through the opening in the finger-safe cover. Tighten the terminal screw making sure the pressure plate secures the wire.

Finger-Safe Cover

Publication 1762-UM001H-EN-P - June 2015

Wire Your Controller 3-3

Wire with Spade Lugs

The diameter of the terminal screw head is 5.5 mm (0.220 in.). The input and output terminals of the MicroLogix 1200 controller are designed for a 6.35 mm (0.25 in.) wide spade (standard for #6 screw for up to 14 AWG) or a 4 mm (metric #4) fork terminal.

When using spade lugs, use a small, flat-blade screwdriver to pry the finger-safe cover from the terminal blocks as shown below. Then loosen the terminal screw.

Use Surge Suppressors

Because of the potentially high current surges that occur when switching inductive load devices, such as motor starters and solenoids, the use of some type of surge suppression to protect and extend the operating life of the controllers output contacts is required. Switching inductive loads without surge suppression can significantly reduce the life expectancy of relay contacts.

By adding a suppression device directly across the coil of an inductive device, you prolong the life of the output or relay contacts. You also reduce the effects of voltage transients and electrical noise from radiating into adjacent systems.

Publication 1762-UM001H-EN-P - June 2015

3-4 Wire Your Controller

Output Device

Varistor

Publication 1762-UM001H-EN-P - June 2015

The following diagram shows an output with a suppression device. We recommend that you locate the suppression device as close as possible to the load device.

+dc or L1

VAC/DC

Suppression

Device ac or dc

Outputs

Out 0

Out 1

Out 2

Out 3

Out 4

Out 5

Out 6

Out 7

COM

Load dc COM or L2

If the outputs are dc, we recommend that you use an 1N4004 diode for surge suppression, as shown below. For inductive dc load devices, a diode is suitable.

A 1N4004 diode is acceptable for most applications. A surge suppressor can

also be used. See Table 3.2 for recommended suppressors. As shown below,

these surge suppression circuits connect directly across the load device.

+24V dc

Relay or Solid

State dc Outputs

VAC/DC

Out 0

Out 1

Out 2

Out 3

Out 4

Out 5

Out 6

Out 7

COM

24V dc common

IN4004 Diode

(A surge suppressor can also be used.)

Suitable surge suppression methods for inductive ac load devices include a varistor, an RC network, or an Allen-Bradley surge suppressor, all shown below. These components must be appropriately rated to suppress the switching transient characteristic of the particular inductive device. See the

table on page 3-5 for recommended suppressors.

Surge Suppression for Inductive ac Load Devices

Output Device

RC Network

Output Device

Surge

Suppressor

Wire Your Controller 3-5

Recommended Surge Suppressors

Use the Allen-Bradley surge suppressors shown in the following table for use with relays, contactors, and starters.

Table 3.2 Recommended Surge Suppressors

Device Coil Voltage

Bulletin 509 Motor Starter

Bulletin 509 Motor Starter

Bulletin 100 Contactor

Bulletin 100 Contactor

120V ac

240V ac

120V ac

240V ac

Bulletin 709 Motor Starter

Bulletin 700 Type R, RM Relays

Bulletin 700 Type R Relay

Bulletin 700 Type RM Relay

Bulletin 700 Type R Relay

Bulletin 700 Type RM Relay

Bulletin 700 Type R Relay

Bulletin 700 Type RM Relay

Bulletin 700 Type R Relay

Bulletin 700 Type RM Relay

Bulletin 700 Type R Relay

Bulletin 700 Type RM Relay

Bulletin 700 Type N, P, or PK Relay

Miscellaneous electromagnetic devices limited to 35 sealed VA

(1) Varistor – Not recommended for use on relay outputs.

(2) RC Type – Do not use with Triac outputs.

120V ac ac coil

12V dc

12V dc

24V dc

24V dc

48V dc

48V dc

115-125V dc

115-125V dc

230-250V dc

230-250V dc

150V max, ac or dc

150V max, ac or dc

Suppressor Catalog

Number

599-K04

(1)

599-KA04

(1)

199-FSMA1

(2)

199-FSMA2

(2)

1401-N10

(2)

None Required

199-FSMA9

199-FSMA9

199-FSMA9

199-FSMA10

199-FSMA11

700-N24

700-N24

(2)

(2)

Publication 1762-UM001H-EN-P - June 2015

3-6 Wire Your Controller

Ground the Controller

In solid-state control systems, grounding and wire routing helps limit the effects of noise due to electromagnetic interference (EMI). Run the ground connection from the ground screw of the controller to the ground bus prior to connecting any devices. Use AWG #14 wire. For AC-powered controllers, this connection must be made for safety purposes.

ATTENTION

All devices connected to the RS-232 channel must be referenced to controller ground, or be floating (not referenced to a potential other than ground). Failure to follow this procedure may result in property damage or personal injury.

For 1762-L24BWA, 1762-L40BWA, 1762-L24BWAR, and 1762-L40BWAR controllers:

The COM of the sensor supply is also connected to chassis ground internally. The

24V dc sensor power source should not be used to power output circuits. It should only be used to power input devices.

For 1762-L24BXB, 1762-L40BXB, 1762-L24BXBR, and 1762-L40BXBR controllers:

The VDC NEUT or common terminal of the power supply is also connected to chassis ground internally.

This product is intended to be mounted to a well grounded mounting surface such as a metal panel. Refer to the Industrial Automation Wiring and

Grounding Guidelines, publication 1770-4.1, for additional information.

Additional grounding connections from the mounting tab or DIN rail, if used, are not required unless the mounting surface cannot be grounded.

TIP

Use all four mounting positions for panel mounting installation.

Publication 1762-UM001H-EN-P - June 2015

Grounding stamping

ATTENTION

Remove the protective debris strip before applying power to the controller. Failure to remove the strip may cause the controller to overheat.

Wiring Diagrams

Wire Your Controller 3-7

The following illustrations show the wiring diagrams for the MicroLogix 1200 controllers. Controllers with dc inputs can be wired as either sinking or

sourcing inputs. (Sinking and sourcing does not apply to ac inputs.) Refer to

Sinking and Sourcing Wiring Diagrams on page 3-12

The controller terminal block layouts are shown below. The shading on the labels indicates how the terminals are grouped. A detail of the groupings is shown in the table following the terminal block layouts.

TIP

This symbol denotes a protective earth ground terminal which provides a low impedance path between electrical circuits and earth for safety purposes and provides noise immunity improvement. This connection must be made for safety purposes on ac-powered controllers.

This symbol denotes a functional earth ground terminal which provides a low impedance path between electrical circuits and earth for non-safety purposes, such as noise immunity improvement.

Terminal Block Layouts

Figure 3.1 1762-L24AWA and 1762-L24AWAR

Inputs

Outputs

Group 0 Group 1

NC

NC

COM

0

IN 0 IN 2

COM

1

IN 1 IN 3 IN 4

IN 5

IN 6

IN 7

IN 8

IN 9 IN 11

IN 10

IN 13

IN 12

VAC

L1

VAC

NEUT

OUT 0 OUT 1 OUT 2 VAC

DC3

OUT 5 OUT 6 OUT 8

VAC

DC 0

VAC

DC 1

VAC

DC 2

OUT 3 OUT 4 VAC

DC 4

OUT 7 OUT 9

G ro up

0

G ro up

1

G ro up

2

G ro up

3

G ro up

4

Publication 1762-UM001H-EN-P - June 2015

3-8 Wire Your Controller

Figure 3.2 1762-L24BWA and 1762-L24BWAR

Inputs

Outputs

Group 0

Group 1

+24

VDC

24

COM

COM

0

IN 0 IN 2

IN 1

COM

IN 3

1

IN 4

IN 5

IN 6

IN 7

IN 8

IN 9 IN 11

IN 10 IN 12

IN 13

VAC

L1

VAC

NEUT

OUT 0

VAC

DC 0

OUT 1

VAC

DC 1

OUT 2

VAC

DC 3

OUT 5 OUT 6 OUT 8

VAC

DC 2

OUT 3 OUT 4

VAC

DC 4

OUT 7 OUT 9

G ro up

0

G ro up

1

G ro up

2

G ro up

3

G ro up

4

ATTENTION

The 24V dc sensor supply of the 1762-L24BWA and

1762-L24BWAR should not be used to power output circuits. It should only be used to power input devices (for

example sensors and switches). See Master Control Relay on page 2-8 for information on MCR wiring in output

circuits.

Figure 3.3 1762-L24BXB and 1762-L24BXBR

Group 0 Group 1

NC

NC

COM

0

IN 0 IN 2

COM

1

IN 1 IN 3 IN 4

IN 5

IN 6

IN 7

IN 8

IN 9 IN 11

IN 10

IN 13

IN 12

+24

VDC

VDC

NEUT

VAC

DC 0

OUT

0

VAC

DC 1

OUT

1

VDC

2

OUT

2

OUT

3

OUT

4

OUT

5

OUT

6

COM

2

VAC

DC 3

OUT

7

OUT

8

OUT

9

G ro up

0

G ro up

1

G ro up

2

G ro up

3

Figure 3.4 1762-L40AWA and 1762-L40AWAR

Inputs

Outputs

Group 0 Group 1 Group 2

NC

NC

COM

0

IN 0 IN 2

COM

1

IN 5 IN 7

IN 1 IN 3 IN 4 IN 6

COM

2

IN 8 IN 10 IN 12 IN 14 IN 16 IN 18 IN 20 IN 22

IN 9 IN 11 IN 13 IN 15 IN 17 IN 19 IN 21 IN 23

VAC

L1

VAC

NEUT

VAC

DC 0

OUT

0

VAC

DC 1

OUT

1

OUT

2

VAC

DC 2

OUT

3

VAC

DC 3

OUT

4

OUT

5

OUT

6

OUT

7

VAC

DC 4

OUT

8

OUT

9

OUT

10

OUT

11

VAC

DC 5

OUT

12

OUT

13

OUT

14

OUT

15

G ro up

0

G ro up

1

G ro up

2

G ro up

3

G ro up

4

G ro up

5

Publication 1762-UM001H-EN-P - June 2015

Wire Your Controller 3-9

Figure 3.5 1762-L40BWA and 1762-L40BWAR

Inputs

24

COM

+24

VDC

COM

0

Group 0

IN 0 IN 2

COM

1

Group 1

IN 5 IN 7 IN 8

IN 1 IN 3 IN 4 IN 6

COM

2

Group 2

IN 10 IN 12 IN 14 IN 16 IN 18 IN 20 IN 22

IN 9 IN 11 IN 13 IN 15 IN 17 IN 19 IN 21 IN 23

Outputs

VAC

L1

VAC

NEUT

VAC

DC 0

OUT

0

VAC

DC 1

OUT

1

VAC

DC 2

OUT

2

OUT

3

VAC

DC 3

OUT

4

OUT

5

OUT

6

OUT

7

VAC

DC 4

OUT

8

OUT

9

OUT

10

VAC

DC 5

OUT

11

OUT

OUT

12

13

OUT

14

OUT

15

G ro up

0

G ro up

1

G ro up

2

G ro up

3

G ro up

4

G ro up

5

ATTENTION

The 24V dc sensor supply of the 1762-L40BWA and

1762-L40BWAR should not be used to power output circuits. It should only be used to power input devices (for

example sensors and switches). See Master Control Relay on page 2-8 for information on MCR wiring in output

circuits.

Figure 3.6 1762-L40BXB and 1762-L40BXBR

Inputs

Outputs

NC

NC

COM

0

Group 0 Group 1

IN 0 IN 2

COM

1

IN 5 IN 7 IN 8

Group 2

IN 10 IN 12 IN 14 IN 16 IN 18 IN 20 IN 22

IN 1 IN 3 IN 4 IN 6

COM

2

IN 9 IN 11 IN 13 IN 15 IN 17 IN 19 IN 21 IN 23

+24

VDC

VDC

NEUT

VAC

DC 0

OUT

0

VAC

DC 1

OUT

1

VDC

2

OUT

2

OUT

3

OUT

4

OUT

5

OUT

6

OUT

7

OUT

8

OUT

9

COM

2

VAC

DC 3

OUT

10

VAC

DC 4

OUT

11

OUT

12

OUT

13

OUT

14

OUT

15

G ro up

0

G ro up

1

G ro up

2

G ro up

3

G ro up

4

Terminal Groupings

Table 3.3 Input Terminal Grouping

Controller

1762-L24AWA

1762-L24AWAR

1762-L24BWA

1762-L24BWAR

1762-L24BXB

1762-L24BXBR

1762-L40AWA

1762-L40AWAR

Input Group

Group 0

Group 1

Group 0

Group 1

Group 0

Group 1

Group 0

Group 1

Group 2

Inputs

Common Terminal Input Terminal

AC COM 0

AC COM 1

DC COM 0

I/0 through I/3

I/4 through I/13

I/0 through I/3

DC COM 1

DC COM 0

DC COM 1

AC COM 0

AC COM 1

AC COM 2

I/4 through I/13

I/0 through I/3

I/4 through I/13

I/0 through I/3

I/4 through I/7

I/8 through I/23

Publication 1762-UM001H-EN-P - June 2015

3-10 Wire Your Controller

Publication 1762-UM001H-EN-P - June 2015

Table 3.3 Input Terminal Grouping

Controller

1762-L40BWA

1762-L40BWAR

1762-L40BXB

1762-L40BXBR

Input Group

Group 0

Group 1

Group 2

Group 0

Group 1

Group 2

Inputs

Common Terminal Input Terminal

DC COM 0 I/0 through I/3

DC COM 1

DC COM 2

DC COM 0

DC COM 1

DC COM 2

I/4 through I/7

I/8 through I/23

I/0 through I/3

I/4 through I/7

I/8 through I/23

Table 3.4 Output Terminal Grouping

Controller

1762-L24AWA

1762-L24AWAR

1762-L24BWA

1762-L24BWAR

1762-L24BXB

1762-L24BXBR

Output

Group

Group 0

Group 1

Group 2

Group 3

Group 4

Group 0

Group 1

Group 2

Group 3

Group 4

Group 0

Group 1

Group 2

Group 3

Voltage

Terminal

VAC/VDC 0

VAC/VDC 1

VAC/VDC 2

VAC/VDC 3

VAC/VDC 4

VAC/VDC 0

VAC/VDC 1

VAC/VDC 2

VAC/VDC 3

VAC/VDC 4

VAC/VDC 0

VAC/VDC 1

VDC 2, VDC

COM 2

VAC/VDC 3

1762-L40AWA

1762-L40AWAR

1762-L40BWA

1762-L40BWAR

Group 0

Group 1

Group 2

Group 3

Group 4

Group 5

Group 0

Group 1

Group 2

Group 3

Group 4

Group 5

VAC/VDC 0

VAC/VDC 1

VAC/VDC 2

VAC/VDC 3

VAC/VDC 4

VAC/VDC 5

VAC/VDC 0

VAC/VDC 1

VAC/VDC 2

VAC/VDC 3

VAC/VDC 4

VAC/VDC 5

Outputs

Output

Terminal

O/0

O/1

O/2 through O/3

O4 through O/5

O/6 through O/9

O/12 through

O/15

O/0

O/1

O/2 through O/3

O/4 through O/7

O/8 through

O/11

O/12 through

O/15

Description

Isolated Relay outputs

O/0

O/1

O/2 through O/3

O/4 through O/5

Isolated Relay outputs

O/6 through O/9

O/0

O/1

Isolated Relay outputs

O/2 through O/6 Isolated FET outputs

O/7 through O/9 Isolated Relay outputs

O/0

O/1

O/2 through O/3

O/4 through O/7

O/8 through

O/11

Isolated Relay outputs

Isolated Relay outputs

Wire Your Controller 3-11

Table 3.4 Output Terminal Grouping

Controller

1762-L40BXB

1762-L40BXBR

Output

Group

Group 0

Group 1

Group 2

Group 3

Voltage

Terminal

VAC/VDC 0

VAC/VDC 1

VDC 2, VDC

COM 2

VAC/VDC 3

Group 4 VAC/VDC 4

Outputs

Output

Terminal

Description

O/0

O/1

Isolated Relay outputs

O/2 through O/9 Isolated FET outputs

O/10 through

O/11

O/12 through

O/15

Isolated Relay outputs

Publication 1762-UM001H-EN-P - June 2015

3-12 Wire Your Controller

Sinking and Sourcing

Wiring Diagrams

Any of the MicroLogix 1200 DC embedded input groups can be configured as sinking or sourcing depending on how the DC COM is wired on the group.

Refer to pages 3-13 through 3-17 for sinking and sourcing wiring diagrams.

Type

Sinking Input

Definition

The input energizes when high-level voltage is applied to the input terminal (active high). Connect the power supply VDC (-) to the input group’s COM terminal.

Sourcing Input The input energizes when low-level voltage is applied to the input terminal (active low). Connect the power supply VDC (+) to the input group’s COM terminal.

ATTENTION

The 24V dc sensor power source must not be used to power output circuits. It should only be used to power input devices (for example sensors and

switches). See Master Control Relay on page 2-8 for

information on MCR wiring in output circuits.

1762-L24AWA, 1762-L24BWA, 1762-L24BXB, 1762-L24AWAR,

1762-L24BWAR and 1762-L24BXBR Wiring Diagrams

TIP

In the following diagrams, lower case alphabetic subscripts are appended to common-terminal connections to indicate that different power sources may be used for different isolated groups, if desired.

Figure 3.7 1762-L24AWA and 1762-L24AWAR Input Wiring Diagram

(1)

L1a

L2b

L1b

NC

NC

COM

0

IN 0 IN 2

COM

1

IN 1 IN 3 IN 4

IN 5

IN 6

IN 7

IN 8

IN 9 IN 11

IN 10

IN 13

IN 12

L2a

L1a

(1) “NC” terminals are not intended for use as connection points.

L1b

Publication 1762-UM001H-EN-P - June 2015

Wire Your Controller 3-13

Figure 3.8 1762-L24BWA and 1762-L24BWAR Sinking Input Wiring Diagram

+DC

+DCa

-DCb

+DCb

+24

VDC

IN 0 IN 2 COM 1 IN 5 IN 7 IN 9 IN 11

24

COM

COM 0

IN 1 IN 3 IN 4 IN 6 IN 8 IN 10 IN 12

IN 13

+DCb

-DC -DCa

+DCa

Figure 3.9 1762-L24BWA and 1762-L24BWAR Sourcing Input Wiring Diagram

24V dc Sensor Power

+DC

-DCa

+DCb

-DCb

+24

VDC

IN 0 IN 2 COM 1 IN 5 IN 7 IN 9 IN 11

24

COM

COM 0

IN 1 IN 3 IN 4 IN 6 IN 8 IN 10 IN 12

IN 13

-DCb

-DC +DCa

-DCa

Publication 1762-UM001H-EN-P - June 2015

3-14 Wire Your Controller

Publication 1762-UM001H-EN-P - June 2015

Figure 3.10 1762-L24BXB and 1762-L24BXBR Sinking Input Wiring Diagram

+DCa

-DCb

+DCb

NOT

USED

IN 0 IN 2

COM 1

IN 5 IN 7 IN 9 IN 11

NOT

USED

COM 0

IN 1 IN 3 IN 4 IN 6 IN 8 IN 10 IN 12

IN 13

+DCb

-DCa

+DCa

Figure 3.11 1762-L24BXB and 1762-L24BXBR Sourcing Input Wiring Diagram

-DCa

+DCb

-DCb

NOT

USED

0 IN 2 COM1 IN 5 IN 7 IN 9 IN 11

NOT

USED

COM0

IN 1 IN 3 IN 4 IN 6 IN 8 IN 10 IN 12

IN 13

-DCb

+DCa

-DCa

Figure 3.12 1762-L24AWA, 1762-L24BWA, 1762-L24AWAR, and 1762-L24BWAR

Output Wiring Diagram

-DCa L2a L2b L1c L2c

L2d

L2

L1

CR CR

VAC

L1

VAC

NEUT

OUT 0 OUT 1 OUT 2 VAC

DC 3

VAC

DC 0

VAC

DC 1

VAC

DC 2

OUT 3

OUT 5 OUT 6 OUT 8

OUT 4 VAC

DC 4

OUT 7 OUT 9

CR

+DCa L1a L1b

L2b

L2c L1d

CR

L2d

Wire Your Controller 3-15

Figure 3.13 1762-L24BXB and 1762-L24BXBR Output Wiring Diagram

-DCa -DCb -DCc

L1d

L2d

+DC -DC

CR

CR

+24

VDC

VDC

NEUT

VAC

DC 0

OUT

0

VAC

DC 1

OUT

1

VDC

2

OUT

2

OUT

3

OUT

4

OUT

5

OUT

6

COM

2

VAC

OUT

DC 3

8

OUT

7

OUT

9

CR CR

+DCa +DCb +DCc

-DCc

L2d

1762-L40AWA, 1762-L40BWA, 1762-L40BXB, 1762-L40AWAR,

1762-L40BWAR and 1762-L40BXBR Wiring Diagrams

Figure 3.14 1762-L40AWA and 1762-L40AWAR Input Wiring Diagram

L1a

L2b

L1b L1c

NC

NC

COM

0

IN 0 IN 2

COM

1

IN 5 IN 7

IN 1 IN 3 IN 4 IN 6

COM

2

IN 8 IN 10 IN 12 IN 14 IN 16 IN 18 IN 20 IN 22

IN 9 IN 11 IN 13 IN 15 IN 17 IN 19 IN 21 IN 23

L2a

L1a

L1b

L2c

L1c

Figure 3.15 1762-L40BWA and 1762-L40BWAR Sinking Input Wiring Diagram

-DCb

+DCb

+DC

+DCa

+DCc

2 4

C O M

+ 2 4

V D C

C O M

0

IN 0 IN 2

IN 1

C O M

IN 3

1

IN 4

IN 5 IN 7

IN 6

C O M

2

IN 8 IN 10 IN 12 IN 14 IN 16 IN 18 IN 20 IN 22

IN 9 IN 11 IN 13 IN 15 IN 17 IN 19 IN 21 IN 23

-DC

-DCa

+DCa

+DCb

-DCc

+DCc

Publication 1762-UM001H-EN-P - June 2015

3-16 Wire Your Controller

Figure 3.16 1762-L40BWA and 1762-L40BWAR Sourcing Input Wiring Diagram

+DCb -DCb

-DCa

-DCc

+DC

2 4

C O M

+ 2 4

V D C

C O M

0

IN 0 IN 2

IN 1

C O M

IN 3

1

IN 5

IN 4

IN 7

IN 6

C O M

2

IN 8 IN 10 IN 12 IN 14 IN 16 IN 18 IN 20 IN 22

IN 9 IN 11 IN 13 IN 15 IN 17 IN 19 IN 21 IN 23

-DC

+DCa

-DCa

-DCb

+DCc

-DCc

Figure 3.17 1762-L40BXB and 1762-L40BXBR Sinking Input Wiring Diagram

+DCa

-DCb +DCb

+DCc

NOT

USED

NOT

USED

COM

0

IN 0 IN 2

IN 1

COM

IN 3

1

IN 4

IN 5

IN 6

IN 7

COM

2

IN 8 IN 10 IN 12 IN 14 IN 16 IN 18 IN 20 IN 22

IN 9 IN 11 IN 13 IN 15 IN 17 IN 19 IN 21 IN 23

-DCa

+DCa

+DCb

-DCc

Figure 3.18 1762-L40BXB and 1762-L40BXBR Sourcing Input Wiring Diagram

+DCb

-DCa

-DCb

-DCc

+DCc

NOT

USED

NOT

USED

COM

0

IN 0 IN 2

COM

1

IN 1 IN 3 IN 4

IN 5 IN 7

IN 6

COM

2

IN 8 IN 10 IN 12 IN 14 IN 16 IN 18 IN 20 IN 22

IN 9 IN 11 IN 13 IN 15 IN 17 IN 19 IN 21 IN 23

-DCc

+DCa

-DCa

-DCb

+DCc

Publication 1762-UM001H-EN-P - June 2015

Controller I/O Wiring

Wire Your Controller 3-17

Figure 3.19 1762-L40AWA, 1762-L40BWA, 1762-L40AWAR, and 1762-L40BWAR

Output Wiring Diagram

L2a L2b L2c

L1d

L2d L2e

L1f

L2f

-DC

L2

L1

CR

CR

CR CR

VAC

L1

VAC

NEUT

VAC

DC 0

OUT

0

VAC

DC 1

OUT

1

VAC

DC 2

OUT

2

OUT

3

VAC

DC 3

OUT

4

OUT

5

OUT

6

OUT

7

VAC

DC 4

OUT

8

OUT

9

OUT

10

VAC

DC 5

OUT

11

OUT

12

OUT

13

OUT

14

OUT

15

CR

CR

CR

CR

L1a L1b L1c

L2c

L2d

L1e

L2e

Figure 3.20 1762-L40BXB and 1762-L40BXBR Output Wiring Diagram

-DCa -DCb

-DCc

-DCd

+DCe

L2f

-DCe

+DC

CR

CR

CR CR

+24

VDC

VDC

NEUT

VAC

DC 0

OUT

0

VAC

DC 1

OUT

1

VDC

2

OUT

2

OUT

3

OUT

4

OUT

5

OUT

6

OUT

7

OUT

8

OUT

9

COM

VAC

DC3

OUT

10

VAC

DC 4

OUT

11

OUT

12

OUT

13

OUT

14

OUT

15

CR

CR CR

CR

CR

-DCe

+DCa +DCb

+DCc

-DCc

+DCd

-DCd

Minimize Electrical Noise

Because of the variety of applications and environments where controllers are installed and operating, it is impossible to ensure that all environmental noise will be removed by input filters. To help reduce the effects of environmental noise, install the MicroLogix 1200 system in a properly rated (NEMA) enclosure. Make sure that the MicroLogix 1200 system is properly grounded.

