E5AN-H - Temperature Controller OMRON - Free user manual and instructions

USER MANUAL E5AN-H OMRON

User's Manual Advanced Type

E5CN-H

E5AN-H

E5EN-H

Digital Controllers

User's Manual

Advanced Type

Revised March 2009

Preface

The E5CN-H, E5AN-H, and E5EN-H are Digital Controllers. The main functions and characteristics of these Digital Controllers are as follows:

• Use the universal inputs to input from thermocouples or temperature-resistance thermometers, or to input analog voltage or analog current inputs.
• Either standard or heating/cooling control can be performed.
• Both auto-tuning and self-tuning are supported.
• Event inputs can be used to switch banks, switch between RUN and STOP status, switch between automatic and manual operation, start/reset the simple program function, and perform other operations.
• Heater burnout detection, heater short (HS) alarms, and heater overcurrent (OC) functions are supported. (Applicable to E5CN-H, E5AN-H, and E5EN-H models with heater burnout detection function.)
• Communications are supported. (Applicable to E5CN-H, E5AN-H, and E5EN-H models with communications.)
• User calibration of the sensor input is supported.
• User calibration of transfer output is supported. (Applicable to E5CN-H, E5AN-H, and E5EN-H models with transfer outputs.)
• Use position-proportional control. (Applicable to the E5AN-H and E5EN-H.)
• Use a remote SP input (Applicable to the E5AN-H and E5EN-H.)
• The structure is waterproof (IP66).
• Conforms to UL, CSA, and IEC safety standards and EMC Directive.
• The PV display color can be switched to make process status easy to understand at a glance.

This manual describes the E5CN-H, E5AN-H, and E5EN-H. Read this manual thoroughly and be sure you understand it before attempting to use the Digital Controller and use the Digital Controller correctly according to the information provided. Keep this manual in a safe place for easy reference. Refer to the following manual for further information on communications: E5CN-H/E5AN-H/E5EN-H Digital Controllers Communications Manual Advanced Type (Cat. No. H159).

Visual Aids

The following headings appear in the left column of the manual to help you locate different types of information.

Note Indicates information of particular interest for efficient and convenient operation of the product.

1,2,3... 1. Indicates lists of one sort or another, such as procedures, checklists, etc.

© OMRON, 2008

All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form, or by any means, mechanical, electronic, photocopying, recording, or otherwise, without the prior written permission of OMRON.

No patent liability is assumed with respect to the use of the information contained herein. Moreover, because OMRON is constantly striving to improve its high-quality products, the information contained in this manual is subject to change without notice. Every precaution has been taken in the preparation of this manual. Nevertheless, OMRON assumes no responsibility for errors or omissions. Neither is any liability assumed for damages resulting from the use of the information contained in this publication.

Read and Understand this Manual

Please read and understand this manual before using the products. Please consult your OMRON representative if you have any questions or comments.

Warranty, Limitations of Liability

WARRANTY

OMRON's exclusive warranty is that the products are free from defects in materials and workmanship for a period of one year (or other period if specified) from date of sale by OMRON.

OMRON MAKES NO WARRANTY OR REPRESENTATION, EXPRESS OR IMPLIED, REGARDING NON-INFRINGEMENT, MERCHANTABILITY, OR FITNESS FOR PARTICULAR PURPOSE OF THE PRODUCTS. ANY BUYER OR USER ACKNOWLEDGES THAT THE BUYER OR USER ALONE HAS DETERMINED THAT THE PRODUCTS WILL SUITABLY MEET THE REQUIREMENTS OF THEIR INTENDED USE. OMRON DISCLAIMS ALL OTHER WARRANTIES, EXPRESS OR IMPLIED.

LIMITATIONS OF LIABILITY

OMRON SHALL NOT BE RESPONSIBLE FOR SPECIAL, INDIRECT, OR CONSEQUENTIAL DAMAGES, LOSS OF PROFITS OR COMMERCIAL LOSS IN ANY WAY CONNECTED WITH THE PRODUCTS, WHETHER SUCH CLAIM IS BASED ON CONTRACT, WARRANTY, NEGLIGENCE, OR STRICT LIABILITY.

In no event shall the responsibility of OMRON for any act exceed the individual price of the product on which liability is asserted.

IN NO EVENT SHALL OMRON BE RESPONSIBLE FOR WARRANTY, REPAIR, OR OTHER CLAIMS REGARDING THE PRODUCTS UNLESS OMRON'S ANALYSIS CONFIRMS THAT THE PRODUCTS WERE PROPERLY HANDLED, STORED, INSTALLED, AND MAINTAINED AND NOT SUBJECT TO CONTAMINATION, ABUSE, MISUSE, OR INAPPROPRIATE MODIFICATION OR REPAIR.

Application Considerations

SUITABILITY FOR USE

OMRON shall not be responsible for conformity with any standards, codes, or regulations that apply to the combination of the products in the customer's application or use of the products.

At the customer's request, OMRON will provide applicable third party certification documents identifying ratings and limitations of use that apply to the products. This information by itself is not sufficient for a complete determination of the suitability of the products in combination with the end product, machine, system, or other application or use.

The following are some examples of applications for which particular attention must be given. This is not intended to be an exhaustive list of all possible uses of the products, nor is it intended to imply that the uses listed may be suitable for the products:

- Outdoor use, uses involving potential chemical contamination or electrical interference, or conditions or uses not described in this manual.

- Nuclear energy control systems, combustion systems, railroad systems, aviation systems, medical equipment, amusement machines, vehicles, safety equipment, and installations subject to separate industry or government regulations.

- Systems, machines, and equipment that could present a risk to life or property.

Please know and observe all prohibitions of use applicable to the products.

NEVER USE THE PRODUCTS FOR AN APPLICATION INVOLVING SERIOUS RISK TO LIFE OR PROPERTY WITHOUT ENSURING THAT THE SYSTEM AS A WHOLE HAS BEEN DESIGNED TO ADDRESS THE RISKS, AND THAT THE OMRON PRODUCTS ARE PROPERLY RATED AND INSTALLED FOR THE INTENDED USE WITHIN THE OVERALL EQUIPMENT OR SYSTEM.

PROGRAMMABLE PRODUCTS

OMRON shall not be responsible for the user's programming of a programmable product, or any consequence thereof.

Safety Precautions

■ Definition of Precautionary Information

The following notation is used in this manual to provide precautions required to ensure safe usage of the product.

The safety precautions that are provided are extremely important to safety. Always read and heed the information provided in all safety precautions.

The following notation is used.

CAUTION

Indicates a potentially hazardous situation which, if not avoided, is likely to result in minor or moderate injury or in property damage.

Symbols

Symbol		Meaning
Caution		General CautionIndicates non-specific general cautions, warnings, and dangers.
		Electrical Shock CautionIndicates possibility of electric shock under specific conditions.
Prohibition		General ProhibitionIndicates non-specific general prohibitions.
Mandatory Caution		General CautionIndicates non-specific general cautions, warnings, and dangers.

■ Safety Precautions

CAUTION
Do not touch the terminals while power is being supplied.Doing so may occasionally result in minor injury due to electric shock.
Do not allow pieces of metal, wire clippings, or fine metallic shavings or filings from installation to enter the product. Doing so may occasionally result in electric shock, fire, or malfunction.
Do not use the product where subject to flammable or explosive gas. Otherwise, minor injury from explosion may occasionally occur.
Never disassemble, modify, or repair the product or touch any of the internal parts. Minor electric shock, fire, or malfunction may occasionally occur.
CAUTION - Risk of Fire and Electric Shocka) This product is UL listed as Open Type Process Control Equipment. It must be mounted in an enclosure that does not allow fire to escape externally.b) When using more than one shutoff switch, always turn OFF all the shutoff switches to ensure that no power is being supplied before servicing the product.c) Signal inputs are SELV, limited energy. (See note 1.)d) Caution: To reduce the risk of fire or electric shock, do not interconnect the outputs of different Class 2 circuits. (See note 2.)
If the output relays are used past their life expectancy, contact fusing or burning may occasionally occur.Always consider the application conditions and use the output relays within their rated load and electrical life expectancy. The life expectancy of output relays varies considerably with the output load and switching conditions.

Note 1: An SELV circuit is one separated from the power supply with double insulation or reinforced insulation, that does not exceed 30 V r.m.s. and 42.4 V peak or 60 VDC.
Note 2: A class 2 power supply is one tested and certified by UL as having the current and voltage of the secondary output restricted to specific levels.

CAUTION
Tighten the terminal screws to between 0.74 and 0.90 N·m. Loose screws may occasionally result in fire.
Set the parameters of the product so that they are suitable for the system being controlled. If they are not suitable, unexpected operation may occasionally result in property damage or accidents.
A malfunction in the Digital Controller may occasionally make control operations impossible or prevent alarm outputs, resulting in property damage. To maintain safety in the event of malfunction of the Digital Controller, take appropriate safety measures, such as installing a monitoring device on a separate line.
When inserting the body of the Digital Controller into the case, confirm that the hooks on the top and bottom are securely engaged with the case. If the body of the Digital Controller is not inserted properly, faulty contact in the terminal section or reduced water resistance may occasionally result in fire or malfunction.
When connecting the Control Output Unit to the socket, press it in until there is no gap between the Control Output Unit and the socket. Otherwise contact faults in the connector pins may occasionally result in fire or malfunction.

Precautions for Safe Use

Be sure to observe the following precautions to prevent operation failure, malfunction, or adverse affects on the performance and functions of the product. Not doing so may occasionally result in unexpected events.

1) The product is designed for indoor use only. Do not use the product outdoors or in any of the following locations.

• Places directly subject to heat radiated from heating equipment.
• Places subject to splashing liquid or oil atmosphere.
• Places subject to direct sunlight.
• Places subject to dust or corrosive gas (in particular, sulfide gas and ammonia gas).
• Places subject to intense temperature change.
• Places subject to icing and condensation.
• Places subject to vibration and large shocks.

2) Use and store the Digital Controller within the rated ambient temperature and humidity.
Gang-mounting two or more Digital Controllers, or mounting Digital Controllers above each other may cause heat to build up inside the Digital Controllers, which will shorten their service life. In such a case, use forced cooling by fans or other means of air ventilation to cool down the Digital Controllers.
3) To allow heat to escape, do not block the area around the product. Do not block the ventilation holes on the product.
4) Be sure to wire properly with correct polarity of terminals.
5) Use specified size (M3.5, width 7.2 mm or less) crimped terminals for wiring. To connect bare wires, use stranded or solid copper wires with a gage of AWG24 to AWG14 (equal to cross-sectional areas of 0.205 to 2.081 mm ^2 ). (The stripping length is 5 to 6 mm.) Up to two wires of same size and type, or two crimp terminals can be inserted into a single terminal.
6) Do not wire the terminals which are not used.
7) To avoid inductive noise, keep the wiring for the Digital Controller's terminal block away from power cables carry high voltages or large currents. Also, do not wire power lines together with or parallel to Digital Controller wiring. Using shielded cables and using separate conduits or ducts is recommended.

Attach a surge suppressor or noise filter to peripheral devices that generate noise (in particular, motors, transformers, solenoids, magnetic coils or other equipment that have an inductance component).

When a noise filter is used at the power supply, first check the voltage or current, and attach the noise filter as close as possible to the Digital controller.

Allow as much space as possible between the Digital Controller and devices that generate powerful high frequencies (high-frequency welders, high-frequency sewing machines, etc.) or surge.

8) Use this product within the rated load and power supply.
9) Make sure that the rated voltage is attained within two seconds of turning ON the power using a switch or relay contact. If the voltage is applied gradually, the power may not be reset or output malfunctions may occur.
10) Make sure that the Digital Controller has 30 minutes or more to warm up after turning ON the power before starting actual control operations to ensure the correct temperature display.
11) When using self-tuning, turn ON power for the load (e.g., heater) at the same time as or before supplying power to the Digital Controller. If power is turned ON for the Digital Controller before turning ON power for the load, self-tuning will not be performed properly and optimum control will not be achieved.
12) A switch or circuit breaker should be provided close to this unit. The switch or circuit breaker should be within easy reach of the operator, and must be marked as a disconnecting means for this unit.
13) Always turn OFF the power supply before pulling out the interior of the product, and never touch nor apply shock to the terminals or electronic components. When inserting the interior of the product, do not allow the electronic components to touch the case.
14) Do not use paint thinner or similar chemical to clean with. Use standard grade alcohol.

15) Design system (control panel, etc.) considering the 2 second of delay that the controller's output to be set after power ON.
16) The output may turn OFF when shifting to certain levels. Take this into consideration when performing control.
17) The number of EEPROM write operations is limited. Therefore, use RAM write mode when frequently overwriting data during communications or other operations.
18) Always touch a grounded piece of metal before touching the Digital Controller to discharge static electricity from your body.
19) Do not remove the terminal block. Doing so may result in failure or malfunction.
20) Control outputs that are voltage outputs are not isolated from the internal circuits. When using a grounded thermocouple, do not connect any of the control output terminals to ground. (Doing so may result in an unwanted circuit path, causing error in the measured temperature.)
21) When replacing the body of the Digital Controller, check the condition of the terminals. If corroded terminals are used, contact failure in the terminals may cause the temperature inside the Digital Controller to increase, possibly resulting in fire. If the terminals are corroded, replace the case as well.
22) Use suitable tools when taking the Digital Controller apart for disposal. Sharp parts inside the Digital Controller may cause injury.
23) Check the specifications of the Control Output Unit and assemble it correctly.
24) When mounting the Control Output Unit, read and follow all relevant information in the product catalogs and manuals.
25) When applying Lloyd's standards, install the Digital Controller according to the requirements given in Shipping Standards.

● Service Life

Use the Digital Controller within the following temperature and humidity ranges:

Temperature: -10 to 55°C (with no icing or condensation), Humidity: 25% to 85%

If the Controller is installed inside a control board, the ambient temperature must be kept to under 55^ C, including the temperature around the Controller.

The service life of electronic devices like Digital Controllers is determined not only by the number of times the relay is switched but also by the service life of internal electronic components. Component service life is affected by the ambient temperature: the higher the temperature, the shorter the service life and, the lower the temperature, the longer the service life. Therefore, the service life can be extended by lowering the temperature of the Digital Controller.

When two or more Digital Controllers are mounted horizontally close to each other or vertically next to one another, the internal temperature will increase due to heat radiated by the Digital Controllers and the service life will decrease. In such a case, use forced cooling by fans or other means of air ventilation to cool down the Digital Controllers. When providing forced cooling, however, be careful not to cool down the terminals sections alone to avoid measurement errors.

- Ambient Noise

To avoid inductive noise, keep the wiring for the Digital Controller's terminal block wiring away from power cables carrying high voltages or large currents. Also, do not wire power lines together with or parallel to Digital Controller wiring. Using shielded cables and using separate conduits or ducts is recommended.

Attach a surge suppressor or noise filter to peripheral devices that generate noise (in particular, motors, transformers, solenoids, magnetic coils or other equipment that have an inductance component). When a noise filter is used at the power supply, first check the voltage or current, and attach the noise filter as close as possible to the Digital Controller.

Allow as much space as possible between the Digital Controller and devices that generate powerful high frequencies (high-frequency welders, high-frequency sewing machines, etc.) or surge.

● Ensuring Measurement Accuracy

When extending or connecting the thermocouple lead wire, be sure to use compensating wires that match the thermocouple types.

When extending or connecting the lead wire of the platinum resistance thermometer, be sure to use wires that have low resistance and keep the resistance of the three lead wires the same.

Mount the Digital Controller so that it is horizontally level.

If the measurement accuracy is low, check to see if input shift has been set correctly.

● Waterproofing

The degree of protection is as shown below. Sections without any specification on their degree of protection or those with IP☐0 are not waterproof.

Front panel: IP66

Rear case: IP20, Terminal section: IP00

Precautions for Operation

1) It takes approximately two seconds for the outputs to turn ON from after the power supply is turned ON. Due consideration must be given to this time when incorporating Digital Controllers into a control panel or similar device.
2) Make sure that the Digital Controller has 30 minutes or more to warm up after turning ON the power before starting actual control operations to ensure the correct temperature display.
3) When executing self-tuning, turn ON power for the load (e.g., heater) at the same time as or before supplying power to the Digital Controller. If power is turned ON for the Digital Controller before turning ON power for the load, self-tuning will not be performed properly and optimum control will not be achieved. When starting operation after the Digital Controller has warmed up, turn OFF the power and then turn it ON again at the same time as turning ON power for the load. (Instead of turning the Digital Controller OFF and ON again, switching from STOP mode to RUN mode can also be used.)
4) Avoid using the Controller in places near a radio, television set, or wireless installing. The Controller may cause radio disturbance for these devices.

Shipping Standards

The E5□N-H Digital Controllers comply with Lloyd's standards. When applying the standards, the following installation and wiring requirements must be met in the application.

■ Application Conditions

1) Installation Location

The E5□N-H Digital Controllers comply with installation categories ENV1 and ENV2 of Lloyd's standards. They must therefore be installed in a location equipped with air conditioning. They cannot be used on the bridge or decks, or in a location subject to strong vibration.

2) Wiring Conditions

Install the recommended ferrite core and wrap the line around it three turns for the applicable lines (e.g., power supply cable line and signal lines) of the models listed in the following table. (See illustrations.) Install the ferrite cores as close to the terminal block of the E5□N-H as possible. (As a guideline, the ferrite core should be within 10 cm of the terminal block.)

● Lines Requiring Ferrite Cores

● Recommended Ferrite Core

● Ferrite Core Connection Examples

1. E5CN/E5CN-H

graph LR
    A["mA"] --> B["DO NOT USE"]
    B --> C["Analog input"]
    D["DO NOT USE"] --> E["TC/Pt universal input"]
    E --> F["Control output 1"]
    E --> G["DO NOT USE"]
    H["Auxiliary outputs (relay outputs)"] --> I["6"]
    H --> J["7"]
    H --> K["8"]
    L["Auxiliary output 2"] --> M["9"]
    N["Auxiliary output 1"] --> O["10"]
    P["Input power supply"] --> Q["3 turns"]
    Q --> R["AC/DC"]
    S["Power supply"] --> T["AC/DC"]

2. E5AN/E5EN/E5AN-H/E5EN-H

graph TD
    A["AC/DC Power Supply"] --> B["3 turns"]
    B --> C["Control Output 1"]
    C --> D["Auxiliary output 3"]
    D --> E["Auxiliary output 2"]
    E --> F["Auxiliary output 1"]
    F --> G["TC/Pt universal Input"]
    G --> H["Analog Input"]
    H --> I["RS-232C Communications"]
    I --> J["RS-485 Communications"]
    J --> K["Connected to communications or event inputs 1 and 2."]
    K --> L["Control Output 2 External Power Supply"]
    L --> M["External power supply 12 VDC, 20 mA"]
    M --> N["DO NOT USE"]
    N --> O["DO NOT USE"]
    O --> P["mA"]
    P --> Q["V"]
    Q --> R["DO NOT USE"]
    R --> S["Analog input"]
    S --> T["RS-485 Communications"]
    T --> U["B (+)"]
    T --> V["A (-)"]
    T --> W["DO NOT USE"]
    W --> X["B (+)"]
    W --> Y["A (-)"]
    T --> Z["RS-485 Communications"]
    Z --> AA["B (+)"]
    Z --> AB["A (-)"]
    style A fill:#f9f,stroke:#333
    style K fill:#f9f,stroke:#333

Preparations for Use

Be sure to thoroughly read and understand the manual provided with the product, and check the following points.

Conventions Used in This Manual

Meanings of Abbreviations

The following abbreviations are used in parameter names, figures and in text explanations. These abbreviations mean the following:

Note: (1) A heater short indicates that the heater remains ON even when the control output from the Digital Controller is OFF because the SSR has failed or for any other reason.
(2) “EU” stands for Engineering Unit. EU is used as the minimum unit for engineering units such as ^ C, m, and g. The size of EU varies according to the input type.

For example, when the input temperature setting range is -200 to +1300°C, 1 EU is 1°C, and when the input temperature setting range is -20.0 to +500.0°C, 1 EU is 0.1°C.

For analog inputs, the size of EU varies according to the decimal point position of the scaling setting, and 1 EU becomes the minimum scaling unit.

How to Read Display Symbols

The following tables show the correspondence between the symbols displayed on the displays and alphabet characters. The default is for 11-segment displays.

The Character Select parameter in the advanced function setting level can be turned OFF to display the following 7-segment characters.

TABLE OF CONTENTS

SECTION 1

Introduction.... 1

1-1 Names of Parts.... 2
1-2 I/O Configuration and Main Functions 5
1-3 Setting Level Configuration and Key Operations 11
1-4 Communications Function.... 14

SECTION 2

Preparations 17

2-1 Installation.... 18
2-2 Wiring Terminals 28
2-3 Using the Support Software Port 40
2-4 Using Infrared Communications 42

SECTION 3

Basic Operation.... 45

3-1 Initial Setting Examples.... 46
3-2 Setting the Input Type 49
3-3 Selecting the Temperature Unit 51
3-4 Selecting PID Control or ON/OFF Control.... 51
3-5 Setting Output Specifications 52
3-6 Setting the Set Point (SP) 56
3-7 Using ON/OFF Control 57
3-8 Determining PID Constants (AT, ST, Manual Setup) 60
3-9 Alarm Outputs 67
3-10 Using Heater Burnout, Heater Short, and Heater Overcurrent Alarms 71
3-11 Setting the No. 3 Display....82

SECTION 4

Applications Operations.... 85

4-1 Shifting Input Values 87
4-2 Alarm Hysteresis 90
4-3 Setting Scaling Upper and Lower Limits for Analog Inputs....92
4-4 Executing Heating/Cooling Control 93
4-5 Using Event Inputs 96
4-6 Setting the SP Upper and Lower Limit Values 100
4-7 Using the SP Ramp Function to Limit the SP Change Rate 102
4-8 Moving to the Advanced Function Setting Level 104
4-9 Using the Key Protect Level 106
4-10 PV Change Color.... 109
4-11 Alarm Delays.... 112
4-12 Loop Burnout Alarm 114
4-13 Performing Manual Control.... 119
4-14 Using the Transfer Output 124

TABLE OF CONTENTS

4-15 Using Banks and PID Sets.... 129
4-16 Using the Simple Program Function 132
4-17 Output Adjustment Functions 141
4-18 Using the Extraction of Square Root Parameter 144
4-19 Setting the Width of MV Variation 146
4-20 Setting the PF Key 148
4-21 Counting Control Output ON/OFF Operations 150
4-22 Displaying PV/SV Status.... 152
4-23 Using a Remote SP 155
4-24 Position-proportional Control 157
4-25 Logic Operations 159

SECTION 5

Parameters.... 169

5-1 Conventions Used in this Section 170
5-2 Protect Level 171
5-3 Operation Level 175
5-4 Adjustment Level.... 190
5-5 Bank Setting Level.... 209
5-6 PID Setting Level. 216
5-7 Monitor/Setting Item Level 220
5-8 Manual Control Level 221
5-9 Initial Setting Level 223
5-10 Advanced Function Setting Level 242
5-11 Communications Setting Level 281

SECTION 6

CALIBRATION 283

6-1 Parameter Structure 284
6-2 User Calibration.... 285
6-3 Thermocouple Calibration (Thermocouple/Resistance Thermometer Input) 285
6-4 Platinum Resistance Thermometer Calibration (Thermocouple/Resistance Thermometer Input).... 289
6-5 Calibrating Analog Input (Analog Input) 290
6-6 Calibrating the Transfer Output.... 292
6-7 Checking Indication Accuracy 294

Appendix 297

Index.... 343

Revision History 351

About this Manual:

This manual describes the E5CN/AN/EN-H Digital Controllers and includes the sections described below.

Please read this manual carefully and be sure you understand the information provided before attempting to set up or operate an E5CN/AN/EN-H Digital Controller.

- Overview

Section 1 introduces the features, components, and main specifications of the E5CN/AN/EN-H Digital Controllers.

- Setup

Section 2 describes the work required to prepare the E5CN/AN/EN-H Digital Controllers for operation, including installation and wiring.

- Basic Operations

Section 3 describes the basic operation of the E5CN/AN/EN-H Digital Controllers, including key operations to set parameters and descriptions of display elements based on specific control examples.

Section 5 describes the individual parameters used to set up, control, and monitor operation.

• Operations for Applications

Section 4 describes scaling, the SP ramp function, and other special functions that can be used to make the most of the functionality of the E5CN/AN/EN-H Digital Controllers.

Section 5 describes the individual parameters used to setup, control, and monitor operation.

- User Calibration

Section 6 describes how the user can calibrate the E5CN/AN/EN-H Digital Controllers.

- Appendix

The Appendix provides information for easy reference, including lists of parameters and settings.

WARNING

Failure to read and understand the information provided in this manual may result in personal injury or death, damage to the product, or product failure. Please read each section in its entirety and be sure you understand the information provided in the section and related sections before attempting any of the procedures or operations given.

SECTION 1 Introduction

This section introduces the features, components, and main specifications of the E5CN-H, E5AN-H, and E5EN-H Digital Controllers.

1-1 Names of Parts 2

1-1-1 Front Panel 2
1-1-2 Explanation of Indicators 3
1-1-3 Using the Keys 4

1-2 I/O Configuration and Main Functions.... 5

1-2-1 I/O Configuration 5
1-2-2 Main Functions.... 8

1-3 Setting Level Configuration and Key Operations.... 11

1-3-1 Selecting Parameters.... 14
1-3-2 Saving Settings 14

1-4 Communications Function 14

1-1 Names of Parts

1-1-1 Front Panel

E5CN-H

E5AN-H

E5EN-H

1-1-2 Explanation of Indicators

No. 1 Display

Displays the process value or parameter name.

Lights for approximately one second during startup.

No. 2 Display

Displays the set point, parameter operation read value, or the variable input value.

Lights for approximately one second during startup.

No. 3 Display (E5AN/EN-H Only)

Displays MV (valve opening), soak time remain, or bank number.

Lights for approximately one second during startup.

Operation Indicators

1,2,3...

1. SUB1 (Sub 1)

Lights when the function set for the Auxiliary Output 1 Assignment parameter is ON.

SUB2 (Sub 2)

Lights when the function set for the Auxiliary Output 2 Assignment parameter is ON.

SUB3 (Sub 3)

Lights when the function set for the Auxiliary Output 3 Assignment parameter is ON.

1. HA (Heater Burnout, Heater Short Alarm, Heater Overcurrent Detection Output Display)

Lights when a heater burnout, heater short alarm, or heater overcurrent occurs.

1. OUT1 (Control Output 1)

Lights when the control output function assigned to control output 1 turns ON. For a current output, however, OFF for a 0% output only.

With position-proportional models, OUT1 lights when the "open" output turns ON.

1-1-3 Using the Keys

○ + ➕ Keys

Press these keys to change to the protect level. For details on operations involving holding these keys down simultaneously, refer to 1-3 Setting Level Configuration and Key Operations. For details on the protect level, refer to SECTION 5 Parameters.

To restrict set value changes (in order to prevent accidental or incorrect operations), these key operations require simultaneously pressing the ☐ key along with ⚠ or ⏱ key. This applies only to the parameter for the password to move to protect level. (Refer to page 174.)

1-2 I/O Configuration and Main Functions

1-2-1 I/O Configuration

E5CN-H

graph LR
    A["Temperature input or analog input"] --> B["Control section"]
    C["CT1 input"] --> B
    D["CT2 input"] --> B
    E["Event inputs 2 channels"] --> B
    B --> F["Control output (heating)"]
    B --> G["Control output (cooling)"]
    F --> H["Heating/cooling"]
    G --> H
    H --> I["Control output 1"]
    H --> J["Control output 2"]
    B --> K["Alarm 3"]
    B --> L["Alarm 2"]
    B --> M["Alarm 1"]
    B --> N["HB alarm"]
    B --> O["HS alarm"]
    B --> P["OC alarm"]
    B --> Q["Input error"]
    B --> R["Program end output"]
    B --> S["Communications function"]
    K --> T["Auxiliary output 2"]
    L --> T
    M --> U["Auxiliary output 1"]

Note

Functions can be assigned individually for each output by changing the set values for the Control Output 1 Assignment, the Control Output 2 Assignment, the Auxiliary Output 1 Assignment, and the Auxiliary Output 2 Assignment parameters in the advanced function setting level.

Model Number Structure

Model Number Legends

Controllers

E5CN-□□□M□-□-500 1 2 3 4 5 6 7

1. Type

H: Advanced

2. Control Output 1

R: Relay output

Q: Voltage output (for driving SSR)

C: Current output

V: Linear voltage output

3. Auxiliary Outputs

2: Two outputs

4. Option 1

M: Option Unit can be mounted.

5. Power Supply Voltage

Blank: 100 to 240 VAC

D: 24 VAC/VDC

6. Case Color

Blank: Black

W: Silver

7. Terminal Cover

-500: With terminal cover

Option Units

E53-□□□□

1 2 3 4

1. Applicable Controller

CN: E5CN-H or E5CN

2. Function 1

Blank: None

Q: Control output 2 (voltage output for driving SSR)

P: Power supply for sensor

C: Current output

3. Function 2

Blank: None

H: Heater burnout/Heater short/Heater overcurrent detection (CT1)

HH: Heater burnout/Heater short/Heater overcurrent detection (CT2)

B: Two event inputs

03: RS-485 communications

H03: Heater burnout/Heater short/Heater overcurrent detection (CT1) + RS-485 communications

HB: Heater burnout/Heater short/Heater overcurrent detection (CT1) + Two event inputs

HH03: Heater burnout/Heater short/Heater overcurrent detection (CT2) + RS-485 communications

H01: Heater burnout/Heater short/Heater overcurrent detection (CT1)/RS-232C communications

F: Transfer output

BF: Two event inputs/Transfer output

4. Version

N2: Available only to models released after January 2008

E5AN/EN-H

graph LR
    A["Temperature input or analog input"] --> B["Control section"]
    C["RSP input error"] --> B
    D["CT1 input"] --> B
    E["CT2 input"] --> B
    F["Event inputs 1 and 2 (2 channels)"] --> B
    G["Event inputs 3 and 4 (2 channels)"] --> B
    B --> H["Control output (heating)"]
    B --> I["Control output (cooling)"]
    H --> J["Heating/cooling"]
    I --> J
    J --> K["Control output 1"]
    J --> L["Control output 2"]
    H --> M["Alarm 3"]
    H --> N["Alarm 2"]
    H --> O["Alarm 1"]
    H --> P["HB alarm"]
    H --> Q["HS alarm"]
    H --> R["OC alarm"]
    H --> S["Input error"]
    H --> T["Remote SP input error"]
    H --> U["Program end output"]
    H --> V["Communications function"]
    M --> W["Alarm output 3"]
    N --> X["Alarm output 2"]
    Q --> Y["Alarm output 1"]

Note

Functions can be assigned individually to each output by changing the set values for the Control Output 1 Assignment, Control Output 2 Assignment, Auxiliary Output 1 Assignment, Auxiliary Output 2 Assignment, and Auxiliary Output 3 Assignment parameters in the advanced function setting level.

