Page 1 MITSUBISHI ELECTRIC FR-D700 Frequency Inverter Instruction Manual FR-D720S SC EC FR-D740 SC EC Art. No: 260451 INDUSTRIAL AUTOMATION 14 02 2013 MITSUBISHI ELECTRIC Version A Version check...
Page 3 Instruction Manual Inverter FR-D700 SC EC Art. no.: 260451 Version Changes / Additions / Corrections 02/2013 —...
Page 5 Thank you for choosing this Mitsubishi inverter. This instruction manual provides instructions for advanced use of the FR-D700 SC series in- verters. Incorrect handling might cause an unexpected fault. Before using the inverter, always read this instruction manual to use the equipment to its optimum. Safety instructions Do not attempt to install, operate, maintain or inspect the inverter until you have read through this instruction manual carefully and can use the equipment correctly.
Page 6 Electric shock prevention WARNING: ● While power is on or when the inverter is running, do not open the front cover. Otherwise you may get an electric shock. ● Do not run the inverter with the front cover removed. Otherwise, you may access the exposed high-voltage terminals or the charging part of the circuitry and get an electric shock.
Page 7 Fire prevention CAUTION: ● Mount the inverter to incombustible material. Install the inverter on a nonflammable wall without holes (so that nobody can touch the inverter heatsink on the rear side, etc.). Mounting it to or near combustible material can cause a fire. ●...
Page 8 Additional instructions Also note the following points to prevent an accidental failure, injury, electric shock, etc. Transport and installation CAUTION: ● Transport the product using the correct method that corresponds to the weight. Failure to observe this could lead to injuries. ●...
Page 9 Trial run CAUTION: ● Before starting operation, confirm and adjust the parameters. A failure to do so may cause some machines to make unexpected motions. Operation WARNING: ● When you have chosen the retry function, stay away from the equipment as it will restart suddenly after an alarm stop.
Page 10 CAUTION: ● The electronic thermal relay function does not guarantee protection of the motor from overheating. It is recommended to install both an external thermal and PTC thermistor for overheat protection. ● Do not use a magnetic contactor on the inverter input for frequent starting/stopping of the inverter.
Page 11 Disposing the inverter CAUTION: ● Treat as industrial waste. General instructions Many of the diagrams and drawings in instruction manuals show the inverter without a cover, or partially open. Never run the inverter in this status. Always replace the cover and follow this in- struction manual when operating the inverter.
Page 12 Typographic conventions Use of notes Notes containing important information are clearly identified as follows: NOTE Note text Use of examples Examples containing important information are clearly identified as follows: Example Example text Numbering in figures and illustrations Reference numbers in figures and illustrations are shown with white numbers in a black circle and the corresponding explanations shown beneath the illustrations are identified with the same numbers, like this: Procedures...
Page 13: Table Of Contents
Contents Contents Product checking and part identification Inverter type ........... .1-1 Description of the case .
Page 14 Contents PU connector ..........3-30 3.5.1 Connecting the parameter unit .
Page 15 Contents Basic settings Simple mode parameter list ........5-1 5.1.1 Overheat protection of the motor by the inverter.
Page 16 Contents Parameter Parameter overview ..........6-1 Adjust the output torque (current) of the motor.
Page 17 Contents Function assignment of external terminals ......6-88 6.9.1 Input terminal function selection (Pr. 178 to Pr. 182) ... . .6-88 6.9.2 Inverter output shutoff signal (MRS signal, Pr.
Page 18 Contents 6.16 Misoperation prevention and parameter setting restriction....6-160 6.16.1 Reset selection/disconnected PU detection/PU stop selection (Pr. 75) ..........6-160 6.16.2 Parameter write selection (Pr.
Page 19 Contents 6.21 Setting for the parameter unit and operation panel ....6-282 6.21.1 RUN key rotation direction selection (Pr. 40) ....6-282 6.21.2 PU display language selection (Pr.
Page 20 Contents Maintenance and inspection Inspection ............8-1 8.1.1 Daily inspection .
Page 21: Inverter Type
Product checking and part identification Inverter type Product checking and part identification Unpack the inverter and check the capacity plate on the front cover and the rating plate on the inverter side face to ensure that the product agrees with your order and the inverter is intact. Inverter type FR - D740 - 036 SC - EC Symbol...
