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LSIS LSLV-S100 Manual

LSIS LSLV-S100 Manual

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This operation manual is intended for users with basic knowledge of electricity and electric

devices.

* LSLV-S100 is the official name for S100.

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Page 1 This operation manual is intended for users with basic knowledge of electricity and electric devices. * LSLV-S100 is the official name for S100.
Page 2 Safety Information Safety Information Read and follow all safety instructions in this manual precisely to avoid unsafe operating conditions, property damage, personal injury, or death. Safety symbols in this manual Indicates an imminently hazardous situation which, if not avoided, will result in severe injury or death.
Page 3 Safety Information • This equipment must be grounded for safe and proper operation. • Do not supply power to a faulty inverter. If you find that the inverter is faulty, disconnect the power supply and have the inverter professionally repaired. •...
Page 4 Maximum allowed prospective short-circuit current at the input power connection is defined in IEC 60439-1 as 100 kA. Depending on the selected MCCB, the LSLV-S100 Series is suitable for use in circuits capable of delivering a maximum of 100 kA RMS symmetrical amperes at the drive's maximum rated voltage.
Page 5 Safety Information Quick Reference Table The following table contains situations frequently encountered by users while working with inverters. Refer to the typical and practical situations in the table to quickly and easily locate answers to your questions. Situation Reference I want to run a slightly higher rated motor than the inverter’s rated capacity. p.
Page 6: Table Of Contents
Table of Contents Table of Contents Preparing the Installation .................. 1 Product Identification ................. 1 Part Names ....................3 0.4-22kW Models ................3 30-75kW Models ................5 IP66 Models .................. 6 Installation Considerations ................ 8 Selecting and Preparing a Site for Installation ......... 9 Cable Selection ..................
Page 7 Table of Contens Initializing All Parameters ............84 Frequency Setting (Keypad) and Operation (via Terminal Input) ..............86 Frequency Setting (Potentiometer) and Operation (Terminal Input) ................87 Frequency Setting (Potentiometer) and Operation (Keypad) .. 88 Monitoring the Operation ................ 90 0.4-22kW Models ................
Page 8 Table of Contents Acc/Dec Time Based on Maximum Frequency ...... 125 Acc/Dec Time Based on Operation Frequency ...... 126 Multi-step Acc/Dec Time Configuration ........127 Configuring Acc/Dec Time Switch Frequency......129 4.11 Acc/Dec Pattern Configuration ............. 130 4.12 Stopping the Acc/Dec Operation ............132 4.13 V/F(Voltage/Frequency) Control ............
Page 9 Table of Contens 4.23 User Sequence Setting ................. 149 4.24 Fire Mode Operation ................157 Learning Advanced Features ............... 159 Operating with Auxiliary References ............ 161 Jog operation ..................165 Jog Operation 1-Forward Jog by Multi-function Terminal ..165 Jog Operation 2-Fwd/Rev Jog by Multi-function Terminal ..167 Jog Operation by Keypad............
Page 10 Table of Contents Manual Energy Saving Operation ........... 210 Automatic Energy Saving Operation ........211 5.15 Speed Search Operation ..............211 5.16 Auto Restart Settings ................215 5.17 Operational Noise Settings (carrier frequency settings) ..... 216 5.18 2 Motor Operation ................218 5.19 Supply Power Transition ...............
Page 11 Table of Contens Motor Protection ..................250 Electronic Thermal Motor Overheating Prevention (ETH) ..250 Overload Early Warning and Trip ..........251 Stall Prevention and Flux Braking..........253 Inverter and Sequence Protection............257 Open-phase Protection ............257 External Trip Signal ..............258 Inverter Overload Protection ............
Page 12 Table of Contents LS INV 485 Protocol ..............280 Modbus-RTU Protocol .............. 286 Compatible Common Area Parameter ..........289 S100 Expansion Common Area Parameter ........292 Monitoring Area Parameter (Read Only) ......... 292 Control Area Parameter (Read/ Write) ........297 Inverter Memory Control Area Parameter (Read and Write) .
Page 13 Table of Contens Annual Inspections ..............392 Bi-annual Inspections ............... 394 10.2 Replacing Major Components .............. 395 Exchange Cycle for Major Components ......... 395 10.3 Storage and Disposal ................395 Storage ..................395 Disposal ..................396 11 Technical Specification ................. 397 11.1 Input and Output Specification .............
Page 14 Table of Contents 11.9 Heat Emmission ..................434 12 Applying Drives to Single-Phase Input Application ......... 435 12.1 Introduction .................... 435 12.2 Power(HP), Input Current and Output Current ........436 12.3 Input Frequency and Voltage Tolerance ..........437 Product Warranty ....................438 Index ........................
Page 15: 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. 1.1 Product Identification The S100 Inverter is manufactured in a range of product groups based on drive capacity and power source specifications.
Page 16 Preparing the Installation...
Page 17: Part Names
Preparing the Installation 1.2 Part Names The illustration below displays part names. Details may vary between product groups. 0.4-22kW Models 0.4-2.2kW (Single Phase) and 0.4-4.0kW (3–Phase)
Page 18 Preparing the Installation 5.5–22kW(3–Phase)
Page 19: 30-75Kw Models
Preparing the Installation 30-75kW Models Note The grounding terminal cover of EMC is not existed in the 55-75kW inverters.
Page 20: Ip66 Models
Preparing the Installation IP66 Models Do not operate Disconnect Switch when motor is operating. The installation location for cooling fan varies according to product capacity. Inside the product: 0.4-4.0kW; bottom of the product: 5.5-7.5kW; inside and top of the product: 11-22kW.
Page 21 Preparing the Installation Front cover removed...
Page 22: Installation Considerations
Preparing the Installation 1.3 Installation Considerations Inverters are composed of various precision, electronic devices, 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. Items Description Ambient Temperature* Heavy Duty: 14–104F (-10–50℃) Normal Duty: 14–122F (-10–...
Page 23: Selecting And Preparing A Site For Installation
Preparing the Installation 1.4 Selecting and Preparing a Site for Installation 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. •...
Page 24 Preparing the Installation • Ensure sufficient air circulation is provided around the inverter when it is installed. If the inverter is to be installed inside a panel, enclosure, or cabinet rack, carefully consider the position of the inverter’s cooling fan and the ventilation louver. The cooling fan must be positioned to efficiently transfer the heat generated by the operation of the inverter.
Page 25 Preparing the Installation • If you are installing multiple inverters in one location, arrange them side-by-side and remove the top covers. The top covers MUST be removed for side-by-side installations. Use a flat head screwdriver to remove the top covers. •...
Page 26 Preparing the Installation • If you are installing multiple inverters, of different ratings, provide sufficient clearance to meet the clearance specifications of the larger inverter.
Page 27: Cable Selection
Preparing the Installation 1.5 Cable Selection When you install power and signal cables in the terminal blocks, only use cables that meet the required specification for the safe and reliable operation of the product. Refer to the following information to assist you with cable selection. •...
Page 28 Preparing the Installation Ground Cable and Power Cable Specifications (30-75kW) Ground Power I/O Load (kW) R/S/T U/V/W R/S/T U/V/W 3–Phase 400V Signal (Control) Cable Specifications Signal Cable Without Crimp Terminal With Crimp Terminal Connectors Terminals Connectors (Bootlace Ferrule) (Bare wire) P1~P7*/CM/VR/V1/I2 /AO1,AO2/Q1/EG/24/TI/ 0.75...
Page 29: Installing The Inverter
Installing the Inverter 2 Installing the Inverter This chapter describes the physical and electrical installation methods, including mounting and wiring of 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 30 Installing the Inverter Basic Configuration Diagram The reference diagram below shows a typical system configuration showing the inverter and peripheral devices. Prior to installing the inverter, ensure that the product is suitable for the application (power rating, capacity, etc). Ensure that all of the required peripherals and optional devices (resistor brakes, contactors, noise filters, etc.) are available.
Page 31: Mounting The Inverter
Installing the Inverter 2.1 Mounting the Inverter 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 suitable to support the installation.
Page 32 Installing the Inverter Mount the inverter on the wall or inside a panel using the two upper bolts, and then fully tighten the mounting bolts. 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 33 Installing the Inverter Note The quantity and dimensions of the mounting brackets vary based on frame size. Refer to 11.3 External Dimensions on page 407 for detailed information about your model. 0.4kW (Single Phase) and 0.4-0.8kW (3-phase) inverters have only two mounting brackets.
Page 34 Installing the Inverter • Do not transport the inverter by lifting with the inverter’s covers or plastic surfaces. The inverter may tip over if covers break, causing injuries or damage to the product. Always support the inverter using the metal frames when moving it. •...
Page 35: Cable Wiring
Installing the Inverter 2.2 Cable Wiring Open the front cover, remove the cable guides 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. Read the following information carefully before carrying out wiring connections to the inverter.
Page 36 Installing the Inverter Step 1 Front Cover, Control Terminal Cover and Cable Guide The front cover, control terminal cover and cable guide must be removed to install cables. Refer to the following procedures to remove the covers and cable guide. The steps to remove these parts may vary depending on the inverter model.
Page 37 Installing the Inverter Remove the bolt that secures the front cover (left side) (❶). Push and hold the latch on the left side of the cover. Then remove the cover by lifting it from the bottom and moving it away from the front of the inverter (❷). Connect the cables to the power terminals and the control terminals.
Page 38 Installing the Inverter 5.5–22kW (3-phase) Loosen the bolt that secures the front cover. Then remove the cover by lifting it from the bottom and away from the front. Push and hold the levers on both sides of the cable guide (❶) and then remove the cable guide by pulling it directly away from the front of the inverter (❷).
Page 39 Installing the Inverter Push and hold the tab on the right side of the control terminal cover. Then remove the cover by lifting it from the bottom and moving it away from the front of the inverter. Connect the cables to the power terminals and the control terminals. For cable specifications, refer to 1.5 Cable Selection on page 13.
Page 40 Installing the Inverter 30-75kW(3-phase 4type) Loosen the bolt that secures the terminal cover (). Push and hold the latch on the right side of the cover (). Then remove the cover by lifting it from the bottom and moving it away from the front of the inverter. Connect the cables to the power terminals and the control terminals.
Page 41 Installing the Inverter IP66 0.4-15kW (3-phase 2type), 0.4-22kW (3-phase 4type) Loosen the bolt that secures the front cover. Then remove the cover by lifting it from the bottom and moving it away from the front of the inverter. Set the bushing to every wiring hole before installing to power and I/O board terminals. Use the bushing that is NEMA 4X (IP66) or more.
Page 42 Installing the Inverter Connect the cables to the power terminals and the control terminals. For cable specifications, refer to 1.5 Cable Selection on page 13. Note To connect an LCD loader, remove the plastic knock-out from the bottom of the front cover (right side).
Page 43 Installing the Inverter 0.4-22kW Locate the ground terminal and connect an appropriately rated ground cable to the terminals. Refer to 1.5 Cable Selection on page 13 to find the appropriate cable specification for your installation. Connect the other ends of the ground cables to the supply earth (ground) terminal.
Page 44 Installing the Inverter 30-75kW Locate the ground terminal and connect an appropriately rated ground cable to the terminals. Refer to 1.5 Cable Selection on page 13 to find the appropriate cable specification for your installation. Connect the other ends of the ground cables to the supply earth (ground) terminal.
Page 45 Installing the Inverter IP66 Locate the ground terminal and connect an appropriately rated ground cable to the terminals. Refer to 1.5 Cable Selection on page 13 to find the appropriate cable specification for your installation. Connect the other ends of the ground cables to the supply earth (ground) terminal.
Page 46 Installing the Inverter Step 3 Power Terminal Wiring The following illustration shows the terminal layout 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 cables selected meet or exceed the specifications in 1.5 Cable Selection on page 13 before installing them.
Page 47 Installing the Inverter 0.4-22kW 0.4kW (single phase), 0.4-0.8kW (3-phase) 0.8–1.5kW (single phase), 1.5–2.2kW (3-phase) 2.2kW (single phase), 3.7-4.0kW (3-phase)
Page 48 Installing the Inverter 5.5–22kW (3-phase) Power Terminal Labels and Descriptions (0.4-22kW) Terminal Labels Name Description R(L1)/S(L2)/T(L3) AC power input terminal Mains supply AC power connections. P1(+)/N(-) DC link terminal DC voltage terminals. DC reactor wiring connection. (When P1(+)/P2(+) DC reactor terminal you use the DC reactor, must remove short-bar) P2(+)/B...
Page 49 Installing the Inverter Power Terminal Labels and Descriptions (30-75kW) Terminal Labels Name Description R(L1)/S(L2)/T(L3) AC power input terminal Mains supply AC power connections. P2(+)/N(-) DC link terminal DC voltage terminals. P3(+)/N(-) Brake unit terminals Brake unit wiring connection. 3-phase induction motor wiring U/V/W Motor output terminals connections.
Page 50 Installing the Inverter 3.7-4.0kW (3-phase) 5.5–22kW (3-phase) Power Terminal Labels and Descriptions (IP66) Terminal Labels Name Description R(L1)/S(L2)/T(L3) AC power input terminal Mains supply AC power connections. P1(+)/N(-) DC link terminal DC voltage terminals. DC reactor wiring connection. (Remove P1(+)/P2(+) DC reactor terminal the short-bar when you use the DC reactor.)
Page 51 Installing the Inverter Note • Do not use 3 core cables to connect a remotely located motor with the inverter. • When you operating Brake resistor, the motor may vibrate under the Flux braking operation. In this case, please turn off the Flux braking(Pr.50). •...
Page 52 Installing the Inverter Step 4 Control Terminal Wiring The illustrations below show the detailed layout of control wiring terminals, and control board switches. Refer to the detailed information provided below and 1.5 Cable Selection on page 13 before installing control terminal wiring and ensure that the cables used meet the required specifications.
Page 53 Installing the Inverter 30-75kW <30-75kW I/O> Control Board Switches Switch Description NPN/PNP mode selection switch analog voltage/current input terminal selection switch analog voltage/current output terminal selection switch Terminating Resistor selection switch Connector (0.4-22kW models only) Name Description Connector Connect to iS7 Loader or Smart Copier...
Page 54 Installing the Inverter 0.4-22kW <Standard I/O> <Multiple I/O>...
Page 55 Installing the Inverter 30-75kW Input Terminal Labels and Descriptions Function Label Name Description Multi-function Configurable for multi-function input terminals. Multi- P1–P7 Input 1-7 (Standard I/O is only provided for P5.) function terminal Common Common terminal for analog terminal inputs and configuration Sequence outputs.
Page 56 Installing the Inverter Function Label Name Description frequency Switch between voltage (V2) and current (I2) reference input modes using a control board switch (SW2). V2 Mode: • Unipolar: 0–10V (12V Max.) I2 Mode • Input current: 4–20mA • Maximum Input current: 24mA •...
Page 57 Installing the Inverter Output/Communication Terminal Labels and Descriptions Function Label Name Description Used to send inverter output information to external devices: output frequency, output current, output voltage, or a DC voltage. Operate switch (SW3) to select the signal output type (voltage or current) at the AO terminal. Voltage/Current Output Signal Specifications: AO, AO1...
Page 58 Installing the Inverter Function Label Name Description Sends out alarm signals when the inverter’s safety features are activated (AC 250V <1A, DC 30V < 1A). Fault signal • Fault condition: A1 and C1 contacts are A1/C1/B1 output connected (B1 and C1 open connection) •...
Page 59 Installing the Inverter To connect cables to the control terminals without using crimp terminals, refer to the following illustration detailing the correct length of exposed conductor at the end of the control cable. Note • While making wiring connections at the control terminals, ensure that the total cable length does not exceed 165ft (50m).
Page 60 Installing the Inverter Step 5 PNP/NPN Mode Selection The S100 inverter supports both PNP (Source) and NPN (Sink) modes for sequence inputs at the terminal. Select an appropriate mode to suit requirements using the PNP/NPN selection switch (SW1) on the control board. Refer to the following information for detailed applications.
Page 61 Installing the Inverter NPN Mode (Sink) Select NPN using the PNP/NPN selection switch (SW1). Note that the factory default setting is NPN mode. CM is is the common ground terminal for all analog inputs at the terminal, and P24 is 24V internal source.
Page 62 Installing the Inverter Step 6 Disabling the EMC Filter for Power Sources with Asymmetrical Grounding S100 built-in EMC filter prevents electromagnetic interference by reducing radio emissions from the inverter. EMC filter is activated as a factory default design. If an inverter uses a power source with an asymmetrical grounding connection or non-grounding, the EMC filter MUST be turned off.
Page 63 Installing the Inverter Disabling the Built-in EMC Filter 0.4-22kW Before using the inverter, confirm the power supply’s grounding system. Disable the EMC filter if the power source has an asymmetrical grounding connection. Refer to the figures below to locate the EMC filter on/off terminal and replace the metal bolt with the plastic bolt. If the EMC filter is required in the future, reverse the steps and replace the plastic bolt with the metal bolt to reconnect the EMC filter.
Page 64 Installing the Inverter 30-75kW Follow the instructions listed below to disable the EMC filters. Remove the EMC ground cover located at the bottom of the inverter. Remove the EMC ground cable from the right terminal (EMC filter-ON / factory default), and connect it to the left terminal (EMC filter-OFF / for power sources with asymmetrical grounding).
Page 65 Installing the Inverter Note The terminal on the right is used to ENABLE the EMC filter (factory default). The terminal on the left is used to DISABLE the EMC filter (for power sources with asymmetrical grounding).
Page 66 Installing the Inverter Step 7 Selecting the brake unit (30-75kW models only) Select the brake unit as following: UL form Capacity of applied motor Braking unit 30-37kW SV037DBH-4 Non UL type 45-55kW (A type) SV075DBH-4, SV075DB-4 75kW LSLV0370DBU-4LN 30-37kW Non UL type LSLV0370DBU-4HN (B type) 45-75kW...
Page 67: Post-Installation Checklist
Installing the Inverter 2.3 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. Items Check Point Ref. Result Is the installation location appropriate? Does the environment meet the inverter’s operating conditions? Installation Does the power source match the inverter’s rated input?
Page 68 Installing the Inverter Items Check Point Ref. Result Are the control cables properly wired? Are the control terminal screws tightened to their p.21 specified torques? Is the total cable length of all control wiring < 165ft p.45 (100m)? Is the total length of safety wiring < 100ft (30m)? p.45 Are optional cards connected correctly? Is there any debris left inside the inverter?