Model Number Structure

Model Number Legends

Controllers

E5AN/E5EN-□□□□□□□□M□-□-500 1 2 3 4 5 6 7 8 9 10 11

1. Type

H: Advanced

2. Control Mode

Blank: Standard or heating/cooling control
P: Position-proportional control

3. Control Output 1

A: Control Output Unit R: Relay output S: SSR output

4. Control Output 2

A: Control Output Unit R: Relay output S: SSR output

5. Auxiliary Outputs

2: Two outputs 3: Three outputs

6. Option 1

Blank: None H: Heater burnout/Heater short/ Heater overcurrent detection (CT1) HH: Heater burnout/Heater short/ Heater overcurrent detection (CT2)

7. Option 2

B: Two event inputs BF: Event input + Transfer output

8. Option 3

M: Option Unit can be mounted.

9. Power Supply Voltage

Blank: 100 to 240 VAC D: 24 VAC/VDC

10. Case Color

Blank: Black W: Silver

11. Terminal Cover

-500: With Terminal Cover

Option Units

E53-□ 1

1. Function

EN01: RS-232C communications EN02: RS-422 communications EN03: RS-485 communications AKB: Event input

Output Units

E53-□□ 1 2

1. Control Output

R: Relay output
Q: Voltage output (for driving SSR)
Q3: Voltage output (for driving SSR) + 24 VDC (NPN)
Q4: Voltage output (for driving SSR) + 24 VDC (PNP)
C3: Current output + 4 to 20 mA DC
C3D: Current output + 0 to 20 mA DC
V34: Linear voltage outp 0 to 10 VDC
V35: Linear voltage outp 0 to 5 VDC

2. Version

Blank: Available for E5AN-H/E5EN-H and E5AK/E5EK. N: Available only for E5AN-H/E5EN-H.

1-2-2 Main Functions

This section introduces the main E5□N-H functions. For details on particular functions and how to use them, refer to SECTION 3 Basic Operation and following sections.

Input Sensor Types

- The following input sensors can be connected.:

Thermocouple: K, J, T, E, L, U, N, R, S, B, W, PLII Platinum resistance thermometer: Pt100, JPt100

Current input: 4 to 20 mA DC, 0 to 20 mA DC Voltage input: 1 to 5 VDC, 0 to 5 V DC, 0 to 10 V DC

Control Outputs

• A control output can be a relay output, voltage output (for driving SSR), linear voltage output, SSR output, or current output, depending on the model.
• With the E5CN-H□2□□, auxiliary output 2 is used as control output (cooling) when heating/cooling control is selected. (It is also possible to allocate a different output.) Therefore, use auxiliary output 1 if an auxiliary output is required while using heating/cooling control.

Alarms

• Set the alarm type and alarm value or the alarm value upper and lower limits.
• If necessary, a more comprehensive alarm function can be achieved by setting a standby sequence, alarm hysteresis, auxiliary output close in alarm/open in alarm, alarm latch, alarm ON delay, and alarm OFF delay.
• If the Input Error Output parameter is set to ON, the output assigned to alarm 1 function will turn ON when an input error occurs.
• If the Remote SP Input Error Output parameter is set to ON, the output assigned to the alarm 1 function will turn ON when an input error occurs.

Control Adjustment

- Optimum PID constants can be set easily by performing AT (auto-tuning) or ST (self-tuning).

Event Inputs

- With the E53-CN□B□N2 for the E5CN-H (for two event inputs), the E5AN/EN-H□B□M□-500 for E5AN/EN-H (for two event inputs) or the E5AN/EN-H□B□M□-500 with the E53-AKB for the E5AN/EN-H (for four event inputs), the following functions can be executed using event inputs: switching banks, switching RUN/STOP, switching between automatic and manual operation, starting/resetting the program, inverting direct/reverse operation, switching SP modes, 100% AT execute/cancel, 40% AT execute/cancel, setting change enable/disable, communications writing enable/disable and canceling the alarm latch.

Heater Burnout, HS Alarm, and Heater Overcurrent

- With the E53-CN□H□N2 or E53-CN□HH□N2 for the E5CN-H, or the E5AN/EN-H□□H□-500 or E5AN/EN-H□□HH□-500, the heater burnout detection function, HS alarm function, and heater overcurrent detection function can be used.

Communications Functions

- Communications functions utilizing CompoWay/F (See note 1.), SYSWAY (See note 2.), or Modbus (See note 3.) can be used.

RS-485 Interface

Use the E53-CN□03N2 for the E5CN-H, or the E53-EN03 for the E5AN/EN-H.

RS-232C Interface

Use the E53-CN□01N2 for the E5CN-H, or the E53-EN01 for the E5AN/EN-H.

RS-422 Interface

Use the E53-EN02 for the E5AN/EN-H.

Note

(1) CompoWay/F is an integrated general-purpose serial communications protocol developed by OMRON. It uses commands compliant with the well-established FINS, together with a consistent frame format on OMRON Programmable Controllers to facilitate communications between personal computers and components.
(2) SYSWAY communications do not support alarm 3.
(3) Modbus is a communications control method conforming to the RTU Mode of Modbus Protocol. Modbus is a registered trademark of Schneider Electric.

(4) The E5CN-H does not support the RS-422 interface.

Transfer Output

A 4 to 20-mA transfer output can be used with the E53-CN☐FN2 for the E5CN-H, or the E5AN/EN-H☐☐F-500.

Remote SP Inputs

Remote SP inputs can be used with the E5AN-H and E5EN-H.

Infrared Communications

When Support Software, such as CX-Thermo version 4.00 or later (EST2-2C-MV4 or later), is used, the personal computer can be connected to the Digital Controller using infrared communications.

1-3 Setting Level Configuration and Key Operations

Parameters are divided into groups, each called a level. Each of the set values (setting items) in these levels is called a parameter. The parameters on the E5CN/AN/EN-H are divided into the following 9 levels.

When the power is turned ON, all of the display lights for approximately one second.

graph TD
    A["Power ON"] --> B["Operation Level"]
    B --> C["Adjustment Level"]
    C --> D["Bank Setting Level"]
    D --> E["Monitor/Setting Item Level"]
    E --> F["Initial Setting Level"]
    F --> G["Advanced Function Setting Level"]
    G --> H["Calibration Level"]

    subgraph Manual Mode
        I["Manual Control Level"] --> J["*3"]
        J --> K["Operation Level"]
        K --> L["Adjustment Level"]
        L --> M["Bank Setting Level"]
        M --> N["Monitor/Setting Item Level"]
        N --> O["Initial Setting Level"]
        O --> P["Advanced Function Setting Level"]
    end

    subgraph Automatic Mode
        Q["Start in manual mode."] --> R["Operation Level"]
        S["Start in automatic mode."] --> T["Adjustment Level"]
        U["Start in automatic mode."] --> V["Bank Setting Level"]
        W["Start in automatic mode."] --> X["Monitor/Setting Item Level"]
        Y["Start in automatic mode."] --> Z["Control Setting Level"]
        AA["Start in automatic mode."] --> AB["Advanced Function Setting Level"]
    end

    I --> AC["Press the PF Key for at least 1 s. *4"]
    J --> AD["Press the PF Key for at least 1 s. *4"]
    K --> AE["Press the PF Key for at least 1 s. *4"]
    L --> AF["Press the PF Key less than 1 s."]
    M --> AG["Press the PF Key less than 1 s."]
    N --> AH["PF Key *5"]
    O --> AI["Press the PF Key for at least 1 s."]
    P --> AJ["Press the PF Key for at least 1 s."]
    Q --> AK["Press the PF Key or the PF Key for at least 1 s. *4"]
    R --> AL["Press the ☐ Key or the PF Key for at least 1 s. *4"]
    S --> AM["Press the ☐ Keys for at least 1 s."]
    T --> AN["Press the ☐ Keys for at least 1 s."]
    U --> AO["Press the ☐ Keys for at least 1 s."]
    V --> AP["Press the ☐ Keys for at least 1 s."]
    W --> AQ["Press the ☐ Keys for at least 1 s."]
    X --> AR["Press the ☐ Keys for at least 1 s."]
    Y --> AS["Press the ☐ Keys for at least 1 s."]
    Z --> AT["Press the ☐ Keys for at least 1 s."]
    AA --> AU["Press the ☐ Keys for at least 1 s."]
    AB --> AV["Press the ☐ Keys for at least 1 s."]
    AC --> AW["Press the ☐ Keys for at least 1 s."]
    AD --> AX["Press the ☐ Keys for at least 1 s."]
    AE --> AY["Press the ☐ Keys for at least 1 s."]
    AF --> AZ["Press the ☐ Keys for at least 1 s."]
    AG --> BA["Press the ☐ Keys for at least 1 s."]
    AH --> BB["Press the ☐ Keys for at least 1 s."]
    AI --> BC["Press the ☐ Keys for at least 1 s."]
    AJ --> BD["Press the ☐ Keys for at least 1 s."]
    AK --> BE["Press the ☐ Keys for at least 1 s."]
    AL --> BF["Press the ☐ Keys for at least 1 s."]
    AM --> BG["Press the ☐ Keys for at least 1 s."]
    AN --> BH["Press the ☐ Keys for at least 1 s."]
    AO --> BI["Press the ☐ Keys for at least 1 s."]
    AP --> BJ["Press the ☐ Keys for at least 1 s."]
    AQ --> BK["Press the ☐ Keys for at least 1 s."]
    AR --> BL["Press the ☐ Keys for at least 1 s."]
    AS --> BM["Press the ☐ Keys for at least 1 s."]
    AT --> BN["Press the ☐ Keys for at least 1 s."]
    AU --> BO["Press the ☐ Keys for at least 1 s."]
    AV --> BP["Press the ☐ Keys for at least 1 s."]
    AW --> BQ["Press the ☐ Keys for at least 1 s."]
    AX --> BR["Press the ☐ Keys for at least 1 s."]
    AY --> BS["Press the ☐ Keys for at least 1 s."]
    AZ --> BT["Press the ☐ Keys for at least 1 s."]
    BA --> BU["Press the ☐ Keys for at least 1 s."]
    BW --> BV["Press the ☐ Keys for at least 1 s."]
    BX --> BY["Press the ☐ Keys for at least 1 s."]
    CA --> BZ["Press the ☐ Keys for at least 1 s."]
    CB --> CC["Press the ☐ Keys for at least 1 s."]
    DD --> DDQ["Press the ☐ Keys for at least 1 s."]
    DB --> DBQ["Press the ☐ Keys for at least 1 s."]
    BE --> DC["Press the ☐ Keys for at least 1 s."]
    BEQ --> DDQ

Note

(1) Your can return to the operation level by executing a software reset.
(2) You cannot move to other levels by operating the keys on the front panel from the calibration level. You must turn OFF the power supply.
(3) From the manual control level, key operations can be used to move to the operation level only.

Of these levels, the initial setting level, communications setting level, advanced function setting level, and calibration level can be used only when control is stopped. Control outputs are stopped when any of these four levels is selected.

(4) When the PF Setting is set to A-M in models with a PF Key (E5AN/EN-H)
(5) When the PF Setting is set to PFDP in models with a PF Key (E5AN/EN-H)

Protect Level

- To switch to the protect level from the operation level, the adjustment level, bank setting level, or PID setting level, simultaneously hold down the ☐ and ☑ Keys for at least 3 seconds. (See note.) This level is for preventing unwanted or accidental modification of parameters. Protected levels will not be displayed, and so the parameters in that level cannot be modified.

Note The key pressing time can be changed in Move to Protect Level parameter (advanced function setting level).

Operation Level

• The operation level is displayed when the power is turned ON. You can move to the protect level, initial setting level, or adjustment level from this level.
• Normally, select this level during operation. While operation is in progress, items such as the PV and manipulated variable (MV) can be monitored, and the set points, alarm values, and alarm upper and lower limits can be monitored and changed.

Adjustment Level

• To move to the adjustment level, press the ☐ Key once (for less than 1 s).
• This level is for entering set values and offset values for control. In addition to AT (auto-tuning), communications write enable/disable switching, hysteresis settings, SP settings, and input offset parameters, it includes HB alarm, HS alarm, OC alarm, and PID constants. From the adjustment level, it is possible to move to the bank setting level, initial setting level, or protect level.

Bank Setting Level

• To move to the bank setting level from the adjustment level, press the ☐ Key once (for less than 1 s).
• This level is used to input parameters such as set points, alarm values, and PID set numbers. From the bank setting level, it is possible to move to the PID setting level, the initial setting level, or the protect level.

PID Setting Level

• To move to the PID setting level from the bank setting level, press the ☐ Key once (for less than 1 s).
• This level is used to input parameters such as the PID values for each PID set, MV upper and lower limits, and automatic selection range upper and lower limits. From the PID setting level, it is possible to move to the operation level, the initial setting level, or the protect level.

Monitor/Setting Item Level

- To switch to the monitor/setting item level, press the PF Key from the operation level, adjustment level, bank setting level, or PID setting level. The contents set for monitor/setting items 1 to 5 can be displayed. You can move from the monitor/setting item level to the operation level or initial setting level. (E5AN/EN-H only.)

Manual Control Level

- When the ☐ Key is pressed for at least 3 seconds from the operation level's auto/manual switching display, the manual control level will be displayed. (The MANU indicator will light.)

- When the PF Setting is set to A-M (auto/manual) and the PF Key is pressed for more than one second from the operation level, adjustment level, bank setting level, or PID setting level the manual control level will be displayed. (E5AN/EN-H only.)

- This is the level for changing the MV in manual mode.

- To return to the operation level, press the ☐ Key for at least one second. It is also possible to return to the operation level by pressing the PF Key for more than one second when the PF Setting is set to A-M.

Initial Setting Level

- To move to the initial setting level from the operation level, the adjustment level, bank setting level, PID setting level, or monitor/setting item level, press the ☐ Key for at least 3 seconds. The PV display flashes after one second. This level is for specifying the input type and selecting the control method, control period, setting direct/reverse operation, setting the alarm types, etc. You can move to the advanced function setting level or communications setting level from this level. To return to the operation level, press the ☐ Key for at least one second. To move to the communications setting level, press the ☐ Key for less than one second.

(When moving from the initial setting level to the operation level, all the indicators will light.)

Note Pressing the ☐ Key for at least 3 seconds in the operation level's auto/manual switching display will move to the manual control level, and not the initial setting level.

Advanced Function Setting Level

- To move to the advanced function setting level, set the Initial Setting/Communications Protect parameter in the protect level to 0 (the default) and then, in the initial setting level, input the password (-169).

- From the advanced function setting level, it is possible to move to the calibration level or to the initial setting level.

- This level is for setting the automatic display return time and standby sequence, and it is the level for moving to the user calibration and other functions.

Communications Setting Level

- To move to the communications setting level from the initial setting level, press the ☐ Key once (for less than 1 s). When using the communications function, set the communications conditions in this level. Communicating with a personal computer (host computer) allows set points to be read and written, and manipulated variables (MV) to be monitored.

Calibration Level

- To move to the calibration level, input the password (1201) from the advanced function setting level. The calibration level is for offsetting error in the input circuit.

- You cannot move to other levels from the calibration level by operating the keys on the front panel. To cancel this level, turn the power OFF then back ON again.

1-3-1 Selecting Parameters

- Within each level, the parameter is changed in order (or in reverse order) each time the ☐ Key is pressed. (In the calibration level, however, parameters cannot be changed in reverse order.) For details, refer to SECTION 5 Parameters.

graph TD
    A["Parameter 1"] --> B["Parameter 2"]
    B --> C["Parameter 3"]
    C --> D["Parameter 4"]
    D --> E["After key is pressed"]
    E --> F["Parameter 3"]
    F --> G["Parameter 2"]
    G --> H["Parameter 3"]
    H --> I["After key has been held down for 1 s."]
    I --> J["Parameter 4"]
    J --> K["Parameter 3"]
    K --> L["Parameter 2"]
    L --> M["Parameter 3"]
    M --> N["After key has been held down for 2 s."]
    N --> O["Parameter 2"]
    O --> P["Parameter 3"]
    P --> Q["Parameter 3"]
    Q --> R["After key is being held down, the parameter will move each second in reverse order."]
    R --> S["Parameter 2"]
    S --> T["Parameter 3"]
    T --> U["Parameter 3"]
    U --> V["After key has been held down for 2 s."]
    V --> W["Parameter 3"]
    W --> X["Parameter 4"]
    X --> Y["Parameter 4"]
    Y --> Z["Parameter 3"]
    Z --> AA["Parameter 2"]
    AA --> AB["Parameter 3"]
    AB --> AC["Parameter 4"]
    AC --> AD["Parameter 3"]
    AD --> AE["Parameter 2"]
    AE --> AF["Parameter 3"]
    AF --> AG["Parameter 4"]

1-3-2 Saving Settings

• If you press the 🔒 Key at the final parameter, the display returns to the top parameter for the current level.
• To change parameter settings, specify the setting using the 🔗 or ⏰ Key, and either leave the setting for at least two seconds or press the 🔔 Key. This saves the setting.
• When another level is selected after a setting has been changed, the contents of the parameter prior to the change is saved.
• When you turn the power OFF, you must first save the settings (by pressing the ☐ Key). The settings are sometimes not changed by merely pressing the ⏠ or ⏰ Keys.

1-4 Communications Function

The E5CN/AN/EN-H Digital Controllers are provided with a communications function that enables parameters to be checked and set from a host computer. If the communications function is required, use a model that has that function (E5CN-H□M□-500 with an E53-CN□01N2 or E53-CN□03N2, E5AN-H/EN-H□M□-500 with an E53-EN01, E53-EN02, or E53-EN03). For details on the communications function, see the separate Communications Manual Advanced Type. Use the following procedure to move to the communications setting level.

1,2,3... 1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

1. Press the ☐ Key for less than one second to move from the initial setting level to the communications setting level.
2. Select the parameters as shown below by pressing the ☐ Key.
3. Press the ↗ or ↕ Key to change the parameter setting.

graph TD
    A["PSEL CWF"] --> B["Communication Unit No."]
    B --> C["Communications Baud Rate"]
    C --> D["6PS 9.6"]
    D --> E["LENN"]
    E --> F["Communications Data Length (See note.)"]
    F --> G["5BIT 2"]
    G --> H["Communications Stop Bits (See note.)"]
    H --> I["PRLY EVEN"]
    I --> J["Communications Parity"]
    J --> K["5DWE 20"]
    K --> L["Send Data Wait Time"]

Note

The Protocol Setting parameter is displayed only when CompoWay/F communications are being used.

Setting Communications Data

Match the communications specifications of the E5CN/AN/EN-H and the host computer. If a 1:N connection is being used, ensure that the communications specifications for all devices in the system (except the communications Unit No.) are the same.

SECTION 2 Preparations

This section describes the work required to prepare the E5CN-H, E5AN-H, and E5EN-H Digital Controllers for operation, including installation and wiring.

2-1 Installation.... 18

2-1-1 Dimensions.... 18
2-1-2 Panel Cutout 19
2-1-3 Mounting.... 21
2-1-4 Removing the Digital Controller from the Case.... 23

2-2 Wiring Terminals.... 28

2-2-1 Terminal Arrangement 28
2-2-2 Precautions when Wiring 30
2-2-3 Wiring.... 30

2-3 Using the Support Software Port. 40
2-4 Using Infrared Communications.... 42

2-1 Installation

2-1-1 Dimensions

Unit: mm

E5CN-H

E5AN-H

E5EN-H

2-1-2 Panel Cutout

Unit: mm

E5CN-H
Individual Mounting

Group Mounting

E5AN-H
Individual Mounting

Group Mounting (See note.)

Note Group mounting is not possible when an SSR output is used for control output 1 or 2 and an E53-C3N or E53-C3DN Output Unit is used. Mount at the intervals shown in the following diagram.

E5EN-H

Individual Mounting

Group Mounting (See note.)

Note Group mounting is not possible when an SSR output is used for control output 1 or 2 and an E53-C3N or E53-C3DN Output Unit is used. Mount at the intervals shown in the following diagram.

• Waterproofing is not possible when group mounting several Controllers.
• The recommended panel thickness is 1 to 5 mm for E5CN-H, and 1 to 8 mm for E5AN/E5EN-H.
• Units must not be group mounted vertically. In addition, group mounting is not possible when an SSR output is used for control output 1 or 2 and an E53-C3N or E53-C3DN Output Unit is used. (Observe the recommended mounting intervals.)
• When group mounting several Controllers, ensure that the surrounding temperature does not exceed the ambient operating temperature listed in the specifications.

2-1-3 Mounting

E5CN-H

Mounting to the Panel

1,2,3...

1. For waterproof mounting, waterproof packing must be installed on the Controller. Waterproofing is not possible when group mounting several Controllers. Waterproof packing is not necessary when there is no need for the waterproofing function.
2. Insert the E5CN-H into the mounting hole in the panel.
3. Push the adapter from the terminals up to the panel, and temporarily fasten the E5CN-H.
4. Tighten the two fastening screws on the adapter. Alternately tighten the two screws little by little to maintain a balance. Tighten the screws to a torque of 0.29 to 0.39 N·m.

Mounting the Terminal Cover

Make sure that the "UP" mark is facing up, and then attach the E53-COV17 Terminal Cover to the holes on the top and bottom of the Digital Controller.

E5AN/EN-H

E5AN-H

E5EN-H

Mounting to the Panel

1,2,3...

1. For waterproof mounting, waterproof packing must be installed on the Controller. Waterproofing is not possible when group mounting several Controllers. Waterproof packing is not necessary when there is no need for the waterproofing function.
2. Insert the E5AN/E5EN-H into the square mounting hole in the panel (thickness: 1 to 8 mm). Attach the Mounting Brackets provided with the product to the mounting grooves on the top and bottom surfaces of the rear case.
3. Use a ratchet to alternately tighten the screws on the top and bottom Mounting Brackets little by little to maintain balance, until the ratchet turns freely.

Mounting the Terminal Cover

Slightly bend the E53-COV16 Terminal Cover to attach it to the terminal block as shown in the following diagram. The Terminal Cover cannot be attached in the opposite direction.

Enlarged Illustration of Terminal Section

2-1-4 Removing the Digital Controller from the Case

The body of the Digital Controller can be removed from the case to set Output Units or to perform maintenance. Check the specifications of the case and Digital Controller before removing the Digital Controller from the case.

E5CN-H

1,2,3...

1. Insert a flat-blade screwdriver into the two tool insertion holes (one on the top and one on the bottom) to release the hooks.
2. Insert the flat-blade screwdriver in the gap between the front panel and rear case, and pull out the front panel slightly. Hold the top and bottom of the front panel and carefully pull it out toward you, without applying unnecessary force.
3. When inserting the body of the Digital Controller into the case, make sure the PCBs are parallel to each other, make sure that the sealing rubber is in place, and press the E5CN-H all the way to the rear case. While pushing the E5CN-H into place, push down on the hooks on the top and bottom surfaces of the rear case so that the hooks are securely locked in place. Be sure that electronic components do not come into contact with the case.

Bottom View of the E5CN-H

E5AN/EN-H

1,2,3...

1. Insert a flat-blade screwdriver into the two tool insertion holes (one on the top and one on the bottom) to release the hooks.
2. Insert a flat-blade screwdriver in the gap between the front panel and rear case (two on the top and two on the bottom), and use it to pry and pull out the front panel slightly. Then, pull out on the front panel gripping both sides. Be sure not to impose excessive force on the panel.

Gap between the Front Panel and Rear Case Four gaps, two on the top and two on the bottom

Top View of E5AN-H

Gap between the Front Panel and Rear Case Four gaps, two on the top and two on the bottom

Top View of E5EN-H

1. When inserting the body of the Digital Controller into the case, make sure the PCBs are parallel to each other, make sure that the sealing rubber is in place, and press the E5AN/EN-H toward the rear case until it snaps into position. While pressing the E5AN/EN-H into place, press down on the hooks on the top and bottom surfaces of the rear case so that the hooks securely lock in place. Make sure that electronic components do not come into contact with the case.

Bottom View of the E5AN-H

Bottom View of the E5EN-H

Mounting Output Units

Before Performing the Setup

• Confirm the type of Output Units that are to be set.
• For details on types of Output Units and the main specifications, refer to Output Units on page 32.
• For position-proportional models and models with SSR outputs, the Output Units are already set. This setting operation is not required.
• When setting the Output Units, draw out the body of the Controller from the case and insert the Output Units into the sockets for control output 1 and 2.

Setting Procedure

- Check the socket positions to be set using the following diagram.

E5AN-H

E5EN-H

1,2,3... 1. While lifting the hooks securing the PCB on the front panel, remove the PCB to which the sockets are attached.

E5AN-H

E5EN-H

1. Set the Output Unit for control output 1 in the OUT1 socket. Set the Output Unit for control output 2 in the OUT2 socket.

1. For the E5AN-H, use the enclosed clamps to secure the Output Units. Do not use clamps for the E5EN-H.

1. Set the PCB back in its original location, and make sure that the hooks securing the PCB are firmly in place.

2-2 Wiring Terminals

Check the terminal arrangements for E5CN-H terminals 1 to 15 and E5AN/EN-H terminals 1 to 30 as marked on the product label and on the side of the case.

2-2-1 Terminal Arrangement

E5CN-H

Controllers

Control output 1

Relay output 250 VAC, 3 A (resistive load) Voltage output (for driving SSR) 12 VDC, 21 mA Linear voltage out 0 to 10 VAC Load 1 kΩ max. Current output 0 to 20 mA DC 4 to 20 mA DC Load 600 Ω max.

graph TD
    A["Control output 1"] --> B["DO NOT USE"]
    B --> C["DO NOT USE"]
    C --> D["+"]
    D --> E["Output 1"]
    E --> F["1"]
    E --> G["2"]
    E --> H["3"]
    E --> I["4"]
    E --> J["5"]
    E --> K["6"]
    E --> L["7"]
    E --> M["8"]
    E --> N["9"]
    E --> O["10"]
    F --> P["Auxiliary outputs (relay outputs)"]
    G --> Q["Auxiliary outputs (relay outputs) 250 VAC, 3 A (resistive load)"]
    H --> R["Auxiliary outputs (relay outputs) 250 VAC, 3 A (resistive load)"]
    I --> S["Auxiliary outputs (relay outputs) 250 VAC, 3 A (resistive load)"]
    J --> T["Auxiliary outputs (relay outputs) 250 VAC, 3 A (resistive load)"]
    K --> U["Auxiliary outputs (relay outputs) 250 VAC, 3 A (resistive load)"]
    L --> V["Auxiliary outputs (relay outputs) 250 VAC, 3 A (resistive load)"]
    M --> W["Auxiliary outputs (relay outputs) 250 VAC, 3 A (resistive load)"]
    N --> X["Auxiliary outputs (relay outputs) 250 VAC, 3 A (resistive load)"]
    O --> Y["Auxiliary outputs (relay outputs) 250 VAC, 3 A (resistive load)"]
    P --> Z["Input power supply"]
    Q --> AA["Input power supply"]
    R --> AB["Input power supply"]
    S --> AC["Input power supply"]
    T --> AD["Input power supply"]
    U --> AE["Input power supply"]
    V --> AF["Input power supply"]
    W --> AG["Input power supply"]
    X --> AH["Input power supply"]
    Y --> AI["Input power supply"]
    Z --> AJ["A heater burnout alarm, heater short, heater overcurrent alarm, or input error is sent to the output to which the alarm 1 function is assigned."]
    AA --> AK["100 to 240 VAC"]
    AB --> AL["24 VAC/VDC (no polarity)"]

Option Units
E53-CNBN2 Event Inputs

E53-CNQBN2 Event Inputs and Control Output 2

graph TD
    A["Input"] --> B["11"]
    A --> C["12"]
    D["EV1"] --> E["13"]
    F["EV2"] --> G["14"]
    H["Control output 2\n12 VDC 21 mA"] --> I["15"]

E53-CNHBN2 Event Inputs and CT

E53-CNBFN2 Event Inputs and Transfer Output

graph TD
    A["11"] --> B["12"]
    C["13"] --> D["14"]
    E["15"] --> F["Transfer output"]
    G["EV1"] --> H["12"]
    I["EV2"] --> J["13"]
    K["+"] --> L["14"]
    M["4 to 20 mA DC (Load 600 Ω max.)"]

E53-CNQHHN2 Control Output 2 and CT2

graph TD
    A["Control output 2\n12 VDC 21 mA"] --> B["11"]
    A --> C["12"]
    A --> D["13"]
    A --> E["14"]
    A --> F["15"]
    G["CT2"] --> D
    H["CT1"] --> E
    I["+"] --> A

E53-CNQFN2 Control Output 2 and Transfer Output

graph TD
    A["Control output 2\n12 VDC 21 mA"] --> B["11"]
    A --> C["12"]
    A --> D["DO NOT\nUSE"]
    A --> E["13"]
    A --> F["14"]
    A --> G["Transfer output\n-"]
    F --> H["15"]
    F --> I["4 to 20 mA DC\n(Load 600 Ω\nmax.)"]

E53-CN01N2 Communications (RS-232)

E53-CNH01N2 Communications (RS-232) and CT

E53-CNQ01N2 Communications (RS-232) and Control Output 2

E53-CN03N2 Communications (RS-485)

E53-CNQ03N2 Communications (RS-485) and Control Output 2

E53-CNH03N2 Communications (RS-485) and CT

E53-CNHH03N2 Communications (RS-485) and CT2

E53-CNQHN2 Control Output 2 and CT

graph TD
    A["Control output 2\n12 VDC 21 mA"] --> B["11"]
    B --> C["12"]
    C --> D["13"]
    D --> E["14"]
    E --> F["15"]
    G["DO NOT\nUSE"] --> E
    H["CT1"] --> E

Note Wire all voltage input terminals correctly. The Controller may fail if voltage input terminals are wired incorrectly.