Page 22: Description Of The Case
Description of the case Product checking and part identification Description of the case Operation panel (refer to section 4.3) Cooling fan (refer to section 8.1.7) Voltage/current input switch (refer to section 3.4) PU connector (refer to section 3.5) Front cover Control circuit terminal block (refer to section 3.4)
Page 23: Accessory
Product checking and part identification Description of the case 1.2.1 Accessory Fan cover fixing screws Capacity Screw Size [mm] Number M3 × 35 FR-D720S-070SC and 100SC M3 × 35 FR-D740-036SC to 080SC M3 × 35 FR-D740-120SC and 160SC Tab. 1-1: Fan cover fixing screws NOTES Inverters FR-D720S-008SC to 042SC and FR-D740-022SC or less are not provided with the cooling fan.
Page 24 Description of the case Product checking and part identification 1 - 4...
Page 25: Removal And Reinstallation Of The Front Cover
Installation Removal and reinstallation of the front cover Installation Removal and reinstallation of the front cover 2.1.1 FR-D720S-008SC to 100SC and FR-D740-012SC to 080SC Removal of the front cover Loosen the installation screw of the front cover. (This screw cannot be removed.) Remove the front cover by pulling it like the direction of arrow.
Page 26: Fr-D740-120Sc And Fr-D740-160Sc
Removal and reinstallation of the front cover Installation 2.1.2 FR-D740-120SC and FR-D740-160SC Removal of the front cover Loosen the installation screws of the front cover. (The screws cannot be removed.) Remove the front cover by pulling it like the direction of arrow with holding the installation hook on the front cover.
Page 27 Installation Removal and reinstallation of the front cover Reinstallation of the front cover Insert the two fixed hooks on the lower side of the front cover into the sockets of the inverter. Then press the cover against the device until it correctly locks on. Tighten the installation screws.
Page 28: Removal And Reinstallation Of The Wiring Cover
Removal and reinstallation of the wiring cover Installation Removal and reinstallation of the wiring cover The cover can be removed easily by pulling it downward (FR-D720S-008SC to 100SC and FR-D740-012SC to 080SC) or toward you (FR-D740-120SC and 160SC). To reinstall, fit the cover to the inverter along the guides. Inverter FR-D720S-008SC to 100SC and FR-D740-012SC to 080SC Alternatively pull the wiring cover downward by Hold the side of the wiring cover, and pull it...
Page 29: Mounting
Installation Mounting Mounting NOTE Install the inverter vertically. Do not mount it horizontally or any other way. Remove the front cover and wiring cover to fix the inverter to the surface. FR-D720S-008SC to 042SC FR-D720S-070SC and 100SC, FR-D740-012SC to 160SC Front cover Front cover Wiring cover...
Page 30 Mounting Installation The inverter consists of precision mechanical and electronic parts. Never install or handle it in any of the following conditions as doing so could cause an operation fault or failure. Direct sunlight Vibration (≥ 5,9 m/s²) High temperature, high humidity Horizontal placement (When mounted Transportation by holding...
Page 31: Enclosure Design
Installation Enclosure design Enclosure design When an inverter enclosure is to be designed and manufactured, heat generated by contained equipment, etc., the environment of an operating place, and others must be fully considered to determine the enclosure structure, size and equipment layout. The inverter unit uses many semiconductor devices.
Page 32 Enclosure design Installation Humidity Normally operate the inverter within the 45% to 90% range of the ambient humidity. Too high hu- midity will pose problems of reduced insulation and metal corrosion. On the other hand, too low humidity may produce a spatial electrical breakdown. The insulation distance specified in JEM1103 "Control Equipment Insulator"...
Page 33 Installation Enclosure design Explosive, flammable gases As the inverter is non-explosion proof, it must be contained in an explosion proof enclosure. In places where explosion may be caused by explosive gas, dust or dirt, an enclosure cannot be used unless it structurally complies with the guidelines and has passed the specified tests. This makes the enclosure itself expensive (including the test charges).
Page 34 Enclosure design Installation Cooling system types for inverter enclosure From the enclosure that contains the inverter, the heat of the inverter and other equipment (transformers, lamps, resistors, etc.) and the incoming heat such as direct sunlight must be dis- sipated to keep the in-enclosure temperature lower than the permissible temperatures of the in- enclosure equipment including the inverter.
Page 35: Inverter Placement
Installation Enclosure design 2.4.2 Inverter placement Clearances around the inverter Always observe the specified minimum clearances to ensure good heat dissipation and ade- quate accessibility of the frequency inverter for servicing. Ambient temperature and humidity Clearances (side) Clearances (front) x = Measurement position ≥...
Page 36 Enclosure design Installation Arrangement of multiple inverters When multiple inverters are placed in the same enclosure, generally arrange them horizontally as shown in the figure (a). When it is inevitable to arrange them vertically to minimize space, take such measures as to provide guides since heat from the bottom inverters can increase the tem- peratures in the top inverters, causing inverter failures.
