TRANSISTORIZED INVERTER FR-A500 FR-A500(-NA)(-EC) TRANSISTORIZED INVERTER INSTRUCTION MANUAL HIGH FUNCTION & LOW ACOUSTIC NOISE FR-A520-0.4K to 55K(-NA) FR-A540-0.4K to 55K(-NA)(-EC) OUTLINE Chapter 1 INSTALLATION AND WIRING Chapter 2 OPERATION /CONTROL Chapter 3 PARAMETERS Chapter 4 IB (NA) 66790-G (0101) ROD Printed in Japan Specifications subject to change without notice.
Thank you for choosing this Mitsubishi transistorized Inverter. This instruction manual gives handling information and precautions for use of this equipment. Incorrect handling might cause an unexpected fault. Before using the inverter, please read this manual carefully to use the equipment to its optimum. Please forward this manual to the end user. This instruction manual uses the International System of Units (SI).
SAFETY INSTRUCTIONS 1. Electric Shock Prevention WARNING ! While power is on or when the inverter is running, do not open the front cover. You may get an electric ! ! ! ! ! ! ! ! ! shock. Do not run the inverter with the front cover removed. Otherwise, you may access the exposed highvoltage terminals or the charging part of the circuitry and get an electric shock. If power is off, do not remove the front cover except for wiring or periodic inspection.
. Additional instructions Also note the following points to prevent an accidental failure, injury, electric shock, etc.: (1) Transportation and installation CAUTION ! When carrying products, use correct lifting gear to prevent injury. ! Do not stack the inverter boxes higher than the number recommended. ! Ensure that installation position and material can withstand the weight of the inverter. Install according to the information in the Instruction Manual.
CAUTION ! The load used should be a three-phase induction motor only. Connection of any other electrical equipment to the inverter output may damage the equipment. ! The electronic overcurrent protection does not guarantee protection of the motor from overheating. ! Do not use a magnetic contactor on the inverter input for frequent starting/stopping of the inverter. ! Use a noise filter to reduce the effect of electromagnetic interference. Otherwise nearby electronic ! ! ! ! ! ! equipment may be affected.
1 OUTLINE 1 1.1 Pre-Operation Information ......................................................................................................................................... 1 1.1.1 Precautions for operation ................................................................................................................................... 1 1.2 Basic Configuration ..........................................................................................................................................
3.3.3 PU operation mode (Operation using the operation panel (FR-DU04))........................................................... 56 3.3.4 Combined operation mode (Operation using the external input signals and PU)............................................ 57 4 PARAMETERS 58 4.1 Parameter List ......................................................................................................................................................... 58 4.1.1 Parameter list .................................
4.2.43 Commercial power supply-inverter switch-over function (Pr. 135 to Pr. 139) ............................................... 137 4.2.44 Output current detection function (Pr. 150, Pr. 151) ...................................................................................... 141 4.2.45 Zero current detection (Pr. 152, Pr. 153) ....................................................................................................... 142 4.2.46 RT signal activated condition selection (Pr. 155)..............
5.3.4 Insulation resistance test using megger ......................................................................................................... 196 5.3.5 Pressure test .................................................................................................................................................. 196 5.3.6 Daily and Periodic Inspection ......................................................................................................................... 196 5.3.
CHAPTER 1 OUTLINE This chapter gives information on the basic "outline" of this product. Always read the instructions in this chapter before using the equipment. 1.1 Pre-Operation Information........................................ 1 1.2 Basic Configuration.................................................. 2 1.3 Structure ..................................................................
1.1 Pre-Operation Information OUTLINE 1 OUTLINE 1.1 Pre-Operation Information 1.1.1 Precautions for operation Incorrect handling might cause the inverter to operate improperly, its life to be reduced considerably, or at the worst, the inverter to be damaged. Handle the inverter properly in accordance with the information in each section as well as the precautions and instructions of this manual to use it correctly. This manual is written for the FR-A500 series transistorized inverters.
1.2 Basic Configuration OUTLINE 1.2 Basic Configuration 1.2.1 Basic configuration The following devices are required to operate the inverter. Proper peripheral devices must be selected and correct connections made to ensure proper operation. Incorrect system configuration and connections can cause the inverter to operate improperly, its life to be reduced considerably, and in the worst case, the inverter to be damaged.
1.3 Structure OUTLINE 1.3 Structure 1.3.
OUTLINE 1.3.2 Removal and reinstallation of the front cover FR-A520-0.4K to 11K, FR-A540-0.4K to 7.5K • Removal 1) Hold both sides of the front cover top and push the front cover down. 2) Hold down the front cover and pull it toward you to remove. (The front cover may be removed with the PU (FR-DU04/FR-PU04) on.) Catch Front cover Inverter 1 • Reinstallation 1) Insert the catches at the bottom of the front cover into the sockets of the inverter.
OUTLINE FR-A520-30K to 55K, FR-A540-30K to 55K • Removal 1) Remove the front cover mounting screws. • Reinstallation 1) Fix the front cover with the mounting screws. Note: 1. Make sure that the front cover has been reinstalled securely. 2. The same serial number is printed on the capacity plate of the front cover and the rating plate of the inverter. Before reinstalling the front cover, check the serial number to ensure that the cover removed is reinstalled to the inverter from where it was removed.
OUTLINE 1.3.3 Removal and reinstallation of the operation panel To ensure safety, remove and reinstall the operation panel after switching power off. • Removal Hold down the top button of the operation panel and pull the operation panel toward you to remove. " Removal Reinstallation 1 To reinstall, insert straight and mount securely. • Reinstallation using the connection cable 1) Remove the operation panel. 2) Disconnect the modular jack type relay connector.
CHAPTER 2 INSTALLATION AND WIRING This chapter gives information on the basic "installation and wiring" of this product. Always read the instructions in this chapter before using the equipment. 2.1 Installation................................................................ 7 2.2 Wiring ...................................................................... 9 2.3 Other wiring .............................................................
2.1 Installation INSTALLATION AND WIRING 2 INSTALLATION AND WIRING 2.1 Installation 2.1.1 Instructions for installation 1) Handle the unit carefully. The inverter uses plastic parts. Handle it gently to protect it from damage. Also, hold the unit with even strength and do not apply too much strength to the front cover alone. 2 2) Install the inverter in a place where it is immune to vibration. (5.9 m/s or less) Also note the cart, press, etc.
INSTALLATION AND WIRING 8) For installation in an enclosure Ventilation fan Inverter Inverter Inverter Inverter Inverter Inverter Built-in cooling fan (Correct example) (Correct example) (Incorrect example) Position of Ventilation Fan (Incorrect example) Accommodation of two or more inverters 9) Vertical mounting 2 (1) Wiring cover and handling (22K or less) 1) When cable conduits are not connected Cut the protective bushes of the wiring cover with nippers or a cutter before running the cables.
2.2 Wiring INSTALLATION AND WIRING 2.2 Wiring 2.2.
INSTALLATION AND WIRING (1) Description of main circuit terminals Symbol R, S, T 〈L1, L2, L3〉 U, V, W AC power input R1, S1 〈L11, L21〉 Power supply for control circuit P, PR 〈+, PR〉 P, N 〈+, −〉 P, P1 〈+, P1〉 Terminal Name Inverter output Brake resistor connection Brake unit connection Power factor improving DC reactor connection Built-in brake circuit connection PR, PX Ground Description Connect to the commercial power supply.
INSTALLATION AND WIRING Type Symbol Terminal Name 10E *1: *2: *3: Frequency setting Frequency setting (voltage) 4 Frequency setting (current) 1 Auxiliary frequency setting 5 Frequency setting input common A, B, C Alarm output Inverter running SU Up to frequency OL Overload alarm IPF Instantaneous power failure FU Frequency detection SE Open collector output common Pulse RUN For meter Analog Open collector 2 FM AM Analog signal output RS-485 Communication Output signals
INSTALLATION AND WIRING 2.2.2 Wiring of the main circuit (1) Wiring instructions 1) Crimping terminals with insulation sleeves are recommended for use with the power and motor cables. 2) Cut the protective bushes of the wiring cover when running the cables. (22K or less) 3) Power must not be applied to the output terminals (U, V, W) of the inverter. Otherwise the inverter will be damaged. 4) After wiring, wire off-cuts must not be left in the inverter.
INSTALLATION AND WIRING 10) When rewiring after operation, make sure that the POWER lamp has gone off, and when more than 10 minutes have elapsed after power-off, check with a meter that the voltage is zero. After that, start rewiring work. For some time after power-off, there is a dangerous voltage in the capacitor. 11) Use the space on the left-hand side of the main circuit terminal block to run the cable for connection of the control circuit power terminals R1, S1 〈L11, L21〉 of the FR-A520-11K.
INSTALLATION AND WIRING (2) Terminal block layout In the main circuit of the inverter, the terminals are arranged as shown below: 1) 200V class FR-A520-0.4K, 0.75K FR-A520-15K, 18.5K, 22K R S T U V W R1 S1 N/– P1 P/+ Screw size (M4) PR PX Charge lamp R1 S1 R S P1 P/+ Screw size (M4) Charge lamp Jumper Screw size (M4) R S T U V W N/– Screw size 15K (M6) 18.5K,22K (M8) Jumper Screw size (M6) FR-A520-1.5K, 2.2K, 3.
INSTALLATION AND WIRING 2) 400V class FR-A540-30K FR-A540-0.4K, 0.75K, 2.2K, 3.7K R 〈L1〉 S 〈L2〉 T 〈L3〉 U V W P1 N/– P/+ S1 R1 〈L11〉 〈L21〉 Charge lamp PX Screw size (M4) R1 S1 〈L11〉 〈L12〉 R S 〈L1〉 〈L2〉 PR R S T 〈L1〉 〈L2〉 〈L3〉 Charge lamp U V W Screw size (M4) N/– P1 P/+ Screw size (M6) Jumper Screw size (M4) Jumper Screw size (M6) FR-A540-5.5K, 7.
INSTALLATION AND WIRING (3) Cables, crimping terminals, etc. The following table lists the cables and crimping terminals used with the inputs (R, S, T) 〈L1, L2, L3〉 and outputs (U, V, W) of the inverter and the torques for tightening the screws: • FR-A520-0.4K to 55K Applicable Inverter Type FR-A520-0.4K to 2.2K FR-A520-3.7K FR-A520-5.5K FR-A520-7.5K FR-A520-11K FR-A520-15K FR-A520-18.
INSTALLATION AND WIRING (5) Connecting the control circuit to a power supply separately from the main circuit If the magnetic contactor (MC) in the inverter power supply is opened when the protective circuit is operated, the inverter control circuit power is lost and the alarm output signal cannot be kept on. To keep the alarm signal on terminals R1 and S1 are available. In this case, connect the power supply terminals R1 and S1 〈L11 and L21〉 of the control circuit to the primary side of the MC.
INSTALLATION AND WIRING 2.2.3 Wiring of the control circuit (1) Wiring instructions 1) Terminals SD, SE and 5 are common to the I/O signals and isolated from each other. These common terminals must not be connected to each other or earthed. 2) Use shielded or twisted cables for connection to the control circuit terminals and run them away from the main and power circuits (including the 200V relay sequence circuit). 3) The frequency input signals to the control circuit are micro currents.
INSTALLATION AND WIRING (3) Changing the control logic The input signals are set to sink logic for the Japanese and NA version, and to source Logic for the EC version. To change the control logic, the connector on the back of the control circuit terminal block must be moved to the other position. (The output signals may be used in either the sink or source logic independently of the connector position.) 1) Loosen the two mounting screws in both ends of the control circuit terminal block.
INSTALLATION AND WIRING 4) Sink logic type • In this logic, a signal switches on when a current flows out of the corresponding signal input terminal. Terminal SD is common to the contact input signals. Terminal SE is common to the open collector output signals. Current flow related to RUN signal R Inverter AX40 Current STF RUN 1 R R R STR SE SD 9 DC24V • When using an external power supply for transistor output, use terminal PC as a common to prevent misoperation caused by leakage current.
INSTALLATION AND WIRING 5) Source logic type • In this logic, a signal switches on when a current flows into the corresponding signal input terminal. Terminal PC is common to the contact input signals. Terminal SE is common to the open collector output signals. Current flow related to RUN signal PC Current Inverter AX80 RUN 1 STF R R SE R STR DC24V 9 R • When using an external power supply for transistor output, use terminal SD as a common to prevent misoperation caused by leakage current.