E5AN/EN-H

Controllers

Option Units

graph TD
    A["E53-EN01\nRS-232C"] --> B["11—SD"]
    A --> C["12—RD"]
    A --> D["13—SG"]
    A --> E["21—DO NOT USE"]
    A --> F["22—DO NOT USE"]
    G["E53-EN02\nRS-422"] --> H["11—RDB"]
    G --> I["12—RDA"]
    G --> J["13—SG"]
    G --> K["21—SDB"]
    G --> L["22—SDA"]
    M["E53-EN03\nRS-485"] --> N["11—B (+)"]
    M --> O["12—A (−)"]
    M --> P["13—DO NOT USE"]
    M --> Q["21—B (+)"]
    M --> R["22—A (−)"]
    S["E53-AKB"] --> T["11—Event Inputs"]
    S --> U["12—EV2 EV1"]
    S --> V["13"]
    V --> W["21"]
    V --> X["22"]

100 to 240 VAC
24 VAC/VDC (no polarity)

graph TD
    A["Input power supply"] --> B["Control output 1"]
    A --> C["Control output 2"]
    A --> D["Auxiliary output 1"]
    A --> E["Auxiliary output 2"]
    B --> F["Event Inputs"]
    C --> G["Control output 1"]
    C --> H["Control output 2"]
    D --> I["Auxiliary output 1"]
    E --> J["Auxiliary output 2"]
    F --> K["Event Inputs"]
    G --> L["Control output 1"]
    H --> M["Control output 2"]
    I --> N["Auxiliary output 1"]
    J --> O["Auxiliary output 2"]
    K --> P["Event Inputs"]
    L --> Q["Control output 1"]
    M --> R["Control output 2"]
    N --> S["Auxiliary output 1"]
    O --> T["Auxiliary output 2"]
    P --> U["Event Inputs"]
    Q --> V["Control output 1"]
    R --> W["Control output 2"]
    S --> X["Auxiliary output 1"]
    T --> Y["Auxiliary output 2"]
    U --> Z["Event Inputs"]
    V --> AA["Control output 1"]
    W --> AB["Control output 2"]
    X --> AC["Auxiliary output 1"]
    Y --> AD["Auxiliary output 2"]
    Z --> AE["Event Inputs"]
    AA --> AF["Control output 1"]
    AB --> AG["Control output 2"]
    AC --> AH["Auxiliary output 1"]
    AD --> AI["Auxiliary output 2"]

Control Output Unit

graph TD
    A["Input power supply"] --> B["1"]
    B --> C["2"]
    C --> D["3"]
    D --> E["4"]
    E --> F["5"]
    F --> G["6"]
    G --> H["7"]
    H --> I["8"]
    I --> J["9"]
    J --> K["10"]
    style A fill:#f9f,stroke:#333
    style K fill:#f9f,stroke:#333
    note1["Output unit"]
    note2["Output unit"]
    note3["Auxiliary output 1"]
    note4["Auxiliary output 2"]
    note5["Auxiliary output 3"]

SSR Outputs

graph TD
    A["Input power supply"] --> B["1"]
    B --> C["2"]
    C --> D["3"]
    D --> E["4"]
    E --> F["5"]
    F --> G["6"]
    G --> H["7"]
    H --> I["8"]
    I --> J["9"]
    J --> K["10"]
    style A fill:#f9f,stroke:#333
    style K fill:#f9f,stroke:#333

Models with Position-proportional Control

graph TD
    A["Input power supply"] --> B["1"]
    B --> C["2"]
    C --> D["3"]
    D --> E["4"]
    E --> F["5"]
    F --> G["6"]
    G --> H["7"]
    H --> I["8"]
    I --> J["9"]
    J --> K["10"]
    style A fill:#f9f,stroke:#333
    style K fill:#f9f,stroke:#333

Event input/
Transfer output/ Remote SP

graph TD
    A["21"] --> B["22"]
    B --> C["23"]
    C --> D["24"]
    D --> E["25"]
    E --> F["26"]
    F --> G["27"]
    G --> H["Transfer output"]
    H --> I["28"]
    I --> J["29"]
    J --> K["30"]
    K --> L["4 to 20 mA DC (Load: 600 max.)"]
    M["DO NOT USE"] --> N["+"]
    O["EV3"] --> P["23"]
    Q["EV4"] --> R["24"]
    S["Remote SP input"] --> T["30"]

Note Wire all voltage input terminals correctly. The Controller may fail if voltage input terminals are wired incorrectly.

2-2-2 Precautions when Wiring

• Separate input leads and power lines in order to prevent external noise.
• Use AWG24 (cross-sectional area: 0.205 ~mm^2 ) to AWG14 (cross-sectional area: 2.081 ~mm^2 ) twisted-pair cable (stripping length: 5 to 6 mm).
• Use crimp terminals when wiring the terminals.
• Use the suitable wiring material and crimp tools for crimp terminals.
• Tighten the terminal screws to a torque of 0.74 to 0.90 ~N · m .
• Use the following types of crimp terminals for M3.5 screws.

Note Do not remove the terminal block. Doing so will result in malfunction or failure.

2-2-3 Wiring

In the connection diagrams, the left side of the terminal numbers represents the inside of the Controller and the right side represents the outside.

Power supply

- With the E5CN-H, connect to terminals 9 and 10; with the E5AN-H and E5EN-H, connect pins 1 and 2. The following table shows the specifications.

- These models have reinforced insulation between the input power supply, the relay outputs, and other terminals.

Input

- Make the connections as shown below, using terminals 3 to 5 for the E5CN-H and pins 17 to 20 for the E5AN/EN-H, and matching the input types.

graph TD
    A["Thermocouple"] --> B["3"]
    B --> C["4"]
    C --> D["5"]
    D --> E["+"]
    E --> F["Platinum resistance thermometer"]
    F --> G["3"]
    G --> H["4"]
    H --> I["5"]
    I --> J["+"]
    J --> K["Analog input"]
    K --> L["mA"]
    L --> M["-"]
    M --> N["Do not use."]

    O["Thermocouple"] --> P["17"]
    P --> Q["18"]
    Q --> R["19"]
    R --> S["20"]
    S --> T["+"]
    T --> U["Platinum resistance thermometer"]
    U --> V["17"]
    V --> W["18"]
    W --> X["19"]
    X --> Y["20"]
    Y --> Z["+"]
    Z --> AA["Analog input"]
    AA --> AB["mA"]
    AB --> AC["-"]
    AC --> AD["Do not use."]

    AE["Analog input"] --> AF["17"]
    AF --> AG["18"]
    AG --> AH["19"]
    AH --> AI["20"]
    AI --> AJ["+"]
    AJ --> AK["V"]
    AK --> AL["-"]
    AL --> AM["Do not use."]

E5AN/EN-H

Note When wiring a voltage input, check the connected terminals carefully to make sure there are no mistakes. Incorrect wiring can cause the Unit to fail.

Control Output 1

- Outputs are sent from terminals 1 and 2 with the E5CN-H and from pins 3 and 4 with the E5AN/EN-H. The following diagrams show the available outputs and their internal equalizing circuits.

E5CN-H

E5AN/EN-H

- The following table shows the specifications for each output type.

E5CN-H

E5AN/EN-H

Note The SSR output (control output 1 or control output 2) ratings are as follows:

• Rated load voltage: 75 to 250 VAC
• Rated load current: 1 A (resistance load)
  Use the load current within the derating curve.
• A zero cross function is not supported.

■ Output Units

• The E5CN-H voltage output (for driving SSR) is not electrically isolated from the internal circuits. When using a grounding thermocouple, do not connect any of the control output terminals to the ground. (If a control output terminal is connected to the ground, errors will occur in the measured temperature as a result of leakage current.) E5AN/EN-H voltage outputs (for driving SSR), however, are functionally isolated from the internal circuits.
• If high levels of noise or surge are imposed between the output terminals of an SSR output, short-circuit faults may occasionally occur. If the output becomes permanently shorted, there is the danger of fire due to overheating of the heater. Design safety into the system, including measures to prevent excessive temperature rise and spreading of fire.

- Take countermeasures such as installing a surge absorber. As an additional safety measure, provide error detection in the control loop. (Use the Loop Burnout Alarm (LBA) and HS alarm that are provided for the E5□N-H.)

graph TD
    A["SSR output"] --> B["3"]
    B --> C["Varistor"]
    C --> D["Load"]
    D --> E["~"]
    F["4"] --> G["Varistor"]
    G --> B

Select a surge absorber that satisfies the following conditions.

Control Output 2

- Outputs are sent from terminals 11, 12, 14, and 15 with the E5CN-H, and from pins 5 and 6 with the E5AN/EN-H. The following diagrams show the available outputs and their internal equalizing circuits.

E5AN/EN-H

- The following table shows the specifications for each output type.

E5CN-H

E5AN/EN-H

Note The SSR output (control output 1 or control output 2) ratings are as follows:

• Rated load voltage: 75 to 250 VAC
• Rated load current: 1 A (resistance load)
  Use the load current within the derating curve.

- A zero cross function is not supported.

■ Output Units

• The E5CN-H voltage output (for driving SSR) is not electrically isolated from the internal circuits. When using a grounding thermocouple, do not connect any of the control output terminals to the ground. (If a control output terminal is connected to the ground, errors will occur in the measured temperature as a result of leakage current.) E5AN/EN-H voltage outputs (for driving SSR), however, are functionally isolated from the internal circuits.
• Control output 2 of the E5CN-H is a voltage output (for driving SSR) only, and outputs across terminals 11(+) and 12(-), or 14(+) and 15(-).
• Control output 1 (voltage output for driving SSR) and control output 2 (voltage output for driving SSR) are not isolated.
• If high levels of noise or surge are imposed between the output terminals of an SSR output, short-circuit faults may occasionally occur. If the output becomes permanently shorted, there is the danger of fire due to overheating of the heater. Design safety into the system, including measures to prevent excessive temperature rise and spreading of fire.

- Take countermeasures such as installing a surge absorber. As an additional safety measure, provide error detection in the control loop. (Use the Loop Burnout Alarm (LBA) and HS alarm that are provided for the E5□N-H.)

graph TD
    A["SSR output"] --> B["5"]
    B --> C["Varistor"]
    C --> D["Load"]
    D --> E["~"]
    F["6"] --> G["Varistor"]
    G --> C

Select a surge absorber that satisfies the following conditions.

Auxiliary Outputs 2, and 3

• On the E5CN-H□2□-500, auxiliary output 1 (SUB1) is output across terminals 7 and 8, and auxiliary output 2 (SUB2) is output across terminals 6 and 8.
• On the E5AN/EN-H□2□-500, auxiliary output 1 (SUB1) is output across terminals 9 and 10, auxiliary output 2 (SUB2) is output across terminals 7 and 8.
• On the E5AN/EN-H□3□-500, auxiliary output 1 (SUB1) is output across terminals 9 and 10, auxiliary output 2 (SUB2) is output across terminals 7 and 8, and auxiliary output 3 (SUB3) is output across terminals 14, 15 and 16.
• When the Input Error Output parameter is set to ON, the output assigned to the alarm 1 function turns ON when an input error occurs.
• If the Remote SP Input Error Output parameter is set to ON, the output assigned to the alarm 1 function will turn ON when an RSP input error occurs.
• When the HB alarm, HS alarm, or heater overcurrent alarm is used with the E5CN-H (with E53-CN□H/HH□N2), alarms are output to the output assigned to the alarm 1 function.
• When the HB alarm, HS alarm, or heater overcurrent alarm is used with the E5AN-H/EN-H, alarms are output across terminals 9 and 10.
• On the E5CN-H, when heating/cooling control is used, auxiliary output 2 becomes control output (cooling).
• On the E5AN-H and E5EN-H, when heating/cooling control is used, control output 2 becomes the control output (cooling).
• For models that have a heater burnout alarm, an OR of the alarm 1 function and the HB alarm, HS alarm, or heater overcurrent alarm is output. If the alarm 1 function is to be used for HB alarm only, set the alarm 1 type to 0 (i.e., do not use alarm 1 function).
• The following diagrams show the internal equalizing circuits for auxiliary outputs 1, 2, and 3.

E5CN-H

graph TD
    A["5"] --> B["6"]
    B --> C["7"]
    C --> D["8"]
    D --> E["9"]
    E --> F["10"]
    G["SUB3"] --> H["SUB2"]
    I["SUB1"] --> J["SUB1"]

E5AN/EN-H

ALM1, 2, 3 can be output to auxiliary output 1, 2, 3 or changed with the advanced function setting level.

- The relay specifications are as follows:

Event Inputs

- The E5□N-H□□□B supports event inputs. When event inputs 1/2 are to be used, connect to terminals 11 to 13, and when event inputs 3/4 are to be used, connect to terminals 23 to 25.

E53-CN□B□N2 (for E5CN-H)

graph TD
    A["11"] --> B["EV1"]
    C["12"] --> D["EV2"]
    E["13"] --> F["..."]
    B --> G["..."]

E53-AKB (for E5AN/EN-H)

graph TD
    A["11"] --> B["EV1"]
    C["12"] --> D["EV2"]
    E["13"] --> F["..."]
    G["23"] --> H["EV3"]
    I["24"] --> J["EV4"]
    K["25"] --> L["..."]

E5AN-H/EN-H□B□M□-500

• Use event inputs under the following conditions:
• The outflow current is approximately 7 mA.

Contact inputON: 1 kΩ max., OFF: 100 kΩ min.

No-contact inputON: Residual voltage 1.5 V max.; OFF: Leakage current 0.1 mA max.

Polarities during no-contact input are as follows:

Two Event Inputs: E53-CN□B□N2 (for E5CN-H)

graph TD
    A["11"] -->|+| B["EV1"]
    C["12"] -->|+| D["EV2"]
    E["13"] -->|-| D
    A --> C
    C --> E

Two Event Inputs: E5AN/EN-H□B□M□-500 (for E5AN/EN-H)

Two Additional Event Inputs: E53-AKB in E5AN/EN-H□B□M□-500 (for E5AN/EN-H)

CT Inputs

• When the HB alarm, HS alarm, or heater overcurrent alarm is to be used with the E5CN-H□M□-500 with an E53-CN□H/HH□N2 Option Unit, connect a current transformer (CT) across terminals 14 and 15 or terminals 13 and 15 (no polarity).
• When the HB alarm, HS alarm, or heater overcurrent alarm is to be used with the E5AN/EN-H□□H□-500 or E5AN/EN-H□□HH□-500, connect a current transformer (CT) across terminals 14 and 15 or terminals 15 and 16 (no polarity).

graph TD
    A["14"] --> C["CT"]
    B["15"] --> C["CT"]

E53-CN□H□N2
(for E5CN-H)

graph TD
    A["13"] --> B["CT1"]
    C["14"] --> B
    D["15"] --> B
    B --> E["CT2"]

E53-CN□HH□N2

graph TD
    A["14"] --> C["CT"]
    B["15"] --> C["CT"]

E5AN/EN-H□□H□-500

graph TD
    A["14"] --> B["CT1"]
    C["15"] --> D["CT2"]
    E["16"] --> F["CT1"]
    E --> G["CT2"]

E5AN/EN-H□□HH□-500

Transfer Output

• On the E5CN-H□M□-500 with an E53-CN□FN2, the transfer output is output across terminals 14 and 15.
• On the E5AN/EN-H□□F-500, transfer output is output across terminals 27 and 28.

E53-CN□FN2
(for E5CN-H)

E5AN/EN-H□□F-500

Even with models that do not have a transfer output, control outputs 1 or 2 can be used as a simple transfer output if it is a current output or linear output. For details on the operation, refer to 4-14 Using the Transfer Output.

Remote SP Input

- The E5AN-H and E5EN-H support remote SP inputs. To use remote SP, connect to terminals 29 and 30.

E5AN/EN-H

Remote SP inputs are not electrically isolated from the internal circuits. When using a grounding thermocouple, do not connect any of the remote SP input terminals to the ground. (If a remote SP input terminal is connected to the ground, errors will occur in the measured temperature as a result of leakage current.)

Communications

RS-485

- When communications are to be used with the E53-CN□03N2 for the E5CN-H, or E53-EN03 for the E5AN/EN-H, connect communications cable across terminals 11 and 12 or 21 and 22.

graph TD
    A["11"] --> B["B(+)"]
    C["12"] --> D["A(-)"]
    E["13"] --> F["Do not use."]
    G["21"] --> H["B(+)"]
    I["22"] --> J["A(-)"]
    K["E53-EN03 (for E5AN/EN-H)"] --> L["RS-485"]

Specify both ends of the transmission path including the host computer as end nodes (that is, connect terminators to both ends).

The minimum terminal resistance is 54 Ω.

Communications Unit Connection Diagram

E5CN-H

graph TD
    A["Host computer"] --> B["RS-485"]
    B --> C["Shield"]
    C --> D["E5CN-H (No. 1)"]
    D --> E["RS-485"]
    E --> F["No. Abbreviation"]
    E --> G["12 A (-)"]
    E --> H["11 B (+)"]
    I["Terminator (120 Ω, 1/2 W)"] --> J["RS-485"]
    J --> K["No. Abbreviation"]
    J --> L["12 A (-)"]
    J --> M["11 B (+)"]

E5AN/EN-H

graph TD
    A["Host computer RS-485"] --> B["+"]
    B --> C["FG"]
    C --> D["Shield"]
    D --> E["E5AN/EN-H (No. 1)"]
    E --> F["RS-485"]
    F --> G["No. Abbreviation"]
    F --> H["22 A (-)"]
    F --> I["21 B (+)"]
    F --> J["12 A (-)"]
    F --> K["11 B (+)"]
    E --> L["E5AN/EN-H (No. 31)"]
    L --> M["No. Abbreviation"]
    L --> N["22 A (-)"]
    L --> O["21 B (+)"]
    L --> P["12 A (-)"]
    L --> Q["11 B (+)"]
    M --> R["Terminator (120 Ω, 1/2 W)"]
    N --> R
    O --> R
    P --> R
    Q --> R
    style A fill:#f9f,stroke:#333
    style E fill:#ccf,stroke:#333
    style L fill:#cfc,stroke:#333

- The RS-485 connection can be either one-to-one or one-to-N. A maximum of 32 Units (including the host computer) can be connected in one-to-N systems. The maximum total cable length is 500m . Use AWG24 (cross-sectional area: 0.205mm^2 ) to AWG14 (cross-sectional area: 2.081mm^2 ) shielded twisted-pair cable.

RS-232C

- When communications are to be used with the E53-CN□01N2 for the E5CN-H, or the E53-EN01 for the E5AN/EN-H, connect communications cable across terminals 11 to 13.

graph LR
    A["Host computer"] --> B["RS-232C: 25-pin"]
    B --> C["SD (TXD) 2"]
    B --> D["RD (RXD) 3"]
    B --> E["RS (RTS) 4"]
    B --> F["CS (CTS) 5"]
    B --> G["DR (DSR) 6"]
    B --> H["SG 7"]
    B --> I["ER (DTR) 20"]
    J["E5□N-H"] --> K["No."]
    K --> L["11 SD"]
    K --> M["12 RD"]
    K --> N["13 SG"]
    O["FG"] --> P["1"]
    P -.-> Q["Output"]

• A 1:1 connection is used. The maximum cable length is 15m . To extend the transmission path, use the OMRON Z3R RS-232C Optical Interface.
• Use AWG24 (cross-sectional area: 0.205 ~mm^2 ) to AWG14 (cross-sectional area: 2.081 ~mm^2 ) shielded twisted-pair cable.

graph TD
    A["Coil with multiple inlet/outlet streams"] --> B{Flow Direction}
    B --> C["Particle with circular holes"]
    C --> D["Outlet of Coating"]
    style A fill:#f9f,stroke:#333
    style D fill:#bbf,stroke:#333

Cross-sectional area of conductor

AWG24: 0.205 mm ^4

AWG14: 2.081 mm²

RS-422 (E5AN/EN-H Only)

- When communications are to be used with the E53-EN02 for the E5AN/EN-H, connect Communications Cable across terminals 11 to 13 and 21 to 22.

graph LR
    A["11"] --> B["RDB"]
    C["12"] --> D["RDA"]
    E["13"] --> F["SG"]
    G["21"] --> H["SDB"]
    I["22"] --> J["SDA"]
    B --> K["RS-422"]
    D --> K
    F --> K
    H --> K
    J --> K

E5AN/EN-H□M□-500 with an E53-EN02

graph TD
    A["Host computer"] --> B["RS-422"]
    B --> C["RDA"]
    B --> D["RDB"]
    B --> E["SDA"]
    B --> F["SDB"]
    B --> G["SG"]
    B --> H["FG"]
    I["E5AN/EN-H (No.1)"] --> J["No. 22 SDA"]
    I --> K["No. 21 SDB"]
    I --> L["No. 12 RDA"]
    I --> M["No. 11 RDB"]
    I --> N["No. 13 SG"]
    O["Two Terminators (240 Ω, 1/2 W)"] --> P["No. 22 SDA"]
    O --> Q["No. 21 SDB"]
    O --> R["No. 12 RDA"]
    O --> S["No. 11 RDB"]
    O --> T["No. 13 SG"]
    U["E5AN/EN-H (No.31)"] --> V["No. 22 SDA"]
    U --> W["No. 21 SDB"]
    U --> X["No. 12 RDA"]
    U --> Y["No. 11 RDB"]
    U --> Z["No. 13 SG"]
    style A fill:#f9f,stroke:#333
    style I fill:#ccf,stroke:#333
    style O fill:#cfc,stroke:#333
    style U fill:#fcc,stroke:#333

• A 1:1 or 1:N connection is used. When a 1:N connection is used, a maximum of 32 nodes including the host computer can be connected.
• Use AWG24 (cross-sectional area: 0.205 ~mm^2 ) to AWG14 (cross-sectional area: 2.081 ~mm^2 ) shielded twisted-pair cable.

2-3 Using the Support Software Port

Use the communications port for Support Software to connect the personal computer to the Digital Controller when using EST2-2C-MV4 CX-Thermo or a version of CX-Thermo higher than 4.00, or other Support Software. The E58-CIFQ1 USB-Serial Conversion Cable is required to make the connection.

For information concerning the models that can be used with CX-Thermo, contact your OMRON sales representative.

Procedure

Use the following procedure to connect the Digital Controller to the personal computer using the USB-Serial Conversion Cable. The USB-Serial Conversion Cable is used to communicate with the COM port of the personal computer. To perform communications using USB-Serial Conversion Cable, set the communications port (COM port) number to be used for the software to the COM port assigned to the Cable.

1,2,3... 1. Turn ON the power to the Digital Controller.

Note If the Cable is connected when the power to the Digital Controller is OFF, power will be supplied from the personal computer and impose a load on the internal circuits of the Digital Controller.

1. Connect the Cable.

Connect the personal computer's USB port with the Support Software port on the Digital Controller using the Cable.

• Digital Controller Connection Method

Note Hold the connector when inserting or disconnecting the Cable.

1. Install the driver.

Install the driver to enable the Cable to be used with the personal computer.

- Installation

When the Cable is connected with the personal computer, the OS detects the product as a new device. At this time, install the driver using the installation wizard. For details on installation methods, refer to the user's manual for the E58-CIFQ1 USB-Serial Conversion Cable.

1. Setting Setup Tool Communications Conditions

Set the communications port (COM port) number to be used for the CX-Thermo Setup Tool to the COM port number assigned to the USB-Serial Conversion Cable.

Refer to the E58-CIFQ1 USB-Serial Conversion Cable Instruction Manual and Setup Manual for details on how to check the COM port assigned to the USB-Serial Conversion Cable.

The communications conditions for Setup Tool COM ports are fixed as shown in the table below. Set the communications conditions for the CX-Thermo Setup Tool according to the following table.

2-4 Using Infrared Communications

When a Setup Tool, such as CX-Thermo version 4.00 or later (EST2-2C-MV4 or later), is used, the personal computer and Digital Controller can be connected using infrared communications. Using infrared communications enables the personal computer and Digital Controller to be connected from the front panel while ensuring a dust-tight and drip-tight structure. Use a USB-Infrared Conversion Cable, and connect it to the USB port at the personal computer. Infrared communications are supported only for the E5AN-H and E5EN-H. The infrared communications port and the Setup Tool port cannot be used at the same time.

For information concerning the models that can be used with the CX-Thermo, contact your OMRON sales representatives.

Procedure

Use the following procedure to connect the Digital Controller to the personal computer using the USB-Infrared Conversion Cable. The USB-Infrared Conversion Cable is used to communicate with the COM port on the personal computer. To perform communications using the USB-Infrared Conversion Cable, set the communications port (COM port) number to be used for the Setup Tool (such as CX-Thermo) to the COM port assigned to the Cable.

1,2,3...

1. Connecting the USB-Infrared Conversion Cable to the Personal Computer Connect the USB-Infrared Conversion Cable to the USB port on the personal computer.

2. Install the driver Install the driver to enable the USB-Infrared Conversion Cable to be used with the personal computer.

- Installation When the Cable is connected with the personal computer, the OS will detect is as a new device. At this time, install the driver using the installation wizard. For details on installation methods, refer to the Instruction Sheet and Setup Manual for the E58-CIFIR USB-Infrared Conversion Cable.

1. Enabling Digital Controller Infrared Communications Mount the Digital Controller to the panel and wire it. Turn ON the power supply for the Digital Controller, go to the adjustment level, and set the Infrared Communications Use parameter to ON. When this parameter is set to ON, the Ir indicator on the front panel of the Digital Controller will light. This enables connecting to a personal computer using infrared communications.

1. Connecting the USB-Infrared Conversion Cable to the Digital Controller Mount the enclosed adapter to the Digital Controller. Hold the USB-Infrared Conversion Cable with the label side facing up, and insert the Cable into the adapter to the line specified on the label.

1. Setting the Setup Tool Communications Conditions

Set the communications port (COM port) number to be used for the CX-Thermo Setup Tool to the COM port number assigned to the USB-Infrared Conversion Cable.

Refer to the E58-CIFIR USB-Infrared Conversion Cable Instruction Sheet and Setup Manual for details on checking the COM port assigned to the USB-Infrared Conversion Cable. The communications conditions for infrared COM ports are fixed as shown in the table below. Set the communications conditions for the CX-Thermo Setup Tool according to the following table.

1. Checking the Settings

After completing all data transfers, be sure that the data is correct. Finally, remove the USB-Infrared Conversion Cable and mounting adapter from the Digital Controller and set the Infrared Communications Use parameter to OFF. Operation can now be started.

Turn ON the Infrared Communications Use parameter only when connected to the Setting Tool through infrared communications. Leave it set to OFF during normal operation.

SECTION 3

Basic Operation

This section describes the basic operation of the E5CN-H, E5AN-H, and E5EN-H Digital Controllers, including key operations to set parameters and descriptions of display elements based on specific control examples.

3-1 Initial Setting Examples 46
3-2 Setting the Input Type.... 49

3-2-1 Input Type.... 49

3-3 Selecting the Temperature Unit.... 51
3-3-1 Temperature Unit 51
3-4 Selecting PID Control or ON/OFF Control 51
3-5 Setting Output Specifications 52

3-5-1 Control Periods.... 52
3-5-2 Direct and Reverse Operation.... 52
3-5-3 Assigned Output Functions.... 53

3-6 Setting the Set Point (SP) 56

3-6-1 Changing the SP 56

3-7 Using ON/OFF Control.... 57

3-7-1 ON/OFF Control.... 57
3-7-2 Settings 58

3-8 Determining PID Constants (AT, ST, Manual Setup) 60

3-8-1 AT (Auto-tuning) 60
3-8-2 ST (Self-tuning) 62
3-8-3 RT (Robust Tuning) 64
3-8-4 Manual Setup 66

3-9 Alarm Outputs.... 67

3-9-1 Alarm Types 67
3-9-2 Alarm Values 69

3-10 Using Heater Burnout, Heater Short, and Heater Overcurrent Alarms.....71

3-10-1 Heater Burnout, Heater Short, and Heater Overcurrent Alarm Operations.... 71
3-10-2 Installing Current Transformers (CT)....72
3-10-3 Calculating Detection Current Values 73
3-10-4 Application Examples....74
3-10-5 Settings: HB Alarm. 78
3-10-6 Settings: Heater Short Alarm 79
3-10-7 Settings: Heater Overcurrent Alarm.... 80

3-11 Setting the No. 3 Display 82

3-11-1 PV/SP Display Selection 82

3-1 Initial Setting Examples

Initial hardware setup, including the sensor input type, alarm types, control periods, and other settings is done using parameter displays. The ☐ and ☑ Keys are used to switch between parameters, and the amount of time that you press the keys determines which parameter you move to.

This section describes 3 typical examples.

Explanation of Examples

graph TD
    A["CN-L"] --> B["CN-M"]
    A --> C["CN-L"]
    A --> D["CNEL"]
    B --> E["CNEL Pcd"]
    C --> F["CNEL Pcd"]

A □ image means that there are parameters. Continue pressing the ☑ key to change parameters until you reach the intended parameter.

Changing Numbers

25.0 Numeric data and selections in each screen can be changed by using the ▲ and ▼ keys.

Example 1

graph TD
    A["Input type: 5 (K thermocouple, -200.0°C to 1,300.0°C)<br>Control method: ON/OFF control<br>Alarm type: 2 (upper limit)<br>Alarm value 1: 20°C (deviation)<br>Set point: 100°C"] --> B["Setup Procedure"]
    B --> C["Power ON"]
    C --> D["Operation Level: 25.0 PV/SP"]
    D --> E["Press the ☐ key for at least 3 s.<br>Control stops."]
    E --> F["Initial Setting Level"]
    F --> G["Set input specifications"]
    G --> H["Set control specifications"]
    H --> I["Set alarm type"]
    I --> J["Operation Level: Set alarm values"]
    J --> K["Start operation"]

    subgraph Operation Levels
        L["Check input type."] --> M["ON-1 5"]
        M --> N["Check that control method is ON/OFF control."]
        N --> O["Check alarm type. RLL 1 2"]
        O --> P["Press the ☐ key for at least 1 s."]
        P --> Q["Control starts."]
        Q --> R["Operation Level: Use the ▲ and √ keys to set the SP to 100°C."]
        R --> S["PV/SP: 100.0"]
        S --> T["Confirm that control is running."]
        T --> U["R-5 RUN"]
        U --> V["Running RUN Stopped: 5±P"]
        V --> W["Use the ▲ and √ keys to set the alarm value to 20°C."]
        W --> X["Alarm Value 1: 20.0"]
        X --> Y["Start operation."]