Page 37: Inverter And Peripheral Devices
Wiring Inverter and peripheral devices Wiring Inverter and peripheral devices 3-phase AC power supply Use within the permissible power supply specifications of the invert- Parameter unit er. To ensure safety, use a moulded (FR-PA07) case circuit breaker, earth leakage RS232C/RS485 converter is By connecting the circuit breaker or magnetic contac- required when connecting to...
Page 38 Inverter and peripheral devices Wiring NOTES The life of the inverter is influenced by surrounding air temperature. The surrounding air temperature should be as low as possible within the permissible range. This must be noted especially when the inverter is installed in an enclosure (refer to section 2.4.2). Wrong wiring might lead to damage of the inverter.
Page 39: Peripheral Devices
Wiring Inverter and peripheral devices 3.1.1 Peripheral devices Check the motor capacity of the inverter you purchased. Appropriate peripheral devices must be selected according to the capacity. Refer to the following list and prepare appropriate peripheral devices: Input Side Magnetic Breaker Selection Contactor Motor Output...
Page 40: Terminal Connection Diagram
Terminal connection diagram Wiring Terminal connection diagram Source Logic *1 DC reactor When connecting a DC reactor, remove the *6 FR-D720S-008SC to 100SC: +, – Main circuit terminal jumper across P1 and P/+. FR-D740-012SC to 160SC: P/+, N/– Control circuit terminal Single-phase power input *7 A brake transistor is not built-in to the Brake unit...
Page 41 Wiring Terminal connection diagram NOTES To prevent a malfunction due to noise, keep the signal cables more than 10cm away from the power cables. Also separate the main circuit wire of the input side and the output side. After wiring, wire offcuts must not be left in the inverter. Wire offcuts can cause an alarm, failure or malfunction.
Page 42: Main Circuit Connection
Main circuit connection Wiring Main circuit connection 3.3.1 Specification of main circuit terminal Terminal Name Description R/L1, AC power input Connect to the commercial power supply. S/L2, Keep these terminals open when using the high power factor converter T/L3 (FR-HC) or power regeneration common converter (FR-CV). U, V, W Inverter output Voltage ouput of the inverter...
Page 43 Wiring Main circuit connection Three-phase, 400V class FR-D740-012SC to 080SC FR-D740-120SC and 160SC Jumper Jumper N/- P/+ Screw size (M4) Screw size (M4) Screw size (M4) L1L2 L3 Screw size (M4) Motor L1L2 L3 Power supply Motor Power supply I002035E I002034E Tab.
Page 44 Main circuit connection Wiring Cables and wiring length Select the recommended cable size to ensure that a voltage drop will be 2% max. If the wiring distance is long between the inverter and motor, a main circuit cable voltage drop will cause the motor torque to decrease especially at the output of a low frequency.
Page 45 Wiring Main circuit connection CAUTION: ● Tighten the terminal screw to the specified torque. A screw that has been tightened too loosely can cause a short circuit or malfunction. A screw that has been tightened too tightly can cause a short circuit or malfunction due to the unit breakage.
Page 46 Main circuit connection Wiring Notes on earthing CAUTION: Leakage currents flow in the inverter or the EMC filter respectively. To prevent an electric shock, the inverter, input filter and motor must be earthed. This inverter must be earthed. Earthing must conform to the requirements of national and local safety regulations and electrical codes (JIS, NEC section 250, IEC 536 class 1 and other applicable standards).
Page 47 Wiring Main circuit connection Total wiring length The maximum possible length of the motor cables depends on the capacity of the inverter and the selected carrier frequency. The lengths in the following tables are for unshielded cables. When shielded cables are use di- vide the values listed in the table by 2.
Page 48 Main circuit connection Wiring NOTES Note that the motor windings are subjected to significantly higher loads when the motor is operated by inverter than with normal mains operation. The motors must be approved for inverter operation by the manufacturer (refer also to section 3.7.4). Especially for long-distance wiring, the inverter may be affected by a charging current caused by the stray capacitances of the wiring, leading to a malfunction of the overcurrent protective function, fast response current limit function, or stall prevention function or a mal-...
Page 49: Control Circuit Specifications
Wiring Control circuit specifications Control circuit specifications The functions of the terminals highlighted in grey can be adjusted with parameters 178 to 182 "Input terminal function assignment" and Pr. 190, Pr. 192 or Pr. 197 "Output terminal function as- signment" (refer to section 6.9). The listed settings show the default configuration as shipped, which you can restore by resetting to the factory defaults.
