Mitsubishi Electric FR-F520L-90K Instruction manual

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Mitsubishi Electric FR-F520L-90K Instruction manual | Manualzz
MITSUBISHI ELECTRIC
FR-F500
Frequency Inverter
Instruction Manual
FR-F540L-75K ~ 530K
(-NA, -CH, -CHG1,-EC, -E1)
Art. no.: 141713
10 07 2003
Version K
IB-07405-10 (200307)
MITSUBISHI ELECTRIC
INDUSTRIAL AUTOMATION
Thank you for choosing this Mitsubishi transistorized Inverter.
This instruction manual gives handling information and precautions for use of this
equipment.
Incorrect handling might cause an unexpected fault. Before using the inverter, please read
this manual carefully to use the equipment to its optimum.
Please forward this manual to the end user.
This section is specifically about safety matters
Do not attempt to install, operate, maintain or inspect the inverter until you have read through this instruction
manual and appended documents carefully and can use the equipment correctly.
Do not use the inverter 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
Assumes that incorrect handling may cause hazardous conditions, resulting in
death or severe injury.
CAUTION
Assumes that incorrect handling may cause hazardous conditions, resulting in
medium or slight injury, or may cause physical damage only.
Note that the CAUTION level may lead to a serious consequence according to conditions. Please follow the
instructions of both levels because they are important to personnel safety.
A-1
SAFETY INSTRUCTIONS
1. Electric Shock Prevention
WARNING
zWhile power is on or when the inverter is running, do not open the front cover. You may get an electric
shock.
zDo not run the inverter with the front cover removed. Otherwise, you may access the exposed highvoltage terminals or the charging part of the circuitry and get an electric shock.
zIf power is off, do not remove the front cover except for wiring or periodic inspection. You may access the
charged inverter circuits and get an electric shock.
zBefore starting wiring or inspection, switch power off, wait for more at least 10 minutes and check for the
presence of any residual voltage with a meter (check chapter 2 for further details.) etc.
zEarth the inverter.
zAny person who is involved in the wiring or inspection of this equipment should be fully competent to do
the work.
zAlways install the inverter before wiring. Otherwise, you may get an electric shock or be injured.
zOperate the switches with dry hands to prevent an electric shock.
zDo not subject the cables to scratches, excessive stress, heavy loads or pinching. Otherwise, you may
get an electric shock.
zDo not change the cooling fan while power is on. To do so will invite a hazardous condition.
2. Fire Prevention
CAUTION
zMount the inverter on an incombustible surface. Installing the inverter directly on or near a combustible
surface could lead to a fire.
zIf the inverter has become faulty, switch off the inverter power. A continuous flow of large current could
cause a fire.
zDo not connect a resistor directly to the DC terminals P, N. This could cause a fire.
3. Injury Prevention
CAUTION
zApply only the voltage specified in the instruction manual to each terminal to prevent damage etc.
zEnsure that the cables are connected to the correct terminals. Otherwise, damage etc. may occur.
zAlways make sure that polarity is correct to prevent damage etc.
zAfter the inverter has been operating for a relatively long period of time, do not touch the inverter as it
may be hot and you may get burnt.
A-2
4. Additional instructions
Also note the following points to prevent an accidental failure, injury, electric shock, etc.:
(1) Transportation and installation
CAUTION
z When carrying products, use correct lifting gear to prevent injury.
zDo not stack the inverter boxes higher than the number recommended.
zEnsure that installation position and material can withstand the weight of the inverter. Install according
to the information in the Instruction Manual.
zDo not operate if the inverter is damaged or has parts missing.
zDo not hold the inverter by the front cover; it may fall off.
zDo not stand or rest heavy objects on the inverter.
zCheck the inverter mounting orientation is correct.
zPrevent screws, wire fragments, conductive bodies, oil or other flammable substances from entering
the inverter.
zDo not drop the inverter, or subject it to impact.
zUse the inverter under the following environmental conditions:
-10°C to +50°C (non-freezing)
90%RH or less (non-condensing)
-20°C to +65°C*
Indoors (free from corrosive gas, flammable gas, oil mist, dust and dirt)
Maximum 1000m above sea level for standard operation.
Altitude, vibration
After that derate by 3% for every extra 500m up to 2500m (91%).
*Temperatures applicable for a short time, e.g. in transit.
Environment
Ambient temperature
Ambient humidity
Storage temperature
Ambience
(2) Wiring
CAUTION
zDo not fit capacitive equipment such as a power factor correction capacitor, radio noise filter or surge
suppressor to the output of the inverter.
zThe connection orientation of the output cables U, V, W to the motor will affect the direction of rotation
of the motor.
(3) Trial run
CAUTION
zCheck all parameters, and ensure that the machine will not be damaged by a sudden start-up.
(4) Operation
CAUTION
zWhen you have chosen the retry function, stay away from the equipment as it will restart suddenly after
an alarm stop.
zThe [STOP] key is valid only when the appropriate function setting has been made. Prepare an
emergency stop switch separately.
zMake sure that the start signal is off before resetting the inverter alarm. A failure to do so may restart
the motor suddenly.
A-3
CAUTION
• The load used should be a three-phase induction motor only. Connection of any other electrical
equipment to the inverter output may damage the equipment.
• Do not modify the equipment.
• The electronic overcurrent protection does not guarantee protection of the motor from overheating.
• Do not use a magnetic contactor on the inverter input for frequent starting/stopping of the inverter.
•Use a noise filter to reduce the effect of electromagnetic interference. Otherwise nearby electronic
equipment may be affected.
• Take measures to suppress harmonics. Otherwise power harmonics from the inverter may heat/damage
the power capacitor and generator.
• When a 400V class motor is inverter-driven, it should be insulation-enhanced or surge voltages
suppressed. Surge voltages attributable to the wiring constants may occur at the motor terminals,
deteriorating the insulation of the motor.
• When parameter clear or all clear is performed, each parameter returns to the factory setting. Re-set the
required parameters before starting operation.
• The inverter can be easily set for high-speed operation. Before changing its setting, examine the
performance of the motor and machine.
• In addition to the inverter's holding function, install a holding device to ensure safety.
• Before running an inverter which had been stored for a long period, always perform inspection and test
operation.
(5) Emergency stop
CAUTION
• Provide a safety backup such as an emergency brake which will prevent the machine and equipment
from hazardous conditions if the inverter fails.
(6) Maintenance, inspection and parts replacement
CAUTION
• Do not carry out a megger (insulation resistance) test on the control circuit of the inverter.
(7) Disposing of the inverter
CAUTION
• Treat as industrial waste.
(8) General instructions
Many of the diagrams and drawings in this instruction manual show the inverter without a cover, or partially
open. Never run the inverter like this. Always replace the cover and follow this instruction manual when
operating the inverter.
A-4
CONTENTS
1 OUTLINE
1
1.1 Pre-Operation Information ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 1
1.1.1
Precautions for operation ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 1
1.2 Basic Configuration ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 2
1.2.1
Basic configuration・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 2
1.3 Structure ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 3
1.3.1
Appearance and structure・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 3
1.3.2
Removal and reinstallation of the front cover・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 4
1.3.3
Removal and reinstallation of the operation panel ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 5
2 INSTALLATION AND WIRING
6
2.1 Installation・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 6
2.1.1
Instructions for installation ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 6
2.2 Wiring ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 8
2.2.1
Terminal connection diagram ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 8
2.2.2
Wiring of the main circuit・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 11
2.2.3
Wiring of the control circuit ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 16
2.2.4
Connection to the PU connector ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 20
2.2.5
Connection of stand-alone option units・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 22
2.2.6
Design information ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 25
2.3 Other wiring・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 26
2.3.1
Inverter-driven 400V class motor ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 26
2.3.2
Peripheral devices ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 27
2.3.3
Instructions for compliance with the UL standards ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 28
2.3.4
Instructions for compliance with the European standards ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 29
2.3.5
Earthing ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 30
2.3.6
Power harmonics ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 31
2.3.7
Japanese harmonic suppression guidelines ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 32
2.3.8
Inverter-generated noises and reduction techniques ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 34
2.3.9
Leakage currents and countermeasures ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 36
2.3.10
Inverter-driven 400V class motor ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 37
3 OPERATION
38
3.1 Pre-Operation Information ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 38
3.1.1
Devices and parts to be prepared for operation ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 38
3.1.2
Power on ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 40
3.2 Operation Panel ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 41
3.2.1
Names and functions of the operation panel (FR-DU04) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 41
3.2.2
Monitor display changed by pressing the [MODE] key ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 42
3.2.3
Monitoring mode ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 42
3.2.4
Frequency setting mode ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 42
3.2.5
Parameter setting mode ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 43
3.2.6
Operation mode ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 43
3.2.7
Help mode ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 44
3.2.8
Copy mode ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 46
3.3 Parameter Checking and Setting ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 47
I
3.3.1
Parameter checking ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 47
3.3.2
Main parameter settings ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 49
3.4 Operation ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 51
3.4.1
Pre-operation checks ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 51
3.4.2
External operation mode (Operation using external input signals) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 52
3.4.3
PU operation mode
3.4.4
Combined operation mode
(Operation using the operation panel (FR-DU04)) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 53
(Operation using the external input signals and PU) ・・・・・・・・・・・・・・・・・・・・・ 54
4 PARAMETERS
55
4.1 Parameter List ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 55
4.1.1
Parameter list ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 55
4.1.2
List of Parameters Classified by Purposes of Use ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 60
4.2 Parameter Function Details ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 61
4.2.1
Torque boost (Pr. 0, Pr. 46) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 61
4.2.2
Output frequency range (Pr. 1, Pr. 2) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 62
4.2.3
Base frequency, base frequency voltage (Pr. 3, Pr. 19, Pr. 47) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 63
4.2.4
Multi-speed operation (Pr. 4 to Pr. 6, Pr. 24 to Pr.27)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 64
4.2.5
Acceleration/deceleration time
4.2.6
Electronic overcurrent protection (Pr. 9) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 66
(Pr. 7, Pr. 8, Pr. 20, Pr. 21, Pr. 44, Pr. 45) ・・・・・・・・・・・・・・・・・・・・・・・・・ 65
4.2.7
DC dynamic brake (Pr. 10 to Pr. 12) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 67
4.2.8
Starting frequency (Pr. 13) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 68
4.2.9
Load pattern selection (Pr. 14) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 69
4.2.10 Jog operation (Pr. 15, Pr. 16) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 70
4.2.11 MRS input selection (Pr. 17) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 71
4.2.12 Stall prevention (Pr. 22, Pr. 23, Pr. 66, Pr. 148, Pr. 149, Pr. 154) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 72
4.2.13 Multi-speed input compensation (Pr. 28)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 73
4.2.14 Acceleration/deceleration pattern (Pr. 29, Pr.140 to Pr.143) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 74
4.2.15 Regenerative brake duty (Pr.30, Pr.70) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 75
4.2.16 Frequency jump (Pr. 31 to Pr. 36) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 76
4.2.17 Speed display (Pr. 37, Pr. 144) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 77
4.2.18 Automatic torque boost (Pr. 38, Pr. 39) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 78
4.2.19 Up-to-frequency sensitivity (Pr. 41) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 78
4.2.20 Output frequency detection (Pr. 42, Pr. 43, Pr. 50) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 79
4.2.21 Second stall prevention (Pr. 48, Pr. 49)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 80
4.2.22 Monitor display / FM, AM terminal function selection
(Pr. 52 to Pr. 54, Pr. 158) ・・・・・・・・・・・・・・・・・・・・・ 81
4.2.23 Monitoring reference (Pr. 55, Pr. 56) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 83
4.2.24 Automatic restart after instantaneous power failure
(Pr. 57, Pr. 58, Pr. 162 to Pr. 165) ・・・・・・・・・・・・・・・ 84
4.2.25 Remote setting function selection (Pr. 59) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 86
4.2.26 Intelligent mode selection (Pr. 60) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 88
4.2.27 Acceleration/deceleration reference current/lift mode starting
frequency (Pr. 61 to Pr. 63) ・・・・・・・・・・・・ 89
4.2.28 Retry function (Pr. 65, Pr. 67 to Pr. 69) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 90
4.2.29 Applied motor (Pr. 71) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 92
4.2.30 PWM carrier frequency (Pr. 72, Pr. 240) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 93
4.2.31 Voltage input (Pr. 73) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 94
4.2.32 Input filter time constant (Pr. 74)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 95
4.2.33 Reset selection/PU disconnection detection/PU stop selection
(Pr. 75) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 95
4.2.34 Alarm code output selection (Pr. 76) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 97
4.2.35 Parameter write inhibit selection (Pr. 77)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 98
II
4.2.36 Reverse rotation prevention selection (Pr. 78) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 99
4.2.37 Operation mode selection (Pr. 79) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 100
4.2.38 V/F control frequency (voltage) (Pr. 100 to Pr. 109) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 103
4.2.39 Computer link operation (Pr. 117 to Pr. 124) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 104
4.2.40 PID control (Pr. 128 to Pr. 134)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 115
4.2.41 Commercial power supply-inverter switch-over function
(Pr. 135 to Pr. 139) ・・・・・・・・・・・・・・・・・・・・・・・ 122
4.2.42 Zero current detection (Pr. 152, Pr. 153)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 128
4.2.43 RT signal activated condition selection (Pr. 155) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 129
4.2.44 Stall prevention function and current limit function (Pr. 156) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 129
4.2.45 OL signal output timer (Pr. 157) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 131
4.2.46 User group selection (Pr. 160, Pr. 173 to Pr. 176)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 132
4.2.47 Watt-hour meter clear/actual operation hour meter clear
(Pr. 170, Pr. 171)・・・・・・・・・・・・・・・・・・・・・・・・ 133
4.2.48 Input terminal function selection (Pr. 180 to Pr. 186) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 133
4.2.49 Output terminal function selection (Pr. 190 to Pr. 195) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 135
4.2.50 User initial value setting (Pr. 199)・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 137
4.2.51 Cooling fan operation selection (Pr. 244) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 138
4.2.52 Output phase failure protection selection (Pr. 251) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 138
4.2.53 Override bias/gain (Pr. 252, Pr. 253) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 138
4.2.54 Meter (frequency meter) calibration (Pr. 900, Pr. 901) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 140
4.2.55 Frequency setting voltage (current) bias and gain
(Pr. 902 to Pr. 905) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 142
4.2.56 Buzzer control (Pr. 990) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 144
5 PROTECTIVE FUNCTIONS
155
5.1 Errors (alarms) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 155
5.1.1
Error (alarm) definitions ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 155
5.1.2
To know the operating status at the occurrence of an alarm・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 164
5.1.3
Correspondences between digital and actual characters ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 164
5.1.4
Alarm code output ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 165
5.1.5
Resetting the inverter・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 165
5.2 Troubleshooting ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 166
5.2.1
Motor remains stopped.・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 166
5.2.2
Motor rotates in opposite direction. ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 166
5.2.3
Speed greatly differs from the setting. ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 166
5.2.4
Acceleration/deceleration is not smooth. ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 166
5.2.5
Motor current is large. ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 167
5.2.6
Speed does not increase. ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 167
5.2.7
Speed varies during operation. ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 167
5.2.8
Operation mode is not changed properly.・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 167
5.2.9
Operation panel (FR-DU04) display is not provided. ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 167
5.2.10
POWER lamp is not lit. ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 167
5.2.11
Parameter write cannot be performed・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 167
5.3 Precautions for Maintenance and Inspection ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 168
5.3.1
Precautions for maintenance and inspection ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 168
5.3.2
Check items・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 168
5.3.3
Periodic inspection ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 168
5.3.4
Insulation resistance test using megger ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 169
5.3.5
Pressure test ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 169
5.3.6
Daily and Periodic Inspection ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 169
III
5.3.7
Replacement of parts・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 172
5.3.8
Inverter replacement ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 173
5.3.9
Measurement of main circuit voltages, currents and power・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 174
6 SPECIFICATIONS
176
6.1 Standard Specifications ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 176
6.1.1
Model specifications・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 176
6.1.2
Common specifications ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 177
6.1.3
Outline drawings ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 179
7 OPTIONS
181
7.1 Option List・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 181
7.1.1
Stand-alone options ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 181
7.1.2
Inboard dedicated options・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 182
APPENDICES
183
Appendix 1 Data Code List ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 183
Appendix 2 Inverter Heat Loss ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 188
IV
CHAPTER 1
OUTLINE
This chapter gives information on the basic "outline" of this
product.
Always read the instructions in this chapter before using the
equipment.
1.1 Pre-Operation Information ・・・・・・・・・・・・・・・・・・・・・・ 1
1.2 Basic Configuration ・・・・・・・・・・・・・・・・・・・・・・・・・・・ 2
1.3 Structure・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 3
<Abbreviations>
DU
Operation panel (FR-DU04)
yPU
Operation panel (FR-DU04) and parameter unit (FR-PU04)
yInverter
Mitsubishi transistorized inverter FR-F500 series
yPr.
Parameter number
yPU operation
Operation using the PU (FR-DU04/FR-PU04)
yExternal operation
Operation using the control circuit signals
yCombined operation
Operation using both the PU (FR-DU04/FR-PU04)
and external operation
y
Chapter 1
Chapter 2
Chapter 3
Chapter 4
Chapter 5
Chapter 6
Chapter 7
1.1 Pre-Operation Information
OUTLINE
1.1.1
Precautions for operation
Incorrect handling might cause the inverter to operate improperly, its life to be reduced considerably, or at the
worst, the inverter to be damaged. Handle the inverter properly in accordance with the information in each
section as well as the precautions and instructions of this manual to use it correctly.
This manual is written for the FR-F500L series transistorized inverters.
For handling information on the parameter unit (FR-PU04), inboard options, stand-alone options, etc., refer to
the corresponding manuals.
(1) Unpacking and product check
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.
1) Inverter type
47
FR - F520L - 75K
Symbol
Voltage Class
F540L
400V Class
F520L
200V Class
-
Symbol
Applicable Motor Capacity
Symbol
75K to 375K
Indicates capacity in "kW"
(Null)
Japanese specifications
CH
Chinese specifications
Specifications
2) Accessory
Instruction manual,DC reactor (DCL)
If you have found any discrepancy, damage, etc., please contact your sales representative.
(2) Preparations of instruments and parts required for operation
Instruments and parts to be prepared depend on how the inverter is operated. Prepare equipment and parts
as necessary. (Refer to page 38.)
(3) Installation
To operate the inverter with high performance for a long time, install the inverter in a proper place, in the
correct direction, and with proper clearances. (Refer to page 6.)
(4) Wiring
Connect the power supply, motor and operation signals (control signals) to the terminal block. Note that
incorrect connection may damage the inverter and peripheral devices. (See page 8.)
1
1.2 Basic Configuration
OUTLINE
1.2.1 Basic configuration
The following devices are required to operate the inverter. Proper peripheral devices must be selected and correct
connections made to ensure proper operation. Incorrect system configuration and connections can cause the
inverter to operate improperly, its life to be reduced considerably, and in the worst case, the inverter to be
damaged.
Please handle the inverter properly in accordance with the information in each section as well as the precautions
and instructions of this manual. (For connections of the peripheral devices, refer to the corresponding manuals.)
Name
Power supply
(NFB)
or
(ELB)
(MC)
Earth leakage
circuit breaker
(ELB) or no-fuse
breaker (NFB)
The breaker should be selected with care
since a large inrush current flows in the
inverter at power on. (Refer to page 26.)
Magnetic
contactor
The magnetic contactor need not be
provided. When installed, do not use it to
start or stop the inverter. It might reduce the
inverter life.
(Refer to page 26.)
Reactors
AC reactor
(MT-BAL)
Description
Use the power supply within the
permissible power supply specifications of
the inverter.
DC reactor
Inverter
The reactors must be used when the
power factor is to be improved or the
inverter is installed near a large power
supply system (1000KVA or more and
wiring distance within 10m). Make selection
carefully.
• The inverter life is influenced by ambient
temperature. The ambient 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 6.)
• Incorrect wiring might lead to inverter
damage. The control signal lines should
be kept away from the main circuit to
protect them from noise.
(Refer to page 8.)
Ground
Devices
connected to the
output
Do not connect a power capacitor, surge
suppressor or radio noise filter to the output
side.
Ground
To prevent an electric shock, always
ground the motor and inverter.
Ground
2
1
1.3 Structure
OUTLINE
1.3.1
Appearance and structure
(1) Front view
(2) Without front cover
POWER lamp
ALARM lamp
PU connector
(Provided with Modular jack type relay connector)
(For use of RS-485 cable)
Operation panel
Display window
Modular jack type relay connector compartment
Inboard option mounting position
Accessory cover
Control circuit terminal block
Rating plate
Grounding terminal
Front cover
Main circuit terminal cover
Wiring port cover for option
3
OUTLINE
1.3.2
Removal and reinstallation of the front cover
・Removal
1) Remove the installation screw for the main circuit terminal
cover.
2) Remove the front cover mounting screws.
2
1
1
・Reinstallation
1) Fix the front cover with the mounting screws.
2) Fix the main circuit terminal cover with the installation screw.
1
2
Note: 1.Confirm that the front cover and main circuit terminal cover have been securely installed.
4
OUTLINE
1.3.3
Removal and reinstallation of the operation panel
To ensure safety, remove and reinstall the operation panel after switching power off.
•Removal
Hold down the top button of the operation panel and pull the operation panel toward you to remove
‚ Removal
‚ Reinstallation
To reinstall, insert straight and mount securely.
•Reinstallation using the connection cable
1) Remove the operation panel.
2) Disconnect the modular jack type relay connector. (Place the disconnected modular jack type relay
connector in the modular jack type relay connector compartment.)
Modular jack type relay connector
Modular jack type relay connector compartment
3) Securely plug one end of the connection cable into the PU connector (modular jack type relay
connector) of the inverter and the other end into the operation panel.
(For the connection cable, refer to 20 page.)
Note: Install the operation panel only when the front cover is on the inverter.
5
CHAPTER 2
INSTALLATION AND WIRING
This chapter gives information on the basic "installation and
wiring" of this product.
Always read the instructions in this chapter before using the
equipment.
2.1 Installation ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 6
2.2 Wiring ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 8
2.3 Other wiring ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 26
Chapter 1
Chapter 2
Chapter 3
Chapter 4
Chapter 5
Chapter 6
Chapter 7
2.1 Installation
INSTALLATION AND WIRING
2.1.1
Instructions for installation
1) Handle the unit carefully.
The inverter uses plastic parts. Handle it gently to protect it from damage. Also, hold the unit with even
strength and do not apply too much pressure to the front cover alone.
2) Install the inverter where it is not subjected to vibration.
Note the vibration of a cart, press, etc.
3) Note on ambient temperature
The inverter life is under great influence of ambient temperature. In the place of installation, ambient
temperature must be within the permissible range (-10ºC to +50ºC (14ºF to 122ºF) ). Check that the
ambient temperature is within that range in the positions shown in figure 3).
4) Install the inverter on a non-combustible surface.
The inverter will be very hot (maximum. about 150ºC (302ºF) ). Install it on a non-combustible surface (e.g.
metal). Also leave sufficient clearances around the inverter.
5) Avoid high temperature and high humidity.
Avoid places where the inverter is subjected to direct sunlight, high temperature and high humidity.
6) The amount of heat generated in an enclosure can be reduced considerably by placing the heat sink
outside the enclosure.
Note: The cooling section outside the enclosure has the cooling fan. Do not use the inverter in any
environment where it is exposed to waterdrops, oil mist, dust, etc.
7) Avoid places where the inverter is exposed to oil mist, flammable gases, fluff, dust, dirt, etc.
Install the inverter in a clean place or inside a "totally enclosed" panel which does not accept any suspended
matter.
8) Note the cooling method when the inverter is installed in an enclosure.
When an inverter is mounted in an enclosure, the ventilation fans of the inverter and enclosure must be
carefully positioned to keep the ambient temperature of the inverter below the permissible value. If they are
installed in improper positions, the rise in ambient temperature will result in reduced performance of the
inverter.
9) Secure the inverter vertically, with bolts.
Install the inverter on an installation surface securely and vertically with screws or bolts.
6
INSTALLATION AND WIRING
5cm
(1.97inches)
5cm
(1.97inches)
5cm
(1.97inches)
20cm
(7.87inches)
or more
15cm(5.91inches)
or more
Measurement
position
4) Clearances around the inverter
10cm(3.94inches)
or more
3) Note on ambient temperature
Leave sufficient
clearances above
and under the
inverter to ensure
adeguate
ventilation.
Cooling air
Measurement
position
Cooling fan
built in the
inverter
20cm
(7.87inches)
or more
8) For installation in an enclosure
9) Vertical mounting
Ventilation fan
Inveter
Inveter
(Correct example) (Incorrect example)
2
Position of Ventilation Fan
7
2.2 Wiring
INSTALLATION AND WIRING
2.2.1
Terminal connection diagram
NFB
Inverter
FR-F500L
MC
Motor
R
S
T
3-phase AC power supply
Jumper
U
V
W
PU
connector
(RS-485)
IM
(Note 8)
Ground
R1
S1
P1
P1
(Note 3)
(Note 1)
24VDC power output and extemal transistor common
(Contact input common for source logic)
DCL (Standard)
PC
P
Forward rotation start
STF
Reverse rotation start
STR
Start self-holding
selection
RH
Low
RL
(Note 8)
E
Ground
N
STOP
High
Multi-speed
selection
Middle
(Max. 15 speeds)
P
Brake resistor
(option)
CN8
Brake unit
(option)
A
RM
B
C
Error output
(contact output)
JOG
Jog mode
Second acceleration/
deceleration time selection
RT
Output stop
RUN
Running
MRS
SU
Up to frequency
RES
Reset
IPF
Current input selection
AU
OL
Selection of automatic restart
after instantaneous power
failure
CS
FU
SD( Contact input )
common
SE
Control input signals(no voltage input allowed)
(Note 1)
(Note 4)
Frequency detection
collector output common
( Open
Common
to sink and source )
calibration resistor
1/2W10k
10E(+10V)
3
10(+5V)
2
(Note 2)
1
(Note 6)
DC0 5V
Selected)
2( DC0 10V
+
FM
type
( Moving-coil
1mA
full-scale )
5(Analog common)
AM
(Note 6)
Current input
Meter
(e.q.frequency meter)
SD
(+)
Common
Auxiliary input
Open collector
outputs
Overload
(Note 7)
(Note 1)
Frequency setting
potentiometer
1/2W1k
Instantaneous power failure
+- 5V
DC0 10( DC0 +- 10V Selected)
4(DC4 20mA)
5
(-)
Analog signal output
(DC0 10V)
(Note 8)
Ground
Frequency setting signals (analog)
Main circuit terminal
Control circuit input terminal
Control circuit output terminal
Notes
(1) This connection diagram shows the example for the sink logic (factoryset) control circuit. When using the source logic, refer to page 15 for the
connections.
(5) The input signal can be changed over with Pr.73.
(2) Use of the 2W1k is recommended when the frequency setting is
changed frequently.
(7) Always ground the inverter unit, DCL and motor.
(6) This is not required when the scale is calibrated with the operation
panel.
(3) Always connect the enclosed DCL.
(4) The output terminal can output the error alarm code, and 26 types of
functions can be independently assigned with Pr. 190 to 195.
8
INSTALLATION AND WIRING
2.2.1
Terminal connection diagram of (-12P)
2
8-A
INSTALLATION AND WIRING
2.2.1
Terminal connection diagram
8-B
INSTALLATION AND WIRING
(1) Description of main circuit terminals
Type
Symbol
R, S, T
<L1, L2, L3>
U, V, W
R1, S1
<L11, L21>
Main
circuit
P, N
<+,->
P, P1
<+, P1>
P0, P1
Terminal Name
AC power input
Inverter output
Power supply for
control circuit
Brake unit
connection
Connect the optional MT-BU5 brake unit.
Optional converter
connection
Connect the optional high power factor converter (MT-HC) or power regenerative
converter (MT-RC).
Power factor
Improving DC
reactor connection
Power factor
Improving DC
reactor connection
Ground
Note:<
Description
Connect to the commercial power supply. Keep these terminals unconnected when
using the high power factor converter (MT-HC).
Connect a three-phase squirrel-cage motor.
Connected to the AC power supply terminals R and S. To retain the alarm display
and alarm output or when using the high power factor converter (MT-HC), remove
the jumpers from terminals R-R1 and S-S1 and apply external power to these
terminals.
Connect DC Reactor. (75K to 375K)
Connect DC Reactor. (450K, 530K)
For grounding the inverter chassis. Must be earthed.
>Terminal names in parentheses are those of the EC, EI version.
(2) Description of control circuit terminals
Type
Symbol
Terminal Name
STF
Forward rotation start
STR
Reverse rotation start
Turn on the STR signal to start reverse rotation and turn it off to
stop.
Start self-holding
selection
Turn on the STOP signal to select the self-holding of the start signal.
STOP
RH,RM,RL Multi-speed selection
Input signals
Contacts, e.g. start, function setting
Description
Turn on the STF signal to start forward rotation and turn it off to
stop. Acts as a programmed operation start signal in the
programmed operation mode. (Turn on to start and turn off to
stop.)
JOG
JOG mode selection
RT
Second acceleration/
deceleration time
selection
MRS
Output stop
RES
Reset
AU
CS
SD
PC
Current input
selection
Automatic restart
after instantaneous
power failure
selection
Contact input
common (sink)
24VDC power and
external transistor
common Contact
input common
(source)
When the STF
and STR signals
are turned on
simultaneously,
the stop
command is
given.
Use the RH, RM and RL signals as appropriate to select multiple
speeds.
Input terminal
Turn on the JOG signal to select jog operation (factory setting).
function selection
Jog operation can be performed with the start signal (STF or
(Pr. 180 to
STR).
Pr. 186) change
Turn on the RT signal to select the second acceleration/
terminal
deceleration time. When the second functions such as "second
functions.
torque boost" and "second V/F (base frequency)" functions have
been set, these functions can also be selected by turning on the
RT signal.
Turn on the MRS signal (20ms or longer) to stop the inverter output.
Used to shut off the inverter output to bring the motor to a stop by the magnetic brake.
Used to reset the protective circuit activated. Turn on the RES signal for more than 0.1
sec, then turn it off.
Input terminal
Only when the AU signal is turned on, the inverter can be
function selection
operated with the 4-20mADC frequency setting signal.
(Pr. 180 to
With the CS signal on, restart can be made automatically when
Pr. 186) change
the power is restored after an instantaneous power failure. Note
terminal
that this operation requires restart parameters to be set. When
the inverter is shipped from the factory, it is set to disallow restart. functions.
Common terminal for the terminal FM.
Common output terminal for 24VDC 0.1A power (PC terminal).
When transistor output (open collector output), such as a programmable controller, is
connected, connect the external power supply common for transistor output to this
terminal to prevent a fault caused by leakage current. This terminal can be used as a
24VDC, 0.1A power output. When source logic has been selected, this terminal
serves as a contact input common.
9
2
INSTALLATION AND WIRING
Type
Symbol
Terminal Name
10E
Analog frequency setting
Frequency setting
(voltage)
4
Frequency setting
(current)
1
Auxiliary frequency
setting
5
Frequency setting
input common
A,B,C
Alarm output
Inverter running
SU
Up to frequency
OL
Overload alarm
IPF
Instantaneous power
failure
FU
Frequency detection
SE
Open collector output
common
Pulse
RUN
For meter
Analog
Open collector
2
FM
AM
Analog signal output
RS485
Communication
Output signals
Contact
Input signals
10
Frequency setting
power supply
――
PU connector
Description
10VDC, permissible load current
10mA
When the frequency setting potentiometer is
connected in the factory-set state, connect it to
terminal 10.
5VDC, permissible load current
When it is connected to terminal 10E, change
10mA
the input specifications of terminal 2.
By entering 0 to 5VDC (0 to 10VDC), the maximum output frequency is reached at
5V (or 10V) and I/O are proportional. Switch between input 0 to 5VDC (factory
setting) and 0 to 10VDC from operation terminal. Input resistance 10kΩ. Maximum
permissible voltage 20V.
By entering 4 to 20mADC, the maximum output frequency is reached at 20mA and
I/O are proportional. This input signal is valid only when the AU signal is on. Input
resistance 250Ω. Maximum permissible current 30mA.
By entering 0 to ±5VDC 0 to ±10VDC, this signal is added to the frequency setting
signal of terminal 2 or 4. Switch between input 0 to ±5VDC and 0 to ±10VDC (factory
setting) from operation terminal. Input resistance 10kΩ. Maximum permissible
voltage ±20V.
Common to the frequency setting signal (terminal 2, 1 or 4) and analog output
terminal AM. Do not earth.
Change-over contact output indicating that the output has been
stopped by the inverter protective function activated.
200VAC 0.3A, 30VDC 0.3A. Alarm: discontinuity across B-C
(continuity across A-C), normal: continuity across B-C
(discontinuity across A-C).
Switched low when the inverter output frequency is equal to or
higher than the starting frequency (factory set to 0.5Hz,
variable).
Switched high during stop or DC dynamic brake operation(note 1)
Output terminal
Permissible load 24VDC 0.1A.
function selection
Switched low when the output frequency has reached within
(Pr. 190 to Pr.
±10% of the set frequency (factory setting, variable). Switched
195) change
high during acceleration, deceleration or stop(note 1). Permissible
terminal
load 24VDC 0.1A.
functions.
Switched low when the stall prevention function has caused
stall prevention to be activated. Switched high when stall
prevention is reset(note 1). Permissible load 24VDC 0.1A.
Switched low when instantaneous power failure or undervoltage
protection is activated(note 1). Permissible load 24VDC 0.1A.
Switched low when the output frequency has reached or
exceeded the detection frequency set as appropriate. Switched
high when below the detection frequency(note 1). Permissible
load 24VDC 0.1A
Common to the RUN, SU, OL, IPF and FU terminals.
One selected from 16 monitoring
items, such as output frequency,
is output(note 2).
The output signal is proportional
to the magnitude of each
monitoring item.
Factory setting of output item:
Frequency
Permissible load current 1mA
1440 pulses/second. at 60Hz
Factory setting of output item:
Frequency
Output signal 0 to 10VDC
Permissible load current 1mA
With the operation panel connector, communication can be made through RS-485.
・Conforming Standard : EIA Standard RS-485
: Multi-drop link
・Transmission format
・Communication speed : Maximum 19200 baud rates
: 500m
・Overall length
Note1: Low indicates that the open collector outputting transistor is on (conducts). High indicates that the
transistor is off (does not conduct).
Note2: Not output while the inverter is reset.
10
INSTALLATION AND WIRING
2.2.2
Wiring of the main circuit
(1) Wiring instructions
1) Power must not be applied to the output terminals (U, V, W) of the inverter. Otherwise the inverter will be
damaged.
2) After wiring, wire off-cuts must not be left in the inverter.
Wire off-cuts can cause an alarm, failure or malfunction. Always keep the inverter clean.
When drilling mounting holes in a control box etc., exercise care to prevent chips and other foreign matter
from entering the inverter.
3) Use cables of the recommended size for wiring to make the voltage drop 2% or less.
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 selection example at the wiring
length of 20m is given on 15 page.)
4) Use thick cables to make a voltage drop of 2% or less.
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.
5) Electromagnetic wave interference
The input/output (main circuit) of the inverter includes harmonic components, which may interfere with the
communication devices (such as AM radios) used near the inverter. In this case, install the FR-BIF optional
radio noise filter (for use in the input side only) or FR-BLF line noise filter to minimize interference.
6) Do not install a power capacitor, surge suppressor or radio noise filter (FR-BIF option) in the output side of
the inverter.This will cause the inverter to trip or the capacitor and surge suppressor to be damaged. If any
of the above devices are installed, immediately remove them. (Connect the FR-BIF optional radio noise
filter in the primary side of the electromagnetic contactor.)
7) When rewiring after operation, make sure that the POWER lamp has gone off, and when more than 10
minutes have elapsed after power-off, check with a tester that the voltage is zero. After that, start rewiring
work. For some time after power-off, there is a dangerous voltage in the capacitor.
CAUTION
Do not use residual current protective device as the only protection against indirect
contact.
Protective earth connection is essential.
Do not connect more than 2 wires on the protective earth terminal.
Use contactor and no fuse breaker EN/IEC standard compliant.
Use transformer or surge absorber EN/IEC standard compliant.
Notes on Grounding
• Leakage currents flow in the inverter. To prevent an electric shock, the inverter and motor must be
grounded (200V class... class C grounding, grounding resistance 100Ω or less, 400V class... class D
grounding, grounding resistance 10Ω or less.).
• Use the dedicated ground terminal to ground the inverter. (Do not use the screw in the case, chassis, etc.)
2
• The ground cable should be 38 mm or more thick, and as short as possible. The grounding should be as
close to the inverter as possible.
11
2
INSTALLATION AND WIRING
(2) Terminal block layout
In the main circuit of the inverter, the terminals are arranged as shown below:
12
INSTALLATION AND WIRING
2
13
INSTALLATION AND WIRING
(2) Terminal block layout (-12P)
FR-F540L-75K-EC-12P
FR-F540L-90K-EC-12P
FR-F540L-110K-EC-12P
FR-F540L-132K-EC-12P / 160K-EC-12P
13-A
INSTALLATION AND WIRING
FR-F540L-185K/-220K-EC-12P
FR-F540L-280K-EC-12P
2
FR-F540L-375K-EC-12P
13-B
INSTALLATION AND WIRING
(2) Terminal block layout of G-series
FR-F540L-75K-(NA,EC,E1,CHG1)
FR-F540L-90K / 110K-(NA,EC,E1,CHG1)
FR-F540L-132K / 160K-(NA,EC,E1,CHG1)
13-C
INSTALLATION AND WIRING
FR-F540L-450K, 530K
2
13-D
INSTALLATION AND WIRING
(3) Cables, crimping terminals, etc.
The following table lists the cables and crimping terminals used with the inputs (R, S, T) <L1, L2, L3> and
outputs (U, V, W) of the inverter and the torques for tightening the screws:
Cables
Applicable
Inverter Type
FR-F540L-75K
FR-F540L-90K
FR-F540L-110K
FR-F540L-132K
FR-F540L-160K
FR-F540L-185K
FR-F540L-220K
FR-F540L-280K
FR-F540L-375K
FR-F520L-75K
FR-F520L-90K
FR-F520L-110K
Load
Characteristic
Terminal
Tightening
Screw
Torque
Kgf・
・ cm
Size
mm2
R, S, T
AWG
U,V,W
<L1, L2, L3>
P,P1 <+,P1 >
R, S, T
<L1, L2, L3>
U,V,W
P,P1 <+,P1 >
Variable torque
M8/M10
270(26.48)
60
60
60
1/0
1/0
1/0
Light Variable torque
M8/M10
270(26.48)
60
60
60
1/0
1/0
1/0
Variable torque
M10
270(26.48)
60
60
80
1/0
1/0
3/0
Light Variable torque
M10
270(26.48)
60
60
80
1/0
1/0
3/0
Variable torque
M10
270(26.48)
80
80
100
3/0
3/0
4/0
Light Variable torque
M10
270(26.48)
100
100
100
4/0
4/0
4/0
Variable torque
M10
270(26.48)
100
100
100
4/0
4/0
4/0
Light Variable torque
M10
270(26.48)
125
150
2×100
MCM250
MCM300
2×4/0
Variable torque
M10
270(26.48)
125
150
2×100
MCM250
MCM300
2×4/0
Light Variable torque
M10
270(26.48)
150
150
2×100
MCM300
MCM300
2×4/0
Variable torque
M12
470(46.09)
150
150
2×100
MCM300
MCM300
2×4/0
Light Variable torque
M12
470(46.09)
2×100
2×100
2×100
2×4/0
2×4/0
2×4/0
Variable torque
M12
470(46.09)
2×100
2×100
2×100
2×4/0
2×4/0
2×4/0
Light Variable torque
M12
470(46.09)
2×100
2×100
2×125
2×4/0
2×4/0
2×MCM250
Variable torque
M12
470(46.09)
2×125
2×125
2×150
2×MCM250
2×MCM250
2×MCM300
Light Variable torque
M12
470(46.09)
2×150
2×150
2×200
2×MCM300
2×MCM300
2×MCM400
Variable torque
M12
470(46.09)
2×150
2×150
2×200
2×MCM300
2×MCM300
2×MCM400
Light Variable torque
M12
470(46.09)
2×200
2×200
2×200
2×MCM400
2×MCM400
2×MCM400



