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LS ELECTRIC LSLV-S300 Series User Manual

Ac variable speed drive

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The right choice for the ultimate yield!

LS ELECTRIC strives to maximize your profits in gratitude for choosing us as your partner.

AC Variable Speed Drive

LSLV-S300 Series

Safety Instructions

• Read this manual carefully before installing,

wiring, operating, servicing or inspecting

this equipment

• Keep this manual within easy reach for

quick reference.

0.4~75 kW[200V] 0.4~220 kW[400V]

User's Manual

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Page 1 The right choice for the ultimate yield! LS ELECTRIC strives to maximize your profits in gratitude for choosing us as your partner. AC Variable Speed Drive LSLV-S300 Series User’s Manual 0.4~75 kW[200V] 0.4~220 kW[400V] Safety Instructions • Read this manual carefully before installing,...
Page 3 This operation manual is intended for users with basic knowledge of electricity and electric devices. * S300 is the series name of the LSLV-S300. * The software of this product may be revised for better functionality or performance. If you find any deviation from this user manual, check out the latest version on our website below.
Page 4: Safety Information
Safety Information Safety Information Read and follow all safety instructions in this manual precisely to avoid unsafe operating conditions, property damage, personal injury, or even death. Safety symbols in this manual Hazard Indicates an imminently hazardous situation that, if not avoided, will result in severe injury or even death.
Page 5 Safety Information Warning • Make sure to install a ground connection between the equipment and the motor for safe use. Otherwise, it may cause an electrical shock and result in personal injury or even death. • Do not turn on the power if the product is damaged or faulty. If you find that the product is faulty, disconnect the power supply and have the product professionally repaired.
Page 6 Safety Information Note Maximum allowed prospective short-circuit current at the input power connection is defined in IEC 60439-1 as 100 kA. LSLV-S300 is suitable for use in a circuit capable of delivering not more than 100kA RMS at the drive’s maximum rated voltage, depending on the selected MCCB.
Page 7: Quick Reference Table
Quick Reference Table Quick Reference Table The table below is a summary of situations that users encounter frequently while using the product. Refer to the following to search for information more easily and quickly: Situation Ref. p.36 What are the recommended wiring lengths? What are the factory default settings for multi-function terminals p.40 DI1 to DI8?
Page 8: Table Of Contents
Contents Contents 1 Preparing the Installation ................1 Product Identification ....................1 Check the Part Names .................... 3 Installation Considerations ..................13 Selecting the Installation Location ................. 15 Wire Selection ......................16 1.5.1 Ground Wire Specifications .............. 16 1.5.2 Power I/O Cable Specifications ............17 1.5.3 Signal (Control) Cable Specifications ..........
Page 9 Contents Basic No-Load Test ....................60 4 Learning to Perform Basic Operations ............62 Description of the Inverter Status Indicator LED ..........62 Description of the Smart Operator's Composition and Functions ......63 4.2.1 Description of Operation Key Functions ........... 66 4.2.2 Description of the Status Indicator LED ..........
Page 10 Contents Acc/Dec Settings ....................126 5.3.1 Acc/Dec Time Settings ..............126 5.3.2 Functions on Acc/Dec ..............130 6 Using the Advanced Functions of the Motor ........... 134 Induction Motor V/F Control ................134 6.1.1 Linear V/F pattern operation ............135 6.1.2 Square Reduction V/F Pattern Operation ........
Page 11 Contents 7 Learning Advanced Features ..............165 Auxiliary Frequency Operation ................165 Jog operation ....................... 168 7.2.1 Jog Operation by Terminal Block 1-Forward Jog ......168 7.2.2 Jog Operation by Terminal Block 2-Forward / Reverse Jog ... 169 7.2.3 Jog Frequency Limits ..............171 7.2.4 Jog Operation with Smart Operator ..........
Page 12 Contents 7.13 Speed Search Operation ..................221 7.13.1 General Acceleration Operation ............222 7.13.2 Start Operation While Powering On ..........223 7.13.3 Restart Operation After Power Interruption ........223 7.13.4 Auto Restart Operation After A Trip ..........224 7.13.5 Emergency Operation ..............224 7.14 Auto Restart Setting .....................
Page 13 Contents 7.27.4 Parameter Function (ParaSet Function) ......... 288 7.27.5 Special Function ................289 7.27.6 Simple Master ................. 290 7.28 Operating Winder/Unwinder ................294 7.28.1 Overall Compositions ..............295 7.28.2 Main Speed Command Part ............299 7.28.3 Tension Command Part ..............303 7.28.4 Tension Command ................
Page 14 Contents Multifunction Digital Output.................. 365 8.3.1 Multifunction Output Terminal Settings ........... 365 8.3.2 Delay Time Settings for Digital Output Terminals ......372 8.3.3 Contact Settings for Digital Output Terminals ......... 372 8.3.4 Digital Output Identification ............. 373 8.3.5 Multifunction Digital Output ............. 373 8.3.6 Direct Control over Multifunction Output .........
Page 15 Contents 9.2.4 Using external 24V power (External 24V) ........404 9.2.5 Loss of Input Value by Inverter Unit ..........406 9.2.6 Dynamic Braking (DB) Resistor Configuration ........ 416 9.2.7 Output Block by Multifunction Terminal ........... 418 9.2.8 Over Speed Error ................419 9.2.9 Speed Deviation Error ..............
Page 16 Contents 10.3 Communication Parameter Address Operation ..........443 10.3.1 Parameters for Common Area ............443 10.3.2 Parameters for Expanded Common Area ........447 10.3.3 Virtual Multifunction Input Settings ..........479 10.3.4 Virtual Multifunction Output Settings ..........480 10.3.5 Communication Memory Map ............480 10.3.6 Parameter Group for Data Transmission ........
Page 17 Contents 13 Table of Functions ..................528 13.1 Drive Group (DRV) ....................529 13.2 Basic Function Group (BAS) ................536 13.3 First Motor Group (MOT1) ................... 542 13.4 The First Motor V/F Group (VF1) ................ 547 13.5 First Motor Control Group (VEC1) ..............551 13.6 Second Motor Group (MOT2) ................
Page 18 Contents 13.28 User Sequence Group (US) ................669 13.29 User Sequence Logical Operation Group (USL) ..........672 13.30 User Sequence Arithmetic Operation Group (USV) ........... 676 13.31 User Sequence Parameter Operation Group (USP) .......... 682 13.32 User Sequence Special Function Group (USM) ..........688 14 Troubleshooting ..................
Page 19 Contents 16.2 Product Specification Details................726 16.2.1 Product Specification Details ............726 16.2.2 Structure and Usage Environment ..........729 16.3 External Dimensions (IP20 Type) ............... 730 16.3.1 External Dimensions ............... 730 16.4 Peripheral Devices ....................740 16.4.1 Standards of Molded Case Circuit Breaker (MCCB), Earth Leakage Circuit Breaker (ELCB), and Magnetic Contactor (MC) ...
Page 20 Image Contents Image Contents 1 Preparing the Installation Image 1. Product Rating Plate ....................2 Image 2. 200 V class 0.4-4 kW / 400 V class 0.4-4 kW Assembly Diagram ...... 3 Image 3. 200 V class 5.5-7.5 kW / 400 V class 5.5-7.5 kW Assembly Diagram ....
Page 21 Image Contents Image 19. 200V Class 30-45kW / 400V Class 45-75kW Power Terminals ...... 34 Image 20. 400V Class 90-110kW Power Terminals ............34 Image 21. 200V Class 55-75kW / 400V Class 132-160kW Power Terminals ....34 Image 22. 400V Class 185-220kW Power Terminals ............
Page 22 Image Contents Image 16. Setting mode screen ..................78 Image 17. Wizard mode screen ..................79 Image 18. Menu screen ...................... 80 Image 19. Parameter configuration group screen] .............. 81 Image 20. Drive Set tab screen in Setting mode] ..............81 Image 21.
Page 23 Image Contents Image 13. An Example of Starting after DC braking ............120 Image 14. An Example of Deceleration Stop ..............121 Image 15. An Example of Stopping after DC braking ............123 Image 16. An Example of Free Run Stop ................
Page 24 Image Contents Image 16. PID Output Mode Block ................... 198 Image 17. An Example of PID Operation Sleep Mode ............ 200 Image 18. An Example of a Pre-PID Operation ............... 201 Image 19. An Example of a PID Operation Switch ............
Page 25 Image Contents Image 51. Logic function (3 : OR(A,B,C)) ................ 278 Image 52. Logic function (4 : NOR(A,B,C)) ..............278 Image 53. Logic function (5 : XOR(A,B,C)) ..............279 Image 54. Logic function (6 : (A AND B) OR C) ...............
Page 26 Image Contents Image 88. An Example of an Operation upon Operation Command Input after a free-run Stop ..................344 Image 89. An Example of an Operation during Restart Prohibition after a free-run/Trip Image 90. An Example of a Restart after a CoastStop(FreeRun)/Trip ......
Page 27 Image Contents 9 Learning Protection Functions Image 1. Example of allowable current value by frequency according to cooling fan type ........................387 Image 2. The trip time according to the current size of electronic thermal (ETH) prevention ......................388 Image 3. Example of an overload warning signal output ..........
Page 28 Image Contents Image 12. Parameter Initialization Item Selection ............510 Image 13. Parameter Initialization Selection in Setting Mode ......... 511 Image 14. Setting mode screen ..................512 Image 15. Parameter Mode Lock Selection in Setting Mode ].......... 512 Image 16. Password Setting for Parameter Mode Lock ..........
Page 29 Image Contents 16 Technical Specifications Image 1. 200 V class 0.4-4 kW/400 V class 0.4-4 kW Exterior Diagram ....... 730 Image 2. 200 V class 5.5-7.5 kW/400 V class 5.5-7.5 kW Exterior Diagram ....731 Image 3. 200 V Class 11 kW/400 V Class 11-15 kW Exterior Diagram ......
Page 30 Image Contents Image 30. The Derating Ratio of Continuous Rated Current Based on the Operating Frequency ................776 Image 31. Carrier Frequency Derating Ratio Based on the Power Unit Temperature .. 777 Image 32. Carrier Frequency Derating Based on the Operating Frequency (Lower than 2 kHz) ..................
Page 31 Table Contents Table Contents 1 Preparing the Installation Table 1. Inverter Installation Environment ................13 Table 2. Maximum Allowed Carrier Frequency per Wiring Length ........13 Table 3. Ground Wire Specifications per Model ..............16 Table 4. I/O Wiring Specifications per Model ..............17 Table 5.
Page 32 Table Contents 5 Learning Basic Functions Table 1. Search Basic Functions ..................90 Table 2. Rotational Directions for Different Operation Commands and Voltage Inputs ..95 Table 3. Parameters for Each Unit of Speed ..............104 6 Using the Advanced Functions of the Motor Table 1.
Page 33 Table Contents 10 Using Built-in Communication Features Table 1. S300 Communication Standards ............... 436 Table 2. LS INV 485 CMD Characters ................484 Table 3. LS INV 485 Exception Code ................489 Table 4. LS INV 485 ASCII Hex Code ................489 Table 5.
Page 34 Table Contents 16 Technical Specifications Table 1. Input/Output Specifications (200 V Class 0.4-18.5 kW) ........719 Table 2. Input/Output Specifications (200 V Class 22-75 kW) ......... 720 Table 3. Input/Output Specifications (400 V Class 0.4-22 kW) ........721 Table 4. Input/Output Specifications (400 V Class 30-75 kW) ......... 723 Table 5.
Page 35: Preparing The Installation
Preparing the Installation 1 Preparing the Installation This chapter provides details on product identification, part names, correct installation, and cable specifications. To install the inverter correctly and safely, carefully read and follow the instructions. Product Identification The S300 inverter is manufactured in a range of product groups based on motor capacity and power source specifications.
Page 36: [ Image 1. Product Rating Plate ]
Preparing the Installation Model LSLV0220S300-2COFD Input Power Specifications Output Power Specifications Maximum Applicable Motor Capacity (based on HD) 0004 - 0.4 kW 0008 - 0.75 kW 0015 - 1.5 kW 0022 - 2.2 kW 0040 - 4 kW 0055 - 5.5 kW 0075 - 7.5 kW 0110 - 11 kW 0150 - 15 kW...
Page 37: Check The Part Names
Preparing the Installation Check the Part Names See the assembly diagram below for the part names. Refer to the following images, as detailed images may vary according to product groups. Refer to 4.1 Description of the Inverter Status Indicator LED for instructions on the LED status light in the front of the inverter.
Page 38: [ Image 3. 200 V Class 5.5-7.5 Kw / 400 V Class 5.5-7.5 Kw Assembly Diagram ]
Preparing the Installation 200 V Class 5.5-7.5 kW / 400 V Class 5.5-7.5 kW LSLV0055S300-2 / LSLV0075S300-2 LSLV0055S300-4 / LSLV0075S300-4 Cooling Top Cover Smart Operator LED Status Light Main Unit Control Terminal Block Front Cover Wire Bracket : Front Cover Bolted Joint [ Image 3.
Page 39: [ Image 4. 200 V Class 11 Kw / 400 V Class 11-15 Kw Assembly Diagram ]
Preparing the Installation 200 V Class 11 kW / 400 V Class 11-15 kW LSLV0110S300-2 LSLV0110S300-4 / LSLV0150S300-4 Cooling Top Cover Smart Operator LED Status Light Control Terminal Block Main Unit Front Cover Wire Bracket : Front Cover Bolted Joint [ Image 4.
Page 40: [ Image 5. 200 V Class 15-18.5 Kw / 400 V Class 18.5-22 Kw Assembly Diagram ]
Preparing the Installation 200 V Class 15-18.5 kW / 400 V Class 18.5-22 kW LSLV0150S300-2 / LSLV0185S300-2 LSLV0185S300-4 / LSLV0220S300-4 Top Cover Smart Operator LED Status Light Control Terminal Block Front Main Unit Cover Cooling Wire Bracket : Front Cover Bolted Joint [ Image 5.
Page 41: [ Image 6. 200 V Class 22 Kw / 400 V Class 30-37 Kw Assembly Diagram ]
Preparing the Installation 200 V Class 22 kW / 400 V Class 30~37 kW LSLV0220S300-2 LSLV0300S300-4 / LSLV0370S300-4 Top Cover Smart Operator LED Status Light Control Terminal Block Main Unit Front Cover Cooling Wire Bracket : Front Cover Bolted Joint [ Image 6.
Page 42: [ Image 7. 200 V Class 30 Kw / 400 V Class 45 Kw Assembly Diagram ]
Preparing the Installation 200 V Class 30 kW / 400 V Class 45 kW LSLV0300S300-2 LSLV0450S300-4 Top Cover Smart Operator LED Status Light Control Terminal Block Main Unit Cooling Front Wire Cover Bracket : Front Cover Bolted Joint [ Image 7. 200 V Class 30 kW / 400 V Class 45 kW Assembly Diagram ]...
Page 43: [ Image 8. 200 V Class 37-45 Kw / 400 V Class 55-75 Kw Assembly Diagram ]
Preparing the Installation 200 V Class 37-45 kW / 400 V Class 55-75 kW LSLV0370S300-2 / LSLV0450S300-2 LSLV0550S300-4 / LSLV0750S300-4 Top Cover Smart Operator LED Status Light Control Terminal Block Main Unit Cooling Wire Front Bracket Cover : Front Cover Bolted Joint [ Image 8.
Page 44: [ Image 9. 400 V Class 90-110 Kw Assembly Diagram ]
Preparing the Installation 400 V Class 90-110 kW LSLV0900S300-4 / LSLV1100S300-4 Smart Operator LED Status Light Control Terminal Block Main Unit Wire Bracket Cooling Front Cover : Front Cover Bolted Joint [ Image 9. 400 V Class 90-110 kW Assembly diagram ]...
Page 45: [ Image 10. 200 V Class 55-75 Kw / 400 V Class 132-160 Kw Assembly Diagram ]
Preparing the Installation 200 V Class 55-75 kW / 400 V Class 132-160 kW LSLV0550S300-2 / LSLV0750S300-2 LSLV1320S300-4 / LSLV1600S300-4 Smart Operator LED Status Light Control Terminal Block Main Unit Wire Bracket Cooling Front Cover : Front Cover Bolted Joint [ Image 10.
Page 46: [ Image 11. 400 V Class 185-220 Kw Assembly Diagram ]
Preparing the Installation 400 V Class 185-220 kW LSLV1850S300-4 / LSLV2200S300-4 Top Cover Internal Cooling Front Cover Smart Operator Main Unit USB Port Status Control Light Terminal Block Front Terminal Cover Cooling Power Cover : Front Cover Bolted Joint [ Image 11. 400 V Class 185-220 kW Assembly diagram ]...
Page 47: Installation Considerations
Preparing the Installation Installation Considerations Inverters are composed of various precise electronic parts, and therefore the installation environment can significantly impact the lifespan and reliability of the product. The table below details the ideal operation and installation conditions for the inverter.
Page 48: [ Image 12. Measurement Criteria For Ambient Temperature For Installation ]
Preparing the Installation 5 cm 5 cm [ Image 12. Measurement Criteria for Ambient Temperature for Installation ] Caution Do not allow the ambient temperature to exceed the allowable range while operating the inverter.
Page 49: Selecting The Installation Location
Preparing the Installation Selecting the Installation Location When selecting an installation location, consider the following points: • The location must be free from vibration, and the inverter must be installed on a wall that can support the inverter’s weight. • The inverter can become very hot during operation. Install the inverter on a surface that is fire-resistant or flame-retardant and with sufficient clearance around the inverter to allow air to circulate.
Page 50: Wire Selection
Preparing the Installation Wire Selection Make sure to use wires that are appropriate for the use and specifications of each I/O and control circuit for safe and reliable operation of the product. Refer to the following information to assist you with cable selection: Caution •...
Page 51: Power I/O Cable Specifications
Preparing the Installation Ground Ground Model Model LSLV□□□□ LSLV□□□□ mm² Bolt mm² Bolt 1320S300-4 1600S300-4 1850S300-4 2200S300-4 1.5.2 Power I/O Cable Specifications Table 4. I/O Wiring Specifications per Model Power Terminal Wiring mm² (AWG) Bolt Specifications Model LSLV□□□□ 0004S300-2 20.0 18.0 18.0 0102-xx04 0102-xx04 M3.5 M3.5 0008S300-2 16.0 14.0 14.0 0102-xx04 0102-xx04 M3.5 M3.5 0015S300-2 14.0 12.0 12.0 0102-xx04 0102-xx04 M3.5 M3.5...
Page 52 Preparing the Installation Power Terminal Wiring mm² (AWG) Bolt Specifications Model LSLV□□□□ 0750S300-2 120x2 180x2 120x2 250x2 350x2 250x2 0114-xx08 0114-xx08 M12 0004S300-4 22.0 22.0 20.0 0102-xx04 0102-xx04 M3.5 M3.5 0008S300-4 20.0 18.0 18.0 0102-xx04 0102-xx04 M3.5 M3.5 0015S300-4 18.0 14.0 14.0 0102-xx04 0102-xx04 M3.5 M3.5 0022S300-4 16.0 14.0 14.0 0102-xx04 0102-xx04 M3.5 M3.5 0040S300-4...
Page 53: Signal (Control) Cable Specifications
Preparing the Installation 1.5.3 Signal (Control) Cable Specifications Table 5. Control Wiring Specifications by Terminal Wire gauge Terminals VR+, VR-, AI1, AI2, AI3, TI, TO, AO1, AO2, EPI, 5G 0.33~1.25 16~22 DI1~DI8, CM, DP, DG 0.33~2.0 14~22 DA1, DB1, DC1, DA2, DC2, DQ3, EG 0.33~2.0 14~22 SP, SA, SB 0.33~2.0 14~22 S+, S-, 5G...
Page 54: Installing The Product
Installing the Product 2 Installing the Product This chapter describes the physical and electrical installation methods, including mounting and wiring the product. Refer to the flowchart and basic configuration diagram provided below to understand the procedures and installation methods to be followed to install the product correctly.
Page 55: [ Image 1. System Configuration ]
Installing the Product Basic configuration diagram The following illustration shows the basic system configuration. Use the diagram as a reference when configuring the system by connecting the product with peripheral devices. Ensure that the product has a suitable rating for the configuration and that all the required peripherals and optional devices (brake units, reactors, noise filters, etc.) are available.
Page 56: Mounting On The Wall Or Within The Panel
Installing the Product Mounting on the Wall or within the Panel Mount the inverter on a wall or inside a panel following the procedures provided below. Before installation, ensure that there is sufficient space to meet the clearance specifications and that there are no obstacles impeding the cooling fan’s air flow. Select a wall or panel capable of supporting the installation, and check the inverter’s mounting bracket dimensions (refer to 16.3.1 External Dimensions).
Page 57: [ Image 3. Fixing Mounting Bolts (Bottom) ]
Installing the Product 3 Mount the inverter on a wall or inside a panel using two mounting bolts. Tighten the upper mounting bolts, then install two lower mounting bolts and tighten them to mount the inverter. Ensure that the inverter is placed flat on the mounting surface and that the installation surface can securely support the weight of the inverter.
Page 58: [ Image 4. Example Of Incorrect Mounting ]
Installing the Product Caution • Always support the inverter by using the metal frames when moving it. Do not transport the inverter by lifting it with the inverter’s covers or plastic surfaces. The inverter may tip over if the covers break, resulting in injury or damage to the product. •...
Page 59: Wiring
Installing the Product Wiring Open the front cover, remove the wiring brackets and control terminal cover, and then install the ground connection as specified. Complete the cable connections by connecting an appropriately rated cable to the terminals on the power and control terminal blocks.
Page 60: Step 1 Front Cover Disassembly
Installing the Product 2.2.1 Step 1 Front Cover Disassembly For power terminal and control terminal wiring, the front cover and the wiring bracket must be disassembled in order. Disassemble each front cover and wiring bracket in the following order. Note Depending on the product family, the number of bolts on the front cover and the location and shape of the wiring bracket may vary.
Page 61: [ Image 6. Wiring Bracket Disassembly ]
Installing the Product 2 While holding both ends of the wiring bracket pressed inward, disassemble the wiring bracket. [ Image 6. Wiring bracket disassembly ] • Disassemble the bolts of the Power Cover on 400 V products with a capacity of 185 - 220 kW.
Page 62: Step 2 Ground Connection
Installing the Product 2.2.2 Step 2 Ground Connection Disassemble the front cover(s) and the wiring bracket. Then, follow the instructions below to install the ground connection for the inverter. 1 Connect the prepared ground wire to the ground ( ) terminal on the bottom of the inverter.
Page 63: Step 3 Power Terminal Wiring
Installing the Product 2.2.3 Step 3 Power Terminal Wiring The following illustration shows the terminal layout and connection configuration on the power terminal block. Refer to the detailed descriptions to understand the function and location of each terminal before making wiring connections. Ensure that the selected cables meet or exceed the specifications in 1.5 Wire Selection before installing them.
Page 64: [ Image 9. Power Terminal ]
Installing the Product Power Terminal Labels and Descriptions ❶ ❶ ❷ ❷ ❸ ❸ ❹ ❹ [ Image 9. Power terminal ] Table 1. Power terminal configuration Terminal Labels Name Description AC power input Mains supply AC power ❶ ❶ R(L1), S(L2), T(L3) terminal connections.
Page 65: [ Image 10. 200V Class 0.4-4Kw / 400V Class 0.4-4Kw Power Terminals ]
Installing the Product 200 V Class 0.4-4kW / 400V Class 0.4-4kW LSLV0004S300-4 / LSLV0008S300-4 / LSLV0015S300-4 / LSLV0022S300-4 / LSLV0040S300-4 LSLV0004S300-2 / LSLV0008S300-2 / LSLV0015S300-2 / LSLV0022S300-2 / LSLV0040S300-2 [ Image 10. 200V Class 0.4-4kW / 400V Class 0.4-4kW Power Terminals ] 200V Class 5.5-7.5kW LSLV0055S300-2 / LSLV0075S300-2 [ Image 11.
Page 66: [ Image 13. 200V Class 11Kw Power Terminals ]
Installing the Product 200V Class 11kW LSLV0110S300-2 [ Image 13. 200V Class 11kW Power Terminals ] 400V Class 11-15kW LSLV0110S300-4 / LSLV0150S300-4 [ Image 14. 400V Class 11-15kW Power Terminals ] 200V Class 15-18.5kW LSLV0150S300-2 / LSLV0185S300-2 [ Image 15. 200V Class 15-18.5kW Power Terminals ]...
Page 67: [ Image 16. 400V Class 18.5-22Kw Power Terminals ]
Installing the Product 400V Class 18.5-22kW LSLV0185S300-4 / LSLV0220S300-4 [ Image 16. 400V Class 18.5-22kW Power Terminals ] 200V Class 22kW / 400V Class 30-37kW LSLV0220S300-2 [ Image 17. 200V Class 22kW / 400V Class 30-37kW Power Terminals ] 400V Class 30-37kW LSLV0300S300-4 / LSLV0370S300-4 [ Image 18.
Page 68: [ Image 19. 200V Class 30-45Kw / 400V Class 45-75Kw Power Terminals ]
Installing the Product 200V Class 30-45kW / 400V Class 45-75kW LSLV0300S300-2/LSLV0370S300-2/LSLV0450S300-2 LSLV0450S300-4/LSLV0550S300-4 / LSLV0750S300-4 [ Image 19. 200V Class 30-45kW / 400V Class 45-75kW Power Terminals ] 400V Class 90-110kW LSLV0900S300-4 / LSLV1100S300-4 [ Image 20. 400V Class 90-110kW Power Terminals ] 200V Class 55-75kW / 400V Class 132-160kW LSLV0550S300-2 / LSLV0750S300-2 LSLV1320S300-4 / LSLV1600S300-4...
Page 69: [ Image 22. 400V Class 185-220Kw Power Terminals ]
Installing the Product 400V Class 185-220kW LSLV1850S300-4 / LSLV2200S300-4 [ Image 22. 400V Class 185-220kW Power Terminals ] Note The location of the power terminal labels may vary according to the product family. Warning Do not connect power to the inverter until the installation has been fully completed and the inverter is ready to be operated.
Page 70 Installing the Product Caution • Connect the input power wiring of the inverter to the R/S/T terminals and the output wiring to the motor to the U/V/W terminals. The product may be damaged if it is connected in reverse. • To use DC input to operate the inverter, connect the DC input terminals to P (+) and N (-).
Page 71: Step 4 Control Terminal Wiring
Installing the Product 2.2.4 Step 4 Control Terminal Wiring Below is a diagram showing the layout and connection configuration of the control circuit. Refer to the detailed information and install the control circuit wiring. Ensure that the cables selected meet or exceed the specifications in 1.5 Wire Selection before installing them.
Page 72: [ Image 24. Input/Output Control Terminal Wiring ]
Installing the Product Input/Output control terminal wiring diagram Multi-Function Input RS-485 Signal Input Safety Signal Input Analog Output 1 Analog Voltage / Current Output 1 Analog Voltage / Current Output 2 Analog Output 2 Relay Output1 (DO1) External Power (24 V) Output Relay Output2 (DO2) Analog Voltage / Current Input 1...
Page 73: [ Image 25. Io Board Switch ]
Installing the Product [ Image 25. IO board switch ] Table 3. Dip switch configuration Switch Factory value Description labels (Default) NPN/PNP setting switch (Left: NPN, Right: PNP) Left: NPN IO1/VO1 terminal setting switch (Left: IO1, Right: VO1) Right: VO1 IO2/VO2 terminal setting switch (Left: IO2, Right: VO2) Right: VO2 I1, I2, I3, PTC ON/V1, V2, V3 Right:...
Page 74 Installing the Product • VR+, VR-: Analog ± Voltage Reference, output voltage ±10 V, Maximum current output 20 mA • TO: Pulse Train Output • TI: Pulse Train Input Table 4. Input/communication terminal configuration Terminal Category Name Description Labels Configurable for digital input terminals. The factory default is as follows: •...
Page 75: [ Image 26. Factory Default Setting For Analog Input Terminal (Sw4 Switch) ]
Installing the Product Terminal Category Name Description Labels Depending on the setting of the switch (SW4), it can be used as either a voltage or current input. AI3 can be used as PTC sensor input. Factory default is V1, 2, and 3. PTC OFF PTC ON I1, I2, I3...
Page 76: [ Image 27. Remove Sw4 Switch Seal Tape ]
Installing the Product Terminal Category Name Description Labels [Note] Remove SW4 dip switch seal tape It is shipped with seal tape attached for SW4 dip switch protection (factory default: Analog voltage input). Remove the seal tape to change the switch settings, as shown in the following Analog illustration.
Page 77: [ Image 28. Factory Default Setting For Analog Output Terminal (Sw2, 3 Switch) ]
Installing the Product Output Terminal Labels and Descriptions Terminal Category Name Description Labels Depending on the selection of the switch (SW2, SW3), it can be used as either a voltage or current output. Factory default is VO1, VO2. [ Image 28. Factory default setting for analog output terminal (SW2, 3 switch) ] Analog [When voltage is selected]...
Page 78 Installing the Product Terminal Category Name Description Labels Digital service power. DC 24 V (21.6 - 26.4 V), 150 mA or less Digital power output terminal Digital • Precautions: Do not connect with the CM power (digital common terminal). Digital External 24 V common terminal.
Page 79: Step 5 Pnp/ Npn Mode Selection
Installing the Product 2.2.5 Step 5 PNP/ NPN Mode Selection The product supports both NPN (Sink) and PNP (Source) modes for sequence inputs at the terminal. Select an appropriate mode to suit requirements using the NPN/PNP selection switch (SW1) on the control board. The NPN/PNP selection switch (SW1) is set to NPN mode when shipped from the factory.
Page 80: [ Image 30. Pnp Mode (Internal Power) ]
Installing the Product PNP mode (Source) Select PNP using the PNP/NPN selection switch (SW1). The CM terminal is an input signal common terminal, and DP/DG is an internal power supply terminal. If you are using the internal power supply in PNP mode, connect the external circuit to DI and DP.
Page 81: Step 6 Enabling And Disabling Emc Filter And Varistor (Var) Ground
Installing the Product 2.2.6 Step 6 Enabling and Disabling EMC filter and Varistor (VAR) Ground The EMC filter and varistor (VAR) ground of the product can be enabled or disabled. EMC filter and VAR ground feature are set to On by factory default. The use of an EMC filter may increase leakage current at the expense of reducing airborne noise generated by the product.
Page 82: Var Ground ]
Installing the Product Enabling and disabling the EMC filter and VAR ground varies depending on the inverter capacity. Refer to the following description of inverter capacity. 200 V level 0.4 - 22 kW / 400 V level 0.4 - 37 kW The EMC filter and VAR ground terminal are located on the terminal block in models with corresponding capacities.
Page 83: Step 7 Reassembling The Wiring Bracket And The
Installing the Product 200 V level 30 - 75 kW / 400 V level 45 - 220 kW The EMC filter and VAR ground terminal are located on the upper-left side of the inverter, not on the terminal block in models with corresponding capacities. Each screw is used to enable and disable the EMC filter and VAR ground.
Page 84: Post-Installation Checklist
Installing the Product Post-Installation Checklist After completing the installation, check the items in the following table to make sure that the inverter has been safely and correctly installed. Table 7. Installation check Situation Details Ref. Check Is the installation location appropriate? p.13 Installation Is the inverter’s rated output sufficient to supply the...
Page 85 Installing the Product Situation Details Ref. Check Are shielded twisted pair (STP) cables used for control terminal wiring? Is the shielding of the STP wiring properly grounded? If 3-wire operation is required, are the multifunction p.37 input terminals defined prior to the installation of the control wiring connections? Is the shielding of the STP wiring properly grounded?
Page 86: Operation Sequence And Testing
Operation Sequence and Testing 3 Operation Sequence and Testing In order to maximize motor performance and operate the normal protection function, various motor information must be set. Set in the following sequence based on the motor control mode you want to use: Start Testing Motor rating plate information settings...
Page 87: Setting Up Motor Rating Plate Information
Operation Sequence and Testing Setting Up Motor Rating Plate Information Enter the information displayed on the motor rating plate. Motor rating plate information is used for motor control, protective operation, and others. Enter the motor type in MOT1 and MOT2-04 (Motor Type) and the motor capacity in MOT1 and MOT2-21 (Motor Capacity).
Page 88 Operation Sequence and Testing Details of motor rating plate information settings Code and Description Functions Set the type of the motor connected to the inverter. The following motors can be selected: MOT1, MOT2-04 Item Functionality Motor Type Induction Motor Induction motor Perm Magnet Motor Permanent magnet motor Set the capacity of the motor connected to the inverter.
Page 89: Setting Control And Operation Method
Operation Sequence and Testing Setting Control and Operation Method Select the appropriate operating mode for your system. Example of setting control and operation method Initial Group Code LCD Display Set Value Setting Range Unit value Control Mode MOT1, MOT2 Torque Control En Details of setting the control and operation method Code and Description...
Page 90: Setting The Encoder
Operation Sequence and Testing Code and Description Functions Set the operation method when operating in vector control mode (Sensorless, Vector). It is disabled when V/F control mode (V/F, Slip Comp., V/F PG) is selected. Item Functionality Set to speed control mode. The speed control function controls the motor to maintain the set speed.
Page 91 Operation Sequence and Testing Details of encoder settings Code and Description Functions ENC-2 Enc Monitor[Hz], The encoder output is converted into motor rotation speed and displayed in Hz or rpm. ENC-3 Enc Monitor[rpm] If set to 1 (Yes), the motor will start from the current motor speed without going through the starting sequence (dwell, brake, Start Mode, etc.) if the motor is rotating when the operation starts, and it ENC-10 Auto...
Page 92: Auto Tuning
Operation Sequence and Testing Auto Tuning You can measure motor parameters automatically. Additionally, you can test the operation of the encoder if the encoder option card is connected to the inverter's main body. Measured motor parameters are used for auto torque boost, sensorless vector control, and vector control, among others.