Page 69: Test Run
Installing the Inverter 2.4 Test Run After the post-installation checklist has been completed, follow the instructions below to test the inverter. Turn on the power supply to the inverter. Ensure that the keypad display light is on. Select the command source. Set a frequency reference, and then check the following: •...
Page 70 Installing the Inverter Note If the forward command (Fx) is on, the motor should rotate counterclockwise when viewed from the load side of the motor. If the motor rotates in the reverse direction, switch the cables at the U and V terminals. Remarque Si la commande avant (Fx) est activée, le moteur doit tourner dans le sens anti-horaire si on le regarde côté...
Page 71: Learning To Perform Basic Operations
Learning to Perform Basic Operations 3 Learning to Perform Basic Operations This chapter describes the keypad layout and functions. It also introduces parameter groups and codes, required to perform basic operations. The chapter also outlines the correct operation of the inverter before advancing to more complex applications. Examples are provided to demonstrate how the inverter actually operates.
Page 72: 30-75Kw Models
Learning to Perform Basic Operations 30-75kW Models About the Display The following table lists display part names and their functions. 3.1.3.1 0.4-22kW Models Name Function Displays current operational status and parameter ❶ 7-Segment Display information. LED flashes during parameter configuration and when the ❷...
Page 73 Learning to Perform Basic Operations The table below lists the way that the keypad displays characters (letters and numbers). 3.1.3.2 30-75kW Models Monitor mode display...
Page 74 Learning to Perform Basic Operations Parameter settings display Names displayed in monitor mode and parameter settings No. Names displayed in monitor mode No. Names displayed in parameter settings 1 Mode Mode 2 Operating/frequency command Group 3 Multi-functional key settings Multi-functional key settings 4 Inverter operation status Inverter operation status 5 Items displayed in the status window...
Page 75 Learning to Perform Basic Operations Name Display Description Application option operation command Internal 485 operation command Terminal operation command Keypad frequency command V1 input frequency command Pulse input frequency command Frequency command for UP operation (Up - Down operation) Frequency command for DOWN operation (Up - Frequency Down operation) commands...
Page 76: Operation Keys
Learning to Perform Basic Operations Operation Keys 3.1.4.1 0.4-22kW Models Install a separate emergency stop switch in the circuit. The [STOP/RESET] key on the keypad works only when the inverter has been configured to accept an input from the keypad. The following table lists the names and functions of the keypad’s operation keys.
Page 77 Learning to Perform Basic Operations 3.1.4.2 30-75kW Models The following table lists the names and functions of the LCD’s operation keys. Name Description [MODE] Key Used to switch between modes. [PROG / Ent] Used to select, confirm, or save a parameter value. [UP] key Switch between codes or increase or decrease parameter [DOWN] key...
Page 78: Control Menu
Learning to Perform Basic Operations Control Menu 0.4-22kW Control Menu The following table lists the functions groups under Parameter mode. Keypad Function Group Description Display Display Name 0.00 DRV-01 Configures reference frequencies. DRV-03 Configures acceleration times. DRV-04 Configures deceleration times. DRV-06 Used to select operation command.
Page 79 Learning to Perform Basic Operations Keypad Function Group Description Display Display Name Configures communication features for RS- Communication 485 or other communication options. Application Configures functions related to PID control. Configures motor and inverter protection Protection features. Configures secondary motor related features. Motor 2 The secondary motor (M2) group appears on (Secondary...
Page 80 Learning to Perform Basic Operations The following table lists the 5 display modes used to control the inverter functions. Mode Name LCD Display Description Displays the inverter’s operation status information. In this mode, information including the inverter’s frequency Monitor mode reference, operation frequency, output current, and voltage may be monitored.
Page 81: Learning To Use The Keypad
Learning to Perform Basic Operations 3.2 Learning to Use the Keypad The keypad enables movement between groups and codes. It also enables users to select and configure functions. At code level, you can set parameter values to turn on or off specific functions, or decide how the functions will be used.
Page 82 Learning to Perform Basic Operations Mode selection in factory default condition • When the power is turned on, Monitor mode is displayed. • Press the [MODE] key. • Parameter mode • Press the [MODE] key. • Config (CNF) mode • Press the [MODE] key. •...
Page 83 Learning to Perform Basic Operations Switching between groups when Trip mode is added Trip mode is accessible only when the inverter has trip fault history. Refer to 4 Learning Basic Features on page 99 for information about monitoring faults. • When the power is turned on, Monitor mode is displayed.
Page 84: Group And Code Selection
Learning to Perform Basic Operations Group and Code Selection Follow the examples below to learn how to switch between groups and codes. 3.2.2.1 0.4-22kW Models Step Instruction Keypad Display Move to the group you want using the [◀] and [▶] keys. Move up and down through the codes using the [▲] and [▼] keys until...
Page 85 Learning to Perform Basic Operations Note For some settings, pressing the [▲] or [▼] key will not increase or decrease the code number by 1. Code numbers may be skipped and not be displayed. This is because certain code numbers have been intentionally left blank (or reserved) for new functions to be added in the future.
Page 86 Learning to Perform Basic Operations Switching between Groups in Parameter Display Mode After entering Parameter mode from Monitor mode, press the [▶] key to change the display as shown below. Press the [◀] key to return to the previous mode. •...
Page 87 Learning to Perform Basic Operations 3.2.2.3 30-75kW Models (Code Navigation) Code Navigation in Monitor mode In monitor mode, press the [▲], [▼] key to display frequency, the output current, or voltage according to the cursor position. • When the power is turned on, Monitor mode is displayed.
Page 88 Learning to Perform Basic Operations • Information about the first item in Monitor mode (Frequency) is displayed. • Information about the first item in Monitor mode (Frequency) disappears and the cursor appears to the left of the first item. Code Navigation in Parameter mode The following examples show you how to move through codes in different function groups (Drive group and Basic group) in Parameter mode.
Page 89: Navigating Directly To Different Codes
Learning to Perform Basic Operations Navigating Directly to Different Codes 3.2.3.1 0.4-22kW Models The following example details navigating to code dr. 95, from the initial code in the Drive group (dr. 0). This example applies to all groups whenever you would like to navigate to a specific code number.
Page 90 Learning to Perform Basic Operations 3.2.3.2 30-75kW Models Parameter mode and Config mode allow direct jumps to specific codes. The code used for this feature is called the Jump Code. The Jump Code is the first code of each mode. The Jump Code feature is convenient when navigating for a code in a function group that has many codes.
Page 91: Setting Parameter Values
Learning to Perform Basic Operations Setting Parameter Values 3.2.4.1 0.4-22kW Models Enable or disable features by setting or modifying parameter values for different codes. Directly enter setting values, such as frequency references, supply voltages, and motor speeds. Follow the instructions below to learn to set or modify parameter values. Step Instruction Keypad Display...
Page 92 Learning to Perform Basic Operations 3.2.4.2 30-75kW Models Parameter settings available in Monitor mode The S100 inverter allows basic parameters to be modified in Monitor mode. The following example shows how to set the frequency. • Make sure that the cursor is at the frequency reference item and that the frequency setting is set to ‘Keypad’...
Page 93 Learning to Perform Basic Operations Parameter settings in other modes and groups The following example shows how to change the frequency in the Drive group. This example can also be applied to other modes and groups. • This is the initial display for Parameter mode. •...
Page 94: Configuring The [Esc] Key (0.4-22Kw Models Only)
Learning to Perform Basic Operations Configuring the [ESC] Key (0.4-22kW models only) The [ESC] key is a multi-functional key that can be configured to carry out a number of different functions. Refer to 4.6 Local/Remote Mode Switching on page 120 for more information about the other functions of the [ESC] key.
Page 95: Actual Application Examples
Learning to Perform Basic Operations 3.3 Actual Application Examples Acceleration Time Configuration (0.4-22kW models only) The following is an example demonstrating how to modify the ACC (Acceleration time) code value (from 5.0 to 16.0) from the Operation group. Step Instruction Keypad Display Ensure that the first code of the Operation group is selected, 0.00...
Page 96: Frequency Reference Configuration (0.4-22Kw Models Only)
Learning to Perform Basic Operations Frequency Reference Configuration (0.4-22kW models only) The following is an example to demonstrate configuring a frequency reference of 30.05 (Hz) from the first code in the Operation group (0.00). Step Instruction Keypad Display Ensure that the first code of the Operation group is selected, 0.00 and the code 0.00 (Command Frequency) is displayed.
Page 97: Jog Frequency Configuration (0.4-22Kw Models Only)
Learning to Perform Basic Operations Jog Frequency Configuration (0.4-22kW models only) The following example demonstrates how to configure Jog Frequency by modifying code 11 in the Drive group (Jog Frequency) from 10.00(Hz) to 20.00(Hz). You can configure the parameters for different codes in any other group in exactly the same way. Step Instruction Keypad Display...
Page 98: Initializing All Parameters
Learning to Perform Basic Operations Initializing All Parameters 3.3.4.1 0.4-22kW Models The following example demonstrates parameter initialization using code dr.93 (Parameter Initialization) in the Drive group. Once executed, parameter initialization will delete all modified values for all codes and groups. Step Instruction Keypad Display...
Page 99 Learning to Perform Basic Operations 3.3.4.2 30-75kW Models The following example demonstrates how to revert all the parameter settings back to the factory default (Parameter Initialization). Parameter initialization may be performed for separate groups in Parameter mode as well. • Monitor mode is displayed. •...
Page 100: Frequency Setting (Keypad) And Operation (Via Terminal Input)
Learning to Perform Basic Operations Frequency Setting (Keypad) and Operation (via Terminal Input) Step Instruction Keypad Display Turn on the inverter. Ensure that the first code of the Operation group is selected, and code 0.00 (Command Frequency) is displayed, then 0.0) press the [ENT] key.
Page 101: Frequency Setting (Potentiometer) And Operation (Terminal Input)
Learning to Perform Basic Operations Note The instructions in the table are based on the factory default parameter settings. The inverter may not work correctly if the default parameter settings are changed after the inverter is purchased. In such cases, initialize all parameters to reset the values to factory default parameter settings before following the instructions in the table (refer to 5.23 Parameter Initialization on page 223).
Page 102: Frequency Setting (Potentiometer) And Operation (Keypad)
Learning to Perform Basic Operations [Wiring Diagram] [Operation Pattern] Note The instructions in the table are based on the factory default parameter settings. The inverter may not work correctly if the default parameter settings are changed after the inverter is purchased.
Page 103 Learning to Perform Basic Operations Step Instruction Keypad Display Press the [▲] key to change it to 2 (Potentiometer), and then press the [ENT] key. The new parameter value will flash. Press the [ENT] key once again. The Frq code is displayed again. The frequency input has been configured for potentiometer.
Page 104: Monitoring The Operation
Learning to Perform Basic Operations 3.4 Monitoring the Operation 0.4-22kW Models 3.4.1.1 Output Current Monitoring The following example demonstrates how to monitor the output current in the Operation group using the keypad. Step Instruction Keypad Display Ensure that the first code of the Operation group is 0.00 selected, and the code 0.00 (Command Frequency) is displayed.
Page 105 Learning to Perform Basic Operations 3.4.1.2 Fault Trip Monitoring The following example demonstrates how to monitor fault trip conditions in the Operation group using the keypad. Step Instruction Keypad Display Refer to the example keypad display. An over current trip fault has occurred. Press the [ENT] key, and then the [▲] key.
Page 106 Learning to Perform Basic Operations Note • If multiple fault trips occur at the same time, a maximum of 3 fault trip records can be retrieved as shown in the following example. • If a warning condition occurs while running at a specified frequency, the current frequency warn and the signal will be displayed alternately, at 1 second intervals.
Page 107: 30-75Kw Models
Learning to Perform Basic Operations 30-75kW Models How to use Monitor mode There are 3 types of items that may be monitored in Monitor mode. Some items, including frequency, may be modified. Users can select the items to be displayed in Config mode (CNF).
Page 108 Learning to Perform Basic Operations Items available for monitoring Mode Number Display Setting Range Initial value Anytime Para 0 Frequency 0: Frequency Monitor Line-1 1 Speed 0: Frequency Monitor Line-2 2 Output Current 2:Output Current 3 Output Voltage 4 Output Power 5 WHour Counter 6 DCLink Voltage 7 DI State...
Page 109 Learning to Perform Basic Operations How to use the status bar On the top-right corner of the display, there is a display item. This item is displayed as long as the inverter is on, regardless of the mode the inverter is operating in. •...
Page 110 Learning to Perform Basic Operations Monitoring Faults during Inverter Operation The following example shows how to monitor faults that occurred during inverter operation. • If a fault trip occurs during inverter operation, the inverter enters Trip mode automatically and displays the type of fault trip that occurred.
Page 111 Learning to Perform Basic Operations Monitoring Multiple Fault Trips The following example shows how to monitor multiple faults that occur at the same time. • If multiple fault trips occur at the same time, the number of fault trips occurred is displayed on the right side of the fault trip type.
Page 112 Learning to Perform Basic Operations • The most recent fault trip is saved in Last-1 code. • Press the [▶] key. • The fault trip changes position and is saved in Last-2 code. • When a fault trip occurs again, the content in Last-2 is moved to Last-3.
Page 113: Learning Basic Features
Learning Basic Features 4 Learning Basic Features This chapter describes the basic features of the S100 inverter. Parameter groups and codes are described based on 0.4-22kW models. For 30-75kW models, refer to 3.1.5 Control Menuon page 64 Check the reference page in the table to see the detailed description for each of the advanced features.
Page 114 Learning Basic Features Basic Tasks Description Ref. without losing or altering saved parameter settings. It can also be used to override remotes and use the keypad immediately in emergencies. Configures the inverter to limit a motor’s rotation direction. p.122 Motor rotation control Configures the inverter to start operating at power-on.
Page 115 Learning Basic Features Basic Tasks Description Ref. momentary torque boost. This configuration is for loads that require a large amount of starting torque, such as elevators or lifts. Automatic configuration of the inverter that provides “auto tuning” that produces a momentary torque boost. This Automatic torque boost p.136 configuration is for loads that require a large amount of...
Page 116: Setting Frequency Reference
Learning Basic Features Basic Tasks Description Ref. Enables the user to monitor multiple inverters with one Multi-keypad configuration p.148 monitoring device. User sequence Enables the user to implement simple sequences using p.149 configuration various function blocks. 4.1 Setting Frequency Reference The S100 inverter provides several methods to setup and modify a frequency reference for an operation.
Page 117: Keypad As The Source (Keypad-2 Setting)
Learning Basic Features Keypad as the Source (KeyPad-2 setting) You can use the [▲] and [▼] keys to modify a frequency reference. To use this as a second option, set the keypad as the source of the frequency reference, by going to the Frq (Frequency reference source) code in the Operation group and change the parameter value to 1 (Keypad-2).
Page 118 Learning Basic Features Parameter Group Code Name LCD Display Setting Range Unit Setting Frequency reference Operation Frq Freq Ref Src 2 V1 0–12 source Frequency at Maximum 0.00–Max. Freq at 100% maximum analog input frequency Frequency V1 input monitor V1 Monitor [V] 0.00 0.00–12.00 V1 polarity options...
Page 119 Learning Basic Features Code Description [V1 Filter ] These parameters are used to configure the gradient level and offset values of the Output Frequency, based on the Input Voltage. In.08 V1 Volt x1– In.11 V1 Perc y2 [Volt x1–In.11 V1 Perc y2] Inverts the direction of rotation.
Page 120 Learning Basic Features Code Description Parameter values for quantizing refer to a percentage based on the maximum input. Therefore, if the value is set to 1% of the analog maximum input (60Hz), the output frequency will increase or decrease by 0.6Hz per 0.1V difference.
Page 121 Learning Basic Features 4.1.3.2 Setting a Frequency Reference for -10–10V Input Set the Frq (Frequency reference source) code in the Operation group to 2 (V1), and then set code 06 (V1 Polarity) to 1 (bipolar) in the Input Terminal group (IN). Use the output voltage from an external source to provide input to V1.
Page 122 Learning Basic Features Parameter Group Code Name LCD Display Setting Range Unit Setting V1maximum input -12.00 –0.00V V1- Volt x2 -10.00 voltage V1 output at maximum V1- Perc y2 -100.00 -100.00–0.00% voltage (%) Rotational Directions for Different Voltage Inputs Input voltage Command / Voltage Input 0–10V...
Page 123 Learning Basic Features 4.1.3.3 Setting a Reference Frequency using Input Current (I2) You can set and modify a frequency reference using input current at the I2 terminal after selecting current input at SW 2. Set the Frq (Frequency reference source) code in the Operation group to 5 (I2) and apply 4–20mA input current to I2.
Page 124: (Terminal I2)
Learning Basic Features Code Description Configures the gradient level and off-set value of the output frequency. In.53 I2 Curr x1– In.56 I2 Perc y2 [Gradient and off-set configuration based on output frequency] Setting a Frequency Reference with Input Voltage (Terminal I2) Set and modify a frequency reference using input voltage at I2 (V2) terminal by setting SW2 to V2.
Page 125: Setting A Frequency With Ti Pulse Input
Learning Basic Features Parameter Setting Group Code Name LCD Display Unit Setting Range voltage Invert V2 rotational V2 Inverting 0–1 direction 0.00*, 0.04– V2 quantizing level V2 Quantizing 0.04 10.00 * Quantizing is disabled if ‘0’ is selected. Setting a Frequency with TI Pulse Input Set a frequency reference by setting the Frq (Frequency reference source) code in Operation group to 12 (Pulse).
Page 126 Learning Basic Features TI Pulse Input Setting Details Code Description In case of Standard I/O (excluding 30-75kW models), Pulse input TI and In.69 P5 Define Multi-function terminal P5 share the same therminal. Set the In.69 P5 Define to 54(TI). Configures the frequency reference at the maximum pulse input. The frequency reference is based on 100% of the value set with In.96.
Page 127: Setting A Frequency Reference Via Rs-485 Communication
Learning Basic Features Setting a Frequency Reference via RS-485 Communication Control the inverter with upper-level controllers, such as PCs or PLCs, via RS-485 communication. Set the Frq (Frequency reference source) code in the Operation group to 6 (Int 485) and use the RS-485 signal input terminals (S+/S-/SG) for communication. Refer to 7 RS-485 Communication Features on page 273.