Page 50 Control circuit specifications Wiring Rated Refer to Terminal Name Description Specifications Page Used as power supply when connecting poten- tiometer for frequency setting (speed setting) 5.0V DC ± 0,2V, Frequency setting from outside of the inverter. Permissible (Output voltage power supply Rated output voltage: 5V DC load current 5V DC)
Page 51 Wiring Control circuit specifications Output signals Rated Refer to Terminal Name Description Specifications Page The alarm is output via relay contacts. The block diagram shows the normal operation and Contact voltage free status. If the protective function is capacity: activated, the relay picks up. Relay output 230V AC/0.3A A, B, C...
Page 52 Control circuit specifications Wiring Safety stop signal Refer to Terminal Name Description Specification Page Safety stop input Terminals S1 and S2 are for safety stop Input resistance: (Channel 1) input signals used with the safety relay 4.7kΩ module. Terminals S1 and S2 are used Current: 4–6 mA simultaneously (dual channel).
Page 53: Control Circuit Terminals
Wiring Control circuit specifications 3.4.1 Control circuit terminals Recommended cable size: 0.3 mm² to 0.75 mm² RUN SE S1 S2 SC STF STR I002183E Fig. 3-6: Terminal layout Connection to the terminals Use a wire end sleeve and a cable with a sheath stripped off for the control circuit wiring. For a single wire, strip off the sheath of the cable and apply directly.
Page 54 Control circuit specifications Wiring Check the condition of the wire end sleeve after crimping. Do not use a wire end sleeve of which the crimping is inappropriate, or the face is damaged. Unstranded wires Wires are not inserted Damaged into the shell Crumpled tip I001985E Fig.
Page 55 Wiring Control circuit specifications Insert the wire into a socket. Fig. 3-10: Cable connection I001986E When using a stranded wire without a wire end sleeve or a single wire, push a open/close button all the way down with a flathead screw driver, and insert the wire. Fig.
Page 56 Control circuit specifications Wiring Wire removal Pull the wire with pushing the open/close button all the way down firmly with a flathead screw- driver. Fig. 3-12: Wire removal Open/close button Flathead screwdriver I001988E CAUTION: ● Use a small flathead screwdriver (Tip thickness: 0.4mm/tip width: 2.5mm, such as SZF 0-0,4 x 2,5 of Phoenix Contact Co., Ltd.).
Page 57: Wiring Instructions
Wiring Control circuit specifications 3.4.2 Wiring instructions ● Use shielded or twisted cables for connection to the control circuit terminals and run them away from the main and power circuits (including the 230V relay sequence circuit). ● Use two or more parallel micro-signal contacts or twin contacts to prevent a contact faults when using contact inputs since the control circuit input signals are micro-currents.
Page 58: Safety Stop Function
Control circuit specifications Wiring 3.4.3 Safety stop function The terminals related to the safety stop function are shown below. For the rated specification of each terminal refer to Tab. 3-12. Terminal Description Between S1 and SC / S2 and SC For input of safety stop channel 1.
Page 59 Wiring Control circuit specifications Wiring connection diagram To prevent restart at fault occurrence, connect terminals RUN (SAFE2 signal) and SE to ter- minals XS0 and XS1, because polarity of XS0 is positive, and polarity of XS1 is negative. To prevent restart at fault occurrence, connect terminals RUN (SAFE2 signal) and SE to ter- minals XS0 and XS1, which are the feedback input terminals of the safety relay module.
Page 60 Control circuit specifications Wiring Safety stop function operation Input Signal Internal Output Signal Safety Input Power Operation State S1-SC S2-SC SAFE SAFE2 Circuit Output shutoff — — — (Safe state) No failure Drive enabled Short Short Output shutoff Detected (Safe state) Output shutoff No failure (Safe state)
Page 61 Wiring Control circuit specifications Safety stop when operating multiple frequency inverters in parallel Wiring of frequency inverters FR-D700 SC The safety stop function can be applied when using multiple FR-D740 SC and FR-D720S SC in- verters. Connect as shown in the diagram below. Details of the safety stop function are written on the "FR-D700 SC EC –...
Page 62 Control circuit specifications Wiring NOTES By setting Pr.190 RUN terminal function selection = "81 (SAFE2 signal)", terminal RUN is turned OFF at fault occurrence. Never connect the FR-D700 SC source-logic safety terminal models with FR-D700 sink- logic safety terminal models. When connected, the safety stop function does NOT operate. 3 - 26...
Page 63: Changing The Control Logic
Wiring Control circuit specifications 3.4.4 Changing the control logic FR-D700 SC frequency inverters offer the possibility of choosing between two types of control logic. Depending on the direction of the flowing current, one distinguishes between: ● In sink logic, a signal switches on when a current flows from the corresponding signal input terminal.
Page 64 Control circuit specifications Wiring NOTES Turn off the inverter power before switching a jumper connector. The sink-source logic change-over jumper 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. The capacity plate is placed on the front cover and the rating plate is on the inverter.
