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Copeland EVH Series Application Engineering Bulletin

Three phase variable frequency drives

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Installation manual (28 pages)

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AE8-1466

SAFETY INSTRUCTIONS ......................................... 4

Safety Icon Explanation ......................................... 5

Drive Safety Information ........................................ 5

Other Important Safety Information ...........................6

Additional Information ......................................... 7

Common Abbreviations ...................................... 7

INTRODUCTION ....................................................... 8

Product Description ................................................ 8

Product Features .................................................... 8

Theory of Drive Operation ...................................... 8

Standards and Certifications .................................. 9

Nomenclature ......................................................... 9

Product Offering ..................................................... 9

TECHNICAL DATA AND SPECIFICATIONS ...........10

Product Specifications ........................................... 10

Drive Dimensions ................................................... 13

Control Board Layout ............................................. 14

Keypad Overview ................................................... 15

Keypad LED Indicator ............................................ 17

Keypad Menu Navigation ....................................... 17

Keypad LCD Display .............................................. 18

Welcome Page ................................................... 19

Upgrade page .................................................... 19

Auto backup page .............................................. 19

Menu Overview ...................................................... 20

Main Menu Page ................................................ 20

Menu Navigation ................................................ 20

M-Monitor ........................................................... 20

Menu Structure .................................................. 21

F-Fault ................................................................ 21

Pop-up Fault ...................................................... 21

Fault History ....................................................... 21

Fault Log ............................................................ 22

P-Parameter ....................................................... 22

Special Pages .................................................... 22

Value Edit ........................................................... 24

T-Favorites ......................................................... 24

Basic Application .................................................... 25

PID Application ....................................................... 25

Advance Application............................................... 26

I/O CONTROLS ................................................. 27

Safe Torque Off (STO) Function ............................ 28

Safety function ...................................................

Safe state ........................................................... 28

System response time ....................................... 28

RECEIVING AND INSPECTION ............................... 30

Unpacking the Drive ............................................... 30

EVH Series Three Phase Variable Frequency

Drives 208-230V, 480V, 575V, 1 to 250HP

TABLE OF CONTENTS

28

1

Real Time Clock (RTC) Battery Activation ............. 30

GENERAL INSTALLATION ...................................... 31

Drive Handling ........................................................ 31

Main Components .................................................. 31

Drive System .......................................................... 31

Electrical Installation ............................................... 34

Wiring Selection ...................................................... 34

Power and Motor leads ...................................... 34

Lines and Motor Cable Installation ..................... 34

Input protection ................................................... 34

Brake Chopper Connection ................................ 34

Cable Routing ..................................................... 35

Wiring the VFD ................................................... 35

Power and Ground wiring ................................... 35

Ground Wiring .................................................... 36

Control Wiring ..................................................... 37

Wiring Diagram and I/O Connections ................. 37

Line and Motor Connections .................................. 38

Checking the cable and motor insulation ........... 40

Bypass Operation ............................................... 41

Input Connections and Configuration ................. 42

Input Voltage and Frequency ............................. 42

Input Voltage Balance ........................................ 43

Total Harmonic Distortion (THD) ........................ 43

Reactive Power Compensation Devices ............ 43

EMC Installation ................................................. 43

EMC measures in the control panel ................... 44

Earthing .............................................................. 44

Screen Earth Kit ................................................. 44

Installation in corner-grounded network and IT

system ................................................................ 44

Mounting and Space Requirements ....................... 47

Standard Mounting Instructions .............................. 47

DRIVE SELECTION ................................................... 49

General Drive Sizing ............................................... 49

Compressors ...................................................... 49

Pumps and Fans ................................................ 52

STARTUP AND COMMISSIONING ........................... 51

Startup Wizard Page .............................................. 51

Startup Wizard ........................................................ 51

PID and Advanced Application Mini-Wizard ........... 54

COMMUNICATION .................................................... 54

Communication Features ....................................... 54

Optional Communication Cards ............................. 54

Modbus RTU ..........................................................

Modbus RTU Specifications ............................... 55

Network and Module Status Lights ......................... 56

May 2024

54

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Summary of Contents for Copeland EVH Series