Page 93 Operation Sequence and Testing Auto tuning results – Synchronous motor Group Code LCD Display Result value Stator Resistance q-axis Inductance MOT1, The auto tuning result value is displayed. MOT2 d-axis Inductance PM Rotor Flux Auto Tuning Parameter Setting Details Code and Description Functions If you press the...
Page 94: Basic No-Load Test
Operation Sequence and Testing Basic No-Load Test After installing the product and checking the checklist, follow the instructions below to test the inverter. Refer to 4.3 How to Use the Smart Operator and 5 Learning Basic Functions for basic information regarding parameter changes, such as setting the operation command source, setting the target frequency, and setting the acceleration/ deceleration time.
Page 95: [ Image 1. Check Motor's Rotational Direction ]
Operation Sequence and Testing Remarque Si la commande avant (Fx) est activée, le moteur doit tourner dans le sens anti-horaire si on le regarde côté charge du moteur. Si le moteur tourne dans le sens inverse, inverser les câbles aux bornes U et V. Check the motor’s rotational direction 1 Set DRV-10 (1st Command Source) of the drive group (DRV) to 0 (Keypad) with the Smart Operator.
Page 96: Learning To Perform Basic Operations
Learning to Perform Basic Operations 4 Learning to Perform Basic Operations This chapter describes the Smart Operator's composition and operation method, as well as the function groups used for inverter operation and the basic operation method using the Smart Operator. Before proceeding with actual use, familiarize yourself with the various functions of the inverter, such as setting, changing frequency or input voltage, and issuing operating instructions, in order to learn the correct basic operating method.
Page 97: Description Of The Smart Operator's Composition And Functions
Learning to Perform Basic Operations Description of the Smart Operator's Composition and Functions Refer to the following illustration and table to identify the part names and functions of the Smart Operator. ❶ ❶ ❹ ❹ Status ❷ ❷ ❺ ❺ Forward/ ❸...
Page 98: [ Image 4. Battery Cover Removal ]
Learning to Perform Basic Operations Note Installing (replacing) the Smart Operator battery When the Smart Operator is shipped, the battery (CR2032) is already installed. Please follow the steps below when installing (replacing) the battery for the first time or when the battery is low and needs to be replaced. 1 Use the snap hook to separate the Smart Operator from the product.
Page 99: [ Image 6. Battery Replacement ]
Learning to Perform Basic Operations Note 4 Remove the old battery and install the new one in the correct orientation when replacing an old battery. [ Image 6. Battery replacement ] 5 Using a flathead (-) screwdriver or coin, close the battery cover by turning it in the closing direction.
Page 100: Description Of Operation Key Functions
Learning to Perform Basic Operations 4.2.1 Description of Operation Key Functions Refer to the following table for descriptions of the functions for each key. Table 3. Smart Operator operation key Classification Display Function name Functionality MODE key Displays the Menu screen. By pressing once in the parameter code that can be set, Program (ENTER)
Page 101: Description Of The Status Indicator Led
Learning to Perform Basic Operations 4.2.2 Description of the Status Indicator LED Refer to the following table for a detailed description of the Smart Operator's status indicator LED. For a description of the status indicator LED located on the front of the inverter body, refer to 4.1 Description of the Inverter Status Indicator LED.
Page 102: Menu (Mode) And Screen
Learning to Perform Basic Operations status bar Details Bottom status bar [ Image 8. LCD Screen Composition ] 4.2.4 Menu (mode) and Screen The S300 series inverter consists of six modes, as follows: Each mode has function items appropriate for its characteristics, and in the case of parameter mode, functions necessary for the operation of the inverter are displayed as group units.
Page 103: [ Image 10. Monitor Mode Screen ]
Learning to Perform Basic Operations 4.2.4.1 Monitor mode In Monitor mode, information about the inverter's operation is displayed. You can set the frequency, display the operating frequency, monitor the output current and voltage, etc. Enter the main menu screen by pressing the key, select the Monitor mode using the direction keys ( / / ), and press the...
Page 104 Learning to Perform Basic Operations Screen name Display Description Smart Operator Fx/Rx-1 Fx/Rx-2 3-Wire Operation RS-485 built-in communication command Option source Smart Operator jog Terminal jog User Sequence Smart Operator ❷ ❷ A1, A2 , A3 Analog A1, A2, A3 Pulse Up/Down 485 built-in communication...
Page 105 Learning to Perform Basic Operations Screen name Display Description STOP Stopped Forward operation Reverse operation TRIP Trip WARN Warning Stall Speed search Inverter ❹ ❹ operation state S/W overcurrent suppression H/W overcurrent suppression TUNE Tuning FIRE Fire Mode PID Operation Sleep Mode DC Braking KEB operation Continuous...
Page 106 Learning to Perform Basic Operations 4.2.4.2 Monitor mode type You can change the monitor screen type by pressing the key in Monitor mode. In Setting mode, you can select the items to be displayed on each monitor. In Monitor mode, you can navigate directly to Setting mode by pressing the key.
Page 107: Parameter Mode
Learning to Perform Basic Operations Monitor screen Description type This monitor mode is displayed as a graph. You can set the graph display time in Setting mode as well as using key on the Smart Operator. Monitor graph 4.2.4.3 Parameter mode You can set the functions necessary for operation.
Page 108 Learning to Perform Basic Operations Table 7. Parameter mode screen composition Classification Description Parameter group Displays the parameter group name (refer to ❶ ❶ information Description of the Parameter configuration mode) Parameter group Displays selected parameter sub-details ❷ ❷ details (code number + code name + parameter value) Parameter property Displayed when default settings are changed to other ❸...
Page 109 Learning to Perform Basic Operations Group name Display Description Configures functions related to application function Application function group activations, speed search, and kinetic energy buffering motion (KEB). Input terminal function Configures the function of the multifunction digital group input terminal. Analog input terminal Configures the functions of the analog input group...
Page 110: Favorite Mode
Learning to Perform Basic Operations 4.2.4.4 Favorite mode A user may group frequently used parameters and edit the parameter values of selected macro functions. Refer to 4.5 Favorites Settings for details. key, select the Favorite mode Enter the main menu screen by pressing the using the direction key ( / / ), and press the key to navigate to the...
Page 111: [ Image 13. Screen When There Is A Previously Occurred Trip ]
Learning to Perform Basic Operations 4.2.4.5 Trip mode When a trip occurs during operation, the type of trip, frequency of operation, current, and voltage at the time of the trip will be displayed. It is also possible to monitor the types of trips that have occurred in the past. The trip data will not be displayed if no trip has been made and there is no past trip history.
Page 112: Configuration Mode
Learning to Perform Basic Operations Table 10. Trip mode screen composition Classification Description The information is displayed according to the type of Trip type/history ❶ ❶ trip or by the history tab, depending on the situation information tab (Fault-1: last occurred trip) Fault trip ❷...
Page 113: Wizard Mode
Learning to Perform Basic Operations Table 11. Setting mode screen composition Classification Description Separates setting items into settings related to ❶ ❶ Tab information operation or Smart Operator operation and displays them in tabs Enter the code number to go directly to the desired ❷...
Page 114: How To Use The Smart Operator
Learning to Perform Basic Operations How to Use the Smart Operator To use the product's functions, it is necessary to select the group and code to which the function belongs with the Smart Operator and set the parameter value for each function.
Page 115: Navigating To Code (Function Item)
Learning to Perform Basic Operations 4.3.2 Navigating to Code (Function Item) On the menu screen, press the direction key ( / / ) to navigate to the desired mode, and press the key to enter it. [Select a parameter group or information tab] You can select the desired parameter group or information tab by pressing the...
Page 116: Navigating Directly To Different Codes (Jump Codes)
Learning to Perform Basic Operations 4.3.3 Navigating Directly to Different Codes (Jump Codes) There is a jump code input item that can be used to navigate to the code of each group in the Parameter mode and Setting mode groups. You can navigate (jump) directly to the desired code by using the Jump Code, which is the first code of a specific group in parameter mode.
Page 117: Parameter Setting
Learning to Perform Basic Operations Parameter Setting You can directly change the parameters required for operation. On the Parameter configuration mode screen, select the parameter group and items to be set, then press the key to change the items. However, items marked as in the list are read-only and cannot be edited.
Page 118: Favorites Settings
Learning to Perform Basic Operations An example of changing the command frequency setting value of code number 01 in the drive group (DRV) is shown in the following illustration. • By pressing the key, navigate to the desired position to enter a value. Then, press the key to enter the desired setting value.
Page 119: [ Image 27. Favorite Registration Screen ]
Learning to Perform Basic Operations Favorite Registration • Navigate to the parameter you want to register as a favorite in the Parameter mode and press the key. Navigate to the Favorite registration screen. • By pressing the key, navigate to the position to enter a value.
Page 120: Editing The Favorite Parameters
Learning to Perform Basic Operations • In the pop-up window asking for deletion, select YES and press the key. The parameter will be deleted from the favorites list. [ Image 30. Confirmation screen for deleting favorites ] 4.5.2 Editing the Favorite Parameters The parameter values registered in the favorite group can be directly edited in Favorite mode.
Page 121: Macro Settings
Learning to Perform Basic Operations Macro settings 4.6.1 Selecting macro Similar to Favorites settings, this function allows you to easily use basic functions in each Parameter mode group by pre-registering them into a group. Setting Initial Mode Group Code Set Value Unit Display Range...
Page 122 Learning to Perform Basic Operations Macro settings Group Code LCD Display Initial Value value Command Frequency 60.00Hz Acc Time 20.00sec Dec Time 30.00sec 1st Command Src Fx/Rx-1 3WIRE 1st Freq Ref Src Keypad DI1 Define DI2 Define DI3 Define 3-Wire Acc Time 20.00sec Dec Time...
Page 123: Edit Macro Parameters
Learning to Perform Basic Operations 4.6.2 Edit macro Parameters The parameter values registered in the favorite group can be directly edited in Macro mode. • Navigate to the parameter you want to delete in Macro mode and press the key. Navigate to the parameter change screen.
Page 124: Learning Basic Functions
Learning Basic Functions 5 Learning Basic Functions This chapter describes the basic functions of the S300 inverter. Check the reference page in the table to see the detailed description for each of the basic features. Table 1. Search Basic Functions Basic Functions Use Example Ref.
Page 125 Learning Basic Functions Basic Functions Use Example Ref. Forward/Reverse Configures the inverter to limit a motor’s rotation p.116 Rotation Prevention direction. Configures to accelerate instantly if the operation Start at power-on p.117 command is on when inverter power is supplied. Configures the inverter to start operating if the operation Reset and restart after p.118...
Page 126: Frequency Settings
Learning Basic Functions Frequency Settings 5.1.1 Operating Frequency Settings 5.1.1.1 Operating Frequency Source Settings Frequency commands for S300 are determined by the frequency command sources as follows: Setting Initial Group Code LCD Display Set value Unit Range Value Keypad Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input...
Page 127: [ Image 1. Operating Frequency Determination Block ]
Learning Basic Functions Command Frequency Freq Ref Src Analog Input SCALE 0 : Keypad 1 : Analog Input 1 Frequency at 100% 2 : Analog Input 2 3 : Analog Input 3 Pulse Input SCALE 4 : Pulse Input 5 : Up Down Drive The 1 Run frequency 6 : InternalComm.
Page 128 Learning Basic Functions 5.1.1.2 Setting Operating Frequency in the Smart Operator-Direct Input Set the frequency in the Smart Operator and press the key to change the frequency. Set the desired frequency in DRV-01 (Command Frequency, target frequency) code after choosing 0 (Keypad) in DRV-11 (1st Freq Ref Src, frequency setting method) code.
Page 129 Learning Basic Functions Setting Initial Group Code LCD Display Set value Unit Range Value -10.00~10.00 AI1 Value 0.00~20.00 -10.00~10.00 AI2 Value 0.00~20.00 -10.00~10.00 AI3 Value 0.00~20.00 * When the speed unit is rpm (select 1 [rpm Display] in DRV-32 [Hz/rpm Select]), gray shaded areas will be visible.
Page 130 Learning Basic Functions Forward Output Frequency -10 ~ 0V 0 ~10V Input Voltage Reverse Output Frequency 5.1.1.4 Setting Frequency via Analog Current Input in Terminal Block You can set the frequency by inputting current from AI1-AI3 terminals (frequency setting [current] terminals) of the control terminal block. Current in between 0 and 20 mA is available for input.
Page 131: Image 2. Inputting Pulse In Terminal Block
Learning Basic Functions 5.1.1.5 Setting the Frequency via Pulse Input in the Terminal Block Set frequency by inputting pulse frequency of 0-32 kHz in the PTI terminal (pulse input terminal) of the control terminal block. Inputting Pulse of 0-32 kHz in Terminal Block Select 4 (Pulse Input) in DRV-11 (1st Freq Ref Src, frequency setting method) code.
Page 132: Up-Down Operation
Learning Basic Functions 5.1.1.7 Up-Down Operation The acceleration and deceleration can be controlled through input at the multifunction terminal block. Similar to a flowmeter, the up-down operation can be applied easily to a system that uses the upper and lower limits of the switch output signals to command acceleration or deceleration for a motor.
Page 133: [ Image 3. Up-Down Operation (Normal) ]
Learning Basic Functions Up/Down Operation (Up/Down Mode) Details • Up/Down Normal Target frequency is accelerated or decelerated according to the input at the Up/Down terminals based on the maximum/minimum frequencies. frequency Down Operation Command (Fx) [ Image 3. Up-Down Operation (Normal) ] •...
Page 134: [ Image 5. Up-Down Operation (Step+ Normal) ]
Learning Basic Functions • Up/Down Step+Normal It is accelerated or decelerated as much as the step frequency set in ADV-77 (Up/ Down Step Freq) or ADV-78 (Up/Down Step Speed) every positive edge according to what is input at the Up/Down terminals. When the input is maintained for three seconds from a positive edge, it works the same as selecting Up/Down Normal.
Page 135: [ Image 6. Up-Down Operation (Save Mode) ]
Learning Basic Functions • Up/Down Save Mode During a constant speed operation, the operating frequency is saved automatically in the following conditions: the operation command (Fx or Rx) is off, a fault trip occurs, or the power is off. When the operation command is turned on again, or when the inverter regains the power source or resumes a normal operation from a fault trip, it resumes operation at the saved frequency.
Page 136: Operating Frequency-Related Functions
Learning Basic Functions 5.1.2 Operating Frequency-related Functions 5.1.2.1 Selecting Operating Frequency Operating frequency is selected and reflected as the following structure: Speed- L Speed- M Speed- H Second Command Speed- X First Operating Frequency Command Auxiliary Speed Multi-Stage Speed Calculation Second Operating Frequency Command Step Frequency-01...
Page 137: [ Image 8. An Example Of Frequency Change Due To Operating Frequency Hold ]
Learning Basic Functions 5.1.2.2 Holding Operating Frequency When a signal is input at the terminal, among multifunction input terminals, for which Command Frequency Hold is selected, the operating frequency is held at the output value at that moment regardless of inverter operation status. Jog operation runs on jog frequency instead of following the frequency on hold.
Page 138 Learning Basic Functions Table 3. Parameters for Each Unit of Speed Code Parameter Name Code Parameter Name DRV-01 Command Frequency DRV-02 Command Speed DRV-15 Jog Frequency DRV-16 Jog Speed DRV-20 Max Frequency DRV-21 Maximum Speed DRV-22 Frequency at 100% DRV-23 Speed at 100% BAS-08 DC Brake Frequency...
Page 139 Learning Basic Functions Code Parameter Name Code Parameter Name PPID-55 Pre-PID Set Freq PPID-56 Pre-PID Set Spd PPID-62 Sleep Boost Freq PPID-63 Sleep Boost Spd PPID-64 Sleep Check Freq 1 PPID-65 Sleep Check Spd1 PPID-70 Sleep Check Freq 2 PPID-71 Sleep Check Spd2 PRT-14 Lost Preset Freq...
Page 140: [ Image 9. An Example Of Frequency Change Due To Multistep Frequency Settings ]
Learning Basic Functions DIN-20 Step DI Check Time You can set the time to check input at the terminal block inside the inverter when you use multifunction input terminals to set multistep frequencies. For example, when you set the time to check input at the terminal block (In Check Time) as 100 msec with input at multifunction terminal DI6, it checks whether input is received at other terminal blocks.
Page 141: Frequency Limit
Learning Basic Functions 5.1.2.5 Frequency Limit Operating frequency settings can be limited with the maximum frequency/start frequency, upper limit, and lower limit of the frequency. Limiting the Frequency Using the Maximum Frequency and Start Frequency Initial Group Code LCD Display Set value Setting Range Unit...
Page 142 Learning Basic Functions Limiting the frequency with upper and lower limits Initial Group Code LCD Display Set value Setting Range Unit Value Cmd Freq Limit Cmd Freq Limit 0.50 0~Cmd Freq Limit Hi 0.50 Cmd Freq Limit Cmd Freq Limit Lo ~ 60.00 60.00 Max Frequency...
Page 143 Learning Basic Functions Frequency Jump Frequency jump is used to avoid mechanical resonant frequencies. When the motor accelerates or decelerates, it passes through the frequency jump band, in which the operating frequency is not configurable. When a frequency setting is increased, the frequency is maintained at the lower limit of the frequency jump while the frequency parameter settings (voltage, current, RS- 485 communication, Smart Operator settings, etc.) are within the jump frequency band.
Page 144: Operation Command Settings
Learning Basic Functions Operation Command Settings 5.2.1 Setting Methods of Operation Commands Select how to configure operation commands. Built-in RS485 communication, Fieldbus, and option cards per application are available for operation commands other than basic operation using the Smart Operator or multifunction terminals. Setting Initial Group Code...
Page 145: In The Smart Operator ]
Learning Basic Functions Output frequency STOP [ Image 10. An Example of Frequency Change When Inputting Operation Commands in the Smart Operator ] 5.2.1.2 Terminal Block as a Command Input Device (Assigning FX/RX Terminals) Select 1 (Fx/Rx-1) for no.10 of the drive group (DRV) to input operation commands with a multifunction terminal block.
Page 146: Image 11. An Example Of A Frequency Change When Inputting Operation
Learning Basic Functions Assigning FX/RX Terminals–Setting Details Code and Functions Description DRV-10 1st Command Source Select 1 (Fx/Rx-1). DIN-01, 03, 05, 07, 09, 11, 13, 15 Select terminals for forward (Fx) and reverse (Rx) DIx Define operation commands. (DIx: DI1~DI8) frequency Output frequency Target...
Page 147: Image 12. An Example Of A Frequency Change When Inputting Operation
Learning Basic Functions Run Command and Fwd/Rev Change Command Using Multifunction Terminal – Setting Details Code and Functions Description DRV-10 1st Command Source Select 2 (FX/RX-2). DIN-01, 03, 05, 07, 09, 11, 13, 15 Select terminals for operation commands (FX) and DIx Define rotation commands (RX).
Page 148: Local/Remote Switching Operations With Multifunction Keys In The Smart Operator
Learning Basic Functions 5.2.1.4 Communication as a Command Input Device To input operation commands via communication, select as per the communication type in DRV-10 (1st Command Source), the code for the operation command method of the drive group (DRV). Use S+/S- (RS-485 signal input terminal) terminals of the control terminal block for internal communication, and use the USB port on the control board for USB communication to control the inverter.
Page 149 Learning Basic Functions • The definition of Local: Local is a function that switches all operation commands, frequency commands, or torque commands to allow control by the Smart Operator. Therefore, it makes all operations available in the Smart Operator. Jog commands are ignored in this case. (However, it is only operable at On if the functions of the multifunction terminal are set as 18 [RUN Enable].) Operating locally is also referred to as onsite operation mode.
Page 150: Functions On Operation Command
Learning Basic Functions FWD_JOG, REV_JOG, or PRE EXCITE are input, it is operable with the Smart Operator when changed to Local, but it does not operate when changed back to Remote. This means that the motor is not operable in remote operation (Remote) mode when any one of the terminals where the above five functions are set is On when the power is on.
Page 151 Learning Basic Functions 5.2.3.2 Immediate Run upon Power Up (Power On Run) When the power is supplied to the inverter, it will accelerate when the operation command in the terminal block is On. It is only valid when ADV-02 (Power-on Run) is set as Start Mode or Speed Search while no.
Page 152 Learning Basic Functions 5.2.3.3 Reset and Restart after A Trip (Reset Restart) The inverter restarts if the operation command at the terminal block is On when the inverter is reset after a trip. When a fault trip occurs, the inverter will cut off the output and the motor will free-run.
Page 153: Start Settings
Learning Basic Functions 5.2.4 Start Settings Select how to start the inverter when the operation command is input. 5.2.4.1 Acceleration Start Acceleration start is a general acceleration method. If there are no extra settings applied, the motor will accelerate directly to the target frequency when an operation command is input Setting Initial...
Page 154: [ Image 13. An Example Of Starting After Dc Braking ]
Learning Basic Functions frequency Output frequency Voltage Output voltage DC Output Current Motor Rated 100% Current DC braking rate (DC Start Level) Operation Command (Fx) Duration DC-Start Time [ Image 13. An Example of Starting after DC braking ] Caution The amount of DC braking required is based on the rated current of the motor.
Page 155: Stop Settings
Learning Basic Functions 5.2.5 Stop Settings Select how to stop the motor when a stop command is input to the inverter during operation. 5.2.5.1 Deceleration Stop It is a general way to stop a motor in which it is decelerated down to MOT1, MOT2-17 (Stop Frequency) before stopping.
Page 156 Learning Basic Functions 5.2.5.2 Stop after DC Braking When the operating frequency reaches the set value (DC braking frequency) during deceleration, the inverter stops the motor by supplying DC power. With a stop command input, the inverter begins decelerating the motor. When the frequency reaches the DC braking frequency (BAS-08 DC Brake Frequency), the inverter supplies DC voltage to the motor and stops it by DC braking.
Page 157: [ Image 15. An Example Of Stopping After Dc Braking ]
Learning Basic Functions frequency Output frequency DC braking frequency (DC Brake Frequency) Voltage Output voltage Output current Motor Rated Current 100% DC Output Current DC braking rate (DC Brake Level) Operation Command (Fx) Duration DC-Brake DC-Brake BlockTime Time [ Image 15. An Example of Stopping after DC braking ] Caution •...
Page 158: [ Image 16. An Example Of Free Run Stop ]
Learning Basic Functions 5.2.5.3 Free Run Stop When the Operation command is off, the inverter output turns off, and the load stops due to residual inertia. Setting Initial Group Code LCD Display Set value Unit Range Value CoastStop Stop mode (FreeRun) Frequency and Voltage...
Page 159: Power Braking
Learning Basic Functions 5.2.5.4 Power Braking When the inverter’s DC voltage rises above a specified level due to the regenerative energy of the motor, a control will be made to either adjust the deceleration gradient level or re-accelerate the motor in order to reduce the regenerative energy. Power braking can be used when short deceleration times are needed without brake resistors, or when optimum deceleration is needed without causing an over voltage fault trip.
Page 160: Acc/Dec Settings
Learning Basic Functions Acc/Dec Settings 5.3.1 Acc/Dec Time Settings 5.3.1.1 Acc/Dec Time Setting Based on the Maximum Frequency Set acceleration and deceleration time with the same gradient based on the maximum frequency regardless of the operating frequency. Select 0 (Max Frequency) in the acceleration or deceleration reference frequency code, BAS-76 (Ramp Time Mode), in basic functional group (BAS) to set acceleration and deceleration times based on the maximum frequency.
Page 161: Image 18. Frequency Change Based On Acceleration And Deceleration Time
Learning Basic Functions 5.3.1.2 Acc/Dec Time Setting Based on the Operating Frequency Set acceleration and deceleration times for a motor based on time needed to reach the target frequency of the next step from the current frequency operating at a fixed speed.
Page 162 Learning Basic Functions 5.3.1.3 Multi-stage Acc/Dec Time Setting with Multifunction Terminals You can set a switch frequency for acceleration and deceleration times to change the acceleration and deceleration gradients without configuring multifunction terminals. Initial Group Code LCD Display Set value Setting Range Unit Value...
Page 163: [ Image 19. Frequency Change Based On Multi-Stage Acc/Dec Time Settings ]
Learning Basic Functions All changes to the terminal block shall be completed within the Step DI Check Time if two or more multi-stage acceleration and deceleration terminals are used. Deceleration0 Acceleration3 Deceleration1 Acceleration2 Deceleration2 frequency Acceleration1 Deceleration3 Acceleration0 Operation Command (Fx) [ Image 19.
Page 164: Functions On Acc/Dec
Learning Basic Functions DRV-05 DRV-06 BAS-70 ADV-60 frequency BAS-71 Operation Command (Fx) [ Image 20. Frequency Change Based on Acc/Dec Time Switch Frequency Settings ] 5.3.2 Functions on Acc/Dec 5.3.2.1 Setting Acc/Dec S-Curve Patterns Acceleration and deceleration gradient patterns can be configured for softer acceleration and deceleration.
Page 165: [ Image 21. Frequency Change Based On Acc/Dec Pattern Settings ]
Learning Basic Functions Acc/Dec Pattern-Setting Details Code and Functions Description Sets the curve ratio (gradient) when starting acceleration if acceleration and deceleration pattern is set as an S-Curve. Gradient level is the ratio which gradient acceleration takes up in the section under 1/2 frequency based on the 1/2 frequency of target frequency.
Page 166: [ Image 22. Frequency Change When Acc/Dec Pattern Is Set As An S-Curve ]
Learning Basic Functions S-Curve frequency frequency 60Hz 60Hz Curve Curve Deceleration Acceleration 40Hz 40Hz Curve 30Hz 30Hz Curve Deceleration Acceleration 15Hz 15Hz Duration Duration [ Image 22. Frequency Change When Acc/Dec Pattern Is Set as an S-Curve ] Note The Calculation of the Actual Acc/Dec Times for S-Curve Application •...
Page 167: [ Image 23. Frequency Change Based On Acc/Dec Stop Command Settings ]
Learning Basic Functions 5.3.2.2 Acc/Dec Stop Command Settings Multifunction input terminals can be configured to stop acceleration or deceleration and operate the inverter at a fixed speed. Setting Initial Group Code LCD Display Set value Unit Range Value 01 ,03, 05, 1, 2, 4, DIx Define XCEL...
Page 168: Using The Advanced Functions Of The Motor
Using the Advanced Functions of the Motor 6 Using the Advanced Functions of the Motor Induction Motor V/F Control Configure the inverter’s output voltages, gradient levels and output patterns to achieve a target output frequency with V/F control. The amount of torque boost used during low frequency operations can also be adjusted.
Page 169: Linear V/F Pattern Operation
Using the Advanced Functions of the Motor 6.1.1 Linear V/F pattern operation A linear V/F pattern configures the inverter to increase or decrease the output voltage at a fixed rate for different operation frequencies based on V/F characteristics. It is used for loads that require constant torque regardless of the frequency.
Page 170: [ Image 1. Comparison Of V/F Pattern Operations ]
Using the Advanced Functions of the Motor Square Reduction V/F pattern Operation - Setting Details Code and Description Functions Select 1 (Square) or 3 (Square 2) according to the load’s starting characteristics. Item Functionality The inverter produces output voltage Square proportional to 1.5 square of the operation frequency.
Page 171: User V/F Pattern Operation
Using the Advanced Functions of the Motor 6.1.3 User V/F Pattern Operation The inverter allows users to configure to suit the V/F pattern and load characteristics of special motors. Initial Group Code LCD Display Set value Setting Range Unit Value V/F Pattern User V/F 0.00~...
Page 172: [ Image 2. Frequency Change Based On User V/F Pattern Operation Settings ]
Using the Advanced Functions of the Motor User V/F pattern Setting Details Code and Functions Description VF1, VF2-02, 05, 08, 11 Sets user frequencies (VF1, VF2-02, 05, 08, User Frequency-x and 11) by selecting arbitrary frequencies in between the start frequency and maximum (Frequency-x: frequency.
Page 173: Slip Compensation Operation
Using the Advanced Functions of the Motor 6.1.4 Slip Compensation Operation The operational characteristics of the induction motor make the difference between the output frequency of the inverter and the actual rotational frequency of the motor. The difference of the frequencies is called the slip frequency, whose size changes as per the load.
Page 174 Using the Advanced Functions of the Motor 6.1.4.2 Advanced Slip Compensation You can calculate the slip with motor parameters and compensate for it more accurately than basic slip compensation. Refer to 3.1 Setting Up Motor Rating Plate Information and check before use and refer to 3.4 Auto Tuning for tuning.
Page 175 Using the Advanced Functions of the Motor Slip Compensation Operation Setting Details Code and Functions Description VF1, VF2-22 Sets gains for calculated slip compensation frequency. SlipGain Mot-Low, VF1, VF2-22 and VF1, VF2-23 set low speed and high speed VF1, VF2-23 gains for a reverse load.
Page 176: Vector Control For Induction Motors
Using the Advanced Functions of the Motor Vector Control for Induction Motors It controls torque instantaneously without rotational speed or feedback of the motor for precise location/speed or torque control and rapid acceleration and deceleration. The rotational speed of the motor is estimated with the internal computational algorithm of the inverter.
Page 177 Using the Advanced Functions of the Motor Control Gain Setting Details Code and Functions Description MOT1, MOT2-08 Sets the use of torque control mode. Torque Control En Sets the bandwidth of an auto current regulator. The bandwidth MOT1, MOT2-51 is set in percentage, and the default, 100%, is calculated automatically.
Page 178: Sensorless Vector Control For Induction Motors
Using the Advanced Functions of the Motor Caution • Controller gains can be adjusted according to load characteristics. However, use with caution because conditions, such as motor overheating or unstable system may occur depending on the controller gain settings. • For high-performance operation, the parameters of the motor connected to the inverter output must be measured.
Page 179 Using the Advanced Functions of the Motor Sensorless Vector Control Operation-Setting Details Code and Functions Description VEC1, VEC2-37 Adjust the speed with these parameters if the estimated and IMSL actual speeds are different at no load. SpdCompNoLoad VEC1, VEC2-38 Adjust the torque with these parameters if the estimated and IMSL Torque Comp actual torque are different.
Page 180: Vector Control For Induction Motors Using Location/Speed Sensors
Using the Advanced Functions of the Motor Relevant function Problem Troubleshooting code Change the value in 5% increments. It tilts counterclockwise as the value increases. Refer to the following for load-rotational frequency curve according to the values: Load If the error rate of the 200% rotational frequency is VEC1, VEC2-...
Page 181: [ Image 5. How Does Vec1, Vec2-9 (Hold Time) Work ]
Using the Advanced Functions of the Motor Vector Control for Induction Motors Using Location/Speed Sensors Setting Initial Group Code LCD Display Set value Unit Range Value Motor Type Induction Motor MOT1, MOT2 Control Mode V/F PG 0.00~ Hold Time 1.00 1.00 VEC1, 60.00...
Page 182: Torque Control For Induction Motors
Using the Advanced Functions of the Motor Torque Control for Induction Motors Torque control controls the motor to achieve the corresponding torque, based on preset command values. It can be used in both sensorless vector control and vector control using location/speed sensors. For vector control using location/speed sensors, check the connection of the encoder (location/speed sensors) before starting operation.
Page 183: Setting Torque Command Sources
Using the Advanced Functions of the Motor 6.3.2 Setting Torque Command Sources Torque commands for S300 are determined by the torque command sources as follows: Torque settings are only available in torque control mode. Initial Group Code LCD Display Set value Setting Range Unit Value...
Page 184 Using the Advanced Functions of the Motor 6.3.2.2 Setting Torque via Terminal Analog Voltage Input (AI1-AI3) Set torque by inputting voltage in AI1-AI3 terminals in the control terminal block. Voltage inputs of 0-+10 V or -10-+10 V are available. SW4 must be selected as V1-V3. Setting Range Initial Group Code...
Page 185 Using the Advanced Functions of the Motor Table 2. Torque Directions for Different Operation Commands and Voltage Inputs Input voltage Operation command 0~10V -10~0V 6.3.2.3 Setting frequency via analog current input in terminal block You can set torque by inputting current from AI1-AI3 terminals (frequency setting (current) terminals) in the control terminal block. Current in between 4 and 20 mA can be input.
Page 186 Using the Advanced Functions of the Motor 6.3.2.5 Setting Torque with Internal Communication Select 5 (Internal Comm.) in DRV-12 (1st Torque Ref Src), the frequency setting code for the drive group (DRV). Control the inverter via communications with upper-level controllers, such as PLCs or PCs, by using S+/S-/SG terminals (RS-485 signal input terminals) of the control terminal block.
Page 187: V/F Control For Synchronous Motors
Using the Advanced Functions of the Motor V/F Control for Synchronous Motors Configure the inverter’s output voltages, gradient levels and output patterns to achieve a target output frequency with V/F control. The amount of torque boost used during low frequency operations can also be adjusted. V/F Control Parameters Initial Group...
Page 188: Vector Control For Synchronous Motors
Using the Advanced Functions of the Motor Vector Control for Synchronous Motors It controls torque for precise location/speed or torque control and rapid acceleration and deceleration. It demonstrates a large amount of torque at low current compared to V/F control. Setting Initial Group...
Page 189: Initial Angle Detection
Using the Advanced Functions of the Motor Caution • Controller gains can be adjusted according to load characteristics. Use with caution because conditions, such as motor overheating or unstable system may occur depending on the controller gain settings. • For high-performance operation, the parameters of the motor connected to the inverter output must be measured.
Page 190: Sensorless Vector Control Operation Settings For Synchronous Motors
Using the Advanced Functions of the Motor Initial Angle Detection-Setting Details Code and Description Functions You need to figure out the initial position of the stimulus when starting the motor for vector control (including sensorless operation) over synchronous motors. Configuration Functionality Starts by detecting position without initial MOT1, MOT2 61...
Page 191 Using the Advanced Functions of the Motor Code and Description Functions MOT1, MOT2-24 Enter the rated speed of the motor rating plate. Rated Speed MOT1, MOT2-25 Enter the number of poles on the motor rating plate. Number of Poles MOT1, MOT2-26 Enter the rated current of the motor rating plate.
