Page 1 June, 2020 ADJUSTABLE SPEED DRIVES DN-57442-006...
Page 3 W7 ASD Installation and Operation Manual Document Number: 57442-006 Date: June, 2020...
Page 5 IEEE 519 1992 at the point of common coupling. The W7 ASD is ideally suited to drive variable torque loads. Toshiba's technology, quality, and reliability enables the motor to develop high torque and provide compensation for motor slip, which results in smooth, quick starts and highly efficient operation.
Page 6 W7 ASD. The information provided in this manual is applicable to the W7 ASD family. In our continuing effort to improve the W7 ASD, Toshiba has increased the available typeforms of the W7 ASD family. The suffix B has been added to the part number of the newly added system types.
Page 7 Contacting Toshiba’s Customer Support Center Toshiba’s Customer Support Center can be contacted to obtain help in resolving any Adjustable Speed Drive system problem that you may experience or to provide application information. The Customer Support Center is open from 8 a.m. to 5 p.m. (CST), Monday through Friday. The Center’s toll free number is US (800) 231-1412/Fax (713) 937-9349 CAN (800) 872-2192 MEX 01...
Page 8 The sales contract contains the entire obligation of Toshiba International Corporation. The warranty contained in the contract between the parties is the sole warranty of Toshiba International Corporation and any statements contained herein do not create new warranties or modify the existing warranty.
Page 9: Table Of Contents
Low-Speed Operation ...................... 11 Overload Protection Adjustment ..................11 Operation Above 60 Hz ....................11 Power Factor Correction ....................11 Light Load Conditions ...................... 11 Motor Braking ........................11 ASD Characteristics ......................... 12 Over-Current Protection ....................12 ASD Capacity ........................12 https://www.toshiba.com/tic/...
Page 10 Direct Access Parameter Information ................... 51 Direct Access Parameters/Numbers ................51 Alarms, Trips, and Troubleshooting ................... 177 Alarms and Trips ......................177 Enclosure Dimensions and Weight Information ............... 187 Current/Voltage Specifications ................... 194 Cable/Terminal Specifications ..................... 196 Spare Parts Listing ........................ 200 https://www.toshiba.com/tic/...
Page 11: General Safety Information
- Remove all power avoided, will result in serious - Wait 10 minutes injury to personnel or loss of life. - Verify no voltage is present - Close panel after servicing Failure to comply will result in death or serious injury https://www.toshiba.com/tic/...
Page 12: Qualified Personnel
• Be trained and authorized to safely energize, de-energize, ground, lockout/tagout circuits and equipment, and clear faults in accordance with • Use proper lifting techniques when moving established safety practices. the ASD; including properly sizing up the load, getting assistance, and using a forklift if required. https://www.toshiba.com/tic/...
Page 13: Disposal
DO NOT obstruct the ventilation openings. Refer to the section titled Installation and Connections on pg. 13 for additional information on ventilation requirements. • The ambient operating temperature range of the W7B ASD is 14° to 104° F (-10° to 40° C). https://www.toshiba.com/tic/...
Page 14: Mounting Requirements
— T h e M e t a l O f C o n d u i t I s input wiring to the equipment. This protection N o t A n A c c e p t a b l e G r o u n d — must be able to interrupt the available fault https://www.toshiba.com/tic/...
Page 15: System Integration Precautions
EE from the environment by double or reinforced insulation, or isolation of the EE and • Insulators, machine guards, and electrical the supply system by a transformer. Toshiba safeguards may fail or be defeated by the https://www.toshiba.com/tic/...
Page 16: System Setup Requirements
Closing Protection, etc.). the output disconnect while the 3-phase output • The operating controls and system status of the ASD is active may result in equipment indicators should be clearly readable and damage or injury to personnel. https://www.toshiba.com/tic/...
Page 17: Operational And Maintenance Precautions
ASD. Call the TIC Customer Support understood all of the product warnings and user Center for repair information. directions. Failure to do so may result in equipment • DO NOT place any objects inside of the ASD. damage, operator injury, or loss of life. https://www.toshiba.com/tic/...
Page 18: Service Life Information
European Standard standards and emission-related standards. EN 50178 specified by the latest revision of the Standards are further categorized according to the Low-Voltage Directive on Electrical Safety, and are available in the European market. operating environment of the ASD. https://www.toshiba.com/tic/...
Page 19: General Emc Guidelines For Compliance
EPCOS Filter FLA @ 40° C 4220 FN 258-30-07 B84143A0036R105 4270 FN 258-42-07 4330 FN 258-55-07 B84143A0050R105 4400 FN 258-75-34 B84143A0066R105 4500 4600 FN 258-100-35 B84143A0090R105 4750 FN 258-130-35 B84143A0120R105 410K FN 258-180-40 B84143A0150R105 412K B84143B0250S020 FN 258-250-40 415K B84143B0250S020 https://www.toshiba.com/tic/...
Page 20 4600 B84143B1600S020 1600 Table 4. W7B ASD 690-Volt Filter Recommendations. ASD Model Schaffner Filter FLA @ 40° C EPCOS Filter FLA @ 40° C 620K FN 3359HV-250-28 B84143B0250S024 625K FN 3359HV-320-99 B84143B0400S024 630K FN 3359HV-400-99 640K FN 3359HV-600-99 B84143B0600S024 https://www.toshiba.com/tic/...
Page 21: Motor Characteristics
The motor may continue to rotate and coast to a the system and determines when an overload stop after being shut off due to the inertia of the condition occurs. The overload current level is a load. If an immediate stop is required, a braking https://www.toshiba.com/tic/...
Page 22: Asd Characteristics
Also, the Stall Prevention Level on pg. 143 setting input voltage may be stepped down if required with may be adjusted to help with nuisance over-current the use of a step-down transformer or some other trips. type of voltage-reduction system. https://www.toshiba.com/tic/...
Page 23: Installation And Connections
Interface problems may occur when an ASD is used contactor is opened. in conjunction with some types of process DO NOT open and then close a secondary controllers. Signal isolation may be required to magnetic contactor between the ASD and the prevent controller and/or ASD malfunction (contact https://www.toshiba.com/tic/...
Page 24: Mounting The Asd
An inductor may be connected across terminals PA them together. and PO to provide additional filtering. When not • Use shielded wires or twisted wires for the used, a jumper must be connected across these control circuits. terminals (see Figure 16 on pg. 24). https://www.toshiba.com/tic/...
Page 25: Lead Length Specifications
When operating in the Vector Control mode, the carrier frequency should be set to 2.2 kHz or above. Note: Above lead lengths are based on total cable length. When using parallel cables, reduce the maximum lead length based on the number of cables in parallel. https://www.toshiba.com/tic/...
Page 26 Table 6. ASD Parameter Changes by Installer/Maintenance Personnel. ASD ID__________Name:______________________Date:_______ Notes Parameter Default or Unit of Parameter Name New Setting Number Previous Setting Measure Note: Settings may also be recorded via Program  Utilities  Type Reset  Save User Settings. https://www.toshiba.com/tic/...
Page 27: I/O And Control
Fault All — Normally open contact (N.O.). Switched Output Fault All — Normally closed contact (N.C.). Figure 15 on pg. 23. Fault All — Common. — Control common; return for all terminal board signals — DO NOT connect to Earth Ground. https://www.toshiba.com/tic/...