Example 2

graph TD
    A["Input type: 9 (T thermocouple, -200.0°C to 400.0°C)<br>Control method: PID control<br>PID constants found using<br>auto-tuning (AT).<br>Alarm type: 2 upper limit<br>Alarm value 1: 30°C<br>Set point: 150°C"] --> B["Setup Procedure"]
    B --> C["Power ON"]
    C --> D["Operation Level"]
    D --> E["Press the ☐ key for at least 3 s.<br>Control stops."]
    E --> F["Initial Setting Level"]
    F --> G["Use the ▲ and ✓ keys to select the input type."]
    G --> H["ON/OFF control: PID control: To execute ON ST: To cancel OFF"]
    H --> I["Check the control period."]
    I --> J["Control Period (Heat) 20 (Unit: Seconds)"]
    J --> K["Alarm 1 Type: 2"]
    K --> L["Press the ☐ key for at least 1 s.<br>Control starts."]
    L --> M["Operation Level"]
    M --> N["Press the ☐ key (for less than 1 s."]
    N --> O["Adjustment Level"]
    O --> P["Execute AT."]
    P --> Q["To execute 100% AT (auto-tuning), select Rt-2. To execute 40% AT, select Rt-1. To cancel AT, select ∅FF: (AT cancel)."]
    O --> R["Operation Level"]
    R --> S["Confirm that the set point is 150°C."]
    S --> T["PV/SP"]
    R --> U["Confirm that control is running."]
    U --> V["R-S RUN"]
    V --> W["Running Stopped Step"]
    W --> X["Alarm Value 1"]
    R --> Y["Start operation."]

    subgraph Adjustment Level
        Z["AT execution<br>(When PID control is selected)"]
        AA["Operation Level"]
        AB["Set alarm value"]
    end

    subgraph Operation Level
        AC["Start operation"]
    end

    style A fill:#f9f,stroke:#333
    style B fill:#ccf,stroke:#333
    style C fill:#cfc,stroke:#333
    style D fill:#fcc,stroke:#333
    style E fill:#ffc,stroke:#333
    style F fill:#cff,stroke:#333
    style G fill:#ffc,stroke:#333
    style H fill:#ffc,stroke:#333
    style I fill:#ffc,stroke:#333
    style J fill:#ffc,stroke:#333
    style K fill:#ffc,stroke:#333
    style L fill:#ffc,stroke:#333
    style M fill:#ffc,stroke:#333
    style N fill:#ffc,stroke:#333
    style O fill:#ffc,stroke:#333
    style P fill:#ffc,stroke:#333
    style Q fill:#ffc,stroke:#333
    style R fill:#ffc,stroke:#333
    style S fill:#ffc,stroke:#333
    style T fill:#ffc,stroke:#333
    style U fill:#ffc,stroke:#333
    style V fill:#ffc,stroke:#333
    style W fill:#ffc,stroke:#333
    style X fill:#ffc,stroke:#333
    style Y fill:#ffc,stroke:#333

Example 3

graph TD
    A["Power ON"] --> B["Initial Setting Level"]
    B --> C["Set input specifications"]
    C --> D["Set control specifications"]
    D --> E["Set travel time"]
    E --> F["Set SP ramp"]
    F --> G["Start operation"]

graph TD
    A["Power ON"] --> B["Operation Level"]
    B --> C["Initial Setting Level"]
    C --> D["Check input type: PV/SP 25.0 0.0"]
    D --> E["Press the key for at least 3 s. Control stops."]
    C --> F["Check that control method is floating control."]
    F --> G["Input Type: 5 LN-8 5"]
    G --> H["Check that control method is floating control."]
    H --> I["Use the & and keys to set the travel time to 45."]
    I --> J["Floating control: FLôt FLôt"]
    J --> K["Use the & and keys to set the SP ramp set value to 10.0°C."]
    K --> L["Close control: CLàS Mat 45 Travel time: 45"]
    C --> M["Operation Level"]
    M --> N["Adjustment Level"]
    N --> O["Use the & and keys to set the SP ramp set value to 250.0°C."]
    N --> P["Use the & and keys to set the SP ramp set value to 250.0°C."]
    M --> Q["Adjustment Level"]
    Q --> R["Use the & and keys to set the SP ramp set value to 250.0°C."]
    M --> S["Operation Level"]
    S --> T["Confirm that control is running."]
    T --> U["Start operation."]
    M --> V["Press the key for at least 1 s. Control starts."]
    N --> W["Press the key (for less than 1 s.)"]
    W --> X["Use the & and keys to set the SP ramp set value to 10.0°C."]
    W --> Y["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> Z["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AA["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AB["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AC["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AD["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AE["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AF["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AG["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AH["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AI["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AJ["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AK["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AL["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AM["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AN["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AO["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AP["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AQ["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AR["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AS["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AT["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AU["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AV["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AW["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AX["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AY["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> AZ["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BA["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BB["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BC["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BD["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BE["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BF["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BG["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BH["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BI["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BJ["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BK["Use the & and keys to set the SP ramp set value to 250.0°C."]
    W --> BL["Use the & and keys to set the SP ramp set value to 250.0°C."]

3-2 Setting the Input Type

The Controller supports 3 input types: platinum resistance thermometer, thermocouple, and analog inputs. Set the input type that matches the sensor that is used.

3-2-1 Input Type

The following example shows how to set a K thermocouple for -20.0 to 500.0°C.

Operating Procedure

Operation Level

Initial Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Press the ⚙ Key to enter the set value of the desired sensor. When you use a K thermocouple ( -20.0 to 500.0^ ), enter 6 as the set value.

Hint: The key operation is saved two seconds after the change, or by pressing the ☐ or ☑ Key.

List of Input Types

• The default is 5.
• If a platinum resistance thermometer is mistakenly connected while a setting for other than a platinum resistance thermometer is in effect, S.ERR will be displayed. To clear the S.ERR display, check the wiring and then turn the power OFF and back ON.

3-3 Selecting the Temperature Unit

3-3-1 Temperature Unit

• Either ^ or ^ can be selected as the temperature unit.
• Set the temperature unit in the Temperature Unit parameter of the initial setting level. The default is (°C).

Operating Procedure

Operation Level

Initial Setting Level

Input Type

Temperature Unit

The following example shows how to select ^ C as the temperature unit.

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select the Temperature Unit parameter by pressing the ☑ Key. Press the ⚠ or √ Key to select either °C or °F.

: ^ F: ^

1. To return to the operation level, press the ☐ Key for at least one second.

3-4 Selecting PID Control or ON/OFF Control

Two control methods are supported: 2-PID control and ON/OFF control. Switching between 2-PID control and ON/OFF control is executed by means of the PID ON/OFF parameter in the initial setting level. When this parameter is set to P_LD^- , 2-PID control is selected, and when set to , ON/OFF control, is selected. The default is P_LD^- . ON/OFF control is not displayed for position-proportional models.

2-PID Control

PID control is set by AT (auto-tuning), ST (self-tuning), or manual setting.

For PID control, set the PID constants in the Proportional Band (P), Integral Time (I), and Derivative Time (D) parameters.

ON/OFF Control

In ON/OFF control, the control output is turned ON when the process value is lower than the current set point, and the control output is turned OFF when the process value is higher than the current set point (reverse operation).

3-5 Setting Output Specifications

The following table shows the parameters related to outputs. Each of the parameters is described in detail following the table.

(●: Supported)

3-5-1 Control Periods

Control Period (Heating)

Control Period (Cooling)

• Set the output periods (control periods). Though a shorter period provides better control performance, it is recommended that the control period be set to 20 seconds or longer for a relay output to preserve the service life of the relay. After the settings have been made in the initial setup, readjust the control period, as required, by means such as trial operation.
• Set the control periods in the Control Period (Heating) and Control Period (Cooling) parameters in the initial setting level. The default is 20 seconds.
• The Control Period (Cooling) parameter is used only for heating/cooling control.
• When the control output is used as a current output or linear voltage output, the Control Period settings cannot be used.
• The control period can be set for standard models only.

3-5-2 Direct and Reverse Operation

- Direct operation increases the manipulated variable whenever the process value increases. Reverse operation decreases the manipulated variable whenever the process value increases.

For example, when the process value (PV) is lower than the set point (SP) in a heating control system, the manipulated variable increases according to the difference between the PV and SP. Accordingly, reverse operation is used in a heating control system. Direct operation is used in a cooling control system, in which the operation is the opposite of a heating control system.

- Direct/reverse operation is set in the Direct/Reverse Operation parameter in the initial setting level. The default is - R (reverse operation).

Operating Procedure

In this example, the input type, temperature unit, direct/reverse operation, and control period (heat) parameters are checked.

Input type = 5 (K thermocouple)

Temperature unit = (°C)

Direct/reverse operation = - (reverse operation)

Control period (heat) = 20 (seconds)

Operation Level

Initial Setting Level

Input Type

Temperature Unit

Control Period (Heating)

Direct/Reverse Operation

Operation Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. The input type is displayed. When the input type is being set for the first time, 5 (K thermocouple) is set. To select a different sensor, press the ▲ or ▼ Key.
3. Select the Temperature Unit parameter by pressing the ☐ Key. The default is (°C). To select (°F), press the ⚠ Key.
4. Select the Control Period (Heating) parameter by pressing the ☐ Key. The default is 20.
5. Select the Direct/Reverse Operation parameter by pressing the ☐ Key. The default is - (reverse operation). To select -d (direct operation), press the ⚠ Key.
6. To return to the operation level, press the ☐ Key for at least one second.

3-5-3 Assigned Output Functions

• Function assignments can be changed by changing the settings for control and auxiliary output assignments.
• The default function assignments for each output are shown below.

- Each output is automatically initialized as shown below by changing the control mode.

Example: E5CN-H

Note

(1) There is no control output 2 and no parameter assignment is displayed for that output.
(2) The Auxiliary Output 1 Assignment parameter becomes the program end output unless the Program Pattern parameter is set to OFF.

Alarms

It will be specified in this section when an alarm must be assigned, i.e., when an alarm must be set for the Control Output 1 or 2 Assignment parameters, or for the Auxiliary Output 1 or 3 Assignment parameters. For example, if alarm 1 is set for the Control Output 1 Assignment parameter, then alarm 1 has been assigned.

Assigning a work bit to either control output 1 or 2 or to auxiliary output 1 to 3 is also considered to be the same as assigning an alarm. For example, if work bit 1 is set for the Auxiliary Output 1 Assignment parameter, then alarms 1 to 3 have been assigned.

Operating Procedure

This procedure sets the following control and auxiliary output assignments.

Control output 1: Control output (heating); Control output 2: Control output (cooling); Auxiliary output 1: Alarm 1; Auxiliary output 2: Alarm 2

Operation Level

Initial Setting Level

Initial Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select the Standard or Heating/Cooling parameter by pressing the Key.

Initial Setting Level

Move to Advanced Function Setting Level

Advanced Function Setting Level

Parameter Initialization

Advanced Function Setting Level

Control Output 1 Assignment

Advanced Function Setting Level

Control Output 2 Assignment

Advanced Function Setting Level

Auxiliary Output 1 Assignment

Advanced Function Setting Level

Auxiliary Output 2 Assignment

1. Press the Key to set the parameter to H-Γ.

Note The following output assignments do not need to be set because they are set automatically by changing the control mode, but they are shown here as a reference for checking the assignments for each output.

1. Select the Move to Advanced Function Setting Level parameter by pressing the ☐ Key. (For details on moving between levels, refer to 4-8 Moving to the Advanced Function Setting Level.)

2. Press the ☑ Key to enter the password (“-169”), and move from the initial setting level to the advanced function setting level.

3. Select the Control Output 1 Assignment parameter by pressing the Key.

4. Press the ▲ or ▼ Key to set . (The default is .)

5. Select the Control Output 2 Assignment parameter by pressing the Key.

6. Press the ⚠ or ⏱ Key to set - . (When H- is selected for the Standard or Heating/Cooling parameter, the setting will be - .)

7. Select the Auxiliary Output 1 Assignment parameter by pressing the Key.

8. Press the ▲ or ▼ Key to set RLM I. (The default is RLM I.)

9. Select the Auxiliary Output 2 Assignment parameter by pressing the Key.

10. Press the ▲ or ▼ Key to set RLM2. (The default is RLM2.)

Initial Setting Level

Operation Level

Auxiliary Output Opening or Closing in Alarm

1. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level.

2. Press the ☐ Key for at least one second to move from the initial setting level to the operation level.

3. When “close in alarm” is set, the status of the auxiliary output is output unchanged. When “open in alarm” is set, the status of the auxiliary output function is reversed before being output.
   • Each auxiliary output can be set independently.

4. These settings are made in the Auxiliary Output 1 to 3 Open in Alarm parameters (advanced function setting level).
5. The default is N - : Close in Alarm.
6. When “open in alarm” is set for the alarm 1 output, the open in alarm status is also applied to heater burnout, HS alarm, heater overcurrent, and input error outputs.

- The alarm output will turn OFF (i.e., the relay contacts will open) when power is interrupted and for about two seconds after the power is turned ON regardless of the setting of the Auxiliary Output 1 to 3 Open in Alarm parameter.

3-6 Setting the Set Point (SP)

Operation Level

Operation Level

The operation level is displayed when the power is turned ON. The process value (PV) is at the top of the display, and the set point (SP) is at the bottom.

For Controllers that support a No. 3 display (E5AN/E5EN-H), the contents set in the PV/SP Display Screen Selection parameter (advanced function setting level) are displayed below the PV and SP.

The MV is displayed as the default. For details, refer to 3-11 Setting the No. 3 Display.

3-6-1 Changing the SP

- The set point cannot be changed when the Operation/Adjustment Protect parameter is set to 3. For details, refer to 4-9 Using the Key Protect Level.

Operating Procedure

Operation Level

Bank Setting Level

Display Bank Selection

Bank 3 SP 1

Bank 3 SP 1

• To change the set point, select the bank number in the Display Bank Selection parameter in the bank setting level, and press the 🔗 or ⬇ Key in the SP parameter (in the bank setting level) for each bank to set the desired set value. The new set point will be selected two seconds after the new value has been specified.
• If the SP parameter is changed in the operation level, the change will be reflected in the set point for the current bank.
• The bank function can be used to change eight set points. For details, refer to Banks on page 129.

In this example, the set point in bank 3 is changed from 0^ C to 200^ C.

1. Normally, the Process Value/Set Point parameter is displayed. The set point is 0.0^ C.
2. The current bank number will be displayed. Press the ☐ Key to move the bank setting level.
3. Press the ↗ or ↕ Key to set 3.
4. Select the Bank 3 SP parameter by pressing the ☑ Key.
5. Press the ▲ and ▼ Keys to set 200.0.

3-7 Using ON/OFF Control

In ON/OFF control, the control output turns OFF when the temperature being controlled reaches the preset set point. When the manipulated variable turns OFF, the temperature begins to fall and the control turns ON again. This operation is repeated over a certain temperature range. At this time, how much the temperature must fall before control turns ON again is determined by the Hysteresis (Heating) parameter. Also, what direction the manipulated variable must be adjusted in response to an increase or decrease in the process value is determined by the Direct/Reverse Operation parameter.

3-7-1 ON/OFF Control

• Switching between 2-PID control and ON/OFF control is performed using the PID ON/OFF parameter in the initial setting level. When this parameter is set to P_LD , 2-PID control is selected, and when it is set to , ON/OFF control is selected. The default is P_LD .
• ON/OFF control can be set for standard models only.

Hysteresis

• With ON/OFF control, hysteresis is used to stabilize operation when switching between ON and OFF. The control output (heating) and control output (cooling) functions are set in the Hysteresis (Heating) and Hysteresis (Cooling) parameters, respectively.
• In standard control (heating or cooling control), the setting of the Hysteresis (Heating) parameter in the adjustment level is used as the hysteresis regardless of whether the control type is heating control or cooling control.

graph TD
    A["Reverse operation"] --> B["Hysteresis (heating)"]
    C["ON"] --> D["Set point"]
    E["OFF"] --> D
    D --> F["PV"]

Three-position Control

- In heating/cooling control, a dead band (an area where both control outputs are 0) can be set to either the heating or cooling side. This makes it possible to use 3-position control.

graph TD
    A["Reverse operation"] --> B["Hysteresis (heating)"]
    B --> C["ON"]
    C --> D["Heating side"]
    D --> E["Set point"]
    E --> F["Off"]
    F --> G["PV"]
    H["Dead band"] --> I["Hysteresis (cooling)"]
    I --> J["Cooling side"]
    J --> K["SET point"]

Parameters

3-7-2 Settings

To execute ON/OFF control, set the Set Point, PID ON/OFF, and Hysteresis parameters.

Setting the PID ON/OFF Parameter

Operating Procedure

The following example shows how to change the PID ON/OFF parameter to in the initial setting level.

Operation Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

Initial Setting Level

Input Type

PID•ON/OFF

PID•ON/OFF

1. The Input Type parameter is displayed in the initial setting level.

2. Select the PID ON/OFF parameter by pressing the ☐ Key.

3. Use the ▲ and ▼ Keys to set onof.

4. To return to the operation level, press the ☐ Key for at least one second. Next, set the set point value.

Setting the SP

Operating Procedure

Operation Level

PV/SP

In this example, the set point is set to 200.0. The set value (i.e., the SP) is shown at the bottom of the display.

1. Select the Process Value/Set Point parameter in the operation level.

2. Use the ⬆ and ⬇ Keys to set the SP. (In this example, it is set to 200.0.) The new set value can be saved by pressing the ⬇ Key, or it will go into effect after two seconds have elapsed. (The new set point will be reflected in the current bank.)

Next, set the hysteresis.

Setting the Hysteresis

Operating Procedure

Operation Level

PV/SP

Adjustment Level

Adjustment Level Display

Hysteresis (Heating)

Set the hysteresis to 2.0^ C.

1. Press the ☐ Key to move from the operation level to the adjustment level.

2. The Adjustment Level Display parameter will be displayed in the adjustment level.

3. Select the Hysteresis (Heating) parameter by pressing the ☐ Key.

4. Press the ⬆ and ⬇ Keys to set the hysteresis (2.0 in this example). Either press the ⬇ Key or wait for at least two seconds after setting the hysteresis value to confirm the setting.

5. To return to the operation level, press the ☐ Key.

3-8 Determining PID Constants (AT, ST, Manual Setup)

3-8-1 AT (Auto-tuning)

• When AT is executed, the optimum PID constants for the set point at that time are set automatically. A method (called the limit cycle method) for forcibly changing the manipulated variable and finding the characteristics of the control object is employed.
• Either 40% AT or 100% AT can be selected depending on the width of MV variation in the limit cycle. In the AT Execute/Cancel parameter, specify - (100% AT) or - I (40% AT). To cancel AT, specify (AT cancel).
• Only 100% AT can be executed for heating and cooling control or for floating control for position-proportional models.
• AT cannot be executed when control has stopped or during ON/OFF control.
• The results of AT are reflected in the Proportional Band (P), Integral Time (I), and Derivative Time (D) parameters for the PID set at the time AT execution starts. For details on PID sets, refer to PID Sets on page 129.

PID Setting Level

PID* Proportional Band

PID* Integral Time

PID* Derivative Time
(*: 1 to 8)

AT Operations

AT is started when either - (100% AT) or -I (40% AT) is specified for the AT Execute/Cancel parameter. During execution, the AT Execute/Cancel parameter on the No. 1 display flashes. When AT ends, the AT Execute/Cancel parameter turns OFF, and the No. 1 display stops flashing.

AT Execute/Cancel

No. 1 display
100% AT execution in progress

If you move to the operation level during AT execution, the No. 2 display flashes to indicate that AT is being executed.

PV/SP

No. 2 display
AT execution in progress

Only the Communications Writing, RUN/STOP, AT Execution/Cancel, and Program Start parameters can be changed during AT execution. Other parameters cannot be changed.

AT Calculated Gain

The AT Calculated Gain parameter sets the gain for when PID values are calculated using AT. When emphasizing response, decrease the set value. When emphasizing stability, increase the set value.

AT Hysteresis

The AT Hysteresis parameter sets the hysteresis when switching ON and OFF for the limit cycle operation during auto-tuning.

Limit Cycle MV Amplitude

The Limit Cycle MV Amplitude parameter sets the MV amplitude for limit cycle operation during auto-tuning.

Note Disabled for 100% AT.

■ 40% AT

The width of MV variation in the limit cycle can be changed in the Limit Cycle MV Amplitude parameter, but the AT execution time may be longer than for 100% AT. The limit cycle timing varies according to whether the deviation (DV) at the start of auto-tuning execution is less than 10% FS.

■ 100% AT

Operation will be as shown in the following diagram, regardless of the deviation (DV) at the start of AT execution. To shorten the AT execution time, select 100% AT.

Note The Limit Cycle MV Amplitude parameter is disabled.

Operating Procedure

Adjustment Level

AT Execute/Cancel

This procedure executes 100%AT.

1. Press the O Key to move from the operation level to the adjustment level. Press the ☐ Key to select the AT Execute/Cancel parameter.

2. Press the Key to select Rt - 2. The No. 1 display for AT Execute/Cancel will flash during AT execution.

Operation Level

1. OFF will be displayed when AT ends.
2. To return to the operation level, press the ☐ Key.

3-8-2 ST (Self-tuning)

ST (self-tuning) is a function that finds PID constants by using step response tuning (SRT) when Digital Controller operation begins or when the set point is changed.

Once the PID constants have been calculated, ST is not executed when the next control operation is started as long as the set point remains unchanged.

ST (self-tuning) is enabled when the ST parameter is set to ON in the initial setting level.

When the ST function is in operation, be sure to turn the power supply of the load connected to the control output ON simultaneously with or before starting Controller operation.

When executing self-tuning, turn ON power for the load (e.g., heater) at the same time as or before supplying power to the Digital Controller. If power is turned ON for the Digital Controller before turning ON power for the load, self-tuning will not be performed properly and optimum control will not be achieved. ST can be set for standard models only.

Operating Procedure

Initial Setting Level

This procedure executes self-tuning (ST).

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

1. Select the ST parameter by pressing the Key.
2. Press the ⬆ Key to select ☑N. ON is the default.
3. To return to the operation level, press the ☐ Key for at least one second. The temperature display flashes during self-tuning (ST) execution.

Operation Level

Note PID Constants

When control characteristics are already known, PID constants can be set directly to adjust control. PID constants are set in the Proportional Band (P), Integral Time (I), and Derivative Time (D) parameters, according to the Display PID Selection parameter setting in the PID setting level. Changing the Proportional Band (P), Integral Time (I), or Derivative Time (D) parameter settings in the adjustment level changes the settings in these parameters in the current PID set.

Startup Conditions

Self-tuning by step response tuning (SRT) is started when the following conditions are met after program execution is started and the set point is changed.

Note

(1) The previous SRT-implemented set point is the set point that was used for calculating the PID constants for the previous SRT.
(2) In this state, the measurement point is within the ST stable range.
(3) In this state, the change width of the PV every 60 seconds is within the ST stable range or less.

In the following instances, PID constants are not changed by self-tuning (ST) for the present set point.

1. When the PID constants have been changed manually with ST set to ON.
2. When auto-tuning (AT) has been executed.
3. When the PID set has been changed during SRT.
4. When the PID set for the current bank is set to 0 (PID set automatic selection).

In addition, the following diagrams show the difference between setting a different PID set for each bank and setting the same PID set. For details on bank settings, refer to 4-15 Using Banks and PID Sets.

Bank 0 PID set number = 1 Bank 1 PID set number = 2

Bank 0 PID set number = 1 Bank 0 PID set number = 1

1,2,3...

1. When operation starts, ST is executed for each bank and the PID constants are saved for each PID set. Stable control is thus enabled, because ST is not executed when the bank is changed or when the next operation starts.
2. ST is executed each time the bank is changed, and PID constants are saved for the same PID set. Therefore ST is executed each time the bank is changed and when the next operation starts.

ST Stable Range

Operating Procedure

The ST stable range determines the condition under which ST (self-tuning) functions.

This procedure sets the ST stable range to 20^ C.

Advanced Function Setting Level

ST Stable Range

1. Select the ST Stable Range parameter by pressing the ☐ Key in the advanced function setting level.

2. Use the ⬆ Key to set the parameter to 20^ C.

3-8-3 RT (Robust Tuning)

• When AT or ST is executed with RT selected, PID constants are automatically set that make it hard for control performance to degenerate even when the characteristics of the controlled object are changed.
• RT can be set in the advanced function setting level when PID control has been set.
• The RT mode cannot be selected while an analog input is set.
• Selecting the RT mode in the following cases will help to prevent hunting from occurring.
• When the set temperature is not constant and is changed in a wide range
• When there are large variations in ambient temperatures due to factors such as seasonal changes or differences between day and night temperatures
• When there are large variations in ambient wind conditions and air flow
• When heater characteristics change depending on the temperature
• When an actuator with disproportional I/O, such as a phase-control-type power regulator, is used
• When a rapidly heating heater is used
• When the control object or sensor has much loss time
• When hunting occurs in normal mode for any reason
• PID constants are initialized to the factory settings by switching to RT mode.
• When the RT mode is selected, the derivative time setting unit becomes the second.

RT Features

- Even when hunting occurs for PID constants when AT or ST is executed in normal mode, it is less likely to occur when AT or ST is executed in RT mode.

- When the temperature (PV) falls short of the set point for the PID constants when using AT or ST in normal mode, executing AT or ST in RT mode tends to improve performance.

- When the manipulated variable (MV) is saturated, the amount of overshooting may be somewhat higher in comparison to PID control based on AT or ST in normal mode.

Operating Procedure

Operation Level

Initial Setting Level

Initial Setting Level

Advanced Function Setting Level

Advanced Function Setting Level

This procedure selects RT mode.

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Select the Move to Advanced Function Setting Level parameter by pressing the ☐ Key.
3. Use the ☑ Key to enter “-169” (the password).

It is possible to move to the advanced function setting level by pressing the ☐ Key or leaving the setting for at least two seconds.

1. Press the ☐ Key to select RL.

Initial Setting Level

Operation Level

1. Press the ⚠️ Key to select . is the default.
2. To return to the initial setting level, press the ☐ Key for at least one second.
3. To return to the operation level, press the ☐ Key for at least one second.

3-8-4 Manual Setup

PID constants can be manually and individually set in the Proportional Band (P), Integral Time (I), and Derivative Time (D) parameters, according to the Display PID Selection parameter set in the PID setting level. Changing the Proportional Band (P), Integral Time (I), or Derivative Time (D) parameter settings in the adjustment level changes the settings in the current PID set. For details on PID sets, refer to PID Sets on page 129.

Operating Procedure

In this example, the PID 2 Proportional Band parameter is set to 10.0, the PID 2 Integral Time parameter to 250, and the PID 2 Derivative Time parameter to 45.

PID Setting Level

1. Press the ☐ Key to move from the operation level to the PID setting level.

1. Use the ▲ and ▼ Keys to set 2.

1. Press the ☐ Key to select the PID 2 Proportional Band parameter.

1. Use the ▲ and ▼ Keys to set 10.0.

1. Press the ☐ Key to select the PID 2 Integral Time parameter.

1. Use the ▲ and ▼ Keys to set 250.0.

1. Press the ☐ Key to select the PID 2 Derivative Time parameter.

1. Use the ▲ and ▼ Keys to set 45.0.

2. To return to the operation level, press the ☐ Key.

Note Proportional Action

When PID constants I (integral time) and D (derivative time) are set to 0, control is executed according to proportional action. As the default, the center value of the proportional band becomes the set point.

Related parameter: Manual reset value (adjustment level)

3-9 Alarm Outputs

• Alarm outputs are determined by a combination of Alarm Type, Alarm Value, and Alarm Hysteresis alarm output conditions. For details, refer to 4-2 Alarm Hysteresis.
• This section describes the Alarm Type, Alarm Value, Upper-limit Alarm and Lower-limit Alarm parameters.

3-9-1 Alarm Types

Set value	Alarm type	Alarm output operation
		When alarm value X is positive	When alarm value X is negative
0	Alarm function OFF	Output OFF
1	Upper- and lower-limit		See note 2.
2 (See note 1.)	Upper-limit		ONOFFSP
3	Lower-limit		ONOFFSP
4 (See note 1.)	Upper- and lower-limit range		See note 3.
5 (See note 1.)	Upper- and lower-limit with standby sequence	See note 5.	See note 4.
6	Upper-limit with standby sequence		ONOFFSP
7	Lower-limit with standby sequence		ONOFFSP
8	Absolute-value upper-limit		ONOFF0
9	Absolute-value lower-limit		ONOFF0
10	Absolute-value upper-limit with standby sequence		ONOFF0
11	Absolute-value lower-limit with standby sequence
12	LBA (alarm 1 type only)	---
13	PV change rate alarm	---
14	Remote SP absolute value upper limit (See note 6.)
15	Remote SP absolute value lower limit (See note 6.)

Note

(1) With set values 1, 4, and 5, the upper- and lower-limit values can be set independently for each alarm type, and are expressed as “L” and “H.”
(2) Set value: 1 (Upper- and lower-limit alarm)

(3) Set value: 4 (Lower limit range)

(4) Set value: 5 (Upper- and lower-limit with standby sequence)

• For the lower-limit alarms in cases 1 and 2 above, the alarm is always OFF if upper- and lower-limit hysteresis overlaps.
• In case 3, the alarm is always OFF.

(5) Set value: 5 (Upper- and lower-limit with standby sequence)

- The alarm is always OFF if upper- and lower-limit hysteresis overlaps.

(6) Displayed when remote SP input is used.

- Set the alarm type independently for each alarm in the Alarm 1 to 3 Type parameters in the initial setting level. The default is 2 (Upper-limit alarm).

3-9-2 Alarm Values

Bank* Alarm Value Lower Limit

(*: 0 to 7)

Alarm Value Upper Limit Value

(*: 0 to 7)

Alarm Value (*: 0 to 7)

• Alarm values are indicated by “X” in the table on the previous page. When the upper and lower limits are set independently, “H” is displayed for upper limit values, and “L” is displayed for lower limit values.
• To set the alarm upper and lower limits for deviation, set the upper and lower limits in the Alarm 1 to 3 Upper Limit and Alarm 1 to 3 Lower Limit parameters.
• Alarm values can be set for each bank. Select the bank number in the Display Bank Selection parameter in the bank setting level, and set the Alarm Value, Alarm Value Upper Limit (1 to 3), and Alarm Value Lower Limit (1 to 3) parameters for that bank.
• When the Alarm Value, Alarm Value Upper Limit, and Alarm Value Lower Limit parameters in the operation level are changed, the changes will be reflected in those parameters for the current bank.