Page 192: Sensorless Vector Control Operation Guide For Synchronous Motors
Using the Advanced Functions of the Motor 6.5.3 Sensorless Vector Control Operation Guide for Synchronous Motors Table 3. Sensorless Vector Control Operation Guide for Synchronous Motors Problem Relevant function code Troubleshooting If there is not enough starting torque If there is motor hunting at the start If there are speed fluctuations during low-speed operation VEC1, VEC2-62...
Page 193: Vector Control For Synchronous Motors Using Location/Speed Sensors
Using the Advanced Functions of the Motor Problem Relevant function code Troubleshooting If speed severely hunts and rated current flows during no-load operation If OCT trip occurs after applying and releasing rapid low-speed regenerative load (more than 100%) If OVT occurs due to rapid Reduce values by 1 at acceleration/deceleration at a time.
Page 194: Common Functions Of Vector Control
Using the Advanced Functions of the Motor Common Functions of Vector Control 6.6.1 Torque Limits in Speed Control Speed control mode limits torque output. You can set both reverse and regenerative torque limits for forward and reverse operations. Torque Limit Settings Setting Initial Group...
Page 195 Using the Advanced Functions of the Motor Torque Limits-Setting Details Code and Description Functions MOT1, MOT2-05 Control Mode, Torque limit is active in sensorless or vector speed control modes. MOT1, MOT2-08 Torque Control En Select a type to which you want to set the amount of torque limits. You can set via Smart Operator, analog input at the terminal block, or various communications.
Page 196: Speed Limits In Torque Control
Using the Advanced Functions of the Motor 6.6.2 Speed Limits in Torque Control If output torque of the motor is bigger than load torque in torque control mode, motor speed gradually increases. Operating frequency (speed) should be limited to prevent this.
Page 197 Using the Advanced Functions of the Motor Speed Limits-Setting Details Code and Description Functions MOT1, MOT2-05 Control Mode, Torque limit is active in sensorless or vector torque control modes. MOT1, MOT2-08 Torque Control En Select a type to which you want to set the amount of speed limits. You can set via Smart Operator, analog input at the terminal block, or various communications.
Page 198: Speed/Torque Switch
Using the Advanced Functions of the Motor 6.6.3 Speed/Torque Switch You can switch from speed mode to torque mode or from torque mode to speed mode with multi-functional input during operation. Torque Limit Settings Setting Initial Group Code LCD Display Set value Unit Range...
Page 199: Learning Advanced Features
Learning Advanced Features 7 Learning Advanced Features Auxiliary Frequency Operation You can use the main frequency and auxiliary frequency simultaneously for an operating frequency with various computational conditions. The main frequency is used for setting the operating frequency, whereas the auxiliary frequency is used to fine-tune during operation at the main frequency.
Page 200 Learning Advanced Features Code and Description Functions After setting the size of the auxiliary reference gain with DRV-37 (Aux Ref Gain), you can set the reflection ratio for the main reference. Note that items 4–7 from the setting items below may result in either plus (+) or minus (-) values with just unipolar analog inputs.
Page 201: Learning Advanced Features
Learning Advanced Features Table 1. An Example of Auxiliary Frequency Operation An Example of Auxiliary Frequency Operation When the frequency setting in Smart Operator is the main frequency and AI1 analog voltage is the auxiliary frequency, • Main frequency: Keypad (operation frequency 30 Hz) •...
Page 202: Jog Operation
Learning Advanced Features Jog operation The jog operation allows for temporary control of the inverter. You can enter a jog operation command using the multifunction terminals. The jog operation is the second-highest priority, after the dwell operation. If a jog operation is requested while operating the multistep, up-down, or 3-wire operation modes, the jog operation overrides all other operation modes.
Page 203: Jog Operation By Terminal Block 2-Forward / Reverse Jog
Learning Advanced Features Forward Jog Description Details Code and Description Functions Select one of the multifunction terminals, DI1-DI8, for the jog frequency settings, then set the codes for the relative terminal of the terminal input group (DIN) to 9 (JOG). DIN-01, 03, 05, 07, 1(FX) 09, 11, 13, 15...
Page 204: [ Image 2. An Example Of Forward / Reverse Jog Operation ]
Learning Advanced Features An Example of Forward / Reverse Jog Settings Setting Initial Group Code LCD Display Set Value Unit Range Value 0.00~Max 10.00 10.00 Frequency Frequency 0~Maximum Jog Speed Speed Jog Acc Time 20.00 0.00~600.00 20.00 Jog Dec Time 30.00 0.00~600.00 30.00...
Page 205: Jog Frequency Limits
Learning Advanced Features 7.2.3 Jog Frequency Limits You can limit jog frequencies with upper limit and lower limit settings at ADV-19 (Jog Freq Limit En) (refer to Limiting the Frequency Using the Maximum Frequency and Start Frequency). Refer to the following parameters to limit the jog frequency: Initial Group Code...
Page 206: Jog Operation With Smart Operator
Learning Advanced Features 7.2.4 Jog Operation with Smart Operator Initial Mode Group Code LCD Display Set Value Setting Range Unit Value Operator Multi Key Setting Select 0.00~Max 10.00 10.00 Frequency Frequency 0~Maximum Jog Speed Parameter Speed Jog Acc Time 20.00 0.00~6000.00 20.00 Jog Dec Time 30.00...
Page 207: 3-Wire Operation
Learning Advanced Features Note • During the inverter operation, you cannot change Multi Key Select parameters or activate/deactivate the key in the Setting mode. • A jog operation is the second-highest priority after a dwell operation, and a jog operation with the Smart Operator is the highest priority among jog operations. 3-Wire Operation The 3-wire operation latches the signal input (the signal stays on after the button is released) and is used when operating the inverter with a push button.
Page 208: Safe Operation Mode
Learning Advanced Features Timing Diagram frequency FX Signal RX Signal DIx (3-Wire) [ Image 5. An Example of 3-Wire Operation ] Safe Operation Mode Operation commands are run only when the signal in the multifunction input terminal set as a safe operation mode is turned on. Safe operation mode is used to safely and carefully control the inverter through the multifunction terminals.
Page 209: [ Image 6. An Example Of Operating In Safe Operation Mode ]
Learning Advanced Features Code and Description Functions Activates or deactivates safe operation mode. Item Functionality ADV-70 Enables safe operation mode. Run Enable Recognizes the operation command from a multifunction input terminal. Sets operation of the inverter when the multifunction input terminal in safe operation mode is off.
Page 210: Dwell Operation
Learning Advanced Features Dwell Operation The dwell operation is used to maintain torque during the application and release of the brakes on lift-type loads. An inverter dwell operation runs as follows based on the acceleration and deceleration dwell frequencies and dwell time set by the user: •...
Page 211: [ Image 8. An Example Of Acceleration Dwell Operation ]
Learning Advanced Features Note Dwell operations do not work when: • Dwell operations will not work if the time is set to 0.00 sec or the dwell frequency is set to 0.00 Hz. • The acceleration dwell operating instructions are only valid once upon initial instruction, so they will not function if the acceleration dwell frequency is passed again during a stop or deceleration and then accelerated again.
Page 212: Torque Boost
Learning Advanced Features Torque Boost 7.6.1 Manual Torque Boost Manual torque boost allows users to adjust output voltage during a low speed operation or motor start. Increase low speed torque or improve motor starting properties by manually increasing output voltage. Configure manual torque boost while running loads that require high starting torque, such as lift-type loads.
Page 213: Auto Torque Boost
Learning Advanced Features 7.6.2 Auto Torque Boost The auto torque boost adjusts the amount of boost automatically based on load volume and outputs inverter voltage, whereas the manual torque boost outputs inverter voltage based on the amount of torque boost set by the user regardless of the load characteristics.
Page 214: Pid Control
Learning Advanced Features PID Control PID control is one of the most common autocontrol methods. It uses a combination of proportional, integral, and differential controls. PID control enables more flexible control over automation systems. The functions of PID control that can be applied to the inverter operation are as follows: Table 2.
Page 215: Basic Pid Operation
Learning Advanced Features 7.7.1 Basic PID Operation PID operates by controlling the output frequency of the inverter, through automated system process control to maintain speed, pressure, flow, temperature and tension. Initial Group Code LCD Display Set Value Setting Range Unit Value Process PID Enable...
Page 216 Learning Advanced Features Initial Group Code LCD Display Set Value Setting Range Unit Value Ref2 Auxiliary Src None Ref2 Auxiliary M+(G*A) 0~12 Mode Ref2 Auxiliary Gain 0.00 -200.00~200.00 0.00 Reference Acc 20.00 0.00~600.00 20.00 Time Reference Dec 30.00 0.00~600.00 30.00 Time Analog Feedback Source...
Page 217 Learning Advanced Features Initial Group Code LCD Display Set Value Setting Range Unit Value Output LPF Gain 0~10000 msec Output Inverse Unit Min Step Reference 1 0.00 0.00 Unit Max Unit Min Step Reference 2 0.00 0.00 Unit Max Unit Min Step Reference 3 0.00 0.00...
Page 218 Learning Advanced Features Initial Group Code LCD Display Set Value Setting Range Unit Value PPID Run Enable PPID Ref Change PPID Gain Change PPID I-Term Clear DIx Define PPID (DIx: DI1~DI8) Output Hold PPID Step Ref-L PPID Step Ref-M PPID Step Ref-H Note •...
Page 219 Learning Advanced Features Basic PID Operation Setting Details Code and Description Functions APP-01 Process Set the code to 1 (Yes) to set functions for process PID. PID Enable DIx Define Set the code to 37 (PPID Run Enable) and input configured terminal block (DIx: to run process PID operation.
Page 220 Learning Advanced Features Code and Description Functions Selects the reference input for the PID control. The same sources are not configurable for both the reference source (PPID-10 and 15) and feedback source (PPID-25). Item Functionality Keypad Smart Operator Analog Input 1 AI terminal of the terminal block (analog input Analog Input 2 terminal)
Page 221 Learning Advanced Features Code and Description Functions Selects an external input source for PID control references. The reference value is determined by the input source at PPID-10 and formula at PPID- 13 if selected as an external input source. Item Functionality None Not used...
Page 222 Learning Advanced Features Code and Description Functions If the value for PPID-12 is anything other than 0 (None), the final reference 1 value is determined by the formula set at PPID-13 with a source input at PPID-10 and one at PPID-12. Configuration M + (G * A) M * (G * A)
Page 223 Learning Advanced Features Code and Description Functions Selects feedback input for PID control. The same sources are not configurable for both the reference source (PPID-10 and 15) and feedback source (PPID-25). Item Functionality Analog Input 1 AI terminal of the terminal block (analog input Analog Input 2 terminal) Analog Input 3...
Page 224 Learning Advanced Features Code and Description Functions If the value for PPID-26 is anything other than 0 (None), the final feedback value is determined by the formula set at PPID-27 with a source input at PPID-25 and one at PPID-26. Configuration M+(G*A) M*(G*A)
Page 225: [ Image 11. An Example Of Pid Output Holding Based On Feedback Value ]
Learning Advanced Features Code and Description Functions Holds the PID output when the feedback value is within the upper and lower limits, which are Deadband Width set at PPID-29 added to or subtracted from the reference value, for longer than the time set at PPID- PID Unit Feedback (PPID-90)
Page 226 Learning Advanced Features Code and Description Functions Sets the time to output accumulated errors. When the error is 100%, the time taken for 100% output will be set. When the integral time is set to one second, 100% will be output one second after the error reaches 100%. Differences in a normal state can be reduced by Integral Time settings.
Page 227 Learning Advanced Features Code and Description Functions PPID-46 Output Limit Low, Limits the output of the controller. PPID-47 Output Limit High PPID-48 Output Adjusts the volume of the controller output. Scale Used when the output of the PID controller changes too fast or the entire PPID-49 system is unstable due to severe oscillation.
Page 228 Learning Advanced Features Code and Description Functions PPID-91 Adjusts the size according to the unit selected at PPID-90. Unit Scale PPID-92 Unit at 0 % Sets PID Unit 0% value and PID Unit 100% value as the minimum and PPID- maximum values of the unit set at PPID-90.
Page 229: [ Image 12. Pid Command Selection Block ]
Learning Advanced Features PID Command Selection Block PPID PPID PPID PPID Ref1 Keypad Set Reference1 Source Ref1Auxiliary Mode Ref1Auxiliary Gain 0 : M+(G*A) Unit Fitting 1 : M*(G*A) 2 : M/(G*A) 3 : M+(M*(G*A)) 4 : M+G*2*(A-50) Aux Mode 5 : M*(G*2*(A-50)) 6 : M/(G*2*(A-50)) 7 : M+M*G*2*(A-50) 8 : (M-A)^2...
Page 230: [ Image 13. Pid Command Scale Block ]
Learning Advanced Features PID Command Scale Block PPID PID Ref Value Unit Fitting PID Reference PID Reference Value RAMP (-100.0% ~ 100.0%) (-100.0% ~ 100.0%) PPID Unit Fitting Reference Acc Time PPID PPID PPID Unit Select Unit at 100% Reference Dec Time (-100.0% ~ 100.0%) ((Unit 0%-Unit 100%) ~ Unit 100%) Unit Fitting Calculation...
Page 231: [ Image 15. Pid Output Block ]
Learning Advanced Features PID output PPID FeedForward Gain PPID 01,03,05,07,09,11,13,15 Error Value DIx Define PI Gain 2 Unit Fitting PPID PPID Proportional Gain1 Output Inverse PPID Proportional Gain2 0: No PID Reference Value (-100.00% ~ 100.00%) PPID Integral Time1 PPID 1: Yes Integral Time2 01,03,05,07,09,11,13,15...
Page 232: Pid Operation Sleep Mode
Learning Advanced Features PID Output Mode Frequency at 100% PID Output Value (-100.00% ~ 100.00%) PPID PID Out Mode Frequency Calculator Max Frequency Not Use Output Only PID Freq Out PID+MainFreq PID Output Frequency Only PID Trq Out Torque (-Max Frequency ~ PID+EPID1 Out Calculator Max Frequency)
Page 233 Learning Advanced Features Initial Group Code LCD Display Set Value Setting Range Unit Value None Always PPID Sleep Mode Enable Dependent Sleep Boost Set 0~Unit Max Unit 0.00~Max Sleep Boost Freq 0.00 0.00 Frequency 0~Maximum Sleep Boost Spd Speed Sleep Check 0.00~Max 0.00 0.00...
Page 234: Pre-Pid Operation
Learning Advanced Features PPID-90 (PID Unit) Feedback Value Sleep Boost Set PID Reference WakeUp Set 1, 2 PID WakeUp Level frequency Output frequency Sleep Boost Freq Pre-PID Set Freq Sleep Check Freq1, 2 Wakeup Delay 1, 2 delay time delay time Delay Time ＜...
Page 235: [ Image 18. An Example Of A Pre-Pid Operation ]
Learning Advanced Features Pre-PID Operation Setting Details Code and Functions Description Enter frequency or rotational speed up to the general acceleration PPID-55 Pre-PID when general acceleration is required without PID control. For Set Freq, example, when PPID-55 is set as 30 Hz, it continues general PPID-56 Pre-PID operation at 30 Hz until the controlled variable (PID feedback Set Spd...
Page 236: Pid Operation Switch (Pid Openloop)
Learning Advanced Features 7.7.4 PID Operation Switch (PID Openloop) When a terminal to which 38 (PPID Open Loop) is set among multifunction input terminal codes (DI1-DI8 Define) for terminal input group (DIN-01, 03, 05, 07, 09, 11, 13, and 15) turns on, PID operation will be stopped and switched to a general operation.
Page 237: External Pid (Epid)
Learning Advanced Features External PID (EPID) It includes PID functions except for basic PID for inverter control. External PID (EPID) output can overlap PID output based on PID output mode (PPID-45 OutputMode) settings. External output is available according to analog output (OUT-01 and 10) settings.
Page 238: Basic Epid Operation
Learning Advanced Features 7.8.1 Basic EPID Operation S300 allows using two EPIDs simultaneously. Each EPI are configurable with two parameter groups (EPI1 and EPI2) as follows: Setting Initial Group Code LCD Display Set Value Unit Range Value ExternalPID Enable Idle Pre-PID Control State Sleep...
Page 239 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value Derivative Time 0~1000 msec FeedForward Gain 0.0~1000.0 -100.00~ Output Limit Low 0.00 Output Limit 0.00 High Output Limit Output Limit High 100.00 100.00 Low~100.00 EPI1, EPI2 Output LPF Gain 0~10000 msec...
Page 240 Learning Advanced Features Basic EPID Operation Setting Details Code and Functions Description Set the code to 1 (Yes) to set functions for the External APP-02 ExternalPID Enable PID. Displays the current status of the EPID control (Idle, EPI1, EPI2-01 Control State RUN, Pre-PID, Sleep, or Sleep Boost).
Page 241 Learning Advanced Features Code and Functions Description Selects the reference input for the PID control. Same sources are not configurable for both the reference source (EPI1 and EPI2-10) and feedback source (EPI1 and EPI2-25). Item Functionality Keypad Smart Operator Analog Input 1 AI terminal of the terminal block Analog Input 2...
Page 242 Learning Advanced Features Code and Functions Description Selects feedback input for EPID control. Same sources are not configurable for both the reference source (EPI1, EPI2-10) and feedback source (EPID-25). Item Functionality Analog Input 1 AI terminal of the terminal block Analog Input 2 (analog input terminal) Analog Input 3...
Page 243 Learning Advanced Features Code and Functions Description Sets the time to output accumulated errors. When the error is 100%, the time taken for 100% output will be set. When the integral time is set to one second, 100% will be output one second after the error reaches 100%. Differences in a normal state can be reduced by Integral Time settings.
Page 244 Learning Advanced Features Code and Functions Description Sets the unit of the control variable. CUST m³/h f³/s f³/m f³/h °F lb/s °C kg/s lb/m EPI1, EPI2-90 Unit Select inWC kg/m lb/h kg/h gl/s mBar gl/m m³/s gl/h m³/m ft/s Adjusts the size according to the unit selected at EPI1 EPI1, EPI2-91 Unit Scale and EPI2-90.
Page 245: Epid Command Block
Learning Advanced Features 7.8.2 EPID Command Block Unit Fitting EPI1,2 EPI1,2 Unit Select Unit at 100% EPI1,2 EPI1,2 (-100.0% ~ 100.0%) ((Unit 0%-Unit 100%) ~ Unit 100%) Ref Keypad Set Reference Source Unit Fitting Calculation EPI1,2 EPL1,2 Unit Scale Unit at 0% EPI1,2 0 : Keypad Reference Value...
Page 246: Epid Output
Learning Advanced Features 7.8.4 EPID Output EPI1,2 FeedForward Gain EPI1,2 Error Value Unit Fitting EPI1,2 EPI1,2 Proportional Gain Output Inverse 0 : No 1 : Yes EPID Reference Value (-100.00% ~ 100.00%) EPI1,2 Integral Time EPID Feedback Value (-100.00% ~ 100.00%) 01,03,05,07,09,11,13,15 DIx Define EPI1,2 I-Term Clear...
Page 247: Kinetic Energy Buffering Operation
Learning Advanced Features Kinetic Energy Buffering Operation When there is interruption of input power, the inverter’s DC link voltage will decrease, causing a low voltage trip and blocking output. Kinetic energy buffering operation maintains DC link voltage with regenerative energy from the motor during the interruption.
Page 248 Learning Advanced Features KEB Operation-Setting Details Code and Description Functions Selects a KEB operation to use when the input power is interrupted. If 1 or 2 is selected, it will control the inverter's output frequency and charge the DC link (inverter's DC part) with regenerative energy from the motor. Item Functionality Do not use the KEB operation.
Page 249: [ Image 24. An Example Of Keb Ride Through Operation ]
Learning Advanced Features DC link voltage APP-17 APP-16 (KEB Stop Level) (KEB Start Level) frequency Start frequency Operation Return Control (APP-18) Operation Command (Fx) [ Image 24. An Example of KEB Ride Through Operation ] DC link voltage APP-17 APP-16 (KEB Stop Level) (KEB Start Level) frequency...
Page 250 Learning Advanced Features Note There may be performance differences according to load status (capacity, inertia, and etc.) for KEB operation. You can adjust the gain related to KEB operation for enhancement. • When a low voltage trip occurs right after an instantaneous power interruption, increase the setting values of APP-18 (KEB Control Gain) if the load inertia is small or the load is big.
Page 251: Current Hunting Prevention (Anti-Hunting Regulator)
Learning Advanced Features 7.10 Current Hunting Prevention (Anti-Hunting Regulator) Current hunting (current distortion or oscillation) occurs during V/F control due to mechanical resonance, which may have a negative impact on the load system. Current hunting prevention (anti-hunting regulator) is a function used to prevent such issues.
Page 252: Fire Mode
Learning Advanced Features 7.11 Fire Mode It protects other systems by allowing continuous operation of the inverter during emergencies, including fire from the inhalation fan or exhaust fan and excluding hardware malfunction or serious trips. It continuously operates at a set frequency in Fire Mode.
Page 253 Learning Advanced Features Fire Mode-Setting Details Code and Description Functions Set a password to select Fire Mode. PRT-90 The initial password for Fire Mode is 9251. Fire Mode By entering the password, you can change the setting value of Fire Mode Password Select at PRT-91 once.
Page 254: Energy Saving Operation
Learning Advanced Features 7.12 Energy Saving Operation 7.12.1 Manual Energy Saving Operation If the output current of the inverter is small, the output voltage is reduced to as much as set at ADV-53 (Energy Save Gain). The voltage before the energy saving operation is the base value of the percentage.
Page 255: Speed Search Operation
Learning Advanced Features 7.13 Speed Search Operation This operation is used to prevent fault trips that can occur while the inverter outputs voltage when the motor is free-running with the inverter output voltage disconnected. Because this feature estimates the rotational speed of the motor approximately based on the inverter output current, it does not detect the exact speed.
Page 256: General Acceleration Operation
Learning Advanced Features Code and Description Functions APP-08 SS Adjusts the gain for a speed search. Bandwidth APP-10 SS This parameter adjusts the size of current during speed search. Accuracy PM SS Curr may be decreased due to noise if the value is too small, while a speed Peak search may be difficult at a high speed if the value is too big.
Page 257: Start Operation While Powering On
Learning Advanced Features 7.13.2 Start Operation While Powering On Setting Initial Group Code LCD Display Set Value Unit Range Value Speed Power-on Run Search DOx Define Speed 50, 52, 54 (DOx: DO1~DO3) Search 14, 0 Speed Search During Start Operation While Powering On-Setting Details Code and Functions Description Sets the value as 2 (Speed Search).
Page 258: Auto Restart Operation After A Trip
Learning Advanced Features 7.13.4 Auto Restart Operation After A Trip Refer to 7.14.2 Auto Restart for Speed Search. 7.13.5 Emergency Operation Setting Initial Group Code LCD Display Set Value Unit Range Value Speed BX Restart Mode Search DOx Define Speed 50, 52, 54 (DOx: DO1~DO3) Search...
Page 259: Auto Restart Setting
Learning Advanced Features 7.14 Auto Restart Setting Used to restart the inverter automatically based on the setting values when a trip is lifted after the operation stops from an inverter abnormality. 7.14.1 Auto Restart for General Acceleration Setting Initial Group Code LCD Display Set Value...
Page 260: Auto Restart For Speed Search
Learning Advanced Features : Trip Occurrence Constant Speed Operation frequency Voltage PRT-07 General Acceleration Operation Reset Operation command Number of Auto Restarts [ Image 27. An Example of Operation When Auto Restart Count for General Acceleration Is Set as 2 ] 7.14.2 Auto Restart for Speed Search Setting Initial...
Page 261: Speed Search Is Set As 2 ]
Learning Advanced Features Auto Restart for Speed Search Setting Details Code and Description Functions When PRT-05 is set as 2 (Speed Search), it will accelerate as a speed search and operate. Auto restart count is set at PRT-06. If a fault trip occurs during operation, the inverter will automatically restart PRT-05 Reset after the time set at PRT-07.
Page 262: Operational Noise Settings (Change Of Carrier Frequency Settings)
Learning Advanced Features 7.15 Operational Noise Settings (Change of Carrier Frequency Settings) Setting Initial Group Code LCD Display Set Value Unit Range Value Normal PWM PWM* Mode LowLeakage Carrier Frequency 1~15 * PWM: Pulse width modulation Operational Noise Setting Details Code and Description Functions...
Page 263: [ Image 29. Rated Current Limit Per Ambient Temperature ]
Learning Advanced Features Note S300 Series Inverter Derating Standard • S300 series inverters are designed to respond to two types of load factors: Heavy loading (heavy duty) and light loading (normal duty). The overload rate represents an acceptable load amount that exceeds the rated load, and is expressed in a ratio of excess to the rated load.
Page 264: Second Motor Operation
Learning Advanced Features 7.16 Second Motor Operation The second motor operation is used when a single inverter switch-operates two motors. The parameters for the second motor are configurable in the second motor operation function. The second motor is operated when a multifunction input terminal defined for the second functions is turned on.
Page 265: Switching Operation To Commercial Power
Learning Advanced Features 7.17 Switching Operation to Commercial Power Power switching operation is used to switch motor operation from the inverter to commercial power or the other way around. Setting Initial Group Code LCD Display Set Value Unit Range Value 01, 03, 05, 1, 2, 4, DIx Define...
Page 266: Input Power Frequency Settings And Voltage Monitoring
Learning Advanced Features 7.18 Input Power Frequency Settings and Voltage Monitoring The inverter input power voltage you monitor can be displayed in a line-to-line RMS value. Setting Initial Group Code LCD Display Set Value Unit Range Value 200 V 200~240 class Ref AC Input Volt 400 V...
Page 267: Second Operation Mode Settings
Learning Advanced Features 7.19 Second Operation Mode Settings Apply two types of operation modes and switch between them as required. Set the second command mode aside from the main command mode for operation commands and frequency settings with the multifunction input terminal. Mode switching can be used to stop remote control, to switch operation mode to operate via local panel, or to operate the inverter from another remote control room during a remote operation using a communication option.
Page 268: Regeneration Avoidance
Learning Advanced Features Caution • When you set the multifunction input terminal to second command source (2nd Source) and turn on the signal, operation status will change, as all the frequency settings and operation commands change to the second commands. Therefore, before inputting functions to the multifunction terminal, ensure that the second commands are correctly set.
Page 269: [ Image 32. An Example Of Regeneration Avoidance ]
Learning Advanced Features Regeneration Avoidance Setting Details Code and Description Functions Frequent occurrence of regenerative voltage during motor operation at a constant speed may force excessive work on the APP-25 RegenAvd brake unit, which may damage the brake or shorten its life. To prevent this situation, select this to suppress the DC link voltage and disable operation of the brake unit.
Page 270: Load Speed
Learning Advanced Features 7.21 Load Speed You can display load speed in monitor mode in the scale and unit of your choice. The load speed is displayed with values to which MOT1, MOT2-96 (Load Speed Gain) and MOT1, MOT2-97 (Load Speed Scale) are applied in the unit of rpm or mpm, whichever is set at MOT1 and MOT2-98 (Load Speed Unit).
Page 271: Output Power Display
Learning Advanced Features 7.22 Output Power Display You can adjust the scale of the output power displayed in the monitor mode. Setting Initial Group Code LCD Display Set Value Unit Range Value Trim Power % 70~130 Refer to 12.2.1 Item Change in Monitor Display Mode and select 4 (Output Power) among monitor items.
Page 272: [ Image 33. An Example Of Operation Command Input During Motor Pre-Heating ]
Learning Advanced Features Motor Pre-Heating Setting Details Code and Functions Description Sets the injectable current for initial heating. The pre-heat APP-40 Pre-Heat Level current is set in % value compared to rated current of the motor. Sets the duty (time) for current flow during 10 seconds of APP-41 Pre-Heat Duty initial heating in a % value.
Page 273: [ Image 34. An Example Of Motor Pre-Heating When Free-Run Stops ]
Learning Advanced Features If a terminal block for initial heating is turned on after the inverter operation command is turned off, the inverter will stop operation and perform motor pre-heating. frequency APP-42 Current Heat Duty Operation Command (Fx) DIx(Pre Heat) [ Image 34.
Page 274: Dc Injection By Terminal Block
Learning Advanced Features 7.24 DC Injection by Terminal Block This function secures flux by supplying DC current to the induction motor via an external sequence. It only works when the inverter is stopped. When an operation command is applied and the operation starts, DC injection will stop even if the terminal block is turned on.
Page 275: Brake Control
Learning Advanced Features 7.25 Brake Control Used to control the On/Off operation of the load’s electronic braking system. If the DI1-DI8 Define code of the terminal block input group (DIN) is anything other than 55 (Brake Monitor Sel), the brake release delay time and brake engage delay time will be ignored.
Page 276 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value 01, 03, 1, 2, 4, 05, 07, DI1~DI8 Brake 5, 10, 09, 11, Define Monitor Sel 11, 12, 13, 15 DO1~DO3 Brake 50, 52, 54 Define Control 14, 0 * When the speed unit is rpm (select 1 [rpm Display] in DRV-32 [Hz/rpm Select]), gray...
Page 277: [ Image 35. Brake Status Block ]
Learning Advanced Features Brake Status Diagram DISABLE ❶ ❶ ❽ ❽ ❷ ❷ ENGAGE ENGAGING RELEASING ❼ ❼ Engage Delay Release Wait ❺ ❺ ❸ ❸ ❻ ❻ ❺ ❺ RELEASE Release Delay Engaging Wait ❹ ❹ ❷ ❷ ❺ ❺ [ Image 35.
Page 278 Learning Advanced Features Status Name Description ENGAGING Enters when there is a brake engage request. The inverter will decelerate to compare the ramp frequency with the frequency set at ADV-49 (Br Engage Freq). If the ramp frequency goes below Engaging Wait the frequency set at ADV-49 Br Engage Freq) during deceleration, the output of the terminal block where 30 (Brake Control) is set will turn off.
Page 279: [ Image 36. An Example Of Brake Control ]
Learning Advanced Features ADV-42 ADV-43 ADV-48 (Br Load Req Delay) (Br Release Delay) (Br Engage Delay) Operation command Ramp Frequency ADV-49 (Br Engage Freq) Output current ADV-44 Brake (BR Release FwdFreq)/ Output Terminal ADV-41(BR Release Load) ADV-46 (BR Release Rev Freq) Motor Speed Mechanical Brake Status...
Page 280: Position Control
Learning Advanced Features 7.26 Position Control Position control helps move to the target position in a preset speed pattern. 7.26.1 Installation, Wiring, and Operation Preparation For position control, an encoder must be installed to figure out the position. Refer to the encoder option manual for its installation.
Page 281: Independent Position Control Operation
Learning Advanced Features 7.26.2 Independent Position Control Operation The inverter can output proper frequency to help the load reach the target position according to current position (Cur Position) and target position (Tar Position) commands. Setting Initial Group Code LCD Display Set Value Unit Range...
Page 282 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value DI Dependent Keypad 2 Internal Comm. Cmd Source USB Comm. Option Comm. UserSequence Stop POS Run POS Run Cmd Keypad Set Pre-Posi POS Run Relative Multi Sync Time 0.00 0.00~650.00 0.00...
Page 283 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value Trip HW Limit Prot Mode Warning Max Track Pulse 30000 0~65000 30000 Puls Tar Bound Pulse 0~65000 Puls CoastStop (FreeRun) Error Stop Mode Trip Dec Stop Inverse + index Inverse...
Page 284 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value 0.00~ TRJ Acc Time-01 10.00 10.00 6000.00 0.00~ TRJ Dec Time-01 10.00 10.00 6000.00 TRJ Tar Pos-02 30000 0~65000 30000 1.00~Max TRJ Tar Freq-02 60.00 60.00 Frequency 0~Maximum TRJ Tar Spd-02...
Page 285 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value 0~Maximum TRJ Tar Spd-05 1800 1800 Speed 0.00~ TRJ Acc Time-05 10.00 10.00 6000.00 0.00~ TRJ Dec Time-05 10.00 10.00 6000.00 TRJ Tar Pos-06 30000 0~65000 30000 1.00~Max TRJ Tar Freq-06...
Page 286 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value TRJ Tar Pos-09 30000 0~65000 30000 1.00~Max TRJ Tar Freq-09 60.00 60.00 Frequency 0~Maximum TRJ Tar Spd-09 1800 1800 Speed 0.00~ TRJ Acc Time-09 10.00 10.00 6000.00 0.00~ TRJ Dec Time-09...
Page 287 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value 0.00~ TRJ Acc Time-12 10.00 10.00 6000.00 0.00~ TRJ Dec Time-12 10.00 10.00 6000.00 TRJ Tar Pos-13 30000 0~65000 30000 1.00~Max TRJ Tar Freq-13 60.00 60.00 Frequency 0~Maximum TRJ Tar Spd-13...
Page 288 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value 1.00~Max TRJ Tar Freq-16 60.00 60.00 Frequency 0~Maximum TRJ Tar Spd-16 1800 1800 Speed POS2 0.00~ TRJ Acc Time-16 10.00 10.00 6000.00 0.00~ TRJ Dec Time-16 10.00 10.00 6000.00...
Page 289: Overall Block Diagram
Learning Advanced Features 7.26.2.1 Overall Block Diagram Independent position control operation mode consists of five functional blocks: Speed pattern occurrence, position control, speed command selection, current position processing, and homing. Homing Reference Speed (Homing Reference Speed) Homing Trip Reference Speed (Trip Reference Speed) Trip Processing Target Position...
Page 290 Learning Advanced Features Selecting Operation Command Source If you set App-44 (Pos Ctrl Enable) to 1 (Yes), operation command source is determined by POS1-10 (Cmd Source) regardless of the settings at DRV-10 (1st Command Source) and DRV-11 (1st Freq Ref Src). The position control operation for each source of POS1-10 (Cmd Source) is as follows: Code and...
Page 291: [ Image 38. Position Path Selection And Speed Pattern Occurrence Block ]
Learning Advanced Features 7.26.2.2 Position Path Selection and Speed Pattern Occurrence Block Select a target path and create a required path profile (trapezoid speed pattern of “acceleration → constant speed → deceleration”) to reach the target position from the current position using the target position, acceleration time, deceleration time, and maximum speed according to the target path.
