Mitsubishi FR-E720-0.4K(SC), FR-E720-5.5K(SC), FR-E720-2.2K(SC), FR-E720-3.7K(SC), FR-E720-0.2K(SC) Instruction Manual
...
INVERTER
FR-E700
INSTRUCTION MANUAL (Applied)
FR-E720-0.1K(SC) to 15K(SC)
FR-E740-0.4K(SC) to 15K(SC)
FR-E720S-0.1K(SC) to 2.2K(SC)
OUTLINE
1
FR-E710W-0.1K to 0.75K
WIRING
PRECAUTIONS FOR USE
OF THE INVERTER
PARAMETERS
TROUBLESHOOTING
PRECAUTIONS FOR
MAINTENANCE AND INSPECTION
2
3
4
5
6
SPECIFICATIONS
7
Thank you for choosing this Mitsubishi Inverter.
This Instruction Manual (applied) provides instructions for advanced use of the FR-E700 series inverters.
Incorrect handling might cause an unexpected fault. Before using the inverter, always read this Instruction Manual
and the instruction manual (basic) [IB-0600276ENG] packed with the product carefully to use the equipment to its
optimum performance.
2. Fire Prevention
This section is specifically about safety matters
Do not attempt to install, operate, maintain or inspect the
inverter until you have read through the Instruction Manual
and appended documents carefully and can use the
equipment correctly. Do not use this product until you have
a full knowledge of the equipment, safety information and
instructions.
In this Instruction Manual, the safety instruction levels are
classified into "WARNING" and "CAUTION".
WARNING
CAUTION
CAUTION
The level may even lead to a serious
consequence according to conditions. Both instruction
levels must be followed because these are important to
personal safety.
Incorrect handling may cause
hazardous conditions, resulting in
death or severe injury.
Incorrect handling may cause
hazardous conditions, resulting in
medium or slight injury, or may cause
only material damage.
1. Electric Shock Prevention
WARNING
z While power is ON or when the inverter is running, do not
open the front cover. Otherwise you may get an electric
shock.
z Do not run the inverter with the front cover or wiring cover
removed. Otherwise you may access the exposed highvoltage terminals or the charging part of the circuitry and
get an electric shock.
z Even if power is OFF, do not remove the front cover
except for wiring or periodic inspection. You may
accidentally touch the charged inverter circuits and get an
electric shock.
z Before wiring or inspection, power must be switched OFF.
To confirm that, LED indication of the operation panel
must be checked. (It must be OFF.) Any person who is
involved in wiring or inspection shall wait for at least 10
minutes after the power supply has been switched OFF
and check that there are no residual voltage using a tester
or the like. The capacitor is charged with high voltage for
some time after power OFF, and it is dangerous.
z
This inverter must be earthed (grounded). Earthing
(grounding) must conform to the requirements of national
and local safety regulations and electrical code (NEC section
250, IEC 536 class 1 and other applicable standards).
A neutral-point earthed (grounded) power supply for 400V
class inverter in compliance with EN standard must be used.
z Any person who is involved in wiring or inspection of this
equipment shall be fully competent to do the work.
z The inverter must be installed before wiring. Otherwise
you may get an electric shock or be injured.
z Setting dial and key operations must be performed with
dry hands to prevent an electric shock.
z Do not subject the cables to scratches, excessive stress,
heavy loads or pinching. Otherwise you may get an
electric shock.
z Do not change the cooling fan while power is ON. It is
dangerous to change the cooling fan while power is ON.
z Do not touch the printed circuit board or handle the
cables with wet hands. Otherwise you may get an electric
shock.
z When measuring the main circuit capacitor capacity, the
DC voltage is applied to the motor for 1s at powering OFF.
Never touch the motor terminal, etc. right after powering
OFF to prevent an electric shock.
z Inverter must be installed on a nonflammable wall without
holes (so that nobody touches the inverter heatsink on the
rear side, etc.). Mounting it to or near flammable material
can cause a fire.
z If the inverter has become faulty, the inverter power must
be switched OFF. A continuous flow of large current could
cause a fire.
z When using a brake resistor, a sequence that will turn OFF
power when a fault signal is output must be configured.
Otherwise the brake resistor may overheat due to damage
of the brake transistor and possibly cause a fire.
z Do not connect a resistor directly to the DC terminals P/+
and N/-. Doing so could cause a fire.
3.Injury Prevention
z The voltage applied to each terminal must be the ones
specified in the Instruction Manual. Otherwise burst,
damage, etc. may occur.
z The cables must be connected to the correct terminals.
Otherwise burst, damage, etc. may occur.
z Polarity must be correct. Otherwise burst, damage, etc.
may occur.
z While power is ON or for some time after power-OFF, do
not touch the inverter as they will be extremely hot. Doing
so can cause burns.
4. Additional Instructions
Also the following points must be noted to prevent an
accidental failure, injury, electric shock, etc.
(1) Transportation and Mounting
z The product must be transported in correct method that
corresponds to the weight. Failure to do so may lead to
injuries.
z Do not stack the boxes containing inverters higher than
the number recommended.
z The product must be installed to the position where
withstands the weight of the product according to the
information in the Instruction Manual.
z Do not install or operate the inverter if it is damaged or
has parts missing.
z When carrying the inverter, do not hold it by the front
cover or setting dial; it may fall off or fail.
z Do not stand or rest heavy objects on the product.
z The inverter mounting orientation must be correct.
z Foreign conductive objects must be prevented from
entering the inverter. That includes screws and metal
fragments or other flammable substance such as oil.
z As the inverter is a precision instrument, do not drop or
subject it to impact.
z The inverter must be used under the following
environment. Otherwise the inverter may be damaged.
Surrounding
air
temperature
Ambient
humidity
Storage
temperature
Atmosphere
Environment
Altitude/
vibration
∗1 Temperature applicable for a short time, e.g. in transit.
-10°C to +50°C (non-freezing)
(-10°C to +40°C for totally-enclosed structure
feature)
90%RH or less (non-condensing)
-20°C to +65°C *1
Indoors (free from corrosive gas, flammable gas,
oil mist, dust and dirt)
Maximum 1,000m above sea level.
5.9m/s
axes)
CAUTION
CAUTION
CAUTION
2
or less at 10 to 55Hz (directions of X, Y, Z
A-1
(2) Wiring
CAUTION
z Do not install a power factor correction capacitor or surge
suppressor/capacitor type filter on the inverter output
side. These devices on the inverter output side may be
overheated or burn out.
z The connection orientation of the output cables U, V, W to
the motor affects the rotation direction of the motor.
(3) Trial run
CAUTION
z Before starting operation, each parameter must be
confirmed and adjusted. A failure to do so may cause
some machines to make unexpected motions.
(4) Usage
WARNING
z Any person must stay away from the equipment when the
retry function is set as it will restart suddenly after trip.
z Since pressing key may not stop output depending
on the function setting status, separate circuit and switch
that make an emergency stop (power OFF, mechanical
brake operation for emergency stop, etc.) must be
provided.
z OFF status of the start signal must be confirmed before
resetting the inverter fault. Resetting inverter alarm with
the start signal ON restarts the motor suddenly.
z
The inverter must be used for three-phase induction motors.
Connection of any other electrical equipment to the
inverter output may damage the equipment.
z Do not modify the equipment.
z
Do not perform parts removal which is not instructed in this
manual. Doing so may lead to fault or damage of the product.
(5) Emergency stop
CAUTION
z A safety backup such as an emergency brake must be
provided to prevent hazardous condition to the machine
and equipment in case of inverter failure.
z When the breaker on the inverter input side trips, the
wiring must be checked for fault (short circuit), and
internal parts of the inverter for a damage, etc. The cause
of the trip must be identified and removed before turning
ON the power of the breaker.
z When any protective function is activated, appropriate
corrective action must be taken, and the inverter must be
reset before resuming operation.
(6) Maintenance, inspection and parts replacement
CAUTION
z Do not carry out a megger (insulation resistance) test on
the control circuit of the inverter. It will cause a failure.
(7) Disposal
CAUTION
z The inverter must be treated as industrial waste.
General instruction
Many of the diagrams and drawings in this Instruction
Manual show the inverter without a cover or partially open
for explanation. Never operate the inverter in this manner.
The cover must be always reinstalled and the instruction in
this Instruction Manual must be followed when operating
the inverter.
CAUTION
z The electronic thermal relay function does not guarantee
protection of the motor from overheating. It is
recommended to install both an external thermal and PTC
thermistor for overheat protection.
z Do not use a magnetic contactor on the inverter input for
frequent starting/stopping of the inverter. Otherwise the
life of the inverter decreases.
z The effect of electromagnetic interference must be
reduced by using a noise filter or by other means.
Otherwise nearby electronic equipment may be affected.
z Appropriate measures must be taken to suppress
harmonics. Otherwise power supply harmonics from the
inverter may heat/damage the power factor correction
capacitor and generator.
z When driving a 400V class motor by the inverter, the
motor must be an insulation-enhanced motor or measures
must be taken to suppress surge voltage. Surge voltage
attributable to the wiring constants may occur at the
motor terminals, deteriorating the insulation of the motor.
z When parameter clear or all parameter clear is performed,
the required parameters must be set again before starting
operations because all parameters return to the initial value.
z The inverter can be easily set for high-speed operation.
Before changing its setting, the performances of the
motor and machine must be fully examined.
z Stop status cannot be hold by the inverter's brake
function. In addition to the inverter’s brake function, a
holding device must be installed to ensure safety.
z Before running an inverter which had been stored for a long
period, inspection and test operation must be performed.
z For prevention of damage due to static electricity, nearby
metal must be touched before touching this product to
eliminate static electricity from your body.