M12
470(46.09)
125
125
150
2×1/0
MCM350
2×2/0
M12
470(46.09)
150
150
2×100
2×2/0
2×3/0
2×4/0
M12
470(46.09)
2×100
2×100
2×100
2×3/0
2×4/0
2×MCM250
Note: 1. The cables used should be 75°C copper cables.
2. Tighten the terminal screws to the specified torques.
Undertightening can cause a short or misoperation.
Overtightening can cause the screws and unit to be damaged, resulting in a short or
misoperation.
(4) Connection of the power supply and motor
Power
supply
Ground
terminal
No-fuse
breaker
R
S
T
〈L1〉 〈L2〉 〈L3〉
U
R
S
T
〈L1〉 〈L2〉 〈L3〉
V
U
W
V
W
Motor
Ground
Connect the motor to U, V, W.
In the above connection,
turning on the forward rotation
switch (signal) rotates the motor
in the counterclockwise (arrow)
direction when viewed from
the load shaft.
The power supply cables
must be connected to R, S, T
〈L1, L2, L3〉.
If they are connected to U, V,
W, the inverter will be damaged.
Phase sequence need not be
matched.
For use with a single-phase
power supply,the power supply
cables must be connected to
R and S 〈L1 and L2〉.
14
Ground
INSTALLATION AND WIRING
(5) Connecting the control circuit to a power supply separately from the main circuit
If the magnetic contactor (MC) in the inverter power supply is opened when the protective circuit is operated,
the inverter control circuit power is lost and the alarm output signal cannot be kept on. To keep the alarm
signal on, connect the power supply terminals R1 and S1 <L11 and L21> of the control circuit to the primary side
of the MC.
<Connection procedure>
R1 S1
<L11> <L21>
Power supply terminal
block for control circuit
Power supply terminal
block for control circuit
R S T
<L1> <L2><L3>
MC
1) Loosen the upper screws.
2) Remove the lower screws.
3) Pull out and remove the jumper.
4) Connect the separate power supply
cables for control circuit to
upper terminals R1, S1<L11, L21>. (Note 4)
Main power supply
Note: 1. When the main circuit power (R, S, T) <L1 L2, L3> is on, do not switch off the control power
(terminals R1, S1 <L11, L21>). Otherwise the inverter may be damaged.
2. When using a separate power supply, the jumpers across R-R1 and S-S1 <L1-L11 and L2-L21>
must be removed. Otherwise the inverter may be damaged.
3. For a different power supply system, which takes the power of the control circuit from other than
the primary side of the MC, the voltage should be equal to the main circuit voltage.
4. The power supply cables must not be connected to the lower terminals. If connected, the inverter
may be damaged.
15
2
INSTALLATION AND WIRING
2.2.3
Wiring of the control circuit
(1) Wiring instructions
1) Terminals SD, SE and 5 are common to the I/O signals and isolated from each other. These common
terminals must not be connected to each other or earthed.
2) Use shielded or twisted cables for connection to the control circuit terminals and run them away from the
main and power circuits (including the 200V relay sequence circuit).
3) The frequency-input signals to the control circuit are micro currents. When contacts are required, use two or
more parallel micro signal contacts or a twin contact to prevent a contact fault.
2
4) It is recommended to use the cables of 0.75mm gauge for connection to the control circuit terminals.
2
If the cable gauge used is 1.25mm or more, the front cover may be lifted when there are many cables
running or the cables are run improperly, resulting in an operation panel or parameter unit contact fault.
(2) Terminal block layout
• NA / CH / (Null) version
In the control circuit of the inverter, the terminals are arranged as shown below:
Terminal screw size: M3.5
B
A
C
RM
RL
PC
RH
SE RUN SU
AM 10E
RT
IPF
10
2
5
AU STOP MRS RES SD
OL
FU
SD
2
5
4
4
1
FM
STF STR JOG CS
•EC version
Terminal screw size: M3
A
B
C
SD
SE RUN SU
AM 10E
LPF
OL
10
FU STOP MRS RES PC
1
RL
RM
RH
RT
STF STR JOG CS
AU
FM
SD
<Wiring procedure>
1) For the wiring of the control circuit, strip the sheaths of the cables and use them as they are.Strip the sheath
to the following dimension. If too much is stripped this may cause a short circuit with the neighboring cable.
If too little stripped this may cause cable disconnection.
6mm ± 1mm
2) Loosen the terminal screw and insert the cable into the terminal.
3) Tighten the screw to the specified torque.Undertigthening can cause cable disconnection or malfunction.
Overtightening can cause a short circuit or malfunction due to the screw or unit damaged.
Tightening torque : 5 to 6 kgf・cm
Note : Wire the stripped cable by twisting it to prevent it from becoming loose. (Do not plate the cable with
solder.)
Note : 1. Use a NFB (No fuse breakers) or fuse on the inverter input (primary) side.
2. Make sure that the control circuit terminal wiring does not touch power circuit terminals (or screws)
or conducting power circuit.
16
INSTALLATION AND WIRING
(3) Changing the control logic
The input signals are set to sink logic for the Japanese version, and to source logic for the EC version.
To change the control logic, the connector on the back of the control circuit terminal block must be moved to
the other position.
(The output signals may be used in either the sink or source logic independently of the connector position.)
1) Loosen the two mounting screws in both ends of the control circuit terminal block. (The screws cannot be
removed.)
With both hands, pull down the terminal block from the back of the control circuit terminals.
2) Remove the connector from the rear surface of the control circuit terminal block and place in required Logic
position (either Sink or Source).
EC version
NA/CH/(Null) version
2
CON
3
2
CON
K
SINK
SOUR
CE
SOUR
CE
SIN
SINK
E
SOUR
C
CON
3
CON
CON2
CON3
CON1
3) Using care not to bend the pins of the control circuit connector, reinstall the control circuit terminal block and
fix it with the mounting screws.
Note: 1. Make sure that the control circuit connector is fitted correctly.
2. While power is on, never disconnect the control circuit terminal block.
3. The sink-source logic change-over connector must be fitted in only one of those positions. If it is
fitted in both positions at the same time, the inverter may be damaged.
17
2
INSTALLATION AND WIRING
4) Sink logic type
• In this logic, a signal switches on when a current flows out of the corresponding signal input terminal.
Terminal SD is common to the contact input signals. Terminal SE is common to the open collector output
signals.
AX40
1
RUN
R
R
Current
R
STF
R
2
SU
STR
R
R
SD
8
9
SE
DC24V
• When using an external power supply for transistor output, use terminal PC as a common to prevent
misoperation caused by leakage current. (Do not connect terminal SD of the inverter with terminal 0V of
the external power supply.)
Inverter
AY40 type
transistor output
module
1
STF
2
STR
3
RH
4
RM
5
RL
6
RES
9
PC
10
DC SD
24V
18
DC24V
(SD)
INSTALLATION AND WIRING
5) Source logic type
• In this logic, a signal switches on when a current flows into the corresponding signal input terminal.
Terminal PC is common to the contact input signals. Terminal SE is common to the open collector output
signals.
PC
SE
AX80
Current
STF
STR
RUN
1
R
R
R
SU
R
2
R
R
DC24V
8
9
• When using an external power supply for transistor output, use terminal SD as a common to prevent
misoperation caused by leakage current.
Inverter
9
PC
1
STF
2
STR
10
DC24V
AY-80
DC24V
(SD)
SD
(4) How to use terminals "STOP", "CS" and "PC"
1) Using the "STOP" terminal
A connection example (for sink logic) for self-holding the start signal (forward
rotation, reverse rotation) is shown on the right.
2) Using the "CS" terminal
This terminal is used to perform automatic restart after instantaneous power
failure and commercial power supply-inverter switch-over operation.
<Example: Automatic restart after instantaneous power failure in sink
logic>
Connect terminals CS-SD and set a value other than "9999" in Pr. 57 "coasting
time for automatic restart after instantaneous power failure".
STOP
Stop
RES
SD
Forward
rotation
Reverse
rotation
STF
STR
CS
SD
(Short)
3) Using the "PC" terminal
This terminal can be used as 24VDC-power output using SD as a common terminal.
Specifications: 18V to 26VDC, 0.1A permissible currents
Note that the wiring length should be within 30m.
Do not short terminals PC-SD.
When terminal PC is used as a 24V power supply, leakage current from transistor output cannot be
prevented.
19
MRS
2
INSTALLATION AND WIRING
2.2.4
Connection to the PU connector
(1) When connecting the operation panel or parameter unit using a connection cable
<Recommended cable connector>
• Parameter unit connection cable (FR-CB2) (option) or the following connector and cable.
• Connector: RJ45 connector
Example: 5-554720-3, Nippon AMP
• Cable: Cable conforming to EIA568 (e.g. 10BASE-T cable)
Example: SGLPEV 0.5mm×4P, MITSUBISHI CABLE INDUSTRIES, LTD.
Note: The maximum wiring length is 20m.
(2) For RS-485 communication
With the operation panel disconnected, the PU connector can be used for communication operation from a
personal computer etc.
When the PU connector is connected with a personal, FA or other computer by a communication cable, a user
program allows the inverter to be run and monitored and the parameter values to be read and written.
<PU connector pin-outs>
Viewed from the inverter (receptacle side) front
8)
1) SG
2) P5S
3) RDA
4) SDB
1)
5) SDA
6) RDB
7) SG
8) P5S
Note: 1. Do not connect the PU connector to the computer's LAN board, FAX modem socket or telephone
modular connector. Otherwise, the product may be damaged due to electrical specification
differences.
2. Pins 2) and 8) (P5S) provide power to the operation unit or parameter unit. Do not use these pins
for RS-485 communication.
<System configuration example>
1) When a computer having a RS-485 interface is used with several inverters
Computer
RS-485
interface/terminal
Station 1
Inverter
PU connector
(Note 1)
10BASE-T
cable
(Note 2)
Station 2
Inverter
PU connector
(Note 1)
Station n
Inverter
PU connector
(Note 1)
Terminal resistor
Distribution terminal
Use the connector and cables, which are available on the market.
Note: 1. Connector: RJ45 connector
Example: 5-554720-3, Nippon AMP Co., Ltd.
2. Cable: Cable conforming to EIA568 (such as 10BASE-T cable)
Example: SGLPEV 0.5mm×4P, Mitsubishi Cable Industries, Ltd.
20
INSTALLATION AND WIRING
2) When a computer having an RS-232C interface is used with inverters
Computer
RS-232C connector
RS-232C cable
Max. 15m
*Converter
Station 1
Inverter
PU connector
(Note 1)
Station 2
Inverter
PU connector
(Note 1)
Station n
Inverter
PU connector
(Note 1)
RS-485 terminal
Terminal resistor
Distribution terminal
10BASE-T cable (Note 2)
*Converter available on the market is required. (Note 3)
Use the connector, cables and converter, which are available on the market.
Note: 1. Connector: RJ45 connector
Example: 5-554720-3, Nippon AMP Co., Ltd.
2. Cable: Cable conforming to EIA568 (such as 10BASE-T cable)
Example: SGLPEV 0.5mm×4P, Mitsubishi Cable Industries, Ltd.
3. *Commercially available converter examples:
Model: FA-T-RS40
Converter
Industrial System Division Mitsubishi Electric Engineering Co., Ltd.
<Wiring method>
1) Wiring of one RS-485 computer and one inverter
2
Inverter
Computer Side Terminals
Signal
Description
name
RDA
Receive data
RDB
Receive data
SDA
Send data
SDB
Send data
RSA
Request to send
RSB
Request to send
CSA
Able to send
CSB
Able to send
SG
Signal ground
FG
Frame ground
Cable connection and signal direction
10BASE-T Cable
PU
connector
SDA
SDB
RDA
RDB
Note 2
0.3mm2 or more
SG
2) Wiring of one RS-485 computer and "n" inverters (several inverters)
Cable connection and signal direction
10 BASE-T Cable
SG
Station 1
Inverter
SG
Station 2
Inverter
Terminal
resistor
jumper
(Note 1)
RDB
RDA
SDB
SDA
Note
2
RDB
RDA
SDB
SDA
Terminal
resistor
(Note 1)
RDB
RDA
SDB
SDA
Computer
RDA
RDB
SDA
SDB
RSA
RSB
CSA
CSB
SG
FG
SG
Station 3
Inverter
Note: 1. There may be the influence of reflection depending on the transmission speed and/or
transmission distance. If this reflection hinders communication, provide a terminal
resistor. If the PU connector is used to make a connection, use a distributor as a
terminal resistor cannot be fitted. Connect the terminal resistor only to the inverter
remotest from the computer. (Terminal resistor: 100 Ω)
2. Make connections in accordance with the instruction manual of the computer used.
Fully check the terminal numbers of the computer as they differ between models.
21
INSTALLATION AND WIRING
2.2.5
Connection of stand-alone option units
The inverter accepts a variety of stand-alone option units as required.
Incorrect connection will cause inverter damage. Connect and operate the option unit carefully in accordance
with the corresponding option unit manual.
(1) Connection of the FR-BU brake unit (option)
Connect the optional FR-BU brake unit as shown below to improve the braking capability during deceleration.
T (Note 4)
ON
MC
U
Motor
S 〈L2〉
V
IM
T 〈L3〉
W
R 〈L1〉
OFF
MC
MC
PR
PR
Inverter
〈+〉 P
P/+
〈–〉 N
N/-
P
HA
HB
TH1
HC
THS TH2
Brake unit
FR-BU-(H)
Resistor unit
FR-BR-(H)
Note: 1. Connect the inverter terminals (P, N) <+, −> and FR-BU brake unit terminals so that their terminal
signals match with each other. (Incorrect connection will damage the inverter.)
2. The wiring distance between the inverter, brake unit and resistor unit should be within 5m. If
twisted wires are used, the distance should be within 10m.
3. If the transistors in the brake unit should fail, the resistor may become extremely hot. CAUTION!
DO NOT TOUCH. Therefore, install a magnetic contactor on the inverter's power supply side to
shut off a current in case of failure.
4. For the power supply of 400V class, install a voltage-reducing transformer.
(2) Connection of the conventional BU brake unit (option)
Connect the BU brake unit correctly as shown below. Incorrect connection will damage the inverter.
R<L1>
U
Motor
S<L2>
V
IM
T<L3>
W
<+> P
<-> N
P
PR
P
Inverter
FR-F500L
Break unit
MT-BU5
22
TH2
PR
CN8
P
PR
TH1
P
TH1
TH2
PR
Resistor Unit
MT-BR5
A contact:normal OFF
INSTALLATION AND WIRING
Note: 1. The wiring distance between the inverter, brake unit and discharge resistor should be used with in
the cables which are attached on this unit (because of cable length). Resistor Unit must be
installed in Air flow area. If twisted wires are used, the distance should be within 5m.
2. If the transistors in the brake unit should fail, the resistor may become extremely hot. CAUTION!
DO NOT TOUCH. Therefore, install a magnetic contactor on the inverter's power supply side to
shut off a current in case of failure. Make a sequence circuit with TH1-TH2 (Dry a contact).
3. The wiring distance between brake unit and resistor should be within 10m with twisted wires. If
not twisted wires, within 5m.
4. The attached cable on this unit should be used for the wiring between brake unit and Inverter.
Power cable are connected with P/N terminals. Control cable should be connected to LL
connector (CN8) through rubber shield. Cut the rubber shield properly.
5. P, PR terminals are prepared for the number of resistor units being used.
(3) Connection of the MT-HC high power factor converter (option)
When connecting the high power factor converter (MT-HC) to suppress power harmonics, wire as shown
below. Wrong connection will damage the high power factor converter and inverter.
After making sure that the wiring is correct, set "2" in Pr. 30 "regenerative function selection".
Inverter must be used "-HC" type Inverter.
MT-HCL01
MT-HCB
MT-HCL02
FR-F500L-
MT-HC
R
R
R2
R2
R3
R3 R4
R4
P
P
Power
S
S
S2
S2
S3
S3 S4
S4
N
N
supply
T
T
T2
T2
T3
T3 T4
T4
R1
2
88R
88R
RDY
MRS
88S
88S
RS0
RES
SE
S1
K-HC
SD
R
R
S
S
T
T
R1 S1
R1 S1
Insulated
Insulated
Transformer
Transformer
Note: 1. Remove the jumpers across terminals R-R1 and S-S1 <L1-L11 and L2-L21> of the inverter and
connect the control circuit power supply to terminals R1-S1 <L11-L21>. The power input terminals
R, S, T < L1, L2, L3 > must be kept open.
Accidental connection to these terminals will damage the inverter. Opposite polarity of terminals N,
P <-, +> will also damage the inverter.
2. Always match the voltage phases of terminals R, S, T < L1, L2, L3 > and terminals R4, S4, T4
before making connection.
3. When connecting the MT-HC, use sink logic (factory setting). For source logic, the MT-HC cannot
be connected.
23
INSTALLATION AND WIRING
(4) Connection of the MT-RC power return converter (option)
(For power coordination, always install the power factor-improving reactor (MT-RCL).)
When connecting the MT-RC power return converter, connect the inverter terminals (P, N <+, ->) and MT-RC
power return converter terminals as shown below so that their signals match with each other. After making
sure that the wiring is correct, set "1" in Pr. 30 "regenerative function selection" and "10" in Pr.70 "regenerative
power (%)".
FR-F500L
MC
NFB
Power
supply
R
U
S
T
R1
V
W
IM
S1
DCL
P1
P1
E
P
N
P
N
P
MT-RCL
R
R2
S
S2
T
T2
Reset Signal
R2
RES
STF
SD
S2
A
T2
B
C
Error Output (Contact Signal)
R
S
RDY
T
Ready Signal
R1
SE
S1
MT-RC
Note: How to connect the MT-BAL power factor improving AC reactor (option)
Refer to MT-RC manual.
24
INSTALLATION AND WIRING
2.2.6
Design information
1) For commercial power supply-inverter switch-over operation, provide electrical and mechanical interlocks
for MC1 and MC2 designed for commercial power supply-inverter switch-over.
When there is a commercial power supply-inverter switch-over circuit as shown below, the inverter will be
damaged by leakage current from the power supply due to arcs generated at the time of switch-over or
chattering caused by a sequence error.
2) If the machine must not be restarted when power is restored after a power failure, provide a magnetic
contactor in the inverter's primary circuit and also make up a sequence, which will not switch on the start
signal.
If the start signal (start switch) remains on after a power failure, the inverter will automatically restart as
soon as the power is restored.
3) When the power supply used with the control circuit is different from the one used with the main circuit,
make up a circuit which will switch off the main circuit power supply terminals R, S, T <L1, L2, L3> when the
power supply terminals R1, S1 <L11, L21> for the control circuit are switched off.
4) Since the input signals to the control circuit are on a low level, use two parallel micro signal contacts or a
twin contact for contact inputs to prevent a contact fault.
5) Do not apply a large voltage to the contact input terminals (e.g. STF) of the control circuit.
6) Do not apply a voltage directly to the alarm output signal terminals (A, B, C).
Always apply a voltage to these terminals via a relay coil, lamp, etc.
2
7) Make sure that the specifications and rating match the system requirements.
1) Commercial power supply-inverter switch-over
4) Low-level signal contacts
MC1
Interlock
Power
supply
R (L1)
U
S (L2)
V
T (L3)
W
IM
MC2
Leakage current
Low-level signal contacts
Inverter
25
Twin contact
2.3 Other wiring
INSTALLATION AND WIRING
2.3.1
Inverter-driven 400V class motor
In the PWM type inverter, a surge voltage attributable to wiring constants is generated at the motor terminals.
Especially for a 400V class motor, the surge voltage may deteriorate the insulation. When the 400V class
motor is driven by the inverter, consider the following measures:
• Measures
It is recommended to take either of the following measures:
(1) Rectifying the motor insulation
For the 400V class motor, use an insulation-rectified motor. Specifically,
1) Specify the “400V class inverter-driven, insulation-rectified motor”.
2) For the dedicated motor such as the constant-torque motor and low-vibration motor, use the
“inverter-driven, dedicated motor”.
(2) Suppressing the surge voltage on the inverter side
On the secondary side of the inverter, connect the optional sine wave filter (MT-BSL/BSC).
26
INSTALLATION AND WIRING
2.3.2
Peripheral devices
(1) Selection of peripheral devices
Check the capacity of the motor to be used with the inverter you purchased. Appropriate peripheral devices
must be selected according to the capacity.
Refer to the following list and prepare appropriate peripheral devices:
For F520L, 200V class, For F540L, 400V class DRIVE
Inverter
Voltage
Inverter Type
FR-F520L-75K
Load
Characteristic
Motor
Output
(kW)
Power
Supply
Capacit
y (kVA)
(Note 2)
DC reactor
(accessory)
No-Fuse Breaker or Earth
Leakage Circuit Breaker
(Note 3)
Magnetic
Contactor
(Note 4)
Cooling fan
(Remarks)
(Note 5)

75
110
T96MH422A
Type NF400, NV400 400A
(NF400, NV400 400A)
S-N300
(S-N300)
EF-30BSB
1φ100/110V
T96MH422A
Type NF400, NV400 400A
(NF600, NV600 500A)
S-N300
(S-N400)
20m3/min,
50/60Hz
200V
class
FR-F520L-90K

90
132
(220V)
4mmAq
Inlet hole size
FR-F520L-110K
FR-F540L-75K
FR-F540L-90K

110
165
T77MH527A
75
110
T397MH176A
90
137
T318MH219A
variable torque
110
165
light variable torque
132
198
132
198
variable torque
light variable torque
variable torque
light variable torque
T265MH263A
FR-F540L-110K
variable torque
FR-F540L-132K
T220MH317A
light variable torque
160
230
variable torque
150
219
light variable torque
185
274
variable torque
160
230
light variable torque
185
274
variable torque
185
274
light variable torque
200
300
variable torque
185
274
light variable torque
220
329
220
329
FR-F540L-160K
T199MH368A
FR-F540L-160K
400V
class
(440V)
FR-F540L-185K
T159MH439A
FR-F540L-185K
variable torque
FR-F540L-220K
T132MH527A
light variable torque
250
364
variable torque
280
417
light variable torque
315
465
variable torque
375
550
FR-F540L-280K
T105MH667A
FR-F540L-375K
T79MH880A
light variable torque
400
572
Type NF600, NV600 500A
(NF600, NV600 600A)
S-N400
(S-N600)
Type NF225, NV225 225A
(NF225, NV225 225A)
Type NF225, NV225 225A
(NF400, NV400 300A)
Type NF225, NV225 225A
(NF400, NV400 350A)
Type NF400, NV400 400A
(NF400, NV400 400A)
Type NF400, NV400 400A
(NF400, NV400 400A)
Type NF400, NV400 400A
(NF600, NV600 500A)
Type NF400, NV400 400A
(NF400, NV400 400A)
Type NF400, NV400 400A
(NF600, NV600 500A)
Type NF400, NV400 400A
(NF600, NV600 500A)
Type NF400, NV400 400A
(NF600, NV600 500A)
Type NF400, NV400 400A
(NF600, NV600 500A)
Type NF400, NV400 400A
(NF600, NV600 600A)
Type NF400, NV400 400A
(NF600, NV600 500A)
Type NF600, NV600 500A
(NF600, NV600 600A)
Type NF600, NV600 500A
(NF600, NV600 600A)
Type NF600, NV600 600A
(NF600, NV600 600A)
Type NF600, NV600 600A
(NF800, NV800 800A)
Type NF800, NV800 800A
(NF800, NV800 800A)
Type NF800, NV800 800A
(NF800, NV800 800A)
Type NF1000, NV1000 1000A
(NF1000, NV1000 1000A)
S-N95
(S-N150)
S-N150
(S-N180)
S-N150
(S-N220)
S-N180
(S-N300)
S-N180
(S-N300)
S-N300
(S-N600)
S-N300
(S-N300)
S-N300
(S-N600)
S-N300
(S-N400)
S-N300
(S-N600)
S-N300
(S-N600)
S-N400
(S-N600)
S-N300
(S-N600)
S-N400
(S-N600)
S-N400
(S-N600)
S-N600
(S-N600)
S-N600
(S-N600)
S-N800
(S-N800)
over 500mm
×500mm
EF-25ASB
1φ100/110V
50/60Hz
12m3/min,
3mmAq
Inlet hole size
over 500mm
×500mm
EF-30BSB
1φ100/110V
50/60Hz
20m3/min,
4mmAq
Inlet hole size
over 500mm
×500mm
S-N800
(S-N800)
Note : 1. Basically the 65kW and above motor is order-made, and the No. of poles, protection, type, etc.,
will differ according to the maker. Check the motor to be used again.
2. Power supply capacity indicated is based on 220V(200V class), 440V(400V class).
3. The types shown in parentheses apply for commercial operation. Select the breaking capacity
that matches the short circuit capacity. When using an earth leakage breaker, use a high
harmonics and surge compatible type, with a sensitivity current of 100 to 500mA.
4. The types shown in parentheses indicate the magnetic contactor on the motor side for
commercial operation.
5. An exhaust fan is required to expel the heat generated in the panel. Consider the pressure loss
caused by the intake port filter, and select a fan that provides sufficient exhaust wind.
27
2
INSTALLATION AND WIRING
2.3.3
Instructions for compliance with the UL standards
Since we obtained the approval of the UL and CSA Standards from the UL, the products conforming to the
Standards carry the UL and CUL marks.)
< For F540L 400V class DRIVE ; F540L is UL Listed >
(1) Installation
The below types of inverter have been approved as products for use in enclosure and approval tests were
conducted under the following conditions. for enclosure design, refer to these conditions so that the ambient
temperature of the inverter 50°C or less.
Inverter Type
FR-F540L-75K
FR-F540L-90K
FR-F540L-110K
FR-F540L-132K
FR-F540L-160K
FR-F540L-185K
FR-F540L-220K
FR-F540L-280K
FR-F540L-375K
Cabinet (enclosure)
(Unit: mm (inches))
Vent Hole Area
Cooling Fan
W
H
D
800 × 2100 × 550
625cm2
Install a cooling fan at top of the enclosure to suck internal
air to the outside.
(Fan air flow: 19m3/min or more)
W
H
D
800 × 2100 × 550
(31.50 x 82.68 x 21.65)
625cm2
Install a cooling fan at top of the enclosure to suck internal
air to the outside.
(Fan air flow: 30m3/min or more)
W
H
D
1300 × 2300 × 800
(51.18 x 82.68 x 21.65)
3726cm2
Install a cooling fan at top of the enclosure to suck internal
air to the outside.
(Fan air flow: 120m3/min or more)
(2) Wiring of the power supply and motor
Use the UL-approved power supply and round crimping terminals to wire the input (R, S, T)<L1, L2,L3 > and output (U,
V, W) terminals of the inverter. Crimp the terminals with the crimping tool recommended by the terminal
manufacturer.
(3) Fuse
The fuse used on the input side should be any of the UL Class K5 fuses having the ratings as listed below:
Applicable Inverter Type
Rating (A)
FR-F540L-75K
250
Applicable Inverter Type
FR-F540L-160K
Rating (A)
400
FR-F540L-90K
300
FR-F540L-185K
500
FR-F540L-110K
300
FR-F540L-220K
600
FR-F540L-132K
350
FR-F540L-280K
800
FR-F540L-375K
1000
(4) Short-circuit rating
This following inverter has been put to the short-circuit test of the UL in the AC circuit whose peak current and
voltage are limited to and 500V maximum, respectively, and conforms to this circuit.
*
Inverter Type
*
75K to 110K
10 kA
132K to 220K
18 kA
280K to 375K
30 kA
28
INSTALLATION AND WIRING
2.3.4
Instructions for compliance with the European standards
(The products conforming to the Low Voltage Directive carry the CE mark.)
(1) EMC Directive
1) Our view of transistorized inverters for the EMC Directive
A transistorized inverter does not function independently. It is a component designed for installation in a
control box and for use with the other equipment to control the equipment/device. Therefore, we
understand that the EMC Directive does not apply directly to transistorized inverters. For this reason,
we do not place the CE mark on the transistorized inverters themselves. (The CE mark is placed on
inverters in accordance with the Low Voltage Directive.) The European power drive manufacturers'
organization (CEMEP) also holds this point of view.
2) Compliance
We understand that the transistorized inverters themselves are not covered directly by the EMC
Directive. However, the EMC Directive applies to machines/equipment into which transistorized
inverters have been incorporated, and these machines and equipment must carry the CE marks.
Hence, we prepared the technical information "EMC Installation Guidelines" (information number
IB07395) so that machines and equipment incorporating transistorized inverters may conform to the
EMC Directive more easily.
3) Outline of installation method
Install an inverter using the following methods:
* Use the inverter with an European Standard-compliant noise filter.
* For wiring between the inverter and motor, use shielded cables or run them in a metal piping and
ground the cables on the inverter and motor sides with the shortest possible distance.
* Insert a line noise filter and ferrite core into the power and control lines as required.
Full information including the European Standard-compliant noise filter specifications are written in
the technical information "EMC Installation Guidelines" (IB07395). Please contact your sales
representative.
(2) Low Voltage Directive
1) Our view of transistorized inverters for the Low Voltage Directive
Transistorized inverters are covered by the Low Voltage Directive.
2) Compliance
We have confirmed our inverters as products compliant to the Low Voltage Directive and place the CE
mark on the inverters.
3) Outline of instructions
* Connect the equipment to the earth securely. Do not use an earth leakage circuit breaker as an
electric shock protector without connecting the equipment to the earth.
* Use the no-fuse breaker and magnetic contactor which conform to the EN or IEC Standard.
* Use the inverter under the conditions of overvoltage category III and contamination level 2 or higher
specified in IEC664. To meet the contamination level 2, install the inverter into a cabinet protected
against ingress of water, oil, carbon, dust, etc. (IP54 or higher).
* In the input and output of the inverter, use cables of the type and size set forth in EN60204 Annex C.
* The operating capacity of the relay outputs (terminal symbols A, B, C) should be 30VDC, 0.3A. (The
relay outputs are basically isolated from the inverter's internal circuitry.)
* Inverter is not used in closed electrical operating area, then supply protective device with the inverter.
* In case of residual-current-operated protective device (RCD), install on mains supply side as a
protection with regard to direct or indirect contact, only Type B is allowed.
* Else another protection measure like separation of equipment from environment by double or
reinforced insulation or from mains by isolating transformer has be applied.
* Protective Earth (PE) conductor is connected to main PE terminal.
* Circuit breaker as short circuit and earth fault protection must be set within the inverter.
Details are given in the technical information "Low Voltage Directive Conformance Guide"(IB07400-01).
Please contact your sales representative.
29
2
INSTALLATION AND WIRING
2.3.5
Earthing
(1) Earthing and Earth Leakage Current
(a) Purpose of Earthing
Electrical equipment usually has an Earthing Terminal, this must be connected to earth before using
equipment.
For protection, electric circuits are normally housed inside an insulated case. However it is impossible
to manufacture insulating materials that prevent all current from leaking across them, therefore it is the
function of the earth (safety earth) to prevent electric shocks when touching the case.
There is however, another important earthing function, which is to prevent equipment that uses very
weak signals (Audio equipment, sensors, transducers, etc.) or micro processors from being affected by
Radio Frequency Interference, (RFI) from external sources.]
(b) Points to remember when Earthing
As detailed above there are two entirely different types of earthing and to attempt to use the same earth
for both will lead to problems. It is necessary to separate the “safety” earthing (a yellow/green wire to
prevent electric shocks) from the “RFI” earthing (a braided wire strap to counter radio noise).
The inverter output voltage does not take the form of a sine wave but of a modulated pulse wave form
causing “noisy” leakage current due to the capacitance of the insulation.
The same type of leakage current will occur in the motor due to the charging and discharging of the
insulation from the high frequency wave form. This trend becomes more pronounced with higher carrier
frequencies.
To solve this problem it is necessary to use separate “dirty” earthing for inverter and motor installations
an “clean” earting for equipment such as sensors, computers and audio equipment.
(2) Earthing methods
Two main types of earth
1-To prevent electrical shocks
Yellow and green cable
2-To prevent RFI induced malfunction
Braided strap
It is important to make a clear distinction between these two, and to keep them separate by following the
measures below.
(a) When possible earth the inverter independently of other equipment.
If independent earthing is not possible, use a common earthing point.
Avoid connecting earthing wires together particularly on high power equipment such as motors and
inverters.
Independent earthing should always be used between sensitive equipment and inverters.
Inverter
Other
equipment
a) Independent grounding
Other
equipment
Inverter
a) Common grounding
30
Inverter
Other
equipment
c) Grounding wire of other
equipment
INSTALLATION AND WIRING
2.3.6
Power harmonics
Power harmonics may be generated from the converter section of the inverter, affecting power supply
equipment, power capacitors, etc. Power harmonics are different in generation source, frequency and
transmission path from radio frequency (RF) noise and leakage currents. Take the following measures.
• The differences between harmonics and RF noise are indicated below:
Item
Frequency
Environment
Quantitative understanding
Harmonics
Normally 40 to 50th degrees, 3kHz or less
To wire paths, power impedance
Logical computation is possible
Generated amount
Approximately proportional to load capacity
Immunity of affected device
Specified in standards for each device.
Example of safeguard
Install a reactor (L)
• Safeguard
The harmonic current generated from the inverter to the
power supply differs according to various conditions such
as the wiring impedance, whether a power factor
improving reactor is used or not, and output frequency
and output current on the load side.
For the output frequency and output current, the adequate
method is to obtain them under rated load at the
maximum operating frequency.
RF Noise
High frequency (several 10kHz to MHz order)
Accross spaces, distance, laying paths
Occurs randomly, quantitative understanding is difficult.
According to current fluctuation rate (larger with faster
switching)
Differs according to maker’s device specifications.
Increase the distance. ( )
Power factor
improving DC
reactor
NFB
Motor
Inverter
Power factor
improving AC
reactor
IM
Do not insert power factor
improving capacitor
Note: A power factor improving capacitor or surge suppressor on the inverter’s output may overheat or be
damaged due to the harmonics of the inverter output. Also, when an overcurrent flows in the inverter,
the overcurrent protection is activated, Hence, when the inverter drives the motor, do not install a
capacitor or surge suppressor on the inverter’s output. To improve the power factor, insert a power
factor improving reactor in the inverter’s input.
31
2
INSTALLATION AND WIRING
2.3.7
Japanese harmonic suppression guidelines
Harmonic currents flow from the inverter to a power receiving point via a power transformer. The harmonic
suppression guidelines were established to protect other consumers from these outgoing harmonic currents.
1) "Harmonic suppression guideline for specific consumers"
This guideline sets forth the maximum values of harmonic currents outgoing from a high-voltage or
especially high-voltage consumer who will install, add or renew harmonic generating equipment. If any of
the maximum values are exceeded, this guideline requires that consumer to take certain suppression
measures.
Table 1 Maximum Values of Outgoing Harmonic Currents per 1kW Contract Power (mA/kW)
Received Power
Voltage
6.6kV
22kV
33kV
5th
7th
11th
13th
17th
19th
23rd
Over 23rd
3.5
1.8
1.2
2.5
1.3
0.86
1.6
0.82
0.55
1.3
0.69
0.46
1.0
0.53
0.35
0.9
0.47
0.32
0.76
0.39
0.26
0.70
0.36
0.24
(1) Application of the harmonic suppression guideline for specific consumers
New installation/addition/renewal of equipment
Calculation of equivalent capacity sum
Not more than
reference capacity
Sum of equivalent capacities
Over reference capacity
Calculation of outgoing harmomic current
Over maximum value
Is outgoing harmonic current equal to or lower than
maximum value ?
Harmomic suppression technique is required.
Not more than
maximum value
Harmomic suppression technique is not required.
Table 2 Conversion Factors for FR-F500 Series
Class
Circuit Type
With reactor (DC side)
3-phase bridge
(Capacitor-smoothed)
With reactors (AC, DC sides)
Self-exciting 3-phase bridge When high power factor converter is used
3
5
Conversion Factor Ki
K33 = 1.8
K34 = 1.4
K5 = 0
Table 3 Equivalent Capacity Limits
Received Power Voltage
6.6kV
Reference Capacity
50kVA
22/33kV
300kVA
66kV or more
2000kVA
Table 4 Harmonic Content (Values at the fundamental current of 100%)
Reactor
Used (DC side)
Used (AC, DC sides)
5th
30
28
7th
13
9.1
11th
8.4
7.2
13th
5.0
4.1
32
17th
4.7
3.2
19th
3.2
2.4
23rd
3.0
1.6
25th
2.2
1.4
INSTALLATION AND WIRING
1) Calculation of equivalent capacity (P0) of harmonic generating equipment
The "equivalent capacity" is the capacity of a 6-pulse converter converted from the capacity of consumer’s
harmonic generating equipment and is calculated with the following equation. If the sum of equivalent
capacities is higher than the limit in Table 3, harmonics must be calculated with the following procedure:
P0 = Σ (Ki × Pi) [kVA]
Ki: Conversion factor (refer to Table 2)
Pi: Rated capacity of harmonic generating equipment* [kVA]
i: Number indicating the conversion circuit type
* Rated capacity: Determined by the
capacity of the applied motor and found
in Table 5. It should be noted that the
rated capacity used here is used to
calculate generated harmonic amount
and is different from the power supply
capacity required for actual inverter
drive.
2) Calculation of outgoing harmonic current
Outgoing harmonic current = fundamental wave current (value converted from received power voltage) ×
operation ratio × harmonic content
• Operation ratio: Operation ratio = actual load factor × operation time ratio during 30 minutes
• Harmonic content: Found in Table 4.
Table 5 Rated Capacities and Outgoing Harmonic Currents for Inverter Drive
Applied
Motor
(kW)
75
90
110
132
160
200
220
250
Rated
Current
[A] 400V
Fundamental
Wave Current
Converted
from 6.6kV
(mA)
Rated
Capacity
(kVA)
8,200
9,800
11,933
14,400
17,200
21,553
23,667
26,867
87
104
127
153
183
229
252
286
123
147
179
216
258
323
355
403
Fundamental Wave Current Converted from 6.6kV
(With DC reactor, 100% operation ratio)
(mA)
5th
2,460
2,940
3,580
4,320
5,160
6,460
7,100
8,606
7th
1,066
1,274
1,551
1,872
2,236
2,799
3,077
3,493
11th
689
823
1,002
1,210
1,445
1,809
1,988
2,257
13th
410
490
597
720
860
1,077
1,183
1,343
17th
385
461
561
677
808
1,012
1,112
1,263
19th
262
314
382
461
550
689
757
860
23rd
246
294
358
432
516
646
710
806
25th
180
216
263
317
378
474
521
591
3) Harmonic suppression technique requirement
If the outgoing harmonic current is higher than the maximum value per 1kW (contract power) × contract
power, a harmonic suppression technique is required.
4) Harmonic suppression techniques
No.
Item
Reactor installation
(ACL, DCL)
Description
Install a reactor (ACL) in the AC side of the inverter or a reactor (DCL) in its DC side or both to
suppress outgoing harmonic currents.
2
High power factor
converter
(MT-HC)
The converter circuit is switched on-off to convert an input current waveform into a sine wave,
suppressing harmonic currents substantially. The high power factor converter (MT-HC) is used with
the standard accessory.
3
Installation of power
factor improving
capacitor
When used with a series reactor, the power factor improving capacitor has an effect of absorbing
harmonic currents.
4
Transformer multiphase operation
Use two transformers with a phase angle difference of 30° as in -∆, ∆-∆ combination to provide
an effect corresponding to 12 pulses, reducing low-degree harmonic currents.
5
AC filter
A capacitor and a reactor are used together to reduce impedance at specific frequencies, producing
a great effect of absorbing harmonic currents.
6
Active filter
This filter detects the current of a circuit generating a harmonic current and generates a harmonic
current equivalent to a difference between that current and a fundamental wave current to suppress
a harmonic current at a detection point, providing a great effect of absorbing harmonic currents.
1
33
2
INSTALLATION AND WIRING
2.3.8
Inverter-generated noises and reduction techniques
Some noises enter the inverter causing it to misoperate and others are radiated by the inverter causing
misoperation of peripheral devices. Though the inverter is designed to be insusceptible to noise, it handles
low-level signals, so it requires the following basic measures to be taken. Also, since the inverter chops the
output at a high carrier frequency, it could generate noise. If these noises cause peripheral devices to
misoperate, measures should be taken to suppress the noise. The measures differ slightly depending on
noise propagation paths.
Basic measures
• Do not run the power cables (I/O cables) and signal cables of the inverter in parallel with each other and
do not bundle them.
• Use twisted shielded cables for the detector connection and control signal cables and connect the
sheathes of the shielded cables to terminal SD.
• Ground the inverter, motor, etc. at one point.
2) Measures against noises which enter and cause misoperation of the inverter
When devices which generate many noises (which contain magnetic contactors, magnetic brakes, many
relays, for example) are installed near the inverter, the inverter may be affected by noise, the following
measures must be taken:
• Provide surge suppressors for devices that generate noise.
• Fit data line filters to signal cables.
• Ground the shields of the detector connection and control signal cables with cable clamp metal.
3) Measures against noise, which is radiated by the inverter causing misoperation of peripheral devices.
Inverter-generated noise is largely classified into those radiated by the cables connected to the inverter and
inverter main circuit (I/O), those electromagnetically and electrostatically inducted to the signal cables of the
peripheral devices close to the main circuit power supply, and those transmitted through the power supply
cables.
Inverter-generated
noise
Air-propagated
noise
Noise directly radiated by inverter
Path 1)
Noise radiated by
power cables
Path 2)
Noise radiated by
motor cables
Path 3)
Magnetic induction
noise
Path 4),5)
Static induction
noise
Path 6)
Cable-propagated
noise
34
Noise propagated
through power
cables
Noise from ground
cable due to
leakage current
Path 7)
Path 8)
INSTALLATION AND WIRING
Noise Path
Measures
1) 2) 3)
When devices which handle low-level signals and are susceptible to misoperation due to noise (such as
instruments, receivers and sensors) are installed near the inverter and their signal cables are contained in the
same panel as the inverter or are run near the inverter, the devices may be effected by air-propagated noises
and the following measures must be taken:
(1) Install easily affected devices as far away as possible from the inverter.
(2) Run easily affected signal cables as far away as possible from the inverter.
(3) Do not run the signal cables and power cables (inverter I/O cables) in parallel with each other and do not
bundle them.
(4) Inset line noise filters into I/O and radio noise filters into input side to suppress cable-radiated noises.
(5) Use shielded cables for signal cables and power cables and run them in individual metal conduits to reduce
further effects.
4) 5) 6)
When the signal cables are run in parallel with or bundled with the power cables, magnetic and static induction
noise may be propagated to the signal cables to effect the devices and the following measures must be taken:
(1) Install easily affected devices as far away as possible from the inverter.
(2) Run easily affected signal cables as far away as possible form the inverter.
(3) Do not run the signal cables and power cables (inverter I/O cables) in parallel with each other and do not
bundle them.
(4) Use shielded cables for signal cables and power cables and run them in individual metal conduits to reduce
further effects.
7)
When the power supplies of the peripheral devices are connected to the power supply of the inverter within the
same line, inverter-generated noise may flow back through the power supply cables to misoperate the devices
and the following measures must be taken:
(1) Install the radio noise filter (FR-BIF) to the power cables (input cables) of the inverter.
(2) Install the line noise filter (FR-BLF) to the power cables (I/O cables) of the inverter.
8)
When a closed loop circuit is formed by connecting the peripheral device wiring to the inverter, leakage current
may flow through the ground cable of the inverter to affect the device. In such a case, disconnection of the
ground cable of the device may cause the device to operate properly.
• Data line filter
Noise entry can be prevented by providing a data line filter for the detector cable etc.
35
2
INSTALLATION AND WIRING
z Example of measures against noises
Control box
Reduce carrier
frequency.
Install
Install filter
filter (FR-BLF)
(FR-BLF) to
to
Install filter (FR-BLF) to
Install filter (FR-BLF,FRinverter input side.
BSF01) to inverter input side.
inverter
output
side.
inverter
input
side.
Install
filter
(FR-BLF,FR-BSF01)
to inverter output side.
FRBLF
Inverter power
supply
Install filter FR-BIF to
inverter input side.
Separate inverter and power line
30cm or more
(at least 10cm )
from sensor circuit.
Control power
supply
Inverter
Motor
Use 4-core cable for motor
power cable and use one
cable as ground cable.
FRBIF
Use twisted pair
shielded cable.
Power
supply for
sensor
Do not ground control box directly.
Stop earthing the control cable.
2.3.9
FRBLF
Sensor
Do not ground shield but connect
it to signal common cable.
Leakage currents and countermeasures
Due to the static capacitance existing in the inverter I/O wiring and motor, leakage currents flow through them.
Since their values depend on the static capacitance, carrier frequency, etc. take the following measures.
(1) To-ground leakage currents
Leakage currents may flow not only into the inverter's own line but also into the other line through the ground
cable, etc. These leakage currents may operate earth leakage circuit breakers and earth leakage relays
unnecessarily.
z Countermeasures
• By using earth leakage circuit breakers designed for harmonics and surges (e.g. Mitsubishi's Progressive
Super Series) in the inverter's own line and other line, operation can be performed with low noise (with the
carrier frequency kept high)
z To-ground leakage current
• Note that a long wiring length will increase leakage currents. Decrease the carrier frequency of the inverter
to reduce leakage currents.
• Higher motor capacity leads to larger leakage currents. Larger leakage currents occur in 400V class than
in 200V class.
36
INSTALLATION AND WIRING
(2) Line-to-line leakage currents
Harmonics of leakage currents flowing in static capacities between the inverter output cables might operate
the external thermal relay unnecessarily.
NFB
Power
supply
Thermal relay
Motor
IM
Inverter
Line static capacitances
Line-to-Line Leakage Current Path
z Countermeasures
• Use the electronic overcurrent protection (Pr. 9) of the inverter.
• Decrease the carrier frequency. Note that the audible motor noise increases. Selection of Soft-PWM (Pr.
240) will make it unoffending.
To ensure that the motor is protected against line-to-line leakage currents, it is recommended to use a
temperature sensor to directly detect motor temperature.
2.3.10
Inverter-driven 400V class motor
In the PWM type inverter, a surge voltage attributable to wiring constants is generated at the motor terminals.
Especially for a 400V class motor, the surge voltage may deteriorate the insulation. When the 400V class
motor is driven by the inverter, consider the following measures:
• Measures
It is recommended to take either of the following measures:
(1) Rectifying the motor insulation
For the 400V class motor, use an insulation-rectified motor. Specifically,
1) Specify the "400V class inverter-driven, insulation-rectified motor".
2) For the dedicated motor such as the constant-torque motor and low-vibration motor, use the "inverterdriven, dedicated motor".
(2) Suppressing the surge voltage on the inverter side
On the secondary side of the inverter, connect the optional surge voltage suppression filter (MT-BSL/BSC).
37
2
CHAPTER 3
OPERATION
This chapter provides the basic "operation" for use of this
product.
Always read this chapter before using the equipment.
3.1 Pre-Operation Information ・・・・・・・・・・・・・・・・・・・・・・ 38
3.2 Opreration Panel・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 41
3.3 Parameter Checking and Setting ・・・・・・・・・・・・・・・・ 47
3.4 Operation ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 51
Chapter 1
Chapter 2
Chapter 3
Chapter 4
Chapter 5
Chapter 6
Chapter 7
3.1 Pre-Operation Information
OPERATION
3.1.1
Devices and parts to be prepared for operation
The inverter can be operated in any of the "external operation mode", "PU operation mode", "combined
operation mode" and "communication operation mode". Prepare required instruments and parts according to
the operation mode.
(1) External operation mode (factory setting)
The inverter is operated under the control of external
operation signals (frequency setting potentiometer,
start switch, etc.) connected to the terminal block. With
input power on, switch on the start signal (STF, STR) to
start operation.
Inverter
DU04
PU04
Preparation
Start switch
• Start signal................................... Switch, relay, etc.
Potentiometer
• Frequency setting signal.............. 0 to 5V, 0 to 10V or 4 to 20mA DC signals from a potentiometer or
outside the inverter
Note: Both the start signal and frequency setting signal are required to run the inverter.
(2) PU operation mode
The inverter is operated from the keypad of the PU
(FR-DU04/FR-PU04).
This mode does not require the operation signals to be
connected and is useful for an immediate start of
operation.
Inverter
DU04
PU04
Preparation
• Operation unit .............................. Operation panel (FR-DU04), parameter unit (FR-PU04)
• Connection cable......................... To be prepared for use of the operation unit away from the inverter.
FR-CB2 (option) or the following connector and cable available on the
market:
Connector : RJ45 connector
Cable
: Cable conforming to EIA568 (e.g. 10BASE-T cable)
(3) External/PU combined operation mode
The inverter is operated with the external operation
and PU operation modes combined in any of the
following ways:
1) The start signal is set with the external signal and
the frequency setting signal set from the PU.
2) The start signal is set with the run command key of
the PU (FR-DU04/FR-PU04) and the frequency
setting signal set with the external frequency setting
potentiometer.
38
Inverter
PU
Potentiometer
Start switch
PU
OPERATION
Preparation
• Start signal................................... Switch, relay, etc. (for 1)
• Frequency setting signal.............. 0 to 5V, 0 to 10V or 4 to 20mA DC signals from a potentiometer or outside
the inverter (for 2)
• Operation unit .............................. Operation panel (FR-DU04), parameter unit (FR-PU04)
• Connection cable......................... To be prepared for use of the operation unit away from the inverter
FR-CB2 (option) or the following connector and cable available on the
market:
Connector : RJ45 connector
Cable
: Cable conforming to EIA568 (e.g. 10BASE-T cable)
3) Combined operation mode
Change the setting of Pr. 79 "operation mode selection" as follows:
Setting
3
4
Description
Running frequency setting
Start signal
PU (FR-DU04/FR-PU04)
Terminal signal
• Direct setting and [UP/DOWN] key setting
• STF
• STR
Parameter unit
Terminal signal
• [FWD] key
• 0 to 5VDC across 2-5
• [REV] key
• 0 to 10VDC across 2-5
• 4 to 20mADC across 4-5
• Multi-speed selection (Pr. 4 to Pr. 6, Pr. 24
to Pr. 27)
• Jog frequency (Pr. 15)
(4) Communication operation mode
Communication operation can be performed by connecting a personal computer and the PU connector with
the RS-485 communication cable.
The inverter setup software (FR-SW0-SETUP-WE (or –WJ for Japanese Version)) is available as a startup
support software package for the FR-F500.
Preparation
• Connection cable......................... Connector
Cable
• Personal computer
: RJ45 connector
: Cable conforming to EIA568
(E.g. 10BASE-T cable)
<Inverter setup software operating environment>
OS .................................................. Windows 3.1, Windows 95
RAM ............................................... 1MB or more
Floppy disk drive ............................ One or more 3.5 inch floppy
disk drives
Mouse ............................................ Mouse connectable to the
personal computer
39
3
OPERATION
3.1.2
Power on
Before switching power on, check the following:
• Installation check
Make sure that the inverter is installed correctly in a proper location. (Refer to page 6.)
• Wiring check
Make sure that the main and control circuits are wired correctly.
Make sure that the options and peripheral devices are selected and connected correctly.
(Refer to page 8.)
• Switch power on.
Power-on is complete when the POWER lamp is lit correctly and the operation panel (FR-DU04) displays
correct data.
40
3.2 Operation Panel
OPERATION
With the operation panel (FR-DU04), you can set the running frequency, monitor the operation command
display, set parameters, display an error, and copy parameters.
3.2.1
Names and functions of the operation panel (FR-DU04)
FR-DU04
CONTROL PANEL
Hz
A
V
Display
LED ×4 digits
MON
[MODE] key
EXT
PU
REV
FWD
MODE
REV
SET
Unit indication
‚ Hz (frequency)
‚ A (current)
‚ V (voltage)
Operation status indication
[Operation command] keys
‚ [REV] (reverse rotation) key
‚ [FWD] (forward rotation) key
FWD
STOP
RESET
[SET] key
[STOP/RESET] key
[UP/DOWN] Key
• Key indications
Key
[MODE] key
Description
You can select the operation mode or setting mode.
[SET] key
You can determine the frequency and parameter setting.
[UP/DOWN] key
• Used to increase or decrease the running frequency consecutively. Hold down this key to change the
frequency.
• Press this key in the setting mode to change the parameter setting consecutively.
(
key)
[FWD] key
Used to give a forward rotation command.
[REV] key
Used to give a reverse rotation command.
• Used to stop operation.
• Used to reset the inverter when its output is stopped by the protective function activated (major fault).
[STOP/RESET] key
3
• Unit indications, operating status indications
Indication
HZ
Description
Lit to indicate the frequency.
A
Lit to indicate the current.
V
Lit to indicate the voltage.
MON
Lit in the monitor display mode.
PU
Lit in the PU operation mode.
EXT
Lit in the external operation mode.
FWD
Flickers to indicate forward rotation.
REV
Flickers to indicate reverse rotation.
41
OPERATION
3.2.2
Monitor display changed by pressing the [MODE] key
zMonitoring mode
FR-DU04
zFrequency setting mode
(Note)
FR-DU04
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
Hz
A
V
MODE
MON
zParameter setting mode
EXT
PU
REV
FWD
zOperation mode
FR-DU04
CONTROL PANEL
Hz
A
V
MODE
MON
EXT
PU
REV
FWD
zHelp mode
Hz
A
V
MODE
MON
FR-DU04
CONTROL PANEL
EXT
PU
REV
FWD
CONTROL PANEL
Hz
A
V
MODE
MON
EXT
PU
REV
FWD
MODE
Note: The frequency setting mode is displayed only in the PU operation mode.
3.2.3
Monitoring mode
• Operation command indications in the monitoring mode
EXT is lit to indicate external operation.
PU is lit to indicate PU operation.
Both EXT and PU are lit to indicate PU/external combined operation mode.
• The monitor display can also be changed during operation.
FR-DU04
FR-DU04
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
zVoltage monitor
zCurrent monitor
zFrequency monitor
Hz
A
V
SET
MON
FR-DU04
CONTROL PANEL
EXT
PU
REV
FWD
CONTROL PANEL
Hz
A
V
SET
MON
SET
SET
*1
*1
Alarm
present
EXT
PU
REV
FWD
zAlarm monitor
FR-DU04
CONTROL PANEL
Hz
A
V
SET
MON
EXT
PU
REV
FWD
SET
*1
Alarm absent
SET
SET
MODE
*2
To 3.2.4 Frequency setting mode (Note 3)
Note: 1. Hold down the [SET] key marked *1 for more than 1.5 seconds to change the current monitor to
the power-on monitor.
2. Hold down the [SET] key marked *2 for more than 1.5 seconds to display four errors including the
most recent one.
3. Shifts to the parameter setting mode when in the external operation mode.
3.2.4
Frequency setting mode
• Used to set the running frequency in the PU operation mode.
To frequency monitor
MODE
zSet frequency change
FR-DU04
FR-DU04
CONTROL PANEL
MODE
EXT
PU
REV
FWD
Hz
A
V
MON
Press
FR-DU04
CONTROL PANEL
Hz
A
V
MON
zSet frequency write
EXT
PU
REV
FWD
to change the set frequency.
To 3.2.5 Parameter setting mode
42
CONTROL PANEL
Hz
A
V
SET
MON
EXT
PU
REV
FWD
OPERATION
3.2.5
Parameter setting mode
• A parameter value may either be set by updating its parameter number or setting the value digit-by-digit
using the [UP/DOWN] key.
• To write the setting, change it and press the [SET] key 1.5 seconds.
Set "1" (PU operation mode) in Pr. 79 "operation mode selection" or select the PU operation mode.
Note: If parameter write cannot be performed, refer to page 101.
zParameter number change zSetting change
FR-DU04
FR-DU04
CONTROL PANEL
MON
MODE
EXT
PU
REV
FWD
Hz
A
V
MON
FR-DU04
CONTROL PANEL
Hz
A
V
EXT
PU
REV
FWD
Hz
A
V
MON
Press
to change the parameter
number.
SET
CONTROL PANEL
SET
EXT
PU
REV
FWD
Press
Flicker
for
zSetting write
1.5
CONTROL PANEL
FR-DU04
FR-DU04
sec.
CONTROL PANEL
Hz
A
V
SET
MON
EXT
PU
REV
FWD
Press
to change the setting.
Hz
A
V
MON
SET
EXT
PU
REV
FWD
MODE
Simultaneous input
z Changing the parameter number
Most significant
Middle digit flickers
digit flickers
FR-DU04
Hz
A
V
MON
FR-DU04
FR-DU04
CONTROL PANEL
EXT
PU
REV
FWD
Hz
A
V
SET
MON
FR-DU04
CONTROL PANEL
EXT
PU
REV
FWD
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
Hz
A
V
SET
MON
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
Hz
A
V
MON
Least significant digit flickers
CONTROL PANEL
CONTROL PANEL
Hz
A
V
MON
0∼9
EXT
PU
REV
FWD
Hz
A
V
MON
0∼9
EXT
PU
REV
FWD
SET
3
0∼9
To 3.2.6 Operation mode
3.2.6
Operation mode
zExternal operation
FR-DU04
CONTROL PANEL
zPU operation
FR-DU04
zPU jog operation
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
MODE
FR-DU04
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
MODE
To 3.2.7 Help mode
Note: If operation mode changing cannot be made, refer to page 101.
43
Hz
A
V
MON
EXT
PU
REV
FWD
MODE
OPERATION
3.2.7
Help mode
zAlarm history
FR-DU04
zParameter
clear
zAlarm history
clear
CONTROL PANEL
zAll clear
zSoftware version
read
zUser clear
Hz
A
V
MON
EXT
PU
REV
FWD
MODE
To 3.2.3 Monitoring mode
• Alarm history
Four past alarms can be displayed with the [UP/DOWN] key.
("." is appended to the most recent alarm.)
(When no alarm exists, E._ _0 is displayed.)
zMost recent alarm
FR-DU04
FR-DU04
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
MON
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
Hz
A
V
SET
MON
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
Hz
A
V
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
Hz
A
V
MON
EXT
PU
REV
FWD
SET
When alarm occurs
z Frequency
FR-DU04
z Current
FR-DU04
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
z Energization
z Voltage
FR-DU04
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
Hz
A
V
MON
EXT
PU
REV
FWD
• Alarm history clear
Clears all alarm history.
Flicker
FR-DU04
Hz
A
V
MON
FR-DU04
CONTROL PANEL
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
MON
SET
EXT
PU
REV
FWD
Hz
A
V
MON
Cancel
44
FR-DU04
CONTROL PANEL
Hz
A
V
SET
time
CONTROL PANEL
EXT
PU
REV
FWD
CONTROL PANEL
Hz
A
V
SET
1.5 sec.
MON
EXT
PU
REV
FWD
OPERATION
• Parameter clear
Initialises the parameter values to the factory settings. The calibration values are not initialized.
(Parameter values are not cleared by setting "1" in Pr. 77 "parameter write disable selection.)
Flicker
FR-DU04
Hz
A
V
MON
FR-DU04
CONTROL PANEL
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
MON
SET
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
Hz
A
V
SET
Hz
A
V
MON
EXT
PU
REV
FWD
CONTROL PANEL
Hz
A
V
SET
1.5 sec.
MON
EXT
PU
REV
FWD
Cancel
• All clear
Initializes the parameter values and calibration values to the factory settings.
Flicker
FR-DU04
Hz
A
V
MON
FR-DU04
CONTROL PANEL
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
MON
SET
EXT
PU
REV
FWD
Hz
A
V
MON
FR-DU04
CONTROL PANEL
Hz
A
V
SET
EXT
PU
REV
FWD
CONTROL PANEL
Hz
A
V
SET
1.5 sec.
MON
EXT
PU
REV
FWD
Cancel
• User clear
Initializes the user-set parameters.
The other parameters are initialized to the factory settings.
Flicker
FR-DU04
Hz
A
V
MON
FR-DU04
CONTROL PANEL
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
MON
SET
EXT
PU
REV
FWD
Hz
A
V
MON
FR-DU04
CONTROL PANEL
Hz
A
V
SET
EXT
PU
REV
FWD
CONTROL PANEL
Hz
A
V
SET
1.5 sec.
MON
EXT
PU
REV
FWD
3
Cancel
45
OPERATION
3.2.8
Copy mode
By using the operation panel (FR-DU04), the parameter values can be copied to another inverter of the same
series. (only F500L to F500L.)
1) Operation procedure
After reading the parameter values from the copy source inverter, connect the operation panel to the copy
destination inverter, and write the parameter values.
After writing the parameters to the destination inverter, always reset the inverter, e.g. switch power off once,
before starting operation.
zParameter setting mode
FR-DU04
FR-DU04
CONTROL PANEL
CONTROL PANEL
Hz
A
V
MON
FR-DU04
EXT
PU
REV
FWD
MON
FR-DU04
CONTROL PANEL
Hz
A
V
MON
Hz
A
V
EXT
REV
EXT
PU
REV
FWD
FR-DU04
CONTROL PANEL
PU
FWD
MON
Press for
1.5 sec.
EXT
REV
FR-DU04
MON
Press for
1.5 sec.
EXT
PU
REV
FWD
Hz
A
V
PU
FWD
(Note 1)
SET
FR-DU04
CONTROL PANEL
EXT
REV
MON
Press for
1.5 sec.
CONTROL PANEL
Hz
A
V
MON
CONTROL PANEL
Hz
A
V
PU
FWD
(Note 1)
SET
FR-DU04
CONTROL PANEL
Hz
A
V
SET
EXT
REV
(Note 1)
SET
FR-DU04
PU
FWD
CONTROL PANEL
Hz
A
V
MON
zParameter read
EXT
PU
REV
FWD
zParameter write
Connect to copy destination inverter.
Hz
A
V
MON
EXT
PU
REV
FWD
zParameter verify
After writing the parameters,
always reset the inverter before
operation.
Note: 1. While the copy function is being activated, the monitor display flickers. The display returns to the
lit-up state on completion of the copy function.
2. If a read error occurs during parameter read, "read error (E.rE1)" is displayed.
3. If a write error occurs during parameter write, "write error (E.rE2)" is displayed.
4. If a data discrepancy occurs during parameter verify, the corresponding parameter number and
"verify error (E.rE3)" are displayed alternately. If the direct frequency setting or jog frequency
setting is incorrect, "verify error (E.rE3)" flickers. To ignore this display and continue verify, press
the [SET] key.
5. When the copy destination inverter is not the FR-F500 series, "model error (E.rE4)" is displayed.
Reference: It is recommended to read the parameter values after completion of parameter setting.
By writing the parameter values from the operation panel fitted to a new inverter after inverter
replacement, parameter setup can be completed.
46
3.3 Parameter Checking and Setting
The inverter is designed to perform simple variable-speed operation with the factory settings of the parameters.
Set the necessary parameters according to the load and operation specifications. Use the operation panel
(FR-DU04) to set, charge and confirm the parameter values. For full information on the parameters, refer to
"CHAPTER 4 PARAMETERS" (Page 55).
3.3.1
Parameter checking
Pr. 160 "user group read selection" is factory-set to display only the simple mode parameters among the
parameters. Set the following parameters as required.
(1) Pr. 160 "user group read selection"
Parameter
Number
160
Factory Setting
Setting Range
9999
0, 1, 10, 11, 9999
Simple mode parameter
OPERATION
• Setting details
For the setting method and in-depth explanation, refer to page 132.
Pr. 160 Setting
0
1
10
11
9999
Description
All parameters are made accessible for reading and writing.
Only the parameters registered in user group 1 are made accessible for reading and writing.
Only the parameters registered in user group 2 are made accessible for reading and writing.
Only the parameters registered in user groups 1 and 2 are made accessible for reading and writing.
Only the simple mode parameters are made accessible for reading and writing. (Factory setting)
(2) Simple mode parameter list
The following parameters are basic parameters made accessible for reading and writing by setting "9999" in
Pr. 160. For details of their functions, refer to Chapter 4 "PARAMETERS" (page 55).
Parameter
Number
Name
Application
Used to compensate for a voltage drop in the low frequency range to improve
motor torque reduction in the low speed range.
0
Torque boost
1
2
3
4
5
6
7
8
Maximum frequency
Minimum frequency
Base frequency
Three-speed setting (high speed)
Three-speed setting (middle speed)
Three-speed setting (low speed)
Acceleration time
Deceleration time
9
Electronic thermal O/L relay
Used to set the current value of the electronic overcurrent protection to protect
the motor from overheat.
11
12
13
DC injection brake operation
frequency
DC injection brake operation time
DC injection brake voltage
Starting frequency
Used to adjust the stopping accuracy according to the load.
14
Load pattern selection
19
52
53
54
55
56
57
58
Base frequency voltage
DU/PU main display data selection
PU level display data selection
FM terminal function selection
Frequency monitoring reference
Current monitoring reference
Restart coasting time
Restart cushion time
10
Used to set the upper and lower limits of the output frequency.
Used to match the inverter outputs (voltage, frequency) to the motor rating.
Set these parameters when using the terminals to change the running speeds
preset in the parameters.
Used to set the acceleration and deceleration times.
Used to select the optimum output characteristic that matches the application
and load characteristics.
Used to set the base voltage (e.g. motor's rated voltage).
Used to choose the monitoring and output signals.
Used to set the frequency and current values, which are referenced, for the
level meter.
Used to perform automatic restart operation after instantaneous power failure
or commercial power supply-inverter switchover.
47
3
Simple mode parameter
OPERATION
Parameter
Number
Name
60
Intelligent mode selection
65
Retry selection
68
69
Stall prevention operation reduction
starting frequency
Number of retries at alarm
occurrence
Retry waiting time
Retry count display erasure
71
Applied motor
72
PWM frequency selection
73
0-5V/0-10V selection
74
Filter time constant
75
Reset selection/disconnected PU
detection/PU stop selection
76
Alarm code output selection
77
Parameter write disable selection
66
67
79
160
180
181
182
183
184
185
186
190
191
192
193
194
195
240
244
900
901
902
903
904
905
Reverse rotation prevention
selection
Operation mode selection
User group read selection
RL terminal function selection
RM terminal function selection
RH terminal function selection
RT terminal function selection
AU terminal function selection
JOG terminal function selection
CS terminal function selection
RUN terminal function selection
SU terminal function selection
IPF terminal function selection
OL terminal function selection
FU terminal function selection
ABC terminal function selection
Soft-PWM setting
Cooling fan operation selection
FM terminal calibration
AM terminal calibration
Frequency setting voltage bias
Frequency setting voltage gain
Frequency setting current bias
Frequency setting current gain
990
Buzzer control
78
Application
Used to cause the inverter to automatically set the appropriate parameters
and perform operation.
Used to select the alarm whose occurrence will cause the inverter to reset and
retry automatically.
Used to set the number of retries to be made when an alarm occurs.
Used to set the number of retries and the waiting time.
Used to set the thermal characteristic of the electronic overcurrent protection
according to the motor used.
Used to change the motor tone.
When using the voltage-input signal to perform operation, set the
specifications of the frequency setting signal input to across terminals 2-5.
Used to set the input section built-in filter constant of an external voltage or
current frequency setting signal.
Used to choose the reset selection, disconnected PU detection and PU stop
selection functions.
Used to output a 4-bit digital signal from the open collector output terminals as
the definition of an alarm that has occurred.
Used to enable or disable the write of various parameters to prevent the
parameters from being rewritten by accidental operation.
Used to prevent reverse operation trouble due to the false input of the start
signal.
Use to choose the operation mode of the inverter.
Used to read the values of the basic parameters or all parameters.
Used to choose and assign the functions of the input terminals.
Used to choose and assign the functions of the output terminals.
Used to change the motor tone.
Used to control the operation of the cooling fan incorporated in the inverter.
Used to calibrate the meters connected to terminals FM-SD and AM-5.
Used to set the magnitude (slope) of the output frequency as desired relative
to the frequency setting signal (0 to 5V, 0 to 10V or 4 to 20mA DC).
Used to produce or mute the operational sound generated when you press the
keys of the operation panel and parameter unit.
48
OPERATION
Main parameter settings
The main parameter settings are given below. For more information, refer to "CHAPTER 4 PARAMETERS".
(1) Setting of maximum frequency (Pr. 1 "maximum frequency")
Set this parameter to define the upper limit of the output frequency.
You can limit the maximum frequency within the range of the frequency set in Pr. 903 or Pr. 905 "frequency
setting voltage (current) gain", but change the setting only when necessary.
Factory setting: 60Hz
(2) Setting of minimum frequency (Pr. 2 "minimum frequency")
Set this parameter to define the lower limit of the output frequency.
When you have set the minimum frequency, simply switching the start signal on runs the motor at the preset
minimum frequency if the frequency setting is 0Hz. (At this time, the output starts from the starting frequency
value for acceleration.)
Factory setting: 0Hz
Simple mode parameter
3.3.2
(3) Setting of acceleration and deceleration times (Pr. 7 "acceleration time", Pr. 8
"deceleration time", Pr. 44 "second acceleration/deceleration time", Pr. 45
"second deceleration time")
Change this time to perform acceleration/deceleration operation at any other time than those factory-set.
Parameter
Pr. 7 "acceleration time"
Pr. 8 "deceleration time"
Pr. 44 "second acceleration/deceleration time"
Pr. 45 "second deceleration time"
Factory Setting
15 seconds or longer
30 seconds or longer
5 seconds
9999 (as set in Pr. 44)
(4) Setting of electronic overcurrent protection (Pr. 9 "electronic thermal O/L relay")
The factory setting is the rated current value of the inverter.
When changing the setting, set the current given for 50Hz on the motor rating plate.
Note: The operation characteristic is based on that of the Mitsubishi standard squirrel-cage motor. Since
this parameter is not applicable to a special motor, use an external thermal relay etc. to protect such a
motor.
(You can select a constant-torque motor with Pr. 71 "applied motor".)
49
3
OPERATION
Simple mode parameter
(5) Selection of load pattern (Pr. 14 "load pattern selection")
Used to select the output characteristic (V/F characteristic) according to the application and load
characteristics.
Application
Setting
For constant torque load
(e.g. conveyor, cart)
0
For variable torque load
(fan, pump)
1
(Factory setting)
Note: When the RT terminal is ON, the second control functions (second acceleration/deceleration, second
torque boost, second base frequency) are selected.
(6) When using a voltage input signal to perform operation (Pr. 73 "0 to 5V, 0 to 10V
selection")
When using a voltage-input signal to perform operation, set the specifications of the frequency setting voltage
signal entered to across terminals 2-5.
1) For 0 to 5VDC
Set "1" (factory setting) in Pr. 73.
2) For 0 to 10VDC
Set "0" in Pr. 73.
• When using a current input signal to perform operation
When using a current input signal to perform operation, input the signal to across terminals 4-5 and short
terminals AU-SD.
(7) Setting of frequency setting voltage (current) gain (highest output frequency)
(Pr. 903 "frequency setting voltage gain", Pr. 905 "frequency setting current
gain")
• For voltage signal: Pr. 903 "frequency setting voltage gain"
• For current signal: Pr. 905 "frequency setting current gain"
When performing operation at any frequency higher than the following factory setting, change the
corresponding parameter setting:
Parameter
Factory Setting
Pr. 903 "frequency setting voltage gain"
60Hz at 5V DC
Pr. 905 "frequency setting current gain"
60Hz at 20mADC
When using the parameter unit to perform operation, the highest output frequency is the maximum
frequency (factory-set to 60Hz). (Refer to Pr. 1 "maximum frequency".)
Note: When connecting a frequency meter across terminals FM-SD to monitor the running frequency, you
must change the factory setting of Pr. 55 "frequency monitoring reference" to the highest frequency
since the output of the FM terminal will be saturated at an output frequency of 100Hz or higher.
50
3.4 Operation
OPERATION
3.4.1
Pre-operation checks
Before starting operation, check the following:
• Safety
Perform test operation after making sure that safety is ensured if the machine should become out of control.
• Machine
Make sure that the machine is free of damage.
• Parameters
Set the parameter values to match the operating machine system environment.
• Test operation
Perform test operation and make sure that the machine operates safely under light load at a low frequency.
After that, start operation.
3
51
OPERATION
3.4.2
External operation mode (Operation using external input signals)
(1) Operation at 60Hz
Step
1
Description
Power-on → Operation mode check
Switch power on and make sure that the operation command indication "EXT" is lit.
(If it is not lit, switch to the external operation mode. For operation mode changing,
refer to page 43.)
Image
ON
FR-DU04
CONTROL PANEL
Hz
A
V
MON
Start
Turn on the start switch (STF or STR).
The operation status indication "FWD" or "REV" flickers.
2
EXT
PU
REV
FWD
Forward
rotation Reverse
rotation
Note: The motor does not start if both the forward and reverse
rotation switches are turned on.
If both switches are turned on during operation, the motor
decelerates to a stop.
FR-DU04
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
Acceleration → Constant speed
Slowly turn the potentiometer (frequency setting potentiometer) full clockwise.
The frequency shown on the display increases gradually to 60.00Hz.
3
FR-DU04
CONTROL PANEL
Hz
A
V
MON
4
EXT
PU
REV
FWD
Deceleration
Slowly turn the potentiometer (frequency setting potentiometer) full counterclockwise.
The frequency shown on the display decreases gradually to 0.00Hz.
The motor stops running.
FR-DU04
CONTROL PANEL
Hz
A
V
MON
Stop
Turn off the start switch (STF or STR).
Forward
rotation
EXT
REV
PU
FWD
Reverse
rotation
Stop
5
OFF
(2) External jog operation
Keep the start switch (STF or STR) on to perform operation, and switch it off to stop.
1) Set Pr. 15 "jog frequency" and Pr. 16 "jog acceleration/deceleration time".
2) Select the external operation mode.
3) Switch on the jog signal. Keep the start switch (STF or STR) on to perform operation.
52
OPERATION
3.4.3 PU operation mode
(Operation using the operation panel (FR-DU04))
(1) Operation at 60Hz
While the motor is running, repeat the following steps 2 and 3 to vary the speed:
Step
1
Description
Power-on → Operation mode check
Switch power on and make sure that the operation command indication "PU" is lit.
(If it is not lit, switch to the PU operation mode. For operation mode changing, refer to
page 102.)
Image
ON
REV
2
Running frequency setting
Set the running frequency to 60Hz.
First, press the [MODE] key to select the frequency setting mode. Then, press the
[UP/DOWN] key to change the setting, and press the [SET] key to write the
frequency.
(or)
FR-DU04
3
Stop
Press the [STOP] key.
The motor is decelerated to a stop.
CONTROL PANEL
Hz
A
V
MON
Start
Press the [FWD] or [REV] key.
The motor starts running. The monitoring mode is automatically selected and the
output frequency is displayed.
FWD
FWD
(or)
EXT
PU
REV
FWD
REV
FWD
REV
FR-DU04
CONTROL PANEL
Hz
A
V
4
MON
EXT
PU
REV
FWD
(2) PU jog operation
Hold down the [FWD] or [REV] key to perform operation, and release it to stop.
1) Set Pr. 15 "jog frequency" and Pr. 16 "jog acceleration/deceleration time".
2) Select the PU jog operation mode.
3) Hold down the [FWD] or [REV] key to perform operation.
(If the motor remains stopped, check Pr. 13 "starting frequency". The motor will not start if its setting is lower
than the starting frequency.)
53
3
OPERATION
3.4.4
Combined operation mode
(Operation using the external input signals and PU)
When entering the start signal from outside the inverter and setting the running frequency from the PU
(Pr. 79 = 3)
The external frequency setting signals and the PU's FWD, REV and STOP keys are not accepted. (Note)
Step
Description
Image
Power-on
Switch power on.
ON
1
2
Operation mode selection
Set "3" in Pr. 79 "operation mode selection".
The combined operation mode is selected and the operation status indication "EXT"
and "PU" are lit.
Start
Turn on the start switch (STF or STR).
3
Flicker
Forward
rotation
Note: The motor does not start if both the forward and reverse rotation switches are
turned on. If both switches are turned on during operation, the motor
decelerates (when Pr. 250 = "9999") to a stop.
Reverse
rotation
FR-DU04
Hz
A
V
ON
MON
Running frequency setting
Using the parameter unit, set the running frequency to 60Hz.
The operation command indication "REV" or "FWD" flickers.
• Select the frequency setting mode and make step setting.
4
Note: Step setting is the way of changing the frequency consecutively by pressing
the [UP/DOWN] key.
Hold down the [UP/DOWN] key to change the frequency.
Stop
Turn off the start switch (STF or STR).
The motor stops running.
<Step setting>
FR-DU04
CONTROL PANEL
Hz
A
V
5
MON
Note: The stop key is made valid when the Pr. 75 "PU stop selection" value is set to 14 ∼ 17.
54
CONTROL PANEL
EXT
PU
REV
FWD
EXT
PU
REV
FWD
CHAPTER 4
PARAMETERS
This chapter explains the "parameters" of this product.
Always read the instructions before using the equipment.
Chapter 1
4.1 Parameter List ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 55
4.2 Parameter Function Details・・・・・・・・・・・・・・・・・・・・・ 61
Chapter 2
Note: By making parameter settings, you can change the functions of contact input
terminals RL, RM, RH, RT, AU, JOG, CS and open collector output terminals RUN,
SU, IPF, OL, FU. Therefore, signal names corresponding to the functions are used
in the description of this chapter (except in the wiring examples). Note that they are
not terminal names.
Note: The settings in brackets refer to the “EC” version default settings.
Chapter 3
Chapter 4
Chapter 5
Chapter 6
Chapter 7
4.1 Parameter List
PARAMETERS
Parameter list
All parameters available when the Pr. 160 "user group read selection" value is "0" are indicated below.
The parameters available when the Pr. 160 value is "9999" (Simple mode parameter) are marked in the
Parameter Number column with a circle ({).
Function
Parameter
Number
Setting Range
Factory
Minimum
Refer
Setting
Setting
To
[EC,CH Version]
Increments 〈EC Version only〉〉 Page:
{
Torque boost
Maximum frequency
Minimum frequency
0 to 30%
0 to 120Hz
0 to 120Hz
0.1%
0.01Hz
0.01Hz
{
3
Base frequency
0 to 120Hz
0.01Hz
{
{
4
5
6
Multi-speed setting (high speed)
Multi-speed setting (middle speed)
Multi-speed setting (low speed)
{
7
Acceleration time
{
8
Deceleration time
0 to 120Hz
0 to 120Hz
0 to 120Hz
0 to 3600 s/
0 to 360 s
0 to 3600 s/
0 to 360 s
0.01Hz
0.01Hz
0.01Hz
0.1 s/
0.01 s
0.1 s/
0.01 s
{
9
Electronic thermal O/L relay
0 to 3600A
0.1A
{
10
11
12
13
14
15
DC injection brake operation frequency
DC injection brake operation time
DC injection brake voltage
Starting frequency
Load pattern selection
Jog frequency
16
Jog acceleration/deceleration time
17
MRS input selection
0 to 120Hz, 9999
0 to 10 s, 8888
0 to 30%
0 to 60Hz
0, 1
0 to 120Hz
0 to 3600 s/
0 to 360 s
0,2
0.01Hz
0.1 s
0.1%
0.01Hz
1
0.01Hz
0.1 s/
0.01 s
1
19
Base frequency voltage
0 to 1000V, 8888, 9999
0.1V
1 to 120Hz
0.01Hz
0,1
{
Basic functions
Name
0
1
2
{
{
{
{
{
{
{
20
Standard operation functions
Parameter List
4.1.1
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
Acceleration/deceleration reference
frequency
Acceleration/deceleration time
increments
Stall prevention operation level
Stall prevention operation level at double
speed
Multi-speed setting (speed 4)
Multi-speed setting (speed 5)
Multi-speed setting (speed 6)
Multi-speed setting (speed 7)
Multi-speed input compensation
Acceleration/deceleration pattern
Regenerative function selection
Frequency jump 1A
Frequency jump 1B
Frequency jump 2A
Frequency jump 2B
Frequency jump 3A
Frequency jump 3B
Speed display
Automatic torque boost
Automatic torque boost operation starting
current
1%
60Hz
0Hz
60Hz
[50Hz]
60Hz
30Hz
10Hz
61
62
62
64
64
64
15 s
65
30 s
65
63
Rated
output
current
3Hz
0.5 s
1%
0.5Hz
1
5Hz
67
67
67
68
69
70
0.5 s
70
0
9999
〈8888〉
60Hz
[50Hz]
71
1
0
65
0 to 150%, 9999
0.1%
120%
72
0 to 200%, 9999
0.1%
9999
72
0 to 120Hz, 9999
0 to 120Hz, 9999
0 to 120Hz, 9999
0 to 120Hz, 9999
0, 1
0, 1, 2, 3
0, 2
0 to 120Hz, 9999
0 to 120Hz, 9999
0 to 120Hz, 9999
0 to 120Hz, 9999
0 to 120Hz, 9999
0 to 120Hz, 9999
0,1 to 9998
0 to 200
0.01Hz
0.01Hz
0.01Hz
0.01Hz
1
1
1
0.01Hz
0.01Hz
0.01Hz
0.01Hz
0.01Hz
0.01Hz
1
0.1%
9999
9999
9999
9999
0
0
0
9999
9999
9999
9999
9999
9999
0
0
64
64
64
64
73
74
75
76
76
76
76
76
76
77
78
0 to 3600A
0.1A
0
78
55
66
63
65
Customer
Setting
Parameter
Number
41
42
Output
terminal
functions
Function
43
Up-to-frequency sensitivity
Output frequency detection
Output frequency detection for reverse
rotation
0 to 100%
0 to 120Hz
0.1%
0.01Hz
10%
6Hz
78
79
0 to 120Hz, 9999
0.01Hz
9999
79
0.1 s/0.01 s
5s
65
0.1 s/0.01 s
9999
65
0.1%
0.01Hz
0.1%
9999
9999
120%
61
63
80
0 to 120Hz, 9999
0.01
0
80
0 to 120Hz
0, 5, 6, 8, 10 to 14, 17, 20,
23, 24, 25, 100
0 to 3, 5, 6, 8, 10 to 14, 17
1 to 3, 5, 6, 8, 10 to 14, 17,
21
0.01Hz
30Hz
79
1
0
81
1
1
81
1
1
81
0 to 3600 s/
0 to 360 s
0 to 3600 s/0 to 360 s,
9999
0 to 30%, 9999
0 to 120Hz, 9999
0 to 150%
45
Second deceleration time
46
47
48
50
Second torque boost
Second V/F (base frequency)
Second stall prevention operation current
Second stall prevention operation
frequency
Second output frequency detection
{
52
DU/PU main display data selection
{
53
PU level display data selection
{
54
FM terminal function selection
{
55
Frequency monitoring reference
0 to 120Hz
0.01Hz
{
56
Current monitoring reference
0 to 3600A
0.1A
Rated
output
current
83
{
57
Restart coasting time
0 to 30 s, 9999
0.1 s
9999
84
{
58
Restart cushion time
0 to 60 s
0.1 s
1.0 s
84
59
Remote setting function selection
0, 1, 2
1
0
86
{
60
61
62
63
65
0, 3, 4, 9
0 to 3600A, 9999
0 to 150%, 9999
0 to 150%, 9999
0 to 5
1
0.1A
0.1%
0.1%
1
88
89
89
89
90
{
66
0 to 120Hz
0.01Hz
{
67
Intelligent mode selection
Reference I for intelligent mode
Ref. I for intelligent mode accel.
Ref. I for intelligent mode decel.
Retry selection
Stall prevention operation level reduction
starting frequency
Number of retries at alarm occurrence
{
68
Retry waiting time
{
{
69
70
71
72
73
74
{
75
Retry count display erasure
Special regenerative brake duty
Applied motor
PWM frequency selection
0-5V/0-10V selection
Filter time constant
Reset selection/disconnected PU
detection/PU stop selection
Alarm code output selection
Parameter write disable selection
Reverse rotation prevention selection
Operation mode selection
V/F1 (first frequency)
V/F1 (first frequency voltage)
V/F2 (second frequency)
V/F2 (second frequency voltage)
V/F3 (third frequency)
V/F3 (third frequency voltage)
V/F4 (fourth frequency)
Second functions
Display functions
Automatic
restart
functions
Setting Range
Second acceleration/deceleration time
49
Additional
function
Operation selection functions
Name
44
{
{
{
{
76
77
{ 78
{ 79
100
101
102
103
104
105
106
{
{
5-point flexible V/F
characteristics
Factory
Minimum
Refer
Setting
Setting
To
[EC,CH Version]
Increments 〈EC Version only〉〉 Page:
60Hz
[50Hz]
83
0 to 10,101 to 110
1
0
9999
9999
9999
0
60Hz
[50Hz]
0
0 to 10 s
0.1 s
1s
90
0
0 to 100%
0, 1, 2
0, 1, 2
0 to 5, 10 to 15
0 to 8