A system may malfunction due to a change in the operating environment after a period of time. We recommend periodically checking system operation, particularly when new machinery or other noise sources are installed near the

Micrologix 1200 system.

Publication 1762-UM001H-EN-P - June 2015

3-18 Wire Your Controller

Expansion I/O Wiring

The following sections show the discrete and analog expansion I/O wiring diagrams.

Discrete Wiring Diagrams

Figure 3.21 1762-IA8 Wiring Diagram

L1

L2

100/120V ac

IN 1

IN 3

IN 5

IN 7

AC

COM

AC

COM

IN 0

IN 2

IN 4

IN 6

Common connected internally.

Figure 3.22 1762-IQ8 Wiring Diagram

+DC (sinking)

-DC (sourcing)

-DC (sinking)

+DC (sourcing)

24V dc

IN 1

IN 3

IN 5

IN 7

DC

COM

DC

COM

IN 0

IN 2

IN 4

IN 6

Common connected internally.

Publication 1762-UM001H-EN-P - June 2015

+DC (Sinking)

-DC (Sourcing)

-DC (Sinking)

+DC (Sourcing)

24V dc

Figure 3.23 1762-IQ16 Wiring Diagram

IN 1

IN 3

IN 5

IN 7

DC

COM 0

IN 0

IN 2

IN 4

IN 6

IN 8

IN 9

IN 11

IN 13

IN 15

IN 10

IN 12

IN 14

DC

COM 1

Wire Your Controller 3-19

24V dc

+DC (Sinking)

-DC (Sourcing)

-DC (Sinking)

+DC (Sourcing)

Publication 1762-UM001H-EN-P - June 2015

3-20 Wire Your Controller

Figure 3.24 1762-IQ32T Wiring Diagram

Publication 1762-UM001H-EN-P - June 2015

Figure 3.25 1762-OA8 Wiring Diagram

L1

L2

CR

OUT 0

OUT 2

VAC

0

OUT 1

OUT 3

CR

CR

CR

CR

VAC

1

OUT 5

OUT 6

OUT 7

OUT 4

CR

L1

L2

44920

Wire Your Controller 3-21

Figure 3.26 1762-OB8 Wiring Diagram

CR

CR

CR

CR

OUT 0

OUT 2

OUT 4

OUT 6

OUT 7

DC COM

+VDC

OUT 1

OUT 3

OUT 5

CR

CR

+DC

24V dc (source)

-DC

Figure 3.27 1762-OB16 Wiring Diagram

CR

CR

CR

CR

CR

CR

CR

CR

OUT 0

OUT 2

OUT 4

VDC+

OUT 1

OUT 3

OUT 5

OUT 6

OUT 7

OUT 8

OUT 9

OUT 10

OUT 11

OUT 12

OUT 13

OUT 15

OUT 14

DC COM

CR

CR

+DC

24V dc (source)

-DC

Publication 1762-UM001H-EN-P - June 2015

3-22 Wire Your Controller

Figure 3.28 1762-OB32T Wiring Diagram

Figure 3.29 1762-OV32T Wiring Diagram

44925

44915

Publication 1762-UM001H-EN-P - June 2015

Wire Your Controller 3-23

Figure 3.30 1762-OW8 Wiring Diagram

L1 VAC2 +

L2 DC2 COM

CR

OUT 0

VAC-VDC 1

OUT 1

OUT 2

OUT3

CR

CR

CR

CR

VAC-VDC2

OUT 4

OUT 5

OUT 6

OUT 7

CR

Figure 3.31 1762-OW16 Wiring Diagram

CR

CR

CR

OUT 0

VAC-VDC

0

OUT 1

OUT 2

OUT 3

OUT 4

OUT 5

OUT 6

OUT 7

CR

CR

CR

CR

CR

VAC-VDC

1

OUT 8

OUT 10

OUT 9

OUT 11

OUT 12

OUT 13

OUT 14

OUT 15

CR

CR

CR

CR

L1

L2

+DC

-DC

L1 VAC1 +

L2 DC1 COM

Publication 1762-UM001H-EN-P - June 2015

3-24 Wire Your Controller

Figure 3.32 1762-OX6I Wiring Diagram

L1-0

OUT0 N.C.

OUT0 N.O.

L1 OR +DC

CR

L2 OR -DC

L1 OR +DC

L2 OR -DC

L1-1

OUT1 N.O.

OUT1 N.C.

CR

L2 OR -DC

CR

L1 OR +DC

L2 OR -DC

CR

OUT2 N.C.

OUT2 N.O.

L1-2

L1-3

OUT3 N.C.

OUT3 N.O.

L1 OR +DC

L1 OR +DC

L2 OR -DC

L1-4

OUT4 N.O.

OUT4 N.C.

CR

CR

L1-5

OUT5 N.C.

OUT5 N.O.

L1 OR +DC

L2 OR -DC

Publication 1762-UM001H-EN-P - June 2015

Wire Your Controller 3-25

Figure 3.33 1762-IQ8OW6 Wiring Diagram

+DC (Sinking)

-DC (Sourcing)

+DC (Sinking)

-DC (Sourcing)

IN 1

IN 3

IN 4

IN 6

IN 7

DC

COM 1

IN 0

IN 2

DC

COM 0

IN 5

-DC (Sinking)

+DC (Sourcing)

-DC (Sinking)

+DC (Sourcing)

L1 or +DC

CR

VAC

VDC

OUT 0

OUT 2

OUT 4

VAC

VDC

OUT 1

OUT 3

OUT 5

Connected Internally

L1 or +DC

CR L2 or -DC

CR

CR

Analog Wiring

System Wiring Guidelines

Consider the following when wiring your analog modules:

The analog common (COM) is not connected to earth ground inside the module. All terminals are electrically isolated from the system.

Channels are not isolated from each other.

Use Belden 8761, or equivalent, shielded wire.

Under normal conditions, the drain wire (shield) should be connected to the metal mounting panel (earth ground). Keep the shield connection to earth ground as short as possible.

To ensure optimum accuracy for voltage type inputs, limit overall cable impedance by keeping all analog cables as short as possible. Locate the

I/O system as close to your voltage type sensors or actuators as possible.

The module does not provide loop power for analog inputs. Use a power supply that matches the input transmitter specifications.

Publication 1762-UM001H-EN-P - June 2015

3-26 Wire Your Controller

1762-IF2OF2 Input Type Selection

Select the input type, current or voltage, using the switches located on the module’s circuit board and the input type/range selection bits in the

Configuration Data File. Refer to MicroLogix 1200 and 1500 Programmable

Controllers Instruction Set Reference Manual, publication number

1762-RM001. You can access the switches through the ventilation slots on the top of the module. Switch 1 controls channel 0; switch 2 controls channel 1.

The factory default setting for both switch 1 and switch 2 is Current. Switch positions are shown below.

Switch Location

Ch0 Ch1

Voltage (OFF)

Current (ON) Default

1 2

1762-IF2OF2 Output Type Selection

The output type selection, current or voltage, is made by wiring to the appropriate terminals, Iout or Vout, and by the type/range selection bits in the

Configuration Data File. Refer to MicroLogix 1200 and 1500 Programmable

Controllers Instruction Set Reference Manual, publication number

1762-RM001.

ATTENTION

Analog outputs may fluctuate for less than a second when power is applied or removed. This characteristic is common to most analog outputs.

While the majority of loads will not recognize this short signal, it is recommended that preventive measures be taken to ensure that connected equipment is not affected.

Publication 1762-UM001H-EN-P - June 2015

Wire Your Controller 3-27

1762-IF2OF2 Wiring

The following illustration shows the 1762-IF2OF2 analog expansion I/O terminal block.

Figure 3.34 1762-IF2OF2 Terminal Block Layout

IN 0 (-)

IN 1 (-)

I Out 0

I Out 1

COM

COM

IN 0 (+)

IN 1 (+)

V Out 0

V Out 1

Common connected internally.

Figure 3.35 Differential Sensor Transmitter Types

Analog Sensor

Load

IN 0 (+)

IN 0 (-)

IN 1 (+)

IN 1 (-)

I out 0

I out 1

V out 0

V out 1

COM

COM

Publication 1762-UM001H-EN-P - June 2015

3-28 Wire Your Controller

Figure 3.36 Single-ended Sensor/Transmitter Types

2-Wire Transmitter

Power

Supply

(1)

+

-

Transmitter

+

-

Module

IN +

IN -

COM

3-Wire Transmitter

Power

Supply

(1)

+

-

Transmitter

Supply Signal

Module

IN +

IN -

COM

4-Wire Transmitter

Power

Supply

(1)

+

-

Transmitter

Supply Signal

+

-

+

-

Module

IN +

IN -

COM

(1) All power supplies rated N.E.C. Class 2.

1762-IF4 Input Type Selection

Select the input type, current or voltage, using the switches located on the module’s circuit board and the input type/range selection bits in the

Configuration Data File. Refer to MicroLogix 1200 and 1500 Programmable

Controllers Instruction Set Reference Manual, publication number

1762-RM001. You can access the switches through the ventilation slots on the top of the module.

Switch Location

Ch0 Ch1

1 2

Ch2 Ch3

Voltage (OFF)

1 2

Current (ON Default)

Publication 1762-UM001H-EN-P - June 2015

Wire Your Controller 3-29

Figure 3.37 1762-IF4 Terminal Block Layout

IN 0 (-)

IN 1 (-)

IN 2 (-)

IN 3 (-)

COM

COM

IN 0 (+)

IN 1 (+)

IN 2 (+)

IN 3 (+)

Commons internally connected.

Figure 3.38 Differential Sensor Transmitter Types

TIP

Analog Sensor

IN 0 (+)

IN 0 (-)

IN 1 (+)

IN 1 (-)

IN 2 (+)

IN 2 (-)

IN 3 (+)

IN 3 (-)

COM

COM

Grounding the cable shield at the module end only usually provides sufficient noise immunity.

However, for best cable shield performance, earth ground the shield at both ends, using a 0.01µF capacitor at one end to block AC power ground currents, if necessary.

Publication 1762-UM001H-EN-P - June 2015

3-30 Wire Your Controller

Figure 3.39 Sensor/Transmitter Types

2-Wire Transmitter

Power

+

Supply

(1)

-

Transmitter

+

-

Module

IN +

IN -

COM

3-Wire Transmitter

Power

Supply

(1)

+

-

Transmitter

Supply Signal

Module

IN +

IN -

COM

4-Wire Transmitter

Power

Supply

(1)

+

-

Transmitter

Supply

+

-

Signal

+

-

Module

IN +

IN -

COM

(1) All power supplies rated N.E.C. Class 2.

1762-OF4 Output Type Selection

The output type selection, current or voltage, is made by wiring to the appropriate terminals, Iout or Vout, and by the type/range selection bits in the

Configuration Data File.

1762-OF4 Terminal Block Layout

I out 0

I out 1

I out 2

I out 3

COM

COM

V out 0

V out 1

V out 2

V out 3

Commons connected internally

Publication 1762-UM001H-EN-P - June 2015

1762-OF4 Wiring

Current Load

Voltage Load

Wire Your Controller 3-31

I out 0

I out 1

I out 2

I out 3

V out 0

V out 1

V out 2

V out 3

COM

COM

Publication 1762-UM001H-EN-P - June 2015

3-32 Wire Your Controller

Notes:

Publication 1762-UM001H-EN-P - June 2015

Chapter

4

Communication Connections

Introduction

This chapter describes how to communicate to your control system. The method you use and cabling required to connect your controller depends on what type of system you are employing. This chapter also describes how the controller establishes communication with the appropriate network. Topics include:

• supported communication protocols

• default communication configurations

• using communications toggle push button

• connecting to RS-232 port

• connecting to DH-485 network

• connecting to AIC+

MicroLogix 1200 controllers with the additional communications port

(1762-L24AWAR, 1762-L24BWAR, 1762-L24BXBR, 1762-L40AWAR,

1762-L40BWAR, 1762-L40BXBR) offer advanced communications options, providing a clean, cost effective solution for applications requiring a network connection and HMI.

The additional communications port (Programmer/HMI Port) enables two communication devices to be connected to the controller simultaneously. For example, it provides local connectivity of an operator interface or programming terminal such as DF1 PanelView HMI, IBM-compatible personal computer using RSLogix 500 programming software, or 1747-PSD program storage device, and also allows the primary port (Channel 0) to be connected to either a network, a modem, or an ASCII device such as a barcode reader or weigh scale.

1

Supported Communication

Protocols

MicroLogix 1200 controllers support the following communication protocols from the primary RS-232 communication channel, Channel 0:

DH-485

DF1 Full-duplex

DF1 Half-duplex

DF1 Radio Modem

Modbus Master and Slave

ASCII

The 1762-L24AWAR, 1762-L24BWAR, 1762-L24BXBR, 1762-L40AWAR,

1762-L40BWAR, and 1762-L40BXBR controllers are equipped with an

Publication 1762-UM001H-EN-P - June 2015

4-2 Communication Connections additional RS-232 communication channel called the Programmer/HMI Port, which supports DH Full-duplex only. The controller cannot initiate messages through this port. It can only respond to messages sent to it. All communication parameters are fixed and cannot be changed by a user.

See Default Communication Configuration on page 4-2 for the configuration

settings.

For more information on MicroLogix 1200 communications, refer to the

MicroLogix 1200 and MicroLogix 1500 Programmable Controllers Instruction

Set Reference Manual, publication number 1762-RM001.

Default Communication

Configuration

The MicroLogix 1200 has the following default communication configuration.

The same default configuration is applied for both Channel 0 and the

Programmer/HMI Port (for 1762-LxxxxxR only). The configurations for the

Programmer/HMI Port are fixed and you cannot change them.

TIP

For Channel 0, the default configuration is present when:

The controller is powered-up for the first time.

The communications toggle push button specifies default communications (the DCOMM LED is on).

An OS upgrade is completed.

See Appendix E for more information about communicating.

Table 4.1 DF1 Full-duplex Default Configuration Parameters

Parameter

Baud Rate

Parity

Source ID (Node Address)

Control Line

Stop Bits

Default

19.2K

none

1 no handshaking

1

Publication 1762-UM001H-EN-P - June 2015

Communication Connections 4-3

Use the Communications

Toggle Push Button

The Communications toggle push button is located on the processor under the processor door (if installed), as shown below.

Use the Communications toggle push button to change from the user-defined communication configuration to the default communications mode and back on Channel 0. The parameters of the Programmer/HMI Port are fixed at the default communications configuration. The Default Communications

(DCOMM) LED operates to show when the controller is in the default

communications mode (settings shown on page 4-2).

0

1

COM

Communications toggle push button

0

1

COM

TIP

The Communications toggle push button must be pressed and held for one second to activate.

The Communications toggle push button only affects the communication configuration of Channel 0.

Publication 1762-UM001H-EN-P - June 2015

4-4 Communication Connections

Connect to the RS-232 Port

There are two ways to connect the MicroLogix 1200 programmable controller to your personal computer using the DF1 protocol: using a point-to-point connection, or using a modem. Descriptions of these methods follow.

ATTENTION

All devices connected to the RS-232 channel must be referenced to controller ground, or be floating (not referenced to a potential other than ground). Failure to follow this procedure may result in property damage or personal injury.

For 1762-L24BWA, 1762-L40BWA, 1762-L24BWAR and 1762-L40BWAR controllers:

The COM of the sensor supply is also connected to chassis ground internally. The 24V dc sensor power source should not be used to power output circuits. It should only be used to power input devices.

For 1762-L24BXB, 1762-L40BXB, 1762-L24BXBR and 1762-L40BXBR controllers:

The VDC NEUT or common terminal of the power supply is also connected to chassis ground internally.

Table 4.2 Available Communication Cables

Communication Cables

1761-CBL-PM02 series C or later

1761-CBL-HM02 series C or later

1761-CBL-AM00 series C or later

1761-CBL-AP00 series C or later

1761-CBL-PH02 series A or later

1761-CBL-AH02 series A or later

2707-NC8 series A or later

2707-NC9 series B or later

2707-NC10 series B or later

2707-NC11 series B or later

Length

2 m (6.5 ft)

2 m (6.5 ft)

45 cm (17.7 in)

45 cm (17.7 in)

2 m (6.5 ft)

2 m (6.5 ft)

2 m (6.5 ft)

15 m (49.2 ft)

2 m (6.5 ft)

2 m (6.5 ft)

Publication 1762-UM001H-EN-P - June 2015

Communication Connections 4-5

Make a DF1 Point-to-Point Connection

You can connect the MicroLogix 1200 programmable controller to your personal computer using a serial cable (1761-CBL-PM02) from your personal computer’s serial port to the controller via Channel 0 and/or the

Programmer/HMI Port (for 1762-LxxxxxR only). The recommended protocol for this configuration is DF1 Full-duplex.

We recommend using an Advanced Interface Converter (AIC+), catalog number 1761-NET-AIC, as your optical isolator, as shown on the following

page. See page 4-13 for specific AIC+ cabling information.

Personal Computer

MicroLogix 1200

Channel 0 or Programmer/HMI Port

1761-CBL-AM00 or 1761-CBL-HM02

(1)

TERM

A

B

COM

SHLD

CHS GND

TX TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

1747-CP3 or 1761-CBL-AC00

24V dc

MicroLogix 1200 provides power to the AIC+ or an external power supply may be used.

(1) Series C or higher cables are required.

Use a Modem

You can use modems to connect a personal computer to one MicroLogix 1200 controller (using DF1 Full-duplex protocol), to multiple controllers (using

DF1 Half-duplex protocol), or Modbus RTU Slave protocol via Channel 0, as

shown in the following illustration. (See Appendix E for information on types

of modems you can use with the micro controllers.

IMPORTANT

Do not attempt to use DH-485 protocol through modems under any circumstance.

Publication 1762-UM001H-EN-P - June 2015

4-6 Communication Connections

Personal Computer

Modem Cable

(straight-through)

Modem

MicroLogix 1200

Channel 0

Protocol Options

DF1 Full-duplex protocol (to 1 controller)

DF1 Half-duplex protocol (to multiple controllers)

Modbus RTU Slave protocol

Optical Isolator

(recommended)

TERM

COM

SHLD

CHS GND

TX TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

Modem

We recommend using an AIC+, catalog number 1761-NET-AIC, as your

optical isolator. See page 4-13 for specific AIC+ cabling information.

Isolated Modem Connection

Using an AIC+ to isolate the modem is illustrated below.

24V dc

MicroLogix 1200 provides power to the AIC+ or an external power

supply may be used. See Appendix F, System Loading and Heat

Dissipation.

MicroLogix 1200

Channel 0

TERM

A

B

COM

SHLD

CHS GND

TX TX

1761-CBL-AM00 or 1761-CBL-HM02

(1)

TX PWR

DC SOURCE

CABLE

EXTERNAL

User-supplied modem cable

Modem

(1) Series C or higher cables are required.

For additional information on connections using the AIC+, refer to the

Advanced Interface Converter (AIC+) User Manual, publication

1761-UM004.

Publication 1762-UM001H-EN-P - June 2015

Communication Connections 4-7

Construct Your Own Modem Cable

If you construct your own modem cable, the maximum cable length is

15.24 m (50 ft) with a 25-pin or 9-pin connector. Refer to the following typical pinout for constructing a straight-through cable:

8

7

1

4

6

3

2

5

DTE Device

(AIC+,

MicroLogix,

SLC, PLC)

9-Pin

TXD

RXD

GND

DCD

DTR

DSR

CTS

RTS

DCE Device

(Modem,

PanelView)

25-Pin 9-Pin

TXD 2 3

RXD 3

GND 7

DCD 8

DTR 20

DSR 6

CTS 5

RTS 4

8

7

1

4

6

2

5

Construct Your Own Null Modem Cable

If you construct your own null modem cable, the maximum cable length is

15.24 m (50 ft) with a 25-pin or 9-pin connector. Refer to the following typical pinout:

DTE Device

(AIC+,

MicroLogix,

SLC, PLC)

9-Pin

3

2

TXD

RXD

5 GND

1 DCD

8

7

4

6

DTR

DSR

CTS

RTS

TXD

RXD

GND

DCD

DTR

DSR

CTS

RTS

DCE Device

(Modem,

PanelView)

25-Pin 9-Pin

2

3

3

2

20

6

7

8

5

4

8

7

4

6

5

1

Publication 1762-UM001H-EN-P - June 2015

4-8 Communication Connections

Connect to a DF1 Half-duplex Network

Use the following diagram for DF1 Half-duplex Master-Slave protocol without hardware handshaking.

SLC 5/03 processor

CH0

COM

0

1

MicroLogix 1200

DF1

Master

(3)

(1)

CH0

(2)

1761-CBL-AM00 or 1761-CBL-HM02

(4)

1761-CBL-AP00 or 1761-CBL-PM02

(4)

DF1 Slave

(3) radio modem or lease line straight 9-25 pin cable

(1) straight 9-25 pin cable

MicroLogix 1200

CH0 to port 1 or port 2

DF1 Slave

(3)

(1)

COM

0

1

(2)

AIC+

1761-CBL-AP00 or

1761-CBL-PM02 to controller

1761-CBL-AM00 or

1761-CBL-HM02 to controller

(4) radio modem or lease line

(4)

CH0 to port 1 or port 2

DF1

Slave

(3)

(1)

(2)

AIC+

MicroLogix 1200

COM

0

1

(2)

AIC+

1761-CBL-AM00 or

1761-CBL-HM02 to controller

(4)

1761-CBL-AP00 or

1761-CBL-PM02 to controller

(4)

RS-485 DF1 Half-duplex

(1) DB-9 RS-232 port

(2) mini-DIN 8 RS-232 port

(3) RS-485 port

(4) Series C or higher cables are required.

RS-485 DF1 Half-duplex

Publication 1762-UM001H-EN-P - June 2015

Connect to a DH-485

Network

Communication Connections 4-9

The following illustration shows how to connect to a DH-485 network.

MicroLogix 1200

MicroLogix DH-485 Network

PC connection from port 1 or port 2 to MicroLogix Channel 0

1761-CBL-AM00

AIC+ or 1761-CBL-HM02

(4)

(3) (2)

TERM

COM

SHLD

CHS GND

TX TX

(1)

TX PWR

DC SOURCE

CABLE

EXTERNAL

24V dc

(user supply required if Port 2 is not connected to a controller)

(1) DB-9 RS-232 port

(2) mini-DIN 8 RS-232 port

(3) RS-485 port

(4) Series C or higher cables are required.

1761-CBL-AP00 or 1761-CBL-PM02

(4)

Belden, shielded, twisted-pair cable

(see table below)

1761-CBL-AP00 or 1761-CBL-PM02

PC to port 1 or port 2

(3)

AIC+

TERM

TX

COM

SHLD

CHS GND

TX

(2)

(1)

TX PWR

DC SOURCE

CABLE

EXTERNAL

1747-CP3 or 1761-CBL-AC00

24V dc

(user supplied)

Recommended Tools

To connect a DH-485 network, you need tools to strip the shielded cable and to attach the cable to the AIC+ Advanced Interface Converter. We recommend the following equipment (or equivalent):

Table 4.3 Working with Cable for DH-485 Network

Description Part Number

Shielded Twisted Pair Cable #3106A or #9842

Stripping Tool 45-164

1/8” Slotted Screwdriver Not Applicable

Manufacturer

Belden

Ideal Industries

Not Applicable

Publication 1762-UM001H-EN-P - June 2015

4-10 Communication Connections

DH-485 Communication Cable

The suggested DH-485 communication cable is either Belden #3106A or

#9842. The cable is jacketed and shielded with one or two twisted-wire pairs and a drain wire.

