Page 1: Industrial Inverter, Instruction Manual

E6582175 Safety precautions Contents Industrial Inverter Read rst (For 3-phase motors) Connection Operations Instruction Manual Setting parameters Main parameters Other parameters Operation with external <Detailed manual> signal Monitoring the operation status Measures to satisfy the standards 3-phase 240V class 0.4 to 15kW Peripheral 1-phase 240V class 0.2 to 2.2kW devices...
Page 2

E6582175 Safety precautions The items described in these instructions and on the inverter itself are very important so that you can use safely the inverter, prevent injury to yourself and other people around you as well as to prevent damage to property in the area.
Page 3: Safety Precautions

 If the inverter begins to emit smoke or an unusual odor, or unusual sounds, immediately turn the power off. Continuous use of the inverter in such a state will cause fire. Contact your Toshiba Mandatory distributor for repairs.
Page 4

 Do not install or operate the inverter if it is damaged or any component is missing. 1.4.4 This can result in electric shock or fire. Contact your Toshiba distributor for repairs.  Do not place any inflammable objects near the inverter.
Page 5

E6582175 Reference Caution section  When removing and installing the terminal cover with a screwdriver, be sure not to scratch 1.3.2 your hand as these results in injury. 1.3.2  Pressing too hard on the screwdriver can scratch the inverter. 1.3.2 ...
Page 6

E6582175 Reference Warning section  Ground must be connected securely. If the ground is not securely connected, it could lead to electric shock or fire. Be Grounded Reference Caution section  Do not attach devices with built-in capacitors (such as noise filters or surge absorbers) to the output (motor side) terminals.
Page 7

E6582175 Reference Caution section  Use an inverter that conforms to the specifications of power supply and three-phase 1.4.1 induction motor being operated. If the inverter being used does not conform to those specifications, not only will the three-phase induction motor not rotate correctly, but it will cause serious accidents through overheating and fire.
Page 8: Maintenance And Inspection

 Do not replace parts. 14.2 This could be a cause of electric shock, fire and bodily injury. To replace parts, contact your Toshiba distributor. Prohibited  The equipment must be inspected daily. If the equipment is not inspected and maintained, errors and malfunctions can not be discovered and that could result in accidents.
Page 9: Table Of Contents

E6582175   Contents Safety precautions ................................. 1 1. Read first ..................................A-1 Check product purchase ............................ A-1 Contents of the product ............................. A-2 Names and functions ............................A-3 Notes on the application ............................ A-21 2. Connection ..................................B-1 Cautions on wiring ............................. B-1 Standard connections ............................
Page 10: Table Of Contents

E6582175 Manual torque boost - increasing torque boost at low speeds ................F-25 Signal output ..............................F-26 Input signal selection ............................F-29 Terminal function selection ..........................F-32 Basic parameters 2 ............................F-34 V/f 5-point setting ...............................F-36 6.10 Frequency priority selection ..........................F-36 6.11 Operation frequency ............................F-45 6.12 DC braking .................................F-47 6.13...
Page 11: Table Of Contents

12.1 Models and their standard specifications ......................L-1 12.2 Outside dimensions and mass ........................... L-4 13. Before contacting your Toshiba distributor - Trip information and remedies ..............M-1 13.1 Trip/Alarm causes and remedies ........................M-1 13.2 Restoring the inverter from a trip ........................M-9 13.3...
Page 12

E6582175 15. Warranty ..................................O-1 16. Disposal of the inverter ..............................P-1 17. Appendix ·········································································································································· UL standard and CSA standard ·········································································································· 한국 KC 마크 ·································································································································· Motor control parameter default setting update information ······································································...
Page 13: Read First, Check Product Purchase

E6582175 1. Read first Check product purchase Before using the product you have purchased, check to make sure that it is exactly what you ordered. Caution Use an inverter that conforms to the specifications of power supply and three-phase induction motor being used.
Page 14: Contents Of The Product

E6582175 Quick start manual Danger label kit Danger labels for sticking in 6 languages. WARNING DANGER ADVERTENCIA Risk of injury, electric shock or fire. Read the instruction manual. Do not open the cover while power is applied DANGER or for 15 minutes after power has been removed. Risk of injury, electric shock or fire.
Page 15

E6582175 Names and functions 1.3.1 Outside view Charge lamp Indicates there is a high voltage still in the inverter. STATUS lamp Do not open the terminal block cover when this lamp is lit because it is dangerous. Lights and blinks when ®...
Page 16

E6582175 Example of the protective label on the top of the inverter [Opening the cover] Insert a small screw driver and slide the door lock to upside for unlock. (Slide it to downside for lock.) About the monitor display The LED on the operation panel uses the following symbols to indicate parameters and operations. LED display (numbers) LED display (letters)
Page 17: Operation Panel

E6582175 [Operation panel] RUN lamp ％ lamp Hz lamp Lit when a frequency is Displayed numbers are Displayed numbers are not output with the ON in Hertz. in %. run command. This lamp blinks when operation RUN key starts. Pressing this key while the RUN key lamp is on PRG lamp starts operation.
Page 18

E6582175 1.3.2 Opening terminal cover and terminal block Warning  Never touch the internal connector while the upper cover of control panel is opened. There is a risk of electrical shock because it carries a high voltage. Prohibited Caution  When removing and mounting the terminal cover or the terminal block with a screwdriver, be sure not to scratch your hand as these results in injury.
Page 19

E6582175 (1) Removing the outside terminal block cover (VFS15-2004PM-W1 to 2007PM-W1, VFS15S-2002PL-W1 to 2007PL-W1) Insert a screwdriver or other thin object into the Press in on the screwdriver. hole indicated with the mark. While pressing on the screwdriver, rotate the Pull the terminal cover up at an angle.
Page 20

E6582175 (2) Removing the inside terminal block cover (VFS15-2004PM-W1 to 2007PM-W1, VFS15S-2002PL-W1 to 2007PL-W1) The finger is put on to the tab part of the While pressing on the screwdriver, rotate the terminal block cover. terminal cover downward to remove it. Pull the terminal cover up at an angle.
Page 21

E6582175 (3) Removing the outside terminal block cover (VFS15-2015PM-W1 to 2037PM-W1, VFS15S-2015PL-W1, 2022PL-W1, VFS15-4004PL-W1 to 4037PL-W1) Insert a screwdriver or other thin object into the Press in on the screwdriver. hole indicated with the mark. While pressing on the screwdriver, sidles the terminal cover downward to remove it.
Page 22

E6582175 (4) Removing the inside terminal block cover (VFS15-2015PM-W1 to 2037PM-W1, VFS15S-2015PL-W1, 2022PL-W1, VFS15-4004PL-W1 to 4015PL-W1) The finger is put on to the tab part of the While pressing on the screwdriver, rotate the terminal block cover. terminal cover downward to remove it. Pull the terminal cover up at an angle.
Page 23

E6582175 (5) Removing the inside terminal block cover (VFS15-4022PL-W1, 4037PL-W1) The finger is put on to the tab part of the While pressing on the screwdriver, rotate the terminal block cover. terminal cover downward to remove it. Pull the terminal cover up at an angle. ●...
Page 24

E6582175 (6) Removing the power terminal cover (VFS15-2055PM-W1 to 2150PM-W1, VFS15-4055PL-W1 to 4150PL-W1) Insert a screwdriver or other thin object into the Press in on the screwdriver. hole indicated with the mark. While pressing on the screwdriver, slide the ● After wiring is complete, be sure to restore the terminal cover downward to remove it.
Page 25

E6582175 1.3.3 Power circuit and control circuit terminal blocks 1) Power circuit terminal In case of the crimp-style terminal, cover the crimp-style terminal with insulating tube, or use the crimp- style terminal with insulation sleeve. Refer to section 2.3.1 for details about terminal functions. Crimp-style Screw Size terminal...
Page 26

E6582175 VFS15-2015PM-W1, 2022PM-W1 M4 screw Shorting-bar Grounding terminal Grounding terminal (M4 screw) (M4 screw) Grounding terminal For EMC plate (M5 screw) VFS15-2037PM-W1 M4 screw Shorting-bar Grounding terminal (M5 screw) For EMC plate Note1) Bend the clips on the wiring port of the terminal cover to connect the PB, PO, PA/+, and PC/- terminals. Note2) Be careful to insert all wires into the cage of terminal block.
Page 27

E6582175 VFS15S-2002PL-W1 to 2007PL-W1 Grounding capacitor switch Shorting-bar Grounding terminal Grounding terminal (M4 screw) (M4 screw) Grounding terminal (M5 screw) For EMC plate VFS15S-2015PL-W1, 2022PL-W1 M4 screw Grounding capacitor switch Shorting-bar Grounding terminal Grounding terminal (M4 screw) (M4 screw) Grounding terminal (M5 screw) For EMC plate Note1) Bend the clips on the wiring port of the terminal cover to connect the PB, PO, PA/+, and PC/- terminals.
Page 28

E6582175 VFS15-4004PL-W1 to 4015PL-W1 Shorting-bar Grounding capacitor switch M4 screw Grounding terminal (M5 screw) For EMC plate VFS15-4022PL-W1, 4037PL-W1 Grounding capacitor switch M4 screw Shorting-bar Grounding terminal (M5 screw) For EMC plate Note1) Bend the clips on the wiring port of the terminal cover to connect the PB, PO, PA/+, and PC/- terminals. Note2) Be careful to insert all wires into the cage of terminal block.
Page 29

E6582175 VFS15-2055PM-W1, 2075PM-W1 VFS15-4055PL-W1, 4075PL-W1 Grounding capacitor switch (4055PL-W, 4075PL-W only) M5 screw Shorting-bar Grounding terminal (M5 screw) Grounding terminal (M5 screw) For EMC plate VFS15-2110PM-W1, 2150PM-W1 M6 screw Shorting-bar Grounding terminal Grounding terminal (M5 screw) (M5 screw) For EMC plate Note1) Bend the clips on the wiring port of the terminal cover to connect the PB, PO, PA/+, and PC/- terminals.
Page 30

E6582175 VFS15-4110PL-W1, 4150PL-W1 Grounding capacitor switch M5 screw Shorting-bar Grounding terminal (M5 screw) Grounding terminal (M5 screw) For EMC plate Note1) Bend the clips on the wiring port of the terminal cover to connect the PB, PO, PA/+, and PC/- terminals. Note2) Be careful to insert all wires into the cage of terminal block.
Page 31

E6582175 2) Grounding capacitor switch Single-phase 240V model and three-phase 500V model have a built-in high-attenuation noise filter and is grounded via a capacitor. A switch makes for easy switching to reduce leakage current from the inverter and the load on the capacitor.
Page 32

E6582175 3) Control circuit terminal block The control circuit terminal block is common to all equipment. VIB CC VIC S3 FM FLA FLB FLC RY RC SINK SOURCE R CC +SU STO OUT P24 F Screw for removable control terminal block RES S1 S2 RS485 connector 1.3.3(3)_制御回路端子台_J.eps...
Page 33

E6582175 Notes on the application 1.4.1 Motors When this inverter and the motor are used in conjunction, pay attention to the following items. Caution Use an inverter that conforms to the specifications of power supply and three-phase induction motor being operated. If the inverter being used does not conform to those specifications, not only will the three-phase induction motor not rotate correctly, but it will cause serious accidents through overheating Mandatory and fire.
Page 34

E6582175 Low loads and low inertia loads The motor may demonstrate instability such as abnormal vibrations or overcurrent trips at light loads of 5% or under of the load percentage, or when the load's inertia moment is extremely small. If that happens reduce the carrier frequency.
Page 35

E6582175 Motors with a brake When motors with a brake are directly connected to the inverter's output, the brake cannot be released at startup because of low voltage. Wire the brake circuit separately from the main circuit. Non-excitation activation type brake FLC S2(ST) 3-phase power...
Page 36

E6582175 1.4.2 Inverters Protecting inverters from overcurrent The inverter has an overcurrent protection function. The programmed current level is set to the inverter's maximum applicable motor. If the motor used has a small capacity, the overcurrent level and the electronic thermal protection must be readjusted. If adjustment is necessary, refer to section 5.6, and make adjustments as directed.
Page 37

E6582175 Circuit breaking when two or more inverters are used on the same power line MCCB1 MCCB2 (circuit breaking fuse) INV1 MCCB3 INV2 MCCB: Molded-case circuit breaker MCCBn  1 INVn Breaking of selected inverter There is no fuse in the inverter's main circuit. Thus, as the diagram above shows, when more than one inverter is used on the same power line, you must select interrupting characteristics so that only MCCB2 to MCCBn+1 will trip and the MCCB1 will not trip when a short occurs in the inverter (INV1).
Page 38

E6582175 1.4.3 What to do about the leakage current Caution The leakage current through the input/output power cables of inverter and capacitance of motor can affect to peripheral devices. The value of leakage current is increased under the condition of the PWM carrier frequency and the Mandatory length of the input/output power cables.
Page 39

E6582175 (2) Influence of leakage current across lines Thermal relays Inverter Power supply Leakage current path across wires Thermal relays The high frequency component of current leaking into electrostatic capacity between inverter out- put wires will increase the effective current values and make externally connected thermal relays operate improperly.
Page 40: Installation Environment

E6582175 Remedies: 1. Use a meter output terminal in the inverter control circuit. The load current can be output on the meter output terminal (FM). If the meter is connected, use an ammeter of 1mAdc full scale or a voltmeter of 10Vdc full scale. 0-20mAdc (4-20mAdc) can be also output.
Page 41

E6582175  Operate under the environmental conditions prescribed in the instruction manual. Operations under any other conditions can result in malfunction.  Check to make sure that the input power voltage is +10%, -15% of the rated power voltage (±10% Mandatory when the load is 100% in continuous operation) written on the name plate.
Page 42

If the inverter is installed in a location that is subject to vibration, anti-vibration measures are required. Please consult with Toshiba about these measures.  If the inverter is installed near any of the equipment listed below, provide measures to insure against errors in operation.
Page 43

Warning  Do not install or operate the inverter if it is damaged or any component is missing. This can result in electric shock or fire. Call your Toshiba distributor for repairs. Prohibited  Mount the inverter on a metal plate.
Page 44

E6582175 The space shown in the diagram is the minimum allowable space. Because air cooled equipment has cooling fans built in on the top or bottom surfaces, make the space on top and bottom as large as possible to allow for air passage.
Page 45

E6582175  Panel designing taking into consideration the effects of noise The inverter generates high frequency noise. When designing the control panel setup, consideration must be given to that noise. Examples of measures are given below.  Wire so that the main circuit wires and the control circuit wires are separated. Do not place them in the same conduit, do not run them parallel, and do not bundle them.
Page 46

E6582175  Installing more than one unit in a cabinet When two or more inverters are installed in one cabinet, pay attention to the followings.  Inverters may be installed side by side with each other with no space left between them. When installing inverters side by side, remove the protective label on the top of the inverter.
Page 47: Cautions On Wiring

2. Connection Warning  Never disassemble, modify or repair. This can result in electric shock, fire and injury. Call your Toshiba distributor for repairs. Disassembly prohibited  Do not stick your fingers into openings such as cable wiring holes and cooling fan covers.
Page 48

E6582175 Warning  Ground must be connected securely. If the ground is not securely connected, it could lead to electric shock or fire. Be Grounded Caution  Do not attach devices with built-in capacitors (such as noise filters or surge absorber) to the output (motor side) terminal.
Page 49: Standard Connections

E6582175 Standard connections Warning  Do not connect input power to the output (motor side) terminals (U/T1, V/T2, W/T3). Connecting input power to the output could destroy the inverter or cause a fire.  Do not insert a braking resistor between DC terminals (between PA/+ and PC/- or PO and PC/-). It could cause a fire.
Page 50: Standard Connection Diagram