0.1%
1
1
1
1
0
0%
0
1
1
1
90
75
92
93
94
95
0 to 3, 14 to 17
1
14
95
0, 1, 2
0, 1, 2
0, 1, 2
0 to 4, 6 to 8
0 to 120Hz, 9999
0 to 1000V
0 to 120Hz, 9999
0 to 1000V
0 to 120Hz, 9999
0 to 1000V
0 to 120Hz, 9999
1
1
1
1
0.01Hz
0.1V
0.01Hz
0.1V
0.01Hz
0.1V
0.01Hz
0
0
0
0
9999
0
9999
0
9999
0
9999
97
98
99
100
103
103
103
103
103
103
103
56
Customer
Setting
Parameter List
PARAMETERS
72
90
4
Parameter
Number
5-point flexible V/F
characteristics
107
V/F4 (fourth frequency voltage)
108
V/F5 (fifth frequency)
109
V/F5 (fifth frequency voltage)
117
118
Station number
Communication speed
119
Stop bit length/data length
120
121
122
123
124
128
129
130
131
132
133
134
Parity check presence/absence
Number of communication retries
Communication check time interval
Waiting time setting
CR, LF presence/absence selection
PID action selection
PID proportional band
PID integral time
Upper limit
Lower limit
PID action set point for PU operation
PID differential time
Commercial power supply-inverter
switch-over sequence output terminal
selection
MC switch-over interlock time
Start waiting time
Commercial power supply-inverter
switch-over selection at alarm occurrence
Automatic inverter-commercial power
supply switch-over frequency
Backlash acceleration stopping
frequency (Note 1)
Backlash acceleration stopping time
(Note 1)
Backlash deceleration stopping
frequency (Note 1)
Backlash deceleration stopping time
(Note 1)
Commercial power supplyinverter switch-over
PID control
Communication functions
Function
135
136
137
138
139
Backlash
140
141
142
Display
143
Additional
functions
Parameter List
PARAMETERS
Name
Setting Range
Factory
Minimum
Refer
Setting
Setting
To
[EC,CH Version]
Increments 〈EC Version only〉〉 Page:
0 to 1000V
0.1V
0
103
0 to 120Hz, 9999
0.01Hz
9999
103
0 to 1000V
0.1V
0
103
0 to 31
48, 96, 192
0, 1 (data length 8)
10, 11 (data length 7)
0, 1, 2
0 to 10, 9999
0, 0.1 to 999.8 s, 9999
0 to 150ms, 9999
0,1,2
10, 11, 20, 21
0.1 to 1000%, 9999
0.1 to 3600 s, 9999
0 to 100%, 9999
0 to 100%, 9999
0 to 100%
0.01 to 10.00 s, 9999
1
1
0
192
104
104
1
1
104
1
1
0.1 s
1ms
1
0.1%
0.1 s
0.1%
0.1%
0.01%
0.01 s
2
1
0 〈9999〉
9999
1
10
100%
1s
9999
9999
0%
9999
104
104
104
104
104
115
115
115
115
115
115
115
0, 1
1
0
122
0 to 100.0 s
0 to 100.0 s
0.1 s
0.1 s
1.0 s
0.5 s
122
122
0, 1
1
0
122
0 to 60.00Hz, 9999
0.01Hz
9999
122
0 to 120Hz
0.01Hz
1.00Hz
74
0 to 360 s
0.1 s
0.5 s
74
0 to 120Hz
0.01Hz
1.00Hz
74
0 to 360 s
0.1 s
0.5 s
74
0, 2, 4, 6, 8, 10, 102,
104, 106, 108, 110
1
4
77

144
Speed setting switch-over
148
Stall prevention level at 0V input
0 to 150%
0.1%
120%
72
149
Stall prevention level at 10V input
0 to 150%
0.1%
150%
72
57
Customer
Setting
152
Zero current detection level
153
Zero current detection period
158
AM terminal function selection
User group read selection
0.1%
5.0%
128
0 to 1 s
0.01 s
0.5 s
128
0, 1
1
1
72
0, 10
0 to 31, 100, 101
0 to 25 s, 9999
1 to 3, 5 to 6, 8,
10 to 14, 17, 21
1
1
0.1 s
0
0
0
129
129
131
1
1
81
0, 1, 10, 11, 9999
1
9999
132
0, 1, 10, 11
1
0
84
0 to 20 s
0.1 s
0s
84
0 to 100%
0.1%
0%
84
165
Restart stall prevention operation level
0 to 150%
0.1%
120%
84
Automatic restart
after instantaneous
power failure
First cushion voltage for restart
Sub
functions
164
Initial
monitor
First cushion time for restart
170
173
User group 1 registration
174
User group 1 deletion
Terminal assignment functions
0 to 200.0%
163
168
Customer
Setting
Parameters set by the manufacturer. Do not set.
169
Watt-hour meter clear
0

0
133
171
Actual operation hour meter clear
0

0
133
175
User group 2 registration
176
User group 2 deletion
{ 180
{ 181
{ 182
{ 183
{ 184
{ 185
{ 186
{ 190
{ 191
{ 192
{ 193
{ 194
{ 195
Additional
function
[EC,CH Version]
〈EC Version only〉〉
Automatic restart after instantaneous
power failure selection
162
User functions
Additional
function
155
156
157
{ 160
Setting Range
Refer
To
Page:
Name
Voltage reduction selection during stall
prevention operation
RT activated condition
Stall prevention operation selection
OL signal waiting time
154
Factory
Setting
Minimum
Setting
Increments
Parameter List
Parameter
Number
Sub functions
Function
Current
detection
PARAMETERS
199
RL terminal function selection
RM terminal function selection
RH terminal function selection
RT terminal function selection
AU terminal function selection
JOG terminal function selection
CS terminal function selection
RUN terminal function selection
SU terminal function selection
IPF terminal function selection
OL terminal function selection
FU terminal function selection
ABC terminal function selection
0 to 999
1
0
132
0 to 999, 9999
1
0
132
0 to 999
1
0
132
0 to 999, 9999
1
0
132
0 to 5, 8, 10, 11,
13 to 19, 25, 26,
98 to 105, 108,
110, 111, 113 to 116,
125, 126, 198, 199,
9999
1
1
1
1
1
1
1
1
1
1
1
1
1
0
1
2
3
4
5
6
0
1
2
3
4
99
133
133
133
133
133
133
133
135
135
135
135
135
135
0 to 999, 9999
1
0
137
0 to 7, 10 to 14, 16,
9999
User's initial value setting
58
4
[EC,CH Version]
〈EC Version only〉〉
Soft-PWM setting
0, 1
1
1
93
Cooling fan operation selection
0, 1
1
0
138
251
Output phase failure protection selection
0, 1
1
1
138
252
Override bias
0 to 200%
0.1%
50%
139
253
Override gain
0 to 200%
0.1%
150%
139
571
Start holding time
0 to 10 sec, 9999
0, 1sec
9999
133






140
140
142
{ 240
{ 244
Additional function
Sub
functions
Setting Range
Refer
To
Page:
Parameter
Number
Calibration functions
Factory
Setting
Minimum
Setting
Increments
Function
Additional
function
Parameter List
PARAMETERS
{ 900
{ 901
Name
{ 902
FM terminal calibration
AM terminal calibration
Frequency setting voltage bias
0 to 10V
0 to 60Hz
0.01Hz
0V
0Hz
{ 903
Frequency setting voltage gain
0 to 10V
1 to 400Hz
0.01Hz
5V
60Hz
〈50Hz〉
142
0.01Hz
4
mA
20
mA
0Hz
142
60Hz
〈50Hz〉
142
{ 904
Frequency setting current bias
{ 905
Frequency setting current gain
{ 990
Buzzer control
0 to 20mA
0 to 20mA
0 to 60Hz
1 to 400Hz
0, 1
0.01Hz
1
1
Customer
Setting
144
Note: 1. Can be accessed when Pr. 29 = 3.
2. The half-tone screened parameters allow their settings to be changed during operation if 0 (factory
setting) has been set in Pr. 77. (Note that the Pr. 72 and Pr. 240 settings cannot be changed
during external operation.)
59
PARAMETERS
4.1.2
List of Parameters Classified by Purposes of Use
Set the parameters according to the operating conditions. The following list indicates purposes of use and
parameters.
Parameter Numbers
Parameter numbers which must be set
Switch-over to optimum excitation control operation
Adjustment of acceleration/deceleration time and
pattern
Selection of optimum output characteristic for load
characteristic
Limit of output frequency
Operation over 60Hz
Adjustment of frequency setting signal and output
Adjustment of motor output torque
Adjustment of brake operation
Multi-speed operation
Pr. 7, Pr. 8, Pr. 20, Pr. 21, Pr. 160
Pr. 3, Pr. 14, Pr. 19, Pr. 60
Pr. 1, Pr. 2
Pr. 903, Pr. 905
Pr. 73, Pr. 74, Pr. 902 to Pr. 905
Pr. 0
Pr. 10, Pr. 11, Pr. 12
Pr. 1, Pr. 2, Pr. 4, Pr. 5, Pr. 6, Pr. 15, Pr. 24, Pr. 25, Pr. 26, Pr. 27,
Pr. 160
Pr. 15, Pr. 16
Pr. 31, Pr. 32, Pr. 33, Pr. 34, Pr. 35, Pr. 36
Pr. 57, Pr. 58
Pr. 60
Calibration of frequency meter
Adjustment of digital frequency meter
Display of speed, etc.
Clearing of inverter's actual operation time
Alarm code output selection
Pr. 54, Pr. 55, Pr. 56, Pr. 158, Pr. 160, Pr. 900, Pr. 901
Pr. 54, Pr. 55, Pr. 56, Pr. 900
Pr. 37, Pr. 52, Pr. 53, Pr. 160
Pr. 171
Pr. 76
Function rewrite prevention
Reverse rotation prevention
To group parameters
To set initial values for parameters
Pr. 77
Pr. 78
Pr. 160, Pr. 173 to Pr. 176
Pr. 199
Assignment of input terminal functions
Assignment of output terminal functions
To increase cooling fan life
Motor overheat protection
Automatic restart after alarm stop
Selection of key beep
Inverter reset selection
Pr. 180 to Pr. 186
Pr. 190 to Pr. 195
Pr. 244
Pr. 9, Pr. 71
Pr. 65, Pr. 67, Pr. 68, Pr. 69
Pr. 990
Pr. 75
Others
Related to application
operation
To make backlash compensation
To suppress noise
Pr. 135 to Pr. 139, Pr. 160, Pr. 180 to Pr. 186,
Pr. 190 to Pr. 195
Pr. 42, Pr. 160, Pr. 190 to Pr. 195
Pr. 28, Pr. 73
Pr. 0, Pr. 3, Pr. 7, Pr. 8, Pr. 44, Pr. 45, Pr. 46, Pr. 47
Pr. 100 to Pr. 109
Pr. 117 to Pr. 124, Pr. 160
Pr. 73, Pr. 79, Pr. 128 to Pr. 134, Pr. 160,
Pr. 180 to Pr. 186, Pr. 190 to Pr. 195
Pr. 140 to Pr. 143
Pr. 72, Pr. 240
Related to
monitoring
Jog operation
Frequency jump operation
Automatic restart after instantaneous power failure
Optimum acceleration/deceleration within continuous
rating range
To perform commercial power supply ↔ inverter
switch-over operation
Timing of magnetic brake operation
Reversible operation according to analog signal polarity
Sub-motor operation
To make desired output characteristics
Operation via communication with personal computer
Pr. 14, Pr. 60
Related to misoperation
prevention
Related to operation
Purpose of Use
Operation under PID control
60
4
4.2 Parameter Function Details
PARAMETERS
4.2.1
Torque boost (Pr. 0, Pr. 46)
Related parameters
Pr. 0 "torque boost"
Pr. 3 "base frequency"
Pr. 19 "base frequency voltage"
Pr. 71 "applied motor"
Pr. 180 to Pr. 186
(input terminal function selection)
Pr. 46 "second torque boost"
You can compensate for a voltage drop in the low frequency
range to improve motor torque reduction in the low speed range.
z Motor torque in the low-frequency range can be adjusted to the load to increase the starting motor torque.
z You can select any of the starting torque boosts by terminal switching.
Factory
Setting
1%
46
9999
Setting Range
Remarks
0 to 30%