One pair provides a balanced signal line and one additional wire is used for a common reference line between all nodes on the network. The shield reduces the effect of electrostatic noise from the industrial environment on network communication.

The communication cable consists of a number of cable segments daisy-chained together. The total length of the cable segments cannot exceed

1219 m (4000 ft). However, two segments can be used to extend the DH-485 network to 2438 m (8000 ft). For additional information on connections using the AIC+, refer to the Advanced Interface Converter (AIC+) User Manual, publication 1761-UM004.

When cutting cable segments, make them long enough to route them from one

AIC+ to the next, with sufficient slack to prevent strain on the connector.

Allow enough extra cable to prevent chafing and kinking in the cable.

Use these instructions for wiring the Belden #3106A or #9842 cable. (See

Cable Selection Guide on page 4-13 if you are using standard Allen-Bradley

cables.)

Connect the Communication Cable to the DH-485 Connector

TIP

We recommend a daisy-chained network. Do not make the incorrect connection shown below:

Belden #3106A or #9842

Belden #3106A or

#9842

Belden #3106A or

#9842

Connector

Connector

Incorrect

Connector

Publication 1762-UM001H-EN-P - June 2015

Communication Connections 4-11

Single Cable Connection

When connecting a single cable to the DH-485 connector, use the following diagram.

Orange with White Stripes

6 Termination

5 A

White with Orange Stripes

Shrink Tubing Recommended

4 B

3 Common

2 Shield

Blue (#3106A) or

Blue with White

Drain Wire

1 Chassis Ground

Stripes (#9842)

Multiple Cable Connection

When connecting multiple cables to the DH-485 connector, use the following diagram.

to Previous Device

to Next Device

Table 4.4 Connections using Belden #3106A Cable

For This Wire/Pair Connect This Wire

Shield/Drain

Blue

White/Orange

Non-jacketed

Blue

White with Orange Stripe

Orange with White Stripe

To This Terminal

Terminal 2 - Shield

Terminal 3 - (Common)

Terminal 4 - (Data B)

Terminal 5 - (Data A)

Table 4.5 Connections using Belden #9842 Cable

For This Wire/Pair

Shield/Drain

Blue/White

White/Orange

Connect This Wire

Non-jacketed

White with Blue Stripe

Blue with White Stripe

White with Orange Stripe

Orange with White Stripe

To This Terminal

Terminal 2 - Shield

Cut back - no connection

(1)

Terminal 3 - (Common)

Terminal 4 - (Data B)

Terminal 5 - (Data A)

(1) To prevent confusion when installing the communication cable, cut back the white with blue stripe wire immediately after the insulation jacket is removed. This wire is not used by DH-485.

Publication 1762-UM001H-EN-P - June 2015

4-12 Communication Connections

Connect the AIC+

Publication 1762-UM001H-EN-P - June 2015

Ground and Terminate the DH-485 Network

Only one connector at the end of the link must have Terminals 1 and 2 jumpered together. This provides an earth ground connection for the shield of the communication cable.

Both ends of the network must have Terminals 5 and 6 jumpered together, as shown below. This connects the termination impedance (of 120 ohm) that is built into each AIC+ as required by the DH-485 specification.

End-of-Line Termination

Jumper

Jumper

Belden #3106A or #9842 Cable

1219 m (4000ft) Maximum

Jumper

The AIC+, catalog number 1761-NET-AIC, enables a MicroLogix 1200 to connect to a DH-485 network. The AIC+ has two RS-232 ports and one isolated RS-485 port. Typically, there is one AIC+ for each MicroLogix 1200.

When two MicroLogix controllers are closely positioned, you can connect a controller to each of the RS-232 ports on the AIC+.

The AIC+ can also be used as an RS-232 isolator, providing an isolation barrier between the MicroLogix 1200 communications port and any equipment connected to it (for example a personal computer or modem).

The following figure shows the external wiring connections and specifications of the AIC+.

3

AIC+ Advanced Interface Converter

(1761-NET-AIC)

2

4

1

5

Communication Connections 4-13

3

4

Item

1

2

Description

Port 1 - DB-9 RS-232, DTE

Port 2 - mini-DIN 8 RS-232 DTE

Port 3 - RS-485 Phoenix plug

DC Power Source selector switch

(cable = port 2 power source, external = external power source connected to item 5)

Terminals for external 24V dc power supply and chassis ground 5

For additional information on connecting the AIC+, refer to the Advanced

Interface Converter (AIC+) User Manual, publication 1761-UM004.

Cable Selection Guide

1761-CBL-AP00

(2)

1761-CBL-PH02

1761-CBL-PM02

(2)

Cable

1761-CBL-AP00

1761-CBL-PM02

1761-CBL-PH02

(2)

(2)

Length

45 cm (17.7 in)

2m (6.5 ft)

2m (6.5 ft)

Connections from

SLC 5/03 or SLC 5/04 processors, ch 0 port 2

MicroLogix 1000, 1200, or 1500 port 1

PanelView 550 through NULL modem adapter port 2

DTAM Plus / DTAM Micro

PC COM port port 2 port 2

to AIC+ External

Power Supply

Required

(1)

yes yes yes

Power

Selection

Switch

Setting

(1)

external external external yes yes external external

(1) External power supply required unless the AIC+ is powered by the device connected to port 2, then the selection switch should be set to cable.

(2) Series C or higher cables are required.

Publication 1762-UM001H-EN-P - June 2015

4-14 Communication Connections

1761-CBL-HM02

(1)

1761-CBL-AM00

(1)

1761-CBL-AH02

Table 4.6

Cable

1761-CBL-AM00

(1)

1761-CBL-HM02

(1)

1761-CBL-AH02

Length

45 cm (17.7 in)

2m (6.5 ft)

2m (6.5 ft)

Connections from

MicroLogix 1000, 1200, or 1500 to port 2 on another AIC+

to AIC+ External

Power Supply

Required

(2)

port 2 port 2 no yes

(1) Series C or higher cables are required.

(2) External power supply required unless the AIC+ is powered by the device connected to port 2, then the selection switch should be set to cable.

Power

Selection

Switch

Settings

cable external

1747-CP3

1761-CBL-AC00

Cable Length Connections from to AIC+ External

Power Supply

Required

(1)

port 1 yes

Power

Selection

Switch

Setting

(1)

external 1747-CP3

1761-CBL-AC00

(1)

3m (9.8 ft)

45 cm (17.7 in)

SLC 5/03 or SLC 5/04 processor, channel

0

PC COM port

PanelView 550 through NULL modem adapter

DTAM Plus / DTAM Micro

Port 1 on another AIC+ port 1 port 1 yes yes port 1 yes port 1 yes

(1) External power supply required unless the AIC+ is powered by the device connected to port 2, then the selection switch should be set to cable.

external external external external user-supplied cable

Cable Length Connections from to AIC+ External

Power Supply

Required

(1)

straight 9-25 pin — modem or other communication device port 1 yes

(1) External power supply required unless the AIC+ is powered by the device connected to port 2, then the selection switch should be set to cable.

Power

Selection

Switch

Setting

(1)

external

Publication 1762-UM001H-EN-P - June 2015

Communication Connections 4-15

1761-CBL-AS09

1761-CBL-AS03

Cable Length Connections from to AIC+ External

Power Supply

Required

(1)

port 3 yes

Power

Selection

Switch

Setting

(1)

external 1761-CBL-AS03

1761-CBL-AS09

3m (9.8 ft)

9.5m (31.17 ft)

SLC 500 Fixed,

SLC 5/01, SLC 5/02, and SLC 5/03 processors

PanelView 550 RJ45 port port 3 yes

(1) External power supply required unless the AIC+ is powered by the device connected to port 2, then the selection switch should be set to cable.

external

1761-CBL-PM02 Series C (or equivalent) Cable Wiring Diagram

3

2

5

4

1

7

6

9

8

Programming

Device

9-Pin D-Shell

RI

CTS

RTS

DSR

GND

DTR

TXD

RXD

DCD

Controller

8-Pin Mini Din

24V

GND

1

2

RTS

RXD

DCD

CTS

TXD

GND

7

8

5

6

3

4

Recommended User-supplied Components

These components can be purchased from your local electronics supplier.

Publication 1762-UM001H-EN-P - June 2015

4-16 Communication Connections

Table 4.7 User Supplied Components

Component Recommended Model

external power supply and chassis ground power supply rated for 20.4 to 28.8V dc

NULL modem adapter standard AT straight 9-25 pin RS-232 cable see table below for port information if making own cables

8

9

7

6

Port 1

DB-9 RS-232

1

2

5

3

4

1761-CBL-AP00 or 1761-CBL-PM02

Port 2 cable straight D connector

6 7 8

3

4

5

1 2

5

4

3

2

1

6

Port 3

RS-485 connector

Table 4.8 AIC+ Terminals

Pin Port 1: DB-9 RS-232

1 received line signal detector

(DCD)

2 received data (RxD)

3 transmitted data (TxD)

4

DTE ready (DTR)

(1)

5 signal common (GND)

6

DCE ready (DSR)

(1)

7 request to send (RTS)

8 clear to send (CTS)

9 not applicable

Port 2

(2)

: (1761-CBL-PM02 cable)

24V dc ground (GND) request to send (RTS) received data (RxD) received line signal detector

(DCD) clear to send (CTS)

(3) transmitted data (TxD) ground (GND) not applicable

(3)

Port 3: RS-485

Connector

chassis ground cable shield signal ground

DH-485 data B

DH-485 data A termination not applicable not applicable not applicable

(1) On port 1, pin 4 is electronically jumpered to pin 6. Whenever the AIC+ is powered on, pin 4 will match the state of pin 6.

(2) An 8-pin mini DIN connector is used for making connections to port 2. This connector is not commercially available. If you are making a cable to connect to port 2, you must configure your cable to connect to the

Allen-Bradley cable shown above.

(3) In the 1761-CBL-PM02 cable, pins 4 and 6 are jumpered together within the DB-9 connector.

Publication 1762-UM001H-EN-P - June 2015

Communication Connections 4-17

Safety Considerations

This equipment is suitable for use in Class I, Division 2, Groups A, B, C, D or non-hazardous locations only.

WARNING

EXPLOSION HAZARD

AIC+ must be operated from an external power source.

This product must be installed in an enclosure. All cables connected to the product must remain in the enclosure or be protected by conduit or other means.

See Safety Considerations on page 2-3 for additional information.

Install and Attach the AIC+

1. Take care when installing the AIC+ in an enclosure so that the cable connecting the MicroLogix 1200 controller to the AIC+ does not interfere with the enclosure door.

2. Carefully plug the terminal block into the RS-485 port on the AIC+ you are putting on the network. Allow enough cable slack to prevent stress on the plug.

3. Provide strain relief for the Belden cable after it is wired to the terminal block. This guards against breakage of the Belden cable wires.

Apply Power to the AIC+

In normal operation with the MicroLogix 1200 programmable controller connected to port 2 of the AIC+, the controller powers the AIC+. Any AIC+ not connected to a controller requires a 24V dc power supply. The AIC+ requires 120 mA at 24V dc.

If both the controller and external power are connected to the AIC+, the power selection switch determines what device powers the AIC+.

ATTENTION

If you use an external power supply, it must be

24V dc (-15%/+20%). Permanent damage results if a higher voltage supply is used.

Publication 1762-UM001H-EN-P - June 2015

4-18 Communication Connections

Set the DC Power Source selector switch to EXTERNAL before connecting the power supply to the AIC+. The following illustration shows where to connect external power for the AIC+.

Bottom View

24VDC

DC

NEUT

CHS

GND

ATTENTION

Always connect the CHS GND (chassis ground) terminal to the nearest earth ground. This connection must be made whether or not an external 24V dc supply is used.

Power Options

Below are two options for powering the AIC+:

Use the 24V dc user power supply built into the MicroLogix 1200 controller. The AIC+ is powered through a hard-wired connection using a communication cable (1761-CBL-HM02, or equivalent) connected to port 2.

Use an external DC power supply with the following specifications:

operating voltage: 24V dc (-15%/+20%)

output current: 150 mA minimum

rated NEC Class 2

Make a hard-wired connection from the external supply to the screw terminals on the bottom of the AIC+.

ATTENTION

If you use an external power supply, it must be 24V dc (-15%/+20%). Permanent damage results if miswired with the wrong power source.

Publication 1762-UM001H-EN-P - June 2015

1

Trim Pot Operation

Chapter

5

Use Trim Pots

The processor has two trimming potentiometers (trim pots) which allow modification of data within the controller. Adjustments to the trim pots change the value in the corresponding Trim Pot Information (TPI) register.

The data value of each trim pot can be used throughout the control program as timer, counter, or analog presets depending upon the requirements of the application.

The trim pots are located below the memory module port cover and to the right of the communications port, as shown below.

Trim Pot 0

Trim Pot 1

0

1

COM

Use a small flathead screwdriver to turn the trim pots. Adjusting their value causes data to change within a range of 0 to 250 (fully clockwise). The maximum rotation of each trim pot is three-quarters, as shown below. Trim pot stability over time and temperature is typically ±2 counts.

Minimum

(fully counterclockwise)

Maximum

(fully clockwise)

Trim pot file data is updated continuously whenever the controller is powered up.

Publication 1762-UM001H-EN-P - June 2015

5-2 Use Trim Pots

Trim Pot Information Function File

The composition of the Trim Pot Information (TPI) Function File is described in the MicroLogix 1200 and 1500 Programmable Controllers Instruction Set

Reference Manual, publication 1762-RM001.

Error Conditions

Error conditions of the TPI Function File are described in the MicroLogix

1200 and 1500 Programmable Controllers Instruction Set Reference Manual, publication 1762-RM001.

Publication 1762-UM001H-EN-P - June 2015

Chapter

6

Use Real-time Clock and Memory Modules

TIP

For more information on ‘Real-time Clock Function

File’ and ‘Memory Module Information File’ refer to the MicroLogix 1200 and 1500 Programmable

Controllers Instruction Set Reference Manual, publication 1762-RM001.

Three modules with different levels of functionality are available for use with the MicroLogix 1200 controller.

Catalog Number

1762-RTC

1762-MM1

1762-MM1RTC

Function

Real-time Clock

Memory Module

Memory Module and Real-time Clock

1

Real-time Clock Operation

The following sections cover:

Removal/Insertion Under Power

Write Data to the Real-time Clock

RTC Battery Operation

Removal/Insertion Under Power

At power-up and when the controller enters a run or test mode, the controller determines if a real-time clock module (RTC) is present. If an RTC is present, its values (date, time and status) are written to the RTC Function File in the controller.

The RTC module can be installed or removed at any time without risk of damage to either the module or the controller. If an RTC is installed while the

MicroLogix 1200 is in a run or test mode, the module is not recognized until either a power cycle occurs or until the controller is placed in a non-executing mode (program mode, suspend mode or fault condition).

Removal of the RTC during run mode is detected within one program scan.

Removal of the RTC while in run mode causes the controller to write zeros to the RTC Function File.

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6-2 Use Real-time Clock and Memory Modules

The following table indicates the accuracy of the RTC for various temperatures.

Table 6.1 RTC Accuracy

Ambient Temperature

0 °C (+32 °F)

+25 °C (+77 °F)

+40 °C (+104 °F)

+55 °C (+131 °F)

Accuracy

(1)

+34 … -70 seconds/month

+36 … -68 seconds/month

+29 … -75 seconds/month

-133 … -237 seconds/month

(1) These numbers are maximum worst case values over a 31-day month.

Write Data to the Real-time Clock

When valid data is sent to the real-time clock from the programming device or another controller, the new values take effect immediately.

The real-time clock does not recognize or accept invalid date or time data.

Use the Disable Clock button in your RSLogix programming software to disable the real-time clock before storing a module. This decreases the drain on the RTC battery during storage.

RTC Battery Operation

The real-time clock has an internal battery that is not replaceable. The RTC

Function File features a battery low indicator bit (RTC:0/BL), which shows the status of the RTC battery. When the battery is low, the indicator bit is set

(1). This means that the battery may fail within 14 days and the real-time clock module needs to be replaced. When the battery low indicator bit is clear (0), the battery level is acceptable or a real-time clock is not attached.

If the RTC battery is low and the controller is powered, the RTC operates normally. If the controller power is removed and the RTC battery is low, RTC data is lost.

Life Span

5 years

(1) Stored for six months.

Operating Temperature

0…40 °C (32 … 104 °F)

Storage Temperature

(1)

-40 … 60 °C (-40 … 140 °F)

Publication 1762-UM001H-EN-P - June 2015

Use Real-time Clock and Memory Modules 6-3

ATTENTION

Operating with a low battery indication for more than 14 days may result in invalid RTC data unless power is on continuously.

Memory Module Operation

The memory module supports the following features:

User Program and Data Back-up

User Program Compare

Data File Download Protection

Memory Module Write Protection

Removal/Insertion Under Power

ATTENTION

Electrostatic discharge can damage the Memory

Module. Do not touch the connector pins or other sensitive areas.

User Program and Data Back-up

The memory module provides a simple and flexible program/data transport mechanism, allowing the user to transfer the program and data to the controller without the use of a personal computer and programming software.

The memory module can store one user program at a time.

During program transfers to or from the memory module, the controller’s

RUN LED flashes.

Publication 1762-UM001H-EN-P - June 2015

6-4 Use Real-time Clock and Memory Modules

Program Compare

The memory module can also provide application security, allowing you to specify that if the program stored in the memory module does not match the program in the controller, the controller will not enter an executing (run or test) mode. To enable this feature, set the S:2/9 bit in the system status file. See

‘Status System File’ in the MicroLogix 1200 and 1500 Programmable

Controllers Instruction Set Reference Manual, Publication 1762-RM001 for more information.

Data File Download Protection

The memory module supports data file download protection. This allows user data to be saved (not overwritten) during a download.

TIP

Data file download protection is only functional if the processor does not have a fault, size of all protected data files in the memory module exactly match the size of protected data files within the controller, and all protected data files are of the same type. See

‘Protecting Data Files During Download’ in the

MicroLogix 1200 and 1500 Programmable Controllers

Instruction Set Reference Manual, publication

1762-RM001.

Memory Module Write Protection

The memory module supports write-once, read-many behavior. Write protection is enabled using your programming software.

IMPORTANT

Once set, write protection cannot be removed. A change cannot be made to the control program stored in a write protected memory module. If a change is required, use a different memory module.

Removal/Insertion Under Power

The memory module can be installed or removed at any time without risk of damage to either the memory module or the controller. If a memory module is installed while the MicroLogix 1200 is executing, the memory module is not recognized until either a power cycle occurs, or until the controller is placed in a non-executing mode (program mode, suspend mode or fault condition).

Publication 1762-UM001H-EN-P - June 2015

Appendix

A

Specifications

1

The 1762 specifications include:

Controller Specifications

Expansion I/O Specifications

Controller Specifications

Table A.1 General

Attribute

Dimensions

Shipping weight

Number of I/O

Power supply voltage

14 inputs and 10 outputs

100 … 240V ac

(-15%, +10%) at 47…63 Hz

15.2 W 15.7 W

120V ac: 25A for 8 ms

240V ac: 40A for 4 ms

24V dc

(-15%, +10%)

Class 2

SELV

17.0 W Heat dissipation

Power supply inrush current

Power supply usage

Power supply output

5V dc

24V dc

68VA

400 mA

350 mA

Sensor power output none

70VA

400 mA

350 mA

(1)

(1)

24V dc:

15A for 20 ms

27 W

400 mA

350 mA

Input circuit type 120V ac

250 mA at 24V dc

AC Ripple < 500 mV peak-to-peak

400 µF max.

(1) none

24V dc sink/source

Relay

24V dc sink/source

Relay/FET Output circuit type Relay

Temperature, operating 0…55 °C (32…131 °F) ambient

Temperature, storage -40…+85 °C (-40…185 °F) ambient

Operating humidity

Vibration

1762-

L24AWA

L24AWAR

L24BWA

L24BWAR

L24BXB

L24BXBR

Height: 90 mm, 104 mm (with DIN latch open)

Width: 110 mm

Depth: 87 mm

0.9 kg (2.0 lbs)

L40AWA

L40AWAR

L40BWA

L40BWAR

L40BXB

L40BXBR

Height: 90 mm, 104 mm (with DIN latch open)

Width: 160 mm

Depth: 87 mm

1.1 kg (2.4 lbs)

24 inputs, 16 outputs

100 … 240V ac

(-15%, +10%) at 47…63 Hz

21.0 W

120V ac: 25A for 8 ms

240V ac: 40A for 4 ms

80VA

600 mA

500 mA none

120V ac

Relay

5…95% relative humidity (non-condensing)

Operating: 10…500 Hz, 5G, 0.030 in. max. peak-to-peak, 2 hours each axis

Relay Operation: 1.5G

22.0 W

82VA

600 mA

(2)

500 mA

(2)

400 mA at 24V dc

AC Ripple < 500 mV peak-to-peak

400 µF max.

(2)

24V dc sink/source

Relay

24V dc

(-15%, +10%)

Class 2

SELV

27.9 W

24V dc:

15A for 30 ms

40 W

600 mA

500 mA none

24V dc sink/source

Relay/FET

Publication 1762-UM001H-EN-P - June 2015

A-2 Specifications

Table A.1 General

Attribute

Shock

Agency certification

Electrical/EMC

1762-

L24AWA

L24AWAR

L24BWA

L24BWAR

L24BXB

L24BXBR

L40AWA

L40AWAR

L40BWA

L40BWAR

Operating: 30G; 3 pulses each direction, each axis

Relay Operation: 7G

Non-Operating: 50G panel mounted (40G DIN Rail mounted); 3 pulses each direction, each axis

UL 508

C-UL under CSA C22.2 no. 142

Class I, Div. 2, Groups A, B, C, D

(UL 1604, C-UL under CSA C22.2 no. 213)

CE/RCM/EAC compliant for all applicable directives

The controller has passed testing at the following levels:

L40BXB

L40BXBR

EN 61000-4-2: 4 kV contact, 8 kV air, 4 kV indirect

EN 61000-4-3: 10V/m, 80 to 1000 MHz, 80% amplitude modulation, +900 MHz keyed carrier

EN 61000-4-4: 2 kV, 5 kHz; communications cable: 1 kV, 5 kHz

EN 61000-4-5: communications cable 1 kV galvanic gun

I/O: 2 kV CM (common mode), 1 kV DM (differential mode)

AC Power Supply: 4 kV CM (common mode), 2 kV DM (differential mode)

DC Power Supply: 500V CM (common mode), 500V DM (differential mode)

EN 61000-4-6: 10V, communications cable 3V

Terminal screw torque 0.791 Nm (7 in-lb) rated

(1) Do not allow the total load power consumed by the 5V dc, 24V dc, and sensor power outputs to exceed 12W.

(2) Do not allow the total load power consumed by the 5V dc, 24V dc, and sensor power outputs to exceed 16W.

See Appendix F for system validation worksheets.

Table A.2 Input Specifications

Attribute

On-state voltage range

Off-state voltage range

Operating frequency

On-state current:

• minimum

• nominal

• maximum

1762-L24AWA

1762-L40AWA

1762-L24AWAR

1762-L40AWAR

79…132V ac

0…20V ac

47…63 Hz

5.0 mA at 79V ac

12 mA at 120V ac

16.0 mA at 132V ac

1762-L24BWA, -L24BXB, -L40BWA, -L40BXB

1762-L24BWAR, -L24BXBR, -L40BWAR, -L40BXBR

Inputs 0 through 3 Inputs 4 and higher

14…24V dc

(+10% at 55 °C/131 °F)

(+25% at 30 °C/86 °F)

0…5V dc

0 Hz…20 kHz

10…24V dc

(+10% at 55 °C/131 °F)

(+25% at 30 °C/86 °F)

0 Hz…1 kHz

(scan time dependent)

2.5 mA at 14V dc

7.3 mA at 24V dc

12.0 mA at 30V dc

2.0 mA at 10V dc

8.9 mA at 24V dc

12.0 mA at 30V dc

Publication 1762-UM001H-EN-P - June 2015

Specifications A-3

Table A.2 Input Specifications

Attribute

Off-state leakage current

Nominal impedance

Inrush current (max.) at 120V ac

1762-L24AWA

1762-L40AWA

1762-L24AWAR

1762-L40AWAR

2.5 mA max.

12 k

Ω

at 50 Hz

10 k

Ω

at 60 Hz

250 mA

1762-L24BWA, -L24BXB, -L40BWA, -L40BXB

1762-L24BWAR, -L24BXBR, -L40BWAR, -L40BXBR

Inputs 0 through 3 Inputs 4 and higher

1.5 mA min.

3.3 k

Ω

2.7 k

Ω

Not Applicable

Table A.3 Output Specifications - General

Attribute 1762-

L24AWA

L24BWA

L24AWAR

L24BWAR

L24BXB

L24BXBR

L40AWA

L40BWA

L40AWAR

L40BWAR

Relay and FET Outputs

Controlled load, max.