E6582175 2.2.1 Standard connection diagram 1 This diagram shows a standard wiring of the main circuit. Standard connection diagram – SINK (Negative) (common: CC) DC reactor (DCL) Braking resistor (Option) *2 (option) Main circuit power supply PA/+ PC/- Motor 3ph-200-240V class: three-phase 200-240V MCCB R/L1 U/T1...
Page 51

E6582175 2.2.2 Standard connection diagram 2 Standard connection diagram – SOURCE (Positive) (common: P24) DC reactor (DCL) Braking resistor (Option) *2 (option) Main circuit power supply PA/+ PC/- Motor 3ph-200-240V class: three-phase 200-240V MCCB R/L1 U/T1 -50/60Hz Noise S/L2 V/T2 1ph-200-240V class: single-phase 200-240V Power circuit filter...
Page 52: Description Of Terminals

E6582175 Description of terminals 2.3.1 Power circuit terminals  Connections with peripheral equipment Molded-case Magnetic Input AC noise contactor circuit braker reactor reduction filter Motor Inverter U/T1 R/L1 Power S/L2 V/T2 supply W/T3 T/L3 Zero-phase PA/+ reactor Braking resistor Note 1: The T/L3 terminal is not provided for any single-phase models. So if you are using single-phase models, use the R/L1 and S/L2/N terminals to connect power cables.
Page 53

E6582175 2.3.2 Control circuit terminals The control circuit terminal block is common to all equipment. Regarding to the function and specification of each terminal, please refer to the following table. Refer to section 1.3.3.3) about the arrangement of control circuit terminals. ...
Page 54

E6582175 Terminal Input / Electrical Function Inverter internal circuits symbol output specifications Common Control circuit's equipotential terminal to Input / (3 terminals) output +24V 10Vdc Voltage Output Analog power supply output (permissible load Regulator current: 10mAdc) Multifunction programmable analog input. Default setting: 0-10Vdc (1/1000 resolution) and 0-60Hz (0-50Hz) 10Vdc...
Page 55

E6582175 Terminal Input / Electrical Function Inverter internal circuits symbol output specifications 1mAdc full-scale ammeter or QS60T(option) Multifunction programmable analog 0-20mA (4-20mA) output. Default setting: output frequency. DC ammeter +24V – The function can be changed to meter Permissible load +24V Voltage Output...
Page 56

E6582175 Terminal Input / Electrical Function Inverter internal circuits symbol output specifications Multifunction programmable open Open collector collector output. Default setting detect output and output speed reach signal. 24Vdc-100mA Multifunction output terminals to which two different functions can be assigned. To output pulse The NO terminal is an equipotential trains,...
Page 57

E6582175  Connection of SINK (Negative) logic/SOURCE (Positive) logic (When the inverter's internal power supply is used) Current flowing out turns control input terminals on. These are called sink logic terminals. The general used method in Europe is source logic in which current flowing into the input terminal turns it Sink logic is sometimes referred to as negative logic, and source logic is referred to as positive logic.
Page 58

E6582175 <Examples of connections when an external power supply is used> The P24 terminal is used as common terminal to connect to an external power supply or to separate a terminal from other input or output terminals. Slide switch SW1 : PLC side Slide switch SW1 : PLC side Source (Positive) logic Sink (Negative) logic...
Page 59

E6582175  Switching of slide switch Refer to section 1.3.3 3) about location of slide switch. (1) Switching of sink/source logic: SW1 (Default setting : PLC side) Setting of sink/source logic for F, R, RES, S1, S2, and S3 terminals are switched by slide switch SW1. When an external power supply is used for sink logic, set the slide switch SW1 to PLC side.
Page 60

Continuous use of the inverter in such a state will cause fire. Call your Toshiba distributor for repairs.  Always turn the power off if the inverter is not used for long periods of time since there is a possibility of malfunction caused by leaks, dust and other material.
Page 61: Setting Parameters

Toshiba distributer.) Each setup menu automatically sets all parameters relating to the base frequency and the base frequency voltage of the motor connected.
Page 62

E6582175  Values set by each setup parameter asia  (Mainly in Asia, Title Function (Mainly in (Mainly in (Mainly in Oceania) Europe) North America) Japan) Note 1) ul/vl/170/ f204 /f213 / 50.0(Hz) 60.0(Hz) 50.0(Hz) Frequency 60.0(Hz) f219 /f330 / f367 /f814 Base 240V...
Page 63

E6582175 Simplified Operation of the VF-S15 Operation command and Operation frequency command are necessary to operate the inverter. Operation method and operation frequency setting can be selected from the following. At default setting, the inverter runs and stops with RUN/STOP key on the panel keypad, and frequency can be set with the setting dial.
Page 64

E6582175 3.2.1 How to run and stop [Example of  setting procedure] Panel operation LED display Operation Displays the output frequency (operation stopped).  (When standard monitor display selection f710=0 [output frequency]) Displays the first basic parameter [History (auh)]. MODE Turn the setting dial, and select "cmod".
Page 65

E6582175 (3) Coast stop Coast stop Assign parameters as described below in case of Motor Coast stop. Inverter will display off at Coast stop. speed 1) Assign "6 (ST)" to an input terminal. Set parameter =. Open the ST-CC for coast stop(see the F-CC status described on the right).
Page 66

E6582175 3.2.2 How to set the frequency [Example of fmod setting procedure] fmod=1: Setting the frequency by the terminal VIA Panel operation LED display Operation Displays the output frequency (operation stopped). 00 (When standard monitor display selection f710=0 [output frequency]) MODE Displays the first basic parameter [History (auh)].
Page 67

E6582175 How to operate the VF-S15 Overview of how to operate the inverter with simple examples Operation Command: Panel Operation Ex.1 Frequency Command: Setting Dial 1 Wiring PC/- PA/+ Motor MCCB U/T1 R/L1 S/L2 V/T2 W/T3 T/L3 Operation panel Parameter setting (default setting) Title Function Setting value...
Page 68

E6582175 Operation Command : Panel Operation Ex.2 Frequency Command: Setting Dial 2 Wiring PA/+ PC/- Motor MCCB R/L1 U/T1 S/L2 V/T2 T/L3 W/T3 Operation panel Parameter setting Title Function Setting value Command mode selection  Frequency setting mode selection 1 ...
Page 69

E6582175 Operation Command: External Signal Ex.3 Frequency Command: Setting Dial Wiring PA/+ PC/- Motor MCCB U/T1 R/L1 S/L2 V/T2 W/T3 T/L3 Forward signal Operation panel Reverse signal Common Parameter setting Title Function Setting value Command mode selection  Frequency setting mode selection 1 0 or 3 ...
Page 70

E6582175 Operation Command: External Signal Ex.4 Frequency Command: External Analog Signal Wiring PC/- PA/+ Motor MCCB R/L1 U/T1 S/L2 V/T2 T/L3 W/T3 Forward signal Reverse signal Common Current signal: VIB PP 4(0)20mA Voltage signal: 0+10V (or -10+10Vdc) External potentiometer (Otherwise, input voltage signal between the terminals VIA-CC.) Parameter setting Title Function...
Page 71

E6582175 4. Setting parameters Setting and Display Modes This inverter has the following three display modes. Standard monitor mode The standard inverter mode. This mode is enabled when inverter power goes on. This mode is for monitoring the output frequency and setting the frequency reference value. If also displays information about status alarms during running and trips.
Page 72

E6582175 Status monitor mode The mode for monitoring all inverter status. Allows monitoring of frequency command value, output current/voltage and terminal information.  Refer to chapter 8. The inverter can be moved through each of the modes by pressing the MODE key. ...
Page 73: How To Set Parameters

E6582175 How to set parameters There are two types of setting monitor modes: Easy mode and Standard setting mode. The mode active when power is turned on can be selected at  (EASY key mode selection), and the mode can be switched by the EASY key. Note, however, that the switching method differs when only the Easy mode is selected.
Page 74

E6582175 Standard setting mode : The mode changes to the Standard setting mode when the EASY key is pressed and "std" is displayed. Both basic and extended all parameters are displayed. Basic parameters : This parameter is a basic parameter for the operation of the inverter.
Page 75

E6582175 4.2.1 Settings in the Easy setting mode The inverter enters this mode by pressing the MODE key when the Easy setting mode is selected Easy setting mode (Registered parameters at default setting) When you are unsure of something during operation: Title Function You can return to the Standard monitor...
Page 76

E6582175 4.2.2 Settings in the Standard setting mode The inverter enters this mode by pressing the MODE key when the Standard setting mode is selected.  How to set basic parameters When you are unsure of something (1) Select parameter to be changed. (Turn the setting dial.) during operation: You can return to the Standard monitor (2) Read the programmed parameter setting.
Page 77: Other Parameters

E6582175  How to set extended parameters Each extended parameter is composed of an "f, a or c "suffixed with a 3-digit figure, so first select and read out the heading of the parameter you want "f1" to "f9", "a", "c" ("f1": Parameter starting point is 100, "a": Parameter starting point is A.) (5) Select the title of the parameter you want to change.
Page 78

E6582175 Set parameters by purpose (Guidance function) auf Only parameters required for a special purpose can be called up and set. To use this function, select parameter auf  Refer to section 6.1.3 for details. Reset parameters to default settings typ Use the typ parameter to reset all parameters back to the default settings.
Page 79

E6582175  How to search and reprogram parameters Panel operation LED display Operation Displays the output frequency (operation stopped). (When standard monitor display selection is set as f710=0 00 [output frequency]) MODE Displays the first basic parameter "History function (auh)." Turn the setting dial, and select gru.
Page 80

E6582175 4.3.2 Return to default settings typ : Default setting  Function It is possible to return groups of parameters to their defaults, clear run times, and record/recall set parameters. [Parameter setting] Title Function Adjustment range Default setting 0: - 1: 50Hz default setting 2: 60Hz default setting 3: Default setting 1 (Initialization)
Page 81

Setting typ to 5 resets the cumulative operation time to the initial value (zero). Initialization of type information (typ = 6) Setting typ to 6 clears the trips when an etyp format error occurs. But if the  displayed, contact your Toshiba distributor. D-11...
Page 82

E6582175 Save user setting parameters (typ = 7) Setting typ to 7 saves the current settings of all parameters. Load user setting parameters (typ = 8) Setting typ to 8 loads parameter settings to (calls up) those saved by setting typ to 7. * By setting typ to 7 or 8, you can use parameters as your own default parameters.
Page 83

E6582175 Checking the region settings selection set : Checking the region setting  Function The region selected on the setup menu can be checked. Also, the setup menu starts and can be changed to a different region. [Parameter setting] Title Function Adjustment range Default setting...
Page 84: Easy Key Function

E6582175 EASY key function psel : EASY key mode selection f750 : EASY key function selection f751 to f782 : Easy setting mode parameter 1 to 32  Function It is possible to switch between standard mode and easy setting mode using the EASY key. (default setting) Up to 32 arbitrary parameters can be registered to easy setting mode.
Page 85

E6582175 psel =0 * When the power is turned on, the inverter is in standard mode. Press the EASY key to switch to easy setting mode. psel =1 * When the power is turned on, the inverter is in easy setting mode. Press the EASY key to switch to standard mode.
Page 86

E6582175 [How to select parameters] Select the desired parameters as easy setting mode parameters 1 to 32 (f751 to f782). Note that parameters should be specified by communication number. For communication numbers, refer to Table of parameters. In easy setting mode, only parameters registered to parameters 1 to 32 are displayed in order of registration. The values of the default settings are shown in the table below.
Page 87

E6582175  Shortcut key function (f750=1) This function allows you to register, in a shortcut list, parameters whose settings need to be changed frequently so that you can read them out easily in a single operation. The shortcut is usable in the frequency monitor mode only. [Operation] Set f750 to 1, read out the setting of the parameter you want to register, and press and hold down the EASY key for 2 seconds or more.
Page 88: Parameters And Data

E6582175 5. Main parameters Here are described main parameters you set before use according to the section 11. Tables of parameters and data. Meter setting and adjustment  : Meter selection  : Meter adjustment gain  Function Output of 0 - 1mAdc, 0 (4) - 20mAdc, 0 - 10vdc can be selected for the output signal from the FM terminal, depending on the ...
Page 89: Inverter

E6582175  Adjustment scale with parameter  (Meter adjustment) Connect meters as shown below. <Displaying output frequency> <Displaying output current> =  =  Inverter Inverter The reading of the The reading of the meter will fluctuate meter will during scale fluctuate during * Optional QS-60T frequency * Meter with a maximum...
Page 90

E6582175  Example of 4-20mA output adjustment (Refer to section 6.33.3 for details) =1, =0 =1, =20 (mA) (mA) Output Output currrent currrent f692 100% 100% Internal calculated value Internal calculated value Note 1) When using the FM terminal for current output, be sure that the external load resistance is less than 600Ω. Use over 1kΩ...
Page 91

E6582175 Setting acceleration/deceleration time   : Acceleration time 1  : Setting of acceleration/deceleration time unit  : Deceleration time 1  : Automatic acceleration/deceleration  Function 1) For acceleration time 1  programs the time that it takes for the inverter output frequency to go from 0.0Hz to maximum frequency .
Page 92

E6582175 Maximum frequency : Maximum frequency  Function 1) Programs the range of frequencies output by the inverter (maximum output values). 2) This frequency is used as the reference for acceleration/deceleration time. Output frequency (Hz) When =80Hz ・This function determines the value 80Hz in line with the ratings of the motor and load.
Page 93: Upper Limit And Lower Limit Frequencies

E6582175 Upper limit and lower limit frequencies : Upper limit frequency : Lower limit frequency  Function Programs the lower limit frequency that determines the lower limit of the output frequency and the upper limit frequency that determines the upper limit of that frequency. Upper limit Lower limit Command frequency (Hz)
Page 94

E6582175 Base frequency  : Base frequency 1  : Base frequency voltage 1  Function Set the base frequency and the base frequency voltage in conformance with load specifications or the base frequency. Note: This is an important parameter that determines the constant torque control area. Base frequency voltage ...
Page 95: Setting The Electronic Thermal

E6582175 Setting the electronic thermal   : Overload characteristic selection   : Motor electronic-thermal protection level 1   : Electronic-thermal protection characteristic selection 3 : Motor electronic-thermal protection level 2  : Motor 150% overload detection time ...
Page 96

E6582175 [Parameter setting] Title Function Adjustment range Default setting 0: Disabled (thr, f173) 1: Enabled (thr, f173) Electronic-thermal memory  2: Disabled (thr) 3: Enabled (thr) 10-100 Overload alarm level  *1: The inverter's rated current is 100%. When  (current/voltage unit selection) = 1 (A (amps)/V (volts)) is selected, it can be set at A (amps).
Page 97

E6582175  Setting of electronic thermal protection characteristics selection  Setting value Overload protection Overload stall valid invalid valid valid invalid invalid invalid valid  Setting of motor electronic thermal protection level 1 thr (Same as f173) When the capacity of the motor in use is smaller than the capacity of the inverter, or the rated current of the motor is smaller than the rated current of the inverter, adjust thermal protection level 1 thr for the motor in accordance with the motor's rated current.
Page 98

E6582175 [Using a VF motor (motor for use with inverter)]  Setting of electronic thermal protection characteristics selection  Setting value Overload protection Overload stall valid invalid   valid valid invalid invalid   invalid valid VF motors (motors designed for use with inverters) can be used in frequency ranges lower than those for standard motors, but their cooling efficiency decreases at frequencies below 6Hz.
Page 99