0 to 30%, 9999
9999: Function invalid
100%
Output
voltage
Parameter
Number
0
Pr.0 Setting
Pr.46 range
0 Output
frequency (Hz)
Base frequency
<Setting>
z Assuming that the base frequency voltage is 100%, set the 0Hz voltage in %.
z Pr. 46 is valid when the RT signal is on.
Note: 1. Increase the setting when the inverter-to-motor distance is long or motor torque in the low-speed
range is insufficient, for example. A too large setting may result in an overcurrent trip.
2. When the RT signal is on, the other second functions such as second acceleration/deceleration
time are also selected.
3. When terminal assignment is changed using Pr. 180 to Pr. 186 during use of the second functions,
the other functions may be affected. Check the functions of the corresponding terminals before
making setting.
61
PARAMETERS
4.2.2
Output frequency range (Pr. 1, Pr. 2)
Pr. 1 "maximum frequency"
Related parameters
Pr. 13 "starting frequency"
Pr. 903 "frequency setting voltage gain"
Pr. 905 "frequency setting current gain"
Pr. 2 "minimum frequency"
Used to clamp the upper and lower limits of the output frequency.
z Can be used to set the upper and lower limits of motor speed.
Parameter
Number
1
Factory
Setting
60Hz
2
0Hz
Setting Range
Output frequency
(Hz)
0 to 120Hz
0 to 120Hz
Pr.1
Frequency setting
Pr.2
0
5,10V
20mA, etc.
<Setting>
• Use Pr. 1 to set the upper limit of the output frequency. If the frequency of the frequency command entered is
higher than the setting, the output frequency is clamped at the maximum frequency.
• Use Pr. 2 to set the lower limit of the output frequency.
Note: When the frequency setting analog signal is used to run the motor beyond 60Hz, change the Pr. 903
and Pr. 905 values. If Pr. 1 is only changed, the motor cannot run beyond 60Hz.
CAUTION
When the Pr. 2 setting is higher than the Pr. 13 value, note that the motor will run at the
set frequency by merely switching the start signal on, without entering the command
frequency.
62
4
PARAMETERS
4.2.3
Base frequency, base frequency voltage (Pr. 3, Pr. 19, Pr. 47)
Pr. 3 "base frequency"
Related parameters
Pr. 19 "base frequency voltage"
Pr. 71 "applied motor"
Pr. 180 to Pr. 186 (input terminal
function selection)
Pr. 47 "second V/F (base frequency)
Used to adjust the inverter outputs (voltage, frequency) to the motor rating.
z When running a standard motor, generally set the frequency rating to 60Hz. When running the motor using
the commercial power supply-inverter switch-over, set the base frequency to the same value as the power
supply frequency.
Factory
Setting
60Hz 〈50Hz〉
19
9999 〈8888〉
0 to 1000V, 8888,9999
47
9999
0 to 120Hz, 9999
Output voltage
Parameter
Number
3
Setting Range
Remarks
0 to 120Hz
8888: 95% of power supply voltage
9999: Same as power supply voltage
9999: Function invalid
Pr.19
Output frequency (Hz)
Pr.3
Pr.47
<Setting>
• Use Pr. 3 and Pr. 47 to set the base frequency (rated motor frequency).
• Pr. 47 is valid when the RT signal is on.
• Use Pr. 19 to set the base voltage (e.g. rated motor voltage).
Note: 1. Set the base frequency to 60Hz when using a constant-torque motor.
2. When "2" (5-point flexible V/F characteristics) is set in Pr. 71, the Pr. 47 setting is made invalid.
3. When the RT signal is on, the other second functions such as second acceleration/deceleration
time are also selected.
4. When terminal assignment is changed using Pr. 180 to Pr. 186 during use of the second functions,
the other functions may be affected. Check the functions of the corresponding terminals before
making setting.
63
PARAMETERS
4.2.4
Multi-speed operation (Pr. 4 to Pr. 6, Pr. 24 to Pr.27)
Pr. 4 "3-speed setting (high speed)"
Related parameters
Pr. 1 "maximum frequency"
Pr. 2 "minimum frequency"
Pr. 15 "jog frequency"
Pr. 28 "multi-speed input
compensation"
Pr. 29 "acceleration/deceleration
pattern"
Pr. 79 "operation mode selection"
Pr. 180 to Pr. 186 (input terminal
function selection)
Pr. 5 "3-speed setting (middle speed)"
Pr. 6 "3-speed setting (low speed)"
Pr. 24 to Pr. 27 "multi-speed setting
(speeds 4 to 7)"
Used to preset the running speeds in parameters and switch between them using terminals.
z Any speed can be selected by switching on-off the contact signal (RH, RM, RL or REX signal).
z By using these functions with jog frequency (Pr. 15), maximum frequency (Pr. 1) and minimum frequency
(Pr. 2), up to 10 speeds can be set.
z Valid in the external operation mode or PU/external combined operation mode (Pr. 79 = 3 or 4).
Factory Setting
Setting Range
Remarks
60Hz
30Hz
10Hz
9999
0 to 120Hz
0 to 120Hz
0 to 120Hz
0 to 120Hz, 9999
9999: Not selected
Output frequency (Hz)
Parameter
Number
4
5
6
24 to 27
Speed 1
(high speed)
Speed 2
Speed 5
(middle speed)
Speed 6
Speed 4
Speed 3
(low speed)
Speed 7
Time
RH
RM
RL
ON
ON ON ON
ON
ON
ON
ON
ON ON
ON
<Setting>
• Set the running frequencies in the corresponding parameters.
Each speed (frequency) can be set as desired between 0 and 120Hz during inverter operation.
After the required multi-speed setting parameter has been read, the setting can be changed by pressing the
[UP/DOWN] key. (In this case, when you release the [UP/DOWN] key, press the [SET] key to store the set
frequency. When using the FR-PU04 (option), press the [WRITE] key.)
Note: 1. The multi-speed settings override the main speeds (across terminals 2-5, 4-5).
2. The multi-speeds can also be set in the PU or external operation mode.
3. For 3-speed setting, if two or three speeds are simultaneously selected, priority is given to the
frequency setting of the lower signal.
4. Pr. 24 to Pr. 27 settings have no priority between them.
5. The parameter values can be changed during operation.
6. When terminal assignment is changed using Pr. 180 to Pr. 186, the other functions may be
affected. Check the functions of the corresponding terminals before making setting.
64
4
PARAMETERS
4.2.5
Acceleration/deceleration time
(Pr. 7, Pr. 8, Pr. 20, Pr. 21, Pr. 44, Pr. 45)
Pr. 7 "acceleration time"
Related parameters
Pr. 8 "deceleration time"
Pr. 3 "base frequency"
Pr. 29 "acceleration/deceleration
pattern"
Pr. 20 "acceleration/deceleration reference
frequency"
Pr. 21 "acceleration/deceleration time increments"
Pr. 44 "second acceleration/deceleration time"
Pr. 45 "second deceleration time"
Used to set motor acceleration/deceleration time.
Set a larger value for a slower speed increase/decrease or a smaller value for a faster speed
increase/decrease.
7
8
20
21
44
Factory
Setting
15 s
30 s
60Hz 〈50Hz〉
0
5s
0 to 3600 s/0 to 360 s
0 to 3600 s/0 to 360 s
1 to 120Hz
0, 1
0 to 3600 s/0 to 360 s
45
9999
0 to 3600 s/0 to 360 s, 9999
Setting Range
Output frequency (Hz)
Parameter Number
Remarks
0: 0 to 3600 s, 1: 0 to 360 s
9999: Acceleration time =
deceleration time
Pr.20
Acceleration Pr.7
time
Pr.44
Running frequency
Time
Deceleration Pr.8
time
Pr.45
<Setting>
• Use Pr. 21 to set the acceleration/deceleration time and minimum setting increments:
Set value "0" (factory setting)............0 to 3600 seconds (minimum setting increments: 0.1 second)
Set value "1"......................................0 to 360 seconds (minimum setting increments: 0.01 second)
• Use Pr. 7 and Pr. 44 to set the acceleration time required to reach the frequency set in Pr. 20 from 0Hz.
• Use Pr. 8 and Pr. 45 to set the deceleration time required to reach 0Hz from the frequency set in Pr. 20.
• Pr. 44 and Pr. 45 are valid when the RT signal is on.
• Set "9999" in Pr. 45 to make the deceleration time equal to the acceleration time Pr. 44.
65
PARAMETERS
Note: 1. In S-shaped acceleration/deceleration pattern A (refer to page 74), the set time is a period
required to reach the base frequency set in Pr. 3.
• Acceleration/deceleration time calculation expression when the set frequency is the base
frequency or higher
4
T
5
2
t = 9 × (Pr.3)2 × f + 9 T
T: Acceleration/deceleration time setting (seconds)
f : Set frequency (Hz)
• Guideline for acceleration/deceleration time at the base frequency of 60Hz (0Hz to set
frequency)
Frequency setting (Hz)
Acceleration/
decelerationtime (seconds)
5
15
60
120
5
15
12
35
2. If the Pr. 20 setting is changed, the settings of calibration functions Pr. 903 and Pr. 905 (frequency
setting signal gains) remain unchanged. To adjust the gains, adjust calibration functions Pr. 903
and Pr. 905.
3. When the setting of Pr. 7, Pr. 8, Pr. 44 or Pr. 45 is "0", the acceleration/deceleration time is 0.04
seconds.
4. When the RT signal is on, the other second functions such as second torque boost are also
selected.
5. If the shortest acceleration/deceleration time is set, the actual motor acceleration/deceleration
time cannot be made shorter than the shortest acceleration/deceleration time determined by the
2
mechanical system's GD and motor torque.
4.2.6
Electronic overcurrent protection (Pr. 9)
Pr. 9 "electronic overcurrent protection"
Related parameter
Pr. 71 "applied motor"
Set the current of the electronic overcurrent protection to protect the motor from overheat. This feature
provides the optimum protective characteristics, including reduced motor cooling capability, at low speed.
Parameter
Number
9
Factory Setting
Setting Range
Rated output current*
0 to 3600A
*0.75K is set to 85% of the rated inverter current.
<Setting>
• Set the rated current [A] of the motor.
(Normally set the rated current value at 50Hz.)
• Setting of "0" makes the electronic overcurrent protection (motor protective function) invalid. (The inverter's
output transistor protective function is valid.)
• When using a Mitsubishi constant-torque motor, first set "1" in Pr. 71 to choose the 100% continuous torque
characteristic in the low-speed range. Then, set the rated motor current in Pr. 9.
Note: 1. When two or more motors are connected to the inverter, they cannot be protected by the
electronic overcurrent protection. Install an external thermal relay to each motor.
2. When a difference between the inverter and motor capacities is large and the setting is small, the
protective characteristics of the electronic overcurrent protection will be deteriorated. In this case,
use an external thermal relay.
3. A special motor cannot be protected by the electronic overcurrent protection. Use an external
thermal relay.
66
4
PARAMETERS
4.2.7
DC dynamic brake (Pr. 10 to Pr. 12)
Pr. 10 "DC dynamic brake operation frequency"
Related parameters
Pr. 11 "DC dynamic brake operation time"
Pr. 13 "starting frequency"
Pr. 71 "applied motor"
Pr. 12 "DC dynamic brake voltage"
By setting the stopping DC dynamic brake voltage (torque), operation time and operation starting frequency,
the stopping accuracy of positioning operation, etc. or the timing of operating the DC dynamic brake to stop
the motor is adjusted according to the load.
Factory
Setting
Setting Range
10
3Hz
0 to 120Hz, 9999
11
0.5 s
0 to 10 s, 8888
12
1%
0 to 30%
Remarks
Output frequency (Hz)
Parameter
Number
9999: Operated at or
below Pr. 13 value.
8888: Operated when
X13 signal switches on.
Operation
Pr.10 frequency
Time
DC dynamic
brake voltage
Pr.12
Operation
voltage
Time
Pr.11 Operation time
<Setting>
• Use Pr. 10 to set the frequency at which the DC dynamic brake application is started.
By setting "9999" in Pr. 10, the motor is decelerated to the frequency set in Pr. 13 and braked.
• Use Pr. 11 to set the period during when the brake is operated. By setting “8888” in Pr. 11, the DC dynamic
brake is operated while the X13 signal is on.
• Use any of Pr. 180 to Pr. 186 to assign the terminal used to input the X13 signal.
• Use Pr. 12 to set the percentage of the power supply voltage.
Note: 1. When Pr. 11 = "0 or 8888" or Pr. 12 = 0, DC dynamic brake operation cannot be performed.
CAUTION
Install a mechanical brake. No holding torque is provided.
67
PARAMETERS
4.2.8
Starting frequency (Pr. 13)
Related parameters
Pr. 13 "starting frequency"
Pr. 2 "minimum frequency"
You can set the starting frequency between 0 and 60Hz.
z Set the starting frequency at which the start signal is switched on.
Parameter
Number
Factory Setting
Setting Range
13
0.5Hz
0 to 60Hz
<Setting>
Setting range
Output frequency
(Hz)
60
Pr.13
Forward
rotation
0
Time
Frequency setting signal (V)
ON
Note: The inverter will not start if the frequency setting signal is less than the value set in Pr. 13 "starting
frequency".
For example, when 5Hz is set in Pr. 13, the motor will start running when the frequency setting signal
reaches 5Hz.
CAUTION
Note that when the Pr. 13 setting is less than the Pr. 2 value, merely turning on the start
signal will start the motor running at the set frequency if the command frequency is not
input.
4
68
PARAMETERS
4.2.9
Load pattern selection (Pr. 14)
Related parameters
Pr. 14 "load pattern selection"
Pr. 0 "torque boost"
Pr. 60 " intelligent mode selection"
Pr. 180 to Pr. 186
(input terminal function selection)
You can select the optimum output characteristic (V/F characteristic) for the application and load
characteristics.
Setting "4" (energy-saving mode) or "9" (optimum excitation control mode) in Pr. 60 "intelligent mode
selection" changes the output voltage.
Parameter
Number
14
Factory
Setting
1
Setting Range
0, 1
Pr.14=0
Pr.14=1
For variable-torque loads
(Fan, pump)
For constant-torque loads
(e.g. conveyor, cart)
Output
voltage
100%
Output
voltage
100%
Base frequency
Output frequency (Hz)
Setting
0
1
Output Characteristics
For constant-torque load
For variable-torque load
Base frequency
Output frequency (Hz)
Application
Conveyor, cart, etc.
Fan, pump
69
PARAMETERS
4.2.10 Jog operation (Pr. 15, Pr. 16)
Pr. 15 "jog frequency"
Related parameters
Pr. 20 "acceleration/deceleration
reference frequency"
Pr. 21 "acceleration/deceleration time
increments"
Pr. 79 "operation mode selection"
Pr. 180 to Pr. 186
(input terminal function selection)
Pr. 16 "jog acceleration/deceleration time"
In the external operation mode, jog operation can be started and stopped with the start signal (STF, STR) after
selection of the jog mode (JOG signal ON). In the PU operation mode, jog operation can also be performed
using the PU (FR-DU04/FR-PU04).
z Set the frequency and acceleration/deceleration time for jog operation
Parameter
Number
15
Factory
Setting
5Hz
16
0.5 s
Setting Range
Remarks
0 to 120Hz
0 to 3600 s
0 to 360 s
When Pr. 21 = 0
When Pr. 21 = 1
Output frequency (Hz)
Pr.20
Jog frequency
Pr.15 setting range
Forward
rotation
Reverse
rotation
Time
Pr.16
ON
JOG
Forward rotation STF
ON
Reverse rotation STR
ON
Note: 1. In S-shaped acceleration/deceleration pattern A, the set time is a period of time required to reach
Pr. 3 "base frequency".
2. The acceleration time and deceleration time cannot be set separately for jog operation.
70
4
PARAMETERS
4.2.11 MRS input selection (Pr. 17)
Pr. 17 "MRS input selection"
Used to select the logic of the MRS signal.
When the MRS signal switches on, the inverter shuts off the output.
Parameter
Number
17
Factory
Setting
0
Setting Range
0, 2
<Setting>
Pr. 17 Setting
0
2
Specifications of MRS Signal
Normally open input
Normally closed input (N/C contact input specifications)
<Wiring example>
• For sink logic
Setting 0 (Factory setting)
Setting 2
Inverter
Inverter
Output stop
Output stop
MRS
MRS
SD
SD
Pr. 19 Î Refer to Pr. 3.
Pr. 20, Pr. 21 Î Refer to Pr.15, Pr. 16.
71
PARAMETERS
4.2.12 Stall prevention (Pr. 22, Pr. 23, Pr. 66, Pr. 148, Pr. 149, Pr. 154)
Pr. 22 "stall prevention operation level"
Related parameters
Pr. 9 "electronic thermal O/L relay"
Pr. 48 "second stall prevention
operation current"
Pr. 49 "second stall prevention
operation frequency"
Pr. 73 "0-5V/0-10V selection"
Pr. 156 "stall prevention operation
selection"
Pr. 23 "stall prevention operation level at double
speed"
Pr. 66 "stall prevention operation level reduction
starting frequency"
Pr. 148 "stall prevention operation level at 0V input"
Pr. 149 "stall prevention operation level at 10V input"
Pr. 154 "voltage reduction selection during stall prevention operation"
z Set the output current level at which the output frequency is adjusted so that the inverter will not come to an
alarm stop due to overcurrent etc.
z For high-speed operation at or over 60Hz, acceleration may not be made because the motor current does
not increase. To improve the operation characteristics of the motor in such a case, the stall prevention level
in the high-frequency range can be reduced. This is effective for operation of a centrifugal separator up to
the high-speed range. Normally, set 60Hz 〈50Hz〉 in Pr. 66 and 100% in Pr. 23.
z For operation in the high-frequency range, the current in the locked motor state is smaller than the rated output
current of the inverter and the inverter does not result in an alarm (protective function is not activated) if the
motor is at a stop. To improve this and activate the alarm, the stall prevention level can be reduced.
z In order to provide torque during stall prevention, Pr. 154 is factory-set not to reduce the output voltage. The
setting of reducing the output voltage further decreases the probability of overcurrent trip occurrence.
z The stall prevention operation level can be varied by entering the analog signal into terminal 1.
Parameter Number
22
23
66
148
149
Factory Setting
120%
9999
60Hz 〈50Hz〉
120%
150%
Setting Range
0 to 150%, 9999
0 to 200%, 9999
0 to 120Hz
0 to 150%
0 to 150%
154
1
0, 1
Remarks
9999: Analog variable
9999: Constant according to Pr. 22
(Bias)
(Gain)
0: Output voltage reduced
1: Output voltage not reduced
Setting example (Pr.22=120%, Pr.23=100%, Pr.66=60Hz)
Pr.22
Stall prevention
operation level (%)
Pr.23
Reduction ratio
compensation factor (%)
Stall prevention
operation level (%)
120
Pr.23 = 9999
112.5
90
75
0
Stall prevention
operation level (%)
Pr.66
120Hz Output
frequency (Hz)
(150%)
(120%)
Pr.149
Pr.148
0%
0V
10(5)V
Input voltage (V)
(across frequency setting terminals 1-5)
72
60
80
100 120
Output
frequency (Hz)
4
PARAMETERS
<Setting>
• In Pr. 22, set the stall prevention operation level. Normally set it to 120% (factory setting). Set "0" in Pr. 22 to
disable the stall prevention operation.
• To reduce the stall prevention operation level in the high-frequency range, set the reduction starting
frequency in Pr. 66 and the reduction ratio compensation factor in Pr. 23.
Calculation expression for stall prevention operation level
Pr.22-A Pr.23-100
] [
]
Pr.22-B
100
Pr.66 (Hz) Pr.22 (%)
Pr.66 (Hz) Pr.22 (%)
where, A=
, B=
output frequency (Hz)
120Hz
Stall prevention operation level (%) = A+B [
• By setting "9999" (factory setting) in Pr. 23, the stall prevention operation level is constant at the Pr. 22
setting up to 120Hz.
• Set "9999" in Pr. 22 to vary the stall prevention operation level using the analog signal (0-5V/0-10V) entered
to the frequency setting auxiliary input terminal [1]. (Use Pr. 73 to select between 10V and 5V.)
• Use Pr. 148 and Pr. 149 to adjust the gain and bias of the analog signal.
• Set "0" in Pr. 154 to reduce the output voltage during stall prevention operation.
Note: 1. When Pr. 22 = "9999", terminal 1 is exclusively used for setting the stall prevention operation level.
The auxiliary input and override functions are not activated.
CAUTION
Do not set a too small value as the stall prevention operation current. Otherwise, torque
generated will reduce.
Test operation must be performed. Stall prevention operation during acceleration may
increase the acceleration time.
Stall prevention operation during constant speed may change the speed suddenly.
Stall prevention operation during deceleration may increase the deceleration time,
increasing the deceleration distance.
Pr. 24 to Pr. 27 Î Refer to Pr. 4 to Pr. 6.
4.2.13 Multi-speed input compensation (Pr. 28)
Related parameters
Pr. 59 "remote setting function"
Pr. 73 "0-5V/0-10V selection"
Pr. 28 "multi-speed input compensation"
By entering a compensation signal into the frequency setting auxiliary input terminal 1 (Note 2), the speeds
(frequencies) of multi-speed settings or the speed setting made by remote setting function can be
compensated for.
Parameter
Number
Factory
Setting
Setting Range
Remarks
28
0
0, 1
0: Not compensated
1: Compensated
Note: 1. Use Pr. 73 to select the compensation input voltage between 0 to ±5V and 0 to ±10V.
2. When any of "4, 5, 14 and 15" is set in Pr. 73, the compensation signal is entered into terminal 2.
(Override functions)
73
PARAMETERS
4.2.14 Acceleration/deceleration pattern (Pr. 29, Pr.140 to Pr.143)
Pr. 29 "acceleration/deceleration pattern"
Related parameters
Pr. 3 "base frequency"
Pr. 7 "acceleration time"
Pr. 8 "deceleration time"
Pr. 20 "acceleration/deceleration
reference frequency"
Pr. 44 "second acceleration/
deceleration time"
Pr. 45 "second deceleration time"
Pr. 140 "backlash acceleration stopping frequency"
Pr. 141 "backlash acceleration stopping time"
Pr. 142 "backlash deceleration stopping frequency"
Pr. 143 "backlash deceleration stopping time"
Output
frequency (Hz)
Set value 0
[Linear acceleration/deceleration]
Time
Setting Range
Remarks
0, 1, 2, 3
0 to 120Hz
0 to 360 s
0 to 120Hz
0 to 360 s
3: Backlash compensation
Valid when Pr. 29 = 3.
Valid when Pr. 29 = 3.
Valid when Pr. 29 = 3.
Valid when Pr. 29 = 3.
Set value 1
[S-shaped acceleration/deceleration A]
Set value 2
[S-shaped acceleration/deceleration B]
Output
frequency (Hz)
Factory
Setting
0
1.00Hz
0.5 s
1.00Hz
0s
Output
frequency (Hz)
Parameter
Number
29
140
141
142
143
fb
Time
f1
f2
Time
Output frequency (Hz)
Set the acceleration/deceleration pattern.
Also, you can suspend acceleration/deceleration at set frequencies and for the time period set in the
parameters.
Set value 3
[Backlash compensation function]
∆f2 Pr.142
∆f1 Pr.140
∆t1 Pr.141
Time
∆t2 Pr.143
<Setting>
Pr. 29
Setting
Function
0
Linear
acceleration/
deceleration
1
S-shaped
acceleration/
deceleration A
(Note 1)
2
S-shaped
acceleration/
deceleration B
3
Backlash
compensation
(Note 2, 3)
Description
Linear acceleration/deceleration is made up/down to the preset frequency (factory setting).
For machine tool spindles
This setting is used when it is necessary to make acceleration/deceleration in a short time up to the
60Hz or higher speed range. In this acceleration/deceleration pattern, fb (base frequency) is always the
inflection point of an S shape, and you can set the acceleration/deceleration time according to the
reduction in motor torque in the 60Hz or higher constant-output operation range.
Prevention of cargo collapse on conveyor, etc.
This setting provides S-shaped acceleration/deceleration from f2 (current frequency) to f1 (target
frequency), easing an acceleration/deceleration shock. This pattern has an effect on the prevention of
cargo collapse, etc.
Backlash compensation for reduction gear, etc.
This function stops the speed change temporarily during acceleration/deceleration, reducing a shock
generated when a reduction gear backlash is eliminated suddenly. Use Pr. 140 to Pr. 143 to set the
stopping times and stopping frequencies in accordance with the above diagrams.
Note: 1. For the acceleration/deceleration time, set the time required to reach the "base frequency" in
Pr. 3, not the "acceleration/deceleration reference frequency" in Pr. 20. For details, refer to Pr. 7 and
Pr. 8.
2. Pr. 140 to Pr. 143 is accessible when "3" is set in Pr. 29.
3. The acceleration/deceleration time is increased by the stopping time.
74
4
PARAMETERS
4.2.15 Regenerative brake duty (Pr.30, Pr.70)
Related parameters
Pr. 30 "regenerative function selection"
Pr. 180 "RL terminal function selection"
Pr. 181 "RM terminal function selection"
Pr. 182 "RH terminal function selection"
Pr. 183 "RT terminal function selection"
Pr. 184 "AU terminal function selection"
Pr. 185 "JOG terminal function selection"
Pr. 186 "CS terminal function selection"
Pr.70 "special regenerative brake duty"
z Use the optional "high power factor converter (FR-HC)" to reduce harmonics, improve the power factor, or
continue the regenerative mode.
Parameter
Number
30
70
Factory
Setting
0
0%
Setting Range
Remarks
0, 2
0 to 100%
0 : No regenerative function
<Setting>
(1) When using the brake unit (MT-BU5)
z Set "1" in Pr. 30.
At this time, set the regenerative brake duty to 10% (Pr.70).
(2) When using the high power factor converter (MT-RC)
z Set "1" in Pr. 30.
z Set "10%" in Pr. 70.
(3) When using the high power factor converter (MT-HC)
1) Set "2" in Pr. 30.
2) Use any of Pr. 180 to Pr. 186 to assign the following signals to the contact input terminals.
z X10: MT-HC connection (inverter operation enable signal) (Note 3)
To make protective coordination with the high power factor converter (MT-HC), use the inverter operation
enable signal to shut off the inverter output. Enter the RDY signal of the high power factor converter.
z X11: MT-HC connection (instantaneous power failure detection signal)
When the computer link inboard option (FR-A5NR) is used and the setting is made to hold the preinstantaneous power failure mode, use this signal to hold that mode. Enter the instantaneous power
failure detection signal of the high power factor converter.
3) The Pr. 70 setting is made invalid.
Set "10" and "11" in any of Pr. 180 to Pr. 186 to allocate the terminals used to input the X10 and X11
signals.
Note: 1. Pr. 70 "regenerative brake duty" indicates the %ED of the brake transistor operation. The setting
should not be higher than the permissible value of the brake resistor used. Otherwise, the resistor
can overheat.
2. The X10 signal may be replaced by the MRS signal.
3. When terminal assignment is changed using Pr. 180 to 186, the other functions may be affected.
Check the functions of the corresponding terminals before making setting.
75
PARAMETERS
4.2.16 Frequency jump (Pr. 31 to Pr. 36)
Pr. 31 "frequency jump 1A"
Pr. 32 "frequency jump 1B"
Pr. 33 "frequency jump 2A"
Pr. 34 "frequency jump 2B"
Pr. 35 "frequency jump 3A"
Pr. 36 "frequency jump 3B"
z When it is desired to avoid resonance attributable to the natural frequency of a mechanical system, these
parameters allow resonant frequencies to be jumped. Up to three areas may be set, with the jump
frequencies set to either the top or bottom point of each area.
z The value set to 1A, 2A or 3A is a jump point and operation is performed at this frequency.
Parameter
Number
31
Factory
Setting
9999
0 to 120Hz, 9999
9999: Function invalid
32
9999
0 to 120Hz, 9999
9999: Function invalid
33
9999
0 to 120Hz, 9999
9999: Function invalid
34
9999
0 to 120Hz, 9999
9999: Function invalid
35
9999
0 to 120Hz, 9999
9999: Function invalid
36
9999
0 to 120Hz, 9999
9999: Function invalid
Remarks
Running frequency
Setting Range
Pr.36
Pr.35
Frequency jump
Pr.34
Pr.33
Pr.32
Pr.31
<Setting>
• To fix the frequency at 30Hz between Pr. 33 and Pr. 34 (30Hz and 35Hz), set 35Hz
in Pr. 34 and 30Hz in Pr. 33.
• To jump to 35Hz between 30 and 35Hz, set 35Hz in Pr. 33 and 30Hz in Pr. 34.
Pr.34:35Hz
Pr.33:30Hz
Pr.33:35Hz
Pr.34:30Hz
Note: 1. During acceleration/deceleration, the running frequency within the set area is valid.
76
4
PARAMETERS
4.2.17 Speed display (Pr. 37, Pr. 144)
Pr. 37 "speed display"
Related parameters
Pr. 144 "speed setting switch-over"
Pr. 52 "PU main display data selection"
Pr. 53 "PU level display data selection"
The units of the running speed monitor display of the PU (FR-DU04/FR-PU04), the running speed setting in
the PU operation mode, and the parameter setting used for frequency setting can be changed from the
frequency to the motor speed or machine speed.
Parameter
Number
37
Factory
Setting
0
144
4
Setting Range
Remarks
0, 1 to 9998
0, 2, 4, 6, 8, 10, 102,
104, 106, 108, 110
0: Frequency setting added
<Setting>
• To display the machine speed, set in Pr. 37 the machine speed for 60Hz operation.
• To display the motor speed, set the number of motor poles (2, 4, 6, 8, 10) or the number of motor poles plus
100 (102, 104, 106, 108, 110) in Pr. 144.
• When values have been set in both Pr. 37 and Pr. 144, priority is as follows:
Pr. 144 = 102 to 110 > Pr. 37 = 1 to 9998 > Pr. 144 = 2 to 10
Hence, the half-tone screened settings in the following list become valid.
• When the running speed monitoring has been selected, the parameter setting unit and the running speed
setting unit in the PU operation mode depend on the combination of the Pr. 37 and Pr. 144 settings as
indicated below:
Running Speed
Monitor Display
Speed of 4-pole motor (r/min)
Parameter Setting Unit
Running Speed Setting Unit
Hz
Motor speed (r/min)
Machine speed
r/min
Hz
r/min
Pr. 37 Setting
Pr. 144 Setting
0
0
1 to 9998
0
1 to 9998
1 to 9998
0
2 to 10
102 to 110
102 to 110
0
2 to 10
Note: 1. In the V/F control mode, the motor speed is converted from the output frequency and does not
match the actual speed.
2. When the running speed display has been selected with "0" set in Pr. 37 and "0" in Pr. 144, the
monitor display shows the speed reference for a 4-pole motor (1800r/min is displayed at 60Hz).
3. To change the PU main monitor (PU main display) or PU level meter (PU level display), refer to
Pr. 52 and Pr. 53.
4. As the operation panel display is 4 digits, "----" is displayed when the monitored value exceeds
"9999".
CAUTION
Make sure that the running speed and number of poles set are correct.
Otherwise, the motor might run at extremely high speed, damaging the machine.
77
PARAMETERS
4.2.18 Automatic torque boost (Pr. 38, Pr. 39)
Pr. 38 "automatic torque boost"
Pr. 39 "automatic torque boost operation starting current"
Used to detect the load current to control the output voltage (torque) of the inverter automatically.
Parameter Number
Factory Setting
Setting Range
Setting Capacity
38
0
0 to 200
Set the boost compensation (%).
Setting "0" makes the automatic torque boost inoperative.
Normally set "100" (%) to make the automatic torque boost
operative
39
0
0 to 500
Set the automatic torque boost operation starting current (A).
Normally set "0" (A).
4.2.19 Up-to-frequency sensitivity (Pr. 41)
Pr. 41 "up-to-frequency sensitivity"
Related parameters
Pr. 190 "RUN terminal function
selection"
Pr. 191 "SU terminal function selection"
Pr. 192 "IPF terminal function selection"
Pr. 193 "OL terminal function selection"
Pr. 194 "FU terminal function selection"
Pr. 195 "ABC terminal function
selection"
The ON range of the up-to-frequency signal (SU) output when the output frequency reaches the running
frequency can be adjusted between 0 and ±100% of the running frequency.
This parameter can be used to ensure that the running frequency has been reached or used as the operation
start signal etc. for related equipment.
Factory
Setting
10%
Setting Range
0 to 100%
Output frequency (Hz)
Parameter
Number
41
4
Running frequency
Output signal
OFF
SU
Adjustable range Pr.41
Time
OFF
ON
78
PARAMETERS
4.2.20 Output frequency detection (Pr. 42, Pr. 43, Pr. 50)
Pr. 42 "output frequency detection"
Pr. 43 "output frequency detection for reverse rotation"
Pr. 50 "second output frequency detection"
The output frequency signal (FU, FU2) is output when the output frequency reaches or exceeds the setting.
This function can be used for electromagnetic brake operation, open signal, etc.
z You can also set the detection of the frequency used exclusively for reverse rotation. This function is
effective for switching the timing of electromagnetic brake operation between forward rotation (rise) and
reverse rotation (fall) during vertical lift operation, etc.
Parameter
Number
42
Factory
Setting
6Hz
43
9999
0 to 120Hz, 9999
50
30Hz
0 to 120Hz
Setting Range
Remarks
0 to 120Hz
9999: Same as Pr. 42
setting
<Setting>
Output frequency (Hz)
Refer to the figure below and set the corresponding parameters:
• When Pr. 43 ≠ 9999, the Pr. 42 setting applies to forward rotation and the Pr. 43 setting applies to reverse
rotation.
Output signal
FU,FU2
OFF
Pr.42
Forward
rotation
Pr.50
Time
Reverse
rotation
ON
OFF
ON
Pr.43
Pr.50
OFF
Output Signal
Parameter Number
42
43
50
Output Signal
FU1
FU2
Use Pr. 190 to Pr. 195 to assign the terminals used to output the FU2 signals.
Note: 1. When terminal assignment is changed using Pr. 190 to Pr. 195, the other functions may be
affected. Check the functions of the corresponding terminals before making setting.
Pr. 44, Pr. 45 Î Refer to Pr. 7.
Pr. 46 Î Refer to Pr. 0.
Pr. 47 Î Refer to Pr. 3.
79
PARAMETERS
4.2.21 Second stall prevention (Pr. 48, Pr. 49)
Pr. 48 "second stall prevention operation current"
Related parameters
Pr. 22 "stall prevention operation level"
Pr. 23 "stall prevention operation level
at double speed"
Pr. 66 "stall prevention operation level
reduction starting frequency"
Pr. 154 "voltage reduction selection
during stall prevention operation"
Pr. 180 to Pr. 186
(input terminal function selection)
Pr. 49 "second stall prevention operation
frequency"
Parameter
Number
48
Factory
Setting
120%
49
0
Stall prevention
operation current
z The stall prevention operation level can be changed within the range from 0Hz to the frequency set inPr. 49.
z The stall prevention operation level can be changed by switching the external input signal on-off.
Setting Range
0 to 150%
0 to 120Hz, 9999
Pr.48
Acceleration
Deceleration/constant speed
Pr.49 Running frequency
<Setting>
• Set the stall prevention operation level in Pr. 48.
• Refer to the following list to set values in Pr. 49.
Pr. 49 Setting
0
0.01Hz to 120Hz
9999
Operation
Second stall prevention function is not activated.
Second stall prevention function is activated according to the
frequency as shown above.
Second stall prevention function is activated according to the RT signal.
RT signal ON ............... Stall level Pr. 48
RT signal OFF ............. Stall level Pr. 22
Note: 1. When Pr. 49 = "9999", setting "0" in Pr. 48 disables the stall prevention function when the RT
signal switches on. When Pr. 49 ≠ "9999" and Pr. 48 = "0", the stall prevention operation level is
0% when the frequency is equal to or less than the value set in Pr. 49.
2. When the stall prevention operation level signal input function is selected (Pr. 22 = 9999), setting
"9999" in Pr. 49 changes the stall prevention operation level from the value of the stall prevention
operation level signal (terminal 1 input) to the value set in Pr. 48 when the RT signal switches on.
3. When the RT signal is on, the second functions such as second acceleration/deceleration time are
also selected.
4. When terminal assignment is changed using Pr. 180 to Pr. 186, the other functions may be
affected. Check the functions of the corresponding terminals before making setting.
CAUTION
Do not set a too small value to the second stall prevention operation current. Otherwise,
torque generated will decrease.
Pr. 50 Î Refer to Pr. 42.
80
4
PARAMETERS
4.2.22 Monitor display / FM, AM terminal function selection
(Pr. 52 to Pr. 54, Pr. 158)
Pr. 52 "DU/PU main display screen data selection"
Related parameters
Pr. 37 "speed display"
Pr. 55 "frequency monitoring reference"
Pr. 56 "current monitoring reference"
Pr. 170 "watt-hour meter clear"
Pr. 171 "actual operation hour meter
clear"
Pr. 900 "FM terminal calibration"
Pr. 901 "AM terminal calibration"
Pr. 53 "PU level display data selection"
Pr. 54 "FM terminal function selection"
Pr. 158 "AM terminal function selection"
z You can select the signals shown on the operation panel (FR-DU04)/parameter unit (FR-PU04) main display
screen and on the parameter unit (FR-PU04) level meter and signals output to the FM and AM terminals.
z There are two different signal outputs: FM pulse train output terminal and AM analog output terminal. Select
the signals using Pr. 54 and Pr. 158.
Parameter Number
Factory Setting
Setting Range
52
53
54
158
0
1
1
1
0, 5, 6, 8, 10 to 14, 17, 20, 23, 24, 25, 100
0 to 3, 5, 6, 8, 10 to 14, 17
1 to 3, 5, 6, 8, 10 to 14, 17, 21
1 to 3, 5, 6, 8, 10 to 14, 17, 21
<Setting>
Set Pr. 52 to Pr. 54 and Pr. 158 in accordance with the following table:
Signal Type
No display
Output frequency
Output current
Output voltage
Alarm display
Frequency setting
Running speed
Converter output voltage
Regenerative brake duty
Electronic overcurrent
protection load factor
Output current peak
value
Converter output voltage
peak value
Input power
Output power
Input terminal status
Output terminal status
Load meter **
Cumulative operation
time
Display
Unit

Hz
A
V

Hz
r/min
V
%
Parameter Setting
Pr.52
Pr.53
Pr.54
Pr.158
DU
PU main PU level
FM
AM
LED
monitor
meter terminal terminal
0
×
×
×
×
0/100
0/100
1
1
1
0/100
0/100
2
2
2
0/100
0/100
3
3
3
0/100
0/100
×
×
×
5
*
5
5
5
6
*
6
6
6
8
*
8
8
8
*
×
×
×
×
Full-Scale Value of
FM, AM, Level Meter

Pr. 55
Pr. 56
400V or 800V

Pr. 55
Pr. 55 value converted into Pr. 37 value
400V or 800V

%
10
*
10
10
10
Protection operation level
A
11
*
11
11
11
Pr. 56
V
12
*
12
12
12
400V or 800V
kW
kW
13
14
13
14
13
14
13
14
Rated power of inverter rating × 2
Rated power of inverter rating × 2

×
×
×
×


×
×
×
×

%
17
*
*
*
*
17
17
17
17
Pr. 56
hr
20
20
×
×
×

Reference voltage output

×
×
×
21
21
1440Hz is output to FM terminal. Fullscale voltage is output to AM terminal.
Actual operation time
Motor load factor
Cumulative power
hr
%
kW
23
24
25
23
24
25
×
×
×

×
×
×
Rated inverter current × 2
×
×
×

81
PARAMETERS
When 100 is set in Pr. 52, the monitored values during stop and during operation differ as indicated below:
(The LED on the left of Hz flickers during a stop and is lit during running.)
Pr. 52
Output frequency
Output current
Output voltage
Alarm display
0
During
operation/during stop
Output frequency
100
During stop
Set frequency
Output current
Output voltage
Alarm display
During operation
Output frequency
Note: 1. During an error, the output frequency at error occurrence is displayed.
2. During MRS, the values are the same as during a stop.
Note: 1. The monitoring of items marked × cannot be selected.
2. By setting "0" in Pr. 52, the monitoring of "output frequency to alarm display" can be selected in
sequence by the SHIFT key.
3. *"Frequency setting to output terminal status" on the PU main monitor are selected by "other
monitor selection" of the parameter unit (FR-PU04).
4. **The load meter is displayed in %, with the current set in Pr. 56 regarded as 100%.
5. The actual operation time displayed by setting "23" in Pr. 52 is calculated using the inverter
operation time. (Inverter stop time is not included.) Set "0" in Pr. 171 to clear it.
6. When Pr. 53 = "0", the level meter display of the parameter unit can be erased.
7. By setting "1, 2, 5, 6, 11 or 17" in Pr. 53, the full-scale value can be set in Pr. 55 or Pr. 56.
8. The cumulative operation time and actual operation time are calculated from 0 to 65535 hours,
then cleared, and recalculated from 0.
When the operation panel (FR-DU04) is used, the display shows "----" after 9999 or more hours
have elapsed.
Confirmation of whether 9999 or more hours have elasped can be made only by using the
parameter unit (FR-PU04).
9. The actual operation time is not calculated unless the inverter has operated for longer than one
hour continuously.
10.When the operation panel (FR-DU04) is used, the display unit is Hz, V or A only.
4
82
PARAMETERS
4.2.23 Monitoring reference (Pr. 55, Pr. 56)
Pr. 55 "frequency monitoring reference"
Related parameters
Pr. 37 "speed display"
Pr. 53 "PU level display data selection"
Pr. 54 "FM terminal function selection"
Pr. 158 "AM terminal function selection"
Pr. 900 "FM terminal calibration"
Pr. 901 "AM terminal calibration"
Pr. 56 "current monitoring reference"
Set the frequency or current which is referenced for display when the frequency or current is selected for the
FM and AM terminals and PU level meter display.
Parameter
Number
55
56
Factory Setting
Setting Range
60Hz 〈50Hz〉
Rated output current
0 to 120Hz
0 to 3600A
Output or display
Output or display
1440 pulses/second. (terminal FM) 1440 pulses/second. (terminal FM)
10VDC (terminal AM)
10VDC (terminal AM)
Full scale (PU level monitor)
Full scale (PU level monitor)
Output frequency Pr.55
Frequency setting
Running speed
Output current
Pr.56
Output current peak value
Load meter
<Setting>
Referring to the above figures and following table, set Pr. 55 and Pr. 56:
Monitoring Reference
Setting Parameter
Frequency monitoring
reference Pr. 55
Current monitoring
reference Pr. 56
Monitored Data Selection
Output frequency (Hz)
Frequency setting (Hz)
Running speed (Pr. 37)
Output current (A)
Output current peak value (A)
Load meter (%)
Setting using Pr. 55, Pr. 56
PU Level Display
Selection
Pr. 53 Setting
1
5
6
2
11
17
Set to make the PU
level meter indication
to be in full-scale.
FM Terminal Function
Selection
Pr. 54 Setting
1
5
6
2
11
17
Set to make the
terminal FM pulse train
output to be 1440
pulses/second.
AM Terminal
Function Selection
Pr. 158 Setting
1
5
6
2
11
17
Set to make the
terminal AM output
voltage to be 10V.
Note: 1. The maximum pulse train output of terminal FM is 2400 pulses/second. If Pr. 55 is not adjusted,
the output of terminal FM will be filled to capacity. Therefore, adjust Pr. 55.
2. The maximum output voltage of terminal AM is 10VDC.
83
PARAMETERS
4.2.24 Automatic restart after instantaneous power failure
(Pr. 57, Pr. 58, Pr. 162 to Pr. 165)
Pr. 57 "coasting time for automatic restart after instantaneous power
failure/commercial power supply-inverter switch-over"
Pr. 58 "cushion time for automatic restart after instantaneous power
failure/commercial power supply-inverter switch-over"
Pr.162 "Automatic restart after instantaneous power failure selection"
Pr.163 "First cushion time for restart"
Pr.164 "First cushion voltage for restart"
Pr.165 "Restart stall prevention operation level"
z You can restart the inverter without stopping the motor (with the motor coasting) when the commercial
power supply is switched to the inverter operation or when the power is restored after an instantaneous
power failure. (When automatic restart operation is set to be enabled, UVT and IPF among the alarm output
signals will not be output at occurrence of an instantaneous power failure.)
Parameter
Number
57
58
Factory
Setting
9999
1.0 s
Setting Range
Remarks
0, 0.1 to 5 s, 9999
0 to 60 s
9999: No restart
162
0
0, 1
163
164
165
0s
0%
120%
0 to 20 s
0 to 100%
0 to 150%
0: Frequency search
1: No frequency search
MC2
Voltage
NFB
MC1
R 〈L1〉
S 〈L2〉
T 〈L3〉
U
V
W
R1 〈L11〉
S1 〈L21〉
STF
CS
SD
Pr.164
(Pr.163)
Pr.58
CS
Time
SD
Voltage rise time
84
MC3
IM
MC switching sequence
Connect CS-SD for use of only
automatic restart after instantaneous
power failure.
4
PARAMETERS
<Setting>
Refer to the figures in the previous page and following table, and set the parameters:
Parameter
Number
Setting
0
162
1
0
57
0.1 to 30 s
58
163
9999
0 to 60 s
0 to 20 s
164
0 to 100%
165
0 to 150%
Description
Frequency search made
Frequency search is made after detection of an instantaneous power failure.
No frequency search
Independently of the motor coasting speed, the output voltage is gradually increased
with the frequency kept as preset.
0.5 s coasting time
Generally use this setting.
Waiting time for inverter-triggered restart after power is restored from an instantaneous
power failure. (Set this time between 0.1 s and 30 s according to the inertia moment
(GD2) and torque of the load.)
No restart
Normally the motor may be run with the factory settings. These values are adjustable to
the load (inertia moment, torque).
Note: 1. When restart operation is selected, UVT and IPF among the alarm output signals are not output at
occurrence of an instantaneous power failure.
2. If the inverter capacity is more than one rank higher than the motor capacity, an overcurrent
(OCT) alarm may take place, disabling the motor from starting.
3. When Pr. 57 ≠ 9999, the inverter will not run if the CS signal remain off.
4. When Pr. 162 = "0", connection of two or more motors to one inverter will make the inverter
function improperly. (The inverter will not start properly.)
5. When Pr. 162 = "0", the DC dynamic brake is operated instantly on detection of restarting speed.
2
Therefore, if the inertia moment (GD ) of the load is small, the speed may reduce.
6. When Pr. 162 = "1", the output frequency before an instantaneous power failure is stored and
output at the time of restart. If the power of the inverter control circuit is lost, the frequency before
an instantaneous power failure cannot be stored and the inverter will start at 0Hz.
7. The SU and FU signals are not output during restart but are output after the restart cushion time
has elapsed.
CAUTION
Provide mechanical interlocks for MC1 and MC2.
The inverter will be damaged if power is entered into the inverter output section.
When automatic restart after instantaneous power failure has been selected, the motor
and machine will start suddenly (after the reset time has elapsed) after occurrence of
an instantaneous power failure. Stay away from the motor and machine.
When you have selected automatic restart after instantaneous power failure, apply the
supplied CAUTION seals in easily visible places.
85
PARAMETERS
4.2.25 Remote setting function selection (Pr. 59)
Pr. 59 "remote setting function selection"
Related parameters
Pr. 1 "maximum frequency"
Pr. 7 "acceleration time"
Pr. 8 "deceleration time"
Pr. 28 "multi-speed input compensation"
Pr. 44 "second acceleration/deceleration
time"
Pr. 45 "second deceleration time"
If the operator panel is located away from the control box, you can use contact signals to perform continuous
variable-speed operation, without using analog signals.
z By merely setting this parameter, you can use the acceleration, deceleration and setting clear functions of
the motorized speed setter (FR-FK).
z When the remote function is used, the output frequency of the inverter can be compensated for as follows:
External operation mode
Frequency set by RH/RM operation plus external running frequency other
than multi-speeds
(Set "1" in Pr. 28 to select the compensation input (terminal 1).)
PU operation mode
Frequency set by RH/RM operation plus PU running frequency
Factory
Setting
0
Setting Range
0, 1, 2
Output frequency (Hz)
Parameter
Number
59
Acceleration (RH)
Deceleration (RM)
Clear (RL)
Forward rotation (STF)
Time
ON
ON
4
<Setting>
Refer to the following table and set the parameter:
Pr. 59 Setting
0
1
2
Operation
Frequency setting
Remote setting function
storage function

No
Yes
Yes
Yes
No
• Use Pr. 59 to select whether the remote setting function is used or not and whether the frequency setting
storage function in the remote setting mode is used or not. When "remote setting function - yes" is selected,
the functions of signals RH, RM and RL are changed to acceleration (RH), deceleration (RM) and clear (RL).
86
PARAMETERS
Note: 1. The frequency can be varied by RH (acceleration) and RM (deceleration) between 0 and 120Hz.
2. When the acceleration or deceleration signal switches on, the set frequency varies according to
the slope set in Pr. 44 or Pr. 45. The output frequency acceleration/deceleration times are as set in
Pr. 7 and Pr. 8, respectively. Therefore, the longer preset times are used to vary the actual output
frequency.
3. The frequency setting storage function stores in memory the remotely-set frequency (frequency
set by RH/RM operation) when the acceleration and deceleration signals remain off for more than
1 minute or as soon as the start signal (STF or STR) switches off. When power is switched off,
then on, operation is resumed with that value.
CAUTION
When selecting this function, re-set the maximum frequency according to the machine.
87
PARAMETERS
4.2.26 Intelligent mode selection (Pr. 60)
Pr. 60 "intelligent mode selection"
Related parameters
Pr. 0 "torque boost"
Pr. 7 "acceleration time"
Pr. 8 "deceleration time"
Pr. 13 "starting frequency"
Pr. 19 "base frequency voltage"
The inverter automatically sets appropriate parameters for operation.
• If you do not set the acceleration and deceleration times and V/F pattern, you can run the inverter as if
appropriate values had been set in the corresponding parameters. This operation mode is useful to start
operation immediately without making fine parameter settings.
Parameter
Number
60
Factory
Setting
0
Setting Range
0, 3, 4, 9
<Setting>
Pr. 60
Setting
Operation Mode
Description
Automatically Set
Parameters
0
Ordinary operation
mode


3
Optimum
acceleration/
deceleration mode
(Note 2, 3)
Optimum operation can be carried out by fully utilizing the inverter capabilities
in the continuous rating range.
Self-learning automatically sets the corresponding parameters so that the
average current during acceleration/deceleration is equal to the rated current.
Appropriate for applications where the load will not vary by a large amount.
Pr. 0, Pr. 7, Pr. 8
4
Energy-saving
mode (Note 4)
Tunes the output voltage online to minimize the inverter output power during
constant-speed operation.
Appropriate for energy-saving applications such as fan and pump operation.
Output voltage
9
Optimum excitation
control mode
(Note 4)
Optimizes the exciting current as an energy-saving technique to maximize the
motor efficiency. Appropriate for further energy-saving applications such as
machines which are large in GD2 and long in acceleration/deceleration time.
Output voltage
Note: 1. When more accurate control is required for your application, set the other parameters as
appropriate.
2. Because of the learning system, this control is not valid at the first time in the optimum
acceleration/deceleration mode. Also, this mode is only valid for frequency setting of 30.01Hz or
more.
3. If an overvoltage (OV3) trip has occurred during operation in the optimum
acceleration/deceleration mode (setting "3"), re-set Pr. 8 "deceleration time" to a larger value and
restart operation in this mode.
4. When "4" (energy-saving mode) or "9" (optimum excitation control mode) has been set to
decelerate the motor to a stop, the deceleration time may be longer than the preset value.
Because overvoltage is more likely to occur in this mode when compared to constant torque load
characteristics, set the deceleration time to a longer value.
88
4
PARAMETERS
4.2.27 Acceleration/deceleration reference current/lift mode starting
frequency (Pr. 61 to Pr. 63)
Pr. 61 "reference current"
Related parameter
Pr. 62 "reference current for acceleration"
Pr. 60 "intelligent mode selection"
Pr. 63 "reference current for deceleration"
z Set these parameters to improve performance in the intelligent mode.
Parameter
Number
61
62
63
Factory
Setting
9999
9999
9999
Setting Range
Remarks
0 to 500A, 9999
0 to 150%, 9999
0 to 150%, 9999
9999: Referenced from rated inverter current.
<Setting>
(1) Pr. 61 "reference current setting"
Setting
9999 (factory setting)
0 to 500A
Reference Current
Referenced from rated inverter current
Referenced from setting (rated motor current)
(2) Pr. 62 "reference current for acceleration"
(The reference value differs between the shortest acceleration/deceleration mode and optimum
acceleration/deceleration mode.)
The reference current setting can be changed.
Setting
9999 (factory setting)
0 to 150%
Reference Current
120% (150%) is the limit value.
100% is the optimum value.
The setting of 0 to 150% is the limit value.
The setting of 0 to 150% is the optimum value.
Remarks
Shortest acceleration/deceleration mode
Optimum acceleration/deceleration mode
Shortest acceleration/deceleration mode
Optimum acceleration/deceleration mode
(3) Pr. 63 "reference current for deceleration"(%)
(The reference value differs between the shortest acceleration/deceleration mode and optimum
acceleration/deceleration mode.)
The reference current setting can be changed.
Setting
9999 (factory setting)
0 to 150%
Reference Current
150% (180%) is the limit value.
100% is the optimum value.
The setting of 0 to 150% is the limit value.
The setting of 0 to 150% is the optimum value.
Remarks
Shortest acceleration/deceleration mode
Optimum acceleration/deceleration mode
Shortest acceleration/deceleration mode
Optimum acceleration/deceleration mode
Note: Pr. 61 to Pr. 63 are only valid when any of "3" or "4" is selected for Pr. 60.
89
PARAMETERS
4.2.28 Retry function (Pr. 65, Pr. 67 to Pr. 69)
Pr. 65 "retry selection"
Pr. 67 "number of retries at alarm occurrence"
Pr. 68 "retry waiting time"
Pr. 69 "retry count display erasure"
When an alarm occurs, the retry function causes the inverter to automatically reset itself to make a restart and
continue operation. You can select whether retry is made or not, alarms reset for retry, number of retries made,
and waiting time.
Parameter
Number
65
67
68
69
Factory
Setting
0
0
1s
0
Setting Range
0 to 5
0 to 10, 101 to 110
0 to 10 s
0
<Setting>
Use Pr. 65 to select alarms to be reset for retry.
Errors Reset for Retry
Display
E.OC1
E.OC2
E.OC3
E.OV1
E.OV2
E.OV3
E.THM
E.THT
E.IPF
E.UVT
E.FIN
E. GF
E. LF
E.OHT
E.OLT
E.OPT
E.OP1
E.OP2
E.OP3
E. PE
E.PUE
E.RET
E.CPU
E.E6
E.E7
E.P24
E.CTE
E.15
0
z
z
z
z
z
z
z
z
z
z
1
z
z
z
Setting
2
3
z
z
z
z
z
z
z
z
z
4
z
z
z
z
z
z
5
z
z
z
z
z
z
z
z
z
z
z
z
z
z
z
z
z
z
z
Note: z indicates the errors selected for retry.
90
4
PARAMETERS
• Use Pr. 67 to set the number of retries at alarm occurrence.
Pr. 67 Setting
0
1 to 10
101 to 110
Number of Retries
Retry is not made.
1 to 10 times
1 to 10 times
Alarm Signal Output