Continuous current, max.

Current per group common

Current per controller at 150V max at 240V max

1440VA – 1440VA

8 A 7.5 A 8 A

30 A or total of per-point loads, whichever is less

20 A or total of per-point loads, whichever is less

Relay Outputs

Turn on time/Turn off time

Relay life - Electrical

Relay life - Mechanical

Load current

(1) scan time dependent

10 msec (minimum)

(1)

Refer to Relay Life Chart

20,000,000 cycles

10 mA (minimum)

Table A.4 Relay Contact Ratings

Maximum Volts Amperes

240V ac

Make

7.5A

120V ac

125V dc

24V dc

15A

0.22A

(2)

1.2A

(2)

Break

0.75A

1.5A

Amperes

Continuous

2.5A

(1)

2.5A

(1)

1.0A

2.0A

Volt-Amperes

Make

1800 VA

1800 VA

28 VA

Break

180 VA

180 VA

(1) 1.5A above 40°C.

(2) For dc voltage applications, the make/break ampere rating for relay contacts can be determined by dividing 28 VA by the applied dc voltage. For example, 28 VA/48V dc = 0.58A. For dc voltage applications less than 14V, the make/break ratings for relay contacts cannot exceed 2A.

L40BXB

L40BXBR

1440VA

8 A

Publication 1762-UM001H-EN-P - June 2015

A-4 Specifications

ATTENTION

Do not exceed the "Current per group common" specification.

Relay Life Chart

300

200

100

50

30

20

10

5

3

2

240VAC COSφ 0.4

30VDC/240VAC resistive

0.1 0.2 0.3 0.5

1 2 3 5

Switching capacity(A)

Publication 1762-UM001H-EN-P - June 2015

Specifications A-5

Table A.5 BXB FET Output Specifications

Attribute General Operation

High Speed Operation

(1)

(Output 2 Only)

Power supply voltage

On-state voltage drop:

• at maximum load current

• at maximum surge current

Current rating per point

• maximum load

• minimum load

• maximum leakage

Maximum output current (temperature dependent):

24V dc (-15%, +10%)

1V dc

2.5V dc

See graphs below.

1.0 mA

1.0 mA

Not Applicable

Not Applicable

100 mA

10 mA

1.0 mA

2.0

1.75

1.5

1.25

1.0

0.75

0.5

0.25

FET Current per Point

(1762-L24BXB, L40BXB

1762-L24BXBR, L40BXBR)

1.5A, 30˚C (86˚F)

Valid

Range

1.0A, 55˚C (131˚F)

9.0

8.0

7.0

6.0

5.0

4.0

3.0

2.0

1.0

FET Total Current

(1762-L40BXB and L40BXBR)

8A, 30˚C (86˚F)

Valid

Range

5.5A, 55˚C (131˚F)

10˚C

(50˚F)

30˚C

(86˚F)

50˚C

(122˚F)

Temperature

70˚C

(158˚F)

10˚C

(50˚F)

30˚C

(86˚F)

50˚C

(122˚F)

Temperature

70˚C

(158˚F)

Surge current per point:

• peak current

• maximum surge duration

• maximum rate of repetition at 30 °C (86 °F)

• maximum rate of repetition at 55 °C (131 °F)

Turn-on time, max.

Turn-off time, max.

Repeatability, max.

Drift, max.

n/a n/a

4.0A

10 ms

• once every second

• once every 2 seconds

0.1 ms

1.0 ms

6 µs

18 µs

2 µs

Not applicable

Not applicable

Not applicable

Not applicable

1 µs per 5 °C (41 °F)

(1) Output 2 is designed to provide increased functionality over the other FET outputs. Output 2 may be used like the other FET transistor outputs, but in addition, within a limited current range, it may be operated at a higher speed. Output 2 also provides a pulse train output (PTO) or pulse width modulation output (PWM) function.

Publication 1762-UM001H-EN-P - June 2015

A-6 Specifications

Table A.6 AC Input Filter Settings

Nominal Filter Setting (ms) ON Delay (ms)

Minimum Maximum

8 2 20

OFF Delay (ms)

Minimum Maximum

10 20

Table A.7 Fast DC Input Filter Settings (Inputs 0 to 3)

Nominal Filter Setting (ms) ON Delay (ms)

0.025

OFF Delay (ms)

Minimum Maximum Minimum Maximum

0.005

0.025

0.005

0.025

0.075

0.100

0.250

0.500

0.040

0.050

0.170

0.370

0.075

0.100

0.250

0.500

0.045

0.060

0.210

0.330

0.075

0.100

0.250

0.500

1.00

2.000

4.000

8.000

(1)

16.000

0.700

1.700

3.400

6.700

14.000

1.000

2.000

4.000

8.000

16.000

0.800

1.600

3.600

7.300

14.000

1.000

2.000

4.000

8.000

16.000

(1) This is the default setting.

Maximum Counter Frequency (Hz)

50% Duty Cycle

20.0 kHz

6.7 kHz

5.0 kHz

2.0 kHz

1.0 kHz

0.5 kHz

250 Hz

125 Hz

63 Hz

31 Hz

Table A.8 Normal DC Input Filter Settings (Inputs 4 and higher)

Nominal Filter Setting (ms) ON Delay (ms) OFF Delay (ms)

Minimum Maximum Minimum Maximum

0.500

0.090

0.500

0.020

0.500

1.000

2.000

0.500

1.100

1.000

2.000

0.400

1.300

1.000

2.000

4.000

8.000

(1)

16.000

2.800

5.800

11.000

4.000

8.000

16.000

2.700

5.300

10.000

4.000

8.000

16.000

(1) This is the default setting.

Maximum Frequency (Hz)

50% Duty Cycle

1.0 kHz

0.5 kHz

250 Hz

125 Hz

63 Hz

31 Hz

Publication 1762-UM001H-EN-P - June 2015

Specifications A-7

Table A.9 Working Voltage (1762-L24AWA, 1762-L40AWA)

Attribute

Input group to backplane isolation

1762-L24AWA, 1762-L40AWA, 1762-L24AWAR, 1762-L40AWAR

Power supply input to backplane isolation Verified by one of the following dielectric tests: 1836V ac for 1 second or 2596V dc for 1 second

265V ac Working Voltage (IEC Class 2 reinforced insulation)

Verified by one of the following dielectric tests:1517V ac for 1 second or 2145V dc for 1 second

132V ac Working Voltage (IEC Class 2 reinforced insulation)

Input group to input group isolation

Output group to backplane isolation

Verified by one of the following dielectric tests:1517V ac for 1 second or 2145V dc for 1 second

132V ac Working Voltage (basic insulation)

Verified by one of the following dielectric tests: 1836V ac for 1 second or 2596V dc for 1 second

265V ac Working Voltage (IEC Class 2 reinforced insulation)

Output group to output group isolation Verified by one of the following dielectric tests: 1836V ac for 1 second or 2596V dc for 1second

265V ac Working Voltage (basic insulation) 150V ac Working Voltage (IEC Class 2 reinforced insulation).

Table A.10 Working Voltage (1762-L24BWA, 1762-L40BWA, 1762-L24BWAR, 1762-L40BWAR)

Attribute 1762-L24BWA, 1762-L40BWA, 1762-L24BWAR, 1762-L40BWAR

Power supply input to backplane isolation Verified by one of the following dielectric tests:1836V ac for 1 second or 2596V dc for 1 second

Input group to backplane isolation and input group to input group isolation

265V ac Working Voltage (IEC Class 2 reinforced insulation)

Verified by one of the following dielectric tests: 1200V ac for 1 second or 1697V dc for 1 second

Output group to backplane isolation

75V dc Working Voltage (IEC Class 2 reinforced insulation)

Verified by one of the following dielectric tests: 1836V ac for 1 second or 2596V dc for 1 second

Output group to output group isolation

265V ac Working Voltage (IEC Class 2 reinforced insulation).

Verified by one of the following dielectric tests: 1836V ac for 1 second or 2596V dc for 1 second

265V ac Working Voltage (basic insulation) 150V Working Voltage (IEC Class 2 reinforced insulation)

Table A.11 Working Voltage (1762-L24BXB, 1762-L40BXB, 1762-L24BXBR, 1762-L40BXBR)

Attribute

Input group to backplane isolation and input group to input group isolation

1762-L24BXB, 1762-L40BXB, 1762-L24BXBR, 1762-L40BXBR

Verified by one of the following dielectric tests: 1200V ac for 1 second or 1697V dc for 1 second

75V dc Working Voltage (IEC Class 2 reinforced insulation)

FET output group to backplane isolation Verified by one of the following dielectric tests: 1200V ac for 1 second or 1697V dc for 1 second

Relay output group to backplane isolation

75V dc Working Voltage (IEC Class 2 reinforced insulation)

Verified by one of the following dielectric tests: 1836V ac for 1 second or 2596V dc for 1 second

Relay output group to relay output group and FET output group isolation

265V ac Working Voltage (IEC Class 2 reinforced insulation).

Verified by one of the following dielectric tests: 1836V ac for 1 second or 2596V dc for 1 second

265V ac Working Voltage (basic insulation) 150V Working Voltage (IEC Class 2 reinforced insulation)

Publication 1762-UM001H-EN-P - June 2015

A-8 Specifications

Expansion I/O

Specifications

Discrete I/O Modules

Table A.12 General Specifications

Attribute

Dimensions

Value

90 mm (height) x 87 mm (depth) x 40.4 mm (width) height including mounting tabs is 110 mm

Temperature, storage

Temperature, operating

Operating humidity

Operating altitude

Vibration

Shock

Agency certification

Hazardous environment class

3.54 in. (height) x 3.43 in. (depth) x 1.59 in. (width) height including mounting tabs is 4.33 in.

-40…85 °C (-40…185 °F)

-20…65 °C (-4…149 °F)

(1)

5…95% non-condensing

2000 m (6561 ft)

Operating: 10…500 Hz, 5G, 0.030 in. max. peak-to-peak,

2 hours per axis

Relay Operation: 1.5G

Operating: 30G panel mounted, 3 pulses per axis

Relay Operation: 7G

Non-Operating: 50G panel mounted, 3 pulses per axis

(40G DIN Rail mounted)

C-UL certified (under CSA C22.2 No. 142)

UL 508 listed

CE compliant for all applicable directives

C-Tick marked for all applicable acts

For 1762-IQ32T, 1762-OB32T, and 1762-OV32T modules

Hazardous Location, Class I, Division 2 Groups A, B, C, D (UL 1604, C-UL under CSA C22.2 No. 213,

ANSI/ISA-12.12.01)

For all other modules:

Hazardous Location, Class I, Division 2 Groups A, B, C, D (UL 1604, C-UL under CSA C22.2 No. 213) for all modules

Radiated and conducted emissions EN50081-2 Class A

Electrical /EMC:

ESD immunity

The module has passed testing at the following levels:

For 1762-IQ32T, 1762-OB32T, and 1762-OV32T modules

IEC61000-4-2: 4 kV contact, 8 kV air, 4 kV indirect

Radiated RF immunity

(IEC1000-4-3)

For all other modules:

IEC1000-4-2: 4 kV contact, 8 kV air, 4 kV indirect

For 1762-IQ32T, 1762-OB32T, and 1762-OV32T modules

IEC61000-4-3: 10V/m, 80…2700 MHz, 80% amplitude modulation

For all other modules:

IEC1000-4-3: 10 V/m, 80…1000 MHz, 80% amplitude modulation, +900 MHz keyed carrier for all modules

Publication 1762-UM001H-EN-P - June 2015

Specifications A-9

Table A.12 General Specifications

Attribute

EFT/B immunity

Value

For 1762-IQ32T, 1762-OB32T, and 1762-OV32T modules

IEC61000-4-4: 2 kV, 5 kHz on signal ports

Surge transient immunity

Conducted RF immunity

For all other modules

IEC1000-4-4: 2 kV, 5 kHz

For 1762-IQ32T, 1762-OB32T, and 1762-OV32T modules

IEC61000-4-5: 2 kV common mode, 1 kV differential mode

For all other modules

IEC1000-4-5: 2 kV common mode, 1 kV differential mode

For 1762-IQ32T, 1762-OB32T, and 1762-OV32T modules

IEC61000-4-6: 10V, 0.15…80 MHz

(2)

For all other modules:

IEC1000-4-6: 10V, 0.15…80 MHz

(2)

(1) For the exact operating temperature range, refer to the Installation Instructions publication for the specific module.

(2) Conducted Immunity frequency range may be 150 kHz to 30 MHz if the Radiated Immunity frequency range is 30…1000 MHz.

Table A.13 Input Specifications

Attribute Value

1762-IA8

209 g (0.46 lbs.) Shipping weight, approx.

(with carton)

Voltage category 100/120V ac

1762-IQ8

200 g (0.44 lbs.)

1762-IQ16

230 g (0.51 lbs.)

1762-IQ32T

200g (0.44 lbs.)

Operating voltage range

Number of inputs

Bus current draw, max.

Heat dissipation, max.

Signal delay, max.

Off-state voltage, max.

Off-state current, max.

On-state voltage, min.

79…132V ac at

47…63 Hz

24V dc (sink/source)

10…30V dc at 30 °C

(86 °F)

10…26.4V dc at 55 °C

(131 °F)

(1) 24V dc

(sink/source)<secondary footnote>(1)

10…30V dc

10…26.4V dc )

(3)(2)

8 8 16

50 mA at 5V dc (0.25 W) 50 mA at 5V dc (0.25 W) 70 mA at 5V dc

(0.35 W)

(3)

2.0 W

On delay: 20.0 ms

Off delay: 20.0 ms

20V ac

2.5 mA

79V ac (min.)

132V ac (max.)

3.7 W

On delay: 8.0 ms

Off delay: 8.0 ms

5V dc

1.5 mA

10V dc

4.3 W at 26.4V

5.4 W at 30V

(3)

On delay: 8.0 ms

Off delay: 8.0 ms

5V dc

1.5 mA

10V dc

24V dc

(sink/source)

(1)

10…30V dc (24 points) at

30 °C (86 °F)

10…26.4V dc

(23 points)at 60 °C

(140 °F)

32

170 mA at 5V dc

0 mA at 24V dc

5.4 W at 26.4V dc

6.8 W at 30V dc

On delay: 8.0 ms

Off delay: 8.0 ms

5V dc

1.0 mA

10V dc

Publication 1762-UM001H-EN-P - June 2015

A-10 Specifications

Table A.13 Input Specifications

Attribute

On-state current, min.

On-state current, nom.

On-state current, max.

Inrush current, max.

Nominal impedance

Value

1762-IA8 1762-IQ8

5.0 mA at 79V ac 47 Hz 2.0 mA at 10V dc

1762-IQ16

2.0 mA at 10V dc

8.0 mA at 24V dc

12.0 mA at 30V dc

-

1762-IQ32T

1.6 mA at 10V dc

2.0 mA at 15V dc

12.0 mA at 120V ac 60 Hz 8.0 mA at 24V dc

16.0 mA at 132V ac 63 Hz 12.0 mA at 30V dc 5.7 mA at 26.4V dc

6.5 mA at 30.0V dc

250 mA

12K

Ω

at 50 Hz

10K

Ω

at 60 Hz

Not applicable

3K

Ω

Not applicable

3K

Ω

6 (The module may not be located more than 6 modules away from the power supply.)

Not applicable

4.7K

Ω

Power supply distance rating

IEC input compatibility

Isolated groups

Type 1+

Group 1: inputs 0 to 7

(internally connected commons)

Type 1+

Group 1: inputs 0 to 7

(internally connected commons)

Type 1+

Group 1: inputs 0 to 7;

Group 2: inputs 8 to 15

Input group to backplane isolation

Verified by one of the following dielectric tests:

1517V ac for 1 s or

2145V dc for 1 s.

132V ac working voltage

(IEC Class 2 reinforced insulation)

Verified by one of the following dielectric tests:

1200V ac for 1 s or 1697V dc for 1 s.

75V dc working voltage (IEC Class 2 reinforced insulation)

Type 1

Group 1: Inputs 0…7;

Group 2: Inputs 8…15;

Group 3: Inputs 16…23;

Group 4: Inputs 24…31

Verified by one of the following dielectric tests:

1200V ac for 2 s or

1697V dc for 2 s

75V dc working voltage

(IEC Class 2 reinforced insulation)

Vendor I.D. code

Product type code

Product code

1

7

114 96 97 99

(1) Sinking/Sourcing Inputs - Sourcing/sinking describes the current flow between the I/O module and the field device. Sourcing I/O circuits supply (source) current to sinking field devices. Sinking I/O circuits are driven by a current sourcing field device. Field devices connected to the negative side (DC Common) of the field power supply are sinking field devices. Field devices connected to the positive side (+V) of the field supply are sourcing field devices.

(2) Refer to Publication 1762-IN10 , MicroLogix 1762-IQ16 DC Input Module Installation Instructions, for the derating chart.

(3) Only applicable to Series B I/O modules.

Table A.14 Output Specifications

Specification

Shipping weight, approx.

(with carton)

Voltage category

1762-OA8

215 g (0.48 lbs.)

100…240V ac

Operating voltage range 85…265V ac at 47 to 63

Hz

Number of outputs 8

1762-OB8

210 g (0.46 lbs.)

24V dc

20.4…26.4V dc

8

Publication 1762-UM001H-EN-P - June 2015

1762-OB16

235 g (0.52 lbs.)

24V dc

20.4…26.4V dc

16

1762-OB32T

200 g (0.44 lbs.)

24V dc source

10.2…26.4V dc

32

Specifications A-11

Table A.14 Output Specifications

Specification

Bus current draw, max.

Heat dissipation, max.

On-state current, min.

On-state voltage drop, max.

Continuous current per point, max.

Continuous current per common, max.

Continuous current per module, max.

Surge current, max.

Power supply distance rating

Isolated groups

Output group to backplane isolation

1762-OA8

115 mA at 5V dc

(0.575 W)

2.9 W

Signal delay, max. – resistive load

On delay: 1/2 cycle

Off delay: 1/2 cycle

Off-state leakage, max.

2 mA at 132V,

2.5 mA at 265V

10 mA

1.5V at 0.5 A

0.25 A at 55 °C (131 °F)

0.5 A at 30 °C (86 °F)

1.0 A at 55 °C (131 °F)

2.0 A at 30 °C (86 °F)

2.0 A at 55°C (131°F)

4.0 A at 30°C (86°F)

5.0 A (Repeatability is once every 2 seconds for a duration of 25 ms.)

Group 1:

Outputs 0 to 3

Group 2:

Outputs 4 to 7

Verified by one of the following dielectric tests:

1836V ac for 1 s or 2596V dc for 1 s.

1762-OB8

115 mA at 5V dc (0.575

W)

1.61 W

On delay: 0.1 ms

Off delay: 1.0 ms

1.0 mA

1.0 mA

1.0V dc

0.5 A at 55 °C (131 °F)

1.0 A at 30°C (86 °F)

4.0A at 55°C (131 °F)

8.0A at 30°C (86°F)

4.0 A at 55°C;

8.0 A at 30°C

2.0A (Repeatability is once every 2 seconds at

55 °C (131 °F), once every second at 30 °C (86 °F) for a duration of 10 ms.)

Group 1:

Outputs 0 to 7

75V dc working voltage (IEC Class 2 reinforced insulation)

1762-OB16

2.9 W at 30 °C (86 °F)

2.1 W at 55 °C (131 °F)

1762-OB32T

175 mA at 5V dc (0.88 W) 175 mA at 5V dc

0 mA at 24V dc

3.4 W at 26.4 dc

On delay: 0.1 ms

Off delay: 1.0 ms

1.0 mA

1.0 mA

1.0V dc

0.5 A at 55°C (131 °F)

1.0 A at 30°C (86 °F)

4.0 A at 55°C (131 °F)

8.0 A at 30°C (86 °F)

4.0 A at 55°C (131 °F)

8.0 A at 30°C (86 °F)

2.0A (Repeatability is once every 2 seconds at

55 °C (131 °F), once every second at 30 °C (86 °F) for a duration of 10 ms.)

6 (The module may not be more than 6 modules away from the power supply.)

Group 1:

Outputs 0 to 15

Verified by one of the following dielectric tests:

1200V ac for 1 s or 1697V dc for 1 s.

On delay: 0.5 ms

Off delay: 4.0 ms

0.1 mA at 26.4V dc

1.0 mA

0.3V dc at 0.5 A

0.5 A at 60 °C (140 °F)

2.0 A at 60 °C (140 °F)

4.0 A at 60 °C (140 °F)

2.0 A (Repeatability is once every 2 s at 60 °C

(140 °F) for 10 ms.)

Group 1: Outputs 0…15

Group 2: Outputs 16…31

(internally connected to common)

Verified by one of the following dielectric tests:

1200V ac for 2 s or 1697V dc for 2 s.

Output group to output group isolation

265V ac working voltage

(IEC Class 2 reinforced insulation)

Verified by one of the following dielectric tests:

1836V ac for 1 s or 2596V dc for 1 s.

Not applicable

75V dc working voltage

(IEC Class 2 reinforced insulation)

Verified by one of the following dielectric tests:

1200V ac for 2 s or 1697V dc for 2 s.

265V ac working voltage

(IEC Class 2 reinforced insulation)

75V dc working voltage

(IEC Class 2 reinforced insulation)

Publication 1762-UM001H-EN-P - June 2015

A-12 Specifications

Table A.14 Output Specifications

Specification

Vendor I.D. code

Product type code

Product code

1762-OA8

1

7

119

1762-OB8

101

1762-OB16

103

1762-OB32T

100

Table A.15 Output Specifications

Specification

Shipping weight, approx.

(with carton)

Voltage category

Operating voltage range

Number of outputs

Bus current draw, max.

1762-OV32T

200 g (0.44 lbs.)

24V dc sink

10.2…26.4V dc

32

175 mA at 5V dc

0 mA at 24V dc

1762-OW8

228 g (0.50 lbs.)

AC/DC normally open relay

5…265V ac

5…125V dc

8

80 mA at 5V dc (0.40 W)

90 mA at 24V dc (2.16 W)

1762-OW16

285 g (0.63 lbs.)

AC/DC normally open relay

5…265V ac

5…125V dc

16

140 mA at 5V dc (0.70 W)

180 mA at 24V dc

(4.32 W)

(1)

1762-OX6I

220 g (0.485 lbs)

AC/DC Type C Relay

5…265V ac

5…125V dc

6

110 mA at 5V dc (0.55 W)

110 mA at 24V dc

(2.64 W)

Heat dissipation, max.

Signal delay, max. – resistive load

Off-state leakage, max.

0.1 mA at 26.4V dc

On-state current, min.

1.0 mA

0.3V dc at 0.5A

On-state voltage drop, max.

Continuous current per point, max.

0.5A at 60 °C (140 °F)

Continuous current per common, max.

Continuous current per module, max.

Surge current, max.

Power supply distance rating

2.7 W at 26.4V dc

On delay: 0.5 ms

Off delay: 4.0 ms

2.9 W

On delay: 10 ms

Off delay: 10 ms

0 mA

10 mA

Not applicable

6.1 W

(1)

On delay: 10 ms

Off delay: 10 ms

0 mA

10 mA

Not applicable

2.8 W

On delay:

10 ms (max)

6 ms (typical)

Off Delay:

20 ms (max)

12 ms (typical)

0 mA

100 mA

Not applicable

2.0 A at 60 °C (140 °F)

4.0 A at 60 °C (140 °F)

2.0 A (Repeatability is once every 2 s at 60 °C

(140 °F) for 10 ms)

2.5 A (Also see “Relay Contact Ratings” on page A-3.) 7A (Also see “Relay

Contact Ratings” on

page A-3.)

8 A 8A 7A (Also see “Relay

Contact Ratings” on

page A-3.)

16 A 16A

See “Relay Contact Ratings” on page A-3

6 (The module may not be more than 6 modules away from the power supply.)

30A (Also see Module

Load Ratings 1762-OX6I on page A-14.

See “Relay Contact

Ratings” on page A-3.

Publication 1762-UM001H-EN-P - June 2015

Specifications A-13

Table A.15 Output Specifications

Specification

Isolated groups

Output group to backplane isolation

1762-OV32T

Group 1: Outputs 0…15

1762-OW8

Group 1: Outputs 0 to 3

Group 2: Outputs 4 to 7

1762-OW16

Group 1: Outputs 0 to 7

Group 2: Outputs 8 to 15

1762-OX6I

All 6 Outputs Individually

Isolated.

Group 2: Outputs 16…31

(internally connected to common)

Verified by one of the following dielectric tests:

1200V ac for 2 s or 1697V dc for 2 s.