Operating Procedure

This procedure sets alarm 1 for bank number 1 as an upper-limit alarm. The related parameters and settings are shown below. The alarm is output when the set point exceeds 10^ C. (In this example, the temperature unit is ^ C.)

Alarm 1 type = 2 (Upper-limit alarm)

Bank 1 Alarm value 1 = 10

Initial Setting Level

Input Type

Alarm 1 Type

PV/SP

Bank Setting Level

Display Bank Selection

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Select the Alarm 1 Type parameter by pressing the ☐ Key. Confirm that the set value is 2. The default value is 2 (Upper-limit alarm).
3. To return to the operation level, press the ☐ Key for at least one second.
4. Press the ☐ Key to move to the bank setting level.
5. Use the ▲ and ▼ Keys to set 1.

1. Press the ☐ Key to select the Bank 1 Alarm Value 1 parameter.

2. Use the Key to set 10.0.

The change width can be found for PV input values in any set period. Differences with previous values in each set period are calculated, and an alarm is output if the result exceeds the alarm value. The PV rate of change calculation period can be set in units of 60 ms.

If a positive value is set for the alarm value, the PV will operate as a change rate alarm in the rising direction. If a negative value is set, the PV will operate as a change rate alarm in the falling direction.

Precaution

If a shorter PV rate of change calculation period is set, outputs set for the PV change rate alarm function may repeatedly turn ON and OFF for a short period of time. It is therefore recommended that the PV change rate alarm be used with the alarm latch turned ON.

SP Alarms When Remote SP Is Used

RSP Absolute Upper Limit and RSP Absolute Lower Limit parameters were added for the E5AN-H and E5EN-H (with remote SP input). These parameters are used for a remote SP regardless of whether the SP mode is set to Remote SP or Local SP Mode.

3-10 Using Heater Burnout, Heater Short, and Heater Overcurrent Alarms

3-10-1 Heater Burnout, Heater Short, and Heater Overcurrent Alarm Operations

• Heater burnout detection and heater overcurrent detection are executed by measuring heater current while the control output (heating) is ON, and heater short detection is executed by measuring heater current while it is OFF. For details, refer to the following table. (Heater burnout detection, heater short detection, and heater overcurrent detection cannot be used with the control output for cooling.)
  • These settings can be made for standard models only.

Note

(1) In the above diagram, power is considered to be ON (normal) if the heater current is greater than the heater burnout detection current during the Ton interval. If the heater is burned out, the measured current decreases and falls below the heater burnout detection value. The output is then activated as the heater burnout alarm.
(2) In the above diagram, power is considered to be OFF (normal) if the leakage current is less than the HS alarm current during the Toff interval. If the SSR output is short-circuited, the measured current increases beyond the HS alarm value. The output is then activated as the HS alarm.
(3) In the above diagram, it is regarded as normal when the heater current is less than the heater overcurrent detection current during the Ton period. Current is increased when excessive current flows to the heater, causing the heater overcurrent detection value to be exceeded and an OC (heater overcurrent) alarm to be output.
(4) Heater burnout and heater overcurrent are not detected if the control output (heating) ON time (Ton) is 100 ms or less.
(5) HS alarms are not detected if the control output (heating) OFF time (Toff) is 100 ms or less.

• For Controllers with heater burnout, HS, and heater overcurrent alarms, an OR output is established between the ALM 1 function and the alarms. If the ALM1 function is to be used for the heater burnout, HS, and heater overcurrent alarms only, set 0 as the alarm 1 type (i.e., do not use ALM1).
• Turn the heater power ON simultaneously or before turning ON the E5□N-H power. If the heater power is turned ON after turning ON the E5AN-H power, the HB alarm will be activated.
• Control is continued even when the heater burnout, HS, or heater over-current alarm is active.
• The rated current value may sometimes differ slightly from the actual current flowing to the heater.
  Use the Heater Current 1 Value Monitor, Heater Current 2 Value Monitor, Leakage Current 1 Monitor, and Leakage Current 2 Monitor parameters to check the actual current being used.
• If there is little difference between the current in normal and abnormal states, detection may become unstable. To stabilize detection, set a current value difference of at least 1.0 A for heaters of less than 10.0 A, and at least 2.5 A for heaters of 10.0 A or more. If the heater current is too low, loop the load line several times through a CT, as shown in the diagram below. Looping it through once will double the detection current.

3-10-2 Installing Current Transformers (CT)

- This function can be used with E5□N-H models that have the HB alarm, HS alarm, and OC alarm.

For the E5CN-H, connect the CT in advance to terminals 14 and 15 (CT1), or 13 and 15 (CT2). For the E5AN-H/EN-H, connect the CT in advance to terminals 14 and 15 (CT1) or 15 and 16 (CT2). Then pass the heater power line through the CT's hole.

For specifications, models and dimensions of current transformers that can be used with this Controller, see Appendix Current Transformer (CT) on page 300.

Single-phase Heaters

For single-phase heaters, install the CT in the position shown in the following diagram.

graph TD
    A["AC line"] --> B["CT"]
    C["Product"] --> B
    D["To CT input"] --> B
    E["Load"] --> F["Load (such as a heater)"]

Three-phase Heaters (E5□N-H□□HH□ 3-phase Heater Detection Models)

When a 3-phase power supply is used, regardless of the types of connecting lines, two current transformers (CTs) are required to detect heater burnout, HS, and OC.

■ Delta connecting lines: Refer to the following diagram for CT installation positions.

Note Heater voltage fluctuations are not considered here, so be take that into account when setting the detection current.

graph TD
    A["AC line"] --> B["Load"]
    B --> C["Load (such as a heater)"]
    D["AC line"] --> E["Load"]
    E --> F["CT"]
    G["Product To CT input"] --> H["Load"]
    I["Product To CT input"] --> J["Load"]
    style A fill:#f9f,stroke:#333
    style D fill:#f9f,stroke:#333
    style G fill:#f9f,stroke:#333
    style I fill:#f9f,stroke:#333

■ Star connecting lines: Refer to the following diagram for CT installation positions.

Note Heater voltage fluctuations are not considered here, so be take that into account when setting the detection current.

graph TD
    A["AC line"] --> B["CT"]
    C["Product To CT input"] --> B
    B --> D["Load"]
    D --> E["Load (such as a heater)"]
    F["Product To CT input"] --> G["CT"]
    G --> E
    E --> H["Load"]

■ V connecting lines: Refer to the following diagram for CT installation positions.

Note Heater voltage fluctuations are not considered here, so be take that into account when setting the detection current.

graph TD
    A["Product To CT input"] --> B["CT"]
    C["AC line"] --> D["CT"]
    B --> E["Load (such as a heater)"]
    D --> F["Load"]

3-10-3 Calculating Detection Current Values

- Calculate the set value using the following equation:

$$ \text { Heater Burnout Detection 1 / 2 set value } = \frac {\text { Normal current value + Burnout current value }}{2} $$

$$ \text { HS Alarm } 1 / 2 \text { set value } = \frac {\text { Leakage current value(output OFF) } + \text { HS current value }}{2} $$

$$ \text { Heater overcurrent 1 / 2 set value } = \frac {\text { Normal current value + Overcurrent value }}{2} $$

- To set the current for heater burnout when two or more heaters are connected through the CT, use the value from when the heater with the smallest current burns out. If all of the heaters have the same current, use the value from when any one of them burns out.

- Make sure that the following conditions are satisfied:

Heater with a current of less than 10.0 A:

(Current value at normal operation) - (Current value at heater burnout) ≥ 1 A

When the difference is less than 1 A, detection is unstable.

Heater with a current of 10.0 A or more:

(Current value at normal operation) - (Current value at heater burnout) ≥ 2.5A

When the difference is less than 2.5 A, detection is unstable.

• The setting range is 0.1 to 49.9 A. Heater burnout, HS, and heater overcurrent are not detected when the set value is 0.0 or 50.0. When the set value is 0.0, the heater burnout alarm is always OFF, the HS alarm is always ON, and the heater overcurrent alarm is always ON. When the set value is 50.0, the heater burnout alarm is always ON, the HS alarm is always OFF, and the heater overcurrent alarm is always OFF.
• Set the total current value for normal heater operation to 50 A or less. When a current value of 55.0 A is exceeded, FFFF is displayed in the Heater Current 1 (or 2) Value Monitor and Leakage Current 1 (or 2) Monitor parameters.

3-10-4 Application Examples

Single-phase Heaters

Example: Using a 200-VAC, 1-kW Heater

The heater power supply provides 5 A when the current is normal, and 0 A when there is a burnout, so the heater burnout detection current is calculated as follows:

$$ \begin{array}{l} \text { Heater burnout detection current } = \frac {\text {(Normal current)} + \text {(Heater burnout current)}}{2} \ = \frac {5 + 0}{2} = 2. 5 [ \mathrm{A} ] \ \end{array} $$

Example: Using Three 200-VAC, 1-kW Heaters

The heater power supply provides 15 A when the current is normal, and 10 A when there is a burnout, so the heater burnout detection current is calculated as follows:

$$ \begin{array}{l} \text {Heater burnout detection current} = \frac {\text {(Normal current)} + \text {(Heater burnout current)}}{2} \ = \frac {1 5 + 1 0}{2} = 1 2. 5 [ \mathrm{A} ] \end{array} $$

Three-phase Heaters

Delta Connecting Lines

Example: Using Three 200-VAC, 2-kW Heaters

The current when each phase is normal is 17.3 A ( ≈ 3 × 10 A).

Current when there is a burnout = 10 A × √3 × (√3/2) = 15 A

graph TD
    A["10 A"] --> B["Burnout"]
    C["200 V"] --> D["17.3 A"]
    E["200 V"] --> F["10 A"]
    G["CT"] --> H["Load"]
    I["CT"] --> J["Load"]
    K["Product To CT input"] --> L["CT"]
    M["Product To CT input"] --> N["CT"]
    O["Load"] --> P["Burnout"]
    Q["Load"] --> R["Burnout"]

Current when there is a burnout = 10 A × √3 × (1/√3) = 10 A

The heater burnout current when there is a burnout at the load line is as follows:

(Heater burnout detection current) = (17.3 + 15) / 2 ≈ 16.1 [A]

The heater burnout current when there is a burnout at the load is as follows:

(Heater burnout detection current) = (17.3 + 10) / 2 ≈ 13.65 [A]

To enable detection in either case, use 16.1 A as the heater burnout detection current.

Star Connecting Lines

Example: Using Three 200-VAC, 2-kW Heaters

graph TD
    A["Normal"] --> B["200 V"]
    B --> C["Product To CT input"]
    C --> D["CT"]
    D --> E["Load"]
    E --> F["Load (such as a heater)"]
    F --> G["Load"]
    G --> H["CT"]
    H --> I["Product To CT input"]
    I --> J["200 V"]
    J --> K["Product"]
    K --> L["200 V"]
    L --> M["5.8 A→"]
    M --> N["Load"]
    N --> O["Load"]
    O --> P["Load"]
    P --> Q["Load"]
    Q --> R["CT"]

The current when each phase is normal is 5.8 A ( ≈ 10 A × (1 / 3 )).

graph TD
    A["Burnout"] --> B["Load (such as a heater)"]
    B --> C["CT"]
    C --> D["Product To CT input"]
    D --> E["200 V"]
    E --> F["200 V"]
    F --> G["5 A→"]
    G --> H["Load"]
    H --> I["CT"]
    I --> J["Product To CT input"]
    J --> K["5 A→"]
    K --> L["200 V"]
    L --> M["Burnout"]
    style A fill:#f9f,stroke:#333
    style B fill:#ccf,stroke:#333
    style C fill:#cfc,stroke:#333
    style D fill:#fcc,stroke:#333
    style E fill:#ffc,stroke:#333
    style F fill:#cfc,stroke:#333
    style G fill:#fcc,stroke:#333
    style H fill:#cfc,stroke:#333
    style I fill:#fcc,stroke:#333
    style J fill:#cfc,stroke:#333
    style K fill:#fcc,stroke:#333
    style L fill:#cfc,stroke:#333

Current when there is a burnout = 10 A × (1/√3)
× (√3/2) = 5 A

graph TD
    A["200 V Input"] --> B["200 V Output"]
    B --> C["Load (such as a heater)"]
    C --> D["Load"]
    D --> E["CT"]
    E --> F["Product To CT input"]
    F --> G["CT"]
    G --> H["Burnout"]
    H --> I["Load"]
    I --> J["Load"]
    J --> K["CT"]
    K --> L["Product To CT input"]
    L --> M["200 V Output"]
    N["5 A"] --> O["Load"]
    O --> P["Load"]
    P --> Q["CT"]
    Q --> R["Product To CT input"]
    R --> S["CT"]

Current when there is a burnout = 10 A × (1/√3)
× (√3/2) = 5 A

The heater burnout detection current for this connecting line is 5.4 A (= (5.8 + 5) / 2).

V Connecting Lines

Example: Using Two 200-VAC, 2-kW Heaters

Normal

Burnout

Current when there is a burnout = 10 A × (1/2) = 5 A

Current when there is a burnout = 0 A

The heater burnout current when there is a burnout at the common is as follows:

Heater burnout detection current = (10 + 5) / 2 ≈ 7.5 [A]

The heater burnout current when there is a burnout at the load is as follows: Heater burnout detection current = (10 + 0) / 2 ≈ 5 [A]

To enable detection in either case, use 7.5 A as the heater burnout detection current.

3-10-5 Settings: HB Alarm

To activate the heater burnout alarm, set the HB ON/OFF parameter to ON in the advanced function setting level and set the Heater Burnout Detection 1 and Heater Burnout Detection 2 parameters in the adjustment level.

Operating Procedure

This procedure sets the Heater Burnout Detection 1 parameter to 2.5.

■ Moving to the Advanced Function Setting Level

The Heater Burnout Detection parameter setting is already ON by default, so set the Heater Burnout Detection 1 parameter.

Operation Level

Initial Setting Level

Initial Setting Level

Advanced Function Setting Level

1. Move to the advanced function setting level. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select Move to Advanced Function Setting Level by pressing the ☐ Key. (For details on moving between levels, refer to 4-8 Moving to the Advanced Function Setting Level.)

3. Press the ☑ Key to enter the password (-169), and move from the initial setting level to the advanced function setting level.

The top parameter in the advanced function setting level is displayed.

1. Select the Heater Burnout Detection parameter by pressing the ☑ Key. Check that this parameter is set to ON (the default). Next, set the Heater Burnout Detection 1 parameter.

■ Setting Heater Burnout Detection

Operation Level

Adjustment Level

1. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level. Press the ☐ key again for at least one second to move to the operation level.

2. Press the ☐ Key for less than one second to move from the operation level to the adjustment level.

3. Select the Heater Current 1 Value Monitor parameter by pressing the Key. Check the current value. Next, set the Heater Burnout Detection 1 parameter.

4. Select the Heater Burnout Detection 1 parameter by pressing the ☑ Key. Refer to Calculating Detection Current Values on page 73 on when making the settings.

1. For this example, set 2.5. To return to the operation level, press the ☐ Key for less than one second.

3-10-6 Settings: Heater Short Alarm

To activate the HS alarm, set the HS Alarm Use parameter to ON in the advanced function setting level and set the HS Alarm 1 and HS Alarm 2 parameters in the adjustment level.

Operating Procedure

This procedure sets the HS Alarm 1 parameter to 2.5.

■ Moving to the Advanced Function Setting Level

The HS Alarm Use parameter setting is already ON by default, so set the HS Alarm 1 parameter.

Operation Level

Initial Setting Level

Initial Setting Level

Advanced Function Setting Level

1. Move to the advanced function setting level.
   Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Select Move to Advanced Function Setting Level by pressing the ☐ Key. (For details on moving between levels, refer to 4-8 Moving to the Advanced Function Setting Level.)
3. Press the ☑ Key to enter the password (-169), and move from the initial setting level to the advanced function setting level.

The top parameter in the advanced function setting level is displayed.

1. Select the HS Alarm Use parameter by pressing the ☐ Key. Check that this parameter is set to ON (the default). Next, set the HS Alarm 1 parameter.

■ HS Alarm Settings

Operation Level

Adjustment Level

Leakage Current 1 Monitor

1. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level. Press the ☐ key again for at least one second to move to the operation level.
2. Press the ☐ Key for less than one second to move from the operation level to the adjustment level.
3. Select the Leakage Current 1 Monitor parameter by pressing the Key. Check the current value. Next, set the HS Alarm 1 parameter.
4. Select the HS Alarm 1 parameter by pressing the ☑ Key. Refer to Calculating Detection Current Values on page 73 when setting the values.
5. For this example, set 2.5. To return to the operation level, press the ☐ Key for less than one second.

HS Alarm 1

3-10-7 Settings: Heater Overcurrent Alarm

To activate heater overcurrent alarm, set the Heater Overcurrent Use parameter to ON in the advanced function setting level and set the Heater Overcurrent Detection 1 and Heater Overcurrent Detection 2 parameters in the adjustment level.

Operating Procedure

This procedure sets the Heater Overcurrent Detection 1 parameter to 20.0.

■ Moving to the Advanced Function Setting Level

The default setting for the Heater Overcurrent Use parameter is ON, so set the Heater Overcurrent Detection 1 parameter.

Operation Level

Initial Setting Level

Initial Setting Level

1. Move to the advanced function setting level. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Press the ☐ Key to select the Move to Advanced Function Setting Level parameter. (For details on moving between levels, refer to 4-8.)
3. Press the ☑ Key to enter the password (-169), and move from the initial setting level to the advanced function setting level.

Advanced Function Setting Level

Move to the Advanced Function Setting Level

Heater Overcurrent Use

The top parameter in the advanced function setting level is displayed.

1. Press the ☐ Key to select the Heater Overcurrent Use parameter. Check that this parameter is set to ON (the default), and then set the Heater Overcurrent Detection 1 parameter.

■ Setting Heater Overcurrent Detection

Operation Level

PV/SP

Adjustment Level

Adjustment Level Display

Heater Current 1 Value Monitor

Heater Overcurrent Detection 1

1. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level. Press the ☐ key again for at least one second to move to the operation level.

2. Press the ☐ Key for less than one second to move from the operation level to the adjustment level.

3. Press the ☐ Key to select the Heater Current 1 Value Monitor parameter. Check the current value, and then set the Heater Overcurrent Detection parameter.

4. Press the ☐ Key to select the Heater Overcurrent Detection 1 parameter. Refer to Calculating Detection Current Values on page 73 when setting the values.

5. For this example, set 20.0. To return to the operation level, press the ☐ Key for less than one second.

3-11 Setting the No. 3 Display

This section describes how to set the No. 3 Display (E5AN/EN-H). The bank No., MV, or soak time remain can be displayed on the No. 3 display.

3-11-1 PV/SP Display Selection

The following table shows the set values and display contents for the PV/SP Display selection.

Note

(1) The default setting is 4.
(2) For details on setting the MV for heating and cooling control, refer to MV Display for Heating and Cooling Control below. The MV for position-proportional models becomes the value for opening the valve.

When 1, 2, 5, or 6 is selected, press the ☐ Key to display the next value set for the PV/SP display (display 2).

Example: When the PV/SP Display Screen Parameter Is Set to 2

MV Display for Heating and Cooling Control

Select either the manipulated variable (heating) or manipulated variable (cooling) as the MV to be displayed for PV/SP/MV during heating and cooling control. This parameter is displayed only when heating/cooling control is being performed and PV/SP/MV is selected in the PV/SP Display Screen parameter or a Monitor/Setting Item Display parameter. This setting can be made for standard models only.

Operating Procedure

This procedure displays PV/SP/MV and PV/SP/Bank No. on the Process Value/Set Point display. The PV/SP Display Screen Selection parameter is set to 2.

Operation Level

Initial Setting Level

Initial Setting Level

Advanced Function Setting Level

Advanced Function Setting Level

Initial Setting Level

Operation Level

Operation Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Press the ☐ Key to select the Move to Advanced Function Setting Level parameter.

3. Use the ☑ Key to enter the password (“-169”). It is possible to move to the advanced function setting level by either pressing the ☐ Key or waiting two seconds without pressing any key.

4. Press the ☐ Key to select the PV/SP Display Screen Selection parameter.

5. Use the ▲ and ▼ Keys to set 2.

6. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level.

7. Press the ☐ Key for at least one second to move from the initial setting level to the operation level. The MV will be displayed on the No. 3 display.

8. Press the ☐ Key to confirm that the Bank No. is displayed on the No. 3

SECTION 4

Applications Operations

This section describes scaling, the SP ramp function, and other special functions that can be used to make the most of the functionality of the E5CN-H, E5AN-H, and E5EN-H Digital Controllers.

4-1 Shifting Input Values.... 87

4-1-1 Shifting Inputs 87
4-1-2 How to Calculate Input Shift Values for a 2-point Shift.....88

4-2 Alarm Hysteresis.... 90

4-2-1 Standby Sequence.... 90
4-2-2 Alarm Latch 91

4-3 Setting Scaling Upper and Lower Limits for Analog Inputs 92

4-3-1 Analog Input.... 92

4-4 Executing Heating/Cooling Control 93

4-4-1 Heating/Cooling Control 93
4-4-2 Settings 95

4-5 Using Event Inputs 96

4-5-1 Event Input Settings 96
4-5-2 Operation Commands Other than Bank Selection 98

4-6 Setting the SP Upper and Lower Limit Values 100

4-6-1 Set Point Limiter.... 100
4-6-2 Setting.... 101

4-7 Using the SP Ramp Function to Limit the SP Change Rate.... 102

4-7-1 SP Ramp 102

4-8 Moving to the Advanced Function Setting Level 104
4-9 Using the Key Protect Level 106

4-9-1 Protection 106
4-9-2 Entering the Password to Move to the Protect Level ..... 107

4-10 PV Change Color 109

4-10-1 PV Color Change Function.... 109
4-10-2 Setting.... 110

4-11 Alarm Delays 112
4-11-1 Alarm Delays 112
4-12 Loop Burnout Alarm.... 114
4-12-1 Loop Burnout Alarm (LBA).... 114
4-13 Performing Manual Control 119
4-13-1 Manual Operation.... 119
4-14 Using the Transfer Output.... 124
4-14-1 Transfer Output Function 124
4-15 Using Banks and PID Sets 129

4-16 Using the Simple Program Function 132

4-16-1 Simple Program Function 132
4-16-2 Operation at the Program End.... 136
4-16-3 Combining a Simple Program with an SP Ramp 137
4-16-4 Relationships between Simple Programs and Other Functions .... 138

4-17 Output Adjustment Functions 141

4-17-1 Output Limits 141
4-17-2 MV at Stop 142
4-17-3 MV at PV Error.... 143

4-18 Using the Extraction of Square Root Parameter 144
4-19 Setting the Width of MV Variation 146
4-20 Setting the PF Key 148

4-20-1 PF Setting (Function Key).... 148

4-21 Counting Control Output ON/OFF Operations 150
4-21-1 Control Output ON/OFF Count Function 150
4-22 Displaying PV/SV Status.... 152
4-22-1 PV and SV Status Display Functions 152
4-23 Using a Remote SP 155
4-24 Position-proportional Control 157
4-25 Logic Operations 159

4-25-1 The Logic Operation Function (CX-Thermo).... 159

4-25-2 Using Logic Operations 159

4-1 Shifting Input Values

4-1-1 Shifting Inputs

Either a 1-point shift or a 2-point shift can be used to shift the input. The default setting is for a 1-point shift. To execute a 2-point shift, change the Input Shift Type parameter setting (advanced function setting level) to INS2.

There is no shift function for analog inputs. Use scaling for fine adjustments.

One-point shift

Temperature Input Shift

- With a 1-point shift, the value set for the Temperature Input Shift parameter (adjustment level) is applied to each point in the entire temperature input range. For example, if the input shift value is set to 1.2^ , the process value is treated as 201.2^ after the input shift is applied when the measured process value is 200^ .

Operating Procedure

In this example, the input from a K sensor is shifted by 1^ C using a 1-point input shift.

Operation Level

Adjustment Level

Adjustment Level Display

Temperature Input Shift

Operation Level

Operation Level

1. Press the ☐ Key to move from the operation level to the adjustment level.

2. Select the Temperature Input Shift parameter by pressing the ☐ Key.

3. Press the ▲ or ▼ Key to set 1.00.

4. To return to the operation level, press the ☐ Key. The process value is 1^ C larger than before the shift was applied.

Two-point shift

Upper-limit Temperature Input Shift Value

Lower-limit Temperature Input Shift Value

• Separate shift values can be set for the upper limit and lower limit of the sensor input range for an infrared sensor as well as for a thermocouple or platinum resistance thermometer with the Input Shift Type parameter set to INS2. If different shift values are set for the upper limit and lower limit, then the slope of the line will be different before and after applying the input shift. For example, if the upper-limit value is set to 2^ C and the lower-limit value is set to 1^ C, the input temperature will be shifted by 1.5^ C for a 50% input, i.e., by the average of the upper-limit and lower-limit values.
• Set the upper-limit value in the Upper-limit Temperature Input Shift Value parameter and the lower-limit value in the Lower-limit Temperature Input Shift Value parameter.

4-1-2 How to Calculate Input Shift Values for a 2-point Shift

Offset the readout value using a 1-point or 2-point shift as described in this section. This offset occurs because a bias current for detecting a Controller sensor error flows to the output impedance of the infrared temperature sensor.

Method for a 1-point Shift

1,2,3...

1. In the configuration shown in Figure 1, bring the set point to near the value at which the temperature of the control target is to be controlled. Assume that the control target temperature (C) and the thermometer temperature (B) are the same.

2. Check the control target temperature (B) and the Controller readout (A). Subtract the Controller readout temperature (A) from the control target temperature (B), and set CNS as the input shift value to the result. The shift is illustrated in Figure 2.

3. After setting the input shift values, check the Controller readout (A) and the control target temperature (B). If they are approximately the same, this completes setting the input shift.

(A) E5□N-H

Figure 2 Illustration of 1-Point Shift

Method for a 2-point Shift

Use a 2-point input shift if you want to increase the accuracy of the readout values across the range of the Sensor.

1,2,3...

1. Shift the Controller readout at two points, near room temperature and near the value at which the temperature of the control target is to be controlled. For this reason, check the thermometer temperature (B) and Controller readout (A) with the thermometer temperature near room temperature and near the set point.

2.

• Y1 is the Controller readout at room temperature before shifting and X1 is the Controller readout at room temperature after shifting.
• Y2 is the Controller readout at the set temperature before shifting and X2 is the Controller readout at the set temperature after shifting.
• Set the upper-limit temperature input shift and the lower-limit temperature input shift using the following formulas based on the temperatures before shifting (Y1 and Y2), the temperatures after shifting (X1 and X2), the set temperature upper limit (YH), and the set temperature lower limit (YL). The shift is illustrated in Figure 3.

Figure 3 Illustration of 2-Point Shift

a. Lower-limit temperature input shift value

$$ \overline {{L N S L}} = \frac {Y L - Y 1}{Y 2 - Y 1} \times {(X 2 - Y 2) - (X 1 - Y 1) } + (X 1 - Y 1) $$

b. Upper-limit temperature input shift value

$$ \bar {L} N S H = \frac {Y H - Y 1}{Y 2 - Y 1} \times {(X 2 - Y 2) - (X 1 - Y 1) } + (X 1 - Y 1) $$

1. After setting the calculated values to and , check the Digital Controller readout (A) and thermometer temperature (B).
2. Here, offsets are set at two points, near room temperature and near the set point. To improve accuracy within the measurement temperature range, another point in the measurement temperature range other than the set point should be set instead of room temperature.

Example of a 2-point Temperature Input Shift

In this example, a K thermocouple from -200.0 to 1,300.0°C is used. In equations 1 and 2, the set temperature lower limit YL is -200°C and the set temperature upper limit YH is 1,300°C. Check the temperature of the control target.

The temperature input offset values can be calculated as shown below when the Digital Controller readout Y1 is 35^ C for a room temperature X1 of 25^ C and when the Digital Controller readout Y2 is 105^ C for a set point temperature X2 of 110^ C.

Lower-limit Temperature Input Shift Value

$$ \bar {L} N S L = \frac {- 2 0 0 - 3 5}{1 0 5 - 3 5} \times {(1 1 0 - 1 0 5) - (2 5 - 3 5) } + (2 5 - 3 5) = - 6 0. 3 5 (\mathrm{C}) $$

Upper-limit Temperature Input Shift Value

$$ \bar {L} N S H = \frac {1 3 0 0 - 3 5}{1 0 5 - 3 5} \times {(1 1 0 - 1 0 5) - (2 5 - 3 5) } + (2 5 - 3 5) = 2 6 1. 0 7 (\mathrm{C}) $$

4-2 Alarm Hysteresis

- The hysteresis of alarm outputs when alarms are switched ON/OFF can be set as follows:

• Alarm hysteresis is set independently for each alarm in the Alarm Hysteresis 1 to Alarm Hysteresis 3 parameters (initial setting level).
• The default is 0.2 (°C/°F) when a temperature input is selected, and 0.02% FS when an analog input is selected.

4-2-1 Standby Sequence

- The standby sequence can be used so that an alarm will not be output until the process value leaves the alarm range once and then enters it again.

Restart

- For example, with a lower limit alarm, the process value will normally be below the set point, i.e., within the alarm range, when the power supply is turned ON, causing an alarm to be output.

If the lower limit alarm with a standby sequence is selected, an alarm will not be output until the process value increases above the alarm set value, i.e., until it leaves the alarm range, and then falls back below the alarm set value.

- The standby sequence is canceled when an alarm is output. It is, however, restarted later by the Standby Sequence Reset parameter (advanced function setting level). For details, refer to the Standby Sequence Reset parameter in SECTION 5 Parameters.

4-2-2 Alarm Latch

- The alarm latch can be used to keep the alarm output ON until the latch is canceled regardless of the temperature once the alarm output has turned ON.

Any of the following methods can be used to clear the alarm latch.

• Turn OFF the power supply. (The alarm latch is also cleared by switching to the initial setting level, communications setting level, advanced function setting level, or calibration level.)
• Use the PF Key.
• Use an event input.

For details on setting the PF Key, refer to 4-20 Setting the PF Key. For details on setting events, refer to 4-5 Using Event Inputs.

Summary of Alarm Operation

The following figure summarizes the operation of alarms when the Alarm Type parameter is set to “lower-limit alarm with standby sequence” and “close in alarm” is set.