INSTALLATION AND WIRING 2.2.4 Connection to the PU connector (1) When connecting the operation panel or parameter unit using a connection cable • Parameter unit connection cable (FR-CB2) (option) or the following connector and cable. • Connector: RJ45 connector Example: 5-554720-3, Tyco Electronics Corporation • Cable: Cable conforming to EIA568 (e.g. 10BASE-T cable) Example: SGLPEV 0.5mm×4P (Twisted pair cable, 4 pairs), MITSUBISHI CABLE INDUSTRIES, LTD.
INSTALLATION AND WIRING 2) When a computer having a RS-232C interface is used with inverters Computer RS-232C connector RS-232C cable Max. 15m Station 1 Station 2 Station n Inverter Inverter Inverter PU connector (Note 1) PU connector (Note 1) PU connector (Note 1) *Converter Termination resistor RS-485 terminal Distribution terminal 10BASE-T cable (Note 2) *Converter available on the market is required. (Note 3) Use the connector, cables and converter which are available on the market.
INSTALLATION AND WIRING 2.2.5 Connection of stand-alone option units The inverter accepts a variety of stand-alone option units as required. Incorrect connection will cause inverter damage or accident. Connect and operate the option unit carefully in accordance with the corresponding option unit manual. (1) Connection of the dedicated external brake resistor (option) The built-in brake resistor is connected across terminals P 〈+〉 and PR.
INSTALLATION AND WIRING (2) Connection of the FR-BU brake unit (option) Connect the optional FR-BU brake unit as shown below to improve the braking capability during deceleration. T (Note 4) ON MC R 〈L1〉 U Motor S 〈L2〉 V IM T 〈L3〉 W MC PR PR Inverter Remove jumper. MC OFF PR P/+ P/+ PX N/– N/- P HA HB TH1 HC THS TH2 Brake unit FR-BU-(H) Resistor unit FR-BR-(H) Note: 1.
INSTALLATION AND WIRING (3) Connection of the conventional BU brake unit (option) Connect the BU brake unit correctly as shown below. Incorrect connection will damage the inverter. NFB MC Inverter R 〈L1〉 U Motor S 〈L2〉 V IM T 〈L3〉 W PR Remove jumper Remove jumpers. PX P/+ N/– T (Note 4) Discharge resistor P HA HB HC TB PC PR OCR Constant-voltage power supply OCR + Comparator N BU brake unit Brake unit HC 2 ON OFF HB MC MC Note: 1. For models 7.
INSTALLATION AND WIRING Note: 1. Remove the jumpers across the R-R1 and S-S1 〈L1-R1 and L2-S1〉 terminals of the inverter, and connect the control circuit power supply across the R1-S1 〈L11-L21〉 terminals. The power input terminals R, S, T 〈L1, L2, L3〉 must be open. Incorrect connection will damage the inverter. Reverse polarity of terminals N (−), P (+) will damage the inverter. 2. The voltage phases of terminals R, S, T 〈L1, L2, L3〉 and terminals R4, S4, T4 must be matched before connection. 3. Use Pr.
INSTALLATION AND WIRING 2.2.6 Design information 1) For commercial power supply-inverter switch-over operation, provide electrical and mechanical interlocks for MC1 and MC2 designed for commercial power supply-inverter switch-over. When there is a commercial power supply-inverter switch-over circuit as shown below, the inverter will be damaged by leakage current from the power supply due to arcs generated at the time of switch-over or chattering caused by a sequence error.
2.3 Other wiring INSTALLATION AND WIRING 2.3 Other wiring 2.3.1 Power harmonics Power harmonics may be generated from the converter section of the inverter, affecting power supply equipment, power capacitors, etc. Power harmonics are different in generation source, frequency and transmission path from radio frequency (RF) noise and leakage currents. Take the following measures.
INSTALLATION AND WIRING 2.3.2 Japanese harmonic suppression guidelines Harmonic currents flow from the inverter to a power receiving point via a power transformer. The harmonic suppression guidelines were established to protect other consumers from these outgoing harmonic currents.
INSTALLATION AND WIRING Table 3 Equivalent Capacity Limits Received Power Voltage 6.6kV Reference Capacity 50kVA 22/33kV 300kVA 66kV or more 2000kVA Table 4 Harmonic Content (Values at the fundamental current of 100%) Reactor Not used Used (AC side) Used (DC side) Used (AC, DC sides) 5th 65 38 30 28 7th 41 14.5 13 9.1 11th 8.5 7.4 8.4 7.2 13th 7.7 3.4 5.0 4.1 17th 4.3 3.2 4.7 3.2 19th 3.1 1.9 3.2 2.4 23rd 2.6 1.7 3.0 1.6 25th 1.8 1.3 2.2 1.
INSTALLATION AND WIRING 3) Harmonic suppression technique requirement If the outgoing harmonic current is higher than; maximum value per 1kW (contract power) × contract power, a harmonic suppression technique is required. 4) Harmonic suppression techniques No.
INSTALLATION AND WIRING 2.3.3 Inverter-generated noises and reduction techniques Some noises enter the inverter causing it to misoperate and others are radiated by the inverter causing misoperation of peripheral devices. Though the inverter is designed to be insusceptible to noise, it handles low-level signals, so it requires the following basic measures to be taken. Also, since the inverter chops the output at a high carrier frequency, it could generate noise.
INSTALLATION AND WIRING 5) Telephone 7) 7) 2) 1) Instrument Receiver 2) Sensor power supply In3) verter 6) 4) Motor Noise Path 1) 2) 3) 4) 5) 6) 7) 8) IM 8) 3) Sensor Measures When devices which handle low-level signals and are susceptible to misoperation due to noise (such as instruments, receivers and sensors) are installed near the inverter and their signal cables are contained in the same panel as the inverter or are run near the inverter, the devices may be affected by air-propagated no
INSTALLATION AND WIRING • Data line filter Noise entry can be prevented by providing a data line filter for the detector cable etc. • Data examples By decreasing the carrier frequency, the noise terminal voltage* can be reduced. Use Pr. 72 to set the carrier frequency to a low value (1kHz). Though motor noise increases at a low carrier frequency, selection of Soft-PWM in Pr. 240 will make it unoffending.
INSTALLATION AND WIRING 2.3.4 Leakage currents and countermeasures Due to the static capacitance existing in the inverter I/O wiring and motor, leakage currents flow through them. Since their values depend on the static capacitance, carrier frequency, etc., take counter measures using the following methods. (1) To-ground leakage currents Leakage currents may flow not only into the inverter's own line but also into the other line through the ground cable, etc.
INSTALLATION AND WIRING 2.3.5 Inverter-driven 400V class motor In the PWM type inverter, a surge voltage attributable to wiring constants is generated at the motor terminals. Especially for a 400V class motor, the surge voltage may deteriorate the insulation.
INSTALLATION AND WIRING 2.3.6 Peripheral devices (1) Selection of peripheral devices Check the capacity of the motor to be used with the inverter you purchased. Appropriate peripheral devices must be selected according to the capacity. Refer to the following list and prepare appropriate peripheral devices: 1) 200V class Inverter Type FR-A520-0.4K FR-A520-0.75K FR-A520-1.5K FR-A520-2.2K FR-A520-3.7K FR-A520-5.5K FR-A520-7.5K FR-A520-11K FR-A520-15K FR-A520-18.
INSTALLATION AND WIRING (2) Selection the rated sensitivity current for the earth leakage circuit breaker Leakage current (mA) Leakage current (mA) When using the earth leakage circuit breaker with the inverter circuit, select its rated sensitivity current as follows, independent of the carrier frequency setting: • Progressive Super Series (Type SP, CF, SF, CP) Example of leakage current Leakage current example per 1km in cable path during of 3-phase induction motor Rated sensitivity current: commercial
INSTALLATION AND WIRING 2.3.7 Instructions for compliance with U.S. and Canadian Electrical Codes (Standard to comply with: UL 508C) (1) Installation The above types have been approved as products for use in enclosure and approval tests were conducted under the following conditions. • 200V class Minimum Enclosure Volume Inverter Model (Ratio of enclosure volume to inverter volume) FR-A520-0.4K FR-A520-0.75K FR-A520-1.5K FR-A520-2.2K FR-A520-3.7K FR-A520-5.5K FR-A520-7.
INSTALLATION AND WIRING (5) Motor overload protection When using the electronic overcurrent protection function as motor overload protection, set the rated motor current in Pr. 9 "electronic thermal O/L relay. When connecting two or more motors to the inverter, install external thermal relays for individual motors.
INSTALLATION AND WIRING (2) Low Voltage Directive 1) Our view of transistorized inverters for the Low Voltage Directive Transistorized inverters are covered by the Low Voltage Directive (compliant with Standard DIN VDE0160). 2) Compliance We have self-confirmed our inverters as products compliant to the Low Voltage Directive and place the CE mark on the inverters. 3) Outline of instructions * In the 400V class inverters, the rated input voltage range is three-phase, 380V to 415V, 50Hz/60Hz.
INSTALLATION AND WIRING 2.3.9 Earthing (EC version) (1) Earthing and Earth Leakage Current (a) Purpose of Earthing Electrical equipment usually has an Earthing Terminal, this must be connected to earth before using equipment. For protection, electric circuits are normally housed inside an insulated case.
INSTALLATION AND WIRING c) The safety earth should be as thick as possible, minimum thickness as stated in below table. d) The earthing point should be as close to the inverter as possible, and the wire as short as possible. 2 e) The RFI earth should be a braided strap with a 10mm minimum cross sectional area, and as short as possible.
CHAPTER 3 OPERATION/CONTROL This chapter provides the basic "operation/control" for use of this product. Always read this chapter before using the equipment. Chapter 1 3.1 Pre-Operation Information........................................ 45 3.2 Operation Panel ....................................................... 48 3.3 Operation .................................................................
3.1 Pre-Operation Information OPERATION/CONTROL 3 OPERATION/CONTROL 3.1 Pre-Operation Information 3.1.1 Devices and parts to be prepared for operation The inverter can be operated in any of the "external operation mode", "PU operation mode", "combined operation mode" and "communication operation mode". Prepare required instruments and parts according to the operation mode.
OPERATION/CONTROL Preparation • Start signal...................................Switch, relay, etc. (for 1) • Frequency setting signal ..............0 to 5V, 0 to 10V or 4 to 20mA DC signals from a potentiometer or outside the inverter (for 2) • Operation unit ..............................Operation panel (FR-DU04), parameter unit (FR-PU04) • Connection cable .........................
OPERATION/CONTROL 3.1.2 Power on Before switching power on, check the following: • Installation check Make sure that the inverter is installed correctly in a proper location. (Refer to page 7.) • Wiring check Make sure that the main and control circuits are wired correctly. Make sure that the options and peripheral devices are selected and connected correctly. (Refer to page 9.) • Switch power on.
3.2 Operation Panel OPERATION/CONTROL 3.2 Operation Panel With the operation panel (FR-DU04), you can set the running frequency, monitor the operation command display, set parameters, display an error, and copy parameters. 3.2.
OPERATION/CONTROL 3.2.
OPERATION/CONTROL 3.2.5 Parameter setting method • A parameter value may either be set by updating its parameter number or setting the value digit-by-digit using the key. • To write the setting, change it and press the SET key 1.5 seconds. Example: To change the Pr. 79 "operation mode selection" setting from "2" (external operation mode) to "1" (PU operation mode) (For details of Pr. 79, refer to page 105.) Press the MODE key, to choose the parameter setting mode.
OPERATION/CONTROL 3.2.6 Operation mode "External operation FR-DU04 "PU operation FR-DU04 CONTROL PANEL "PU jog operation Hz A V MON EXT PU REV FWD FR-DU04 CONTROL PANEL CONTROL PANEL Hz A V MON MODE EXT PU REV FWD Hz A V MON EXT PU REV FWD MODE MODE To 3.2.7 Help mode Note: If the operation mode cannot be changed, refer to page 194. 3.2.
OPERATION/CONTROL (2) Alarm history clear Clears all alarm history. Flicker FR-DU04 Hz A V MON FR-DU04 CONTROL PANEL EXT PU REV FWD FR-DU04 CONTROL PANEL MON SET EXT PU REV FWD FR-DU04 CONTROL PANEL Hz A V SET Hz A V MON EXT PU REV FWD CONTROL PANEL Hz A V SET MON EXT PU REV FWD Cancel (3) Parameter clear Initialises the parameter values to the factory settings. The calibration values are not initialized. (Parameter values are not cleared by setting "1" in Pr.
OPERATION/CONTROL 3.2.8 Copy mode By using the operation panel (FR-DU04), the parameter values can be copied to another inverter (only the FR-A500 series). 1) Operation procedure After reading the parameter values from the copy source inverter, connect the operation panel to the copy destination inverter, and write the parameter values. After writing the parameters to the inverter of copy destination, always reset the inverter, e.g. switch power off once, before starting operation.