Verified by one of the following dielectric tests: 1836V ac for 1 s or 2596V dc for

1 s.

265V ac working voltage (IEC Class 2 reinforced insulation)

Output group to output group isolation

Vendor I.D. code

Product type code

Product code

75V dc working voltage

(IEC Class 2 reinforced insulation)

Verified by one of the following dielectric tests:

1200V ac for 2 s or 1697V dc for 2 s.

Verified by one of the following dielectric tests: 1836V ac for 1 s or 2596V dc for

1 s.

265V ac working voltage (basic insulation)

150V ac working voltage (IEC Class 2 reinforced insulation)

75V dc working voltage

(IEC Class 2 reinforced insulation)

1

7

102

(1) Only applicable to Series B I/O modules.

120 121 124

Table A.16 Relay Contact Ratings (1762-OW8 and 1762-OW16)

Maximum Volts Amperes

240V ac

Make

7.5 A

120V ac

125V dc

15 A

Break

0.75 A

1.5 A

Amperes

Continuous

2.5 A

(2)

2.5 A

(1)

1.0 A

Volt-Amperes

Make

1800VA

1800VA

Break

180VA

180VA

24V dc

0.22 A

(1)

1.2 A

(2) 2.0 A

28VA

(1) For dc voltage applications, the make/break ampere rating for relay contacts can be determined by dividing 28

VA by the applied dc voltage. For example, 28VA/48V dc = 0.58 A. For dc voltage applications less than 14 V, the make/break ratings for relay contacts cannot exceed 2 A.

(2) 1.5 A above 40 °C (104 °F).

Publication 1762-UM001H-EN-P - June 2015

A-14 Specifications

Publication 1762-UM001H-EN-P - June 2015

Table A.17 Relay Contact Ratings 1762-OX6I

Volts (max.)

240V ac

120V ac

125V dc

Amperes

Make

15 A

30 A

0.4 A

(1)

Break

1.5 A

3.0 A

Continuous

Amps per Point

(max.)

(2)

5.0 A

7.0 A

(3)

2.5 A

Voltamperes

Make

3600VA

Break

360VA

24V dc 7.0 A

7.0 A

(3)

50VA

(4)

168VA

(4)

(1) Surge Suppression – Connecting surge suppressors across your external inductive load will extend the life of the relay contacts. For additional details, refer to Industrial Automation Wiring and Grounding Guidelines, publication 1770-4.1.

(2) The continuous current per module must be limited so the module power does not exceed 1440VA.

(3) 6 A in ambient temperatures above 40 °C (104 °F)

(4) DC Make/Break Voltamperes must be limited to 50 VA for DC voltages between 28V dc and 125V dc.

DC Make/Break Voltamperes below 28V dc are limited by the 7 A Make/Break current limit.

Table A.18 Module Load Ratings 1762-OX6I

Volts (max.)

240V ac

120V ac

125V dc

24V dc

Controlled Load (Current) per Module (max.)

6 A

12 A

(1)

11.5 A

30 A

(2)

(1) Current per relay limited to 6 A at ambient temperatures above 40 °C (104 °F).

(2) 24 A in ambient temperatures above 40 °C (104 °F). Limited by ambient temperature and the number of relays controlling loads. See diagram below.

Relays Used vs. Maximum Current per Relay (24V dc) 1762-OX6I

Ambient Temperature below 40°C

Ambient Temperature above 40°C

1 2 3 4 5 6

Number of Relays Controlling Loads

4

3

8

7

6

5

Specifications A-15

Analog Modules

Table A.19 Analog Modules Common Specifications

Specification

Dimensions

Temperature, storage

Temperature, operating

Operating humidity

Operating altitude

Vibration

Shock

Module power LED

Recommended cable

1762-IF2OF2, 1762-IF4, 1762-IR4, 1762-IT4 and 1762-OF4

90 mm (height) x 87 mm (depth) x 40 mm (width), height including mounting tabs is 110 mm

3.54 in. (height) x 3.43 in. (depth) x 1.58 in. (width), height including mounting tabs is 4.33 in.

-40…85 °C (-40…185 °F)

-20…65 °C (-4…149 °F)

(1)

5…95% non-condensing

2000 m (6561 ft)

Operating: 10…500 Hz, 5G, 0.030 in. max. peak-to-peak

Operating: 30G

On: indicates power is applied.

Belden 8761 (shielded)

(For 1762-IT4, Shielded thermocouple extension wire for the specific type of thermocouple you are using. Follow thermocouple manufacturer’s recommendations.)

Agency certification

Hazardous environment class

Noise immunity

C-UL certified (under CSA C22.2 No. 142)

UL 508 listed

CE compliant for all applicable directives

C-Tick marked for all applicable acts (1762-IR4 and 1762-IT4)

Radiated and conducted emissions EN50081-2 Class A

Electrical/EMC: The module has passed testing at the following levels:

ESD immunity

(IEC1000-4-2)

Radiated RF immunity

(IEC1000-4-3)

Class I, Division 2, Hazardous Location, Groups A, B, C, D (UL 1604, C-UL under CSA C22.2 No. 213)

NEMA standard ICS 2-230

4 kV contact, 8 kV air, 4 kV indirect

10 V/m, 80…1000 MHz, 80% amplitude modulation, +900 MHz keyed carrier

2 kV, 5 kHz EFT/B immunity

(IEC1000-4-4)

Surge transient immunity

(IEC1000-4-5)

Conducted RF immunity

(IEC1000-4-6)

1 kV galvanic gun

10 V, 0.15…80 MHz

(2) (3)

(1) Refer to the module’s Installation Instruction for exact operating temperature range.

(2) Conducted Immunity frequency range may be 150 kHz to 30 MHz if the Radiated Immunity frequency range is 30 MHz to 1000 MHz.

(3) For grounded thermocouples, the 10 V level is reduced to 3V.

Publication 1762-UM001H-EN-P - June 2015

A-16 Specifications

Table A.20 General Specifications for Analog Modules

Specification

Shipping weight, approx.

(with carton)

Bus current draw, max.

Analog normal operating range

Full scale

(1)

analog ranges

1762-IF2OF2

240 g (0.53 lbs.)

40 mA at 5V dc

105 mA at 24V dc

Voltage: 0…10V dc

Current: 4…20 mA

Voltage: 0…10.5V dc

Current: 0…21 mA

1762-IF4

40 mA at 5V dc

50 mA at 24V dc

Voltage: -10…+10V dc

Current: 4… 20 mA

Voltage:

-10.5…+10.5V dc

Current: -21…+21 mA

15 bits (bipolar)

(4)

1762-OF4

235 g (0.517 lbs.)

40 mA at 5V dc

165 mA at 24V dc

Voltage 0…10V dc

Current: 4…20 mA

Voltage: 0…10.5V dc

Current: 0…21 mA

1762-IR4

260 g (0.57 lbs.)

40 mA at 5V dc

50 mA at 24V dc

NA

NA

1762-IT4

220 g (0.53 lbs.)

40 mA at 5V dc

50 mA at 24V dc

NA

NA

Resolution

Repeatability

(2)

Input and output group to system isolation

12 bits (unipolar)

±0.12%

30V ac/30V dc rated working voltage

(N.E.C. Class 2 required)

(IEC Class 2 reinforced insulation)

(3) type test: 500V ac or 707V dc for 1 minute

Vendor I.D. code 1

Product type code 10

Product code 75

(4)

±0.12%

1

10

67

(4)

1

10

66

12 bits (unipolar)

±0.12%

(4)

30V ac/30V dc rated working voltage

(IEC Class 2 reinforced insulation) type test: 500V ac or

707V dc for 1 minute

Input filter and configuration dependent

±0.1 °C (±0.18 °F) for

Ni and NiFe

±0.2 °C (±0.36 °F) …

±0.2 °C (±0.36 °F) for other RTD inputs

±0.04 ohm for 150 ohm resistances

±0.2 ohm for other resistances

15 bits plus sign

See Table A.24 on page A-20.

30V ac/30V dc working voltage type test: 500V ac or

707V dc for 1 minute

30V ac/30V dc working voltage qualification test: 720V dc for

1 minute

1

10

65

1

10

64

(1) The over- or under-range flag comes on when the normal operating range (over/under) is exceeded. The module continues to convert the analog input up to the maximum full scale range.

(2) Repeatability is the ability of the module to register the same reading in successive measurements for the same signal.

(3) Rated working voltage is the maximum continuous voltage that can be applied at the terminals with respect to earth ground.

(4) Only applicable to Series B I/O modules.

Publication 1762-UM001H-EN-P - June 2015

Specifications A-17

Table A.21 Input Specifications

Specification

Number of inputs

1762-IF2OF2

2 differential (unipolar)

1762-IF4

4 differential (bipolar)

1762-IR4

4

Input filter and configuration dependent

Delta-Sigma

1762-IT4

4 input channels plus 1

CJC sensor

NA Update time (typical)

A/D converter type

2.5 ms

Successive approximation

±27 V

130, 250, 290, 450,

530 ms (selectable)

Successive approximation

±27 V

Delta-Sigma

Common mode voltage range

(1)

Common mode rejection

(2)

NA ±10 V

> 55 dB at 50 and 60 Hz > 55 dB at 50 and 60 Hz >110 dB at 50 Hz

(with 10 or 50 Hz filter)

>110 dB at 60 Hz

(with 10 or 60 Hz filter)

±0.12%

(4)

±0.12%

(4)

±0.05% NA

>110 dB at 50 Hz

(with 10 or 50 Hz filter)

>110 dB at 60 Hz

(with 10 or 60 Hz filter)

Non-linearity (in percent full scale)

Typical overall accuracy

Input impedance

(3) ±0.55% full scale at

-20…65 °C

(-4 …149 °F)

(4)

±0.3% full scale at

25 °C (77 °F)

Voltage Terminal: 200 k

Ω

Current Terminal: 250

Ω

Current input protection ±32 mA

±0.32% full scale at

-20…65 °C

(-4 …149 °F)

(4)

±0.24% full scale at

25 °C (77 °F)

Voltage Terminal: 200 k

Ω

Current Terminal: 275

Ω

±32 mA

±0.5 °C (32.9 °F) for

Pt 385

>10

NA

ΜΩ

NA

>10

NA

ΜΩ

Voltage input protection ±30 V

Channel diagnostics Over or under range or open circuit condition by bit reporting for analog inputs.

±30 V

Over or under range or open circuit condition by bit reporting for analog inputs.

NA

Over or under range or open circuit condition by bit reporting for analog inputs.

NA

Over or under range or open circuit condition by bit reporting for analog inputs.

(1) For proper operation, both the plus and minus input terminals must be within ±27V (±10V for 1762-IT4) of analog common.

(2) Vcm = 1 Vpk-pk AC

(3) Vcm = 0 (includes offset, gain, non-linearity and repeatability error terms)

(4) Only applicable to Series B I/O modules.

Publication 1762-UM001H-EN-P - June 2015

A-18 Specifications

Table A.22 Input Specifications 1762-IR4

Specification

Input types

Heat dissipation

Normal mode rejection ratio

Typical accuracy

[Autocalibration enabled] at 25 °C (77 °F) ambient with module operating temperature at

25 °C (77 °F)

(1)

Typical accuracy

[Autocalibration enabled] at 0…55 °C

(32…131 °F)

(1)

Accuracy drift at 0…55 °C

(32…131 °F)

Excitation current source

Open-circuit detection time

(2)

Input channel configuration

Calibration

Maximum overload at input terminals

Cable impedance, max.

Power supply distance rating

Channel to channel isolation

1762-IR4

100

Ω

Platinum 385

200

Ω

Platinum 385

500

Ω

Platinum 385

1000

Ω

Platinum 385

100

Ω

Platinum 3916

200

Ω

Platinum 3916

500

Ω

Platinum 3916

1000

Ω

Platinum 3916

10

Ω

Copper 426

120

Ω

Nickel 672

120

Ω

Nickel 618

604

Ω

Nickel-Iron 518

0…150

Ω

0…500

Ω

0…1000

Ω

0…3000

Ω

1.5 Total Watts (The Watts per point, plus the minimum Watts, with all points enabled.)

70 dB minimum at 50 Hz with the 10 or 50 Hz filter selected

70 dB minimum at 60 Hz with the 10 or 60 Hz filter selected

±0.5 °C (32.9 °F) for Pt 385

±0.4 °C (32.72 °F) for Pt 3916

±0.2 °C (32.36 °F) for Ni

±0.3 °C (32.54 °F) for NiFe

±0.6 °C (33.08 °F) for Cu

±0.15

Ω

for 150

Ω

range

±0.5

Ω

for 500

Ω

range

±1.0

Ω

for 1000

Ω

range

±1.5

Ω

for 3000

Ω

range

±0.9 °C (33.62 °F) for Pt 385

±0.8 °C (33.44 °F) for Pt 3916

±0.4 °C (32.72 °F) for Ni

±0.5 °C (32.9 °F) for NiFe

±1.1 °C (33.98 °F) for Cu

±0.25

±0.8

±1.5

±2.5

Ω

Ω

Ω

Ω

for 150

for 500

Ω

for 1000

for 3000

Ω

Ω

range

range

Ω

range

range

±0.026 °C/°C (0.026 °F/°F) for Pt 385

±0.023 °C/°C (0.023 °F/°F) for

Pt 3916

±0.012 °C/°C (0.012 °F/°F) for Ni

±0.015 °C/°C (0.015 °F/°F) for NiFe

±0.032 °C/°C (0.032 °F/°F) for Cu

0.5 mA and 1.0 mA selectable per channel

±0.007

Ω

/°C (0.012

Ω

/°F) for 150

Ω

range

±0.023

Ω

/°C (0.041

Ω

/°F) for 500

Ω

range

±0.043

Ω

/°C (0.077

Ω

/°F) for 1000

Ω

range

±0.072

Ω

/°C (0.130

Ω

/°F) for 3000

Ω

range

6…1212 ms

Via configuration software screen or the user program (by writing a unique bit pattern into the module’s configuration file). Refer to your controller’s user manual to determine if user program configuration is supported.

The module performs autocalibration on channel enable and on a configuration change between channels. You can also program the module to calibrate every five minutes.

±35V dc continuous

25

Ω (

Operating with >25

Ω will reduce accuracy.)

6 (The module may not be more than 6 modules away from the system power supply.)

±10V dc

(1) Accuracy is dependent upon the Analog/Digital converter filter rate selection, excitation current selection, data format, and input noise.

(2) Open-circuit detection time is equal to channel update time.

Publication 1762-UM001H-EN-P - June 2015

Specifications A-19

Table A.23 Input Specifications 1762-IT4

Specification

Heat dissipation

Response speed per channel

Rated working voltage

(1)

Normal mode rejection ratio

Value

1.5 Total Watts (The Watts per point, plus the minimum Watts, with all points energized.)

Input filter and configuration dependent.

30V ac/30V dc

Maximum cable impedance

Open-circuit detection time

Calibration

85 dB (minimum) at 50 Hz (with 10 Hz or 50 Hz filter)

85 dB (minimum) at 60 Hz (with 10 Hz or 60 Hz filter)

25

Ω ( for specified accuracy)

7 ms to 1.515 seconds

(2)

The module performs autocalibration upon power-up and whenever a channel is enabled. You can also program the module to calibrate every five minutes.

±1.3 °C (±2.34 °F)

±35V dc continuous

(3)

CJC accuracy

Maximum overload at input terminals

Input channel configuration via configuration software screen or the user program

(by writing a unique bit pattern into the module’s configuration file).

(1) Rated working voltage is the maximum continuous voltage that can be applied at the input terminal, including the input signal and the value that floats above ground potential (for example, 30V dc input signal and 20V dc potential above ground).

(2) Open-circuit detection time is equal to the module scan time, which is based on the number of enabled channels, the filter frequency of each channel, and whether cyclic calibration is enabled.

(3) Maximum current input is limited due to input impedance.

Publication 1762-UM001H-EN-P - June 2015

A-20 Specifications

Table A.24 1762-IT4 Repeatability at 25°C (77°F)

(1) (2)

Input Type

Thermocouple J

Thermocouple N (-110…1300 °C [-166…2372 °F])

Thermocouple N (-210…110 °C [-346…166 °F])

Thermocouple T (-170…400 °C [-274…752 °F])

Thermocouple T (-270…170 °C [-454…274 °F])

Thermocouple K (-270…1370 °C [-454…2498 °F])

Thermocouple K (-270…170 °C [-454…274 °F])

Thermocouple E (-220…1000 °C [-364…1832 °F])

Thermocouple E (-270…220 °C [-454…364 °F])

Thermocouples S and R

Thermocouple C

Thermocouple B

±50 mV

±100 mV

Repeatability for

10 Hz Filter

±0.1 °C [±0.18 °F]

±0.1 °C [±0.18 °F]

±0.25 °C [±0.45 °F]

±0.1 °C [±0.18 °F]

±1.5 °C [±2.7 °F]

±0.1 °C [±0.18 °F]

±2.0 °C [±3.6 °F]

±0.1 °C [±0.18 °F]

±1.0 °C [±1.8 °F]

±0.4 °C [±0.72 °F]

±0.2 °C [±0.36 °F]

±0.7 °C [±1.26 °F]

±6

μ

V

±6

μ

V

(1) Repeatability is the ability of the input module to register the same reading in successive measurements for the same input signal.

(2) Repeatability at any other temperature in the 0 to 60°C (32 to 140°F) range is the same as long as the temperature is stable.

Publication 1762-UM001H-EN-P - June 2015

Specifications A-21

Table A.25 1762-IT4 Accuracy

Input Type

(1)

Thermocouple J (-210…1200 °C [-346…2192 °F])

Thermocouple N (-200…1300 °C [-328…2372 °F])

Thermocouple N (-210…-200 °C [-346…-328 °F])

Thermocouple T (-230…400 °C [-382…752 °F])

Thermocouple T (-270…-230 °C [-454…-382 °F])

Thermocouple K (-230…1370 °C [-382…2498 °F])

Thermocouple K (-270…-225°C [-454…-373°F])

Thermocouple E (-210…1000°C [-346…1832°F])

Thermocouple E (-270…-210 °C [-454…-346 °F])

Thermocouple R

Thermocouple S

Thermocouple C

Thermocouple B

±50 mV

±100 mV

With Autocalibration Enabled

Accuracy

(2) (3)

for 10 Hz, 50 Hz and 60

Hz Filters (max.) at 25 °C [77 °F]

Ambient

±0.6 °C [±1.1 °F]

at 0 to 60 °C

[32 to 140 °F]

Ambient

Without Autocalibration

Maximum Temperature

Drift

(2) (4) at 0 to 60 °C [32 to 140 °F]

Ambient

±0.9 °C [±1.7 °F] ±0.0218 °C/°C [±0.0218 °F/°F]

±1 °C [±1.8 °F]

±1.2 °C [±2.2 °F]

±1 °C [±1.8 °F]

±5.4 °C [±9.8 °F]

±1.5 °C [±2.7 °F]

±1.8 °C [±3.3 °F]

±1.5 °C [±2.7 °F]

±7.0 °C [±12.6 °F]

±0.0367 °C/°C [±0.0367 °F/°F]

±0.0424 °C/°C [±0.0424 °F/°F]

±0.0349 °C/°C [±0.0349 °F/°F]

±0.3500 °C/°C [±0.3500 °F/°F]

±1 °C [±1.8 °F]

±7.5°C [±13.5°F]

±0.5°C [±0.9°F]

±4.2 °C [±7.6 °F]

±1.7 °C [±3.1 °F]

±1.7 °C [±3.1 °F]

±1.8 °C [±3.3 °F]

±3.0 °C [±5.4 °F]

±15

μ

V

±20

μ

V

±1.5 °C [±2.7 °F] ±0.4995 °C/°C [±0.4995 °F/°F]

±10°C [±18 °F] ±0.0378°C/°C [±0.0378°F/°F]

±0.8°C [±1.5 °F] ±0.0199°C/°C [±0.0199°F/°F]

±6.3 °C [±11.4 °F] ±0.2698 °C/°C [±0.2698 °F/°F]

±2.6 °C [±4.7 °F] ±0.0613 °C/°C [±0.0613 °F/°F]

±2.6 °C [±4.7 °F] ±0.0600 °C/°C [±0.0600 °F/°F]

±3.5 °C [±6.3 °F] ±0.0899 °C/°C [±0.0899 °F/°F]

±4.5 °C [±8.1 °F] ±0.1009 °C/°C [±0.1009 °F/°F]

±25

μ

V

±30

μ

V

±0.44

μ

V/°C [±0.80

μ

V/°F]

±0.69

μ

V/°C [±01.25

μ

V/°F]

(1) The module uses the National Institute of Standards and Technology (NIST) ITS-90 standard for thermocouple linearization.

(2) Accuracy and temperature drift information does not include the affects of errors or drift in the cold junction compensation circuit.

(3) Accuracy is dependent upon the analog/digital converter output rate selection, data format, and input noise.

(4) Temperature drift with autocalibration is slightly better than without autocalibration.

TIP

For more detailed 1762-IT4 accuracy information, see publication 1762-UM002.

Publication 1762-UM001H-EN-P - June 2015

A-22 Specifications

Table A.26 Output Specifications

Specification

Number of outputs

Update time (typical)

D/A converter type

Resistive load on current output

Load range on voltage output

Reactive load, current output

Reactive load, voltage output

Typical overall accuracy

(1)

1762-IF2OF2

2 single-ended (unipolar)

4.5 ms

Resistor string

0…500

Ω

(includes wire resistance)

> 1 k

Ω

< 0.1 mH

< 1

μ

F

±1.17% full scale at -20…65 °C

(-4…149 °F)

(2)

±0.5% full scale at 25 °C (77 °F)

< ±0.1% Output ripple range 0 to 500 Hz

(referred to output range)

Non-linearity (in percent full scale)

Open and short-circuit protection

Output protection

Heat dissipation

< ±0.59%

(2)

Continuous

±32 mA

2.6 W

(1) Includes offset, gain, non-linearity and repeatability error terms.

(2) Only applicable to Series B I/O modules.

1762-OF4

4 single-ended (unipolar)

(2)

R-2R Ladder Voltage Switching

0…500

Ω

(includes wire resistance)

> 1 k

Ω

< 0.1 mH

< 1

μ

F

±1.17% full scale at -20…65 °C

(-4…149 °F)

(2)

±0.5% full scale at 25 °C (77 °F)

< ±0.1%

< ±0.59%

(2)

Continuous

±32 mA

2.8 W

Table A.27 Valid Input/Output Data Word Formats/Ranges for 1762-IF2OF2

Normal Operating Range

0…0V dc

4… 20 mA

Full Scale Range

10.5V dc

0.0V dc

21.0 mA

20.0 mA

4.0 mA

0.0 mA

RAW/Proportional Data

32760

0

32760

31200

6240

0

Scaled-for-PID

16380

0

16380

15600

3120

0

Publication 1762-UM001H-EN-P - June 2015

Specifications A-23

Combination Module DC-Input/Relay Output

Table A.28 DC-Input/Relay-Output Combination Module - 1762-IQ80W6 Input

Specifications

Specification

Voltage category

Operating voltage range

Number of inputs

On-state voltage, min.

Off-state voltage, max.

On-state current, min.

Off-state current, max.

Inrush current, max.

Nominal impedance

Input compatibility

Signal delay time, max.

Value

24V dc (Sink/Source)

(1)

10…30V dc @ 30 °C (86 °F)

10…26.4V dc @ 65 °C (149 °F)

8

10V dc

5V dc

2.0 mA

1.5 mA

250 mA

3 k

Ω

IEC Type 1+

On-delay: 8 ms

Off-delay: 8 ms

(1) Sinking/Sourcing Inputs - Sinking/Sourcing describes the current flow between the I/O module and the field device. Sourcing I/O circuits supply (source) current to sinking field devices. Sinking I/O circuits are driven by a current sourcing field device. Field devices connected to the negative side (DC Common) of the field power supply are sinking field devices. Field devices connected to the positive side (+V) of the field supply are sourcing field devices.

Table A.29 DC-Input/Relay-Output Combination Module - 1762-IQ80W6 Output

Specifications

Specification

Voltage range

Commons per module

Output type

Signal delay time

Off leakage current

On-state current, min.

Continuous current per point

Continuous current per module

Total controlled load

Value

5…265V ac

5…125V dc

6

6-Form A (normally open)

On-delay: 10 mS (max) Off-delay: 10 mS (max)

0 mA

10 mA @ 5V dc

See table on page A-24.

8 A

1440VA/Module max

Publication 1762-UM001H-EN-P - June 2015

A-24 Specifications

Publication 1762-UM001H-EN-P - June 2015

Table A.30 DC-Input/Relay-Output Combination Module - 1762-IQ80W6 Relay

Contact Ratings

Volts

(max.)