E6582175  = (150%-60s), = (Constant torque characteristic) Protection is given uniformly regardless of temperature, as shown by the 150%-60 sec overload curve in the figure below. Inverter overload Current Inverter overload time [s] time [s] (Outline data) 2400 Monitored output current [%] Inverter overload protection characteristics 110% 150%...
Page 100

E6582175 Note 1: At extremely low speeds of 1 Hz or less, an overload trip (ol3) can occur in a short time to protect the inverter. Note 2: At over 150% current , an overload trip (ol1) can occur in a short time to protect the inverter. Note 3: Overload detection level is variable by condition of output frequency and carrier frequency.
Page 101

E6582175 5) Overload characteristic selection aul Overload characteristic of inverter can be selected to 150%-60s or 120%-60s. [Parameters settings] Title Function Adjustment range Default setting 0: - 1: Constant torque characteristic（150%-60s） Overload characteristic selection 2: Variable torque characteristic（120%-60s） ● Regarding to characteristic for aul=1 setting, refer to section 5.6.3). Note) In case of aul=2 setting, be sure to install the input AC reactor (ACL) between power supply and inverter, to remove the protective label on the top of the inverter, and to connect the grounding capacitors by pressing the grounding capacitor switch.
Page 102

E6582175  = (Variable torque characteristic), = (Temperature estimation) This parameter adjusts automatically overload protection, predicting the inverter internal temperature rise. (diagonally shaded area in the figure below) time [s] f631=0 Monitored output current [%] 105% 120% 100%: Inverter rated output current Note 1: The rated output current of inverter is changed by setting of aul=1 or 2.
Page 103

E6582175 Preset-speed operation (speeds in 15 steps) sr0 to sr7 : Preset-speed frequency 0 to 7 f287 to f294 : Preset-speed frequency 8 to15 : Operation frequency setting target by setting dial f724 Function A maximum of 15 speed steps can be selected just by switching an external logic signal. Multi-speed frequencies can be programmed anywhere from the lower limit frequency ...
Page 104: Connection

E6582175 Note) When the other preset-speed command is input while adjusting frequency with the setting dial, operation frequency will change but not the inverter display and the subject of adjustment. Ex) If sr2 is input when operating under sr1 and changing frequency with the setting dial, operation frequency will change to sr2 but inverter display and the subject of adjustment continue to be sr1.
Page 105

E6582175 3) Using other speed commands with preset-speed command 1: Panel keypad (including extension panel) Command mode 2: RS485 communication 0: Terminal block selection 3: CANopen communication  4: Communication option 0:Setting dial 1 (save even if power is off) 0:Setting dial 1 (save even if power is off) 1: Terminal VIA 1: Terminal VIA...
Page 106: Parameter Setting

E6582175 Switching between two frequency commands fmod : Frequency setting mode selection1 f200 : Frequency priority selection f207 : Frequency setting mode selection2  Function These parameters are used to switch between two frequency commands automatically or with input terminal signals. Parameter setting Title Function...
Page 107

E6582175 2) Automatic switching by frequency command Frequency priority selection parameter f200 = 1 Switch frequency command set with fmod and f207 automatically according to the frequency command entered. If the frequency set with fmod is above 1Hz: The frequency command set with fmod If the frequency set with fmod is 1Hz or less: The frequency command set with f207 E-20...
Page 108

E6582175 Auto-restart (Restart of coasting motor) f301 : Auto-restart control selection Caution  Stand clear of motors and mechanical equipment If the motor stops due to a momentary power failure, the equipment will start suddenly when power is restored. Mandatory This could result in unexpected injury.
Page 109

E6582175 2) Restarting motor during coasting (Motor speed search function) Motor speed Forward / reverse ST-CC ● Setting f301 to 2 or 3: This function operates after the ST-CC terminal connection has been opened first and then connected again. Note 1: As the default setting for ST (Standby) is Always ON, change the following settings. ...
Page 110

E6582175 5.10 Changing operation panel display 5.10.1 Changing the unit (A/V) from a percentage of current and voltage f701 :Current/voltage unit selection  Function These parameters are used to change the unit of monitor display. %  A (ampere)/V (volt) Current 100% = Rated current of inverter Voltage 100% = 200Vac (240V class), 400Vac (500V class) ...
Page 111

E6582175 5.10.2 Displaying the motor or the line speed f702 : Frequency free unit display magnification f703 : Frequency free unit coverage selection f705 : Inclination characteristic of free unit display f706 : Free unit display bias  Function The frequency or any other item displayed on the monitor can be converted into the rotational speed of the motor or load device.
Page 112

E6582175 * The f702 converts the following parameter settings: In case of f703=0 Free unit Frequency monitor display Output frequency, Frequency command value, PID feedback value, Stator frequency, fc, fh, ul, ll, sr0  sr7, Frequency-related parameters f100, f101, f102, f167, f190, f192, f194, f196, f198, f202, f204, f211, f213, f217, f219 f240, f241, f242, f250, f260, f265,...
Page 113: Extended Parameters

E6582175 6. Other parameters Extended parameters are provided for sophisticated operation, fine adjustment and other special purposes. Modify parameter settings as required. Refer to section 11 tables of parameters. Refer to the corresponding sections regarding the following parameters. Title Function Reference Overload characteristic selection 5.6, 6.18...
Page 114

E6582175 Parameters useful for settings and adjustments 6.1.1 Searching for changes using the history function (auh) auh : History function History function (auh): Automatically searches for 5 latest parameters that are programmed with values different from the default setting and displays them in the auh. Parameter setting can also be changed within this group auh.
Page 115

E6582175 Note1: The parameters set by communication option or RS485 communication are not searched and not displayed. Note2: The following parameters are not displayed in this auh, even if they are the most recent changes. fc (Operation frequency of operation panel), auf (Guidance function), aul (Overload characteristic selection), au1 (Automatic acceleration/deceleration),...
Page 116

E6582175  How to use the Application easy setting Choose the machine Operation panel LED display Operation action Displays the output frequency. (When standard monitor display selection  is set to  00 [output frequency]) The first basic parameter “auh” (history function) is displayed. MODE Turn the setting dial to the right to change the parameter to aua.
Page 117

E6582175 Table of parameters that can be set using  1: Initial 3: Material 4: Hoisting 5: Fan 6: Pump easy setting Conveyor handling Compressor f751 cmod cmod cmod cmod cmod cmod cmod f752 fmod fmod fmod fmod fmod fmod fmod f753 f754...
Page 118

E6582175 6.1.3 Setting a parameter using the guidance function (auf) auf : Guidance function Guidance function (auf): The guidance function refers to the special function of calling up only functions necessary to set up the inverter in response to the user’s needs. When a purpose-specific guidance is selected, a group of parameters needed for the specified application (function) is formed and the inverter is switched automatically to the mode of setting the group of parameters selected.
Page 119

E6582175  How to use the guidance function Here are the steps to follow to set parameters, using the guidance function. (When the Preset speed guidance auf = 2) Operation panel LED display Operation action Displays the operation frequency (output stopped). (When standard monitor display selection =...
Page 120

E6582175 Table of parameters that can be changed using the guidance function Preset-speed setting Motor 1&2 switching operation Motor constant setting guidance auf=2 auf=4 auf=5                ...
Page 121

E6582175 Example in case the acceleration Example in case the acceleration Output Output and deceleration time become short and deceleration time become long frequency (Hz) frequency (Hz)   Time Time [sec] [sec] Deceleration Acceleration Acceleration Deceleration time time time time Set ...
Page 122: Increasing Starting Torque

E6582175 6.1.5 Increasing starting torque au2 : Torque boost setting macro function  Function Simultaneously switches inverter output (V/F) control and programs motor constants automatically (On- line automatic-tuning function) to improve torque generated by the motor. This parameter integrates the selection of function including vector control and setting of auto-tuning.
Page 123

E6582175 2) When using vector control (increasing starting torque and high-precision operations)  is set to  (Vector control + auto-tuning) Setting torque boost setting macro function control  to  (vector control + auto-tuning) provides high starting torque bringing out the maximum in motor characteristics from the low-speed range. This suppresses changes in motor speed caused by fluctuations in load to provide high precision operation.
Page 124

E6582175 When vector control cannot be programmed..First read the precautions about vector control in section 6.3.9). 1) If the desired torque cannot be obtained  Refer to section 6.25 selection 2 2) If auto-tuning error "" appears  Refer to section 6.25 selection 4 ...
Page 125: Selection Of Operation Mode

E6582175 Selection of operation mode 6.2.1 Selection of start/stop and frequency settings cmod : Command mode selection fmod : Frequency setting mode selection  Function These parameters are used to specify which input device (panel keypad, terminal block, or communication) takes priority in entering an operation stop command or frequency setting mode (terminal VIA/VIB/VIC, setting dial, communication, or UP/DOWN from external logic).
Page 126

E6582175 <Frequency setting mode selection> [Parameter setting] Title Function Adjustment range Default setting 0: Setting dial 1(save even if power is off) 1: Terminal VIA 2: Terminal VIB 3: Setting dial 2(press in center to save) 4: RS485 communication 5: UP/DOWN from external logic input ...
Page 127

E6582175 Communication Frequencies are set by commands from a communication option. : option  Refer to each Instruction Manual of option. A frequency command is set by means of external analog signals. : Terminal VIC (VIC terminal: 0 (4) - 20mAdc) ...
Page 128

E6582175  Example of run and frequency command switching Command mode and frequency setting mode switching Command mode selection With extension panel Terminal block RS485 communication (option) RKP007Z active (CMTB) priority clear  Input terminal (SCLC) function Input terminal function :108/109 :48/49 Terminal block...
Page 129

E6582175 6.2.2 Forward/reverse run selection (Panel keypad) fr : Forward/reverse run selection (Panel keypad)  Function Program the direction of rotation of the motor when the running and stopping are made using the RUN key and STOP key on the operation panel. Valid when ...
Page 130

E6582175 Selecting control mode pt : V/F control mode selection  Function The V/F controls shown below can be selected.  V/F constant  Variable torque  Automatic torque boost control *1  Vector control *1  Energy saving *1 ...
Page 131

E6582175 Steps in setting are as follows (In this example, the V/F control mode selection parameter  is set to  (Vector control). [Setting V/F control mode selection to 3 (sensorless vector control)] Operation panel LED display Operation action Displays the output frequency. (Perform during operation stopped.) ....
Page 132

E6582175 1) Constant torque characteristics Setting of V/F control mode selection  to  (V/F constant) This is applied to loads with equipment like conveyors and cranes that require the same torque at low speeds as at rated speeds. Base frequency voltage ...
Page 133

● Motor constant must be set If the motor you are using is a 4P Toshiba standard motor which has the same capacity as the inverter, there is basically no need to set the motor constant. There are three setting methods as mentioned below. In any method, set the following parameters according to the motor’s name plate.
Page 134

If the motor you are using is a 4P Toshiba standard motor which has the same capacity as the inverter, there is basically no need to set the motor constant. There are three setting methods as mentioned below. In any method, set the following parameters according to the motor’s name plate.
Page 135

Note that this feature can be used only for specific motors after tuned with an connected specific motor. For more information, contact your Toshiba distributor. If the specific motor is not connected at tuning, e-39 trip will occur.
Page 136

E6582175 9) Cautions for vector control 1) When performing vector control, look at the motor's name plate and set the following parameters.  (Base frequency 1),  (Base frequency voltage 1),  (Motor rated capacity),  (Motor rated current),  (Motor rated speed) 2) The sensorless vector control exerts its characteristics effectively in frequency areas below the base frequency ().
Page 137: Manual Torque Boost - Increasing Torque Boost At Low Speeds

E6582175 Manual torque boost - increasing torque boost at low speeds vb : Torque boost value 1  Function If torque is inadequate at low speeds, increase torque by raising the torque boost rate with this parameter. Base frequency voltage ...
Page 138: Signal Output

E6582175 Signal Output 6.5.1 Output running signal and braking signal (Low-speed signal) Refer to section 7.2.2 for output terminal function. f100 : Low-speed signal output frequency  Function When the output frequency become f100 or more, an ON signal will be generated. This signal can be used as an electromagnetic brake excitation/release signal.
Page 139

E6582175 6.5.2 Output of designated frequency reach signal f102 : Speed reach detection band  Function When the output frequency becomes equal to the setting by designated frequency  f102, an ON or OFF signal is generated. [Parameter setting] Parameter setting of designated frequency and detection band Title Function Adjustment range...
Page 140

E6582175 6.5.3 Output of set frequency speed reach signal f101 : Speed reach setting frequency f102 : Speed reach detection band  Function When the output frequency becomes equal to the frequency set by f101f102, an ON or OFF signal is generated. [Parameter setting] Parameter setting of frequency and detection band Title...
Page 141: Input Signal Selection

E6582175 Input signal selection 6.6.1 Priority selection (Both F and R are ON) f105 : Priority selection (Both F and R are ON)  Function This parameter allows you to select the direction in which the motor runs when a forward run (F) command and a reverse run (R) command are entered simultaneously.
Page 142

E6582175 (2) [f105 = 1 (Stop)]: If an F command and an R command are entered simultaneously, the motor will deceleration stop. Output frequency [Hz] Setting frequency Forward run Time[s] Reverse run Forward run command Reverse run command 6.6.2 Changing the voltage range of VIB terminal f107 : Analog input terminal selection (VIB) ...
Page 143

E6582175 6.6.3 Changing the functions of VIA and VIB terminals f109 : Analog/logic input selection (VIA/VIB)  Function This parameter allows you to choose between analog signal input and contact signal input for the VIA and VIB terminals. [Parameter setting] Title Function Adjustment range...
Page 144: Terminal Function Selection

E6582175 Terminal function selection 6.7.1 Keeping an input terminal function always active (ON) f104 : Always active function selection 1 f108 : Always active function selection 2 f110 : Always active function selection 3  Function This parameter specifies an input terminal function that is always to be kept active (ON). [Parameter setting] Title Function...
Page 145: Modifying Input Terminal Functions, Modifying Output Terminal Functions

E6582175 6.7.2 Modifying input terminal functions f111 : Input terminal selection 1A (F) f151 : Input terminal selection 1B (F) f112 : Input terminal selection 2A (R) f152 : Input terminal selection 2B (R) f113 : f153 : Input terminal selection 3A (RES) Input terminal selection 3B (RES) f114 : Input terminal selection 4A f154 : Input terminal selection 4B...
Page 146: Basic Parameters 2

E6582175 Basic parameters 2 6.8.1 Switching motor characteristics via terminal input f170 : Base frequency 2 f171 : Base frequency voltage 2 f172 : Torque boost value 2 f173 : Motor electronic-thermal protection level 2 f185 : Stall prevention level 2 ...
Page 147

E6582175  Setting of switching terminals To switch to motor 2, assign the following functions to a terminal not being used. It is also possible to switch to acceleration/deceleration 2 (AD2). Refer to section 6.27 for details. It is possible to set 3 functions for terminal F and R, and 2 functions for terminal S1 and RES. Input terminal function number Parameters changed from applicable parameters and default standards...
Page 148: V/f 5-point Setting

E6582175 V/f 5-point setting f190 : V/f5-point setting VF1 frequency f196 : V/f 5-point setting VF4 frequency f191 : V/f 5-point setting VF1 voltage f197 : V/f 5-point setting VF4 voltage f192 : V/f 5-point setting VF2 frequency f198 : V/f 5-point setting VF5 frequency f193 : V/f 5-point setting VF2 voltage f199 : V/f 5-point setting VF5 voltage f194 : V/f 5-point setting VF3 frequency...
Page 149: Setting Frequency Command Characteristics