Page 28 The function of the VI input is to receive a 0 – 10 programmed to any of the functions that are listed VDC input signal that controls a Table 8 on page 170. 0 – Maximum Frequency output. This input terminal https://www.toshiba.com/tic/...
Page 29 — DO NOT connect to Earth Ground. Figure 3. FLA, FLB, and FLC Switching Contacts Shown in the Faulted State. Note: The relay is shown in the Faulted condition. During normal system operation, the relay connection is FLC-to- FLA. https://www.toshiba.com/tic/...
Page 30 AM and FM output terminals. F670 F005 for more information on the AM and FM terminals. Terminals Shown below are the TB1 input and output terminals of the Terminal Board. For further information on these terminals, see OUT1 OUT2 https://www.toshiba.com/tic/...
Page 31: Asd Control
For more information on the W7B ASD Communications and the ability to communicate in communication requirements, please visit https:// either half- or full-duplex modes. www.toshiba.com/tic/tools-resources/downloads. Using the optional multiple-protocol (Select “Manuals” under Download Type, “Industrial communications interface, the ASD-NANOCOM, Drives” under Product Family, “All Categories” under the Control Board may be configured for the type of Category, and “7-Series Serial Communications...
Page 32 CNU2A Pinout Pin # (Control Board) CN7 of the Control Board connects to CN7A of the (EOI) Terminal Board. Programmable terminals are listed as their default settings. Pin # Function Pin # Function Open Open OUT1 OUT2 — — https://www.toshiba.com/tic/...
Page 33 Figure 6. Discrete Input. Figure 7. RR Input. Figure 8. RX Input. Figure 9. VI/II Input. Figure 10. P24 Output. Figure 11. PP Output. Figure 12. OUT1/OUT2 Output. Figure 13. FP Output. Figure 14. FM/AM Output. Figure 15. Fault Relay (active fault). https://www.toshiba.com/tic/...
Page 34: Typical Connection Diagram
Figure 16. W7B ASD Typical Connection Diagram. Note:When connecting multiple wires to the PA, PB, PC, or PO terminals, DO NOT connect a solid wire and a stranded wire to the same terminal. Control Board Terminal Board OUT1 OUT2 https://www.toshiba.com/tic/...
Page 35: Electronic Operator Interface
6. ESC Key — Returns to the previous level of the menu tree, toggles between the Panel screen and the Frequency Command screen, or cancels changes made to a field if pressed while still in the reverse video mode (dark background/light text). The three functions are menu-specific. https://www.toshiba.com/tic/...
Page 36: Front Panel Indicators/Control
On when On when On when Power is in Run Fault is applied. mode. active. HAND AUTO Note: Lamp and switch positions are typeform-specific. See received drawing for actual positions. Hand/Off/Auto Switch Push to activate-Turn CW to reset. https://www.toshiba.com/tic/...
Page 37: Eoi Remote Mounting
• ASD-CAB7F: Cable, RJ-45, 7 ft. cables are available in lengths of 7, 10, or 15 feet • ASD-CAB10F: Cable, RJ-45, 10 ft. and may be ordered through the TIC Customer Support Center. • ASD-CAB15F: Cable, RJ-45, 15 ft. https://www.toshiba.com/tic/...
Page 38 6 split lock washers. gasses, water, solvents, or other fluids. Connect the RJ-45 extension cable(s). • Turn on the power only after securing the EOI Mounting Dimensions front cover to the ASD. Figure 19. EOI Mounting Dimensions. https://www.toshiba.com/tic/...
Page 39 CAUTION: Failure to use the correct hardware may result in damage to the outer surface of the EOI panel and/or improper seating of the panel to the bezel plate. Use caution when mounting the EOI assembly to ensure that the internal thread clearance is maintained. Correct Incorrect https://www.toshiba.com/tic/...
Page 40: System Operation
Direct Access Applicable Parameter Number). A See the section titled Startup Wizard Requirements on pg. 47 for additional information on the Startup listing of all parameters that have been changed Wizard. from the default setting may be viewed sequentially https://www.toshiba.com/tic/...
Page 41 Rotary Encoder, the system scrolls through the 7-Series Serial Communications Manual may be parameters and stops at the next parameter that acquired from the Toshiba web site at https:// has been changed. www.toshiba.com/tic/tools-resources/downloads. Pressing the Rotary Encoder while a changed Select “Manuals”...
Page 42: System Configuration And Menu Options
Monitor Screen on pg. The Panel Menu screen provides easy access to only and is accessed by pressing the ESC key from the most common setup parameters. Panel Menu the Frequency Command screen. changes will affect EOI-controlled ASD operation https://www.toshiba.com/tic/...
Page 43: Monitor Screen
Torque Reference — Displays the commanded torque. RX — Displays the RX input as a percentage of its Torque Current — Displays the torque current. full range. https://www.toshiba.com/tic/...
Page 44: Program Screen
Panel menu are effective for the active motor (of a multiple motor configuration). the LCD EOI control only if accessed via the The settings of profiles 1 – 4 may be setup at F441, Frequency Command screen. F444, F446, and F448, respectively. https://www.toshiba.com/tic/...
Page 45: Program Menu Navigation
(F004) Frequency Mode 1 (F000) Automatic Acceleration / (F701) Current/Voltage Units Deceleration Selection Setup PRIMARY MENU: CHANGED FROM DEFAULT See the section titled Default Setting Changes on pg. 30. PRIMARY MENU: DIRECT ACCESS See the section titled Direct Access Parameters/Numbers on pg. https://www.toshiba.com/tic/...
Page 46 (N/A) CPU Revision (F702) Free Unit Multiplication (N/A) Control Board EEPROM Factor [0 = off] Version (F703) Free Unit Selection (N/A) EOI Version (F704) Acc/Dec Unit Time Setup (N/A) Select Language (N/A) Display the Startup Wizard Next Power Up https://www.toshiba.com/tic/...
Page 47 (F144) Input Terminal 5-8 (S1- (F154) OUT5 On Delay S4) Response Time (F164) OUT5 Off Delay (F145) Input Terminal 9-16 (S5- (F155) OUT6 On Delay S12) Response Time (F165) OUT6 Off Delay (F156) OUT7 On Delay (F166) OUT7 Off Delay https://www.toshiba.com/tic/...
Page 48 (F387) Preset Speed 7 Settings (F294) / (F395) Preset Speed 15 Settings (F287) / (F388) Preset Speed 8 Settings Preset Speed Modes Forward/Reverse Disable Motorized Pot Settings (F380) Preset Speed (F311) Forward/Reverse Disable (F108) UP/DOWN Frequency Disposition Operation Mode at Power Down https://www.toshiba.com/tic/...
Page 49 Lower Band [0 = disabled] During Regenerative Braking (F618) Over-Torque Detection Time Brake Fault Timer Base Frequency Voltage Soft Start (F630) Brake Answer Waiting Time (F307) Supply Voltage Correction (F609) Suppression of Inrush Current (F632) Brake Release After Run Timer Timing https://www.toshiba.com/tic/...
Page 50 Torque Speed Limiting (F429) Torque Command Mode Selection (F430) Speed Limit (torque = 0) Center Value Reference Selection (F431) Speed Limit (torque = 0) Center Value (F432) Speed Limit (torque = 0) Band (F433) Speed Limit (torque = 0) Recovery Time https://www.toshiba.com/tic/...
Page 51 (F375) Current Control Integral Gain (F376) Speed Loop Proportional Gain (F377) Speed Loop Integral Gain (rad/second) (F378) Motor Counter Data Selection (F379) Speed Loop Parameter Ratio Override Control (F660) Adding Input Selection (F661) Multiplying Input Selection (F729) CN8 Option Override Multiplication Gain https://www.toshiba.com/tic/...
Page 52 Torque Limit Group Torque Limit Group Preset Speed 6 Preset Speed 12 (F023) Speed (F291) Speed (F386) ACC/DEC Group (F392) ACC/DEC Group V/f Group V/f Group Torque Limit Group Torque Limit Group Preset Speed Modes (F380) Preset Speed Operation Mode https://www.toshiba.com/tic/...
Page 53 (F672) MON 1 Terminal Meter Selection (F006) FM Output Terminal Adjustment (F673) MON 1 Terminal Meter Adjustment (F670) AM Output Terminal Function (F674) MON 2 Terminal Meter Selection (F671) AM Output Terminal Adjustment (F675) MON 2 Terminal Meter Adjustment https://www.toshiba.com/tic/...