Not output.
Output.
• Use Pr. 68 to set the waiting time from when an inverter alarm occurs until a restart in the range 0 to 10
seconds.
• Reading the Pr. 69 value provides the cumulative number of successful restart times made by retry. The
setting of "0" erases the cumulative number of times.
Note: 1. The cumulative number in Pr. 69 is incremented by "1" when retry operation is regarded as
successful, i.e. when normal operation is continued without any alarm occurring during a period
more than four times longer than the time set in Pr. 68.
2. If alarms occur consecutively within a period four times longer than the above waiting time, the
operation panel (FR-DU04) may show data different from the most recent data or the parameter
unit (FR-PU04) may show data different from the first retry data. The data stored as the error reset
for retry is only that of the alarm which occurred the first time.
3. When an inverter alarm is reset at the restart time, the stored data of the electronic overcurrent
protection, regenerative brake duty, etc. are not cleared. (Different from the power-on reset.)
CAUTION
When you have selected the retry function, stay away from the motor and machine
unless required. They will start suddenly (after the reset time has elapsed) after
occurrence of an alarm.
When you have selected the retry function, apply the supplied CAUTION seals in easily
visible places.
Pr. 66 Î Refer to Pr. 22.
91
PARAMETERS
4.2.29 Applied motor (Pr. 71)
Pr. 71 "applied motor"
Related parameters
Pr. 0 "torque boost"
Pr. 12 "DC dynamic brake voltage"
Pr. 19 "base frequency voltage"
Pr. 60 "intelligent mode"
Pr. 100 to Pr. 109 "
V/F frequency/voltage"
Set the motor used.
Parameter
Number
71
Factory
Setting
0
Setting Range
0, 1, 2
<Setting>
• Refer to the following list and set this parameter according to the motor used.
Pr. 71
Setting
0
1
2
Thermal Characteristics of Electronic Overcurrent Protection
Thermal characteristics matching a standard motor
Thermal characteristics matching the Mitsubishi constant-torque motor
Thermal characteristics matching a standard motor
5-point flexible V/F characteristics
Motor
Constant
Standard
Torque
{
{
{
• For the 5.5K and 7.5K, the Pr. 0 and Pr. 12 settings are automatically changed depending on the Pr. 71
setting.
Pr. 71
Pr. 0
Pr. 12
0, 2
3%
4%
1
2%
2%
Note: 1. When "9999" is set in Pr. 19, "2" cannot be set in Pr. 71. To set "2" in Pr. 71, set the appropriate
value (other than "9999") in Pr. 19.
2. When "2" is set in Pr. 71, Pr. 100 to Pr. 109 are displayed on the parameter unit (FR-PU04). In
other settings, if any of Pr. 100 to Pr. 109 settings is changed, the new setting is not displayed in
the "Default parameter list" and "Set parameter list".
4
CAUTION
Set this parameter correctly according to the motor used.
Incorrect setting may cause the motor to overheat and burn.
92
PARAMETERS
4.2.30 PWM carrier frequency (Pr. 72, Pr. 240)
Pr. 72 "PWM frequency selection"
Pr. 240 "Soft-PWM setting"
You can change the motor tone.
z By parameter setting, you can select Soft-PWM control which changes the motor tone.
z Soft-PWM control changes motor noise from a metallic tone into an unoffending complex tone.
Parameter
Number
72
240
Factory
Setting
1
1
Setting Range
Remarks
0, 1, 2, 17
0, 1
0: 0.7kHz, 1: 1kHz, 2: Sine wave filter, 17: 2.5kHz
1: Soft-PWM valid
<Setting>
• Refer to the following list and set the parameters:
Parameter
Number
72
240
Factory Setting
0, 1, 2, 17
0
1
Description
PWM carrier frequency can be changed.
Soft-PWM invalid
Soft-PWM valid.
Note: 1. A reduced PWM carrier frequency will decrease inverter-generated noise and leakage current but
increase motor noise.
2. When using the optional sine wave filter, always set Pr. 72 to 2.
3. When Pr. 72 is set to "2", the Soft PWM will be invalid regardless of the Pr. 240 setting.
4. When "2" is set in Pr. 570, "2" and "17" cannot be set in Pr.72.
5. When Pr. 72 is set to "17", make sure that the motor’s rated current × (1.05 to 1.1) is within 80%
of the inverter’s rated current even if the optional sine wave filter is not used.
93
PARAMETERS
4.2.31 Voltage input (Pr. 73)
Pr. 73 "0-5V/0-10V selection"
Related parameters
Pr. 22 "stall prevention operation level"
Pr. 903 "frequency setting voltage bias"
Pr. 905 "frequency setting current gain"
You can select the analog input terminal specifications, the override function and the function to switch
between forward and reverse rotation depending on the input signal polarity.
Parameter
Number
73
Factory
Setting
1
Setting Range
0 to 5, 10 to 15
<Setting>
Pr. 73
Setting
0
1
2
3
4
5
10
11
12
13
14
15
0
1
2
3
4
5
10
11
12
13
14
15
Terminal AU
Signal
OFF
(No)
Terminal 2
Input Voltage
∗0 to 10V
∗0 to 5V
∗0 to 10V
∗0 to 5V
0 to 10V
0 to 5V
∗0 to 10V
∗0 to 5V
∗0 to 10V
∗0 to 5V
0 to 10V
0 to 5V
Invalid
ON
(Yes)
Terminal 1
Input Voltage
0 to ±10V
0 to ±10V
0 to ±5V
0 to ±5V
∗0 to ±10V
∗0 to ±5V
0 to ±10V
0 to ±10V
0 to ±5V
0 to ±5V
∗0 to ±10V
∗0 to ±5V
0 to ±10V
0 to ±10V
0 to ±5V
0 to ±5V
0 to 10V
0 to 5V
Invalid
Invalid
0 to ±10V
0 to ±10V
0 to ±5V
0 to ±5V
0 to 10V
0 to 5V
Terminal 4 Input,
4 to 20mA
Override Function
×
Polarity
Reversible
No
(Note 3)
{
Invalid
×
Valid
{
×
Yes
∗
No
(Note 3)
{
×
Valid
Invalid
{
Note: 1. The value of terminal 1 (frequency setting auxiliary input) is added to the main speed setting signal
of terminal 2 or 4.
2. When override has been selected, terminal 1 or 4 is for the main speed setting and terminal 2 is
for the override signal (50 to 150% at 0-5V or 0-10V).
3. Indicates that a negative-polarity frequency command signal is not accepted.
4. To change the maximum output frequency at the input of the maximum frequency command
voltage (current), use the frequency setting voltage (current) gain, Pr. 903 (Pr. 905). At this time,
the command voltage (current) need not be input. Also, the acceleration/deceleration time, which
is a slope up/down to the acceleration/deceleration reference frequency, is not affected by the
change in Pr. 73 setting.
5. When the Pr. 22 setting is "9999", the value of terminal 1 is for the stall prevention operation level
setting.
6. ∗ indicates the main speed setting.
94
4
PARAMETERS
4.2.32 Input filter time constant (Pr. 74)
Pr. 74 "filter time constant"
You can set the input section's internal filter constant to an external voltage or current frequency setting signal.
z Effective for eliminating noise in the frequency setting circuit.
z Increase the filter time constant if steady operation cannot be performed due to noise. A larger setting
results in lower response. (The time constant can be set between approximately 1ms to 1s with the setting of
0 to 8. A larger setting results in a larger filter time constant.)
Parameter
Number
74
Factory
Setting
1
Setting Range
0 to 8
4.2.33 Reset selection/PU disconnection detection/PU stop selection
(Pr. 75)
Pr. 75 "reset selection/PU disconnection detection/PU stop selection"
You can select the reset input acceptance, PU (FR-DU04/FR-PU04) connector disconnection detection
function and PU stop function.
• Reset selection
: You can select the reset function input timing.
• PU disconnection detection : When it is detected that the PU (FR-DU04/FR-PU04) connector is
disconnected from the inverter for more than 1 second, the inverter outputs
an alarm code (E.PUE) and comes to an alarm stop.
• PU stop selection
: When an alarm occurs in any operation mode, you can stop the motor from
the PU by pressing the [STOP] key.
Parameter
Number
75
Factory
Setting
14
Setting Range
0 to 3, 14 to 17
<Setting>
Pr. 75
Setting
0
1
2
3
14
15
Reset Selection
Reset input normally enabled.
Reset input enabled only when the
protective function is activated.
Reset input normally enabled.
Reset input enabled only when the
protective function is activated.
Reset input normally enabled.
Reset input enabled only when the
protective function is activated.
16
Reset input normally enabled.
17
Reset input enabled only when the
protective function is activated.
PU Disconnection Detection
If the PU is disconnected, operation
will be continued.
When the PU is disconnected, the
inverter output is shut off.
If the PU is disconnected, operation
will be continued.
When the PU is disconnected, the
inverter output is shut off.
95
PU Stop Selection
Pressing the [STOP] key decelerates
the motor to a stop only in the PU
operation mode.
Pressing the [STOP] key decelerates
the motor to a stop in any of the PU,
external and communication operation
modes.
PARAMETERS
How to make a restart after a stop made by the [STOP] key from the PU during
external operation
(1) Operation panel (FR-DU04)
1) After completion of deceleration to a stop, switch off the STF or STR signal.
2) Press the [MODE] key two times* to call the
indication. (Note 8)
(*: For monitor screen)
3) Press the [SET] key.
4) Turn on the STF or STR signal.
Speed
(2) Parameter unit (FR-PU04)
1) After completion of deceleration to a stop, switch off the STF or STR signal.
2) Press the [EXT] key.
3) Switch on the STF or STR signal.
Time
Operation panel
STF ON
(STR) OFF
[SET] key
[STOP] key
Stop and restart example for external operation
Note: 1. By entering the reset signal (RES) during operation, the inverter shuts off output while it is reset,
the data of the electronic overcurrent protection and regenerative brake duty are reset, and the
motor coasts.
2. The PU disconnection detection function judges that the PU connector is disconnected when it is
removed from the inverter for more than 1 second. If the PU had been disconnected before
power-on, it is not judged as an alarm.
3. To resume operation, reset the inverter after confirming that the PU is connected securely.
4. When PU disconnection detection is set and the PU is then disconnected during PU jog operation,
the motor decelerates to a stop. The motor will not stop if a PU disconnection alarm occurs.
5. The Pr. 75 value can be set any time. Also, if parameter (all) clear is executed, this setting will not
return to the initial value.
6. When the motor is stopped by the PU stop function, PS is displayed but an alarm is not output.
When the PU connector is used for RS-485 communication operation, the reset selection and PU
stop selection functions are valid but the PU disconnection detection function is invalid.
7. The reset key of the PU is only valid when the protective function is activated, independent of the
Pr. 75 setting.
8. When Pr. 79 = "3", press the [MODE] key three times to call the
indication.
Then press the [DOWN] key and proceed to step 3).
CAUTION
Do not reset the inverter with the start signal on.
Otherwise, the motor will start instantly after resetting, which may lead to hazardous
conditions.
96
4
PARAMETERS
4.2.34 Alarm code output selection (Pr. 76)
Pr. 76 "alarm code output selection"
Related parameters
Pr. 79 "operation mode selection"
Pr. 190 to Pr. 195
(multi-function outputs)
When an alarm occurs, its code can be output as a 4-bit digital signal from the open collector output terminals.
When programmed operation has been selected, this parameter also serves to output a group operation
signal.
The alarm code can read by a programmable controller etc to show its remedy on a display. Also you can look
at the progress of programmed operation.
Parameter
Number
76
Factory
Setting
0
Setting Range
0, 1, 2
<Setting>
• Alarm code output
Pr. 76 Setting
0
1
2
Output Terminals
IPF
OL
FU
Alarm code is not output. (Depends on Pr. 190 to Pr. 195).
Alarm code bit 3
Alarm code bit 2
Alarm code bit 1
Alarm code bit 0
When an alarm occurs, an alarm code signal is output. (Output signal is the same as in 1.)
When operation is normal, an operation status signal is output. (Output signal is the same as in 0.)
SU
Note: 1. For alarm code definitions, refer to page 155.
2. The Pr. 76 setting overrides the Pr. 190 to Pr. 195 settings. Therefore, if you assign other signals
to output terminals SU, IPF, OL and FU using Pr. 190 to Pr. 195, these terminals provide the
output signals as listed above when any of "1 to 2" is set in Pr. 76. This should be noted when
using the functions which use the output signals to exercise control.
97
PARAMETERS
4.2.35 Parameter write inhibit selection (Pr. 77)
Pr. 77 "parameter write disable selection"
You can select between write-enable and disable for parameters. This function is used to prevent parameter
values from being rewritten by accident.
Parameter
Number
77
Factory
Setting
0
Setting Range
0, 1, 2
<Setting>
Pr. 77 Setting
0
1
2
Function
Write enabled during a stop only.
Parameter values may only be written during a stop in the PU operation mode.
Write disabled.
Values of Pr.75, Pr. 77 and Pr. 79 "operation mode selection" may be written.
Write enabled even during operation.
Note: 1. The values of the parameters half-tone screened in "4.1.1 Parameter list" can be set at any time.
(Pr. 72 and Pr. 240 values cannot be set during external operation.)
2. If Pr. 77 = "2", the values of the following parameters and 180 to 186, 190 to 195 cannot be written
during operation. Stop operation when changing their parameter settings.
Parameter
Number
Parameter
Number
Name
71
Stall prevention operation level at
double speed
Second stall prevention operation
current
Second stall prevention operation
frequency
Intelligent mode selection
Reference current
Stall prevention operation reduction
starting frequency
Applied motor
79
Operation mode selection
135
100
101
V/F1 (first frequency)
V/F1 (first frequency voltage)
136
137
102
V/F2 (second frequency)
138
23
48
49
60
61
66
Name
103
V/F2 (second frequency voltage)
104
V/F3 (third frequency)
105
V/F3 (third frequency voltage)
106
107
V/F4 (fourth frequency)
V/F4 (fourth frequency voltage)
108
V/F5 (fifth frequency)
109
V/F5 (fifth frequency voltage)
Commercial power supply-inverter
switch-over sequence output
terminal selection
MC switch-over interlock time
Start waiting time
Commercial power supply-inverter
switch-over selection at alarm
occurrence
Automatic inverter-commercial
power supply switch-over frequency
139
180 to 186,
190 to 195
Input / Output signal set
3. By setting "1" in Pr. 77, the following clear operations can be inhibited:
• Parameter clear
• All clear
• User clear
98
4
PARAMETERS
4.2.36 Reverse rotation prevention selection (Pr. 78)
Pr. 78 "reverse rotation prevention selection"
This function can prevent any reverse rotation fault resulting from the misoperation of the start signal.
z Used for a machine which runs only in one direction, e.g. fan, pump.
(The setting of this function is valid for the PU, external and communication operations.)
Parameter
Number
78
Factory
Setting
0
Setting Range
0, 1, 2
<Setting>
Pr. 78 Setting
0
1
2
Function
Both forward and reverse rotations allowed
Reverse rotation disallowed
Forward rotation disallowed
99
PARAMETERS
4.2.37 Operation mode selection (Pr. 79)
Related parameters
Pr. 79 "operation mode selection"
Pr. 15 "jog frequency"
Pr. 4 to Pr. 6, Pr. 24 to 27
"multi-speed operation"
Pr. 76 "alarm code output selection"
Pr. 180 to Pr. 186
(input terminal function selection)
Used to select the operation mode of the inverter.
You can choose any of the operation modes: operation using external signals (external operation), operation
from the PU (FR-DU04/FR-PU04) (PU operation), combination of PU operation and external operation
(external/PU combined operation), and computer link operation (when the FR-A5NR option is used).
Parameter
Number
79
Factory
Setting
0
Setting Range
0 to 4, 6 to 8
<Setting>
Pr. 79 Setting
0
1
2
3
4
6
7
8
Function
PU or external operation can be selected.
PU operation mode
External operation mode
External/PU combined operation mode 1
Running frequency ... Set from the PU (FR-DU04/FR-PU04) (direct setting, [UP/DOWN] key) or external
signal input (multi-speed setting only)
Start signal............... External signal input (terminal STF, STR)
External/PU combined operation mode 2
Running frequency ... External signal input (terminal 2, 4, 1, jog, multi-speed selection)
Start signal............... Input from the PU (FR-DU04/FR-PU04) ([FWD] key, [REV] key)
Switch-over mode
Switch-over between PU operation, external operation and computer link operation (when the communication
option such as the FR-A5NR is used) modes can be done while running.
External operation mode (PU operation interlock)
X12 signal ON.......... May be switched to PU operation mode (output stop during external operation)
X12 signal OFF ........ Switching to PU operation mode inhibited
Switching to other than external operation mode (disallowed during operation)
X16 signal ON ......... Switched to external operation mode
X16 signal OFF ........ Switched to PU operation mode
Note: 1. Either "3" or "4" may be set to select the PU/external combined operation. These settings differ in
starting method.
100
4
PARAMETERS
(1) Switch-over mode
You can select between PU operation, external operation and computer link operation (when FR-A5NR option
is used).
Operation Mode Switching
Switching Operation/Operating Status
External operation to PU operation
1) Select the PU operation mode.
• Rotation direction is the same as that of external operation.
• Set frequency is as set by the potentiometer (frequency setting potentiometer). (Note that
the setting will disappear when power is switched off or the inverter is reset.)
External operation to computer link
operation
1) Mode change command to computer link mode is transmitted from the computer.
• Rotation direction is the same as that of external operation.
• Set frequency is as set by the potentiometer (frequency setting potentiometer). (Note that
the setting will disappear when power is switched off or the inverter is reset.)
PU operation to external operation
1) Press the external operation key of the parameter unit.
• Rotation direction is determined by the external operation input signal.
• Set frequency is determined by the external frequency setting signal.
PU operation to computer link
operation
1) Mode change command to computer link mode is transmitted from the computer.
• Rotation direction and set frequency are the same as those of PU operation.
Computer link operation to external
operation
1) The switch-over command to the external mode is sent from the computer.
• Rotation direction is determined by the external operation input signal.
• Set frequency is determined by the external frequency setting signal.
Computer link operation to PU
operation
1) Select the PU operation mode with the operation panel or parameter unit.
• Rotation direction and set frequency are the same as those of computer link operation.
(2) PU operation interlock
When the PU operation interlock signal is switched off, the operation mode is forcibly changed to the external
operation mode. This function prevents the inverter from being inoperative by the external command if the
mode is accidentally left unswitched from the PU operation mode.
1) Preparation
• Set "7" in Pr. 79 (PU operation interlock).
• Using any of Pr. 180 to Pr. 186 (multi-function input terminal assignment), allocate the terminal used to
input X12 (PU external interlock signal).
• When the X12 signal is not assigned, the function of the MRS signal changes from MRS (output stop) to
PU external interlock.
2) Function
X12 (MRS) Signal
Function/Operation
ON
Output stopped during external operation.
Operation mode can be switched to PU operation mode.
Parameter values can be rewritten in PU operation mode.
PU operation allowed.
OFF
Forcibly switched to external operation mode.
External operation allowed.
Switching to PU operation mode inhibited.
101
PARAMETERS
<Function/operation changed by switching on-off the X12 (MRS) signal>
Operating Condition
Operation
mode
PU
External
X12 (MRS)
Signal
Status
During stop
ON → OFF
(Note 3)
During
operation
ON → OFF
(Note 3)
During stop
OFF → ON
ON → OFF
During
operation
OFF → ON
ON → OFF
Operation
Mode
(Note 4)
External
External
Operating Status
Parameter Write
Switching
to PU
Operation
Mode
During stop
Allowed → disallowed
Disallowed
If external operation
frequency setting and start
signal are entered,
operation is performed in
that status.
Allowed → disallowed
Disallowed
During stop
Disallowed → disallowed
Disallowed → disallowed
Allowed
Disallowed
Disallowed → disallowed
Disallowed
Disallowed → disallowed
Disallowed
During operation →
output stop
Output stop →
During operation
Note: 1. When the Pr. 79 setting is 7 and the PU operation interlock signal is OFF, network operation such
as computer link cannot be used.
2. If the X12 (MRS) signal is on, the operation mode cannot be switched to the PU operation mode
when the start signal (STF, STR) is on.
3. The operation mode switches to the external operation mode independently of whether the start
signal (STF, STR) is on or off. Therefore, the motor is run in the external operation mode when the
X12 (MRS) signal is switched off with either of STF and STR on.
4. When an alarm occurs, the inverter can be reset by pressing the [RESET] key of the operation
panel.
5. When the MRS signal is used as the PU interlock signal, switching the MRS signal on and
rewriting the Pr. 79 value to other than 7 in the PU operation mode causes the MRS signal to
provide the ordinary MRS function (output stop). Also, as soon as 7 is set in Pr. 79, the MRS signal
acts as a PU interlock signal.
6. When the MRS signal is used as the PU external interlock signal, the signal logic conforms to the
Pr. 17 setting. When Pr. 17 = 2, read ON for OFF and OFF for ON in the above explanation.
(3) Operation mode external signal switching function
1) Preparation
Set "8" (switching to other than external operation mode) in Pr. 79. Using any of Pr. 180 to Pr. 186 (input
terminal function selection), allocate the terminal used to input the X16 (PU-external operation switching)
signal.
2) Function
When the X16 signal is switched on in the PU operation mode, the operation mode is forcibly changed to
the external operation mode. When the X16 signal is switched off in the external operation mode, the
operation mode is changed to the PU operation mode. When the X16 signal is switched off during network
operation such as computer link, the operation mode is changed to the PU operation mode as soon as the
switch-over command to the external operation mode is sent from the computer. Note that this switch-over
may only be made while the inverter is at a stop and cannot be made during operation.
X16 Signal
ON
OFF
Operation Mode
External operation mode (cannot be changed to the PU operation mode)
PU operation mode (cannot be changed to the external operation mode)
Note: When terminal assignment is changed using Pr. 180 to Pr. 186, the other functions may be affected.
Check the functions of the corresponding terminals before making setting.
102
4
PARAMETERS
4.2.38 V/F control frequency (voltage) (Pr. 100 to Pr. 109)
Pr. 100 "V/F1 (first frequency)"
Related parameters
Pr. 19 "base frequency voltage"
Pr. 47 "second V/F (base frequency)"
Pr. 60 "intelligent mode selection"
Pr. 71 "applied motor"
Pr. 101 "V/F1 (first frequency voltage)"
Pr. 102 "V/F2 (second frequency)"
Pr. 103 "V/F2 (second frequency voltage)"
Pr. 104 "V/F3 (third frequency)"
Pr. 105 "V/F3 (third frequency voltage)"
Pr. 106 "V/F4 (fourth frequency)"
Pr. 107 "V/F4 (fourth frequency voltage)"
Pr. 108 "V/F5 (fifth frequency)"
Pr. 109 "V/F5 (fifth frequency voltage)"
You can make a dedicated V/F pattern by using V/F (frequency Voltage/Frequency) control to set V/F
characteristics from the start to the basic frequency and basic voltage as desired.
z Desired V/F characteristics can be set by presetting V/F1 (first frequency voltage/first frequency), V/F2, V/F3,
V/F4 and V/F5 in the corresponding parameters.
Parameter
Number
100
101
102
103
104
105
106
107
108
109
Factory
Setting
9999
0
9999
0
9999
0
9999
0
9999
0
Setting Range
Remarks
0 to 120Hz, 9999
0 to 1000V
0 to 120Hz, 9999
0 to 1000V
0 to 120Hz, 9999
0 to 1000V
0 to 120Hz, 9999
0 to 1000V
0 to 120Hz, 9999
0 to 1000V
Set "2" in Pr. 71 and a value
other than 9999 in Pr. 19.
These functions are not
activated when any of "1 to 8"
is set in Pr. 60.
Voltage
Base frequency voltage
(Pr. 19)
V/F4
V/F5
V/F3
V/F1
Boost value
(Pr. 0)
V/F2
Frequency
0
V/F characteristic
Base frequency
(Pr. 3)
<Setting>
(1) Confirm the settings of Pr. 19, Pr. 60 and Pr. 71.
Parameter Number
19
60
71
Description
Set the rated motor voltage.
This function is not activated if its value is "9999" and "8888" (factory setting).
Set "0" (ordinary operation mode).
Set "2" (V/F 5-point flexible characteristic).
103
PARAMETERS
(2) Set the desired frequencies and voltages in Pr. 100 to Pr. 109.
• The setting must satisfy the following relationship: F1≠F2≠F3≠F4≠F5≠Pr. 19 "base frequency".
If the set frequencies are the same, a write error occurs.
If any frequency setting is "9999", its point is ignored.
Note: 1.
2.
3.
4.
The V/F 5-point flexible characteristic functions for V/F control only.
The V/F 5-point flexible characteristic does not function when Pr. 60 is selected.
The frequency voltage setting should be equal to or less than the Pr. 3 and Pr. 19 settings.
Pr. 19 must be set. (When Pr. 19 = "9999", Pr. 71 cannot be set to "2" (5-point flexible V/F
characteristic).)
5. If "2" is set in Pr. 71, Pr. 47 and Pr. 113 do not function.
6. When "2" is set in Pr. 71, the electronic overcurrent protection is calculated for a standard motor.
4.2.39 Computer link operation (Pr. 117 to Pr. 124)
Pr. 117 "station number"
Pr. 118 "communication speed"
Pr. 119 "stop bit length/data length"
Pr. 120 "parity check presence/absence"
Pr. 121 "number of communication retries"
Pr. 122 "communication check time interval"
Pr. 123 "waiting time setting"
Pr. 124 "CR, LF presence/absence selection"
Used to perform required settings for RS-485 communication between the inverter and personal computer.
Using the inverter setup software (FR-SW0-SETUP-WE (or -WJ for Japanese version)), parameter setting,
monitoring, etc. can be done efficiently.
z The motor can be run from the PU connector of the inverter using RS-485 communication.
Communication specifications
Communication
specifications
Conforming standard
Number of inverters connected
Communication speed
Control protocol
Communication method
Character system
Stop bit length
Terminator
Parity check
Check system
Sumcheck
Waiting time setting
RS-485
1:N (maximum 32 inverters)
Selected between 19200, 9600 and 4800bps
Asynchronous
Half-duplex
ASCII (7 bits/8 bits) selectable
Selectable between 1 bit and 2 bits.
CR/LF (presence/absence selectable)
Selected between presence (even/odd) or absence
Present
Selectable between presence or absence
104
4
PARAMETERS
z For the data codes of the parameters, refer to the data code list in the appendices.
Parameter
Number
117
118
Factory
Setting
0
192
119
1
120
121
122
123
124
2
1
0 <9999>
9999
1
Setting Range
0 to 31
48, 96, 192
Data length 8
0, 1
Data length 7
10, 11
0, 1, 2
0 to 10, 9999
0 to 999.8 sec, 999
0 to 150ms, 9999
0, 1, 2
<Setting>
To make communication between the personal computer and inverter, the communication specifications must
be set to the inverter initially. If initial setting is not made or there is a setting fault, data transfer cannot be
made.
Note: After making the initial setting of the parameters, always reset the inverter. After you have changed the
communication-related parameters, communication will not occur until the inverter is reset.
Parameter
Number
Name
117
Station
number
118
Communication
speed
119
Stop bit
length/data
length
120
Parity check
presence/
absence
Setting
Description
0 to 31
48
96
192
0
8 bits
1
10
11
7 bits
0
1
2
0 to 10
121
122
123
124
Number of
communication retries
Communication
check time
interval
Waiting
time setting
CR, LF
presence/
absence
selection
9999
(65535)
0
0.1 to 999.8
9999
0 to 150ms
9999
0
1
2
Station number specified for communication from the PU connector.
Set the inverter station numbers when two or more inverters are connected to one
personal computer.
4800 baud
9600 baud
19200 baud
Stop bit length 1 bit
Stop bit length 2 bits
Stop bit length 1 bit
Stop bit length 2 bits
Absent
Odd parity present
Even parity present
Set the permissible number of retries at occurrence of data receive error. If the
number of consecutive errors exceeds the permissible value, the inverter will come
to an alarm stop.
If a communication error occurs, the inverter will not come to an alarm stop. At this
time, the inverter can be coasted to a stop by MRS or RESET input.
During an error, the light fault signal (LF) is given to the open collector output.
Allocate the used terminal with any of Pr. 190 to Pr. 195 (output terminal function
selection).
No communication
Set the communication check time [seconds] interval.
If a no-communication state persists for longer than the permissible time, the
inverter will come to an alarm stop.
Set the waiting time between data transmission to the inverter and response.
Set with communication data.
Without CR/LF
With CR • Without LF
With CR/LF
105
PARAMETERS
<Computer programming>
(1) Communication protocol
Data communication between the computer and inverter is performed using the following procedure:
Data read
Computer
↓ (Data flow)
*2
4)
1)
Inverter
Inverter
2)
5)
Time
3)
*1
↓ (Data flow)
Data write
Computer
*1. If a data error is detected and a retry must be made, execute retry operation from the user program. The
inverter comes to an alarm stop if the number of consecutive retries exceeds the parameter setting.
*2. On receipt of a data error occurrence, the inverter returns “reply data 3)” to the computer again. The
inverter comes to an alarm stop if the number of consecutive data errors reaches or exceeds the
parameter setting.
(2) Communication operation presence/absence and data format types
Communication operation presence/absence and data format types are as follows:
No.
1)
2)
3)
4)
5)
Operation
Communication request is sent to the
inverter in accordance with the user
program.
Inverter data processing time
Reply data from the No error
inverter
Request accepted
(Data 1) is checked With error
for error)
request rejected
Computer processing delay time
Answer from
No error
computer in
No processing
response to reply
data 3)
With error data
(Data 3) is checked 3) is output
for error)
Run
Command
Running
Frequency
Parameter
Write
Inverter
Reset
Monitoring
Parameter
Read
A’
A
A
A
B
B
Present
Present
Present
Absent
Present
Present
C
C
C
Absent
E
E’
E
D
D
D
Absent
F
F
Absent
Absent
Absent
Absent
G
G
Absent
Absent
Absent
Absent
G
G
Absent
Absent
Absent
Absent
H
H
(3) Data format
Hexadecimal data is used. Data is automatically transferred in ASCII between the computer and inverter.
• Data format types
1) Communication request data from computer to inverter
[Data format]
Format A
*3
ENQ
1
Format A'
[Data read]
Format B
*3
ENQ
1
*3
ENQ
1
Inverter
station
number
2
3
Inverter
station
number
2
3
Inverter
station
number
2
3
*5
Instruction
Waiting
code
time
4
5
6
7
*5
Instruction
Waiting
code
time
4
5
6
5
6
8
Data
7
*5
Instruction
Waiting
code
time
4
Sum
sheck
Data
9
Sum
sheck
8
9
Sum
sheck
*4
8
9
7
106
10
10
11
12
*4
13 ←Number of characters
*4
11 ←Number of characters
←Number of characters
4
PARAMETERS
Note: 1. The inverter station numbers may be set between H00 and H1F (stations 0 and 31) in
hexadecimal.
2. *3 indicates the control code.
3. *4 indicates the CR or LF code.
When data is transmitted from the computer to the inverter, codes CR (carriage return) and
LF (line feed) are automatically set at the end of a data group on some computers. In this
case, setting must also be made from the inverter according to the computer.
Also, the presence and absence of the CR and LF codes can be selected using Pr. 124.
4. *5: When Pr. 123 "waiting time setting" ≠ 9999, create the communication request data with
no "waiting time" in the data format. (The number of characters decreases by 1.)
2) Send data from computer to inverter during data write
[No data error detected]
Format C
*3
ACK
1
[Data error detected]
Inverter
station *4
number
2
3
4 ←Number of
characters
Format D
*3 Inverter Error
NAK station code *4
number
1
2
3
4
5 ←Number of
characters
3) Reply data from inverter to computer during data read
[Data error detected]
[No data error detected]
Format E
*3
STX
1
Format E'
*3
STX
1
Inverter
station
number
2
3
4
Inverter
station
number
2
*3
ETX
Read data
5
Read
data
3
4
6
*3
ETX
5
6
7
Sum
check
8
9
Sum
check
*4
7
8
10
Format F
*4
11
*3
NAK
9 ←Number of characters
1
Inverter
station
number
2
3
Error
code
*4
4
5
4) Reply data from computer to inverter during data read
[No data error detected]
Format G
*3
ACK
1
[Data error detected]
Inverter
station
number
*4
2
4 ←Number of characters
3
Format H
*3
NAK
1
Inverter
station
number
*4
2
4
3
←Number of characters
(4) Data definitions
1) Control codes
Signal
STX
ETX
ENQ
ACK
LF
CR
NAK
ASCII Code
H02
H03
H05
H06
H0A
H0D
H15
Description
Start of Text (Start of data)
End of Text (End of data)
Enquiry (Communication request)
Acknowledge (No data error detected)
Line Feed
Carriage Return
Negative Acknowledge (Data error detected)
2) Inverter station number
Specify the station number of the inverter which communicates with the computer.
3) Instruction code
Specify the processing request (e.g. operation, monitoring) given by the computer to the inverter. Hence,
the inverter can be run and monitored in various ways by specifying the instruction code as appropriate.
(Refer to page 173)
4) Data
Indicates the data such as frequency and parameters transferred to and from the inverter. The definitions
and ranges of set data are determined in accordance with the instruction codes. (Refer to page 173)
107
PARAMETERS
5) Waiting time
Specify the waiting time between the receipt of data at the inverter from the computer and the transmission
of reply data. Set the waiting time in accordance with the response time of the computer between 0 and
150ms in 10ms increments (e.g. 1 = 10ms, 2 = 20ms).
Computer
↓
Inverter
Inverter
↓
Computer
Inverter data processing time
= waiting time
+ data check time
(set value×10ms)
(12ms)
Note: If the Pr. 123 "waiting time setting" value is not 9999, create the communication request data with no
"waiting time" in the data format. (The number of characters is decremented by 1.)
6) Sum check code
The sum check code is 2-digit ASCII (hexadecimal) representing the lower 1 byte (8 bits) of the sum
(binary) derived from the checked ASCII data.
Computer→Inverter
ASCII code→
ENQ
H05
Station
number
Instruction
code
*Waiting
time
(Example1)
Sum check
code
Data
0
1
E
1
1
0
7
A
D
F
4
H30
H31
H45
H31
H31
H30
H37
H41
H44
H46
H34
←Binary code
↓
H
H
H
H H
H
H H
H
30 + 31 + 45 + 31 + 31 + 30 + 37 + 41 + 44
H
=1F4
Sum
*When Pr. 123 "waiting time setting" ≠ 9999, create the communication request data with no "waiting time" in the data format.
(The number of characters is decreased by 1.)
(Example2)
Inverter→Computer
STX
ASCII code→
H02
Station
number
ETX Sum check
code
Read data
0
1
1
7
7
0
H30
H31
H31
H37
H37
H30
↓
H
H H
H
H
H
30 + 31 + 31 + 37 + 37 + 30
H
=130
Sum
108
H03
3
0
H33
H30
←Binary code
4
PARAMETERS
7) Error code
If any error is found in the data received by the inverter, its definition is sent back to the computer together
with the NAK code. (Refer to page109.)
Note: 1. When the data from the computer has an error, the inverter will not accept that data.
2. Any data communication, e.g. run command, monitoring, is started when the computer
gives a communication request. Without the computer's command, the inverter does not
return any data. For monitoring, therefore, design the program to cause the computer to
provide a data read request as required.
3. Data for link parameter expansion setting differs as indicated below between access to
Pr. 0 to Pr. 99 values and access to Pr. 100 to Pr. 905:
Instruction
Code
Read
H7F
Write
HFF
Link parameter
expansion setting
Data
H00: Pr. 0 to Pr. 79 values are accessible.
H01: Pr. 100 to Pr. 158 and Pr. 900 to Pr. 905 values are
accessible.
H02: Pr. 160 to Pr. 244 values are accessible.
H03: Pr. 300 to Pr. 342 values are accessible.
H09: Pr. 990 and Pr.991 values are accessible.
109
PARAMETERS
Instructions for the program
(1) If the data from the computer is in error, the inverter will not accept that data. Hence, always insert a dataerror retry program in the user program.
(2) Since any data communication, such as operation command or monitoring, is always requested by the
computer, the inverter will not return data without the computer's request. Hence, design the program so
that the computer gives a data read request for monitoring, etc. as required.
(3) Program example
When the operation mode is switched to communication operation
Initial setting of I/O file
: Communication file opening
: Circuit control signal (RS, ER) ON/OFF setting
: Interrupt definition at data receive
: Interrupt enable
Transmission data setting
10 OPEN "COM1: 9600, E, 8, 2, HD" AS#1
20 COMST1, 1, 1: COMST1, 2, 1
30 ON COM (1) GOSUB*REC
40 COM (1) ON
50 D$= "01FB10002"
60 S=0
70 FOR I=1 TO LEN (D$)
80 A$=MID$ (D$, I, 1)
90 A=ASC (A$)
100 S=S+A
110 NEXTI
120 D$=CHR$ (&H5) +D$+RIGHT$ (HEX$ (S) , 2)
130 PRINT#1, D$
140 GOTO 50
1000 *REC
1010 IF LOC (1)=0 THEN RETURN
1020 PRINT "RECEIVE DATA"
1030 PRINT INPUT$ (LOC (1) , #1)
1040 RETURN
Sum code calculation
: Addition of control and sum codes
Data transmission
Interrupt data receive
: Interrupt occurrence at data receive
General flowchart
Line number
10
40
50
140
I/O file
initial setting
Transmission data
processing
{Data setting
{Sum code calculation
{Data transmission
1000
Interrupt
Receive data processing
{Data import
{Screen display
1040
CAUTION
When the inverter's communication check time interval is not set, interlocks are
provided to disable operation to prevent hazard. Always set the communication check
time interval before starting operation.
Data communication is not started automatically but is made only when the computer
provides a communication request. If communication is disabled during operation due
to signal cable breakage etc, the inverter cannot be stopped. When the communication
check time interval has elapsed, the inverter will come to an alarm stop (E.PUE).
The inverter can be coasted to a stop by switching on its RES signal or by switching
power off.
If communication is halted due to signal cable breakage, computer fault etc., the
inverter does not detect such a fault. This should be fully noted.
110
4
PARAMETERS
<Setting items and set data>
After completion of parameter setting, set the instruction codes and data and start communication from the
computer to allow various types of operation control and monitoring.
No.
Instruction
Code
Item
Read
1
H7B
Operation
mode
Write
HFB
Output frequency
[speed]
H6F
Output current
H70
Output voltage
H71
Special monitor
H72
Number of
Data Digits
Description
H0000: Communication option operation
H0001: External operation
H0002: Communication operation (PU connector)
H0000: Communication option operation
H0001: External operation
H0002: Communication operation (PU connector)
H0000 to HFFFF: Output frequency (hexadecimal) in 0.01Hz
increments
[Speed (hexadecimal) in 1r/min increments if Pr. 37 = 1 to
9998 or Pr. 144 = 2 to 10, 102 to 110.]
H0000 to HFFFF: Output current (hexadecimal) in 0.01A
increments
H0000 to HFFFF: Output voltage (hexadecimal) in 0.1V
increments
H0000 to HFFFF: Monitored data selected by instruction code
HF3
H01 to H0E
Monitor selection data
Data
Description
Increments
Data
Description
4 digits
4 digits
4 digits
4 digits
4 digits
Increments
Electronic
H01
Read
H73
Special monitor
selection No.
Output
frequency
0.01Hz
H0A
0.01A
H0B
overcurrent
protection
load
0.1%
factor
H02
Output current
Output
current
peak value
0.01A
2 digits
Converter output
H03
Output voltage
0.1V
H0C
voltage
peak
0.1V
value
Monitoring
2
H05
Write
HF3
H06
Frequency
setting
Running
speed
0.01Hz
H0D
Input power
0.01kW
r/min
H0E
Output power
0.01kW
H0000 to HFFFF: Two most recent alarm definitions
Read data: [Example] H30A0
(Previous alarm ........ THT)
(Most recent alarm ..... OPT)
b15
b8b7
b0
0 0 1 1 0 0 0 0 1 0 1 0 0 0 0 0
Previous alarm
(H30)
Alarm definition
H74 to H77
Most recent alarm
(HA0)
Alarm data
Data
Description
Data
Description
Data
Description
H00
No alarm
H40
FIN
HA2
OP2
H10
0C1
H50
IPF
HA3
OP3
H11
0C2
H51
UVT
HB0
PE
H12
0C3
H60
OLT
HB1
PUE
H20
0V1
H80
GF
HB2
RET
H21
0V2
H81
LF
HC1
CTE
HC2
P24
H22
0V3
H90
OHT
H30
THT
HA0
OPT
H31
THM
HA1
OP1
111
2 digits
PARAMETERS
No.
Instruction
Code
Item
H00 to HFF: Run command
b7
0 0
3
Run command
HFA
0
0
0
0
b0
0
1
(For example 1)
[Example 1] H02
... Forward rotation
[Example 2] H00
... Stop
b0:
b1: Forward rotation (STF)
b2: Reverse rotation (STR)
b3:
b4:
b5:
b6:
b7:
2 digits
b0: Inverter running (RUN) *
b1: Forward rotation
b2: Reverse rotation
b3: Up to frequency (SU) *
b4: Overload (OL) *
b5: Instantaneous power
failure (IPF) *
b6: Frequency detection (FU) *
b7: Alarm occurrence *
2 digits
H00 to HFF: Inverter status monitor
b7
0
0
0
0
0
0
1
0
(For example 1)
4
Inverter status monitor
H7A
5
Running frequency
write
(E2PROM)
HEE
6
Inverter reset
HFD
Number
of Data
Digits
Description
[Example 1] H02
... During forward rotation
[Example 2] H80
... Stop due to alarm
*The output data depends on the Pr. 190 to Pr. 195 settings.
H0000 to H9C40:
0.01Hz increments (hexadecimal)
(0 ≠ 400.00 Hz)
To change the running frequency consecutively, write data
to the inverter RAM. (Instruction code: HED)
H9696: Resets the inverter.
As the inverter is reset on start of communication by the computer, the
inverter cannot send reply data back to the computer.
4 digits
4 digits
All parameters return to the factory settings.
Any of four different clear operations is performed according to the data.
Pr.
7
All clear
HFC
HEC
Communi-
Calibration
cation Pr.
Data
H9696
Other Pr.
HF3
HFF
{
×
{
{
H9966
{
{
{
{
H5A5A
×
×
{
{
H55AA
×
{
{
{
4 digits
When all parameter clear is executed for H9696 or H9966,
communication-related parameter settings also return to the factory
settings. When resuming operation, set the parameters again.
H9669: User clear is made.
HEC
8
User clear
HFC
Communi-cation Pr.
Calibration
Other Pr.
HF3
4 digits
HFF
×
{
9
Parameter write
H80 to HE3
10
Parameter read
H00 to H63
11
Link parameter
expansion
setting
12
Second
parameter
changing
(Code
FF = 1)
Read
H7F
Write
HFF
Read
H6C
Write
HEC
{
{
Refer to the data list (page 173) and write and/or read parameter values
as required.
Note that some parameters may not be accessible.
H00 to H6C and H80 to HEC parameter values are changed.
H00: Pr. 0 to Pr. 79 values are accessible.
H01: Pr. 100 to Pr. 158 and Pr. 900 to Pr. 905 values are accessible.
H02: Pr. 160 to Pr. 244 values are accessible.
H03: Pr. 300 to Pr. 342 values are accessible.
H09: Pr. 990 and Pr. 991 values are accessible.
When setting the programmed operation
(data code H3D to H5A, H8D to HAD)
6 3 3 B
parameter
Time (Min.) Min. (Sec.)
H00: Time
H01: Time
H02: Rotation direction
When setting the bias/gain (data code H5E to H6A, HDE to HED)
parameter
H00: Offset/gain
H01: Analog
H02: Analog value of terminal
112
4 digits
2 digits
2 digits
4
PARAMETERS
<Error Code List>
The corresponding error code in the following list is displayed if an error is detected in any communication
request data form the computer.
Error
Code
Item
H0
Computer NAK error
H1
Parity error
H2
Sum check error
H3
Protocol error
H4
Framing error
H5
Overrun error
H6

H7
H8
H9
Character error


HA
Mode error
HB
Instruction code error
HC
Data range error
HD
HE
HF



Definition
The number of errors consecutively detected in communication request
data from the computer is greater than allowed number of retry times.
The parity check result does not match the specified parity.
The sum check code in the computer does not match that of the data
received by the inverter.
Data received by the inverter is in the wrong protocol, data receive is not
completed within the given time, or CR and LF are not as set in the
parameter.
The stop bit length is not as specified.
New data has been sent by the computer before the inverter completes
receiving the preceding data.

The character received is invalid (other than 0 to 9, A to F, control code).


Parameter write was attempted in other than the computer link operation
mode or during inverter operation.
The specified command does not exist.
Invalid data has been specified for parameter write, frequency setting,
etc.



113
Inverter Operation
Brought to an alarm stop
(E.OPT) if error occurs
continuously more than
the allowable number of
retry times.

Does not accept receive
data but is not brought to
alarm stop.


Does not accept or
receive data but is not
brought to alarm stop.