A-2
CONTENTS
1 OUTLINE 1
1.1 Product checking and parts identification ........................................ 2
1.2 Inverter and peripheral devices ......................................................... 3
1.2.1 Peripheral devices .......................................................................................................................... 4
1.3 Removal and reinstallation of the cover............................................ 5
1.3.1 Front cover ..................................................................................................................................... 5
1.3.2 Wiring cover.................................................................................................................................... 7
1.4 Installation of the inverter and enclosure design ............................. 8
1.4.1 Inverter installation environment..................................................................................................... 8
1.4.2 Cooling system types for inverter panel ....................................................................................... 10
1.4.3 Inverter placement........................................................................................................................ 11
2 WIRING 13
2.1 Wiring ................................................................................................ 14
2.1.1 Terminal connection diagram ....................................................................................................... 14
2.2 Main circuit terminal specifications ................................................ 16
2.2.1 Specification of main circuit terminal ............................................................................................ 16
2.2.2 Terminal arrangement of the main circuit terminal, power supply and the motor wiring .............. 16
2.2.3 Cables and wiring length .............................................................................................................. 18
CONTENTS
2.3 Control circuit specifications .......................................................... 22
2.3.1 Control circuit terminal.................................................................................................................. 22
2.3.2 Changing the control logic ............................................................................................................ 25
2.3.3 Wiring of control circuit ................................................................................................................. 27
2.3.4 Safety stop function (available only for the safety stop function model)....................................... 31
2.3.5 Connection to the PU connector................................................................................................... 33
2.4 Connection of stand-alone option unit............................................. 35
2.4.1 Connection of a dedicated external brake resistor (MRS type, MYS type, FR-ABR)
(0.4K(SC) or more) ...................................................................................................................... 35
2.4.2 Connection of the brake unit (FR-BU2) ........................................................................................ 37
2.4.3 Connection of the high power factor converter (FR-HC) .............................................................. 38
2.4.4 Connection of the power regeneration common converter (FR-CV) ............................................ 39
2.4.5 Connection of the DC reactor (FR-HEL)....................................................................................... 39
3 PRECAUTIONS FOR USE OF THE INVERTER 41
3.1 EMC and leakage currents ............................................................... 42
3.1.1 Leakage currents and countermeasures ...................................................................................... 42
I
3.1.2 EMC measures............................................................................................................................. 44
3.1.3 Power supply harmonics............................................................................................................... 46
3.1.4 Harmonic suppression guideline in Japan ....................................................................................47
3.2 Installation of power factor improving reactor ................................ 49
3.3 Power-OFF and magnetic contactor (MC) ........................................ 50
3.4 Inverter-driven 400V class motor ..................................................... 51
3.5 Precautions for use of the inverter................................................... 52
3.6 Failsafe of the system which uses the inverter ............................... 54
4 PARAMETERS 57
4.1 Operation panel................................................................................. 58
4.1.1 Names and functions of the operation panel ................................................................................ 58
4.1.2 Basic operation (factory setting) ................................................................................................... 59
4.1.3 Easy operation mode setting (easy setting mode)........................................................................ 60
4.1.4 Changing the parameter setting value.......................................................................................... 61
4.1.5 Setting dial push ........................................................................................................................... 61
4.2 Parameter list.................................................................................... 62
4.2.1 Parameter list................................................................................................................................ 62
Parameters according to purposes ................................................. 80
4.3 Control mode .................................................................................... 83
4.3.1 Changing the control method (Pr. 80, Pr. 81, Pr. 800) ................................................................ 84
4.4 Adjustment of the output torque (current) of the motor................. 85
4.4.1 Manual torque boost (Pr. 0, Pr. 46) ............................................................................................. 85
4.4.2 Advanced magnetic flux vector control (Pr. 71, Pr. 80, Pr. 81, Pr.89, Pr. 800) .......................... 86
4.4.3 General-purpose magnetic flux vector control (Pr. 71, Pr. 80, Pr. 81, Pr. 800) ........................... 89
4.4.4 Slip compensation (Pr. 245 to Pr. 247) ....................................................................................... 91
4.4.5 Stall prevention operation (Pr. 22, Pr. 23, Pr. 48, Pr. 66, Pr. 156, Pr. 157, Pr. 277) ................... 92
4.5 Limiting the output frequency ......................................................... 96
4.5.1 Maximum/minimum frequency (Pr. 1, Pr. 2, Pr. 18)..................................................................... 96
4.5.2 Avoiding mechanical resonance points (frequency jumps) (Pr. 31 to Pr. 36) .............................. 97
4.6 V/F pattern........................................................................................ 98
4.6.1 Base frequency, voltage (Pr. 3, Pr. 19, Pr. 47) ............................................................................ 98
4.6.2 Load pattern selection (Pr. 14) .................................................................................................. 100
4.7 Frequency setting by external terminals ...................................... 102
4.7.1 Operation by multi-speed operation (Pr. 4 to Pr. 6, Pr. 24 to Pr. 27, Pr. 232 to Pr. 239)........... 102
4.7.2 Jog operation (Pr. 15, Pr. 16) .................................................................................................... 104
II
4.7.3 Remote setting function (Pr. 59)................................................................................................ 106
4.8 Setting of acceleration/deceleration time and acceleration/
deceleration pattern...................................................................... 109
4.8.1 Setting of the acceleration and deceleration time
(Pr. 7, Pr. 8, Pr. 20, Pr. 21, Pr. 44, Pr. 45, Pr. 147) .................................................................. 109
4.8.2 Starting frequency and start-time hold function (Pr. 13, Pr. 571) .............................................. 112
4.8.3 Acceleration/deceleration pattern (Pr. 29) ................................................................................. 113
4.8.4 Shortest acceleration/deceleration (automatic acceleration/deceleration)
(Pr. 61 to Pr. 63, Pr. 292, Pr. 293)............................................................................................. 114
4.9 Selection and protection of a motor ............................................. 116
4.9.1 Motor overheat protection (Electronic thermal O/L relay) (Pr. 9, Pr. 51) ................................... 116
4.9.2 Applied motor (Pr. 71, Pr. 450) .................................................................................................. 118
4.9.3 Exhibiting the best performance for the motor (offline auto tuning)
(Pr. 71, Pr. 80 to Pr. 84, Pr. 90 to Pr. 94, Pr. 96, Pr. 859) ......................................................... 120
4.10 Motor brake and stop operation.................................................... 128
4.10.1 DC injection brake (Pr. 10 to Pr. 12).......................................................................................... 128
4.10.2 Selection of a regenerative brake (Pr. 30, Pr. 70) ..................................................................... 130
4.10.3 Stop selection (Pr. 250) ............................................................................................................. 132
4.10.4 Stop-on contact control function (Pr. 6, Pr. 48, Pr. 270, Pr. 275, Pr. 276) ................................ 133
4.10.5 Brake sequence function (Pr. 278 to Pr. 283, Pr. 292) .............................................................. 135
CONTENTS
4.11 Function assignment of external terminal and control................ 139
4.11.1 Input terminal function selection (Pr. 178 to Pr. 184) ................................................................ 139
4.11.2 Inverter output shutoff signal (MRS signal, Pr. 17) .................................................................... 141
4.11.3 Condition selection of function validity by second function selection signal (RT) ...................... 142
4.11.4 Start signal operation selection (STF, STR, STOP signal, Pr. 250) .......................................... 143
4.11.5 Output terminal function selection (Pr. 190 to Pr. 192).............................................................. 145
4.11.6 Detection of output frequency (SU, FU signal, Pr. 41 to Pr. 43) ................................................ 149
4.11.7 Output current detection function (Y12 signal, Y13 signal, Pr. 150 to Pr. 153) ......................... 150
4.11.8 Remote output selection (REM signal, Pr. 495 to Pr. 497)........................................................ 152
4.12 Monitor display and monitor output signal ................................... 153
4.12.1 Speed display and speed setting (Pr. 37).................................................................................. 153
4.12.2 Monitor display selection of DU/PU and terminal FM
(Pr. 52, Pr. 54, Pr. 170, Pr. 171, Pr. 268, Pr. 563, Pr. 564) ....................................................... 154
4.12.3 Reference of the terminal FM (pulse train output) (Pr. 55, Pr. 56) ............................................ 159
4.12.4 Terminal FM calibration (calibration parameter C0 (Pr. 900)) ................................................... 160
4.13 Operation selection at power failure and instantaneous power
failure ............................................................................................. 162
4.13.1 Automatic restart after instantaneous power failure/flying start
(Pr. 30, Pr. 57, Pr. 58, Pr. 96, Pr. 162, Pr. 165, Pr. 298, Pr. 299, Pr. 611)................................ 162
4.13.2 Power-failure deceleration stop function (Pr. 261) .................................................................... 168
4.14 Operation setting at fault occurrence .......................................... 170
III
4.14.1 Retry function (Pr. 65, Pr. 67 to Pr. 69) ..................................................................................... 170
4.14.2 Input/output phase loss protection selection (Pr. 251, Pr. 872)................................................. 172
4.14.3 Earth (ground) fault detection at start (Pr. 249) ......................................................................... 172
4.15 Energy saving operation ................................................................ 173
4.15.1 Optimum excitation control (Pr. 60) ........................................................................................... 173
4.16 Motor noise, EMI measures, mechanical resonance .................... 174
4.16.1 PWM carrier frequency and soft-PWM control (Pr. 72, Pr. 240)................................................ 174
4.16.2 Speed smoothing control (Pr. 653)............................................................................................ 175
4.17 Frequency setting by analog input (terminal 2, 4) ........................ 176
4.17.1 Analog input selection (Pr. 73, Pr. 267) ..................................................................................... 176