Page 54 Output Power Output Voltage Torque Ref Peak Current Direction Torque Current Peak Voltage Freq Ref Exciting Current PG Speed DC Voltage PID Feedback PG Position Input Terminal Block Motor Overload Graphic ASD Overload Trip Monitor From ASD Main Monitor Selections https://www.toshiba.com/tic/...
Page 55 Forward Direction (F338) Switching Load Torque During Reverse Run (F339) Heavy Load Torque During Acc in the Reverse Direction (F340) Heavy Load Torque During Dec in the Reverse Direction (F341) Frequency for Automatic High- Speed Operation at Light Load (cont’d) https://www.toshiba.com/tic/...
Page 56 Current and Voltage Control (F484) Control Margin Modulation for Cooperation (F680) Optional Analog Terminal Mark Constant Vector Control (F485) Stall Cooperation Gain at (F454) Current Differential Gain Field Weakening Zone (F486) Exciting Starting Rate (F487) Compensation Coefficient for Iron Loss https://www.toshiba.com/tic/...
Page 57: Startup Wizard Requirements
The motor and the load must be connected prior to selecting Automatic Accel/ Decel. If Automatic Accel/Decel is disabled (No), the Acceleration screen will appear fol- lowed by the Deceleration screen as shown below. Accelerati on Time Acceleration Time Deceleration Time Decelerati on Time https://www.toshiba.com/tic/...
Page 58 9. Frequency Command Source 3 — RX Command Source 4 — RX2 (option) 5 — CN8 Option 6 — Binary/BCD Input 7 — Common Serial (TTL) 8 — RS232/RS485 9 — Communication Card 10 — UP/DOWN Frequency 11 — Pulse Input (option) https://www.toshiba.com/tic/...
Page 59 This screen is the final screen of the Startup Wizard. The basic parameters of Finished! the W7B ASD have been set. Click Exit to load the Startup Wizard input and to return to the Frequency Command screen. Additional application-specific pro- gramming may be required. https://www.toshiba.com/tic/...
Page 61: Direct Access Parameter Information
The Command Mode Selection establishes the source of the command input for the ASD. Command inputs include Run, Stop, Forward, etc. Changeable During Run — No Settings: 0 — Terminal Board 1 — CN8 Option 2 — Common Serial (TTL) 3 — RS232/RS485 4 — Communication Option Board https://www.toshiba.com/tic/...
Page 62 0 – 1 mA or 4 – 20 mA when providing an output current, or either 0 – 1 or 1 – 7.5 volts when providing an output voltage at this terminal. https://www.toshiba.com/tic/...
Page 63 Note: *User settings that are stored in the memory of the EOI are not saved via the Save User Parameters selection. The unsaved functions  include the EOI Option Setups, (Utilities Display Attributes, and  (Monitor Setup ) Scrolling Monitor Select. https://www.toshiba.com/tic/...
Page 64 This setting determines the absolute maximum frequency that the ASD can output. Changeable During Run — No Minimum — 30.0 Accel/decel times are calculated based on the Maximum Frequency Maximum — 299.0 setting. Units — Hz Note: This setting may not be lower than the Upper-Limit setting (F012 https://www.toshiba.com/tic/...
Page 65 Output Voltage at F306). There are four Base Frequency profile settings: Maximum — 299.0 1 – 4. Units — Hz Note: For proper motor operation, the Base Frequency is normally set for the name-plated frequency of the motor. Note: Not used with the W7B ASD. https://www.toshiba.com/tic/...
Page 66 The value programmed as a boost percentage establishes an output voltage vs. output frequency relationship to be used to start the motor or Units — % to provide smoother operation. Note: Setting an excessive Torque Boost level may cause nuisance tripping and mechanical stress to loads. https://www.toshiba.com/tic/...
Page 67 3 — Soft Stall Only 4 — V/f Motor OL Trip without Soft Stall 5 — V/f Motor OL Trip with Soft Stall 6 — V/f Motor without OL Trip or Soft Stall 7 — V/f Motor Soft Stall Only https://www.toshiba.com/tic/...
Page 68 Preset Speed 2. The binary number is applied to S1 – S4 Changeable During Run — Yes of the Control Terminal Strip to output the Preset Speed (see F018 Minimum — Lower-Limit (F013) additional information on this parameter). Maximum — Upper-Limit (F012) Units — Hz https://www.toshiba.com/tic/...
Page 69 Preset Speed 7. The binary number is applied to S1 – S4 Changeable During Run — Yes of the Control Terminal Strip to output the Preset Speed (see F018 Minimum — Lower-Limit (F013) additional information on this parameter). Maximum — Upper-Limit (F012) Units — Hz https://www.toshiba.com/tic/...
Page 70 Program  Terminal  Reach Settings Parameter Type — Numerical Factory Default — 2.5 This parameter sets the bandwidth of the Speed Reach Frequency (F101) setting. Changeable During Run — Yes Minimum — 0.0 Maximum — Upper Limit (F012) Units — Hz https://www.toshiba.com/tic/...
Page 71 F or R. Opening the F and R contact will disable the ASD and the motor will coast to a stop. The control terminal ST may be configured for other functions. https://www.toshiba.com/tic/...
Page 72 Control Terminal Strip will receive priority over commands from the EOI. F260 for additional information on using the Jog function. F250 – F252 for additional information on DC Injection Braking. Settings: 0 — Disabled 1 — Enabled (Box checked) https://www.toshiba.com/tic/...
Page 73 This setpoint will be used as the initial frequency setpoint when the ASD is restarted. A control terminal configured as MOP Frequency Clear will establish a frequency setpoint of 0.0 Hz regardless of the UP/DOWN Frequency at Power Down setting. https://www.toshiba.com/tic/...
Page 74 Changeable During Run — No In addition, the input terminal must be specified as Normally Open or Normally Closed. This parameter sets the programmable RES terminal to one of the possible functions that are listed in Table 8 on pg. 170. https://www.toshiba.com/tic/...
Page 75 Changeable During Run — No In addition, the input terminal must be specified as Normally Open or Normally Closed. This parameter sets the programmable S4 terminal to one of the possible functions that are listed in Table 8 on pg. 170. https://www.toshiba.com/tic/...
Page 76 In addition, the input terminal must be specified as Normally Open or Normally Closed. This parameter sets the programmable S7 terminal to one of the possible functions that are listed in Table 8 on pg. 170. https://www.toshiba.com/tic/...
Page 77 In addition, the input terminal must be specified as Normally Open or Normally Closed. This parameter sets the programmable terminal S10 to one of the possible functions that are listed in Table 8 on pg. 170. https://www.toshiba.com/tic/...
Page 78 The on and off delay times of the OUT1 terminals may be adjusted to provide more response time to the device that is connected to the output terminals. In addition, the output terminals must be specified as Normally Open or Normally Closed. https://www.toshiba.com/tic/...
Page 79 The on and off delay times of the OUT5 terminals may be adjusted to provide more response time to the device that is connected to the output terminals. In addition, the output terminals must be specified as Normally Open or Normally Closed. https://www.toshiba.com/tic/...
Page 80 (see waveforms at F140). Changeable During Run — No Minimum — 2.0 The delay may be increased to provide additional electrical noise Maximum — 200.0 immunity or to prevent the ASD from responding to contact bounce or chatter. Units — mS https://www.toshiba.com/tic/...
Page 81 – S16 terminal input by the programmed value (see waveforms at F140). Changeable During Run — No Minimum — 2.0 The delay may be increased to provide additional electrical noise Maximum — 200.0 immunity or to prevent the ASD from responding to contact bounce or chatter. Units — mS https://www.toshiba.com/tic/...