PARAMETERS
(5) Communication specifications for RS-485 communication
Operation Mode
Operation Location
Communication
Operation from PU
Connector
Enable
Item
Run command (start)
Computer user program via
PU connector
Computer user program via
inboard option
Control circuit terminal
Running frequency setting
Enable
Monitoring
Parameter write
Parameter read
Inverter reset
Stop command (*3)
Run command
Running frequency setting
Monitoring
Parameter write
Parameter read
Inverter reset
Stop command (*3)
Inverter reset
Run command
Running frequency setting
Enable
Enable (*4)
Enable
Enable
Enable
Disable
Disable
Enable
Disable (*4)
Enable
Disable
Enable
Enable
Disable
Disable
External
Operation
Computer Link Operation
(inboard option used)
Disable
Enable
(Combined
operation mode)
Enable
Disable (*4)
Enable
Enable
Enable
Disable
Disable
Enable
Disable (*4)
Enable
Disable
Enable
Enable
Enable
Enable
Disable
Disable
Enable
Disable (*4)
Enable
Enable
Enable
Enable (*1)
Enable (*1)
Enable
Enable (*4)
Enable
Enable
Enable
Enable
Enable (*1)
Enable (*1)
(*1) As set in the operation and speed command write parameters.
(*2) At occurrence of RS-485 communication fault, the inverter cannot be reset from the computer.
(*3) As set in Pr. 75.
(*4) As set in Pr. 77.
(6) Operation at alarm occurrence
Operation Mode
Fault Location
Communication
Operation
(PU connector)
Stop
Stop
Computer link
Operation
(inboard option used)
Stop
PU connector
Continued
Continued
Continued
Inboard option
Continued
Continued
Continued
Continued
Description
Inverter operation
Inverter fault
Communication error
(Communication
from PU connector)
Communication error
(Inboard option)
Communication
Inverter operation
Communication
Stop/continued (*5)
Continued
PU connector
Stop
Stop
Stop
Inboard option
Continued
Continued
Continued
Continued
Continued
Stop/continued (*6)
PU connector
Continued
Continued
Continued
Inboard option
Stop
Stop
Stop
Inverter operation
Communication
(*5) Can be selected using the corresponding parameter (factory-set to continue)
(*6) Can be selected using the corresponding parameter (factory-set to stop)
(7) Communication error
Fault Location
Communication error
(Communication from PU connector)
Communication error
(Inboard option)
External
Operation
Error Message
E.PUE
E.OP1 to E.OP3
114
4
PARAMETERS
4.2.40 PID control (Pr. 128 to Pr. 134)
Pr. 128 "PID action selection"
Related parameters
Pr. 73 "0-5V/0-10V selection"
Pr. 79 "operation mode selection"
Pr. 180 to Pr. 186
(input terminal assignment)
Pr. 191 to Pr. 194
(output terminal assignment)
Pr. 902 to Pr. 905
(frequency setting voltage
(current) biases and gains)
Pr. 129 "PID proportional band"
Pr. 130 "PID integral time"
Pr. 131 "upper limit"
Pr. 132 "lower limit"
Pr. 133 "PID action set point for PU operation"
Pr. 134 "PID differential time"
The inverter can be used to exercise process control, e.g. flow rate, air volume or pressure.
z The voltage input signal (0 to ±5V or 0 to ±10V) or Pr. 133 setting is used as a set point and the 4 to
20mADC current input signal used as a feedback value to constitute a feedback system for PID control.
Parameter
Number
128
129
130
131
132
133
134
Factory
Setting
10
100%
1s
9999
9999
0%
9999
Setting Range
Remarks
10, 11, 20, 21
0.1 to 1000%, 9999
0.1 to 3600 s, 9999
0 to 100%, 9999
0 to 100%, 9999
0 to 100%
0.01 to 10.00 s, 9999
9999: No proportional control
9999: No integral control
9999: Function invalid
9999: Function invalid
9999: No differential control
<Setting>
(1) Basic PID control configuration
Manipulated
variable
Deviation
Set point
U
x
+
- y
PID Kp 1+ 1 +Td ‚ S
Ti ‚ S
operation
fi
Motor
Inverter
drive circuit
IM
y
Process value
Kp: Proportional constant
Ti: Integral time
S: Operator
Td: Differential time
(2) PID action overview
1) PI action
A combination of proportional control action (P) and integral control action (I) for providing a manipulated
variable in response to deviation and changes with time.
[Operation example for stepped changes of process value]
Deviation Set point
Process value
Note: PI action is the sum of P and I actions.
P action
I action
PI action
115
Time
Time
Time
PARAMETERS
2) PD action
A combination of proportional control action (P) and differential control action (D) for providing a
manipulated variable in response to deviation speed to improve the transient characteristic.
Set point
[Operation example for proportional changes of process
value]
Note: PD action is the sum of P and D actions.
Deviation
P action
Process
value
Time
D action
Time
PD action
Time
3) PID action
The PI action and PD action are combined to utilize the advantages of both actions for control.
Note: The PID action is the sum of P and I and D actions.
4) Reverse action
Increases the manipulated variable (output frequency) if deviation X (set point - process value) is positive,
and decreases the manipulated variable if deviation is negative.
Deviation
Set point
[Heating]
Set point
X>0
+
-
X<0
Cold → fi up
Hot → fi down
Process value
Process value
5) Forward action
Increases the manipulated variable (output frequency) if deviation X (set point - process value) is negative,
and decreases the manipulated variable if deviation is positive.
Process value
[Cooling]
Set point
X>0
+
-
X<0
Set point
Too cold → fi down
Hot
→ fi up
Process value
Deviation
Relationships between deviation and manipulated variable (output frequency)
Reverse action
Forward action
Deviation
Positive
Negative
Ò
Ô
Ô
Ò
116
4
PARAMETERS
(3) Wiring example
• Sink logic
• Pr. 183 = 14
• Pr. 192 = 16
• Pr. 193 = 14
• Pr. 194 = 15
Inverter
NFB
Power supply
R 〈L1〉
S 〈L2〉
T 〈L3〉
Forward rotation
STF
Reverse rotation
STR
PID control selection
RT(Note 3)
SD
Setting potentiometer
(Set point setting)
U
V
W
10
Pump
IM
P
For 2-wire
For 3-wire
Detector
type
type
Upper limit
Lower limit
+
+ - +
Forward
IPF
rotation output
Reverse
SE
rotation output
(OUT) (COM) (24V)
Output signal common
(Note 2)
FU
OL
2
5
Deviation signal
Motor
1
4
(Process values) 4 ∼ 20mADC
0 24V
DC
power (Note 1)
supply
AC1φ
200/220V 50/60Hz
Note: 1. The power supply must be selected in accordance with the power specifications of the detector
used.
2. The output signal terminals used depends on the Pr. 191 to Pr. 194 settings.
3. The input signal terminals used depends on the Pr. 180 to Pr. 186 settings.
117
PARAMETERS
(4) I/O signals
2
1
1
4
4
Input
X14
Output
Terminal Used
Depending on
Pr. 180 to Pr. 186
2
Function
PID control
selection
Set point input
Deviation signal
input
Process value
input
FUP
Upper limit output
FDN
Lower limit output
Depending on
Pr. 191 to Pr. 195
RL
SE
Forward (reverse)
rotation direction
output
Output terminal
common
SE
Description
Remarks
Switch on X14 to select PID control.
Set any of "10, 11, 20
and 21" in Pr. 128.
Enter the set point for PID control.
Enter the deviation signal calculated externally.
Enter the 4-20mADC process value signal from
the detector.
Output to indicate that the process value signal
exceeded the upper limit value.
Output to indicate that the process value signal
exceeded the lower limit value.
"Hi" is output to indicate that the output indication
of the parameter unit is forward rotation (FWD) or
"Low" to indicate that it is reverse rotation (REV)
or stop (STOP).
(Pr. 128 = 20, 21)
(Pr. 128 = 10, 11,
20, 21)
Open collector output
Signal
Common to terminals FUP, FDN and RL
z To start PID control, switch on the X14 signal. When this signal is off, ordinary inverter operation is
performed without the PID action being performed.
z Enter the set point across inverter terminals 2-5 or into Pr. 133 and enter the process value signal across
inverter terminals 4-5.
When entering the externally calculated deviation signal, enter it across terminals 1-5. At this time, set "10" or
"11" in Pr. 128.
Item
Entry
Description
Set 0V as 0% and 5V as 100%.
Set point
Across terminals 2-5
Set 0V as 0% and 10V as 100%.
Set point
Pr. 133
Deviation
signal
Across terminals 1-5
Process
value
Across terminals 4-5
Set the set point (%) in Pr. 133.
Set −5V as −100%, 0V as 0% and +5V as
+100%.
Set −10V as −100%, 0V as 0% and +10V as
+100%.
When "1, 3, 5, 11, 13 or 15" is set in Pr. 73
(5V selected for terminal 2).
When "0, 2, 4, 10, 12 or 14" is set in Pr. 73
(10V selected for terminal 2).
When "2, 3, 5, 12, 13 or 15" is set in Pr. 73
(5V selected for terminal 1).
When "0, 1, 4, 10, 11 or 14" is set in Pr. 73
(10V selected for terminal 1).
4mADC is equivalent to 0% and 20mADC to 100%.
4
118
PARAMETERS
(5) Parameter setting
Parameter
Number
Setting
Name
For heating, pressure control,
etc.
10
11
PID action
selection
128
20
21
129
0.1 to 1000%
PID proportional
band
9999
130
0.1 to 3600 s
PID integral time
9999
131
0 to 100%
Upper limit
9999
132
0 to 100%
Lower limit
9999
133
134
Description
PID action set
point for PU
operation
0 to 100%
0.01 to 10.00 s
PID differential
time
9999
PID reverse
action
PID forward
For cooling, etc.
action
For heating, pressure control,
PID reverse
etc.
action
Process value input
(terminal 4)
PID forward
For cooling, etc.
action
If the proportional band is narrow (parameter setting is small), the
manipulated variable varies greatly with a slight change of the process value.
Hence, as the proportional band narrows, the response sensitivity (gain)
improves but the stability deteriorates, e.g. hunting occurs.
Gain Kp = 1/proportional band
No proportional control
Time required for the integral (I) action to provide the same manipulated
variable as that for the proportional (P) action. As the integral time decreases,
the set point is reached earlier but hunting occurs more easily.
No integral control.
Set the upper limit. If the feedback value exceeds the setting, the FUP signal
is output. (Process value of 4mA is equivalent to 0% and 20mA to 100%.)
No function
Set the lower limit. (If the process value goes out of the setting range, an
alarm can be output. In this case, the process value of 4mA is equivalent to
0% and 20mA to 100%.)
No function
Only valid for the PU command in the PU operation or PU/external combined
mode.
For external operation, the voltage across 2-5 is the set point.
(Pr. 902 value is equivalent to 0% and Pr. 903 value to 100%.)
Time only required for the differential (D) action to provide the same process
value as that for the proportional (P) action. As the differential time increases,
greater response is made to a deviation change.
No differential control.
Deviation value
signal input
(terminal 1)
(6) Adjustment procedure
Parameter setting
Terminal setting
Adjust the PID control parameters, Pr. 128 to Pr. 134
Set the I/O terminals and PID control terminals.
Pr. 128 = 10, 11, 20, 21
Switch X14 signal on.
Run
119
PARAMETERS
(7) Calibration example
(A detector of 4mA at 0°C and 20mA at 50°C is used to adjust the room temperature to 25°C under PID
control. The set point is given to across inverter terminals 2-5 (0-5V).)
START
Determine the set point.
xxxxxxSet the room temperature to 25°C.
Set Pr. 128 and switch on the X14 signal to enable PID control.
Determine the set point of the
item to be adjusted.
Convert the set point into %.
Calculate the ratio (%) of the set
point to the detector output.
Make calibration.
Set the set point.
Enter a voltage to across
terminals 2-5 according to
the set point (%).
Operation
Set the proportional band and
integral time to slightly higher
values and the differential time to
a slightly lower value, and switch
on the start signal.
Is the process
value steady?
xxxxxxDetector specifications
When the detector used has the specifications that 0°C is equivalent to
4mA and 50°C to 50mA, the set point of 25°C is 50% because 4mA is
equivalent to 0% and 20mA to 100%.
xxxxxxWhen the set point setting input (0 to 5V) and detector output (4 to
20mA) must be calibrated, make the following calibration*.
xxxxxxSet point = 50%
Since the specifications of terminal 2 are such that 0% is equivalent
to 0V and 100% to 5V, enter 2.5V into terminal 2.
xxxxxxFor PU operation, set the set point (0 to 100%) in Pr. 133.
During operation, set the proportional band and integral time to
slightly higher values and set the differential time to a slightly
lower value. In accordance with the system operation, reduce the
proportional band and integral time and increase the differential time.
Yes
4
No
Adjust parameters.
Set the proportional band and
integral time to slightly higher
values and set the differential time
to a slightly lower value to stabilize
the process value.
Optimize parameters.
While the process value is steady,
the proportional band and integral
time may be reduced and the
differential time increased
throughout the operation.
END
*When calibration is required, use Pr. 902 to Pr. 905 to calibrate the detector output and set point setting
input in the PU mode during an inverter stop.
120
PARAMETERS
<Set point input calibration>
1. Apply the input voltage of 0% set point setting (e.g. 0V) to across terminals 2-5.
2. Make calibration using Pr. 902. At this time, enter the frequency (e.g. 0Hz) which should be output by the
inverter at the deviation of 0%.
3. Apply the voltage of 100% set point setting (e.g. 5V) to across terminals 2-5.
4. Make calibration using Pr. 903. At this time, enter the frequency (e.g. 60Hz) which should be output by the
inverter at the deviation of 100%.
<Detector output calibration>
1. Apply the output current of 0% detector setting (e.g. 4mA) to across terminals 4-5.
2. Make calibration using Pr. 904.
3. Apply the output current of 100% detector setting (e.g. 20mA) to across terminals 4-5.
4. Make calibration using Pr. 905.
Note: The frequencies set in Pr. 904 and Pr. 905 should be the same as set in Pr. 902 and Pr. 903.
The results of the above calibration are as shown below:
[Detection value]
[Set point setting]
(%)
100
(%)
100
60
0
0
0
0
5
(V)
[Manipulated variable]
Manipulated
variable (Hz)
0 4
20
(mA)
0
100 Deviation (%)
Note: 1. If the multi-speed (RH, RM, RL) signal or jog operation (jog) signal is entered with the X14 signal
on, PID control is stopped and multi-speed or jog operation is started.
2. When "20" or "21" is set in Pr. 128, note that the input across inverter terminals 1-5 is added to the
set point across terminals 2-5.
3. When "6" (switch-over mode) is selected for Pr. 79, PID is made invalid.
4. When "9999" is set in Pr. 22, the stall prevention level is the value entered from terminal 1. To use
terminal 1 as the edit input terminal for PID, set a value other than "9999"
in Pr. 22.
5. When the terminal functions are changed using Pr. 180 to Pr. 186 and/or Pr. 190 to Pr. 195, the
other functions may be affected. Confirm the functions of the corresponding terminals before
making settings.
6. When you have chosen the PID control, the minimum frequency is as set in Pr. 902 and the
maximum frequency is as set in Pr. 903.
(The settings of Pr. 1 "maximum frequency" and Pr. 2 "minimum frequency" are also valid.)
121
PARAMETERS
4.2.41 Commercial power supply-inverter switch-over function
(Pr. 135 to Pr. 139)
Pr. 135 "commercial power supply-inverter
switch-over sequence output terminal selection"
Pr. 136 "MC switch-over interlock time"
Pr. 137 "start waiting time"
Pr. 138 "commercial power supply-inverter
switch-over selection at alarm occurrence"
Pr. 139 "automatic inverter-commercial power
supply switch-over frequency"
Related parameters
Pr. 11 "DC dynamic brake operation
time"
Pr. 17 "MRS input selection"
Pr. 57 "restart coasting time"
Pr. 58 "restart cushion time"
Pr. 180 to Pr. 186
(input terminal function selection)
Pr. 190 to Pr. 195
(output terminal function selection)
The inverter contains a complicated sequence circuit for commercial power supply-inverter operation switchover. Hence, the magnetic contactors for switch-over can be interlocked easily by merely entering the start,
stop or automatic switch-over select signal.
Parameter
Number
135
136
137
138
Factory
Setting
0
0.1 sec.
0.5 sec.
0
139
9999
Setting Range
Remarks
0, 1
0 to 100.0 sec.
0 to 100.0 sec.
0,1
0 to 60.0Hz, 9999
9999: No automatic
switch-over
4
122
PARAMETERS
(1) Wiring example
Sink logic, Pr. 185 = 7, Pr. 186 = 6, Pr. 192 = 17, Pr. 193 = 18, Pr. 194 = 19
MC2
NFB
MC1
Inverter
R 〈L1〉
S 〈L2〉
T 〈L3〉
Inverter start
(forward rotation)
Inverter-commercial
power supply switch-over
Operation interlock
External thermal relay
Reset
Frequency setting signal
×
MC3
External
thermal relay
U
V
W
R1 〈L11〉
S1 〈L21〉
Signal set in Pr. 190 to Pr. 195
SU
IPF
STF
CS
MRS
IM
*1
MC
1
*1 MC3 MC
OL
2
*1 MC2 MC
FU
3
*2
DC24V
OH *3
SE
RES
SD
10
2
5
IPF
OL
FU
SE
DC
24V
Note: ‚This switch-over function is used in the external operation
mode. Always connect terminals R1, S1 (L11, L21) to a
different power supply (power supply different from the one
for MC1) to ensure proper operation.
‚MC2 and MC3 must be mechanically interlocked.
*1. Note the sequence output terminal capacities. The terminals used
depend on the Pr. 190 to Pr. 194 settings.
Output Terminal Capacity
Permissible Output Terminal Load
Inverter's open collector outputs
(IPF, OL, FU)
24VDC 0.1A
FR-A5AR (option output)
230VAC 0.3A
30VDC 0.3A
*2. When connecting an AC power supply, connect the FR-A5AR option
and use the contact output.
When connecting a DC power supply, install the following protective
diode.
*3. The terminals used depend on the Pr. 180 to Pr. 186 settings.
123
PARAMETERS
• Roles of the magnetic contactors (MC1, MC2, MC3)
Magnetic
Contactor
Place of Installation
MC1
Between power supply and inverter
MC2
Between power supply and motor
MC3
Between inverter output and motor
Role
Normally shorted with the following exception:
Opened only when an inverter fault occurs (shorted again by resetting)
Shorted for commercial power supply operation, opened for inverter
operation
Shorted when an inverter fault occurs (selected with parameter, except
for external thermal relay operation)
Shorted for inverter operation, opened for commercial power supply
operation
Opened when an inverter fault occurs
<I/O signals>
1) When this function is used (Pr. 135 = "1"), the input signals are switched on-off as indicated below:
Signal
Terminal Used
MRS
MRS
CS
Depending on
Pr. 180 to Pr.186
STF
(STR)
STF
(STR)
OH
Depending on
Pr. 180 to Pr.186
RES
RES
Note:
Function
Operation
enable/disable selection
Inverter-commercial
power supply switchover
Inverter operation
command (invalid for
commercial power
supply) (Note)
External thermal relay
input
Operating condition
initialization
On-Off
Commercial power supplyinverter operation enable
........................ON
Commercial power supplyinverter operation disable
........................OFF
Inverter operation
........................ON
Commercial power supply
operation..........OFF
Forward (reverse) rotation
........................ON
Stop .................OFF
Motor normal....ON
Motor fault........OFF
Initialization ......ON
Normal operation
........................OFF
MC Operation ({: ON, × : OFF)
MC1
MC2
MC3


{
{
×
Unchanged
{
×
{
{
{
×
{
×
{
{
×
{
{
×
Unchanged
{

×
×


×
Unchanged

• In the above MC Operation field, [-] indicates that MC1 is on, MC2 is off and MC3 is on in inverter
operation and MC1 is on, MC2 is off and MC3 is off in commercial power supply operation.
[Unchanged] indicates that the status before signal-on or -off is held.
• The CS signal only functions when the MRS signal is on. STF (STR) only functions when MRS and
CS are on.
• MC1 switches off when an inverter fault occurs.
• If the MRS signal is not switched on, neither commercial power supply nor inverter operation can be
performed.
2) The output signals are output as follows:
Signal
MC1
MC2
MC3
Terminal Used
Depending on Pr. 190
to Pr. 195
Description
MC1's operation signal is output
MC2's operation signal is output
MC3's operation signal is output
124
4
PARAMETERS
(2) Parameter setting
Parameter
Number
135
Name
Setting
Commercial power
supply-inverter
switch-over
sequence output
terminal selection
Description
Sequence output is not provided. (Pr. 136, Pr. 137, Pr. 138 and Pr. 139 settings
are ignored.)
Sequence output is provided.
When MC1 to MC3 are assigned with Pr. 190 to Pr. 195 (output terminal function
selection), open collector outputs are provided. When they are not assigned,
relay outputs are provided from the FR-A5AR (option).
0
1
136
MC switch-over
interlock time
0 to 100.0 s
137
Start waiting time
0 to 100.0 s
138
Commercial power
supply-inverter
switch-over
selection at alarm
occurrence
139
Automatic invertercommercial power
supply switch-over
frequency
0
1
0 to 60.0Hz
9999
Sets the MC2 and MC3 operation interlock time.
Set a slightly longer (about 0.3 to 0.5 s) value than the time from when the ON
signal enters inverter operation MC3 to when it actually switches on.
Stops inverter operation and coasts the motor.
The inverter stops when an inverter fault occurs (both MC2 and MC3 switch off).
Stops inverter operation and automatically switches inverter operation to
commercial power supply operation.
When an inverter fault occurs, inverter operation is automatically switched to
commercial power supply operation (MC2: ON, MC3: OFF).
The motor is started and run by the inverter up to the set frequency, and when
the output frequency reaches or exceeds the set frequency, inverter operation is
automatically switched to commercial power supply operation. Start and stop are
controlled by the inverter operation command (STF or STR).
Automatic switch-over is not done.
Note: 1. Pr. 139 functions when Pr. 135 setting is other than "0".
2. When the motor started by the inverter reaches the automatic switch-over frequency, inverter
operation is switched to commercial power supply operation. If the inverter's run command value is
then lowered to or below the switch-over frequency, commercial power supply operation is not
automatically switched to inverter operation.
Switch off the inverter operation command signal (STF or STR) to switch commercial power supply
operation to inverter operation and decelerate the motor to a stop.
<Operation sequence>
Operation interlock
(MRS)
Inverter operation command
(STF)
Inverter-commercial power supply switch-over
(CS)
ON
OFF
ON
OFF
ON
OFF
ON
OFF
Commercial power supply-inverter switch-over
(MC1)
Commercial power supply-inverter switch-over
(MC3)
Commercial power supply-inverter switch-over
(MC2)
ON
OFF
ON
OFF
ON
OFF
Power
Each timer
Operating status
(Motor speed)
ON: Operation enable
OFF: Operation disable
ON: Forward rotation
OFF: Stop
ON: Inverter operation
OFF: Commercial power
supply operation
Off for inverter fault only
A
A,B
C,
D
Coast to stop
A
A
B C,D
Coast- Inverter
Inverter Coastoperat- ing
ing
operation
ion
Commercial power
Stop
Commercial power
supply stop
supply operation
Operation command
Actual operation (Note)
Note: Indicates a delay
until MC switches on.
125
Inverter
operation
Each timer
A: Pr. 136 MC switch-over interlock time
B: Pr. 137 MC3 start commencement
(start waiting time)
C: Pr. 57 (reset time)
D: Pr. 58 (switch-over cushion time)
PARAMETERS
(3) Operation procedure
1) Operation procedure for running
Operation pattern
Switch power on.
Set parameters.
Start, inverter operation
‚ Pr. 135 = "1" (inverter's open collector output terminals)
‚ Pr. 136 = "2.0 s"
‚ Pr. 137 = "1.0 s" (Set the value equal to or longer than the time
from when MC3 switches on actually until the inverter and
motor are connected. If it is shorter, restart may not function properly.
‚ Pr. 57 = "0.5 s"
‚ Pr. 58 = "0.5 s" (Always set this parameter when commercial power
supply operation is switched to inverter operation.)
Constant-speed operation,
commercial power supply
operation
Deceleration (stop),
inverter operation
2) Signal on-off after parameter setting
MRS
CS
STF
MC1
MC2
MC3
Power on
OFF
(OFF)
OFF
(OFF)
OFF
(OFF)
OFF→ON
(OFF→ON)
OFF
(OFF)
OFF→ON
(OFF→ON)
At start
(Inverter)
OFF→ON
OFF→ON
OFF→ON
ON
OFF
ON
Constant speed
(Commercial
power supply)
ON
ON→OFF
ON
ON
OFF→ON
ON→OFF
Switched to
inverter
operation for
deceleration
(Inverter)
ON
OFF→ON
ON
ON
ON→OFF
OFF→ON
Stop
ON
ON
ON→OFF
ON
OFF
ON
Remarks
External operation mode
(PU operation mode)
After MC3 switches off,
MC2 switches on.
(Motor coasts during this
period.)
Waiting time 2 seconds.
After MC2 switches off,
MC3 switches on.
(Motor coasts during this
period.)
Waiting time 4 seconds.
4
126
PARAMETERS
Note: 1. This function is only activated when R1 and S1 are connected to a different power supply (power
supply which is not connected to MC1).
2. This function is only valid in the external operation or PU (speed command) and external (run
command) operation mode when the Pr. 135 value is other than "0". When the Pr. 135 value is
other than "0" in the operation mode other than the above, MC1 and MC3 switch on.
3. MC3 is on when the MRS and CS signals are on and STR is off, but when the motor run by the
commercial power supply was coasted to a stop at the last time, it restarts after the time set in
Pr. 137 has elapsed.
4. Inverter operation is enabled when the MRS, STF and CS signals switch on. In other cases (MRS
is on), commercial power supply operation is performed.
5. When the CS signal is switched off, the motor is switched over to commercial power supply
operation. Note that when the STF (STR) signal is switched off, the motor is decelerated to a stop
by the inverter.
6. When both MC2 and MC3 are off and MC2 or MC3 is then switched on, the motor restarts after
the waiting time set in Pr. 136 has elapsed.
7. If the Pr. 135 setting is other than 0, the Pr. 136 and Pr. 137 settings are ignored in the PU
operation mode.
Also, the inverter's input terminals (STF, CS, MRS, OH) return to their ordinary functions.
8. When the commercial power supply-inverter switch-over sequence is selected, the PU operation
interlock function (Pr. 79 = 7) is not activated if it has been set.
9. When the terminal functions are changed using Pr. 180 to Pr. 186 and/or Pr. 190 to Pr. 195, the
other functions may be affected. Confirm the functions of the corresponding terminals before
making settings.
Pr. 140 to Pr. 143 Î Refer to Pr. 29.
Pr. 144
Î
Refer to Pr. 37.
Pr. 148, Pr. 149 Î
Refer to Pr. 22.
127
PARAMETERS
4.2.42 Zero current detection (Pr. 152, Pr. 153)
Pr. 152 "zero current detection level"
Related parameters
Pr. 153 "zero current detection time"
Pr. 190 to Pr. 195
(output terminal function selection)
When the inverter's output current falls to "0", torque will not be generated. This may cause a gravity drop
when the inverter is used in vertical lift application.
To prevent this, the output current "zero" signal can be output from the inverter to close the mechanical brake
when the output current has fallen to "zero".
z If the output current remains lower than the Pr. 152 setting during inverter operation for longer than the time
set in Pr. 153, the zero current detection (Y13) signal is output from the inverter's open collector output
terminal.
(Use any of Pr. 190 to Pr. 195 to assign the terminal used for Y13 signal output.)
Parameter
Number
152
153
Factory Setting
Setting Range
5.0%
0.5 s
0 to 200.0%
0 to 1 s
Start signal
OFF ON
Pr. 152 "zero current
detection level"
Zero current detection
signal output
Output current 0 [A]
Pr.152
OFF
100 ms (Note)
ON
Pr. 153 "detection time"
OFF
ON
Pr. 153 "detection time"
<Setting>
Refer to the following list and set the parameters:
Parameter
Number
152
153
Description
Set the zero current detection level.
Set this parameter to define the percentage of the rated current at which the zero current will be detected.
Set the zero current detection time.
Set a period of time from when the output current drops to or below the Pr. 152 setting to when the zero current
detection signal (Y13) is output.
Note: 1. If the current falls below the preset detection level but the timing condition is not satisfied, the zero
current detection signal is held on for about 100ms.
2. When the terminal functions are changed using Pr. 190 to Pr. 195, the other functions may be
affected. Confirm the functions of the corresponding terminals before making settings.
CAUTION
The zero current detection level setting should not be too high, and the zero current
detection time setting not be too long. Otherwise, the detection signal may not be
output when torque is not generated at a low output current.
To prevent the machine and equipment from resulting in hazardous conditions by use
of the zero current detection signal, install a safety backup such as an emergency
brake.
Pr. 154 Î
Refer to Pr. 22.
128
4
PARAMETERS
4.2.43 RT signal activated condition selection (Pr. 155)
Pr. 155 "RT signal activated condition selection"
Related parameters
Pr. 14 "load pattern selection"
Pr. 44 to Pr. 49
(second function selection)
Pr. 180 to Pr. 186
(input terminal function selection)
z Set the condition of activating the RT terminal to select the second control functions by switching on-off the
RT signal.
Parameter
Number
155
Factory
Setting
0
Setting Range
0, 10
<Setting>
Refer to the following table and set the parameter:
Pr. 155 Setting
0
10
Description
Made valid immediately by switching the RT signal
on-off.
Made valid only when the RT signal is on at constant
speed.
(Invalid during acceleration/deceleration)
4.2.44 Stall prevention function and current limit function (Pr. 156)
Pr. 156 "stall prevention operation selection"
Related parameters
Pr. 22 "stall prevention operation level"
Pr. 23 "stall prevention operation level at
double speed"
Pr. 47 "second stall prevention operation
current"
Pr. 48 "second stall prevention operation
frequency"
Pr. 154 "voltage reduction selection
during stall prevention operation"
Pr. 157 "OL signal output waiting time"
Stall prevention and fast-response current limit can be disabled and the OL signal output delayed.
Parameter
Number
156
Factory
Setting
0
Setting Range
0 to 31, 100, 101
129
PARAMETERS
<Setting>
Refer to the following table and set the parameter as required:
Pr. 156 Setting
100
101
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
Driving
Regenerative
Driving
Regenerative
Fast-Response
Current Limit
{...Activated
z...Not activated
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
{
z
z
z
Acceleration
{
{
z
z
{
{
z
z
{
{
z
z
{
{
z
z
{
{
z
z
{
{
z
z
{
{
z
z
{
{
z
z
{
z
{
z
Stall Prevention
{...Activated
z...Not activated
Constant speed
{
{
{
{
z
z
z
z
{
{
{
{
z
z
z
z
{
{
{
{
z
z
z
z
{
{
{
{
z
z
z
z
{
z
{
z
Deceleration
{
{
{
{
{
{
{
{
z
z
z
z
z
z
z
z
{
{
{
{
{
{
{
{
z
z
z
z
z
z
z
z
{
z
{
z
OL Signal Output
{...Operation continued
z...Operation not
continued (Note 1)
{
{
{
{
{
{
{
{
{
{
{
{
{
{
{
{
z
z
z
z
z
z
z
z
z
z
z
z
z
z
z
z
{
{
{
{
Note 1: When "Operation not continued for OL signal output" is selected, the "E.OLT" alarm code (stopped
by stall prevention) is displayed and operation stopped.
(Alarm stop display "E.OLT")
2: If the load is heavy, the lift is predetermined, or the acceleration/deceleration time is short, the stall
prevention may be activated and the motor not stopped in the preset acceleration/deceleration
time. Therefore, set optimum values to the Pr. 156 stall prevention operation level.
(When the output voltage reduces during stall prevention operation, an overcurrent trip will be less
liable to occur but the torque decreases. Set "0" in Pr. 154 when the torque may be reduced.)
130
4
PARAMETERS
CAUTION
Always perform test operation.
Stall prevention operation performed during acceleration may increase the acceleration
time.
Stall prevention operation performed during constant speed may cause sudden speed
changes.
Stall prevention operation performed during deceleration may increase the
deceleration time, increasing the deceleration distance.
4.2.45 OL signal output timer (Pr. 157)
Related parameters
Pr. 157 "OL signal output waiting time"
Pr. 190 "RUN terminal function
selection"
Pr. 191 "SU terminal function selection"
Pr. 192 "IPF terminal function selection"
Pr. 193 "OL terminal function selection"
Pr. 194 "FU terminal function selection"
Pr. 195 "ABC terminal function selection"
Use this parameter to set whether the overload alarm signal (OL signal) is output immediately or a preset
period of time after occurrence of an overload status.
Parameter
Number
Factory
Setting
Setting Range
Remarks
157
0
0 to 25 s, 9999
9999: No signal output
Overload status (OL output)
OL output signal
Set time t (seconds)
<Setting>
Refer to the following table and set the parameter:
Pr. 157
Setting
0
0.1 to 25
9999
Pr. 158 Î
Description
Output immediately.
Output after the set time t (seconds) has elapsed.
Overload alarm signal is not output.
Refer to Pr. 54.
131
PARAMETERS
4.2.46 User group selection (Pr. 160, Pr. 173 to Pr. 176)
Pr. 160 "user group read selection"
Pr. 173 "user group 1 registration"
Pr. 174 "user group 1 deletion"
Pr. 175 "user group 2 registration"
Pr. 176 "user group 2 deletion"
• Pr. 160 "user group read selection" is used to limit the parameters which may be read.
• From among all parameters, a total of 32 parameters can be registered to two different user groups.
The registered parameters may only be accessed for reading and writing.
Other parameters than those registered to the user groups cannot be read.
Parameter
Number
160
173
174
175
176
Factory
Setting
9999
0
0
0
0
Setting Range
Remarks
0, 1, 10, 11, 9999
0 to 999
0 to 999, 9999
0 to 999
0 to 999, 9999
9999: Batch deletion
9999: Batch deletion
<Examples of use>
(1) Parameter registration to user group (when registering Pr. 3 to user group 1)
Flickering
Pr. 173 reading
EXT
PU
REV
FWD
CONTROL PANEL
3) FR-DU04
MON
EXT
PU
REV
FWD
Hz
A
V
MON
4) FR-DU04
CONTROL PANEL
Hz
A
V
.....
MON
2) FR-DU04
SET
PU
REV
FWD
The number of parameters
registered for user setting
appears.
5) FR-DU04
Using the [UP/DOWN] key,
choose the parameter
number to be registered.
CONTROL PANEL
Hz
A
V
1.5 s
EXT
CONTROL PANEL
SET
MON
EXT
PU
REV
FWD
Hz
A
V
MON
EXT
PU
REV
FWD
.....
Hz
A
V
.....
CONTROL PANEL
.....
1) FR-DU04
Pr. 3 is registered to user
group 1.
Using the [UP/DOWN] key,
move to the next parameter
to be registered.
Using the [SET] key, make
registration.
(2) Parameter deletion from user group (when deleting Pr. 5 from user group 1)
Flickering
Pr. 174 reading
EXT
PU
REV
FWD
CONTROL PANEL
3) FR-DU04
CONTROL PANEL
Hz
A
V
SET
MON
EXT
PU
REV
FWD
.....
MON
2) FR-DU04
The number of parameters
registered for user setting
appears.
Hz
A
V
MON
EXT
PU
REV
FWD
4) FR-DU04
CONTROL PANEL
SET
1.5 s
5) FR-DU04
CONTROL PANEL
Hz
A
V
MON
EXT
PU
REV
FWD
Using the [UP/DOWN] key, Pr. 5 is deleted from user
choose the parameter
group 1.
number to be deleted.
Hz
A
V
MON
EXT
PU
REV
FWD
.....
Hz
A
V
.....
CONTROL PANEL
.....
1) FR-DU04
Using the [UP/DOWN] key,
choose the parameter to be
deleted.
Using the [SET] key, make
deletion.
(3) By setting the required value in Pr. 160, make the user groups valid or invalid.
Pr. 160 Setting
0
1
10
11
9999
Description
All parameters can be accessed for reading and writing.
Parameters registered to user group 1 may only be accessed for reading and writing.
Parameters registered to user group 2 may only be accessed for reading and writing.
Parameters registered to user groups 1 and 2 may only be accessed for reading and writing.
Simple mode parameters may only be accessed for reading and writing. For more information, refer to page 47.
132
4
PARAMETERS
Note: 1. Pr. 77, Pr. 160 and Pr. 991 values can always be read independently of the user group setting.
2. When Pr. 173 or Pr. 174 is read, the number of parameters registered to user group 1 appears.
When Pr. 175 or Pr. 176 is read, the number of parameters registered to user group 2 appears.
3. "0" set in the second digit of the 2-digit Pr. 160 setting is not displayed. However, it is displayed
when "0" is set in the first digit only.
4. When "9999" is set in Pr. 174 or Pr. 176, the parameters registered to the corresponding user
group is batch-deleted.
Pr. 162 to Pr. 165 Î Refer to Pr. 57.
4.2.47 Watt-hour meter clear/actual operation hour meter clear
(Pr. 170, Pr. 171)
Related parameter
Pr. 170 "watt-hour meter clear"
Pr. 171 "actual operation hour meter clear"
Pr. 52 "DU/PU main display data
selection"
You can clear the watt-hour value and actual operation hour monitoring function.
Parameter
Number
170
171
Factory
Setting
0
0
Setting Range
0
0
<Setting>
Write "0" in the parameters to clear the watt-hour value and actual operation hour.
Pr. 173 to Pr. 176
Î Refer to Pr. 160.
4.2.48 Input terminal function selection (Pr. 180 to Pr. 186)
Pr. 180 "RL terminal function selection"
Pr. 181 "RM terminal function selection"
Pr. 182 "RH terminal function selection"
Pr. 183 "RT terminal function selection"
Pr. 184 "AU terminal function selection"
Pr. 185 "JOG terminal function selection"
Pr. 186 "CS terminal function selection"
Use these parameters to select/change the input terminal functions.
Parameter
Number
180
181
182
183
184
185
Terminal
Symbol
RL
RM
RH
RT
AU
JOG
Factory
Setting
0
1
2
3
4
5
186
CS
6
Factory-Set Terminal Function
Low-speed operation command (RL)
Middle-speed operation command (RM)
High-speed operation command (RH)
Second function selection (RT)
Current input selection (AU)
Jog operation selection (JOG)
Automatic restart after instantaneous power
failure selection (CS)
133
Setting Range
0 to 7, 10 to 14,
16, 17, 9999
PARAMETERS
<Setting>
Refer to the following list and set the parameters:
Setting
0
1
Signal
Name
RL
RM
2
RH
3
4
5
6
RT
AU
JOG
CS
7
OH
10
11
12
13
14
16
9999
X10
X11
X12
X13
X14
X16
Functions
Relevant Parameters
Pr. 59 = 0
Low-speed operation command
Pr. 59 = 1, 2*
Remote setting (setting clear)
Pr. 59 = 0
Middle-speed operation command
Pr. 59 = 1, 2*
Remote setting (deceleration)
Pr. 59 = 0
High-speed operation command
Pr. 59 = 1, 2*
Remote setting (acceleration)
Second function selection
Current input selection
Jog operation selection
Automatic restart after instantaneous power failure selection
External thermal relay input**
The externally provided overheat protection thermal relay,
motor-embedded temperature relay or the like is operated to
stop the inverter.
FR-HC connection (inverter operation enable)
FR-HC connection (instantaneous power failure detection)
PU operation external interlock
External DC dynamic braking start
PID control valid terminal
PU-external operation switch-over
No function
Pr. 4 to Pr. 6
Pr. 24 to Pr. 27
Pr. 232 to Pr. 239
Pr. 59
Pr. 4 to Pr. 6, Pr. 24 to Pr. 27, Pr. 232 to
Pr. 239
Pr. 59
Pr. 4 to Pr. 6, Pr. 24 to Pr. 27,
Pr. 232 to Pr. 239
Pr. 59
Pr. 44 to Pr. 50
Refer to page 11
Pr. 15, Pr. 16
Pr. 57, Pr. 58, Pr. 162 to Pr. 165
Refer to page 145
Pr. 30, Pr. 70
Pr. 30, Pr. 70
Pr. 79
Pr. 10 to Pr. 12
Pr. 128 to Pr. 134
Pr. 79
*: When Pr. 59 = "1" or "2", the functions of the RL, RM, RH and RT signals change as listed above.
**: Operated when the relay contact "opens".
Note: 1. One function can be assigned to two or more terminals. In this case, the terminal inputs are
OR’ed.
2. The speed command priorities are higher in order from jog, multi-speed setting (RH, RM, RL) and
AU.
3. When HC connection (inverter operation enable signal) is not selected, the MRS terminal shares
this function.
4. Use common terminals to assign the multi-speeds (7 speeds) and remote setting. They cannot be
set individually.
(Common terminals are used since these functions are designed for speed setting and need not
be set at the same time.)
5. When FR-HC connection inverter operation enable (X10) signal is not assigned, the MRS terminal
shares this function.
6. When "7" is set in Pr. 79 and the PU operation external interlock (X12) signal is not assigned, the
MRS signal acts as this function.
134
4
PARAMETERS
4.2.49 Output terminal function selection (Pr. 190 to Pr. 195)
Pr. 190 "RUN terminal function selection"
Related parameter
Pr. 76 "operation mode selection"
Pr. 191 "SU terminal function selection"
Pr. 192 "IPF terminal function selection"
Pr. 193 "OL terminal function selection"
Pr. 194 "FU terminal function selection"
Pr. 195 "ABC terminal function selection"
You can change the functions of the open collector and contact output terminals.
Parameter
Number
190
191
Terminal
Symbol
RUN
SU
Factory
Setting
0
1
192
IPF
2
193
194
195
OL
FU
A, B, C
3
4
99
Factory-Set Terminal
Function
Inverter running
Up to frequency
Instantaneous power
failure/undervoltage
Overload alarm
Frequency detection
Alarm output
Setting Range
0 to 5, 8, 10, 11, 13 to 19,
25, 26,
98 to 105, 108,
110, 111,
113 to 116,
125, 126, 198, 199, 9999
<Setting>
Refer to the following table and set the parameters:
Setting
Positive Negative
logic
logic
Signal
Name
Function
Operation
Output during operation when the inverter output
frequency rises to or above the starting frequency.
Refer to Pr. 41 "up-to-frequency sensitivity". (Note
Up to frequency
2)
Instantaneous power failure or Output when an instantaneous power failure or
undervoltage
undervoltage occurs.
0
100
RUN
Inverter running
1
101
SU
2
102
IPF
3
103
OL
Overload alarm
4
104
FU
Output frequency detection
5
105
FU2
8
108
THP
10
110
PU
Second output frequency
detection
Electronic overcurrent
protection pre-alarm
PU operation mode
11
111
RY
Inverter operation ready
13
113
Y13
Zero current detection
14
15
114
115
FDN
FUP
16
116
RL
PID lower limit
PID upper limit
PID forward-reverse rotation
output
Output while stall prevention function is activated.
Related
parameter

Pr. 41

Pr. 22, Pr. 23,
Pr. 66, Pr. 148,
Pr. 149,Pr. 154
Refer to Pr. 42, Pr. 43 (output frequency
Pr. 42, Pr. 43
detection).
Refer to Pr. 50 (second output frequency
Pr. 50
detection).
Output when the cumulative electronic overcurrent
Pr. 9
protection value reaches 85% of the preset level.
Output when the PU operation mode is selected.
Pr. 17
Output when the inverter can be started by

switching the start signal on or while it is running.
Refer to Pr. 152 and Pr. 153 (zero current
Pr. 152, Pr. 153
detection).
Refer to Pr. 128 to Pr. 134 (PID control).
135
Pr. 128 to
Pr. 134
PARAMETERS
Setting
Positive Negative
logic
logic
Signal
Name
Function
Commercial power supplyinverter switch-over MC1
Commercial power supplyinverter switch-over MC2
Commercial power supplyinverter switch-over MC3
17

MC1
18

MC2
19

MC3
26
126
FIN
Fin overheat pre-alarm
98
198
LF
Minor fault output
99
199
ABC
Alarm output

No function
9999
Operation
Refer to Pr. 135 to Pr.139 (commercial power
supply-inverter switch-over).
Output when the heat sink temperature reaches
about 85% of the fin overheat protection
temperature.
Output when a minor fault occurs. (Refer to page
156.)
Output when the inverter's protective function is
activated to stop the output (major fault).