Page 128: Frequency Hold By Analog Input
Learning Basic Features 4.2 Frequency Hold by Analog Input If you set a frequency reference via analog input at the control terminal block, you can hold the operation frequency of the inverter by assigning a multi-function input as the analog frequency hold terminal.
Page 129: Changing The Displayed Units (Hz↔Rpm)
Learning Basic Features 4.3 Changing the Displayed Units (Hz↔Rpm) You can change the units used to display the operational speed of the inverter by setting Dr. 21 (Speed unit selection) to 0 (Hz) or 1 (Rpm). This function is available only with the LCD keypad.
Page 130 Learning Basic Features Code Description Choose the terminals to setup as multi-step inputs, and then set the relevant codes (In.65–71) to 7(Speed-L), 8(Speed-M), or 9(Speed-H). Provided that terminals P3, P4 and P5 have been set to Speed-L, Speed-M and Speed-H respectively, the following multi-step operation will be available.
Page 131: Command Source Configuration
Learning Basic Features 4.5 Command Source Configuration Various devices can be selected as command input devices for theS100 inverter. Input devices available to select include keypad, multi-function input terminal, RS-485 communication and field bus adapter. If UserSeqLink is selected, the common area can be linked with user sequence output and can be used as command.
Page 132: Terminal Block As A Command Input Device (Fwd/Rev Run Commands)
Learning Basic Features Terminal Block as a Command Input Device (Fwd/Rev Run Commands) Multi-function terminals can be selected as a command input device. This is configured by setting the drv (command source) code in the Operation group to 1(Fx/Rx). Select 2 terminals for the forward and reverse operations, and then set the relevant codes (2 of the 5 multi-function terminal codes, In.65–71 for P1–P7) to 1(Fx) and 2(Rx) respectively.
Page 133: Terminal Block As A Command Input Device
Learning Basic Features Terminal Block as a Command Input Device (Run and Rotation Direction Commands) Multi-function terminals can be selected as a command input device. This is configured by setting the drv (command source) code in the Operation group to 2(Fx/Rx-2). Select 2 terminals for run and rotation direction commands, and then select the relevant codes (2 of the 5 multi-function terminal codes, In.65–71 for P1–P7) to 1(Fx) and 2(Rx) respectively.
Page 134: Communication As A Command Input Device
Learning Basic Features RS-485 Communication as a Command Input Device Internal RS-485 communication can be selected as a command input device by setting the drv (command source) code in the Operation group to 3(Int 485). This configuration uses upper level controllers such as PCs or PLCs to control the inverter by transmitting and receiving signals via the S+, S-, and Sg terminals at the terminal block.
Page 135 Learning Basic Features Local/Remote Mode Switching Setting Details Code Description Set dr.90 to 2(Local/Remote) to perform local/remote switching using the [ESC] key. Once the value is set, the inverter will automatically begin operating in remote mode. Changing from local to remote will not alter any previously configured parameter values and the operation of the inverter dr.90 will not change.
Page 136: Forward Or Reverse Run Prevention
Learning Basic Features • Analog commands via terminal input: the inverter will continue to run without interruption based on the command at the terminal block. If a reverse operation (Rx) signal is ON at the terminal block at startup, the inverter will operate in the reverse direction even if it was running in the forward direction in local operation mode before the reset.
Page 137: Power-On Run
Learning Basic Features 4.8 Power-on Run A power-on command can be setup to start an inverter operation after powering up, based on terminal block operation commands (if they have been configured). To enable power-on run set the drv (command source) code to 1(Fx/Rx-1) or 2 (Fx/Rx-2) in the Operation group. Group Code Name...
Page 138: Reset And Restart
Learning Basic Features 4.9 Reset and Restart Reset and restart operations can be setup for inverter operation following a fault trip, based on the terminal block operation command (if it is configured). When a fault trip occurs, the inverter cuts off the output and the motor will free-run. Another fault trip may be triggered if the inverter begins its operation while motor load is in a free-run state.
Page 139: Setting Acceleration And Deceleration Times
Learning Basic Features 4.10 Setting Acceleration and Deceleration Times Acc/Dec Time Based on Maximum Frequency Acc/Dec time values can be set based on maximum frequency, not on inverter operation frequency. To set Acc/Dec time values based on maximum frequency, set bA. 08 (Acc/Dec reference) in the Basic group to 0 (Max Freq).
Page 140: Acc/Dec Time Based On Operation Frequency
Learning Basic Features Code Description Use the time scale for all time-related values. It is particularly useful when a more accurate Acc/Dec times are required because of load characteristics, or when the maximum time range needs to be extended. bA.09 Configuration Description Time scale...
Page 141: Multi-Step Acc/Dec Time Configuration
Learning Basic Features Acc/Dec Time Based on Operation Frequency – Setting Details Code Description Set the parameter value to 1 (Delta Freq) to set Acc/Dec times based on Maximum frequency. Configuration Description Set the Acc/Dec time based on Maximum Max Freq frequency.
Page 142 Learning Basic Features Acc/Dec Time Setup via Multi-function Terminals – Setting Details Code Description bA. 70–82 Set multi-step acceleration time1–7. Acc Time 1–7 bA.71–83 Set multi-step deceleration time1–7. Dec Time 1–7 Choose and configure the terminals to use for multi-step Acc/Dec time inputs.
Page 143: Configuring Acc/Dec Time Switch Frequency
Learning Basic Features Configuring Acc/Dec Time Switch Frequency You can switch between two different sets of Acc/Dec times (Acc/Dec gradients) by configuring the switch frequency without configuring the multi-function terminals. Parameter Setting Group Code Name LCD Display Unit Setting Range ACC Acceleration time Acc Time 10.0...
Page 144: Acc/Dec Pattern Configuration
Learning Basic Features 4.11 Acc/Dec Pattern Configuration Acc/Dec gradient level patterns can be configured to enhance and smooth the inverter’s acceleration and deceleration curves. Linear pattern features a linear increase or decrease to the output frequency, at a fixed rate. For an S-curve pattern a smoother and more gradual increase or decrease of output frequency, ideal for lift-type loads or elevator doors, etc.
Page 145 Learning Basic Features [Acceleration / deceleration pattern configuration] [Acceleration / deceleration S-curve parrten configuration] Note The Actual Acc/Dec time during an S-curve application Actual acceleration time = user-configured acceleration time + user-configured acceleration time x starting gradient level/2 + user-configured acceleration time x ending gradient level/2. Actual deceleration time = user-configured deceleration time + user-configured deceleration time x starting gradient level/2 + user-configured deceleration time x ending gradient level/2.
Page 146: Stopping The Acc/Dec Operation
Learning Basic Features 4.12 Stopping the Acc/Dec Operation Configure the multi-function input terminals to stop acceleration or deceleration and operate the inverter at a fixed frequency. Setting Group Code Name LCD Display Parameter Setting Unit Range Px Define 65– Px terminal XCEL Stop 0–54 configuration...
Page 147: Square Reduction V/F Pattern Operation
Learning Basic Features Linear V/F Pattern Setting Details Code Description Sets the base frequency. A base frequency is the inverter’s output frequency dr.18 Base Freq when running at its rated voltage. Refer to the motor’s rating plate to set this parameter value.
Page 148: User V/F Pattern Operation
Learning Basic Features User V/F Pattern Operation The S100 inverter allows the configuration of user-defined V/F patterns to suit the load characteristics of special motors. Parameter Group Code Name LCD Display Setting Range Unit Setting V/F pattern V/F Pattern User V/F 0–3 0–Maximum User Frequency1...
Page 149: Torque Boost
Learning Basic Features The 100% output voltage in the figure below is based on the parameter settings of bA.15 (motor rated voltage). If bA.15 is set to 0 it will be based on the input voltage. • When a normal induction motor is in use, care must be taken not to configure the output pattern away from a linear V/F pattern.
Page 150: Auto Torque Boost-1
Learning Basic Features Manual Torque Boost Setting Details Code Description dr.16 Fwd Boost Set torque boost for forward operation. dr.17 Rev Boost Set torque boost for reverse operation. Excessive torque boost will result in over-excitation and motor overheating . Auto Torque Boost-1 Auto torque boost enables the inverter to automatically calculate the amount of output voltage required for torque boost based on the entered motor parameters.
Page 151: Auto Torque Boost-2
Learning Basic Features Auto Torque Boost-2 In V/F operation, this adjusts the output voltage if operation is unavailable due to a low output voltage. It is used when operation is unavailable, due to a lack of starting torque, by providing a voltage boost to the output voltage via the torque current. Parameter Group Code Name...
Page 152: Start Mode Setting
Learning Basic Features 4.16 Start Mode Setting Select the start mode to use when the operation command is input with the motor in the stopped condition. Acceleration Start Acceleration start is a general acceleration mode. If there are no extra settings applied, the motor accelerates directly to the frequency reference when the command is input.
Page 153: Stop Mode Setting
Learning Basic Features 4.17 Stop Mode Setting Select a stop mode to stop the inverter operation. Deceleration Stop Deceleration stop is a general stop mode. If there are no extra settings applied, the motor decelerates down to 0Hz and stops, as shown in the figure below. Group Code Name LCD Display Parameter Setting...
Page 154 Learning Basic Features DC Braking After Stop Setting Details Code Description Set the time to block the inverter output before DC braking. If the inertia of the load is great, or if DC braking frequency (Ad.17) is set too high, a Ad.14 DC-Block fault trip may occur due to overcurrent conditions when the inverter Time...
Page 155: Free Run Stop
Learning Basic Features Free Run Stop When the Operation command is off, the inverter output turns off, and the load stops due to residual inertia. Parameter Group Code Name LCD Display Setting Range Unit Setting Stop Method Stop Mode Free-Run 0–4 Note that when there is high inertia on the output side and the motor is operating at high speed, the load’s inertia will cause the motor to continue rotating even if the inverter output is blocked.
Page 156: Frequency Limit
Learning Basic Features • To prevent overheating or damaging the motor, do not apply power braking to the loads that require frequent deceleration. • Stall prevention and power braking only operate during deceleration, and power braking takes priority over stall prevention. In other words, when both Pr.50 (stall prevention and flux braking) and Ad.08 (power braking) are set, power braking will take precedence and operate.
Page 157: Frequency Limit Using Upper And Lower Limit Frequency Values
Learning Basic Features Frequency Limit Using Upper and Lower Limit Frequency Values Grou Parameter Code Name LCD Display Setting Range Unit Setting Frequency limit Freq Limit 0–1 Frequency lower limit 0.0–maximum Freq Limit Lo 0.50 value frequency minimum– Frequency upper Maximum Freq Limit Hi maximum...
Page 158: Frequency Jump
Learning Basic Features Frequency Jump Use frequency jump to avoid mechanical resonance frequencies. Jump through frequency bands when a motor accelerates and decelerates. Operation frequencies cannot be set within the pre-set frequency jump band. When a frequency setting is increased, while the frequency parameter setting value (voltage, current, RS-485 communication, keypad setting, etc.) is within a jump frequency band , the frequency will be maintained at the lower limit value of the frequency band.
Page 159: Operation Mode Setting
Learning Basic Features 4.19 2 Operation Mode Setting Apply two types of operation modes and switch between them as required. For both the first and second command source, set the frequency after shifting operation commands to the multi-function input terminal. Mode swiching can be used to stop remote control during an operation using the communication option and to switch operation mode to operate via the local panel, or to operate the inverter from another remote control location.
Page 160: Multi-Function Input Terminal Control
Learning Basic Features 4.20 Multi-function Input Terminal Control Filter time constants and the type of multi-function input terminals can be configured to improve the response of input terminals Parameter Group Code Name LCD Display Setting Range Unit Setting Multi-function input DI On Delay 0–10000 terminal On filter...
Page 161: P2P Setting
Learning Basic Features Code Description Display the configuration of each contact. When a segment is configured as A terminal using dr.87, the On condition is indicated by the top segment turning on. The Off condition is indicated when the bottom segment is turned on.
Page 162: Multi-Keypad Setting
Learning Basic Features Slave Parameter Group Code Name LCD Display Parameter Setting Setting Range Unit Communication Int 485 Func P2P Slave 0–3 selection P2P DO setting P2P OUT Sel 0–2 selection P2P Setting Details Code Description Set master inverter to 1(P2P Master), slave inverter to 2(P2P CM.95 Int 485 Func Slave).
Page 163: User Sequence Setting
Learning Basic Features Slave Parameter Group Code Name LCD Display Parameter Setting Setting Range Unit Station ID Int485 St ID 3–99 communication Int 485 Func KPD-Ready 0–3 options Multi-keypad Setting Details Code Description Prevents conflict by designating a unique identification value to an inverter.
Page 164 Learning Basic Features Parameter Setting Group Code Name LCD Display Unit Setting Range User sequence User Seq En 0–1 activation User sequence User Seq Con 0–2 operation command User sequence User Loop 0–5 operation time Time Link UserOut 11– Output address link1–18 0–0xFFFF 1–18 31–...
Page 165 Learning Basic Features Parameter Setting Group Code Name LCD Display Unit Setting Range -32767– User function output 4 User Output 4 32767 User function 5 User Func5 0–28 User function input 5-A User Input 5-A 0–0xFFFF User function input 5-B User Input 5-B 0–0xFFFF User function input 5-C...
Page 166 Learning Basic Features Parameter Setting Group Code Name LCD Display Unit Setting Range -32767– User function output 10 User Output 10 32767 User function 11 User Func11 0–28 User function input 11-A User Input 11-A 0–0xFFFF User function input 11-B User Input 11-B 0–0xFFFF User function input 11-C User Input 11-C 0–0xFFFF...
Page 167 Learning Basic Features Parameter Setting Group Code Name LCD Display Unit Setting Range -32767– User function output 16 User Output 16 32767 User function 17 User Func17 0–28 User function input 17-A User Input 17-A 0–0xFFFF User function input 17-B User Input 17-B 0–0xFFFF User function input 17-C User Input 17-C 0–0xFFFF...
Page 168 Learning Basic Features Function Block Parameter Structure Type Description User Func @* Choose the function to perform in the function block. User Input @-A Communication address of the function’s first input parameter. User Input @-B Communication address of the function’s second input parameter. User Input @-C Communication address of the function’s third input parameter.
Page 169 Learning Basic Features Number Type Description Comparison operation, if(A != B) then the output is C. For all other values the output is 0. COMPARE- If the condition is met, the output parameter is C. If the condition is NEQUAL not met, the output is 0(False).
Page 170 Learning Basic Features Number Type Description In the above formula, set the time when the output of A reaches 63.3% C stands for the filter operation. If it is 0, the operation is started. P, I gain = A, B parameter input, then output as C. Conditions for PI_PROCESS output: C = 0: Const PI, C = 1: PI_PROCESS-B >= PI_PROCESS-OUT >= 0, C = 2: PI_PROCESS-B >= PI_PROCESS-OUT >= -...
Page 171: Fire Mode Operation
Learning Basic Features 4.24 Fire Mode Operation This function is used to allow the inverter to ignore minor faults during emergency situations, such as fire, and provides continuous operation to fire pumps. When turned on, Fire mode forces the inverter to ignore all minor fault trips and repeat a Reset and Restart for major fault trips, regardless of the restart trial count limit.
Page 172 Learning Basic Features Fire Mode Function Setting Details Code Description Details The frequency set at Ad. 81 (Fire mode frequency) is used for Ad.81 Fire Fire mode the inverter operation in Fire mode. The Fire mode frequency Mode frequency takes priority over the Jog frequency, Multi-step frequencies, frequency reference and the keypad input frequency.
Page 173: Learning Advanced Features
Learning Advanced Features 5 Learning Advanced Features This chapter describes the advanced features of the S100 inverter. Parameter groups and codes are described based on 0.4-22kW models. For 30-75kW models, refer to 3.1.5 Control Menu on page 64. Check the reference page in the table to see the detailed description for each of the advanced features.
Page 174 Learning Advanced Features Advanced Tasks Description Ref. operation inverter when a trip condition is released, after the inverter stops operating due to activation of protective devices (fault trips). Used to switch equipment operation by connecting two motors Second motor to one inverter. Configure and operate the second motor using p.218 operation the terminal input defined for the second motor operation.
Page 175: Operating With Auxiliary References
Learning Advanced Features 5.1 Operating with Auxiliary References Frequency references can be configured with various calculated conditions that use the main and auxiliary frequency references simultaneously. The main frequency reference is used as the operating frequency, while auxiliary references are used to modify and fine-tune the main reference.
Page 176 Learning Advanced Features Code Description Set the auxiliary reference gain with bA.03 (Aux Ref Gain) to configure the auxiliary reference and set the percentage to be reflected when calculating the main reference. Note that items 4–7 below may result in either plus (+) or minus (-) references (forward or reverse operation) even when unipolar analog inputs are used.
Page 177 Learning Advanced Features Auxiliary Reference Operation Ex #1 Keypad Frequency Setting is Main Frequency and V1 Analog Voltage is Auxiliary Frequency • Main frequency: Keypad (operation frequency 30Hz) • Maximum frequency setting (dr.20): 400Hz • Auxiliary frequency setting (bA.01): V1[Display by percentage(%) or auxiliary frequency (Hz) depending on the operation setting condition] •...
Page 178 Learning Advanced Features Example: an input current of 10.4mA is applied to I2, with the frequency corresponding to 20mA of 60Hz. The table below shows auxiliary frequency A as 24Hz(=60[Hz] X {(10.4[mA]- 4[mA])/(20[mA] - 4[mA])} or 40%(=100[%] X {(10.4[mA] - 4[mA])/(20[mA] - 4[mA])}. Setting* Calculating final command frequency** M[Hz]+(G[%]*A[Hz])
Page 179: Jog Operation
Learning Advanced Features 30Hz(M)x{50%(G)x2x(40%(A)–50%)}=- M[HZ]*{G[%]*2*(A[%]-50[%])} 3Hz(Reverse) 30Hz(M)/{50%(G)x2x(60%–40%)}=- M[HZ]/{G[%]*2*(A[%]-50[%])} 300Hz(Reverse) M[HZ]+M[HZ]*G[%]*2*(A[%]- 30Hz(M)+30Hz(M)x50%(G)x2x(40%(A)– 50[%]) 50%)=27Hz * M: main frequency reference (Hz or rpm)/G: auxiliary reference gain (%)/A: auxiliary frequency reference (Hz or rpm) or gain (%). **If the frequency setting is changed to rpm, it is converted to rpm instead of Hz. Note When the maximum frequency value is high, output frequency deviation may result due to analog input variation and deviations in the calculations.