Page 1: Table Of Contents
AE8-1466 May 2024 EVH Series Three Phase Variable Frequency Drives 208-230V, 480V, 575V, 1 to 250HP TABLE OF CONTENTS SAFETY INSTRUCTIONS ......... 4 Real Time Clock (RTC) Battery Activation ..... 30 Safety Icon Explanation ......... 5 GENERAL INSTALLATION ........31 Drive Safety Information ........
Page 2 Table 14 Input and Output Specifications ........................41 Table 15 Space and Cooling Air Requirements ......................52 Table 18 Approved Frequency for Copeland™ Fixed Speed Compressors .............. 54 Table 19 Communication Features ..........................58 Table 20 Communication Board Connections ......................59...
Page 3 Mounting Instructions Appendix E Circuit Breaker Sizing / Cable and Fuse Guidelines Appendix F Quick Start Guide Appendix G Troubleshooting & Fault Codes Appendix H Modbus RTU Commissioning Appendix I Temperature Derating Appendix J EVH Accessories © 2024 Copeland LP.
Page 4: Safety Instructions
SAFETY INSTRUCTIONS Copeland™ products are manufactured according to the latest U.S. and European Safety Standards. Particular emphasis has been placed on the user's safety. Safety icons are explained below. You are strongly advised to follow these safety instructions. Safety Icon Explanation...
Page 5: Drive Safety Information
Due to the states even for a short time. If necessary, charge in the capacitors, these parts may still be emergency-stop devices should be implemented. live after disconnection. Fit appropriate warning signs. © 2024 Copeland LP.
Page 6: Other Important Safety Information
WARNING With the Auto Restart function activated, the • • The components of the power unit of EVH Series motor will restart automatically after an automatic are live when the AC drive is connected to mains fault is reset. potential. Coming into contact with this voltage is Do not perform any measurements when the AC •...
Page 7: Additional Information
Ignoring this procedure may result in a damaged product. Common Abbreviations Abbreviation Definition Variable torque with low overload rating (110%) Low overload Current (110%) Variable frequency drive Online Product Information Relative Humidity © 2024 Copeland LP.
Page 8: Introduction
● Two expansion slots - intended to support additional I/O or communication protocols as necessary ● Quick disconnect terminals for I/O connections - supports fast, easy installation ● Copeland™ Energy Control - minimizes energy losses in the motor, resulting in industry-leading energy efficiency for your application ● Energy savings calculator ●...
Page 9: Standards And Certifications
Output Voltage Size Current 12 amps 31 amps 61 amps 208V, 480V, 575V 208V, 480V, 575V Three-phase Three-phase 114 amps 211 amps 312 amps See Appendix A for the complete list of drive and their corresponding ratings. © 2024 Copeland LP.
Page 10: Technical Data And Specifications
100% continuous maximum rating Ambient operating –10 °C (-30°C with Cold Weather Mode Enabled) to +50 °C, Ambient temperature up to +60 C with derating conditions Storage temperature –40 °C to +70 °C Relative humidity 0–95% RH, noncondensing, non-corrosive © 2024 Copeland LP.
Page 11: Ambient Conditions
230 V drives: 456 V 480 V drives: 911 V 575 V drives: 1100 V Safety/protections Undervoltage protection Undervoltage trip 230 V drives: 211 V limit 480 V drives: 370 V 575 V drives: 550 V © 2024 Copeland LP.
Page 12 Yes (differential mode 2 kV; common mode 4 kV 230 V drives: 275 Vac, 10,000 A 480 V drives: 320 Vac, 8000 A 575 V drives: 385 Vac, 10,000 A Common coated Yes (prevents corrosion) boards © 2024 Copeland LP.
Page 13: Drive Dimensions
Size (lbs) 12.9 12.3 11.5 14.3 16.5 16.0 15.0 23.4 10.4 22.0 21.5 20.4 49.8 11.6 24.8 24.3 23.3 77.5 13.4 35.0 29.7 27.8 11.3 11.1 154.3 14.6 40.8 33.3 31.4 19.1 18.9 15.8 15.8 247.0 © 2024 Copeland LP.
Page 14: Control Board Layout
The EVH drive control board layout is shown on Figure 3. Figure 3 EVH Control Board Layout Safe Torque Off (STO) RJ45 to Serial Connection Port Note: This is a representation showing location of items. Location may be slightly different depending on frame size. © 2024 Copeland LP.
Page 15: Keypad Overview
• Cancels Modify in edit mode. • Resets the active faults (all the active faults shall be reset by pressing this button more than 2 seconds in any page). • Pressing Back/Reset takes you to Default Page. © 2024 Copeland LP.
Page 16 • This button operates as motor start button for normal operation when the “Keypad” is selected as the active START control source. When Keypad is the reference place after hitting the start button, it will jump directly to the Keypad Ref Screen. © 2024 Copeland LP.
Page 17: Keypad Led Indicator
Turn on when there is one or more active drive fault(s). Note: Must hit auto and run twice to switch to manual input - allows user to enter run frequency Keypad Menu Navigation Figure 6 Keypad Menu Navigation © 2024 Copeland LP.
Page 18: Keypad Lcd Display
“FLT”; If operation menu, then display “OPE”; If quick start wizard, then display “QSW”; If optional card menu, then display “BOA”; If favorite menu, then display “FAV”; If main menu, then display “TPM”. “BUx” indicates the drive being a backup drive when in the redundant drive system. © 2024 Copeland LP.
Page 19: Welcome Page
Figure 10. keys “DELETE” and “BYPASS” shall be shown, and “DELETE” means you can delete the Figure 10 Auto Backup Page selected parameter from favorite list. Figure 13 Favorite Menu © 2024 Copeland LP.
Page 20: Menu Overview
In monitor page, user shall not be able to edit the parameters except multi-monitor parameter. Multi-monitor parameters allow for displaying 3 monitor values on display. The three values can be changed to any of the listed values. © 2024 Copeland LP.
Page 21: Menu Structure
Back key is pressed, it returns to the last level menu. In pop-up faults page, it returns to the last page. Fault History In any page, OK button is used to clear all the active faults and fault history by pressing more than 5s without password. 10 latest faults are stored in the Fault history. © 2024 Copeland LP.
Page 22: Fault Log
Fault Log The Fault Log will store the last 50 faults in it with 1 being the most recent and 50 being the oldest. Only the fault code, name and time stamp are stored with these faults. P-Parameter The navigation for the parameter menu. In parameter page, the parameter code shall be shown in the second line (such as P1.1).
Page 23: Figure 15 Up To Keypad And Down From Keypad
3 seconds, the page shall return to the parameter read page. If the password is in use, and user inputs the right password, then the value shall flash, which indicates that it can be edited. © 2024 Copeland LP.
Page 24: Value Edit
“DELETE” will be shown. This allows you to remove the selected parameter from favorite list. After one parameter is removed from favorite list, the next parameter in the favorite list will be selected by default. © 2024 Copeland LP.
Page 25: Basic Application
It provides full customization on the motor control sequence with the ability to be in frequency or speed control mode and tuning of the V/Hz curve can be selected. Drive/Motor protections can be customized to defined actions for added user control. © 2024 Copeland LP.
Page 26: Advance Application
Bump-less transition between Hand and Auto* Start source (Local/Remote control function) • • Drooping* Reference source • • * added parameters vs. Basic Application See Appendix B for the complete list of parameters for Advanced Application. © 2024 Copeland LP.
Page 27: I/O Controls
8 Digital inputs on the Main control board. Example: If we set Run Enable to DigIN:6 the drive will be enabled when digital input 6 (Terminal 8) is closed, and would not be enabled when digital input 6 (Terminal 8) is open. © 2024 Copeland LP.
Page 28: Safe Torque Off (Sto) Function
STO function. If the function is used by customer, the STO terminal block shall be connected to emergency stop switch, safety relay or PLC, and so on. The STO function needs to be always on, which means the idle-current principle shall be followed by the end user. © 2024 Copeland LP.
Page 29: Figure 18 Sto Terminal Location
Figure 18 STO Terminal Location *Remove Keypad to access RJ45 to Serial communications Figure 19 STO wiring diagram © 2024 Copeland LP.
Page 30: Receiving And Inspection
Real Time Clock (RTC) Battery Activation To activate the real time clock (RTC) functionality in the EVH Series drive, the RTC battery (already mounted in the drive) must be connected to the control board. Simply remove the primary drive cover, locate the RTC battery directly below the keypad, and connect the white 2-wire connector to the receptacle on the control board.
Page 31: General Installation
Table 12. Figure 32 shows the installation overview for EVH drives. Table 12 Drive System Components ITEM DESCRIPTION Power Grid Breaker, Fuses, Cable Cross Sections Residual-Current Protective Devices Input Contactor Frequency Inverter Output Contactor Output Reactor Motor Protection Motor Cables Motor © 2024 Copeland LP.
Page 32: Figure 22 Drive System
Figure 22 Drive System © 2024 Copeland LP.
Page 33: Figure 23 Evh Installation Overview
Figure 23 EVH Installation Overview © 2024 Copeland LP.
Page 34: Electrical Installation
Dynamic braking resistor connections are made to the R+ and R- terminal on the drive. Wire size should be followed according to the wattage being transferred. Below are images of the locations for wiring. Figure 24 Brake Resistor Wiring © 2024 Copeland LP.
Page 35: Cable Routing