Parameters

Note * = 1 to 3

4-3 Setting Scaling Upper and Lower Limits for Analog Inputs

4-3-1 Analog Input

Scaling Upper Limit

Scaling Lower Limit

Decimal Point

• When an analog input is selected, scaling can be performed as needed by the control application.
• Scaling is set in the Scaling Upper Limit, Scaling Lower Limit, and Decimal Point parameters (initial setting level). These parameters cannot be used when a temperature input is selected.
• The Scaling Upper Limit parameter sets the physical quantity to be expressed by the upper limit value of input, and the Scaling Lower Limit parameter sets the physical quantity to be expressed by the lower-limit value of input. The Decimal Point parameter specifies the number of digits below the decimal point.
• The following figure shows a scaling example for a 4 to 20-mV analog input. After scaling, the temperature can be directly read. The decimal point is set to 1.

Operating Procedure

Initial Setting Level

Input Type

Scaling Upper Limit

In this example scaling is set to display 4 to 20 mA as 10.0% to 95.0%.

1. Press the ☐ Key for three seconds to move from the operation level to the initial setting level.
2. Press the ▲ and ▼ Keys to set 25.
3. Select Scaling Upper Limit parameter by pressing the ☐ Key.
4. Use the ▲ and ▼ Keys to set the parameter to 950.
5. Select the Scaling Lower Limit parameter by pressing the Key.
6. Press the ▲ and ▼ Keys to set 100.

Decimal Point

1. Select the Decimal Point parameter by pressing the Key.

1. Press the ⏠ and ⏰ Keys to set 1.

2. To return to the operation level, press the ☐ Key for one second.

4-4 Executing Heating/Cooling Control

4-4-1 Heating/Cooling Control

Heating/cooling control operates when H- (heating/cooling) is selected for the Standard or Heating/Cooling parameter for standard models. The following functions are assigned to outputs by default.

Each output assignment is automatically initialized as shown below when the control mode is changed.

Example: E5CN-H

Note

(1) No parameter assignment is displayed because there is no control output 2.
(2) The output set for the Auxiliary Output 1 Assignment parameter becomes the program END output unless the program pattern is OFF.

- The heating/cooling operation of the control outputs will switch when the Direct/Reverse Operation parameter is set to “direct.”

- When DRS (Invert Direct/Reverse Operation) is assigned for an Event Input Assignment (1 to 4), control will start with the contents set for the Direct/Reverse Operation parameter inverted when the event input turns ON, and with the contents left according to the setting when the event input turns OFF. For details on event inputs and control combined with the Direct/Reverse Operation parameter, refer to Control by Inverting Direct/Reverse Operation on page 99.

Dead Band

• When heating/cooling control is selected, the Dead Band and Cooling Coefficient parameters can be used.
• For heating/cooling control, the dead band is set with the set point as its center. The dead band width is the set value of the Dead Band parameter (adjustment level). Setting a negative value produces an overlapping band.
• If an overlapping band is set, the bumpless function may not operate when switching between manual operation and automatic operation.
• The default is 0.0 EU for a temperature input and 0.00% FS for an analog input.

Cooling Coefficient

If the heating characteristics and cooling characteristics of the control object are very different and good control characteristics cannot be achieved with the same PID constants, the cooling coefficient can be used to adjust the proportional band (P) for the control output assigned to the cooling side. Use this to achieve balanced control between the heating side and cooling side. The proportional bands (P) for the control outputs assigned to the heating/cooling sides can be calculated using the following equations.

P for control output assigned to heating side = P

P for control output assigned to cooling side = P for control output assigned to heating side × cooling coefficient

The cooling coefficient is multiplied by the P for the control output assigned to the heating side to obtain control with characteristics that differ from those of the control output assigned to the heating side.

A cooling coefficient can be set for each PID set. To set the cooling coefficient, select the PID set number in the Display PID Selection parameter (PID setting level) and then set the Cooling Coefficient parameter. If the Cooling Coefficient parameter setting is changed in the adjustment level, the change will be reflected in the Cooling Coefficient parameter for the current PID set.

P for control output assigned to heating side × 0.8

P for control output assigned to heating side × 1.5

Automatic Cooling Coefficient Adjustment

By executing AT during heating/cooling control, the cooling coefficient can be automatically calculated along with the PID parameters.

Note

If there is strong non-linear gain for the cooling characteristics, such as when cooling water boils for cooling control, it may not be possible to obtain the optimum cooling coefficient at the Controller, and control may take the form of oscillating waves. If that occurs, increase the proportional band or the cooling coefficient to improve control.

4-4-2 Settings

To set heating/cooling control, set the Standard or Heating/Cooling, Dead Band, and Cooling Coefficient parameters.

Setting Heating/Cooling Control

Operating Procedure

Initial Setting Level

Standard or Heating/ Cooling

Standard or heating/cooling = Heating/cooling

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select "heating/cooling control" in the initial setting level.

SEND: Standard control

H-C: Heating/cooling control

Setting the Cooling Coefficient

Operating Procedure

PID Setting Level

Display PID selection

PID1 Cooling Coefficient

PID 1 Cooling Coefficient = 10

1. Press the ☐ Key to move from the operation level to the PID setting level. The current PID set number will be displayed. Use the ⚠ or ⏱ Key to select 1.
2. Select the PID1 Cooling Coefficient parameter by pressing the ☐ Key.
3. Press the ▲ and ▼ Keys to set 10.00.

Setting the Dead Band

Operating Procedure

Adjustment Level

Dead Band

Dead Band = 5

1. Select the Dead Band parameter in the adjustment level.
2. Use the ⬆ Key to set the parameter to 5.0.

4-5 Using Event Inputs

4-5-1 Event Input Settings

• Depending on the Controller, there are either two event inputs (event inputs 1 and 2 or 3 and 4) or four event inputs (event inputs 1 to 4). The number of event inputs that can be used varies. (Only the E5AN/EN-H has event inputs 3 and 4.)
• Event inputs can be used for Bank Selection, RUN/STOP, Auto/Manual Switch, Program Start, Direct/Reverse Operation, SP Mode Switch (E5AN/EN-H only), 100% AT Execute/Cancel, 40% AT Execute/Cancel, Setting Change Enable/Disable, Communications Write Enable/Disable, and Alarm Latch Cancel.
• Of these, only the number of event inputs (0 to 3) set in the Bank Numbers Used parameter (initial setting level) are used for the bank selection function.
• Event inputs (1 to 4) that are not used for the bank selection function are assigned using the Event Input Assignment (1 to 4) parameters (initial setting level).
• Event inputs can be used on the following models:
  Two Event Inputs;
  E5CN-H□M□-500 with the E53-CN□B□N2 for the E5CN-H
  E5AN/EN-H□B□M□-500 for the E5AN/EN-H
  Four Event Inputs;
  E5AN/EN-H□B□M□-500 with the E53-AKB for the E5AN/EN-H
• When using event inputs for bank selection, the event input assignment screen will not be displayed. Whether the set value and event input assignments 1 to 4 will be displayed or hidden is shown in the tables below.
• Do not connect the contacts from the same switch for more than one E5□N Controllers.

Controllers with Event Inputs 1 and 2 (Two Event Inputs)

Controllers with Event Inputs 3 and 4 (Two Event Inputs)

Controllers with Event Inputs 1 to 4 (Four Event Inputs)

The following table shows the relation between ON/OFF combinations of event inputs and the banks that are selected.

Note

(1) For models with event inputs 3 and 4, this becomes event input 3.
(2) For models with event inputs 3 and 4, this becomes event input 4.

To set two banks are externally, make the setting in the Bank Numbers Used parameter.

- Switching is possible between two banks (0 and 1) by setting the Bank Numbers Used parameter to 1. The default setting is 1 and does not need to be changed. Banks 0 and 1 are specified by the status of event input 1 or 3.

Two Event Inputs: E53-CN□B□N2 (for E5CN-H)

graph TD
    A["E5AN/EN-H"] --> B["11"]
    A --> C["12"]
    A --> D["13"]
    B --> E["EV1"]
    C --> F["EV2"]
    D --> G["+"]
    D --> H["-"]
    E --> I["EV1"]
    F --> J["EV2"]

Two Event Inputs: E5AN/EN-H□B□M□-500 (for E5AN/EN-H)

Two Additional Event Inputs: E53-AKB in E5AN/EN-H□B□M□-500 (for E5AN/EN-H)

4-5-2 Operation Commands Other than Bank Selection

The following table shows the functions assigned when an Event Input Assignment (1 to 4) is displayed.

Note

(1) PRST (Program Start) can be set even when the Program Pattern parameter is set to OFF, but the function will be disabled.
(2) This function can be selected only with models that support remote SP.
(3) This function can be set for heating/cooling control, but the function will be disabled.
(4) This function can be selected only with models that support communications. Also, when a work bit is selected as event input data, Communications Write Enable/Disable parameter cannot be selected.

When any of the following functions is set for an Event Input Assignment parameter, the same function cannot be set for another Event Input Assignment parameter: STOP (RUN/STOP), MANU (Auto/Manual Switch), PRST (Program Start), DRS (Direct/Reverse Operation), RSP (SP Mode Switch), AT-2 (100% AT Execute/Cancel), AT-1 (40% AT Execute/Cancel), WTPT (Setting Change Enable/Disable), CMWT (Communications Write Enable/Disable), or LAT (Alarm Latch Cancel).

Turn event inputs ON and OFF while the power is being supplied. Event input ON/OFF changes are detected for inputs of 50 ms or longer. (However, inputs of 250 ms or longer is determined using logic operation.)

The functions are described in detail below. Event inputs 1 and 2 are taken as examples. When using event inputs 3 and 4, substitute event input 3 for event input 1 and event input 4 for event input 2.

Executing Run/Stop Control

When the Event Input Assignment 1 or Event Input Assignment 2 parameter is set to STOP (RUN/STOP), control is started when event input 1 or 2 turns OFF. Control is stopped when the input turns ON. Alarm outputs, however, will be according to the process value.

The STOP indicator will light while control is stopped.

Switching between Auto and Manual Control

When the Event Input Assignment 1 or Event Input Assignment 2 parameter is set to MANU (auto/manual), manual control will start when event input 1 or 2 turns ON. Auto control will start when the input turns OFF.

Controlling the Start of the Simple Program Function

Control by Inverting Direct/Reverse Operation

Switching SP Mode

Switching 100% AT Execute/Cancel

Switching 40% AT Execute/Cancel

The MANU indicator will light during manual control.

When the Event Input Assignment 1 or Event Input Assignment 2 parameter is set to PRST (program start), the program will start when event input 1 or 2 turns ON. The program will be reset when the input turns OFF and the RUN/STOP status will automatically switch to STOP mode. If the program END output is ON, the program END output will turn OFF.

When DRS (Invert Direct/Reverse Operation) is set for the Event Input Assignment 1 or Event Input Assignment 2 parameter and the Direct/Reverse Operation parameter is set for reverse operation, control starts with direct operation (cooling control) when event input 1 or 2 turns ON and control starts with reverse operation (heating control) when the event input turns OFF.

When RSP (SP Mode Switch) is set for either the Event Input Assignment 1 or Event Input Assignment 2 parameter, operation will be started with remote SP when event input 1 or 2 turns ON. Operation will start with local SP when the input turns OFF. The RSP operation indicator will light while in remote SP mode.

When AT-2 (100% AT Execute/Cancel) is set for either the Event Input Assignment 1 or Event Input Assignment 2 parameter, 100% AT will be executed when event input 1 or 2 turns ON and will be cancelled when the input turns OFF.

When AT-1 (40% AT Execute/Cancel) is set for either the Event Input Assignment 1 or Event Input Assignment 2 parameter, 40% AT will be executed when event input 1 or 2 turns ON and will be cancelled when the input turns OFF.

Switching Setting Change Enable/Disable

When WTPT (Setting Change Enable/Disable) is set for either the Event Input Assignment 1 or Event Input Assignment 2 parameter, the setting change will be disabled when event input 1 or 2 turns ON and will be enabled when the input turns OFF.

Switching Communications Write Enable/Disable

Only event inputs 3 and 4 can be set to Communications Write Enable/Disable.

When CMWT (Communications Write Enable/Disable) is set for either the Event Input Assignment 3 or Event Input Assignment 4 parameter, communications writing will be enabled when event input 3 or 4 turns ON and will be disabled when the input turns OFF.

Switching Alarm Latch Cancel

When LAT (Alarm Latch Cancel) is set for either the Event Input Assignment 1 or Event Input Assignment 2 parameter, all alarm latches (alarms 1 to 3, heater burnout, HS alarm, and heater overcurrent latch) will be cancelled when event input 1 or 2 turns ON.

Parameters

4-6 Setting the SP Upper and Lower Limit Values

4-6-1 Set Point Limiter

The setting range of the set point is limited by the set point limiter. The set point limiter is used to prevent the control target from reaching abnormal temperatures. The upper- and lower-limit values of the set point limiter are set using the Set Point Upper Limit and Set Point Lower Limit parameters in the initial setting level. When the set point limiter is reset, the set point is forcibly changed to the upper- or lower-limit value of the set point limiter if the set point is out of the limiter range. Also, when the input type and the temperature unit, scaling upper-limit value, or lower-limit value are changed, the set point limiter is forcibly reset to the input setting range or the scaling upper- or lower-limit value.

graph TD
    A["Input setting range"] --> B["Set point limiter"]
    B --> C["Setting range"]
    C --> D["Upper limit value changed"]
    D --> E["Input type changed"]
    E --> F["Set point"]
    F --> G["Set point"]
    G --> H["Set point"]
    H --> I["Sensor upper/lower limit values"]
    I --> J["Upper limit value changed"]
    J --> K["Set point"]
    K --> L["Set point"]
    L --> M["Sensor upper/lower limit values"]
    M --> N["Upper limit value changed"]
    N --> O["Set point"]
    O --> P["Sensor upper/lower limit values"]
    P --> Q["Upper limit value changed"]
    Q --> R["Set point"]
    R --> S["Sensor upper/lower limit values"]
    S --> T["Upper limit value changed"]
    T --> U["Set point"]
    U --> V["Sensor upper/lower limit values"]
    V --> W["Upper limit value changed"]
    W --> X["Set point"]
    X --> Y["Sensor upper/lower limit values"]
    Y --> Z["Upper limit value changed"]
    Z --> AA["Set point"]
    AA --> AB["Sensor upper/lower limit values"]
    AB --> AC["Upper limit value changed"]
    AC --> AD["Set point"]
    AD --> AE["Sensor upper/lower limit values"]
    AE --> AF["Upper limit value changed"]
    AF --> AG["Set point"]
    AG --> AH["Sensor upper/lower limit values"]
    AH --> AI["Upper limit value changed"]
    AI --> AJ["Set point"]
    AJ --> AK["Sensor upper/lower limit values"]
    AK --> AL["Upper limit value changed"]
    AL --> AM["Set point"]
    AM --> AN["Sensor upper/lower limit values"]
    AN --> AO["Upper limit value changed"]
    AO --> AP["Set point"]
    AP --> AQ["Sensor upper/lower limit values"]
    AQ --> AR["Upper limit value changed"]
    AR --> AS["Set point"]
    AS --> AT["Sensor upper/lower limit values"]
    AT --> AU["Upper limit value changed"]
    AU --> AV["Set point"]
    AV --> AW["Sensor upper/lower limit values"]
    AW --> AX["Upper limit value changed"]
    AX --> AY["Set point"]
    AY --> AZ["Sensor upper/lower limit values"]
    AZ --> BA["Upper limit value changed"]
    BA --> BB["Set point"]
    BB --> BC["Sensor upper/lower limit values"]
    BC --> BD["Upper limit value changed"]
    BD --> BE["Set point"]
    BE --> BF["Sensor upper/lower limit values"]
    BF --> BG["Upper limit value changed"]
    BG --> BH["Set point"]
    BH --> BI["Sensor upper/lower limit values"]
    BI --> BJ["Upper limit value changed"]
    BJ --> BK["Set point"]
    BK --> BL["Sensor upper/lower limit values"]
    BL --> BM["Upper limit value changed"]
    BM --> BN["Set point"]
    BN --> BO["Sensor upper/lower limit values"]
    BO --> BP["Upper limit value changed"]
    BP --> BQ["Set point"]
    BQ --> BR["Sensor upper/lower limit values"]
    BR --> BS["Upper limit value changed"]
    BS --> BT["Set point"]
    BT --> BU["Sensor upper/lower limit values"]
    BU --> BV["Upper limit value changed"]
    BV --> BW["Set point"]

Parameters

4-6-2 Setting

Set the set point upper and lower limits in the Set Point Upper Limit and Set Point Lower Limit parameters in the initial setting level. In this example, it is assumed that the input type is set to a K thermocouple with a temperature range of -200.0 to 1300.0°C.

graph TD
    A["Input setting range"] --> B["Set point limiter"]
    B --> C["-100.0"]
    B --> D["1000.0"]
    C --> E["-200.0"]
    D --> F["1300.0"]

Setting the Set Point Upper-limit Value

Operating Procedure

Input Type

Set Point Upper-limit

Set Point Upper Limit = 1000

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Select the Set Point Upper Limit parameter.
3. Use the ▲ and ▼ Keys to set the parameter to 1000.0.

Setting the Set Point Lower-limit Value

Operating Procedure

Set Point Lower Limit = -100

1. Select the Set Point Lower Limit parameter in the initial setting level.
2. Use the ⏠ and ⏰ Keys to set the parameter to -100.0.

4-7 Using the SP Ramp Function to Limit the SP Change Rate

4-7-1 SP Ramp

The SP ramp function is used to restrict the width of changes in the set point as a rate of change. When the SP ramp function is enabled and the change width exceeds the specified rate of change, an area where the set point is restricted will be created, as shown in the following diagram.

During the SP ramp, control will be performed not for the specified set point but rather for the set point restricted by the rate of change set for the SP ramp function.

The rate of change during SP ramp is specified using the SP Ramp Set Value and SP Ramp Time Unit parameters. The SP Ramp Set Value parameter is set to OFF by default, i.e., the SP ramp function is disabled.

The SP Ramp Set Value parameter can be set for each bank. Select the bank number in the Display Bank Selection parameter (bank setting level), and then set the SP Ramp Set Value parameter. Also, the ramp set point for the current bank can be monitored in the Set Point During SP Ramp parameter (operation level). Use this parameter when monitoring SP ramp operation.

If the SP Ramp Set Value parameter setting is changed in the adjustment level, the change will be reflected in the SP Ramp Set Value parameter for the current bank.

The SP ramp function is enabled even when switching from local SP to remote SP, and the SP ramp will operate.

Parameters

Operation at Startup

If the SP ramp function is enabled when the Controller is turned ON or when switching from STOP to RUN mode, the process value reaches the set point using the SP ramp function in the same way as when the set point is changed. In this case, operation is carried out with the process value treated as the set point before the change was made. The direction of the SP ramp changes according to the relationship between the process value and the set point.

Restrictions during SP Ramp Operation

• Execution of auto-tuning starts after the end of the SP ramp.
• When control is stopped or an error occurs, the SP ramp function is disabled.

Alarms during SP Ramp Operation

The operation of alarms during SP ramp operation depends on whether alarms are set to be based on the ramp set point or the target set point (refer to the following diagrams). The set point to be used is set in the Alarm SP Selection parameter.

Alarm SP Selection = Ramp SP (Alarm Type: 1 (Upper/Lower Limits))

Alarm SP Selection = Target SP (Alarm Type: 1 (Upper/Lower Limits))

4-8 Moving to the Advanced Function Setting Level

Use the following procedure to move to the advanced function setting level.

1,2,3...

1. Press the ☐ and ☑ Keys simultaneously for at least three seconds in operation level.

Note The key pressing time can be changed in the Move to Protect Level Time parameter (advanced function setting level).

Protect Level

Operation/Adjustment Protect

1. The Controller moves to the protect level, and the Operation/Adjustment Protect parameter is displayed.

Initial Setting/Communications Protect

1. Press the ☑ Key once to move to the Initial Setting/Communications Protect parameter.

1. Set the set value to 0. The default setting is 0 (possible to reach).

Operation Level

Initial Setting Level

Initial Setting Level

Advanced function setting level

Initial Setting Level

Operation Level

1. Press the ☐ and ☑ Keys simultaneously for at least one second to return to the operation level.

2. Move to the advanced function setting level.

Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

1. Select the Move to Advanced Function Setting Level parameter by pressing the ☐ Key.

2. Press the Key, enter the password (-169), and then either press the Key or leave the setting for at least two seconds to move to the advanced function setting level from the initial setting level.

3. To return to the initial setting level, press the ☐ Key for at least one second.

4. To return to the operation level, press the ☐ Key for at least one second.

4-9 Using the Key Protect Level

4-9-1 Protection

- To move to the protect level, press the and Keys simultaneously for at least three seconds in operation level or adjustment level. (See note.)

Note The key pressing time can be changed in the Move to Protect Level Time parameter (advanced function setting level).

- The protect level protects parameters that are not changed during Controller operation until operation is started to prevent them from being modified unintentionally.

There are four types of protection: operation/adjustment protect, initial setting/communications protect, setting change protect, and PF Key protect.

- The protect level settings restrict the range of parameters that can be used.

Operation/Adjustment Protect

The following table shows the relationship between set values and the range of protection.

• Parameters are not protected when the set value is set to 0.
• The default is 0.

Initial Setting/ Communications Protect

This protect level restricts movement to the initial setting level, communications setting level, and advanced function setting level.

- The default is 0.

Setting Change Protect

This protect level restricts key operations.

• The default is OFF.
• The all protect indication (On) will light when setting change protect is set.

PF Key Protect

This protect level enables or disables PF Key operations.

- The default is OFF.

4-9-2 Entering the Password to Move to the Protect Level

- Protect level can be moved to only by display the password display and entering the correct password. (The user can set any password in the Protect Level Password parameter. If no password is set (i.e., if the password is set to 0 in the Protect Level Password parameter), the password input display to move to protect level will not be displayed and the protect level can be moved to directly.

Operating Procedure

Use the following procedure to move to protect level.

■ Example with a Password of 1234

Operation Level

Protect Level

Protect Level

1. Press the ☐ and ☑ Keys simultaneously for at least the time set in the Move to Protect Level Time parameter to move from the operation level to the protect level.
2. Press the ☑ Key to set the parameter to 1234 (password input).
3. Move to the Operation/Adjustment Protect parameter by pressing the ☐ or ☑ Key or leaving the setting for at least two seconds.

■ Example with No Password Set

Operation Level

Protect Level

Press the ☐ and ☑ Keys simultaneously for at least the time set in the Operation/Adjustment Protect parameter to move from the operation level to the protect level.

When a password is not set, the Operation/Adjustment Protect parameter will be displayed.

Setting the Password

Operating Procedure

Use the following procedure to set the password to move to the protect level.

■ Example To set the Password to 1234

Operation Level

Protect Level

Protect Level

1. Press the ☐ and ☑ Keys simultaneously for at least the time set in the Move to Protect Level Time parameter to move from the operation level to the protect level.
2. Select the Password to Move to Protect Level parameter by pressing the Key.
3. Press the ☐ and ⚠ Keys to set the parameter to 1234. (To prevent setting the password incorrectly, the ⚠ and ☐ Keys or ⚡ and ☐ Keys must be pressed simultaneously to set the password.)

Note Protection cannot be cleared or changed without the password. Be careful not to forget it. If you forget the password, contact your OMRON sales representative.

Communications Operation Command to Move to the Protect Level

Note

- The Write Variable operation command can be used via communications to write the password to the Move to Protect Level parameter. When the correct password is written, the display will change to the Operation/Adjustment Protect parameter and writing the parameters in the protect level will be enabled.

(1) If the Write Variable operation command is used to write the wrong password to the Move to Protect Level parameter after the correct parameter has been written, the Move to Protect Level parameter will be displayed and any Write Variable operation commands to write parameters in the protect level will result in operation errors.
(2) If a password is not set or if it is set to 0, the display will change to the Operation/Adjustment Protect parameter and writing the parameters in the protect level will be enabled immediately.

4-10 PV Change Color

4-10-1 PV Color Change Function

PV Change Color

Use the PV color change function to change the color of the PV display (No. 1 display).

There are three display colors, orange, red, and green, and you can select from the following three modes and eight functions.

• Constant: This mode displays orange, red, or green all the time.
• Linked to Alarm 1: This mode switches the PV display color from red to green when alarm 1 turns ON or from green to red when alarm 1 turns ON.
• Linked to PV stable band: This mode switches the PV display color between red outside the PV stable band and green within PV stable band, or between green outside the PV stable band and red within PV stable band.

Set the PV stable band in the PV Stable Band parameter (advanced function setting level).

- The default is REd (red).

The following tables shows the display functions that can be set using the PV color change function.

Mode	Setting	Function	PV change color			Application example
Constant		Orange	Constant: Orange			To match the display color with other Controller models
	RED	Red	Constant: Red			To match the display color with other Controller models
	GRN	Green	Constant: Green			To match the display color with other Controller models
Linked to alarm 1
			ALM1 not lit		ALM1 lit	Application example
	R-G	Red to Green	Red		Green	To display the PV reached signal
	G-R	Green to Red	Green		Red	To display error signals
Linked to PV stable band
			Low	Within PV stable band	High	Application example
	R-G,R	Red to Green to Red	Red	Green	Red	To display stable status
	G-G,R	Green to Orange to Red	Green	Orange	Red	To display stable status
	G-G,R	Orange to Green to Red	Orange	Green	Red	To display stable status

PV Stable Band

PV Stable Band

When the mode to link to the PV stable band is selected, the PV display color will change according to whether the present value (PV) is lower than, within, or higher than the PV stable band shown in the following figure. The PV stable band is set with the SP as the center, as shown below.

The default is 5.0 (°C/°F) for a temperature input and 5.0% FS for an analog input.

4-10-2 Setting

Setting the PV Change Color to Indicate Stable Status

To display the PV in a stable green display when the PV is within ±15.0^ of the set point to enable checking the control process at a glance, set the PV Change Color and PV Stable Band parameters.

PV change color = R - G R (Red to Green to Red)

PV stable band = 15.0°C

Operating Procedure

Release the protection before setting the PV Change Color and PV Stable Band parameters to enable moving to advanced function setting level. (Refer to steps 1 to 8 on page 104.)

PV Change Color: -, (Red to Green to Red)

PV Stable Band: 15.0 (°C)

Operation Level

Initial Setting Level

Initial Setting Level

Advanced Function Setting Level

Advanced Function Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select the Move to Advanced Function Setting Level parameter by pressing the ☐ Key.

3. Use the ☑ Key to enter “-169” (the password).

Move to the advanced function setting level by pressing the ☐ Key or leaving the setting for at least two seconds.

1. Select the PV Change Color parameter by pressing the ☐ Key.

Advanced Function Setting Level

Operation Level

1. Press the ⚠️ Key to set the parameter to R-GR.
2. Select the PV Stable Band parameter by pressing the ☐ Key.
3. Use the ⬆ Key to set the parameter to 15.0.
4. To return to the initial setting level, press the ☐ Key for at least one second.
5. To return to the operation level, press the ☐ Key for at least one second.

4-11 Alarm Delays

4-11-1 Alarm Delays

- Delays can be set for the alarm outputs. ON and OFF delays can be set separately for alarms 1, 2, and 3. The ON and OFF delays for alarm 1 function only for the alarm function. If the alarm 1 function is set to be output as an OR with other alarms (i.e., the heater burnout alarm, HS alarm, heater overcurrent alarm, or input error output alarm), delays cannot be set for the other alarms. The ON and OFF delays for alarms 1, 2, and 3 also apply to the individual SUB1, SUB2, and SUB3 indicators and to communications status. The alarm ON delays will also function when power is turned ON or when moving from the initial setting level to operation level (e.g., to software resets). All outputs will turn OFF and the OFF delays will not function when moving to the initial setting level or when an alarm is output for a A/D converter error.

Operation of Alarm ON and OFF Delays (for an Upper-limit Alarm)

graph TD
    A["Alarm setting"] --> B["ON delay set time"]
    B --> C["OFF delay set time"]
    C --> D["Alarm Latch = OFF"]
    D --> E["Alarm will not turn ON."]
    style A fill:#f9f,stroke:#333
    style B fill:#ccf,stroke:#333
    style C fill:#cfc,stroke:#333
    style D fill:#fcc,stroke:#333
    style E fill:#ffc,stroke:#333

• The alarm will not turn ON if the time that the alarm is ON is equal to or less than the ON delay set time. Also, the alarm will not turn OFF if the time that the alarm is OFF is equal to or less than the OFF delay set time.
• If an alarm turns OFF and then back ON during the ON delay time, the time will be remeasured from the last time the alarm turns ON. Also, if an alarm turns ON and then back OFF during the OFF delay time, the time will be remeasured from the last time the alarm turns OFF.

Parameters Related to Alarm Delays

Note

(1) The defaults are 0, i.e., the ON and OFF delays are disabled.
(2) The parameters are displayed when alarm functions are assigned and when the alarm type is set to any type but 0 (none), 12: LBA, or 13: PV change rate alarm.

Operating Procedure

Use the following procedure to set ON and OFF delays for the alarm 1.

An ON delay of 5 seconds and an OFF delay of 10 s will be set.

Operation Level

Initial Setting Level

Initial Setting Level

Advanced Function Setting Level

Advanced Function Setting Level

Advanced Function Setting Level

Initial Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Select the Move to Advanced Function Setting Level parameter by pressing the ☑ Key. (For details on moving between levels, refer to 4-8 Moving to the Advanced Function Setting Level.)
3. Press the ☑ Key to enter the password (-169) and move from the initial setting level to the advanced function setting level.
4. Press the ☐ Key to select the Alarm 1 ON Delay parameter.
5. Press the ⬆ Key to set the parameter to 5.
6. Press the ☐ Key to select the Alarm 1 OFF Delay parameter.
7. Press the ⬆ Key to set the parameter to 10.
8. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level.

Operation Level

1. Press the ☐ Key for at least one second to move from the initial setting level to the operation level.

4-12 Loop Burnout Alarm

4-12-1 Loop Burnout Alarm (LBA)

• The loop burnout alarm can be used only with standard models.
• With a loop burnout alarm, there is assumed to be an error in the control loop if the control deviation (SP – PV) is greater than the threshold set in the LBA Level parameter and if the control deviation is not reduced by at least the value set in the LBA Detection Band parameter within the LBA detection time.
• Loop burnout alarms are detected at the following times.