Page 292 Learning Advanced Features Current position (POS1-04 Cur Position), target position (POS2 TRJ Tar Pos-1116), path acceleration time (POS2 TRJ Acc Time-1-16), path deceleration time (POS2 TRJ Dec Time-1-16), and path normal speed (POS2 TRJ Freq/Spd-1-16) are required for speed profile algorithm. In POS2 group, there are 16 position control paths in total, each path consisting of four parameters (target position, acceleration time, deceleration time, and frequency/ speed).
Page 293: [ Image 39. An Example Of Operation Based On Position Control Path Settings ]
Learning Advanced Features An Example of Position Control Path Reference • TRJ Tar Pos-xx: 14400UC • TRJ Freq-xx: 30.00 Hz (based on TRJ Spd-x: 900 rpm, 4 Poles) • TRJ Acc Time-xx: 20sec • TRJ Dec Time-xx: 30sec • ENC-12 Resolution/Pulse: 1024 •...
Page 294: [ Image 40. Position Control Block ]
Learning Advanced Features Caution • Make sure the value of 65535 * UC Denominator / UC Numerator does not exceed 2,147,483,647. That is, the position control does not work properly when the value of UC Denominator / UC Numerator is smaller than 1 / 32768. •...
Page 295: [ Image 41. Speed Command Selection Block ]
Learning Advanced Features Related Parameters-Setting Details Code and Description Functions Displays the difference (pulses) between the position reference POS1-6 Error Value pulse and position feedback pulse real-time during position control operation. It is always 0 in other operation modes. Enter P gain (%). For example, where the P gain is 10% with 2 πrad of position error based on mechanical angle of the motor, POS1-20 10% of normal speed of position control (POS-2 TRJ Tar Freq-xx...
Page 296: Trip Processing Block
Learning Advanced Features 7.26.3 Trip Processing Block It processes trips regarding position control operation during position control operation. You can monitor upper and lower limit hardware switch (Pos HW Limit High/Low) or upper and lower limit software switch (Pos SW Limit Low/High) inputs. When it is in the relative status, it will operate according to the set mode at POS1-40 Error Stop Mode (0: CoastStop(FreeRun)/1: Trip Dec Stop).
Page 297 Learning Advanced Features List of Related Parameters Code and Functions Description POS1-07 Reference Value Current command position value. POS1-08 Feedback Value Current position value. Selects operation mode when there is a trip from control operation. Item Functionality Immediately blocks inverter output.
Page 298: [ Image 43. Current Position Calculation Block ]
Learning Advanced Features 7.26.3.1 Current Position Calculation Block Performs functions such as monitoring and position change for pulses from encoder feedback. POS1 UC Numerator POS1 UC Denominator Encoder Input A, B, Z POS1 Speed Position Calculation Calculation Cur Position [ Image 43. Current Position Calculation Block ]...
Page 299: Homing Operation
Learning Advanced Features 7.26.3.2 Homing Operation Moves according to certain speed and certain acceleration and deceleration times by multifunction input signals and determines the position reference using various methods when it reaches position reference. POS1 Run Home Homing Type POS1 Homing Dir POS1 52/53...
Page 300: [ Image 45. An Example Of Homing Operation (Fwd [Rev] + Index) ]
Learning Advanced Features Homing operation according to POS1-50 Homing Type is as follows: Speed Cur Position Encoder Z-Pulse (Pos Run Home) (Pos Home) [ Image 45. An Example of Homing Operation (Fwd [Rev] + Index) ] Speed Cur Position Encoder Z-Pulse (Pos Run Home) (Pos Home) [ Image 46.
Page 301 Learning Advanced Features Code and Item Section Functionality Functions When the multifunction terminal that is set as 57 (POS Run Home) is turned on, it will operate according to the settings at POS1-51 (Homing Dir), POS1-52, 53 (Homing Freq, Homing Speed), and POS1-54 (Homing Ramptime).
Page 302: Proportional Synchronous Position Control
Learning Advanced Features Code and Item Section Functionality Functions When the multifunction terminal that is set as 57 (POS Run Home) is turned on, it will operate according to the settings at POS1-51 (Homing Dir), POS1-52, 53 (Homing Freq, Homing Speed), and POS1-54 (Homing Ramptime).
Page 303: [ Image 47. Proportional Synchronous Position Control System ]
Learning Advanced Features 7.26.4.1 Implementation of Proportional Synchronous Position Control System In proportional synchronous position control operation mode, multiple inverters reach respective target position (mm) at the same time. The following image shows implementation of proportional synchronous control system using superordinate controller and inverters.
Page 304 Learning Advanced Features The following is the implementation of proportional synchronous position control operation per each step from the above image. Step 1 Setting proportional synchronous position control operation mode Select 1 (Multi Sync Pos) at POS1-02 (Pos Ctrl Mode) for all inverters (1-n) to set proportional synchronous position control operation mode.
Page 305: Cause Of Abnormalities And Inspection
Learning Advanced Features 7.26.5 Cause of Abnormalities and Inspection When there is a trip related to position control, refer to the following depending on the type of trips for inspection: Table 8. Position Control-Related Trips Trip Cause of Abnormality Inspections Occurs when the setting value of Check if the setting values of POS1-04 (Cur Position) is higher...
Page 306: Using User Sequence
Learning Advanced Features 7.27 Using User Sequence User sequence is used to implement a simple sequence by utilizing the combination of various function blocks via DriveView9, the PC software for inverter connection from our company. Refer to DriveView9 manual for more details. 7.27.1 Operation Preparations To use a user sequence, implement the user sequence with DriveView9 and download related parameters to S300, and then operate with the user sequence.
Page 307 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value Command 0.00~Max 0.00 0.00 Frequency Frequency 0~Maximum Command Speed Speed Command Torque -180.0~180.0 0.00~ Acc Time 20.00 20.00 6000.00 0.00~ Dec Time 30.00 30.00 6000.00 Output Current Output Frequency Output RPM Output Voltage...
Page 308 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value H/W OCS S/W OCS Dwell Operating Stopped Forward Direction Reverse Direction DC Operating Warned Tripped * When the speed unit is rpm (select 1 [rpm Display] in DRV-32 [Hz/rpm Select]), gray shaded areas will be visible.
Page 309 Learning Advanced Features Auto Restart for General Acceleration Setting Details Code and Description Functions Set this parameter to 1 (Yes) and five parameter groups related to APP-03 UserSeq user sequence (US, USL, USV, USP, and USM) will be displayed Enable in the Smart Operator.
Page 310 Learning Advanced Features Code and Description Functions Sets the display mode for parameters used in the user sequence. Item Functionality Signed 0 dec. pl. Signed integer, decimal number Signed real number to one decimal Signed 1 dec. pl. place, decimal number Signed real number to two decimal Signed 2 dec.
Page 311: Logic Function
Learning Advanced Features 7.27.2 Logic Function It is a function block used for user sequence and logic operations. Code and Description Functions Selects an operator for a logic operation. Operator NOT(A) AND(A,B,C) NAND(A,B,C) OR(A,B,C) NOR(A,B,C) XOR(A,B) (A AND B) OR C USL- AND(A,B,!C) 05, 10, 15, 20, 25,...
Page 312: [ Image 49. Logic Function (1 : And(A,B,C)) ]
Learning Advanced Features Code and Description Functions [1 : AND(A,B,C)] Input A Input B Output Input C [ Image 49. Logic function (1 : AND(A,B,C)) ] [2 : NAND(A,B,C)] Input A Input B Output USL- Input C 05, 10, 15, 20, 25, [ Image 50.
Page 313: [ Image 53. Logic Function (5 : Xor(A,B,C)) ]
Learning Advanced Features Code and Description Functions [5 : XOR(A,B,C)] Input A Input B Output Input C [ Image 53. Logic function (5 : XOR(A,B,C)) ] [6 : (A AND B) OR C] Input A Input B Output Input C USL- 05, 10, 15, 20, 25, [ Image 54.
Page 314: [ Image 57. Logic Function (9 : R-Edge-Detect(A)) ]
Learning Advanced Features Code and Description Functions [9 : R-EDGE-DETECT(A)] Input A Output (Input C == 0) Output (Input C == 1) US-02 USL- UserSeq Loop Time 05, 10, 15, 20, 25, [ Image 57. Logic function (9 : R-EDGE-DETECT(A)) ] 30, 35, 40, 45, 50, 55, 60, 65, 70, 75 [10 : F-EDGE-DETECT(A)]...
Page 315 Learning Advanced Features Code and Description Functions USL-06, 11, 16, 21, 26, 31, 36, 41, 46, 51, 56, 61, 66, 71, Input A value of each logic block. 76 Valuexx InputA (Valuexx: Value01~Value15) USL-07, 12, 17, 22, 27, 32, 37, 42, 47, 52, 57, 62, 67, 72, Input B value of each logic block.
Page 316: Arithmetic Function (Value Function)
Learning Advanced Features 7.27.3 Arithmetic Function (Value Function) It is a function block used for user sequence and arithmetic operations. Code and Description Functions Selects an operator for an arithmetic operation. Operator Description A+B+C Outputs A + B + C. A-B-C Outputs A - B - C.
Page 317 Learning Advanced Features Code and Description Functions Operator Description Implements hysteresis band C to B A>B+/-C value. A>=B Outputs 1 if A >= B, and 0 if not. A<=B Outputs 1 if A <= B, and 0 if not. A(1+B) Outputs A * (1 + B / 100).
Page 318 Learning Advanced Features Code and Description Functions Additional descriptions on main functions [12/13 : Up/Down Counter] Count works under the following conditions: Condition A for Count Operation 0→1 1→0 Change A [14 : BINARY DECODE] Decoded output according to C, B, and A values follow below conditions: USV-05, 10, 15, 20, Output...
Page 319: [ Image 59. Logic Function (26 : On Delay) ]
Learning Advanced Features Code and Description Functions [20 : ABS(A)>ABS(B)+/-C] Output works under the following conditions: Condition Output ABS(A) > ABS(B)+C ABS(A) < ABS(B)-C ABS(B)-C < ABS(A) < ABS(B)+C No change [26 : ON DELAY] Input A Output (Input C == 0) USV-05, 10, 15, 20, 25, 30, 35, 40, 45, Output...
Page 320: [ Image 61. Logic Function (28 : Timer) ]
Learning Advanced Features Code and Description Functions [28 : TIMER] Input A Input B Output [ Image 61. Logic function (28 : TIMER) ] Timer works under the following conditions: Output USV-05, 10, 15, 20, 25, 30, 35, 40, 45, Increase by 1 every 100 msec, 50, 55, 60, 65, 70, 0 after 99999999...
Page 321: [ Image 63. Logic Function (30 : Window C <= A <= B) ]
Learning Advanced Features Code and Description Functions [30 : WINDOW C<= A<=B] Input B USV-05, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, Input C 75 Logicxx Type (Logicxx: Input A Logic02~Logic15) Output [ Image 63. Logic function (30 : WINDOW C <= A <= B) ] USV-06, 11, 16, 21, 26, 31, 36, 41, 46, 51, 56, 61, 66, 71,...
Page 322: Parameter Function (Paraset Function)
Learning Advanced Features 7.27.4 Parameter Function (ParaSet Function) This function sets parameters registered in the block by getting inputs of rising edge or falling edge values from the user sequence. Code and Description Functions USP-01, 04, 07, 10, 13, 16, 19, 22, 25, 28, 31, 34, 37, 40, Sets event parameter values of your choice.
Page 323: Special Function
Learning Advanced Features 7.27.5 Special Function It is a special function used in the user sequence. Code and Functions Description USM-01~16 Mux1 Inputxx (Inputxx: Input01~Input16), Input data and output value for MUX1. USM-17 Mux1 Output USM-18 Demux1 Input USM-19~34, Input data and output value for DEMUX1. Demux1 Outputxx (Outputxx: Output01~Output16) USM-35 PI Run Enable,...
Page 324: Simple Master
Learning Advanced Features 7.27.6 Simple Master Simple master allows you to operate multiple inverters as slaves by having one of the inverters acting as a communication master through the user sequence. 7.27.6.1 Simple Master Simple master consists of the following: S300 #1 S300 #2 S300 #3 S300 #N S300 Master RS485: S+ S- 5G...
Page 325 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value Comm Enable Always Mode Enable 02, 09, 16, P01~10-Slave 23, 30, 37, Used RW Mode 44, 51, 58, 65 3, 10, 17, 24, P01~10- 31, 38, 45, 1~64 SlaveStationID 52, 59, 66...
Page 326 Learning Advanced Features Communication Parameters Setting Details Code and Functions Description Sets the value to 2 (Modbus RTU Master). INTC-02 Protocol The inverter plays as a self-communication master and allows for communication with subordinate inverters. Sets simple master operations. Item Functionality None Deactivates the simple master.
Page 327 Learning Advanced Features Code and Functions Description INTM-05, 12, 19, 26, 33, 40, 47, 54, 61 Sets the starting address of parameters for communication frames with each slave, P1-10. P01~10-Slave DataAddr INTM-06, 13, 20, 27, 34, 41, 48, 55, 62 Sets the starting address of the master parameter for communication frames with each slave, P1-10.
Page 328: Operating Winder/Unwinder
Learning Advanced Features 7.28 Operating Winder/Unwinder Also called a spooler, a winder winds web materials (iron wire, iron sheet, steel wire, etc.) while maintaining consistent tension. While, unwinder unwinds the web materials while maintaining consistent tension. The inverter’s winder and unwinder functions are used in a closed-loop tension control system, which winds or unwinds tensions by basically using the analog feedback from tension control/detection devices, including a dancer and load cell, to operate the PID controller.
Page 329: Overall Compositions
Learning Advanced Features • Inertia compensation function (Related code: WEB1-47, 48) • Function to maintain the tension and conduct emergency stop operation (Related code: APP-46) • Function to detect web material before broken (Related code: WEB1-80~84) 7.28.1 Overall Compositions 7.28.1.1 Speed Control Mode with a Tension Sensor (Capstan Operation) Output frequency Diameter/ thickness...
Page 330: [ Image 66. Torque Control Mode With A Tension Sensor ]
Learning Advanced Features 7.28.1.2 Torque Control Mode with a Tension Sensor Output frequency Diameter/ thickness Diameter Calculation part Final speed Final speed command Main speed Main speed Calculation Command WEB Break occurred part part Output torque Disconnection detection part Tension PID feedback Tension PID Tension PID command...
Page 331: [ Image 67. Speed Control Mode Without A Tension Sensor ]
Learning Advanced Features 7.28.1.3 Speed Control Mode without a Tension Sensor Output frequency Diameter/ thickness Diameter Calculation part Final speed Final speed command Main speed Main speed Calculation Command WEB Break occurred part part Output torque Disconnection detection part Tension PID feedback Tension PID Tension PID command...
Page 332: [ Image 68. Torque Control Mode Without A Tension Sensor ]
Learning Advanced Features 7.28.1.4 Torque Control Mode without a Tension Sensor Output frequency Diameter/ Diameter thickness Calculation part Final speed Final speed command Main speed Main speed Calculation Command WEB Break occurred part part Output torque Disconnection detection Tension PID feedback part Tension PID Tension PID...
Page 333: Main Speed Command Part
Learning Advanced Features 7.28.2 Main Speed Command Part The unit for the main speed command is percent (%) and is the same concept as the flux (mpm). For example, there is a system with a maximum flux of 800 mpm, and if you want to operate the system at 400 mpm, set the main speed command to 50% (400/800x100%).
Page 334 Learning Advanced Features 7.28.2.1 Main Speed Command Main Speed Command Settings Setting Initial Group Code LCD Display Set Value Unit Range Value Main Spd Monitor Main Spd Keypad 0-11 Source Main Spd Kpd 0.00-100.00 0.00 WEB1 Main XcelTime Main Spd Acc 0.00-300.00 10.00 Time...
Page 335 Learning Advanced Features Code and Description Functions Operator Description Operates at the main speed input in the Keypad WEB1-12. Analog Input 1 AI terminal of the terminal block Analog Input 2 (analog input terminal) Analog Input 3 PTI terminal of the terminal block Pulse Input (pulse input terminal, input pulse of WEB1-11 Main Spd...
Page 336 Learning Advanced Features 7.28.2.2 Emergency Stop (Quick Stop) Setting Initial Group Code LCD Display Set Value Unit Range Value Q Stop Dec T 0.00-6000.00 5.00 01, 03, 1, 2, 4, DIx Define 05, 07, Quick Stop 5, 10, 09, 11, (DIx: DI1-DI8) 11, 12, 9 13, 15...
Page 337: Tension Command Part
Learning Advanced Features 7.28.3 Tension Command Part The unit for the tension command is percent (%) and is the same concept as the force (kgf). For example, if you want to maintain the value of 10 kgf in the system with the load cell’s maximum measured load (force) of 2 kgf, set the tension command to 50% (10/20 x 100%).
Page 338: Tension Command
Learning Advanced Features 7.28.4 Tension Command Setting Initial Group Code LCD Display Set Value Unit Range Value Reference Value Keypad Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Internal Comm. Reference WEB1 Source Comm. Option Comm. User Sequence X-Analog Input 1...
Page 339: Taper Function
Learning Advanced Features Tension Command Settings Details Code and Description Functions WEB1-08 Shows the current PID controller reference (%, tension). Reference Value You can set the PID controller's reference value by using a WEB1-21 Ref Keypad Set keypad. Activated when WEB1-20 value is 0 (Keypad). WEB1-20 Selects the input type (analog, built-in communication, external Reference Source...
Page 340: [ Image 71. Changes In Stress And Tension According To The Diameter Of The Roll Winder ]
Learning Advanced Features Web material Desired tension Stress Synthesized tension Roll Set up the taper to create the desired size of the synthesized tension [ Image 71. Changes in stress and tension according to the diameter of the roll winder ] Linear Taper Tension Demand = Tension Spt ×...
Page 341 Learning Advanced Features 7.28.4.2 Tension Boost/Down Function You can boost/down the tension (PID reference) by the set values. Setting Initial Group Code LCD Display Set Value Unit Range Value Fixed Tension Up Type Proportional Tension Up In 0.00-50.00 0.00 WEB1 Fixed Tension Down Type...
Page 342: Web Pid Controller
Learning Advanced Features 7.28.5 Web PID Controller Uses analog feedback from tension detection devices, including a dancer and load cell to determine the Web PID controller outputs in the closed-loop tension control system. The Web PID controller means the optimized PID controller for tension control system.
Page 343 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value -100.00- Output Value 100.00 -300.00- Reference Value 300.00 -300.00- Feedback Value 300.00 -300.00- Error Value 300.00 Web PID Enable Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Internal Comm.
Page 344 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value 01, 03, Web I-Term Clear 1, 2, 4, DIx Define 05, 07, Disable WPID 5, 10, 09, 11, (DIx: DI1-DI8) 11, 12, 9 Web Splice 13, 15 Web PID Controller Settings Details Code and Description...
Page 345 Learning Advanced Features Code and Description Functions You can adjust the scale of the PID controller output. When WEB1-39 assuming PID controller saturation, setting it to 100% will return 100% of the PID controller output, and setting it to 30% will return Output Scale 30% of the PID controller output.
Page 346: [ Image 74. How Does Web1-42 (Pid Start Ramp) Work ]
Learning Advanced Features Code and Description Functions The PID output can be increased ramp for a set time during the inverter's initial powering on. This function allows the smooth output of the PID controller during the initial powering on to improve transient phenomena, including fluctuations of a dancer or load cell during the initial powering on.
Page 347: [ Image 75. Web Pid Gain Calculation ]
Learning Advanced Features 7.28.5.2 Web PID Gain Calculation Part WPID Gain Change WEB1 WEB1 PI Gain Ramp Time PI Gain Chg Mode WEB1 Proportional Gain1 WEB1 PGain Proportional Gain2 Linear Interpolation Output frequency WEB1 PI Gain Speed1 WEB1 WEB1 PI Change Speed2 Profile P Mode WEB1 Profile P Gain...
Page 348 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value Proportional 0.00- 100.0 5.00 Gain1 100.00 0.00- Integral Time1 10.00 10.00 200.00 Proportional 0.00- 5.00 5.00 Gain2 100.00 0.00- Integral Time2 10.00 10.00 200.00 Derivative Time msec 1000 Ramp...
Page 349 Learning Advanced Features Web PID Gain Calculation Part Settings Details Code and Description Functions WEB1-32 Is a Proportional (P) gain for the PID controller. The P controller Proportional Gain1 output is 100% when the P gain is 100% and the error value is WEB1-34 100%.
Page 350: [ Image 76. Gain Change According To The Multifunction Input's Wpid Gain Change ]
Learning Advanced Features P, I Gain Switchover Function [Gain change according to the input change] If something changes in the terminal input set to 73 (WPID Gain Change) during the inverter operation or the user changes the WEB1-32 (PID Proportional Gain1) and WEB1-33 (Integral Gain1) settings and P/I gain switchover is triggered temporarily without switchover ramp time, the system response may unstable.
Page 351: [ Image 77. P/I Gain Switchover According To The Speed ]
Learning Advanced Features [Gain change according to the speed] You can change the P/I gain to the ramp according to the inverter’s operation speed changes. WEB1-34 WEB1-35 Proportional Gain2 Integral Time2 WEB1-32 WEB1-33 Proportional Gain1 Integral Time1 WEB1-44 WEB1-45 WEB1-44 WEB1-45 PI Change Speed1 PI Change Speed2...
Page 352: Diameter Calculation Part
Learning Advanced Features 7.28.6 Diameter Calculation Part Output frequency (Hz) WEB1 WEB1 WEB1 Max Main Freq Min Diameter Diameter Calc Mode WEB1 Dia Calc Hold Freq Diameter (%) Main speed Main speed (%) Min Diameter Output frequency X 100% Max Main Freq WEB1 Min Main Speed Diameter calculation...
Page 353 Learning Advanced Features The flux of the winder/unwinder, motor speed, and diameter in the tension control system has a correlation in the Formula 2. Flux [ mpm ] = motor speed [ rpm ] × ( diameter × π ) [ m ] = consistent Formula 2 In a closed-loop tension control system, the winder always has a consistent flux (MPM) unless the user adjusts it at their own discretion, and the winder’s actual...
Page 354 Learning Advanced Features 7.28.6.1 Bobbin Selection and Initializing Diameter Functions Setting Initial Group Code LCD Display Set Value Unit Range Value Curr Bobbin 0.00- Bobbin1 10.00 10.00 100.00 0.00- Bobbin2 15.00 15.00 WEB1 100.00 0.00- Bobbin3 20.00 20.00 100.00 0.00- Bobbin4 25.00 25.00...
Page 355: [ Image 80. When There Are Bobbins In Various Sizes ]
Learning Advanced Features Code and Description Functions The bobbin diameter is selected as follows according to the combination of multifunction input terminals set to 74 (Web Bobbin-L) and 75 (Web Bobbin-H). When the bobbin is selected, initialize to the selected bobbin's diameter by turning the multifunction input terminal set to 76 (Web Preset) on and off.
Page 356 Learning Advanced Features 7.28.6.2 Diameter Calculation Function Setting Initial Group Code LCD Display Set Value Unit Range Value Curr Diameter 0.00- Diameter LPF 30.00 1.00 300.00 0.00-Max WEB1 Max Main Freq Frequency 60.00 5.00- Min Diameter 10.00 10.00 100.00 Disable WPID 01, 03, 1, 2, 4, Diameter Calc...
Page 357 Learning Advanced Features Diameter Calculation Function Details Code and Description Functions Displays the current bobbin's diameter (%). After turning on/off the WEB1-50 multifunction terminal set to 76 (Web Preset), the diameter (%) of the selected bobbin will be displayed, and the calculated diameter Curr Diameter (%) in the Formula 4 will be updated during the operation.
Page 358 Learning Advanced Features 7.28.6.3 Stopping Diameter Calculation Function Setting Initial Group Code LCD Display Set Value Unit Range Value 0.00- Dia Calc Hold 5.00 5.00 Freq 30.00 WEB1 0.00- Min Main Speed 3.00 1.00 100.00 01, 03, 1, 2, 4, DIx Define 05, 07, Diameter Calc...
Page 359: Final Speed Calculation Part
Learning Advanced Features 7.28.7 Final Speed Calculation Part WEB1 Splice Level WEB1 Splice Level Main speed 100% Max Main Freq Main speed (%) U1[%] U1(%) Max Main Freq WEB1 100% Fixed WPID Enable If (Main speed >= Fixed WPID min Main Spd) Main speed + WPID(%) Main speed PID output...
Page 360 Learning Advanced Features 7.28.7.1 How does PID output works (for fixed /unfixed PID controller) Setting Initial Group Code LCD Display Set Value Unit Range Value Fixed WPID Enable WEB1 Fixed WPID Min 10.00 0.00-50.00 10.00 Main Spd Code and Description Functions Setting the EB1-70 (Fixed WPID Enable) value to 1 (Yes), the PID output (%), which is the Web PID controller's output in the Formula 6, will always be consistent regardless of the size of the main speed (%).
Page 361 Learning Advanced Features Code and Description Functions Prevent Web PID controller's output becomes too small when the WEB1-70 value is 0 (No) and the system receives the main speed (%) command below the value set in the Fixed WPID Min Main Spd or lower.
Page 362 Learning Advanced Features 7.28.7.2 Final Speed (Hz) Calculation [ Image 81 ] In the Illustration 81, the U1 (%) is the main speed command (%) = PID output (%), and it is converted to frequency (Hz) as follows: Main Speed + PID output [%] Main speed + PID output [ Hz ] = ×...
Page 363 Learning Advanced Features 7.28.7.3 Reverse Extremely Slow Speed Function Setting Initial Group Code LCD Display Set Value Unit Range Value Rev Tension WEB1 Enable [ Image 81 ] When the symbol of the U1 (%), or the main speed command (%) + PID output (%) is (-) in Illustration 81, select WEB1-72 (Rev Tension Enable) code to 1 (Yes) value and send forward operation command will operate the system reverse orientation by the absolute value of the PID output (%).
Page 364 Learning Advanced Features 7.28.7.4 Splicing Function Setting Initial Group Code LCD Display Set Value Unit Range Value 0.00- WEB1 Splice Level 0.00 0.00 100.00 01, 03, 1, 2, 4, DIx Define 05, 07, 5, 10, Web Splice 09, 11, 11, 12, (DIx: DI1-DI8) 13, 15 A splicing system is a system allowing bobbin replacement during operation by...
Page 365: [ Image 82. Splicing Diagram ]
Learning Advanced Features The splicing system of the winder has the structure below: Orientation of the Superordinate Superordinate Orientation of the material material controller controller Bobbin1 Bobbin2 Bobbin1 Bobbin2 [ Image 82. Splicing Diagram ] Table 12. Explanation for splicing diagram Description The Bobbin 1, wrapped with materials, will send a signal to the ❶...
Page 366: Final Tension Calculation Part
Learning Advanced Features Add the frequency value by the WEB1-74 (Web Bias Freq) to the command speed to output final command speed. This setting is only valid for open-loop speed control mode. By adding the speed bias, the speed controller in the open-loop speed control mode will be saturated, and the torque limit output will be obtained during the operation.
Page 367: Disconnection Detection Part
Learning Advanced Features The open-loop tension system requires the WEB1-90 (Web PID FF Gain) values to be at 100%, a set value shipped from the factory. The closed-loop tension system allows other values for faster tension response. 7.28.9 Disconnection Detection Part 0: Speed Control mode with tension sensor Tension PID feedback (%) 1: Torque Control mode with tension sensor...
Page 368 Learning Advanced Features The closed-loop tension control system uses tension detection devices, including a dancer and load cell. When the feedback from the tension detection device is maintained at too-higher or too-lower values for longer than the set time, the inverter sends signals to the superordinate controller via contact with a multifunction output and starts suitable protection behavior to prevent web materials from breaking.
Page 369 Learning Advanced Features Setting Initial Group Code LCD Display Set Value Unit Range Value 1, 2, 4, DOx Define 50, 52, 5, 10, WebBreak Warn 0-50 (DOx: DO1- 11, 12, DO3) Disconnection Detection Part Details Code and Description Functions Sets whether to use the disconnection detection function. Configuration Functionality None...
Page 370: Torque Limit Calculation Part
Learning Advanced Features 7.28.10 Torque Limit Calculation Part WEB2 Friction Auto Tuning WEB2 Tuning friction loss Friction Comp Freq 01 MOT1,2 Torque Control En Spd/Trq Change WEB2 Friction Comp Trq 01 Friction loss Diameter is increasing or not changing Output frequency (Hz) Trq2-Trq1 Torque Control mode (CurrSpd-Spd1)+Trq1...
Page 371 Learning Advanced Features 7.28.10.2 Measuring Friction Loss Friction occurs for all mechanical equipment during operations. It decreases the system control performance and results in loss. When the materials are connected by a certain tension, for example, a tension control system, the friction loss from the roll may affect the materials’...
Page 372 Learning Advanced Features Initial Group Code LCD Display Set Value Setting Range Unit Value Fric Comp Spd 4~ Fric Comp Spd 5 Fric Comp Spd 6 Fric Comp Trq 5 0.00 0.00~100.00 0.00 Fric Comp Freq 5~ Fric Comp Freq 6 36.00 36.00 Fric Comp Freq 7...
Page 373: [ Image 86. Friction Loss According To The Speed ]
Learning Advanced Features Friction Loss Measurement Settings Details Code and Description Functions Select 1 (Yes) after installing an empty bobbin not connected to the materials to the roll to measure the friction loss. The friction loss measurement is triggered when selecting the function. The friction WEB2-1 Friction loss is measured by 10 speed intervals set in WEB2-2-31 and at Auto Tuning...
Page 374 Learning Advanced Features 7.28.10.3 Initial Tension Boost Setting Initial Group Code LCD Display Set Value Unit Range Value TrqLimit 1.00 0.1-60.00 1.00 BoostTime WEB1 100.00- TrqLimit Boost 150.00 150.00 500.00 Initial Tension Boost Details Code and Description Functions WEB1-95 TrqLimit Outputs the torque limit of the initial boost for the set time.
Page 375: How To Set Parameters
Learning Advanced Features 7.28.11 How to set parameters 7.28.11.1 How to activate WEB groups To use the WEB functions, APP-45 (Tension Ctrl En) code value is set to 1 (Yes). When the WEB1 and WEB2 groups are activated, you can set the WEB related parameters.
Page 376 Learning Advanced Features Finally, select No. 70 (WebCtrl Fwd Run) or 71 (WebCtrl Rev Run) to Define codes of DI1-DI8 of the terminal input group (DIN) to send the operation command. Setting Initial Group Code LCD Display Set Value Unit Range Value WebCtrl...
Page 377: System Stop (Quick Stop)
Learning Advanced Features 7.29 System Stop (Quick Stop) The function stops to set the deceleration time through multifunction inputs during an emergency. Setting Initial Group Code LCD Display Set Value Unit Range Value Q Stop Dec T 5.00 0.00~6000.00 5.00 01, 03, 05, 1, 2, 4, DIx Define...
Page 378: No Restart After A Free-Run Stop
Learning Advanced Features 7.30 No Restart after a Free-Run Stop It prevents trips by prohibiting the restart command when restarting after a free-run stop due to free-run stop during an operation or a trip. When this function is in use, the restart command is prohibited for a fixed time as defined in the inverter according to its capacity or start setting.
Page 379: [ Image 89. An Example Of An Operation During Restart Prohibition After A Free-Run/Trip ]
Learning Advanced Features An Example of an Operation during a free-run Stop and Restart Prohibition A prevent Cmd trip occurs when there is an operation command during a free-run stop and restart prohibition after a free-run stop or a trip. Output frequency Free-run stop...
Page 380: [ Image 90. An Example Of A Restart After A Coaststop(Freerun)/Trip ]
Learning Advanced Features An Example of a Restart after Reset (Reset Restart) during a free-run Stop and Restart Prohibition When you run speed search restart after free-run stop or a trip, speed search starts after a free-run stop and the restart prohibition time. A longer time between PRT-07 (Retry Delay) and a free-run stop and restart prohibition apply for the start time for speed search restart.
Page 381: Timer Settings
Learning Advanced Features 7.31 Timer Settings Use a timer function of the multifunction input terminal to control the On/Off for a relay and multifunction output according to the timer settings. Setting Initial Group Code LCD Display Set Value Unit Range Value 01, 03, 05, 1, 2, 4,...
Page 382: [ Image 91. An Example Of Timer Settings At Multifunction Terminal ]
Learning Advanced Features Timer Setting Details Code and Functions Description DIN-01, 03, 05, 07, 09, 11, 13, 15 Choose one of the multifunction input terminals for DIx Define the timer and set it to 32 (Timer Input). (DIx: DI1~DI8) OUT-50, 52, 54 Set a multifunction output terminal or relay for the DOx Define timer to 23 (Timer Output).
Page 383: Functions Of Terminal Block
Functions of Terminal Block 8 Functions of Terminal Block Multifunction Digital Inputs 8.1.1 Delay Time Settings for Multifunction Input Terminals You can set the time constant of filters for the multifunction input terminals. It is used to improve the responsiveness of the input terminals. Setting Initial Group...
Page 384: Contact Settings For Multifunction Input Terminals
Functions of Terminal Block Delay Time for Multifunction Input Terminal Setting Details Code and Functions Description Sets the DI1-DI8 On Delay and Off Delay values for each input terminal. It is not used when set to 0. DIN-25, 28, 31, 34, 37, 40, 43, 46 When you change the set time while a function DIx On Delay, is working during the time set for the parameter,...
Page 385: Multifunction Input Identification
Functions of Terminal Block 8.1.3 Multifunction Input Identification You can check the status of the multifunction input terminals. For example, when you select an input terminal as contact A (normal Open) and input at the relevant terminal, the status of the input terminal becomes On. Setting Initial Group...