Page 65 Wiring Control circuit specifications Using an external power supply ● Sink logic type Use terminal PC as a common terminal to prevent a malfunction caused by undesirable current. Do not connect terminal SD of the inverter with terminal 0V of the external power supply.
Page 66: Pu Connector
PU connector Wiring PU connector Using the PU connector, you can perform communication operation from a parameter unit FR-PU07/FR-PA07 or a personal computer. Parameter setting and monitoring can be per- formed by FR Configurator. Remove the inverter front cover when connecting. Fig.
Page 67: Rs485 Communication
Wiring PU connector 3.5.2 RS485 communication When the PU connector is connected with a personal, FA or other computer by a communication cable, a user program can run and monitor the inverter or read and write to parameters. The protocol can be selected from Mitsubishi inverter and Modbus RTU. For detailed informa- tion refer to section 6.18.
Page 68: Connection Of Stand-Alone Option Units
Connection of stand-alone option units Wiring Connection of stand-alone option units The inverter accepts a variety of stand-alone option units as required. CAUTION: Incorrect connection will cause inverter damage or accident. Connect and operate the option unit carefully in accordance with the corresponding option unit manual. 3.6.1 Magnetic contactors (MC) Inverter input side magnetic contactor (MC)
Page 69 Wiring Connection of stand-alone option units Example As shown below, always use the start signal (ON or OFF across terminals STF or STR-PC) to make a start or stop. (Refer to section 6.9.4.) Inverter MCCB R/L1 Power To the S/L2 supply motor T/L3...
Page 70 Connection of stand-alone option units Wiring 3.6.2 Connection of a dedicated external brake resistor FR-ABR (FR-D720S-025SC or more, FR-D740-012SC or more) Install a dedicated brake resistor (FR-ABR) outside when the motor is made to run by the load, quick deceleration is required, etc. Connect a dedicated brake resistor (FR-ABR) to terminal P/+ and PR.
Page 71 Wiring Connection of stand-alone option units FR-D720S-070SC and 100SC and FR-D740-012SC to 080SC Fig. 3-25: Jumper Connection of a brake resistor to the terminals P/+ and PR for the inverters FR-D720S- 070SC and 100SC and FR-D740-012SC to FR-D740-080SC Terminal P/+ Terminal PR Brake resistor I001923E...
Page 72 Connection of stand-alone option units Wiring It is recommended to configure a sequence, which shuts off power in the input side of the in- verter by the external thermal relay as shown below, to prevent overheat and burnout of the high duty brake resistor in case the regenerative brake transistor is damaged.
Page 73: Connection Of A Brake Unit Fr-Bu2
Wiring Connection of stand-alone option units 3.6.3 Connection of a brake unit FR-BU2 When connecting a brake unit to improve the brake capability at deceleration, make connection as shown below. Connection example with the GRZG type discharging resistor OCR- contact GRZG type Inverter discharging resistor...
Page 74 Connection of stand-alone option units Wiring CAUTION: ● If the transistors in the brake unit should become faulty, the resistor can be unusually hot, causing a fire. Therefore, install a magnetic contactor on the inverters input side to configure a circuit so that a current is shut off in case of fault.
Page 75 Wiring Connection of stand-alone option units Connection example with the FR-BR(-H) type resistor Inverter Motor 3-phase AC power supply ≤ 5m 002045E Fig. 3-31: Connection with the brake unit FR-BU2 If the control contacts are only specified for 230V control power you must install a transformer when using a 400V power supply.
Page 76: Connection Of The High Power Factor Converter Fr-Hc
Connection of stand-alone option units Wiring 3.6.4 Connection of the high power factor converter FR-HC When connecting the high power factor converter (FR-HC) to suppress power harmonics, per- form wiring securely as shown below. CAUTION: Perform wiring of the high power factor converter (FR-HC) securely as shown below. Incorrect connection will damage the high power factor converter and inverter.
Page 77: Connection Of The Power Regeneration Common Converter Fr-Cv
Wiring Connection of stand-alone option units 3.6.5 Connection of the power regeneration common converter FR-CV When connecting the power regeneration common converter (FR-CV), make connection so that the inverter terminals (P/+, N/−) and the terminal symbols of the power regeneration common converter (FR-CV) are the same.
Page 78: Connection Of The Power Improving Dc Reactor Ffr-Hel-(H)-E
Connection of stand-alone option units Wiring 3.6.6 Connection of the power improving DC reactor FFR-HEL-(H)-E When using the DC reactor (FFR-HEL-(H)-E), connect it between terminals P1 and P/+. In this case, the jumper connected across terminals P1 and P/+ must be removed. Otherwise, the re- actor will not exhibit its performance.