E6582175 6.10.2 Setting frequency command characteristics f107 : Analog input terminal selection(VIB) f109 : Analog/logic input selection (VIA/VIB) f201 : VIA input point 1 setting f202 : VIA Input point 1 frequency f203 : VIA Input point 2 setting f204 : VIA Input point 2 frequency f209 : Analog input filter f210 : VIB input point 1 setting f211 : VIB input point 1 frequency...
Page 150

E6582175 [Parameter setting] Title Function Adjustment range Default setting Analog input terminal 0: 0-+10V f107 selection (VIB) 1: -10-+10V Analog/logic input 0: VIA - analog input VIB - analog input selection (VIA/VIB) 1: VIA - analog input VIB - contact input 2: - f109 3: VIA - contact input (Sink)
Page 151

E6582175 For details about analog signal setting, refer to section 7.3. 1) 0-10Vdc voltage input adjustment (VIA, VIB terminals) Adjust the frequency command for / the voltage input by setting the two 50/60 (Hz) points.  / 0 ( Hz) ...
Page 152

E6582175 6.10.3 Fine adjustment of analog frequency command f470 : VIA input bias f473 : VIB input gain f471 : VIA input gain f474 : VIC input bias f472 : VIB input bias f475 : VIC input gain  Function These parameters are used to fine adjust the relation between the frequency command input through the analog input terminal VIA, VIB, VIC and the output frequency.
Page 153

E6582175 6.10.4 Setting of frequency with the input from an external logic  : External logic input - UP response time  : External logic input - UP frequency steps  : External logic input - DOWN response time  : External logic input - DOWN frequency steps ...
Page 154

E6582175  Adjustment with continuous signals (Operation example 1) Set parameters as follows to adjust the output frequency up or down in proportion to the frequency adjustment signal input time: External logic input up/down frequency incremental gradient = f265/f264 setting time External logic input up/down frequency decremental gradient = f267/f266 setting time Set parameters as follows to adjust the output frequency up or down almost synchronously with the adjustment by the external logic input up/down frequency command:...
Page 155

E6582175 <<Sample sequence diagram 2: Adjustment with pulse signals>>  If two signals are impressed simultaneously  If a clear single and an up or down signal are impressed simultaneously, priority will be given to the clear signal.  If up and down signals are impressed simultaneously, the frequency will change at the specified up or down rate.
Page 156

E6582175 6.10.5 Setting of frequency with the pulse train input 146 : Logic input / pulse train input selection (S2) 378 : Number of pulse train input 679 : Pulse train input filter  Function These parameters are used to set output frequency by means of pulse train input signal of S2 terminal.
Page 157: Operation Frequency

E6582175 6.11 Operation frequency 6.11.1 Starting frequency/ Stop frequency f240 : Starting frequency f243 : Stop frequency setting  Function The frequency set with  is put out instantly when operation is started. Use the  parameter when a delay in response of starting torque due to the acceleration/deceleration time may affect the operation.
Page 158

E6582175 6.11.2 Run/stop control with frequency command f241 : Operation starting frequency f242 : Operation starting frequency hysteresis  Function The Run/stop of operation can be controlled simply with frequency command. [Parameter setting] Title Function Adjustment range Default setting Operation starting frequency 0.0-fh (Hz) f241 Operation starting frequency hysteresis...
Page 159: Dc Braking

E6582175 6.12 DC braking 6.12.1 DC braking f249 : PWM carrier frequency during DC braking f250 : DC braking starting frequency f251 : DC braking current f252 : DC braking time  Function A large braking torque can be obtained by applying a direct current to the motor. These parameters set the direct current to be applied to the motor, the application time and the starting frequency.
Page 160: Motor Shaft Fixing Control

E6582175 6.12.2 Motor shaft fixing control f254 : Motor shaft fixing control  Function This function is used to preheat the motor or to prevent the motor from running unexpectedly when its shaft is not restrained. [Parameter setting] Title Function Adjustment range Default setting f254...
Page 161: Stop At Lower-limit Frequency Operation (sleep Function)

E6582175 Note1: Nearly the same motor shaft fixing control can be exercised when entering a DC braking command with the signal at an input terminal. Note2: If a power failure occurs during motor shaft fixing control and the motor starts to coast, motor shaft fixing control will be canceled.
Page 162: Jog Run Mode

E6582175 Output frequency [Hz] ll+f391 Time[s]     Forward/ reverse Note: This function is valid when doing forward/reverse switching. When starting operation, f256 function will not work until output frequency reaches ll. When the output frequency exceeds ll, f259 function will be invalid until operation signal is OFF. 6.14 Jog run mode f260 : Jog run frequency f261 : Jog run stopping pattern...
Page 163

E6582175 [Setting of jog run mode (RES-CC)] Ex) Assign jog run mode to control terminal RES. Title Function Adjustment range Setting Input terminal selection (RES) 0-203 f113 (Jog run mode) Note 1: During the jog run mode, low speed detection signal (LOW) is output but designated frequency reach signal (RCH) is not output, and PID control does not work.
Page 164

E6582175  Panel jog mode (if f262 is set to 1)  The direction of rotation can change by using extension panel. Using RKP007Z : Display switches to fjog and rjog by every pressing the FWD/REV key. Using RKP002Z : Pressing the UP key changes display to fjog and pressing the DOWN key changes display to rjog.
Page 165: Jump Frequency - Avoiding Resonant Frequencies

E6582175 6.15 Jump frequency - avoiding resonant frequencies f270 : Jump frequency 1 f271 : Jumping width 1 f272 : Jump frequency 2 f273 : Jumping width 2 f274 : Jump frequency 3 f275 : Jumping width 3  Function Resonance due to the natural frequency of the mechanical system can be avoided by jumping the resonant frequency during operation.
Page 166: Bumpless Operation

E6582175 6.16 Bumpless operation f295 : Bumpless operation selection f732 : Local/remote key prohibition of extension panel f750 : Easy key function selection  Function When switching from Remote mode to Local mode, the status of start and stop, and operating frequency at Remote mode are moved to Local mode.
Page 167

E6582175 Operation example : Remote mode ( cmod=0: (Terminal block)) Remote mode Local mode EASY Setting frequency and start/stop status are moved to Local mode Output when switching from Remote frequency mode to Local mode. Motor runs continuously for the F-CC case described on the left.
Page 168: Low Voltage Operation

E6582175 6.17 Low voltage operation f297 : Low voltage operation upper limit frequency f298 : Low voltage operation DC voltage  Refer to “Low voltage operation instruction manual: E6581918” for details. 6.18 PWM carrier frequency aul : Overload characteristic selection f300 : PWM carrier frequency f312 : Random mode f316 : PWM carrier frequency control mode selection...
Page 169

E6582175 [Parameter setting] Title Function Adjustment range Default setting 0: - Overload characteristic 1: Constant torque characteristic（150%-60s） selection 2: Variable torque characteristic（120%-60s） PWM carrier frequency 2.0-16.0 (kHz) 12.0 f300 0: Disabled 1: Random mode 1 Random mode f312 2: Random mode 2 3: Random mode 3 0: Carrier frequency without reduction 1: Carrier frequency with automatic reduction...
Page 170

E6582175  Load reduction (current reduction) by carrier frequency, ambient temperature and input volgate [240V class] In case of aul=1 (Constant torque characteristic (150%-60s)) setting. PWM carrier frequency VFS15- Ambient temperature VFS15S- 2.0k~4.0kHz 4.1k~12.0kHz 12.1k~16.0kHz 40C or less 1.5 A 1.5 A 1.5 A 2002PL-W1...
Page 171

E6582175 [500V class] In case of aul=1 (constant torque characteristic (150%-60s) setting) (Input voltage 480V or less) PWM carrier frequency VFS15- Ambient temperature 2.0k~4.0kHz 4.1k~12.0kHz 12.1k~16.0kHz 1.5 A 1.5 A 1.5 A 40C or less 4004PL-W1 Above 40  50C 1.5 A 1.5 A 1.5 A...
Page 172

E6582175 (Input voltage above 480V) PWM carrier frequency Ambient VFS15- temperature 2.0k~4.0kHz 4.1k~12.0kHz 12.1k~16.0kHz 1.5 A 1.5 A 1.2 A 40C or less Above 40  50C 4004PL-W1 1.5 A 1.5 A 1.2 A Above 50  60C 1.4 A 1.2 A 1.0 A 40C or less...
Page 173

E6582175 In case of aul=2 (Variable torque characteristic (120%-60s)) setting. PWM carrier frequency Ambient VFS15- temperature 2.0k~4.0kHz 2004PM-W1 40C or less 3.5 A 2007PM-W1 6.0 A 40C or less 2015PM-W1 9.6 A 40C or less 2022PM-W1 40C or less 12.0 A 2037PM-W1 19.6 A 40C or less...
Page 174

E6582175 In case of aul=2 (Variable torque characteristic (120%-60s)) setting. PWM carrier frequency Ambient VFS15- temperature 2.0k~4.0kHz 4004PL-W1 40C or less 2.1 A 4007PL-W1 3.0 A 40C or less 4015PL-W1 5.4A 40C or less 4022PL-W1 40C or less 6.9 A 4037PL-W1 11.1 A 40C or less...
Page 175: Trip-less Intensification

E6582175 6.19 Trip-less intensification 6.19.1 Auto-restart (Restart of coasting motor) f301 : Auto-restart control selection  Refer to section 5.9 for details. 6.19.2 Regenerative power ride-through control/Deceleration stop during power failure/Synchronized acceleration/deceleration f302 : Regenerative power ride-through control (Deceleration stop) f317 : Synchronized deceleration time f318 : Synchronized acceleration time •...
Page 176

E6582175 [Parameter setting] Title Function Adjustment range Default setting 0: Disabled 1: Regenerative power ride-through control 2: Deceleration stop during power failure Regenerative power ride-through 3: Synchronized acceleration / deceleration f302 control (Deceleration stop) (signal) 4: Synchronized acceleration / deceleration (signal + power failure) Synchronized deceleration time (time elapsed between start of...
Page 177

E6582175 [If momentary power failure occurs] Input voltage Internal DC voltage level Motor speed Non-stop control Normal acceleration Note 5: If momentary power failure occurs during deceleration stop, power ride-through control will not be performed.  An example of setting when f302=2 Input voltage Motor speed Time...
Page 178

E6582175  An example of setting when f302=3 (when the function of receiving power failure synchronized signal is assigned to the input terminal S1) f114 (Input terminal function selection 4A (S1)) =62 (Power failure synchronized signal) Power failure Inverter 1 synchronized signal (terminal S1)
Page 179

E6582175 Input voltage Power failure synchronized signal Inverter 1 (terminal S1) Motor speed   Time Inverter 2   F-67...
Page 180: Retry Function

E6582175 6.19.3 Retry function f303 : Retry selection (number of times) Caution  Stand clear of motors and equipment. If the motor and equipment stop when the alarm is given, selection of the retry function will restart them suddenly after the specified time has elapsed. This could result in unexpected injury. Mandatory ...
Page 181

E6582175 6.19.4 Dynamic (regenerative) braking - For abrupt motor stop f304 : Dynamic braking selection f308 : Dynamic braking resistance f309 : Dynamic braking resistor capacity f626 : Over-voltage stall protection level  Function The inverter does not contain a braking resistor. Connect an external braking resistor in the following cases to enable dynamic braking function: 1) when decelerating the motor abruptly or if overvoltage tripping (op) occurs during deceleration stop...
Page 182

E6582175 1) Connecting an external braking resistor (optional) Separate-optional resistor (with thermal fuse) Braking resistor (optio nal) MCCB PA/+ Motor U/T1 R/L1 Main circuits V/T2 S/L2 P ower supply W/T3 T/L3 Inverter Connecting thermal relays and an external braking resistor TH-R Braking resistor (optional) MCCB...
Page 183

E6582175 [Parameter setting] Title Function Setting Dynamic braking selection f304 f305 Overvoltage limit operation Dynamic braking resistance Proper value f308 f309 Dynamic braking resistor capacity Proper value 136 (%) (240V class) f626 Over-voltage stall protection level 141 (%) (500V class) ●...
Page 184

Note 1: The data in Rating above refer to the resultant resistance capacities (watts) and resultant resistance values (Ω). Note 2: Braking resistors for frequent regenerative braking are optionally available. For more information, contact your Toshiba distributor. Note 3: Type-form of “PBR-” indicates the thermal fuse”. Type-form of “PBR7-“ indicates the thermal fuse and thermal relay.
Page 185: Avoiding Overvoltage Tripping

E6582175 6.19.5 Avoiding overvoltage tripping f305 : Overvoltage limit operation f319 : Regenerative over-excitation upper limit f626 : Overvoltage stall protection level  Function These parameters are used to keep the output frequency constant or increase it to prevent overvoltage tripping in case the voltage in the DC section rises during deceleration or varying speed operation.
Page 186

E6582175 6.19.6 Output voltage adjustment/Supply voltage correction : Base frequency voltage 1 f307 : Supply voltage correction (output voltage limitation)  Function Supply voltage correction: Prevent torque decline during low-speed operation. Maintains a constant V/F ratio, even when the input voltage fluctuates. Output voltage limitation: Limits the voltage to prevent outputting the voltage exceeding base frequency voltage (vlv).
Page 187

E6582175 [f307=0: No voltage compensation/output voltage limited] [f307=1: Voltage compensation/output voltage limited] Input voltage Input voltage High Input voltage High  Output frequency Output frequency  * The above is applied when V/F control mode selection parameter  is set to "0" or "1". [f307=2: No voltage compensation/no output voltage limit] [f307=3: Voltage compensation/no output voltage control] Input voltage...
Page 188: Drooping Control

E6582175 6.19.7 Reverse-run prohibition f311 : Reverse-run prohibition  Function This function prevents the motor from running in the forward or reverse direction when it receives the wrong operation signal. [Parameter setting] Title Function Adjustment range Default setting 0: Forward/reverse run permitted Reverse-run prohibition 1: Reverse run prohibited f311...
Page 189: Maximum Frequency

E6582175 Power running ● The drooping control function is to operate the power-running motor at operating frequency f (Hz), which is lower than command frequency f (Hz) by droop frequency Δf (Hz), when the torque current is T (%). (See the figure above.) ...
Page 190: Light-load High-speed Operation Function

E6582175 6.21 Light-load high-speed operation function f328 : Light-load high-speed operation f335 : Switching load torque during selection power running : Light-load high-speed learning f336 : Heavy-load torque during power f329 function running f330 : Automatic light-load high-speed f337 : Heavy-load torque during operation frequency constant power running f331 : Light-load high-speed operation...
Page 191: Acceleration/deceleration Suspend Function (dwell Function)

E6582175 6.22.2 Hit and stop control 382 : Hit and stop control 383 : Hit and stop control frequency  Refer to “Hit & Stop control: E6581873” for details. 6.23 Acceleration/deceleration suspend function (Dwell function) f349 : Acceleration/deceleration suspend f352 : Deceleration suspend function frequency f350 : Acceleration suspend frequency...
Page 192

E6582175 1) To suspend acceleration or deceleration automatically Set the frequency with f350 or f352 and the time with f351 or f353, and then set f349 to 1. When reached the set frequency, the motor stops accelerating or decelerating to run at a constant speed. Output frequency [Hz] ...
Page 193: Pid Control

E6582175 Output frequency [Hz]   Time [s]  Stall f351 (Momentary acceleration (deceleration) suspend time) = (t1 + t2 + ts)  Stall control The inverter will automatically change the operation frequency when it detects an overcurrent, overload or overvoltage.
Page 194

E6582175  Function Process control including keeping airflow, pressure, and the amount of flow constant, can be exercised using feedback signals (4 to 20mA, 0 to 10V) from a detector. Or, it is also possible to always set 0 for integral and differential at terminal input. ...
Page 195