To meet the UL requirements, if conduit is being used for wiring, the enclosure openings provided for conduit connections in the field shall be closed by UL listed conduit fittings with the same type rating (Type 1/ Type 12) as the enclosure. © 2024 Copeland LP.
Page 36: Ground Wiring
Provide dedicated wire for low impedance ground between drive and motor as shown on Figure 35. DO NOT USE conduit as ground Figure 26 Drive Grounding NOTICE Improper grounding could result in damage to the motor and/or drive and could void warranty. © 2024 Copeland LP.
Page 37: Control Wiring
• Control I/O terminals must be tightened to 4.5 in-lb (0.5 Nm) • Wiring or ferrule size: 28~12 (Sol) AWG, 30~12 (Str) AWG, or 0.2~2.5 mm2 Figure 27 Unplugging the board terminal blocks Figure 28 Terminal Block Layout © 2024 Copeland LP.
Page 38: Line And Motor Connections
CMB and close the inputs to ground. When using the +10 V for AI1, it is important to wire AI1—ground (as shown by dashed line). If using +10 V for AI1 or AI2, terminals 3, 5, and 6 need to be jumpered together. AI1+ and AI2+ Support 10K potentiometer. © 2024 Copeland LP.
Page 39: Figure 30 Line And Motor Connections
On the drive, there are two grounding clamp connections located on each side. Different type of screws and corresponding torque values used for grounding clamps are shown on Figure 40. Figure 31 Grounding Screws and Torque Values © 2024 Copeland LP.
Page 40: Checking The Cable And Motor Insulation
After having performed the change write “EMC level modified” on the sticker included in the EVH Series delivery (see Figure 41) and note the date. Unless already done, attach the sticker close to the name plate of the drive.
Page 41: Bypass Operation
If an option to operate the motor with the VFD or directly from the input supply is required, the input branches must be interlocked mechanically. Figure 42 shows and example of a typical bypass motor control circuit. *DO NOT apply direct line voltage to any Copeland Variable Speed compressor (BPM motors). Immediate motor damage will result. NOTICE Debounced inputs may not be used in the safety circuit diagram.
Page 42: Input Connections And Configuration
AC-3 for the rated operational current of the motor. Input Connections and Configuration The EVH series drives can be connected and operated with all control-point grounded AC power networks as shown on Figure 43. Figure 34 AC power networks types The EVH drive can be applied to all types of power networks above.
Page 43: Input Voltage Balance
The technology and system of a frequency inverter cause the flow of high frequency leakage current during operation. All grounding measures must therefore be implemented with low impedance connections over a large surface area. With leakage currents greater than 3.5 mA, in accordance with VDE 0160 or EN 61800-5-1, either © 2024 Copeland LP.
Page 44: Emc Measures In The Control Panel
EMC screws with a simple procedure described below. In addition, on FR2 and FR4 the MOV screw is required to be removed. WARNING Do not perform any modifications on the AC drive when it is connected to mains. © 2024 Copeland LP.
Page 45: Figure 35 Emc Compliant Setup
Remove the main cover of the drive and remove the EMC/MOV screws depending on frame size (see Figure 45 to Figure 47). Once the screw is removed, it can be reconnected to re-engage the EMC protection. Figure 35 EMC Compliant Setup © 2024 Copeland LP.
Page 46: Figure 36 Location Of The Emc And Mov Screws In Fr2
(PES). Large-area cable shield contacts with motor. Large area earth connection of all metallic parts. Figure 36 Location of the EMC and MOV screws in FR2 and FR4 Figure 37 Location of the EMC screw in FR1 and FR3 © 2024 Copeland LP.
Page 47: Mounting And Space Requirements
Select the mounting location based on requirements listed in this chapter • Mounting surface must be a flat, non-flammable surface. EVH Series drives may be mounted side-by-side or stacked vertically • Surface must be strong enough to support the drive and not subject to excessive motion or vibration •...
Page 48: Table 15 Space And Cooling Air Requirements
480 and 575 V: 400 (679) NOTICE The above guidelines apply unless testing has been completed to validate a design outside of these recommendations. Minimum clearances A and B for drives with Type 12 (IP54) enclosure is 0 mm (in). © 2024 Copeland LP.
Page 49: Drive Selection
*For Permanent Magnet Scrolls (BPM) , please reach out to your Copeland Rep General Drive Sizing For the Copeland™ EVM series VFD the follow sizing recommendations should be followed to pick the proper variable frequency drives for the application. This will make sure the drive has enough power for the application and it also follows the NEC guidelines.
Page 50: Frequency Range
Table 16 Approved Frequency for Copeland™ Fixed Speed Compressors Compressor Family Frequency Range 25 hz to 60 hz 4MSLS 4MTLS ZB*KA ZF*KA ZS*KA ZS*KA ZB*K5 Ref K5 ZF*K5 Ref K5 45 hz to 60 hz ZF*K4 Quantum ZS*K4 Quantum ZB*KA Quest...
Page 51: Pumps And Fans
Make sure to plug in the Real Time Clock (RTC) during EVH start up (see the Figure 29). Startup Wizard In the Start-up Wizard, you will be prompted for essential information needed by the drive so that it can start controlling your process. In the Wizard, you will need the following keypad buttons: © 2024 Copeland LP.
Page 52 Follow these instructions to easily set up your device. Once you have connected power to your Copeland EVH drive the Startup Wizard is enabled. ITEM DESCRIPTION Startup Wizard Press OK? Application 0 = basic 1 = PID 2 = Advanced...
Page 53 12 = AI2 - AI1 13 = AI1 * AI2 14 = AI1 or AI2 15 = Min(AI1,AI2) 16 = Max(AI1,AI2) PID1 Control Output PID2 Control Output Bypass Enabled 0 = Disabled 1 = Enabled Application Mini-Wizard Press OK? © 2024 Copeland LP.
Page 54: Pid And Advanced Application Mini-Wizard
This addressing is executed individually for each VFD via the communication parameters. The electrical connection between master and the slaves connected in parallel are implemented via the serial interface A-B (A = positive, B = negative) with a shielded RS-485 twisted pair cable. © 2024 Copeland LP.
Page 55: Modbus Rtu Specifications
The RS-485 communication port is connected via the A and B terminals (terminal 25/26) on the drives control board as shown on Figure 49. Shielding and installation of terminal resistor is shown on Figure 50. Figure 40 Terminal Wiring © 2024 Copeland LP.
Page 56: Network And Module Status Lights
Figure 42 Location of Network and Module Status LED Table 19 Network and Module LED Network Status Module Status Green Connected Operating / Standby Major Fault Minor/Major Fault Flashing Green No Connection Flashing Red Communication Timed Out © 2024 Copeland LP.
Page 57: Maintenance And Inspection
The contents of this publication are presented for informational purposes only and are not to be construed as warranties or guarantees, express or implied, regarding the products or services described herein or their use or applicability. Copeland and/or its affiliates (collectively "Copeland LP"), as applicable, reserve the right to modify the design or specifications of such products at any time without notice.
Page 58: Appendix A: Evh Models List
APPENDIX A: EVH Models List Frame IP Output Output Input Input Output Size Rating Model Number Current Phase Voltage Voltage EVH‐3224D8‐R21BDN 0.75 3Ø 208‐240v 208‐240v EVH‐3224D8‐R21BEN 0.75 3Ø 208‐240v 208‐240v EVH‐3226D6‐R21BDN 3Ø 208‐240v 208‐240v EVH‐3226D6‐R21BEN 3Ø 208‐240v 208‐240v EVH‐3227D8‐R21BDN 3Ø 208‐240v 208‐240v EVH‐3227D8‐R21BEN 3Ø...
Page 59: Table 20 Communication Board Connections
APPENDIX A: EVH Models List Frame IP Output Output Input Input Output Size Rating Model Number Current Phase Voltage Voltage EVH‐3445D6‐R54BEN 3Ø 380‐480v 380‐480v EVH‐3447D6‐R54BDN 3Ø 380‐480v 380‐480v EVH‐3447D6‐R54BEN 3Ø 380‐480v 380‐480v EVH‐344009‐R54BDN 3Ø 380‐480v 380‐480v EVH‐344009‐R54BEN 3Ø 380‐480v 380‐480v EVH‐3554D5‐R54BDN 3Ø...
Page 60 APPENDIX A: EVH Models List Frame IP Output Output Input Input Output Size Rating Model Number Current Phase Voltage Voltage EVH‐355022‐R21BEN 3Ø 525‐600v 525‐600v EVH‐355022‐R21BEN 3Ø 525‐600v 525‐600v EVH‐355013‐R54BDN 3Ø 525‐600v 525‐600v EVH‐355013‐R54BEN 3Ø 525‐600v 525‐600v EVH‐355018‐R54BDN 3Ø 525‐600v 525‐600v EVH‐355018‐R54BEN 3Ø...
Page 61 APPENDIX A: EVH Models List Frame IP Output Output Input Input Output Size Rating Model Number Current Phase Voltage Voltage EVH‐322075‐R21BDN 18.5 3Ø 208‐240v 208‐240v EVH‐322075‐R21BEN 18.5 3Ø 208‐240v 208‐240v EVH‐322088‐R21BDN 3Ø 208‐240v 208‐240v EVH‐322088‐R21BEN 3Ø 208‐240v 208‐240v EVH‐322114‐R21BDN 3Ø 208‐240v 208‐240v EVH‐322114‐R21BEN 3Ø...
Page 62 APPENDIX A: EVH Models List EVH‐322170‐R54BDN 3Ø 208‐240v 208‐240v EVH‐322170‐R54BEN 3Ø 208‐240v 208‐240v EVH‐322211‐R54BDN 3Ø 208‐240v 208‐240v EVH‐322211‐R54BEN 3Ø 208‐240v 208‐240v EVH‐344140‐R21BDN 3Ø 380‐480v 380‐480v EVH‐344140‐R21BEN 3Ø 380‐480v 380‐480v EVH‐344170‐R21BDN 3Ø 380‐480v 380‐480v EVH‐344170‐R21BEN 3Ø 380‐480v 380‐480v EVH‐344205‐R21BDN 3Ø 380‐480v 380‐480v EVH‐344205‐R21BEN 3Ø...
Page 63 APPENDIX A: EVH Models List Frame IP Output Output Input Input Output Size Rating Model Number Current Phase Voltage Voltage EVH‐355208‐R21BDN 3Ø 525‐600v 525‐600v EVH‐355208‐R21BEN 3Ø 525‐600v 525‐600v EVH‐355250‐R21BDN 3Ø 525‐600v 525‐600v EVH‐355250‐R21BEN 3Ø 525‐600v 525‐600v EVH‐355208‐R54BDN 3Ø 525‐600v 525‐600v EVH‐355208‐R54BEN 3Ø...
Page 64 APPENDIX A: EVH Models List Frame IP Output Output Input Input Output Size Rating Model Number Current Phase Voltage Voltage EVH‐355010‐R21BDB 3Ø 525‐600v 525‐600v EVH‐355013‐R21BDB 3Ø 525‐600v 525‐600v EVH‐3226D6‐R21BDB 3Ø 200‐240v 200‐240v EVH‐3227D8‐R21BDB 3Ø 200‐240v 200‐240v EVH‐3443D3‐R21BDB 3Ø 380‐480v 380‐480v EVH‐3444D6‐R21BDB 3Ø...