Page 79: Installation Of A Reactor
Wiring Connection of stand-alone option units 3.6.7 Installation of a reactor When the inverter is connected near a large-capacity power transformer (500kVA or more) or when a power capacitor is to be switched over, an excessive peak current may flow in the power input circuit, damaging the converter circuit.
Page 80: Electromagnetic Compatibility (Emc)
Electromagnetic compatibility (EMC) Wiring Electromagnetic compatibility (EMC) 3.7.1 Leakage currents and countermeasures Mains filters, shielded motor cables, the motor, and the inverter itself cause stationary and var- iable leakage currents to PE. Since its value depends on the capacitances, carrier frequency, etc., low acoustic noise operation at the increased carrier frequency of the inverter will increase the leakage current.
Page 81 Wiring Electromagnetic compatibility (EMC) Example Line-to-line leakage current data example Dedicated motor: SF-JR 4P Carrier frequency: 14.5kHz Used wire: 2mm², 4 cores, cab tyre cable Leakage Currents [mA] Motor Capacity [kW] Rated Motor Current [A] Wiring Length 50m Wiring Length 100m 1000 0.75 1060...
Page 82 Electromagnetic compatibility (EMC) Wiring Note on selecting a suitable power supply ELCB If your application requires by installation standards an RCD (residual current device) as up stream protection please select according to DIN VDE 0100-530 as following: Single phase inverter type A or B Three phase inverter only type B Additionally, when selecting a residual current device (RCD), leakage current caused by the mains filter, the length of the shielded motor cable and the carrier frequency must be taken into...
Page 83 Wiring Electromagnetic compatibility (EMC) Example 5.5mm² × 5m 5.5mm² × 60m Noise filter (optional) Inverter 3~, 400V, 2.2kW Ig1 Ign Breaker Designed for Harmonic Standard Breaker and Surge Suppression Leakage current Ig1 [mA] × × -- - ------------------- - 0.11 1000 m Leakage current Ign [mA] 0 (without noise filter)
Page 84: Inverter-Generated Noises And Their Reduction Techniques
Electromagnetic compatibility (EMC) Wiring 3.7.2 Inverter-generated noises and their reduction techniques Some noises enter the inverter to malfunction it and others are radiated by the inverter to mal- function peripheral devices. Though the inverter is designed to be insusceptible to noises, it han- dles low-level signals, so it requires the following basic techniques.
Page 85 Wiring Electromagnetic compatibility (EMC) Inverter Noise directly radiated Air propagated ... Path generated noise from inverter noise Noise radiated from ... Path power supply cable Noise radiated from ... Path motor connection cabl Electromagnetic ... Path induction noise Electrostatic ... Path induction noise Noise propagated Electrical path...
Page 86 Electromagnetic compatibility (EMC) Wiring Noise Measures Propagation Path When devices that handle low-level signals and are liable to malfunction due to noises, e.g. instruments, receivers and sensors, are contained in the enclosure that contains the inverter or when their signal cables are run near the inverter, the devices may be malfunctioned by air- propagated noises.
Page 87: Power Supply Harmonics
Wiring Electromagnetic compatibility (EMC) 3.7.3 Power supply harmonics The inverter may generate power supply harmonics from its converter circuit to affect the power generator, power capacitor etc. Power supply harmonics are different from noise and leakage currents in source, frequency band and transmission path. Take the following countermeasure suppression techniques.
Page 88: Inverter-Driven 400V Class Motor
Electromagnetic compatibility (EMC) Wiring 3.7.4 Inverter-driven 400V class motor In the PWM type inverter, a surge voltage attributable to wiring constants is generated at the mo- tor terminals. Especially for a 400V class motor, the surge voltage may deteriorate the insula- tion.
Page 89: Precautions For Use Of The Inverter
Operation Precautions for use of the inverter Operation Precautions for use of the inverter The FR-D700 SC series is a highly reliable product, but incorrect peripheral circuit making or op- eration/handling method may shorten the product life or damage the product. Before starting operation, always recheck the following items.
Page 90 Precautions for use of the inverter Operation ● Do not use the inverter input side magnetic contactor to start/stop the inverter. Since repeated inrush currents at power ON will shorten the life of the converter circuit (switching life is about 1,000,000 times), frequent starts and stops of the MC must be avoided.
Page 91 Operation Precautions for use of the inverter ● Handling of inverter output side magnetic contactor Switch the magnetic contactor between the inverter and motor only when both the inverter and motor are at a stop. When the magnetic contactor is turned ON while the inverter is operating, overcurrent protection of the inverter and such will activate.