3.3 Operation OPERATION/CONTROL 3.3 Operation 3.3.1 Pre-operation checks Before starting operation, check the following: • Safety Perform test operation after making sure that safety is ensured if the machine should become out of control. • Machine Make sure that the machine is free of damage. • Parameters Set the parameter values to match the operating machine system environment. • Test operation Perform test operation and make sure that the machine operates safely under light load at a low frequency.
OPERATION/CONTROL 3.3.2 External operation mode (Operation using external input signals) (1) Operation at 60Hz Step 1 Description Power-on → Operation mode check Switch power on and make sure that the operation command indication "EXT" is lit. Image ON FR-DU04 (If it is not lit, press the MODE key to choose the operation mode and press the key to switch to external operation.) Start Turn on the start switch (STF or STR). The operation status indication "FWD" or "REV" flickers.
OPERATION/CONTROL 3.3.3 PU operation mode (Operation using the operation panel (FR-DU04)) (1) Operation at 60Hz While the motor is running, repeat the following steps 2 and 3 to vary the speed: Step 1 Description Power-on → Operation mode check Switch power on and make sure that the operation command indication "PU" is lit. Image ON FR-DU04 (If it is not lit, press the press the MODE Hz A V MON key to switch to PU operation.) Running frequency setting Set the running frequency to 60Hz.
OPERATION/CONTROL 3.3.4 Combined operation mode (Operation using the external input signals and PU) When entering the start signal from outside the inverter and setting the running frequency from the PU (Pr. 79 = 3) The external frequency setting signals and the PU's FWD, REV and STOP keys are not accepted. (Note) Step Description Image Power-on Switch power on. ON 1 2 Operation mode selection Set "3" in Pr. 79 "operation mode selection".
CHAPTER 4 PARAMETERS This chapter explains the "parameters" of this product. The inverter is designed to perform simple variable-speed operation with the factory settings of the parameters. Set the necessary parameters according to the load and operation specifications. Always read the instructions before using the equipment. Chapter 1 Chapter 2 4.1 Parameter List ......................................................... 58 4.2 Parameter Function Details......................................
4.1 Parameter List PARAMETERS 4 PARAMETERS 4.1 Parameter List Output terminal functions Standard operation functions Basic functions Function Second functions Parameter List 4.1.
Display functions 52 DU/PU main display data selection 53 PU level display data selection 54 FM terminal function selection 55 56 Frequency monitoring reference Current monitoring reference 57 Operation selection functions Advanced magnetic flux vectorcontrol Setting Range Minimum Setting Increments Factory Setting 〈 EC Version〉〉 Refer To Page: 1 0 85 1 1 85 0 to 20, 22, 23, 24, 25, 100 0 to 3, 5 to 14, 17, 18 1 to 3, 5 to 14, 17, 18, 21 0 to 400Hz 0 to 500A 1 1 85 0.01Hz 0.
Third functions 5-point flexible V/F characteristics Function Parameter Number Communication functions PID control Commercial power supplyinverter switch-over Backlash Setting Range Minimum Setting Increments Factory Setting 〈 EC Version〉〉 Refer To Page: V/F4 (fourth frequency voltage) (Note 1) 0 to 1000V 0.1V 0 118 108 V/F5 (fifth frequency) (Note 1) 0 to 400Hz, 9999 0.01Hz 9999 118 109 V/F5 (fifth frequency voltage) (Note 1) 0 to 1000V 0.
Parameter Number Setting Range Minimum Setting Increments Factory Setting 〈 EC Version〉〉 Refer To Page: 0 to 200% 0.1% 150% 141 0 to 10 s 0.1 s 0 141 0 to 200.0% 0.1% 5.0% 142 0 to 1 s 0.01 s 0.5 s 142 0, 1 1 1 77 0, 10 0 to 31, 100, 101 0 to 25 s, 9999 1 to 3, 5 to 14, 17, 18, 21 1 1 0.1 s 0 0 0 143 143 145 1 1 85 0, 1, 10, 11 1 0 146 0, 1 1 0 89 0 to 20 s 0.
High-speed frequency control Selection Additional Stop selection Power failure stop function Sub functions Multi-speed operation function function function Programmed operation Function Stop on contact Parameter List PARAMETERS Parameter Number Name Setting Range 200 Programmed operation minute/second selection 0, 2: Minute, second 1, 3: Hour, minute 201 Program set 1 1 to 10 0-2: Rotation direction 0-400, 9999: Frequency 0-99.
Additional function Calibration functions Additional function Brake sequence functions Function Name Setting Range 0 to 30Hz 0 to 200% 0 to 2 s 285 286 287 Brake opening frequency (Note 3) Brake opening current (Note 3) Brake opening current detection time (Note 3) Brake operation time at start (Note 3) Brake operation frequency (Note 3) Brake operation time at stop (Note 3) Deceleration detection function selection (Note 3) Overspeed detection frequency Droop gain Droop filter constant Minimum Set
PARAMETERS 4.1.2 List of Parameters Classified by Purpose of Use Set the parameters according to the operating conditions. The following list indicates purpose of use and corresponding parameters. Parameter Numbers Parameter numbers which must be set Related to operation Purpose of Use Adjustment of acceleration/deceleration time and pattern Selection of optimum output characteristic for load characteristic Limit of output frequency Operation over 60Hz Pr. 1, Pr. 2 Pr. 18 Pr. 903, Pr.
PARAMETERS 4.1.3 Parameters recommended to be set by the user We recommend the following parameters to be set by the user. Set them according to the operation specifications, load, etc.
4.2 Parameter Function Details PARAMETERS 4.2 Parameter Function Details 4.2.1 Torque boost (Pr. 0, Pr. 46, Pr. 112) Related parameters Pr. 0 "torque boost" Pr. 3 "base frequency" Pr. 19 "base frequency voltage" Pr. 71 "applied motor" Pr. 80 "motor capacity" Pr. 81 "number of motor poles" Pr. 180 to Pr. 186 (input terminal function selection) Pr. 46 "second torque boost" Pr.
PARAMETERS 4.2.2 Output frequency range (Pr. 1, Pr. 2, Pr. 18) Pr. 1 "maximum frequency" Related parameters Pr. 13 "starting frequency" Pr. 903 "frequency setting voltage gain" Pr. 905 "frequency setting current gain" Pr. 2 "minimum frequency" Pr. 18 "high-speed maximum frequency" Used to clamp the upper and lower limits of the output frequency. Used for high-speed operation at or over 120Hz. " Can be used to set the upper and lower limits of motor speed.
PARAMETERS 4.2.3 Base frequency, base frequency voltage (Pr. 3, Pr. 19, Pr. 47, Pr. 113) Related parameters Pr. 3 "base frequency" Pr. 14 "load pattern selection" Pr. 71 "applied motor" Pr. 80 "motor capacity" Pr. 81 "number of motor poles" Pr. 83 "rated motor voltage" Pr. 84 "rated motor frequency" Pr. 180 to Pr. 186 (input terminal function selection) Pr. 19 "base frequency voltage" Pr. 47 "second V/F (base frequency) Pr.
PARAMETERS 4.2.4 Multi-speed operation (Pr. 4 to Pr. 6, Pr. 24 to Pr.27, Pr. 232 to Pr. 239) Related parameters Pr. 4 "multi-speed setting (high speed)" Pr. 1 "maximum frequency" Pr. 2 "minimum frequency" Pr. 15 "jog frequency" Pr. 28 "multi-speed input compensation" Pr. 29 "acceleration/deceleration pattern" Pr. 79 "operation mode selection" Pr. 180 to Pr. 186 (input terminal function selection) Pr. 5 "multi -speed setting (middle speed)" Pr. 6 "multi -speed setting (low speed)" Pr. 24 to Pr.
PARAMETERS 4.2.5 Acceleration/deceleration time (Pr. 7, Pr. 8, Pr. 20, Pr. 21, Pr. 44, Pr. 45, Pr. 110, Pr. 111) Related Relatedparameters parameters Pr. 7 "acceleration time" Pr. 3 "base frequency" Pr. 29 "acceleration/deceleration pattern" Pr. 180 to Pr. 186 (input terminal function selection) Pr. 8 "deceleration time" Pr. 20 "acceleration/deceleration reference frequency" Pr. 21 "acceleration/deceleration time increments" Pr. 44 "second acceleration/deceleration time" Pr.
PARAMETERS Note: 1. In S-shaped acceleration/deceleration pattern A (refer to page 79), the set time is a period required to reach the base frequency set in Pr. 3. • Acceleration/deceleration time calculation expression when the set frequency is the base frequency or higher 4 T 5 2 t = 9 × (Pr.
PARAMETERS 4.2.7 DC injection brake (Pr. 10, Pr. 11, Pr. 12) Related parameters Pr. 10 "DC injection brake operation frequency" Pr. 13 "starting frequency" Pr. 71 "applied motor" Pr. 11 "DC injection brake operation time" Pr. 12 "DC injection brake voltage" By setting the stopping DC dynamic brake voltage (torque), operation time and operation starting frequency, the stopping accuracy of positioning operation, etc.
PARAMETERS 4.2.8 Starting frequency (Pr. 13) Related parameters Pr. 13 "starting frequency" Pr. 2 "minimum frequency" You can set the starting frequency between 0 and 60Hz. " Set the starting frequency at which the start signal is switched on. Factory Setting Setting Range 13 0.5Hz 0 to 60Hz Output frequency (Hz) 60 Setting range Parameter Number Pr.
PARAMETERS 4.2.9 Load pattern selection (Pr. 14) Related parameters Pr. 14 "load pattern selection" Pr. 0 "torque boost" Pr. 60 "intelligent mode selection" Pr. 80 "motor capacity" Pr. 81 "number of motor poles" Pr. 180 to Pr. 186 (input terminal function selection) You can select the optimum output characteristic (V/F characteristic) for the application and load characteristics. " The output voltage changes when "4" (energy-saving mode) is set in Pr. 60 "intelligent mode selection".
PARAMETERS 4.2.10 Jog operation (Pr. 15, Pr. 16) Related parameters Pr. 15 "jog frequency" Pr. 20 "acceleration/deceleration reference frequency" Pr. 21 "acceleration/deceleration time increments" Pr. 79 "operation mode selection" Pr. 180 to Pr. 186 (input terminal function selection) Pr.
PARAMETERS 4.2.11 MRS input selection (Pr. 17) Pr. 17 "MRS input selection" Used to select the logic of the MRS signal. When the MRS signal switches on, the inverter shuts off the output. Parameter Number 17 Factory Setting 0 Setting Range 0, 2 Pr.
PARAMETERS 4.2.12 Stall prevention (Pr. 22, Pr. 23, Pr. 66, Pr. 148, Pr. 149, Pr. 154) Related parameters Pr. 48 "second stall prevention operation current" Pr. 49 "second stall prevention operation frequency" Pr. 73 "0-5V/0-10V selection" Pr. 114 "third stall prevention operation current" Pr. 115 "third stall prevention operation frequency" Pr. 156 "stall prevention operation selection" Pr. 22 "stall prevention operation level" Pr.
PARAMETERS • In Pr. 22, set the stall prevention operation level. Normally set it to 150% (factory setting). Set "0" in Pr. 22 to disable the stall prevention operation. • To reduce the stall prevention operation level in the high-frequency range, set the reduction starting frequency in Pr. 66 and the reduction ratio compensation factor in Pr. 23. Calculation expression for stall prevention operation level Pr.22-A Pr.23-100 Stall prevention operation level (%) = A + B × [ Pr.
PARAMETERS 4.2.14 Acceleration/deceleration pattern (Pr. 29, Pr. 140 to Pr. 143) Related parameters Pr. 29 "acceleration/deceleration pattern" Pr. 140 "backlash acceleration stopping frequency" Pr. 141 "backlash acceleration stopping time" Pr. 142 "backlash deceleration stopping frequency" Pr. 143 "backlash deceleration stopping time" Pr. 3 "base frequency" Pr. 7 "acceleration time" Pr. 8 "deceleration time" Pr. 20 "acceleration/deceleration reference frequency" Pr.
PARAMETERS 4.2.15 Regenerative brake duty (Pr. 30, Pr. 70) Related parameters Pr. 30 "regenerative function selection" Pr. 180 "RL terminal function selection" Pr. 181 "RM terminal function selection" Pr. 182 "RH terminal function selection" Pr. 183 "RT terminal function selection" Pr. 184 "AU terminal function selection" Pr. 185 "JOG terminal function selection" Pr. 186 "CS terminal function selection" Pr. 70 "special regenerative brake duty" " When making frequent starts/stops with a 7.