4.17.2 Response level of analog input and noise elimination (Pr. 74).................................................. 178
4.17.3 Bias and gain of frequency setting voltage (current)
(Pr. 125, Pr. 126, Pr. 241, C2 (Pr. 902) to C7 (Pr. 905)) ........................................................... 179
4.18 Misoperation prevention and parameter setting restriction ........ 184
4.18.1 Reset selection/disconnected PU detection/PU stop selection (Pr. 75) .................................... 184
4.18.2 Parameter write disable selection (Pr. 77)................................................................................. 187
4.18.3 Reverse rotation prevention selection (Pr. 78) .......................................................................... 188
4.18.4 Extended parameter display and user group function (Pr. 160, Pr. 172 to Pr. 174) .................. 188
4.18.5 Password function (Pr. 296, Pr. 297)......................................................................................... 191
4.19 Selection of operation mode and operation location.................... 194
4.19.1 Operation mode selection (Pr. 79)............................................................................................. 194
4.19.2 Operation mode at power-ON (Pr. 79, Pr. 340)......................................................................... 204
4.19.3 Start command source and frequency command source during communication
operation (Pr. 338, Pr. 339, Pr. 550, Pr. 551) ............................................................................ 205
4.20 Communication operation and setting .......................................... 211
4.20.1 Wiring and configuration of PU connector ................................................................................. 211
4.20.2 Initial settings and specifications of RS-485 communication
(Pr. 117 to Pr. 120, Pr. 123, Pr. 124, Pr. 549) ........................................................................... 214
4.20.3 Operation selection at communication error occurrence (Pr. 121, Pr. 122, Pr. 502)................. 215
4.20.4 Communication EEPROM write selection (Pr. 342) .................................................................. 218
4.20.5 Mitsubishi inverter protocol (computer link communication) ...................................................... 219
4.20.6 Modbus-RTU communication specifications
(Pr. 117, Pr. 118, Pr. 120, Pr. 122, Pr. 343, Pr. 502, Pr. 549) ................................................... 232
4.20.7 USB communication (Pr. 547, Pr. 548)...................................................................................... 245
4.21 Special operation and frequency control ...................................... 246
4.21.1 PID control (Pr. 127 to Pr. 134) ................................................................................................. 246
4.21.2 Dancer control (Pr. 44, Pr. 45, Pr. 128 to Pr. 134)..................................................................... 253
4.21.3 Droop control (Pr. 286 to Pr. 287) ............................................................................................. 260
4.21.4 Regeneration avoidance function (Pr. 665, Pr. 882, Pr. 883, Pr. 885, Pr. 886)......................... 261
4.22 Useful functions ............................................................................. 263
IV
4.22.1 Cooling fan operation selection (Pr. 244) .................................................................................. 263
4.22.2 Display of the life of the inverter parts (Pr. 255 to Pr. 259)........................................................ 264
4.22.3 Maintenance timer alarm (Pr. 503, Pr. 504) .............................................................................. 268
4.22.4 Current average value monitor signal (Pr. 555 to Pr. 557) ........................................................ 269
4.22.5 Free parameter (Pr. 888, Pr. 889) ............................................................................................. 271
4.23 Setting from the parameter unit and operation panel.................. 272
4.23.1 RUN key rotation direction selection (Pr. 40) ............................................................................ 272
4.23.2 PU display language selection(Pr.145) ..................................................................................... 272
4.23.3 Operation panel frequency setting/key lock operation selection (Pr. 161) ................................ 273
4.23.4 Magnitude of frequency change setting (Pr. 295)...................................................................... 275
4.23.5 Buzzer control (Pr. 990)............................................................................................................. 276
4.23.6 PU contrast adjustment (Pr. 991) .............................................................................................. 276
4.24 FR-E500 series operation panel (PA02) setting ............................ 277
4.24.1 Built-in potentiometer switching (Pr. 146).................................................................................. 277
4.24.2 Bias and gain of the built-in frequency setting potentiometer (C22 (Pr. 922) to C25 (Pr. 923)) 278
4.25 Parameter clear/ All parameter clear ........................................... 284
4.26 Initial value change list ................................................................. 285
4.27 Check and clear of the faults history ........................................... 286
5 TROUBLESHOOTING 289
5.1 Reset method of protective function ............................................. 290
CONTENTS
5.2 List of fault or alarm indications.................................................... 291
5.3 Causes and corrective actions ...................................................... 292
5.4 Correspondences between digital and actual characters ............ 302
5.5 Check first when you have a trouble ............................................. 303
5.5.1 Motor does not start.................................................................................................................... 303
5.5.2 Motor or machine is making abnormal acoustic noise................................................................ 305
5.5.3 Inverter generates abnormal noise ............................................................................................. 305
5.5.4 Motor generates heat abnormally............................................................................................... 305
5.5.5 Motor rotates in the opposite direction ....................................................................................... 306
5.5.6 Speed greatly differs from the setting......................................................................................... 306
5.5.7 Acceleration/deceleration is not smooth..................................................................................... 306
5.5.8 Speed varies during operation.................................................................................................... 307
5.5.9 Operation mode is not changed properly ................................................................................... 307
5.5.10 Operation panel display is not operating .................................................................................... 308
5.5.11 Motor current is too large............................................................................................................ 308
5.5.12 Speed does not accelerate ......................................................................................................... 309
5.5.13 Unable to write parameter setting............................................................................................... 309
V
6 PRECAUTIONS FOR MAINTENANCE AND INSPECTION 311
6.1 Inspection items ............................................................................. 312
6.1.1 Daily inspection........................................................................................................................... 312
6.1.2 Periodic inspection...................................................................................................................... 312
6.1.3 Daily and periodic inspection...................................................................................................... 313
6.1.4 Display of the life of the inverter parts ........................................................................................ 314
6.1.5 Checking the inverter and converter modules ............................................................................ 315
6.1.6 Cleaning...................................................................................................................................... 316
6.1.7 Replacement of parts.................................................................................................................. 316
6.1.8 Inverter replacement................................................................................................................... 319
6.2 Measurement of main circuit voltages, currents and powers....... 320
6.2.1 Measurement of powers ............................................................................................................. 322
6.2.2 Measurement of voltages and use of PT .................................................................................... 322
6.2.3 Measurement of currents............................................................................................................ 323
6.2.4 Use of CT and transducer........................................................................................................... 323
6.2.5 Measurement of inverter input power factor ............................................................................... 323
6.2.6 Measurement of converter output voltage (across terminals P/+ and N/-) ................................. 323
6.2.7 Measurement of inverter output frequency ................................................................................. 323
6.2.8 Insulation resistance test using megger ..................................................................................... 324
6.2.9 Pressure test............................................................................................................................... 324
7 SPECIFICATIONS 325
7.1 Rating .............................................................................................. 326
7.2 Common specifications .................................................................. 328
7.3 Outline dimension drawings ........................................................... 329
APPENDIX 335
Appendix 1 For customers who are replacing the conventional model
with this inverter .......................................................................................336
Appendix 1-1 Replacement of the FR-E500 series ............................................................................... 336
Appendix 2 Specification change ................................................................................338
Appendix 2-1 SERIAL number check .................................................................................................... 338
Appendix 2-2 Changed Functions ......................................................................................................... 338
Appendix3 Index........................................................................................................... 341
VI
1 OUTLINE
This chapter explains the "OUTLINE" for use of this product.
Always read the instructions before using the equipment.
1.1 Product checking and parts identification ................................. 2
1.2 Inverter and peripheral devices................................................... 3
1.3 Removal and reinstallation of the cover ..................................... 5
1.4 Installation of the inverter and enclosure design ...................... 8
<Abbreviations>
PU .................................................. Operation panel and parameter unit (FR-PU04
Inverter ........................................... Mitsubishi inverter FR-E700 series
FR-E700 ........................................ Mitsubishi inverter FR-E700 series
Pr.................................................... Parameter number (Function number of inverter)
PU operation .................................. Operation using the PU (operation panel/FR-PU04/FR-PU07)
External operation.......................... Operation using the control circuit signals
Combined operation ....................... Operation using both the PU (operation panel/FR-PU04/FR-
PU07) and external operation
Operation panel for E500, PA02..... FR-E500 series operation panel
Mitsubishi standard motor .............. SF-JR
Mitsubishi constant-torque motor ... SF-HRCA
<Trademarks>
Microsoft and Visual C++ are registered trademarks of Microsoft Corporation in the United States
and/or other countries.
ONWORKS
L
DeviceNet
Other company and product names herein are the trademarks and registered trademarks of their
respective owners.
<Mark>
®
is a registered trademark of Echelon Corporation in the U.S.A and other countries.
®
is a registered trademark of ODVA (Open DeviceNet Vender Association, Inc.).
/FR-PU07)
1
2
3
4
5
REMARKS :Additional helpful contents and relations with other functions are stated
NOTE :Contents requiring caution or cases when set functions are not
activated are stated.
POINT :Useful contents and points are stated.
Parameters referred to : related parameters are stated.
.....Specifications differ according to the date assembled. Refer to page 338 to check
the SERIAL number.