Page 386 Functions of Terminal Block Code and Item Functionality Functions XEL-L Refer to 5.3.1.3 Multi-stage Acc/Dec Time XEL-M Setting with Multifunction Terminals. XEL-H Refer to 5.3.2.2 Acc/Dec Stop Command XEL-Stop Settings. Run Enable Refer to 7.4 Safe Operation Mode. Refer to 7.3 3-Wire Operation. 3-Wire 2nd Source Refer to 7.19 Second Operation Mode Settings.
Page 387 Functions of Terminal Block Code and Item Functionality Functions Forward JOG Refer to 7.2.2 Jog Operation by Terminal Block 2-Forward / Reverse Jog. Reverse JOG Refer to 7.7.1 Basic PID Operation. PPID Run Enable Refer to 7.7.4 PID Operation Switch (PID PPID Open Loop Openloop).
Page 388 Functions of Terminal Block Code and Item Functionality Functions POS HW Lmt L Refer to 7.26.3 Trip Processing Block. POS HW Lmt H POS Pattern-L POS Pattern-M Refer to 7.26.2.2 Position Path Selection and Speed Pattern Occurrence Block. POS Pattern-H POS Pattern-X POS Run Refer to 7.26.2.1 Overall Block Diagram.
Page 389: Analog Input
Functions of Terminal Block Analog Input 8.2.1 Analog Input Mode You can use Unipolar Voltage/Bipolar Voltage/Current inputs according to analog input mode settings. To use current mode, turn on SW4 at the relevant input port. Setting Initial Group Code LCD Display Set Value Unit Range...
Page 390: [ Image 2. External Power Source Connection ]
Functions of Terminal Block Analog Input Terminal Setting Details Code and Description Functions You can select and use the types of analog input terminals as follows: Unipolar Voltage: Input voltage of 0-10 V AI1,2,3 AI1,2,3 [ Image 2. External [ Image 3. Internal Power Source Connection ] Power Source Connection ] Bipolar Voltage: input voltage of -10-10 V...
Page 391: The Scale Of Analog Input
Functions of Terminal Block 8.2.2 The Scale of Analog Input Initial Group Code LCD Display Set Value Setting Range Unit Value 0.00 AI1 + x1 In 0.00 0.00~AI1 + x2 In 4.00 AI1 + y1 Percent -10.00 -100.00~100.00 0.00 -100.00 AI1 + x1 In~10.00 10.00 AI1 + x2 In...
Page 392: [ Image 7. The Size Of Analog Input Based On Analog Voltage Input - 1 ]
Functions of Terminal Block The Size of Analog Input Setting Details Code and Description Functions These parameters are used to configure the gradient level and offset the values of the output frequency, based on the size of the input voltage. When the voltage value is smaller than the setting values of AIN-05, 20, and 35, the setting values of AIN-06, 21, and 36 will be applied to more than 0 V.
Page 393: [ Image 8. The Size Of Analog Input Based On Analog Voltage Input - 2 ]
Functions of Terminal Block Code and Description Functions Analog Input Percentage (%) 100.00% AI1~AI3+y1 Percent AIN-05, 20, 35 AIx + x1 In, AIN-06, 21, 36 AIx+ y1 Percent, AIN-07, 22, 37 AIx + x2 In, AIN-08, 23, 38 AIx + y2 Percent AI1~AI3 +X2 In (AIx: AI1~AI3) Voltage...
Page 394: (Bipolar Voltage) - 1 ]
Functions of Terminal Block Code and Description Functions Analog Input Percentage (%) 100.00% AI1~AI3 AI1~AI3 AI1~AI3 -y2 -y1Percent Percent Percent AI1~AI3 +x1 In 0.00% Voltage AI1~AI3 -10V AI1~AI3 AI1~AI3 -x2 In -x1 In +x2 In AIN-09, 24, 39 AIx-x1 In [ Image 9.
Page 395: (Bipolar Voltage) - 3 ]
Functions of Terminal Block Code and Description Functions Analog Input Percentage (%) Analog Input Value 100.00% AI1~AI3 +y1Percent AI1~AI3 AI1~AI3-x2 In AI1~AI3-x1 In -x2 In 0.00% Voltage -10V AI1~AI3 -x1 In AI1~AI3 -y1Percent AI1~AI3 +y2Percent AI1~AI3 -y2Percent AIN-09, 24, 39 100.00% AIx-x1 In [ Image 11.
Page 396: Quantization
Functions of Terminal Block Code and Description Functions For instance, when you set AI1-AI3-x1 In (AIN-9, 24, and 39) as -2 V, AI1-AI3-y1 Percent (AIN-10, 25, and 40) as 10%, AI1-AI3-x2 In (AIN- 11, 26, and 41) as -8 V, and AI1-AI3-y2 Percent (AIN-12, 27, and 42) as 80%, the output frequency moves in between 6 and 48 Hz.
Page 397: [ Image 14. Frequency Change Based On Quantization Settings ]
Functions of Terminal Block Quantization Setting Details Code and Description Functions Sets values for quantization. The inverter outputs the frequency by measuring (quantizing) the height (value) of the input signal at a consistent interval when quantization values are set. This means that the delicate control on the output frequency (power resolution) is low, but the noise is reduced, so it is suitable for systems that are sensitive to noise.
Page 398: Filter
Functions of Terminal Block 8.2.4 Filter Initial Group Code LCD Display Setting Range Unit Value Value AI1~AI3 LPF 04, 19, 34 ~10000 msec Gain Filter-Setting Details Code and Description Functions Sets time constant for the low-pass filter. Use this when the change in frequency settings is too big from too much noise.
Page 399: Multifunction Digital Output
Functions of Terminal Block Multifunction Digital Output 8.3.1 Multifunction Output Terminal Settings Multifunction output terminal and relay settings Setting Initial Group Code LCD Display Set Value Unit Range Value None DO1~DO3 50, 52, 54 0~45 24, 14, 0 Define Trip Virtual 50, 52, 54, VIRT...
Page 400: [ Image 16. An Example Of Torque Detection - 1 ]
Functions of Terminal Block Torque Detection Settings Initial Group Code LCD Display Setting Range Unit Value Value Torque Detect 100.0 0.0~150.0 100.0 Level Torque Detect 50.0 0.0~100.0 50.0 Band Multifunction Output Terminal and Relay Settings Details Code and Description Functions Sets terminal items for relay 1, 2, and open collector output.
Page 401: [ Image 17. An Example Of Torque Detection - 2 ]
Functions of Terminal Block Code and Description Functions Item Functionality Outputs a signal when the user-set frequency and detected frequency (OUT-75 FDT Frequency) are equal, and fulfills no. 1 above, FDT-1 conditions at the same time. • [Absolute value (set frequency - detected frequency) < detected frequency band / 2] &...
Page 402: [ Image 19. An Example Of Torque Detection - 4 ]
Functions of Terminal Block Code and Description Functions Item Functionality Output signal can be separately set for acceleration and deceleration conditions. • In acceleration: Operating frequency ≧ detected frequency • In deceleration: Operating frequency > (detected frequency - detected frequency band / 2) FDT-4 output is as follows when the detected frequency band is 10 Hz and the detected...
Page 403 Functions of Terminal Block Code and Description Functions Item Functionality Outputs a signal when there is a warning for Lost Int RS-485 communication command loss at the Comm Warn terminal block. Outputs a signal when an operation command is entered and the inverter outputs voltage. No signal output during DC braking.
Page 404 Functions of Terminal Block Code and Description Functions Item Functionality Trip Outputs a signal after a fault trip. Lost Keypad Outputs a signal when there is a warning for Warn Smart Operator command loss. Outputs a signal when there is a warning for braking resistance utilization.
Page 405 Functions of Terminal Block Code and Description Functions Item Functionality Outputs a signal when there is an input loss Lost AI-1 warning for the AI1 terminal (analog input Warn terminal) at the control terminal block. Outputs a signal when there is an input loss Lost AI-2 warning for the AI2 terminal (analog input Warn...
Page 406: Delay Time Settings For Digital Output Terminals
Functions of Terminal Block 8.3.2 Delay Time Settings for Digital Output Terminals You can set time constant of filters for the digital output terminals. It is used to improve the responsiveness of the output terminals. Initial Group Code LCD Display Setting Range Unit Value...
Page 407: Digital Output Identification
Functions of Terminal Block 8.3.4 Digital Output Identification You can check the status of the digital output terminals. For example, when you select an output terminal as contact A (Normal Open), the relevant terminal turns on when there is an output. Setting Initial Group Code...
Page 408 Functions of Terminal Block Code and Item Functionality Functions Stop Steady Drive Output Line Supply Power Line Speed Search Ready Zero Speed Detect Torque Detect Timer Output Trip Lost Keypad Warn DB Warn %ED OUT-50, 52, 54 27 Encoder Tune Warn Refer to 8.3.1 Multifunction Output Terminal Encoder Dir Warn Define...
Page 409: Direct Control Over Multifunction Output
Functions of Terminal Block Code and Item Functionality Functions AuxFan Repl Warn 43 MainCap Diag Alarm OUT-50, 52, 54 Pos Tar Bound Err Refer to 8.3.1 Multifunction Output Terminal Define Pos Max Track Err Settings. (DOx: OCS Run DO1~ DO3) FWD Run REV Run 8.3.6...
Page 410: Pulse Input
Functions of Terminal Block Pulse Input 8.4.1 Pulse Input Scale Wire the pulse input terminal as follows and input the pulse frequency in between 0.00-32.00 kHz for use: [ Image 20. Connecting External Pulse Train ] Related Parameters Initial Group Code LCD Display Setting Range...
Page 411: [ Image 21. Pulse Input Frequency Monitor ]
Functions of Terminal Block Code and Description Functions Pulse Monitor[%] = ([PTI Input] - [PTI +x1 In]) × ([PTI +y2 Percent] - [PTI +y1 Percent]) / ([PTI +x2 In] - [PTI +x1 In])) + [PTI +y1 Percent] PTI Percent (-100%~100%) PTI +y2 Percent AIN-48 PTI+x1 In,...
Page 412: Pulse Input Filter
Functions of Terminal Block 8.4.2 Pulse Input Filter Related Parameters Initial Group Code LCD Display Setting Range Unit Value Value PTI LPF Gain 10~10000 msec Setting Details Code and Description Functions AIN-47 PTI LPF It is the same as 8.2.4 Filter. Gain 8.4.3 Pulse Input Quantization...
Page 413: Analog Output
Functions of Terminal Block Analog Output AO1 and AO2 terminals of the control terminal block provide output of -10 V –10 V voltage or 4–20 mA current. Select SW2 and SW3 as VO1 and VO2 for voltage output and select them as IO1 and IO2 for the current output.
Page 414: Setting Details Of Analog Output Of Voltage And Current
Functions of Terminal Block Initial Group Code LCD Display Set Value Setting Range Unit Value AO2 LPF Gain 0~10000 msec 0.00 -100.00~100.00 0.00 Constant% AO2 Monitor -100.00~100.00 8.5.2 Setting Details of Analog Output of Voltage and Current Code and Description Functions Select 0 (Unipolar Voltage) and 0-+10 V of voltage is output.
Page 415 Functions of Terminal Block Code and Description Functions Sets terminal items for relay 1, 2, and open collector output. Max (100% Output) Configuration Description Reference Value Outputs the operating The frequency set at DRV-20 Frequency frequency (Max Frequency) Output Outputs the inverter 200% of rated current of the Current sensing current...
Page 416 Functions of Terminal Block Code and Description Functions Max (100% Output) Configuration Description Reference Value Deviation between speed reference Speed (command) and Twice the rated slip Deviation rotational speed of the motor input via an encoder option card PPID Command value 1.5 times the 100% of Reference of the PID controller...
Page 417 Functions of Terminal Block Code and Description Functions In the following image, Y-axis represents analog output voltage (0–10 V) whereas X-axis represents the percentage (%) value of the output item. For instance, where the maximum frequency is 60 Hz with a current frequency of 30 Hz, the X-axis is 50%.
Page 418: Pulse Output
Functions of Terminal Block Pulse Output POT terminal of the control terminal block can output a pulse of 0-32.00 kHz. 8.6.1 Pulse Output Settings You can select output items and adjust the size of the output. Initial Group Code LCD Display Set Value Setting Range Unit...
Page 419: Pulse Output Setting Details
Functions of Terminal Block 8.6.2 Pulse Output Setting Details Code and Description Functions It is the same as OUT-01 (AO1 Define) and OUT-10 (AO2 Define) OUT-20 PTO items of 8.5.2 Setting Details of Analog Output of Voltage and Define Current. OUT-21 PTO It is the same as the OUT-03 (AO1 Gain), OUT-12 (AO2 Gain), OUT- Gain,...
Page 420: Learning Protection Functions
Learning Protection Functions 9 Learning Protection Functions This chapter describes the protection functions provided by the S300 series. Protection functions are categorized into two types: Protection from overheating and damage to the motor, and protection of the inverter itself and protection against inverter malfunction.
Page 421: Type ]
Learning Protection Functions Code and Description Functions Sets according to whether the cooling fan of the motor is integrated with the motor or the power is supplied separately. Make sure you check the cooling fan structure of the motor you are using and enter it. Item Functionality As the cooling fan is connected to the motor axis,...
Page 422: Overload Early Warning And Trip
Learning Protection Functions Code and Description Functions Sets the amount of current with the ETH function activated. The range below details the set values that can be used during continuous operation without the protection function. Current (%) MOT1, MOT2-77 ETH Cont MOT1, MOT2 Current MOT1,MOT2...
Page 423: [ Image 3. Example Of An Overload Warning Signal Output ]
Learning Protection Functions Overload Early Warning and Trip Setting Details Code and Description Functions If the overload reaches the warning level, the terminal block PRT-35 OL Warn multifunction output terminals will be used to output a warning signal. Select If 1 (Yes) is selected, it will operate. If 0 (No) is selected, it will not operate.
Page 424: Underload Fault Trip And Warning
Learning Protection Functions Note Overload warnings warn of an overload before an overload fault trip occurs. The overload warning signal may not work in an overload fault trip situation, if the overload warning level (OL Warn Level) and the overload warning time (OL Warn Time) are set higher than the overload trip level (OL Trip Level) and overload trip time (OL Trip Time).
Page 425: (Load Class: Heavy Load) ]
Learning Protection Functions Code and Description Functions Select how the inverter operates in the event of an underload fault trip. Item Functionality None No protective action is taken. In the event of an underload fault trip, the inverter CoastStop PRT-47 UL Trip output will be blocked and the motor will enter a (FreeRun) Select...
Page 426: (Load Class: Underload) ]
Learning Protection Functions Code and Description Functions [When the preset value of DRV-25 (Load Duty Select) is 0 (Normal Duty) ] • In PRT-49 (underload lower limit level), the underload rate is set at the frequency twice the rated slip of the motor. However, the rated slip of the motor is calculated from base frequency (MOT1, MOT2- 23 Base Frequency), motor rated speed (MOT1, MOT2-24 Rated Speed), and number of poles (MOT1, MOT2-25 Number of Poles)
Page 427: Stall Prevention
Learning Protection Functions 9.1.4 Stall Prevention The stall prevention function is a protective function that prevents motor stalling caused by overloads. If this function is used, the inverter output frequency will be adjusted automatically according to the load size. When a stall is caused by an overload, high currents are induced in the motor and may cause motor overheating or damage to the motor and interrupt the operation of the motor-driven devices.
Page 428: [ Image 6. Stall Prevention Level By Frequency Band ]
Learning Protection Functions Stall Prevention Setting Details Code and Description Functions The output frequency will be adjusted and accelerated within the set stall level range if the magnitude of the inverter output current exceeds the set stall level (VF1, VF2-81, 84, 87, 90) during VF1, VF2-76 acceleration.
Page 429: Flux Braking
Learning Protection Functions Note • To obtain the shortest and most optimal deceleration performance by avoiding an overvoltage trip in a load with large inertia but short deceleration time, set BAS-85 (Flux Brake Enable) to 1 (Yes) with stall prevention during deceleration. Do not use this function when frequent deceleration of the load is required, as the motor can overheat and may be damaged easily.
Page 430: Electronic Thermal (Eth) Prevention Through Motor Overheat Sensor
Learning Protection Functions Note Flux braking may be less effective if the input voltage (DRV-30 Ref AC Input Volt) is high. Caution • Flux braking will operate simultaneously only during deceleration. Do not use this function when frequent deceleration of the load is required, as the motor can overheat and may be damaged easily.
Page 431 Learning Protection Functions Motor Overheat Sensor Input Setting Details Code and Description Functions Sets the inverter operation status when the motor is overheated. Item Functionality None No protective action is taken. In the event of an electronic thermal (ETH) fault CoastStop trip, the inverter output will be blocked and the (FreeRun)
Page 432: [ Image 7. Ptc Sensor 2-Wire Connection Method ]
Learning Protection Functions Code and Description Functions Item Functionality Operates when the motor overheat sensor input PRT-63 Under Level is less than PRT-62. Thermal-T Area Operates when the motor overheat sensor input Over Level is greater than PRT-62. OUT-01, 10 AOx Define, OUT-02, 11 AOx They are used to supply constant current to the temperature sensor...
Page 433: [ Image 8. Ptc Sensor 3-Wire Connection Method ]
Learning Protection Functions • 3-wire connection: Set PRT-61 (Thermal-T Source) to 3 (Analog Input 3). Select the switch (SW4) as V3, and set the PTC selection switch to the Off state. Select the switch (SW2) as IO1. When using the analog output (AO1) terminal to supply a constant current to the temperature sensor and receive the sensor through the analog input (AI3) terminal, wire as follows.
Page 434: Inverter And Sequence Protection
Learning Protection Functions Inverter and Sequence Protection 9.2.1 Input/output open-phase protection Open-phase protection is used to prevent overcurrent levels induced at the inverter inputs due to an open-phase within the input power supply. Furthermore, if there is a open-phase between the motor and the inverter output, there might be motor stall due to a lack of torque.
Page 435: External Trip Signal
Learning Protection Functions 9.2.1.2 Output Open-phase Protection In the event of an open-phase in the connection between the motor and the inverter output, there may be motor stall due to a lack of torque. In the event of one or more open-phases of U, V, or W of the inverter output terminal block, the inverter will detect the output open-phase, cut off the output, and display a trip.
Page 436: [ Image 9. Example Of External Trip Signal Settings ]
Learning Protection Functions External Trip Signal Setting Details Code and Description Functions Selects the type of multifunction input contact. DIN-27, 30, 33, Item Functionality 35, 39, 42, 45, 48 DIx NC/NO Normal Open Operates as an A contact (Normal Open). (DIx: DI1~DI8) Normal Close Operates as a B contact (Normal Close).
Page 437: Inverter Overload Protection
Learning Protection Functions 9.2.3 Inverter Overload Protection When the inverter input current exceeds the rated current, a protective function is activated to prevent damages to the inverter based on inverse proportional characteristics. Setting Initial Group Code LCD Display Set Value Unit Range Value...
Page 438: Using External 24V Power (External 24V)
Learning Protection Functions Note When DRV-25 (Load Duty Select) is set, the initial value of DRV-27 Carrier Frequency is changed in accordance with the inverter's capacity. Table 1. Initial value of carrier frequency for each load Configuration Initial value of carrier frequency 200V Normal Duty Full capacity...
Page 439 Learning Protection Functions Caution • Definition of inverter operation state when external 24V power is supplied (when PRT-89 [Ext 24V Pwr Lost] is set as 1 [Yes]) Table 2. Inverter operation items when using an external 24V power supply Disabled items Enabled items Inverter operation is unavailable (When the Smart Enabled communication Operator inputs an operation command, the frequency options...
Page 440: Loss Of Input Value By Inverter Unit
Learning Protection Functions 9.2.5 Loss of Input Value by Inverter Unit You can select the inverter operating method when the input value is lost due to disconnection of the signal line of the analog input of the terminal block, internal communication, communication option, USB or Smart Operator.
Page 441 Learning Protection Functions Code and Description Functions Selects how the inverter operates when Smart Operator communication is lost. Item Functionality The protection function for lost Smart Operator None communication will not operate. In the event of lost Smart Operator CoastStop communication, the inverter output is blocked (FreeRun) and the motor will enter a free run due to inertia.
Page 442 Learning Protection Functions 9.2.5.1 Lost Internal Communication Initial Group Code LCD Display Set Value Setting Range Unit Value Lost Preset 0.00~Max 60.00 0.00 Freq Frequency Lost Preset 0~Maximum Speed Speed Lost IntComm CoastStop Mode (FreeRun) Lost IntComm 0.1~120.0 Time DOx Define Lost 50, 52, ( DOx:...
Page 443 Learning Protection Functions Lost Internal Communication Setting Details Code and Description Functions In situations where the operation of the lost internal communication PRT-14 Lost (PRT-17 Lost IntComm Mode) is set to 5 (Lost Preset), the protection Preset Freq function will operate and sets the frequency to continue operation. Selects the operation method when Smart Operator communication is lost.
Page 444 Learning Protection Functions 9.2.5.2 Lost USB Initial Group Code LCD Display Set Value Setting Range Unit Value Lost Preset 0.00~Max 60.00 0.00 Freq Frequency Lost Preset 0~Maximum Speed Speed Lost USB CoastStop Mode (FreeRun) Lost USB 0.1~120.0 Time DOx Define Lost 50, 52, ( DOx:...
Page 445 Learning Protection Functions Code and Description Functions Selects how the inverter operates when USB is lost. Item Functionality The protection function for lost USB will not None operate. In the event of lost USB, the inverter output will CoastStop be blocked and the motor will enter a free run (FreeRun) due to inertia.
Page 446 Learning Protection Functions 9.2.5.3 Lost Analog Input Initial Group Code LCD Display Set Value Setting Range Unit Value Lost Preset 0.00~Max 60.00 0.00 Freq Frequency Lost Preset 0~Maximum Speed Speed 25, 28, Lost AIx Mode CoastStop (AIx: AI1~AI3) (FreeRun) Lost AIx Chk Half of 26, 29, Level...
Page 447 Learning Protection Functions Code and Description Functions Selects how the inverter operates when analog input is lost. Item Functionality The protection function for lost analog input will None not operate. In the event of lost analog input, the inverter CoastStop output will be blocked and the motor will enter a (FreeRun) free run due to inertia.
Page 448 Learning Protection Functions Code and Description Functions Item Functionality When the analog input value is within the range of the following table (that is, set value), it will be considered an analog input loss, depending on the settings of AIN-01, 16, 31 (AI1-AI3 Type Select).
Page 449: [ Image 10. Example Of Operation In Case Of Lost Analog Input ]
Learning Protection Functions If analog input is lost when the analog input definition is used as a speed command, PRT-25 (Lost AI1 Mode) is set to 2 (Trip Dec Time Stop), PRT-26 (Lost AI1 Chk Level) is set to 1 (Below Low Limit), and PRT-27 (Lost AI1 Time) is set to 5.0 sec, it will operate as follows: Input Loss Occurrence AI1~3...
Page 450: Dynamic Braking (Db) Resistor Configuration
Learning Protection Functions 9.2.6 Dynamic Braking (DB) Resistor Configuration It is possible to adjust the DC link voltage through a braking resistor. The products with 200V class 18.5kW or less and 400V class 37kW or less are equipped with a built-in braking unit to prevent overvoltage caused by an increase in the DC link voltage during regenerative operation.
Page 451: [ Image 11. Example Of Dynamic Braking Resistor Setting-1 ]
Learning Protection Functions Code and Description Functions Sets dynamic braking (DB) resistor (% ED: Einschaltdauer). Braking resistor configuration sets the rate at which the braking resistor operates for one operation cycle. The maximum time for continuous braking is 15 sec and the braking resistor signal will not be output from the inverter after the 15 sec period has expired.
Page 452: Output Block By Multifunction Terminal
Learning Protection Functions 9.2.7 Output Block by Multifunction Terminal When the multifunction input terminal is set as the output block signal terminal and the signal is input to the terminal, then the operation stops. Setting Initial Group Code LCD Display Set Value Unit Range...
Page 453: Over Speed Error
Learning Protection Functions Code and Description Functions Item Functionality Does not restart the motor even if the emergency None stop operation is reset. Accelerates and operates in the same way PRT-85 BX Start Mode as normal acceleration operation when the Restart Mode emergency stop operation is reset.
Page 454: Speed Deviation Error
Learning Protection Functions 9.2.9 Speed Deviation Error It is a function that operates when the control mode (MOT1, MOT2-05 Control Mode) is 3 (Sensorless) or 4 (Vector). If the motor rotates at a speed higher than the speed deviation (PRT-67 Speed Dev BandFreq) for the set detection time (PRT-69 Speed Dev Time), the inverter output will be blocked.
Page 455 Learning Protection Functions Cooling Fan Control Setting Details Code and Description Functions Item Functionality Cooling fan runs when the power is supplied to the inverter and the operation command is on. The cooling fan stops when the power is supplied to the inverter and the operation command is During Run off.
Page 456: Cooling Fan Trip Detection
Learning Protection Functions 9.2.11 Cooling Fan Trip Detection Setting Initial Group Code LCD Display Set Value Unit Range Value MainFan Trip Trip Mode AuxFan Trip Trip Mode DO1~DO3 50, 52, 54 MainFan Warn 0~45 24, 14, 0 Define Cooling Fan Trip Detection Setting Details Code and Description Functions...
Page 457: Diagnostic Functions
Learning Protection Functions Diagnostic Functions 9.3.1 Main Capacitor Diagnostic Function Using the change in electric capacity value, it is possible to indirectly verify the degree of deterioration of the inverter's main capacitor. An induction motor must be connected and DIAG-01 (Main Cap Diag En) must be set to 1 (Yes) in order to perform a measurement.
Page 458: Main Capacitor Diagnostic Check Alarm Function
Learning Protection Functions Caution AC 190V/370V is the minimum input voltage for measuring the electric capacity of the main capacitor. A Main Cap Diag Fail trip will occur when the input voltage falls below the minimum. 9.3.2 Main Capacitor Diagnostic Check Alarm Function Displays an alarm so that periodic testing of the main capacitor can be performed.
Page 459: Main Capacitor Life Diagnostic Function
Learning Protection Functions 9.3.3 Main Capacitor Life Diagnostic Function When the cumulative run time of the main capacitor reaches the main capacitor replacement diagnostic level, a warning message will be displayed. To perform this function, DIAG-11 (MainCap Repl En) must be set to 1 (Yes). When DIAG-13 (MainCap Used Level) reaches DIAG-12 (MainCap Repl Level), a Main Cap Repl Warn warning message will be displayed.
Page 460: Aux Fan Life Diagnostic Functions
Learning Protection Functions 9.3.5 Aux Fan Life Diagnostic Functions When the cumulative run time of the aux fan reaches the replacement diagnostic level, a warning message will be displayed. To perform this function, DIAG-62 (AuxFan Repl En) must be set to 1 (Yes). When DIAG-64 (AuxFan Used Level) reaches the value set in DIAG-63 (AuxFan Repl Level), an AuxFan Repl Warn warning message will be displayed.
Page 461: Monitoring Operation Time
Learning Protection Functions 9.3.7 Monitoring Operation Time It is possible to monitor the operation time of the inverter and the fan. Initial Group Code LCD Display Set Value Setting Range Unit Value MainFan Time MainFan Time Reset AuxFan Time DIAG AuxFan Time Reset Drive On Time...
Page 462: Operation Settings Related To Trip Occurrence
Learning Protection Functions Operation Settings related to Trip Occurrence 9.4.1 Operation related to Low Voltage Trip When inverter input power is lost and the internal DC link voltage drops below a certain voltage level, the inverter will stop output and a low voltage trip will occur. A trip occurs only during operation, and not when input voltage drops due to power off during stop.
Page 463: Operation Related To Safety Trip
Learning Protection Functions 9.4.2 Operation related to Safety Trip This function sets the reset operation mode when a safety trip occurs. In the case of PRT-82 (Safety Trip Mode) set to 0 (Latch), the inverter will maintain the trip even if the safety signal is input, and the trip will be released only when it is forcibly reset through the terminal block or Smart Operator.
Page 464: Trip/Warning List
Learning Protection Functions Trip/Warning List The following list shows the types of trips and warnings that can occur while using the S300 inverter. Please refer to 9 Learning Protection Functions for details about trips and warnings. 9.5.1 Trip List Table 3. Trip list LCD Display Description Property...
Page 465 Learning Protection Functions LCD Display Description Property Remark External Trip-1 External Trip-2 Latch/ External signal trip Level External Trip-3 External Trip-4 Fuse Open Fuse open Latch Reserved Gate Power Loss Power supply circuit error Latch Ground Fault Trip Ground fault occurrence Latch Overcurrent control Hw OCS Fail...
Page 466 Learning Protection Functions LCD Display Description Property Remark Lost keypad Disabled by Lost Keypad Level (Smart Operator) default Lost option card Lost Option Comm Level communication Lost Power MCU Power unit fault Latch Disabled by Lost USB Lost USB connection Level default Latch /...
Page 467 Learning Protection Functions LCD Display Description Property Remark Para Write Trip Parameter writing error Latch Parameter abnormal ParameterReset Err Latch initialization PM motor stimulus Pole Pos Detect F Latch estimation failure Latch/ Pos HW Limit High H/W upper limit Position control Warning Latch/ Pos HW Limit Low...
Page 468: Warning List
Learning Protection Functions 9.5.2 Warning List Table 4. Warning list LCD Display Description Property Remark Over Load Warn Motor overload Warning Under Load Warn Motor under load Warning Drv Over Load Warn Inverter overload Warning Lost Internal Lost Int Comm Warn Warning Communication Lost option card...
Page 469 Learning Protection Functions LCD Display Description Property Remark Low main capacitor Low Capacity Warn Warning capacity MainCap Diag Alarm Main capacitor diagnosis Warning Main capacitor diagnosis Main capacitor Power Off Please requires power off diagnosis Exceeding the allowable AC Input Over Volt Warning input power Running Auto Tune...
Page 470: Using Built-In Communication Features
Using Built-in Communication Features 10 Using Built-in Communication Features This section in the user manual explains how to control the inverter with a PLC or a computer over a long distance using RS485 communication features. To use the RS485 communication features, connect the communication cables and set the communication parameters on the inverter.
Page 471: Communication System Configuration
Using Built-in Communication Features 10.2 Communication System Configuration In the RS485 communication system, the S300 basically works as a slave and can be connected via various superordinate controllers. 10.2.1 Slave Inverter Composition PLC Master S300 #1 S300 #2 S300 #N S+ S- 5G RS485 [ Image 1.
Page 472: Parameter Settings For Slave Communication
Using Built-in Communication Features 10.2.2 Parameter Settings for Slave Communication Before proceeding with setting communication configurations, make sure that the communication lines are connected properly. Turn on the inverter and set the communication parameters. Initial Group Code LCD Display Set Value Setting Range Unit Value...
Page 473 Using Built-in Communication Features Communication Parameters Setting Details Code and Description Functions Sets the station ID of the inverter. INTC-01 Station You can set station ID between 1-250 or 1-31 depending on the setting values at INTC-02. Select one of the two built-in protocols: Modbus-RTU or LS INV 485. Item Functionality INTC-02...
Page 474 Using Built-in Communication Features Code and Description Functions When using modbus-RTU, the modbus address will be 1 subtracted from the parameter address of the inverter. However, to use the inverter parameter address as itself, set this parameter to 0 (No), and you can use the same address for modbus and inverter parameter.
Page 475: Setting Operation Command And Frequency
Using Built-in Communication Features 10.2.3 Setting Operation Command and Frequency Set DRV-10 (1st Command Source) to 4 (Internal Comm.) and DRV-11 (1st Freq Ref Src) code to 6 (Internal Comm.) in order to set the operation command and frequency to the parameters in the common area via communication. Refer to 5.2.1 Setting Methods of Operation Commands for operation commands and 5.1.1 Operating Frequency Settings for set frequency commands.
Page 476 Using Built-in Communication Features Command Loss Protective Operation Setting Details Code and Description Functions Selects inverter operation to run when a communication error has occurred and lasted for the time set at PRT-18. Item Functionality The speed command immediately becomes None the operation frequency without any protection function.
Page 477: Communication Parameter Address Operation
Using Built-in Communication Features 10.3 Communication Parameter Address Operation 10.3.1 Parameters for Common Area Communication parameter Scale Unit Details Address 0000h Inverter model 0x11 S300 0 .4kW 0.75kW 1.1kW 1.5kW 2.2lW 3.7kW 5.5kW 7.5kW 11kW 15kW 0001h Inverter capacity 18.5kW 22kW 30kW 37kW...
Page 478 Using Built-in Communication Features Communication parameter Scale Unit Details Address 200 V class Inverter input 0002h voltage 400 V class Inverter software 0003h 0066h Version 1.00 (Example) version 0004h Reserved Command 0005h 0.01 frequency Reserved Operation 0006h command CoastStop(FreeRun) stop Fault reset Stopped 0007h...
Page 479 Using Built-in Communication Features Communication parameter Scale Unit Details Address Reserved 000Eh Operation status Decelerating Accelerating Fault (trip) Operating in reverse direction Operating in forward direction Stopped Normal state Fault trip 000Fh information Tripped...
Page 480 Using Built-in Communication Features Communication parameter Scale Unit Details Address Reserved Input terminal 0010h information Output terminal 0011h Reserved information Output terminal 0011h information...
Page 481: Parameters For Expanded Common Area
Using Built-in Communication Features Communication parameter Scale Unit Details Address 0012h 0.01 0013h 0.01 0014h 0.01 Rotational speed 0015h of the motor Displays the Hz 001Ah or rpm Displays the 001Bh number of poles of the motor 001Ch Reserved 001Dh Reserved 0100h~ Reserved...
Page 482 Using Built-in Communication Features Communication parameter Scale Unit Details Address Definition by Data Bit Unit Capacity above the decimal point 0301h Inverter capacity Capacity below the decimal point Value per Capacity (Example) 400W 1900h 1.5kW 4015h 7.5kW 4075h 18.5kW 4125h 75kW 44B0h 220kW 4DC0h 280kW 5180h...