Page 82 This parameter delays the closing of the OUT4 output terminals by the programmed value (see waveforms at F150). Changeable During Run — No Minimum — 2.0 The delay may be increased to prevent relay chatter. Maximum — 200.0 Units — mS https://www.toshiba.com/tic/...
Page 83 (see waveforms at F160). Changeable During Run — No Minimum — 2.0 The delay may be increased to allow the devices that are connected to Maximum — 200.0 OUT2 to respond. Units — mS https://www.toshiba.com/tic/...
Page 84 This parameter delays the opening of the OUT7 output terminals by the programmed value (see waveforms at F160). Changeable During Run — No Minimum — 2.0 The delay may be increased to allow the devices that are connected to Maximum — 200.0 OUT7 to respond. Units — mS https://www.toshiba.com/tic/...
Page 85 Units — % This parameter is used only when the parameters for motor set 2 are configured and selected. Motor set 2 may be selected by a properly configured input terminal. Note: Not used with the W7B ASD. https://www.toshiba.com/tic/...
Page 86 ASD and the Supply Voltage Compensation setting (F307). Units — Volts This parameter is used only when the parameters for motor set 3 are configured and selected. Motor set 3 may be selected by a properly configured input terminal. Note: Not used with the W7B ASD. https://www.toshiba.com/tic/...
Page 87 Motor set 4 may be selected by a properly Units — Hz configured input terminal. For proper motor operation, the Base Frequency should be set for the name-plated frequency of the motor. Note: Not used with the W7B ASD. https://www.toshiba.com/tic/...
Page 88 (see F701 to change the display unit). Motor Overload Protection Level (1 – 4) will be displayed in Amps if the EOI display attributes are set to V/A rather than %. Note: Not used with the W7B ASD. https://www.toshiba.com/tic/...
Page 89 The V/f Five-Point 1 Voltage establishes the percentage of the output voltage that is to be associated with the frequency setting of F190 (V/f Changeable During Run — No Five-Point 1 Frequency). Minimum — 0.00 Maximum — 100.00 F190 for additional information on custom V/f curves. Units — % https://www.toshiba.com/tic/...
Page 90 The V/f Five-Point 4 Voltage establishes the percentage of the output voltage that is to be associated with the frequency setting of F196 (V/f Changeable During Run — No Five-Point 4 Frequency). Minimum — 0.0 Maximum — 100.0 F190 for additional information on custom V/f curves. Units — % https://www.toshiba.com/tic/...
Page 91 The V/f Five-Point 5 Voltage establishes the percentage of the output voltage that is to be associated with the frequency setting of F198 (V/f Changeable During Run — No Five-Point 5 Frequency). Minimum — 0.0 Maximum — 100.0 F190 for additional information on custom V/f curves. Units — % https://www.toshiba.com/tic/...
Page 92 Frequency Mode 2 setting has priority over Frequency Mode 1 setting. Frequency Source Priority Switching allows for a preconfigured input terminal to activate Frequency Source 1 or Frequency Source 2. Any unused programmable discrete input terminals may be programmed as the Frequency Priority switching terminal. https://www.toshiba.com/tic/...
Page 93 4 – 20 mA current loop signal where 4 mA equals 20% of a 20 mA signal. If the VI input is used (0 – 10 VDC input), parameter F201 may be changed to 0.0% (of the input signal). https://www.toshiba.com/tic/...
Page 94 This parameter sets Torque Reference Setpoint 1 and is the output torque value that is associated with the setting of F201. This value is entered as 0 to 250% of the rated torque. https://www.toshiba.com/tic/...
Page 95 This parameter sets the threshold frequency that will be used in F200 determine if Frequency Source 1 or 2 will control the output of the ASD. Changeable During Run — Yes Minimum — 0.1 F200 for additional information on this setting. Maximum — Max. Freq. (F011) Units — Hz https://www.toshiba.com/tic/...
Page 96 (digital) values. The rolling average is updated (every 4 μS) and scaled for use by the microprocessor. False responses to electrical noise are eliminated with no loss in bandwidth because the value used by the drive is the average value of several samples. https://www.toshiba.com/tic/...
Page 97 Minimum — 0.0 F210 for additional information on this setting. Maximum — Max. Freq. (F011) This parameter sets the RR Speed Frequency Setpoint 1 and is the Units — Hz frequency that is associated with the setting of F210. https://www.toshiba.com/tic/...
Page 98 This parameter sets RR Torque Reference Setpoint 2 and is the output torque value that is associated with setting of F212. This value is entered as 0 – 250% of the rated torque. https://www.toshiba.com/tic/...
Page 99 Minimum — -Max. Freq. (F011) Maximum — +Max. Freq. (F011) F216 for additional information on this setting. Units — Hz This parameter sets RX Speed Frequency Setpoint 1 and is the frequency that is associated with the setting of F216. https://www.toshiba.com/tic/...
Page 100 This parameter sets RX Torque Reference Setpoint 2 and is the output torque value that is associated with setting of F218. This value is entered as -250 to +250% of the rated torque. https://www.toshiba.com/tic/...
Page 101 This parameter sets the RX2 input level that represents RX2 Reference Setpoint 1 (frequency) (direction/torque/frequency). This value is entered as -100 to +100% of the -10 to +10 VDC RX2 input signal range. The input signal may be trimmed using F476 (Bias) and F477 (Gain). https://www.toshiba.com/tic/...
Page 102 This parameter sets RX2 Torque Reference Setpoint 1 and is the output torque value that is associated with the setting of F222. This value is entered as -250 to +250% of the rated torque. https://www.toshiba.com/tic/...
Page 103 This parameter sets RX2 Torque Reference Setpoint 2 and is the output torque value that is associated with the setting of F224. This value is entered as -250 to +250% of the rated torque. https://www.toshiba.com/tic/...
Page 104 This parameter sets BIN Reference Setpoint 1 (direction/torque/ frequency) and is entered as 0 to 100% of the BIN binary input word 11111111 (255 https://www.toshiba.com/tic/...
Page 105 Maximum — +250.0 a given BIN binary input and motor load. Units — % F228 for additional information on this setting. This parameter sets BIN Torque Reference Setpoint 1 and is entered as -250 to +250% of the rated torque. https://www.toshiba.com/tic/...
Page 106 Setpoint 1 (frequency) (direction/speed). The range of values for this parameter is -100 to +100% of the PG input pulse count range. Note: Additional application-specific PG settings may be performed   from the following path: Program Feedback Parameters  Settings https://www.toshiba.com/tic/...
Page 107 Maximum — 10.0 Output frequencies below the Startup Frequency will not be output from Units — Hz the drive during startup. However, once reaching the Startup Frequency, speed values below the Startup Frequency may be output from the drive. https://www.toshiba.com/tic/...
Page 108 ASD will output 0.0 Changeable During Run — Yes Hz to the motor. Minimum — 0.0 Note: This setting will override the Startup Frequency setting (F240) if Maximum — 5.0 this setting has a higher value. Units — Hz https://www.toshiba.com/tic/...
Page 109 Parameter Type — Selection List Factory Default — Disabled This parameter determines if DC Injection braking is to be used during a change in the direction of the motor. Changeable During Run — Yes Settings: 0 — Disabled 1 — Enabled https://www.toshiba.com/tic/...
Page 110 This parameter selects the go-to-zero method to be used by the ASD Injection Braking) when the ASD is commanded to go to 0.0 Hz. Changeable During Run — No Settings: 0 — Standard (DC Injection Braking) 1 — 0 Hz Command https://www.toshiba.com/tic/...