Page 65 APPENDIX A: EVH Models List Frame IP Output Output Input Input Output Size Rating Model Number Current Phase Voltage Voltage EVH‐3557D5‐R54BDB 3Ø 525‐600v 525‐600v EVH‐355010‐R54BDB 3Ø 525‐600v 525‐600v EVH‐355013‐R54BDB 3Ø 525‐600v 525‐600v EVH‐355018‐R54BDB 3Ø 525‐600v 525‐600v EVH‐355022‐R54BDB 3Ø 525‐600v 525‐600v EVH‐355027‐R54BDB 18.5 3Ø...
Page 66: Appendix B: Monitor And Operate Mode Parameters
Appendix B: Monitor and Operate Mode Parameters Parameters List On the next pages you will find the lists of parameters within the respective parameter groups. The parameter descriptions are given in Appendix C. The descriptions are arranged according to the parameter number. Column explanations: Code = Location indication on the keypad;...
Page 67 Appendix B: Monitor and Operate Mode Parameters Table 148. Optional Boards — M3 Code Parameter Min. Max. Unit Default Note M3.1 PT100 Temperature Deg. C 1000.0 Table 149. Energy Savings — M4 Code Parameter Min. Max. Unit Default Note M4.1 Energy Savings Varies 0.000...
Page 68 Appendix B: Monitor and Operate Mode Parameters FB Monitor Menu — M5, continued Code Parameter Min. Max. Unit Default Note M5.4 Application Status Bit 0 = MC_Ready Bit 8 = IO Control Indicator Word Bit 1 = MC_Run Bit 9 = Panel Control Indicator Bit 2 = MC_Fault or Fault Trip Bit 10 = Panel Fieldbus Control Indicator Bit 3 = FB_Ref_Active...
Page 69 Appendix B: Monitor and Operate Mode Parameters Table 152. Timer/Interval Control — M7 Code Parameter Min. Max. Unit Default Note M7.1 TC1, TC2, TC3 M7.2 Interval 1 0 = Inactive 1 = Active M7.3 Interval 2 See Par ID 559 M7.4 Interval 3 See Par ID 559...
Page 70 Appendix B: Monitor and Operate Mode Parameters Parameters — P1 Code Parameter Min. Max. Unit Default Note 0 = AI1 11 = AI1 - AI2 P1.12 Hand Reference 1 = AI2 12 = AI2 - AI1 2 = Slot A: AI1 13 = AI1 * AI2 3 = Slot B: AI1 14 = AI1 or AI2...
Page 71 Appendix B: Monitor and Operate Mode Parameters Digital Input — P2.2 continued Code Parameter Min. Max. Unit Default Note 18 = DigIN: A: IO5: 6 P2.2.2 IO Terminal 1 Start Signal 1 0 = DigIN:NormallyOpen 19 = DigIN: B: IO1: 1 1 = DigIN:NormallyClose 20 = DigIN: B: IO1: 2 2 = DigIN: 1...
Page 72 Appendix B: Monitor and Operate Mode Parameters Digital Input — P2.2, continued Code Parameter Min. Max. Unit Default Note P2.2.25 Accel/Decel Prohibit See Par ID 190 P2.2.26 No Access To Param See Par ID 190 P2.2.27 Auto Control See Par ID 190 P2.2.28 Hand Control See Par ID 190...
Page 73 Appendix B: Monitor and Operate Mode Parameters AI1 Settings — P2.4 Code Parameter Min. Max. Unit Default Note P2.4.1 AI1 Mode 0 = 0 - 20 mA 1 = 0 -10 V P2.4.2 AI1 Signal Range 0 = 0-100%/0-20mA/0-10V 1 = 20-100%/4-20mA/2-10V 2 = Customized P2.4.3 AI1 Custom Min...
Page 74 Appendix B: Monitor and Operate Mode Parameters Outputs Digital Output — P3.1 Code Parameter Min. Max. Unit Default Note P3.1.1 DO1 Function 0 = Not Used 1 = Ready 2 = Run 3 = Fault 4 = Fault Invert 5 = Warning 6 = Reversed 7 = At Speed 8 = Zero Frequency...
Page 75 Appendix B: Monitor and Operate Mode Parameters Digital Output — P3.1, continued Code Parameter Min. Max. Unit Default Note P3.1.2 RO1 Function See Par ID 151 P3.1.3 RO1 On Delay 320.0 2112 P3.1.4 RO1 Off Delay 320.0 2113 P3.1.5 RO2 Function See Par ID 151 P3.1.6 RO2 On Delay...
Page 76 Appendix B: Monitor and Operate Mode Parameters Supervisions — P3.2 Continued Code Parameter Min. Max. Unit Default Note P3.2.31 Second AI Limit Supv Val 0.00 100.00 0.00 2195 P3.2.32 Second AI Supv Hyst 0.00 10.00 1.00 2199 P3.2.33 PID1 Superv Enable 1346 0 = Disabled 1 = Enabled...
Page 77 Appendix B: Monitor and Operate Mode Parameters Analog Output 2 — P3.4 Code Parameter Min. Max. Unit Default Note P3.4.1 AO2 Mode See Par ID 222 P3.4.2 AO2 Function See Par ID 146 P3.4.3 AO2 Minimum See Par ID 149 P3.4.4 AO2 Filter Time 0.00...
Page 78: Drive Control
Appendix B: Monitor and Operate Mode Parameters Drive Control P4.1 Code Parameter Min. Max. Unit Default Note P4.1.1 Keypad Reference See Par ID 101 See Par ID 102 20.00 P4.1.2 Keypad Direction 0 = Forward 1 = Reverse P4.1.3 Keypad Stop 0 = Enabled-Keypad Operation 1 = Always Enabled P4.1.4...
Page 79: Motor Control
Appendix B: Monitor and Operate Mode Parameters Energy Savings Calc — P4.4 Code Parameter Min. Max. Unit Default Note P4.4.1 Currency 2122 0 = $ 1 = £ 2 = € 3 = ¥ 4 = Rs 5 = R$ 6 = Fr 7 = kr P4.4.2...
Page 80 Appendix B: Monitor and Operate Mode Parameters P5.1 Continued Code Parameter Min. Max. Unit Default Note P5.1.12 OverVoltage Control See Par ID 1346 P5.1.13 Load Drooping 0.00 100.00 0.00 P5.1.14 Droop Control Filter 3000 1630 Time Constant P5.1.15 Overmodulation Enable 2835 P5.1.16 Speed Control Kp0...
Page 81 Appendix B: Monitor and Operate Mode Parameters Second Motor Parameter — P5.2 Code Parameter Min. Max. Unit Default Note DriveNom DriveNom P5.2.1 Motor Nom Current 2 DriveNomCurrVT 577 CurrCT*1/10 CurrCT*2 P5.2.2 Motor Nom Speed 2 20000 Varies P5.2.3 Motor PF 2 0.30 1.00 0.85...
Page 82 Appendix B: Monitor and Operate Mode Parameters Motor — P6.1, continued Code Parameter Min. Max. Unit Default Note P6.1.18 Preheat Control Source 2160 10 = DigIN: A: IO1: 1 11 = DigIN: A: IO1: 2 12 = DigIN: A: IO1: 3 13 = DigIN: A: IO5: 1 14 = DigIN: A: IO5: 2 15 = DigIN: A: IO5: 3...
Page 83 Appendix B: Monitor and Operate Mode Parameters Drive — P6.2 Continued Code Parameter Min. Max. Unit Default Note P6.2.4 4mA Fault Frequency 0.00 See Par ID 102 0.00 P6.2.5 External Fault See Par ID 308 P6.2.6 Input Phase Fault See Par ID 308 P6.2.7 Uvolt Fault Response See Par ID 308...
Page 84: Pid Controller
Appendix B: Monitor and Operate Mode Parameters PID Controller 1 Basic Setting — P7.1 Code Parameter Min. Max. Unit Default Note PID1 Control Gain 0.00 200.00 100.00 1294 P7.1.1 P7.1.2 PID1 Control ITime 0.00 600.00 1.00 1295 P7.1.3 PID1 Control DTime 0.00 100.00 0.00...
Page 85 Appendix B: Monitor and Operate Mode Parameters Monitor — P7.2 Code Parameter Min. Max. Unit Default Note P7.2.1 FB PID1 Set Point 1 See Par ID 1298 See Par ID 1300 Varies 2542 P7.2.2 FB PID1 Set Point 2 See Par ID 1298 See Par ID 1300 Varies 2544 P7.2.3 FB PID1 Feedback 1...
Page 86 Appendix B: Monitor and Operate Mode Parameters Setpoint 2 — P7.3.3 Code Parameter Min. Max. Unit Default Note P7.3.3.1 PID1 Set Point 2 Source 1321 0 = Not Used P7.3.3.2 PID1 Set Point 2 Min -200.00 200.00 0.00 1322 P7.3.3.3 PID1 Set Point 2 Max -200.00 200.00...
Page 87 Appendix B: Monitor and Operate Mode Parameters Feedback 2 — P7.4.3 Code Parameter Min. Max. Unit Default Note P7.4.3.1 PID1 Feedback 2 Source 1335 See Par ID 1332 P7.4.3.2 PID1 Feedback 2 Min -200.00 200.00 0.00 1336 P7.4.3.3 PID1 Feedback 2 Max -200.00 200.00 100.00...
Page 88 Appendix B: Monitor and Operate Mode Parameters PID Controller 2 Basic Setting — P8.1 Code Parameter Min. Max. Unit Default Note P8.1.1 PID2 Control Gain 0.00 200.00 100.00 1356 P8.1.2 PID2 Control I Time 0.00 600.00 1.00 1357 P8.1.3 PID2 Control D Time 0.00 100.00 0.00...
Page 89 Appendix B: Monitor and Operate Mode Parameters Setpoint 1 — P8.3.2, continued Code Parameter Min. Max. Unit Default Note P8.3.2.6 PID2 Set Point 1 Sleep Level Varies 0.00 2454 P8.3.2.7 PID2 Set Point 1 Sleep Delay 3000 1379 P8.3.2.8 PID2 Set Point 1 WakeUp -99999.99 99999.99 Varies...
Page 90 Appendix B: Monitor and Operate Mode Parameters Feedback 2 — P8.4.3 Code Parameter Min. Max. Unit Default Note P8.4.3.1 PID2 Feedback 2 Source 1397 See Par ID 1394 P8.4.3.2 PID2 Feedback 2 Min -200.00 200.00 0.00 1398 P8.4.3.3 PID2 Feedback 2 Max -200.00 200.00 100.00...
Page 91: Real Time Clock
Appendix B: Monitor and Operate Mode Parameters Bypass P10.1 Code Parameter Min. Max. Unit Default Note P10.1.1 Bypass Enable 1418 See Par ID 1346 P10.1.2 Bypass Start Delay 32765 P10.1.3 Auto Bypass See Par ID 1346 P10.1.4 Auto Bypass Delay 32765 P10.1.5 OverCurrent Bypass Enable...
Page 92 Appendix B: Monitor and Operate Mode Parameters Interval 2 — P11.2 Code Parameter Min. Max. Unit Default Note P11.2.1 Interval 2 Setting 2488 See Par ID 2487 P11.2.2 Interval 2 On Time P11.2.3 Interval 2 Off Time P11.2.4 Interval 2 From Day See Par ID 517 P11.2.5 Interval 2 To Day...
Page 93 Appendix B: Monitor and Operate Mode Parameters Communication FB Process Data Input Sel — P12.1 Code Parameter Min. Max. Unit Default Note P12.1.1 FB Process Data Input 1 Sel 3000 2533 P12.1.2 FB Process Data Input 2 Sel 2560 2542 2534 P12.1.3 FB Process Data Input 3 Sel...
Page 94 Appendix B: Monitor and Operate Mode Parameters FB Process Data Output Sel — P12.2, continued Code Parameter Min. Max. Unit Default Note P12.2.9 Standard Status Word Bit0 2415 60 = Run Bypass/Drive Function Select (cont.) 61 = Bypass Overload 62 = Bypass Run 63 = Auto Local On COM Fault 64 = Fieldbus RTU Fault 65 = Fieldbus TCP Fault...
Page 95 Appendix B: Monitor and Operate Mode Parameters BACnet MS/TP — P12.3.3 Code Parameter Min. Max. Unit Default Note P12.3.3.1 MSTP Baud Rate 0 = 9600 1 = 19200 2 = 38400 3 = 76800 4 = 115200 P12.3.3.2 MSTP Device Address P12.3.3.3 MSTP Instance Number 4194302...
Page 96 Appendix B: Monitor and Operate Mode Parameters BACnet IP — P12.4.3 Code Parameter Min. Max. Unit Default Note P12.4.3.1 BACnet IP UDP port number 47808 1733 47808 = BAC0 47809 = BAC1 47810 = BAC2 47811 = BAC3 47812 = BAC4 47813 = BAC5 47814 = BAC6 47815 = BAC7...
Page 97 Appendix B: Monitor and Operate Mode Parameters P13.1, continued Code Parameter Min. Max. Unit Default Note P13.1.5 Down From Keypad 0 = No 1 = All Parameters 2 = All, No Motor 3 = App Parameters P13.1.6 Parameter Comparison 0 = No 1 = Compare with Keypad 2 = Compare with Default 3 = Compare with Set 1...