Page 483 Using Built-in Communication Features Communication parameter Scale Unit Details Address Voltage/Power Type Cooling (Single Phase, type Three Phase) 0302h Inverter input 200 V / Powerful 0231h 3-phase cooling 400 V / Powerful 0431h 3-phase cooling Inverter software 0303h 0066h Version 1.00 (Example) version 0304h Inverter capacity...
Page 484 Using Built-in Communication Features Communication parameter Scale Unit Details Address Same as B7 Stopped Operating in forward direction Inverter operation 0305h state Operating in reverse direction Operating DC Same as B3 Operation command source Smart Operator Communication option Built-in RS485 communication Inverter Terminal block...
Page 485 Using Built-in Communication Features Communication parameter Scale Unit Details Address Frequency command source Smart Operator Up/down operation speed Pulse Built-in RS485 communication Communication option Inverter operation, 0306h frequency Multi-step speed command source 25~31 frequency Same as B5 Smart Operator 0307h 0064h Version 1.00 (example) software version...
Page 486 Using Built-in Communication Features Communication parameter Scale Unit Details Address Final target speed applied to the 030Bh Target speed inverter Final target torque applied to the 030Ch Target torque inverter Final acceleration time applied to 030Dh Acceleration time the inverter Final deceleration time applied to 030Eh Deceleration time...
Page 487 Using Built-in Communication Features Communication parameter Scale Unit Details Address Reserved Digital input 0320h information...
Page 488 Using Built-in Communication Features Communication parameter Scale Unit Details Address Reserved Digital output 0321h information...
Page 489 Using Built-in Communication Features Communication parameter Scale Unit Details Address Virtual DI16 Virtual DI15 Virtual DI14 Virtual DI13 Virtual DI12 Virtual DI11 Virtual DI10 Virtual D 9 Virtual digital 0322h input information Virtual DI8 Virtual DI7 Virtual DI6 Virtual DI5 Virtual DI4 Virtual DI3 Virtual DI2...
Page 490 Using Built-in Communication Features Communication parameter Scale Unit Details Address Virtual 0323h digital output information Virtual DO4 Virtual DO3 Virtual DO2 Virtual DO1 Information on 0324h analog input 1 0.01 (V1, I1) Information on 0325h analog input 2 0.01 (V2, I2) Information on 0326h analog input 3...
Page 491 Using Built-in Communication Features Communication parameter Scale Unit Details Address 032Ch Reserved 032Dh Temperature NTC temperature ℃ 032Eh Reserved 032Fh Reserved 0330h Reserved 0331h Reserved 0332h Reserved 0333h Reserved 0334h Reserved 0335h~ Reserved 0339h 033Ah Reserved 033Bh Reserved 033Ch Reserved 033Dh~ Reserved 0339h...
Page 492 Using Built-in Communication Features 10.3.2.2 Parameters for Inverter Control Area Communication parameter Scale Unit Details Address Frequency 0380h 0.01 Set command frequencies command 0381h rpm command Command rpm settings Reserved Operation 0382h command CoastStop(FreeRun) stop Trip reset 0383h Acceleration time Acceleration time setting 0384h Deceleration time...
Page 493 Using Built-in Communication Features Communication parameter Scale Unit Details Address Virtual DI16 Virtual DI15 Virtual DI14 Virtual DI13 Virtual DI12 Virtual DI11 Virtual DI10 Virtual digital Virtual DI9 0385h input control (0: Virtual DI8 Off, 1: On) Virtual DI7 Virtual DI 6 Virtual DI 5 Virtual DI 4 Virtual DI 3...
Page 494 Using Built-in Communication Features Communication parameter Scale Unit Details Address Virtual digital 0386h output control (0: Off, 1: On) Virtual DO4 Const Virtual DO3 Const Virtual DO2 Const Virtual DO1 Const 0387h Reserved 0388h PID reference PID feedback 0389h value 038Ah Reserved 038Bh...
Page 495 Using Built-in Communication Features Communication parameter Scale Unit Details Address Forward motoring Sets the forward motoring torque 0391h torque limits limit Forward Sets the forward regenerative 0392h regenerative torque limits torque limits Reverse Sets the reverse motoring torque 0393h motoring torque limit limits Reverse...
Page 496 Using Built-in Communication Features Communication parameter Scale Unit Details Address 03A5h EPID2 reference EPID2 reference EPID2 feedback 03A6h EPID2 feedback value value 03A7h EPID2 reference EPID2 reference EPID2 feedback 03A8h EPID2 feedback value value 03A9h Reserved ~03AFh Monitor 2 line-1 03B0h item Monitor 2 line-2...
Page 497 Using Built-in Communication Features 10.3.2.3 Parameters for Inverter Memory Control Area Communication parameter Scale Unit Details Address 03E1h Reserved Parameter 03E2h Parameter initialization initialization Changed 03E3h parameter Changed parameter display display 03E4h Reserved Delete all trip 03E5h Delete all trip history history 03E6h Reserved...
Page 498 Using Built-in Communication Features 10.3.2.4 Parameters for Inverter Trip Mode Area (Read Only) Communication parameter Scale Unit Details Address ADC Offset Watchdog Gate Power Loss Main OS Error Over Load Under Load Inverter Over Load E-Thermal Ground Fault Out Phase U Open In Phase Open Over Speed Index of the first...
Page 499 Using Built-in Communication Features Communication parameter Scale Unit Details Address Fuse Open Encoder Encoder No Connection Encoder Wrong Dir Motor Over Heat Main Fan Fault Parameter Write Pre PID Fail No Motor Option 1 Option 2 Option 3 Low Voltage Lost Sensor Index of the first 0400h...
Page 500 Using Built-in Communication Features Communication parameter Scale Unit Details Address STO P24 Fault STO P5 Fault Aux Fan Fault Control Fan Fault Data Storage Precharge Fail H/W OCS Fail TR Tune Fail RS Tune Fail SLS Tune Fail LS Tune Fail Index of the first 0400h current trip...
Page 501 Using Built-in Communication Features Communication parameter Scale Unit Details Address Index of the 0403h fourth current trip Same as 0400h Index of the fifth 0404h current trip Output frequency 0405h 0.00 Displays the output frequency right before a trip Output current 0406h Displays output current right before a trip...
Page 502 Using Built-in Communication Features Communication parameter Scale Unit Details Address DI5 (default I/O) DI4 (default I/O) Status of the input terminal 0409h DI3 (default I/O) block right before a trip DI2 (default I/O) DI1 (default I/O) Reserved Reserved Reserved Reserved Reserved Reserved Reserved...
Page 503 Using Built-in Communication Features Communication parameter Scale Unit Details Address Total time of 040Dh inverter operation LO WORD Displays the total time of motor operation by the inverter Total time of 040Eh inverter operation HI WORD 040Fh Reserved Inverter 0410h temperature right °C before a trip...
Page 504 Using Built-in Communication Features Communication parameter Scale Unit Details Address Control Fan Lock Main Fan Replace Aux Fan Replace Index of current 0420h warning Control Fan Replace Precharger Replace Supply P24V Output frequency 0422h right before an 0.00 Displays the output frequency alarm occurrence Output current 0423h...
Page 505 Using Built-in Communication Features Communication parameter Scale Unit Details Address Reserved Reserved Reserved Reserved Reserved Reserved Reserved Input terminal Reserved block status right 0426h before an alarm DI8(default I/O) occurrence DI7(default I/O) DI6(default I/O) DI5(default I/O) DI4(default I/O) DI3(default I/O) DI2(default I/O) DI1(default I/O) Reserved...
Page 506 Using Built-in Communication Features Communication parameter Scale Unit Details Address Reserved Reserved Output terminal Reserved block status right 0427h before an alarm DO3(default I/O) occurrence DO2(default I/O) DO1(default I/O) Total time of power supply to 0428h Displays the total time of power the inverter LO supply to the inverter WORD...
Page 507 Using Built-in Communication Features Communication parameter Scale Unit Details Address 0433h Second trip type Trip history ID set in 0431h 0434h Third trip type Trip history ID set in 0431h 0435h Fourth trip type Trip history ID set in 0431h 0436h Fifth trip type Trip history ID set in 0431h...
Page 508 Using Built-in Communication Features Communication parameter Scale Unit Details Address Trip history ID set in 0431h Reserved Reserved Reserved Reserved Reserved Reserved Reserved Status of the input terminal 043Bh Reserved block right before a trip DI8(default I/O) DI7(default I/O) DI6(default I/O) DI5(default I/O) DI4(default I/O) DI3(default I/O)
Page 509 Using Built-in Communication Features Communication parameter Scale Unit Details Address Trip history ID set in 0431h Reserved Reserved Reserved Reserved Reserved Reserved Reserved Status of the output terminal 043Ch Reserved block right before a trip Reserved Reserved Reserved Reserved Reserved DO3(default I/O) DO2(default I/O) DO1(default I/O)
Page 510 Using Built-in Communication Features Communication parameter Scale Unit Details Address Inverter temperature right 0442h °C before alarm occurrence Note Writing the total time of power supply to and operation of the inverter Time is a LONG type variable that uses minutes as the unit. That is, LO WORD and HI WORD are combined to make a variable of a LONG type before dividing a year into 12 months, a month into 30 days, a day into 24 hours, and an hour into 60 minutes, which are written in year, month, day, time, and minute.
Page 511 Using Built-in Communication Features 10.3.2.5 Position Control Parameters Communication parameter Scale Unit Details Address Target of Synchronous time required to be proportional set for slaves from the master or 0605h 0.00 synchronous PLC in proportional synchronous operation time control STOP Position control POS Run 0606h...
Page 512 Using Built-in Communication Features Communication parameter Scale Unit Details Address Status of Position Control STOP POS Run POS Run Pre- Posi POS Run Relative TRIP 0607h Operation status Same as B7 Status of Position Control Activation Total operation 0608h 0.00 Total time of position control time...
Page 513: Virtual Multifunction Input Settings
Using Built-in Communication Features 10.3.3 Virtual Multifunction Input Settings You can control virtual multifunction inputs via built-in communication (communication address 0385h) or Smart Operator parameters (VIRT-03, 06, 09, 12, 15, 18, 21, 24, 27, 30, 33, 36, 39, 42, 45, 48 Virtual DI1~DI16 Const). Set DRV-10 (1st Command Source) to 1, 2, or 3 (Fx/Rx-1, Fx/Rx-2, or 3-Wire) for inverter operation with virtual multifunction inputs.
Page 514: Virtual Multifunction Output Settings
Using Built-in Communication Features 10.3.4 Virtual Multifunction Output Settings You can control multifunction outputs via built-in communication (communication address 0386h) or Smart Operator parameters (VIRT-03, 06, 09, 12, 15, 18, 21, 24, 27, 30, 33, 36, 39, 42, 45, 48 Virtual DIx Const). Refer to 8.3 Multifunction Digital Output for related functions.
Page 515 Using Built-in Communication Features Communication Memory Map Description Area For built- Area registered in in RS485 INTC-11-26 Para communication Status-1-16 0100h~010Fh For USB Area registered in USBC- communication 11-26 Para Status-1-16 For built- Area registered in in RS485 INTC-31-46 communication 110h~11Fh For USB Area registered in...
Page 516: Parameter Group For Data Transmission
Using Built-in Communication Features 10.3.6 Parameter Group for Data Transmission By defining a parameter group, the communication addresses registered in the communication-related function group (INTC) can be used in communication. The parameter group for data transmission may be defined to transmit multiple parameters at once, in a single communication frame.
Page 517: Built-In Communication Protocol
Using Built-in Communication Features 10.4 Built-in Communication Protocol 10.4.1 LS INV 485 protocol Request Station ID Data 1 byte 2 bytes 1 byte n bytes 2 bytes 1 byte Normal Response Station ID Data 1 byte 2 bytes 1 byte n x 4 bytes 2 bytes 1 byte...
Page 518 Using Built-in Communication Features Table 2. LS INV 485 CMD Characters Character ASCII-Hex Command ‘R’ Read ‘W’ Write ‘X’ Request monitor registration ‘Y’ Perform monitor registration * Single quotation mark (‘’) indicates characters. • Data are written in ASCII-Hex (where data value is 3000: 3000 (decimal) → 0BB8h (Hex) →...
Page 519 Using Built-in Communication Features 10.4.1.1 Detailed Read Protocol Read Request For a read request of successive n words from address XXXX Number of Station ID Address Addresses ‘01’~’FA’ ‘R’ ‘XXXX‘ ‘1’~‘8’ = n ‘XX’ 1 byte 2 bytes 1 byte 4 bytes 1 byte 2 bytes...
Page 520 Using Built-in Communication Features Note If there is invalid data among the consecutive numbers of data from XXXX address, the data returns "FFFF". i.e., the system reads DRV-05-08(1205h-1208h) and returns "FFFF" for data corresponding to the two parameters below, as DRV-07 and 08 don't exist: Request Number of...
Page 521 Using Built-in Communication Features Write Error Response Station ID error code ‘01’~‘FA’ ‘W’ ‘**’ ‘XX’ 1 byte 2 bytes 1 byte 2 bytes 2 bytes 1 byte * Total byte = 9, single quotation mark (‘’) indicates characters. Note If there is invalid data among the consecutive numbers of data from XXXX address, the data returns "FFFF".
Page 522 Using Built-in Communication Features Monitor Registration Normal Response Station ID ‘01’~‘FA’ ‘X’ ‘XX’ 1 byte 2 bytes 1 byte 2 bytes 1 byte * Total byte = 7, single quotation mark (‘’) indicates characters. Monitor Registration Error Response Station ID error code ‘01’~‘FA’...
Page 523: Exception Code
Using Built-in Communication Features 10.4.1.4 Exception Code Table 3. LS INV 485 Exception Code Items Abbreviation Description ILLEGAL The requested function cannot be performed by a FUNCTION slave, the corresponding function does not exist. ILLEGAL DATA The received parameter address is not valid in the ADDRESS slave, the number of addresses is 9 or more ILLEGAL DATA...
Page 524 Using Built-in Communication Features Character Character Character space " & ’ < >...
Page 525: Modbus-Rtu
Using Built-in Communication Features 10.4.2 Modbus-RTU 10.4.2.1 Function Code and Protocol (unit: byte) Station ID is INTC-01 (Station ID), the start communication address is the communication address, and the unit is bytes. Refer to 10.3.1 Parameters for Common Area for communication address. The communication address of the modbus is 1 subtracted from the parameter address of our inverter by default.
Page 526 Using Built-in Communication Features Note If there is invalid data among the consecutive numbers of data from XXXX address, the data returns "FFFF". i.e., the system reads DRV-05-08(1205h-1208h) and returns "FFFF" for data corresponding to the two parameters below, as DRV-07 and 08 don't exist: Request Slave...
Page 527 Using Built-in Communication Features Error Response Slave Station ID Function Code Exception Code CRC(Lo) CRC (Hi) 1 byte 1 byte 1 byte 1 byte 1 byte * The function code of error response is required function code + 0x80. Write Multiple Registers (Function Code: 0x10) This is a protocol that writes consecutive parameters of the inverter as many as set numbers.
Page 528 Using Built-in Communication Features Note If there is invalid data among the consecutive numbers of data from XXXX address, the value is written only for the normal address register and returns a normal response. i.e., when you write 5.00 sec (500,01F4h) for each DRV-05-08 (1205h-1208h), 5.00 sec (500,01F4h) value will be written for each DRV05 and 06 and returns a normal response.
Page 529 Using Built-in Communication Features Items Description SLAVE DEVICE The slave is performing other commands BUSY Write-Protection The write command is not executable Table 6. An Example Modbus-RTU Communication Example of Modbus-RTU Communication in Use The example assumes the acceleration time (communication address 0383h) was changed to 5.0 seconds and the deceleration time (communication address 0384h) was changed to 10.0 seconds.
Page 530: Using Usb Communication Functions
Using USB Communication Functions 11 Using USB Communication Functions The S300 has a built-in USB Type-C port, which can be used to connect to PC and control the S300 with modbus-RTU protocols. Refer to 10.4.2 Modbus-RTU for more details on modbus-RTU protocols. The USB port is located above the RJ45 port on the main inverter unit.
Page 531 Using USB Communication Functions Communication Parameters Setting Details Code and Description Functions Sets time for the slave (inverter) to respond to the master (PLC or INTC-05 inverter). Response time is used in a system where the slave device Response Delay response is too fast for the master device to process.
Page 532: Parameter Group For Data Transmission
Using USB Communication Functions 11.2 Parameter Group for Data Transmission By defining a parameter group, the communication addresses registered in the communication related function group (USBC) can be used in communication. The parameter group for data transmission may be defined to transmit multiple parameters at once, in a single communication frame.
Page 533: Inverter Setting Mode
Inverter Setting Mode 12 Inverter Setting Mode 12.1 Parameter Management 12.1.1 Setting Mode Parameters Setting Initial Mode Group Code LCD Display Set Value Unit Range Value English Russian Spanish Italian Language Turkish Select Polish Persian Chinese Korean Level Level Level 10 Contrast 0-20 Operator Set...
Page 534 Inverter Setting Mode Setting Initial Mode Group Code LCD Display Set Value Unit Range Value Drive S/W Drive Set Ver. Operator S/W Ver. Operator Set Operator TitleVer. Local/ Remote Multi Key Drive Set JOG Key Select Favorite Add/Del Command Yes/No Edit Anytime Parameter...
Page 535 Inverter Setting Mode Setting Initial Mode Group Code LCD Display Set Value Unit Range Value Monitor Gauge 31 Monitor Graph Refer to 12.2 Monitoring Settings. Graph Time Period Drive Set I/O Type Standard IO 36 Option-1 Type 37 Option-2 Type None 38 Option-3 Type 39 Parameter Init Refer to 12.1.4 Parameter Initialization.
Page 536 Inverter Setting Mode Setting Mode Parameter Details Code and Description Functions Operator Set-01 Sets a language for the Smart Operator. Language Select Adjusts the LCD contrast ratio on the Smart Operator. Press the key while holding the key. Operator Set-02 LCD Contrast Adjust with the keys when the contrast ratio setting pop-up is...
Page 537 Inverter Setting Mode Code and Description Functions Sets initial screen of the Smart Operator. Item Functionality Operator Set-08 Menu is displayed as the initial screen upon Menu Map On power supply to the Smart Operator. The monitoring screen is displayed as the initial screen upon power supply to the Smart Operator.
Page 538: Parameter Easy Start (Easy Start On)
Inverter Setting Mode 12.1.2 Parameter Easy Start (Easy Start On) You can easily set basic parameters for operating a motor with Easy Start On. You can also set this function in Wizard mode on the main menu screen. Refer to 4.2.4.7 Wizard mode for details. Go to the Drive Set tab in Setting mode, and set 61 (Easy Start On) as Yes.
Page 539: Reading And Writing Parameters
Inverter Setting Mode 12.1.3 Reading and Writing Parameters Reading and writing parameters enable users to copy parameter settings saved in the main inverter unit to the Smart Operator memory or copy parameter settings saved in the Smart Operator memory to the main inverter unit. Setting Initial Mode...
Page 540: [ Image 3. Saving Parameter Settings ]
Inverter Setting Mode • Press keys to select an empty slot you want to save parameter settings • Press the key. [ Image 3. Saving Parameter Settings ] • When you successfully read parameter settings from the inverter, the pop- up window will display the Success message.
Page 541: [ Image 6. Main Menu ]
Inverter Setting Mode An Example of Writing Parameter Settings in the Inverter • Move to Setting mode by pressing key on the menu screen. [ Image 6. Main Menu ] • Press the key in the Operator Set tab and move to code no. 41. •...
Page 542: Parameter Initialization
Inverter Setting Mode • When you successfully write parameter settings in the inverter, the pop-up window will display the Success message. [ Image 9. The Screen after Successfully Writing Parameters ] 12.1.4 Parameter Initialization You can initialize changed parameter settings collectively or by group. However, during a fault trip or inverter operation, parameter settings cannot be initialized.
Page 543 Inverter Setting Mode Setting Initial Mode Group Code Set Value Unit Display Range Value OUT Group XDIN Group XAIN Group XOUT Group PPID Group SYNC Group PRT Group DIAG Group RSR2 Group INTC Group INTM Group USBC Group Operator Parameter Setting 0~35 Init...
Page 544: [ Image 10. Setting Mode Screen ]
Inverter Setting Mode An Example of Parameter Initialization • Move to Setting mode by pressing key on the menu screen. [ Image 10. Setting mode screen ] • Press the key in the Operator Set tab and move to code no. 39. •...
Page 545: Parameter Mode Lock
Inverter Setting Mode • It returns to the initialization selection screen once initialization is complete. [ Image 13. Parameter Initialization Selection in Setting Mode ] 12.1.5 Parameter Mode Lock You can use a registered password to make the parameter mode inaccessible. Setting Initial Mode...
Page 546 Inverter Setting Mode Code and Description Functions Registers the password to lock parameter mode. Follow the procedures below to register password. 1 Press the key in Smart Operator. 2 Enter 0000 upon initial registration, or enter the previous password if you already have one. Operator Set-51 If the password you entered matches your previous password, ParaViewLock...
Page 547 Inverter Setting Mode • Enter the password. (The initial password is 0000.) • Press the key. [ Image 16. Password Setting for Parameter Mode Lock ] • The ParaView Lock code value is changed to Locked and parameter mode lock is set. [ Image 17.
Page 548: Parameter Lock
Inverter Setting Mode 12.1.6 parameter lock You can use registered password to prohibit changing parameter values in parameter mode. Setting Initial Mode Group Code LCD Display Set Value Unit Range Value ParaEdit Lock Unlocked Unlocked Operator Setting ParaEditLock 0000 0~9999 0000 PwSet Parameter Lock Setting Details...
Page 549 Inverter Setting Mode An Example of a Parameter Change Prohibition • Move to Setting mode by pressing key on the menu screen. [ Image 19. Setting mode screen ] • Press the key in the Operator Set tab and move to code no. 52. •...
Page 550 Inverter Setting Mode • The ParaEdit Lock code value is changed to Locked and parameter change prohibition is set. [ Image 22. Screen after Parameter Change Prohibition Setting ] • Press the key and move to parameter mode and check if parameter items are deactivated.
Page 551: Changed Parameter Display
Inverter Setting Mode 12.1.7 Changed parameter display It exclusively shows parameters with different settings from the factory default in parameter mode. Use this feature to track changed parameters. Setting Initial Mode Group Code LCD Display Set Value Unit Range Value View Changed Operator...
Page 552: Monitoring Settings
Inverter Setting Mode 12.2 Monitoring Settings 12.2.1 Item Change in Monitor Display Mode You can monitor three items simultaneously in monitor mode. You can also change monitoring items. Refer to 4.2.4.1 Monitor mode for details on screen composition and items of the monitor mode. The following is an example of changing a monitor display item.
Page 553 Inverter Setting Mode • The screen moves to code no. 23 in the Operator Set tab in Setting mode. • Press the key and set the items to display in Monitor mode. (You may change parameter values directly in the Operator Set tab in Setting mode instead of pressing the key for one second.)
Page 554: Monitoring Item Settings For Top Status Bar
Inverter Setting Mode 12.2.2 Monitoring Item Settings for Top Status Bar Items displayed on the right of top status bar in Smart Operator are always displayed regardless of the mode. Therefore, if you register parameters of your choice in the top status bar, you can always check the values even when you move or change modes.
Page 555 Inverter Setting Mode • Press the keys and move the cursor to 2 (Output Current). • Press the key to change the setting. [ Image 32. Selecting the Output Current among Monitoring Items in the Top Status Bar ] • The changed item will be displayed in code no.
Page 556: Operation Status Monitor Settings
Inverter Setting Mode 12.2.3 Operation Status Monitor Settings The following are setting mode parameters for the operation status monitor. You can set additional features with the Smart Operator. Setting Initial Mode Group Code LCD Display Set Value Unit Range Value Anytime Para Frequency 0~24...
Page 557 Inverter Setting Mode Operation Status Monitor Parameters Settings Details Code and Description Functions Select the items to display on the status bar in the top-right corner of the Smart Operator. Select setting values for the information to be displayed from below. Drive Set-21-31 have the same setting values. Refer to 12.2.2 Monitoring Item Settings for Top Status Bar for more details on this parameter.
Page 558 Inverter Setting Mode Code and Description Functions Item Functionality PID Output Displays output of the PID controller. Displays the size of reference value of the PID controller and the PID reference values are Reference configurable. Displays the feedback volume of the PID Feedback controller.
Page 559: Trip Status Monitoring
Inverter Setting Mode Note Watt Hour Meter (inverter power consumption) Among the codes of Drive Set-20, 5 (Watt Hour Meter, inverter power consumption) uses calculations with voltage and current and is accumulated based on the power calculated every second. Power consumption is displayed as follows: •...
Page 560 Inverter Setting Mode • To check information such as output frequency, current, or operation status at the time of a trip occurrence, press key and move to the relevant position. [ Image 36. Trip Status Selection ] • If there is a trip history, press the keys and check the status of the trip at that moment.
Page 561: For Concurrent Trips Of Two Or More
Inverter Setting Mode 12.3.2 For Concurrent Trips of Two or More The following example demonstrates how to monitor output current in the operation group using the Smart Operator. • When there are two or more trips, the list of trips will be displayed at the top of the screen.
Page 562 Table of Functions 13 Table of Functions This chapter lists all the function settings for S300 series inverter. Set the parameters required for operation according to the table of functions. The parameter address when accessing the inverter parameter with communication is calculated as follows: 16-bit parameter address = 16 bit group code + code number 32-bit parameter address = 32 bit group code + code number *2...
Page 563: Drive Group (Drv)
Table of Functions - Drive Group (DRV) Group 16-Bit 32-Bit Group 16-Bit 32-Bit 1C00h 9C00h 3900 B900 1D00h 9D00h 3A00 BA00 PPID 2200h A200h 3B00 BB00 2400h A400h 3C00 BC00 DIAG 2500h A500h 3D00 BD00 13.1 Drive Group (DRV) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote).
Page 564 Table of Functions - Drive Group (DRV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1206h 920Ch Dec Time 0.00-6000.00 30.00 5.3.1 0.01 Keypad Fx/Rx-1 Fx/Rx-2 3-Wire Command 5.2.1 120ah 9214h △ Internal Comm Source USB Comm.
Page 565 Table of Functions - Drive Group (DRV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Keypad Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Internal Comm. 1st Torque 6.3.2 120ch 9218h △...
Page 566 Table of Functions - Drive Group (DRV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1218h 9230h Torque at 0.0-200.0 100.0 6.3.2.2 100% Normal Duty 9.1.3 Load Duty 1219h 9232h △ Select Heavy Duty 9.1.2 Normal PWM PWM Mode...
Page 567 Table of Functions - Drive Group (DRV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit M + (G * A) M * (G * A) M / (G * A) M+(M*(G*A)) M+G*2*(A-50) M*(G*2*(A-50)) Auxiliary M/(G*2*(A-50)) 1225h 924Ah △...
Page 568 Table of Functions - Drive Group (DRV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Keypad Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Up Down Drive 2nd Freq Internal Comm. 7.18 122ah 9254h Ref Src...
Page 569 Table of Functions - Drive Group (DRV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit During Run Fan Control Always Run 9.2.10 1232h 9264h Temp. Control 1255h 92AAh Temperature ℃ 1256h 92ACh Sync Frequency 0.01 0.01...
Page 570 Table of Functions - Basic Function Group (BAS) 13.2 Basic Function Group (BAS) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Max Frequency and Maximum Speed refer to the setting values at DRV-20 (Max Frequency) and DRV-21 (Maximum Speed) respectively.
Page 571 Table of Functions - Basic Function Group (BAS) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1309h 9312h DC Brake 0-1800 5.2.5.2 △ Speed 130ah 9314h DC Injection 1-200 7.24 △ Level 130bh 9316h PwrBrk 0-500 5.2.5.4...
Page 572 Table of Functions - Basic Function Group (BAS) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit None Auto Tuning 130fh 931eh △ Auto Tuning 1318h 9330h Ldq Tune 80-150 △ Freq Perc 1319h 9332h Ldq Tune 20-50 △...
Page 573 Table of Functions - Basic Function Group (BAS) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 132bh 9356h Step 0.00-Max Frequency 25.00 5.1.2.4 Frequency-13 0.01 0.01 132ch 9358h Step 0.00-Max Frequency 15.00 5.1.2.4 Frequency-14 0.01 0.01 132dh 935ah...
Page 574 Table of Functions - Basic Function Group (BAS) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 133ah 9374h Step 0-Maximum Speed 5.1.2.4 Speed-13 133bh 9376h Step 0-Maximum Speed 5.1.2.4 Speed-14 133ch 9378h Step 0-Maximum Speed 5.1.2.4 Speed-15 Linear...
Page 575 Table of Functions - Basic Function Group (BAS) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1350h 93a0h Acc Time-2 0.00-6000.00 30.00 5.3.1.3 0.01 1351h 93a2h Dec Time-2 0.00-6000.00 30.00 5.3.1.3 0.01 1352h 93a4h Acc Time-3 0.00-6000.00 40.00...
Page 576 Table of Functions - First Motor Group (MOT1) 13.3 First Motor Group (MOT1) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Communication Initial Property address/scale Code LCD Display...
Page 577 Table of Functions - First Motor Group (MOT1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 0.2 kW 0.4 kW 0.75 kW 1.5 kW 2.2 kW 4 kW 5.5 kW 7.5 kW 11 kW 15 kW 18.5 kW 22 kW...
Page 578 Table of Functions - First Motor Group (MOT1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1418h 9430h 16.8 Rated Speed 900-24000 △ Note 1419h 9432h Number of 2-100 Pole △ Poles 141ah 9434h Rated 16.8 1.0-1000.0...
Page 579 Table of Functions - First Motor Group (MOT1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 142ah 9454h PM Rotor 0.000-65.000 0.100 △ Flux 0.001 0.001 1433h 9466h 50-400 Bandwidth 1434h 9468h Active 0-1000 Resistance 1436h 946ch ASR Adjust...
Page 580 Table of Functions - First Motor Group (MOT1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit x 0.1 Load Speed x 0.01 7.21 1461h 94c2h Scale x 0.001 x 0.0001 Load Speed 7.21 1462h 94c4h Unit Note Table 1.
Page 581 Table of Functions - The First Motor V/F Group (VF1) 13.4 The First Motor V/F Group (VF1) This group is activated when the MOT1-05 (Control Mode) value is 0 (V/F) or 1 (Slip Comp.). The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote).
Page 582 Table of Functions - The First Motor V/F Group (VF1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 150ah 9514h User 0-100 6.1.3 △ Voltage-3 150bh 9516h User User Frequency-3- 6.1.3 60.00 △ Frequency-4 Max Frequency 0.01 0.01...
Page 583 Table of Functions - The First Motor V/F Group (VF1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1521h 9542h Reverse 0-15.0 △ Boost 1522h 9544h ATB Mot- 0.0-300.0 100.0 7.6.2 Gain 1523h 9546h ATB Gen- 0.0-300.0 100.0...
Page 584 Table of Functions - The First Motor V/F Group (VF1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Stall Prevent 9.1.4 154eh 959ch △ 154fh 959eh Stall 0.00- 15.00 9.1.4 Frequency-1 Stall Frequency-2 0.01 0.01 1550h 95a0h Stall Speed-1...
Page 585 Table of Functions - First Motor Control Group (VEC1) 13.5 First Motor Control Group (VEC1) This group is activated when the MOT1-05 (Control Mode) value is 3 (Sensorless) or 4 (Vector). The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote).
Page 586 Table of Functions - First Motor Control Group (VEC1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1617h 962eh Rev +Torque 0.0-320.0 180.0 6.6.1 Limit 1618h 9630h Rev -Torque 0.0-320.0 180.0 6.6.1 Limit 161ah 9634h TrqMode 0.00-Max Frequency 60.00...
Page 587 Table of Functions - Second Motor Group (MOT2) 13.6 Second Motor Group (MOT2) This group is activated when one of the DIN-01, 03, 05, 07, 09, 11, 13, and 15 (DI1- DI8 Define) values is 27 (2nd Motor). The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote).
Page 588 Table of Functions - Second Motor Group (MOT2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 0.2 kW 0.4 kW 0.75 kW 1.5 kW 2.2 kW 4 kW 5.5 kW 7.5 kW 11 kW 15 kW 18.5 kW 22 kW...
Page 589 Table of Functions - Second Motor Group (MOT2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1718h 9730h 16.8 Rated 900-24000 △ Speed Note 1719h 9732h Number of 2-100 Pole △ Poles 171ah 9734h 16.8 Rated 1.0-1000.0...
Page 590 Table of Functions - Second Motor Group (MOT2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1733h 9766h 50-400 Bandwidth 1736h 976ch ASR Adjust 1-10 Gain IPPE Enable 6.5.1 173dh 977ah 173eh 977ch IPPE Volt 10-100 6.5.1 Ref Perc...
Page 591 Table of Functions - Second Motor V/F Group (VF2) 13.7 Second Motor V/F Group (VF2) This group is activated when one of the DIN-01, 03, 05, 07, 09, 11, 13, and 15 (DI1- DI8 Define) values is 27 (2nd Motor) and the MOT2-05 (Control Mode) value is 0 (V/F) or 1 (Slip Comp.).
Page 592 Table of Functions - Second Motor V/F Group (VF2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1809h 9812h User Speed-2- User Speed-3 1350 6.1.3 △ User Speed-4 180ah 9814h User 0-100 6.1.3 △ Voltage-3 180bh 9816h User...
Page 593 Table of Functions - Second Motor V/F Group (VF2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1820h 9840h Forward 0.0-15.0 △ Boost 1821h 9842h Reverse 0.0-15.0 △ Boost 1822h 9844h ATB Mot- 0.0-300.0 100.0 7.6.2 Gain...
Page 594 Table of Functions - Second Motor V/F Group (VF2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Stall Prevent 9.1.4 184ch 9898h △ Stall Prevent 9.1.4 184dh 989ah △ Stall Prevent 9.1.4 184eh 989ch △...
Page 595 Table of Functions - Second Motor Control Group (VEC2) 13.8 Second Motor Control Group (VEC2) This group is activated when one of the DIN-01, 03, 05, 07, 09, 11, 13, and 15 (DI1- DI8 Define) values is 27 (2nd Motor) and the MOT2-05 (Control Mode) value is 3 (Sensorless) or 4 (Vector).