Page 180 Learning Advanced Features Forward Jog Description Details Code Description Select the jog frequency from P1- P7 and then select 6. Jog from In.65-71. In.65–71 Px Define [Terminal settings for jog operation] dr.11 JOG Frequency Set the operation frequency. dr.12 JOG Acc Time Set the acceleration speed.
Page 181: Jog Operation 2-Fwd/Rev Jog By Multi-Function Terminal
Learning Advanced Features Jog Operation 2-Fwd/Rev Jog by Multi-function Terminal For jog operation 1, an operation command must be entered to start operation, but while using jog operation 2, a terminal that is set for a forward or reverse jog also starts an operation.
Page 182: Up-Down Operation
Learning Advanced Features Set dr.90 to 1(JOG Key) and set the drv code in the Operation group to 0(Keypad). When the [ESC] key is pressed, the SET display light flashes and the jog operation is ready to start. Pressing the [RUN] key starts the operation and the inverter accelerates or decelerates to the designated jog frequency.
Page 183 Learning Advanced Features Code Description 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 to a normal operation from a fault trip, it resumes operation at the saved frequency.
Page 184: 3-Wire Operation
Learning Advanced Features 5.4 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. Group Code Name LCD Display Parameter Setting Setting Range Unit Command Operation Cmd Source*...
Page 185: Safe Operation Mode
Learning Advanced Features 5.5 Safe Operation Mode When the multi-function terminals are configured to operate in safe mode, operation commands can be entered in the Safe operation mode only. Safe operation mode is used to safely and carefully control the inverter through the multi-function terminals. Group Code Name...
Page 186: Dwell Operation
Learning Advanced Features 5.6 Dwell Operation The dwell operation is used to manitain torque during the application and release of the brakes on lift-type loads. Inverter dwell operation is based on the Acc/Dec dwell frequency and the dwell time set by the user. The following points also affect dwell operation: •...
Page 187 Learning Advanced Features Note Dwell operation does not work when: • Dwell operation time is set to 0 sec or dwell frequency is set to 0 Hz. • Re-acceleration is attempted from stop or during deceleration, as only the first acceleration dwell operation command is valid.
Page 188: Slip Compensation Operation
Learning Advanced Features 5.7 Slip Compensation Operation Slip refers to the variation between the setting frequency (synchronous speed) and motor rotation speed. As the load increases there can be variations between the setting frequency and motor rotation speed. Slip compensation is used for loads that require compensation of these speed variations.
Page 189: Pid Control
Learning Advanced Features Code Description �� =Rated slip frequency �� =Rated frequency �� =Number of the rated motor rotations ��=Number of motor poles 5.8 PID Control Pid control is one of the most common auto-control methods. It uses a combination of proportional, integral, and differential (PID) control that provides more effective control for automated systems.
Page 190: Pid Basic Operation
Learning Advanced Features PID Basic Operation PID operates by controlling the output frequency of the inverter, through automated system process control to maintain speed, pressure, flow, temperature and tension. Parameter Group Name LCD Display Setting Range Unit Setting Application function App Mode Proc PID 0–2...
Page 191 Learning Advanced Features Parameter Group Name LCD Display Setting Range Unit Setting selection Level PID controller unit PID Unit Sel 0-12 selection 43 PID unit gain PID Unit Gain 100.0 0-300 44 PID unit scale PID Unit Scale PID 2 proportional PID P2-Gain 100.00...
Page 192 Learning Advanced Features Code Description Selects the reference input for the PID control. If the V1 terminal is set to PID feedback source (PID F/B Source), the V1 terminal cannot be set to the PID reference source (PID Ref Source). To set V1 as a reference source, change the feedback source.
Page 193 Learning Advanced Features Code Description 100%, output occurs at 1% per 10ms. Sets the ratio that adds the target to the PID output. Adjusting this value AP.25 PID F-Gain leads to a faster response. Used when the output of the PID controller changes too fast or the entire system is unstable, due to severe oscillation.
Page 194 Learning Advanced Features [PID control block diagram]...
Page 195: Pre-Pid Operation
Learning Advanced Features Pre-PID Operation When an operation command is entered that does not include PID control, general acceleration occurs until the set frequency is reached. When the controlled variables increase to a particular point, the PID operation begins. Pre-PID Operation Setting Details Code Description AP.34 Pre-PID...
Page 196: Pid Operation Sleep Mode
Learning Advanced Features PID Operation Sleep Mode If the operation continues at a frequency lower than the set condition for PID operation, the PID operation sleep mode starts. When PID operation sleep mode starts, the operation will stop until the feedback exceeds the parameter value set at AP.39 (PID WakeUp Lev). PID Operation Sleep Mode Setting Details Code Description...
Page 197: Pid Switching (Pid Openloop)
Learning Advanced Features PID Switching (PID Openloop) When one of the multi-function terminals (In. 65-71) is set to 23 (PID Openloop) and is turned on, the PID operation stops and is switched to general operation. When the terminal turns off, the PID operation starts again. 5.9 Auto Tuning The motor parameters can be measured automatically and can be used for auto torque boost or sensorless vector control.
Page 198 Learning Advanced Features Parameter Group Code Name LCD Display Setting Range Unit Setting Rotor time 25-5000 constant Default Motor Parameter Settings Motor Capacity Rated No-load Rated Slip Stator Leakage (kW) Current (A) Current (A) Frequency(Hz) Resistance() Inductance (mH) 3.33 14.0 40.4 3.33 6.70...
Page 199 Learning Advanced Features Auto Tuning Parameter Setting Details Code Description Select an auto tuning type and run it. Select one of the options and then press the [ENT] key to run the auto tuning. Setting Function Auto tuning function is not enabled. Also, if you select one of the auto tuning options and run it, the None parameter value will revert back to “0”...
Page 200 Learning Advanced Features Code Description Curr, bA.21 Rs– are not included in the auto tuning measurement list, the default setting will bA.24 Tr be displayed. • Perform auto tuning ONLY after the motor has completely stopped running. • Before you run auto tuning, check the motor pole number, rated slip, rated current, rated volage and efficiency on the motor’s rating plate and enter the data.
Page 201: Sensorless Vector Control For Induction Motors
Learning Advanced Features 5.10 Sensorless Vector Control for Induction Motors Sensorless vector control is an operation to carry out vector control without the rotation speed feedback from the motor but with an estimation of the motor rotation speed calculated by the inverter. Compared to V/F control, sensorless vector control can generate greater torque at a lower level of current.
Page 202 Learning Advanced Features Setting Group Code Name LCD Display Parameter Setting Unit Range integral gain2 motor capacity Sensorless current ACR SL P controller proportional 10-1000 Gain gain Sensorless current ACR SL I 10-1000 controller integral gain Gain Torque controller output Torque Out 0-2000 filter...
Page 203: Sensorless Vector Control Operation Setting For Induction Motors
Learning Advanced Features For high-performance operation, the parameters of the motor connected to the inverter output must be measured. Use auto tuning (bA.20 Auto Tuning) to measure the parameters before you run sensorless vector operation. To run high-performance sensorless vector control, the inverter and the motor must have the same capacity.
Page 204 Learning Advanced Features Sensorless Vector Control Operation Setting Details for Induction Motors Code Description Setting Function Does not display sensorless (II) vector control gain code. Allows the user to set various gains applied when the motor rotates faster than medium speed (approx. 1/2 of Cn.20 SL2 G View the base frequency) through sensorless (II) vector control.
Page 205 Learning Advanced Features Code Description Changes the speed PI controller gain during sensorless vector control. For a PI speed controller, P gain is a proportional gain for the speed deviation. If speed deviation becomes higher than the torque the output Cn.21 ASR-SL P command increases accordingly.
Page 206 Learning Advanced Features Code Description Sets the torque limit with the communication Int 485 terminal of the terminal block. Sets the torque limit with the FieldBus FieldBus communication option. This enters the torque reference by linking the common area with the user sequence UserSeqLink output.
Page 207: Sensorless Vector Control Operation Guide For Induction Motors
Learning Advanced Features Sensorless Vector Control Operation Guide for Induction Motors Problem Relevant function code Troubleshooting Set the value of Cn. 90 to be more than 3 times the value of bA.24 or increase the value of Cn.10 by increments of 50%. If the bA.24 Tr value of Cn.10 is high, an overcurrent trip at Cn.09 PreExTime...
Page 208: Sensorless Vector Control For Pm (Permanent-Magnet) Synchronous Motors
Learning Advanced Features Problem Relevant function code Troubleshooting increments/decrements of 5% (set below 100%). The motor hunts when Increase the value of Cn.22 by increments of the load increases from Cn.22 ASR-SL I Gain1 50m/s or decrease the value of Cn.24 by the base frequency or Cn.23 ASR-SL I Gain2 decrements of 5%.
Page 209 Learning Advanced Features Group Code Name LCD Display Parameter Setting Setting Range Unit Ld and Lq Auto tuning Ld,Lq Tune frequency for Ld 100.0% 80.0–150.0 and Lq PM speed ASR P Gain 1 100 0–5000 controller P gain 1 PM speed ASR I Gain 1 0–5000 controller I gain 1...
Page 210: Detecting The Initial Pole Position
Learning Advanced Features Group Code Name LCD Display Parameter Setting Setting Range Unit Initial pole position Init Angle Sel 1: Angle Detect 0–2 0–2 estimation type Current controller P ACR P Gain 1200 0–10000 gain Current controller I ACR I Gain 0–10000 gain Voltage controller...
Page 211: Sensorless Vector Control Mode Settings For Pm Synchronous Motors
Learning Advanced Features When Cn. 46 is set to 0 (None), the motor is operated according to the pole position estimated by the inverter’s sensorless control algorithm, instead of actually detecting the physical position of the rotor pole. When Cn. 46 is set to 1 (Angle Detect), the motor is operated according to the pole position detected by changes in the current.
Page 212 Learning Advanced Features After entering the codes, set bA.20 (Auto tuning) to 7 [All(PM)] and perform a static auto tuning operation. When auto tuning is complete, the bA.21 (Rs), bA.28 Ld (PM), bA. 29 Lq (PM), and bA. 30 (PM Flux Ref) parameters are automatically measured and saved. Sensorless Vector Control Operation Setting Details Code Description...
Page 213 Learning Advanced Features Code Description response rate. Set these parameters to change the speed estimator gain during a PM synchronous motor operation in sensorless vector control mode. Cn.41 PM SpdEst Kp, If fault trips occur or excessive oscillation is observed at low speeds, Cn.42 PM SpdEst Ki decrease the value at Cn.41 in 10% decrements until the motor Cn.43 PM SpdEst Kp2...
Page 214 Learning Advanced Features Code Description Sets the torque limit with the FieldBus FieldBus communication option. Sets the torque limit with a user sequence UserSeqLink output. The torque reference is received via the common area addresses. Sets the torque limit with the pulse input of Pulse the terminal block.
Page 215: Guidelines For Running A Pm Synchronous Motor In Sensorless Vector Control Mode
Learning Advanced Features Guidelines for Running a PM Synchronous Motor in Sensorless Vector Control Mode Relevant function Problem Troubleshooting code Cn.48 ACR P-Gain If an overcurrent trip occurs at startup, try Cn.39 PMdeadBand decreasing the value at Cn.48 in 10% Starting torque is insufficient.
Page 216 Learning Advanced Features Relevant function Problem Troubleshooting code massive load change while the motor is operated at mid- speed (above 30Hz). If the motor is operated at the rated Speed variation occurs during speed, try decreasing the value at Cn.50 an operation at rated motor Cn.45 PM Flux FF % in 5% increments.
Page 217 Learning Advanced Features Relevant function Problem Troubleshooting code around 20% of the base frequency, and the motor is stopped and starts again after a massive current rises. During a high-speed operation in PM control mode Cn.78 KEB Start Lev utilizing the kinetic energy Cn.79 KEB Stop Lev Try increasing the values at Cn.78 and buffering, a massive current...
Page 218: Kinetic Energy Buffering Operation
Learning Advanced Features 5.12 Kinetic Energy Buffering Operation When the input power supply is disconnected, the inverter’s DC link voltage decreases, and a low voltage trip occurs blocking the output. A kinetic energy buffering operation uses regenerative energy generated by the motor during the blackout to maintain the DC link voltage.
Page 219 Learning Advanced Features Kinetic Energy Buffering Operation Setting Details Code Description Select the kinetic energy buffering operation when the input power is disconnected. If 1 or 2 is selected, it controls the inverter's output frequency and charges the DC link (inverter's DC part) with energy generated from the motor.
Page 220 Learning Advanced Features Code Description Cn.78 KEB Start Sets the start and stop points of the kinetic energy buffering operation. Lev, The set values must be based on the low voltage trip level as 100% and Cn.79 KEB Stop Lev the stop level (Cn.
Page 221: Torque Control
Learning Advanced Features 5.13 Torque Control The torque control function controls the motor to maintain the preset torque value. The motor rotation speed maintains the speed constantly when the output torque and load torque of the motor keep a balance. Therefore, the motor rotation speed is decided by the load when controlling the torque.
Page 222 Learning Advanced Features Note • To operate in torque control mode, basic operation conditions must be set. For more information, refer to page 193. • The torque control cannot be used in a low speed regeneration area or low load conditions. •...
Page 223 Learning Advanced Features Group Code Name LCD Display Parameter Setting Unit Monitor mode display 3 Monitor Line-3 3 Output Voltage *Available on LCD keypad only. Torque reference setting details Code Description Select an input method to use as the torque reference. Parameter Setting Description Keypad-1...
Page 224: Energy Saving Operation
Learning Advanced Features Code Description exceeds the speed limit value. Select a parameter from the Config (CNF) mode and then select21 Torque CNF-21~23 Bias. Select a multi-functional input terminal to set as the (35 Speed/Torque). If In 65-71 you turn on the terminal while the operation is stopped, it operates in vector control (speed limit) mode.
Page 225: Automatic Energy Saving Operation
Learning Advanced Features Automatic Energy Saving Operation The amount of energy saving can be automatically calculated based on the rated motor current (bA.13) and the no-load current (bA.14). From the calculations, the output voltage can be adjusted. Group Code Name LCD Display Parameter Setting Setting Range...
Page 226 Learning Advanced Features Speed Search Operation Setting Details Code Description Sets the speed search current based on the motor’s rated current. This Cn.69 SS Pulse Curr parameter is only displayed when dr.09 (Control Mode) is set to 6 (PM Sensorless). Select a speed search type.
Page 227 Learning Advanced Features Code Description LCD keypad Type and Functions of Speed Search Setting Setting Function bit4 bit3 bit2 bit1 Speed search for general  acceleration  Initialization after a fault trip Restart after instantaneous power  interruption  Starting with power-on •...
Page 228 Learning Advanced Features Code Description • Starting with power-on: Set bit 4 to 1 and Ad.10 (Power-on Run) to 1 (Yes). If inverter input power is supplied while the inverter operation command is on, the speed search operation will accelerate the motor up to the frequency reference.
Page 229: Auto Restart Settings
Learning Advanced Features 5.16 Auto Restart Settings When inverter operation stops due to a fault and a fault trip is activated, the inverter automatically restarts based on the parameter settings. Parameter Setting Group Code Name LCD Display Unit Setting Range Select start at trip reset RST Restart 0 0–1...
Page 230: Operational Noise Settings (Carrier Frequency Settings)
Learning Advanced Features [Example of auto restart with a setting of 2] If the auto restart number is set, be careful when the inverter resets from a fault trip. The motor may automatically start to rotate. 5.17 Operational Noise Settings (carrier frequency settings) Setting Group...
Page 231 Learning Advanced Features Code Description The heat loss and leakage current from the inverter can be reduced by changing the load rate option at Cn.05 (PWM Mode). Selecting 1 (LowLeakage PWM) reduces heat loss and leakage current, compared to when 0 (Normal PWM) is selected. However, it increases the motor noise. Low leakage PWM uses 2 phase PWM modulation mode, which helps minimize degradation and reduces switching loss by approximately 30%.
Page 232: Motor Operation
Learning Advanced Features 5.18 2 Motor Operation The 2 motor operation is used when a single inverter switch operates two motors. Using the 2 motor operation, a parameter for the 2 motor is set. The 2 motor is operated when a multi-function terminal input defined as a 2 motor function is turned on.
Page 233: Supply Power Transition
Learning Advanced Features 5.19 Supply Power Transition Supply power transition is used to switch the power source for the motor connected to the inverter from the inverter output power to the main supply power source (commercial power source), or vice versa. Group Code Name LCD Display...
Page 234: Cooling Fan Control
Learning Advanced Features Code Description Set multi-function relay or multi-function output to 17 (Inverter Line) or 18 (COMM line). Relay operation sequence is as follows. OU.31 Realy 1 Define, OU.33 Q1 Define 5.20 Cooling Fan Control This function turns the inverter’s heat-sink cooling fan on and off. It is used in situations where the load stops and starts frequently, or noise free environment is required.
Page 235: Input Power Frequency And Voltage Settings
Learning Advanced Features Cooling Fan Control Detail Settings Code Description Settings Description 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 During Run and the operation command is off.
Page 236: Read, Write, And Save Parameters
Learning Advanced Features 5.22 Read, Write, and Save Parameters Use read, write and save function parameters on the inverter to copy parameters from the inverter to the LCD loader or from the LCD loader to the inverter. The 7-Segment keypad does not support this function.
Page 237: Parameter Initialization
Learning Advanced Features 5.23 Parameter Initialization User changes to parameters can be initialized (reset) to factory default settings on all or selected groups. However, during a fault trip situation or operation, parameters cannot be initialized. Setting Group Code Name LCD Display Parameter Setting Unit Range...
Page 238: Parameter View Lock
Learning Advanced Features 5.24 Parameter View Lock Use parameter view lock to hide parameters after registering and entering a user password. This function is only available on the LCD loader. Group Code Name LCD Display Parameter Setting Setting Range Unit Parameter view View Lock Set Unlocked 0–9999...