6
7
1
Product checking and parts identification
1.1 Product checking and parts identification
Unpack the inverter and check the capacity plate on the front cover and the rating plate on the inverter side face to ensure that
the product agrees with your order and the inverter is intact.
zInverter model
--
FR
E740 3.7
K
No. Voltage class
E720
E740
E720S
E710W
Operation panel
(Refer to page 58)
PU connector
(Refer to page 24)
Voltage/current input switch
(Refer to page 22)
USB connector cover
(Refer to page 245)
Front cover
(Refer to page 5)
PU connector cover
(Refer to page 33)
Three-phase 200V class
Three-phase 400V class
Single-phase 200V class
Single-phase 100V class
Represents the
inverter capacity [kW]
No symbol
Control circuit terminal specificationSymbol
Standard control circuit terminal
(screw type)
Safety stop function modelSC
Cooling fan
(Refer to page 316)
USB connector
(mini-B connector)
(Refer to page 245)
Connector for plug-in
option connection
(Refer to the instruction
manual of options.)
Control circuit terminal
block
(Refer to page 22)
Changing the control
logic jumper connector
(Refer to page 25)
Main circuit
terminal block
(Refer to page 16)
Example of FR-E740-3.7K
Combed shaped wiring cover
(Refer to page 7)
Capacity plate *
FR-E740-3.7K
Inverter model
Serial number
∗ Location of the capacity plate and the rating plate differs
according to the inverter capacity.
Refer to the outline dimension drawing. (Refer to page 329)
• Accessory
· Fan cover fixing screws (M3 × 35mm)
These screws are necessary for compliance with the EU Directive (
Capacity Number
FR-E720-1.5K(SC) to 3.7K(SC), FR-E740-1.5K(SC) to 3.7K(SC), FR-E720S-0.75K(SC) to 2.2K(SC) 1
FR-E720-5.5K(SC) to 15K(SC), FR-E740-5.5K(SC) to 15K(SC) 2
Harmonic suppression guideline (when inverters are used in Japan)
All models of general-purpose inverters used by specific consumers are covered by "Harmonic suppression guideline for consumers who
receive high voltage or special high voltage". (For further details, refer to page 47.)
Rating plate *
Inverter model
Input rating
Output rating
Serial number
Refer to the Instruction Manual (Basic)
FR-E740-3.7K
)
2
1.2 Inverter and peripheral devices
AC power supply
Use within the permissible power supply
specifications of the inverter. To ensure
safety, use a moulded case circuit breaker,
AC reactor (FR -HAL)
earth leakage circuit breaker or magnetic
contactor to switch power ON/OFF.
(Refer to page 326)
Moulded case circuit breaker
(MCCB) or earth leakage circuit
breaker (ELB), fuse
The breaker must be selected carefully
since an in-rush current flows in the
inverter at power on.
(Refer to page 4)
Magnetic contactor (MC)
Install the magnetic contactor to ensure
safety. Do not use this magnetic contactor
to start and stop the inverter. Doing so will
cause the inverter life to be shorten.
(Refer to page 50)
Reactor (FR-HAL, FR-HEL option)
Reactors (option) must be used when
power harmonics measures are taken,
the power factor is to be improved or the
inverter is installed near a large power
supply system (500kVA or more). The
inverter may be damaged if you do not
use reactors. Select the reactor according
to the model. Remove the jumpers across
terminals P/+ and P1 to connect the DC reactor.
DC reactor (FR-HEL) *
EMC filter (ferrite core) *
(FR-BSF01, FR-BLF)
Install
an EMC filter (ferrite core)
to reduce the electromagnetic
noise generated from the
inverter. Effective in the range
from about 1MHz to 10MHz.
When more wires are passed
through, a more effective result
can be obtained. A wire should
be wound four turns or more.
P/+
Parameter unit
(FR-PU07)
P1
EMC filter
(capacitor) *
(FR-BIF)
Reduces the
radio noise.
Enclosure surface
operation panel
(FR-PA07)
By connecting the connection
cable (FR-CB2) to the PU
connector, operation can be
performed from FR-PU07,
FR-PA07.
(Refer to page 33)
Inverter (FR-E700)
R/L1 S/L2T/L3
Inverter and peripheral devices
USB connector
A personal computer and an inverter
can be connected with a
USB (Ver1. 1) cable.
(Refer to page 245)
Earth (Ground)
P/+
N/-
P/+
PR
V
UW
S1
S2
PC
Required for compliance with
safety standard. Only the
safety stop function model
can be connected.
Brake resistor
(FR-ABR, MRS type, MYS type)
Braking capability can be improved. (0.4K
or more)
Always install a thermal relay when using
a brake resi stor whose capacity is 11K or
more.
EMC filter (ferrite core)
(FR-BSF01, FR-BLF)
Install
to reduce the electromagnetic
noise generated from the inverter.
Effective in the range from about
1MHz to 10MHz. A wire should be
wound four turns at a maximum.
Approved safety
relay module
(Refer to page 35)
an EMC filter (ferrite core)
Motor
1
OUTLINE
* Filterpack (FR-BFP2), which contains DC reactor and EMC filter in one package, is also available.
Brake unit
(FR-BU2)
P/+
P/+
PR
High power factor
converter (FR-HC)
Power supply harmonics
can be greatly suppressed.
Install this as required.
Power regeneration
common converter
(FR-CV)
Great braking capability
is obtained.
Install this as required.
Resistor unit (FR-BR)
Discharging resistor (GZG, GRZG)
The regenerative braking capability
of the inverter can be exhibited fully.
Install this as required.
NOTE
The life of the inverter is influenced by surrounding air temperature. The surrounding air temperature should be as low as
possible within the permissible range. This must be noted especially when the inverter is installed in an enclosure. (Refer
to page 8)
y Wrong wiring might lead to damage of the inverter. The control signal lines must be kept fully away from the main circuit
to protect them from noise. (Refer to page 14)
Do not install a power factor correction capacitor, surge suppressor or capacitor type filter on the inverter output side.
This will cause the inverter to trip or the capacitor and surge suppressor to be damaged. If any of the above devices are
connected, immediately remove them.
Electromagnetic wave interference
The input/output (main circuit) of the inverter includes high frequency components, which may interfere with the
communication devices (such as AM radios) used near the inverter. In this case, install options among the capacitor type
EMC filter FR-BIF (for use in the input side only), the ferrite core type EMC filter FR-BSF01/FR-BLF, filterpack, and EMC
filter to minimize the interference. (Refer to page 44).
Refer to the instruction manual of each option and peripheral devices for details of peripheral devices.
Devices connected to the output
PR
Do not install a power factor correction capacitor,
surge suppressor or capacitor type filter on the output
side of the inverter. When installing a moulded case
circuit breaker on the output side of the inverter,
contact each manufacturer for selection of the
moulded case circuit breaker.
Earth (Ground)
To prevent an electric shock, always earth (ground)
the motor and inverter. For reduction of induction noise
from the power line of the inverter, it is recommended
to wire the earthing cable by returning it to the earth
(ground) terminal of the inverter.
Earth (Ground)
3
Inverter and peripheral devices
1.2.1 Peripheral devices
Check the inverter model of the inverter you purchased. Appropriate peripheral devices must be selected according to the capacity.
Refer to the following list and prepare appropriate peripheral devices:
Moulded Case Circuit Breaker
(MCCB) ∗1
(ELB) ∗2
Reactor connection Reactor connection
Applicable Inverter
Model
Motor
Output
(kW)
or Earth Leakage Circuit Breaker
without with without with
FR-E720-0.1K(SC) 0.1 5A 5A S-N10 S-N10 0.4K ∗5
FR-E720-0.2K(SC) 0.2 5A 5A S-N10 S-N10
FR-E720-0.4K(SC) 0.4 5A 5A S-N10 S-N10 0.4K 0.4K
FR-E720-0.75K(SC) 0.75 10A 10A S-N10 S-N10 0.75K 0.75K
FR-E720-1.5K(SC) 1.5 15A 15A S-N10 S-N10 1.5K 1.5K
FR-E720-2.2K(SC) 2.2 20A 15A S-N10 S-N10 2.2K 2.2K
FR-E720-3.7K(SC) 3.7 30A 30A S-N20, S-N21 S-N10 3.7K 3.7K
FR-E720-5.5K(SC) 5.5 50A 40A S-N25 S-N20, S-N21 5.5K 5.5K
Three-Phase 200V
FR-E720-7.5K(SC) 7.5 60A 50A S-N25 S-N25 7.5K 7.5K
FR-E720-11K(SC) 11 75A 75A S-N35 S-N35 11K 11K
FR-E720-15K(SC) 15 125A 100A S-N50 S-N50 15K 15K
FR-E740-0.4K(SC) 0.4 5A 5A S-N10 S-N10 H0.4K H0.4K
FR-E740-0.75K(SC) 0.75 5A 5A S-N10 S-N10 H0.75K H0.75K
FR-E740-1.5K(SC) 1.5 10A 10A S-N10 S-N10 H1.5K H1.5K
FR-E740-2.2K(SC) 2.2 15A 10A S-N10 S-N10 H2.2K H2.2K
FR-E740-3.7K(SC) 3.7 20A 15A S-N10 S-N10 H3.7K H3.7K
FR-E740-5.5K(SC) 5.5 30A 20A S-N20, S-N21 S-N11, S-N12 H5.5K H5.5K
FR-E740-7.5K(SC) 7.5 30A 30A S-N20, S-N21 S-N20, S-N21 H7.5K H7.5K
Three-Phase 400V
FR-E740-11K(SC) 11 50A 40A S-N20, S-N21 S-N20, S-N21 H11K H11K
FR-E740-15K(SC) 15 60A 50A S-N25 S-N20, S-N21 H15K H15K
FR-E720S-0.1K(SC) 0.1 5A 5A S-N10 S-N10
FR-E720S-0.2K(SC) 0.2 5A 5A S-N10 S-N10
FR-E720S-0.4K(SC) 0.4 10A 10A S-N10 S-N10
FR-E720S-0.75K(SC) 0.75 15A 10A S-N10 S-N10
FR-E720S-1.5K(SC) 1.5 20A 20A S-N10 S-N10
FR-E720S-2.2K(SC) 2.2 40A 30A S-N20, S-N21 S-N10 3.7K
Single-Phase 200V
FR-E710W-0.1K 0.1 10A 5A S-N10 S-N10
Magnetic Contactor (MC)
∗3
Reactor
FR-HAL FR-HEL
0.4K
0.4K
∗5 0.4K ∗5
0.4K
∗5 0.4K ∗5
0.4K
∗5 0.4K ∗5
0.75K
∗5 0.75K ∗5
1.5K
∗5 1.5K ∗5
2.2K
∗5 2.2K ∗5
∗5 3.7K ∗5
0.75K ∗4
,
∗5
−−− ∗ 6
∗5
FR-E710W-0.2K 0.2 10A 10A S-N10 S-N10
FR-E710W-0.4K 0.4 15A 15A S-N10 S-N10 2.2K
FR-E710W-0.75K 0.75 30A 20A S-N10 S-N10
Single-Phase 100V
∗1 Select an MCCB according to the power supply capacity.