Page 92: Failsafe Of The System Which Uses The Inverter
Precautions for use of the inverter Operation 4.1.1 Failsafe of the system which uses the inverter When a fault occurs, the inverter trips to output a fault signal. However, a fault output signal may not be output at an inverter fault occurrence when the detection circuit or output circuit fails, etc. Although Mitsubishi assures best quality products, provide an interlock which uses inverter sta- tus output signals to prevent accidents such as damage to machine when the inverter fails for some reason.
Page 93 Operation Precautions for use of the inverter Checking the inverter operating status by the inverter operation ready completion signal Operation ready signal (RY signal) is output when the inverter power is on and the inverter be- comes operative. Check if the RY signal is output after powering on the inverter. Checking the inverter operating status by the start signal input to the inverter and inverter running signal The inverter running signal (RUN signal) is output when the inverter is running (RUN signal is as-...
Page 94 Precautions for use of the inverter Operation Output terminal function assignment When using various signals, assign functions to Pr. 190, Pr. 192 and Pr. 197 "output terminal function selection" referring to the table below 190, 192 and 197 Setting Output Signal Positive Logic Negative Logic Tab.
Page 95: Drive The Motor
Operation Drive the motor Drive the motor The inverter needs frequency command and start command. Refer to the flow chart below to perform setting. Step of operation Installation/mounting Frequency command Frequency [Hz] Wiring of the power supply and motor Output frequency Time [s] System examination...
Page 96: Operation Panel
Operation panel Operation Operation panel 4.3.1 Parts of the operation panel LED-Display 4-digit 7-segment display for operational values, parameter numbers, etc. Unit Indication LED to indicate the current unit Hz: Frequency A: Current Off: Voltage Flicker: Set frequency Rotation Direction Indication Lit or flicker during inverter operation RUN is lit: Forward rotation RUN flickering slowly: Reverse...
Page 97 Operation Operation panel Function Description Used to change the frequency setting and parameter values. Press to display the following: Displays the set frequency in the monitor mode Digital dial Currently set value is displayed during calibration Displays the order in the faults history mode RUN command for forward/reverse rotation.
Page 98: Basic Operation (Factory Setting)
Operation panel Operation 4.3.2 Basic operation (factory setting) Operation mode switch over At powering on (external operation mode) PU Jog operation mode (Refer to page 4-16.) Example PU operation mode Value change and frequency flicker (output frequency monitor) Frequency setting has been written and completed! Output current monitor Output voltage monitor...
Page 99: Easy Operation Mode Setting (Easy Setting Mode)
Operation Operation panel 4.3.3 Easy operation mode setting (easy setting mode) A frequency inverter can be controlled alone via the parameter unit, through external signals (switch, SPC outputs, external setpoint sources, etc.) or through a combination of external sig- nals and inputs to the parameter unit. The choice of operation mode is done by setting param- eter 79.
Page 100 Operation panel Operation Operation Method Operation Mode Operation Panel Indication Start Command Frequency Command Flickering PU Modes Flickering Flickering External External (Analog signal at External operation mode (STF-, STR) terminal 2 (voltage) or 4 (current)) Flickering Flickering Combined operation External (STF-, STR) mode 1 Flickering...
Page 101: Operation Lock
Operation Operation panel 4.3.4 Operation lock Operation using the digital dial and key of the operation panel can be made invalid to prevent pa- rameter change and unexpected start and stop. Operation lock ● Set "10" or "11" in Pr. 161, then press the MODE key for 2s to make the digital dial and key operation invalid.
Page 102 Operation panel Operation Operation Display Screen at powering on The monitor display appears. PU indication is lit. Press the PU/EXT key to choose the PU operation mode. PRM indication is lit. Press the MODE key to choose the parameter setting mode. The parameter number read previously appears.
Page 103: Monitoring Of Output Current And Output Voltage
Operation Operation panel 4.3.5 Monitoring of output current and output voltage Monitor display of output frequency, output current and output voltage can be changed by push- ing the SET key during monitoring mode. Operation Display Press the MODE key during operation to choose the output frequency monitor.
Page 104: Change The Parameter Setting Value
Operation panel Operation 4.3.8 Change the parameter setting value Example Change the Pr. 1 "Maximum frequency" setting from 120Hz to 50Hz. Operation Display Screen at powering on The monitor display appears. PU indication is lit. Press the PU/EXT key to choose the PU operation mode.
Page 105: Parameter Clear/All Parameter Clear
Operation Operation panel 4.3.9 Parameter clear/All Parameter clear ● Set "1" in Pr.CL "Parameter clear" or ALLC "all parameter clear" to initialize all parameters. (Parameters are not cleared when "1" is set in Pr. 77 "Parameter write selection".) ● Parameter clear returns all parameters except calibration parameters C1 (Pr. 901) to C7 (Pr.