Page 596 Table of Functions - Second Motor Control Group (VEC2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1917h 992eh Rev +Torque 0.0-320.0 180.0 6.6.1 Limit 1918h 9930h Rev -Torque 0.0-320.0 180.0 6.6.1 Limit 191ah 9934h TrqMode 0.00-Max Frequency 60.00...
Page 597 Table of Functions - Advanced Function Group (ADV) 13.9 Advanced Function Group (ADV) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Max Frequency and Maximum Speed refer to the setting values at DRV-20 (Max Frequency) and DRV-21 (Maximum Speed) respectively.
Page 598 Table of Functions - Advanced Function Group (ADV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1a0fh 9a1eh Cmd Freq 0.00-Cmd Freq 0.50 5.1.2.5 Limit Lo Limit Hi 0.01 0.01 1a10h 9a20h Cmd Freq Cmd Freq Limit Lo- 60.00 5.1.2.5...
Page 599 Table of Functions - Advanced Function Group (ADV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1a1bh 9a36h Jump Cmd 0 - Jump Cmd Speed 5.1.2.5 Speed Lo1 Hi 1 1a1ch 9a38h Jump Cmd Jump Cmd Speed 5.1.2.5 Speed Hi1...
Page 600 Table of Functions - Advanced Function Group (ADV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1a2dh 9a5ah Br Release 0-Maximum Speed 7.25 Fwd Spd 1a2eh 9a5ch Br Release 0.00-Max Frequency 1.00 7.25 RevFreq 0.01 0.01 1a2fh 9a5eh...
Page 601 Table of Functions - Advanced Function Group (ADV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Run Enable 1a46h 9a8ch △ CoastStop (FreeRun) Run Disable Quick Stop 1a47h 9a8eh △ Stop Quick Stop Resume 1a48h 9a90h Quick Stop 0.00-6000.00...
Page 602 Table of Functions - Application Function Group (APP) 13.10 Application Function Group (APP) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Communication Initial Property address/scale Code LCD Display...
Page 603 Table of Functions - Application Function Group (APP) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1b12h 9b24h KEB Control 0.0-1000.0 100.0 Gain 1b13h 9b26h Damping 0-300 Gain 1b14h 9b28h KEB Acc 0.00-60.00 10.00 Time 0.01 RegenAvd...
Page 604 Table of Functions - Application Function Group (APP) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 200 V class 350-400 1b23h 9b46h DB Turn On 9.2.6 △ Level 400 V class 600-800 DB Warn 9.2.6 1b24h 9b48h %ED Enable...
Page 605 Table of Functions - Digital Input Terminal Block Group (DIN) 13.11 Digital Input Terminal Block Group (DIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Jump Code 1-99 4.3.3 1c00h 9c00h NONE External Trip-1 External Trip-2 External Trip-3 External Trip-4...
Page 606 Table of Functions - Digital Input Terminal Block Group (DIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Down Up/Down Clear Up/Down Save Cmd Frequency Hold 2nd Motor Dc Injection 29 Spd/Trq Change Reserved Reserved Timer Input Reserved...
Page 607 Table of Functions - Digital Input Terminal Block Group (DIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 47 PPID Step Ref-H Fire Mode Fwd Fire Mode Rev Pre Heat EPID1 Run EPID1 I-Term Clear EPID2 Run EPID2 I-Term...
Page 608 Table of Functions - Digital Input Terminal Block Group (DIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 70 WebCtrl Fwd Run 71 WebCtrl Rev Run Web Splice WPID Gain Change Web Bobbin-L Web Bobbin-H Web Preset DI1 Define 1c01h 9c02h...
Page 609 Table of Functions - Digital Input Terminal Block Group (DIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit DI1 Status 8.1.3 1c02h 9c04h DI2 Define 1c03h 9c06h △ DI2 Status 8.1.3 1c04h 9c08h DI3 Define 1c05h 9c0ah △...
Page 610 Table of Functions - Digital Input Terminal Block Group (DIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Normal Open DI2 NC/NO 8.1.2 1c1eh 9c3ch Normal Close 1c1fh 9c3eh 31 DI3 On Delay 0-100000 msec 8.1.1 1c20h 9c40h...
Page 611 Table of Functions - Digital Input Terminal Block Group (DIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Normal Open DI7 NC/NO 8.1.2 1c2dh 9c5ah Normal Close 1c2eh 9c5ch 46 DI8 On Delay 0-100000 msec 8.1.1 1c2fh 9c5eh...
Page 612 Table of Functions - Analog Input Terminal Block Group (AIN) 13.12 Analog Input Terminal Block Group (AIN) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Communication Initial Property...
Page 613 Table of Functions - Analog Input Terminal Block Group (AIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1d0ch 9d18h AI1 - y2 -100.00-100.00 -100.00 8.2.2 Percent 0.01 0.01 1d0dh 9d1ah 0.04-10.00 0.04 8.2.3 Quantizing 0.01 0.01...
Page 614 Table of Functions - Analog Input Terminal Block Group (AIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1d1bh 9d36h AI2 - y2 -100.00-100.00 -100.00 8.2.2 Percent 0.01 0.01 1d1ch 9d38h 0.04-10.00 0.04 8.2.3 Quantizing 0.01 0.01...
Page 615 Table of Functions - Analog Input Terminal Block Group (AIN) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1d2bh 9d56h 0.04-10.00 0.04 8.2.3 Quantizing 0.01 0.01 1d2dh 9d5ah 0.00-32.00 8.4.1 Monitor[kHz] 0.01 0.01 1d2eh 9d5ch -100.00-100.00 8.4.1 Monitor[%]...
Page 616 Table of Functions - Output Terminal Block Group (OUT) 13.13 Output Terminal Block Group (OUT) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Max Frequency and Maximum Speed refer to the setting values at DRV-20 (Max Frequency) and DRV-21 (Maximum Speed) respectively.
Page 617 Table of Functions - Output Terminal Block Group (OUT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1e03h 9e06h AO1 Gain -1000.00-1000.00 100.00 0.01 0.01 1e04h 9e08h AO1 Bias -100.00-100.00 0.00 0.01 0.01 1e05h 9e0ah AO1 LPF 0-10000 msec...
Page 618 Table of Functions - Output Terminal Block Group (OUT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1e17h 9e2eh PTO LPF 0-10000 msec Gain 1e18h 9e30h 0.00-100.00 0.00 Constant % 0.01 0.01 1e19h 9e32h PTO Monitor 0.00-100.00 0.01...
Page 619 Table of Functions - Output Terminal Block Group (OUT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Ready Zero Speed Detect Torque Detect Timer Output Trip Lost Keypad Warn DB Warn %ED Encoder Tune Warn Encoder Dir Warn...
Page 620 Table of Functions - Output Terminal Block Group (OUT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit MainCap Diag Alarm Pos Tar Bound Pos Max Track DO1 Define 8.3.1 1e32h 9e64h OCS Run FWD Run REV Run Fire Mode DO1 Status...
Page 621 Table of Functions - Output Terminal Block Group (OUT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 1e42h 9e84h DO3 On 0-100000 msec 8.3.2 Delay 1e43h 9e86h DO3 Off 0-100000 msec 8.3.2 Delay Normal Open DO3 NC/NO 8.3.3 1e44h 9e88h...
Page 622 Table of Functions - Process PID Group (PPID) 13.14 Process PID Group (PPID) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Max Frequency and Maximum Speed refer to the setting values at DRV-20 (Max Frequency) and DRV-21 (Maximum Speed) respectively.
Page 623 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Keypad Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Internal Comm. Reference1 USB Comm. 7.7.1 220ah a214h Source Option Comm.
Page 624 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit M + (G * A) M * (G * A) M / (G * A) M+(M*(G*A)) M+G*2*(A-50) M*(G*2*(A-50)) M/(G*2*(A-50)) Ref1 Auxiliary 7.7.1...
Page 625 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit None Analog Input 1 Ref2 Auxiliary Analog Input 2 7.7.1 2211h a222h Analog Input 3 Pulse Input M + (G * A) M * (G * A) M / (G * A) M+(M*(G*A))
Page 626 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Internal Comm. USB Comm. Feedback 7.7.1 2219h a232h Source Option Comm.
Page 627 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit M + (G * A) M * (G * A) M / (G * A) M+(M*(G*A)) M+G*2*(A-50) M*(G*2*(A-50)) Fdb Auxiliary M/(G*2*(A-50)) 7.7.1...
Page 628 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2229h a252h Integral 0.00-200.00 10.00 7.7.1 Time2 0.01 0.01 222ah a254h Derivative 0-1000 msec 7.7.1 Time2 Not Use Output Only PID Out PID + Main Freq...
Page 629 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 223ah a274h Pre-PID 0.0-600.0 60.0 7.7.3 Delay None Sleep Mode Always Enable 7.7.2 223ch a278h DI Dependent 223dh a27ah Sleep Boost 0.00 - Unit Max / 2 0.00...
Page 630 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2249h a292h 73 WakeUp Set2 0 - Unit Default 7.7.2 Unit Unit Unit 224ah a294h WakeUp 0.0-600.0 60.0 7.7.2 Delay2 2250h a2a0h...
Page 631 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit CUST °F °C inWC mBar Unit Select 7.7.1 225ah a2b4h m³/s m³/m...
Page 632 Table of Functions - Process PID Group (PPID) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit m³/h kg/s kg/m kg/h gl/s gl/m Unit Select gl/h 7.7.1 225ah a2b4h ft/s f³/s f³/m f³/h lb/s lb/m lb/h X100 Unit Scale...
Page 633 Table of Functions - Protection Function Group (PRT) 13.15 Protection Function Group (PRT) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Max Frequency and Maximum Speed refer to the setting values at DRV-20 (Max Frequency) and DRV-21 (Maximum Speed) respectively.
Page 634 Table of Functions - Protection Function Group (PRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2407h a40eh Retry Delay 0.0-60.0 7.14.1 In Phase 9.2.1.1 240ah a414h Open Chk 240bh a416h IPO Voltage 1-100 9.2.1.1 Band Out Phase...
Page 635 Table of Functions - Protection Function Group (PRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit None CoastStop (FreeRun) Lost USB 9.2.5.2 2413h a426h Mode Trip Dec Stop Warning Lost Preset 2414h a428h 2415h a42ah Lost USB 0.1-120.0 9.2.5.2...
Page 636 Table of Functions - Protection Function Group (PRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Half of Low Limit Lost AI1 Chk Below Low Limit 9.2.5.3 241ah a434h Level Below Or Maximum 241bh a436h 27 Lost AI1 Time 0.1-120.0 9.2.5.3...
Page 637 Table of Functions - Protection Function Group (PRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2421h a442h 33 Lost AI3 Time 0.1-120.0 9.2.5.3 OL Warn 9.1.2 2423h a446h Select 2424h a448h OL Warn 30-200 9.1.2 Level...
Page 638 Table of Functions - Protection Function Group (PRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit None CoastStop (FreeRun) Thermal-T 9.1.6 243ch a478h Mode Trip Dec Stop Warning Lost Preset None Analog Input 1 Thermal-T 9.1.6 243dh a47ah...
Page 639 Table of Functions - Protection Function Group (PRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Trip MainFan Trip 9.2.11 244bh a496h Mode Warning Trip AuxFan Trip 9.2.11 244dh a49ah Mode Warning Latch Ext-Trip 1 9.2.2 244eh a49ch Mode...
Page 640 Table of Functions - Protection Function Group (PRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit None Fire Mode Test Mode 7.11 245bh a4b6h △ Select Fire Mode 245dh a4bah FireMode 0.00-Max Frequency 60.00 7.11 Frequency 0.01...
Page 641 Table of Functions - Diagnosis Function Group (DIAG) 13.16 Diagnosis Function Group (DIAG) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Communication Initial Property address/scale Code LCD Display...
Page 642 Table of Functions - Diagnosis Function Group (DIAG) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 250ch a518h MainCap 10.0-100.0 90.0 9.3.3 Repl Level 0.01 0.01 250dh a51ah MainCap 0.0-100.0 9.3.3 Used Level 0.01 0.01 PreCharger 9.3.6...
Page 643 Table of Functions - Diagnosis Function Group (DIAG) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit AuxFan Time 9.3.7 2560h a5c0h △ Reset 2562h a5c4h Drive On 9.3.7 Time 2563h a5c6h Drive Run 9.3.7 Time...
Page 644 Table of Functions - Internal Communication Group (INTC) 13.17 Internal Communication Group (INTC) The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Communication Initial Property address/scale Code LCD Display...
Page 645 Table of Functions - Internal Communication Group (INTC) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Modbus Addr 10.2.2 2706h a70ch Mode Termi 10.2.2 2707h a70eh Resistor En 270bh a716h 11 Para Status-1 0000-FFFF 000Ah Hex 10.3.6 △...
Page 646 Table of Functions - Internal Communication Group (INTC) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2718h a730h Para 0000-FFFF 0000 10.3.6 △ Status-14 2719h a732h Para 0000-FFFF 0000 10.3.6 △ Status-15 271ah a734h Para 0000-FFFF 0000...
Page 647 Table of Functions - Internal Communication Group (INTC) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 272bh a756h Para 0000-FFFF 0000 10.3.6 △ Control-13 272ch a758h Para 0000-FFFF 0000 10.3.6 △ Control-14 272dh a75ah Para 0000-FFFF 0000...
Page 648 Table of Functions - Modbus Master Group (INTM) 13.18 Modbus Master Group (INTM) This group is only activated when the INTC-02 (Protocol) value is 2 (Modbus RTU Master). Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Jump Code 1-99...
Page 649 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P01 - Comm ILLEGAL DATA 2808h a810h Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT Not Used...
Page 650 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P02 - Comm ILLEGAL DATA 280fh a81eh Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT Not Used...
Page 651 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P03-Comm ILLEGAL DATA 2816h a82ch Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT Not Used Read Mode P04-Slave...
Page 652 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P04-Comm ILLEGAL DATA 281dh a83ah Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT Not Used Read Mode P05-Slave...
Page 653 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P05-Comm ILLEGAL DATA 2824h a848h Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT Not Used Read Mode P06-Slave...
Page 654 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P06-Comm ILLEGAL DATA 282bh a856h Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT Not Used Read Mode P07-Slave...
Page 655 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P07-Comm ILLEGAL DATA 2832h a864h Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT Not Used Read Mode P08-Slave...
Page 656 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P08-Comm ILLEGAL DATA 2839h a872h Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT Not Used Read Mode P09-Slave...
Page 657 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P09-Comm ILLEGAL DATA 2840h a880h Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT Not Used Read Mode P10-Slave...
Page 658 Table of Functions - Modbus Master Group (INTM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Not Used IDLE ILLEGAL FUNC ILLEGAL ADDR P10-Comm ILLEGAL DATA 2847h a88eh Diagnostic WRITE PERMISSION UNDEF CONDITION DISCONNECT...
Page 659 Table of Functions - USB Communication Group (USBC) 13.19 USB Communication Group (USBC) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Jump Code 1-99 4.3.3 2a00h aa00h 2a05h aa0ah Response 0-1000 msec 10.2.2 Delay Modbus Addr 10.2.2 2a06h aa0ch △...
Page 660 Table of Functions - USB Communication Group (USBC) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2a16h aa2ch Para 0000-FFFF 0000 10.3.5 △ Status-12 2a17h aa2eh Para 0000-FFFF 0000 10.3.5 △ Status-13 2a18h aa30h Para 0000-FFFF 0000...
Page 661 Table of Functions - USB Communication Group (USBC) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2a29h aa52h Para 0000-FFFF 0000 10.3.5 △ Control-11 2a2ah aa54h Para 0000-FFFF 0000 10.3.5 △ Control-12 2a2bh aa56h Para 0000-FFFF 0000...
Page 662 Table of Functions - USB Communication Group (USBC) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2a3bh aa76h S.Scope 0000-FFFF 0000 ParaAddr 7 2a3ch aa78h S.Scope 0000-FFFF 0000 ParaAddr 8 2a62h aac4h Error Count Error Count 2a63h aac6h Reset...
Page 663 Table of Functions - Virtual Terminal Block Group (VIRT) 13.20 Virtual Terminal Block Group (VIRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Jump Code 1-99 4.3.3 2c00h ac00h NONE External Trip-1 External Trip-2 External Trip-3 External Trip-4 SPEED_L...
Page 664 Table of Functions - Virtual Terminal Block Group (VIRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Down Up/Down Clear Up/Down Save Cmd Frequency Hold 2nd Motor Dc Injection 29 Spd/Trq Change Reserved Reserved Timer Input Reserved 34 Disable Aux Ref...
Page 665 Table of Functions - Virtual Terminal Block Group (VIRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Fire Mode Fwd Fire Mode Rev Pre Heat EPID1 Run EPID1 I-Term Clear EPID2 Run EPID2 I-Term Clear 55 Brake Monitor Sel POS Home...
Page 666 Table of Functions - Virtual Terminal Block Group (VIRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Virtual DI2 2c04h ac08h Define Virtual DI2 2c05h ac0ah Status Virtual DI2 2c06h ac0ch Const Virtual DI3 2c07h ac0eh Define Virtual DI3...
Page 667 Table of Functions - Virtual Terminal Block Group (VIRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Virtual DI7 2c13h ac26h Define Virtual DI7 2c14h ac28h Status Virtual DI7 2c15h ac2ah Const Virtual DI8 2c16h ac2ch Define Virtual DI8...
Page 668 Table of Functions - Virtual Terminal Block Group (VIRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Virtual DI12 2c23h ac46h Status Virtual DI12 2c24 ac48h Const Virtual DI13 2c25h ac4ah Define Virtual DI13 2c26h ac4ch Status Virtual DI13...
Page 669 Table of Functions - Virtual Terminal Block Group (VIRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit None FDT-1 FDT-2 FDT-3 FDT-4 Over Load Warn Drv Over Load Warn 7 Under Load Warn MainFan Warn Stall 10 Over Voltage Trip Low Voltage...
Page 670 Table of Functions - Virtual Terminal Block Group (VIRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Trip Lost Keypad Warn DB Warn %ED Encoder Tune Warn 28 Encoder Dir Warn On/Off Control Brake Control Run with Zero STO Monitor 33 Rst Restart F Trip...
Page 671 Table of Functions - Virtual Terminal Block Group (VIRT) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit FWD Run Virtual DO1 10.3.4 2c32h ac64h Define REV Run Virtual DO1 10.3.4 2c33h ac66h Status Virtual DO2 2c34h ac68h Define Virtual DO2...
Page 672 Table of Functions - Encoder Group (ENC) 13.21 Encoder Group (ENC) This group is only activated when the encoder card (optional) is installed. The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote). Communication Initial Property...
Page 673 Table of Functions - External PID 1 Group (EPI1) 13.22 External PID 1 Group (EPI1) This group is only activated when the APP-02 (ExternalPID Enable) value is 1 (Yes). The values below have the following meanings: • Unit Max: Unit at 100% (EPI1-93) •...
Page 674 Table of Functions - External PID 1 Group (EPI1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Keypad Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Up Down Drive Reference Internal Comm. 2e0ah ae14h Source USB Comm.
Page 675 Table of Functions - External PID 1 Group (EPI1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2e24h ae48h 36 Integral Time 0.0-200.0 10.0 2e25h ae4ah Derivative 0-1000 msec Time 2e26h ae4ch FeedForward 0-1000.0 Gain 2e2eh ae5ch Output Limit...
Page 676 Table of Functions - External PID 1 Group (EPI1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit CUST °F °C inWC mBar Unit Select 2e5ah aeb4h m³/s m³/m m³/h kg/s...
Page 677 Table of Functions - External PID 1 Group (EPI1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit kg/m kg/h gl/s gl/m gl/h ft/s f³/s Unit Select 2e5ah aeb4h f³/m f³/h lb/s lb/m lb/h X100 Unit Scale 2e5bh aeb6h X0.1...
Page 678 Table of Functions - External PID 2 Group (EPI2) 13.23 External PID 2 Group (EPI2) This group is only activated when the APP-02 (ExternalPID Enable) value is 1 (Yes). The values below have the following meanings: • Unit Max: Unit at 100% (EPI2-93) •...
Page 679 Table of Functions - External PID 2 Group (EPI2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Keypad Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Up Down Drive Reference Internal Comm. 2f0a af14 Source...
Page 680 Table of Functions - External PID 2 Group (EPI2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 2f24 af48 Integral 0.0-200.0 10.0 Time1 2f25 af4a Derivative 0-1000 msec Time1 2f26 af4c FeedForward 0.0-1000.0 Gain 2f2f af5c Output Limit...
Page 681 Table of Functions - External PID 2 Group (EPI2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit CUST °F °C inWC mBar Unit Select 2f5a afb4 m³/s m³/m...
Page 682 Table of Functions - External PID 2 Group (EPI2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit m³/h kg/s kg/m kg/h gl/s gl/m Unit Select gl/h 2f5ah afb4h ft/s f³/s f³/m f³/h lb/s lb/m lb/h X100 Unit Scale...
Page 683 Table of Functions - Position Control Group 1 (POS1) 13.24 Position Control Group 1 (POS1) This group is only activated when the APP-44 (Pos Ctrl Enable) value is 1 (Yes). The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote).
Page 684 Table of Functions - Position Control Group 1 (POS1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 3008h b010h Feedback Puls 7.26 Value 3009h b012h Total Move 0.00-650.00 7.26 Time 0.01 0.01 DI Dependent Keypad Internal Comm.
Page 685 Table of Functions - Position Control Group 1 (POS1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit SW Limit Lo 7.26 3020h b040h Enable 3021h b042h Pos SW Limit Pos SW Limit Low - 60000 7.26 High...
Page 686 Table of Functions - Position Control Group 1 (POS1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Run Relative 7.26 3037h b06eh △ 303ch b078h 1-65000 7.26 △ Numerator 303dh b07ah 1-65000 7.26 △ Denominator...
Page 687 Table of Functions - Position Control Group 2 (POS2) 13.25 Position Control Group 2 (POS2) This group is only activated when the APP-44 (Pos Ctrl Enable) value is 1 (Yes). The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote).
Page 688 Table of Functions - Position Control Group 2 (POS2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 310dh b11ah TRJ Tar 0-65000 30000 7.26 Pos-03 310eh b11ch TRJ Tar 0.00-Max Frequency 60.00 7.26 Freq-03 0.01 0.01 310fh b11eh...
Page 689 Table of Functions - Position Control Group 2 (POS2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 311fh b13eh TRJ Tar 0-65000 30000 7.26 Pos-06 3120h b140h TRJ Tar 0.00-Max Frequency 60.00 7.26 Freq-06 0.01 0.01 3121h b142h...
Page 690 Table of Functions - Position Control Group 2 (POS2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 3131h b162h TRJ Tar 0-65000 30000 7.26 Pos-09 3132h b164h TRJ Tar 0.00-Max Frequency 60.00 7.26 Freq-09 0.01 0.01 3133h b166h...
Page 691 Table of Functions - Position Control Group 2 (POS2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 3143h b186h TRJ Tar 0-65000 30000 7.26 Pos-12 3144h b188h TRJ Tar 0.00-Max Frequency 60.00 7.26 Freq-12 0.01 0.01 3145h b18ah...
Page 692 Table of Functions - Position Control Group 2 (POS2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 3154h b1a8h TRJ Tar 0-65000 30000 7.26 Pos-15 3155h b1aah TRJ Tar 0.00-Max Frequency 60.00 7.26 Freq-15 0.01 0.01 3156h b1ach...
Page 693 Table of Functions - WEB1 Group (WEB1) 13.26 WEB1 Group (WEB1) This group is only activated when the APP-45 (Tension Ctrl Enable) value is 1 (Yes). Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Jump Code 1-99 4.3.3...
Page 694 Table of Functions - WEB1 Group (WEB1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Keypad Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Internal comm. Main Spd USB Comm. 7.28.2.1 320bh b216h Source Option Comm.
Page 695 Table of Functions - WEB1 Group (WEB1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Keypad Analog Input 1 Analog Input 2 Analog Input 3 Pulse Input Internal comm. Reference USB Comm. 7.28.4 3214h b228h Source Option Comm.
Page 696 Table of Functions - WEB1 Group (WEB1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Fixed Tension 7.28.4.2 321bh b236h Down Type Proportional 321ch b238h Tension 0.00-50.00 7.28.4.2 Down In 0.01 0.01 Web PID 7.28.5.1 321eh b23ch △...
Page 697 Table of Functions - WEB1 Group (WEB1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 321eh b24ah Out Limit Lo -100.00-100.00 100.00 7.28.5.1 0.01 0.01 321eh b24ch Out Limit Hi -100.00-100.00 100.00 7.28.5.1 0.01 0.01 321eh b24eh 39 Output Scale...
Page 698 Table of Functions - WEB1 Group (WEB1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 3234h b268h Bobbin1 0.00-100.00 10.00 7.28.6.1 △ Diameter 0.01 0.01 3235h b26ah Bobbin2 0.00-100.00 15.00 7.28.6.1 △ Diameter 0.01 0.01 3236h b26ch Bobbin3...
Page 699 Table of Functions - WEB1 Group (WEB1) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 324ah b294h Web Bias 0.00-60.00 7.28.7.5 Freq 0.01 0.01 None WebBreak Trip 7.28.9 3250h b2a0h Enable Warning 3251h b2a2h WebBreak 0.00-100.00 20.00...
Page 700 Table of Functions - WEB2 Group (WEB2) 13.27 WEB2 Group (WEB2) This group is only activated when the APP-45 (Tension Ctrl Enable) value is 1 (Yes). The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote).
Page 701 Table of Functions - WEB2 Group (WEB2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 330ch b318h Fric Comp Fric Comp Spd 3- 7.28.10.2 △ Spd 4 Fric Comp Spd 5 330dh b31ah Fric Comp 0.00-100.00 0.00 7.28.10.2...
Page 702 Table of Functions - WEB2 Group (WEB2) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 331bh b336h Fric Comp Fric Comp Spd 8- 1620 7.28.10.2 △ Spd 9 Fric Comp Spd 10 331ch b338h Fric Comp 0.01 0.01...
Page 703: User Sequence Group (Us)
Table of Functions - User Sequence Group (US) 13.28 User Sequence Group (US) This group is only activated when the APP-03 (User Seq Enable) value is 1 (Yes). The codes in the gray shaded area are hidden when shipped from the factory and shown only when setting the parameter (refer to the footnote).
Page 704 Table of Functions - User Sequence Group (US) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 11 Run Reverse 7.27.1 340bh b416h Command 0.00-Max Frequency 0.00 7.27.1 340fh b41eh Frequency 3410h b420h Command 0-Maximum Speed 7.27.1 Speed 3411h b422h...
Page 705 Table of Functions - User Sequence Group (US) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Acceleration 7.27.1 3429h b452h ConstRate 7.27.1 342ah b454h Operating Deceleration 7.27.1 342bh b456h Dec to stop 7.27.1 342ch b458h H/W OCS 7.27.1 342dh b45ah S/W OCS...
Page 706 Table of Functions - User Sequence Logical Operation Group (USL) 13.29 User Sequence Logical Operation Group (USL) This group is only activated when the APP-03 (User Seq Enable) value is 1 (Yes). Communication Initial Property address/scale Code LCD Display Setting Range Ref.
Page 707 Table of Functions - User Sequence Logical Operation Group (USL) Communication Initial Property address/scale Code LCD Display Setting Range Ref. Value 16-Bit 32-Bit Logic03 InputA 7.27.2 3510h b520h Logic03 InputB 7.27.2 3511h b522h Logic03 InputC 7.27.2 3512h b524h Logic03 Output 7.27.2 3513h b526h Same as Logic01 Logic04 Type...
Page 708 Table of Functions - User Sequence Logical Operation Group (USL) Communication Initial Property address/scale Code LCD Display Setting Range Ref. Value 16-Bit 32-Bit Logic08 InputB 7.27.2 352ah b554h Logic08 InputC 7.27.2 352bh b556h Logic08 Output 7.27.2 352ch b558h Same as Logic01 Logic09 Type 7.27.2 352dh b55ah Type...
Page 709 Table of Functions - User Sequence Logical Operation Group (USL) Communication Initial Property address/scale Code LCD Display Setting Range Ref. Value 16-Bit 32-Bit Logic13 InputC 7.27.2 3544h b588h Logic13 Output 7.27.2 3545h b58ah Same as Logic01 Logic14 Type 7.27.2 3546h b58ch Type Logic14 InputA 7.27.2 3547h b58eh...
Page 710 Table of Functions - User Sequence Arithmetic Operation Group (USV) 13.30 User Sequence Arithmetic Operation Group (USV) This group is only activated when the APP-03 (User Seq Enable) value is 1 (Yes). Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref.
Page 711 Table of Functions - User Sequence Arithmetic Operation Group (USV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit IF(A==B) IF(A!=B) IF(C) HOLD(A) ON DELAY OFF DELAY Timer Value01 Type 7.27.3 3605h b60ah Window Window C <= A <= B Lowpass Filter 32 LimitA UprB LwrC...
Page 712 Table of Functions - User Sequence Arithmetic Operation Group (USV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Value03 -99999999-99999999 7.27.3 3610h b620h InputA Value03 -99999999-99999999 7.27.3 3611h b622h InputB Value03 -99999999-99999999 7.27.3 3612h b624h InputC Value03 -99999999-99999999...
Page 713 Table of Functions - User Sequence Arithmetic Operation Group (USV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Value06 -99999999-99999999 7.27.3 3621h b642h InputC Value06 -99999999-99999999 7.27.3 3622h b644h Output Same as Value01 35 Value07 Type 7.27.3 3623h b646h Type Value07...
Page 714 Table of Functions - User Sequence Arithmetic Operation Group (USV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Same as Value01 50 Value10 Type 7.27.3 3632h b664h Type Value10 -99999999-99999999 7.27.3 3633h b666h InputA Value10 -99999999-99999999 7.27.3 3634h b668h...
Page 715 Table of Functions - User Sequence Arithmetic Operation Group (USV) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Value13 -99999999-99999999 7.27.3 3643h b686h InputB Value13 -99999999-99999999 7.27.3 3644h b688h InputC Value13 -99999999-99999999 7.27.3 3645h b68ah Output Same as Value01 70 Value14 Type...
Page 716 Table of Functions - User Sequence Parameter Operation Group (USP) 13.31 User Sequence Parameter Operation Group (USP) This group is only activated when the APP-03 (User Seq Enable) value is 1 (Yes). Note Please only use a 32-bit address for USP-61-90 (Var 01-30). Communication Initial Property...
Page 717 Table of Functions - User Sequence Parameter Operation Group (USP) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 0-1 EDGE Paraset05 7.27.4 370eh b71ch Type 1-0 EDGE Paraset 05 7.27.4 370fh b71eh Result Paraset06 In 7.27.4 3710h b720h 0-1 EDGE Paraset06...
Page 718 Table of Functions - User Sequence Parameter Operation Group (USP) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 0-1 EDGE Paraset11 In 7.27.4 371fh b73eh 1-0 EDGE Paraset11 7.27.4 3720h b740h Type Paraset 11 7.27.4 3721h b742h Result 0-1 EDGE...
Page 719 Table of Functions - User Sequence Parameter Operation Group (USP) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Paraset16 7.27.4 372fh b75eh Type Paraset 16 7.27.4 3730h b760h Result 0-1 EDGE Paraset17 In 7.27.4 3731h b762h 1-0 EDGE Paraset17 7.27.4 3732h b764h...
Page 720 Table of Functions - User Sequence Parameter Operation Group (USP) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit -99999999- Var 04 7.27.4 3740h b780h 99999999 -99999999- Var 05 7.27.4 3741h b782h 99999999 -99999999- Var 06 7.27.4 3742h b784h 99999999 -99999999-...
Page 721 Table of Functions - User Sequence Parameter Operation Group (USP) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit -99999999- Var 21 7.27.4 3751h b7a2h 99999999 -99999999- Var 22 7.27.4 3752h b7a4h 99999999 -99999999- Var 23 7.27.4 3753h b7a6h 99999999 -99999999-...
Page 722 Table of Functions - User Sequence Special Function Group (USM) 13.32 User Sequence Special Function Group (USM) This group is only activated when the APP-03 (User Seq Enable) value is 1 (Yes). Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref.
Page 723 Table of Functions - User Sequence Special Function Group (USM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 12 Mux1 Input12 7.27.5 380ch b818h 13 Mux1 Input13 7.27.5 380dh b81ah 14 Mux1 Input14 7.27.5 380eh b81ch 15 Mux1 Input15 7.27.5 380fh b81eh...
Page 724 Table of Functions - User Sequence Special Function Group (USM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Demux1 7.27.5 381bh b836h Out09 Demux1 7.27.5 381ch b838h Out10 Demux1 7.27.5 381dh b83ah Out11 Demux1 7.27.5 381eh b83ch Out12 Demux1...
Page 725 Table of Functions - User Sequence Special Function Group (USM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit 382fh b85eh Output Limit -100.00-100.00 100.00 7.27.5 High 0.01 0.01 3831h b862h 49 Output Scale 0.1-1000.0 100.0 7.27.5 I-Term Clear...
Page 726 Table of Functions - User Sequence Special Function Group (USM) Communication Initial Property address/scale Code LCD Display Setting Range Unit Ref. Value 16-Bit 32-Bit Block Output 0-65535 7.27.5 3842h b884h Block Output 0-65535 7.27.5 3843h b886h Block Output 0-65535 7.27.5 3844h b888h Block Output 0-65535 7.27.5 3845h b88ah...
Page 727: Troubleshooting
Troubleshooting 14 Troubleshooting 14.1 Trip and Warning When the inverter detects an abnormal condition, it will stop (trip) the operation or display a warning to protect the internal circuit. When a trip or warning occurs, detailed trip information and warning information will be displayed on the Smart Operator.
Page 728 Troubleshooting Trip LCD Display Details condition Displayed when internal DC circuit voltage is less than Latch/ the specified value during operation. It is possible to Low Voltage Level set the trip type (Latch/Level) in the PRT-02 (LV Trip Mode) code. Displayed when a ground fault trip occurs on the output side of the inverter and causes the current to Ground Fault Trip...