Install one MCCB per inverter.
∗2 For the use in the United States or Canada, select a UL and cUL certified fuse with Class T fuse equivalent cut-off
speed or faster with the appropriate rating for branch circuit protection. Alternatively, select a UL489 molded case circuit breaker (MCCB).
( Refer to the Instruction Manual (basic))
∗3 Magnetic contactor is selected based on the AC-1 class. The electrical durability of magnetic contactor is 500,000 times. When the magnetic contactor is
used for emergency stop during motor driving, the electrical durability is 25 times.
When using the MC for emergency stop during motor driving or using on the motor side during commercial-power supply operation, select the MC with class
AC-3 rated current for the motor rated current.
∗4 When connecting a single-phase 100V power input inverter to a power transformer (50kVA or more), install a AC reactor (FR-HAL) so that the performance
is more reliable. (Refer to page 49 for details.)
∗5 The power factor may be slightly lower.
∗6 Single-phase 100V power input model is not compatible with DC reactor.
1.5K
∗4, ∗5 −−− ∗ 6
∗4, ∗5 −−− ∗ 6
3.7K
∗4, ∗5 −−− ∗ 6
MCCB INV
MCCB INV
IM
IM
NOTE
When the inverter capacity is larger than the motor capacity, select an MCCB and a magnetic contactor according to
the inverter model and cable and reactor according to the motor output.
When the breaker on the inverter input side trips, check for the wiring fault (short circuit), damage to internal parts of
the inverter, etc. Identify the cause of the trip, then remove the cause and power on the breaker.
4
Removal and reinstallation of the cover
1.3 Removal and reinstallation of the cover
1.3.1 Front cover
FR-E720-3.7K(SC) or less, FR-E740-7.5K(SC) or less, FR-E720S, FR-E710W
zRemoval (Example of FR-E740-3.7K)
Remove the front cover by pulling it toward you in the direction of arrow.
zReinstallation (Example of FR-E740-3.7K)
To reinstall, match the cover to the inverter front and install it straight.
1
OUTLINE
5
Removal and reinstallation of the cover
r
FR-E720-5.5K(SC) to 15K(SC), FR-E740-11K(SC), 15K(SC)
zRemoval (Example of FR-E740-11K)
1) Loosen the installation screws of the front cover 1.
2) Remove the front cover 1 by pulling it toward you in the direction of arrow.
3) Remove the front cover 2 by pulling it toward you in the direction of arrow.
1) 2) 3)
Front cover 2
Front cover 1
Installation
screws
zReinstallation (Example of FR-E740-11K)
1) Match the front cover 2 to the inverter front and install it straight.
2) Insert the two fixed hooks on the lower side of the front cover 1 into the sockets of the inverter.
3)Tighten the screw of the front cover 1.
1) 2) 3)
Tighten
the installation
screws
Front cover 1
Front cover 2
Fixed hook
Socket of the inverte
NOTE
Fully make sure that the front cover has been reinstalled securely.
The same serial number is printed on the capacity plate of the front cover and the rating plate of the inverter. Since
these plates have the same serial numbers, always reinstall the removed cover onto the original inverter.
6
Removal and reinstallation of the cover
r
r
e
1.3.2 Wiring cover
zRemoval and reinstallation
The cover can be removed easily by pulling it toward you. To reinstall, fit the cover to the inverter along the guides.
FR-E720-0.1K(SC) to 0.75K(SC)
FR-E720S-0.1K(SC) to 0.4K(SC)
FR-E710W-0.1K to 0.4K
Guide
Wiring cove
Example of FR-E720S-0.4K Example of FR-E740-3.7K
FR-E740-5.5K(SC), 7.5K(SC)
FR-E720-1.5K(SC) to 3.7K(SC)
FR-E740-0.4K(SC) to 3.7K(SC)
FR-E720S-0.75K(SC) to 2.2K(SC)
FR-E710W-0.75K
FR-E720-5.5K(SC) to 15K(SC)
FR-E740-11K(SC), 15K(SC)
Guide
Wiring cove
1
Guid
Wiring cover
Dent
For removal, push the dent on the wiring cover with your finger and
pull toward you.
Example of FR-E740-5.5K Example of FR-E740-11K
OUTLINE
Guide
Wiring cover
7
Installation of the inverter and enclosure design
1.4 Installation of the inverter and enclosure design
When an inverter enclosure is to be designed and manufactured, heat generated by contained equipment, etc., the
environment of an operating place, and others must be fully considered to determine the enclosure structure, size and
equipment layout. The inverter unit uses many semiconductor devices. To ensure higher reliability and long period of
operation, operate the inverter in the ambient environment that completely satisfies the equipment specifications.
1.4.1 Inverter installation environment
As the inverter installation environment should satisfy the standard specifications indicated in the following table, operation in
any place that does not meet these conditions not only deteriorates the performance and life of the inverter, but also causes a
failure. Refer to the following points and take adequate measures.
Environmental standard specifications of inverter
Item Description
Surrounding air
temperature
Ambient humidity 90%RH or less (non-condensing)
Atmosphere Free from corrosive and explosive gases, free from dust and dirt
Maximum altitude 1,000m or less
Vibration
-10 to +50
5.9m/s
(1) Temperature
The permissible surrounding air temperature of the inverter is between -10 and +50°C
structure feature). Always operate the inverter within this temperature range. Operation outside this range will considerably
shorten the service lives of the semiconductors, parts, capacitors and others. Take the following measures so that the
surrounding air temperature of the inverter falls within the specified range.
1) Measures against high temperature
Use a forced ventilation system or similar cooling system. (Refer to page 10)
Install the panel in an air-conditioned electrical chamber.
Block direct sunlight.
Provide a shield or similar plate to avoid direct exposure to the radiated heat and wind of a heat source.
Ventilate the area around the panel well.
°C (non-freezing) (-10 to +40°C
2
or less at 10 to 55Hz (directions of X, Y, Z axes)
for totally-enclosed structure feature)
(-10 to +40°C
for totally-enclosed
2) Measures against low temperature
Provide a space heater in the enclosure.
Do not power off the inverter. (Keep the start signal of the inverter off.)
3) Sudden temperature changes
Select an installation place where temperature does not change suddenly.
Avoid installing the inverter near the air outlet of an air conditioner.
If temperature changes are caused by opening/closing of a door, install the inverter away from the door.
(2) Humidity
Normally operate the inverter within the 45 to 90% range of the ambient humidity. Too high humidity will pose problems of
reduced insulation and metal corrosion. On the other hand, too low humidity may produce a spatial electrical breakdown. The
insulation distance specified in JEM1103 "Control Equipment Insulator" is defined as humidity 45 to 85%.
1) Measures against high humidity
Make the panel enclosed, and provide it with a hygroscopic agent.
Take dry air into the enclosure from outside.
Provide a space heater in the enclosure.
2) Measures against low humidity
What is important in fitting or inspection of the unit in this status is to discharge your body (static electricity)
beforehand and keep your body from contact with the parts and patterns, besides blowing air of proper humidity into
the panel from outside.
3) Measures against condensation
Condensation may occur if frequent operation stops change the in-panel temperature suddenly or if the outside-air
temperature changes suddenly.
Condensation causes such faults as reduced insulation and corrosion.
Take the measures against high humidity in 1).
Do not power OFF the inverter. (Keep the start signal of the inverter OFF.)
8
Installation of the inverter and enclosure design
(3) Dust, dirt, oil mist
Dust and dirt will cause such faults as poor contact of contact points, reduced insulation or reduced cooling effect due to
moisture absorption of accumulated dust and dirt, and in-panel temperature rise due to clogged filter. In the atmosphere
where conductive powder floats, dust and dirt will cause such faults as malfunction, deteriorated insulation and short circuit in
a short time.
Since oil mist will cause similar conditions, it is necessary to take adequate measures.
Countermeasures
Place in a totally enclosed enclosure.
Take measures if the in-enclosure temperature rises. (Refer to page 10)
Purge air.
Pump clean air from outside to make the in-panel pressure higher than the outside-air pressure.
(4) Corrosive gas, salt damage
If the inverter is exposed to corrosive gas or to salt near a beach, the printed board patterns and parts will corrode or the
relays and switches will result in poor contact.
In such places, take the measures given in Section 3.