PARAMETERS Note: 1. The Pr. 70 setting is invalid for the inverter of 11K or more. 2. Pr. 70 "regenerative brake duty" indicates the %ED of the built-in brake transistor operation. Its setting should not be higher than the setting of the brake resistor used. Otherwise, the brake resistor can overheat. 3. The X10 signal may be replaced by the MRS signal. 4. When terminal assignment is changed using Pr. 180 to Pr. 186, the other functions may be affected.
PARAMETERS 4.2.17 Speed display (Pr. 37, Pr. 144) Related parameters Pr. 37 "speed display" Pr. 52 "DU/PU main display data selection" Pr. 53 "PU level display data selection" Pr. 80 "motor capacity" Pr. 81 "number of motor poles" Pr.
PARAMETERS 4.2.18 Up-to-frequency sensitivity (Pr. 41) Related parameters Pr. 41 "up-to-frequency sensitivity" Pr. 190 "RUN terminal function selection" Pr. 191 "SU terminal function selection" Pr. 192 "IPF terminal function selection" Pr. 193 "OL terminal function selection" Pr. 194 "FU terminal function selection" Pr.
PARAMETERS Output frequency (Hz) Refer to the figure below and set the corresponding parameters: • When Pr. 43 ≠ 9999, the Pr. 42 setting applies to forward rotation and the Pr. 43 setting applies to reverse rotation. Pr.42 Forward rotation Pr.50 Pr.116 Time Pr.43 Reverse rotation Pr.50 Pr.116 Output signal OFF FU,FU2,FU3 ON OFF ON OFF Output Signal Parameter Number 42 43 50 116 Output Signal FU FU2 FU3 Use Pr. 190 to Pr.
PARAMETERS • Set the stall prevention operation level in Pr. 48 and Pr. 114. • Refer to the following list to set values in Pr. 49 and Pr. 115. • Pr. 114 and Pr. 115 are made valid by switching on the X9 signal. Set "9" in any of Pr. 180 to Pr. 186 to allocate the terminal used to input the X9 signal. Pr. 49 Setting Pr. 115 Setting 0 0.01Hz to 400Hz 9999 Cannot be set. Operation Second (third) stall prevention function is not activated.
PARAMETERS Set Pr. 52 to Pr. 54 and Pr. 158 in accordance with the following table: Signal Type Display Unit Parameter Setting Pr.53 Pr.54 Pr.52 Pr.
PARAMETERS Note: 1. The monitoring of items marked × cannot be selected. 2. By setting "0" in Pr. 52, the monitoring of "output frequency to alarm display" can be selected in sequence by the SHIFT key. 3. *"Frequency setting to output terminal status" on the PU main monitor are selected by "other monitor selection" of the parameter unit (FR-PU04). 4. **The load meter is displayed in %, with the current set in Pr. 56 regarded as 100%. 5.
PARAMETERS 4.2.22 Monitoring reference (Pr. 55, Pr. 56) Related parameters Pr. 55 "frequency monitoring reference" Pr. 37 "speed display" Pr. 53 "PU level display data selection" Pr. 54 "FM terminal function selection" Pr. 158 "AM terminal function selection" Pr. 900 "FM terminal calibration" Pr. 901 "AM terminal calibration" Pr.
PARAMETERS 4.2.23 Automatic restart after instantaneous power failure (Pr. 57, Pr. 58, Pr. 162 to Pr. 165) Pr. 57 "restart coasting time" Pr. 58 "restart cushion time" Pr.162 "Automatic restart after instantaneous power failure selection" Pr.163 "First cushion time for restart" Pr.164 "First cushion voltage for restart" Pr.
PARAMETERS Refer to the above figures and following table, and set the parameters: Parameter Number Setting 0 162 1 0 0.4K to 1.5K 2.2K to 7.5K 11K or more 57 0.1 to 5 s 9999 58 163 164 165 0 to 60 s 0 to 20 s 0 to 100% 0 to 200% Description Frequency search made Frequency search is made after detection of an instantaneous power failure. No frequency search Independently of the motor coasting speed, the output voltage is gradually increased with the frequency kept as preset. 0.
PARAMETERS 4.2.24 Remote setting function selection (Pr. 59) Related parameters Pr. 59 "remote setting function selection" Pr. 1 "maximum frequency" Pr. 7 "acceleration time" Pr. 8 "deceleration time" Pr. 18 "high-speed maximum frequency" Pr. 28 "multi-speed input compensation" Pr. 44 "second acceleration/deceleration time" Pr.
PARAMETERS Note: 1. The frequency can be varied by RH (acceleration) and RM (deceleration) between 0 and the maximum frequency (Pr. 1 or Pr. 18 setting). 2. When the acceleration or deceleration signal switches on, the set frequency varies according to the slope set in Pr. 44 or Pr. 45. The output frequency acceleration/deceleration times are as set in Pr. 7 and Pr. 8, respectively. Therefore, the longer preset times are used to vary the actual output frequency. 3.
PARAMETERS Pr. 60 Setting Operation Mode Description Automatically Set Parameters 0 Ordinary operation mode 1, 2 Shortest acceleration/ deceleration mode 3 Optimum acceleration/ deceleration mode (Note 2, 4) 4 Energy-saving mode (Note 3, 5) 5, 6 Elevator mode (Note 3) 7 Brake sequence mode 8 Set to accelerate/decelerate the motor in the shortest time. The inverter makes acceleration/deceleration in the shortest time using its full capabilities.
PARAMETERS 4.2.26 Acceleration/deceleration reference current/lift mode starting frequency (Pr. 61 to Pr. 64) Related parameter Pr. 61 "reference I for intelligent mode" Pr. 60 "intelligent mode selection" Pr. 62 "ref. I for intelligent mode accel." Pr. 63 "ref. I for intelligent mode decel." Pr. 64 "starting frequency for elevator mode" ! Set these parameters to improve performance in the intelligent mode.
PARAMETERS 4.2.27 Retry function (Pr. 65, Pr. 67 to Pr. 69) Pr. 65 "retry selection" Pr. 67 "number of retries at alarm occurrence" Pr. 68 "retry waiting time" Pr. 69 "retry count display erasure" When an alarm occurs, the retry function causes the inverter to automatically reset itself to make a restart and continue operation. You can select whether retry is made or not, alarms reset for retry, number of retries made, and waiting time.
PARAMETERS • Use Pr. 67 to set the number of retries at alarm occurrence. Pr. 67 Setting 0 1 to 10 101 to 110 Number of Retries Retry is not made. 1 to 10 times 1 to 10 times Alarm Signal Output Not output. Output. • Use Pr. 68 to set the waiting time from when an inverter alarm occurs until a restart in the range 0 to 10 seconds. • Reading the Pr. 69 value provides the cumulative number of successful restart times made by retry. The setting of "0" erases the cumulative number of times. Note: 1.
PARAMETERS 4.2.28 Applied motor (Pr. 71) Related parameters Pr. 71 "applied motor" Pr. 0 "torque boost" Pr. 12 "DC injection brake voltage" Pr. 19 "base frequency voltage" Pr. 60 "intelligent mode selection" Pr. 80 "motor capacity" Pr. 81 "number of motor poles" Pr. 96 "auto tuning setting/status" Pr. 100 to Pr. 109 (V/F frequency/voltage) Set the motor used.
PARAMETERS 4.2.29 PWM carrier frequency (Pr. 72, Pr. 240) Pr. 72 "PWM frequency selection" Pr. 240 "Soft-PWM setting" You can change the motor tone. ! By parameter setting, you can select Soft-PWM control which changes the motor tone. ! Soft-PWM control changes motor noise from a metallic tone into an unoffending complex tone. Parameter Number 72 240 Factory Setting 2 1 Setting Range 0 to 15 0, 1 Remarks 0: 0.7kHz, 15: 14.
PARAMETERS 4.2.30 Voltage input (Pr. 73) Related parameters Pr. 73 "0-5V/0-10V selection" Pr. 22 "stall prevention operation level" Pr. 903 "frequency setting voltage gain" Pr. 905 "frequency setting current gain" You can select the analog input terminal specifications, the override function and the function to switch between forward and reverse rotation depending on the input signal polarity. Parameter Number 73 Factory Setting 1 Setting Range 0 to 5, 10 to 15 Pr.
PARAMETERS 4.2.31 Input filter time constant (Pr. 74) Pr. 74 "filter time constant" You can set the input section's internal filter constant for an external voltage or current frequency setting signal. ! Effective for eliminating noise in the frequency setting circuit. ! Increase the filter time constant if steady operation cannot be performed due to noise. A larger setting results in lower response. (The time constant can be set between approximately 1ms to 1s. with the setting of 0 to 8.
PARAMETERS How to make a restart after a stop made by the external operation STOP RESET key from the PU during (1) Operation panel (FR-DU04) 1) After completion of deceleration to a stop, switch off the STF or STR signal. 2) Press the MODE key three times* to call the Note: When Pr. 79 = "3", press the MODE indication. (Note 8) key three times to display , then press the key and proceed to step 3). (*: For monitor screen) .......
PARAMETERS 4.2.33 Alarm code output selection (Pr. 76) Related parameters Pr. 76 "alarm code output selection" Pr. 79 "operation mode selection" Pr. 190 to Pr. 195 (multi-function outputs) Pr. 200 to Pr. 231 (programmed operation) When an alarm occurs, its code can be output as a 4-bit digital signal from the open collector output terminals. When programmed operation has been selected, this parameter also serves to output a group operation signal.
PARAMETERS 4.2.34 Parameter write inhibit selection (Pr. 77) Pr. 77 "parameter write disable selection" Related parameters Pr. 79 "operation mode selection" You can select between write-enable and disable for parameters. This function is used to prevent parameter values from being rewritten by accident. Parameter Number 77 Factory Setting 0 Setting Range 0, 1, 2 Pr. 77 Setting 0 1 2 Function Write enabled during a stop only.
PARAMETERS 4.2.35 Reverse rotation prevention selection (Pr. 78) Pr. 78 "reverse rotation prevention selection" Related parameters Pr. 79 "operation mode selection" This function can prevent any reverse rotation fault resulting from the misoperation of the start signal. ! Used for a machine which runs only in one direction, e.g. fan, pump. (The setting of this function is valid for the PU, external and communication operations.) Parameter Number 78 Factory Setting 0 Setting Range 0, 1, 2 Pr.
PARAMETERS 4.2.36 Operation mode selection (Pr. 79) Related parameters Pr. 79 "operation mode selection" Pr. Pr.1515"jog "jogfrequency" frequency" Pr. 4 to Pr. 6, Pr. 4 to Pr. 6,Pr. Pr.2424toto27, 27,Pr.232 Pr.232toto Pr.239 Pr.239 (multi-speed "multi-speedoperation) operation" Pr. 76 Pr. 76"alarm "alarmcode codeoutput outputselection" selection" Pr. 180 to Pr. 186 Pr. 180 to Pr. 186 (input (inputterminal terminalfunction functionselection) selection) Pr. 200 to Pr. 231 Pr. 200 to Pr.
PARAMETERS (2) Switch-over mode You can select between PU operation, external operation and computer link operation (when FR-A5NR option is used). Operation Mode Switching External operation to PU operation External operation to computer link operation PU operation to external operation PU operation to computer link operation Computer link operation to external operation Computer link operation to PU operation Switching Operation/Operating Status 1) Select the PU operation mode.
PARAMETERS Operating Condition Operation mode PU Status During stop ON → OFF (Note 3) During operation ON → OFF (Note 3) During stop External X12 (MRS) Signal During operation OFF → ON ON → OFF OFF → ON ON → OFF Operation Mode (Note 4) External Operating Status Parameter Write Switching to PU Operation Mode During stop Allowed → disallowed Disallowed If external operation frequency setting and start signal are entered, o
PARAMETERS 4.2.37 Motor capacity/number of motor poles/speed control gain (Pr. 80, Pr. 81, Pr. 89) Related parameters Pr. 80 "motor capacity" Pr. 81 "number of motor poles" Pr. 89 "speed control gain" You can set the advanced magnetic flux vector control. ! Advanced magnetic flux vector control Provides large starting torque and sufficient low-speed torque. Effective for great load fluctuation. Parameter Number 80 81 89 Factory Setting 9999 9999 100% Pr. 71 "applied motor" Pr.
PARAMETERS Note: 1. Speed fluctuation is slightly greater than in the V/F control. (Advanced magnetic flux vector control may not be suitable for machines which attach importance to little speed fluctuation at low speed, e.g. grinders, lapping machines.) 2. When the surge voltage suppression filter (FR-ASF-H) is used between the inverter and motor, output torque may reduce. 3. When the terminal functions are changed using Pr. 180 to Pr. 186, the other functions may be affected.