Page 98 Appendix B: Monitor and Operate Mode Parameters P13.1, continued Code Parameter Min. Max. Unit Default Note P13.1.21 Output Display Unit Min -60000.00 See Par ID 2425 Varies 0.00 2460 P13.1.22 Output Display Unit Max See Par ID 2460 60000.00 Varies Varies 2425 P13.1.23...
Page 99: Application Level
Appendix C: Description of Parameters On the following pages you will find the parameter Column Explanations: descriptions arranged according to the parameter number. Code = Location indication on the keypad; shows the operator Some parameter names are followed by a number code the preset number indicating the applications in which the parameter is included.
Page 100: Motor Parameters From Ratings Plate
Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW Motor Nom Current DriveNomCurrCT*1/10 DriveNomCurrCT*2 DriveNomCurrCT P1.5 1,2,3 Use this parameter to set the Motor rated current. Motor parameters from ratings plate P1.8 P1.5 230/400V 4.0/2.3A cos 0.67 0.75 kW 1410 min –1...
Page 101 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P1.13 Auto 1 Control Place 1,2,3 Selects where the drive will look for the start command in the "Auto 1" location. • I/O terminal Start 1 and 2 would be from the Digital hardwired inputs assigned via the input group •...
Page 102 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P1.17 2840 Frequency reference upper limit 1,2,3 The max value of Frequency reference, it is used to limit the value of Frequency reference. P1.18 2841 Frequency reference upper limit source 1,2,3 Frequency reference upper limit source select 0 = Not Used...
Page 103 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW 0.00 400.00 0.00 AI Ref Scale Max Value P2.1.5 1,2,3 Max Frequency when max of Analog Reference is applied. With values set at 0 scaling will follow the maximum frequency value parameter Para ID 102.
Page 104 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P2.2.1 1 = Para ID 190: DI closed contact = start /open contact = stop Para ID 191: DI closed contact = reverse / open 1,2,3 contact = forward - This would be considered 2 wire control with a contact on start/stop, contact open it stops and direction on 2nd start signal.
Page 105 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P2.2.1 3 = Three-wire connection (pulse control): Para ID 190: DI changes from open to closed = start pulse Para ID 1,2,3 191: DI changes from closed to open = stop pulse Para ID 198: DI closed contact = reverse/ open contact = forward - This would be considered 3 wire control with Start Signal 1 being the Start Pulse and Start Signal 2 being the NC Stop.
Page 106 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW IO Terminal 2 Start Stop Logic P2.2.4 2206 1,2,3 This parameter defines the start and stop of the drive with the digital signals. 0 = Para ID 2207: DI closed contact = start forward Para ID 2208: DI closed contact = start reverse - This would be considered 2 wire control with either a contact used on the Start FWD or Start REV commands.
Page 107 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P2.2.4 2206 2 = Para ID 2207: DI closed contact = start / open contact = stop Para ID 2208: DI closed contact = start 1,2,3 enabled / open contact = start disabled and drive stopped if running Motor direction keeps forward - This would be considered 3 wire control with Start signal 2 required to be closed to enable Start on Start signal 1.
Page 108 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P2.2.9 Ext. Fault 1 NO 1,2,3 Use this parameter for setting external input causing drive to fault. This function is defined as NO so the function activates on a closed contact. If this function is assigned to Normally Open - the function is always off so the drive will not fault, when set to Normally Closed the function will be active and fault all the time.
Page 109 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW Ext. Fault 2 Text P2.2.14 2298 1,2,3 This parameter allows for the text to be changed when using external Fault 1 NO or NC. 0 = External Fault 1 = Vibration Cut Out 2 = High Motor Temp 3 = Low Pressure...
Page 110 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P2.2.19 Run Enable 1,2,3 Use this parameter for setting external safety start input that is required along with start command for frequency converter to turn on output. When using this command if the function is set for Normally Open, the drive will see this as a open input and not allow the drive to run due to no Ready.
Page 111 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P2.2.23 Jog Enable 1,2,3 Use this parameter for selecting an external input for enabling the jog frequency reference and starts the drive to slowly advance the system. When this function is set for Normally Open the drive will not follow the jog enable speed.
Page 112 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P2.2.30 2395 HOA On/Off 1,2,3 Use this parameter for setting external input for disabling any control signal when the input is the off/open position, when closed drive will follow the desired control signal. If the function is set for Normally Open this will cause the drive to operate, if the function is set for Normally Closed then the drive will e in the off location and not allow operation.
Page 113 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P2.2.37 PID2 Control Enable Use this parameter for selecting the digital input for turn on or off the PID2 controller. If the input is not enabled when starting the drive with PID1 Controller set as the reference the drive output will not start. Can be set to DigiIN:X indicates on board terminal inputs, DigiIN:A:IOX:X indicates optional board inputs in A slot, DigiIN:B:IOX:X indicates optional board inputs in B slot, or Timer Channel X.
Page 114 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P2.2.45 Start Timer 1 Use this parameter for selecting an external input for enabling the timer functions to begin counting. When this function is set for Normally Open the drive will not start the Timer sequence. If the function is set for Normally Close the Timer function will start.
Page 115 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW Preset Speed 5 0.00 See Par ID 102 25.00 P2.3.5 1,2,3 Use this parameter to set the Preset Frequency 5. Preset Speed 6 0.00 See Par ID 102 30.00 P2.3.6 1,2,3...
Page 116 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW AI1 Signal Range 0 P2.4.2 1,2,3 Configures the Analog input 1 signal source scaling. 0 = 0-100%/0-20mA/0-10V - 0-100% is equal to 0 to 10V, 0-20mA. 1 = 20-100%/4-20mA/2-10V - 20-100% is equal to 2 to 10V, 4-20mA. 2 = “Customized,”...
Page 117 Appendix C: Description of Parameters Unit Default Code Application RO/RW Modbus ID Parameter P2.4.6 AI1 Signal Invert 1,2,3 This parameter is used to invert the logic of the analog input. 0 No Inversion = no inversion of analog Vin signal takes place. 0V/0(4)mA = min frequency, 10V/20mA = max frequency 1 Inverted = inversion of analog signal takes place.
Page 118 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW AI1 Sleep Limit 0.00 100.00 0.00 P2.4.8 This parameter defines the sleep frequency level in the joystick control mode. The output of the drive turns off if the joystick reference stays below the sleep limit for longer than the sleep delay time parameter Para ID 180.
Page 119 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW AI2 3wire-current Standard I/O Board Terminal Signal 10V+ 10V supply AI1+ Analog input 1+ 3-wire transducer AI1- Analog input 1- Actual AI2+ Analog input 2+ Value − AI2- Analog input 2- I = (0)4...20mA POW...
Page 120 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW 0.00 10.00 0.10 P2.5.5 AI2 Filter Time 1,2,3 When this parameter is given a value greater than 0, the function that filters out disturbances from the incoming analog signal is activated. A long filtering time makes the regulation response slower.
Page 121 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P3.1.1 DO1 Function 1,2,3 Use this parameter to select signal to show the digital output. Setting Value Signal Content 0 = Not Used - Out of operation 1 = Ready - Frequency converter is ready for operation 2 = Run - frequency converter is operating (motor is running 3 = Fault - A fault trip has occurred...
Page 122 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P3.1.2 RO1 Function 1,2,3 Use this parameter to select signal to show the digital output. Setting Value Signal Content 0 = Not Used - Out of operation 1 = Ready - Frequency converter is ready for operation 2 = Run - frequency converter is operating (motor is running 3 = Fault - A fault trip has occurred...
Page 123 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P3.1.5 RO2 Function 1,2,3 Use this parameter to select signal to show the digital output. Setting Value Signal Content 0 = Not Used - Out of operation 1 = Ready - Frequency converter is ready for operation 2 = Run - frequency converter is operating (motor is running 3 = Fault - A fault trip has occurred...
Page 124 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P3.1.8 RO3 Function 1,2,3 Use this parameter to select signal to show the digital output. Setting Value Signal Content 0 = Not Used - Out of operation 1 = Ready - Frequency converter is ready for operation 2 = Run - frequency converter is operating (motor is running 3 = Fault - A fault trip has occurred...
Page 125 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P3.1.12 2463 Virtual RO1 Function 1,2,3 Use this parameter to select the function of output relay VO1. This relay is a internal relay that can be used to tie to internal functions in the drive.