Page 239: Parameter Lock
Learning Advanced Features 5.25 Parameter Lock Use parameter lock to prevent unauthorized modification of parameter settings. To enable parameter lock, register and enter a user password first. Setting Group Code Name LCD Display Parameter Setting Unit Range Password registration 0–9999 Parameter lock 0–9999 password...
Page 240: Changed Parameter Display
Learning Advanced Features 5.26 Changed Parameter Display This feature displays all the parameters that are different from the factory defaults. Use this feature to track changed parameters. Parameter Setting Group Code Name LCD Display Unit Setting Range Changed parameter View display Changed Changed parameter...
Page 241: User Group
Learning Advanced Features 5.27 User Group Create a user defined group and register user-selected parameters from the existing function groups. The user group can carry up to a maximum of 64 parameter registrations. This function is only available on the LCD loader. Group Code Name LCD Display...
Page 242: Easy Start On
Learning Advanced Features Code Description ❺ Setting range of the user group code. Entering 0 cancels the settings. Set a code number (❸) to use to register the parameter in the user group. Select code number and press [PROG/ENT] key. Changing the value in ❸...
Page 243: Config(Cnf) Mode
Learning Advanced Features Easy Start On Setting Details Code Description Follow the procedures listed below to set parameter easy start. Procedures Set CNF-61 (Easy Start On) to 1(Yes). Select 1(All Grp) in CNF-40 (Parameter Init) to initialize all parameters in the inverter. Restarting the inverter will activate the Easy Start On.
Page 244: Timer Settings
Learning Advanced Features Config Mode Parameter Setting Details Code Description CNF-2 LCD contrast Adjusts LCD brightness/contrast on the LCD keypad. CNF-10 Inv S/W Ver, Check OS version in the inverter and on the LCD keypad. CNF-11 Keypad S/W Ver CNF-12 KPD title Ver Checks title version on the LCD keypad.
Page 245: Brake Control
Learning Advanced Features 5.31 Brake Control Brake control is used to control the On/Off operation of electronic brake load system. Group Code Name LCD Display Parameter Setting Setting Range Unit Control mode Control Mode Brake open current BR Rls Curr 50.0 0.0–180% Brake open delay time BR Rls Dly...
Page 246: Multi-Function Output On/Off Control
Learning Advanced Features 5.32 Multi-Function Output On/Off Control Set reference values (on/off level) for analog input and control output relay or multi-function output terminal on/off status accordingly. Parameter Group Code Name LCD Display Setting Range Unit Setting Output terminal on/off On/Off Ctrl Src 1 V1 control mode Output terminal...
Page 247: Press Regeneration Prevention
Learning Advanced Features 5.33 Press Regeneration Prevention Press regeneration prevention is used during press operations to prevent braking during the regeneration process. If motor regeneration occurs during a press operation, motor operation speed automatically goes up to avoid the regeneration zone. Parameter Group Code Name...
Page 248: Analog Output
Learning Advanced Features Code Description Ad.76 CompFreq Set alternative frequency width that can replace actual operation Limit frequency during regeneration prevention. Ad.77 RegenAvd To prevent regeneration zone, set P gain/I gain in the DC link voltage Pgain, Ad.78 supress PI controller. RegenAvd Igain Note Press regeneration prevention does not operate during accelerations or decelerations, but it only...
Page 249 Learning Advanced Features AO1: 0~10V / 4~20mA Output Group Code Name LCD Display Parameter Setting Setting Range Unit Analog output1 AO1 Mode Frequency 0–15 -1000.0– Analog output1 gain AO1 Gain 100.0 1000.0 Analog output1 bias AO1 Bias -100.0–100.0 Analog output1 filter AO1 Filter 0–10000 Analog constant output1...
Page 250 Learning Advanced Features Code Description Outputs inverter DC link voltage as a standard. Outputs 10V when the DC link voltage is DC Link Volt 410Vdc for 200V models, and 820Vdc for 400V models. Outputs the generated torque as a standard. Torque Outputs 10V at 250% of motor rated torque.
Page 251: Analog Pulse Output
Learning Advanced Features Code Description OU.04 AO1 Filter, Set filter time constant on analog output. OU.10 AO2 Filter If analog output at OU.01 (AO1 Mode) is set to 15(Constant), the analog OU.05 A01 Const %, OU.11 A02 Const % voltage output is dependent on the set parameter values (0–100%). OU.06 AO1 Monitor, Monitors analog output value.
Page 252 Learning Advanced Features Analog Pulse Output Setting Details Code Description In case of Standard I/O, pulse output TO and multi-function output Q1 share the same terminal. Set OU.33 to 32kHz pulse output and follow the instructions below to make wiring connections that configure the open collector output circuit.
Page 253 Learning Advanced Features Code Description and present output frequency is 30Hz, then the x-axis value on the next graph is 50%. OU.64 TO Filter Sets filter time constant on analog output. OU.65 TO If analog output item is set to constant, the analog pulse output is dependent Const % on the set parameter values.
Page 254: Digital Output
Learning Advanced Features 5.35 Digital Output Multi-function Output Terminal and Relay Settings Parameter Group Code Name LCD Display Setting Range Unit Setting Multi-function relay1 Relay 1 29 Trip setting Multi-function relay2 Relay 2 14 Run setting Multi-function output1 Q1 Define 14 Run setting Multi-function output...
Page 255 Learning Advanced Features Code Description Outputs a signal when the user set frequency and detected frequency (FDT Frequency) are equal, and fulfills FDT-1 condition at the same time. [Absolute value (set frequency-detected frequency) < detected frequency width/2]&[FDT-1] Detected frequency width is 10Hz. When the detected frequency is set to 30Hz, FDT-2 output is as shown in the graph below.
Page 256 Learning Advanced Features Code Description • In deceleration: Operation frequency>(Detected frequency–Detected frequency width/2) Detected frequency width is 10Hz. When detected frequency is set to 30Hz, FDT-4 output is as shown in the graph below. Overload Outputs a signal at motor overload. Outputs a signal when a fault is triggered from a protective function operation by inverter overload inverse proportion.
Page 257 Learning Advanced Features Code Description Outputs a signal at operation command off, and 15 Stop when there is no inverter output voltage. 16 Steady Outputs a signal in steady operation. Outputs a signal while the motor is driven by the 17 Inverter line inverter line.
Page 258: Fault Trip Output Using Multi-Function Output Terminal And Relay
Learning Advanced Features Fault Trip Output using Multi-Function Output Terminal and Relay The inverter can output fault trip state using multi-function output terminal (Q1) and relay (Relay 1). Parameter Group Code Name LCD Display Setting Range Unit Setting Trip Out Fault trip output mode Mode Multi-function relay1...
Page 259: Multi-Function Output Terminal Delay Time Settings
Learning Advanced Features Multi-function Output Terminal Delay Time Settings Set on-delay and off-delay times separately to control the output terminal and relay operation times. The delay time set at codes OU.50–51 applies to multi-function output terminal (Q1) and relay (Relay), except when the multi-function output function is in fault trip mode.
Page 260: Keypad Language Settings
Learning Advanced Features 5.36 Keypad Language Settings Select the language to be displayed on the LCD loader. Keypad S/W Ver 1.04 and above provides language selections. This setting is only available on the LCD loader. Parameter Setting Group Code Name LCD Display Unit Setting...
Page 261 Learning Advanced Features Code Description Output Displays output voltage. Voltage Displays output power. Output Power Displays inverter power consumption. WHour Counter DCLink Displays DC link voltage within the inverter. Voltage Displays input terminal status of the terminal block. Starting from the right, DI Status displays P1–P8.
Page 262 Learning Advanced Features Code Description applied as rpm or mpm set at ADV-63 (Load Spd Unit). Select the items to be displayed in monitor mode. Monitor mode is CNF-21–23 Monitor the first displayed mode when the inverter is powered on. A total of Line-x three items, from monitor line-1 to monitor line- 3, can be displayed simultaneously.
Page 263: Operation Time Monitor
Learning Advanced Features cumulated electric energy consumption. Power consumption is displayed as shown below: • Less than 1,000 kW: Units are in kW, displayed in 999.9 kW format. • 1–99 MW: Units are in MW, displayed in 99.99 MWh format. •...
Page 264: Learning Protection Features
Learning Protection Features 6 Learning Protection Features Protection features provided by the S100 series inverter are categorized into two types: protection from overheating damage to the motor, and protection against the inverter malfunction. 6.1 Motor Protection Electronic Thermal Motor Overheating Prevention (ETH) ETH is a protective function that uses the output current of the inverter without a separate temperature sensor, to predict a rise in motor temperature to protect the motor based on its heat characteristics.
Page 265: Overload Early Warning And Trip
Learning Protection Features Code Description Setting Function As the cooling fan is connected to the motor axis, Self-cool the cooling effect varies, based on motor speed. Most universal induction motors have this design. Additional power is supplied to operate the cooling Forced- fan.
Page 266 Learning Protection Features Parameter Group Code Name LCD Display Setting range Unit Setting Heavy Load level setting Load Duty Duty Overload warning OL Warn Select 1 selection Overload warning level OL Warn Level 30-180 Overload warning time OL Warn Time 10.0 0-30 Motion at overload trip...
Page 267: Stall Prevention And Flux Braking
Learning Protection Features Coden Description Pr.22 OL Trip Time the overload trip time (OL Trip Time), the inverter output is either blocked according to the preset mode from Pr. 17 or slows to a stop after deceleration. 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 warn level (OL Warn Level) and the overload warn time (OL Warn Time) are set higher than the overload trip level (OL Trip Level) and overload trip time (OL Trip Time).
Page 268 Learning Protection Features Group Code Name LCD Display Parameter Setting Setting range Unit Stall Freq 3– Stall frequency 4 Stall Freq 4 60.00 Maximum frequency Stall level 4 Stall Level 4 180 30-250 Multi-function relay 1 Relay 1 item Multi-function relay 2 32** Relay 2 9 Stall...
Page 269 Learning Protection Features Code Description Stall Similar to stall protection function during protection acceleration, the output frequency automatically while decelerates when the current level exceeds the 0010 operating at preset stall level while operating at constant speed. constant When the load current decelerates below the speed preset level, it resumes acceleration.
Page 270 Learning Protection Features Code Description set above the base frequency. The lower and upper limits are set using numbers that correspond in ascending order. For example, the range for Stall Frequency 2 (Stall Freq 2) becomes the lower limit for Stall Frequency 1 (Stall Freq 1) and the upper limit for Stall Frequency 3 (Stall Freq 3).
Page 271: Inverter And Sequence Protection
Learning Protection Features 6.2 Inverter and Sequence Protection 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. Open-phase output protection is also available. An open-phase at the connection between the motor and the inverter output may cause the motor to stall, due to a lack of torque.
Page 272: External Trip Signal
Learning Protection Features External Trip Signal Set one of the multi-function input terminals to 4 (External Trip) to allow the inverter to stop operation by using external signals. Group Code Name LCD Display Parameter Setting Setting range Unit Px terminal setting Px Define External 65-71...
Page 273: Inverter Overload Protection
Learning Protection Features 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. Group Code Name LCD Display Parameter Setting Setting range Unit Multi-function relay 1 Relay 1...
Page 274 Learning Protection Features Speed Command Loss Setting Details Code Description In situations when speed commands are lost, the inverter can be configured to operate in a specific mode: Setting Function The speed command immediately becomes the None operation frequency without any protection function.
Page 275: Dynamic Braking (Db) Resistor Configuration
Learning Protection Features Set Pr.15 (Al Lost Level) to 1 (Below x 1), Pr.12 (Lost Cmd Mode) to 2 (Dec), and Pr.13 (Lost Cmd Time) to 5 sec. Then it operates as follows: Note If speed command is lost while using communication options or the integrated RS-485 communication, the protection function operates after the command loss decision time set at Pr.13 (Lost Cmd Time) is passed.
Page 276 Learning Protection Features Code Description ��_�� %�� = × 100% ��_�� + ��_�� + ��_�� + ��_�� [Example 1] ��_�� %�� = × 100% ��_�� + ��_��1 + ��_�� + ��_��2 [Example 2] • T_acc: Acceleration time to set frequency •...
Page 277: Under Load Fault Trip And Warning
Learning Protection Features 6.3 Under load Fault Trip and Warning Group Code Name LCD Display Parameter Setting Setting range Unit 04* Load level selection Load Duty Normal Duty Under load warning UL Warn Sel 1 selection Under load warning UL Warn 10.0 0-600 time...
Page 278: Fan Fault Detection
Learning Protection Features Code Description - At Pr.29, the under load rate is decided based on twice the operation frequency of the motor’s rated slip speed (bA.12 Rated Slip). - At Pr.30, the under load rate is decided based on the base frequency set at dr.18 (Base Freq).An upper limit and lower limit is based on the inverter’s rated current.
Page 279: Lifetime Diagnosis Of Components
Learning Protection Features Lifetime diagnosis of components Registering a capacitance reference for inspection Note To perform a capacitor diagnosis, a capacitance reference must be measured and registered by setting Pr-61 (CAP Diag) to 1 (Ref Diag) when the inverter is used for the first time. The measured reference value is saved at Pr-63 and is used asthe reference for the capacitor life diagnosis.
Page 280 Learning Protection Features Group Code Name LCD Display Setting value Setting Range Unit Init Diag CAP Exchange Exchange 50.0 ~ 95.0 Level Level CAP Diag CAP Diag Level 0.0 ~ 100.0 Level Inspecting the capacitor life and initializing the capacitance reference Refer to the following instructions to inspect the capacitor life and initialize the capacitance reference.
Page 281: Low Voltage Fault Trip
Learning Protection Features Setting Group Code Name LCD Display Setting value Unit Range Accumulated 0.0-6553.5 FAN Time Perc percentof fan usage Fan exchange FAN Exchange 90.0 0.0-100.0 warning Level level Initialize operation FAN Time Rst time of cooling fans Initialize operation 75** FAN Time Rst time of cooling fans...
Page 282: Output Block By Multi-Function Terminal
Learning Protection Features Output Block by Multi-Function Terminal When the multi-function input terminal is set as the output block signal terminal and the signal is input to the terminal, then the operation stops. Setting Group Code Name LCD Display Parameter Setting Unit range Px terminal setting...
Page 283: Inverter Diagnosis State
Learning Protection Features Inverter Diagnosis State Check the diagnosis of components or devices for inverter to check if they need to be replaced. Parameter Group Code Name LCD Display Setting Range Unit Setting Bit 00-10 CAP, FAN 00 - replacement Inverter State 01 CAP Warning warning...
Page 284: No Motor Trip
Learning Protection Features No Motor Trip If an operation command is run when the motor is disconnected from the inverter output terminal, a ‘no motor trip’ occurs and a protective operation is performed by the system. Setting Group Code Name LCD Display Parameter Setting Unit...
Page 285: Fault/Warning List
Learning Protection Features 6.4 Fault/Warning List The following list shows the types of faults and warnings that can occur while using the S100 inverter. Please refer to 6 Learning Protection Features on page 250 for details about faults and warnings. Category LCD Display Details...
Page 286 Learning Protection Features Category LCD Display Details Under Load Motor underload fault trip Lost Command Command loss fault trip warning Over Load Overload warning Under Load Under load warning Inverter OLT Inverter overload warning Warning Fan Warning Fan operation warning DB Warn %ED Braking resistor braking rate warning Retry Tr Tune...
Page 287: Communication Features
RS-485 Communication Features 7 RS-485 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 the RS-485 communication features. To use the RS- 485 communication features, connect the communication cables and set the communication parameters on the inverter.
Page 288: Communication System Configuration
RS-485 Communication Features 7.2 Communication System Configuration In an RS-485 communication system, the PLC or computer is the master device and the inverter is the slave device. When using a computer as the master, the RS-232 converter must be integrated with the computer, so that it can communicate with the inverter through the RS-232/RS-485 converter.
Page 289: Setting Communication Parameters
RS-485 Communication Features Setting Communication Parameters Before proceeding with setting communication configurations, make sure that the communication lines are connected properly. Turn on the inverter and set the communication parameters. Parameter Group Code Name LCD Display Setting range Unit Setting Built-in communication Int485 St ID 1-250...
Page 290: Setting Operation Command And Frequency
RS-485 Communication Features Code Description Set a communication configuration. Set the data length, parity check method, and the number of stop bits. Setting Function CM.04 Int485 Mode D8/PN/S1 8-bit data / no parity check / 1 stop bit D8/PN/S2 8-bit data / no parity check / 2 stop bits D8/PE/S1 8-bit data / even parity / 1 stop bit D8/PO/S1...
Page 291: Command Loss Protective Operation
RS-485 Communication Features Parameter Group Code Name LCD Display Setting range Unit Setting Multi-function output 1 Q1 Define Command Parameter Group Code Name LCD Display Setting range Unit Setting Command Cmd Source* Int 485 source Operation Frequency Freq Ref Src Int 485 0-12 setting method...
Page 292: Setting Virtual Multi-Function Input
RS-485 Communication Features Setting Virtual Multi-Function Input Multi-function input can be controlled using a communication address (0h0385). Set codes CM.70–77 to the functions to operate, and then set the BIT relevant to the function to 1 at 0h0322 to operate it. Virtual multi-function operates independently from In.65-71 analog multi-function inputs and cannot be set redundantly.
Page 293: Total Memory Map For Communication
RS-485 Communication Features Total Memory Map for Communication Communication Area Memory Map Details Communication common compatible 0h0000- iS5, iP5A, iV5, iG5A compatible area area 0h00FF 0h0100- Areas registered at CM.31–38 and 0h01FF CM.51–58 0h0200- Area registered for User Group 0h023F Parameter registration type area 0h0240- Area registered for Macro Group...
Page 294: Communication Protocol
RS-485 Communication Features Currently Registered CM Group Parameter Address Parameter Assigned content by bit 0h0100- Status Parameter-1- Parameter communication code value registered at 0h0107 Status Parameter-8 CM.31-38 (Read-only) 0h0110- Control Parameter-1- Parameter communication code value registered at 0h0117 Control Parameter-8 CM.51-58 (Read/Write access) Note When registering control parameters, register the operation speed (0h0005, 0h0380, 0h0381)
Page 295 RS-485 Communication Features • An error response starts with NAK and ends with EOT. • A station ID indicates the inverter number and is displayed as a two-byte ASCII-HEX string that uses characters 0-9 and A-F. • CMD: Uses uppercase characters (returns an IF error if lowercase characters are encountered)—please refer to the following table.