PARAMETERS When you use the advanced magnetic flux vector control, you can perform the offline auto tuning operation to calculate motor constants automatically. ! Offline auto tuning is made valid only when other values than "9999" are set in Pr. 80 and Pr. 81 to select the advanced magnetic flux vector control. ! The offline tuning data (motor constants) can be copied to another inverter with the PU (FR-DU04/ FR-PU04). ! If the motor used is not Mitsubishi's standard motor (SF-JR 0.
PARAMETERS • • • • • The motor is connected. The motor capacity is equal to or one rank lower than the inverter capacity. (0.4kW or more) The maximum frequency is 120Hz. Special motors such as high-slip motor and high-speed motor cannot be tuned. When "101" (offline auto tuning with motor running) is set in Pr. 96, note the following: 1) Torque may not be enough during tuning. 2) The motor may be run at nearly its rated frequency (Pr. 84 setting) without problem.
PARAMETERS $ Parameter details Parameter Number 9 Setting Description 0 to 500A 0 Set the rated motor current (A). Electronic overcurrent protection thermal characteristics suitable for standard motor Electronic overcurrent protection thermal characteristics suitable for Mitsubishi's constant-torque motor Electronic overcurrent protection thermal characteristics suitable for standard motor 5-point flexible V/F characteristics Mitsubishi's SF-JR4P standard motor (1.
PARAMETERS (3) Monitoring the offline tuning status When the parameter unit (FR-PU04) is used, the Pr. 96 value is displayed during tuning on the main monitor as shown below. When the operation panel (FR-DU04) is used, only the same numerical value as on the PU is displayed: • Parameter unit (FR-PU04) main monitor (For inverter trip) 2. Tuning in progress 1. Setting TUNE 1 STOP PU TUNE 3 COMPLETION STF STOP PU PU TUNE 103 COMPLETION STF STOP PU 2 STF FWD PU 3.
PARAMETERS 5) When tuning was forced to end A forced end occurs when tuning is forced to end by pressing the STOP RESET key or turning off the start signal (STF or STR) during tuning. In this case, offline auto tuning was not brought to a normal end. (The motor constants are not yet set.) Reset the inverter and restart tuning. Note: 1. The motor constants measured once in the offline auto tuning are stored as parameters and their data is held until the offline auto tuning is performed again. 2.
PARAMETERS Note: 1. Pr. 82 and Pr. 90 to Pr. 94 values may only be read when the Pr. 80 and Pr. 81 settings are other than "9999" (advanced magnetic flux vector control selected). 2. Set "9999" in Pr. 90 to Pr. 94 to use the standard motor constants (including those for the constant-torque motor). 3. Set "3" (standard motor), "13" (constant-torque motor) or "23" (Mitsubishi standard motor SF-JR 4P (1.5kW (2HP) or less)) in Pr. 71 to use the constants measured in the offline auto tuning.
PARAMETERS ! To enter the Pr. 92 and Pr. 93 motor constants in [mH] 1. Set any of the following values in Pr. 71: • Standard motor....................................................................................... Pr. 71 = "0" • Constant-torque motor ........................................................................... Pr. 71 = "1" • Mitsubishi standard motor SF-JR 4 poles (1.5kW (2HP) or less) .......... Pr. 71 = "20" 2. Set "801" in Pr. 77. (Only when the Pr. 80 and Pr.
PARAMETERS Parameter Number 95 Factory Setting 0 Setting Range Remarks 0, 1 1: Online auto tuning • Data required for online auto tuning is calculated in offline auto tuning. Before starting the operation of this function, always execute the offline auto tuning once more. The offline auto tuning is also required for use of the Mitsubishi standard motor (SF-JR) or constant-torque motor (SF-JRCA). • Offline auto tuning should be carried out with "101" (motor running) set in Pr.
PARAMETERS 4.2.40 V/F control frequency (voltage) (Pr. 100 to Pr. 109) Related parameters Pr. 100 "V/F1 (first frequency)" Pr. 19 "base frequency voltage" Pr. 47 "second V/F (base frequency)" Pr. 60 "intelligent mode selection" Pr. 71 "applied motor" Pr. 113 "third V/F (base frequency)" Pr. 101 "V/F1 (first frequency voltage)" Pr. 102 "V/F2 (second frequency)" Pr. 103 "V/F2 (second frequency voltage)" Pr. 104 "V/F3 (third frequency)" Pr. 105 "V/F3 (third frequency voltage)" Pr.
PARAMETERS (2) Set the desired frequencies and voltages in Pr. 100 to Pr. 109. • The setting must satisfy the following relationship: F1≠F2≠F3≠F4≠F5≠Pr. 3 "base frequency". If the set frequencies are the same, a write error occurs. If any frequency setting is "9999", its point is ignored. Note: 1. The V/F 5-point flexible characteristic functions for V/F control only. It does not function for advanced magnetic flux vector control. 2. The V/F 5-point flexible characteristic does not function when Pr.
PARAMETERS ! For the data codes of the parameters, refer to the data code list in the appendices. REMARKS For computer link operation, set the value "8888" as 65520 (HFFF0) and the value "9999" as 65535 (HFFFF). Parameter Number 117 118 Factory Setting 0 192 119 1 120 121 122* 123 124 342 2 1 0 <9999> 9999 1 0 Setting Range 0 to 31 48, 96, 192 Data length 8 0, 1 Data length 7 10, 11 0, 1, 2 0 to 10, 9999 0, 0.1 to 999.
PARAMETERS (1) Communication protocol Data communication between the computer and inverter is performed using the following procedure: Data read Computer ↓ (Data flow) *2 Time Inverter ↓ 5) 4) 1) Inverter 2) 3) *1 (Data flow) Data write Computer *1. If a data error is detected and a retry must be made, execute retry operation from the user program. The inverter comes to an alarm stop if the number of consecutive retries exceeds the parameter setting. *2.
PARAMETERS Note: 1. The inverter station numbers may be set between H00 and H1F (stations 0 and 31) in hexadecimal. 2. *3 indicates the control code. 3. *4 indicates the CR or LF code. When data is transmitted from the computer to the inverter, codes CR (carriage return) and LF (line feed) are automatically set at the end of a data group on some computers. In this case, setting must also be made from the inverter according to the computer.
PARAMETERS 5) Waiting time Specify the waiting time between the receipt of data at the inverter from the computer and the transmission of reply data. Set the waiting time in accordance with the response time of the computer between 0 and 150ms in 10ms increments (e.g. 1 = 10ms, 2 = 20ms). Computer ↓ Inverter Inverter data processing time =waiting time + data check time (set value×10ms) (12ms) Inverter ↓ Computer Note : When Pr.
PARAMETERS 7) Sum check code The sum check code is 2-digit ASCII (hexadecimal) representing the lower 1 byte (8 bits) of the sum (binary) derived from the checked ASCII data. Computer→Inverter ENQ Station number ASCII code→ H05 H30 H31 0 Instruction code 1 E *Waiting time (Example1) 1 H45 H31 1 Sum check code Data 0 H31 H30 7 A H37 H41 D F H44 H46 4 ←Binary code H34 ↓ H H H H H H H H H 30 + 31 + 45 + 31 + 31 + 30 + 37 + 41 + 44 H =1F4 Sum *When Pr.
PARAMETERS (5) Instructions for the program 1) When the operation mode is switched to communication operation. 2) Since any data communication, such as operation command or monitoring, is always requested by the computer, the inverter will not return data without the computer's request. Hence, design the program so that the computer gives a data read request for monitoring, etc. as required.
PARAMETERS After completion of parameter setting, set the instruction codes and data and start communication from the computer to allow various types of operation control and monitoring. No.
PARAMETERS No. Instruction Code Item b7 0 b0 0 0 0 0 0 1 (For example 1) 3 Run command HFA Number of Data Digits Description [Example 1] H02 ... Forward rotation [Example 2] H00 ... Stop 0 b0: b1: Forward rotation (STF) b2: Reverse rotation (STR) b3: b4: b5: b6: b7: 2 digits b0: Inverter running (RUN) * b1: Forward rotation (STF) 0 0 0 0 0 0 1 0 b2: Reverse rotation (STR) (For example 1) b3: Up to frequency (SU) * b4: Overload (OL) * [Example 1] H02 b5: Instantaneous power ...
PARAMETERS No.
PARAMETERS (6) Communication specifications for RS-485 communication Operation Mode Operation Location Communication Operation from PU Connector Enable Item Run command (start) Computer user program via PU connector Computer user program via inboard option Control circuit terminal Running frequency setting Enable Monitoring Parameter write Parameter read Inverter reset Stop command (*3) Run command Running frequency setting Monitoring Parameter write Parameter read Inverter reset Stop command (*3) I
PARAMETERS 4.2.42 PID control (Pr. 128 to Pr. 134) Related parameters Pr. 128 "PID action selection" Pr. 73 "0-5V/0-10V selection" Pr. 79 "operation mode selection" Pr. 180 to Pr. 186 (input terminal assignment) Pr. 190 to Pr. 195 (output terminal assignment) Pr. 902 to Pr. 905 (frequency setting voltage (current) biases and gains) Pr. 129 "PID proportional band" Pr. 130 "PID integral time" Pr. 131 "upper limit" Pr. 132 "lower limit" Pr. 133 "PID action set point for PU operation" Pr.
PARAMETERS 2) PD action A combination of proportional control action (P) and differential control action (D) for providing a manipulated variable in response to deviation speed to improve the transient characteristic. [Operation example for proportional changes of process value] Note: PD action is the sum of P and D actions.
PARAMETERS (3) Wiring example " " " " " Sink logic Pr. 183 = 14 Pr. 192 = 16 Pr. 193 = 14 Pr.
PARAMETERS (4) I/O signals Input X14 Terminal Used Depending on Pr. 180 to Pr. 186 2 2 1 1 4 4 FUP Output FDN Upper limit output Depending on Pr. 191 to Pr. 195 RL SE Function PID control selection Set point input Deviation signal input Process value input SE Lower limit output Forward (reverse) rotation direction output Output terminal common Description Switch on X14 to select PID control. Remarks Set any of "10, 11, 20 and 21" in Pr. 128. Enter the set point for PID control.
PARAMETERS (5) Parameter setting Parameter Number Setting Name Description For heating, pressure control, etc. 10 11 PID action selection 128 20 21 129 0.1 to 1000% PID proportional band 9999 130 0.1 to 3600 s PID integral time 9999 131 0 to 100% Upper limit 9999 132 0 to 100% Lower limit 9999 133 134 PID action set point for PU operation 0 to 100% 0.01 to 10.00 s PID differential time 9999 PID reverse action PID forward For cooling, etc.
PARAMETERS (7) Calibration example (A detector of 4mA at 0°C and 20mA at 50°C is used to adjust the room temperature to 25°C under PID control. The set point is given to across inverter terminals 2-5 (0-5V).) START Determine the set point. &&&&&&Set the room temperature to 25°C. Set Pr. 128 and switch on the X14 signal to enable PID control. Determine the set point of the item to be adjusted. Convert the set point into %. Calculate the ratio of the set point to the detector output. Make calibration.
PARAMETERS 1. Apply the input voltage of 0% set point setting (e.g. 0V) to across terminals 2-5. 2. Make calibration using Pr. 902. At this time, enter the frequency which should be output by the inverter at the deviation of 0% (e.g. 0Hz). 3. Apply the voltage of 100% set point setting (e.g. 5V) to across terminals 2-5. 4. Make calibration using Pr. 903. At this time, enter the frequency which should be output by the inverter at the deviation of 100% (e.g. 60Hz).
PARAMETERS 4.2.43 Commercial power supply-inverter switch-over function (Pr. 135 to Pr. 139) Pr. 135 "commercial power supply-inverter switch-over sequence output terminal selection" Pr. 136 "MC switch-over interlock time" Pr. 137 "start waiting time" Pr. 138 "commercial power supply-inverter switch-over selection at alarm occurrence" Related parameters Pr. 11 "DC injection brake operation time" Pr. 57 "restart coasting time" Pr. 58 "restart cushion time" Pr. 180 to Pr.