Page 126 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P3.1.13 2464 Virtual RO2 Function 1,2,3 Use this parameter to select the function of output relay VO2. This relay is a internal relay that can be used to tie to internal functions in the drive.
Page 127: Supervision Function
Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P3.2.1 Freq Limit 1 Supv 1,2,3 Use this parameter to select how the frequency converter supervision controller functions as either a high or low limit based off the set supervision value. It can also be used to enabled an external brake control relay. 0 = No supervision 1 = Low limit supervision 2 = High limit supervision...
Page 128 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P3.2.10 Ref Limit Supv 1,2,3 Use this parameter to select how the frequency converter functions upon the reference supervision value being a high or low limit. 0 = No supervision 1 = Low limit supervision 2 = High limit supervision 0.00...
Page 129 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P3.2.23 2189 Motor Current 1 Supv 1,2,3 Use this parameter to select how the frequency converter functions based off the motor current supervision. The drive monitors the active motor current and based of this supervision will enable itself based off the supervision value.
Page 130 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P3.2.37 1408 PID2 Superv Enable Use this parameter to select enabling of the upper and lower limits around the reference are set. When the actual value goes above or below these, a counter starts counting up toward the Delay. When the actual value is within the allowed area, the same counter counts down instead.
Page 131: Analog Output Scaling
Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW 1000 P3.3.5 AO1 Scale 1,2,3 This parameter will scale the analog output function from 10% to 1000%, in adjusting this value it will either extend or shrink the scale on the analog signal from 0-10V/0-20mA or 2-10V/4-20mA. Analog output scaling Analog Output...
Page 132 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW 0.00 10.00 1.00 P3.4.4 AO2 Filter Time 1,2,3 Use this parameter to define the filtering time for the analog output signal, with a higher number the more filtering time is added on the output signal. Setting this parameter value to 0.00 will deactivate filtering.
Page 133 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW 32500 P4.1.9 2423 Run Delay Time 1,2,3 Run Delay time parameter sets the time required for the drive to wait before another run command can be received. During this time the run signal is given it is ignored until the time has expired upon which it will then start, in keypad, I/O, or fieldbus Control Modes.
Page 134: Appendix C: Description Of Parameters
Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P4.1.16 Power Loss Function 1,2,3 Use this parameter to enable or disable the power loss ride thru function. When enabled the drive will stop the output voltage to the motor allowing motor to coast down but PWM active to feed power back into drive to keep the drive powered up as long as it can before power is lost.
Page 135 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P4.2.5 Brake Chopper Define 1,2,3 Use this parameter to enable/disable the internal brake chopper logic if a break chopper is installed. When the frequency converter is decelerating the motor, the inertia of the motor and the load is fed into an external brake resistor.
Page 136 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW See Par ID 260 400.00 0.00 P4.3.7 Skip F3 High Limit 1,2,3 Use this parameter to set frequency limits to prevent the drive from operating in, the frequency converter will skip the set frequencies, ramp time will be the same.
Page 137 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P4.5.2 Motor Pot Ref Reset Defines how the motor pot reference signal is handled on shutting down frequency converter output or powering down the frequency converter. 0 = No reset—reference stays at last setting 1 = Memory reset in stop and power down—reference resets to 0 when drive is stopped or the power is cycled to the drive 2 = Memory reset in power down—reference resets to 0 when drive is powered down only...
Page 138 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P5.1.3 V/Hz Optimization 1,2,3 Use this parameter to enable an increase in voltage to the motor change automatically, this allows the motor to produce sufficient torque to start and run at low frequencies because of high starting torque processes.
Page 139 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW 2 = Programmable V/Hz curve. The V/Hz curve can be programmed with three different points. These points are P5.1.4 1,2,3 the 0 frequency voltage, midpoint and weakening point. A programmable V/Hz curve can be used if the other settings do not satisfy the needs of the application.
Page 140 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW 0.00 100.00 0.00 P5.1.13 Load Drooping This parameter is used to enable speed drop as a function of the load, used to share loads between mechanically coupled motors. This parameter corresponds to the nominal torque of the motor. Example: If load drooping is set to 10% for a motor that has a nominal frequency of 50Hz and is nominally loaded (100% of torque) the output frequency is allowed to decrease 5Hz from the frequency reference.
Page 141 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P5.1.30 1631 Startup Torque Selection Voltage across the q-axis stator inductance of the PM motor at the rated motor current and the rated motor frequency displayed in line-to-line rms value. Value is measured when performing Identification. P5.1.31 1632 Torque Memory Start...
Page 142 Use this parameter to set the second motor set name plate Frequency. Selected based off of a digital input. VF Stable Kd P5.2.6 1656 1,2,3 Parameter for drive stability. This should only be changed after review and suggestion of a Copeland engineer. P5.2.7 1657 VF Stable Kq 1,2,3 Parameter for drive stability.
Page 143 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P6.1.1 Output Phase Fault 1,2,3 Use this parameter to set the device reaction to a “Phase Loss Output” condition. This failure could be device dependent. 0 = No response 1 = Warning 2 = Fault, stop mode after fault according to standard stop mode 3 = Fault, stop mode after fault always by coasting...
Page 144 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P6.1.6 Motor Thermal Time 1,2,3 This parameter is used to set the time constant of the motor to rise to 63% of thermal load. The motor thermal time is specific to the motor design and it varies between different motor manufacturers.
Page 145 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW 120.0 15.0 P6.1.9 Stall Time Limit 1,2,3 This parameter is used to set the time limit before a stall error occurs. The stall time is counted by an internal up/down counter based off the current being above the limit setting. If the stall time counter value goes above this limit the protection will cause a trip (see Para ID313).
Page 146 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW 150.0 10.0 P6.1.13 Underload F0 Torque 1,2,3 This parameter gives value for the minimum torque allowed at zero frequency. If you change the value of Para ID486, nominal motor current, this parameter is automatically restored to the default value.
Page 147 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P6.1.18 2160 Preheat Control Source 1,2,3 This parameter selects the source of where the temperature is coming from to enable the preheat function, it can be enabled from a digital input or automatically via internal/external temperature sensors. 0 = DigIN: NormallyOpen 1 = DigIN: NormallyClosed 2 = DigIN: 1...
Page 148 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P6.2.2 2483 Fault Reset Start 1,2,3 This parameter is used to defines how the drive would start after a Fault Reset is given if the run command is still present to the device.
Page 149 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P6.2.11 1257 Replace Fan Fault Response 1,2,3 This parameter sets the device reaction after a “Replace Device Fan” condition has occurred, when the fan run time counter expires. This condition could be possible device dependent. 0 = No response 1 = Warning 2 = Fault, stop mode after fault according to standard stop mode...
Page 150 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P6.3.3 1678 IP Address Confliction Resp 1,2,3 This parameter sets the device reaction after a “IP Conflict” condition has occurred, when the ip address is duplicated on the network. This condition could be possible device dependent. 0 = No response 1 = Warning 2 = Fault, stop mode after fault according to standard stop mode...
Page 151 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P6.4.6 OverCurrent Attempts 1,2,3 This parameter determines the number of allowed restart-attempts after “Overcurrent” condition has occurred. Note: An IGBT temperature fault, Saturation Fault and Overcurrent Faults are included as part of this fault. 0 = No automatic restart after overcurrent fault trip >0 = Number of automatic restarts after an overcurrent trip, saturation trip or IGBT temperature fault.
Page 152 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P7.1.9 1304 PID1 Dead Band This parameter sets the PID Dead band around the set point in process units. This is a band where no actions occur to the output of the PID controller, to prevent oscillation or repeated activation/deactivation of controller.