Page 111 Reverse or Forward (Program  Frequency Settings  Jog Settings  Enable Jog Window). Press MON/PRG to access the Jog Window. 5. Place the system in the Auto mode. 6. Connect the assigned Jog terminal (from step 1) to CC for the desired Jog duration. https://www.toshiba.com/tic/...
Page 112 (see the plus-or-minus value setting at F273). When multiple jump frequencies overlap, the system will Minimum — 0.00 recognize the lowest and the highest frequencies as one jump range. Maximum — Max. Freq. (F011) Units — Hz https://www.toshiba.com/tic/...
Page 113 Preset Speed 8. The binary number is applied to S1 – S4 Changeable During Run — Yes of the Control Terminal Strip to output the Preset Speed (see F018 Minimum — Lower-Limit (F013) additional information on this parameter). Maximum — Upper-Limit (F012) Units — Hz https://www.toshiba.com/tic/...
Page 114 Preset Speed 13. The binary number is applied to S1 – Changeable During Run — Yes S4 of the Control Terminal Strip to output the Preset Speed (see F018 Minimum — Lower-Limit (F013) additional information on this parameter). Maximum — Upper-Limit (F012) Units — Hz https://www.toshiba.com/tic/...
Page 115 Preset Speed 15. The binary number is applied to S1 – Changeable During Run — Yes S4 of the Control Terminal Strip to output the Preset Speed (see F018 Minimum — Lower-Limit (F013) additional information on this parameter). Maximum — Upper-Limit (F012) Units — Hz https://www.toshiba.com/tic/...
Page 116 ASD will reduce the capability of the ASD. After Derate Carrier-Frequency Derate Threshold Frequency Derate Derate Model Model Threshold Threshold Voltage Voltage Frequency Frequency Carrier Frequency (kHz) 8.0 kHz 575 V 2.2 kHz 5.0 kHz 4.0 kHz 8.0 kHz 460 V 5.0 kHz 2.2 kHz https://www.toshiba.com/tic/...
Page 117 • EEP1 (EEPROM Fault), • Err2 through Err9 (Main RAM/ROM Fault), • E-10 (Sink/Source Error), • 13 (Speed Error), • 17 (Key Error). See the section titled General Safety Information on pg. 1 for additional information on this setting. https://www.toshiba.com/tic/...
Page 118 Maximum — 600.0 The actual output voltage will be influenced by the input voltage of the Units — Volts ASD and the Supply Voltage Compensation setting (F307). Note: Not used with the W7B ASD. https://www.toshiba.com/tic/...
Page 119 Maximum — 600.00 For additional information on selecting the proper resistor wattage value Units — kW for a given application contact the Toshiba Customer Support Center. Note: Using a resistor with a wattage rating that is too low may result in system damage.
Page 120 See F301 F312 additional information on this parameter. Settings: 0 — Normal 1 — Start from 0.0 Hz 2 — Start from Running Frequency 3 — Option Board 4 — PG https://www.toshiba.com/tic/...
Page 121 Drooping Control mode. This function determines Changeable During Run — Yes the lowest speed that Drooping will be in effect for motors that share the Minimum — 0.00 same load. Maximum — 320.00 Units — Hz https://www.toshiba.com/tic/...
Page 122 This setting applies to load inertia compensation Changeable During Run — Yes while operating in the Drooping Control mode. Minimum — 0.0 Maximum — 200.0 This parameter should be gradually adjusted to provide smoother Drooping Control operation while operating with heavy loads. https://www.toshiba.com/tic/...
Page 123 Maximum — Upper-Limit (F012) threshold (F331) and the following conditions are met: Units — Hz 1) Light-Load High-Speed Operation Enable is configured at F330. 2) The output torque is less than the setting established in F335 when reaching the frequency setting here. https://www.toshiba.com/tic/...
Page 124 Light-Load High-Speed Changeable During Run — Yes (F331) operation may engage or remain engaged if active. Minimum — 0 Maximum — 250 If the Light-Load High-Speed operation is terminated normal operation resumes. Units — % https://www.toshiba.com/tic/...
Page 125 Parameter Type — Numerical Factory Default — 80 This parameter establishes the speed that the ASD will ramp to when operating in the Light-Load High-Speed mode. Changeable During Run — Yes Minimum — 0.00 Maximum — Max. Freq. (F011) Units — % https://www.toshiba.com/tic/...
Page 126 This parameter determines the amount of time that the drive will wait before outputting a signal to the motor once the switch-to-drive-output Changeable During Run — Yes criteria has been met. Minimum — 0.01 Maximum — 10.00 Units — Seconds https://www.toshiba.com/tic/...
Page 127 Parameter Type — Numerical Factory Default — 0 This parameter determines the delay in the ASD output response to the motor-control feedback signal (signal source is selected at F360). Changeable During Run — Yes Minimum — 0 Maximum — 255 https://www.toshiba.com/tic/...
Page 128 Factory Default — 500 This parameter is used to set the end-of-travel range when using an encoder on a motor-driven positioning system (e.g., hoist/crane, etc.). Changeable During Run — No Minimum — 1 Maximum — 9999 Units — Pulse Count https://www.toshiba.com/tic/...
Page 129 Parameter Type — Numerical Factory Default — 100 During a deceleration ramp, this parameter sets a speed range that must be attained before the Stop command may be executed. Changeable During Run — Yes Minimum — 1 Maximum — 4000 https://www.toshiba.com/tic/...
Page 130 Factory Default — (ASD-Dependent) This parameter sets the response time of the Speed Loop Integral Gain. The smaller the value here, the more pronounced (quicker) the effect of Changeable During Run — Yes the integral function. Minimum — 10.0 Maximum — 200.0 https://www.toshiba.com/tic/...
Page 131 Direct Access Number — F379 Program  Feedback  PG Settings Parameter Type — Numerical Factory Default — 1.00 Contact the Toshiba Customer Support Center for information on this parameter. Changeable During Run — No Minimum — 0.01 Maximum — 10.00 Preset Speed Operation Mode Direct Access Number —...
Page 132 Direct Access Number — F388 Program  Pattern Run  Preset Speeds Parameter Type — Selection List Factory Default — Forward Determines the forward/reverse setting for the Preset Speed 8 F287). Changeable During Run — No Settings: 0 — Forward 1 — Reverse https://www.toshiba.com/tic/...
Page 133 Direct Access Number — F394 Program  Pattern Run  Preset Speeds Parameter Type — Selection List Factory Default — Forward Determines the forward/reverse setting for the Preset Speed 14 F293). Changeable During Run — No Settings: 0 — Forward 1 — Reverse https://www.toshiba.com/tic/...
Page 134 This value is used in conjunction with other constants to tune the motor. Changeable During Run — No Minimum — 0.00 This setting (motor tuning) is required to use the Vector Control, Maximum — 6500.0 Automatic Torque Boost, or Automatic Energy-saving functions. Units — μH https://www.toshiba.com/tic/...
Page 135 Motor Type Direct Access Number — F413 Program  Motor  Vector Motor Model Parameter Type — Selection List Factory Default — Toshiba EQP III This parameter identifies the type of motor being used. TEFC Settings: Changeable During Run — No 0 —...
Page 136 Synchronized Torque Bias input signal. Settings: 0 — Disabled 1 — VI/II 2 — RR 3 — RX 4 — RX2 (Option Card) 5 — CN8 Option 6 — Binary/BCD Input 7 — Common Serial (TTL) 8 — RS232/RS485 9 — Communication Card https://www.toshiba.com/tic/...
Page 137 If Setting is selected, the value set at F426 is used as the Forward Speed Limit input. Settings: 0 — Disabled 1 — VI/II 2 — RR 3 — RX 4 — RX2 (Option Card) 5 — Setting (F426) https://www.toshiba.com/tic/...
Page 138 Parameter Type — Selection List Factory Default — Fixed Direction This parameter specifies whether the torque command function is to be used in one direction or both (F/R). Changeable During Run — No Settings: 0 — Fixed Direction 1 — F/R Permitted https://www.toshiba.com/tic/...
Page 139 Torque Control Changeable During Run — No mode. This parameter sets the response time of the system to torque Minimum — 0.00 change requirements. Maximum — 2.50 Units — Seconds https://www.toshiba.com/tic/...