PARAMETERS • Roles of the magnetic contactors (MC1, MC2, MC3) Magnetic Contactor Place of Installation power supply Role MC1 Between inverter and MC2 Between power supply and motor MC3 Between inverter output and motor Normally shorted with the following exception: Opened only when an inverter fault occurs (shorted again by resetting) Shorted for commercial power supply operation, opened for inverter operation Shorted when an inverter fault occurs (selected with parameter, except for external the
PARAMETERS (2) Parameter setting Parameter Number 135 Name Setting Description 0 Commercial power supply-inverter switch-over sequence output terminal selection 1 136 MC switch-over interlock time 0 to 100.0 s 137 Start waiting time 0 to 100.0 s 138 Commercial power supply-inverter switch-over selection at alarm occurrence 139 Automatic invertercommercial power supply switch-over frequency 0 1 0 to 60.0Hz 9999 Sequence output is not provided. (Pr. 136, Pr. 137, Pr. 138 and Pr.
PARAMETERS (3) Operation procedure 1) Operation procedure for running Operation pattern Switch power on. # Pr. 135 = "1" (inverter's open collector output terminals) # Pr. 136 = "2.0 s" # Pr. 137 = "1.0 s" (Set the value equal to or longer than the time from when MC3 switches on actually until the inverter and motor are connected. If it is shorter, restart may not function properly.) # Pr. 57 = "0.5 s" # Pr. 58 = "0.
PARAMETERS 4.2.44 Output current detection function (Pr. 150, Pr. 151) Related parameters Pr. 150 "output current detection level" Pr. 190 to Pr. 195 (output terminal function selection) Pr. 151 "output current detection period" " If the output current remains higher than the Pr. 150 setting during inverter operation for longer than the time set in Pr. 151, the output current detection signal (Y12) is output from the inverter's open collector output terminal. (Use any of Pr. 190 to Pr.
PARAMETERS 4.2.45 Zero current detection (Pr. 152, Pr. 153) Related parameters Pr. 152 "zero current detection level" Pr. 190 to Pr. 195 (output terminal function selection) Pr. 153 "zero current detection period" When the inverter's output current falls to "0", torque will not be generated. This may cause a gravity drop when the inverter is used in vertical lift application.
PARAMETERS Pr. 154 ' Refer to Pr. 22. 4.2.46 RT signal activated condition selection (Pr. 155) Related parameters Pr. 155 "RT signal activated condition" Pr. 14 "load pattern selection" Pr. 44 to Pr. 49 (second function selection) Pr. 81 "number of motor poles" Pr. 180 to Pr. 186 (input terminal function selection) " Set the condition of activating the RT terminal to select the second control functions by switching on-off the RT signal.
PARAMETERS Refer to the following table and set the parameter as required: Pr. 156 Setting 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 100 101 (Note 3) Driving Regenerative Driving Regenerative Fast-Response Current Limit !...Activated "...Not activated ! " ! " ! " ! " ! " ! " ! " ! " ! " Stall Prevention Operation Selection !...Activated "...
PARAMETERS 4.2.48 OL signal output timer (Pr. 157) Related parameters Pr. 157 "OL signal waiting time" Pr. 190 "RUN terminal function selection" Pr. 191 "SU terminal function selection" Pr. 192 "IPF terminal function selection" Pr. 193 "OL terminal function selection" Pr. 194 "FU terminal function selection" Pr.
PARAMETERS 4.2.49 User group selection (Pr. 160, Pr. 173 to Pr. 176) Pr. 160 "user group read selection" Pr. 173 "user group 1 registration" Pr. 174 "user group 1 deletion" Pr. 175 "user group 2 registration" Pr. 176 "user group 2 deletion" • Pr. 160 "user group read selection" is used to limit the parameters which may be read. • From among all parameters, a total of 32 parameters can be registered to two different user groups. The registered parameters may only be accessed for reading and writing.
PARAMETERS Pr. 162 to Pr. 165 ' Refer to Pr. 57. 4.2.50 Watt-hour meter clear/actual operation hour meter clear (Pr. 170, Pr. 171) Related parameter Pr. 170 "watt-hour meter clear" Pr. 171 "actual operation hour meter clear" Pr. 52 "DU/PU main display data selection" You can clear the watt-hour value and actual operation hour monitoring function. Parameter Number 170 171 Factory Setting 0 0 Setting Range 0 0 Write "0" in the parameters to clear the watt-hour value and actual operation hour.
PARAMETERS Refer to the following list and set the parameters: Setting Signal Name Functions Relevant Parameters Low-speed operation command Pr. 59 = 0 0 RL Pr. 59 = 1, 2 * Pr. 79 = 5 * Pr. 270 = 1, 3 * Pr. 59 = 0 1 RM Pr. 59 = 1, 2 * Pr. 79 = 5 * RH Stop-on-contact selection 0 Middle-speed operation command Remote setting (deceleration) Programmed operation group selection High-speed operation command Pr.
PARAMETERS Note: 1. One function can be assigned to two or more terminals. In this case, the terminal inputs are OR’ed. 2. The speed command priorities are higher in order of jog, multi-speed setting (RH, RM, RL) and AU. 3. When HC connection (inverter operation enable signal) is not selected, the MRS terminal shares this function. 4. When advanced magnetic flux vector-V/F switch-over and load pattern selection forward/reverse rotation boost are not selected, the second functions (RT) share these functions.
PARAMETERS 4.2.52 Output terminal function selection (Pr. 190 to Pr. 195) Pr. 190 "RUN terminal function selection" Pr. 191 "SU terminal function selection" Pr. 192 "IPF terminal function selection" Pr. 193 "OL terminal function selection" Pr. 194 "FU terminal function selection" Pr. 195 "A, B, C terminal function selection" You can change the functions of the open collector and contact output terminals.
PARAMETERS Setting Positive Negative logic logic Signal Name Function Commercial power supplyinverter switch-over MC1 Commercial power supplyinverter switch-over MC2 Commercial power supplyinverter switch-over MC3 17 MC1 18 MC2 19 MC3 20 120 BOF Brake opening request 25 125 FAN Fan fault output 26 126 FIN Fin overheat pre-alarm 27 28 29 30 31 32 33 127 128 129 130 131 132 133 ORA ORM Y29 Y30 Y31 Y32 RY2 98 198 LF 99 199 ABC Alarm output No function 9999 In-po
PARAMETERS 4.2.53 User initial value setting (Pr. 199) Related parameter Pr. 199 "user's initial value setting" Pr. 77 "parameter write disable selection" Among the parameters, you can set user-only parameter initial values. These values may be set to 16 parameters. By performing user clear operation from the operation panel or parameter unit, you can initialize the parameters to the user-set initial values.
PARAMETERS 4.2.54 Programmed operation function (Pr. 200 to Pr. 231) Related parameters Pr. 200 "programmed operation minute/second selection" Pr. 76 "alarm code output selection" Pr. 79 "operation mode selection" Pr. 201 to Pr. 210 "program set 1 1 to 10" Pr. 211 to Pr. 220 "program set 2 11 to 20" Pr. 221 to Pr. 230 "program set 3 21 to 30" Pr.
PARAMETERS (1) Set the time unit for programmed operation in Pr. 200. Select either of "minute/second" and "hour/minute". Setting 0 1 2 3 Description Minute/second unit (voltage monitor) Hour/minute unit (voltage monitor) Minute/second unit (reference time of day monitor) Hour/minute unit (reference time of day monitor) Note: 1. When "2" or "3" is set in Pr. 200, the reference time-of-day monitor screen is displayed instead of the voltage monitor screen. 2. Note that when the Pr.
PARAMETERS (Example: Set point No. 1, forward rotation, 30Hz, 4 hours 30 minutes) 1) Read Pr. 201 value. 2) Enter "1" (forward rotation) in Pr. 201 and press the SET key ( WRITE key when using the FR-PU04 parameter unit). 3) Enter 30 (30Hz) and press the SET 4) Enter "4.30" and press the key ( WRITE key when using the FR-PU04 parameter unit). (Note 2) 5) Press the SET key ( WRITE key when using the FR-PU04 parameter unit). (Note 1) key to move to the next parameter (Pr.
PARAMETERS (6) Operation 1) Ordinary operation After completion of all preparations and settings, turn on the desired group select signal (any of RH (group 1), RM (group 2) and RL (group 3)), then turn on the start signal (STF). This causes the internal timer (reference time of day) to be reset automatically and the operation of that group to be performed in sequence in accordance with the settings. When the operation of the group ends, a signal is output from the time-out output terminal.
PARAMETERS Pr. 232 to Pr. 239 ' Refer to Pr. 4. Pr. 240 ' Refer to Pr. 72. 4.2.55 Cooling fan operation selection (Pr. 244) Pr. 244 "cooling fan operation selection" You can control the operation of the cooling fan built in the inverter (200V class... 1.5K or more, 400V class... 2.2K or more). Parameter Number 244 Factory Setting Setting Range 0 0, 1 Setting 0 1 Description Operated at power on (independently of whether the inverter is running or at a stop).
PARAMETERS 4.2.56 Stop selection (Pr. 250) Related parameters Pr. 250 "stop selection" Pr. 7 "acceleration time" Pr. 8 "deceleration time" Pr. 44 "second acceleration/deceleration time" Pr. 45 "second deceleration time" Pr. 110 "third acceleration/deceleration time" Pr. 111 "third deceleration time" Used to select the stopping method (deceleration to a stop or coasting) when the start signal (STF/STR) switches off. Parameter Number 250 Factory Setting 9999 Setting Range 0 to 100 s, 9999 (1) Pr.
PARAMETERS 4.2.57 Output phase failure protection selection (Pr. 251) Pr. 251 "Output phase failure protection selection" You can make invalid the output phase failure protection (E.LF) function which stops the inverter output if one of the three phases (U, V, W) on the inverter's output side (load side) becomes open.
PARAMETERS 4.2.59 Power failure-time deceleration-to-stop function (Pr. 261 to Pr. 266) Related parameters Pr. 261 "power failure stop selection" Pr. 12 "DC dynamic brake voltage" Pr. 20 "acceleration/deceleration reference frequency" Pr. 262 "subtracted frequency at deceleration start" Pr. 263 "subtraction starting frequency" Pr. 264 "power-failure deceleration time 1" Pr. 265 "power-failure deceleration time 2" Pr.
PARAMETERS Note: 1. This function is invalid when the automatic restart after instantaneous power failure function is activated. 2. If (output frequency at occurrence of undervoltage or power failure) minus (frequency set in Pr. 263) is negative, the calculation result is regarded as 0Hz. 3. The power failure stop function is not activated during a stop or error. 4. If power is restored during deceleration, the inverter is kept decelerating to a stop.
PARAMETERS 4.2.61 High-speed frequency control (Pr. 271 to Pr. 274) Related parameters Pr. 271 "high-speed setting maximum current" Pr. 4 "multi-seed setting (high speed)" Pr. 5 "multi-seed setting (middle speed)" Pr. 6 "multi-seed setting (low speed)" Pr. 59 "remote setting function selection" Pr. 180 to Pr. 186 (input terminal function selection) Pr. 272 "mid-speed setting minimum current" Pr. 273 "current averaging range" Pr.
PARAMETERS Power running A Pr.4 Regenerating B Pr.5 1 2 Pr.5 × Pr.5 1 2 Less than Pr. 271 setting × Pr.5 rated current Pr. 272 setting rated current or more ON Terminal OFF STF (STR) CS • When operation is performed with X19 (load detection high-speed frequency function selection) signal on, the inverter automatically varies the maximum frequency between Pr. 4 “multi-speed setting (high speed)” and Pr.
PARAMETERS Note: 1. This function is only valid in the external operation mode. This function is not activated when "1" or "2" (remote setting function) is selected for Pr. 59. 2. If the current averaging zone range the constant power region, the output current may increase in the constant power region. 3. When the average current within the current averaging range is small, the running frequency increases, which causes the longer deceleration time. 4. The maximum output frequency is 120Hz.
PARAMETERS ! Function list (The following specifications apply to the external operation mode.) Pr. 270 Setting 0 1 2 3 Load Torque High-Speed Frequency Control Stop-On-Contact Control Multi-Speeds (7 speeds) × " " " " × × " " " " × ": Indicates that the function is valid. ! Restrictions when 1 to 3 are selected for Pr. 270 Under the following conditions, the functions of Pr.
PARAMETERS 4.2.62 Stop on contact (Pr. 275, Pr. 276) Related parameters Pr. 275 "stop-on-contact exciting current low-speed multiplying factor" Pr. 4 "multi-seed setting (high speed)" Pr. 5 "multi-seed setting (middle speed)" Pr. 6 "multi-seed setting (low speed)" Pr. 48 "second stall prevention operation current" Pr. 72 "PWM carrier frequency" Pr. 180 to Pr. 186 (input terminal function selection) Pr. 270 "stop-on-contact, load torque high-speed frequency selection" Pr.