(5) Explosive, flammable gases
As the inverter is non-explosion proof, it must be contained in an explosion proof enclosure. In places where explosion may be
caused by explosive gas, dust or dirt, an enclosure cannot be used unless it structurally complies with the guidelines and has
passed the specified tests. This makes the enclosure itself expensive (including the test charges). The best way is to avoid
installation in such places and install the inverter in a non-hazardous place.
(6) Highland
Use the inverter at the altitude of within 1000m. If it is used at a higher place, it is likely that thin air will reduce the cooling
effect and low air pressure will deteriorate dielectric strength.
(7) Vibration, impact
The vibration resistance of the inverter is up to 5.9m/s2 at 10 to 55Hz frequency and 1mm amplitude for the directions of X, Y,
Z axes. Vibration or impact, if less than the specified value, applied for a long time may make the mechanism loose or cause
poor contact to the connectors.
Especially when impact is imposed repeatedly, caution must be taken as the part pins are likely to break.
Countermeasures
Provide the panel with rubber vibration isolators.
Strengthen the structure to prevent the panel from resonance.
Install the panel away from sources of vibration.
1
OUTLINE
9
Installation of the inverter and enclosure design
1.4.2 Cooling system types for inverter panel
From the panel that contains the inverter, the heat of the inverter and other equipment (transformers, lamps, resistors, etc.)
and the incoming heat such as direct sunlight must be dissipated to keep the in-panel temperature lower than the permissible
temperatures of the in-panel equipment including the inverter.
The cooling systems are classified as follows in terms of the cooling calculation method.
1) Cooling by natural heat dissipation from the enclosure surface (totally enclosed type)
2) Cooling by heat sink (aluminum fin, etc.)
3) Cooling by ventilation (forced ventilation type, pipe ventilation type)
4) Cooling by heat exchanger or cooler (heat pipe, cooler, etc.)
Cooling System Panel Structure Comment
Natural
cooling
Forced
cooling
Natural ventilation
(enclosed, open type)
Natural ventilation
(totally enclosed type)
Fin cooling
Forced ventilation
Heat pipe Totally enclosed type for panel downsizing.
Heatsink
INV
INV
INV
INV
Heat pipe
INV
Low in cost and generally used, but the panel size increases
as the inverter capacity increases. For relatively small
capacities.
Being a totally enclosed type, the most appropriate for hostile
environment having dust, dirt, oil mist, etc. The panel size
increases depending on the inverter capacity.
Having restrictions on the heatsink mounting position and
area, and designed for relative small capacities.
For general indoor installation. Appropriate for panel
downsizing and cost reduction, and often used.
10
Installation of the inverter and enclosure design
1.4.3 Inverter placement
(1) Installation of the inverter
Enclosure surface mounting
Remove the front cover and wiring cover to fix the inverter to the surface.
FR-E720-0.1K(SC) to 0.75K(SC)
FR-E720S-0.1K(SC) to 0.4K(SC)
FR-E710W-0.1K to 0.4K
Front cover
Front cover
FR-E720-1.5K(SC) or more
FR-E740-0.4K(SC) or more
FR-E720S-0.75K(SC) or more
FR-E710W-0.75K
Wiring cover
Wiring cover
NOTE
When encasing multiple inverters, install them in parallel as a
cooling measure.
Install the inverter vertically.
Refer to the clearances below.
Vertical
(2) Clearances around inverter
To ensure ease of heat dissipation and maintenance, leave at least the shown clearances around the inverter. At least the
following clearances are required under the inverter as a wiring space, and above the inverter as a heat dissipation space.
Surrounding air temperature and humidity
Measurement
position
Inverter
5cm
Measurement
position
Temperature: -10 C to +50 C
-10 C to +40 C for totally
-enclosed structure feature
Humidity: 90% RH or less
Leave enough clearances and
take cooling measures.
5cm
5cm
Clearances (front)
10cm or more
1cm
or more*
* When using the inverters at the surrounding air
temperature of 40 C or less, the inverters can be
installed without any clearance between them (0cm
clearance).
When surrounding air temperature exceeds 40 C,
clearances between the inverters should be 1cm or
more (5cm or more for the 5.5K or more).
1cm
or more*
10cm or more
Clearances (side)
Inverter
1cm
or more
*
* 5cm or more for the
5.5K(SC) or more
1
OUTLINE
(3) Inverter mounting orientation
Mount the inverter on a wall as specified. Do not mount it horizontally or any other way.
11
Installation of the inverter and enclosure design
(4) Above inverter
Heat is blown up from inside the inverter by the small fan built in the unit. Any equipment placed above the inverter should be
heat resistant.
(5) Arrangement of multiple inverters
When multiple inverters are placed in the same
enclosure, generally arrange them horizontally as shown
in the right figure (a). When it is inevitable to arrange
them vertically to minimize space, take such measures as
to provide guides since heat from the bottom inverters
can increase the temperatures in the top inverters,
causing inverter failures.
When mounting multiple inverters, fully take caution not
to make the surrounding air temperature of the inverter
higher than the permissible value by providing ventilation
and increasing the panel size.
(6) Arrangement of ventilation fan and inverter
(a) Horizontal arrangement
InverterInverter
Enclosure Enclosure
Arrangement of multiple inverters
Inverter
Guide Guide
Inverter
Inverter
Inverter
(b) Vertical arrangement
Guide
Heat generated in the inverter is blown up from the bottom of
the unit as warm air by the cooling fan. When installing a
ventilation fan for that heat, determine the place of ventilation
fan installation after fully considering an air flow. (Air passes
through areas of low resistance. Make an airway and airflow
plates to expose the inverter to cool air.)
Inverter Inverter
<Good example> <Bad example>
Placement of ventilation fan and inverter
12
2 WIRING
This chapter describes the basic "WIRING" for use of this
product.
Always read the instructions before using the equipment.
2.1 Wiring............................................................................................. 14
2.2 Main circuit terminal specifications ............................................ 16
2.3 Control circuit specifications ...................................................... 22
2.4 Connection of stand-alone option unit....................................... 35
1
2
3
4
5
13
6
7
Wiring
2.1 Wiring
2.1.1 Terminal connection diagram
(1) Standard control circuit terminal model
Sink logic
Main circuit terminal
Control circuit terminal
Single-phase power input
MCCB MC
Single-phase
AC power
supply
MCCB MC
Three-phase
AC power
supply
Control input signals (No voltage input allowed)
Terminal functions vary
with the input terminal
assignment (Pr. 178 to
Pr. 184)
Forward
rotation start
Reverse
rotation start
High
speed
Multi-speed selection
*2 When using terminals PC-
SD as a 24VDC power
supply, take care not to
short across terminals
PC-SD.
Middle
speed
Low
speed
Output
stop
Reset
Contact input common
24VDC power supply
(Common for external power supply transistor)
Frequency setting signals (Analog)
*3 Terminal input specifications
can be changed by analog
input specifications
switchover (Pr. 73).
*4 It is recommended to use 2W1kΩ
when the frequency setting signal
is changed frequently.
Frequency
setting
potentiometer
1/2W1kΩ
*4
Terminal 4 input
(Current input)
*5 Terminal input specifications can be changed by analog
input specifications switchover (Pr. 267). Set the
voltage/current input switch in the "V" position to select
voltage input (0 to 5V/0 to10V) and "I" (initial value) to
select current input (4 to 20mA).
To use terminal 4 (initial setting is current input), set "4"
in any of Pr.178 to Pr.184 (input terminal function selection)
to assign the function, and turn ON AU signal.
R/L1
S/L2
Earth
(Ground)
3
2
1
(+)
(-)
*1. DC reactor (FR-HEL)
When connecting a DC reactor, remove the
jumper across P1 and P/+.
Not available for single-phase 100V power
input model.
Earth
(Ground)
Jumper
R/L1
S/L2
T/L3
*1
P1 P/+
*6
Inrush current
limit circuit
R
*8
PR
*7
Main circuit
Control circuit
STF
STR
RH
RM
RL
MRS
RES
SD
*2
PC
10(+5V)
2 0 to 5VDC
(0 to 10VDC)
5(Analog common)
4 4 to 20mADC
0 to 5VDC
0 to 10VDC
IV
Voltage/current
input switch
SINK
SOURCE
*3
*5
24V
connector
*5
connector
N/-
USB
Brake unit
(Option)
C
B
A
RUN
FU
SE
PU
*6 Terminal P1 is not available for single-
phase 100V power input model.
*7 A brake transistor is not built-in to the 0.1K
and 0.2K.
*8 Brake resistor (FR-ABR, MRS, MYS type)
Install a thermal relay to prevent an
overheat and burnout of the brake resistor.
(The brake resistor can not be connected
to the 0.1K and 0.2K.)
U
Motor
V
W
Earth (Ground)
Standard control terminal block
Relay output
Terminal functions vary
Relay output
(Fault output)
Running
Frequency detection
Open collector output common
Sink/source common
Calibration resistor
+
FM
*9
SD
by Pr. 192 A,B,C terminal
function selection
Open collector output
Terminal functions vary with
the output terminal assignment
(Pr. 190 and Pr. 191)
Indicator
(Frequency meter, etc.)
-
Moving-coil type
1mA full-scale
*9 It is not necessary when
calibrating the indicator
from the operation panel.
IM
14
Connector for
plug-in option connection
Option connector
NOTE
To prevent a malfunction caused by noise, separate the signal cables more than 10cm from the power cables. Also
separate the main circuit wire of the input side and the output side.
After wiring, wire offcuts must not be left in the inverter.
Wire offcuts can cause an alarm, failure or malfunction. Always keep the inverter clean. When drilling mounting holes
in an enclosure etc., take care not to allow chips and other foreign matter to enter the inverter.