Page 140 This parameter is used to set the positive torque upper-limit for the 2 motor profile when multiple motors are controlled by a single drive or Changeable During Run — Yes when a single motor is controlled by multiple profiles. Minimum — 0.00 Maximum — 250.0 Units — % https://www.toshiba.com/tic/...
Page 141 This parameter is used to set the negative torque upper-limit for the 4 motor profile when multiple motors are controlled by a single drive or Changeable During Run — Yes when a single motor is controlled by multiple profiles. Minimum — 0.00 Maximum — 250.0 Units — % https://www.toshiba.com/tic/...
Page 142 Direct Access Number — F450 Program  Torque  Torque Limit Settings Parameter Type — Selection List Factory Default — Power-Running / Contact the Toshiba Customer Support Center for information on this Regenerative Torque Limit parameter. Changeable During Run — No Settings: 1 —...
Page 143 (pot, pressure transducer, flow meter, etc.) is also the zero level setting of the ASD system. This is accomplished by setting the input source to zero and either increasing or decreasing this setting to provide an output of zero from the ASD. https://www.toshiba.com/tic/...
Page 144 (pot, pressure transducer, flow meter, etc.) is also the 100% level setting of the ASD system. This is accomplished by setting the input source to 100% and either increasing or decreasing this setting to provide an output of 100% from the ASD. https://www.toshiba.com/tic/...
Page 145 If Effective is selected, Changeable During Run — Yes the preset Torque Control or Speed Control settings will determine the rate that the motor reaches excitation saturation. Settings: 0 — Effective 1 — Applied by F480 https://www.toshiba.com/tic/...
Page 146 Program  Special  Special Parameters Parameter Type — Numerical Factory Default — 105.0 This parameter compensates for losses in the rotor-to-stator coupling of the excitation and torque current energy. Changeable During Run — Yes Minimum — 0 Maximum — 255 https://www.toshiba.com/tic/...
Page 147 This setting is also used to determine the acceleration rate of the UP/ Units — Seconds DOWN Frequency function. Note: An acceleration time shorter than the load will allow may cause nuisance tripping and mechanical stress to loads. Automatic Accel/Decel and Stall settings may lengthen the acceleration time. https://www.toshiba.com/tic/...
Page 148 This setting is also used to determine the deceleration rate of the UP/ Units — Seconds DOWN Frequency function. Note: A deceleration time shorter than the load will allow may cause nuisance tripping and mechanical stress to loads. Automatic Accel/Decel and Stall settings may lengthen the acceleration time. https://www.toshiba.com/tic/...
Page 149 S-Pattern 1 is used for applications that require quick acceleration and deceleration. This setting is also popular for applications that require shock absorption at the start of acceleration or deceleration. S-Pattern 2 acceleration and deceleration decreases the rate of change above the base frequency. https://www.toshiba.com/tic/...
Page 150 Direct Access Number — F506 Program  Special  ACC/DEC Special Parameter Type — Numerical Factory Default — 25.00 This parameter sets the lower-limit of S-Pattern 1 and 2. Changeable During Run — Yes Minimum — 0.00 Maximum — 50.00 Units — % https://www.toshiba.com/tic/...
Page 151 Factory Default — Linear This parameter enables a user-selected preprogrammed output profile that controls the acceleration and deceleration pattern for the Accel/ Changeable During Run — Yes Decel 3 parameter. Settings: 0 — Linear 1 — S-Pattern 1 2 — S-Pattern 2 https://www.toshiba.com/tic/...
Page 152 This parameter sets the frequency at which the acceleration control is switched from the Accel 3 profile to the Accel 4 profile during a multiple- Changeable During Run — Yes acceleration profile configuration. Minimum — 0.00 Maximum — Max. Freq. (F011) Units — Hz https://www.toshiba.com/tic/...
Page 153 The trip information may be Changeable During Run — No viewed from the Monitor screen. When disabled, the trip information will be cleared when the system powers down. Settings: 0 — Cleared after power off 1 — Hold after power off https://www.toshiba.com/tic/...
Page 154 This parameter is used to reduce the start frequency during very low- speed motor operation. During very low-speed operation the cooling Changeable During Run — Yes efficiency of the motor decreases. Lowering the start frequency aides in Minimum — 0.00 minimizing the generated heat. Maximum — 30.00 Units — Hz https://www.toshiba.com/tic/...
Page 155 Factory Default — 0 When the low-current monitor is enabled, this function sets the time that the low-current condition must exist to cause a trip. Changeable During Run — Yes Minimum — 0 Maximum — 255 Units — Seconds https://www.toshiba.com/tic/...
Page 156 This parameter sets the torque threshold level that is used as a setpoint for over-torque tripping during regeneration. This setting is a percentage Changeable During Run — Yes of the maximum rated torque of the drive. Minimum — 0.00 Maximum — 250.0 Units — % https://www.toshiba.com/tic/...
Page 157 Parameter Type — Numerical Factory Default — 0.0 This parameter sets the upper level of the Base Frequency range that, once exceeded, will cause an Over-Speed Detected alert. Changeable During Run — Yes Minimum — 0.0 Maximum — 30.0 Units — Hz https://www.toshiba.com/tic/...
Page 158 F628 setting. A user-selected contact may be actuated if so configured. If Disabled the ASD will stop and not trip; the FL contact is not active. Settings: 0 — Disabled 1 — Enabled (Box Checked) https://www.toshiba.com/tic/...
Page 159 Parameter Type — Numerical Factory Default — 100 This parameter sets the threshold level (%) that must be exceeded to meet the Earth Fault Alarm activation criteria. Changeable During Run — No Minimum — 0 Maximum — 100 Units — % https://www.toshiba.com/tic/...
Page 160 Upper-Limit. When enabled, either VI/II or RR may be Changeable During Run — Yes used as an input source for the modification of the Upper-Limit setting. Settings: 0 — Disabled 1 — VI/II 2 — RR https://www.toshiba.com/tic/...
Page 161 Torque Boost setting. Selecting either VI/II or RR Changeable During Run — Yes enables this feature. The selected input is used as a modifier of the programmed Torque Boost setting. Settings: 0 — Disabled 1 — VI/II 2 — RR https://www.toshiba.com/tic/...
Page 162 If operating using the CN8 Option and Setting is selected, the value entered at F729 is used as the multiplier. Settings: 0 — Disabled 1 — VI/II 2 — RR 3 — RX 4 — RX2 5 — Setting (F729) https://www.toshiba.com/tic/...
Page 163 This parameter sets the Analog 1 multifunction programmable terminal to 1 of 31 possible functions and is available on the ASD Multicom Changeable During Run — Yes option board only. Possible assignments for this output terminal are listed in Table 8 on pg. 175. https://www.toshiba.com/tic/...
Page 164 This parameter sets the full-scale reading of the FP Terminal. The full- scale reading of the monitored variable selected in F676 may be set Changeable During Run — Yes here. Minimum — 1.000 Maximum — 43.200 Units — kHz https://www.toshiba.com/tic/...
Page 165 Program  Utilities  Display Parameters Parameter Type — Selection List Factory Default — 0.1 This parameter sets the number of decimal places to be displayed for Accel/Decel functions. Changeable During Run — Yes Settings: 0 — 1 1 — 0.1 2 — 0.01 https://www.toshiba.com/tic/...
Page 166 1 — Decel Stop 2 — Coast Stop Note: The Stop Pattern setting has no effect on the Emergency Off settings of F603. If using the LCD EOI, press ESC from the Frequency Command screen to access this parameter. https://www.toshiba.com/tic/...