Page 296 RS-485 Communication Features 7.3.1.1 Detailed Read Protocol Read Request: Reads 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 1 byte Total bytes=12.
Page 297 RS-485 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 bytes=9 7.3.1.3 Monitor Registration Detailed Protocol Monitor registration request is made to designate the type of data that requires continuous monitoring and periodic updating.
Page 298 RS-485 Communication Features Monitor Registration Execution Normal Response Station ID Data ‘01’-‘FA’ ‘Y’ ‘XXXX…’ ‘XX’ 1 byte 2 bytes 1 byte n x 4 bytes 2 bytes 1 byte Total bytes= (7 + n x 4): a maximum of 39 Monitor Registration Execution Error Response Station ID Error Code...
Page 299 RS-485 Communication Features Character Character Character space " & < >...
Page 300: Modbus-Rtu Protocol
RS-485 Communication Features Modbus-RTU Protocol 7.3.2.1 Function Code and Protocol (unit: byte) In the following section, station ID is the value set at CM.01 (Int485 St ID), and starting address is the communication address. (starting address size is in bytes). For more information about communication addresses, refer to 7.4 Compatible Common Area Parameter on page 289.
Page 301 RS-485 Communication Features Function Code #06: Preset Single Register Query Field Name Response Field Name Station ID Station ID Function (0x06) Function (0x06) Starting Address Hi Register Address Hi Register Address Lo Register Address Lo Preset Data Hi Preset Data Hi Preset Data Lo Preset Data Lo CRC Lo...
Page 302 RS-485 Communication Features Response Field Name Station ID Function* Exception Code CRC Lo CRC Hi * The function value uses the top level bit for all query values. Example of Modbus-RTU Communication in Use When the Acc time (Communication address 0x1103) is changed to 5.0 sec and the Dec time (Communication address 0x1104) is changed to 10.0 sec.
Page 303: Compatible Common Area Parameter
RS-485 Communication Features 7.4 Compatible Common Area Parameter The following are common area parameters compatible with iS5, iP5A, iV5, and iG5A. Comm. Parameter Scale Unit Assigned Content by Bit Address 0h0000 Inverter model 6: S100 0: 0.75 kW, 1: 1.5 kW, 2: 2.2 kW 3: 3.7 kW, 4: 5.5 kW, 5: 7.5 kW 6: 11 kW, 7: 15 kW, 8: 18.5 kW 0h0001...
Page 304 RS-485 Communication Features Comm. Parameter Scale Unit Assigned Content by Bit Address 0h0009 Output current 0h000A Output frequency 0.01 0h000B Output voltage 0h000C DC link voltage 0h000D Output power 0: Remote, 1: Keypad Local 1: Frequency command source by communication (built-in, option) 1: Operation command source by communication...
Page 305 RS-485 Communication Features Comm. Parameter Scale Unit Assigned Content by Bit Address Latch Type trip B15-B7 Reserved Input terminal 0h0010 information Reserved Reserved Reserved Reserved Reserved Reserved Reserved Output terminal Reserved 0h0011 information Reserved Reserved Reserved Reserved Reserved Reserved Relay 1 0h0012 0.01 V1 input voltage...
Page 306: S100 Expansion Common Area Parameter
RS-485 Communication Features 7.5 S100 Expansion Common Area Parameter Monitoring Area Parameter (Read Only) Comm. Parameter Scale Unit Assigned content by bit Address 0h0300 Inverter model S100: 0006h 0.4kW : 1900h, 0.75kW: 3200h 1.1kW: 4011h, 1.5kW: 4015h 2.2kW: 4022h, 3.0kW: 4030h 3.7kW: 4037h, 4.0kW: 4040h 5.5kW: 4055h, 7.5kW: 4075h 0h0301...
Page 307 RS-485 Communication Features Comm. Parameter Scale Unit Assigned content by bit Address 5: Decelerating to stop 6: H/W OCS 7: S/W OCS 8: Dwell operating 0: Stopped 1: Operating in forward direction 2: Operating in reverse direction 3: DC operating (0 speed control) Operation command source 0: Keypad 1: Communication option...
Page 308 RS-485 Communication Features Comm. Parameter Scale Unit Assigned content by bit Address 0h0318 PID reference 0h0319 PID feedback Display the Displays the number of poles for the first 0h031A number of poles motor for the 1 motor Display the Displays the number of poles for the 2nd number of poles 0h031B motor...
Page 309 RS-485 Communication Features Comm. Parameter Scale Unit Assigned content by bit Address 0h0325 Reserved 0.01 0h0326 0.01 Analog input V2 (I/O board) 0h0327 0.01 Analog input I2 (I/O board) 0h0328 0.01 Analog output 1 (I/O board) 0h0329 0.01 Analog output 2 (I/O board) 0h032A 0.01 Analog output 3 (Extension I/O)
Page 310 RS-485 Communication Features Comm. Parameter Scale Unit Assigned content by bit Address Reserved Reserved Reserved Reserved Reserved Reserved Reserved Level type trip 0h0332 Reserved information Reserved Keypad Lost Command Lost Command Reserved Reserved Reserved Queue Full H/W Diagnosis 0h0333 Reserved Trip information Watchdog-2 error Watchdog-1 error...
Page 311: Control Area Parameter (Read/ Write)
RS-485 Communication Features Comm. Parameter Scale Unit Assigned content by bit Address Total number of minutes excluding the total 0h0341 On Time minute number of On Time days Total number of days the inverter has 0h0342 Run Time date driven the motor Total number of minutes excluding the total 0h0343 Run Time minute...
Page 312 RS-485 Communication Features Comm. Address Parameter Scale Unit Assigned Content by Bit input control Reserved (0: Off, 1:On) Reserved Virtual DI 8(CM.77) Virtual DI 7(CM.76) Virtual DI 6(CM.75) Virtual DI 5(CM.74) Virtual DI 4(CM.73) Virtual DI 3(CM.72) Virtual DI 2(CM.71) Virtual DI 1(CM.70) Reserved Reserved...
Page 313: Inverter Memory Control Area Parameter (Read And Write)
RS-485 Communication Features Comm. Address Parameter Scale Unit Assigned Content by Bit Torque Limit 0h0395 Torque Bias 0.1 Torque bias 0h0396- 0h399 Reserved Anytime Set the CNF.20 value (refer to 5.37 Operation 0h039A Para State Monitor on page 246) Monitor Set the CNF.21 value (refer to 5.37 Operation 0h039B...
Page 314 RS-485 Communication Features Changeable Comm. Parameter Scale Unit During Function Address Operation parameters 0h03E4 Reserved Delete all fault 0h03E5 0: No, 1: Yes history Delete user- 0h03E6 registrated 0: No, 1: Yes codes Write: 0-9999 Hide parameter 0h03E7 mode Read: 0: Unlock, 1: Lock Write: 0-9999 Lock parameter 0h03E8...
Page 315 RS-485 Communication Features It may take longer to set the parameter values in the inverter memory control area because all data is saved to the inverter. Be careful as communication may be lost during parameter setup if parameter setup is continues for an extended period of time.
Page 316: Table Of Functions
Table of Functions 8 Table of Functions This chapter lists all the function settings for S100 series inverter. Set the parameters required according to the following references. If a set value input is out of range, the following messages will be displayed on the keyboard. In these cases, the inverter will not operate with the [ENT] key.
Page 317: Drive Group (Par→Dr)
Table of Functions Comm. Keypad Code Name Setting Range Initial Value Property* V/F SL Ref. Address Display Field Bus Pulse Multi-step 0.00-Maximum 0h1F05 speed 10.00 frequency(Hz) frequency 1 Multi-step 0.00-Maximum 0h1F06 speed 20.00 frequency(Hz) frequency 2 Multi-step 0.00-Maximum speed 0h1F07 30.00 frequency(Hz) frequency 3...
Page 318 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address value Maximum frequency(Hz) Torque 0h1102 Cmd Torque -180~180[%] command Acceleration 0h1103 Acc Time 0.0-600.0(s) 20.0 p.125 time Deceleration 0h1104 Dec Time 0.0-600.0(s) 30.0 p.125 time Keypad Fx/Rx-1...
Page 319 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address value 0.00, Start frequency- 0h110B 10.00 p.165 frequency Frequency Maximum frequency(Hz) Jog run Jog Acc 0h110C acceleration 0.0-600.0(s) 20.0 p.165 Time time Jog run Jog Dec 0h110D deceleration...
Page 320 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address value [V/F, Slip Compen] 40.00~120.00( Sensorless] 30.00~180.00( Sensorless] Start 0.01- 0h1113 Start Freq 0.50 p.132 frequency 10.00(Hz) 40.00~400.00( [V/F, Slip Compen] 40.00~120.00( Maximum 0h1114 Max Freq 60.00 p.142...
Page 321 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address value on time Decelerati on time Command source Frequenc reference source Multi-step speed frequency Multi-step speed frequency Multi-step speed frequency Output current Motor Inverter voltage User select...
Page 322 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address value Monitors user selected code Output voltage(V) Select Output 0h1151 output monitor code electric voltage power(kW Torque(kg f  m) Display View All 0h03E3 changed View p.226...
Page 323: Basic Function Group (Par→Ba)
Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address value Multiple Display I/O Standard Standard 0h1163 board H/W IO H/W Ver version Standard IO (M) 8.3 Basic Function group (PAR→bA) In the following table, the data shaded in grey will be displayed when a related code has been selected.
Page 324 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value source Fx/Rx-2 Int 485 FieldBus Keypad-1 Keypad-2 0h1205 frequency Freq 2nd Src Keypa I/P p.145 Int 485 source FieldBus UserSeqLin 12 Pulse Keypad-1 Keypad-2 2nd Torque 0h1206...
Page 325 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value efficiency dent motor setting Load inertia 0h1211 Inertia Rate I/P p.174 rate Trim power Trim 0h1212 70-130(%) I/P - display Power % 220/38 Input power 0h1213 AC Input Volt 170-480V...
Page 326 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value reference Regeneratio Ls Regen n inductance 70 ~ 100[%] Scale scale Q-axis Lq(PM) inductance 50–150[%] Scale scale PM auto Ld,Lq Tune 20.0–50.0[%] 33.3 tuning level PM auto Ld,Lq Tune...
Page 327 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value speed frequency(Hz) frequency4 Multi-step 0.00-Maximum 0h1236 speed Step Freq-5 50.00 I/P p.115 frequency(Hz) frequency5 Maxim Multi-step 0.00-Maximum 0h1237 speed Step Freq-6 I/P p.115 frequency(Hz) freque frequency6...
Page 328: Expanded Function Group (Par→Ad)
Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value time5 Multi-step 0h1250 acceleration Acc Time-6 0.0-600.0(s) 30.0 I/P p.127 time6 Multi-step 0h1251 deceleration Dec Time-6 0.0-600.0(s) 30.0 I/P p.127 time6 Multi-step 0h1252 acceleration Acc Time-7 0.0-600.0(s)
Page 329 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value gradient S-curve deceleration 0h1306 Dec S End 1-100(%) I/P p.130 end point gradient 0h1307 Start Mode Start Mode 0:Acc I/P p.138 DC-Start DC-Brake 0h1308 Stop Mode Stop Mode Free-Run...
Page 330 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value Dwell operation Acc Dwell 0h1315 0.0-60.0(s) I/P p.172 time on Time acceleration Dwell Start frequency- Dec Dwell 0h1316 frequency on Maximum 5.00 I/P p.172 Freq deceleration frequency(Hz)
Page 331 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value Maximum upper limit3 frequency(Hz) Brake release 0h1329 BR Rls Curr 0.0-180.0(%) 50.0 I/P p.231 current Brake release delay 0h132A BR Rls Dly 0.00-10.00(s) 1.00 I/P p.231 time...
Page 332 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value control Always ON g Run Temp Control Up/down operation U/D Save 0h1341 0:No I/P p.168 frequency Mode save None Output contact On/Off Ctrl 0h1342 On/Off 0:None X/A...
Page 333: Control Function Group (Par→Cn)
Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* V/F SL Ref. Address Value n frequency Limit limit of regeneration evasion for press Regeneration RegenAvd 0h134D evasion for 0.0- 100.0% 50.0 p.233 Pgain press P gain Regeneration RegenAvd evasion for 20-30000(ms)
Page 334 Table of Functions Comm. Initial Code Name Setting Range Property* V/F SL Ref. Address Display Value Code V/F: 1.0~15.0 (kHz) Heavy p.216 2.0~15.0 Duty (kHz) Carrier Carrier 2.0~10.0 0h1404 frequency Freq (kHz) V/F: 1.0~ 5.0 Normal (kHz) p.216 Duty 2.0~5.0 (kHz) Normal 0:Nor...
Page 335 Table of Functions Comm. Initial Code Name Setting Range Property* V/F SL Ref. Address Display Value PM S/L speed ASR P controller 0h140F 0~5000 Gain 1 integral gain1 PM S/L speed controller ASR P 0h1410 0~5000 proportional Gain 1 gain2 PM S/L speed ASR P controller...
Page 336 Table of Functions Comm. Initial Code Name Setting Range Property* V/F SL Ref. Address Display Value estimator Gain1 proportional gain Speed S-Est I 0h141D estimator 100-1000 p.190 Gain1 integral gain1 Speed S-Est I 0h141E estimator 100-10000 p.190 Gain2 integral gain2 Sensorless current ACR SL...
Page 337 Table of Functions Comm. Initial Code Name Setting Range Property* V/F SL Ref. Address Display Value PM dead time PMdeadBa 50.0~100.0 100.0 X/A 0h1427 range [%] nd Per PMdeadVol PM dead time 50.0~100.0 100.0 X/A 0h1428 voltage [%] Speed PM SpdEst estimator P 0~32000 0h1429...
Page 338 Table of Functions Comm. Initial Code Name Setting Range Property* V/F SL Ref. Address Display Value FieldBus UserSeqLi Pulse Positive- direction 0h1436 0.0-200.0(%) I/P p.190 reverse +Trq Lmt torque limit Positive- direction 0h1437 0.0-200.0(%) I/P p.190 –Trq Lmt regeneration torque limit Negative- direction REV +Trq...
Page 339 Table of Functions Comm. Initial Code Name Setting Range Property* V/F SL Ref. Address Display Value Flying Start-1 Speed search Flying 0h 1446 mode SS Mode Flying I/P p.211 Start-2 selection Start-1 Flying Start-3 0000- 1111 Selection of speed search 0001 acceleratio When...
Page 340 Table of Functions Comm. Initial Code Name Setting Range Property* V/F SL Ref. Address Display Value Start-2 Flying Start-1 : 200 Speed search 0h144A SS I-Gain 0-9999 p.211 integral gain Flying Start-2 : 1000 Output blocking time SS Block 0h144B 0.0-60.0(s) I/P p.211 before speed...
Page 341 Table of Functions Comm. Initial Code Name Setting Range Property* V/F SL Ref. Address Display Value Flux estimator Flux P 0h1456 proportional 0-100 p.190 Gain2 gain2 Flux estimator Flux P proportional 0h1457 0-500 p.190 Gain3 gain3 Flux estimator Flux I 0h1458 0-200 p.190...
Page 342: Input Terminal Block Function Group (Par→In)
Table of Functions 8.6 Input Terminal Block Function group (PAR→In) In the following table, the data shaded in grey will be displayed when a related code has been selected. SL: Sensorless vector control (dr.09) , I – IM Sensorless, P – PM Sensorless *O/X: Write-enabled during operation, 7/L/A: Keypad/LCD keypad/Common Comm.
Page 343 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* SL Ref. Address Value Maximum input voltage V1 output at V1 –Perc 0h150F Maximum -100.00-0.00(%) -100.00 O I/P p.107 y2’ voltage (%) V1 rotation 0h1510 direction V1 Inverting 0: No O I/P p.103 change...
Page 344 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* SL Ref. Address Value constant I2 minimum 0h1535 I2 Curr x1 0.00-20.00(mA) 4.00 O I/P p.109 input current I2 output at Minimum 0h1536 I2 Perc y1 0.00-100.00(%) 0.00 O I/P p.109 current (%) I2 maximum...
Page 345 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* SL Ref. Address Value Enable 3-Wire p.170 p.145 Source Exchange p.219 p.168 Down p.168 U/D Clear p.168 Analog p.114 Hold I-Term p.176 Clear p.176 Openloop P Gain2 p.176 XCEL p.132 Stop...
Page 346 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* SL Ref. Address Value Multi- function input DI Off Delay 0-10000(ms) 0h1556 O I/P p.146 terminal Off filter P7 – P1 Multi- function A contact DI NC/NO 0h1557 input (NO) O I/P p.146...
Page 347: Output Terminal Block Function Group (Par→Ou)
Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* SL Ref. Address Value I2, NPN status I2, PNP 8.7 Output Terminal Block Function group (PAR→OU) In the following table, the data shaded in grey will be displayed when a related code has been selected.
Page 348 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 0 Frequency 1 Output Current 2 Output Voltage 3 DCLink Voltage 4 Torque 5 Output Power Idse Analog 0h1607 output 2 AO2 Mode Iqse Freque O I/P p.234 item Target Freq...
Page 349 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value (Relay 2) FDT-3 FDT-4 Over Load Under Load Fan Warning Stall 10 Over Voltage 11 Low Voltage 12 Over Heat 13 Lost Command 14 Run 15 Stop 16 Steady 17 Inverter Line...
Page 350 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 15 Stop 16 Steady 17 Inverter Line 18 Comm Line 19 Speed Search 22 Ready 28 Timer Out 29 Trip 31 DB Warn%ED 34 On/Off Control 35 BR Control CAP.
Page 351 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value Detected 0.00-Maximum 0h1639 30.00 O I/P p.230 frequency Frequency frequency(Hz) Detected 0.00-Maximum 0h163A frequency FDT Band 10.00 O I/P p.240 frequency(Hz) band Frequency Output Current Output Voltage DCLink Voltage...
Page 352: Communication Function Group (Par→Cm)
Table of Functions 8.8 Communication Function group (PAR→CM) In the following table, the data shaded in grey will be displayed when a related code has been selected. SL: Sensorless vector control (dr.09) , I – IM Sensorless, P – PM Sensorless *O/X: Write-enabled during operation, 7/L/A: Keypad/LCD keypad/Common Comm.