If the control deviation is reduced in the area between 1 and 2 (i.e., the set point is approached) and the amount the control deviation is reduced is at least equal to the LBA band, the loop burnout alarm will remain OFF.

The process value is within the LBA level between 3 and 4, and thus loop burnout alarms will not be detected. (The loop burnout alarm will remain OFF.)

If the process value is outside the LBA level between 4 and 5 and the control deviation is not reduced by at least the LBA band within the LBA detection time, the loop burnout alarm will turn ON.

If the control deviation is reduced in the area between 5 and 6 (i.e., the set point is approached) and the amount the control deviation is reduced is at least equal to the LBA band, the loop burnout alarm will turn OFF.

If the control deviation is reduced in the area between 6 and 7 (i.e., the set point is approached) and the amount the control deviation is reduced is less than the LBA band, the loop burnout alarm will turn ON.

• If the LBA detection time, LBA level, LBA detection band, and PID settings are not appropriate, alarms may be detected inappropriately or alarms may not be output when necessary.

• Loop burnout alarms may be detected if unexpectedly large disturbances occur continuously and a large deviation does not decrease.

• If a loop burnout occurs when the set point is near the ambient temperature, the temperature deviation in a steady state may be less than the LBA level, preventing detection of the loop burnout.

• If the set point is so high or low that it cannot be reached even with a saturated manipulated variable, a temperature deviation may remain even in a steady state and a loop burnout may be detected.
• Detection is not possible if a fault occurs that causes an increase in temperature while control is being applied to increase the temperature (e.g., an SSR short-circuit fault).
• Detection is not possible if a fault occurs that causes a decrease in temperature while control is being applied to decrease the temperature (e.g., a heater burnout fault).

Parameters Related to Loop Burnout Alarms

Note Set "None" as the unit for analog inputs.

• A loop burnout alarm can be output by setting the alarm 1 type to 12 (LBA).
• A setting of 12 (LBA) can be set for alarm 2 or alarm 3, but the setting will be disabled.
• Loop burnouts are not detected during SP ramp operation.
• Loop burnouts are not detected during auto-tuning, manual operation, or while stopped.
• If the alarm 1 latch is set to ON, the latch will be effective for the loop burnout alarm.
• Loop burnout alarms are not detected when using a remote SP.

Automatically Setting the LBA Detection Time

• Automatic setting is not possible for ON/OFF control. Set the LBA Detection Time parameter in the advanced function setting level.
• When PID control is being used, the LBA detection time can be set individually for each PID set. First select the PID set number in the Display PID Selection parameter (PID setting level), and then set the time in the LBA Detection Time parameter.
• The LBA detection time is automatically set by auto-tuning, and the execution results are saved in the PID set when auto-tuning is started. (The results are not set automatically, however, for heating/cooling control.)
• If the optimum LBA detection time is not obtained by auto-tuning, set the LBA Detection Time parameter (PID setting level).

Determining the LBA Detection Time

1,2,3...

- To manually set the LBA detection time, set the LBA Detection Time parameter to twice the LBA reference time given below.

1. Set the output to the maximum value.
2. Measure the time required for the width of change in the input to reach the LBA band.

1. Set the LBA Detection Time parameter to two times the measured time.

LBA Level

• Set the control deviation when the control loop is working properly.
• The default is 8.0 (°C/°F) for a temperature input and 10.00% FS for an analog input.
• There is assumed to be an error in the control loop if the control deviation is greater than the threshold set in the LBA Level parameter and if the control deviation does not change by at least the value set in the LBA Band parameter.
• The default is 3.0 (°C/°F) for a temperature input and 0.20% FS for an analog input.

LBA Band

Operating Procedure

Perform the following procedure to use the loop burnout alarm.

In this example, the LBA detection time is set to 10, the LBA level is set to 8.0, and the LBA band is set to 3.0.

Operation Level

Initial Setting Level

Initial Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Select the Alarm 1 Type parameter by pressing the ☐ Key.

Initial Setting Level

Operation Level

PID Setting Level

Initial Setting Level

Advanced Function Setting Level

Advanced Function Setting Level

Advanced Function Setting Level

1. Press the Key to set the parameter to 12.

To return to the operation level, press the ☐ Key for at least one second.

1. Press the ☐ Key to move from the operation level to the PID setting level.

2. The current PID set number will be displayed. Press the 🔗 or ⬆ Key to select PID set 2.

3. Press the ☐ Key to select the PID 2 LBA Detection Time parameter.

4. Press the ⬆ Key to set the parameter to 10.

5. Press the ☐ Key for at least three seconds to move to the initial setting level.

6. Select the Move to Advanced Function Setting Level parameter by pressing the ☐ Key. (For details on moving between levels, refer to 4-8 Moving to the Advanced Function Setting Level.)

7. Press the ☑ Key to enter the password (-169), and move from the initial setting level to the advanced function setting level.

8. Select the LBA Level parameter by pressing the ☑ Key.

9. Press the ⚠️ Key to set the parameter to 8.0. (The default is 8.0.)

10. Select the LBA Band parameter by pressing the ☐ Key.

11. Press the ▲ or ▼ Key to set the parameter to 3.0. (The default is 3.0.)

1. Press the ⬆ Key to set the parameter to 12. To return to the operation level, press the ⭕ Key for at least one second.

1. Press the ☐ Key to move from the operation level to the PID setting level.

1. The current PID set number will be displayed. Press the ⏠ or ⏰ Key to select PID set 2.

1. Press the ☐ Key to select the PID 2 LBA Detection Time parameter.

1. Press the ▲ Key to set the parameter to 10.

1. Press the ☐ Key for at least three seconds to move to the initial setting level.

1. Select the Move to Advanced Function Setting Level parameter by pressing the ☐ Key. (For details on moving between levels, refer to 4-8 Moving to the Advanced Function Setting Level.)

1. Press the ☑ Key to enter the password (-169), and move from the initial setting level to the advanced function setting level.

1. Select the LBA Level parameter by pressing the ☐ Key.

1. Press the ⚠️ Key to set the parameter to 8.0. (The default is 8.0.)

1. Select the LBA Band parameter by pressing the ☐ Key.

1. Press the ▲ or ▼ Key to set the parameter to 3.0. (The default is 3.0.)

Initial Setting Level

Operation Level

1. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level.

2. Press the ☐ Key for at least one second to move from the initial setting level to the operation level.

4-13 Performing Manual Control

4-13-1 Manual Operation

• With standard models, the MV is manipulated directly. With position-proportional models, the MV is manipulated through the amount of valve opening or by parameter settings.
• The manipulated variable can be set in manual mode if the PV/MV parameter is displayed in the manual control level. The final MV used in automatic mode will be used as the initial manual MV when moving from automatic mode to manual mode. In manual mode, the change value will be saved immediately and reflected in the actual MV.
• Manual operation can be used only for PID control.

Standard Models

• The automatic display return function will not operate in manual mode.
• Balanceless-bumpless operation will be performed for the MV when switching from manual operation to automatic operation. (See note.)
• If a power interruption occurs during manual operation, manual operation will be restarted when power is restored using the same MV as when power was interrupted.
• Switching between automatic and manual operation is possible for a maximum of one million times.

The overall manual operation is illustrated in the following figure.

Position-proportional Models

- When floating control is used or when the Direct Setting of Position Proportional MV parameter is set to OFF:

- Pressing the ⬆ Key turns ON the open output, and pressing the ∨ Key turns ON the close output.

• The automatic display return function will not operate in manual mode.
• Balanceless-bumpless operation will be performed for the MV when switching between manual and automatic operation. (See note.)
• Switching between manual and automatic operation is possible for a maximum of one million times.

- When close control is used or when the Direct Setting of Position Proportional MV parameter is set to ON:

• Just as with standard models, the MV is set numerically.
• The automatic display return function will not operate in manual mode.
• Balanceless-bumpless operation will be performed for the MV when switching between manual and automatic operation. (See note.)

Note In balanceless-bumpless operation, the MV before switching is used initially after the switch and then gradually changed to achieve the proper value after switch to prevent radical changes in the MV after switching operation.

• If a power interruption occurs during manual operation, manual operation will be restarted when power is restored using the same MV as when power was interrupted.
• Switching between manual and automatic operation is possible for a maximum of one million times.
• Operation will be as described below if a potentiometer input error occurs.
  When the Manual MV Limit Enable Parameter Is Set to OFF:

Manual MV ≥ 100

Open output: ON

Manual MV ≤ 0

Close output: ON

If the manual MV is other than the above, the open and close outputs will both be OFF.

When the Manual MV Limit Enable Parameter Is Set to ON:

Manual MV = MV upper limit

Open output: ON

Manual MV = MV lower limit

Close output: ON

If the manual MV is other than the above, the open and close outputs will both be OFF.

Related Displays and Parameters

Note (1) Refer to 4-17 Output Adjustment Functions for information on the priority for the MV.

(2) For Manual MV Limit Enable, this value will be between the MV upper limit and the MV lower limit.
(3) This setting is enabled only when the Direct Setting of Position Proportional MV parameter is set to ON.

Manual MV Limit Enable

When the Manual MV Limit Enable parameter is set to ON (enabled), the MV limits will function and the setting range for the Manual MV parameter will be between the MV upper limit and the MV lower limit. When the parameter is set to OFF (disabled), MV limits will not function.

Moving from the Operation Level to the Manual Control Level

- When the ☐ Key is pressed for at least 3 seconds in the operation level's auto/manual switching display, the manual mode will be entered and the manual control level will be displayed. It is not possible to move to any displays except for the PV/MV parameter during manual operation. Press the ☐ Key for at least one second from the PV/MV parameter display in manual control level to return to automatic mode and display the top parameter in the operation level.

graph TD
    A["Manual Control Level"] --> B["PV/MV 25.0 20.0"]
    B --> C["R-M display flashes for at least 1 s."]
    C --> D["-R-M"]
    D --> E["Auto/Manual Switch R-M 25.0 100.0"]
    E --> F["Bank No. 6ANK"]
    F --> G["Operation Level"]
    G --> H["PV 25.0"]
    H --> I["PV/SP 25.0"]
    I --> J["Auto/Manual Switch"]
    J --> K["Bank No. 6ANK"]
    K --> L["Operation Level"]
    style A fill:#f9f,stroke:#333
    style L fill:#ccf,stroke:#333

- If an event input is set to MANU (auto/manual), the Auto/Manual Switch parameter will not be displayed. Use the event input to switch between automatic and manual modes.

Using the PF Key to Move to the Manual Control Level

• When the PF Setting parameter is set to A-M (Auto/Manual), pressing the PF Key for at least one second while in the adjustment, operation, bank setting, or PID setting level will change the mode to manual mode and move to the manual control level. During manual operation it is not possible to move to any displays other than PV/MV (Manual MV). Press the PF Key for at least one second from the PV/MV display in the manual control mode to change the mode to automatic mode, move to the operation level, and display the top parameter in the operation level.
• When MANU (Auto/Manual) is selected for an event input, the Auto/Manual Switch parameter is not displayed. In that case, switching between auto and manual mode is executed by using an event input.
• The Auto/Manual Select Addition parameter must be set to ON in the advanced function setting level before it is possible to move to manual mode. The default is .

Auto/Manual Select Addition

Note

(1) Priority of Manual MV and Other Functions Even when operation is stopped, the manual MV is given priority. Auto-tuning and self-tuning will stop when manual mode is entered.
(2) Manual MV and SP Ramp If operating, the SP ramp function will continue even when manual mode is entered.

Operating Procedure

Use the following procedure to set the manipulated variable in manual mode.

Operation Level

Initial Setting Level

Initial Setting Level

Advanced Function Setting Level

Advanced Function Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Select the PID ON/OFF parameter by pressing the ☐ Key. (The default is PID.)
3. Select the Move to Advanced Function Setting Level parameter by pressing the ☑ Key. (For details on moving between levels, refer to 4-8 Moving to the Advanced Function Setting Level.)
4. Press the ☑ Key to enter the password (-169), and move from the initial setting level to the advanced function setting level.
5. Select the Auto/Manual Select Addition parameter by pressing the Key.

Initial Setting Level

Operation Level

Manual Control Level

Operation Level

Operating Procedure

Operation Level

Initial Setting Level

Initial Setting Level

1. Use the ⬆ Key to set the parameter to ON. (The default is ON.)

2. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level.

3. Press the ☐ Key for at least one second to move from the initial setting level to the operation level.

4. Select the Auto/Manual Switch parameter by pressing the ☐ Key.

5. Press the ☐ Key for at least three seconds to move from the operation level to the manual control level.

6. Press the ☑ or ☑ Key to set the manual MV. (In this example, the MV is set to 500%.)

Note The manual MV setting must be saved (see page 14), but values changed with Key operations are reflected in the control output immediately.

1. Press the ☐ Key for at least one second to move from the manual control level to the operation level.

In this example, A-M (Auto/Manual) is set for the PF Setting parameter (E5AN/EN-H only).

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select the PID ON/OFF parameter by pressing the ⚠ Key. (The default is PID.)

3. Select the Move to Advanced Function Setting Level parameter by pressing the ☑ Key. (For details on moving between levels, refer to 4-8 Moving to the Advanced Function Setting Level.)

Advanced Function Setting Level

Parameter Initialization

Advanced Function Setting Level

Auto/Manual Select Addition

Initial Setting Level

Manual Control Level

Operation Level

1. Press the ☑ Key to enter the password (-169), and move from the initial setting level to the advanced function setting level.
2. Select the Auto/Manual Select Addition parameter by pressing the Key.
3. Use the ⚠️ Key to set the parameter to ON. (The default is ON.)
4. Press the ☐ Key to select the PF Setting parameter and confirm that it is set to "A-M." ("A-M" is the default setting.)
5. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level.
6. Press the ☐ Key for at least one second to move from the initial setting level to the operation level.
7. Press the PF Key for at least one second to move from the operation level to the manual control level.
8. Press the ☑ or ☑ Key to set the manual MV. (In this example, the MV is set to 50.0%.)

Note The manual MV setting must be saved (see page 14), but values changed with key operations are reflected in the control output immediately.

1. Press the PF Key to move from the manual control level to the operation level.

4-14 Using the Transfer Output

4-14-1 Transfer Output Function

• The transfer output function can be used by Controllers that support a transfer output (E5AN/EN-H□F). For Controllers that do not have a transfer output, a control output can be used as a simple transfer output if the control output is a current output or a linear voltage output.
• To use a transfer output, change the setting for the Transfer Type parameter to anything other than OFF. (This will enable the Transfer Output Upper Limit and Transfer Output Lower Limit parameters.)

- The operation differs for models with a transfer output and models without a transfer output for which control output 1 or control output 2 is used as a simple transfer output, as shown in the following table.

Transfer Output Destination

■ Precision and User Calibration

Note For details on the calibration method, refer to SECTION 6 CALIBRATION.

Transfer Output Type

Note

(1) The default is OFF. For a Controller that does not support a transfer output, the item specified for the Control Output 1 Assignment or Control Output 2 Assignment parameter will be output.
(2) The output value will be different between when the Transfer Output Type parameter is set to a heating control output or cooling control output, and when the Control Output 1 Assignment or Control Output 2 Assignment parameter is set to a heating control output or cooling control output.

Example: When a Current Output Is Set to 4 to 20 mA and MV Monitor (Heating) Is Selected

When used as a transfer output, 4.0 mA will be output for 0% and 20.0 mA will be output for 100%.

When used as a control output, 3.7 mA will be output for 0% and 20.3 mA will be output for 100% so that the actuator is controlled at 0% or 100%.

(The above graph is for when the linear current output is set to 4 to 20 mA.)

(3) When the set point is selected, remote SP will be output while the Remote SP Mode is set in the SP Mode parameter.
(4) This setting will be ignored for position-proportional models.
(5) This setting will be ignored for standard control or for position-proportional models.
(6) Displayed for position-proportional models only when there is a potentiometer input.

Transfer Scaling

• Reverse scaling is possible by setting the Transfer Output Lower Limit parameter larger than the Transfer Output Upper Limit parameter. If the Transfer Output Lower Limit and Transfer Output Upper Limit parameters are set to the same value when 4 to 20 mA is set, the transfer output will be output continuously at 0% (4 mA).
• If the SP, SP during SP ramp, or PV is selected, the Transfer Output Lower Limit and Transfer Output Upper Limit parameters will be forcibly initialized to the respective upper and lower setting limits for changes in the upper and lower limits of the SP limiter and the temperature unit.

If the MV for heating or MV for cooling is selected, the Transfer Output Lower Limit and Transfer Output Upper Limit parameters will be initialized to 100.0 and 0.0, respectively, when a switch is made between standard control and heating/cooling control using the Standard or Heating/Cooling parameter.

• The output current when the linear current type is set to 4 to 20 mA, the transfer output upper limit is set to 90.0, and the transfer output lower limit is set to 10.0 is shown in the following graph.
• For scaling from 0.0% to 100.0%, the output for -5.0 to 0.0 will be the same value as for 0.0%, and the output for 100.0 to 105.0 will be the same value as for 100.0%

(The above graph is for when the linear current output is set to 4 to 20 mA.)

Operating Procedure

The following procedure sets the transfer output for an SP range of -50 to 200.

Operation Level

Initial Setting Level

Initial Setting Level

Initial Setting Level

Initial Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select the Transfer Output Type parameter by pressing the ☐ Key.

3. Press the ⬆ Key to select 5P (set point).

4. Select the Transfer Output Upper Limit parameter by pressing the ☐ Key.

5. Use the ☑ Key to set the parameter to 200.0. The default is 1300.0.

6. Select the Transfer Output Lower Limit parameter by pressing the ☐ Key.

Operation Level

1. Use the ⬆ Key to set the parameter to -50.0. The default is -200.0.
2. To return to the operation level, press the ☐ Key for at least one second.

4-15 Using Banks and PID Sets

Banks

Up to eight banks, each of which contains the following parameters, can be created. The current bank number can be changed by using key operations, event inputs, communications (operation commands), or simple programs.

In the bank setting level, select the bank numbers to be edited with the Display Bank Selection parameter, and make the settings for each bank.

Note The current bank will be displayed. If you change the bank using the U and D Keys, monitor function will be canceled.

If the following parameters are changed, the changes will be saved in the current bank:

Set Point, Alarm Values 1 to 3, Alarm Value Upper Limits 1 to 3, Alarm Value Lower Limits 1 to 3, (operation level)

SP Ramp Set Value, Soak Time, Wait Band (adjustment level).

PID Set Number

• Select a number from 1 to 8 to specify the PID set for each bank.
• The default setting is 1. For details, refer to PID Sets.
• The bank number can be confirmed by checking the number at the beginning of the parameter.

Simple Program and Bank Functions

For each bank, the Soak Time and Wait Band parameters can be set, and a simple program can be created. For details on creating a simple program, refer to 4-16 Using the Simple Program Function.

PID Sets

• The PID set to be executed is selected by using the PID Set No. parameter in the bank setting level. If 0 (Automatic selection) is set, then the PID set will be selected automatically according to preset conditions.
• Up to eight of the following parameters can be registered for each PID set.

Note When the PID Automatic Selection Data parameter is set to DV, the unit will be %FS.

The settings for the PID sets are made in the PID setting level. In the PID setting level, select the PID set numbers to be edited with the Display PID Selection parameter, and make the settings for each PID set.

Note The current PID set is displayed. If you use the ⏻ and ⏽ Keys to change the PID set, the monitor function will be canceled

When the following parameters are changed, the changes will be reflected in the current PID set:

Proportional Band, Integral Time, Derivative Time, MV Upper Limit, MV Lower Limit, Cooling Coefficient (adjustment level)

LBA Detection Time (advanced function setting level)

- If the PID Set No. parameter for a bank is set to 0, the PID set will be selected automatically according to preset conditions.

In the setting example on the left (with the PID Set Automatic Selection Data parameter set to PV), the following PID parameters are used:

PV ≤ 200°C: PID Set No. 1

200^ < PV ≤ 400^ : PID Set No. 2

Set the PID Set Automatic Selection Range Upper Limit so that the set value becomes larger as the PID set number increases. For PID Set No. 8, however, the automatic selection range upper limit always equals the upper limit of the specified range.

The PID Set Automatic Selection Hysteresis parameter can be used to set the hysteresis to prevent chattering when changing the PID set.

The PID Set Automatic Selection Data parameter can be used to select PV, DV (Derivative), or SP.

Automatic PID Set Selection

Note When the PID Set Automatic Hysteresis parameter is set to DV, the default setting becomes %FS.

4-16 Using the Simple Program Function

4-16-1 Simple Program Function

- A simple program consists of multiple banks.

The program can be created from the required number of banks by specifying the end bank in the Valid Program Bank parameter.

A simple program can be started from any of the banks from bank 0 to the end bank. When operation is finished in one bank, the program switches to the next bank and operation starts in that bank. Operation after the end bank has been completed can be set in the Program Pattern parameter.

• The program starts when the Program Start parameter is changed from RSET to STRT.
• The program stops when the Program Start parameter is changed from STRT to RSET. The program can be reset in any bank.

graph TD
    A["SP0"] --> B["Wait band 0"]
    B --> C["SP1"]
    C --> D["Wait band n"]
    D --> E["SPn"]
    F["(Bank 0)"] --> G["(Bank 1)"]
    G --> H["(Bank n)"]
    I["Soak time 0"] --> J["Soak time 1"]
    J --> K["Soak time n"]
    L["Wait band 1"] --> M["Wait band n"]

Parameters Related to the Simple Program Function

Note

(1) The setting unit is %FS for analog inputs.
(2) When the Soak Time or Wait Band parameter is changed in the adjustment level, the changes will be reflected in the current bank.
(3) Displayed when the Program Pattern parameter is set to any value other than OFF. The bank cannot be switched to any other bank.

Program Pattern

Any of three program patterns can be selected. The simple program will not be run if the Program Pattern parameter is set to OFF.

• Banks where the Soak Time parameter is set to 0 will not be executed.
• The bank number can be changed even during program operation by using either an event input or key operations.
• The bank number is initialized to 0 when the program pattern is changed.

■ Pattern 1 (STOP)

Control will stop and the STOP mode will be entered when the program has ended.

■ Pattern 2 (CONT)

Control will continue in RUN mode when the program has ended.

■ Pattern 3 (LOOP)

At the end of the program, operation switches to the start bank and continues in RUN mode.

Starting Method

Any of the following three methods can be used to start the simple program.

• Setting the Program Start parameter to STRT.
• Turning ON an event input. (The program start must be assigned to an event input. See note.)
• Starting with an Operation Command using communications. (When the program start is not assigned to an event input.)

Note

When an event input is used to start and reset the simple program, writing is performed to EEPROM. Be sure to consider the write life (1 million writes) of the EEPROM in the system design. When the program start is assigned to an event input, the Program Start parameter will function as a monitor display, and the RSET/STRT displays can be used to check when the event input has started or reset the simple program. When this is done, the Program Start parameter functions as a monitor display only and cannot be changed using key operations. If the Program Pattern parameter is set to OFF, the event input assignment setting will be initialized to "None."

The following table shows the operations when the program is started.

- Changing from RSET to STRT

The following table shows the operations when the program is reset.

- Changing from STRT to RSET

Note

(1) The bank number can be changed even during program operation by using either an event input or key operations.
(2) The bank number is initialized to 0 when the program pattern is changed.
(3) Even if an event input assigned to "Program Start" is switched from STRT to RSET while the power is OFF, the RUN/STOP status will not be changed when the power is turned ON and the bank number will not be initialized to 0.

Soak Time and Wait Band

The wait band is the band within which the process value is stable in respect to the set point. The soak time is measured within the wait band. The timer that measures the soak time operates only when the process value is within the wait band around the set point (i.e., SP ± wait band). In the following diagram, the timer will be stopped between the start and (1), (2) and (3), and (4) and (5) and will measure the time only between (1) and (2), (3) and (4), and (5) and the end.

Note

If the wait band is set to OFF, the wait band will be treated as infinity and the timer will measure time continuously after changing from RSET to STRT.

Operation When Power Is Turned ON

The following will occur if a power interruption occurs during execution of a simple program:

• The program start (RSET/STRT) and RUN/STOP status from before the power interruption will be held.
• The timer value for the Soak Time parameter will be reset.

Therefore, when a power interruption occurs, the timer value for the Soak Time parameter will not be correct. In addition, if starting the program is assigned to an event input, the event input status when a power interruption occurs will be the program start status from just before the power interruption.

4-16-2 Operation at the Program End

The following table shows operation when program operation ends, according to the Program Pattern parameter setting.

Note

(1) The bank number can be changed even during program operation by using either an event inputs or key operation.
(2) The bank number is initialized to 0 when the program pattern is changed.

Display at the Program End

When the program ends, the process value will be displayed on the No. 1 display (see note) and the set point and “end” will be alternately displayed on the No. 2 display at 0.5 s intervals.

Note

One of the following displays: PV/SP, PV only, or PV/MV.

Program End Output

When the Program Pattern parameter is changed from OFF to STOP, CONT, or LOOP, the Auxiliary Output 1 Assignment parameter will automatically be set to the end output. Conversely, when the Program Pattern parameter is changed from STOP, CONT, or LOOP to OFF, the Alarm 1 Output Assignment parameter will automatically be initialized to ALM1. The output assignment parameters can also be used to assign the program end output to any output. A program end output is also provided in communications status.

Clearing the Program End Status

The program END output and display will be cleared when the Program Start parameter is changed from STRT to RSET. The setting is changed from STRT to RSET while the Program Start parameter is displayed.

The program END status can also be cleared using an event. If the program start function is assigned to an event, however, the program end status cannot be cleared from the Program Start parameter display, which will function only as a monitor display.

4-16-3 Combining a Simple Program with an SP Ramp

Control can be combined with the SP ramp by setting the SP Ramp Set Value and Soak Time parameters for each bank.

If the program moves to the next bank at the end of the soak time before the ramp SP reaches the SP, the SP ramp operation will extend across the banks as shown below as long as the SP Ramp Set Value parameter is not set to 0.

If the SP Ramp Set Value parameter is set to 0 for the next bank, SP ramp operation will be stopped as shown below.

SP Start

Program operation can be started by using an SP start from the bank 0 LSP. To use an SP start, set the SP Ramp Set Value and Soak Time parameters for bank 0 to 0.

4-16-4 Relationships between Simple Programs and Other Functions

- Changing the Soak Time

If the soak time is changed while the program is being executed, timing will be continued from the time value at that point. The timer value will be reset, however, if a power interruption occurs.

- Changing the SP

If the soak time is changed while the program is being executed, timing will be continued from the timer value at that point.

- Input Errors

Timing will be continued even if an input error occurs during operation in program mode.

Note Timing will be performed according to the PV at the time of the input error (i.e., the sensor input setting range upper limit).

- Changing to Manual Mode

Timing will be continued when changing to manual mode while the simple program is being executed.

• AT

AT will be executed even if it is started while the simple program is being executed. While AT is being executed, operation will not move to the next bank and the soak remain time will remain at 0. Operation will move to the next bank after AT has been completed. After operation has been completed for the end bank, one of the following operations will be executed depending on the program pattern.

- SP Mode

STRT and RSET can be executed for the simple program without regard to the SP mode. SP mode changes are enabled while the simple program is being executed. Timing will continue in the SP mode after the change.

- RSP Input Errors

Timing will be continued even if an RSP input error occurs while the simple program is being executed.

Note Timing will be performed according to the PV and remote SP at the time of the RSP error.

- Switching RUN and STOP

Timing will continue if RUN and STOP are switched while the simple program is being executed.

- Changing Banks

If the bank is changed while the simple program is being executed, the time up to that point will be cleared and timing will start for the new bank's set value.

Operating Procedure

Perform the following procedure to use the simple program function.

Program pattern: STOP

Valid program bank: 1

Bank 0 set point: 150°C, Soak time: 5 min, Wait band: 3°C

Bank 0 set point: 200°C, Soak time: 10 min, Wait band: 5°C

Operation Level

Initial Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select the Program Pattern parameter by pressing the Key.

Initial Setting Level

Program Pattern

Operation Level

Bank setting level

Display Bank Selection

1. Use the ⏠ Key to set the parameter to STOP.

2. Press the ☐ Key to select the Valid Program Bank parameter.

3. Use the ⏠ and ⏰ Keys to set 2.

4. Press the ☐ Key for at least one second to move from the initial setting level to the operation level.

5. Press the ☐ Key to move from the operation level to the bank setting level.

6. The Display Bank Selection parameter will be displayed. The current bank number will be displayed, so use the 🔊 and ⬆ Keys to select 0.

7. Press the ☐ Key to select the Bank 0 SP parameter.

8. Use the ⏠ and ⏰ Keys to set the parameter to 150.0.

9. Press the ☐ Key to select the Bank 0 Soak Time parameter.

10. Use the ⏠ and ⏰ Keys to set the parameter to 5.

11. Press the ☐ Key to select the Bank 0 Wait band parameter.

12. Use the ▲ and ▼ Keys to set the parameter to 3.0.

13. Press the ☐ Key to select the Display Bank Selection parameter.

Display Bank Selection

1. Use the ⏠ and ⏰ Keys to set the parameter to 1.

1. Press the ☐ Key to select the Bank 1 SP parameter.

Bank 1 SP

1. Use the ▲ and ▼ Keys to set the parameter to 200.0.

1. Press the ☐ Key to select the Bank 1 Soak Time parameter.

Bank 1 Soak Time

1. Use the ▲ and ▼ Keys to set the parameter to 10.

1. Press the ☐ Key to select the Bank 1 Wait band parameter.

Bank 1 Wait band

1. Use the ⬆ and ⬇ Keys to set the parameter to 5.0.

1. Press the ☐ Key to move from the bank setting level to the operation level.

Operation Level

4-17 Output Adjustment Functions

4-17-1 Output Limits

• Output limits can be set to control the output using the upper and lower limits to the calculated MV.
• The following MV takes priority over the MV limits.
  Manual MV (See note.)
  MV at stop
  MV at PV error

Note When the manual MV limit is enabled, the manual MV will be restricted by the MV limit.

- For heating/cooling control, upper and lower limits are set of overall heating/cooling control. (They cannot be set separately for heating/cooling.)

4-17-2 MV at Stop

The MV when control is stopped can be set.

When setting the MV when control is stopped, set the MV at Stop and Error Addition parameter (advanced function setting level) to ON.

■ Standard Models

For heating/cooling control, the MV at stop will apply to the cooling side if the MV is negative and to the heating side if the MV is positive. The default is 0.0, so an MV will not be output for either standard or heating/cooling control.