Page 167 Parameter Type — Selection List Factory Default — Disabled Enables/Disables the Low Output Disable function and, if enabled, selects a stopping method. Changeable During Run — Yes Settings: 0 — Disabled 1 — Enabled — Decel Stop 2 — Enabled — Coast Stop https://www.toshiba.com/tic/...
Page 168 The Low Output Disable Feedback Level sets a frequency level that, until the output of the ASD drops below this setting, the Restart Delay Changeable During Run — Yes Timer does not start. Minimum — 0.0 Maximum — Max. Freq. (F011) Units — Hz https://www.toshiba.com/tic/...
Page 169 ASD. Changes made to this parameter require that the power be cycled (off then on) for the changes to take effect. Settings: 0 — No Parity 1 — Even Parity 2 — Odd Parity https://www.toshiba.com/tic/...
Page 170 Settings: 0 — RS232/RS485=No action/TTL=No action 1 — RS232/RS485=Alarm/TTL=No action 2 — RS232/RS485=No action/TTL=Alarm 3 — RS232/RS485=Alarm/TTL=Alarm 4 — RS232/RS485=Trip/TTL=Alarm 5 — RS232/RS485=No action/TTL=Trip 6 — RS232/RS485=No action/TTL=Trip 7 — RS232/RS485=Alarm/TTL=Trip 8 — RS232/RS485=Trip/TTL=Trip https://www.toshiba.com/tic/...
Page 171 Scaling the communications signal is not required for all applications. Changes made to this parameter require that the power be cycled (off then on) for the changes to take effect. Settings: 0 — Disabled 1 — Common Serial (TTL) 2 — RS232/RS485 3 — Communication Card https://www.toshiba.com/tic/...
Page 172 Maximum — Max. Freq. (F011) This parameter sets Communications Reference Speed Setpoint 1. Units — Hz Changes made to this parameter require that the power be cycled (off then on) for the changes to take effect. https://www.toshiba.com/tic/...
Page 173 This parameter sets the communications protocol to the 2- or 4-wire method. Changeable During Run — Yes Changes made to this parameter require that the power be cycled (off then on) for the changes to take effect. Settings: 0 — 2 wire 1 — 4 wire https://www.toshiba.com/tic/...
Page 174 1 — Command Request Held Input Reference 1 Direct Access Number — F831 Program  Communications  Scan Receive Settings Parameter Type — Numerical Not used. Factory Default — 0 Changeable During Run — Yes Minimum — 0 Maximum — 16 https://www.toshiba.com/tic/...
Page 175 Maximum — 16 Output Monitor 1 Direct Access Number — F841 Program  Communications  Scan Transmit Settings Parameter Type — Numerical Not used. Factory Default — 0 Changeable During Run — Yes Minimum — 0 Maximum — 16 https://www.toshiba.com/tic/...
Page 176 This parameter is used to set the length of time that no communications activity may exist before the communications link is disconnected. Changeable During Run — Yes Settings: 0 — Mode 0 1 — Mode 1 2 — Mode 2 3 — Mode 3 4 — Mode 4 https://www.toshiba.com/tic/...
Page 177 Maximum — 1023 Torque Reference Station [0 = disabled] Direct Access Number — F865 Program  Communications  S20 Settings Parameter Type — Numerical Not used. Factory Default — 0 Changeable During Run — Yes Minimum— 0 Maximum — 64 https://www.toshiba.com/tic/...
Page 178 Minimum— 0 Maximum — 65535 Optional Parameters 3 Direct Access Number — F892 Program  Communications  Optional Parameters Parameter Type — Numerical Not used. Factory Default — 0 Changeable During Run — No Minimum— 0 Maximum — 65535 https://www.toshiba.com/tic/...
Page 179 Maximum — 65535 S20 Reset Direct Access Number — F899 Program  Communications  S20 Settings Parameter Type — Selection List Not used. Factory Default — Disabled Changeable During Run — No Settings: 0 — Disabled 1 — Reset https://www.toshiba.com/tic/...
Page 180 The settings of the A/D selections 1 – 4 are A/D SW Terminal performed at F009/F010, F500/F501, F510/ A/D Profile Selection F511, and F514/F515, respectively. Accel/Decel profiles are comprised of the Accel/Decel settings, Pattern, and Switching Frequency. 1 = Terminal Activated https://www.toshiba.com/tic/...
Page 181 CC (the status of the F and R terminals is ignored). Use F260 to set the Jog Frequency and use F261 to select the Jog Stop Method. https://www.toshiba.com/tic/...
Page 182 When configured to Run (Run/Stop to CC), the make or break of this connection to CC changes the direction of the motor. Run/Stop — This terminal enables the motor to run when connected to CC and disables the motor when the connection is broken. https://www.toshiba.com/tic/...
Page 183 Braking Answer is returned, fault E-11 will occur. Otherwise, the brake releases the motor and normal motor operations resume. The Braking Release function is primarily used at startup; but, may be used when the brake is applied while the motor is running. https://www.toshiba.com/tic/...
Page 184 System Consistent (BT: brake test) — Factory use. Fire Speed — When activated, Preset Speed 1 is output from the ASD. Test — Factory use. No MOFF — Activation turns off the Main Circuit Under-Voltage (MOFF) monitoring, alarm, and trips. https://www.toshiba.com/tic/...
Page 185 Jogging Alarm Code 28 Panel/Terminal Operation Switching Alarm Code 29 Cumulative Run Time Alarm Alarm Code 30 Abnormal Communication Alarm (External Alarm Code 31 Cause) Forward/Reverse Operation FL3 (non EOff Trip) Status Ready for Operation (Including ST and RUN) https://www.toshiba.com/tic/...
Page 186 PG Counter 32767 Encoder Pulses Position Pulse RR Input 100% VI/II Input RX Input RX2 Input (Option Card) FM Output (Used For Factory Testing Only) AM Output (Used For Factory Testing Only) Meter Adjust Value Analog Output Load Torque 150% https://www.toshiba.com/tic/...
Page 187: Alarms, Trips, And Troubleshooting
ASD system in the event that a subsystem of the ASD is malfunctioning, or one or more of the variables listed below exceeds its normal range (time and/or magnitude). • Current, • Voltage, • Speed, • Temperature, • Torque, or • Load. https://www.toshiba.com/tic/...
Page 188 Other Motor is selected at parameter F413. db or dbOn DC Braking Active This code conveys that the DC Injection function being carried out. The display shows db when braking and dbOn when the Shaft Stationary function is active. https://www.toshiba.com/tic/...
Page 189 • ASD is too close to heat-generating equipment. • Cooling fan vent is obstructed (see Mounting the ASD on pg. 14). • Cooling fan is inoperative. • Internal thermistor is disconnected. Timer Run-time counter • Type Reset required; select Clear run timer. exceeded. https://www.toshiba.com/tic/...
Page 190 • Excessive load on power supply. supply. • Low input voltage. PtSt Reference Two speed-reference • Two speed reference frequency setpoints are Point frequency setpoint values too close to each other (increase the are too close to each difference). other. https://www.toshiba.com/tic/...
Page 191 Table 10. (Continued) ASD Alarms. Function Description Possible Causes Display * Reset ignored if active. Under-Current Output current of the ASD is below the level defined at parameter F611 remains there for greater than the time set at parameter F612. https://www.toshiba.com/tic/...
Page 192 • Encoder signal missing while running during closed-loop operation. Flash Memory Fault • Flash memory malfunction. Gate Array Fault • Defective Gate Array or Gate Array malfunction. Input Phase Loss • 3-phase input to the ASD is low or missing. https://www.toshiba.com/tic/...
Page 193 HP or less during a fixed-speed run or if during a fixed-speed run the ASD over-heats. On ASDs that are greater than 100 HP, it occurs when the ASD current exceeds 320% of the rated FLA on a fixed-speed run. https://www.toshiba.com/tic/...
Page 194 Typeform Error • Firmware information (typeform) loaded into the Gate Driver board is inconsistent with the device in which the firmware is being used. • The Gate Driver board has been replaced. • The Gate Driver board is defective. https://www.toshiba.com/tic/...
Page 195 U-Phase OC • Low impedance at the U lead of the ASD output. V-Phase OC • Low impedance at the V lead of the ASD output. W-Phase OC • Low impedance at the W lead of the ASD output. https://www.toshiba.com/tic/...