Related
parameter
Pr. 135 to
Pr. 139




0 to 99:
Positive logic
100 to 199: Negative logic
Note: 1. When the frequency setting is varied with the analog signal or the [UP/DOWN] key of the operation
panel, note that the output of the SU (up-to-frequency) signal may alternate between ON and OFF
due to that varying speed and the timing of the varying speed dependent on the
acceleration/deceleration time setting.
(Such alternation will not take place when the acceleration/deceleration time setting is
"0 seconds".)
2. The same function may be set to more than one terminal.
3. When the function is activated, the terminal conducts with the settings of 0 to 99 and does not
conduct with the settings of 100 to 199.
4. Pr. 190 to Pr. 195 do not function if the values set are other than the above.
5. When Pr. 76 = 1 or 3, the output signals of the SU, IPF, OL and FU output terminals conform to
Pr. 76. When an inverter alarm occurs, the signal outputs are switched over to alarm code outputs.
6. The output assignment of the RUN terminal and alarm output relay conforms to the above setting
independently of Pr. 76.
4
136
PARAMETERS
4.2.50 User initial value setting (Pr. 199)
Related parameter
Pr. 77 "parameter write disable
selection"
Pr. 199 "user's initial value setting"
Among the parameters, you can set user-only parameter initial values. These values may be set to 16
parameters.
By performing user clear operation from the operation panel or parameter unit, you can initialize the
parameters to the user-set initial values. Note that the parameters of which initial values have not been set are
initialized to the factory settings by user clear operation.
z You can read the user's initial value list in the help mode of the parameter unit (FR-PU04).
Parameter
Number
199
Factory
Setting
0
Setting Range
0 to 999, 9999
The read Pr. 199 value is displayed as the number of parameters registered.
<Setting example>
(1) To set "1" in Pr. 7 and "2" in Pr. 8 as user's initial values. (Operation from the FR-DU04)
1) Set "1" (target initial value) in Pr. 7.
2) Set "2" (target initial value) in Pr. 8.
3) Press the [SET] key to read Pr. 199.
The number of parameters having user's initial values are
then displayed.
4) Further press the [SET] key for 1.5 seconds.
The parameter setting screen is then displayed.
5) Select Pr. 7 and Pr. 8 with the [UP/DOWN] key and
press the [SET] key for 1.5 seconds to enter.
6) Through the above steps, the initial values of Pr. 7 and
Pr. 8 are registered.
The settings of the parameters whose numbers are set in Pr. 199 (i.e. Pr. 7 = 1, Pr. 8 = 2 in the above
example) are user's initial values.
(2) Deletion of user's initial values
By writing "9999" to Pr. 199 (and pressing the [SET] key for 1.5 seconds), the user's initial values registered
are batch-deleted.
Note: 1. When user's initial values for Pr. 902 to Pr. 905 are set, one parameter uses the area of two
parameters for registration.
2. As this setting is concerned with user-cleared initial values, the parameter numbers which cannot
be cleared cannot be set.
3. The operation panel (FR-DU04) cannot be used to refer to user's initial values.
Pr. 240 Î Refer to Pr. 72.
137
PARAMETERS
4.2.51 Cooling fan operation selection (Pr. 244)
Pr. 244 "cooling fan operation selection"
You can control the operation of the cooling fan built in the inverter.
Parameter
Number
Factory Setting
Setting Range
244
0
0, 1
<Setting>
Setting
Description
0
Operated at power on (independently of whether the inverter is running or at a stop).
1
Cooling fan on-off control valid
(The cooling fan is always on while the inverter is running. During a stop, the inverter status
is monitored and the fan switches on-off according to temperature.)
4.2.52 Output phase failure protection selection (Pr. 251)
Pr. 251 "output phase failure protection selection"
You can disable the output phase failure protection (E.LF) function which will stop the inverter output if one of
the three phases (U, V, W) on the output side (load side) of the inverter opens.
Parameter
Number
Setting
Range
Minimum
Setting
Increments
Factory Setting
Description
251
0, 1
1
1
0: Without output phase failure protection
1: With output phase failure protection
4.2.53 Override bias/gain (Pr. 252, Pr. 253)
Related parameter
Pr. 252 "override bias"
Pr. 73 "0 to 5V, 0 to 10V selection"
4
Pr. 253 "override gain"
When you have selected override in Pr. 73 "0 to 5V, 0 to 10V selection", you can increase the override range
of 50%-150% (to 0%-200%) and make setting as desired.
Parameter Number
Setting Range
252
253
0 to 200%
0 to 200%
Minimum Setting
Increments
0.1%
0.1%
Factory Setting
50%
150%
Pr.252
Pr.253
Override (%)
200
150
Factory setting (50% to 150%)
100
50
0
0V
2.5V
5V
(5V)
(10V)
Voltage across terminals 2-5
138
PARAMETERS
Pr. 571 "Start holding time"
Parameter
Number
571
Factory Setting
Setting Range
Min. Setting Range
Name
Screen Display
9999
0 to 10S, 9999
0.1S
Start holding time
―――
z The output frequency will be held at the start frequency for the time set in Pr. 571.
This setting is invalid when Pr. 571 is set to 9999.
This setting is invalid during automatic tuning, primary flux and instantaneous low restart.
ON
Start signal
Output f
Pr. 13
Time
Pr. 571
Pr. 570 " VT/Light VT selection"
(Only Type 02)
Set the load characteristic to variable torque application (VT) or light variable torque application (Light VT).
Parameter Number
570
Factory Setting
Setting Range
Min Setting Range
1, 2
1
1 (NA, EC version)
2 (CH version)
Initial value
・Pr.9
・Pr.56
Set value
Application
Overload capacity
・Rated current and rated power
・Pr.22
・Pr.48
・Pr.149
・Pr.148
in monitoring
・Pr.165
1
Variable torque
120% 1minute
VT rated current and power
120%
150%
2
Light Variable torque
110% 1minute
Light VT rated current and power
110%
120%
This parameter could not be changed while inverter running.
If this parameter setting is changed, the change is valid after parameter clear, and inverter reset or
re-energized.
This parameter is not reset to factory setting after parameter (all) clear.
139
PARAMETERS
4.2.54 Meter (frequency meter) calibration (Pr. 900, Pr. 901)
Related parameters
Pr. 900 "FM terminal calibration"
Pr. 54 "FM terminal function selection"
Pr. 55 "frequency monitoring reference"
Pr. 56 "current monitoring reference"
Pr. 158 "AM terminal function selection"
Pr. 901 "AM terminal calibration"
z By using the operation panel/parameter unit, you can calibrate a meter connected to terminal FM to full
scale.
z Terminal FM provides the pulse output. By setting Pr. 900, you can calibrate the meter connected to the
inverter from the parameter unit without providing a calibration resistor.
z You can display a digital value on a digital counter using the pulse train signal from terminal FM. A 1440Hz
output is provided at the full scale value as explained in the section of Pr. 54. When the running frequency
has been selected for monitoring, the ratio of this FM terminal output frequency can be set in Pr. 55.
T1
Meter
1mA full scale
Analog meter
(–)
DC8V
(Digital meter)
1mA
T2
(+)
FM (AM)
SD (5)
Pulse width T1 :Adjusted with Pr. 900
Pulse period T2 :Set in Pr. 55 (valid for frequency monitoring only)
(–)
(+) 1440Hz
FM (AM)
SD (5)
Note: The parameter is factory-set to 1mA full-scale or
1440Hz FM output frequency at 60Hz.
z Terminal AM is factory-set to provide a 10VDC output in the full-scale state of each monitored data. Pr. 901
allows the output voltage ratio (gain) to be adjusted according to the meter reading. Note that the maximum
output voltage is 10VDC.
(1) Calibration of terminal FM
1) Connect a meter (frequency meter) across inverter terminals FM-SD. (Note the polarity. FM is the
positive terminal.)
2) When a calibration resistor has already been connected, adjust the resistance to "0" or remove the
resistor.
3) Set any of "1 to 3, 5, 6, 8, 10 to 14, 17 and 21" in Pr. 54.
When the running frequency or inverter output current has been selected as the output signal, preset in
Pr. 55 or Pr. 56 the running frequency or current at which the output signal is 1440Hz.
At this 1440Hz, the meter normally deflects to full scale.
(2) Calibration of terminal AM
1) Connect a 0-10VDC meter (frequency meter) across inverter terminals AM-5. (Note the polarity. AM is
the positive terminal.)
2) Set any of "1 to 3, 5, 6, 8, 10 to 14, 17 and 21" in Pr. 158.
When the running frequency or inverter output current has been selected as the output signal, preset in
Pr. 55 or Pr. 56 the running frequency or current at which the output signal is 10V.
3) When outputting a signal which cannot achieve a 100% value easily by operation, e.g. output current, set
"21" in Pr. 158 and perform the following operation. After that, set "2" (output current, for example) in Pr.
158.
140
4
PARAMETERS
<Operation procedure>
• When operation panel (FR-DU04) is used
1) Select the PU operation mode.
2) Set the running frequency.
3) Press the [SET] key.
4) Read Pr. 900 "FM terminal calibration" or Pr. 901 "AM terminal calibration".
5) Press the [FWD] key to run the inverter. (Motor need not be connected.)
6) Hold down the [UP/DOWN] key to adjust the meter pointer to the required position.
(Depending on the setting, it may take some time until the pointer moves.)
7) Press the [SET] key for about 1.5 seconds.
8) Press the [STOP/RESET] key to stop the inverter.
Note: 1. Pr. 900 is factory-set to 1mA full-scale or 1440Hz FM output frequency at 60Hz. The maximum
pulse train output of terminal FM is 2400Hz.
2. When a frequency meter is connected across terminals FM-SD to monitor the running frequency,
the FM terminal output is filled to capacity at the factory setting if the maximum output frequency
reaches or exceeds 100Hz. In this case, the Pr. 55 setting must be changed to the maximum
frequency.
3. For the operation procedure using the parameter unit (FR-PU04), refer to the FR-PU04 instruction
manual.
141
PARAMETERS
4.2.55 Frequency setting voltage (current) bias and gain
(Pr. 902 to Pr. 905)
Pr. 902 "frequency setting voltage bias"
Related parameters
Pr. 903 "frequency setting voltage gain"
Pr. 20 "acceleration/deceleration
reference frequency"
Pr. 73 "0-5V/0-10V selection"
Pr. 904 "frequency setting current bias"
Pr. 905 "frequency setting current gain"
You can set the output frequency as desired in relation to the frequency setting signal (0 to 5V, 0 to 10V or 4 to
20mA DC).
The "bias" and "gain" functions are used to adjust the relationship between the input signal entered from
outside the inverter to set the output frequency, e.g. 0 to 5VDC, 0 to 10VDC or 4 to 20mADC, and the output
frequency.
z Use Pr. 902 to set the bias frequency at 0V.
z Use Pr. 903 to set the output frequency relative to the frequency command voltage set in Pr. 73.
z Use Pr. 904 to set the bias frequency at 4mA.
z Use Pr. 905 to set the output frequency relative to the 20mA frequency command current (4 to 20mA).
Factory Setting
0V
5V
4mA
20mA
Setting Range
0Hz
60Hz 〈50Hz〉
0Hz
60Hz 〈50Hz〉
Output frequency (Hz)
Parameter
Number
902
903
904
905
0 to 10V
0 to 10V
0 to 20mA
0 to 20mA
0 to 60Hz
1 to 120Hz
0 to 60Hz
1 to 120Hz
Factory setting
60Hz
〈50Hz〉
Gain Pr.903
Bias
Pr.905
Pr.902
4
Pr.904
0
0
0
4
100% Pr.73
Frequency setting signal 5V
10V
20mA
<Setting>
(1) The frequency setting voltage biases and gains may be adjusted in either of the following three ways:
1) Any point can be adjusted with a voltage applied across terminals 2-5.
2) Any point can be adjusted with no voltage applied across terminals 2-5.
3) Bias voltage is not adjusted.
(2) The frequency setting current biases and gains may be adjusted in either of the following three ways:
1) Any point can be adjusted with a current flowing at terminal 4.
2) Any point can be adjusted with no current flowing at terminal 4.
3) Bias current is not adjusted.
142
PARAMETERS
<Adjustment procedure> Pr. 902 (Pr. 904) "frequency setting voltage (current) bias"
• When operation panel (FR-DU04) is used
Select the PU operation mode.
Read Pr. 902 (Pr. 904) value.
Press the [SET] key.
Using the [UP/DOWN] key, set the bias
frequency.
Press the [SET] key for about 1.5 seconds
The analog voltage (current) monitor value
across terminals 2(4)-5 is displayed.
(2) Any point is adjusted with
no voltage (current) applied
(1) Any point is adjusted with
a voltage (current) applied
Apply the bias voltage (current).
Using the [UP/DOWN] key, set
the bias voltage (current) in %.
[0% for 0V (0mA), 100% for 5V
(10V, 20mA)]
(3) Bias voltage (current)
is not adjusted.
When the [UP] or [DOWN] key
is pressed, the present setting is
displayed.
Press the [SET] key for about 1.5 seconds.
The bias voltage (current) setting flickers.
Bias setting complete.
Press the [SET] key.
The cursor moves to the next parameter.
*Pr. 903 to Pr. 905 can also be adjusted similarly using the above procedure.
Note: 1. If the Pr. 903 or Pr. 905 (gain adjustment) value is changed, the Pr. 20 value does not change.
The input signal to terminal 1 (frequency setting auxiliary input) is added to the frequency setting
signal.
2. For the operation procedure using the parameter unit (FR-PU04), refer to the FR-PU04 instruction
manual.
143
PARAMETERS
CAUTION
Be careful when setting the bias frequency at 0V to any value other than "0". Even
without the speed command, the motor will start running at the set frequency by merely
switching on the start signal.
4.2.56 Buzzer control (Pr. 990)
Pr. 990 "buzzer control"
You can make the buzzer "beep" when you press any key of the operation panel or parameter unit.
Parameter
Number
990
Factory
Setting
1
Setting Range
Remarks
0, 1
0: Without beep, 1: With beep
4
144
PARAMETERS
Advanced PID control (Pr. 500 to Pr. 516) (NA, EC versions only)
Pr. 500 "Auxiliary motor operation selection"
Related parameters
Pr. 128 to Pr.134 (PID control)
Pr. 180 to Pr. 186
(input terminal assignment)
Pr. 190 to Pr. 195
(output terminal assignment)
Pr. 501 "Motor switch-over selection"
Pr. 502 "MC switching interlock time"
Pr. 503 "Start waiting time"
Pr. 504 "Auxiliary motor connection-time deceleration time"
Pr. 505 "Auxiliary motor disconnection-time acceleration time"
Pr. 506 "Output stop detection time"
Pr. 507 "Output stop detection level"
Pr. 508 "Output stop cancel process value level"
Pr. 509 "Auxiliary motor 1 starting frequency"
Pr. 510 "Auxiliary motor 2 starting frequency"
Pr. 511 "Auxiliary motor 3 starting frequency"
Pr. 512 "Auxiliary motor 1 stopping frequency"
Pr. 513 "Auxiliary motor 2 stopping frequency"
Pr. 514 "Auxiliary motor 3 stopping frequency"
Pr. 515 "Auxiliary motor start delay frequency"
Pr. 516 "Auxiliary motor stop delay frequency"
With the advanced PID control functions, you can control pumps/fans using several motors (maximum of 4
motors).
<Operation outline>
# Set the number of commercial power supply operation motors in Pr. 500 "auxiliary motor operation
selection", and the motor switch-over method in Pr. 501 "motor switch-over selection".
Pr. Number
Name
Setting Range
Setting Increments
Factory Setting
500
Auxiliary motor
operation selection
0 to 3
1
0
501
Motor switch-over
selection
0 to 2
1
0
145
Description
Set the number of auxiliary
motors to be run. (1 to 3
motors)
0: Auxiliary motors are not run.
0: Basic Method
1: Alternative Method
2: Direct Method
PARAMETERS
Flow rate Q
Qmax
Q3
Q2
Q1
Time
(1) Pr. 501=0
Motor 1 (M1)
Motor 2 (M2)
Motor 3 (M3)
Motor 4 (M4)
(Note)
(Note)
(2) Pr. 501=1
Motor 1 (M1)
Motor 2 (M2)
Motor 3 (M3)
Motor 4 (M4)
(3) Pr. 501=2
Motor 1 (M1)
Motor 2 (M2)
Motor 3 (M3)
Motor 4 (M4)
Inverter operation drive
Commercial power supply operation drive
Stop
(1) Pr. 501 "motor switch-over selection" = "0" (Basic Method)
The inverter-driven motor is always fixed, and the MCs between power supply and motors are turned on/off
by the output frequency to increase/decrease the number of motors run by commercial power supply.
(2) Pr. 501 "motor switch-over selection" = "1" (Alternative Method)
During operation, as in the basic method (Pr. 501 = 0), the inverter-driven motor is fixed, and the number of
motors run by commercial power supply is controlled by the output frequency. When the output is stopped by
the sleep function, the MC between inverter and motor is switched over to change the inverter-driven motor.
Note: At this time, if the sequence of starting the motors was from M1 to M2 to M3 last time, it will be from
M2 to M3 to M1 this time.
146
4
PARAMETERS
(3) Pr. 501 "motor switch-over selection" = "2" (Direct Method)
When the start signal is entered, the motor is started by the inverter. When the conditions for starting the next
motor are enabled, the MCs between inverter and motor and between power supply and motor are switched
over to change the inverter-driven motor to commercial power supply operation, starting the next motor by the
inverter. Reversely, when the conditions for stopping the motors are enabled during running of several
motors, the motors are stopped, beginning with the one started first (run by the commercial power supply).
Note: • When the inverter is reset, the sequence of starting the motors to be driven returns to the initial
status. (Pr. 501 = 1 or 2)
• You cannot write values to Pr. 500 and Pr. 501 during operation. Also when the Pr. 500 or Pr. 501
setting is changed in a stop state, the sequence of starting the motors to be driven returns to the
initial status.
<System configuration>
(1) Pr. 501 "motor switch-over selection" = 0 (Basic Method)
Example Distributed water
MC
R04
R03
R02
Inverter
Power
supply
RST
M2
PUMP2
M1
Supplied water
STR
X14
X24
RT
JOG
FU
SD
OL
10
IPF
2
SE
R02
R03
R04
MC
R02
MC
R03
MC
R04
DC24V
For 2-wire type Detector
Sink logic
When Pr. 183=14, Pr. 185=24,
Pr. 194=42, Pr. 193=43, Pr. 192=44
5
Deviation signal
PUMP3
STF
Reverse rotation
Setting potentiometer
(Set point setting)
PUMP4
M3
PUMP1
Forward rotation
Advanced PID
control selection
PID forward-reverse
action switching
UVW
M4
1
4
(Process value) 4 to 20mA
0
Power 24V
supply
147
-
+
PARAMETERS
(2) Pr. 501 "motor switch-over selection" = 1 (Alternative Method), 2 (Direct Method)
Example
Inverter
Power
supply
Forward rotation
RST
Advanced PID
control selection
PID forward
-reverse
action switching
Setting
potentiometer
(Set point setting)
Deviation signal
UVW
M1
RI01
STF
Reverse rotation
X14
X24
STR
FU
RT
OL
JOG
SD
10
2
Distributed water
MC (Note 2)
RI01
R01
IPF
RI02
SU
R02
RUN RI03
MC
RI01
R01
R01
FR-A5AR
(Note 1)
(Option)
1
1A
4
1C
2A
RI02
R02
PUMP3
R02
RI03
M3
RI03
R03
RI04
DC24V
MC
R03
R03
M4
PUMP1
RI04
R04
R04
PUMP2
RI04
2C
3A
M2
RI02
SE
5
PUMP4
R04
For 2-wire Detector
type
Supplied water
+
3C
(Process value) 4 to 20mA
0
Power
supply
24V
Sink logic
When Pr. 183=14, Pr. 185=24
Pr. 194=45, Pr. 193=41, Pr. 192=46
Pr. 191=42, Pr. 190=47, Pr. 320=43
Pr. 321=48, Pr. 322=44
Note: 1. When driving three or more motors, use the inboard option (FR-A5AR).
2. Always provide mechanical interlocks for the MCs.
# Assign the advanced PID control selection signal X14 to any terminal using any of Pr. 180 to Pr. 186 (input
terminal function selection).
X14 signal
ON
OFF
Advanced PID control valid
Advanced PID control invalid
148
4
PARAMETERS
# PID control
PID actions are performed as set in Pr. 128 to Pr. 134 (PID control). (Refer to page 120)
In this advanced PID control, a voltage input (0 to ±5V or 0 to ±10V) may also be used as a process value.
Parameter Number
128
Name
PID action selection
Additional Setting
Range
30, 31
Description
30: PID reverse action
31: PID forward action
# PID forward-reverse action switching function
Use the X24 signal to switch between the forward and reverse actions under the control of the external
signal. Assign the signal X24 to any terminal using any of Pr. 180 to Pr. 186 (input terminal function
selection). (Refer to page 138)
Parameter Number
180 to 186
Name
Input terminal function
selection
Additional Setting
Range
24
Description
X24 signal
• At PID reverse action setting (Pr. 128 = 10, 20, 30): Turning on the X24 signal starts a forward action.
A reverse action is performed when the X24 signal is
off.
• At PID forward action setting (Pr. 128 = 11, 21, 31): Turning on the X24 signal starts a reverse action.
A forward action is performed when the X24 signal is
off.
# Assign the motor control signals (SLEEP, R01 to R04, RI01 to RI04) to Pr. 190 to Pr. 195 (output terminal
function selection) or assign them to Pr. 320 to Pr. 322 (RA1, RA21, RA3 output selection) using the
inboard option (FR-A5AR). (The functions of the output terminals are positive logic only.) (Refer to page
140)
Parameter Number
190
191
192
193
194
320
321
322
Name
RUN terminal function selection
SU terminal function selection
IPF terminal function selection
OL terminal function selection
FU terminal function selection
RA1 output selection (valid only when the FR-A5AR is used)
RA2 output selection (valid only when the FR-A5AR is used)
RA3 output selection (valid only when the FR-A5AR is used)
Additional Setting
Range
40, 41, 42, 43, 44, 45,
46, 47, 48
Description
Set value
40
41
42
43
44
45
46
47
48
Signal name
SLEEP
R01
R02
R03
R04
RI01
RI02
RI03
RI04
Function
Output at stop
Commercial power supply side motor 1 connection R01
Commercial power supply side motor 2 connection R02
Commercial power supply side motor 3 connection R03
Commercial power supply side motor 4 connection R04
Inverter side motor 1 connection RI01
Inverter side motor 2 connection RI02
Inverter side motor 3 connection RI03
Inverter side motor 4 connection RI04
149
PARAMETERS
<Motor switch-over timing>
(1) Pr. 501 "motor switch-over selection" = 0 (Basic method)
Pr. 501 "motor switch-over selection" = 1 (Alternative method)
Switch-over timing at start and stop of auxiliary motor 1
Pr. 515:
Motor start detection time
Output frequency
Maximum
frequency
Pr. 509:
Motor starting
frequency
Pr. 512:
Motor stopping
frequency
Variation
Pr. 509-Pr. 512
Variation
Pr. 509-Pr. 512
Minimum
frequency
Flow
Pr. 505 Pr. 516
Pr. 504
"Auxiliary motor connection-time deceleration time"
"Auxiliary motor disconnection-time acceleration time"
"Motor stop detection time"
When the number of
commercial power supply
operation motors increases
START
When the number of
commercial power supply
operation motors decreases
STOP
(2) Pr. 501 "motor switch-over selection" = 2 (Direct method)
Switch-over timing at start and stop of auxiliary motor 1
Pr. 515:
Motor start detection time
Output frequency
Maximum
frequency
4
Pr. 509:
Motor starting
frequency
Pr. 512:
Motor stopping
frequency
Variation
Pr. 509-Pr. 512
Minimum
frequency
Pr. 502 + Pr. 503
Pr. 505 Pr. 516
Flow
"Interlock time" + "start waiting time"
"Auxiliary motor disconnection-time acceleration time"
"Motor stop detection time"
When the number of
motors increases
START
When the number of
motors decreases
STOP
150
PARAMETERS
# You can set the output frequency of the inverter-operated motor at which the commercial power supply
operation motors start. When the output frequency higher than the preset value continues for longer than
the time set in Pr. 515, the commercial power supply motors start. In this case, the starting sequence
depends on the pattern in Pr. 501. Here, the Pr. 509 value means the set value at which the commercial
power supply motors start when the number of commercial power supply motors running is 0.
Parameter Number
Name
509
Auxiliary motor 1 starting frequency
510
Auxiliary motor 2 starting frequency
511
Auxiliary motor 3 starting frequency
Setting Range
0 to 120Hz
0 to 120Hz
0 to 120Hz
Setting Increments
0.01Hz
0.01Hz
0.01Hz
Factory Setting
<EC version>
60Hz
<50Hz>
60Hz
<50Hz>
60Hz
<50Hz>
# You can set the output frequency of the inverter-operated motor at which the commercial power supply
operation motors stop. When the output frequency lower than the preset value continues for longer than the
time set in Pr. 516, the commercial power supply motors stop. In this case, the stopping sequence depends
on the pattern in Pr. 501. Here, the Pr. 512 value means the set value at which the commercial power
supply motors stop when the number of commercial power supply motors running is 1.
Parameter Number
512
513
514
Name
Auxiliary motor 1 stopping frequency
Auxiliary motor 2 stopping frequency
Auxiliary motor 3 stopping frequency
Setting Range
0 to 120Hz
0 to 120Hz
0 to 120Hz
Setting Increments
0.01Hz
0.01Hz
0.01Hz
Factory Setting
0Hz
0Hz
0Hz
# You can set the delay time until the auxiliary motor is started. The auxiliary motor starts actually when the
time set in Pr. 515 elapses after the output frequency of the inverter operation motor has risen to or above
the value set in any of Pr. 509 to Pr. 511.
Parameter Number
515
Name
Auxiliary motor start delay time
Setting Range
0 to 3600s
Setting Increments
0.1s
Factory Setting
5s
# You can set the delay time until the auxiliary motor is stopped. The auxiliary motor stops actually when the
time set in Pr. 516 elapses after the output frequency of the inverter operation motor has dropped to or
below the value set in any of Pr. 512 to Pr. 514.
Parameter Number
516
Name
Auxiliary motor stop delay time
Setting Range
0 to 3600s
Setting Increments
0.1s
Factory Setting
5s
# You can set the MC switching interlock time (e.g. time from when RI01 turns off until R01 turns on) when
Pr. 501 = 2.
Parameter Number
502
Name
MC switching interlock time
Setting Range
0 to 100s
Setting Increments
0.1s
Factory Setting
1s
# You can set the time from MC switch-over to a start (time from when RI01 turns off and RI02 turns on until
inverter output starts) when Pr. 501 = 2. Set this time a little longer than the MC switching time.
Parameter Number
503
Name
Start waiting time
Setting Range
0 to 100s
Setting Increments
0.1s
Factory Setting
1s
# You can set the deceleration time until the output frequency varies by the decrement = Pr. 509 to Pr. 512
(for M2) if a motor connection occurs under advanced PID control. When the setting is 9999, the output
frequency is not forcibly changed.
Parameter Number
504
Name
Auxiliary motor connection-time
deceleration time
Setting Range
Setting Increments
Factory Setting
0 to 3600s
0.1s/0.01s
1s
# You can set the acceleration time until the output frequency varies by the increment = Pr. 509 to Pr. 512 (for
M2) if a motor disconnection occurs under advanced PID control. When the setting is 9999, the output
frequency is not forcibly changed.
Parameter Number
505
Name
Auxiliary motor disconnection-time
acceleration time
Setting Range
Setting Increments
Factory Setting
0 to 3600s, 9999
0.1s/0.01s
1s
151
PARAMETERS
<Output stop detection>
Process value
Pr. 508: Output stop
cancel level
Time
Output frequency
Pr. 506: Output stop
detection time
Td
Output at stop
Pr. 507: Output stop
level
Time
Motor
STOP
START
# The output stops if the output frequency continues to be lower than the Pr. 507 value for longer than the
time set in Pr. 506.
When the setting is 9999, the output stop function is not performed.
Also, an output stop is not detected when the process value is not more than the Pr. 508 value or when the
start signal is off. It is not detected during auxiliary motor operation either.
Parameter Number
506
Name
Output stop detection time
Setting Range
0 to 3600s, 9999
Setting Increments
0.1s
Factory Setting
9999
# You can set the set the output frequency value at which an output stop is detected. The output is stopped
when the output frequency continues to be lower than the Pr. 507 value for longer than the time set in
Pr. 506.
Parameter Number
507
Name
Output stop detection level
Setting Range
0 to 120Hz
Setting Increments
0.01Hz
Factory Setting
0Hz
# You can set the process value at which a restart is made after the output stop. Set the ratio of the process
value to the set point.
Parameter Number
508
Name
Output stop cancel process value
level
Setting Range
Setting Increments
Factory Setting
0 to 100%
0.1%
100%
152
4
PARAMETERS
<Status transition chart>
(1) Pr. 501 "motor switch-over selection" = 0 (Basic method) (For four motors)
STF
(STR)
R02
R03
R04
Pr. 515
Pr. 903
Inverter
M1 operation
Pr. 515
Pr. 903
Pr. 509
Pr. 515
Pr. 903
Pr. 510
Pr. 511
Pr. 516
Pr. 516
Pr. 516
Pr. 514
Pr. 513
Pr. 512
Pr. 507
Pr. 902
Pr. 902
M2
Commercial
power supply
operation
M3
Commercial
power supply
operation
M4
Pr. 506
Commercial
power supply
operation
153
Pr. 902
Sleep
PARAMETERS
(2) Pr. 501 "motor switch-over selection" = 1 (Alternative method) (For two motors)
STF
(STR)
Sleep
RI01
RI02
R01
R02
Pr. 509
Pr. 515
60Hz
(EC version 50Hz)
M1
Inverter
operation
M2
60Hz
(EC version
50Hz)
Pr. 506
Pr. 903
Pr. 516
Commercial power
supply operation
Pr. 507
Pr. 512
Pr. 515
Pr. 902 Sleep
Pr. 903
Pr. 509
Commercial power
supply operation
Inverter
operation
(3) Pr. 501 "motor switch-over selection" = 2 (Direct method) (For two motors)
RI01
RI02
R01
R02
Pr. 502
Pr. 502
Commercial power
supply operation
Pr. 503
Pr. 515
Pr. 903
Pr. 509
M1
M2
Inverter
operation
60Hz
(EC version
50Hz)
Pr. 515
Pr. 902
Pr. 509
Pr. 503
Pr. 516
Pr. 512
Inverter
operation
Pr. 902
Inverter operation
Commercial power
supply operation
Inverter
operation
Note: 1. If the start signal is turned off during operation, the MCs (R01 to R04) turn off and the inverter
decelerates.
2. If an error occurs during operation, the MCs (R01 to R04) turn off and the inverter shuts off the
output.
154
4
CHAPTER 5
PROTECTIVE FUNCTIONS
This chapter explains the "protective functions" of this
product.
Always read the instructions before using the equipment.
5.1 Errors (Alarms) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 155
5.2 Troubleshooting ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 166
5.3 Precautions for Maintenance and Inspection ・・・・・・ 168
Chapter 1
Chapter 2
Chapter 3
Chapter 4
Chapter 5
Chapter 6
Chapter 7
5.1 Errors (Alarms)
PROTECTIVE FUNCTIONS
If any fault has occurred in the inverter, the corresponding protective function is activated to bring the inverter
to an alarm stop and automatically give the corresponding error (alarm) indication on the PU display.
If your fault does not correspond to any of the following errors or if you have any other problem, please contact
your sales representative.
• When the protective function is activated, take the corresponding corrective action, then reset the inverter,
and resume operation.
• Resetting method
When the protective function is activated and the inverter has stopped its output, the inverter output is kept
stopped (and the motor is coasted to a stop). Unless reset, therefore, the inverter cannot restart. To reset,
use any of the following methods: switch power off once, then on again; short reset terminal RES-SD for
more than 0.1 seconds, then open; or press the [RESET] key of the operation panel or parameter unit (use
the help function of the parameter unit). If RES-SD are kept shorted, the operation panel shows "Err." and
the parameter unit indicates that the inverter is being reset.
5.1.1
Error (alarm) definitions
(1) Major faults
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
E.OC1
FR-PU04
OC During Acc
Overcurrent shut-off during acceleration
When the inverter output current reaches or exceeds approximately 150% of the
rated current during acceleration, the protective circuit is activated to stop the
inverter output.
Check for sudden acceleration.
Check for output short circuit.
Increase the acceleration time.
E.OC2
FR-PU04
Stedy Spd OC
Overcurrent shut-off during constant speed
When the inverter output current reaches or exceeds approximately 150% of the
rated current during constant speed, the protective circuit is activated to stop the
inverter output.
Check for sudden load change.
Check for output short circuit.
Keep load stable.
E.OC3
FR-PU04
OC During Dec
Overcurrent shut-off during deceleration
When the inverter output current reaches or exceeds approximately 150% of the
rated current during deceleration (other than acceleration or constant speed), the
protective circuit is activated to stop the inverter output.
Check for sudden speed reduction.
Check for output short circuit.
Check for too fast operation of motor's mechanical brake.
Increase the deceleration time.
Adjust brake operation.
155
PROTECTIVE FUNCTIONS
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
E.OV1
FR-PU04
OV During Acc
Regenerative overvoltage shut-off during acceleration
If regenerative energy causes the inverter's internal main circuit DC voltage to reach
or exceed the specified value, the protective circuit is activated to stop the inverter
output. It may also be activated by a surge voltage generated in the power supply
system.
Check for too slow acceleration.
Decrease the acceleration time.
E.OV2
FR-PU04
Stedy Spd OV
Regenerative overvoltage shut-off during constant speed
If regenerative energy causes the inverter's internal main circuit DC voltage to reach
or exceed the specified value, the protective circuit is activated to stop the inverter
output. It may also be activated by a surge voltage generated in the power supply
system.
Check for sudden load change.
• Keep load stable.
• Use the brake unit or power return converter (FR-RC) as required.
E.OV3
FR-PU04
OV During Dec
Regenerative overvoltage shut-off during deceleration or stop
If regenerative energy causes the inverter's internal main circuit DC voltage to reach
or exceed the specified value, the protective circuit is activated to stop the inverter
output. It may also be activated by a surge voltage generated in the power supply
system.
Check for sudden speed reduction.
• Increase the deceleration time. (Set the deceleration time which meets load GD2)
• Decrease the braking duty.
• Use the brake unit or power return converter (FR-RC) as required.
5
156
PROTECTIVE FUNCTIONS
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Note 1:
Note 2:
E.THM
FR-PU04
Motor Overload
Motor overload shut-off (electronic overcurrent protection) (Note 1)
The electronic overcurrent protection in the inverter detects motor overheat due to
overload or reduced cooling capability during constant-speed operation. When 85%
of the preset value is reached, pre-alarm (TH indication) occurs. When the specified
value is reached, the protective circuit is activated to stop the inverter output. When
a special motor such as a multi-pole motor or two or more motors are run, provide a
thermal relay in the inverter output side since the motor(s) cannot be protected by
the electronic overcurrent protection.
Check the motor for use under overload.
Reduce the load weight.
E.THT
FR-PU04
Inv. Overload
Inverter overload shut-off (electronic overcurrent protection) (Note 1)
If a current of more than 120% of the rated output current flows and overcurrent
shut-off does not occur (150% or less), inverse-time characteristics cause the
electronic overcurrent protection to be activated to stop the inverter output in order
to protect the output transistors.
(Overload immunity 120%, 60 seconds.)
Check the motor for use under overload.
Reduce the load weight.
E.IPF
FR-PU04
Inst. Pwr. Loss
Instantaneous power failure protection
If a power failure occurs for longer than 15ms (this also applies to inverter input
shut-off), the instantaneous power failure protective function is activated to stop the
inverter output in order to prevent the control circuit from malfunctioning. At this
time, the alarm warning output contacts open (across terminals B-C) and close
(across terminals A-C). (Note 2) If a power failure persists for longer than 100ms,
the alarm warning output is not provided, and the inverter restarts if the start signal
is on upon power restoration. (The inverter continues operating if an instantaneous
power failure is within 15ms.)
Find the cause of instantaneous power failure occurrence.
• Remedy the instantaneous power failure.
• Prepare a backup power supply for instantaneous power failure.
• Set the function of automatic restart after instantaneous power failure. (Refer
to page 84.)
Resetting the inverter initializes the internal heat integrating data of the electronic overcurrent
protection.
When an instantaneous power failure occurs, the alarm display and alarm output are not provided,
but the inverter performs protective operation to prevent a fault from occurring in itself. In some
operating status (load size, acceleration/deceleration time setting, etc.), overcurrent or other
protection may be activated upon power restoration.
157
PROTECTIVE FUNCTIONS
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
E.UVT
FR-PU04
Under Voltage
Undervoltage protection
If the power supply voltage of the inverter reduces, the control circuit will not operate
properly and will result in decreased motor torque or increased heat generation. To
prevent this, if the power supply voltage reduces below 150V (approximately 300V
for the 400V class), this function stops the inverter output.
When a jumper is not connected across P-P1 <+ - P1>, the undervoltage protective
function is activated.
Check for start of large-capacity motor.
Check that a jumper or DC reactor is connected across terminals P-P1 <+ - P1>.
Check the power supply system equipment such as power supply.
Connect a jumper or DC reactor across terminals P-P1 <+ - P1>.
E.FIN
FR-PU04
H/Sink O/Temp
Fin overheat
If the cooling fin overheats, the overheat sensor is actuated to stop the inverter
output.
• Check for too high ambient temperature.
• Check for cooling fin clogging.
Set the ambient temperature to within the specifications.
E.GF
FR-PU04
Ground Fault
Output side ground fault overcurrent protection
This function stops the inverter output if a ground fault overcurrent flows due to a
ground fault which occurred in the inverter's output (load) side at the start of the
inverter.
Check for a ground fault in the motor and connection cable.
Remedy the ground fault portion.
E.OHT
FR-PU04
OH Fault
External thermal relay operation (Note 3)
If the external thermal relay designed for motor overheat protection or the internally
mounted temperature relay in the motor switches on (contacts open), the inverter
output is stopped. If the relay contacts are reset automatically, the inverter will not
restart unless it is reset.
• Check for motor overheating.
• Check that the value of 7 (OH signal) is set correctly in any of Pr. 180 to
Pr. 186 (input terminal function selection).
Reduce the load and operating duty.
Note 3:The output terminals used must be allocated using Pr. 190 to Pr. 195 (output terminal function
selection). This function is activated only when OH has been set to any of Pr. 180 to Pr. 186 (input
terminal function selection).
158
5
PROTECTIVE FUNCTIONS
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
E.OLT
FR-PU04
Stll Prev STP (OL shown during stall
prevention operation)
Stall prevention
The running frequency has fallen to 0 by stall prevention activated. (OL while stall
prevention is being activated.)
Check the motor for use under overload.
Reduce the load weight.
E.OPT
FR-PU04
Option Fault
Option alarm
Stops the inverter output if the dedicated option used in the inverter results in setting
error or connection (connector) fault.
When the high power factor converter connection is selected, this alarm appears if
an AC power supply is connected to R, S, T <L1, L2, L3>.


E.OP1
to OP3
FR-PU04
Option slot alarm 1 to 3
Option slot alarm
Stops the inverter output if a functional alarm occurs in the plug-in option loaded in
the corresponding slot (e.g. communication alarm of the communication option).
Check for a wrong option function setting and operation.
(1 to 3 indicate the option slot numbers.)
Confirm the option function setting, etc.
E.PE
FR-PU04
Corrupt Memry
Parameter storage device alarm
2
Stops the inverter output if a fault occurs in the E PROM device which stores
parameter settings.
Check for too many number of parameter write times.
Change the inverter.
159
PROTECTIVE FUNCTIONS
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
E.PUE
FR-PU04
PU Leave Out
Parameter unit disconnection
This function stops the inverter output if communication between the inverter and
PU is suspended, e.g. the operation panel or PU is disconnected, when "2", "3", "16"
or "17" was set in Pr. 75 "reset selection/disconnected PU detection/PU stop
selection". This function stops the inverter output if the number of successive
communication errors is greater than the permissible number of retries when the Pr.
121 value is "9999" for RS-485 communication from the PU connector. This function
stops the inverter output if communication is broken for the time set in Pr. 122.
• Check for loose fitting of the DU or PU.
• Check the Pr. 75 setting.
Fit the DU and PU securely.
E.RET
FR-PU04
Retry No Over
Retry count exceeded
If operation cannot be resumed properly within the number of retries set, this
function stops the inverter output.
Find the cause of alarm occurrence.
Eliminate the cause of the error preceding this error indication.
E.LF
FR-PU04

Output phase failure protection
This function stops the inverter output if one of the three phases
inverter's output side (load side) results in open phase.
Check the wiring (Check the motor for a fault.)
(U, V, W) on the
• Wire the cables properly.
E.CPU
FR-PU04
CPU Fault
CPU error
If the arithmetic operation of the built-in CPU does not end within a predetermined
period, the inverter self-determines it as an alarm and stops the output.

• Make connection securely.
E. 6
FR-PU04
Error 6
CPU error
If the arithmetic operation of the peripheral circuit of the built-in CPU does not end
within a predetermined period, the inverter self-determines it as an alarm and stops
the output.
Check for a loose connector.
• Make connection securely.
160
5
PROTECTIVE FUNCTIONS
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
E. 7
FR-PU04
Error 7
CPU error
If the arithmetic operation of the peripheral circuit of the built-in CPU does not end
within a predetermined period, the inverter self-determines it as an alarm and stops
the output.

• Make connection securely.
E.LF
FR-PU04

Error
The inverter output is stopped if a malfunction occurs in the built-in CPU.
Check value of parameter, operation mode and connectors.
• Make connection securely.
E.P24
FR-PU04

24VDC power output short circuit
When the 24VDC power output from the PC terminal is shorted, this function shuts
off the power output. At this time, all external contact inputs switch off. The inverter
cannot be reset by entering the RES signal. To reset, use the operation panel or
switch power off, then on again.
Check for a short circuit in the PC terminal output.
Remedy the short circuit portion.
E.CTE
FR-PU04

Operation panel power supply short circuit
When the operation panel power supply (P5S of the PU connector) is shorted, this
function shuts off the power supply output. At this time, the operation panel
(parameter unit) cannot be used and RS-485 communication from the PU connector
cannot be made. To reset, enter the RES signal or switch power off, then on again.
Check for a short circuit in the PU connector cable.
Check the PU and cable.
E.15
FR-PU04
Error 15
Main circuit error
Brake unit cooling fin overheat, DC fuse blown, control board ambient temperature
error, output overcurrent, cooling fan power supply error, capacitor overcurrent,
cooling fin overheat, gate power supply error.
Refer to the next page (page 160) for details.
Refer page 148.
161
PROTECTIVE FUNCTIONS
Main circuit error [E,15] details
There are two 7-segment LEDs on the
right of the operation panel as shown on
the right. The following fault details are
indicated by the LED display.
CHARGE
FREQROL-A500L
ALARM
Left LED
Brake unit
cooling fin
overheating
DC fuse
blown
Control
board
Output
ambient
overcurrent
temperature
error
Right LED
Cooling
Gate power
____
Cooling fin
fan power
supply
overcurrent overheat
supply
error
error
For example, if the display is , the DC fuse blown, ___ overcurrent and gate power supply
errors have occurred.
Name
Brake unit cooling fin overheating
DC fuse blown
Control board ambient temperature error
Output overcurrent
Cooling fan power supply error
Capacitor
overcurrent
Cooling fin overheat
Gate power supply error
Details
The inverter output will stop if the brake unit's cooling fin temperature rises above the
specified value.
The inverter output will stop if the DC fuse blows.
The inverter output will stop if the ambient temperature of the control board rises above
the specified value.
The inverter output will stop if the inverter's output current flows above the specified
value.
The inverter output will stop if the cooling fan's power drops below the specified value.
The inverter will stop if a current exceeding the specified value flows to the main circuit
smoothing capacitor.
The inverter output will stop if the cooling fin's temperature rises above the specified
value.
The inverter output will stop if the gate power supply voltage drops below the specified
value.
162
5
PROTECTIVE FUNCTIONS
(1) Warnings
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Name
Description
Check point
Corrective action
OL
FR-PU04
OL (Stall Prev STP)
Stall prevention (Over current)
If a current of more than 120% (Note 4) of the rated inverter
current flows in the motor, this function stops the increase in
During
frequency until the overload current reduces to prevent the
acceleration
inverter from resulting in overcurrent shut-off. When the
overload current has reduced below 120%, this function
increases the frequency again.
If a current of more than 120% (Note 4) of the rated inverter
current flows in the motor, this function lowers the frequency
During constantuntil the overload current reduces to prevent overcurrent shutspeed operation
off. When the overload current has reduced below 120%, this
function increases the frequency up to the set value.
If a current of more than 120% (Note 4) of the rated inverter
current flows in the motor, this function stops the decrease in
During
frequency until the overload current reduces to prevent the
deceleration
inverter from resulting in overcurrent shut-off. When the
overload current has reduced below 120%, this function
decreases the frequency again.
Check the motor for use under overload.
The acceleration/deceleration time may change. Increase the stall prevention
operation level with Pr. 22 "stall prevention operation level" or disable stall
prevention with Pr. 156 "stall prevention operation selection".
oL
FR-PU04
oL
Stall prevention (overvoltage)
If the regenerative energy of the motor increases too much to
During
exceed the brake capability, this function stops the decrease in
deceleration
frequency to prevent overvoltage shut-off. As soon as the
regenerative energy has reduced, deceleration resumes.
Check for sudden speed reduction.
The deceleration time may change. Increase the deceleration time with Pr. 8
"deceleration time".
Note 4: The stall prevention operation current may be set as desired. It is factory-set to 120%.
Operation Panel
Indication
Name
Description
Check point
Corrective action
Operation Panel
Indication
Description
Corrective action
PS
FR-PU04
PS
PU stop
A stop made by pressing the [STOP] key of the PU has been set in Pr. 75 "PU stop
selection".
Check for a stop made by pressing the STOP key of the operation panel.
Refer to page 95.
Err.
This alarm appears if:
• The RES signal is on.
• You attempted to set any parameter value in the external operation mode.
• You attempted to change the operation mode during operation.
• You attempted to set any parameter value outside its setting range.
Perform operation correctly.
163
PROTECTIVE FUNCTIONS
5.1.2
To know the operating status at the occurrence of an alarm
When any alarm has occurred, the display automatically switches to the indication of the corresponding
protective function (error). By pressing the [MODE] key at this point without resetting the inverter, the display
shows the output frequency. In this way, it is possible to know the running frequency at the occurrence of the
alarm. It is also possible to know the current in the same manner. However, these values are not stored in
memory and are erased when the inverter is reset.
5.1.3
Correspondences between digital and actual characters
There are the following correspondences between the actual alphanumeric characters and the digital
characters displayed on the operation panel:
Actual
Digital
Actual
Digital
Actual
A
M
B
N
C
O
D
o
E
P
F
S
G
T
H
U
I
V
J
r
L
-
Digital
0
1
2
3
4
5
6
7
8
9
5
164
PROTECTIVE FUNCTIONS
5.1.4
Alarm code output
By setting Pr. 76 "alarm code output selection", an alarm definition can be output as a 4-bit digital signal. This
signal is output from the open collector output terminals equipped as standard on the inverter.
Correlations between alarm definitions and alarm codes are as follows.
Operation Panel
Display
(FR-DU04)
E.OC1
E.OC2
E.OC3
E.OV1
E.OV2
E.OV3
E.THM
E.THT
E.IPF
E.UVT
E.FIN
E. GF
E.OHT
Output Terminal Signal On-Off
Alarm Code
Alarm Output (across B-C)
SU
IPF
OL
FU
0
0
0
0
0
0
0
1
1
1
0
1
1
2
3
Provided (Open)
0
1
0
0
4
Provided (Open)
0
0
0
1
1
1
1
1
1
1
0
0
0
1
0
1
1
0
0
1
0
1
0
1
0
1
1
0
5
6
7
8
9
B
C
E.OLT
1
1
0
1
D
E.OPT
E.OP1 to E.OP3
E. PE
E.PUE
E.RET
E.LF
E.CPU
E.E 6
E.E 7
1
1
1
1
1
1
0
0
E
E
1
1
1
1
F
Provided (Open)
Provided (Open)
Provided (Open)
Provided (Open)
Provided (Open)
Provided (Open)
Not provided (Provided when OLT
is displayed) (Open)
Provided (Open)
Provided (Open)
Provided (Open)
Provided (Open)
Provided (Open)
Provided (Open)
Provided (Open)
Provided (Open)
Provided (Open)
(Note) 0: Output transistor OFF, 1: Output transistor ON (common terminal SE)
The alarm output assumes that Pr. 195 setting is "99" (factory setting).
5.1.5
Resetting the inverter
The inverter can be reset by performing any of the following operations. Note that the electronic overcurrent
protection's internal heat calculation value and the number of retries are cleared (erased) by resetting the
inverter.
Operation 1: Using the operation panel (FR-DU04), press the [RESET] key to reset the inverter.
Operation 2: Switch power off once, then switch it on again.
Operation 3: Switch on the reset signal (RES).
165
5.2 Troubleshooting
PROTECTIVE FUNCTIONS
POINT: Check the corresponding areas. If the cause is still unknown, it is recommended to initialize the
parameters (return to factory settings), re-set the required parameter values, and check again.
5.2.1
Motor remains stopped.
1) Check the main circuit
• Check that a proper power supply voltage is applied (operation panel display is provided).
• Check that the motor is connected properly.
2) Check the input signals
• Check that the start signal is input.
• Check that both the forward and reverse rotation start signals are not input.
• Check that the frequency setting signal is not zero.
• Check that the AU signal is on when the frequency setting signal is 4 to 20mA.
• Check that the output stop signal (MRS) or reset signal (RES) is not on.
• Check that the CS signal is not off when automatic restart after instantaneous power failure is selected
(Pr. 57 = other than "9999").
3) Check the parameter settings
• Check that the Pr. 160 "user group read selection" setting is correct.
• Check that the reverse rotation prevention (Pr. 78) is not selected.
• Check that the operation mode (Pr. 79) setting is correct.
• Check that the bias and gain (Pr. 902 to Pr. 905) settings are correct.
• Check that the starting frequency (Pr. 13) setting is not greater than the running frequency.
• Check that various operational functions (such as three-speed operation), especially the maximum
frequency (Pr. 1), are not zero.
4) Check the load
• Check that the load is not too heavy.
• Check that the shaft is not locked.
5) Others
• Check that the ALARM lamp is not lit.
• Check that the Pr. 15 "jog frequency" setting is not lower than the Pr. 13 "starting frequency" value.
5.2.2
Motor rotates in opposite direction.
• Check that the phase sequence of output terminals U, V and W is correct.
• Check that the start signals (forward rotation, reverse rotation) are connected properly.
5.2.3
Speed greatly differs from the setting.
• Check that the frequency setting signal is correct. (Measure the input signal level.)
• Check that the following parameter settings are proper: Pr. 1, Pr. 2, Pr. 902 to Pr. 905, Pr. 19.
• Check that the input signal lines are not affected by external noise. (Use shielded cables)
• Check that the load is not too heavy.
5.2.4
Acceleration/deceleration is not smooth.
• Check that the acceleration and deceleration time settings are not too short.
• Check that the load is not too heavy.
• Check that the torque boost (Pr. 0, Pr. 46) setting is not too large to activate the stall function.
166
5
PROTECTIVE FUNCTIONS
5.2.5
Motor current is large.
• Check that the load is not too heavy.
• Check that the torque boost (Pr. 0, Pr. 46) setting is not too large.
5.2.6
Speed does not increase.
• Check that the maximum frequency (Pr. 1) setting is correct.
• Check that the load is not too heavy. (In agitators, etc., load may become heavy in winter.)
• Check that the torque boost (Pr. 0, Pr. 46) setting is not too large to activate the stall prevention function.
• Check that the brake resistor is not connected to terminals P-P1 accidentally.
5.2.7
Speed varies during operation.
1) Inspection of load
• Check that the load is not varying.
2) Inspection of input signal
• Check that the frequency setting signal is not varying.
• Check that the frequency setting signal is not affected by induced noise.
5.2.8
Operation mode is not changed properly.
If the operation mode is not changed properly, check the following:
1. External input signal ... Check that the STF or STR signal is off.
When it is on, the operation mode cannot be changed.
2. Parameter setting ...... Check the Pr. 79 setting.
When the setting of Pr. 79 "operation mode selection" is "0" (factory setting),
switching input power on places the inverter in the external operation mode.
Press the operation panel's [MODE] key three times and press the [UP] key
(press the [PU] key for the parameter unit (FR-PU04)). This changes the
external operation mode into the PU operation mode. For any other setting (0
to 4, 6 to 8), the operation mode is limited according to the setting.
(For the detail of Pr.79, refer to 100 page)
5.2.9
Operation panel (FR-DU04) display is not provided.
• Make sure that the operation panel is connected securely with the inverter.
5.2.10
POWER lamp is not lit.
• Make sure that the wiring and installation are correct.
5.2.11
Parameter write cannot be performed
• Check that operation is not being performed (signal STF or STR is not ON).
• Check that the [SET] key ([WRITE] key) is pressed for longer than 1.5 seconds.
• Check that you are not attempting to make parameter setting outside the setting range.
• Check that you are not attempting to make parameter setting in the external operation mode.
• Check the setting of Pr. 77 "parameter write inhibit selection".
167
5.3 Precautions for Maintenance and Inspection
PROTECTIVE FUNCTIONS
The transistorized inverter is a static unit mainly consisting of semiconductor devices. Daily inspection must be
performed to prevent any fault from occurring due to adverse influence by the operating environment, such as
temperature, humidity, dust, dirt and vibration, changes in the parts with time, service life, and other factors.
5.3.1
Precautions for maintenance and inspection
For some short time after the power is switched off, a high voltage remains in the smoothing capacitor. When
accessing the inverter for inspection, switch power off. When more than 10 minutes have elapsed, make sure
that the voltage across the main circuit terminals P-N <+ - −> of the inverter is 30VDC or less using a meter,
etc.
5.3.2
Check items
(1) Daily inspections
• Check the following:
1) Motor operation fault
2) Improper installation environment
3) Cooling system fault
4) Unusual vibration and noise
5) Unusual overheating and discoloration
• During operation, check the inverter input voltages using a meter.
(2) Cleaning
Always run the inverter in a clean state.
When cleaning the inverter, gently wipe dirty areas with a soft cloth immersed in neutral detergent or ethanol.
Note: Do not use solvent, such as acetone, benzene, toluene and alcohol, as they will cause the inverter
surface paint to peel off.
Do not use detergent or alcohol to clean the display and other sections of the operation panel
(FR-DU04) or parameter unit (FR-PU04) as these sections will deform.
5.3.3
Periodic inspection
Check the areas inaccessible during operation and requiring periodic inspection. For periodic inspection,
consult us.
1) Cooling system: .................... Clean the air filter, etc.
2) Screws and bolts:.................. These parts may become loose due to vibration, temperature changes, etc.
Check that they are tightened securely and retighten as necessary.
3) Conductors and insulating materials: Check for corrosion and damage.
4) Insulation resistance: Measure.
5) Cooling fan, smoothing capacitor, relay: Check and change if necessary.
168
5
PROTECTIVE FUNCTIONS
5.3.4
Insulation resistance test using megger
1) Before performing the insulation resistance test using a megger on the external circuit, disconnect the
cables from all terminals of the inverter so that the test voltage is not applied to the inverter.
2) For the continuity test of the control circuit, use a meter (high resistance range) and do not use the megger
or buzzer.
3) For the inverter, conduct the insulation resistance test on the main circuit only as shown below and do not
perform the test on the control circuit. (Use a 500VDC megger.)
R 〈L1〉 Inverter
S 〈L2〉
T 〈L3〉
Power
supply
Motor
U
V
M
IM
DC500V
megger
Ground terminal
5.3.5
Pressure test
Do not conduct a pressure test. The inverter's main circuit uses semiconductors, which may be deteriorated if
a pressure test is made.
5.3.6
Area of
Inspection
Daily and Periodic Inspection
Inspection
Item
Description
Check ambient
Surrounding
temperature, humidity,
environment
dust, dirt, etc.
Interval
Periodic
Daily
1
2
year years
Method
Power
supply
voltage
{
(Refer to page 6)
{
Visual and auditory
checks.
No fault.
{
Measure voltage
across inverter
terminals R-S-T
<L1-L2-L3>.
Within permissible
AC voltage
Meter, digital
fluctuation
multimeter
(Refer to page
166)
Check that main circuit
voltage is normal.
(1) Check with megger
(across main circuit
terminals and
ground terminal).
(2) Check for loose
screws and bolts.
(3) Check for overheating of each part.
(4) Clean.
{
(1) Check conductors
Conductors,
for distortion.
cables
(2) Check cable sheaths
for breakage.
Terminal
Check for damage.
block
{
General
Main
circuit
Check for unusual
vibration and noise.
Instrument
Ambient
temperature:
(constant torque)
−10°C to +50°C,
non-freezing.
Thermometer,
(Variable torque) hygrometer,
−10°C to +40°C,
recorder
non-freezing
Ambient humidity:
90% or less,
non-condensing.
General
Overall unit
Criterion
{
{
{
{
{
(1) Disconnect all
cables from
inverter and
measure across
terminals R, S, T,
(1) 5M Ω or more. 500VDC class
U, V, W <L1, L2, L3,
(2), (3) No fault.
megger
U, V, W> and
ground terminal
with megger.
(2) Re-tighten.
(3) Visual check.
(1), (2) Visual check.
(1), (2) No fault.
Visual check.
No fault
* For periodic inspection, consult Mitsubishi.
169
PROTECTIVE FUNCTIONS
Area of
Inspection
Inspection
Item
Inverter
module,
Converter
module
Main
circuit
Smoothing
capacitor
Relay
Resistor
Control
circuit
Operation
Proteccheck
tive circuit
Cooling
system
Cooling fan
Display
Description
Interval
Periodic*
Daily
1
2
year years
Check resistance
across terminals.
(1) Check for liquid
leakage.
(2) Check for safety
valve projection and
bulge.
(3) Measure
electrostatic
capacity.
(1) Check for chatter
during operation.
(2) Check for rough
surface on contacts.
(1) Check for crack in
resistor insulation.
(2) Check for open
cable.
(1) Check balance of
output voltages
across phases with
inverter operated
independently.
(2) Perform sequence
protective operation
test to make sure of
no fault in protective
and display circuits.
(1) Check for unusual
vibration and noise.
(2) Check for loose
connection.
(1) Check if LED lamp
is blown.
(2) Clean.
{
{
{
Method
Disconnect cables
from inverter and
measure across
terminals R, S, T, ↔ P,
N and U, V, W, ↔ P, N
〈L1, L2, L3 ↔ +, −
and U, V, W, ↔ +, −〉
with tester range of
100Ω.
(1), (2) Visual check.
(3) Measure with
capacity meter.
Meter
General
(1) Check for unusual
vibration and noise.
(2) Check for unusual
odor.
{
(See the following
Analog meter
pages)
(1), (2) No fault.
(3) 85% or more
of rated
capacity.
Capacity
meter
(1) Auditory check.
(2) Visual check.
(1) No fault.
(2) No fault.
(1) Visual check.
Cement resistor,
wire-wound
resistor.
(2) Disconnect one
end and measure
with tester.
(1) Measure voltage
across inverter
output terminals UV-W.
(2) Simulatively
connect or
disconnect inverter
protective circuit
output terminals.
(1) No fault.
(2) Error should
be within ±10%
Meter, digital
of indicated
multimeter
resistance
value.
{
{
{
{
{
{
(1) Turn by hand with
power off.
(2) Visual check
{
(1) Light indicator
lamps on panel.
(2) Clean with rag.
{
{
Check reading of
meters on panel.
{
{
{
Motor
Insulation
resistance
Instrument
{
Display
Check that reading is
normal.
Crlterlon
Check with megger
(across terminals and
ground terminal).
{
Note: Values in parentheses are those of the 400V class.
*For periodic inspection, consult Mitsubishi.
170
(1) Auditory, sensory,
visual checks.
(2) Check for unusual
odor due to
overheating,
damage, etc.
Disconnect cables
from U, V, W,
including motor
cables.
(1) Phase-tophase voltage
balance within
4V(8V) for
200V(400V).
(2) Fault must
occur because
of sequence.
Digital
multimeter,
rectifier type
voltmeter
No unusual
vibration, unusual
noise.
(1) Check that
lamps are lit.
Must satisfy
specified and
management
values.
Voltmeter,
ammeter, etc.
5
(1), (2) No fault.
5M Ω or more
500V megger
PROTECTIVE FUNCTIONS
(1) Checking the inverter and converter modules
<Preparation>
• Disconnect the external power supply cables (R, S, T) <L1, L2, L3> and motor cables (U, V, W).
• Prepare a meter. (Use 100Ω range.)
<Checking method>
Change the polarity of the tester alternately at the inverter terminals R, S, T, U, V, W, P and N < L1, L2, L3, U, V,
W, + and −>, and check for continuity.
Note: 1. Before measurement, check that the smoothing capacitor is discharged.
2. At the time of continuity, the measured value is several to several ten’s-of ohms depending on the
module type, circuit tester type, etc. If all measured values are almost the same, the modules are
without fault.
<Module device numbers and terminals to be checked>
Inverter module
Converter module
Tester Polarity
D1
D2
D3
TR1
TR2
TR5
R <L1>
P <+>
<L1>
Discontinuity
P <+>
R
S <L2>
P <+>
Discontinuity
P <+>
S <L2>
Continuity
T <L3>
P <+>
Discontinuity
P <+>
T <L3>
Continuity
U
P <+>
Discontinuity
P <+>
U
V
P <+>
P <+>
V
W
P <+>
P <+>
W
Tester Polarity
Measured Value
D4
Continuity
D5
D6
TR4
Continuity
Discontinuity
TR6
Continuity
Discontinuity
TR2
Continuity
Converter module
R <L1>
N <−>
<L1>
D2
Continuity
N <−>
R
S <L2>
N <−>
Continuity
N <−>
S <L2>
Discontinuity
T <L3>
N <−>
Continuity
N <−>
T <L3>
Discontinuity
U
N <−>
Continuity
N <−>
U
V
N <−>
N <−>
V
W
N <−>
N <−>
W
P 〈+〉
Discontinuity
Discontinuity
Continuity
Discontinuity
Continuity
Discontinuity
Inverter module
TR1
D1
Measured Value
TR3
TR5
D3
R
〈L1〉
S
〈L2〉
T
〈L3〉
U
C
V
W
D4
D5
D6
TR4
N 〈–〉
171
TR6
TR2
PROTECTIVE FUNCTIONS
5.3.7
Replacement of parts
The inverter consists of many electronic parts such as semiconductor devices.
The following parts may deteriorate with age because of their structures or physical characteristics, leading to
reduced performance or failure of the inverter. For preventive maintenance, the parts must be changed
periodically.
Replacement Parts of the Inverter
Part Name
Standard Replacement Interval
Description
Cooling fan
2 to 3 years
Change (as required)
Smoothing capacitor in main circuit
5 years
Change (as required)
Smoothing capacitor on control board
5 years
Change the board (as required)
Relays