PARAMETERS Note: 1. By increasing the Pr. 275 setting, the low-speed (stop-on-contact) torque increases, but the overcurrent alarm (E.OCT) may occur or the machine may oscillate in a stop-on-contact state. 2. The stop-on-contact function is different from the servo lock function, and if used to stop or hold a load for an extended period, the function can cause the motor to overheat. After a stop, immediately reset this function and use a mechanical brake to hold the load. 3.
PARAMETERS Frequencies set in stop-on-contact control (Pr. 270 = 1 or 3) (In external operation mode) The following table lists the frequencies set when the input terminals (RH, RM, RL, RT, JOG) are selected together.
PARAMETERS 4.2.63 Brake sequence function (Pr. 278 to Pr. 285) Related parameters Pr. 278 "brake opening frequency" Pr. 60 "intelligent mode selection" Pr. 80 "motor capacity" Pr. 81 "number of motor poles" Pr. 180 to Pr. 186 (input terminal function selection) Pr. 190 to Pr. 195 (output terminal function selection) Pr. 279 "brake opening current" Pr. 280 "brake opening current detection time" Pr. 281 "brake operation time at start" Pr. 282 "brake operation frequency" Pr.
PARAMETERS ! At start: When the start signal is input to the inverter, the inverter starts running. When the output frequency reaches the value set in Pr. 278 and the output current is not less than the value set in Pr. 279, the inverter outputs the brake opening request signal (BOF) after the time set in Pr. 280 has elapsed. When the time set in Pr. 281 elapses after the brake opening completion signal (BRI) was activated, the inverter increases the output frequency to the set speed.
PARAMETERS (1) Parameter setting 1) Select advanced magnetic flux vector control. (Pr. 80, Pr. 81 •"9999") 2) Set "7 or 8" (brake sequence mode) in Pr. 60. To ensure more complete sequence control, it is recommended to set "7" (brake opening completion signal input) in Pr. 60. Note that the automatic restart after instantaneous power failure function is not activated when the brake sequence mode is selected.
PARAMETERS (3) Protective functions If any of the following errors occur in the brake sequence mode, the inverter results in an alarm, shuts off the output and switches off the brake opening request signal (BOF terminal). On the operation panel (FR-DU04) LED and parameter unit (FR-PU04) screen, the following errors are displayed: Error Display E.MB1 E.MB2 E.MB3 E.MB4 E.MB5 E.MB6 E.MB7 Error Display (Detected frequency) - (output frequency) > Pr. 286 in the PLG feedback control mode.
PARAMETERS 4.2.64 Droop control (Pr. 286, Pr. 287) Related parameters Pr. 286 "Droop gain" Pr. 9 "Electronic thermal O/L relay" Pr. 71 "Applied motor" Pr. 84 "Rated motor frequency" Pr. 287 "Droop filter constant" This function balances the load in proportion to the load torque with or without PLG, and provides speed drooping characteristics. This is effective in balancing the load when using multiple inverters.
PARAMETERS 4.2.65 Meter (frequency meter) calibration (Pr. 900, Pr. 901) Related parameters Pr. 900 "FM terminal calibration" Pr. 54 "FM terminal function selection" Pr. 55 "frequency monitoring reference" Pr. 56 "current monitoring reference" Pr. 158 "AM terminal function selection" Pr. 901 "AM terminal calibration" ! By using the operation panel/parameter unit, you can calibrate a meter connected to terminal FM to full scale. ! Terminal FM provides the pulse output. By setting Pr.
PARAMETERS • When operation panel (FR-DU04) is used 1) Select the PU operation mode. 2) Set the running frequency. 3) Press the SET key. 4) Read Pr. 900 "FM terminal calibration" or Pr. 901 "AM terminal calibration". 5) Press the FWD key to run the inverter. (Motor need not be connected.) 6) Hold down the key to adjust the meter pointer to the required position. (Depending on the setting, the pointer may take some time to move.
PARAMETERS 4.2.66 Frequency setting voltage (current) bias and gain (Pr. 902 to Pr. 905) Related parameters Pr. 902 "frequency setting voltage bias" Pr. 20 "acceleration/deceleration reference frequency" Pr. 73 "0-5V/0-10V selection" Pr. 79 "operation mode selection" Pr. 903 "frequency setting voltage gain" Pr. 904 "frequency setting current bias" Pr.
PARAMETERS Pr. 903 "frequency setting voltage gain" (Pr.902, Pr. 904, Pr. 905 can also be adjusted similarly.) When using the frequency setting signal from the operation panel (FR-DU04) to set the frequency. (1) Power-on (monitoring mode) FR-DU04 CONTROL PANEL Hz A V MON EXT PU REV FWD (2) Choose the PU operation mode. 1) Using the MODE key, make sure that the PU operation mode has been selected.
PARAMETERS 2) Set "1" (PU operation mode) in Pr. 79 "operation mode selection". Example: To change the external operation mode (Pr. 79=2) to the PU operation mode (Pr. 79=1) Using the key, MODE choose the "parameter setting mode" as in 1).
PARAMETERS (3) Read Pr. 903 and show the current setting of the gain frequency. (Pr. 902, Pr. 904 and Pr. 905 can also be adjusted similarly.) !Parameter setting mode Using the FR-DU04 key, choose the "parameter setting mode" as in (2)-1). MODE CONTROL PANEL Hz A V MON EXT PU REV FWD SET Most significant digit flickers. Middle digit flickers. Least significant digit flickers.
PARAMETERS 1) When not adjusting the gain voltage → go to (5) 2) When adjusting any point by applying a voltage → go to (6) 3) When adjusting any point without applying a voltage → go to (7) (5) How to adjust the gain frequency only without the voltage being adjusted or key once to display ! Analog voltage A/D value (%) !Press the across terminals 2-5 the current analog voltage adjustment.
PARAMETERS Note: 1. If the Pr. 903 or Pr. 905 (gain adjustment) value is changed, the Pr. 20 value does not change. The input signal to terminal 1 (frequency setting auxiliary input) is added to the frequency setting signal. 2. For the operation procedure using the parameter unit (FR-PU04), refer to the FR-PU04 instruction manual. CAUTION Be careful when setting any value other than "0" as the bias frequency at 0V.
CHAPTER 5 PROTECTIVE FUNCTIONS This chapter explains the "protective functions" of this product. Always read the instructions before using the equipment. Chapter 1 5.1 Errors (Alarms) ........................................................ 182 5.2 Troubleshooting ....................................................... 193 5.3 Precautions for Maintenance and Inspection ...........
5.1 Errors (Alarms) PROTECTIVE FUNCTIONS 5 PROTECTIVE FUNCTIONS 5.1 Errors (Alarms) If any fault has occurred in the inverter, the corresponding protective function is activated and the error (alarm) indication appears automatically on the PU display. When the protective function is activated, refer to "5.2 Troubleshooting" and clear up the cause by taking proper action. If an alarm stop has occurred, the inverter must be reset to restart it.
PROTECTIVE FUNCTIONS Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action E.
PROTECTIVE FUNCTIONS Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Note 1: E.THM FR-PU04 Motor Ovrload Motor overload shut-off (electronic overcurrent protection) (Note 1) The electronic overcurrent protection in the inverter detects motor overheat due to overload or reduced cooling capability during constant-speed operation.
PROTECTIVE FUNCTIONS Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Note 3: E.
PROTECTIVE FUNCTIONS Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name E.BE FR-PU04 Br. Cct. Fault Brake transistor alarm detection If the brake circuit fault has occurred due to damaged brake transistors, etc., this function stops the inverter output. In this case, the inverter power must be switched off immediately. • Reduce load J.
PROTECTIVE FUNCTIONS Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action E.
PROTECTIVE FUNCTIONS Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name E. 6 Fault 6 FR-PU04 Fault 7 E. 7 CPU error This function stops the inverter output if a communication error occurs in the built-in CPU. Contact your sales representative. E.P24 FR-PU04 E.
PROTECTIVE FUNCTIONS Operation Panel Indication Name Description Check point Corrective action E.ECT FR-PU04 No encoder signal Wire break detection The inverter output is stopped if the encoder signal is turned off during orientation, PLG feedback or vector control executed with the FR-A5AP. Check for encoder signal wire break. Repair wire break. (2) Minor fault When the protective function is activated, the output is not shut off. You can make parameter setting to output the light fault signal.
PROTECTIVE FUNCTIONS Operation Panel Indication Name Description Check point Corrective action Operation Panel Indication Name oL FR-PU04 Stall prevention (overvoltage) If the regenerative energy of the motor increases too much to During exceed the brake capability, this function stops the decrease deceleration in frequency to prevent overvoltage shut-off. As soon as the regenerative energy has reduced, deceleration resumes. Check for sudden speed reduction. The deceleration time may change.
PROTECTIVE FUNCTIONS 5.1.2 To know the operating status at the occurrence of an alarm When any alarm has occurred, the display automatically switches to the indication of the corresponding protective function (error). By pressing the MODE key at this point without resetting the inverter, the display shows the output frequency. In this way, it is possible to know the running frequency at the occurrence of the alarm. This also applies to the current.
PROTECTIVE FUNCTIONS 5.1.4 Alarm code output By setting Pr. 76 "alarm code output selection", an alarm definition can be output as a 4-bit digital signal. This signal is output from the open collector output terminals equipped as standard on the inverter. Correlations between alarm definitions and alarm codes are as follows. Operation Panel Display (FR-DU04) E.OC1 E.OC2 E.OC3 E.OV1 E.OV2 E.OV3 E.THM E.THT E.IPF E.UVT E.FIN E. BE E. GF E.
5.2 Troubleshooting PROTECTIVE FUNCTIONS 5.2 Troubleshooting POINT: Check the corresponding areas. If the cause is still unknown, it is recommended to initialize the parameters (return to factory settings), re-set the required parameter values, and check again. 5.2.1 Motor remains stopped 1) Check the main circuit Check that a proper power supply voltage is applied (operation panel display is provided). Check that the motor is connected properly. Check that the conductor across P1-P〈+〉 is connected.
PROTECTIVE FUNCTIONS 5.2.6 Speed does not increase Check that the maximum frequency (Pr. 1) setting is correct. Check that the load is not too heavy. (In agitators, etc., load may become heavy in winter.) Check that the torque boost (Pr. 0, Pr. 46, Pr. 112) setting is not too large to activate the stall prevention function. Check that the brake resistor is not connected to terminals P〈+〉-P1 by mistake. 5.2.
5.3 Precautions for Maintenance and Inspection PROTECTIVE FUNCTIONS 5.3 Precautions for Maintenance and Inspection The transistorized inverter is a static unit mainly consisting of semiconductor devices. Daily inspection must be performed to prevent any fault from occurring due to adverse influence by the operating environment, such as temperature, humidity, dust, dirt and vibration, changes in the parts with time, service life, and other factors. 5.3.
PROTECTIVE FUNCTIONS 5.3.4 Insulation resistance test using megger 1) Before performing the insulation resistance test using a megger on the external circuit, disconnect the cables from all terminals of the inverter so that the test voltage is not applied to the inverter. 2) For the continuity test of the control circuit, use a meter (high resistance range) and do not use the megger or buzzer.
PROTECTIVE FUNCTIONS Daily and Periodic Inspection Area of Inspection Inspection Item Inverter module, Converter module Main circuit Relay Resistor Control circuit Operation Proteccheck tive circuit Cooling system Cooling fan Display Display Meter General Description Interval Periodic Daily 1 2 year years Check resistance across terminals. " " (1) Check for chatter during operation. (2) Check for rough surface on contacts. (1) Check for crack in resistor insulation. (2) Check for open cable.
PROTECTIVE FUNCTIONS ! Checking the inverter and converter modules (1) Disconnect the external power supply cables (R, S, T) 〈L1, L2, L3〉 and motor cables (U, V, W). (2) Prepare a meter. (Use 100Ω range.) Change the polarity of the tester alternately at the inverter terminals R, S, T, U, V, W, P and N 〈L1, L2, L3, U, V, W, + and −〉, and check for continuity. Note: 1. Before measurement, check that the smoothing capacitor is discharged. 2.
PROTECTIVE FUNCTIONS 5.3.7 Replacement of parts The inverter consists of many electronic parts such as semiconductor devices. The following parts may deteriorate with age because of their structures or physical characteristics, leading to reduced performance or failure of the inverter. For preventive maintenance, the parts must be changed periodically. The part replacement guidelines for the inverter are indicated in the following table.
PROTECTIVE FUNCTIONS (2) Smoothing capacitors A large-capacity aluminum electrolytic capacitor is used for smoothing the DC in the main circuit, and an aluminum electrolytic capacitor is also used for stabilizing the control power in the control circuit. Their characteristics are adversely affected by ripple current, etc. This is greatly influenced by the ambient temperature and operating conditions.