E6582175 External connection R/L1 U/T1 S/L2 V/T2 Pressure T/L3 W/T3 transmitter (1) PID set value DC: 0 to 10V (2)Feedback signals DC : 4~20mA 2) Selecting PID set value and feedback value PID set value and feedback value can be combined as follows for the PID control. (1) PID set value (2) Feedback value PID set value signal selection f389...
Page 196

E6582175 3) Setting PID control Set "" (Process type PID control operation) in the parameter f360 (PID control). (1) Set parameters acc(acceleration time) and dec (deceleration time) to the system fitting values. (2) Please set the following parameters to place limits to the setting value and the control value. Placing a limit to the PID set value : The parameter f367(Upper limit of set value), f368 (Lower limit of set value) Placing a limit to the output frequency : The parameter ul(Upper limit frequency ), ll (Lower limit...
Page 197

E6582175 f363 (I-gain adjustment parameter) This parameter adjusts the integral gain level during PID control. Any remaining deviations (residual deviation offset) during proportional action are cleared to zero. A larger I-gain adjustment value reduces residual deviations. Too large an adjustment value, however, results in an unstable event such as hunting.
Page 198

E6582175 5) Adjusting feedback value Make adjustment by converting input level of the feedback value into frequency. Refer to section 6.10.2 for details. Example of 0 - 10 Vdc voltage input Example of 0 - 10 Vdc voltage input Example of 4 - 20 mAdc voltage input setting setting setting...
Page 199

E6582175 Comparing PID set value and feedback value If the PID set value specified using f389 and the feedback value from f369 match the range of  f167, an ON or OFF signal will be sent out from the output terminal. Assign function number 144/145, Signal in accordance of PID set value, to an output terminal PID set value f389...
Page 200: Setting Motor Constants

E6582175 6.25 Setting motor constants 6.25.1 Setting motor constants for induction motors f400 : Auto-tuning f416 : Motor no-load current f401 : Slip frequency gain f417 : Motor rated speed f402 : Automatic torque boost value f459 : Load inertia moment ratio f405 : Motor rated capacity f462 : Speed reference filter f415 : Motor rated current...
Page 201

E6582175 [Selection 2: Setting vector control and auto-tuning independently] Set vector control, automatic torque boost, energy saving and auto-tuning individually. After setting pt (V/F control mode selection), auto-tuning starts. Set the auto-tuning parameter f400 to 2 (Auto-tuning enabled) [Parameter setting] Title Function Adjustment range...
Page 202

E6582175 [Selection 4: Setting vector control and manual tuning independently] If an "etn1" tuning error is displayed during auto-tuning or when vector control characteristics are to be improved, set independent motor constants. If an "etn1" tuning error is displayed, Set f400 to 0. [Parameter setting] Title Function...
Page 203

E6582175 6.25.2 Setting motor constants for PM motors f400 : Auto-tuning f462 : Speed reference filter f402 : Automatic torque boost value coefficient f405 : Motor rated capacity f912 : q-axis inductance f415 : Motor rated current f913 : d-axis inductance f417 : Motor rated speed f459 : Load inertia moment ratio Caution:...
Page 204

E6582175 Set f400 to 2 to before the start of operation. Tuning is performed at the start of the motor. ● Precautions on auto-tuning (1) Conduct auto-tuning after the motor has been connected properly and operation completely stopped. If auto-tuning is conducted immediately after operation stops, the presence of a residual voltage may result in abnormal tuning.
Page 205

E6582175 Setting procedure Adjust the following parameters: f402: Adjust the primary resistive component of the motor. Decreases in torque due to a possible voltage drop during low-speed operation can be suppressed by setting a large value in this parameter. Be careful as setting a value larger than necessary may lead to an increased current causing a trip at low speeds.
Page 206: Torque Limit

E6582175 6.26 Torque limit 6.26.1 Torque limit switching f441 : Power running torque limit 1 level f445 : Regenerative braking torque limit f443 : Regenerative braking torque limit 2 level 1 level f454 : Constant output zone torque limit f444 : Power running torque limit 2 level selection ...
Page 207

E6582175 [Parameter setting] Title Function Adjustment range Default setting 0.0-249.9 (%), 250.0 f441 Power running torque limit 1 level 250.0: Disabled 0.0-249.9 (%), 250.0 f443 Regenerative braking torque limit 1 level 250.0: Disabled Constant output zone torque limit 0: Constant output limit f454...
Page 208

E6582175 Operation frequency Frequency [Hz] If the torque limit function is not activated Actual speed Time [s] Torque [N·m] Torque limit level Time [s] Mechanical brake (released) Time [s] (2) f451=1(In sync with min. time) The operation frequency keeps increasing, even if the torque limit function is activated. In this control mode, the actual speed is kept in sync with the operation frequency, while torque is held at a limit level in spite of torque decrease when releasing the mechanical brake.
Page 209: Power Running Stall Continuous Trip Detection Time

E6582175 6.26.3 Power running stall continuous trip detection time f452 : Power running stall continuous trip detection time • Function A function for preventing lifting gear from failing accidentally. If the stall prevention function is activated in succession, the inverter judges that the motor has stalled and trips. [Parameter setting] Title Function...
Page 210

E6582175 2) In case of torque limitation Output frequency [Hz] “2” trip Time [s] Output torque [%]  Time [s] less than   ot2 trip is occurred if the output torque reached the power running torque limit level (f441) or more, and this situation maintain in f452 during power running.
Page 211: Acceleration/deceleration Time 2 And 3

E6582175 6.27 Acceleration/deceleration time 2 and 3 6.27.1 Selecting acceleration/deceleration patterns f502 : Acceleration/deceleration 1 pattern f506 : S-pattern lower-limit adjustment amount f507 : S-pattern upper-limit adjustment amount  Function These parameters allow you to select an acceleration/deceleration pattern that suits the intended use. Title Function Adjustment range...
Page 212

E6582175 S-pattern 2 acceleration/deceleration Select this pattern to obtain slow acceleration in a demagnetizing region with a small motor acceleration torque. Perfect for high-speed spindle operation. Output frequency [Hz] Output frequency [Hz] Maximum frequency Maximum frequency   Set frequency Set frequency Base frequency Base frequency...
Page 213

E6582175 Title Function Adjustment range Default setting Acceleration time 2 0.0-3600 (0.00-360.0) [sec] 10.0 f500 f501 Deceleration time 2 0.0-3600 (0.00-360.0) [sec] 10.0 1: Acceleration/deceleration 1 Acceleration/deceleration selection 2: Acceleration/deceleration 2 f504 (1, 2 , 3) (Panel keypad) 3: Acceleration/deceleration 3 f510...
Page 214

E6582175 (1) Acceleration at the gradient corresponding (4) Deceleration at the gradient corresponding to acceleration time acc to deceleration time f511 (2) Acceleration at the gradient corresponding (5) Deceleration at the gradient corresponding to acceleration time f500 to deceleration time f501 (3) Acceleration at the gradient corresponding (6) Deceleration at the gradient corresponding to acceleration time f510...
Page 215: Shock Monitoring Function

E6582175  How to set parameters a) Operating method: Terminal input Set the operation control mode selection cmod to 0. b) Use the S2 and S3 terminals for switching. (Instead, other terminals may be used.) S2: Acceleration/deceleration switching signal 1 S3: Acceleration/deceleration switching signal 2 Title Function...
Page 216: Protection Functions

E6582175 6.29 Protection functions 6.29.1 Setting motor electronic thermal protection thr : Motor electronic-thermal protection level 1 173 : Motor electronic-thermal protection level 2 f607 : Motor 150% overload detection time f632 : Electronic-thermal memory Refer to section 5.6. 6.29.2 Setting of stall prevention level f601 : Stall prevention level 1 f185 : Stall prevention level 2 Caution...
Page 217: Emergency Stop

E6582175 6.29.3 Inverter trip retention f602 : Inverter trip retention selection  Function If the inverter trips, this parameter will retain the corresponding trip information. Trip information that has thus been stored into memory can be displayed, even after power has been reset. [Parameter setting] Title Function...
Page 218

E6582175 1) Emergency stop from terminal Emergency stop occurs at contact a or b. Follow the procedure below to assign a function to an input terminal and select a stop method. [Parameter setting] Title Function Adjustment range Default setting f515 Deceleration time at emergency stop 0.0-3600 (360.0) (s) 10.0 0: Coast stop...
Page 219: Output Phase Failure Detection

E6582175 6.29.5 Output phase failure detection f605 : Output phase failure detection selection  Function This parameter detects inverter output phase failure. If the phase failure status persists for one second or more, trip occurs and the failure signal FL will be activated. Trip information epho will be displayed.
Page 220

E6582175 6.29.6 Input phase failure detection f608 : Input phase failure detection selection  Function This parameter detects inverter input Phase failure. If the abnormal voltage status of main circuit capacitor persists for few minutes or more, the tripping function and the failure signal FL will be activated.
Page 221

E6582175 6.29.7 Control mode for small current f609 : Small current detection hysteresis f610 : Small current trip/alarm selection f611 : Small current detection current f612 : Small current detection time  Function If the output current falls below the value set at f611 and doesn’t return above f611+f609 for a time that exceeds the value set at f612, tripping or output alarm will be activated.
Page 222

E6582175 6.29.8 Detection of output short-circuit f613 : Detection of output short-circuit at start-up  Function This parameter detects inverter output short-circuit. It can be usually detected in the length of the standard pulse. When operating low-impedance motor such as high-speed motor, however, select the short-time pulse.
Page 223

E6582175 6.29.10 Over-torque trip f615 : Over-torque trip/alarm selection f616 : Over-torque detection level f618 : Over-torque detection time f619 : Over-torque detection hysteresis  Function If the torque value exceeds the value set at f616 and doesn’t return below f616-f619 for a time that exceeds the value set at f618, tripping or output alarm will be activated.
Page 224: Cooling Fan Control Selection

E6582175 <Example of operation> 1) Output terminal function: 28 (OT) Over-torque detection f615=0 (Alarm only) Over-torque signal output less than    － Torque (%) Time [sec] When f615 = 1 (tripping), the inverter will trip if over-torque lasts for the period of time set with f618 .
Page 225: Cumulative Operation Time Alarm Setting, Undervoltage Trip

E6582175 6.29.12 Cumulative operation time alarm setting f621 : Cumulative operation time alarm setting  Function Put out an alarm signal after a lapse of the cumulative operation time set with f621 . [Parameter setting] Title Function Adjustment range Default setting Cumulative operation time 0.0-999.0 (100 hours) 876.0...
Page 226

E6582175 =: Inverter is stopped. However, it is not tripped (Failure signal FL not activated). The inverter stop (Failure signal FL not activated.), only after detection of a voltage not exceeding 50% of its rating. Be sure to connect the input AC or DC reactor specified in section 10.4. [Parameter setting] Title Function...
Page 227

E6582175 6.29.15 Parts replacement alarms f634 : Annual average ambient temperature (Parts replacement alarms)  Function Calculate the remaining service life of the cooling fan, main circuit capacitor and on-block capacitor based on the cumulative power on time, cumulative operation time, cumulative fan operation time, the output current (inverter load factor) and the setting of f634 .
Page 228

E6582175 6.29.16 Motor PTC thermal protection f147 : Logic input / PTC input selection (S3) f645 : PTC thermal selection f646 : Resistor value for PTC detection  Function This function is used to protect motor from overheating using the signal of PTC built-in motor. The trip display is “...
Page 229

E6582175 6.29.17 Number of starting alarm f648 : Number of starting alarm  Function Counting the number of starting, when it will reach the value of parameter f648 setting, it will be displayed and alarm signal is output. [Parameter setting] Title Function Adjustment range...
Page 230: Forced Fire-speed Control Function

E6582175 6.30 Forced fire-speed control function f650 : Forced fire-speed control selection f294 : Preset-speed frequency 15  Function With forced fire-speed control, operate the motor at the specified frequency in case of an emergency. Two kinds of operation are selectable by assignment of input terminal function. (1) Input terminal function 56 (FORCE) : Input signal is retained once signal is ON.
Page 231: Override

E6582175 6.31 Override f205 : VIA input point 1 rate f206 : VIA input point 2 rate f214 : VIB input point 1 rate f215 : VIB input point 2 rate f220 : VIC input point 1 rate f221 : VIC input point 2 rate f660 : Override addition input selection f661 : Override multiplication input selection f729 : Operation panel override multiplication gain...
Page 232

E6582175 The override functions calculate output frequency by the following expression: Value [%] selected with  Frequency command value × (1+ )+Value [Hz] selected with f660 1) Additive override In this mode, an externally input override frequency is added to operation frequency command. [Ex.1: VIA (Reference frequency), VIC (Override input)] [Ex.2: VIB (Reference frequency), VIA (Override input)] Output frequency Over-ridden frequency...
Page 233

E6582175 2) Multiplicative override In this mode, each output frequency is multiplied by an externally override frequency. [Ex.1: VIA (Reference frequency), VIC (Override input)] [Ex.2: VIB (Reference frequency), VIA (Override input)] Output frequency Over-ridden frequency Output  Over-ridden frequency frequency Forward run ...
Page 234: Analog Input Terminal Function Selection

E6582175 6.32 Analog input terminal function selection f214 : VIB input point 1 rate f215 : VIB input point 2 rate f663 : Analog input terminal function selection (VIB)  Function Parameter is normally set from operation panel. However some parameters can be continuously set from external analog input by using this function.
Page 235: Adjustment Parameters

E6582175 6.33 Adjustment parameters 6.33.1 Inputting integral input power pulse  : Integral input power pulse output unit  : Integral input power pulse output width  Function Pulse signal can be output each time integral input power reaches integral power unit that is set by f667 .
Page 236

E6582175 [Parameter setting] Reference Default of maximum Title Function Adjustment range setting value of f677 Logic output/pulse train 0: Logic output – f669 output selection (OUT) 1: Pulse train output 0: Output frequency fh  1: Output current 185% 2: Frequency command value fh ...
Page 237

E6582175 6.33.3 Calibration of analog output f681 : Analog output signal selection f684 : Analog output filter f691 : Inclination characteristic of analog output f692 : Analog output bias  Function Output signal from the FM terminal can be switched between 0 to 1mAdc output, 0 to 20mAdc output, and 0 to 10Vdc output with the f681 setting.
Page 238

E6582175 ■ Example of setting f681 =1, f691 =1, f692 =0(%) f681 =1, f691 =1, f692 =20(%) f681 =1, f691 =0, f692 =100(%) f681 =1, 691 =0, f692 =100(%) ● The analog output inclination can be adjusted using the parameter . Refer to section 5.1 about how to adjustment.
Page 239: Operation Panel Parameter

E6582175 6.34 Operation panel parameter 6.34.1 Prohibition of key operations and parameter settings f700 : Parameter protection selection f730 : Panel frequency setting prohibition (fc) f731 : Disconnection detection of extension panel f732 : Local/remote key prohibition of extension panel f733 : Panel operation prohibition (RUN key) f734 : Panel emergency stop operation prohibition f735 : Panel reset operation prohibition...
Page 240

E6582175 Title Function Adjustment range Default setting Panel emergency stop operation 0: Permitted, 1: Prohibited f734  prohibition f735  Panel reset operation prohibition 0: Permitted, 1: Prohibited cmod / fmod change prohibition 0: Permitted, 1: Prohibited f736  during operation All key operation prohibition Note 2) 0: Permitted, 1: Prohibited ...
Page 241

E6582175 ■ Password examination method When f738 or f739 are read out and the value is 9999 , a password has already been set. Password has to be removed in order to change parameters. Enter a the number ( 1 to 9998 ) registered to f739 when the password was set for f738 . If the password matches, pass blinks on the display and the password is removed.
Page 242