Change as required
(1) Cooling fan
The cooling fan cools heat-generating parts such as the main circuit semiconductor devices. The life of the
cooling fan bearing is usually 40,000 to 50,000 hours. Hence, the cooling fan must be changed every 5years if
the inverter is run continuously. When unusual noise and/or vibration is noticed during inspection, the cooling
fan must be changed immediately.
z Removal
1) Turn the four knurled knobs fixing the cooling fan installation plate counterclockwise.
(The knobs can be turned easily using a coin, etc.)
2) Lift the installation plate and cooling fan slightly, and disconnect the fan connectors.
3) Remove the fan with the installation plate.
4) Remove the four screws fixing the cooling fan to the installation plate.
z Reinstallation
1) After confirming the orientation of the fan, reinstall the fan so that the arrow on the left of "AIR FLOW"
faces up.
AIR FLOW
<Fan side face>
2) Connect the fan connectors
When wiring, use care to avoid catching the wires in the fan and sandwiching in the metal sections of
the cooling fan and inverter unit.
3) Insert the cooling fan installation plate into the inverter unit, and securely fix with screws.
Fan installation plate
Knourted knobs
5
Cooling fan
Fan connectors
A500 L
<Looking from side>
Inverter unit
FR-A500L
Caution: The number of cooling fans used differs according to the inverter capacity. Depending on the
number of cooling fans used, they may be installed on two installation plates.
172
PROTECTIVE FUNCTIONS
(2) Smoothing capacitors
A large-capacity aluminum electrolytic capacitor is used for smoothing the DC in the main circuit, and an
aluminum electrolytic capacitor is also used for stabilizing the control power in the control circuit. Their
characteristics are adversely affected by ripple current, etc. When the inverter is operated in an ordinary, airconditioned environment, change the capacitors about every 5 years. When 5 years have elapsed, the
capacitors will deteriorate more rapidly.
Check the capacitors at least every year (less than six months if their life will be expired soon).
Check the following:
1) Case (side faces and bottom face for expansion)
2) Sealing plate (for remarkable warping and extreme cracks)
3) Explosion-proof valve (for excessive valve expansion and operation)
4) Appearance, external cracks, discoloration, leakage. When the measured capacitance of the capacitor has
reduced below 85% of the rating, change the capacitor.
(3) Relays
To prevent a contact fault, etc., relays must be changed according to the number of accumulative switching
times (switching life).
See the following table for the inverter parts replacement guide. Lamps and other short-life parts must also be
changed during periodic inspection.
5.3.8
Inverter replacement
The inverter can be changed with the control circuit wiring kept connected. Before replacement, remove the
screws in the wiring cover of the inverter.
1) Remove the mounting screws in both ends of the control circuit terminal block.
2) With both hands, pull down the terminal block from the back of the control circuit terminals.
3) When installing the terminal block to a new inverter, exercise care not to bend the pins of the control circuit
terminal block connector.
173
PROTECTIVE FUNCTIONS
5.3.9
Measurement of main circuit voltages, currents and power
Measurement of voltages and currents
Since the voltages and currents on the inverter power supply and output sides include harmonics, accurate
measurement depends on the instruments used and circuits measured.
When instruments for commercial frequency are used for measurement, measure the following circuits using
the instruments given on the next page.
Input voltage
Output voltage
Input current
Output current
Inverter
W11
Ar
3-phase
power
supply
R 〈L1〉 U
Vu
W12
As
S 〈L2〉 V
Av
Vs
Vt
To motor
Vv
W13
At
W12
Au
Vr
T 〈L3〉 W
P 〈+〉 〈–〉 N
5
2
+
V
W22
Aw
Vw
-
Instrument
types
Typical Measuring Points and Instruments
Note: Use an FFT to measure the output voltage accurately. Accurate measurement cannot be made if you
use a tester or general measuring instrument.
174
5
PROTECTIVE FUNCTIONS
Measuring Points and Instruments
Item
Power supply side
current I1
Power supply side power
P1
Power supply side power
factor Pf1
Across R-S, S-T and T-R
<Across L1-L2, L2-L3 and L3-L1>
Measuring Instrument
Moving-iron type AC voltmeter
R, S and T line currents
Moving-iron type AC ammeter
<L1, L2 and L3 line currents>
At R, S and T, and across R-S,
P1 = W 11 + W 12 + W 13
S-T and T-R
Electrodynamic type single<At L1, L2 and L3, and across
(3-wattmeter method)
phase wattmeter
L1-L2, L2-L3 and L3-L1>
Calculate after measuring power supply voltage, power supply side current and power supply side power.
Pf1 =
P1
× 100%
3 V1 × I1
Output side voltage V2
Across U-V, V-Wand W-U
Rectifier type AC voltmeter
(Note 1) (Not moving-iron type)
Output side current I2
U, V and W line currents
Moving-iron type AC ammeter
(Note 3)
Output side power P2
At U, V and W, and across U-V
and V-W
Electrodynamic type singlephase wattmeter
Output side power factor
Pf2
Converter output
Frequency setting signal
Frequency setting power
supply
Remarks
(Reference Measured Value) *
Commercial power supply
Within permissible AC voltage
fluctuation (Refer to 173 page)
Difference between phases is
within ±1% of maximum output
voltage.
Current should be equal to or less
than rated inverter current.
Difference between phases is 10%
or lower.
P2 = W 21 + W 22
2-wattmeter method
(or 3-wattmeter method)
Calculate in similar manner to power supply side power factor.
Pf2 =
P2
× 100%
3 V2 × I2
Across P-N <Across + and −>
Moving-coil type (such as
tester)
Across 2 (+) –5
Across 1 (+) –5
Across 4 (+) –5
Across 10 (+) –5
Across 10E (+) –5
POWER lamp lit
1.35 × V1
Maximum 380V (760V) during
regenerative operation
0 to 5V/0 to 10VDC
0 to ±5V/0 to ±10VDC
4 to 20mADC
5VDC
10VDC
Approximately 5VDC at
maximum frequency
(without frequency meter)
“5” is common.
Power supply voltage V1
Measuring Point
T1
Frequency meter signal
Moving-coil type (Tester, etc.
may be used) (Internal
resistance: 50kΩ or larger)
Across AM (+) –5
Start signal
Select signal
Reset
Output stop
Across STF, STR, RH, RM, RL,
JOG, RT, AU, STOP, CS (+) -SD
Across RES (+) –SD
Across MRS (+) –SD
Alarm signal
Across A-C
Across B-C
T2
Pulse width T1:
Adjusted by Pr.900
Pulse cycle T2: Set by Pr.55
(Valid for frequency
monitoring only)
Approximately 10DVC at
maximum frequency
(without frequency meter)
SD is common.
DC8V
Across FM (+) –SD
20 to 30VDC when open.
ON voltage: 1V or less
Continuity check (Note 2)
Moving-coil type
(such as tester)
<At OFF>
<At ON>
Across A-C: Discontinuity Continuity
Across B-C: Continuity
Discontinuity
Note 1. Accurate data will not be obtained by a tester.
2. When Pr. 195 "A, B, C terminal function selection" setting is positive logic.
3. When the carrier frequency exceeds 5kHz, do not use the instrument because overcurrent losses occurring in the metallic parts
inside the instrument will increase and may lead to burnout.
In this case, use an approximate effective value type instrument.
*Values in parentheses are those of the 400V class.
175
CHAPTER 6
SPECIFICATIONS
This chapter provides the "specifications" of this product.
Always read the instructions before using the equipment.
Chapter 1
6.1 Standard Specifications ・・・・・・・・・・・・・・・・・・・・・・・・ 176
Chapter 2
Chapter 3
Chapter 4
Chapter 5
Chapter 6
Chapter 7
6.1 Standard Specifications
SPECIFICATIONS
6.1.1
Model specifications
200V class
200V
200V:Model FR-F520L-□□
Power supply
Output
Applicable motor capacity (kW) (Note 1)
Rated capacity (kVA)
(HP)
(Note 2)
Rated current (A)
(Note 3)
Overload capacity
75K
90K
110K
75
90
110
110
132
165
100
125
150
288
346
432
120% 60 sec, 150% 0.5 sec (inverse-time characteristics)
Voltage (Note 4)
Three phase, 200V to 230V 50/60Hz
Rated input AC voltage, frequency
Three phase, 200V to 230V 50/60Hz
Tolerable AC voltage fluctuation
170V to 253V 50/60Hz
Tolerable frequency fluctuation
±5%
Power facility capacity (kVA)
(Note 5)
110
132
165
Protective structure (JEM 1030)
Open type (IP00)
Cooling method
Forced air cooling
83
(183)
Approx. mass (kg (Ib))
83
(183)
85
(187)
400V class
400V
400V:Model FR-F540L-□□
Applicable motor capacity
(kW) (Note 1)
Output
Rated
capacity
(HP)
Light Variable torque
Variable torque
Light Variable torque
(kVA) (Note 2)
Variable torque
Light Variable torque
Variable torque
Rated current (A)
Overload capacity
Power supply
(Note 2)
Variable torque
Light Variable torque
(Note 3)
75K
75
75
100
90K
90
90
150
110K
110
132
150
132K
132
160
200
160K
160
185
250
185K
185
220
300
220K
220
250
350
280K
280
315
450
375K
375
400
600
450K
450
700
530K
530
800
100
110
110
144
144
150
137
137
180
180
200
165
198
216
260
250
198
230
260
302
300
230
274
302
360
350
274
329
360
432
400
329
364
432
477
500
417
464
547
610
700
550
571
722
750
660
866
-
770
1010
-
-
-
120% 60 sec, 150% 0.5 sec (inverse-time characteristics)
110% 60 sec (inverse-time characteristics)
Three phase, 380V to 480V 50/60Hz
Three phase, 380V to 480V 50/60Hz
323 to 528V 50/60Hz
±5%
Variable torque
Light Variable torque
Voltage (Note 4)
Rated input AC voltage, frequency
Tolerable AC voltage fluctuation
Tolerable frequency fluctuation
Power facility capacity
(kVA) (Note 5)
Variable torque
110
137
165
198
230
274
329
417
550
660
770
Light Variable torque
110
137
198
230
274
329
364
464
571
-
-
Protective structure (JEM 1030)
Cooling method
Approx. mass (kg (Ib))
41
(90.34)
57
66
66
(125.66)
(145.50)
(145.50)
Open type (IP00)
Forced air cooling
68
120
120
(150.00)
(264.55)
(264.55)
220
235
490
500
(485.01)
(518.08)
(1078)
(1100)
Note: 1. The applicable motor capacity indicated is the maximum capacity applicable when
Mitsubishi 4-pole standard motor is used.
2. The rated output capacity (KVA) indicated is based on 220V (200V class), 440V (400V
class).
The rated output capacity (HP) indicated is based on National Electric Code for 208V and
460V.
3. The overload capacity indicated in % is the ratio of the overload current to the inverter’s
rated current. For repeated duty, allow time for the inverter and motor to return to or
below the temperatures under 100% load.
4. The maximum output voltage cannot exceed the power supply voltage. The maximum
output voltage may be set as desired below the power supply voltage.
5. The power supply capacity changes with the values of the power supply side inverter
impedances (including those of the input reactor and cables).
176
SPECIFICATIONS
Control specifications
6.1.2
Common specifications
Control system
Output frequency range
Frequency
Analog input
setting
resolution
Digital input
Frequency accuracy
Voltage/frequency
characteristic
Torque boost
Acceleration/deceleration
time setting
DC dynamic brake
Stall prevention operation
level
Analog input
Frequency
setting
Digital input
signal
Start signal
Input signals
Operation current level can be set (0 to 150% variable), presence or absence can be selected.
0 to 5VDC, 0 to 10VDC, 0 to ±10VDC, 4 to 20mADC
3-digit BCD or 12-bit binary using operation panel or parameter unit (when the FR-A5AX option
is used)
Forward and reverse rotation, start signal automatic self-holding input (3-wire input) can be
selected.
Up to 7 speeds can be selected. (Each speed can be set between 0 and
120Hz, running speed can be changed during operation from the PU
(FR-DU04/FR-PU04).)
Second acceleration/
deceleration time
selection
Jog operation selection
Provided with jog operation mode select terminal (Note 1)
Current input selection
Input of frequency setting signal 4 to 20mADC (terminal 4) is selected.
Selection of automatic
restart after an
instantaneous power
failure
External thermal relay
input
MT-HC connection
External DC dynamic
braking start signal
PID control valid
PU-external operation
switch-over
PU operation external
interlock
Output stop
Alarm reset
Operation functions
Output signals
Operational specifications
Multi-speed selection
Soft-PWM control/high carrier frequency PWM control (V/F control), Optimum excitation control.
0.5 to 120Hz
0.015Hz/60Hz (terminal 2 input: 12 bits/0 to 10V, 11 bits/0 to 5V, terminal 1 input: 12 bits/-10 to
+10V, 11 bits/-5 to +5V)
0.01Hz
Within ±0.2% of maximum output frequency (25°C ±10°C for analog input, within 0.01% of set
output frequency for digital input.
Base frequency set as required between 0 and 120Hz. Constant torque or variable torque
pattern can be selected.
Manual torque boost.
0 to 3600 s (acceleration and deceleration can be set individually), linear or S-pattern
acceleration/deceleration mode can be selected.
Operation frequency (0 to 120Hz), operation time (0 to 10 s), voltage (0 to 30%) variable.
0 to 3600 seconds (up to two different acceleration and deceleration times can
be set individually.)
Selection of whether automatic restart is made or not after an instantaneous
power failure.
Thermal relay contact input when the thermal relay provided externally is used
to stop the inverter.
Use Pr. 180 to
Pr. 186 for
selection.
Inverter operation enable input and instantaneous power failure detection input
External input for DC dynamic braking start.
Selection for exercising PID control.
External selection between PU and external operation.
External interlock switch-over of PU operation.
Instantaneous shut-off of inverter output (frequency, voltage)
Alarm retained at the activation of protective function is reset.
Maximum/minimum frequency setting, frequency jump operation, external thermal relay input
selection, polarity reversible operation, automatic restart operation after instantaneous power
failure, commercial power supply-inverter switch-over operation, forward/reverse rotation
prevention, operation mode selection, PID control, computer link operation (RS-485)
Operating status
5 different signals can be selected from inverter running, up to frequency, instantaneous power
failure (undervoltage), frequency detection, second frequency detection, during PU operation,
overload alarm, electronic overcurrent protection pre-alarm, zero current detection, PID lower
limit, PID upper limit, PID forward/reverse rotation, commercial power supply-inverter switchover MC1, 2, 3, operation ready, fan fault and fin overheat pre-alarm minor fault. Open collector
output.
Alarm (inverter trip)
Contact output...change-over contact (230VAC 0.3A, 30VDC 0.3A) Open collector...alarm code
(4 bit) output.
For meter
1 signal can be selected from output frequency, motor current (steady or peak value), output
voltage, frequency setting, running speed, converter output voltage (steady or peak value),
regenerative brake duty, electronic overcurrent protection load factor, input power, output power
and load meter. Pulse train output (1440 pulses/sec./full scale) and analog output (0 to 10VDC).
177
6
SPECIFICATIONS
PU (FR-DU04
/FR-PU04)
Operating
status
Display
Alarm
definition
Additional
display on
parameter unit
(FR-PU04)
only
Operating
status
Alarm
definition
Interactive
guidance
Environment
Protective/alarm functions
Ambient temperature
Ambient humidity
Storage temperature
(Note 2)
Ambience
Altitude, vibration
1 signal can be selected from output frequency, motor current (steady or peak value), output
voltage, frequency setting, running speed, motor torque, overload, converter output voltage
(steady or peak value), electronic overcurrent protection load factor, input power, output power,
load meter and reference voltage output. Pulse train output (1440 pulses/sec./full scale) and
analog output (0 to 10VDC).
Alarm definition is displayed when protective function is activated. 8 alarm definitions are stored.
(Four alarm definitions are only displayed on the operation panel.)
Input terminal signal states, output terminal signal states, option fitting status, terminal
assignment status
Output voltage/current/frequency/cumulative ON time immediately before activation of
protective function
Operation guide and troubleshooting by help function
Overcurrent shut-off (during acceleration, deceleration, constant speed), regenerative
overvoltage shut-off, undervoltage, instantaneous power failure, overload shut-off (electronic
overcurrent protection), ground fault current, output short circuit, main circuit device overheat,
stall prevention, overload alarm, fin overheat, fan fault, option fault, parameter error, PU
disconnection, retry count exceeded, output phase failure, CPU error, 24VDC power output
short circuit, operation panel power supply short circuit
-10°C to +50°C (non-freezing, Variable Torque at 75K to 375K), -10°C to +40°C (non-freezing,
Variable Torque at 450K to 530K), -10°C to +40°C (non-freezing, Light Variable Torque at 75K
to 375K)
90%RH or less (non-condensing)
-20°C to +65°C
Indoors. (No corrosive and flammable gases, oil mist, dust and dirt.)
Maximum 1000m above sea level 5.9m/s2 {0.6G} or less (conforms to JIS C 0911)
Note: 1. Jog operation may also be performed from the operation panel or parameter unit.
2. Temperature applicable for a short period in transit, etc.
178
SPECIFICATIONS
6.1.3
Outline drawings
zFR-F540L-75K to 160K / FR-F520L-75K to 110K (-CH)
C hole
hole
W
W1
W2
H
H1
D
D1
C
FR-F540L-75K
Inverter Type
360
260
336
610
584
360
160
10
FR-F540L-90K to 160K
480
400
456
740
714
360
160
10
FR-F520L-75K to 110K
480
400
456
740
714
360
160
10
(Unit : mm)
zAccessory DC reactor
2-S2 suspension bolt *
2 terminal
(for bolt)
Main
nameplate
Caution plate
4-installation hole
(for S screw)
Grounding terminal
(for S1 screw)
Tap diagram
The ・marks indicates start of coil.
Inverter Type
Outline drawing (mm)
Z1
B
H
G
X
Y
Z
S
S1
φ
FR-F540L-75K
140
170
320
230
120
295
25
M6
M6
M10
FR-F540L-90K
150
175
337
265
130
FR-F540L-110K
150
180
337
255
130
310
25
M6
M6
M12
310
25
M6
M6
M12
FR-F540L-132K
175
185
400
300
150
365
32
M8
M6
M12
FR-F540L-160K
175
190
400
315
150
365
32
M8
M6
M12
FR-F520L-75K/90K
150
195
337
220
130
310
25
M6
M6
M12
FR-F520L-110K
175
200
400
300
150
365
32
M8
M6
M12
Weight
(Kg(Ib))
14
(31)
18
(40)
19
(42)
22
(49)
22
(49)
19
(42)
20
(44)
(Unit : mm)
179
6
SPECIFICATIONS
zFR-F540L-185K to 375K (-CH)
C hole
hole
Inverter Type
W
W1
W2
H
H1
D
D1
C
FR-F540L-185K/220K
498
200
474
1010
984
380
185
10
FR-F540L-280K
680
300
656
1010
984
380
185
10
FR-F540L-375K
790
315
766
1330
1300
440
196
12
(Unit : mm)
zAccessory DC reactor
2-S2 suspension bolt *
2 terminal
(for bolt)
2-S2 suspension bolt *
Main
nameplate
2 terminal
(for bolt)
Caution plate
Main nameplate
Caution plate
4-installation hole
(for S screw)
4-installation hole
(for S screw)
Grounding terminal
(for S1 screw)
Grounding terminal
(for S1 screw)
*Remove the suspension bolt
after installing the product.
Tap diagram
The ・marks indicates start of coil.
Inverter Type
Outline drawing (mm)
B
H
G
X
Y
Z
Z1
FR-F540L-185K
175
225
400
285
150
365
FR-F540L-220K
190
225
438
305
165
400
S
S1
S1
φ
32
M8
M6
-
M12
38
M8
M8
M8
M12
FR-F540L-280K
210
235
495
350
185
450
44
M10
M8
M8
M16
FR-F540L-375K
220
250
495
380
195
450
44
M10
M8
M8
M16
Weight
(Kg(Ib))
29
(64)
36
(80)
48
(106)
57
(126)
(Unit : mm)
180
SPECIFICATIONS
z
FR-F540L-450K, 530K
Air exhaust
This (Top attachment)
should be removed at
operating because of
air exhaust.
Control Panel
These (Side attachments)
can be used for fixing this
inverter unit.
Air inlet
Cabling Hole
(For main circuit)
Bottom View
z
Accessory
DC REACTOR (for FR-F540L-450K, 530K)
6
180-A
CHAPTER 7
OPTIONS
This chapter describes the "options" of this product.
Always read the instructions before using the equipment.
Chapter 1
7.1 Option List ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 181
Chapter 2
Chapter 3
Chapter 4
Chapter 5
Chapter 6
Chapter 7
7.1 Option List
OPTIONS
7.1.1
Stand-alone options
Name
Parameter unit
(8 languages)
Parameter unit connection
cable
Cooling fin protrusion
attachment
Type
FR-PU04
FR-CB2□□
MT-A5CN□□
Power factor improving AC
reactor
MT-BAL (Note 1)
Radio noise filter
Line noise filter
FR-BIF (Note 1)
FR-BLF
Brake unit
MT-BU5
Resistor unit
MT-BR5
Power return converter
MT-RC (Note 2)
High power factor converter
MT-HC (Note 2)
(Note 3)
Manual controller
FR-AX (Note 4)
DC tach. follower
FR-AL (Note 4)
Three speed selector
FR-AT (Note 4)
Motorized speed setter
FR-FK (Note 4)
Ratio setter
FR-FH (Note 4)
PG follower (Note 4)
FR-FP
Master controller (Note 4)
FR-FG
Soft starter (Note 4)
FR-FC
Deviation detector (Note 4)
FR-FD
Preamplifier (Note 4)
FR-FA
Application, Specifications, etc.
Interactive parameter unit using LCD display (For use in
Japanese, English, German, French, Spanish, Italian,
Swedish and Finnish)
Cable for connection of the operation panel or parameter
unit.
Used to place only the heat generating section of the
inverter in the back of the control box.
Used to improve the inverter input power factor (overall
power factor about 90%) and cooperate with the power
supply.
For radio noise reduction
For line noise reduction
Applicable
Inverter
Common to
all models
according to
capacity
according to
capacity
Common to
all models
Used to improve the braking capability of the inverter (for
high-inertia load or negative load). Use the brake unit and
resistor unit together.
High-function brake unit which can return motor-generated
braking energy to the power supply.
The high power factor converter switches the converter
circuit on-off to convert the input current waveform into a
sine wave to suppress harmonics considerably. (Used with
the standard accessories.)
For independent operation. With frequency meter,
frequency setting potentiometer and start switch.
For joint operation using external signals. (0 to 5VDC, 0 to
10VDC) (1VA)
For three-speed (high, middle, low) switching operation.
(1.5VA)
For remote operation. Allows operation to be controlled
from several places. (5VA)
For ratio control. Allows ratios to be set to five inverters.
(3VA)
For follow-up operation using the signal of a pilot generator
(PG). (2VA)
For parallel operation of several (up to 35) inverters. (5VA)
For soft start and stop. Allows parallel operation and
acceleration/deceleration. (3VA)
For synchronous operation. Used with a deviation sensor
and synchro. (5VA)
Can be used as A/V conversion or operational amplifier.
(3VA)
According to
capacity
Common to
all models
Note: 1. "H" in the type code indicates 400V class. Power supply specifications of FR series controllers and
setters: 200VAC 50Hz, 200V/220VAC 60Hz, 115VAC 60Hz.
2. Maximum rated input voltage is 460V.
3. Inverter type name should be "-HC" for MT-HC converter.
4. Options available in Japan only.
181
OPTIONS
7.1.2
Inboard dedicated options
•Inboard options
Name
12-bit digital input
Type
FR-A5AX
• Among 21 standard output signals of the inverter, this option outputs any 7 selected signals
from open collector output terminals.
Digital output
FR-A5AY
Extension analog
output
Relay output
FR-A5AR
Computer link
FR-A5NR
• Outputs extra 16 signals which can be monitored on the FM and AM terminals such as output
frequency, output voltage and output current, etc.
• 20mADC or 5V(10V)DC meter can be connected.
• Among 26 standard output signals of the inverter, this option outputs any 3 selected signals
from relay contact output terminals.
• Operation/monitoring/parameter change of the inverter can be performed under the control of
a user program from a computer, e.g. personal computer or FA controller, connected by a
communication cable.
• Any one output signal can be selected from among the standard output signals of the inverter
and output as a relay contact (contactor) signal.
Relay output
Communication
Function
• Input interface used to set the inverter frequency accurately using external 3-digit BCD or 12bit binary-coded digital signals.
• Gains and offsets can also be adjusted.
Profibus DP
FR-A5NP
• Operation/monitoring/parameter change of the inverter can be performed from a computer or
PLC.
Device Net TM
FR-A5ND
• Operation/monitoring/parameter change of the inverter can be performed from a computer or
PLC.
CC-Link (Note 2)
FR-A5NC
• Operation/monitoring/parameter change of the inverter can be performed from a PLC.
Modbus Plus
FR-A5NM
• Operation/monitoring/parameter change of the inverter can be performed from a computer or
PLC.
Note: 1. Three inboard options may be mounted at the same time (the number of the same options mountable is only one, and only one
of the communication options may be mounted.)
2. CC-Link stands for Control & Communication Link.
182
7
APPENDICES
This chapter provides the "appendices" for use of this
product.
Always read the instructions before using the equipment.
Appendix 1 Data Code List・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 183
Appendix 2 Inverter Heat Loss・・・・・・・・・・・・・・・・・・・・・・・・・ 188
Appendix 1
Data Code List
APPENDICES
Standard operation functions
Basic functions
Function
Parameter
Number
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
Rated
output
current
Display
functions
Second functions
Output
terminal
functions
39
Name
Read
Torque boost
Maximum frequency
Minimum frequency
Base frequency
Multi-speed setting (high speed)
Multi-speed setting (middle speed)
Multi-speed setting (low speed)
Acceleration time
Deceleration time
Electronic thermal O/L relay
DC injection brake operation frequency
DC injection brake operation time
DC injection brake voltage
Starting frequency
Load pattern selection
Jog frequency
Jog acceleration/deceleration time
MRS input selection
Base frequency voltage
Acceleration/deceleration reference frequency
Acceleration/deceleration time increments
Stall prevention operation level
Stall prevention operation level at double
speed
Multi-speed setting (speed 4)
Multi-speed setting (speed 5)
Multi-speed setting (speed 6)
Multi-speed setting (speed 7)
Multi-speed input compensation
Acceleration/deceleration pattern
Regenerative function selection
Frequency jump 1A
Frequency jump 1B
Frequency jump 2A
Frequency jump 2B
Frequency jump 3A
Frequency jump 3B
Speed display
Automatic torque boost
Automatic torque boost operation starting
current
00
01
02
03
04
05
06
07
08
09
0A
0B
0C
0D
0E
0F
10
11
13
14
15
16
Data Codes
Link Parameter Extension
Write
Setting (Data code 7F/FF)
80
0
81
0
82
0
83
0
84
0
85
0
86
0
87
0
88
0
89
0
8A
0
8B
0
8C
0
8D
0
8E
0
8F
0
90
0
91
0
93
0
94
0
95
0
96
0
17
97
0
18
19
1A
1B
1C
1D
1E
1F
20
21
22
23
24
25
26
98
99
9A
9B
9C
9D
9E
9F
A0
A1
A2
A3
A4
A5
A6
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
27
A7
0
41
Up-to-frequency sensitivity
29
A9
0
42
Output frequency detection
2A
AA
0
43
Output frequency detection for reverse rotation
2B
AB
0
44
45
46
47
48
49
50
52
53
54
55
56
Second acceleration/deceleration time
Second deceleration time
Second torque boost
Second V/F (base frequency)
Second stall prevention operation current
Second stall prevention operation frequency
Second output frequency detection
DU/PU main display data selection
PU level display data selection
FM terminal function selection
Frequency monitoring reference
Current monitoring reference
2C
2D
2E
2F
30
31
32
34
35
36
37
38
AC
AD
AE
AF
B0
B1
B2
B4
B5
B6
B7
B8
0
0
0
0
0
0
0
0
0
0
0
0
57
Restart coasting time
39
B9
0
58
Restart cushion time
3A
BA
0
183
APPENDICES
59
Remote setting function selection
3B
BB
0
60
61
62
63
65
Intelligent mode selection
Reference current
Reference current for acceleration
Reference current for deceleration
Retry selection
Stall prevention operation level reduction
starting frequency
Number of retries at alarm occurrence
Retry waiting time
Retry count display erasure
Applied motor
PWM frequency selection
0-5V/0-10V selection
Filter time constant
Reset selection/disconnected PU detection/PU
stop selection
Alarm code output selection
Parameter write disable selection
Reverse rotation prevention selection
Operation mode selection
V/F1 (first frequency)
V/F1 (first frequency voltage)
V/F2 (second frequency)
V/F2 (second frequency voltage)
V/F3 (third frequency)
V/F3 (third frequency voltage)
V/F4 (fourth frequency)
V/F4 (fourth frequency voltage)
V/F5 (fifth frequency)
V/F5 (fifth frequency voltage)
3C
3D
3E
3F
41
BC
BD
BE
BF
C1
0
0
0
0
0
42
C2
0
43
44
45
47
48
49
4A
C3
C4
C5
C7
C8
C9
CA
0
0
0
0
0
0
0
4B
CB
0
4C
4D
4E
4F
00
01
02
03
04
05
06
07
08
09
CC
None
CE
None
80
81
82
83
84
85
86
87
88
89
0
0
0
0
1
1
1
1
1
1
1
1
1
1
5-point flexible V/F
characteristics
Operation selection functions
Parameter
Number
Additional
function
Data Codes
Link Parameter Extension
Write
Setting (Data code 7F/FF)
Function
66
67
68
69
71
72
73
74
75
76
77
78
79
100
101
102
103
104
105
106
107
108
109
Name
Read
184
APPENDICES
Write
11
12
13
14
15
16
17
18
1C
1D
1E
1F
20
21
22
None
None
None
None
None
None
None
None
9C
9D
9E
9F
A0
A1
A2
23
A3
1
24
25
A4
A5
1
1
26
A6
1
27
A7
1
140
Station number
Communication speed
Stop bit length/data length
Parity check presence/absence
Number of communication retries
Communication check time interval
Waiting time setting
CR, LF presence/absence selection
PID action selection
PID proportional band
PID integral time
Upper limit
Lower limit
PID action set point for PU operation
PID differential time
Commercial power supply-inverter switch-over
sequence output terminal selection
MC switch-over interlock time
Start waiting time
Commercial power supply-inverter switch-over
selection at alarm occurrence
Automatic inverter-commercial power supply
switch-over frequency
Backlash acceleration stopping frequency
28
A8
1
141
Backlash acceleration stopping time
29
A9
1
142
Backlash deceleration stopping frequency
2A
AA
1
143
Backlash deceleration stopping time
2B
AB
1
144
Speed setting switch-over
2C
AC
1
145
Parameter unit language switch-over
2D
AD
1
148
Stall prevention level at 0V input
30
B0
1
149
Stall prevention level at 10V input
31
B1
1
152
Zero current detection level
34
B4
1
153
Zero current detection period
35
B5
1
154
117
118
119
120
121
122
123
124
128
129
130
131
132
133
134
135
136
137
138
B6
1
37
38
39
3A
B7
B8
B9
BA
1
1
1
1
160
User group read selection
00
80
2
162
Automatic restart after instantaneous power
failure selection
02
82
2
163
First cushion time for restart
03
83
2
164
First cushion voltage for restart
04
84
2
165
Restart stall prevention operation level
05
85
2
170
Watt-hour meter clear
0A
8A
2
171
Actual operation hour meter clear
0B
8B
2
Additional
function
36
155
156
157
158
Voltage reduction selection during stall
prevention operation
RT activated condition
Stall prevention operation selection
OL signal waiting time
AM terminal function selection
Restart after
instantaneous
power failure
139
Initial
monitor
Backlash
Commercial power
supply-inverter
switch-over
PID control
Communication
functions
Read
Display
Data Codes
Link Parameter Extension
Setting (Data code 7F/FF)
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Additional
functions
Name
Current
detection
Parameter
Number
Sub functions
Function
185
APPENDICES
Analog output, digital output
12-bit digital input
Sub
Additional
function function
Terminal assignment functions
User
functions
Function
Parameter
Number
Name
Read
Data Codes
Link Parameter Extension
Write
Setting (Data code 7F/FF)
8D
2
8E
2
8F
2
90
2
94
2
95
2
96
2
97
2
98
2
99
2
9A
2
9E
2
9F
2
A0
2
A1
2
A2
2
A3
2
173
174
175
176
180
181
182
183
184
185
186
190
191
192
193
194
195
User group 1 registration
User group 1 deletion
User group 2 registration
User group 2 deletion
RL terminal function selection
RM terminal function selection
RH terminal function selection
RT terminal function selection
AU terminal function selection
JOG terminal function selection
CS terminal function selection
RUN terminal function selection
SU terminal function selection
IPF terminal function selection
OL terminal function selection
FU terminal function selection
ABC terminal function selection
0D
0E
0F
10
14
15
16
17
18
19
1A
1E
1F
20
21
22
23
199
User's initial value setting
27
A7
2
240
Soft-PWM setting
30
B0
2
244
Cooling fan operation selection
34
B4
2
300
301
302
303
00
01
02
03
80
81
82
83
3
3
3
3
04
84
3
305
BCD code input bias
BCD code input gain
Binary input bias
Binary input gain
Selection of whether digital input and analog
compensation input are enabled or disabled
Data read timing signal on/off selection
05
85
3
306
Analog output signal selection
06
86
3
307
Setting for zero analog output
07
87
3
308
Setting for maximum analog output
08
88
3
309
Analog output signal voltage/current switchover
09
89
3
310
Analog meter voltage output selection
0A
8A
3
311
Setting for zero analog meter voltage output
0B
8B
3
312
Setting for maximum analog meter voltage
output
0C
8C
3
313
Y0 output selection
0D
8D
3
314
Y1 output selection
0E
8E
3
315
Y2 output selection
0F
8F
3
316
Y3 output selection
10
90
3
317
Y4 output selection
11
91
3
318
Y5 output selection
12
92
3
319
Y6 output selection
13
93
3
304
186
APPENDICES
Parameter
Number
14
321
RA2 output selection
15
95
3
322
330
331
332
333
334
335
336
337
338
339
340
341
342
RA3 output selection
RA output selection
Inverter station number
Communication speed
Stop bit length
Parity check yes/no
Communication retry count
Communication check time interval
Waiting time setting
Operation command write
Speed command write
Link start mode selection
CR, LF yes/no selection
E2PROM write yes/no
16
1E
1F
20
21
22
23
24
25
26
27
28
29
2A
96
9E
9F
A0
A1
A2
A3
A4
A5
A6
A7
A8
A9
AA
3
3
3
3
3
3
3
3
3
3
3
3
3
3
571
Start holding time
47
C7
5
900
901
902
903
904
905
990

FM terminal calibration
AM terminal calibration
Frequency setting voltage bias
Frequency setting voltage gain
Frequency setting current bias
Frequency setting current gain
Buzzer control
Second parameter switch-over
5C
5D
5E
5F
60
61
5A
6C
DC
DD
DE
DF
E0
E1
DA
EC
1
1
1
1
1
1
9

Running frequency (RAM)
6D
ED

Running frequency (E2PROM)
6E
EE

Frequency monitor
Output current monitor
Output voltage monitor
Special monitor
Special monitor selection No.
Most recent No. 1, No. 2/alarm display
clear
Most recent No. 3, No. 4
Most recent No. 5, No. 6
Most recent No. 7, No. 8
Inverter status monitor/run command
Operation mode acquisition
All clear
Inverter reset
Link parameter extension setting
6F
70
71
72
73




F3





74
F4

75
76
77
7A
7B


7F



FA
FB
FC
FD
FF























Monitor
RA1 output selection
Frequency
setting
Read
Data Codes
Link Parameter Extension
Write
Setting (Data code 7F/FF)
94
3
320

Calibration functions
Name
Alarm display
sub
function
Computer link function
Relay
output
Function
187
Appendix 2
Inverter Heat Loss
APPENDICES
(1) Inverter Loss and DC reactor loss
Table 1 Inverter Loss and DC reactor loss at 100% load
Voltage (V)
Inverter Type
VT/LVT
200V series
FR-F520L-75K
FR-F520L-90K
FR-F520L-110K
―
―
―
VT
LVT
VT
LVT
VT
LVT
VT
LVT
VT
LVT
VT
LVT
VT
LVT
VT
LVT
VT
LVT
FR-F540L-75K
FR-F540L-90K
FR-F540L-110K
FR-F540L-132K
400V series
FR-F540L-160K
FR-F540L-185K
FR-F540L-220K
FR-F540L-280K
FR-F540L-375K
Rated current
(A)
―
―
―
144
144
180
180
216
260
260
302
302
360
360
432
432
477
547
610
722
750
Motor Capacity
(kW)
75
90
110
75
75
90
90
110
132
132
160
160
185
185
220
220
250
280
315
375
400
Inverter Loss
(W)
2,250
2,750
3,375
2,250
2,250
2,750
2,750
3,375
4,120
4,120
4,800
4,800
5,550
5,550
6,750
6,750
7,500
8,590
9,450
11,250
12,000
DC reactor Loss
(W)
176
176
202
133
133
146
146
166
192
192
202
202
214
214
253
253
260
276
312
372
396
(2) Inverter Loss
Inverter Loss are shown in Table 1 at 100% Load.
Motor Load(%) vs. Inverter Loss is shown in Fig.1.
You can use this curve under 100% load.
100
75
Loss (%)
50
25
0
20
40
60
80
100
Motor load (%)
Fig.1 Motor Load(%) vs. Inverter Loss Curve
(3) Option Mounting fixture Housing data
On panel design we can greatly decrease the amount of heat generated inside a panel in which an inverter is
installed by making sure the inverter’s heat dissipation fins go outside of the panel.
Table 2 Inverter Loss with Option Mounting Fixture (100% load)
Voltage (V)
Motor Capacity (kW)
Inverter Type
Panel Inside (W)
Panel Outside (W)
200V series
75
90
110
FR-F520L-75K
FR-F520L-90K
FR-F520L-110K
750
920
1,125
1,500
1,830
2,250
Voltage (V)
400V series
Motor Capacity (kW)
VT(kW)
LVT(kW)
75
90
110
132
160
185
220
280
375
75
90
132
160
185
220
250
315
400
Inverter Type
FR-F540L-75K
FR-F540L-90K
FR-F540L-110K
FR-F540L-132K
FR-F540L-160K
FR-F540L-185K
FR-F540L-220K
FR-F540L-280K
FR-F540L-375K
VT (Variable Torque) Load
LVT (Light Variable Torque) Load
Panel Inside (W)
Panel Outside (W)
Panel Inside (W)
Panel Outside (W)
750
920
1,125
1,370
1,600
1,850
2,250
2,860
3,750
1,500
1,830
2,250
2,750
3,200
3,650
4,500
5,730
7,500
750
920
1,370
1,600
1,850
2,250
2,500
3,150
4,000
1,500
1,830
2,750
3,200
3,650
4,500
5,000
6,300
8,000
188
MITSUBISHI ELECTRIC
HEADQUARTERS
EUROPEAN REPRESENTATIVES
EUROPEAN REPRESENTATIVES
EURASIAN REPRESENTATIVES
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EUROPE
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Phone: +49 (0)2102 486-0
Fax: +49 (0)2102 486-1120
e mail: [email protected]
MITSUBISHI ELECTRIC
FRANCE
EUROPE B.V.
French Branch
25, Boulevard des Bouvets
F-92741 Nanterre Cedex
Phone: +33 1 55 68 55 68
Fax: +33 1 55 68 56 85
e mail: [email protected]
MITSUBISHI ELECTRIC
IRELAND
EUROPE B.V.
Irish Branch
Westgate Business Park, Ballymount
IRL-Dublin 24
Phone: +353 (0) 1 / 419 88 00
Fax: +353 (0) 1 / 419 88 90
e mail: [email protected]
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Phone: +39 039 60 53 1
Fax: +39 039 60 53 312
e mail: [email protected]
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EUROPE B.V.
UK Branch
Travellers Lane
GB-Hatfield Herts. AL10 8 XB
Phone: +44 (0) 1707 / 27 61 00
Fax: +44 (0) 1707 / 27 86 95
e mail: [email protected]
MITSUBISHI ELECTRIC
JAPAN
CORPORATION
Office Tower “Z” 14 F
8-12,1 chome, Harumi Chuo-Ku
Tokyo 104-6212
Phone: +81 3 622 160 60
Fax: +81 3 622 160 75
MITSUBISHI ELECTRIC
USA
AUTOMATION
500 Corporate Woods Parkway
Vernon Hills, IL 60061
Phone: +1 847 478 21 00
Fax: +1 847 478 22 83
GEVA
AUSTRIA
Wiener Straße 89
AT-2500 Baden
Phone: +43 (0)2252 / 85 55 20
Fax: +43 (0)2252 / 488 60
e mail: [email protected]
TEHNIKON
BELARUS
Oktjabrskaya 16/5, Ap 704
BY-220030 Minsk
Phone: +375 (0)17 / 2104626
Fax: +375 (0)17 / 2275830
e mail: [email protected]
Getronics b.v.
BELGIUM
Control Systems
Pontbeeklaan 43
BE-1731 Asse-Zellik
Phone: +32 (0)2 / 467 17 51
Fax: +32 (0)2 / 467 17 45
e mail: [email protected]
TELECON CO.
BULGARIA
4, A. Ljapchev Blvd.
BG-1756 Sofia
Phone: +359 (0)2 / 97 44 058
Fax: +359 (0)2 / 97 44 061
e mail: —
INEA CR d.o.o.
CROATIA
Losinjska 4 a
HR-10000 Zagreb
Phone: +385 (0) 1 / 36 940-01
Fax: +385 (0) 1 / 36 940-03
e mail: [email protected]
AutoCont
CZECH REPUBLIC
Control Systems s.r.o.
Nemocnicni 12
CZ-70200 Ostrava 2
Phone: +420 59 / 6152 111
Fax: +420 59 / 6152 562
e mail: [email protected]
louis poulsen
DENMARK
industri & automation
Geminivej 32
DK-2670 Greve
Phone: +45 (0)43 / 95 95 95
Fax: +45 (0)43 / 95 95 91
e mail: [email protected]
UTU Elektrotehnika AS
ESTONIA
Pärnu mnt.160i
EE-10621 Tallinn
Phone: +372 (0)6 / 51 72 80
Fax: +372 (0)6 / 51 72 88
e mail: [email protected]
UTU POWEL OY
FINLAND
Box 236
FIN-28101 Pori
Phone: +358 (0)2 / 550 800
Fax: +358 (0)2 / 550 8841
e mail: [email protected]
UTECO A.B.E.E.
GREECE
5, Mavrogenous Str.
GR-18542 Piraeus
Phone: +302 (0)10 / 42 10 050
Fax: +302 (0)10 / 42 12 033
e mail: [email protected]
Meltrade Automatika Kft. HUNGARY
55, Harmat St.
HU-1105 Budapest
Phone: +36 (0)1 / 2605 602
Fax: +36 (0)1 / 2605 602
e mail: [email protected]
SIA POWEL
LATVIA
Lienes iela 28
LV-1009 Riga
Phone: +371 784 2280
Fax: +371 784 2281
e mail: [email protected]
UAB UTU POWEL
LITHUANIA
Savanoriu Pr. 187
LT-2053 Vilnius
Phone: +370 (0)52323-101
Fax: +370 (0)52322-980
e mail: [email protected]
Intehsis Srl
MOLDOVA
Cuza-Voda 36/1-81
MD-2061 Chisinau
Phone: +373 (0)2 / 562 263
Fax: +373 (0)2 / 562 263
e mail: [email protected]
Getronics b.v.
NETHERLANDS
Control Systems
Donauweg 2 B
NL-1043 AJ Amsterdam
Phone: +31 (0)20 / 587 6700
Fax: +31 (0)20 / 587 6839
e mail: [email protected]
Motion Control
NETHERLANDS
Automation b.v.
Markenweg 5
NL-7051 HS Varsseveld
Phone: +31 (0)315 / 257 260
Fax: +31 (0)315 / 257 269
e mail: —
Beijer Electronics AS
NORWAY
Teglverksveien 1
NO-3002 Drammen
Phone: +47 (0)32 / 24 30 00
Fax: +47 (0)32 / 84 85 77
e mail: [email protected]
MPL Technology Sp. z o.o. POLAND
ul. Sliczna 36
PL-31-444 Kraków
Phone: +48 (0)12 / 632 28 85
Fax: +48 (0)12 / 632 47 82
e mail: [email protected]
Sirius Trading & Services srl ROMANIA
Str. Biharia Nr. 67-77
RO-013981 Bucuresti 1
Phone: +40 (0) 21 / 201 1146
Fax: +40 (0) 21 / 201 1148
e mail: [email protected]
INEA SR d.o.o.
SERBIAANDMONTENEGRO
Karadjordjeva 12/260
SCG-113000 Smederevo
Phone: +381 (0)26/ 617 - 163
Fax: +381 (0)26/ 617 - 163
e mail: [email protected]
ACP Autocomp a.s.
SLOVAKIA
Chalupkova 7
SK-81109 Bratislava
Phone: +421 (02)5292-2254
Fax: +421 (02)5292-2248
e mail: [email protected]
INEA d.o.o.
SLOVENIA
Stegne 11
SI-1000 Ljubljana
Phone: +386 (0)1 513 8100
Fax: +386 (0)1 513 8170
e mail: [email protected]
Beijer Electronics AB
SWEDEN
Box 426
S-20124 Malmö
Phone: +46 (0)40 / 35 86 00
Fax: +46 (0)40 / 35 86 02
e mail: [email protected]
ECONOTEC AG
SWITZERLAND
Postfach 282
CH-8309 Nürensdorf
Phone: +41 (0)1 / 838 48 11
Fax: +41 (0)1 / 838 48 12
e mail: [email protected]
GTS
TURKEY
Darülaceze Cad. No. 43A KAT: 2
TR-80270 Okmeydani-Istanbul
Phone: +90 (0)212 / 320 1640
Fax: +90 (0)212 / 320 1649
e mail: [email protected]
CSC Automation
UKRAINE
15, M. Raskova St., Fl. 10, Off. 1010
UA-02002 Kiev
Phone: +380 (0)44 / 238 83 16
Fax: +380 (0)44 / 238 83 17
e mail: [email protected]
Avtomatika Sever Ltd.
RUSSIA
Lva Tolstogo St. 7, Off. 311
RU-197376 St Petersburg
Phone: +7 812 / 11 83 238
Fax: +7 812 / 11 83 239
e mail: [email protected]
CONSYS
RUSSIA
Promyshlennaya St. 42
RU-198099 St Petersburg
Phone: +7 812 / 325 36 53
Fax: +7 812 / 325 36 53
e mail: [email protected]
ELEKTROSTYLE
RUSSIA
Poslannikov Per., 9, Str.1
RU-107005 Moscow
Phone: +7 095 / 542-4323
Fax: +7 095 / 956-7526
e mail: [email protected]
ELEKTROSTYLE
RUSSIA
Krasnij Prospekt 220-1, Office 312
RU-630049 Novosibirsk
Phone: +7 3832 / 10 66 18
Fax: +7 3832 / 10 66 26
e mail: [email protected]
ICOS
RUSSIA
Ryazanskij Prospekt, 8A, Office 100
RU-109428 Moscow
Phone: +7 095 / 232 0207
Fax: +7 095 / 232 0327
e mail: [email protected]
SMENA
RUSSIA
Polzunova 7
RU-630051 Novosibirsk
Phone: +7 095 / 416 4321
Fax: +7 095 / 416 4321
e mail: [email protected]
STC Drive Technique
RUSSIA
Poslannikov per., 9, str.1
RU-107005 Moscow
Phone: +7 095 / 786 21 00
Fax: +7 095 / 786 21 01
e mail: [email protected]
MITSUBISHI ELECTRIC
MIDDLE EAST REPRESENTATIVE
SHERF Motion Techn. Ltd
ISRAEL
Rehov Hamerkava 19
IL-58851 Holon
Phone: +972 (0)3 / 559 54 62
Fax: +972 (0)3 / 556 01 82
e mail: —
AFRICAN REPRESENTATIVE
INDUSTRIAL AUTOMATION
Gothaer Strasse 8 Phone: +49 2102 486-0
Fax:
+49 2102 486-717 www.mitsubishi-automation.de
D-40880 Ratingen Hotline: +49 2102 1805 000-765 [email protected] www.mitsubishi-automation.com
INV 12.04 - Printed in Germany
CBI Ltd
SOUTH AFRICA
Private Bag 2016
ZA-1600 Isando
Phone: +27 (0)11 / 928 2000
Fax: +27 (0)11 / 392 2354
e mail: [email protected]

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