Page 353 Table of Functions Comm. Initial Code Name Setting Range Property* Ref. Address Display Value FIELD BUS FBUS 0h1708 communication 12Mbps -/A O I/P - BaudRate speed Communication FieldBus 0h1709 option LED O I/P - status Number of ParaStatus 0h171E output O I/P parameters Output...
Page 354 Table of Functions Comm. Initial Code Name Setting Range Property* Ref. Address Display Value address2 Input Para Communication 0h1735 0000-FFFF Hex 0000 O I/P p.279 Control-3 address3 Input Para 0h1736 Communication 0000-FFFF Hex 0000 O I/P p.279 Control-4 address4 Input Para 0h1737 Communication...
Page 355 Table of Functions Comm. Initial Code Name Setting Range Property* Ref. Address Display Value XCEL-M Enable 3-Wire Source Exchange Down U/D Clear Analog Hold I-Term Clear Openloop P Gain2 XCEL Stop 2nd Motor Pre Excite Timer In dis Aux Ref FWD JOG REV JOG XCEL-H...
Page 356: Application Function Group (Par→Ap)
Table of Functions Comm. Initial Code Name Setting Range Property* Ref. Address Display Value Frame count Communication Comm 0:No O I/P - data upload Update Disable All Int 485 Master communication 0h1760 Disable O I/P p.147 Func P2P Slave selection M-KPD Ready 000~111...
Page 357 Table of Functions Comm. Initial Name LCD Display Setting Range Property* Ref. Address Value PID reference PID Ref 0h1811 50.00 O I/P p.176 monitor Value PID feedback PID Fdb 0h1812 0.00 O I/P p.176 monitor Value PID reference -100.00- 0h1813 PID Ref Set 50.00 O I/P p.176...
Page 358 Table of Functions Comm. Initial Name LCD Display Setting Range Property* Ref. Address Value PID lower limit PID upper limit 0h181D PID Limit Hi frequency- 60.00 O I/P p.176 frequency 300.00(Hz) -300.00 -PID PID lower limit 0h181E PID Limit Lo upper limit -60.00 O/A O I/P p.176...
Page 359: Protection Function Group (Par→Pr)
Table of Functions Comm. Initial Name LCD Display Setting Range Property* Ref. Address Value 0.00- 0h182B PID unit gain PID Unit Gain 100.00 O/A O I/P p.176 300.00(%) x100 PID Unit 0h182C PID unit scale 2:x 1 O I/P p.176 Scale x 0.1 x 0.01...
Page 360 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* Ref. Address Value Input voltage 0h1B06 range during IPO V Band 1-100(V) O I/P p.257 open-phase Deceleration Trip Dec 0h1B07 time at fault 0.0-600.0(s) O I/P - Time trip Selection of 0h1B08...
Page 361 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* Ref. Address Value warning Select selection Overload OL Warn 0h1B12 30-180(%) O I/P p.251 alarm level Level Overload OL Warn 0h1B13 0.0-30.0(s) 10.0 O I/P p.251 warning time Time None Motion at...
Page 362 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* Ref. Address Value Self-cool Motor cooling Motor 0:Self- 0h1B29 O I/P p.250 Forced- fan type Cooling cool cool Electronic 0h1B2A thermal 1 ETH 1min 120-200(%) O I/P p.250 minute rating Electronic thermal...
Page 363 Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* Ref. Address Value Maximum frequency(Hz) 0h1B3A Stall level4 Stall Level 4 30-250(%) p.253 Flux Brake Flux braking 0h1B3B 0 ~ 150[%] gain CAP. Diag 0h1B3C 10 ~ 100[%] O I/P - diagnosis Perc...
Page 364: 2Nd Motor Function Group (Par→M2)
Table of Functions Comm. Initial Code Name LCD Display Setting Range Property* Ref. Address Value Fan exchange 0h1B57 Exchange 0.0~100.0[%] 90.0 O I/P - warning level level Fan Time 0h1B58 Fan reset time O I/P - Bit 00~10 CAP, FAN CAP, FAN 0h1B59 O I/P -...
Page 365 Table of Functions Comm. Initial Property Code Name LCD Display Setting Range Ref. Address Value Deceleration M2-Dec 0h1C05 0.0-600.0(s) 30.0 p.218 time Time 0.2 kW 0.4 kW 0.75 kW 1.1 kW 1.5 kW 2.2 kW 3.0 kW 3.7 kW 4.0 kW 5.5 kW 0h1C06 Motor capacity 10 7.5 kW...
Page 366 Table of Functions Comm. Initial Property Code Name LCD Display Setting Range Ref. Address Value Motor 0h1C0F 64-100(%) p.218 efficiency Efficiency Load inertia M2-Inertia 0h1C10 p.218 rate Stator M2-Rs p.218 resistance Leakage Dependent on M2-Lsigma p.218 inductance motor settings Stator M2-Ls p.218 inductance...
Page 367: User Sequence Group (Us)
Table of Functions 8.12 User Sequence group (US) This group appears when AP.02 is set to 1 (Yes) or CM.95 is set to 2 (P2P Master). The parameter cannot be changed while the user sequence is running. SL: Sensorless vector control function (dr.09) , I – IM Sensorless, P – PM Sensorless *O/X: Write-enabled during operation, 7/L/A: keypad/LCD keypad/common Comm.
Page 368 Table of Functions Comm. Setting Initial Code Name LCD Display Property* Ref. Address Range Value Output address Link 0h1D18 0-0xFFFF O I/P p.149 link14 UserOut14 Output address Link 0h1D19 0-0xFFFF O I/P p.149 link15 UserOut15 Output address Link 0h1D1A 0-0xFFFF O I/P p.149 link16 UserOut16...
Page 369: User Sequence Function Group(Uf)
Table of Functions Comm. Setting Initial Code Name LCD Display Property* Ref. Address Range Value setting18 Input constant 0h1D31 Void Para19 -9999-9999 0 O I/P p.149 setting19 Input constant 0h1D32 Void Para20 -9999-9999 0 O I/P p.149 setting20 Input constant 0h1D33 Void Para21 -9999-9999 0...
Page 370 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value Jump Jump code 1-99 O I/P p.71 Code ADDSUB NEGATE MPYDIV REMAINDER 10 COMPARE-GT 11 COMPARE-GEQ COMPARE- EQUAL COMPARE- User 0:NO NEQUAL 0h1E01 User function1 O I/P p.149 Func1 14 TIMER...
Page 371 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value User User function 0h1E04 Input1- 0-0xFFFF O I/P p.149 input1-C User function User 0h1E05 -32767-32767 O I/P p.149 output1 Output1 ADDSUB NEGATE MPYDIV REMAINDER 10 COMPARE-GT 11 COMPARE-GEQ COMPARE- EQUAL...
Page 372 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value User User function 0h1E07 Input2- 0-0xFFFF O I/P p.149 input2-A User User function 0h1E08 Input2- 0-0xFFFF O I/P p.149 input2-B User User function 0h1E09 Input2- 0-0xFFFF O I/P p.149 input2-C...
Page 373 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT User User function 12 0h1E0C Input3- 0-0xFFFF O I/P p.149 input3-A User User function 13 0h1E0D Input3- 0-0xFFFF O I/P p.149 input3-B User User function...
Page 374 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT User User function 0h1E11 Input4- 0-0xFFFF O I/P p.149 input4-A User User function 0h1E12 Input4-...
Page 375 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT User function User 0h1E16 0-0xFFFF O I/P p.149 input5-A Input5-A User function...
Page 376 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 18 XOR 19 ANDOR 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT User function User 0h1E1B 0-0xFFFF O I/P p.149...
Page 377 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 17 OR 18 XOR 19 ANDOR 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT User function User 0h1E20 0-0xFFFF...
Page 378 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 15 LIMIT 16 AND 17 OR 18 XOR 19 ANDOR 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT User function User...
Page 379 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value COMPARE- NEQUAL 14 TIMER 15 LIMIT 16 AND 17 OR 18 XOR 19 ANDOR 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT...
Page 380 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value COMPARE- EQUAL COMPARE- NEQUAL 14 TIMER 15 LIMIT 16 AND 17 OR 18 XOR 19 ANDOR 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT...
Page 381 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value MPYDIV REMAINDER 10 COMPARE-GT 11 COMPARE-GEQ COMPARE- EQUAL COMPARE- NEQUAL 14 TIMER 15 LIMIT 16 AND 17 OR 18 XOR 19 ANDOR 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER...
Page 382 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value NEGATE MPYDIV REMAINDER 10 COMPARE-GT 11 COMPARE-GEQ COMPARE- EQUAL COMPARE- NEQUAL 14 TIMER 15 LIMIT 16 AND 17 OR 18 XOR 19 ANDOR 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR...
Page 383 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value ADDSUB NEGATE MPYDIV REMAINDER 10 COMPARE-GT 11 COMPARE-GEQ COMPARE- EQUAL COMPARE- User User 0:NO NEQUAL 61 0h1E3D O I/P p.149 function13 Func13 14 TIMER 15 LIMIT 16 AND 17 OR 18 XOR...
Page 384 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value User User function 0h1E40 Input13- 0-0xFFFF O I/P p.149 input13-C User User function 0h1E41 Output -32767-32767 O I/P p.149 output13 ADDSUB NEGATE MPYDIV REMAINDER 10 COMPARE-GT 11 COMPARE-GEQ COMPARE- EQUAL...
Page 385 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value User User function 0h1E43 Input14- 0-0xFFFF O I/P p.149 input14-A User User function 0h1E44 Input14- 0-0xFFFF O I/P p.149 input14-B User User function 0h1E45 Input14- 0-0xFFFF O I/P p.149 input14-C...
Page 386 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT User User function 0h1E48 Input15- 0-0xFFFF O I/P p.149 input15-A User User function 0h1E49 Input15- 0-0xFFFF O I/P p.149 input15-B User User function...
Page 387 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT User User function 77 0h1E4D Input16- 0-0xFFFF O I/P p.149 input16-A User User function...
Page 388 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value 17 OR 18 XOR 19 ANDOR 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT User User function 0h1E52 Input17-...
Page 389 Table of Functions Comm. Initial Code Name Setting Range Property* SL Ref. Address Display Value COMPARE- NEQUAL 14 TIMER 15 LIMIT 16 AND 17 OR 18 XOR 19 ANDOR 20 SWITCH 21 BITTEST 22 BITSET 23 BITCLEAR 24 LOWPASSFILTER 25 PI_CONTORL 26 PI_PROCESS 27 UPCOUNT 28 DOWNCOUNT...
Page 390: Groups For Lcd Keypad Only
Table of Functions 8.14 Groups for LCD Keypad Only Trip Mode (TRP Last-x) Code Name LCD Display Setting Range Initial Value Ref. Trip type display Trip Name(x) Frequency reference at Output Freq trip Output current at trip Output Current Acceleration/Deceleration Inverter State state at trip DC section state...
Page 391 Table of Functions Code Name LCD Display Setting Range Initial Value Ref. Monitor mode display Monitor Line-1 1 Speed 0: Frequency p.246 item1 Monitor mode display Output 2:Output Monitor Line-2 p.246 item2 Current Current Output Voltage 4 Output Power WHour Counter DCLink Voltage...
Page 392 Table of Functions Code Name LCD Display Setting Range Initial Value Ref. 3 BAS Grp 4 ADV Grp 5 CON Grp 6 IN Grp 7 OUT Grp 8 COM Grp 9 APP Grp 11 APO Grp 12 PRT Grp 13 M2 Grp 0 View All Display changed Changed Para...
Page 393 Table of Functions Code Name LCD Display Setting Range Initial Value Ref. 0 No 60 Additional title update Add Title Up 0:No p.229 1 Yes 0 No Simple parameter Easy Start On 1:Yes p.227 setting 1 Yes 0 No Power consumption WHCount Reset 0:No p.229...
Page 394: Troubleshooting
This chapter explains how to troubleshoot a problem when inverter protective functions, fault trips, warning signals, or a fault occurs. If the inverter does not work normally after following the suggested troubleshooting steps, please contact the LSIS customer service center.
Page 395 Troubleshooting Keypad Type Description Display Display Over Displayed when internal DC circuit voltage exceeds the Latch Voltage specified value. Displayed when internal DC circuit voltage is less than Level Voltage the specified value. Displayed when internal DC circuit voltage is less than Latch Voltage2 the specified value during inverter operation.
Page 396 Troubleshooting Keypad LCD Display Type Description Display Displayed when the inverter output is blocked by a signal provided from the multi-function terminal. Set one Level of the multi-function input terminals at In.65-71 to 5 (BX) to enable input block function. Displayed when an error is detected in the memory (EEPRom), analog-digital converter output (ADC Off Set), or CPU watchdog (Watch Dog-1, Watch Dog-2).
Page 397: Warning Messages
Troubleshooting Keypad LCD Display Type Description Display Displayed when the I/O board or external communication card is not connected to the inverter or there is a bad connection. hold IO Board Latch hold Displayed when the error code continues for Trip more than 5 sec.
Page 398: Troubleshooting Fault Trips
Troubleshooting Keypad LCD Display Description Display An alarm occurs when the value set at PRT-86 is less than the value set at PRT-87. To receive fan exchange output signals, set eran Exchange the digital output terminal or relay (OUT-31 or OUT-33) to 38 (Fan Exchange).
Page 399 Check the input wiring. Open Replace the DC link capacitor. Contact The DC link capacitor needs to be the retailer or the LSIS customer replaced. service center. The load is greater than the rated motor Replace the motor and inverter with capacity.
Page 400: Troubleshooting Other Faults
The ambient temperature is too low. -10℃. NTC Open There is a fault with the internal Contact the retailer or the LSIS temperature sensor. customer service center. A foreign object is obstructing the fan’s Remove the foreign object from the air FAN Trip / air vent.
Page 401 Troubleshooting Type Cause Remedy command is incorrect. frequency command. The input voltage or current for the Check the input voltage or current for frequency command is incorrect. the frequency command. The PNP/NPN mode is selected Check the PNP/NPN mode setting. incorrectly.
Page 402 Troubleshooting Type Cause Remedy Check the motor fan and remove any The motor fan has stopped or the fan is obstructed with debris. foreign objects. The motor stops Reduce the load. during Replace the motor and the inverter acceleration or The load is too high.
Page 403 Troubleshooting Type Cause Remedy While the Change the carrier frequency to the inverter is in minimum value. operation, a Noise occurs due to switching inside control unit the inverter. Install a micro surge filter in the malfunctions or inverter output. noise occurs.
Page 404 Troubleshooting Type Cause Remedy The frequency reference is within the Set the frequency reference higher jump frequency range. than the jump frequency range. The output frequency does The frequency reference is exceeding Set the upper limit of the frequency not increase to the upper limit of the frequency command higher than the frequency the frequency...
Page 405: Maintenance
Maintenance 10 Maintenance This chapter explains how to replace the cooling fan, the regular inspections to complete, and how to store and dispose of the product. An inverter is vulnerable to environmental conditions and faults also occur due to component wear and tear. To prevent breakdowns, please follow the maintenance recommendations in this section.
Page 406: Annual Inspections
Maintenance Inspection Inspection Inspection Judgment Inspection Inspection details area item method standard equipment Is the capacitor swollen? Turn off the system and Is there any Cooling check Fan rotates Cooling fan abnormal system operation by smoothly vibration or noise? rotating the fan manually.
Page 407 Maintenance Inspection Inspection Inspection Inspection Judgment Inspection area item details method standard equipment cables? Is there any damage to cable insulation? Visual Is there any Terminal block inspection damage? abnormality Measure Measure with Rated Smoothing electrostatic capacity capacity over Capacity meter condenser capacity.
Page 408: Bi-Annual Inspections
Maintenance Inspection Inspection Inspection Inspection Judgment Inspection area item details method standard equipment loose? parts and tighten all screws. Check the Specified and command Is the display managed Voltmeter, Display Display device value on the value normal? values must Ammeter, etc. display match.
Page 409: Replacing Major Components
Maintenance 10.2 Replacing Major Components Refer to following for information on replacing major components. Exchange Cycle for Major Components Following table shows the cycles and information for major components. Components Exchange standard Symptom Action Make inquiries to the A/S center Cooling fan 3 years Spinning failure...
Page 410: Disposal
Maintenance Disposal When disposing of the product, categorize it as general industrial waste. Recyclable materials are included in the product, so recycle them whenever possible. The packing materials and all metal parts can be recycled. Although plastic can also be recycled, it can be incinerated under contolled conditions in some regions.
Page 411: Technical Specification
Technical Specification 11 Technical Specification 11.1 Input and Output Specification 0.4-22kW Models Single Phase 200V (0.4-2.2 kW) Model □□□□S100–1□□□□□ 0004 0008 0015 0022 Heavy load 0.75 Applied motor Normal load 0.75 Heavy Rated load capacity (kVA) Normal load Heavy Rated 11.0 output Rated current...
Page 412 Technical Specification 3 Phase 200V (0.4-4 kW) Model □□□□S100–2□□□□□ 0004 0008 0015 0022 0037 0040 Heavy load 0.75 Applied motor Normal load 0.75 Heavy load Rated apacity (kVA) Normal load Heavy 11.0 16.0 17.0 Rated current load [3-Phase Normal input] (A) 12.0 18.0 18.0...
Page 413 Technical Specification 3 Phase 200V (5.5-15 kW) Model □□□□S100–2□□□□□ 0055 0075 0110 0150 Heavy load Applied motor Normal load 18.5 Heavy 12.2 17.5 22.9 Rated load capacity Normal (kVA) 11.4 15.2 21.3 26.3 load Heavy Rated 24.0 32.0 46.0 60.0 load current [3- Phase input]...
Page 414 Technical Specification 3-Phase 400V (0.4-4 kW) Model □□□□S100–4□□□□□ 0004 0008 0015 0022 0037 0040 Heavy load 0.75 Applied motor Normal load 0.75 Heavy Rated load capacity Normal (kVA) load Heavy Rated load current [3- Phase Normal 10.0 10.0 input] (A) load Rated output...
Page 415 Technical Specification 3-Phase 400V (5.5-22 kW) Model □□□□S100–4□□□□□ 0055 0075 0110 0150 0185 0220 Heavy load 18.5 Applied motor Normal load 18.5 Heavy 12.2 18.3 22.9 29.7 34.3 Rated load capacity Normal (kVA) 12.2 17.5 22.9 29.0 33.5 44.2 load Heavy 12.0 16.0...