Page 153 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P7.3.2.5 2396 PID1 Set Point 1 Sleep Unit Sel Use this parameter to define the variable used when going into the sleep mode. 0 = Output Frequency 1 = Motor Speed 2 = Motor Current 3 = PID1 Feedback...
Page 154 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW -2.0 P7.3.3.9 1329 PID1 Set Point 2 Boost Use this parameter to set the value the set point can be boosted when going into sleep mode. This is an additive variable that will add to the setpoint before drive output goes to sleep to prevent premature cycling.
Page 155 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P7.4.2.1 1332 PID1 Feedback 1 Source Use this parameter is used to select where feedback signal is being fed into the drive. This signal could be defined as analog inputs or fieldbus data value. -200.00 200.00 0.00...
Page 156 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW -99999.99 99999.99 Varies 100.00 P8.1.6 1362 PID2 Process Unit Max This parameter is used to defines the maximum process unit value for the PID controller. PID2 Process Unit Decimal 0 P8.1.7 1364 This parameter is used to defines the amount of decimal places used in the value for the PID Controller...
Page 157 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P8.3.2.1 1374 PID2 Set Point 1 Source Use this parameter to define the source of the PID set point value. This can either be an internal preset value, keypad set point, analog signal or Fieldbus message.
Page 158 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P8.3.3.5 2399 PID2 Set Point 2 Sleep Unit Sel Use this parameter to define the variable used when going into the sleep mode. 0 = Output Frequency 1 = Motor Speed 2 = Motor Current 3 = PID1 Feedback...
Page 159 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW -200.00 200.00 0.00 P8.3.3.11 1417 PID2 Set Point 2 Comp Max Use this parameter to set the maximum compensation for the PID setpoint value that is applied to the output frequency of the drive is at its maximum frequency level.
Page 160 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P8.4.3.1 1397 PID2 Feedback 2 Source Use this parameter is used to select where feedback signal is being fed into the drive. This signal could be defined as analog inputs or fieldbus data value. -200.00 200.00 0.00...
Page 161 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P10.1.1 1418 Bypass Enable 1,2,3 Use this parameter to enable the bypass functionality in the drive to have a soft key or input to force bypass. 32765 P10.1.2 Bypass Start Delay 1,2,3...
Page 162 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P10.1.14 1702 Saturation Trip Fault Bypass Enable 1,2,3 This parameter specifies whether an automatic switch to bypass when an Saturation fault occurs. 0 = Disable Auto bypass on Saturation fault 1 = Enable Auto bypass on Saturation fault P10.1.15 1703...
Page 163 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P10.2.4 2478 Redundant Run Time Reset Use this parameter to manually Reset the Redundant Drive Run timer. 300000.0 P10.2.5 2479 Redundant RunTime Limit Use this parameter to set the time limit for Run time of the drive when enabled for the Redundant drive scheme.
Page 164 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P11.2.4 Interval 2 From Day Use this parameter to set the day of week for Interval function to start on. 0 = Sunday 1 = Monday 2 = Tuesday 3 = Wednesday 4 = Thursday 5 = Friday...
Page 165 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P11.4.1 2490 Interval 4 Setting Use this parameter with the Interval time setting for interval 4 to set the desired time frame for the selection; to be Weekly or Daily. 0 - Weekly - would setup the timer for the week long.
Page 166 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P11.5.5 Interval 5 To Day Use this parameter to set the day of week for Interval function to stop on. 0 = Sunday 1 = Monday 2 = Tuesday 3 = Wednesday 4 = Thursday 5 = Friday...
Page 167 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW 2560 P12.1.6 2538 FB Process Data Input 6 Sel 1,2,3 Use this parameter to assign the Fieldbus Data Input Selections, parameter/monitor Para ID's can be assigned to these registers and then writen over the desired Fieldbus Network Word for Process Data.
Page 168 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P12.2.5 1560 FB Process Data Output 5 Sel 1,2,3 Use this parameter to accessing the Fieldbus Data Output Selections, parameter/monitor ID's can be assigned to these registers and then read over the desired Fieldbus Network Word for Process Data. Default Values for Process Data Out in Fieldbus(build table for below values) Process Data Out1 - Output Frequency = ID 1 Process Data Out2 - Motor Speed = ID 2...
Page 169 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P12.2.13 2419 Standard Status Word Bit4 Function Select 1,2,3 Use this parameter to select status indication of this bit4 to be read over the communication Standard Status Word.
Page 170 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P12.3.4.1 1727 SA Bus Baud Rate 1,2,3 SA Bus Baud Rate. P12.3.4.2 1726 SA Bus Device Address 1,2,3 SA Bus Device Address. P12.3.4.3 1728 SA Bus Instance Number 1,2,3 SA Bus Instance Number.
Page 171 Appendix C: Description of Parameters Unit Default Code Modbus ID Parameter Application RO/RW P12.4.2.7 Trusted IP White List 1,2,3 With P12.4.2.6, only IP addresses located in the white list can be used with the drive (cybersecurity). 47808 BACnet IP UDP port number P12.4.3.1 1733 1,2,3...
Page 172 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P13.1.6 Parameter Comparison 1,2,3 Use this parameter to initiate a Parameter Comparison function, you can compare the actual parameter values to the values of your customized parameter sets and those loaded to the control keypad. The actual parameter values are first compared to those of the customized parameter Set1.
Page 173 Disabled. The Startup Wizard is always enabled for the initial power up of the EVH Series vfd. By setting this parameter to Disable without going through the Startup Wizard it will disable it from being active on Start up. If user goes into Start Up Wizard after completion or defaults drive the Startup wizard will be Enabled.
Page 174 Appendix C: Description of Parameters Unit Default Modbus ID Parameter Code Application RO/RW P13.2.2 Motor Control Software Version 1,2,3 DSP/Motor Control Software Version P13.2.3 Application Software Version 1,2,3 MCU/Application Software Version P13.2.4 1714 Software Bundle Version 1,2,3 Software bundle version number, this encompasses the keypad software, Motor control software and application software.
Page 175: Appendix D: Mounting Instructions
Appendix D: Mounting Instructions...
Page 176 Appendix D: Mounting Instructions...
Page 177 Appendix D: Mounting Instructions...
Page 178 Appendix D: Mounting Instructions...
Page 179: Appendix E: Circuit Breaker Sizing / Cable And Fuse Guidelines
Appendix E: Circuit Breaker Sizing / Cable and Fuse Guidelines Circuit Breaker Sizing The Circuit Breaker selected must be in accordance with the National Electric Code (NEC) Requirements. The NEC determines that circuit breakers should handle 80% of their rated capacity for continuous loads and 100% for intermittent loads.
Page 180: Figure 14 Main
Appendix E: Circuit Breaker Sizing / Cable and Fuse Guidelines International cable and fuse sizes — 208 VAC to 240 VAC ratings Terminal cable size Mains and 208 V Main Earth motor input Current Fuse terminal terminal cable Frame current (VT/IL) rating Model...
Page 181 Appendix E: Circuit Breaker Sizing / Cable and Fuse Guidelines North America cable and fuse sizes — 440 VAC to 500 VAC ratings Terminal connection NEC motor wire size (AWG) size (AWG) Current Frame Line and Line and rating (VT/IL) Recommended Model size...
Page 182 Appendix E: Circuit Breaker Sizing / Cable and Fuse Guidelines International cable and fuse sizes — 380 VAC to 440 VAC ratings Terminal cable size 400 V input Current Fuse Mains and Main Earth Frame current (VT/IL) rating motor cable terminal terminal Model...
Page 183 Appendix E: Circuit Breaker Sizing / Cable and Fuse Guidelines North America and fuse sizes — 525 VAC to 600VAC ratings Nec wire Terminal connection 575 V motor size (AWG) size (AWG) Input Current Frame current rating (VT/IL) at Recommended Line and Line and Model...
Page 184: Input Power And Motor Cable Stripping Lengths
Input power and motor cable stripping lengths Power Wiring in Inches (mm) Motor Wiring in Inches (mm Frame Size 0.39 1.77 0.39 1.38 0.39 1.77 0.39 1.38 (10) (45) (10) (35) (10) (45) (10) (35) 0.59 1.77 0.59 1.77 0.59 1.57 0.59 1.57...
Page 185: Appendix F: Quick Start Guide
Appendix F: Quick Start Guide Copeland Commercial HVACR ™ Variable Frequency Drive – EVH Series QUICK START GUIDE This guide is a supplement to the application manual supplied with the drive. Improper wiring can cause bodily harm and damage the equipment. Follow good wiring practices and all applicable codes and standards.
Page 186 The following table lists the standard parameters that A: Hold the OFF/STOP and BACK/RESET buttons for 5 seconds happen when the drive is energized. Refer to the Variable Frequency Drive – EVH Series to return drive to factory default. application manual for parameter descriptions.
Page 187: Appendix G: Troubleshooting & Fault Codes
Appendix G: Troubleshooting & Fault Codes Under this menu, you can find Active faults, History faults and Fault codes. Active faults Menu Function Note Active Faults When a fault/faults appear(s), the display with the name and fault time of The fault remains active until it is cleared with the Reset button the fault will be pop.