E6582175 6.34.2 Change the unit (A/V) from a percentage of current and voltage f701 :Current/voltage unit selection  Refer to section 5.10.1. 6.34.3 Display the motor or the line speed f702 : Frequency free unit display magnification f703 : Frequency free unit coverage selection f705 : Inclination characteristic of free unit display f706 : Free unit display bias ...
Page 243

E6582175  When f707 is not 0.00, and f708 is not 0 The value displayed on the panel can be changed in steps. (In the case of the setting “initial panel display selection” f710 = 0 [Output frequency])  Panel display = Output frequency × ...
Page 244

E6582175 [Parameter setting] Title Function Adjustment range Default setting 0: Output frequency (Hz/free unit) 1: Output current (%/A) 2: Frequency command value (Hz/free unit) 3: Input voltage (DC detection) (%/V) 4: Output voltage (command value) (%/V) 5: Input power (kW) 6: Output power (kW) 7: Torque (%) 8: -...
Page 245

E6582175 6.34.6 Change display of the status monitor f711 to f718 : Status monitor 1 to 8 Change monitor display items in the status monitor mode.  Refer to chapter 8 for details. 6.34.7 Change the status monitor condition f709 : Standard monitor hold function f746 : Status monitor filter ...
Page 246

E6582175 6.34.8 Cancel the operation command f719 : Selection of operation command clear  Function This parameter allows you to select operation command retained or operation command cleared, when coast stop occurs due to standby terminal function (ST), coast stop command terminal function (FRR), and when under voltage in main circuit alarm ( moff ) occurs, during panel operation or RS485 communication operation.
Page 247

E6582175 6.34.9 Select the operation panel stop pattern f721 : Selection of operation panel stop pattern  Function This parameter are used to select a panel stop pattern in which the motor started by pressing the key on the operation panel. STOP Deceleration stop The motor slows down to a stop in the deceleration time set with ...
Page 248: Tracing Functions

E6582175 [Parameter setting] Title Function Adjustment range Default setting 0: hello 1: f791 to f794  Panel display selection at power on 2, 3: - 0-FFFF 2d2d  1st and 2nd characters of  0-FFFF 2d2d  3rd and 4th characters of  0-FFFF 2d2d ...
Page 249: Integrating Wattmeter

E6582175 6.36 Integrating wattmeter f748 : Integrating wattmeter retention selection f749 : Integrating wattmeter display unit selection  Function At the main power off, display unit of integral output power values and whether or not retain integral output power values are selectable. The integrating wattmeter display can be cleared by the signal to the input terminal.
Page 250: Communication Function

E6582175 6.38 Communication function 6.38.1 Setting of communication function f800 : Baud rate f814 : Communication command  f801 : Parity point 2 frequency f802 : Inverter number f829 : Selection of communication f803 : Communication time-out time protocol f804 : Communication time-out action f856 : Number of motor poles for...
Page 251

(setting of point frequencies) in an abbreviated manner. ● Communication protocol … Toshiba inverter protocol and Modbus RTU protocol are supported. ● 2-wire RS485 communication options are as follows. (1) USB communication conversion unit (Type: USB001Z)
Page 252

Communication command point 1 f812  0.0- fh frequency Communication command point 2 f813  0-100 setting Communication command point 2 0.0- fh f814  frequency Selection of communication 0: Toshiba inverter protocol f829 protocol 1: Modbus RTU protocol F-140...
Page 253

E6582175 Title Function Adjustment range Default setting 1: 2 poles 2: 4 poles 3: 6 poles Number of motor poles for 4: 8 poles f856  communication 5: 10 poles 6: 12 poles 7: 14 poles 8: 16 poles 0: No selection 1: Communication command 1 Block write data 1 f870...
Page 254

Moreover, selecting local mode with the EASY key as Local / remote key function changes to panel frequency/panel operation mode.  Transmission specifications Item Specifications MODBUS-RTU TOSHIBA inverter protocol Communication protocol protocol Interface RS485 compliant Half duplex [Serial bus type (Line terminations resistor necessary at...
Page 255

E6582175  Connection example when using the computer link function <Independent communication> Perform computer-inverter connection as follows to send operation frequency commands from the host computer to inverter No. 3: : Wiring (Host  INV) : Data Host computer : Response data (INV  Host) ...
Page 256

E6582175 <Broadcast communication> When sending an operation frequency command via a broadcast from the host computer : Wiring : Data (Host  INV) : Response data (INV  Host) Host computer      No.00 No.01 No.02 No.03 No.29 No.30 INV= inverter...
Page 257

E6582175  Peer-to-peer communication When all slave inverters are connected they operate at the same frequency as the master inverter (no setting of point frequencies in this case) : Wiring : Data (Master  Slave) Master inverter    ...
Page 258: Permanent Magnet Motors

E6582175 6.38.4 Open network option c700 to c789 , c800 to c830 : CANopen communication parameters c001 to c111 , c160 to c164 : Communication option common c885 to c896 , c900 to c999 parameters c120 to c148 : CC-Link option parameters c150 to c159 : PROFIBUS DP option parameters c200 to c203 : DeviceNet option parameters c400 to c421 , c850 to c880 : EtherCAT option parameters...
Page 259: Traverse Function

 Factory specific coefficient 9L  Refer to section 6.25.2 about setting motor constants. Note 1: When using an PM motor, consult your Toshiba distributor, since the inverter is not compatible with all types of PM motors. Note 2: The inverter may fail to detect step-out in some cases, because it uses an electrical method to detect step-out.
Page 260: Operating External Signals

E6582175 7. Operations with external signal Operating external signals You can control the inverter externally. The parameter settings differ depending upon your method of operation. Determine your method of operation (the operational signal input method, speed (frequency) command input method) before using the procedure below to set the parameters.
Page 261: Applied Operations By An I/o Signal (operation From The Terminal Block)

E6582175 Applied operations by an I/O signal (operation from the terminal block) Input terminal sink and source logic are set by using slide switch SW1. 7.2.1 Input terminal function [Control terminal block] (sink logic) SOURCE SINK This function is used to send a signal to the input terminal from an external programmable controller to operate or configure the inverter.
Page 262

E6582175 Note 1) Multiple functions assigned to a single terminal operate simultaneously. Note 2) In case of setting always active function, assign the menu number to ,  and  (always active function selection). Note 3) In case of using terminal S2 as a logic input, set the parameter =0 (logic input). Note 4) In case of using terminal S3 as a logic input, set the slide switch SW2 (lower) to S3 side and the parameter =0 (logic input).
Page 263

E6582175 Forward run (F) : Pressing forward run (F) rotates forward at Forward run the specified frequency command value. Reverse run Reverse run (R) : Pressing reverse run (R) rotates in reverse at the specified frequency command value. HD (S2): Pressing HD (S2) decelerates and stops. Output Forward frequency...
Page 264

E6582175  List of logic input terminal function settings Parameter Parameter programmed value programmed value Function Function Positive Negative Positive Negative logic logic logic logic Integrating wattmeter (kWh) display     No function     clear ...
Page 265

E6582175 7.2.2 Output terminal function (sink logic) [Control terminal block] This function is used to output a variety of signals to external devices from the inverter. With the logic output terminal function, you can SOURCE SINK select from multiple output terminal functions. Set two types of functions for the RY-RC, OUT terminal and then you can output when either one or both of them is ON.
Page 266

E6582175  Assign one type of function to an output terminal Terminal Title Function Adjustment range Default setting symbol 4 (Low-speed detection RY-RC  Output terminal selection 1A signal) 6 (Output frequency  Output terminal selection 2A 0 - 255 attainment signal) ...
Page 267

E6582175 (1) Output signals when two types of functions are simultaneously turned ON. <AND> In case of RY-RC terminal, signals are output when parameter  = 0 or 2, and the functions set at parameters  and  are simultaneously turned on. ●...
Page 268

E6582175 (3) Holding the output of signals in ON status ● If the conditions for activating the functions assigned to RY-RC terminal and OUT terminal agree with and as a result the output of signals is put in ON status, the output of signals is held ON, even if the conditions change.
Page 269

E6582175  List of output terminal function settings <Explanation of terminology>  Alarm …... Alarm output when a setting has been exceeded.  Pre-alarm …... Alarm output when the inverter may cause a trip during continued operation. List of detection levels for output terminal selection Parameter Parameter programmed value...
Page 270

E6582175 Note 1) ON with positive logic : Open collector output transistor or relay turned ON. OFF with positive logic : Open collector output transistor or relay turned OFF. ON with negative logic : Open collector output transistor or relay turned OFF. OFF with negative logic : Open collector output transistor or relay turned ON.
Page 271: Speed Instruction (analog Signal) Settings From External Devices

E6582175 Speed instruction (analog signal) settings from external devices [Control terminal block] Function of analog input terminals can be selected from four functions (external potentiometer, 0 to 10Vdc, 4 (0) to 20mAdc, SOURCE SINK -10 to +10Vdc). The selective function of analog input terminals gives system design flexibility.
Page 272

E6582175 7.3.1 Settings depending on voltage (0 to 10 V) input <external potentiometer> You can set the frequency settings by connecting the external potentiometer (1k to 10kΩ) between PP, VIA, and CC terminals. You can also set by inputting an analog voltage signal of 0 to 10Vdc between the VIA and CC terminals. The following shows examples when the run command is input from the terminal.
Page 273

E6582175 7.3.2 Settings depending on current (4 to 20 mA) input You can set the frequency settings by inputting an analog current signal of 4 (0) to 20mA dc between the VIC and CC terminals. The following shows examples when the run command is input from the terminal. Title Function Adjustment range...
Page 274

E6582175 7.3.3 Settings depending on voltage (-10 to +10 V) input You can set the frequency settings by inputting an analog voltage signal of -10 to +10Vdc between the VIB and CC terminals. The following shows examples when the run command is input from the terminal. Title Function Adjustment range...
Page 275: Monitoring The Operation Status

E6582175 8. Monitoring the operation status Flow of status monitor mode Status monitor mode Flow of monitor as following About Setting monitor mode 20 kinds of data   MODE MODE ● Display mode Standard monitor mode (Refer to section 4.1) 60.0 ...
Page 276: Status Monitor Mode

E6582175 Status monitor mode 8.2.1 Status monitor under normal conditions In this mode, you can monitor the operation status of the inverter. To display the operation status during normal operation: Press the MODE key twice. Setting procedure (eg. operation at 60Hz) Panel Communic Item displayed...
Page 277

E6582175 (Continued) Panel Communic Item displayed Description operated display ation No. The ON/OFF status of each of the control signal input terminals (F, R, RES, S1, S2, S3, VIB, VIA) are displayed in bits. }}i}}i}i ON:  FE06 OFF:  }}i}}i}i Note 4 Input terminal...
Page 278: Display Of Detailed Information On A Past Trip

E6582175 (Continued) Panel Communic Item displayed Description operated display ation No. The status of signal transmission and reception of communication are displayed in bits. Communication FD57 Status RX: signal receiving TX: signal transmitting receiving or transmitting :  not receiving or not transmitting:  The ON/OFF status of each of the cooling fan, circuit board capacitor, main circuit capacitor of parts replacement alarm, cumulative operation...
Page 279

E6582175 Panel LED display Description Item displayed operated The output frequency when the trip occurred is 6 Output frequency displayed. The direction of rotation when the trip occurred is Direction of  displayed. rotation (: Forward run, : Reverse run) The frequency command value when the trip occurred is Frequency Note 1...
Page 280: Display Of Trip Information

E6582175 Display of trip information 8.3.1 Trip code display If the inverter trips, an error code is displayed to suggest the cause. Since trip records are retained, information on each trip can be displayed anytime in the status monitor mode. Refer to section 13.1 for details about trip code display.
Page 281

E6582175 (Continued) Panel Communic Item displayed Description operated display ation No. The ON/OFF status of each of the control signal input terminals (F, R, RES, S1, S2, S3, VIB, VIA) are displayed in bits. }}i}}i}i ON:  Input terminal FE06 OFF: ...
Page 282

E6582175 (Continued) Panel Communic Item displayed Description operated display ation No. The status of signal transmission and reception of communication are displayed in bits. Communication FD57 Status RX: signal receiving TX: signal transmitting receiving or transmitting :  not receiving or not transmitting:  The ON/OFF status of each of the cooling fan, circuit board capacitor, main circuit capacitor of parts replacement alarm, cumulative operation...
Page 283

E6582175 Note 6: Overload characteristic of inverter and region setting are displayed on the monitor as follows; c -xx : aul = 1 (Constant torque characteristic) is selected. v -xx : aul = 2 (Variable torque characteristic) is selected. x- eu : Setup menu is selected to eu . x- as : Setup menu is selected to asia .
Page 284

E6582175 Parameter Setting No. LED display Function Unit Communication No. Output frequency Hz / free unit FE00 x60.0 Output current % / A FC02 c16.5 Frequency command value Hz / free unit FE02 f50.0 Input voltage (DC detection) % / V FC05 y100 Output voltage (command value)
Page 285

E6582175 *1: These monitor values can be filtered by  setting. *2: If a negative value of signed signal is specified, the negative sign “-“ is displayed. When the negative sign “-“ is displayed, do not display “ q ”, “ b ”. *3: Data set with FA65-FA79 is displayed.
Page 286: Measures To Satisfy The Standards

E6582175 9. Measures to satisfy the standards How to cope with the CE Marking Directive In Europe, the EMC Directive and the Low Voltage Directive, which took effect in 1996 and 1997, respectively, made it obligatory to put the CE mark on every applicable product to prove that it complies with the directives. Inverters do not work alone but are designed to be installed in a control panel and always used in combination with other machines or systems for the purpose of controlling them.
Page 287: Measures To Satisfy The Emc Directive

E6582175 Table 1 EMC standards Product Category Subcategory Test standard standards Radiated noise CISPR11(EN55011) Emission Conducted noise CISPR11(EN55011) Static discharge IEC61000-4-2 Radioactive radio-frequency IEC61000-4-3 magnetic contactor field IEC 61800-3 First transient burst IEC61000-4-4 Immunity Surge IEC61000-4-5 Radio-frequency IEC61000-4-6 induction/transmission interference Voltage dip/Interruption of power IEC61000-4-11 9.1.2...
Page 288

E6582175 Single-phase 240 V class Combination of inverter and filter Conducted noise Conducted noise Conducted noise IEC61800-3, category C2 IEC61800-3, category C1 IEC61800-3, category C2 Inverter type (Motor wiring length of (Motor wiring length of (Motor wiring length of 5m or less) 20m or less) 50m or less) EMFS11S-2009AZ...
Page 289

E6582175 (2) Use shielded power cables, such as inverter output cables, and shielded control cables. Route the cables and wires so as to minimize their lengths. Keep a distance between the power cable and the control cable and between the input and output wires of the power cable. Do not route them in parallel or bind them together. Instead, if necessary, cross at right angle.
Page 290

E6582175 [Example of wiring] Install the shield cable after modifying it as shown below. Fixed by insulation lock Remove the covering of the cable and fix the shield in the metal saddle. EMC plate Braking resistor wiring (Shielded cables) Motor wiring (Shielded cables) PA/+, PB U/T1, V/T2, W/T3 Control wiring (Shielded cables)
Page 291: Compliance With Ul Standard And Csa Standard

About the Low Voltage Directive The Low Voltage Directive provides for the safety of machines and systems. All Toshiba inverters are CE-marked in accordance with the standard EN 50178 specified by the Low Voltage Directive, and can therefore be installed in machines or systems and imported without problem to European countries.
Page 292: Peripheral Devices