Page 416: 30-75Kw Models
Technical Specification Note Precautions for 1–phase input to 3-phase drive • Please connect single-phase input to R(L1) and T(L3). • AC or DC reactor is necessary to reduce DC ripple. Please select built-in reactor type for 30-75kW. For 0.4-22kW, external AC or DC reactor should be installed. •...
Page 417 Technical Specification Model □□□□S100–4□□□ 0300 0370 0450 0550 0750 50-60 Hz (5%) Input frequency (In case of single phase input, input frequency is only 60Hz(5%).) Heavy load Rated current Normal load Weight (lb /kg) 57/26 77/35 77/35 95/43 95/43 (Built-in EMC filter ) (55/25) (75/34) (75/34)
Page 418: Product Specification Details
Technical Specification 11.2 Product Specification Details Items Description Control method V/F control, slip compensation, sensorless vector Frequency settings Digital command: 0.01 Hz power resolution Analog command: 0.06 Hz (60 Hz standard) Frequency 1% of maximum output frequency accuracy Control V/F pattern Linear, square reduction, user V/F Heavy load rated current: 150% 1 min, normal load rated Overload capacity...
Page 419 Technical Specification Items Description open collector terminal Multi Less than (N.O., N.C.) AC250V function relay Less than DC 30V, 1A terminal Analog output, 0-12Vdc (0-24mA): Select frequency, output current, output Analog voltage, DC terminal voltage and others output 1 Analog 0-12Vdc: Select frequency, output current, output voltage, output 2 DC terminal voltage and others...
Page 420 Technical Specification Items Description option.) • IP66(NEMA 4X Indoor Only) • 0.4-22kW: Keypad (LCD loader: Installation available Input Mode but sold separately.) • 30-75kW: LCD loader Heavy load: -10-50℃ (14–122F), normal load: -10-40℃ (14–104F) Ambient No ice or frost should be present. temperature Working under normal load at 50℃...
Page 421: External Dimensions
Technical Specification 11.3 External Dimensions 0.4-22kW Models 0.4 kW (Single Phase), 0.4-0.8 kW (3-Phase)
Page 422 Technical Specification 0.8kW-1.5kW(Single Phase 200V), 1.5kW-2.2kW(3-Phase 400V) EMC filter Type Φ Items 0004S100-1, 61.1 0008S100-2, (2.41) (5.04) (4.69) (0.20) (5.04) (0.14) (0.16) (0.16) (2.68) 0008S100-4 0004S100-2, 61.1 0004S100-4 (2.41) (5.04) (4.69) (0.20) (4.84) (0.14) (0.16) (0.17) (2.68) 004S100-1, 63.5 170.5 004S100-4, (2.50) (7.09)
Page 423 Technical Specification 0.8-1.5 kW (Single Phase), 1.5-2.2 kW(3-Phase) 0.8kW-1.5kW(Single Phase 200V), 1.5kW-2.2kW(3-Phase 400V) EMC filter Type Φ Items 0008S100-1, 0015S100-2, (3.94) (3.58) (5.04) (4.72) (0.18) (5.12) (0.18) (0.18) (0.18) 0015S100-4...
Page 424 Technical Specification Φ Items 0015S100-1, 0022S100-2, (3.94) (3.58) (5.04) (4.72) (0.18) (5.71) (0.18) (0.18) (0.18) 0022S100-4 0008S100-1, 0015S100-1, 0015S100-4, (3.94) (3.58) (7.09) (6.69) (0.20) (5.51) (0.18) (0.18) (0.17) 0022S100-4 EMC Type Units: mm (inches) 2.2 kW (Single Phase), 3.7-4.0 kW (3 Phase)
Page 425 Technical Specification 2.2kW(Single Phase 200V), 3.7-4.0kW(3-Phase 400V) EMC filter Type Φ Items 0022S100-1 0037S100-2 132.2 120.7 0040S100-2 (5.20) (5.04) (4.75) (0.15) (5.71) (0.15) (0.17) (0.18) (5.51) 0037S100-4 0040S100-4 0022S100-1, 0037S100-4, 0040S100-4 (5.20) (7.09) (6.69) (0.20) (5.51) (0.16) (0.16) (0.17) (5.51) EMC Type Units: mm (inches)
Page 426 Technical Specification 5.5-22 kW (3-Phase) Φ Items 0055S100-2 216.5 10.5 (6.30) (5.39) (9.13) (8.52) (0.41) (5.51) (0.20) (0.20) 0075S100-2 273.7 11.3 phase 0110S100-2 (7.09) (6.18) (11.4) (10.8) (0.44) (6.42) (0.20) (0.20) 200V 193.8 0150S100-2 (8.66) (7.63) (13.8) (13.0) (0.51) (7.36) (0.24) (0.24) 0055S100-4...
Page 427: 30-75Kw Models
Technical Specification 30-75kW Models 30 kW (3-Phase) 37–45 kW (3-Phase)
Page 428 Technical Specification 55–75 kW (3-Phase) Items 0300S100-4 428.5 (10.8) (17.7) (11.2) (0.28) (0.28) 0370S100-4 486.5 (20.1) 0450S100-4 (12.8) 0550S100-4 524.5 (21.7) 0750S100-4 (12.2) Units: mm (inches)
Page 429: Ip66 Models
Technical Specification IP66 Models 0.4-4.0kW (3-Phase) Φ Items 0004S100-2 180 256.6 174.2 188.2 22.3 (7.09) (6.69) (1010) (9.65) (0.32) (6.86) (7.41) (0.18) (0.18) (0.88) 0008S100-2 0015S100-2 phase 0022S100-2 258.8 11.8 22.3 28.6 200V (8.66) (8.03) (10.19) (9.49) (0.46) (7.91) (8.46) (0.22) (0.22) (0.88)
Page 430 Technical Specification Φ Items 0004S100-4 180 256.6 174.2 188.2 22.3 (7.09) (6.69) (1010) (9.65) (0.32) (6.86) (7.41) (0.18) (0.18) (0.88) 0008S100-4 0015S100-4 phase 0022S100-4 258.8 11.8 22.3 28.6 400V (8.66) (8.03) (10.19) (9.49) (0.46) (7.91) (8.46) (0.22) (0.22) (0.88) (1.13) 0037S100-4 0040S100-4 Units: mm (inches)
Page 431 Technical Specification 5.5-7.5kW (3-Phase) Φ Items 0055S100-2 250 227.2 241.2 22.3 28.6 phase (9.84) (9.13) (12.91) (12.13) (0.43) (8.94) (9.50) (0.24) (0.24) (0.88) (1.13) 200V 0075S100-2 0055S100-4 250 227.2 241.2 22.3 28.6 phase (9.84) (9.13) (12.91) (12.13) (0.43) (8.94) (9.50) (0.24) (0.24) (0.88)
Page 432 Technical Specification 11.0-22.0kW (3 Phase)
Page 433: Peripheral Devices
(0.61) (9.84) (10.39) (0.24) (0.88) (1.75) 0220S100-4 Units: mm (inches) 11.4 Peripheral Devices 0.4-22kW Models Compatible Circuit Breaker, Leakage Breaker and Magnetic Contactor Models (manufactured by LSIS) Circuit Breaker Leakage Breaker Magnetic Contactor Product Current Current Current Current (kW) Model...
Page 434: 30-75Kw Models
ABS53c EBS53c MC-50a ABS63c EBS63c MC-65a 18.5 MC-75a ABS103c EBS103c MC-85a 30-75kW Models Compatible Circuit Breaker, Leakage Breaker and Magnetic Contactor Models (manufactured by LSIS) Magnetic Circuit Breaker Leakage Breaker Contactor Product(kW) Current Current Current Current Model Model Model Model...
Page 435: Fuse And Reactor Specifications
Technical Specification 11.5 Fuse and Reactor Specifications 0.4-22kW Models AC Input Fuse AC Reactor DC Reactor Product (kW) Voltage Inductance Inductance Current Current (A) Current(A) (mH) (mH) 1.20 8.67 0.75 Single phase 200V 0.88 13.05 0.56 18.45 1.20 8.67 0.75 0.88 13.05 0.56...
Page 436: 30-75Kw Models
Technical Specification 30-75kW Models AC Input Fuse AC Reactor Product (kW) Current (A) Voltage (V) Inductance(mH) Current(A) 30 kW-4 0.29 125 A 37 kW-4 0.24 45 kW-4 160 A 0.20 55 kW-4 0.15 200 A 75 kW-4 0.13 Only use Class H or RK5, UL listed input fuses and UL listed circuit breakers. See the table above for the voltage and current ratings for fuses and circuit breakers.
Page 437 Technical Specification Product (kW) Terminal Screw Size Screw Torque (Kgfcm/Nm) 4.0-10.2/0.4-1.0 0.75 M3.5 2.1-6.1/0.2-0.6 3-phase 400V 4.0-10.2/0.4-1.0 18.5 11.6.1.2 30-75kW Models Product (kW) Terminal Screw Size Screw Torque (Kgfcm/Nm) 30-75 kW 61.2~91.8/6.1~9.2...
Page 438: Control Circuit Terminal Screw Specification
Technical Specification Control Circuit Terminal Screw Specification 11.6.2.1 0.4-22kW Models Terminal Terminal Screw Size Screw Torque (Kgfcm/Nm) P1-P7/ CM/VR/V1/I2/AO/Q1/EG/24/TI 2.2-2.5/0.22-0.25 /TO/ SA,SB,SC/S+,S-,SG A1/B1/C1 M2.6 4.0/0.4 * Standard I/O doesn’t support P6/P7/TI/TO terminal. Refer to Step 4 Control Terminal Wiring on page 38. 11.6.2.2 30-75kW Models Terminal...
Page 439: Dynamic Braking Unit(Dbu) And Resistors
Technical Specification 11.7 Dynamic Braking Unit(DBU) and Resistors Braking Resistor Specification (0.4-22kW) Product (kW) Resistance (Ω) Rated Capacity (W) 0.75 Single phase 200V 0.75 3-phase 200V 1,200 2,400 2,400 1,200 0.75 3-phase 400V 1,000 1,200 2,000 2,400 18.5 3,600 3,600 •...
Page 440: Dynamic Braking Unit (30-75Kw)
Technical Specification Dynamic Braking Unit (30-75kW) Capacity of applied Terminal arrangement & UL form Braking unit motor Dimensions 30-37kW SV370DBU-4U UL type 45-55kW SV550DBU-4U Refer to Group 1. (A type) 75kW SV750DBU-4U 30-37kW SV037DBH-4 Non UL Refer to Group 2. SV075DBH-4 type 45-75kW...
Page 441 Technical Specification Group 3: Terminals Functions Ground Terminal Terminal for connection with B2 of DBU Terminal for connection with B1 of DBU Terminal for connection with N of Inverter Terminal for connection with P1 of Inverter Group 4,5: P(+) N(-) Terminals Functions P(+)
Page 442: Dynamic Braking Unit Dimensions
Technical Specification Dynamic Braking Unit Dimensions Group1 Group 2 ynamic raking Dynamic RESE POWE WIRING (P2)     166. Group 3 Group 5 WIRING (P2) WIRING (P2) 적 용...
Page 443 Technical Specification Hole position Hole size for Capacity of Dimension (mm) for installation Voltage Weight installation applied (mm) (kg) motor(kW) () 30~37 1.56 227.4 192 76.4 215.4 45~75 1.85 Group 4 Hole position Hole size for Capacity Weig Dimension (mm) for installation Voltage of applied...
Page 444: Display Functions
Technical Specification Display Functions DB Resistors connect with B1, B2 of DB Unit. DBU has 3 LEDs. Red LED which is located in middle displays supplying main power, one Green LED which is right side displays under breaking and another green LED which is left side displays Over Heat Trip(OHT). Displays Function description POWER...
Page 445: Continuous Rated Current Derating
Technical Specification 11.8 Continuous Rated Current Derating Carrier Frequency Setting Range and Default Values (by product capacity) Refer to the following graphs for carrier frequency ranges and default values by product capacity. Heavy Duty Normal Duty Setting Range Setting Range Capacity Default Default...
Page 446 Technical Specification Continuous Rated Current Graph (30-75kW Heavy Duty) Carrier frequency (kHz) Continuous Rated Current Graph (0.4-75kW Normal Duty) Carrier frequency (kHz) Capacity (kW) DR (%) Capacity (kW) DR (%) Capacity (kW) DR (%) 0.4kW-2 15kW-2 11kW-4 0.8kW-2 0.4kW-4 15kW-4 1.5kW-2 0.8kW-4 18.5kW-4...
Page 447 Technical Specification Continuous Rated Current Derating by Input Voltage The continuous rated current of the inverter is limited based on the input voltage. Refer to the following graph. Input Voltage Continuous Rated Current Derating by Ambient Temperature and Installation Type The constant-rated current of the inverter is limited based on the ambient temperature and installation type.
Page 448: Heat Emmission
Technical Specification 11.9 Heat Emmission The following graph shows the inverters’ heat emission characteristics (by product capacity). Single Phase 3-Phase Heat Heat Heat Capacity Capacity Capacity Emmission(Kcal) Emmission(Kcal) Emmission(Kcal) 0.4kW-1 7.5kW-2 11kW-4 0.8kW-1 11kW-2 15kW-4 1.5kW-1 15kW-2 18.5kW-4 2.2kW-1 0.4kW-4 22kW-4 0.4kW-2 0.8kW-4...
Page 449: Applying Drives To Single-Phase Input Application
12 Applying Drives to Single-Phase Input Application 12.1 Introduction LSLV-S100 is a three-phase standard variable frequency drive(VFD). When applying single-phase power to a three-phase VFD, there are several constraints that need to be considered. Standard Pulse-Width-Modulated (PWM) VFDs use a 6-pulse diode rectifier.
Page 450: Power(Hp), Input Current And Output Current
Applying Drives to Single-Phase Input Application Figure-2 Typical Single-Phase Configuration 12.2 Power(HP), Input Current and Output Current When using a three-phase VFD with single-phase input, derating the drive’s output current and horsepower will be necessary because of the increase in DC bus ripple voltage and current.
Page 451: Input Frequency And Voltage Tolerance
Applying Drives to Single-Phase Input Application 12.3 Input Frequency and Voltage Tolerance The single-phase current ratings are valid for 60Hz input only. The AC supply voltage must be within the required voltage range of 240/480Vac +10% to –5% to maximize motor power production.
Page 452: Product Warranty
Warranty Service Information During the product warranty period, warranty service (free of charge) is provided for product malfunctions caused under normal operating conditions. For warranty service, contact an official LSIS agent or service center.
Page 453 • power supply problems or from other appliances being connected to the product • acts of nature (fire, flood, earthquake, gas accidents etc.) • modifications or repair by unauthorized persons • missing authentic LSIS rating plates • expired warranty period Visit Our Website for detailed service information.
Page 455 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 459: Revision History
Manual Revision History Revision History Date Edition Changes First 2013.12 Release 2014.11 Edition S/W Version up(V2.0) 2015.06 Edition S/W Version up(V2.3) 2016.09 Edition S/W Version up(V2.5) 2017.09 Edition 3 manuals combined...
Page 460: Index
Index Index Ａ [DOWN] key ............. 63 [ESC] key ..............63 A terminal (Normally Open) ........146 [HAND] key ............... 63 A1/C1/B1 terminal ............44 [LEFT] key ..............63 R/S/T terminal AC power input terminal ..Refer to [MODE] key .............. 63 R/S/T terminal R/S/T terminal Refer to...
Page 461 Index analog output selection switch(SW3)....39 braking torque ........... 425 AP(Application Function group) ......342 braking resistors............16 Over Current2 broadcast ..............281 ARM short current fault trip .. Refer to RS-485 built-in communication ...... Refer to ASCII code.............. 284 asymmetric ground power ........48 BX ..............
Page 462 Index saving parameters defined by communication draw operation ............159 ............... 278 Drive group ..... Refer to DRV (Drive group) setting virtual multi-function input ....278 Dwell Operation ............. 172 Communication function group ... Refer to COM Acc/Dec dewel frequency ........ 172 (communication function group) acceleration Dwell ..........
Page 463 Index 0.4kW(Single Phase), 0.4~0.8kW(3 Phase) .. 407 variable resistor ............87 External dimensions frequency setting (Pulse train) terminal ..Refer to 0.4kW(Single Phase), 0.4~0.8kW(3 Phase) .. 415 terminal External Trip ........... 271, 381 frequency setting(voltage) terminal ..Refer to external trip signal ..........258 terminal Ｆ...
Page 464 Index input terminal ............41 navigating between groups ........65 CM terminal ............41 operation keys .............57 I2 terminal ............41 parameter mode ..........66 S/W version ............229 P1–P7 terminal ............ 41 trip mode...............66 SA terminal ............42 Keypad SB terminal ............42 Keypad Language ..........
Page 465 Index LS INV 485 protocol..........280 multi-function input terminal control ..... 146 multi-function key ............58 Ｍ Multi Key Sel ............. 378 multi-function key options ........ 378 multi-function output M2(2nd Motor Function group) ......350 multi-function output terminal delay time settings magnetic contactor ..........
Page 466 Index Operation accumulated time ......249 setting ............147, 148 Operation accumulated time initialization ..249 slave parameter ..........148 Option Trip-x parameter ..............77 option trip ......269, Refer to display changed parameter ......226 Option Trip-x ............271 hide parameters ..........224 option trip ............
Page 467 Index Pr(Protection Function group) ....... 345 RS-485 ..............273 pre-exciting time ............. 190 communication ..........274 Preinsulated Crimp Terminal ........44 converter............274 press regeneration prevention ......233 integrated communication ........ 113 Press regeneration prevention signal terminal ..........44, 113 S+/S-/SG P gain/I gain ............
Page 468 Index setting virtual multi-function input......278 Cmd Frequency ..........303 single phase 200V (0.4~2.2 kW) ......397 technical specification ........... 397 Slave ............... 274 terminal ..............146 slave inverter ............148 A terminal........... 146, 245 slave unit ..............147 B terminal ..........146, 245 Slip ................
Page 469 Index Under Load ............. 272 I2 voltage input ........... 110 underload fault trip ..........272 variable resistor ............87 underload trip............. 380 variable torque load ........133, 206 underload warning ........272, 383 voltage drop ..............37 Under Load AO terminal underload fault trip ....Refer to voltage/current output terminal Refer to update ............

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