The output of the single-phase power input model is three-phase 200V.
(2) Safety stop function model
Sink logic
Main circuit terminal
Control circuit terminal
Single-phase power input
MCCB MC
Single-phase
AC power
supply
MCCB MC
Three-phase
AC power
supply
R/L1
S/L2
*1. DC reactor (FR-HEL)
When connecting a DC reactor, remove the
jumper across P1 and P/+.
Earth
(Ground)
Jumper
R/L1
S/L2
T/L3
*1
P1 P/+
Inrush current
limit circuit
R
*7
PR
*6
N/-
Brake unit
(Option)
*6 A brake transistor is not built-in to the 0.1K
and 0.2K.
*7 Brake resistor (FR-ABR, MRS, MYS type)
Install a thermal relay to prevent an
overheat and burnout of the brake resistor.
(The brake resistor can not be connected
to the 0.1K and 0.2K.)
U
V
W
Wiring
Motor
IM
Earth
(Ground)
Control input signals (No voltage input allowed)
Terminal functions vary
with the input terminal
assignment (Pr. 178 to
Pr. 182 and Pr. 184)
Forward
rotation start
Reverse
rotation start
High
speed
Multi-speed selection
*2 When using terminals PC-
SD as a 24VDC power
supply, take care not to
short across terminals
PC-SD.
Middle
speed
Low
speed
Reset
Contact input common
(Common for external power supply transistor)
24VDC power supply
Safety stop input common terminal
Safety stop input (Channel 1)
Safety stop input (Channel 2)
Shorting wire
Frequency setting signals (Analog)
*3 Terminal input specifications
can be changed by analog
input specifications
switchover (Pr. 73).
*4 It is recommended to use 2W1kΩ
when the frequency setting signal
is changed frequently.
Frequency
setting
potentiometer
1/2W1kΩ
Terminal 4 input
(Current input)
*5 Terminal input specifications can be changed by analog
input specifications switchover (Pr. 267). Set the
voltage/current input switch in the "V" position to select
voltage input (0 to 5V/0 to10V) and "I" (initial value) to
select current input (4 to 20mA).
To use terminal 4 (initial setting is current input), set "4"
in any of Pr.178 to Pr.184 (input terminal function selection)
to assign the function, and turn ON AU signal.
3
2
*4
1
(+)
(-)
Main circuit
Control circuit
STF
STR
RH
RM
RL
RES
SD
*2
PC
S1
Output shutoff
S2
circuit
10(+5V)
2 0 to 5VDC
(0 to 10VDC)
5(Analog common)
4 4 to 20mADC
0 to 5VDC
0 to 10VDC
VI
Voltage/current
input switch
SINK
SOURCE
*3
*5
24V
Earth (Ground)
Safety stop function model
C
B
Relay output
(Fault output)
A
RUN
Running
FU
Frequency detection
SE
Open collector output common
Sink/source common
Calibration resistor
FM
*8
SD
PU
connector
*5
USB
connector
Relay output
Terminal functions vary
by Pr. 192 A,B,C terminal
function selection
Open collector output
Terminal functions vary with
the output terminal assignment
(Pr. 190 and Pr. 191)
Indicator
+
(Frequency meter, etc.)
-
Moving-coil type
1mA full-scale
*8 It is not necessary when
calibrating the indicator
from the operation panel.
2
WIRING
Connector for
plug-in option connection
Option connector
NOTE
To prevent a malfunction caused by noise, separate the signal cables more than 10cm from the power cables. Also
separate the main circuit wire of the input side and the output side.
After wiring, wire offcuts must not be left in the inverter.
Wire offcuts can cause an alarm, failure or malfunction. Always keep the inverter clean. When drilling mounting holes
in an enclosure etc., take care not to allow chips and other foreign matter to enter the inverter.
The output of the single-phase power input model is three-phase 200V.
15
Main circuit terminal specifications
r
2.2 Main circuit terminal specifications
2.2.1 Specification of main circuit terminal
Terminal
Symbol
R/L1,
S/L2,
T/L3 ∗1
U, V, W Inverter output Connect a three-phase squirrel-cage motor.
P/+, PR Brake resistor connection
P/+, N/- Brake unit connection
P/+, P1 ∗2 DC reactor connection
∗1 When using single-phase power input, terminals are R/L1 and S/L2.
∗2 Terminal P1 is not available for single-phase 100V power input model.
AC power input
Earth (Ground) For earthing (grounding) the inverter chassis. Must be earthed (grounded).
Terminal Name Description
Connect to the commercial power supply.
Keep these terminals open when using the high power factor converter (FR-HC) or
power regeneration common converter (FR-CV).
Connect a brake resistor (FR-ABR, MRS type, MYS type) across terminals P/+ and
PR.
(The brake resistor can not be connected to the 0.1K or 0.2K.)
Connect the brake unit (FR-BU2), power regeneration common converter (FR-CV)
or high power factor converter (FR-HC).
Remove the jumper across terminals P/+ and P1 and connect a DC reactor.
Single-phase 100V power input model is not compatible with DC reactor.
2.2.2 Terminal arrangement of the main circuit terminal, power supply and the motor wiring
Three-phase 200V class
FR-E720-0.1K(SC) to 0.75K(SC) FR-E720-1.5K(SC) to 3.7K(SC)
Screw size (M3.5)
N/-
Jumpe
N/-
P/+ PR
Jumper
P/+
R/L1 S/L2 T/L3
Screw size (M4)
R/L1 S/L2 T/L3
Screw size
FR-E720-5.5K(SC), 7.5K(SC) FR-E720-11K(SC), 15K(SC)
Screw size (M5)
R/L1 S/L2 T/L3
IM
(M3.5)
MotorPower supply
N/-
P/+
Screw size
(M5)
Screw size(11K:M5/15K:M6)
R/L1 S/L2 T/L3
PR
Jumper
PR
Power supply
N/-
IM
Power supply
Motor
Screw size
P/+
Screw size
(M5)
(M4)
PR
Jumper
IM
Motor
IM
MotorPower supply
16
Main circuit terminal specifications
r
r
Three-phase 400V class
FR-E740-0.4K(SC) to 3.7K(SC) FR-E740-5.5K(SC), 7.5K(SC)
N/-
P/+
R/L1 S/L2 T/L3
PR
FR-E740-11K(SC), 15K(SC)
N/-
P/+
Jumper
Power supply
Jumper
Screw size (M4)
Screw size
(M4)
MotorPower supply
Screw size (11K: M4/15K: M5)
R/L1 S/L2 T/L3
PR
Screw size
(11K: M4/15K: M5)
IM
Motor
IM
Jumper
N/-
P/+
Screw size (M4)
R/L1 S/L2 T/L3
PR
Single-phase 200V class
FR-E720S-0.1K(SC) to 0.4K(SC) FR-E720S-0.75K(SC) to 2.2K(SC)
Screw size (M3.5)
N/-
Jumpe
N/-
P/+ PR
Jumper
P/+
R/L1 S/L2
Screw size (M4)
IM
MotorPower supply
Screw size
(M4)
R/L1 S/L2
Screw size
(M3.5)
IM
MotorPower supply
Single-phase 100V class
FR-E710W-0.1K to 0.4K FR-E710W-0.75K
Screw size (M3.5)
N/-
R/L1 S/L2
Screw size
(M3.5)
P/+ PR
IM
MotorPower supply
Jumpe
NOTE
Make sure the power cables are connected to the R/L1, S/L2, T/L3. (Phase need not be matched.) Never connect the
power cable to the U, V, W of the inverter. Doing so will damage the inverter.
Connect the motor to U, V, W. Turning ON the forward rotation switch (signal) at this time rotates the motor
counterclockwise when viewed from the load shaft.
PR
N/-
PR
Power supply
Jumper
P/+
Screw size (M4)
R/L1 S/L2
Power supply
Screw size
(M4)
Screw size
(M4)
2
IM
Motor
WIRING
IM
Motor
17
Main circuit terminal specifications
2.2.3 Cables and wiring length
(1) Applicable cable size
Select the recommended cable size to ensure that a voltage drop will be 2% max.
If the wiring distance is long between the inverter and motor, a main circuit cable voltage drop will cause the motor torque to
decrease especially at the output of a low frequency.
The following table indicates a selection example for the wiring length of 20m.