Page 196 Monitor screen (see 33). The Via Program  Utilities  Type Resets  Monitor screen at-trip record is erased when the • ASD is reset and may be viewed without the use of Clear Past Trips. https://www.toshiba.com/tic/...
Page 197: Enclosure Dimensions And Weight Information
Figure 25. W7B ASD Part Numbering Convention. Note: The Type 1 enclosed versions of the W7B ASD meet or exceed the specification UL 1995, the Standard for Heating and Cooling Equipment, and complies with the applicable requirements for installation in a compartment handling conditioned air. https://www.toshiba.com/tic/...
Page 198 84/2134 440K 3000/1361 72/1829 450K AS=Fig. 28 108/2743 Table 14 W7 NEMA 1 460-Volt Enclosure Dimensions. Figure Approx. Shipping Weight Model Number Width Height Depth Number (lbs/kg) (in/mm) (in/mm) (in/mm) 460K 470K Fig. 29 76/1930 105/2667 24/610 5000/2273 480K https://www.toshiba.com/tic/...
Page 199 Table 16 W7B NEMA 1 690-Volt Enclosure Dimensions. Figure Approx. Shipping Weight Model Number Width Height Depth Number (lbs/kg) (in/mm) (in/mm) (in/mm) 610K 612K 615K 30/762 1300/591 617K Fig. 32 100/2540 24/610 620K 625K 2250/1023 630K 42/1067 2330/1046 640K https://www.toshiba.com/tic/...
Page 200 Enclosure Dimensions W7B ASD Installation & Operation Manual Figure 26. W7B NEMA 1 460V. See Table 13 on page 188 for Actual Dimensions. Figure 27. W7B NEMA 1 460V. See Table 13 on page 188 for Actual Dimensions. https://www.toshiba.com/tic/...
Page 201 Enclosure Dimensions W7B ASD Installation & Operation Manual Figure 28. W7B NEMA 1 460V. See Table 13 on page 188 for Actual Dimensions. Figure 29. W7B NEMA 1 460V. See Table 14 on page 188 for Actual Dimensions. https://www.toshiba.com/tic/...
Page 202 Enclosure Dimensions W7B ASD Installation & Operation Manual Figure 30. W7B NEMA 12 460V. See Table 15 on page 189 for Actual Dimensions. Figure 31. W7B NEMA 12 460V. See Table 15 on page 189 for Actual Dimensions. https://www.toshiba.com/tic/...
Page 203 Enclosure Dimensions W7B ASD Installation & Operation Manual Figure 32. W7B NEMA 1 690V. See Table 16 on page 189 for Actual Dimensions. https://www.toshiba.com/tic/...
Page 204: Current/Voltage Specifications
302 A 362 A 430K 300/224 370 A 444 A 440K 400/298 480 A 576 A 450K 500/373 628 A 754 A 460K 600/447 740 A 888 A 470K 700/522 900 A 1080 A 480K 800/597 960 A 1152 A https://www.toshiba.com/tic/...
Page 205 615K 155 A 186 A 617K 177 A 212 A 575 – 690 VAC Input Voltage (±10%) Level (Max.) 620K 216 A 259 A 625K 272 A 326 A 630K 335 A 402 A 640K 420 A 482 A https://www.toshiba.com/tic/...
Page 206: Cable/Terminal Specifications
Note: The following ratings are recommendations and shall not be the sole determining factor of the Note: Input and Output power wires require lug or wire size used with the W7B ASD. shielding for CE compliance. https://www.toshiba.com/tic/...
Page 207 ***253 ***300 ***152 Note: (*) Item is one of a set of two parallel cables. Note: (**) Item is one of a set of three parallel cables. Note: (***) Item is one of a set of four parallel cables. https://www.toshiba.com/tic/...
Page 208 *253 *300 *152 Note: (*) Item is one of a set of two parallel cables. Note: (*) Item is one of a set of two parallel cables. Note: (**) Item is one of a set of three parallel cables. https://www.toshiba.com/tic/...
Page 209 2x 14-2/0 4500 620K 4600 625K 2x 2/0-500 4750 630K 2x 2-600 410K 3/0-350 640K 412K 415K 6-350 2x 2-500 420K 425K 430K 2x 4-500 435K 3x 3/0-500 440K 450K 2x 2-600 460K 470K 4x 3/0-500 5x 3/0-500 480K https://www.toshiba.com/tic/...
Page 210: Spare Parts Listing
Parenthesized values are the total quantities per model for the part immediately above the parenthesized quantity only. Toshiba recommends a spare part inventory of two minimum for the parts listed. If the total quantity per unit is three or more, then the suggested spare parts inventory is one third of the total unit quantity (two minimum).
Page 211 57528 46112 25242 61293 430K 41443 PC4020 51958 55383 0P600 60651 (12) 440K 03670 43855 57529 41444 PC18110 59651 450K 03669 47244 P728 The following items are common to the above-listed typeforms: EOI — 58363-W Fan B — 43480 https://www.toshiba.com/tic/...
Page 212 470K 480K The following items are common to the above-listed typeforms: Control Terminal PCB — 48570A 4-20 mA PCB — 48576A Power Supply PCB — 48776B Jumper PCB — 50611A Speed Search PCB — 52266 Control PCB — 56000E2 https://www.toshiba.com/tic/...
Page 213 The following items are common to the above-listed typeforms: Control Terminal PCB — 48570A 4-20 mA PCB — 48576A Power Supply PCB — 48776B Speed Search PCB — 52266 Control PCB — 56000E2 Interface PCB — 562221 Soft Start PCB — 58411A https://www.toshiba.com/tic/...
Page 214 ASD Side Switching Wait Time (F356), 116 Compensation Coefficient for Iron Loss (F487), 136 ASD-NANOCOM, 21 Conduit Plate Information, 187 Auto Restart Selection (F301), 107 Connecting the ASD, 14 Autotuning Control Board, 21 Autotuning, 11 Control Terminal Strip, 17 of Motor Constant 3 (F414), 126 https://www.toshiba.com/tic/...
Page 215 FLC, 17, 19 Speed at Drooping Gain 0% (F321), 111 Speed at F320 Drooping Gain (F322), 112 FM, 17, 19, 34 Dynamic Braking Enable (F304), 108 Terminal Adjustment (F006), 53 Terminal Function (F005), 52 Forward Speed Limit Input Level (F426), 128 https://www.toshiba.com/tic/...
Page 216 Feedback Level (Hz) (F736), 158 Low Output Disable, 157 Restart Delay Time (F737), 159 I/O and Control, 17 Setpoint Boost (Hz) (F734), 158 I/O Circuit Configurations, 23 Start Level (Hz) (F732), 158 ICCDESIGNS, 21 Start Time (F733), 158 II, 17, 18 https://www.toshiba.com/tic/...
Page 217 On Delay (F154), 73 Preset Speed OUT6 1 (F018), 58 Off Delay (F165), 74 10 (F289), 104 On Delay (F155), 73 11 (F290), 104 OUT7 12 (F291), 104 Off Delay (F166), 74 13 (F292), 104 On Delay (F156), 73 https://www.toshiba.com/tic/...
Page 218 Reverse Speed Limit Level (F428), 128 Lower-Limit Adjustment (F506), 140 Root Menus, 32 Upper-Limit Adjustment (F507), 141 Rotary Encoder, 25 Speed Limit (torque) Center Value Reference Selection (F430), 129 Speed Limit Center Value (F431), 129 Speed Loop Integral Gain (F377), 120 https://www.toshiba.com/tic/...
Page 219 ROM Err, 184 Manual Torque Boost 2 (F172), 75 Sink/Source Error, 184 Manual Torque Boost 3 (F176), 77 Speed Error, 184 Over-Torque Detection Level During Power Type(form) Error, 184 Running (F616), 146 U Phase OC, 185 Under Curr(ent) Trip, 185 https://www.toshiba.com/tic/...
Page 220 Over-Voltage Limit Operation (F305), 108 Five-Point 5 Voltage (F199), 81 Over-Voltage Limit Operation Level (fast) Group (F720), 156 (F625), 148 Pattern (F015), 56 Regenerative Power Ridethrough Control Level Setting, 48 (F629), 149 Under-Voltage Detection Time (F628), 149 Under-Voltage Trip Selection (F627), 148 https://www.toshiba.com/tic/...
Page 222 © 2020 Toshiba International Corporation Motors & Drives 13131 West Little York Road Houston, Texas 77041 USA Tel +713-466-0277 US 1-800-231-1412 TOSHIBA MOTORS & DRIVES Adjustable Speed Drives • Motors • Motor Controls www.toshiba.com/tic...

Toshiba W7 DN-57442-006 Installation & Operation Manual

General Safety Information

Installation Precautions

System Integration Precautions

Operational and Maintenance Precautions

CE Directive

Motor Characteristics

ASD Characteristics

Installation and Connections

Electronic Operator Interface

System Operation

System Configuration and Menu Options

Startup Wizard Requirements

Direct Access Parameter Information

Alarms, Trips, and Troubleshooting

Enclosure Dimensions and Weight Information

Current/Voltage Specifications

Cable/Terminal Specifications

Spare Parts Listing

Quick Links

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Summary of Contents for Toshiba W7 DN-57442-006

Table of Contents