Page 729 Troubleshooting 14.1.1.2 Protection Functions Using Abnormal Internal Circuit Conditions and External Signals Table 2. Trip related to internal circuit/external signal Trip LCD Display Details condition Displayed when there is an error in reading/writing Data Storage Error Fatal parameters due to damage to the inverter's internal storage device.
Page 730 Troubleshooting Trip LCD Display Details condition Displayed when there is an error in the power circuit Gate Power Loss Latch of the power unit in the inverter. Displayed when there is an error in the capacity Power Index Error Level recognition circuit of the power unit in the inverter.
Page 731 Troubleshooting Trip LCD Display Details condition Displayed if a trip signal is provided when communication is not performed through the USB Lost USB Level connector. Operates when PRT-19 (Lost USB Mode) is set to a value other than 0. Lost Ext Ana In- Displayed if a trip signal is provided when the analog Level 1, 2, 3, 4...
Page 732: Advanced Functions
Troubleshooting 14.1.1.4 Advanced Functions Table 4. Trip related to application functions Trip LCD Display Details condition Displayed when there is an error with the mechanical Mechanical Brake Latch brake sequence. Displayed when the restart function is activated Reset Restart Fail Latch after more than the set number of resets has been performed.
Page 733 Troubleshooting Trip LCD Display Details condition Displayed when an input signal is input into the Pos HW Limit High Latch multifunction terminal whose DI1-DI8 Define code is set to 59 (POS HW Lmt H). Displayed when an input signal is input into the Pos HW Limit Low Latch multifunction terminal whose DI1-DI8 Define code is...
Page 734: Warning Messages
Troubleshooting 14.1.2 Warning Messages 14.1.2.1 Fault status Table 7. Fault status warning LCD Display Details Displayed when the motor becomes overloaded. Operates when PRT-35 (OL Warn Select) code is set to 1 (Yes). Over Load Warn To receive a warning output signal, set the OUT-50, 52, 54 (DO1-DO3 Status) codes to 5 (Over Load Warn).
Page 735 Troubleshooting LCD Display Details Displayed when the DB resistor warning level is greater than the APP-37 (DB Warn %ED) set value. Operates when the APP-36 DB Warn %ED (DB Warn %ED Enable) code is set to 1 (Yes). To receive a warning output signal, set the OUT-50, 52, 54 (DO1-DO3 Status) codes to 26 (DB Warn %ED).
Page 736 Troubleshooting 14.1.2.2 Status display according to advanced tasks Table 8. Status display warning according to advanced tasks LCD Display Details Displayed when converting to speed control mode during a Torque->Speed torque control mode operation in torque control mode. Displayed when converting to torque control mode during a Speed->Torque speed control mode operation in torque control mode.
Page 737: Troubleshooting Fault Trips
Troubleshooting 14.2 Troubleshooting Fault Trips When a fault trip or warning occurs due to a protection function, refer to the following table for possible causes and remedies. Table 10. Troubleshooting Fault Trips Items Cause Remedy Replace the motor and inverter The load is greater than the with models that have a larger rated motor capacity.
Page 738 Troubleshooting Items Cause Remedy Set the deceleration time Deceleration time is too short (PRT-01 Trip Dec Time) to a for the load inertia (GD2). longer value. Use the braking unit. Refer to 16.6 Braking Unit and Braking Resistor Over Voltage A generative load occurs at the Specifications for more inverter output.
Page 739 Troubleshooting Items Cause Remedy The magnetic contactor (MC) Check the magnetic contactor on the output side has a on the output side. Out Phase Open connection fault. The output wiring is faulty. Check the output wiring. The magnetic contactor Check the magnetic contactor (MC) on the input side has a on the input side.
Page 740 Troubleshooting 14.3 Actions on Other Faults When a fault other than those identified as fault trips or warnings occurs, refer to the following table for possible causes and remedies. Table 11. Actions on Other Faults Items Cause Remedy Stop the inverter to change to program mode and set the The inverter is in operation parameter.
Page 741 Troubleshooting Items Cause Remedy The load is too high. Operate the motor independently. An emergency stop signal is Reset the emergency stop signal. input. The wiring for the control Check the wiring for the control circuit terminal is incorrect. circuit terminal. Check the input voltage or current The input voltage or current for the frequency command.
Page 742 Troubleshooting Items Cause Remedy Reverse rotation prevention Remove the reverse rotation is selected. prevention. The motor Check the input signal associated only rotates in one The reverse rotation signal with the 3-wire operation and direction. is not provided, even when a adjust as necessary.
Page 743 Troubleshooting Items Cause Remedy Reduce the load. Manually increase the amount of torque boost to operate. Refer to 7.6.1 Manual Torque Boost for The load is too high. details. Replace the motor and the The motor stops when inverter with models with accelerating.
Page 744 Troubleshooting Items Cause Remedy Replace the motor and inverter There is a high variance in with models that have a larger load. capacity. Motor revolutions per Stabilize the power supply minute varies during The input voltage varies. voltage. operation. Adjust the output frequency (DRV- Motor speed variations occur 01 Command Frequency) to avoid at a specific frequency.
Page 745 Troubleshooting Items Cause Remedy Check the input voltage and The motor vibrates balance the voltage. The voltage between phases severely and does not is badly balanced. Check and test the motor’s rotate normally. insulation. Resonance occurs between Increase or decrease the carrier the motor’s natural frequency frequency (DRV-27 Carrier and the carrier frequency.
Page 746 Troubleshooting Items Cause Remedy The frequency reference is Set the frequency reference within the jump frequency higher than the jump frequency range. range. The output frequency The frequency reference is Set the upper limit of the does not increase exceeding the upper limit of frequency command higher than to the frequency the frequency command.
Page 747: Maintenance
Maintenance 15 Maintenance 15.1 Regular Inspection Lists 15.1.1 Daily Inspections Table 1. Regular Inspection List Inspection Inspection Inspection Inspection Judgment Inspection Area Item Details Method Standard Equipment Is the There must ambient be no danger temperature of freezing and humidity Refer to 2.1 with ambient within the...
Page 748 Maintenance Inspection Inspection Inspection Inspection Judgment Inspection Area Item Details Method Standard Equipment Turn off Is there any the system Cooling abnormal and check Fan rotates Cooling Fan system vibration or operation by smoothly noise? rotating the fan manually. Check the Check and Is the reading of...
Page 749: Annual Inspections
Maintenance 15.1.2 annual Inspections Table 2. Regular (Yearly) Inspection List Inspection Inspection Inspection Inspection Judgment Inspection Area Item Details Method Standard Equipment Remove wiring from the inverter and short R/S/T/U/V/W Megger test terminals, and (between then measure Must be above 5 input/output from each MΩ...
Page 750 Maintenance Inspection Inspection Inspection Inspection Judgment Inspection Area Item Details Method Standard Equipment Is there any chattering Visual noise inspection during Relay No abnormality operation? Is there any Visual damage to the Input/ inspection contacts? Output circuit Is there any Visual damage from No abnormality...
Page 751: Bi-Annual Inspections
Maintenance 15.1.3 bi-annual Inspections Table 3. Regular (Biennial) Inspection List Inspection Inspection Inspection Inspection Judgment Inspection Area Item Details Method Standard Equipment Remove the Megger test DC 500 V wires from class megger (between Insulation terminals Must be above 5 Motor (insulation- the output...
Page 752: Storage And Disposal
Maintenance 15.2 Storage and Disposal 15.2.1 Proper Product Storage If you are not using the product for an extended period, store it in the following way: • Store the product in the environmental suitable for operation (refer to 1.3 Installation Considerations). •...
Page 753: Technical Specifications
Technical Specifications 16 Technical Specifications 16.1 Input and Output Specifications 16.1.1 200 V Class 0.4-18.5 kW (LSLV0004 - 0185S300-2) Table 1. Input/Output Specifications (200 V Class 0.4-18.5 kW) Model: LSLV□□□□S300-2 0004 0008 0015 0022 0040 0055 0075 0110 0150 0185 [HP] Heavy Duty (HD) [kW] 0.4 0.75 1.5 18.5 Applied Motor [HP] Normal Duty (ND)
Page 754 Technical Specifications Model: LSLV□□□□S300-2 0004 0008 0015 0022 0040 0055 0075 0110 0150 0185 Input 3-phase 200-240, -15% - +10% Voltage Input [Hz] 50/60 ±5% frequency Input Rating 9.6 15.5 22.1 29.6 42.6 54.8 68.4 Rated Current 6.8 10.5 14.1 19.5 26.9 38.1 51.1 63.9 75.8 Weight (lb /kg) 7.2 12.9 13.2 16.1.2 200 V Class 22-75 kW (LSLV0220 - 0750S300-2)
Page 755 Technical Specifications Model: LSLV□□□□S300-2 0220 0300 0370 0450 0550 0750 V/F, V/F-SC 0.01~590 Output V/F-PG 0~400 [Hz] frequency Output SLVC-IM , SLVC-PM 0~400 Rating SVC-IM , SVC-PM Output 3-phase 200-240 voltage Input 3-phase 200-240, -15% - +10% Voltage Input [Hz] 50/60 ±5% frequency Input...
Page 756 Technical Specifications Model: LSLV□□□□S300-4 0004 0008 0015 0022 0040 0055 0075 0110 0150 0185 0220 1.4 2.6 3.7 4.2 7.0 11.3 12.6 18.3 23.6 29.7 34.3 [kVA] Rated capacity 1.9 3.1 4.6 6.1 9.2 13.3 18.3 23.6 29.0 34.3 46.5 [kVA] 1.8 3.4 4.8 5.5 9.2 14.8 16.5 24 Rated Current...
Page 757 Technical Specifications 16.1.4 400 V Class 30-75 kW (LSLV0300 - 0750S300-4) Table 4. Input/Output Specifications (400 V Class 30-75 kW) Model: LSLV□□□□S300-4 0300 0370 0450 0550 0750 [HP] Heavy Duty (HD) [kW] Applied Motor [HP] Normal Duty (ND) [kW] 46.5 57.2 69.4 83.8 115.8 [kVA] Rated capacity 57.2 69.4 81.5...
Page 758 Technical Specifications Model: LSLV□□□□S300-4 0300 0370 0450 0550 0750 Input 3-phase 380-480, -15% - +10% Voltage Input [Hz] 50/60 ±5% frequency Input Rating 56.7 70.1 85.1 103.5 146.5 Rated current 70.1 85.1 100.7 136.8 162.9 Weight (lb /kg) 18.6 18.7 28.3 41.2 41.9 16.1.5 400 V Class 90-220 kW (LSLV0900 - 2200S300-4)
Page 759 Technical Specifications Model: LSLV□□□□S300-4 0900 1100 1320 1600 1850 2200 [kVA] Rated capacity [kVA] Rated Current (380 - 460 V) Output Rated Rating Current (460-480 V) V/F, V/F-SC 0.01~590 Output V/F-PG 0~400 [Hz] frequency SLVC-IM , SLVC-PM 0~400 SVC-IM , SVC-PM Output 3-phase 380-480 voltage...
Page 760: Product Specification Details
Technical Specifications 16.2 Product Specification Details 16.2.1 Product Specification Details Table 6. Product Specifications Items Description V/F control, slip compensation, V/F PG Control method sensorless vector, sensored vector Digital command 0.01Hz Frequency settings power resolution Analog command 0.06 Hz(60 Hz standard) Frequency accuracy 1% of maximum output frequency Control V/F pattern Linear, square reduction, user V/F...
Page 761 Technical Specifications Items Description Forward operation, reverse operation Reset Emergency stop External trip 1, 2, 3, 4 Jog operation Multi-stage frequency: L/M/H/X Multi-stage acceleration and deceleration: high/medium/ Acceleration or deceleration stop Safe operation (Run Enable) 3-wire Second operation (2nd Source) Switching to commercial power (Exchange) Multifunction Increase/reduce/delete/save up-down operation Terminal...
Page 762 Technical Specifications Items Description Multifunction Open Less than DC 26V, 50mA Collector Terminal Trip output and inverter Less than AC 250 V, 2 A, N.O. operation less than DC 30 V, 3 A Trip Relay status Terminal Less than AC 250 V, 1 A, Output output N.C.
Page 763 Technical Specifications 16.2.2 Structure and Usage Environment Table 7. Product Structure/Usage Environment Items Description Cooling type Forced fan cooling structure Protection IP 20 (default), UL Open & Enclosed Type 1 (optional) structure Installing Conduit option fulfills UL Enclosed Type 1 Where there is no ice or frost, •...
Page 764: External Dimensions (Ip20 Type)
Technical Specifications 16.3 External Dimensions (IP20 Type) 16.3.1 External Dimensions 200 V Class 0.4-4 kW / 400 V Class 0.4-4 kW Mounting Hole [ Image 1. 200 V class 0.4-4 kW/400 V class 0.4-4 kW Exterior Diagram ] Table 8. External Dimensions (200 V Class 0.4-4 kW/400 V Class 0.4-4 kW) Model LSLV□□□□...
Page 765 Technical Specifications 200 V Class 5.5-7.5 kW / 400 V Class 5.5-7.5 kW Mounting Hole [ Image 2. 200 V class 5.5-7.5 kW/400 V class 5.5-7.5 kW Exterior Diagram ] Table 9. External Dimensions (200 V Class 5.5-7.5 kW/400 V Class 5.5-7.5 kW) Model LSLV□□□□...
Page 766 Technical Specifications 200 V Class 11 kW / 400 V Class 11-15 kW Mounting Hole [ Image 3. 200 V Class 11 kW/400 V Class 11-15 kW Exterior Diagram ] Table 10. External Dimensions (200 V Class 11 kW/400 V Class 11-15 kW) Model LSLV□□□□...
Page 767 Technical Specifications 200 V Class 15-18.5 kW / 400 V Class 18.5-22 kW Mounting Hole [ Image 4. 200 V class 15-18 kW/400 V class 18.5-22 kW Exterior Diagram ] Table 11. External Dimensions (200 V Class 15-18.5 kW/400 V Class 18.5-22 kW) Model LSLV□□□□...
Page 768 Technical Specifications 200 V Class 22 kW / 400 V Class 30-37 kW Mounting Hole [ Image 5. 200 V Class 22 kW/400 V Class 30-37 kW Exterior Diagram ] Table 12. External Dimensions (200 V Class 22 kW/400 V Class 30-37 kW) Model LSLV□□□□...
Page 769 Technical Specifications 200 V Class 30 kW / 400 V Class 45 kW Mounting Hole [ Image 6. 200 V Class 30 kW/400 V Class 45 kW Exterior Diagram ] Table 13. External Dimensions (200 V Class 30 kW/400 V Class 45 kW) Model LSLV□□□□...
Page 770 Technical Specifications 200 V Class 37-45 kW / 400 V Class 55-75 kW Mounting Hole [ Image 7. 200 V class 37-45 kW/400 V class 55-75 kW Exterior Diagram ] Table 14. External Dimensions (200 V Class 37-45 kW/400 V Class 55-75 kW) Model LSLV□□□□...
Page 771 Technical Specifications 400 V Class 90-110 kW Mounting Hole [ Image 8. 400 V Class 90-110 kW Exterior diagram ] Table 15. External Dimensions (400 V Class 90-110 kW) Model LSLV□□□□ LSLV0900S300-4 306.4 725.0 391.0 200.0 53.2 240.0 33.2 688.5 27.0 19.0 LSLV1100S300-4 (12.06)
Page 772 Technical Specifications 200 V Class 55-75 kW / 400 V Class 132-160 kW Mounting Hole [ Image 9. 200 V class 55-75 kW/400 V class 132-160 kW Exterior Diagram ] Table 16. External Dimensions (200 V Class 55-75 kW/400 V Class 132-160 kW) Model LSLV□□□□...
Page 773 Technical Specifications 400 V Class 185-220 kW Mounting Hole [ Image 10. 400 V Class 185-220 kW Exterior diagram ] Table 17. External Dimensions (400 V Class 185-220 kW) Model LSLV□□□□ LSLV1850S300-4 426.0 920.0 440.9 160.0 53.0 895.5 11.0 24.0 11.0 LSLV2200S300-4 (16.77) (36.22)
Page 774: Peripheral Devices
Technical Specifications 16.4 Peripheral Devices 16.4.1 Standards of Molded Case Circuit Breaker (MCCB), Earth Leakage Circuit Breaker (ELCB), and Magnetic Contactor (MC) You may use molded case circuit breakers (MCCB), earth leakage circuit breakers (ELCB), and magnetic contactors (MC) in the following table: Table 18.
Page 775 Technical Specifications Earth Leakage Molded Case Circuit Breaker Magnetic Contactor Circuit (MCCB) (MC) Model Breaker LSLV□□□□ (ELCB) Rating Rating Rating Model Model Model 0022S300-4 UTS150·L·MCP·12·3P·UL EBS33c MC-12a 0040S300-4 UTS150·L·MCP·20·3P·UL EBS33c MC-18a 0055S300-4 UTS150·L·MCP·32·3P·UL EBS33c MC-32a 0075S300-4 UTS150·L·MCP·32·3P·UL EBS33c MC-32a 0110S300-4 UTS150·L·FTU·40·3P·UL EBS53c MC-50a...
Page 776 Technical Specifications 16.4.2 AC Input Fuse and Reactor Specifications This product has a built-in DC reactor. To additionally install an AC reactor, contact our customer service center. Table 19. Input Fuse and Reactor Specifications AC Input Fuse AC Reactor* Model LSLV□□□□ Voltage [V] Current [A] Inductance [mH] Current [A] 0004S300-2 2.02 0008S300-2 1.12...
Page 777 Technical Specifications AC Input Fuse AC Reactor* Model LSLV□□□□ Voltage [V] Current [A] Inductance [mH] Current [A] 0110S300-4 0.59 0150S300-4 0.47 0185S300-4 0.37 0220S300-4 0.29 0300S300-4 0.24 0370S300-4 0.19 0450S300-4 0.16 0550S300-4 0.12 0750S300-4 0.09 0900S300-4 0.08 1100S300-4 0.07 1320S300-4 0.05 1600S300-4 0.05 1850S300-4...
Page 778 Technical Specifications 16.5 Terminal Screw Specifications 16.5.1 Input/output Terminal Screw Specification Table 20. Input/output Terminal Screw Specification Model Terminal Block Screw Size Screw Torque [Kgf·cm (N·m)] LSLV□□□□ 0004S300-2 12.2~14.3(1.2~1.4) 0008S300-2 12.2~14.3(1.2~1.4) 0015S300-2 12.2~14.3(1.2~1.4) 0022S300-2 12.2~14.3(1.2~1.4) 0040S300-2 12.2~14.3(1.2~1.4) 0055S300-2 12.2~14.3(1.2~1.4) 0075S300-2 12.2~14.3(1.2~1.4) 0110S300-2 20.4~24.5(2.0~2.4) 0150S300-2 20.4~24.5(2.0~2.4) 0185S300-2 20.4~24.5(2.0~2.4) 0220S300-2 30.6~38.2(3~3.74) 0300S300-2 61.2~91.8(6~9) 0370S300-2...
Page 779 Technical Specifications Model Terminal Block Screw Size Screw Torque [Kgf·cm (N·m)] LSLV□□□□ 0110S300-4 12.2~14.3(1.2~1.4) 0150S300-4 12.2~14.3(1.2~1.4) 0185S300-4 20.4~24.5(2.0~2.4) 0220S300-4 20.4~24.5(2.0~2.4) 0300S300-4 M5 / M6 24.5~31.8(2.4~3.1)/30.6~38.2(3~3.74) 0370S300-4 M5 / M6 24.5~31.8(2.4~3.1)/30.6~38.2(3~3.74) 0450S300-4 61.2~91.8(6~9) 0550S300-4 61.2~91.8(6~9) 0750S300-4 61.2~91.8(6~9) 0900S300-4 61.2~91.8(6~9) 1100S300-4 61.2~91.8(6~9) 1320S300-4 182.4~215.0(18~21.2) 1600S300-4 182.4~215.0(18~21.2)
Page 780 Technical Specifications Caution Apply rated torques to the terminal screws. Loose screws may cause short circuits and malfunctions. Tightening the screw too much may damage the terminals and cause short circuits and malfunctions. Use copper wires only with 600V, 90 rating for the ℃...
Page 781 Technical Specifications 16.6 Braking Unit and Braking Resistor Specifications 16.6.1 Type of Braking Units Table 22. Type of Braking Units Exterior and Product Type Voltage Brake unit Terminal Type Capacity Arrangement Type A 22kW SV220DBU-2U (Refer to the 200 V 37kW SV370DBU-2U table 16.6.5 class...
Page 782 Technical Specifications Note • Make sure to check the changes in the user manual of the relevant braking unit before use. • Refer to 16.6.5 Braking Resistor Specifications, or check the user manual of each braking unit for the resistance values of Type A. •...
Page 783 Technical Specifications The terminal arrangement of the braking unit is as the following groups: Group 1 [ Image 11. Terminal Arrangement in the Braking Unit - Group 1 ] Group 2 [ Image 12. Terminal Arrangement in the Braking Unit - Group 2 ] Group 3 [ Image 13.
Page 784 Technical Specifications Group 5 [ Image 15. Terminal Arrangement in the Braking Unit - Group 5: A Frame (200 V Class 37 kW, 400 V Class 37 kW/75 kW) [ Image 16. Terminal Arrangement in the Braking Unit - Group 5: B/C Frame (200 V Class 75 kW) ]...
Page 785 Technical Specifications 16.6.3 Braking unit and braking resistor wiring diagram by capacity 200 V class 0.4-22 kW / 400 V class 0.4-37 kW When using the built-in braking unit Connect the braking resistor to B (1) and B (2) terminals when using the built-in braking unit.
Page 786 Technical Specifications 200 V class 30-45 kW / 400 V class 45-75kW Connect the braking unit to P (+) and N (-) terminals when using the separate braking unit. R (L1) S (L2) T (L3) P (+) N (-) Brake unit N B1 B2 Motor 3-phase AC...
Page 787: Right Side
Technical Specifications Table 24. Braking Resistor Terminal Braking Resistor Terminal Terminal Description Wire correctly referring to the wiring diagram. Wire braking B1, B2 (DB) resistor to B1 and B2 terminals in the braking unit. Do not use it. 16.6.4 Exterior Diagram of Braking Unit It shows the exterior diagram of the braking unit and product size.
Page 788 Technical Specifications Group 2 WIRING RESISTOR INVERTER UNIT (P2) MOTOR DYNAMIC BRAKING UNIT MAX 5m POWER Right Side Front Rear [ Image 22. Exterior Diagram of Braking Unit - Group 2 ]...
Page 789 Technical Specifications Group 3 Right Side Front Rear [ Image 23. Exterior Diagram of Braking Unit - Group 3 ]...
Page 790 Technical Specifications Group 4 Right Side Front Rear [ Image 24. Exterior Diagram of Braking Unit - Group 4 ]...
Page 791 Technical Specifications Group 5 Right Side Front Rear [ Image 25. Exterior Diagram of Braking Unit - Group 5: A Frame ]...
Page 792 Technical Specifications Right Side Front Rear [ Image 26. Exterior Diagram of Braking Unit - Group 5: B Frame ]...
Page 793 Technical Specifications Right Side Front Rear [ Image 27. Exterior Diagram of Braking Unit - Group 5: C Frame ]...
Page 794 Technical Specifications Table 25. Exterior Dimensions of Braking Unit (Group 5) Installation Hole Size Duty Voltage Product Size (mm) Location Weight Capacity Cycle Frame Used (mm) Installation (kW) (%ED) (Kg) ( f ) 3.77 219 190 160 208.5 Frame 165.2 3.84 3.98 8.48 340 311...
Page 795 Technical Specifications Braking resistance 100% Torque 150% Torque Model Reference Braking LSLV□□□□ Unit Capacity (kW) Resistance Capacity (kW) Resistance (Ω) (Ω) ED 5% ED 10% ED 5% ED 10% 0185S300-2 0220S300-2 LSLV0220DBU-2LN 0300S300-2 LSLV0370DBU-2HN 0370S300-2 LSLV0370DBU-2HN 0450S300-2 LSLV0750DBU-2HN 0550S300-2 LSLV0750DBU-2HN 0750S300-2 LSLV0750DBU-2HN 12.8 19.2...
Page 796 Technical Specifications Braking resistance 100% Torque 150% Torque Model Reference Braking LSLV□□□□ Unit Capacity (kW) Resistance Capacity (kW) Resistance (Ω) (Ω) ED 5% ED 10% ED 5% ED 10% 1320S300-4 LSLV1320DBU-4HN 1600S300-4 LSLV1600DBU-4HN 1850S300-4 LSLV2200DBU-4HN 2200S300-4 LSLV2200DBU-4HN Note • Products that are less than 18.5 kW-200 V or 37 kW-400 V have a built-in braking unit by default and do not require separate installation.
Page 797: Continuous Rated Current Derating
Technical Specifications 16.7 Derating 16.7.1 Continuous Rated Current Derating The continuous rated current of the inverter is limited based on the carrier frequency. Refer to the following table: Table 27. Inverter Rated Current Based on the Carrier Frequency (200 V Class) Rated Current (A) Capacity Heavy Duty, Low Leakage PWM...
Page 798 Technical Specifications Rated Current (A) Capacity Heavy Duty, Normal PWM (kW) 1kHz 3kHz 5kHz 8kHz 10kHz 0.75 10.4 17.5 17.5 17.5 16.5 15.8 23.7 22.8 31.3 30.1 43.6 57.4 55.6 18.5 71.7 69.5 72.4 100.4 78.6 126.5 98.8 157.3 123.3 1kHz 4kHz 5kHz 6kHz...
Page 799 Technical Specifications Rated Current (A) Capacity Normal Duty, Low Leakage PWM (kW) 1kHz 3kHz 5kHz 8kHz 10kHz 12kHz 15kHz 0.75 11.7 11.3 11.1 10.8 10.4 15.7 15.2 14.9 14.6 14.1 21.6 20.9 20.5 20.1 19.4 29.3 28.2 27.5 26.8 25.7 39.5 38.5 37.5 54.4...
Page 800 Technical Specifications Rated Current (A) Capacity Normal Duty, Normal PWM (kW) 1kHz 2kHz 5kHz 8kHz 10kHz 0.75 11.6 11.1 10.8 15.3 14.6 14.2 21.1 20.1 19.5 28.7 27.3 26.4 40.1 38.3 52.7 49.5 47.3 65.8 61.7 58.9 18.5 77.1 72.3 93.5 109.1 80.1 134.3...
Page 801 Technical Specifications Table 28. Inverter Rated Current Based on Carrier Frequency (400 V-460 V Class) Rated Current (A) Capacity Heavy Duty, Low Leakage PWM (kW) 1kHz 3kHz 5kHz 8kHz 10kHz 12kHz 15kHz 0.75 14.8 14.8 14.8 14.8 13.7 12.6 16.5 16.5 16.5 16.5 15.3...
Page 802 Technical Specifications Rated Current (A) Capacity Heavy Duty, Normal PWM (kW) 1kHz 3kHz 5kHz 8kHz 10kHz 0.75 14.8 14.8 14.8 13.5 12.6 16.5 16.5 16.5 21.2 19.4 27.4 18.5 35.7 33.5 41.2 38.6 45.4 61.5 41.2 76.4 54.6 89.8 59.6 2kHz 3kHz 4kHz 5kHz...
Page 803 Technical Specifications Rated Current (A) Capacity Normal Duty, Low Leakage PWM (kW) 1kHz 3kHz 5kHz 8kHz 10kHz 12kHz 15kHz 0.75 12.1 12.1 11.3 10.2 17.5 17.5 16.8 15.6 14.9 14.2 13.1 21.5 20.4 19.4 17.9 29.1 26.3 24.5 22.6 19.8 35.7 32.3 27.7 24.3...
Page 804 Technical Specifications Rated Current (A) Capacity Normal Duty, Normal PWM (kW) 2kHz 4kHz 6kHz 8kHz 10kHz 0.75 12.1 11.1 10.1 17.5 16.4 15.3 14.2 13.1 22.5 19.4 17.9 28.7 26.3 21.6 35.1 32.3 29.4 26.5 18.5 35.9 32.9 56.9 52.8 48.7 44.6 65.3 55.5...
Page 805 Technical Specifications Table 29. Inverter Rated Current Based on the Carrier Frequency (Over 460 V Class) Rated Current (A) Capacity Heavy Duty, Low Leakage PWM (kW) 1kHz 3kHz 5kHz 8kHz 10kHz 12kHz 15kHz 0.75 10.2 10.4 19.2 17.3 14.6 24.6 22.3 18.7 18.5 31.8...
Page 806 Technical Specifications Rated Current (A) Capacity Heavy Duty, Normal PWM (kW) 1kHz 3kHz 5kHz 8kHz 10kHz 0.75 12.7 11.9 18.6 16.9 23.9 21.8 18.5 31.1 29.2 36.6 34.3 38.7 29.8 53.3 35.7 64.7 46.2 78.4 101.2 66.9 2kHz 3kHz 4kHz 5kHz 6kHz 149.5 136.6...
Page 807 Technical Specifications Rated Current (A) Capacity Normal Duty, Low Leakage PWM (kW) 1kHz 3kHz 5kHz 8kHz 10kHz 12kHz 15kHz 0.75 10.3 13.4 12.5 11.9 11.3 10.4 20.1 18.8 17.9 15.7 25.4 22.9 21.3 19.7 17.3 28.9 26.8 24.8 21.7 18.5 37.7 34.1 31.8 29.4...
Page 808 Technical Specifications Rated Current (A) Capacity Normal Duty Normal PWM (kW) 2kHz 4kHz 6kHz 8kHz 10kHz 0.75 10.1 13.1 12.2 11.3 10.4 19.7 18.3 15.7 22.9 20.9 18.8 31.4 28.9 26.3 23.7 18.5 37.3 34.6 31.9 29.2 48.5 41.5 56.6 48.1 39.7 31.2 64.2...
Page 809 Technical Specifications 16.7.1.1 The Continuous Rated Current Derating Based on Input Voltage The continuous rated current of the inverter is limited based on the input voltage. Refer to the following graph. Continuous Rated Current 100% DC link voltage 339.4 (AC Input Voltage) Current rating based on (240) inverter specifications...
Page 810 Technical Specifications 16.7.1.2 The Continuous Rated Current Derating Based on Operating Frequency The following table shows the maximum value of the carrier frequency that guarantees 100% of the rated current. The continuous rated current of the inverter is limited based on the operating frequency if it is operated with the carrier frequency that exceeds this value.
Page 811: Carrier Frequency Derating
Technical Specifications 16.7.2 Carrier Frequency Derating 16.7.2.1 Carrier Frequency Derating Based on the Power Unit Temperature The carrier frequency may change according to the power unit temperature. This is to prevent burning the inverter from the temperature increase in the power unit. It reduces the switching loss and suppresses temperature increase.
Page 812 Technical Specifications 16.7.2.2 Carrier Frequency Derating Based on Operating Frequency The carrier frequency may change according to the operating frequency. When the operating frequency is under 5 Hz, the carrier frequency will be changed to 2 kHz (derating carrier frequency), and when the operating frequency is 5 Hz or higher, the carrier frequency will be changed to the setting value at DRV-27 (Carrier Frequency).
Page 813 Technical Specifications 16.7.2.3 Carrier Frequency Derating Based on the Inverter Load The carrier frequency may change according to the inverter load. When the inverter load is too high and causes a overload warning, the carrier frequency will be changed to 2 kHz (derating carrier frequency), and when the overload warning is lifted, the carrier frequency will be changed to the setting value at DRV-27 (Carrier Frequency).
Page 814 Technical Specifications 16.8 Parameter Default Values Based on the Motor Capacity 16.8.1 200 V Class Motor Table 31. Parameter Default Values Based on the Motor Capacity (200 V class) Motor Rated No-Load Rated Acceleration Deceleration Torque Eﬃciency Lsigma Output Current Current Speed Time Time...
Page 815 Technical Specifications 16.8.2 400V Class Motor Table 32. Parameter Default Values Based on the Motor Capacity (400 V class) Motor Rated No-Load Rated Acceleration Deceleration Torque Eﬃciency Lsigma Output Current Current Speed Time Time Boost (mΩ) (uH) (uH) (ms) (kW) (rpm) (sec) (sec) 1700 28000.0 121200 1045000 93...
Page 816: Product Warranty
Product Warranty Product Warranty Warranty Period The warranty period for the purchased product is 24 months from the date of manufacture. Warranty Coverage 1. The initial fault diagnosis should be conducted by the customer as a general principle. However, upon request, we or our service network can carry out this task for a fee. If the fault is found to be our responsibility, the service will be free of charge.
Page 817 EC DECLARATION OF CONFORMITY We, the undersigned, Representative: LS ELECTRIC Co., Ltd. Address: LS Tower, 127, LS-ro, Dongan-gu, Anyang-si, Gyeonggi-do, Korea Manufacturer: LS ELECTRIC Co., Ltd. Address: 56, Samseong 4-gil, Mokcheon-eup, Dongnam-gu, Cheonan-si, Chungcheongnam-do, Korea Certify and declare under our sole responsibility that the following apparatus:...
Page 818 UL mark The UL mark applies to products in the United States and Canada. This mark indicates that UL has tested and evaluated the products and determined that the products satisfy the UL standards for product safety. If a product received UL certification, this means that all components inside the product had been certified for UL standards as well.
Page 819: Manual Revision History
Manual Revision History Revision History Date Version Changes 2023/7/7 First Issue 2024/1/26 Contents Improved 2024/5/8 Macro Setting/Winder Operation added...
Page 820 Tel: 1-949-333-3140 • LS ELECTRIC Türkiye Co., Ltd. • LS ELECTRIC Italy Office (Italy) E-Mail: Türkiye @ls-electric.com E-Mail: italia @ls-electric.com Tel: 90-212-806-1225 Tel: 39-030-8081-833 ⓒ 2024. 07 LS ELECTRIC Co.,Ltd. All rights reserved. / (01) 2024. 07 Human Power 2024. 07...