Three-phase 200V class (when input power supply is 220V)
Crimping
Applicable Inverter
Model
FR-E720-0.1K(SC) to
0.75K(SC)
FR-E720-1.5K(SC),
2.2K(SC)
FR-E720-3.7K(SC) M4 1.5 5.5-4 5.5-4 3.5 3.5 3.5 12 12 4 4 4
FR-E720-5.5K(SC) M5 2.5 5.5-5 5.5-5 5.5 5.5 5.5 10 10 6 6 6
FR-E720-7.5K(SC) M5 2.5 14-5 8-5 14 8 5.5 6 8 16 10 6
FR-E720-11K(SC) M5 2.5 14-5 14-5 14 14 14 6 6 16 16 16
FR-E720-15K(SC) M6(M5) 4.4 22-6 22-6 22 22 14 4 4 25 25 16
Ter minal
Screw
Size ∗4
Tightening
Torque
·
m
N
M3.5 1.2 2-3.5 2-3.5 2 2 2 14 14 2.5 2.5 2.5
M4 1.5 2-4 2-4 2 2 2 14 14 2.5 2.5 2.5
Terminal
R/L1
S/L2
T/L3
U, V, W
HIV Cables, etc. (mm2) ∗1
R/L1
S/L2
T/L3
U, V, W
Earthing
cable
Cable Size
AWG ∗2
R/L1
S/L2
U, V, W
T/L3
PVC Cables, etc. (mm2) ∗3
R/L1
S/L2
T/L3
U, V, W
Earthing
cable
Three-phase 400V class (when input power supply is 440V)
Crimping
Applicable Inverter
Model
FR-E740-0.4K(SC) to
3.7K(SC)
FR-E740-5.5K(SC) M4 1.5 5.5-4 2-4 3.5 2 3.5 12 14 4 2.5 4
FR-E740-7.5K(SC) M4 1.5 5.5-4 5.5-4 3.5 3.5 3.5 12 12 4 4 4
FR-E740-11K(SC) M4 1.5 5.5-4 5.5-4 5.5 5.5 8 10 10 6 6 10
FR-E740-15K(SC) M5 2.5 8-5 8-5 8 8 8 8 8 10 10 10
Ter minal
Screw
Size ∗4
Tightening
Torque
·
m
N
M4 1.5 2-4 2-4 2 2 2 14 14 2.5 2.5 2.5
Terminal
R/L1
S/L2
T/L3
U, V, W
HIV Cables, etc. (mm2) ∗1
R/L1
S/L2
T/L3
U, V, W
Earthing
cable
Cable Size
AWG ∗2
R/L1
S/L2
U, V, W
T/L3
PVC Cables, etc. (mm2) ∗3
R/L1
S/L2
T/L3
U, V, W
Earthing
cable
Single-phase 200V class (when input power supply is 220V)
Applicable Inverter
Model
FR-E720S-0.1K(SC) to
0.4K(SC)
FR-E720S-0.75K(SC) M4 1.5 2-4 2-4 2 2 2 14 14 2.5 2.5 2.5
FR-E720S-1.5K(SC) M4 1.5 2-4 2-4 2 2 2 14 14 2.5 2.5 2.5
FR-E720S-2.2K(SC) M4 1.5 5.5-4 2-4 3.5 2 2 12 14 4 2.5 2.5
Ter minal
Screw
Size ∗4
Tightening
Torque
·
m
N
M3.5 1.2 2-3.5 2-3.5 2 2 2 14 14 2.5 2.5 2.5
Crimping
Terminal
R/L1
S/L2
U, V, W
HIV Cables, etc. (mm2) ∗1
R/L1
S/L2
U, V, W
Earthing
cable
Cable Size
AWG ∗2
R/L1
U, V, W
S/L2
PVC Cables, etc. (mm2) ∗3
R/L1
S/L2
U, V, W
Earthing
cable
Single-phase 100V class (when input power supply is 100V)
Applicable Inverter
Model
FR-E710W-0.1K to 0.4K M3.5 1.2 2-3.5 2-3.5 2 2 2 14 14 2.5 2.5 2.5
FR-E710W-0.75K M4 1.5 5.5-4 2-4 3.5 2 2 14 14 2.5 2.5 2.5
Ter minal
Screw
Size ∗4
Tightening
Torque
·
m
N
Crimping
Terminal
R/L1
S/L2
U, V, W
HIV Cables, etc. (mm2) ∗1
R/L1
S/L2
U, V, W
Earthing
cable
Cable Size
AWG ∗2
R/L1
U, V, W
S/L2
PVC Cables, etc. (mm2) ∗3
R/L1
S/L2
U, V, W
Earthing
cable
18
Main circuit terminal specifications
∗1
The cable size is that of the cable (HIV cable (600V class 2 vinyl-insulated cable) etc.) with continuous maximum permissible temperature of 75°C. Assumes
that the surrounding air temperature is 50°C or less and the wiring distance is 20m or less.
∗2
The recommended cable size is that of the cable (THHW cable) with continuous maximum permissible temperature of 75°C. Assumes that the surrounding air
temperature is 40°C or less and the wiring distance is 20m or less. (Selection example for use mainly in the United States.)
∗3
The recommended cable size is that of the cable (THHW cable) with continuous maximum permissible temperature of 70°C. Assumes that the surrounding air
temperature is 40°C or less and the wiring distance is 20m or less. (Selection example for use mainly in Europe.)
∗4
The terminal screw size indicates the terminal size for R/L1, S/L2, T/L3, U, V, W, and a screw for earthing (grounding).
A screw for earthing (grounding) of the FR-E720-15K(SC) is indicated in ( ).
For single-phase power input, the terminal screw size indicates the size of terminal screw for R/L1, S/L2, U, V, W, PR, P/+, N/-, P1 and a screw for earthing
(grounding).
NOTE
Tighten the terminal screw to the specified torque. A screw that has been tighten too loosely can cause a short circuit
or malfunction. A screw that has been tighten too tightly can cause a short circuit or malfunction due to the unit
breakage.
Use crimping terminals with insulation sleeve to wire the power supply and motor.
The line voltage drop can be calculated by the following formula:
Line voltage drop [V]=
Use a larger diameter cable when the wiring distance is long or when it is desired to decrease the voltage drop (torque
reduction) in the low speed range.
3 × wire resistance[mΩ/m] × wiring distance[m] × current[A]
1000
2
WIRING
19
Main circuit terminal specifications
(2) Earthing (Grounding) precautions
Always earth (ground) the motor and inverter.
1) Purpose of earthing (grounding)
Generally, an electrical apparatus has an earth (ground) terminal, which must be connected to the ground before use.
An electrical circuit is usually insulated by an insulating material and encased. However, it is impossible to manufacture
an insulating material that can shut off a leakage current completely, and actually, a slight current flow into the case.
The purpose of earthing (grounding) the case of an electrical apparatus is to prevent operator from getting an electric
shock from this leakage current when touching it.
To avoid the influence of external noises, this earthing (grounding) is important to audio equipment, sensors, computers
and other apparatuses that handle low-level signals or operate very fast.
2) Earthing (grounding) methods and earthing (grounding) work
As described previously, earthing (grounding) is roughly classified into an electrical shock prevention type and a noise-
affected malfunction prevention type. Therefore, these two types should be discriminated clearly, and the following
work must be done to prevent the leakage current having the inverter's high frequency components from entering the
malfunction prevention type earthing (grounding):
(a)If possible, use (l) independent earthing (grounding) in figure below for the inverter. If independent earthing
(grounding) is not available, use (ll) joint earthing (grounding) in the figure below which the inverter is connected with
the other equipment at an earthing (grounding) point. The (lll) common earthing (grounding) as in the figure below,
which inverter shares a common earthing cable with the other equipment, must be avoided.
A leakage current including many high frequency components flows in the earthing cables of the inverter and
inverter-driven motor. Therefore, use the independent earthing (grounding) and separated the earthing (grounding)
cable of the inverter from equipments sensitive to EMI.
In a high building, it may be effective to use the EMI prevention type earthing (grounding) connecting to an iron
structure frame, and electric shock prevention type earthing (grounding) with the independent earthing (grounding)
together.
(b)This inverter must be earthed (grounded). Earthing (Grounding) must conform to the requirements of national and
local safety regulations and electrical codes. (NEC section 250, IEC 536 class 1 and other applicable standards).
Use an neutral-point earthed (grounded) power supply for 400V class inverter in compliance with EN standard.
(c)Use the thickest possible earthing cable. The earthing cable should be of not less than the size indicated in the table
on the previous page 18.
(d)The grounding point should be as near as possible to the inverter, and the ground wire length should be as short as
possible.
(e)Run the earthing cable as far away as possible from the I/O wiring of equipment sensitive to noises and run them in
parallel in the minimum distance.
20
Inverter
(I)Independent earthing.......Best
Other
equipment
Inverter
(II)Common earthing.......Good
Other
equipment
Inverter
(III)Common earthing.......Not allowed
Other
equipment
POINT
To be compliant with the EU Directive (Low Voltage Directive), refer to the Instruction Manual (Basic).
Main circuit terminal specifications
(3) Total wiring length
The overall wiring length for connection of a single motor or multiple motors should be within the value in the table
below.
Pr. 72 PWM frequency selection
1 (1kHz) or less
(2kHz to 14.5kHz)
Setting
(carrier frequency)
100V class,
200V class
400V class - - 200m 200m 300m 500m 500m
2 to15
100V class,
200V class
400V class - - 30m 100m 200m 300m 500m
0.1K 0.2K 0.4K 0.75K 1.5K 2.2K
200m 200m 300m 500m 500m 500m 500m
30m 100m 200m 300m 500m 500m 500m
Total wiring length (3.7K(SC) or more)
500m or less
300m
300m
300m+300m=600m
or More
3.7K
When driving a 400V class motor by the inverter, surge voltages attributable to the wiring constants may occur at the
motor terminals, deteriorating the insulation of the motor.(Refer to page 96)
NOTE
Especially for long-distance wiring, the inverter may be affected by a charging current caused by the stray
capacitances of the wiring, leading to a malfunction of the overcurrent protective function, fast response current limit
function, or stall prevention function or a malfunction or fault of the equipment connected on the inverter output side.
If malfunction of fast-response current limit function occurs, disable this function. If malfunction of stall prevention
function occurs, increase the stall level. (Refer to page 92 for Pr. 22 Stall prevention operation level and Pr. 156 Stall prevention
operation selection )
Refer topage 174 for details of Pr. 72 PWM frequency selection. Refer to the manual of the option for details of surge voltage
suppression filter (FR-ASF-H/FR-BMF-H).
When using the automatic restart after instantaneous power failure function with wiring length exceeding 100m,
select without frequency search (Pr. 162 = "1, 11"). ( Refer to page 162)
2
WIRING
21
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