E6582175 10. Peripheral devices Warning  When using switchgear for the inverter, it must be installed in a cabinet. Failure to do so can lead to risk of electric shock. Mandatory action  Ground must be connected securely. If the ground is not securely connected, it could lead to electric shock or fire. Be Grounded 10.1 Selection of wiring materials and devices ...
Page 293

Note 4: The wire sizes specified in the above table apply to HIV wires (copper wires shielded with an insulator with a maximum allowable temperature of 75°C) used at an ambient temperature of 50°C or less. Note 5: In case of aul=2 setting, contact your Toshiba distributor for wire size.
Page 294

Note 1: Selections for use the Toshiba 4-pole standard motor with power supply voltage of 200V/ 400 - 50Hz. Note 2: Be sure to attach a surge absorber to the exciting coil of the relay and the magnetic contactor.
Page 295: Installation Of A Magnetic Contactor

E6582175 10.2 Installation of a magnetic contactor If using the inverter without installing a magnetic contactor (MC) in the primary circuit, use an MCCB (with a power cut off device) to open the primary circuit when the inverter protective circuit is activated. When using an optional braking resistor, install a magnetic contactor (MC) or molded-case circuit breaker with a power cutoff device on the primary power supply of the inverter, so that the power circuit opens when the failure detection relay (FL) in the inverter or the externally installed overload relay is actuated.
Page 296: Installation Of An Overload Relay

(  ) and appropriate to the motor used should be installed between the inverter and the motor.  When using a motor with a current rating different to that of the corresponding Toshiba general-purpose motor  When operating a single motor with an output smaller than that of the applicable standard motor or more than one motor simultaneously.
Page 297: Optional External Devices

E6582175 10.4 Optional external devices The following external devices are optionally available for this inverter series. Power supply Molded-case circuit breaker MCCB Magnetic contactor (1) Input AC reactor (ACL) (10) Parameter writer : RKP002Z PWU003Z (3) High-attenuation radio noise (11) Extension panel : RKP007Z reduction filter (5) EMC noise reduction filter...
Page 298

E6582175 ■ Mounting, wiring and removing of the Communication option adaptor (SBP009Z) Warning  Do not connect any communication device other than applicable communication options to the option adapter. This can result in malfunction or accident. Prohibited  The mounting/removing of option must be performed without supplying power(Turn off all input power, wait at least 15 minutes, confirm that the charge lamp of inverter is no longer lit).
Page 299

E6582175 ■ The option is mounted 5) Hang the hook of the option adapter on the bottom of the front cover and After mounting the option adapter, mount it to the inverter. the depth increases 25.5mm. ST AT ST AT RU N RU N PR G...
Page 300: Table Of Parameters And Data, Basic Parameters

E6582175 11. Table of parameters and data 11.1 Frequency setting parameter Minimum setting unit User Title Function Unit Adjustment range Default setting Reference Panel/Comm setting unication Operation 0.1/0.01 - 3.2.2  frequency of operation panel 11.2 Basic parameters  Five navigation functions Minimum Communication setting unit...
Page 301

E6582175  Basic parameters Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0003 Command mode 0: Terminal block  selection 1: Panel keypad (including extension 6.2.1 panel) 2: RS485 communication 3: CANopen communication 4: Communication option 0004 Frequency setting...
Page 302

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0009 Acceleration time 0.1/0.1 0.0-3600 (360.0) *8 10.0  0010 Deceleration time 0.1/0.1 0.0-3600 (360.0) *8 10.0  0011 Maximum 0.1/0.01 30.0-500.0 80.0 ...
Page 303

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0007 Default setting 0: - 4.3.2  1: 50Hz default setting 2: 60Hz default setting 3: Default setting 1 (Initialization) 4: Trip record clear 5: Cumulative operation time clear 6: Initialization of type information 7: Save user setting parameters...
Page 304

E6582175 11.3 Extended parameters  Input/output parameters 1 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0100 Low-speed signal 0.1/0.01 0.0- 6.5.1  output frequency 0101 Speed reach 0.1/0.01 0.0- 6.5.3  setting frequency 0102 Speed reach...
Page 305

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0130 Output terminal 6.7.3  selection 1A (LOW) 7.2.2 (RY-RC) 0131 Output terminal  selection 2A (OUT) (RCH) 0132 Output terminal  selection 3 (FL) 0-255 *7 (FL) 0137...
Page 306: Basic Parameter

E6582175  Basic parameter 2 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0170 Base frequency 2 0.1/0.01 20.0-500.0 6.8.1  0171 Base frequency 1/0.1 50-330 (240V class)  voltage 2 50-660 (500V class) 0172 Torque boost 0.1/0.1...
Page 307

E6582175  Frequency parameters Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0200 Frequency priority 0:  (Switchable to  by  selection terminal input) 6.10.1 1:  (Switchable to  at 1.0Hz or less of designated frequency) 0201...
Page 308

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0249 PWM carrier 0.1/0.1 2.0-16.0 6.12.1  frequency during DC braking 0250 DC braking 0.1/0.01 0.0-  starting frequency 0251 DC braking %(A) 0-100 *12 ...
Page 309

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0287 Preset-speed 0.1/0.01 -  frequency 8 0288 Preset-speed 0.1/0.01 -  frequency 9 0289 Preset-speed 0.1/0.01 -  frequency 10 0290 Preset-speed 0.1/0.01 -...
Page 310

E6582175  Operation mode parameters Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0300 PWM carrier 0.1/0.1 2.0 -16.0 12.0 6.18  frequency 0301 Auto-restart 0: Disabled  control selection 1: At auto-restart after momentary stop 2: At ST terminal off and on 3: 1+2...
Page 311

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0315 Factory specific  coefficient 3M 0316 PWM carrier 0: Carrier frequency without reduction 6.18  frequency control (240V 1: Carrier frequency with automatic mode selection class) reduction...
Page 312

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0331 Light-load high- 0.1/0.01 5.0-ul 40.0  6.21 speed operation switching lower limit frequency 0329 Light-load high- 0:No learning  speed learning 1:Forward run learning function 2:Reverse run learning 0330...
Page 313

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0349 Acceleration/decele  6.23 0:Disabled  ration suspend 1:Parameter setting function 2:Terminal input 0350 0.1/0.01 0.0-    Acceleration suspend frequency  ...
Page 314

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0384 Factory specific  coefficient 3G 0385 Factory specific  coefficient 3H 0386 Factory specific  coefficient 3I 0389 PID set value 0: fmod/f207 selected 6.24 ...
Page 315

E6582175  Torque boost parameters 1 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0400 Auto-tuning 6.25  0: Auto-tuning disabled 1: Initialization of  (after execution : 0) 2: Auto-tuning executed (after execution: 0) 3: - 4: Motor constant auto calculation...
Page 316

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0460 Motor specific  coefficient 3 0461 Motor specific  coefficient 4 0462 Speed reference 0-100 6.25  filter coefficient 0467 Motor specific ...
Page 317

E6582175  Acceleration/deceleration time parameters Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0500 Acceleration time 2 0.1/0.1 0.0-3600 (360.0) *8 10.0 6.27.2  0501 Deceleration time 2 0.1/0.1 0.0-3600 (360.0) *8 10.0 ...
Page 318

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0590 Shock monitoring 0: Disabled 6.28  1: Current detection 2: Torque detection 3: - 0: Alarm only 0591 Shock monitoring  trip/alarm 1: Tripping selection 0592...
Page 319

E6582175  Protection parameters Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0601 Stall prevention 10-199, *12 6.29.2  level 1 200 (disabled) Inverter trip 0: Cleared with power off 0602 6.29.3 ...
Page 320

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0625 Factory specific  coefficient 6A 0626 Over-voltage stall 100-150 6.19.4  protection level 6.19.5 0627 Undervoltage 0: Alarm only(detection level 60% or less) 6.29.13 ...
Page 321

E6582175 Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0663 Analog input 0: Frequency command 6.32  terminal function 1: Acceleration/deceleration time selection (VIB) 2: Upper limit frequency 3, 4: - 5: Torque boost value 6: Stall prevention level 7: Motor electronic-thermal protection level...
Page 322

E6582175  Output parameters Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0667 Integral input 0: 0.1kWh 6.33.1  power pulse 1: 1kWh output unit 2: 10kWh 3: 100kWh 0668 Integral input 0.1/0.1 0.1-1.0 ...
Page 323

E6582175  Operation panel parameters Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0700 Parameter 0: Permitted 6.34.1  protection 1: Writing prohibited (Panel and selection extension panel) 2: Writing prohibited (1 + RS485 communication) 3: Reading prohibited (Panel and extension panel)
Page 324

E6582175 Minimum Communication Default User setting unit Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0710 Initial panel 0: Output frequency (Hz/free unit) 6.34.5  display selection 1: Output current (%/A) 8.2.1 2: Frequency command value 8.3.2 (Hz/free unit) 3: Input voltage (DC detection) (%/V) 4: Output voltage (command value) (%/V) 5: Input power (kW)
Page 325

E6582175 Minimum Communication Default User setting unit Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0711 Status monitor 1 0: Output frequency (Hz/free unit) 6.34.6  1: Output current (%/A) 8.2.1 2: Frequency command value 8.3.2 (Hz/free unit) 3: Input voltage (DC detection) (%/V) 4: Output voltage (command value) (%/V) 0712...
Page 326

E6582175 Minimum Communication Default User setting unit Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0729 Operation panel 1/0.01 -100-+100 6.31  override multiplication gain 0730 Panel frequency 0: Permitted 6.34.1  setting prohibition 1: Prohibited () 0731 Disconnection 0: Permitted ...
Page 327

E6582175 Minimum Communication Default User setting unit Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0750 EASY key function 0: Easy / standard setting mode  selection switching function 6.16 1: Shortcut key 6.37 2: Local / remote key 3: Monitor peak / minimum hold trigger 4: -...
Page 328

E6582175 Minimum Communication Default User setting unit Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0778 Easy setting mode  parameter 28 6.37 0779 Easy setting mode  parameter 29 0780 Easy setting mode 0-2999  parameter 30 (Set by communication number) 0781 Easy setting mode...
Page 329

E6582175  Communication parameters Minimum Communication Default User setting unit Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0800 Baud rate 3: 9600bps 6.38.1  4: 19200bps 5: 38400bps 0801 Parity 0: No parity  1: Even parity 2: Odd parity 0802 Inverter number...
Page 330

User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication 0829 Selection of 0: Toshiba inverter protocol 6.38.1  communication 1: Modbus RTU protocol protocol 0856 Number of motor 1: 2 poles  poles for 2: 4 poles communication...
Page 331

E6582175  PM motor parameters Minimum Communication Default User setting unit Title Function Unit Adjustment range Reference Panel/Commun setting setting ication Factory specific 0900  coefficient 9A 0901 Factory specific  coefficient 9B 0902 Factory specific  coefficient 9C 0908 Factory specific ...
Page 332

E6582175  Traverse parameters Minimum Communication setting unit Default User Title Function Unit Adjustment range Reference Panel/Commun setting setting ication Traverse selection 0: Disabled 6.40  0980 1: Enabled Traverse 0.1/0.1 0.1-120.0 0981 25.0  acceleration time Traverse 0.1/0.1 0.1-120.0 ...
Page 333

E6582175 11.4 Default settings by inverter rating Dynamic Dynamic Automatic Torque boost braking Motor rated Motor rated braking torque boost value resistor capacity current resistance value capacity Inverter type ／       (Ω) (kW) (kW) VFS15-2004PM-W1 200.0 0.12 0.40...
Page 334

E6582175 Integrating Over-voltage Motor no-load wattmeter Motor rated speed stall protection current display unit level selection Inverter type     (JP,USA) (ASIA,EU)  (%) (%) (min (min VFS15-2004PM-W1 1710 1410 VFS15-2007PM-W1 1730 1440 VFS15-2015PM-W1 1740 1445 VFS15-2022PM-W1 1755 1460 VFS15-2037PM-W1 1755...
Page 335: Default Settings By Setup Menu

E6582175 11.5 Default settings by setup menu Main regions Function Title asia  (Asia, (North (Europe) (Japan) Oceania) America) f170 / f204 / 50.0(Hz) 50.0(Hz) Frequency f213 / 60.0(Hz) 60.0(Hz) f219 / f330 / f367 / f814 240V class Base 230(V) 230(V) 230(V)
Page 336: Input Terminal Function

E6582175 11.6 Input Terminal Function It can be assigned the function No. in the following table to parameter f104, f108, f110 to f118, f151 to f156, a973 to a976.  Table of input terminal functions 1 Function Code Function Action Reference No function Disabled...
Page 337

E6582175  Table of input terminal functions 2 Function Code Function Action Reference PID integral/differential clear ON: Integral/differential clear, OFF: Clear canceled 6.24 IDCN Inversion of PID integral/differential clear Inversion of IDC PID characteristics switching ON: Inverted characteristics of  selection OFF: Characteristics of ...
Page 338

E6582175  Table of input terminal functions 3 Function Code Function Action Reference Run/Stop command ON: Run command 7.2.1 OFF: Stop command Inversion of run/Stop command Inversion of RS FCHG Frequency setting mode forced switching ON: f207 (f200=0) 6.2.1 OFF: fmod FCHGN Inversion of frequency setting mode forced Inversion of FCHG...
Page 339

E6582175  Table of input terminal functions 4 Function Code Function Action Reference Parameter editing prohibition ON: Parameter editing prohibited 6.34.1 OFF: Setting of  PWPN Inversion of parameter editing prohibition Inversion of PWP PRWP Parameter reading prohibition ON: Parameter reading / editing prohibited OFF: Setting of ...
Page 340

E6582175  Input terminal function priority 88,89 6,7 8,9 10,11 24,25 36,37 12,13 28,29 52,53 90,91 Function 14,15 32,33 54,55 92,93 Code 16,17 ○ ○ ○ ○ ○ ○ ○ ○ ○ ◎ ○ ◎ ◎ ○ ◎ ○ ○ ○...
Page 341: Output Terminal Function

E6582175 11.7 Output Terminal Function It can be assigned the function No. in the following table to parameter f130 to f138, f157, f158.  Table of output terminal functions 1 Function Code Function Action Reference Frequency lower limit ON: Output frequency is more than  OFF: Output frequency is or less Inversion of frequency lower limit Inversion of LL...
Page 342

E6582175  Table of output terminal functions 2 Function Code Function Action Reference POLR Braking resistor overload pre-alarm ON: 50% or more of calculated value of  set 6.19.4 overload protection level OFF: Less than 50% of calculated value of  set overload protection level POLRN Inversion of braking resistor overload pre-...
Page 343

E6582175  Table of output terminal functions 3 Function Code Function Action Reference DATA1 Designated data output 1 ON: bit0 of FA50 is ON 6.38 OFF: bit0 of FA50 is OFF DATA1N Inversion of designated data output 1 Inversion of DATA1 DATA2 Designated data output 2 ON: bit1 of FA50 is ON...
Page 344

E6582175  Table of output terminal functions 4 Function Code Function Action Reference PIDF Signal in accordance of PID set value ON: PID set value by  is within ± of . 6.24 OFF: Other than those above PIDFN Inversion of signal in accordance of PID set Inversion of PIDF value Fault signal (output also at a retry waiting)
Page 345: Application Easy Setting

E6582175 11.8 Application easy setting When 1 to 7 is set by parameter aua (Application easy setting), the parameters of the table below are set to parameter f751 to f782 (Easy setting mode parameter 1 to 32). Parameter f751 to f782 are displayed at easy setting mode. Refer to section 4.2 about easy setting mode.
Page 346: Unchangeable Parameters In Running