240V ac

120V ac

125V dc

24V dc

Continuous

Amps per

Point (Max.)

2.5 A

1.0 A

2.0 A

Amperes

Make

7.5 A

15 A

0.22 A

(2)

1.2 A

(1)

Break

0.75 A

1.5 A

Voltamperes

Make

1800VA

28VA

(2)

28VA

(2)

Break

180VA

(1) Surge Suppression - Connecting surge suppressors across your external inductive load will extend the life of the relay contacts. For additional details, refer to Industrial Automation Wiring and Grounding Guidelines, publication 1770-4.1.

(2) For dc voltage applications, the make/break ampere rating for relay contacts can be determined by dividing

28VA by the applied dc voltage. For example, 28VA/48V dc = 0.58 A. For dc voltage applications less than 14 V, the make/break rating for relay contacts cannot exceed 2 A.

Table A.31 DC-Input/Relay-Output Combination Module - 1762-IQ80W6 General

Specifications

Specification

Dimensions

Value

90 mm (height) x 87 mm (depth) x 40.4 mm (width) height including mounting tabs is 110 mm

3.54 in. (height) x 3.43 in. (depth) x 1.59 in. (width) height including mounting tabs is 4.33 in.

280 g (0.62 lbs.) Shipping weight, approx.

(with carton)

Bus current draw, max.

Heat dissipation

110 mA @ 5V dc

80 mA @ 24V dc

5.0 W @ 30V dc

4.4 W @ 26.4V dc

(The Watts per point, plus the minimum W, with all points energized.)

6 Power supply distance rating

Isolated group

Vibration

Shock

Group 1 (input 0…3)

Group 2 (input 4…7)

Group 3 (output 0…5)

Operating: 10 to 500 Hz, 5G, 0.030 in. max. peak-to-peak,

2 hours per axis.

Relay Operation: 1.5 G

Operating: 30G panel mounted, 3 pulses per axis

Relay Operation: 7G

Non-Operating: 50G panel mounted, 3 pulses per axis

(40G DIN Rail mounted)

Specifications A-25

Table A.31 DC-Input/Relay-Output Combination Module - 1762-IQ80W6 General

Specifications

Specification

Vendor ID code

Product type code

Product code

Value

1

7

98

Table A.32 DC-Input/Relay-Output Combination Module - 1762-IQ80W6

Environmental Specifications

Specification

Temperature range, operating

Temperature range, storage

Operating humidity

Operating altitude

Value

-20…+65 °C (-4…+149 °F)

-40…+85 °C (-40…+185 °F)

5…95% non-condensing

2000 m (6561 ft)

Table A.33 Certifications

Certification

Agency certification

Hazardous environment class

Value

C-UL certified (under CSA C22.2 No. 142)

UL 508 listed

CE compliant for all applicable directives

Class I, Division 2, Hazardous Location,

Groups A, B, C, D (UL 1604, C-UL under

CSA C22.2 No. 213)

Radiated and conducted emissions

Electrical/EMC:

ESD immunity (IEC1000-4-2)

Radiated RF immunity

(IEC1000-4-3)

EN50081-2 Class A

The module has passed testing at the following levels:

4 kV contact, 8 kV air, 4 kV indirect

10 V/m, 80…1000 MHz, 80% amplitude modulation, +900 MHz keyed carrier

EFT/B immunity (IEC1000-4-4) 2 kV, 5 kHz

Surge transient immunity

(IEC1000-4-5)

2 kV common mode, 1 kV differential mode

Conducted RF immunity

(IEC1000-4-6)

10V, 0.15…80 MHz

(1)

(1) Conducted Immunity frequency range may be 150 kHz to 30 MHz if the Radiated Immunity frequency range is 30…1000 MHz.

Publication 1762-UM001H-EN-P - June 2015

A-26 Specifications

Notes:

Publication 1762-UM001H-EN-P - June 2015

Appendix

B

1762 Replacement Parts

MicroLogix 1200 RTB

Replacement Kit

The 40-point controller removable terminal blocks kit (catalog number

1762-RPLRTB40) consists of:

• one 25-point double row terminal block

• one 29-point double row terminal block

(Both are terminal blocks for a 40-point controller.)

1 Publication 1762-UM001H-EN-P - June 2015

B-2 1762 Replacement Parts

Notes:

Publication 1762-UM001H-EN-P - June 2015

1

Appendix

C

Troubleshoot Your System

This chapter describes how to troubleshoot your controller. Topics include:

• understanding the controller LED status

• controller error recovery model

• analog expansion I/O diagnostics and troubleshooting

• calling Rockwell Automation for assistance

Interpret LED Indicators

The controller status LEDs provide a mechanism to determine the current status of the controller if a programming device is not present or available.

Figure C.1 Controller LED Location

POWER

RUN

FAULT

FORCE

COMM 0

DCOMM

IN

0 1 2 3 4 5 6 7 8 9 10 11 12 13

0 1 2 3 4 5 6 7 8 9

OUT

Table C.1 Controller LED Indicators

LED

POWER

RUN

FAULT

FORCE

COMM 0

DCOMM

INPUTS

OUTPUTS

(1)

(2) red off amber off green off green off

Color

off green off green green flashing off red flashing amber off amber

Indicates

No input power, or power error condition

Power on

Not executing the user program

Executing the user program in run mode

Memory module transfer occurring

No fault detected

Application fault detected

Controller hardware faulted

No forces installed

Forces installed

Not transmitting via RS-232 port

Transmitting via RS-232 port

Configured communications

Default communications

Input is not energized

Input is energized (terminal status)

Output is not energized

Output is engerized (logic status)

(1) 1762-L24AWAR, -L24BWAR, -L24BXBR, -L40AWAR, -L40BWAR, -L40BXBR controllers are equipped with an additional communications port (Programmer/HMI Port) but provide no additional LED indictor indicating its operational status.

(2) When using a 1762-L24AWAR, -L24BWAR, -L24BXBR, -L40AWAR, -L40BWAR, or -L40BXBR controller, the

DCOMM LED applies only to Channel 0.

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C-2 Troubleshoot Your System

Normal Operation

The POWER and RUN LEDs are on. If a force condition is active, the

FORCE LED turns on and remains on until all forces are removed.

Error Conditions

If an error exists within the controller, the controller LEDs operate as described in the following table.

If the

LEDS indicate

The Following Error

Exists

All LEDs off No input power or power supply error

Probable Cause

No line Power

Power Supply

Overloaded

Hardware faulted Power and

FAULT

LEDs on solid

Power LED on and

FAULT LED flashing

RUN

Application fault

Operating system fault

Processor Hardware

Error

Loose Wiring

Hardware/Software

Major Fault Detected

Missing or Corrupt

Operating System

FORCE

Recommended Action

Verify proper line voltage and connections to the controller.

This problem can occur intermittently if power supply is overloaded when output loading and temperature varies.

Cycle power. Contact your local Allen-Bradley representative if the error persists.

Verify connections to the controller.

For error codes and Status File information, see MicroLogix 1200 and 1500

Programmable Controllers Instruction Set Reference Manual, Publication

1762-RM001.

See Missing/Corrupt OS LED Pattern on page D-2.

FAULT

LEDs all flashing

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Troubleshoot Your System C-3

Controller Error Recovery

Model

Use the following error recovery model to help you diagnose software and hardware problems in the micro controller. The model provides common questions you might ask to help troubleshoot your system. Refer to the recommended pages within the model for further help.

Identify the error code and description.

No

Refer to page C-2 for

probable cause and recommended action.

Clear Fault.

Correct the condition causing the fault.

Return controller to RUN or any of the REM test modes.

Test and verify system operation.

Is the error hardware related?

Yes

Start

Are the wire connections tight?

Yes

No

Tighten wire connections.

Is the Power

LED on?

Yes

No

Is the RUN

LED on?

Yes

No

Is the Fault

LED on?

Yes

Refer to page C-2 for

probable cause and recommended action.

No

Does the controller have power supplied?

Yes

Refer to page C-2 for

probable cause and recommended action.

No

Is an input LED accurately showing status?

Yes

Check power.

No

Refer to page C-2 for

probably cause and recommended action.

End

Publication 1762-UM001H-EN-P - June 2015

C-4 Troubleshoot Your System

Analog Expansion I/O

Diagnostics and

Troubleshooting

Module Operation and Channel Operation

The module performs operations at two levels:

• module level

• channel level

Module-level operations include functions such as power-up, configuration, and communication with the controller.

Internal diagnostics are performed at both levels of operation. Both module hardware and channel configuration error conditions are reported to the controller. Channel over-range or under-range conditions are reported in the module’s input data table. Module hardware errors are reported in the controller’s I/O status file. Refer to the MicroLogix 1200 and 1500

Programmable Controllers Instruction Set Reference Manual, publication

1762-RM001 for more information.

When a fault condition is detected, the analog outputs are reset to zero.

Power-up Diagnostics

At module power-up, a series of internal diagnostic tests are performed.

Table C.2 Module Status LED State Table

If module status LED is

On

Off

Indicated condition

Proper Operation

Module Fault

Corrective action

No action required.

Cycle power. If condition persists, replace the module. Call your local distributor or

Allen-Bradley for assistance.

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Troubleshoot Your System C-5

Critical and Noncritical Errors

Noncritical module errors are recoverable. Channel errors (over-range or under-range errors) are noncritical. Noncritical error conditions are indicated in the module input data table. Noncritical configuration errors are indicated by the extended error code.

See Table C.5 on page C-7.

Critical module errors are conditions that prevent normal or recoverable operation of the system. When these types of errors occur, the system leaves the run mode of operation.

Critical module errors are indicated in Table C.5 on page C-7.

Module Error Definition Table

Analog module errors are expressed in two fields as four-digit Hex format with the most significant digit as ‘don’t care’ and irrelevant. The two fields are

‘Module Error’ and ‘Extended Error Information’. The structure of the module error data is shown below.

Table C.3 Module Error Table

15

0

‘Don’t Care’ Bits

14 13

0 0

Hex Digit 4

12

0

11

Module Error

10 9

0 0 0

Hex Digit 3

8

0

7

0

6

Extended Error Information

5 4 3 2

0 0

Hex Digit 2

0 0 0

1

0

Hex Digit 1

0

0

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C-6 Troubleshoot Your System

Module Error Field

The purpose of the module error field is to classify module errors into three distinct groups, as described in the table below. The type of error determines what kind of information exists in the extended error information field. These types of module errors are typically reported in the controller’s I/O status file.

Refer to the MicroLogix 1200 and 1500 Programmable Controllers Instruction

Set Reference Manual, publication 1762-RM001 for more information.

.

Table C.4 Module Error Types

Error Type

No Errors

Hardware Errors

Configuration Errors

Module Error Field Value

Bits 11 through 09

(Binary)

000

001

010

Description

No error is present. The extended error field holds no additional information.

General and specific hardware error codes are specified in the extended error information field.

Module-specific error codes are indicated in the extended error field. These error codes correspond to options that you can change directly. For example, the input range or input filter selection.

Extended Error Information Field

Check the extended error information field when a non-zero value is present

in the module error field. See Table C.5 on page C-7.

TIP

If no errors are present in the module error field, the extended error information field is set to zero.

Hardware Errors

General or module-specific hardware errors are indicated by module error

code 2. See Table C.5.

Configuration Errors

If you set the fields in the configuration file to invalid or unsupported values, the module ignores the invalid configuration, generates a non-critical error, and keeps operating with the previous configuration.

The table below lists the configuration error codes defined for the module.

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Troubleshoot Your System C-7

Error Codes

Table C.5 Extended Error Codes for 1762-IF2OF2

Error Type

No Error

General Common

Hardware Error

Hex

Equivalent

(1)

X000

X200

X201

Hardware-Specific

Error

X210

Configuration Error X400

X401

X402

X403

X404

(1) X represents ‘Don’t Care’.

Module

Error Code

Binary

000

001

001

001

010

010

010

010

010

Extended Error

Information Code

Error Description

Binary

0 0000 0000

0 0000 0000

0 0000 0001

0 0001 0000

No error

General hardware error; no additional information

Power-up reset state

Reserved

0 0000 0000

0 0000 0001

0 0000 0010

0 0000 0011

0 0000 0100

General configuration error; no additional information

Invalid input data format selected (channel 0)

Invalid input data format selected (channel 1)

Invalid output data format selected (channel 0)

Invalid output data format selected (channel 1)

Table C.6 Extended Error Codes for 1762-IF4 and 1762-OF4

Error Type

No Error

General Common

Hardware Error

Hex

Equivalent

(1)

X000

X200

Module

Error Code

Binary

000

001

Extended Error

Information Code

Error Description

Binary

0 0000 0000

0 0000 0000

No error

General hardware error; no additional information

X201 001 0 0000 0001 Power-up reset state

Hardware-

Specific Error

X300

Configuration Error X400

X401

X402

X403

X404

X405

X406

X407

X408

X409

X40A

X40B

X40C

(1) X represents ‘Don’t Care’.

001

010

010

010

010

010

010

010

010

010

010

010

010

010

1 0000 0000

0 0000 0000

0 0000 0001

0 0000 0010

0 0000 0011

0 0000 0100

0 0000 0101

0 0000 0110

0 0000 0111

0 0000 1000

0 0000 1001

0 0000 1010

0 0000 1011

0 0000 1100

Reserved

General configuration error; no additional information

Invalid range select (Channel 0)

Invalid range select (Channel 1)

Invalid range select (Channel 2)

Invalid range select (Channel 3)

Invalid filter select (Channel 0) 1762-IF4 only

Invalid filter select (Channel 1) 1762-IF4 only

Invalid filter select (Channel 2) 1762-IF4 only

Invalid filter select (Channel 3) 1762-IF4 only

Invalid format select (Channel 0)

Invalid format select (Channel 1)

Invalid format select (Channel 2)

Invalid format select (Channel 3)

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C-8 Troubleshoot Your System

Call Rockwell Automation for Assistance

If you need to contact Rockwell Automation or local distributor for assistance, it is helpful to obtain the following (prior to calling):

• controller type, series letter, revision letter, and firmware (FRN) number of the controller

• controller LED status

• controller error codes (Refer to MicroLogix 1200 and 1500

Programmable Controllers Instruction Set Reference Manual,

Publication 1762-RM001 for error code information.)

Publication 1762-UM001H-EN-P - June 2015

Appendix

D

Use Control Flash to Upgrade Your Operating

System

1

Prepare for Upgrade

The operating system (OS) can be upgraded through the communication port on the controller. In order to download a new operating system, you must have the following:

ControlFlash Upgrade Kit containing the new OS

Go to http://www.ab.com/micrologix to download the upgrade kit.

• a Windows 95, Windows 98, Windows 2000 or

Windows NT based computer to run the download software.

The ControlFlash Upgrade Kit includes:

• the operating system upgrade to be downloaded

• the ControlFlash programming tool, along with its support drivers and on-line help

• a readme first file explaining how to upgrade the operating system

Before upgrading the controller’s operating system, you must:

• install ControlFlash software on your personal computer

• prepare the controller for updating

IMPORTANT

Installing a new operating system deletes the user program. After the operating system upgrade is successful, you must transfer your control program back to the controller. The communication

parameters are described on Table 4.1 on page 4-2.

Install ControlFlash Software

For 1762-Lxxxxx controllers, double click the 1762-LSC-FRNxx.exe file to install the operating system upgrade (where xx is the firmware revision number).

For 1762-LxxxxxR controllers, double click the 1762-LRC-FRNxx.exe file to install the operating system upgrade.

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D-2 Use Control Flash to Upgrade Your Operating System

Prepare the Controller for Updating

Controller Configuration

The controller must be configured for default communications (use communications toggle push button; DCOMM LED on) and be in the

Program mode to allow the download of a new operating system.

Sequence of Operation

The following steps detail the key events in the upgrade process.

1. Controller mode and communications parameters are checked.

2. Download begins.

3. During the download, the Force, Battery, and Comms LEDs perform a walking bit pattern.

4. When the download is complete, the integrity of the new OS is checked.

If the new OS is corrupt, the controller sends an error message to the download tool and flashes the Missing or Corrupt OS LED pattern. See

Missing/Corrupt OS LED Pattern below.

5. Following a successful transfer, the Power, Force, and Battery LEDs flash on and remain on for five seconds. Then the controller resets.

Missing/Corrupt OS LED

Pattern

When an operating system download is not successful or if the controller does not contain a valid operating system, the controller flashes the Run, Force, and

Fault LEDS on and off.

Publication 1762-UM001H-EN-P - June 2015

Appendix

E

Connect to Networks via RS-232 Interface

1

The following protocols are supported from the RS-232 communication channel:

DF1 Full-duplex

DF1 Half-duplex

DH-485

Modbus

ASCII

RS-232 Communication

Interface

The communications port on the MicroLogix 1200 utilizes an RS-232 interface. RS-232 is an Electronics Industries Association (EIA) standard that specifies the electrical and mechanical characteristics for serial binary communication. It provides you with a variety of system configuration possibilities. (RS-232 is a definition of electrical characteristics; it is not a protocol.)

One of the biggest benefits of an RS-232 interface is that it lets you integrate telephone and radio modems into your control system (using the appropriate

DF1 protocol only, not DH-485 protocol).

DF1 Full-duplex Protocol

DF1 Full-duplex protocol provides a point-to-point connection between two devices. DF1 Full-duplex protocol combines data transparency (American

National Standards Institute ANSI - X3.28-1976 specification subcategory

D1) and 2-way simultaneous transmission with embedded responses

(subcategory F1).

The MicroLogix 1200 controllers support the DF1 Full-duplex protocol via

RS-232 connection to external devices, such as computers, or other controllers that support DF1 Full-duplex.

DF1 is an open protocol. Refer to DF1 Protocol and Command Set Reference

Manual, publication 1770-6.5.16, for more information.

DF1 Full-duplex protocol (also referred to as DF1 point-to-point protocol) is useful where RS-232 point-to-point communication is required. DF1 protocol controls message flow, detects and signals errors, and retries if errors are detected.

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E-2 Connect to Networks via RS-232 Interface

Example DF1 Full-duplex Connections

For information about required network connecting equipment, see Chapter 4,

Communication Connections.

1761-CBL-AM00 or 1761-CBL-HM02

Personal Computer

Personal Computer

MicroLogix 1200

TERM

COM

SHLD

CHS GND

TX TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

Optical

Isolator

Modem cable

Modem

1761-CBL-PM02

Modem

MicroLogix 1200

Optical Isolator

TERM

COM

SHLD

CHS GND

PWR

DC SOURCE

CABLE

EXTERNAL

1761-CBL-PM02

We recommend using an AIC+, catalog number 1761-NET-AIC, as your optical isolator.

DF1 Half-duplex Protocol

DF1 Half-duplex protocol is a multi-drop single master/multiple slave network. DF1 Half-duplex protocol supports data transparency (American

National Standards Institute ANSI - X3.28-1976 specification subcategory

D1). In contrast to DF1 Full-duplex, communication takes place in one direction at a time. You can use the RS-232 port on the MicroLogix 1200 as both a Half-duplex programming port and a Half-duplex peer-to-peer messaging port.

MicroLogix 1200 can act as the master or as a slave on a Half-duplex network.

When the MicroLogix 1200 is a slave device, a master device is required to

‘run’ the network. Several other Allen-Bradley products support DF1

Half-duplex master protocol. They include the SLC 5/03 and higher processors, enhanced PLC-5 processors and Rockwell Software RSLinx

(version 2.x and higher).

DF1 Half-duplex supports up to 255 devices (address 0 to 254) with address

255 reserved for master broadcasts. As a DF1 Half-duplex slave device, the

MicroLogix 1200 supports broadcast reception. As a DF1 Half-duplex master, the MicroLogix 1200 supports both the reception and initiation of broadcast write commands (via the MSG instruction). The MicroLogix 1200 also supports Half-duplex modems using RTS/CTS hardware handshaking.

Publication 1762-UM001H-EN-P - June 2015

Rockwell Software RSLinx 2.0 (or higher), SLC 5/03, SLC 5/04, and

SLC 5/05, or PLC-5 processors configured for DF1 Half-duplex

Master.

Example DF1 Half-duplex Connections

RS-232

(DF1 Half-duplex Protocol)

Modem

Connect to Networks via RS-232 Interface E-3

TERM

COM

SHLD

CHS GND

TX TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

TERM

COM

SHLD

CHS GND

TX TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

MicroLogix

1000 (Slave)

MicroLogix

1200 (Slave)

MicroLogix

1500 (Slave)

TERM

COM

SHLD

CHS GND

TX TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

SLC 5/04 (Slave)

SLC 5/03 with

1747-KE Interface

Module (Slave)

Use Modems with MicroLogix 1200 Programmable Controllers

The types of modems you can use with MicroLogix 1200 controllers include the following:

• dial-up phone modems

A MicroLogix 1200 controller, on the receiving end of the dial-up connection, can be configured for DF1 Full-duplex protocol with or without handshaking. The modem connected to the MicroLogix controller should support auto-answer. The MicroLogix 1200 supports

ASCII out communications. Therefore, it can cause a modem to initiate or disconnect a phone call.

• leased-line modems

Leased-line modems are used with dedicated phone lines that are typically leased from the local phone company. The dedicated lines may be in a point-to-point topology supporting Full-duplex communications between two modems or in a multi-drop topology supporting

Half-duplex communications between three or more modems.

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E-4 Connect to Networks via RS-232 Interface

• radio modems

Radio modems may be implemented in a point-to-point topology supporting either Half-duplex or Full-duplex communications, or in a multi-drop topology supporting Half-duplex communications between three or more modems. MicroLogix 1200 also supports DF1 Radio

Modem protocol.

• line drivers

Line drivers, also called short-haul modems, do not actually modulate the serial data, but rather condition the electrical signals to operate reliably over long transmission distances (up to several miles). Line drivers are available in Full-duplex and Half-duplex models.

Allen-Bradley’s AIC+ Advanced Interface Converter is a Half-duplex line driver that converts an RS-232 electrical signal into an RS-485 electrical signal, increasing the signal transmission distance from 50 to

4000 feet (8000 feet when bridged).

For point-to-point Full-duplex modem connections that do not require any modem handshaking signals to operate, use DF1 Full-duplex protocol with no handshaking. For point-to-point Full-duplex modem connections that require

RTS/CTS handshaking, use DF1 Full-duplex protocol with handshaking.

For radio modem connections, use DF1 Radio Modem protocol, especially if store and forward capability is required.

For general multi-drop modem connections, or for point-to-point modem connections that require RTS/CTS handshaking, use DF1 Half-duplex slave protocol. In this case, one (and only one) of the other devices must be configured for DF1 Half-duplex master protocol.

IMPORTANT

Never attempt to use DH-485 protocol through modems under any circumstance.

TIP

All MicroLogix 1200 controllers support RTS/CTS modem handshaking when configured for DF1

Full-duplex protocol with the control line parameter set to Full-duplex Modem Handshaking or DF1

Half-duplex slave protocol with the control line parameter set to ‘Half-duplex Modem’. No other modem handshaking lines (Data Set Ready, Carrier

Detect and Data Terminal Ready) are supported by any MicroLogix 1200 controllers.

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Connect to Networks via RS-232 Interface E-5

DH-485 Communication

Protocol

The DH-485 protocol defines the communication between multiple devices that coexist on a single pair of wires. DH-485 protocol uses RS-485

Half-duplex as its physical interface. (RS-485 is a definition of electrical characteristics; it is not a protocol.) RS-485 uses devices that are capable of co-existing on a common data circuit, thus allowing data to be easily shared between devices.

The DH-485 protocol supports two classes of devices: initiators and responders. All initiators on the network get a chance to initiate message transfers. To determine which initiator has the right to transmit, a token passing algorithm is used.

Devices that use the DH-485 Network

In addition to the MicroLogix 1200 controllers, the devices shown in the following table also support the DH-485 network.

Table E.1 Allen-Bradley Devices that Support DH-485 Communication

Catalog

Number

Bulletin 1761

Controllers

Description Installation Function

Bulletin 1764 MicroLogix 1500 Series A or higher

Bulletin 1747

Processors

1746-BAS

MicroLogix 1000 Series C or higher

SLC 500

Processors

BASIC Module

These controllers support DH-485 communications.

These controllers support DH-485 communications.

SLC Chassis These processors support a variety of I/O requirements and functionality.

SLC Chassis Provides an interface for SLC 500 devices to foreign devices.

Program in BASIC to interface the 3 channels (2 RS232 and 1

DH-485) to printers, modems, or the DH-485 network for data collection.

1785-KA5 DH

+

/DH-485

Gateway

(1771) PLC

Chassis

Provides communication between stations on the PLC-5 (DH+) and SLC 500 (DH-485) networks. Enables communication and data transfer from PLC to SLC 500 on DH-485 network. Also enables programming software programming or data acquisition across DH+ to DH-485.