PROTECTIVE FUNCTIONS 5.3.9 Measurement of main circuit voltages, currents and power ! Measurement of voltages and currents Since the voltages and currents on the inverter power supply and output sides include harmonics, accurate measurement depends on the instruments used and circuits measured. When instruments for commercial frequency are used for measurement, measure the following circuits using the instruments given on the next page.
PROTECTIVE FUNCTIONS Measuring Points and Instruments Item Power supply voltage V1 Power supply side current I1 Power supply side power P1 Power supply side power factor Pf1 Measuring Point Across R-S, S-T and T-R 〈Across L1-L2, L2-L3 and L3-L1〉 Measuring Instrument Moving-iron type AC voltmeter Remarks (Reference Measured Value) * Commercial power supply Within permissible AC voltage fluctuation (Refer to page 203) R, S and T line currents Moving-iron type AC ammeter 〈L1, L2 and L1 line currents〉 At R
CHAPTER 6 SPECIFICATIONS This chapter provides the "specifications" of this product. Always read the instructions before using the equipment. Chapter 1 6.1 Standard Specifications ...........................................
6.1 Standard Specifications SPECIFICATIONS 6 SPECIFICATIONS 6.1 Standard Specifications 6.1.1 Model specifications ! 200V class (Japanese version, NA version) 0.4 0.4 0.75 0.75 1.5 1.5 2.2 2.2 3.7 3.7 5.5 5.5 7.5 7.5 11 11 15 15 18.5 18.5 22 22 30 30 37 37 45 45 55 55 motor capacity (Note 1) CT 1/2 1 2 3 5 7.5 10 15 20 25 30 40 50 60 75 VT CT VT CT VT CT VT 1 1.1 1.3 3 3.6 1.5 1.9 1.9 5 5 3 3.1 3.7 8 9.6 3 4.2 4.6 11 12 50 44 49.7 115 130 60 55 58.4 145 154 75 67 70.
SPECIFICATIONS ! 400V class (Japanese version, NA version, EC version) Type FR-A540-""K kW Applicable motor capacity (Note 1) HP 0.4 0.4 0.75 0.75 1.5 1.5 2.2 2.2 CT 1/2 1 2 3 VT CT VT CT VT CT VT 1 1.1 1.3 1.5 1.8 1.5 1.9 2.3 2.5 3 3 3 3.6 4 4.8 3 4.6 5.1 6 6.7 3.7 3.7 5.5 5.5 7.5 7.5 11 11 15 15 18.5 18.5 22 22 30 30 5 7.5 10 15 20 25 30 40 5 10 15 20 25 30 40 50 6.9 9.1 13 17.5 23.6 29 32.8 43.4 6.9 10.6 16.0 20.5 25.9 30.5 39.7 49.
SPECIFICATIONS 6.1.
SPECIFICATIONS Protective/alarm functions Environment Ambient temperature Ambient humidity Storage temperature (Note 3) Ambience Altitude, vibration Overcurrent shut-off (during acceleration, deceleration, constant speed), regenerative overvoltage shut-off, undervoltage, instantaneous power failure, overload shut-off (electronic overcurrent protection), brake transistor alarm (Note 2), ground fault current, output short circuit, main circuit device overheat, stall prevention, overload alarm, brake resis
SPECIFICATIONS 6.1.3 Outline drawings ! FR-A520-0.4K, 0.75K 110 (4.33) D 2-φ6 hole ! 200V class 5 (0.20) D 110 (4.33) 125 (4.92) 245 (9.65) 260 (10.24) Inverter Type FR-A520-0.4K FR-A520-0.75K 6 (0.24) 95 (3.74) (Unit: mm (inches)) ! FR-A520-1.5K, 2.2K, 3.7K ! FR-A540-0.4K, 0.75K, 1.5K, 2.2K, 3.7K 150 (5.91) 140 (5.51) 2-φ 6 hole 49.5 (1.95) 245 (9.65) 260 (10.24) 5 (0.20) 6 (0.24) 125 (4.92) Note: FR-A540-0.4K to 1.5K are not provided with the cooling fan. (Unit: mm (inches)) 143 (5.
SPECIFICATIONS ! FR-A520-5.5K, 7.5K, 11K ! FR-A540-5.5K, 7.5K 220 (8.66) D 2-φ6 hole 10.5 (0.41) ! 200V class Inverter Type FR-A520-5.5K FR-A520-7.5K H1 H D1 FR-A520-11K H H1 D 260 245 170 (10.24) (9.65) (6.69) 260 245 170 (10.24) (9.65) (6.69) 300 285 190 (11.81) (11.22) (7.48) D1 84 (3.31) 84 (3.31) 101.5 (4.00) ! 400V class Inverter Type 6 (0.24) 195 (7.68) FR-A540-5.5K FR-A540-7.5K H H1 260 245 (10.24) (9.65) 260 245 (10.24) (9.65) D 170 (6.69) 170 (6.69) D1 84 (3.31) 84 (3.
SPECIFICATIONS ! FR-A520-30K, 37K, 45K, 55K ! FR-A540-30K, 37K, 45K, 55K D H2 3.2 (0.13) H D1 2-φC hole H1 W C W1 W2 ! 200V class Inverter Type FR-A520-30K FR-A520-37K FR-A520-45K FR-A520-55K W 340 (13.39) 450 (17.72) 450 (17.72) 480 (18.90) W1 270 (10.63) 380 (14.96) 380 (14.96) 410 (16.14) W2 320 (12.60) 430 (16.93) 430 (16.93) 460 (18.11) H 550 (21.65) 550 (21.65) 550 (21.65) 700 (27.56) H1 530 (20.87) 525 (20.67) 525 (20.67) 675 (26.57) H2 10 (0.39) 15 (0.59) 15 (0.59) 15 (0.
SPECIFICATIONS ! Operation panel (FR-DU04) 16.5 (0.65) 24 (0.94) Effective depth 4.5 54 (2.13) 3.5 (0.14) 17 (0.67) 19.75 (0.78) 2-M3 hole 46.5 (1.83) 23.75 (0.94) 2- φ4 hole 20 (0.79) 81.5 (3.21) 46.5 (1.83) 15 (0.59) 10.5 (0.41) 72 (2.83) 16.5 (0.65) 3.25 (0.13) 54 (2.13) (Unit: mm (inches)) Choose the mounting screws whose length will not exceed the effective depth of the mounting threads.
CHAPTER 7 OPTIONS This chapter describes the "options" of this product. Always read the instructions before using the equipment. Chapter 1 7.1 Option List................................................................
7.1 Option List OPTIONS 7 OPTIONS 7.1 Option List 7.1.1 Stand-alone options Name Parameter unit (8 languages) Parameter unit connection cable Type Application, Specifications, etc. FR-PU04 Interactive parameter unit using LCD display (For use in Japanese, English, German, French, Spanish, Italian, Swedish and Finnish) FR-CB2"" Cable for connection of the operation panel or parameter unit.
OPTIONS Name Type PG follower (Note 4) FR-FP Master controller (Note 4) FR-FG Soft starter (Note 4) FR-FC Deviation detector (Note 4) FR-FD Preamplifier (Note 4) FR-FA Pilot generator (Note 4) QVAH-10 Deviation sensor (Note 4) YVGC-500W-NS Frequency setting potentiometer (Note 4) WA2W 1kΩ Frequency meter (Note 4) YM206RI 1mA Calibration resistor (Note 4) RV24YN 10kΩ Inverter setup software FR-SW0-SETUP-WE Application, Specifications, etc.
OPTIONS 7.1.
OPTIONS 1. Addition of Pr. 285 "excessive speed deviation detection frequency" In case the motor speed is increased or decreased due to load, etc. during vector control and can not be controlled to meet the speed command value, alarm stop occurs (E. OSD). Parameter Number Name 285 Excessive speed deviation detection frequency Setting Range 0 to 30Hz, 9999 Minimum Setting Increments Factory Setting Description 0.01Hz 9999 9999: Not detected Running speed (Note) E.
OPTIONS The extended functions for E.OP3 error and E. 3 error have been added to this instruction manual. (Pr. 500 to 502) 1) Addition of Pr. 500 "communication error recognition waiting time" You can set the waiting time from when a communication line fault occurs until it is recognized as a communication error. Parameter Number Setting Range 500 0 to 999.8s Minimum Setting Increments 0.
OPTIONS 3) Addition of Pr. 502 "error-time stop mode selection" You can select the inverter operation if a communication line fault or a fault of the CC-Link plug-in option itself occurs. Parameter Number Setting Range 502 0, 1, 2 Minimum Setting Increments 1 Error Recognition after Elapse of Pr. 500 Time Alarm Operation Indication output Factory Setting 0 (About setting) Plug-in option itself Communication line Pr.
OPTIONS The methods of setting DeviceNet node address and baud rate using FR-DU04 or FR-PU04 are shown as follows.
APPENDICES This chapter provides the "appendices" for use of this product. Always read the instructions before using the equipment. Appendix 1 Data Code List .................................................. 218 Appendix 2 Operating the Inverter Using a Single-Phase Power Supply ...................
Appendix 1 Data Code List APPENDICES APPENDICES Appendix 1 Data Code List Read 97 0 24 25 26 27 28 29 30 31 32 33 34 35 36 37 18 19 1A 1B 1C 1D 1E 1F 20 21 22 23 24 25 98 99 9A 9B 9C 9D 9E 9F A0 A1 A2 A3 A4 A5 0 0 0 0 0 0 0 0 0 0 0 0 0 0 41 Up-to-frequency sensitivity 29 A9 0 42 Output frequency detection 2A AA 0 43 Output frequency detection for reverse rotation 2B AB 0 44 45 46 47 48 49 50 52 53 54 55 56 Second acceleration/deceleration time Second deceleration time Second torque b
APPENDICES 59 Remote setting function selection 3B BB 0 60 61 62 63 64 65 Intelligent mode selection Reference I for intelligent mode Ref. I for intelligent mode accel Ref.
APPENDICES Parameter Number Read 11 12 13 14 15 16 17 18 1C 1D 1E 1F 20 21 22 140 Station number Communication speed Stop bit length Parity check presence/absence Number of communication retries Communication check time interval Waiting time setting CR, LF presence/absence selection PID action selection PID proportional band PID integral time Upper limit Lower limit PID action set point for PU operation PID differential time Commercial power supply-inverter switch-over sequence output terminal selection
APPENDICES Parameter Number Terminal assignment functions 180 181 182 183 184 185 186 190 191 192 193 194 195 RL terminal function selection RM terminal function selection RH terminal function selection RT terminal function selection AU terminal function selection JOG terminal function selection CS terminal function selection RUN terminal function selection SU terminal function selection IPF terminal function selection OL terminal function selection FU terminal function selection A, B, C terminal functio
APPENDICES Stop Sub selection function function 240 Soft-PWM setting 30 B0 2 244 Cooling fan operation selection 34 B4 2 250 Stop selection 3A BA 2 251 Output phase failure protection selection 3B BB 2 252 Override bias 3C BC 2 253 Override gain 3D BD 2 261 262 263 264 265 Power failure stop selection Subtracted frequency at deceleration start Subtraction starting frequency Power-failure deceleration time 1 Power-failure deceleration time 2 Power-failure deceleration time sw
APPENDICES Parameter Number Name Data Codes Link Parameter Extension Write Setting (Data code 7F/FF) 318 Y5 output selection 12 92 3 319 Y6 output selection 13 93 3 320 RA1 output selection 14 94 3 321 RA2 output selection 15 95 3 322 330 331 332 333 334 335 336 337 338 339 340 341 342 900 901 902 903 904 905 990 991 RA3 output selection RA output selection Inverter station number Communication speed Stop bit length Parity check yes/no Communication retry count Communication check
Appendix 2 Operating the Inverter Using a Single-Phase Power Supply APPENDICES Appendix 2 Operating the Inverter Using a Single-Phase Power Supply If a single-phase power supply is used to operate the inverter only 4 of the 6 of the diodes will be used. Therefore the ripple current of the capacitor will increase when compared to operation from a three-phase power supply, resulting in a higher temperature rise of the converter and the capacitor.
REVISIONS * The manual number is given on the bottom left of the back cover. Print Data *Manual Number Revision Sep., 1997 IB(NA)-66790-A First edition Oct., 1997 IB(NA)-66790-B Partly modified Front cover Nov., 1997 IB(NA)-66790-C Additions ! ! Instructions for Standard-compliant products (pages 38, 39) FR-A540-30K to 55K Modifications ! ! ! Mar., 1998 IB(NA)-66790-D Pr. 902 to Pr.