■ Position-proportional Models

Open, close, or hold status can be selected for floating control or when the Direct Setting of Position Proportional MV parameter is set to OFF. With open status, only the open output will turn ON. With close status, only the close output will turn ON. With hold status, the open and close outputs will both turn OFF. The default setting is for hold status, with no outputs.

If the Direct Setting of Position Proportional MV parameter is set to ON during close control, the valve opening can be specified. The default setting is 0.0 (i.e., the open and close outputs are adjusted so that valve opening will be 0).

Note The order of priority is as follows: Manual MV > MV at stop > MV at PV error.

- The following table shows the operation when a potentiometer error occurs when the Direct Setting of Position Proportional MV parameter is set to ON.

MV at stop ≥ 100

Open output ON

MV at stop ≤ 0

Close output ON

When the MV at stop is other than the above, the open and close outputs will both be OFF.

4-17-3 MV at PV Error

- A fixed MV is output for an input error, RSP input error, or potentiometer error (close control only). To set the MV at PV error, set the MV at Stop and Error Addition parameter (advanced function setting level) to ON. The MV at stop takes priority when stopped and the manual MV takes priority in manual mode.

■ Standard Models

With heating/cooling control, the MV on the cooling side is taken to be a negative value, so the output is made to the heating side for a positive value and to the cooling side for a negative value. The default setting is 0.0 (i.e., there are not outputs for either standard control or heating/cooling control).

■ Position-proportional Models

Open, close, or hold status can be selected for floating control or when the Direct Setting of Position Proportional MV parameter is set to OFF. With open status, only the open output will turn ON. With close status, only the close output will turn ON. With hold status, the open and close outputs will both turn OFF. The default setting is for hold status, with no outputs.

If the Direct Setting of Position Proportional MV parameter is set to ON during close control, valve opening can be specified. The default setting is 0.0, so open and close outputs are adjusted so that valve opening will be 0.

Note The order of priority is as follows: Manual MV > MV at stop > MV at PV error.

- The following table shows the operation when a potentiometer error occurs when the Direct Setting of Position Proportional MV parameter is set to ON.

MV at stop ≥ 100

Open output ON

MV at stop ≤ 0

Close output ON

When the MV at stop is other than the above, the open and close outputs will both be OFF.

- The order of priority of the MVs is illustrated in the following diagram.

graph LR
    A["PID calculations"] --> B["Manipulated variable"]
    B --> C["RSP input error<br>Potentiometer input error (close control)"]
    C --> D["RUN/STOP"]
    D --> E["Auto/manual switch"]
    E --> F["Output"]

    subgraph Time
        B
        C
        D
        E
    end

    G["MV upper limit"] --> B
    H["MV at PV Error"] --> C
    I["Manual MV (See note.)"] --> E
    J["MV at Stop"] --> D
    K["MV lower limit"] --> B

Note When the Manual MV Limit Enable parameter is set to ON, the setting range will be the MV lower limit to the MV upper limit.

4-18 Using the Extraction of Square Root Parameter

Extraction of Square Roots

Extraction of Square Root Enable

• For analog inputs, the Extraction of Square Root parameter is provided for inputs so that differential pressure-type flow meter signals can be directly input.
• The default setting for the Extraction of Square Root parameter is OFF. The Extraction of Square Root Enable parameter must be set to ON in order to use this function.

Extraction of Square Root Low-cut Point

- If the PV input (i.e., the input before extracting the square root) is higher than 0.0% and lower than the low cut point set in the Extraction of Square Root Low-Cut Point parameter, the results of extracting the square root will be 0.0%. If the PV input is lower than 0.0% or higher than 100.0%, extraction of the square root will not be executed, so the result will be equal to the PV input. The low-cut point is set as normalized data for each input, with 0.0 as the lower limit and 100.0 as the upper limit for the input setting range.

Argument 1 (Input Data)

Operating Procedure

Input type = 25 (4 to 20 mA)

This procedure sets the Extraction of Square Root Low-cut Point parameter to 10.0%.

Operation Level

Initial Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Use the ⬆ and ⬇ Keys to set the parameter to 25 (4 to 20 mA).
3. Press the ☑ Key to select the Extraction of Square Root Enable parameter.
4. Use the ⏠ Key to select ON.

Operation Level

Adjustment Level

Operation Level

1. Press the ☐ Key for at least one second to move from the initial setting level to the operation level.

2. Press the ☐ Key to move from the operation level to the adjustment level.

3. Select the Extraction of Square Root Low-cut Point parameter by pressing the ☐ Key.

4. Use the ⬆ Key to set the parameter to -10.0.

5. Press the ☐ Key to return to the operation level.

4-19 Setting the Width of MV Variation

MV Change Rate Limit

MV Change Rate Limit (Heating)

• The MV change rate limit sets the maximum allowable width of change in the MV per second. If the change in the MV exceeds this setting, the MV will be changed by the MV change rate limit until the calculated value is reached. This function is disabled when the setting is 0.0.

• The MV change rate limit does not function in the following situations:

• In manual mode

• During ST execution (Cannot be set when ST is ON.)
• During AT execution
• During ON/OFF control
• While stopped (during MV at Stop output)
  • During MV at PV Error output

Operating Procedure

This procedure sets the MV change rate limit to 5.0%/s. The related parameters are as follows:

$$ \mathrm{PID} \cdot \mathrm{ON/OFF} = \mathrm{PID} $$

$$ \mathrm{ST} = \mathrm{OFF} $$

Operation Level

Initial Setting Level

Operation Level

Adjustment Level

Operation Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select the PID ON/OFF parameter by pressing the ☐ Key.

3. Use the Key to select 2-PID control. (The default is PID.)

4. Press the ☐ Key to select the ST parameter.

5. Press the ▼ Key to select OFF.

6. Press the ☐ Key for at least one second to move from the initial setting level to the operation level.

7. Press the ☐ Key to move from the operation level to the adjustment level.

8. Press the ☐ Key to select the MV Change Rate Limit parameter.

9. Use the ⬆ Key to set the parameter to 5.0.

10. Press the ☐ Key to return to the operation level.

4-20 Setting the PF Key

4-20-1 PF Setting (Function Key)

PF Setting

- Pressing the PF Key for at least one second executes the operation set in the PF Setting parameter (E5AN/EN-H only).

Note

(1) When AT cancel is specified, it means that AT is cancelled regardless of whether the AT currently being executed is 100% AT or 40% AT.
(2) The setting of AT-1 will be ignored for heating/cooling control or for position-proportional floating control.
(3) Alarms 1 to 3, heater burnout, HS alarms, and heater overcurrent latches are cancelled.
(4) For details on auto/manual operations using the PF Key, refer to 4-13 Performing Manual Control.
(5) Pressing the PF Key for at least one second executes operation according to the set value. When the Monitor/Setting Item parameter is selected, however, the display is changed in order from Monitor/Setting Item 1 to 5 each time the key is pressed.
(6) This function is enabled when PF Key Protect is OFF.

Monitor/Setting Item

Monitor/Setting Item 1

Setting the PF Setting parameter to the Monitor/Setting Item makes it possible to display monitor/setting items using the function key. The following table shows the details of the settings. For setting (monitor) ranges, refer to the applicable parameter.

Note

(1) The SP for the current bank will be displayed.
(2) For details on MV settings for heating and cooling control, refer to MV Display for Heating and Cooling Control on page 82.
(3) The set value for the current PID set will be displayed.
(4) The set value for the current bank will be displayed.

Setting Monitor/Setting Items

Pressing the PF Key in the operation, adjustment, bank setting, or PID setting level displays the applicable monitor/setting items. Press the PF Key to display in order Monitor/Setting Items 1 to 5. After Monitor/Setting Item 5 has been displayed, the display will switch to the top parameter in the operation level.

Note

(1) Items set as disabled in the Monitor/Setting Items 1 to 5 parameters will not be displayed, and the display will skip to the next enabled setting.
(2) While a monitor/setting item is being displayed, the display will be switched to the top parameter in the operation level if the ☐ Key or the ☐ Key is pressed.

Operating Procedure

This procedure sets the PF Setting parameter to PFDP, and the Monitor/Setting Item 1 parameter to 7 (Alarm Value 1).

Operation Level

Initial Setting Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

Initial Setting Level

Move to Advanced Function Setting Level

Advanced Function Setting Level

Parameter Initialization

PF Setting

PF Setting

Monitor/Setting Item 1

Monitor/Setting Item 1

Initial Setting Level

Input Type

Operation Level

Monitor/Setting Item Level

Monitor/Setting Item Display 1

1. Select the Move to Advanced Function Setting Level parameter by pressing the ☐ Key.

2. Press the ☑ Key to enter the password (-169). It is possible to move to the advanced function setting level by either pressing the ☑ Key or waiting two seconds without pressing any key.

3. Press the ☐ Key to select the PF Setting parameter.

4. Press the ⏠ Key to select PFDP (Monitor/Setting Item).

5. Press the ☑ Key to select the Monitor/Setting Item 1 parameter.

6. Press the ⬆ Key to select 7 (Alarm Value 1).

7. Press the ☐ Key for at least one second to move from the advanced function setting level to the initial setting level.

8. Press the ☐ Key for at least one second to move from the initial setting level to the operation level.

9. Press the PF Key to display Alarm Value 1 for the current bank.

4-21 Counting Control Output ON/OFF Operations

4-21-1 Control Output ON/OFF Count Function

If Control Output 1 and 2 are ON/OFF outputs (relay outputs, voltage outputs for driving SSR, or SSR outputs), the number of times that a control output turns ON and OFF can be counted. Based on the control output ON/OFF count alarm set value, an alarm can be output and an error can be displayed if the set count value is exceeded.

The default setting of the Control Output ON/OFF Alarm Set Value parameter is 0. ON/OFF operations are not counted when this parameter is set to 0. To enable counting ON/OFF operations, change the setting to a value other than 0.

Control Output ON/ OFF Counter Monitor Function

This function is not displayed when the Control Output 1 ON/OFF Alarm Set Value and the Control Output 2 ON/OFF Alarm Set Value parameter are set to 0, or when the control outputs are set for linear outputs.

Display When ON/OFF Count Alarm Occurs

When an ON/OFF count alarm occurs, the PV display in the No. 1 display shown below alternates with the RRLM display on the No. 2 display.

• PV
- PV/SP (Including the items displayed by setting the “PV/SP” Display Screen Selection parameter.)
- PV/Manual MV (Valve Opening), PV/SP/Manual MV (Valve Opening)
- PV/SP displayed for the monitor/setting items

Control Output ON/OFF Count Alarm Function

If the ON/OFF counter exceeds the control output ON/OFF count alarm set value, an ON/OFF count alarm will occur. The alarm status can be assigned to a control output or an auxiliary output, or it can be displayed at the Controller. The ON/OFF count alarm set value function is disabled by setting the ON/OFF count alarm set value to 0.

ON/OFF Counter Reset Function

The ON/OFF counter can be reset for a specific control output.

Note After the counter has been reset, the control output ON/OFF count monitor value will be automatically returned to 0.

If an error occurs in the control output ON/OFF counter data, the ON/OFF count monitor value will be set to 9999 and an ON/OFF count alarm will occur. The alarm can be cleared by resetting the ON/OFF counter.

Operating Procedure

This procedure sets the Control Output 1 ON/OFF Alarm Set Value parameter to 10 (1,000 times).

Initial Setting Level

Initial Setting Level

Advanced Function Setting Level

Initial Setting Level

Operation Level

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.

2. Select the Move to Advanced Function Setting Level parameter by pressing the ☐ Key.

3. Use the ☑ Key to enter the password (“-169”). It is possible to move to the advanced function setting level by either pressing the ☑ Key or waiting two seconds without pressing any key.

4. Press the ☑ Key to select the Control Output 1 ON/OFF Count Alarm Set Value parameter.

5. Use the Key to set the parameter to 10.

6. Press the ☐ Key for at least one second to move to the initial setting level.

7. Press the ☐ Key for at least one second to move to the operation level.

4-22 Displaying PV/SV Status

4-22-1 PV and SV Status Display Functions

PV Status Display Function

The PV function in the PV/SP, PV, or PV/Manual MV (Valve Opening) Display and the control and alarm status specified for the PV and PV status display are alternately displayed in 0.5-s

- The default is OFF.

Note “HA” can be selected for models that do not support heater burnout detection, but the function will be disabled.

Example: When STOP Is Selected for the PV Status Display Function

SV Status Display Function

The SP, Blank, or Manual MV in the PV/SP, PV, or PV/Manual MV Display (Valve Opening) and the control and alarm status specified for the SV status display function are alternately displayed in 0.5-s cycles.

- The default is OFF.

Note “HA” can be selected for models that do not support heater burnout detection, but the function will be disabled.

Example: When ALM1 Is Selected for the SV Status Display Function

Note The order of priority for flashing and alternating displays on the No. 2 display are as follows:

Operating Procedure

Initial Setting Level

Input Type

Initial Setting Level

Move to Advanced Function Setting Level

Advanced Function Setting Level

Parameter Initialization

PV Status Display Function

PV Status Display Function

Initial Setting Level

Input Type

Operation Level

(1) Alternating display in SV status display
(2) Alternating display during program end output
(3) Flashing display during auto-tuning
(4) Alternating display when a control output ON/OFF count alarm occurs
(5) Flashing display when out of the setting range

This procedure sets the PV Status Display Function parameter to ALM1.

1. Press the ☐ Key for at least three seconds to move from the operation level to the initial setting level.
2. Select the Move to Advanced Function Setting Level parameter by pressing the ☐ Key.
3. Use the ☑ Key to enter the password (-169). It is possible to move to the advanced function setting level by either pressing the ☐ Key or waiting two seconds without pressing any key.
4. Press the ☐ Key to select the PV Status Display Function parameter.
5. Press the ⏠ Key to select ALM1.
6. Press the ☐ Key for at least one second to move to the initial setting level.
7. Press the ☐ Key for at least one second to move to the operation level. If the Alarm 1 status is ON, PV and ALM1 will be alternately displayed.

4-23 Using a Remote SP

The remote SP function scales a remote SP input (4 to 20 mA) to the remote SP upper and lower limits, and takes it as the set point. (This function is supported by the E5AN-H and E5EN-H only.)

Set the Remote SP Enable parameter (advanced function setting level) to ON, and use an event input or an operation command to select the remote SP.

Precautions

• When the ST (self-tuning) parameter is turned ON, the SP Mode parameter is forcibly set to LSP.
• The remote SP input is not accepted during autotuning. Autotuning is executed for the remote SP at the beginning of autotuning.
• Changes in the remote SP value are not used as conditions for resetting the standby sequence.

Remote SP Scaling

• The remote SP input (4 to 20 mA) can be scaled to match the PV input range, based on the Remote SP Upper Limit and Remote SP Lower Limit parameter settings.
• The remote SP input can be input in a range of -10% to 110% of 4 to 20 mA. Input values outside of this range treated as out-of-range input values (RSP input error) and clamped to the upper or lower limit. In SP mode, the RSP single indicator will flash, and in local SP mode the No. 2 indicator for the Remote SP Monitor will flash.
• An alarm can be output if an RSP input error occurs by setting the Remote SP Input Error Output parameter to ON.

- When the SP Upper Limit or SP Lower Limit parameter setting is changed, the remote SP upper or lower limit will be forcibly changed to the SP upper or lower limit. For example, if the upper limit for the SP limiter is changed from A to B, the remote SP upper and lower limits will be changed as shown in the following diagram.

graph TD
    A["Before change"] --> B["SP limiter"]
    B --> C["RSP scaling range"]
    C --> D["After limiter upper limit change"]
    D --> E["Upper limit changed from A to B"]
    E --> F["Remote SP upper and lower limits"]
    style A fill:#f9f,stroke:#333
    style B fill:#ccf,stroke:#333
    style C fill:#cfc,stroke:#333
    style D fill:#fcc,stroke:#333
    style E fill:#ffc,stroke:#333
    style F fill:#cff,stroke:#333

SP Mode

The SP mode is used to switch between local SP and remote SP. When a remote SP is selected in SP mode, the RSP single indicator will light.

Remote SP Monitor

In remote SP mode, the remote SP can be checked on the No. 2 display in the PV/SP Display Screen. In local SP mode, it can be checked with the Remote SP Monitor parameter.

SP Tracking

• If the SP tracking function is enabled, the local SP inherits the remote SP value after switching from remote SP to local SP. To enable the SP tracking function, set the SP Tracking parameter to ON.
• SP tracking operates as follows:

1,2,3... 1. Switching to remote SP when the SP is LSP1 will result in switching to RSP2.
2. The operation will proceed according to remote SP inputs.
3. If the SP tracking function is enabled, the SP will become LSP2 after switching to local SP. If the SP tracking function is disabled, the SP will remain as LSP1.
- If the SP tracking function is enabled when switching from local SP to remote SP, the SP ramp will operate.

4-24 Position-proportional Control

The control method used to adjust the opening and closing of a valve with a control motor is called "position-proportional control" or "ON/OFF servo control." Either closed control or floating control can be selected for position-proportional control. Only models that support position-proportional control (E5AN/EN-HPRR□) can be used for position-proportional control. In addition, the following functions are disabled when using position-proportional control.

• ST
• LBA
- Heater burnout, heater short, and heater overcurrent alarms
- ON/OFF control
- P and PD control (for floating control only)
• 40% AT (for floating control only)

Closed Control

Closed control provides control using feedback on the valve opening by connecting a potentiometer.

Floating Control

Floating control provides control without using feedback on the valve opening, so control is still possible even if a potentiometer is not connected. With floating control, the expected valve opening is calculated from the travel time, and that value is treated as the valve opening for executing control outputs.

If there is no FB input, then even if the Closed/Floating parameter is set to Closed the parameter will be disabled and floating control will be executed.

Motor Calibration and Travel Time

Calibrate the motor when a potentiometer is connected, such as in closed control or in floating control for monitoring valve opening. The fully closed and fully open valve positions will be calibrated and the travel time, i.e., the time from the fully open to the fully closed position, will be automatically measured and set. Set the Motor Calibration parameter to ON to execute the motor calibration. The setting will be automatically changed OFF when the calibration has been completed.

For floating control (i.e., without a potentiometer connection), it is necessary to manually set the travel time. Set the Travel Time parameter to the time from the fully open to the fully closed valve position.

Position-proportional Dead Band and Open/Close Hysteresis

The interval during which the valve output is held (for the ON and OFF switching points for the open output and closed output) is set by the Position Proportional Dead Band parameter, and the hysteresis is set by the Open/Close Hysteresis parameter.

PV Dead Band

When the process value (PV) is within the PV dead band, control is executed as if the process value is equal to the set point for the current bank to prevent unnecessary outputs when the process value is in the vicinity of the set point.

Valve Opening Monitor

Valve opening can be monitored by connecting a potentiometer. The motor must be calibrated after the potentiometer is connected.

Note If no potentiometer is connected or if a potentiometer input error occurs, "----" will be displayed.

With the E5AN/EN-H, valve opening can also be monitored on the PV/SP/MV (Valve Opening) Screen.

Manual Operation

With models that support position-proportional control, manual operation is possible by moving to the manual control level and pressing the Up and Down Keys. The output on the open side is ON while the Up Key is pressed, and the output on the closed side is ON while the Down Key is pressed. If the Direct Setting of Position Proportional MV parameter is set to ON and closed control is used, however, the Manual MV parameter can be set with the same display and operations as for standard models.

MV at Stop and Error

With floating control or when the Direct Setting of Position Proportional MV parameter is set to OFF, select to output open, closed, or hold status when stopped or when an error occurs. If the Direct Setting of Position Proportional MV parameter is set to ON for closed control, set the MV.

4-25 Logic Operations

4-25-1 The Logic Operation Function (CX-Thermo)

- The logic operation function logically calculates as 1 or 0 the Controller status (alarms, SP ramp, RUN/STOP, auto/manual, etc.) and the external event input status, and outputs the results to work bits. The work bit status can be output to auxiliary or control outputs, and operating status can be switched according to the work bit status. - Work bit logic operation can be set from 1 to 8. Set them to No operation (Always OFF) (the default) when the work bits are not to be used. When logic operations are being used, a dot will be displayed on the No. 2 display of the adjustment level display

4-25-2 Using Logic Operations

Logic operations are set using the CX-Thermo.

Starting Logic Operations

There are two ways to start logic operations.

- Select Logic Operation Editor from the CX-Thermo tree, and click the Start Button.

- Select Logic Operation Editor from the CX-Thermo Options Menu.

Making the Settings

The following display will appear on the Logic Operation Editor Setting Window. Set each of the parameters.

1,2,3... 1. Displaying the Library Import Dialog Box

Logic operation samples for specific cases are set in the library in advance. Examples of settings for specific cases are loaded by selecting them from the library list and clicking the OK Button.

Example: Selecting Library 1

2. Switching Work Bit Operations

Select the work bit logic operations from the Operation of Work Bit 1 to Operation of Work Bit 8 Tab Pages.

3. Selecting the Operation Type

From one to four operations are supported. If work bits are not to be used, set them to No operation (Always OFF) (the default).

- No Operation (Always OFF)

- Operation 1

- Operation 2

(A and B) or (C and D) When conditions A and B or conditions C and D are satisfied

(A or C) and (B or D) When condition A or C and condition B or D are satisfied

- Operation 3

A or B or C or D

When condition A, B, C or D is satisfied

- Operation 4

A and B and C and D

When conditions A, B,

C and D are all satisfied

4. Selecting Input Assignments

Select the input assignment for the work bit logic operation from the following settings.

Note (1) The event inputs that can be used depend on the Controller model.

(2) Turns ON when either the control output 1 or 2 ON/OFF count alarm is ON.

1. Switching between Normally Open and Normally Closed for Inputs A to D Click the condition to switch between normally open and normally closed inputs A to D.

1. Switching between Normally Open and Normally Closed for Work Bits Click the condition to switch between normally open and normally closed work bits.

Normally open	Normally closed

1. Setting ON Delay Times

When an input with an ON delay turns ON, the output will turn ON after the set delay time has elapsed. The setting range is 0 to 9,999. The default is 0 (disabled).

1. Setting OFF Delay Times

When an input with an OFF delay turns OFF, the output will turn OFF after the set delay time has elapsed. The setting range is 0 to 9,999. The default is 0 (disabled).

1. Switching ON/OFF Delay Time Unit

Select either seconds or minutes for the ON/OFF delay time unit. The default is seconds.

1. Selecting the Number of Banks to Use

Select a number from 0 to 3 for the Bank Numbers Used parameter.

(For models with two event inputs, select a number between 0 and 2.)

Note If a work bit is assigned for either the Event Input Data 1 or Event Input Data 2 parameter for a model that does not support event inputs 1 and 2 and if a number greater than 0 is set for the Bank Numbers Used parameter, then event inputs 1 and 2 will be used for bank selection.

For example, if the Bank Numbers Used parameter is set to 2 for a model with event inputs 3 and 4, and the following settings are made, then event input 1 (work bit 1) and event input 2 (work bit 2) will be used for bank selection.

• Event Input Data 1: Work bit 1
• Event Input Data 2: Work bit 2
• Event Input Data 3: Event input 3 (external input)
• Event Input Data 4: Event input 4 (external input)

To use event input 3 (external input) and event input 4 (external input) for bank selection, make the following settings:

• Event Input Data 1: Event input 3 (external input)
• Event Input Data 2: Event input 4 (external input)
• Event Input Data 3: Work bit 1
• Event Input Data 4: Work bit 2

11. Changing Event Input Data

Select the event input conditions from the following setting ranges.

Note The event input data can be changed from the default setting even if there is no event input terminal (external input). By changing the default setting, the event input assignment parameters will be displayed at the Controller display and can be set from the Controller.

1. Changing the Event Input Assignment Function

Select the setting for the event input assignment.

When a work bit is selected as event input data, Communications Write Enable/Disable cannot be assigned to an event input.

1. Changing Control Output and Auxiliary Output Settings

Control output and auxiliary output assignments can be changed. The items that can be changed depend on the Controller model. For details, refer to 3-5-3 Assigned Output Functions.

Assigning a work bit to either a control output or to an auxiliary output is also considered to be the same as assigning an alarm. For example, if work bit 1 is set for the Auxiliary Output 1 Assignment parameter, then alarms 1 to 3 have been assigned.

1. Displaying Parameter Guides

A description of the parameters can be displayed.

1. Displaying the Work Bit Use Destinations

Display a list of destinations where the work bits are used.

Operating Procedure

This procedure uses event input 2 to change to RUN or STOP.

Event input 2 ON: RUN

Event input 2 OFF: STOP

graph TD
    A["Event 2"] --> B["Always OFF"]
    A --> C["Always OFF"]
    A --> D["Always OFF"]
    B --> E["Reverse operation"]
    C --> E
    D --> E
    E --> F["Work bit 1"]

1. Select Logic Operation Editor from the CX-Thermo tree, and click the Start Button.

2. The Logic Operation Editor will be displayed. Confirm that the screen for work bit 1 is displayed, and select Operation 3 from the Operation Type Field.

3. Set the operation by selecting one of the following: Work bit 1 input assignment A = 4: Event input 2 (external input) Work bit 1 input assignment B = 0: Always OFF Work bit 1 input assignment C = 0: Always OFF Work bit 1 input assignment D = 0: Always OFF

4. Invert work bit 1. Click (Normally open) to change it to (Normally closed).

5. Assign RUN/STOP to event input 2. Set "5: Work bit 1" for the event input data for event input 2, and set "RUN/STOP" for the assignment function.

6. Closing the Logic Operation Editor Dialog Box Click the Close Button.

This completes the procedure for setting parameters using the CX-Thermo. Transfer the settings to the Controller to set the Controller. Refer to CX-Thermo help for the procedure to transfer the settings.

Operating Procedure

This procedure outputs alarm 1 status to auxiliary output 1 during operation (RUN). A library object is used to make the setting.

graph TD
    A["Alarm 1"] --> B["RUN/STOP"]
    B --> C["Work bit 1"]
    D["Always OFF"] --> E["Always OFF"]
    E --> B

1. Select Logic Operation Editor from the CX-Thermo tree, and click the Start Button.

1. Click the Import of Library Button.

1. Select Library 1 from the library list, and then click the OK Button.

Confirm the following settings, and then click the OK Button.

Work bit 1 operation type: Operation 1

Work bit 1 input assignment A = 7: Alarm 1

Work bit 1 input assignment B = 19: Invert for RUN/STOP

Work bit 1 input assignment C = 0: Always OFF

Work bit 1 input assignment D = 0: Always OFF

Auxiliary output 1 = Work bit 1

1. Closing the Logic Operation Editor Dialog Box Click the Close Button.

This completes the procedure for setting parameters using the CX-Thermo. Transfer the settings to the Controller to set the Controller. Refer to CX-Thermo help for the procedure to transfer the settings.

SECTION 5 Parameters

This section describes the individual parameters used to setup, control, and monitor operation.

5-1 Conventions Used in this Section 170

5-1-1 Meanings of Icons Used in this Section 170

5-1-2 About Related Parameter Displays.... 170

5-1-3 The Order of Parameters in This Section 170

5-1-4 Alarms.... 170

5-2 Protect Level 171

5-3 Operation Level.... 175

5-4 Adjustment Level 190

5-5 Bank Setting Level 209

5-6 PID Setting Level 216

5-7 Monitor/Setting Item Level.... 220

5-8 Manual Control Level 221

5-9 Initial Setting Level.... 223

5-10 Advanced Function Setting Level.... 242

5-11 Communications Setting Level.... 281

5-1 Conventions Used in this Section

5-1-1 Meanings of Icons Used in this Section

Describes the functions of the parameter.

Describes the setting range and default of the parameter.

Used to indicate parameters used only for monitoring.

Describes the parameter settings, such as those for Operation Commands, and procedures.

Used to indicate information on descriptions in which the parameter is used or the names of related parameters.

5-1-2 About Related Parameter Displays

Parameters are displayed only when the conditions for use given on the right of the parameter heading are satisfied. Protected parameters are not displayed regardless of the conditions for use, but the settings of these parameters are still valid.

graph LR
    A["AT Execute/Cancel"] --> B["Displayed symbol"]
    A --> C["Parameter name"]
    A --> D["Conditions for use"]
    A --> E["The E5CN-H must be in operation, and control must be 2-PID control."]

5-1-3 The Order of Parameters in This Section

Parameters are described level by level.

The first page of each level describes the parameters in the level and the procedure to switch between parameters.

5-1-4 Alarms

It will be specified in this section when alarms are set for the Control Output 1 or 2 Assignment parameters, or for the Auxiliary Output 1 or 3 Assignment parameters. For example, when alarm 1 is set for the Control Output 1 Assignment parameter, it will be specified that alarm 1 is assigned.

Assigning a work bit to either control output 1 or 2 or to auxiliary output 1 to 3 is also considered to be the same as assigning an alarm. For example, if work bit 1 is set for the Auxiliary Output 1 Assignment parameter, then alarms 1 to 3 have been assigned.

5-2 Protect Level

Four levels of protection are provided on the E5CN-H, operation/adjustment protect, initial setting/ communications protect, setting change protect, and PF key protect (PF Key protect is supported for the E5AN-H and E5EN-H only). These protect levels prevent unwanted operation of the keys on the front panel in varying degrees.

graph TD
    A["Power ON"] --> B["Operation Level"]
    B --> C["Adjustment Level"]
    C --> D["Bank Setting Level"]
    D --> E["PID Setting Level"]
    E --> B
    B --> F["Press the ☐ Key for at least 1 s."]
    F --> B
    C --> G["Press the ☐ + ☐ Keys for at least 1 s."]
    G --> H["Protect Level"]
    H --> I["Press the ☐ + ☐ Keys for at least 3 s. (See note.)"]
    I --> J["Press the ☐ + ☐ keys; display will flash."]
    J --> K["25.0 100.0"]
    K --> L["Control in Progress"]

To move from the operation level to the protect level, press ☐ and ☑ Keys for three seconds (see note) or more.

Note The time taken to move to the protect level can be adjusted by changing the Move to Protect Level Time parameter setting.

graph TD
    A["PMoV"] --> B["Operation/Adjustment Protect"]
    B --> C["Initial Setting/Communications Protect"]
    C --> D["Setting Change Protect"]
    D --> E["PF Key Protect"]
    E --> F["Parameter Mask Enable"]
    F --> G["Password to Move to Protect Level"]

Parameters that are protected will not be displayed and their settings cannot be changed.