2760-RB Flexible Interface

Module

(1771) PLC

Chassis

Provides an interface for SLC 500 (using protocol cartridge

2760-SFC3) to other A-B PLCs and devices. Three configurable channels are available to interface with Bar Code, Vision, RF,

Dataliner, and PLC systems.

1784-KTX,

-KTXD

PC DH-485 IM

1784-PCMK

1747-PT1

PCMCIA IM

Hand-Held

Terminal

IBM XT/AT

Computer

Bus

Provides DH-485 using RSLinx.

PCMCIA slot in computer and

Interchange

NA

Provides DH-485 using RSLinx.

Provides hand-held programming, monitoring, configuring, and troubleshooting capabilities for SLC 500 processors.

Publication

1761-6.3

1764-UM001

1747-UM011

1746-UM004

1746-PM001

1746-RM001

1785-6.5.5

1785-1.21

1747-6.12

2760-ND001

1784-6.5.22

1784-6.5.19

1747-NP002

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E-6 Connect to Networks via RS-232 Interface

Table E.1 Allen-Bradley Devices that Support DH-485 Communication

Catalog

Number

1747-DTAM,

2707-L8P1,

-L8P2, -L40P1,

-L40P2,

-V40P1,

-V40P2,

-V40P2N,

-M232P3, and

-M485P3

2711-K5A2,

-B5A2, -K5A5,

-B5A5, -K5A1,

-B5A1, -K9A2,

-T9A2, -K9A5,

-T9A5, -K9A1, and -T9A1

Description

DTAM, DTAM

Plus, and DTAM

Micro Operator

Interfaces

Installation Function

Panel Mount Provides electronic operator interface for SLC 500 processors.

PanelView 550 and

PanelView 900

Operator Terminals

Panel Mount Provides electronic operator interface for SLC 500 processors.

NA = Not Applicable

Publication

1747-6.1

2707-800,

2707-803

2711-UM014

Important DH-485 Network Planning Considerations

Carefully plan your network configuration before installing any hardware.

Listed below are some of the factors that can affect system performance:

• amount of electrical noise, temperature, and humidity in the network environment

• number of devices on the network

• connection and grounding quality in installation

• amount of communication traffic on the network

• type of process being controlled

• network configuration

The major hardware and software issues you need to resolve before installing a network are discussed in the following sections.

Hardware Considerations

You need to decide the length of the communication cable, where you route it, and how to protect it from the environment where it will be installed.

When the communication cable is installed, you need to know how many devices are to be connected during installation and how many devices will be added in the future. The following sections help you understand and plan the network.

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Connect to Networks via RS-232 Interface E-7

Number of Devices and Length of Communication Cable

The maximum length of the communication cable is 1219 m (4000 ft). This is the total cable distance from the first node to the last node in a segment.

However, two segments can be used to extend the DH-485 network to 2438 m

(8000 ft). For additional information on connections using the AIC+, refer to the Advanced Interface Converter (AIC+) User Manual, publication

1761-UM004.

Planning Cable Routes

Follow these guidelines to help protect the communication cable from electrical interference:

Keep the communication cable at least 1.52 m (5 ft) from any electric motors, transformers, rectifiers, generators, arc welders, induction furnaces, or sources of microwave radiation.

If you must run the cable across power feed lines, run the cable at right angles to the lines.

If you do not run the cable through a contiguous metallic wireway or conduit, keep the communication cable at least

0.15 m (6 in.) from ac power lines of less than 20 A, 0.30 m (1 ft) from lines greater than 20 A, but only up to 100 kVA, and 0.60 m (2 ft) from lines of 100 kVA or more.

If you run the cable through a contiguous metallic wireway or conduit, keep the communication cable at least 0.08 m (3 in) from ac power lines of less than 20 A, 0.15 m (6 in) from lines greater than 20 A, but only up to 100 kVA, and 0.30 m (1 ft) from lines of 100 kVA or more.

Running the communication cable through conduit provides extra protection from physical damage and electrical interference. If you route the cable through conduit, follow these additional recommendations:

Use ferromagnetic conduit near critical sources of electrical interference. You can use aluminum conduit in non-critical areas.

Use plastic connectors to couple between aluminum and ferromagnetic conduit. Make an electrical connection around the plastic connector (use pipe clamps and the heavy gauge wire or wire braid) to hold both sections at the same potential.

Ground the entire length of conduit by attaching it to the building earth ground.

Do not let the conduit touch the plug on the cable.

Arrange the cables loosely within the conduit. The conduit should contain only serial communication cables.

Publication 1762-UM001H-EN-P - June 2015

E-8 Connect to Networks via RS-232 Interface

Install the conduit so that it meets all applicable codes and environmental specifications.

For more information on planning cable routes, see Industrial Automation

Wiring and Grounding Guidelines, publication Number 1770-4.1.

Software Considerations

Software considerations include the configuration of the network and the parameters that can be set to the specific requirements of the network. The following are major configuration factors that have a significant effect on network performance:

• number of nodes on the network

• addresses of those nodes

• baud rate

The following sections explain network considerations and describe ways to select parameters for optimum network performance (speed). See your programming software’s user manual for more information.

Number of Nodes

The number of nodes on the network directly affects the data transfer time between nodes. Unnecessary nodes (such as a second programming terminal that is not being used) slow the data transfer rate. The maximum number of nodes on the network is 32.

Setting Node Addresses

The best network performance occurs when node addresses are assigned in sequential order. Initiators, such as personal computers, should be assigned the lowest numbered addresses to minimize the time required to initialize the network. The valid range for the MicroLogix 1200 controllers is 1 to 31

(controllers cannot be node 0). The default setting is 1. The node address is stored in the controller Communications Status file (CS0:5/0 to CS0:5/7).

Setting Controller Baud Rate

The best network performance occurs at the highest baud rate, which is 19200.

This is the default baud rate for a MicroLogix 1200 device on the DH-485 network. All devices must be at the same baud rate. This rate is stored in the controller Communications Status file (CS0:5/8 to CS0:5/15).

Setting Maximum Node Address

Once you have an established network set up and are confident that you will not be adding more devices, you may enhance performance by adjusting the

Publication 1762-UM001H-EN-P - June 2015

Connect to Networks via RS-232 Interface E-9 maximum node address of your controllers. It should be set to the highest node address being used.

IMPORTANT

All devices should be set to the same maximum node address.

Example DH-485 Connections

The following network diagrams provide examples of how to connect

MicroLogix 1200 controllers to the DH-485 network using the Advanced

Interface Converter (AIC+, catalog number 1761-NET-AIC). For more information on the AIC+, see the Advanced Interface Converter and

DeviceNet Interface Installation Instructions, Publication 1761-IN002.

DH-485 Network with a MicroLogix 1200 Controller

MicroLogix

1200 connection from port 1 or port 2 to MicroLogix

1761-CBL-AM00 or

1761-CBL-HM02

1761-CBL-AP00 or

1761-CBL-PM02

(1) DB-9 RS-232 port

(2) mini-DIN 8 RS-232 port

(3) RS-485 port

(3)

TERM

COM

SHLD

CHS GND

TX TX

(2)

(1)

TX PWR

DC SOURCE

CABLE

EXTERNAL

AIC+

+24V dc user supply

DH-485

TIP

1761-CBL-AP00 or

1761-CBL-PM02

AIC+

(3) (2)

TERM

TX

COM

SHLD

CHS GND

TX

(1)

TX PWR

DC SOURCE

CABLE

EXTERNAL

+24V dc user supply connection from port 1 or port 2 to PC

1747-CP3 or

1761-CBL-AC00

Series C or higher cables are required.

Publication 1762-UM001H-EN-P - June 2015

E-10 Connect to Networks via RS-232 Interface

Typical 3-Node Network

PanelView 550

A-B PanelView

MicroLogix 1200

RJ45 port

1761-CBL-AS09 or 1761-CBL-AS03

TIP

1761-CBL-AM00 or 1761-CBL-HM02

AIC+

TERM

COM

SHLD

CHS GND

TX TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

1747-CP3 or 1761-CBL-AC00

This 3-node network is not expandable.

DH-485 Network

TX

TERM

COM

SHLD

CHS GND

TX

AIC+

TX PWR

DC SOURCE

CABLE

EXTERNAL

Networked Operator Interface Device and MicroLogix Controllers

AIC+

TX

TERM

COM

SHLD

CHS GND

TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

AIC+

TX

TERM

COM

SHLD

CHS GND

TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

A-B PanelView

SLC 5/04

PanelView 550

AIC+

TX

TERM

COM

SHLD

CHS GND

TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

AIC+

TX

TERM

COM

SHLD

CHS GND

TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

AIC+

TX

TERM

COM

SHLD

CHS GND

TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

Personal

Computer

MicroLogix 1000 MicroLogix 1200 MicroLogix 1500

MicroLogix Remote Packet Support

MicroLogix 1200 controllers can respond and initiate with communications

(or commands) that do not originate on the local DH-485 network. This is useful in installations where communication is needed between DH-485 and

DH+ networks.

The example below shows how to send messages from a device on the DH+ network to a MicroLogix controller on the DH-485 network. This method uses an SLC 5/04 processor as the bridge connection.

When using this method (as shown in the illustration below):

PLC-5 devices can send read and write commands to MicroLogix 1200 controllers.

MicroLogix 1200 controllers can respond to MSG instructions received.

Publication 1762-UM001H-EN-P - June 2015

Connect to Networks via RS-232 Interface E-11

The MicroLogix 1200 controllers can initiate MSG instructions to devices on the DH+ network.

PC can send read and write commands to MicroLogix 1200 controllers.

PC can do remote programming of MicroLogix 1200 controllers.

AIC+

TERM

COM

SHLD

CHS GND

TX TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

SLC 5/04

DH-485 Network

TX

TERM

COM

SHLD

CHS GND

TX

AIC+

TX PWR

DC SOURCE

CABLE

EXTERNAL

MicroLogix 1000

DH+ Network

TERM

COM

SHLD

CHS GND

TX TX

AIC+

TX PWR

DC SOURCE

CABLE

EXTERNAL

MicroLogix 1200

TX

TERM

COM

SHLD

CHS GND

TX

AIC+

TX PWR

DC SOURCE

CABLE

EXTERNAL

MicroLogix 1500

AIC+

TERM

COM

SHLD

CHS GND

TX TX

TX PWR

DC SOURCE

CABLE

EXTERNAL

AIC+

TERM

TX

COM

SHLD

CHS GND

TX

A-B

TX PWR

DC SOURCE

CABLE

EXTERNAL

SLC 5/04

PanelView

PanelView 550

Personal Computer

SLC 5/04 PLC-5

Publication 1762-UM001H-EN-P - June 2015

E-12 Connect to Networks via RS-232 Interface

Modbus Communication

Protocol

Modbus is a Half-duplex, master-slave communications protocol. The Modbus network master reads and writes coils and registers. Modbus protocol allows a single master to communicate with a maximum of 247 slave devices.

MicroLogix 1200 controllers support Modbus RTU Master and Modbus RTU

Slave protocol.

For more information on configurating your MicroLogix 1200 controller for

Modbus protocol, refer to the MicroLogix 1200 and 1500 Programmable

Controllers Instruction Set Reference Manual, publication 1762-RM001. For more information about the Modbus protocol, see the Modbus Protocol

Specifications (available from http://www.modbus.org).

ASCII

ASCII provides connection to other ASCII devices, such as bar code readers, weigh scales, serial printers, and other intelligent devices.

You can use ASCII by configuring the RS-232 port, channel 0 for ASCII driver.

Refer to the MicroLogix 1200 and MicroLogix 1500 Programmable

Controllers Instruction Set Reference Manual, publication 1762-RM001 for detailed configuration information.

Publication 1762-UM001H-EN-P - June 2015

1

Appendix

F

System Loading and Heat Dissipation

System Loading Limitations

When you connect MicroLogix accessories and expansion I/O, an electrical load is placed on the controller power supply. This section shows how to calculate the load and validate that the system will not exceed the capacity of the controller power supply.

The following example is provided to illustrate system loading validation. The system validation procedure accounts for the amount of 5V dc and 24V dc current consumed by controller, expansion I/O, and user-supplied equipment.

Use the System Loading Worksheet on page F-4 to validate your specific

24-point controller configuration.

Use the System Loading Worksheet on page F-9 to validate your specific

40-point controller.

Current consumed by the processor, memory modules, and the real-time clock modules has already been factored into the calculations. A system is valid if the current and power requirements are satisfied.

System Current Loading Example Calculations (24-point

Controller)

Table F.1 Calculating the Current for MicroLogix Accessories

Catalog Number Device Current Requirements Calculated Current

1761-NET-AIC

(1)

when powered by the base unit communications port, selector switch in the up position

at 5V dc (mA) at 24V dc (mA) at 5V dc (mA) at 24V dc (mA)

0 120 0

120

Subtotal 1: 0 120

(1) This is an optional accessory. Current is consumed only if the accessory is installed.

Publication 1762-UM001H-EN-P - June 2015

F-2 System Loading and Heat Dissipation

Table F.2 Calculating the Current for Expansion I/O

1762-IA8

1762-IF4

1762-IF2OF2

1762-IQ8

1762-IQ16

1762-IQ32T

1762-IR4

1762-IT4

1762-OA8

1762-OB8

1762-OB16

1762-OB32T

1762-OF4

1762-OV32T

1762-OW8

1762-OW16

Catalog Number

(1)

1762-OX6I

1762-IQ8OW6

Total Modules (6 maximum): n

Number of

Modules

2

2

4

115

175

175

40

175

50

40

40

50

A at 5V dc (mA)

B

Device Current Requirements

(max) n x A n x B

Calculated Current at 24V dc (mA) at 5V dc (mA) at 24V dc (mA)

100 0

70

(2)

170

0

50

105

0

0

40

40

115

0

50

50

0

0

0

0

165

0

80

140

(2)

110

110

Subtotal 2:

90

180

(2)

110

80

160

260

180

180

(1) Refer to your expansion I/O Installation Instructions for Current Requirements not listed in this table.

(2) Only applicable to Series B I/O modules.

Validate the System

The example systems shown in the tables below are verified to be acceptable configurations. The systems are valid because:

Calculated Current Values < Maximum Allowable Current Values

Calculated System Loading < Maximum Allowable System Loading

Publication 1762-UM001H-EN-P - June 2015

System Loading and Heat Dissipation F-3

Table F.3 Validating Systems Using 1762-L24AWA, 1762-L24BXB, 1762-L24AWAR or 1762-L24BXBR

Maximum Allowable Values Calculated Values

Current:

400 mA at 5V dc

System Loading:

350 mA at 24V dc

Current (Subtotal 1 + Subtotal 2 from Table F.1 and Table F.2 on page F-2.):

0 mA + 260 mA = 260 mA at 5V dc

System Loading:

= (260 mA x 5V) + (300 mA x 24 V)

120 mA + 180 mA = 300 mA at 24V dc

10.4 Watts

= (1300 mW) + (7200 mW)

= 8500 mW

= 8.50 Watts

Table F.4 Validating Systems using 1762-L24BWA or 1762-L24BWAR

Maximum Allowable Values Calculated Values

Current for Devices Connected to the +24V dc

Sensor Supply:

Sum of all sensor currents

250 mA at 24V dc

Current for MicroLogix Accessories and

Expansion I/O:

400 mA at 5V dc

System Loading:

350 mA at 24V dc

140 mA at 24V dc (example sensor value)

Current Values (Subtotal 1 from Table F.1 + Subtotal 2 from Table F.2):

0 mA + 260 mA = 260 mA at 5V dc

System Loading:

120 mA + 180 mA = 300 mA at 24V dc

= (140 mA x 24 V) + (260 mA x 5 V) + (300 mA x 24 V)

12 Watts

= (3360 mW) + (1300 mW) + (7200 mW)

= 11,860 mW

= 11.9 Watts

Publication 1762-UM001H-EN-P - June 2015

F-4 System Loading and Heat Dissipation

System Loading Worksheet

The tables below are provided for system loading validation for 24-point

Controllers. See System Current Loading Example Calculations (24-point

Controller) on page F-1.

Current Loading

Table F.5 Calculating the Current for MicroLogix Accessories

Catalog Number Device Current Requirements Calculated Current at 5V dc (mA) at 24V dc (mA) at 5V dc (mA) at 24V dc (mA)

0 120

1761-NET-AIC

(1)

when powered by the base unit communications port, selector switch in the up position

Subtotal 1:

(1) This is an optional accessory. Current is consumed only if the accessory is installed.

Table F.6 Calculating the Current for Expansion I/O

Catalog Number

1762-IA8

1762-IF4

1762-IF2OF2

1762-IQ8

1762-IQ16

1762-IQ32T

1762-IR4

1762-IT4

1762-OA8

1762-OB8

1762-OB16

1762-OB32T

1762-OF4

1762-OV32T

1762-OW8

1762-OW16

1762-OX6I

1762-IQ8OW6

(1)

Total Modules (6 maximum): n

Number of

Modules

115

175

175

40

170

40

40

115

40

40

50

70

(2)

A B

Device Current Requirements at 5V dc (mA)

50

at 24V dc (mA)

0

n x A n x B

Calculated Current at 5V dc (mA) at 24V dc (mA)

0

0

50

105

175

80

140

(2)

110

110

Subtotal 2:

0

50

50

0

0

0

0

165

0

90

180

110

80

(2)

(1) Refer to your expansion I/O Installation Instructions for Current Requirements not listed in this table.

(2) Only applicable to Series B I/O modules.

Publication 1762-UM001H-EN-P - June 2015

System Loading and Heat Dissipation F-5

Table F.7 Validating Systems using 1762-L24AWA, 1762-L24BXB, 1762-L24AWAR or 1762-L24BXBR

Maximum Allowable Values Calculated Values

Current:

400 mA at 5V dc

System Loading:

350 mA at 24V dc

Current (Subtotal 1 from Table F.5 + Subtotal 2 from Table F.6.):

mA at 5V dc

System Loading: mA at 24V dc

= (________ mA x 5V) + (________ mA x 24V)

10.4 Watts

= __________ mW + __________ mW

= __________ mW

= __________ W

Table F.8 Validating Systems using 1762-L24BWA or 1762-L24BWAR

Maximum Allowable Values Calculated Values

Current for Devices Connected to the +24V dc Sensor

Supply:

Sum of all sensor currents

Include 1761-NET-AIC here rather than in Table F.5, if it is powered externally by

the sensor supply

250 mA at 24V dc mA at 24V dc

Current for MicroLogix Accessories and Expansion I/O: Current (Subtotal 1 from Table F.5 + Subtotal 2 from Table F.6.)

400 mA at 5V dc

System Loading:

350 mA at 24V dc mA at 5V dc

System Loading: mA at 24V dc

= (________ mA x 24 V) + (________ mA x 5V) + (________ mA x 24 V)

12 Watts

= __________ mW + __________ mW + __________ mW

= __________ mW

= __________ W

Publication 1762-UM001H-EN-P - June 2015

F-6 System Loading and Heat Dissipation

System Current Loading Example Calculations (40-point

Controller)

Table F.9 Calculating the Current for MicroLogix Accessories

Catalog Number Device Current Requirements at 5V dc (mA) at 24V dc (mA)

Calculated Current at 5V dc

(mA)

0

at 24V dc

(mA)

120

1761-NET-AIC

(1)

when powered by the base unit communications port, selector switch in the up position

Subtotal 1:

0

(1) This is an optional accessory. Current is consumed only if the accessory is installed.

120

0 120

Table F.10 Calculating the Current for Expansion I/O

1762-IQ32T

1762-IR4

1762-IT4

1762-OA8

1762-OB8

1762-OB16

1762-OB32T

1762-OF4

1762-OV32T

1762-OW8

1762-OW16

Catalog Number

1762-IA8

1762-IF4

1762-IF2OF2

1762-IQ8

1762-IQ16

(1)

1762-OX6I

1762-IQ8OW6

Total Modules (6 maximum): n

Number of

Modules

1

2

1

1

6

115

175

175

40

170

40

40

115

175

80

140

(2)

110

110

Subtotal 2:

50

40

40

50

70

(2)

A B n x A n x B

Device Current Requirements (max) Calculated Current at 5V dc (mA) at 24V dc (mA) at 5V dc (mA) at 24V dc (mA)

0

0

0

50

105 40

140

(2)

105

0

0

0

0

165

0

50

50

0

0

90

180

(2)

110

80

115

140

(2)

0

180

(2)

435 285

(1) Refer to your expansion I/O Installation Instructions for Current Requirements not listed in this table.

(2) Only applicable to Series B I/O modules.

Publication 1762-UM001H-EN-P - June 2015

System Loading and Heat Dissipation F-7

Validate the System

The example systems shown in Table F.11 and Table F.12 are verified to be

acceptable configurations. The systems are valid because:

Calculated Current Values < Maximum Allowable Current Values

Calculated System Loading < Maximum Allowable System Loading

Table F.11 Validating Systems using 1762-L40AWA, 1762-L40BXB, 1762-L40AWAR or 1762-L40BXBR

Maximum Allowable Values Calculated Values

Current:

600 mA at 5V dc

System Loading:

500 mA at 24V dc

Current (Subtotal 1 from Table F.9 + Subtotal 2 from Table F.10):

0 mA + 435 mA = 435 mA at 5V dc 120 mA + 285 mA = 405 mA at 24V dc

15 Watts

System Loading:

= (4.5 mA x 5V) + (405 mA x 24V)

= (2175 mW) + (9720 mW)

= 11,895 mW

= 11.90 Watts

Table F.12 Validating Systems using 1762-L40BWA or 1762-L40BWAR

Maximum Allowable Values Calculated Values

Current for Devices Connected to the +24V dc

Sensor Supply:

Sum of all current sensors

400 mA at 24V dc

Current for MicroLogix Accessories and

Expansion I/O:

600 mA at 5V dc

System Loading:

500 mA at 24V dc

150 mA at 24V dc (example sensor value)

Current (Subtotal 1 from Table F.9 + Subtotal 2 from Table F.10):

0 mA + 435 mA = 435 mA at 5V dc

System Loading:

120 mA + 285 mA = 405 mA at 24V dc

= (150 mA x 24V) + (435 mA x 5V) + (405 mA x 24V)

16 Watts

= (3600 mW) + (2175 mW) + (9720 mW)

= 15,495 W

= 15.50 Watts

Publication 1762-UM001H-EN-P - June 2015

F-8 System Loading and Heat Dissipation

System Loading Worksheet

The tables below are provided for system loading validation for 40-point

Controllers. See System Current Loading Example Calculations (40-point

Controller) on page F-6.

Current Loading

Table F.13 Calculating the Current for MicroLogix Accessories

Catalog Number Device Current Requirements Calculated Current at 5V dc (mA) at 24V dc (mA) at 5V dc (mA) at 24V dc (mA)

0 120

1761-NET-AIC

(1)

when powered by the base unit communications port, selector switch in the up position

Subtotal 1:

(1) This is an optional accessory. Current is consumed only if the accessory is installed.

1762-IQ32T

1762-IR4

1762-IT4

1762-OA8

1762-OB8

1762-OB16

1762-OB32T

1762-OF4

1762-OV32T

1762-OW8

1762-OW16

Table F.14 Calculating the Current for Expansion I/O

Catalog Number

(1) n

Number of

Modules

1762-IA8

1762-IQ8

1762-IF4

1762-IF2OF2

1762-IQ16

115

175

175

40

170

40

40

115

175

80

140

(2)

50

50

40

40

70

(2)

A B

Device Current Requirements at 5V dc (mA) n x A n x B

Calculated Current at 24V dc (mA) at 5V dc (mA) at 24V dc (mA)

0

0

50

105

0

0

50

50

0

0

0

0

165

0

90

180

(2)

Publication 1762-UM001H-EN-P - June 2015

System Loading and Heat Dissipation F-9

Table F.14 Calculating the Current for Expansion I/O

1762-OX6I

1762-IQ8OW6

Total Modules (6 maximum):

110

110

Subtotal 2:

110

80

(1) Refer to your expansion I/O Installation Instructions for Current Requirements not listed in this table.

(2) Only applicable to Series B I/O modules.