Page 188 Appendix G: Troubleshooting & Fault Codes Fault code Fault Name Fault Type Default Possible Cause Remedy Realization Brake Chopper Superv Fault No brake resistor installed Check brake resistor and cabling. If these • are OK, the chopper is faulty. Contact the Brake resistor is broken •...
Page 189 Appendix G: Troubleshooting & Fault Codes Fault code Fault Name Fault Type Default Possible Cause Remedy Realization Keypad Comm Fault Configurable Fault The connection between the Check keypad connection and possible control “keypad and frequency keypad cable. converter is broken, and The local reference is keypad reference or the local control place is keypad, and The keypad communication fault...
Page 190 Appendix G: Troubleshooting & Fault Codes Fault code Fault Name Fault Type Default Possible Cause Remedy Realization Fieldbus Fault Configurable Fault Loss of communication with Check RS485 communication wiring. Modbus RTU, and the fieldbus Verify drive parameter are set correctly. reference is the remote reference Check master programming to verify OR the fieldbus control place is the...
Page 191 Appendix G: Troubleshooting & Fault Codes Fault code Fault Name Fault Type Default Possible Cause Remedy Realization Compatibility Fault Warning Keypad firmware is not compatible Check the keypad firmware revision with MCB firmware Compatibility Fault Warning IO1 card firmware is not compatible Check the IO1 card firmware revision with MCB firmware Compatibility Fault...
Page 192 Appendix G: Troubleshooting & Fault Codes variable variable...
Page 193 Appendix G: Troubleshooting & Fault Codes For an over voltage to come from the output of the drive there is either regenerative feedback or induced voltage. For there to be regenerative power, the drive either has to be running or there is a PM motor (PM motors are not very common).
Page 194 Appendix G: Troubleshooting & Fault Codes User Select...
Page 195 Appendix G: Troubleshooting & Fault Codes F10 Input Phase Fault - The input phase fault is looking for voltage in the rectified 3 phase in puts. The drive monitors all 3 phase voltages and performs a calculation for differential voltage min and max values.
Page 196 Appendix G: Troubleshooting & Fault Codes Mode Conditions Actions Shut down VFD PWM within 100ms, Normal Send drive under temperature fault to MCU. mode Start normal Drives starts ignoring under temp condition until the drive is Under Temp Fault Override is Yes powered down.
Page 197 Appendix G: Troubleshooting & Fault Codes...
Page 198 Appendix G: Troubleshooting & Fault Codes • Motor heating time constant: This is basically how long it takes the motor to heat up to 63% of 100% temp. Normally the bigger the motor the longer this time is. This value should not be changed unless this number is provided from the motor manufacturer.
Page 199 Appendix G: Troubleshooting & Fault Codes - The watch dog fault is a register overflow in the control board memory. F25 Watchdog Fault Power cycle the drive. If this is the first time this has occurred, it could have been a voltage dis turbance or the micro was overloaded.
Page 200 Appendix G: Troubleshooting & Fault Codes...
Page 201 Appendix G: Troubleshooting & Fault Codes - The option card fault is an indication that either an option card or slot F54 Option Card Fault on the control board has failed. The drive monitors the software ID and if that value is not re ceived or is corrupted, the drive will fault on option card fault.
Page 202 Appendix G: Troubleshooting & Fault Codes F60 Control Board Over Temperature Fault - The control board over temperature fault occurs ° ° C or greater than 85 C. If this fault oc when the temperature of the control board is below -30 curs, it should be handled similar to the over temperature fault on the drive.
Page 203 Appendix G: Troubleshooting & Fault Codes...
Page 204 Appendix G: Troubleshooting & Fault Codes F74 FRAM Fault - The FRAM fault is an indication that the data sent from the FRAM chip to the main processor chips CRC error checking failed. When this fault occurs, try cycling power the drive to reset error messages.
Page 205 Appendix G: Troubleshooting & Fault Codes - The Fieldbus fault is an indication that there is an issue with the F85 MSTP Fieldbus Fault BACnet MS/TP network messages. There was a loss in communication between the drive and the master after a specified timeout time. To handle this fault, verify cabling from master to the drive and veri-fy parameters in the master and drive are matching up correctly for message addressing.
Page 206 Appendix G: Troubleshooting & Fault Codes F93 External Fault 3 - The external fault is something that is fed into a digital input. The first thing to do is go into programming and figure out what input is set for an external fault. There can be multiple external faults and there can also be normally open and normally closed external faults.
Page 207 Appendix G: Troubleshooting & Fault Codes - The PID2 feedback Al loss fault is used with the multi-pump control F99 PID2 Feedback Al Loss where the drive is setup to monitor the feedback signal, if this signal is lost then the drive would indicate there is an issue.
Page 208 Appendix G: Troubleshooting & Fault Codes F104 Compatability Fault- This warning is an indication that the drives DSP processor and MCB processor firmware is not compatible. This fault condition will require firmware update to get processors up to the compatible versions, this firmware is on the website as a single bundle of all firmware.
Page 209 Appendix G: Troubleshooting & Fault Codes Copeland™ Copeland™ Copeland™...
Page 210 Appendix G: Troubleshooting & Fault Codes...
Page 211 Appendix G: Troubleshooting & Fault Codes Copeland™...
Page 212 Appendix G: Troubleshooting & Fault Codes Checking the output of the drive with its output disconnected (drive has to be set for ramp to start and not flying start): What a drive actually controls is the voltage and frequency on its output. It controls everything else by adjusting these 2 things.
Page 213: Appendix H: Modbus Rtu Commissioning
Appendix H: Modbus RTU Commissioning...
Page 214 Appendix H: Modbus RTU Commissioning Appendix H: Modbus RTU Commissioning...
Page 215 Appendix H: Modbus RTU Commissioning Modbus communication standards The function code field of a message frame contains two characters (ASCII) or eight bits (RTU). Valid codes are in the The Modbus protocol is an industrial communications and range of 1-255 decimal. When a message is sent from a distributed control system to integrate PLCs, computers, master to a slave device, the function code field tells the terminals, and other monitoring, sensing and control devices.
Page 216 Appendix H: Modbus RTU Commissioning...
Page 217: Read Diagnostics
Appendix H: Modbus RTU Commissioning Example of the request to read exception status from Slave Example of Write coils 19--28 from Slave device 18. device 18. Write coils 19-28 Request to read exception status Item Coda Description Item Code Description Slave Address Ox12 Slave address...
Page 218: Modbus Registers
Appendix H: Modbus RTU Commissioning Modbus registers Process data The variables and fault codes as well as the parameters can The process data fields are used to control the drive (e.g., be read and written from Modbus. The parameter addresses Run, Stop, Reference, Fault Reset) and to quickly read actual are determined in the application.
Page 219: Process Data In
Appendix H: Modbus RTU Commissioning Process data in This register range is reserved for the control of the VFD. Process Data In is located in range ID 2001-2099. The registers are updated every 10 ms. See table below. Fieldbus basic input table Modbus register Group Range/Type...
Page 220 Appendix H: Modbus RTU Commissioning Process data out FB general status word Description This register range is normally used to fast monitoring of the Value= 0 Value= 1 VFD. Process Data Out is located in range ID 2101-2199. Ready Not Ready See table below.
Page 221 Appendix H: Modbus RTU Commissioning...
Page 222 Appendix H: Modbus RTU Commissioning...
Page 223 Appendix H: Modbus RTU Commissioning...
Page 224 Appendix H: Modbus RTU Commissioning...
Page 225 Appendix H: Modbus RTU Commissioning...
Page 226 Appendix H: Modbus RTU Commissioning...
Page 227 Appendix H: Modbus RTU Commissioning...
Page 228 Appendix H: Modbus RTU Commissioning...
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Page 230 Appendix H: Modbus RTU Commissioning...
Page 231 Appendix H: Modbus RTU Commissioning...
Page 232 Appendix H: Modbus RTU Commissioning...
Page 233 Appendix H: Modbus RTU Commissioning...
Page 234 Appendix H: Modbus RTU Commissioning...
Page 235 Appendix H: Modbus RTU Commissioning...
Page 236 Appendix H: Modbus RTU Commissioning...
Page 237 Appendix H: Modbus RTU Commissioning...
Page 238 Appendix H: Modbus RTU Commissioning...
Page 239: Appendix I: Temperature Derating
Appendix I: Temperature Derating When using the EVH series drive at elevated temperatures or elevation, derating may be required to size the drive appropriately in order to maintain proper cooling. *4 kHz is default switching frequency Should any of the below be true for given application / VFD location, please reach out to your AE or Sales rep for assistance.
Page 240: Appendix J: Accessories
Appendix J: Accessories EVH Accessories EVH Flange Kits Description Catalog Number EVH Frame 1 Flange Kit Type 12/IP54 962-0022-00 EVH Frame 2 Flange Kit Type 12/IP54 962-0023-00 EVH Frame 3 Flange Kit Type 12/IP54 962-0024-00 EVH Frame 4 Flange Kit Type 12/IP54 962-0025-00 EVH Frame 5 Flange Kit Type 12/IP54 962-0026-00...