E6582175 11.9 Unchangeable parameters in running For reasons of safety, the following parameters cannot be changed during inverter running. Change parameters while inverter stops. ［Basic parameters］  (Guidance function) *1(Frequency setting mode selection)  (Application easy setting)  (Maximum frequency) (Automatic acceleration/deceleration) (V/F control mode selection) ...
Page 347: Specifications

E6582175 12. Specifications 12.1 Models and their standard specifications  Standard specifications Item Specification Input voltage 3-phase 240V Applicable motor (kW) 0.75 Type VFS15 Form 2004PM-W1 2007PM-W1 2015PM-W1 2022PM-W1 2037PM-W1 2055PM-W1 2075PM-W1 2110PM-W1 2150PM-W1 Capacity (kVA) Note 1) 10.5 12.6 20.6 25.1 Rated output current...
Page 348

E6582175 Note 5. Required power supply capacity varies with the value of the power supply side inverter impedance (including those of the input reactor and cables).  Common specification Item Specification Control system Sinusoidal PWM control Output voltage range Adjustable within the range of 50 to 330V (240V class) and 50 to 660V (500V class) by correcting the supply Note1) voltage Output frequency range...
Page 349

E6582175 Item Specification Protective function Stall prevention, current limitation, over-current, output short circuit, over-voltage, over-voltage limitation, undervoltage, ground fault detection, input phase failure, output phase failure, overload protection by electronic thermal function, armature over-current at start-up, load side over-current at start-up, over-torque, undercurrent, overheating, cumulative operation time, life alarm, emergency stop, braking resistor overcurrent / overload, various pre-alarms Electronic thermal...
Page 350: Outside Dimensions And Mass

E6582175 12.2 Outside dimensions and mass  Outside dimensions and mass Applicable Dimensions (mm) Approx. Voltage motor Inverter type Drawing weight class (kW) (kg) VFS15-2004PM-W1 0.75 VFS15-2007PM-W1 121.5 VFS15-2015PM-W1 VFS15-2022PM-W1 3-phase VFS15-2037PM-W1 240V VFS15-2055PM-W1 VFS15-2075PM-W1 VFS15-2110PM-W1 VFS15-2150PM-W1 VFS15S-2002PL-W1 VFS15S-2004PL-W1 1-phase 0.75 VFS15S-2007PL-W1 240V...
Page 351: Outline Drawing

E6582175  Outline drawing STOP STOP EASY MODE EASY 60(Mounting dimension) 93(Mounting dimension) VF-S15 VF-S15 EMC plate EMC plate (Option) (Option) Note 2) Note 2) *58mm for 1-phase 240V- 1.5, 2.2kW models. Fig.A Fig.B Note 1 To make it easier to grasp the dimensions of each inverter, dimensions common to all inverters in these figures are shown with numeric values but not with 2- 5...
Page 352

E6582175 STOP EASY 130(Mounting dimension) 2-R2.5 VF-S15 EMC plate (Option) Note 2) Fig.D STOP EASY 160(Mounting dimension) 2-R3 VF-S15 EMC plate (Option) Note 2) Fig.E...
Page 353: Before Contacting Your Toshiba Distributor - Trip Information And Remedies

E6582175 13. Before contacting your Toshiba distributor - Trip information and remedies 13.1 Trip /Alarm causes and remedies When a problem arises, diagnose it in accordance with the following table. If it is found that replacement of parts is required or the problem cannot be solved by any remedy described in the table, contact your Toshiba distributor.
Page 354

E6582175 [Trip information] Error code Failure code Name Description Remedies 000A Overvoltage during  The input voltage fluctuates abnormally.  Insert a suitable input reactor.  acceleration (1) The power supply has a capacity of 500kVA or more. (2) A power factor improvement capacitor is opened or closed.
Page 355

 Reduce f300 : PWM carrier frequency.  Set f136= 1 (Carrier frequency with automatic reduction)  The temperature sensor has a fault.  Contact your Toshiba distributor.  (When the trip arises, as soon as it is reset after a while.) ...
Page 356

 Check the suitable detection level for the  fault system (, , ).  Contact your Toshiba distributor if the setting is correct.  The input voltage (in the main circuit) is  Check the input voltage. 001E...
Page 357

 setting is too high. parameter  setting.  The motor has too small impedance.  Make an auto-tuning.  The control CPU is defective.  Contact your Toshiba distributor. 0035 CPU fault 2  0037 Optional unit fault 2 ...
Page 358

E6582175 [Alarm information] Each message in the table is displayed to give a warning but does not cause the inverter to trip. Error code Name Description Remedies ST (assigned standby function) terminal  The ST-CC (or P24) circuit is opened. ...
Page 359

E6582175 [Alarm information] Each message in the table is displayed to give a warning but does not cause the inverter to trip. Error code Name Description Remedies Output frequency upper limit  An attempt was made to operate at a ...
Page 360

E6582175 [Pre-alarm information] Each message in the table is displayed to give a warning but dues not cause the inverter to trip The following error code and the frequency will blink alternately. Error code Name Description Remedies Overcurrent pre-alarm Same as oc (overcurrent) ...
Page 361: Restoring The Inverter From A Trip

E6582175 13.2 Restoring the inverter from a trip Do not reset the inverter when tripped because of a failure or error before eliminating the cause. Resetting the tripped inverter before eliminating the problem causes it to trip again. The inverter can be restored from a trip by any of the following operations: (1) By turning off the power (Keep the inverter off until the LED turns off.) Note) See inverter trip hold selection ...
Page 362: If The Motor Does Not Run While No Trip Message Is Displayed

Connect the shoring bar between Is the shorting bar being connected ? P0 and PA. Contact your Toshiba distributor.  Close the circuit between CC (or P24) and the terminal to which the ST (standby) Is  displayed? function on the control circuit terminal is assigned.
Page 363: How To Determine The Causes Of Other Problems

E6582175 13.4 How to determine the causes of other problems The following table provides a listing of other problems, their possible causes and remedies. Problems Causes and remedies  The motor runs in the Invert the phases of the output terminals U/T1, V/T2 and W/T3. ...
Page 364: Inspection And Maintenance

E6582175 14. Inspection and maintenance Warning  The equipment must be inspected daily. If the equipment is not inspected and maintained, errors and malfunctions can not be discovered which could lead to accidents.  Before inspection, perform the following steps. (1) Shut off all input power to the inverter.
Page 365: Periodical Inspection

Performing an inspection without carrying out these steps first could lead to electric shock.  Do not replace parts. This could be a cause of electric shock, fire and bodily injury. To replace parts, call your Toshiba distributor. Prohibited...
Page 366: Check Items

E6582175  Check items 1. Check to see if all screwed terminals are tightened firmly. If any screw is found loose, tighten it again with a screwdriver. 2. Check to see if all caulked terminals are fixed properly. Check them visually to see that there is no trace of overheating around any of them.
Page 367

E6582175  Replacement of expendable parts The inverter is composed of a large number of electronic parts including semiconductor devices. The following parts deteriorate with the passage of time because of their composition or physical properties. The use of aged or deteriorated parts leads to degradation in the performance or a breakdown of the inverter.
Page 368: Contacting With Your Toshiba Distributor

For the Toshiba distributor, refer to the back cover of this instruction manual. When contacting with your Toshiba distributor, please inform us of the contents of the name plate label on the right panel of the inverter, the presence or absence of optional devices, etc., in addition to the details of the failure.
Page 369: Keeping The Inverter In Storage

E6582175 14.4 Keeping the inverter in storage If you store the inverter temporarily or for a long time after purchase, follow the instructions below. Storage location Store the inverter indoors. Avoid to be exposed to direct sunlight, corrosive, explosive or flammable gases, salt, oil mist, dust, metal powder, vapor or condensation.
Page 370

Failure or damage caused by the use of the inverter for any purpose or application other than the intended one All expenses incurred by Toshiba for on-site services shall be charged to the customer, unless a service contract is signed beforehand between the customer and Toshiba, in which case the service contract has priority over this...
Page 371: Disposal Of The Inverter

E6582175 16. Disposal of the inverter Caution  If you dispose of the inverter, have it done by a specialist in industry waste disposal(*). If you dispose of the inverter by yourself, this can result in explosion of capacitor or produce noxious gases, resulting in injury.
Page 372

E6582175 17．．．． Appendix ■ UL standard and CSA standard The VF-S15 standard type-form listed on table 5 is conformed to UL standard and CSA standard. That UL/CSA conformity of the specific type-form depends on the individual specification. (The specific type-form is the type-form except the standard type-form.
Page 373

E6582175 Environments Indoors; not exposed to direct sunlight, corrosive gas, explosive gas, flammable gas, Location of use oil mist, or dust; and vibration of less than 5.9m/s (10 to 55Hz). Elevation 1000 m or less -10 to +40° C (50° C) Maximum Surrounding Air Temperature Ambient temperature 40 °...
Page 374

E6582175 [Three-phase 400/500V class] Input voltage 380V to 480V Input voltage Above 480V to 500V Ambient VFS15- PWM carrier frequency PWM carrier frequency temperature 2.0k to 4.0kHz 4.1k to 12.0kHz 2.0k to 4.0kHz 4.1k to 12.0kHz 40°C or less 1.5 A 1.5 A 1.5 A 1.5 A...
Page 375

E6582175 Table 2 Ring terminal sizes for earth cables Earth Cable Sizes M4 (grounding terminal) M5 (grounding terminal) AWG14 R2-4 [JIS standard] R2-5 [JIS standard] AWG12 R5.5-4 [JIS standard] R5.5-5 [JIS standard] AWG10 R5.5-4 [JIS standard] R5.5-5 [JIS standard] AIC, Fuse and Wire sizes Use the UL listed fuses at connecting to power supply.
Page 376

E6582175 (1) Input withstand rating is that for which the product has been designed thermally. (2) Output interrupt rating relies on Integral solid state short circuit protection. This does not provide branch circuit protection. Branch circuit protection must be provided in accordance with the National Electrical Code and any additional local codes.
Page 377

E6582175 Main and control circuit terminals This diagram shows an example of wiring of the main and control circuit (in case of sink logic). Standard connection diagram – SINK (Negative) (common: CC) DC reactor (DCL) Braking resistor (Option) *2 (option) Main circuit power supply PA/+ PC/-...
Page 378

E6582175 Main circuit terminals Terminal symbol Terminal function Grounding terminal for connecting inverter. There are 3 terminals in cooling fin or mounting part of EMC plate. 200/240 V class : Three-phase 200 to 240V-50/60Hz : Single-phase 200 to 240V-50/60Hz R/L1,S/L2,T/L3 400/500 V class : Three-phase 380 to 500V-50/60Hz * Single-phase inputs are R/L1 and S/L2/N terminals.
Page 379

E6582175 Terminal Input / Electrical Function symbol output specifications Shorting across F-CC or P24-F causes forward rotation; open No voltage causes deceleration stop. Input logic input (When Standby ST is always ON) 24Vdc-5mA or 3 different functions can be assigned. less Shorting across R-CC or P24-R causes reverse rotation;...
Page 380

E6582175 Terminal Input / Electrical Function symbol output specifications 1mAdc full-scale ammeter or QS60T(option) 0-20mA (4-20mA) Multifunction programmable analog output. Default setting: output DC ammeter frequency. Permissible load Output resistance: The function can be changed to meter option (0-1mA), 0-10Vdc voltage 600Ω...
Page 381: Overload Protection, Motor Thermal Protection

E6582175 Terminal Input / Electrical Function symbol output specifications Max. switching Multifunction programmable relay contact output. capacity Detects the operation of the inverter's protection function. 250Vac-2A, Output Contact across FLA-FLC is closed and FLB-FLC is opened during 30Vdc-2A Note 3) protection function operation.
Page 382

E6582175 thr  : Motor electronic-thermal protection level 1 olm  : Electronic-thermal protection characteristic selection f173 : Motor electronic-thermal protection level 2  : Motor 150% overload detection time  : Inverter overload detection method  : Electronic-thermal memory ...
Page 383

E6582175 1) Setting the electronic thermal protection characteristics selection olm and motor electronic thermal protection level 1 thr thr, 2 f173 f173 f173 f173 The electronic thermal protection characteristics selection (olm) is used to enable or disable the motor overload trip function (ol2) and the overload stall function.
Page 384

E6582175 Output current reduction factor [%]/[A] ×1.0 ×0.6 30Hz Output frequency (Hz) Note: The motor overload protection start level is fixed at 30Hz. [Using a VF motor (motor for use with inverter)] Setting of electronic thermal protection characteristics selection olm Setting value Overload protection Overload stall...
Page 385

E6582175 2) Motor 150%-overload detection time f607 f607 f607 f607 Parameter f607 is used to set the time elapsed before the motor trips under a load of 150% (overload trip 2) within a range of 10 to 2400 seconds. 3) Inverter overload detection method f631 f631 f631 f631...
Page 386

The PTC input alarm is assigned to the output terminal by setting the parameter of the output terminal selection function to 150 or 151. 7. Other Please contact where you purchase the inverter, your Toshiba sales representative, if you need the hard copy (paper) of CD-ROM. Or please contact to phone number of back cover. Q-15...
Page 387

■ 한국 한국 KC KC 마크 마크 한국 한국 마크 마크 도시바산업용 인버터 TOSVERT VF-S15 은, 한국 전파법에 적합한 기기 입니다. 한국에서 본제품을 사용하게될 경우, 아래내용에 주의하여 주십시오. A 급 급 급 급 기기 기기 (업무용 업무용 방송통신기자재 방송통신기자재) 기기 기기...
Page 388

E6582175 표 인버터와 EMC 필터 결합 3 상 240V 급 인버터와 필터의 결합 인버터 타입 5m 이하의 모터 배선 길이 VFS15-2004PM-W1 EMFS11-2007AZ VFS15-2007PM-W1 EMFS11-2007AZ VFS15-2015PM-W1 EMFS11-4015BZ VFS15-2022PM-W1 EMFS11-4015BZ VFS15-2037PM-W1 EMFS11-4025CZ VFS15-2055PM-W1 EMFS11-4047DZ VFS15-2075PM-W1 EMFS11-4047DZ VFS15-2110PM-W1 EMFS11-2083EZ VFS15-2150PM-W1 EMFS11-2083EZ 3 상 500V 급 인버터와...
Page 389

■ Adaptation to TOSHIBA IE3 motor TOSHIBA standard motor has been changed from traditional IE1 motor to IE3 motor for energy efficiency improvement. VF-S15 inverter parameter default setting values are changed to adapt the motor control characteristics of IE3 motor.
Page 390

E6582175 ■ In case of replacing inverter of software version V116 or earlier Regarding all of the parameters on Table 1, copy all of the parameter setting values from V116 or earlier version inverter, and then set them to V120 or later version inverter. Same motor control characteristics will be obtained. f456 to f458 are manufacturer setting parameters.
Page 391

E6582175 ■ Parameters changed default setting values Table 1 : Parameter list changed default setting values at software V120 or later version Minimum Com. Adjustment Default Reference Title Function Unit setting unit range setting Panel/Com. 0016 Torque boost value 1 0.1 / 0.1 0.0 - 30.0 f172...
Page 392

E6582175 Table 3: Parameter default setting values for IE3 motor (V120 or later version defaults) f417 f417 f402 f415 f416 f456 f457 f458 f459 Type form f172 (JP,USA)*3 (ASIA,EU)*3 Times －－ VFS15-2004PM-W1 Same values as Table 4 (V116 or earlier version) VFS15-2007PM-W1 3.40 1730...
Page 393

V110 or earlier version inverter by Parameter writer or other options, because f456 and f457 do not exist on V110 or earlier version inverter. Therefore, change f456 and f457 manually. © Toshiba Schneider Inverter Corporation 2012...