Table F.15 Validating Systems using 1762-L40AWA, 1762-L40BXB, 1762-L40AWAR or 1762-L40BXBR

Maximum Allowable Values Calculated Values

Current:

600 mA at 5V dc 500 mA at 24V dc

Current (Subtotal 1 from Table F.13 + Subtotal 2 from Table F.14.):

System Loading: System Loading:

= (________ mA x 5V) + (________ mA x 24V)

15 Watts

= __________ mW + __________ mW

= __________ mW

= __________ W

Table F.16 Validating Systems using 1762-L40BWA or 1762-L40BWAR

Maximum Allowable Values Calculated Values

Current for Devices Connected to the +24V dc Sensor

Supply:

Sum of all sensor currents

Include 1761-NET-AIC here rather than in Table F.13, if it is powered externally by

the sensor supply

400 mA at 24V dc mA at 24V dc

Current for MicroLogix Accessories and Expansion I/O: Current (Subtotal 1 from Table F.13 + Subtotal 2 from page Table F.14.):

600 mA at 5V dc

System Loading:

500 mA at 24V dc mA at 5 V dc

System Loading: mA at 24V dc

= (________ mA x 24V) + (________ mA x 5V) + (________ mA x 24V)

16 Watts

= __________ mW + __________ mW + __________ mW

= __________ mW

= __________ W

Publication 1762-UM001H-EN-P - June 2015

F-10 System Loading and Heat Dissipation

Calculating Heat

Dissipation

Use the following table when you need to determine the heat dissipation of your system for installation in an enclosure. For System Loading, take the value

from the appropriate system loading worksheets on pages F-4, F-5, F-8 or F-9:

Table F.17 Heat Dissipation

Catalog Number

1762-L24AWA, -L24AWAR

1762-L24BWA, -L24BWAR

1762-L24BXB, -L24BXBR

1762-L40AWA, -L40AWAR

1762-L40BWA, -L40BWAR

1762-L40BXB, -L40BXBR

1762-IA8

1762-IF4

1762-IF2OF2

1762-IQ8

1762-IQ16

1762-IQ32T

Heat Dissipation

Equation or Constant

15.2W + (0.4 x System Loading)

15.7W + (0.4 x System Loading)

17.0W + (0.3 x System Loading)

21.0W + (0.4 x System Loading)

22.0W + (0.4 x System Loading)

Calculation

15.2W + (0.4 x ______ W)

15.7W + (0.4 x ______ W)

17.0W + (0.3 x ______ W)

21.0W + (0.4 x ______ W)

22.0W + (0.4 x ______ W)

27.9W + (0.3 x ______ W)

2.0W x _________

27.9W + (0.3 x System Loading)

2.0W x number of modules

2.0W x number of modules

2.6W x number of modules

3.7W x number of modules

5.1W

(1)

x number of modules

2.0W x _________

2.6W x _________

3.7W x _________

5.1W

(1)

x _________

6.8 W x number of modules (at 30.0V dc)

5.4 W x number of modules (at 26.4V dc)

6.8 W x _________ (at 30.0V dc)

5.4 W x _________ (at 26.4V dc)

1.5W x number of modules 1.5W x _________ 1762-IR4

1762-IT4

1762-OA8

1762-OB8

1762-OB16

1762-OB32T

1762-OF4

1762-OV32T

1.5W x number of modules

2.9W x number of modules

1.6W x number of modules

2.9W x number of modules

3.4 W x number of modules

2.8W x number of modules

2.7 W x number of modules

1762-OW8

1762-OW16

2.9W x number of modules

6.1

(1)

W x number of modules

1762-OX6I

1762-IQ8OW6

2.8W x number of modules

5.0W x number of modules (at 30V dc)

4.4W x number of modules (at 26.4V dc)

Add Sub-totals to determine Heat Dissipation

1.5W x _________

2.9W x _________

1.6W x _________

2.9W x _________

3.4 W x _________

2.8W x _________

2.7 W x _________

2.9W x _________

6.1W

(1)

x _________

2.8W x _________

5.0W x _________

4.4W x _________

(1) Only applicable to Series B I/O modules.

Sub-Total

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

W

Publication 1762-UM001H-EN-P - June 2015

1

Glossary

The following terms are used throughout this manual. Refer to the

Allen-Bradley Industrial Automation Glossary, Publication Number AG-7.1, for a complete guide to Allen-Bradley technical terms.

address

A character string that uniquely identifies a memory location. For example,

I:1/0 is the memory address for the data located in the Input file location word1, bit 0.

AIC+ Advanced Interface Converter

A device that provides a communication link between various networked devices. (Catalog Number 1761-NET-AIC.)

application

1) A machine or process monitored and controlled by a controller.

2) The use of computer- or processor-based routines for specific purposes.

baud rate

The speed of communication between devices. All devices must communicate at the same baud rate on a network.

bit

The smallest storage location in memory that contains either a 1 (ON) or a 0

(OFF).

block diagrams

A schematic drawing.

Boolean operators

Logical operators such as AND, OR, NAND, NOR, NOT, and Exclusive-OR that can be used singularly or in combination to form logic statements or circuits. Can have an output response of T or F.

branch

A parallel logic path within a rung of a ladder program.

communication scan

A part of the controller’s operating cycle. Communication with other devices, such as software running on a personal computer, takes place.

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Glossary 2

Publication 1762-UM001H-EN-P - June 2015

controller

A device, such as a programmable controller, used to monitor input devices and control output devices.

controller overhead

An internal portion of the operating cycle used for housekeeping and set-up purposes.

control profile

The means by which a controller determines which outputs turn on under what conditions.

counter

1) An electro-mechanical relay-type device that counts the occurrence of some event. May be pulses developed from operations such as switch closures or interruptions of light beams.

2) In controllers, a software counter eliminates the need for hardware counters.

The software counter can be given a preset count value to count up or down whenever the counted event occurs.

CPU (Central Processing Unit)

The decision-making and data storage section of a programmable controller.

data table

The part of processor memory that contains I/O values and files where data is monitored, manipulated, and changed for control purposes.

DIN rail

Manufactured according to Deutsche Industrie Normenausshus (DIN) standards, a metal railing designed to ease installation and mounting of your controller.

download

Data is transferred from a programming or storage device to another device.

DTE (Data Terminal Equipment)

Equipment that is attached to a network to send or receive data, or both.

embedded I/O

Embedded I/O is the controller’s on-board I/O.

Glossary 3

EMI

Electromagnetic interference.

encoder

1) A rotary device that transmits position information.

2) A device that transmits a fixed number of pulses for each revolution.

executing mode

Any run or test mode.

expansion I/O

Expansion I/O is I/O that is connected to the controller via a bus or cable.

MicroLogix 1200 controllers use Bulletin 1762 expansion I/O.

false

The status of an instruction that does not provide a continuous logical path on a ladder rung.

FIFO (First-In-First-Out)

The order that data is entered into and retrieved from a file.

file

A collection of information organized into one group.

full-duplex

A bidirectional mode of communication where data may be transmitted and received simultaneously (contrast with half-duplex).

half-duplex

A communication link in which data transmission is limited to one direction at a time.

hard disk

A storage area in a personal computer that may be used to save processor files and reports for future use.

high byte

Bits 8 to 15 of a word.

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Glossary 4

Publication 1762-UM001H-EN-P - June 2015

input device

A device, such as a push button or a switch, that supplies signals to the input circuits of the controller.

inrush current

The temporary surge current produced when a device or circuit is initially energized.

instruction

A mnemonic and data address defining an operation to be performed by the processor. A rung in a program consists of a set of input and output instructions. The input instructions are evaluated by the controller as being true or false. In turn, the controller sets the output instructions to true or false.

instruction set

The set of general purpose instructions available with a given controller.

I/O (Inputs and Outputs)

Consists of input and output devices that provide and/or receive data from the controller.

jump

Change in normal sequence of program execution, by executing an instruction that alters the program counter (sometimes called a branch). In ladder programs a JUMP (JMP) instruction causes execution to jump to a labeled rung.

ladder logic

A program written in a format resembling a ladder-like diagram. The program is used by a programmable controller to control devices.

least significant bit (LSB)

The digit (or bit) in a binary word (code) that carries the smallest value of weight.

LED (Light Emitting Diode)

Used as status indicator for processor functions and inputs and outputs.

LIFO (Last-In-First-Out)

The order that data is entered into and retrieved from a file.

Glossary 5

low byte

Bits 0 to 7 of a word.

logic

A process of solving complex problems through the repeated use of simple functions that can be either true or false. General term for digital circuits and programmed instructions to perform required decision making and computational functions.

Master Control Relay (MCR)

A mandatory hard-wired relay that can be de-energized by any series-connected emergency stop switch. Whenever the MCR is de-energized, its contacts open to de-energize all application I/O devices.

mnemonic

A simple and easy to remember term that is used to represent a complex or lengthy set of information.

modem

Modulator/demodulator. Equipment that connects data terminal equipment to a communication line.

modes

Selected methods of operation. Example: run, test, or program.

negative logic

The use of binary logic in such a way that “0” represents the voltage level normally associated with logic 1 (for example, 0 = +5V, 1 = 0V). Positive is more conventional (for example, 1 = +5V, 0 = 0V).

network

A series of stations (nodes) connected by some type of communication medium. A network may be made up of a single link or multiple links.

nominal input current

The current at nominal input voltage.

normally closed

Contacts on a relay or switch that are closed when the relay is de-energized or the switch is deactivated; they are open when the relay is energized or the

Publication 1762-UM001H-EN-P - June 2015

Glossary 6

Publication 1762-UM001H-EN-P - June 2015 switch is activated. In ladder programming, a symbol that allows logic continuity (flow) if the referenced input is logic “0” when evaluated.

normally open

Contacts on a relay or switch that are open when the relay is de-energized or the switch is deactivated. (They are closed when the relay is energized or the switch is activated.) In ladder programming, a symbol that allows logic continuity (flow) if the referenced input is logic “1” when evaluated.

off-delay time

The OFF delay time is a measure of the time required for the controller logic to recognize that a signal has been removed from the input terminal of the controller. The time is determined by circuit component delays and by any filter adjustment applied.

offline

Describes devices not under direct communication.

offset

The steady-state deviation of a controlled variable from a fixed point.

off-state leakage current

When an ideal mechanical switch is opened (off-state) no current flows through the switch. Practical semiconductor switches, and the transient suppression components which are sometimes used to protect switches, allow a small current to flow when the switch is in the off state. This current is referred to as the off-state leakage current. To ensure reliable operation, the off-state leakage current rating of a switch should be less than the minimum operating current rating of the load that is connected to the switch.

on-delay time

The ON delay time is a measure of the time required for the controller logic to recognize that a signal has been presented at the input terminal of the controller.

one-shot

A programming technique that sets a bit for only one program scan.

online

Describes devices under direct communication. For example, when RSLogix

500 is monitoring the program file in a controller.

Glossary 7

operating voltage

For inputs, the voltage range needed for the input to be in the On state. For outputs, the allowable range of user-supplied voltage.

output device

A device, such as a pilot light or a motor starter coil, that is controlled by the controller.

processor

A Central Processing Unit. (See CPU.)

processor file

The set of program and data files used by the controller to control output devices. Only one processor file may be stored in the controller at a time.

program file

The area within a processor file that contains the ladder logic program.

program mode

When the controller is not executing the processor file and all outputs are de-energized.

program scan

A part of the controller’s operating cycle. During the scan the ladder program is executed and the output data file is updated based on the program and the input data file.

programming device

Executable programming package used to develop ladder diagrams.

protocol

The packaging of information that is transmitted across a network.

read

To acquire data from a storage place. For example, the processor READs information from the input data file to solve the ladder program.

relay

An electrically operated device that mechanically switches electrical circuits.

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Glossary 8

Publication 1762-UM001H-EN-P - June 2015

relay logic

A representation of the program or other logic in a form normally used for relays.

restore

To download (transfer) a program from a personal computer to a controller.

reserved bit

A status file location that the user should not read or write to.

retentive data

Information associated with data files (timers, counters, inputs, and outputs) in a program that is preserved through power cycles.

RS-232

An EIA standard that specifies electrical, mechanical, and functional characteristics for serial binary communication circuits. A single-ended serial communication interface.

run mode

This is an executing mode during which the controller scans or executes the ladder program, monitors input devices, energizes output devices, and acts on enabled I/O forces.

rung

Ladder logic is comprised of a set of rungs. A rung contains input and output instructions. During Run mode, the inputs on a rung are evaluated to be true or false. If a path of true logic exists, the outputs are made true. If all paths are false, the outputs are made false.

save

To upload (transfer) a program stored in memory from a controller to a personal computer; OR to save a program to a computer hard disk.

scan time

The time required for the controller to execute the instructions in the program. The scan time may vary depending on the instructions and each instruction’s status during the scan.

Glossary 9

sinking

A term used to describe current flow between an I/O device and controller

I/O circuit — typically, a sinking device or circuit provides a path to ground, low, or negative side of power supply.

sourcing

A term used to describe current flow between an I/O device and controller

I/O circuit — typically, a sourcing device or circuit provides a path to the source, high, or positive side of power supply.

status

The condition of a circuit or system, represented as logic 0 (OFF) or 1 (ON).

terminal

A point on an I/O module that external I/O devices, such as a push button or pilot light, are wired to.

throughput

The time between when an input turns on and the corresponding output turns on.

true

The status of an instruction that provides a continuous logical path on a ladder rung.

upload

Data is transferred to a programming or storage device from another device.

watchdog timer

A timer that monitors a cyclical process and is cleared at the conclusion of each cycle. If the watchdog runs past its programmed time period, it causes a fault.

workspace

The main storage available for programs and data and allocated for working storage.

write

To copy data to a storage device. For example, the processor WRITEs the information from the output data file to the output modules.

Publication 1762-UM001H-EN-P - June 2015

Glossary 10

Notes:

Publication 1762-UM001H-EN-P - June 2015

Index

Numerics

1762-24AWA wiring diagram

3-12

1762-40BWA sourcing wiring diagram

3-15

1762-IA8 wiring diagram

3-18

1762-IF2OF2

input type selection

3-26

output type selection terminal block layout wiring

3-27

3-26

3-27

1762-IF4

input type selection

3-28

terminal block layout

3-29

1762-IQ16 wiring diagram

3-19

1762-IQ32T wiring diagram

1762-IQ8 wiring diagram

3-20

3-18

1762-IQ80W6 wiring diagram

3-25

1762-OA8 wiring diagram

3-20

1762-OB16 wiring diagram

3-21

1762-OB32T wiring diagram

3-22

1762-OB8 wiring diagram

3-21

1762-OV32T wiring diagram

3-22

1762-OW16 wiring diagram

1762-OW8 wiring diagram

3-23

3-23

1762-OX6I wiring diagram

3-24

A

address

G-1

Advanced Interface Converter. See AIC+

agency certifications

2-1

AIC+

apply power to

4-17 attach to the network

4-17

connect

4-12

connecting

isolated modem

4-6

definition

G-1

install

4-17

modem connections

4-6

recommended user supplied components

4-15

safety consideration

4-17

4-14

select cable

analog expansion I/O

C-4 diagnostics

C-4 module operation vs. channel operation

C-4 power-up diagnostics

C-4

system wiring guidelines troubleshooting

application

G-1

C-4

3-25

B

battery

6-2

baud rate

G-1

bit

G-1

block diagrams

G-1

Boolean operators

G-1

branch

G-1

C

cables

planning routes for DH485 connections

E-7

selection guide for the AIC+

4-14

call for assistance

C-8

CE mark

2-2

common mode rejection ratio

specification

A-19

common techniques used in this manual

P-2

communication connections

4-1

communication options

1-4

communication protocols

DF1 Full-duplex

DF1 Half-duplex

E-1

E-2

DH485

E-5

Modbus

E-12

communication scan

G-1

communications toggle push button

use

4-3

component descriptions

1-2

1762 expansion I/O

1-3

communication cables

1-4

memory module

1-2 real-time clock

1-2

configuration errors

C-6

connect expansion I/O

2-19

connect the system

AIC+

4-12, 4-17

DF1 Full-Duplex protocol

4-4

DF1 isolated point-to-point connection

4-5

DH485 network

4-9

connect to DF1 Half-Duplex network

4-8

contactors (bulletin 100), surge suppressors for

3-5

control profile

G-2

ControlFlash

missing/corrupt OS LED pattern

D-2

sequence of operation

D-2

use

D-1

Publication 1762-UM001H-EN-P - June 2015

2 Index

controller

G-2

ground

3-6

I/O wiring

3-17

installation

2-1

LED status

C-1

LED status error conditions

C-2

LED status normal operation

C-2

3-17

minimize electrical noise mount

2-14

mount on DIN rail mount on panel

2-15

2-16

mounting dimensions prevent excessive heat

controller overhead

G-2

2-13

2-7

controller spacing

2-13

counter

G-2

CPU (Central Processing Unit)

G-2

D

data table

G-2

default communication configuration

4-2

DF1 Full-Duplex protocol

connect

4-4, 4-5

DF1 Full-duplex protocol

description

E-1

example system configuration

use a modem

4-5

using a modem

E-3

E-2

DF1 Half-Duplex protocol

description

E-2

DH485 network

configuration parameters

connect

4-9

E-8

devices that use the network example system configuration

installation

4-9

E-5

E-9

planning considerations

E-6

DIN rail

G-2

disconnect main power

2-5

download

G-2

DTE (Data Terminal Equipment)

G-2

encoder

G-3

error recovery model

C-3

errors

configuration

C-6

critical

C-5

extended error information field

hardware

C-6

module error field

non-critical

C-5

EMC Directive

2-2

low voltage directive

executing mode

G-3

C-6

C-6

European Union Directive compliance

2-2

2-2

expansion I/O

1762-IF2OF2 input type selection

3-26

1762-IF2OF2 output type selection

expansion I/O mount

2-18

expansion I/O wiring

3-18

3-18

3-26

1762-IA8 wiring diagram

1762-IF2OF2 wiring

3-27

1762-IF4 terminal block layout

1762-IQ16 wiring diagram

3-29

3-19

1762-IQ32T wiring diagram

3-20

1762-IQ8 wiring diagram

3-18

1762-IQ80W6 wiring diagram

3-25

1762-OA8 wiring diagram

3-20

1762-OB16 wiring diagram

3-21

3-22

1762-OB32T wiring diagram

1762-OB8 wiring diagram

3-21

1762-OV32T wiring diagram

1762-OW16 wiring diagram

3-22

3-23

1762-OW8 wiring diagram

1762-OX6I wiring diagram analog wiring guidelines

3-23

3-24

3-25

extended error information field

C-6

F

false

G-3

FIFO (First-In-First-Out)

G-3

file

G-3

Full-duplex

4-5

full-duplex

G-3

E

Electronics Industries Association (EIA)

E-1

EMC Directive

2-2

EMI

G-3

G

general considerations

2-2

ground the controller

3-6

Publication 1762-UM001H-EN-P - June 2015

H

Half-duplex

4-8, G-3

hard disk

G-3

hardware errors

C-6

hardware features

1-1

heat dissipation

calculating

F-10

heat protection

2-7

high byte

G-3

I

I/O (Inputs and Outputs)

G-4

input device

G-4

input states on power down

2-7

inrush current

G-4

install

ControlFlash software

D-1

memory module

2-12

your controller

2-1

install real-time clock

2-12

instruction

G-4

instruction set

G-4

isolated link coupler

install

4-10

isolation transformers

power considerations

2-6

J

jump

G-4

L

ladder logic

G-4

least significant bit (LSB)

G-4

LED (Light Emitting Diode)

G-4

LIFO (Last-In-First-Out)

G-4

logic

G-5

low byte

G-5

M

manuals

related

P-2

master control relay

2-8

emergency-stop switches

2-9

Index 3 using ANSI/CSA symbols schematic

2-11

using IEC symbols schematic

2-10

Master Control Relay (MCR)

G-5

master control relay circuit

periodic tests

2-6

memory module

data file protection

6-4

operation

6-3

program compare

6-4

program/data backup

6-3

removal/installation under power

6-4

write protection

6-4

minimize electrical noise

3-17

mnemonic

G-5

Modbus communication protocol

E-12

modem

G-5

modem cable

construct your own

4-7

modems

use with MicroLogix controllers

E-3

modes

G-5

module error field

C-6

motor starters (bulletin 509)

surge suppressors

3-5

motor starters (bulletin 709)

surge suppressors

3-5

mount expansion I/O

2-17

mount on DIN rail

2-17

N

negative logic

G-5

network

G-5

nominal input current

G-5

normally closed

G-5

normally open

G-6

null modem cable

4-7

O

offline

G-6

offset

G-6

off-state leakage current

G-6

one-shot

G-6

online

G-6

operating voltage

G-7

output device

G-7

Publication 1762-UM001H-EN-P - June 2015

4 Index

P

planning considerations for a network

E-6

power considerations

input states on power down

2-7

isolation transformers

2-6

loss of power source

other line conditions

2-7

2-7

overview

2-6 power supply inrush

2-6

power distribution

2-5

power source

loss of

2-7

power supply inrush

power considerations

prepare for upgrade

2-6

D-1

prevent excessive heat

2-7

processor

G-7

processor file

G-7

program

1-4

program file

G-7

program mode program scan

G-7

G-7

programming device

G-7

protocol

G-7

publications

related

P-2

purpose of this manual

P-1

R

read

G-7

real-time clock

battery operation

disable

6-2

operation

6-1

6-2

removal/installation under power write data

6-2

related documentation

P-2

related publications

P-2

relay

G-7

relay logic

G-8

6-1

relays

surge suppressors for

remote packet support

3-5

E-10

replacement parts

B-1

reserved bit

G-8

restore

G-8

retentive data

G-8

RS-232

G-8

RS-232 communication interface

E-1

Publication 1762-UM001H-EN-P - June 2015

run mode rung

G-8

G-8

S

safety circuits

2-5

safety considerations

2-3

disconnect main power

hazardous location

2-3

2-5

master control relay circuit periodic tests

2-6

periodic tests of master control relay

circuit

2-6

power distribution

2-5

save

safety circuits

G-8

scan time

G-8

2-5

sinking

G-9

sinking and sourcing wiring diagrams

3-12

sinking wiring diagram

1762-24BWA

3-13

sourcing

G-9

sourcing wiring diagram

1762-24BWA

3-13

specifications

A-1

status

G-9

surge suppressors

for contactor

3-5

for motor starters

for relays

3-5

recommended use

3-3

3-5

3-5

system configuration

DF1 Full-duplex examples

E-2

DH485 connection examples

E-9

system loading

example calculations limitations worksheet

F-1

F-4

F-1

system loading and heat dissipation

F-1

T

terminal

G-9

terminal block layouts

1762-IF2OF2

1762-IF4

3-27

3-29

controllers

3-7

terminal groupings

3-9

terminal groupings

3-9

throughput

G-9

Index 5

Trim Pot Information Function File

5-2

trim pot operation

5-1

trim pots

5-1 adjustment

5-1

error conditions

5-2

location

5-1

troubleshoot your system

C-1

true

G-9

U

upload

G-9

use communications toggle push button

4-3

use emergency-stop switches

2-9

use memory modules

6-1

use real-time clock

6-1

use trim pots

5-1

W

wire your controller

3-1

wiring diagram

1762-IA8

3-18

1762-IF2OF2 differential sensor

3-27

1762-IF2OF2 single-ended sensor

3-28

1762-IQ16

3-19

1762-IQ32T

3-20

1762-IQ8

3-18

1762-IQ80W6

3-25

1762-L24AWA input

3-12

1762-L24AWA output

3-14

1762-L24BWA output

3-14

1762-L24BWA sinking

3-13

1762-L24BWA sourcing

3-13

1762-L24BXB output

3-15

1762-L24BXB sinking

3-14

1762-L24BXB sourcing

3-14

1762-L40AWA input

3-15

1762-L40AWA output

3-17

1762-L40BWA output

3-17

1762-L40BWA sourcing

3-16

1762-L40BXB output

3-17

1762-L40BXB sinking

3-16

1762-L40BXB sourcing

3-16

1762-OA8

3-20

1762-OB16

3-21

1762-OB32T

3-22

1762-OB8

3-21

1762-OV32T

3-22

1762-OW16

3-23

1762-OW8

3-23

1762-OX6I

3-24

terminal block layouts

3-7, 3-27, 3-29

wiring diagrams

3-7

workspace

G-9

write

G-9

Publication 1762-UM001H-EN-P - June 2015

6 Index

Notes:

Publication 1762-UM001H-EN-P - June 2015

Rockwell Automation Support

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At http://www.rockwellautomation.com/support/ , you can find technical manuals, a knowledge base of FAQs, technical and application notes, sample code and links to software service packs, and a MySupport feature that you can customize to make the best use of these tools.

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Installation Assistance

If you experience a problem within the first 24 hours of installation, review the information that is contained in this manual.

You can contact Customer Support for initial help in getting your product up and running.

United States or Canada

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Use the Worldwide Locator at http://www.rockwellautomation.com/support/americas/phone_en.html

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New Product Satisfaction Return

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Publication 1762-UM001H-EN-P - June 2015

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Supersedes Publication 1762-UM001G-EN-P - March 2011 Copyright © 2015 Rockwell Automation, Inc. All rights reserved. Printed in the U.S.A.

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