Page 106: Initial Value Change List
Operation panel Operation 4.3.10 Initial value change list Displays and sets the parameters changed from the initial value. NOTES Calibration parameters (C1 (Pr. 901) to C7 (Pr. 905)) are not displayed even they are changed from the initial settings. Only simple mode parameter is displayed when simple mode is set (Pr. 160 "Extended func- tion display selection"...
Page 107 Operation Operation panel Operation Display Screen at powering on The monitor display appears. PU indication is lit. Press the PU/EXT key to choose the PU operation mode. PRM indication is lit. Press the MODE key to choose the parameter setting mode. The parameter number read previously appears.
Page 108 Operation panel Operation 4 - 20...
Page 109: Simple Mode Parameter List
Basic settings Simple mode parameter list Basic settings Simple mode parameter list For simple variable-speed operation of the inverter, the initial setting of the parameters may be used as they are. Set the necessary parameters to meet the load and operational specifications. Parameter setting, change and check can be made from the operation panel.
Page 110: Overheat Protection Of The Motor By The Inverter
Simple mode parameter list Basic settings 5.1.1 Overheat protection of the motor by the inverter Set this parameter when using a motor other than the Mitsubishi standard motor (SF-JR) and Mitsubishi constant torque motor (SF-HRCA). Set the rated motor current in Pr. 9 "Electronic thermal O/L relay"...
Page 111 Basic settings Simple mode parameter list NOTES Protective function by electronic thermal relay function is reset by inverter power reset and reset signal input. Avoid unnecessary reset and power-off. When two or more motors are connected to the inverter, they cannot be protected by the electronic thermal relay function.
Page 112: When The Rated Motor Frequency Is 60Hz (Pr. 3)
Simple mode parameter list Basic settings 5.1.2 When the rated motor frequency is 60Hz (Pr. 3) First, check the motor rating plate. If a frequency given on the rating plate is "60Hz" only, always set Pr. 3 "Base frequency" to "60Hz". Leaving the base frequency unchanged from "50Hz" may make the voltage low and the torque insufficient.
Page 113: Increase The Starting Torque (Pr. 0)
Basic settings Simple mode parameter list 5.1.3 Increase the starting torque (Pr. 0) Set this parameter when the motor with a load does not rotate, an alarm OL is output, resulting in an inverter trip due to OC1, etc. Setting Name Initial Value Description...
Page 114 Simple mode parameter list Basic settings Operation Display Screen at powering on The monitor display appears. PU indication is lit. Press the PU/EXT key to choose the PU operation mode. PRM indication is lit. Press the MODE key to choose the parameter setting mode.
Page 115: Limit The Maximum And Minimum Output Frequency (Pr. 1, Pr. 2)
Basic settings Simple mode parameter list 5.1.4 Limit the maximum and minimum output frequency (Pr. 1, Pr. 2) Setting Name Initial Value Description Range Maximum frequency 120Hz 0–120Hz Set the upper limit of the output frequency. Minimum frequency 0–120Hz Set the lower limit of the output frequency. Example You can limit the motor speed.
Page 116 Simple mode parameter list Basic settings Operation Display Screen at powering on The monitor display appears. PU indication is lit. Press the PU/EXT key to choose the PU operation mode. PRM indication is lit. Press the MODE key to choose the parameter setting mode.
Page 117: Change The Acceleration/Deceleration Time (Pr. 7, Pr. 8)
Basic settings Simple mode parameter list 5.1.5 Change the acceleration/deceleration time (Pr. 7, Pr. 8) Set in Pr. 7 "Acceleration time" a larger value for a slower speed increase and a smaller value for a faster speed increase. Set in Pr. 8 "Deceleration time" a larger value for a slower speed decrease and a smaller value for a faster speed decrease.
Page 118 Simple mode parameter list Basic settings Operation Display Screen at powering on The monitor display appears. PU indication is lit. Press the PU/EXT key to choose the PU operation mode. PU indication is lit. Press the MODE key to choose the parameter setting mode.
Page 119: Operation Mode Selection (Pr. 79)
Basic settings Simple mode parameter list 5.1.6 Operation mode selection (Pr. 79) Select the operation command location and frequency command location. LED Indication Initial Setting : OFF Name Description Value Range : ON External operation mode External/PU switch over mode Press the PU/EXT key to switch between the PU and external operation mode.
Page 120 Simple mode parameter list Basic settings 5.1.7 Large starting torque and low speed torque are necessary (General-purpose magnetic flux vector control) (Pr. 9, Pr. 71, Pr. 80) GP MFVC GP MFVC GP MFVC Large starting torque and low speed torque are available with general-purpose magnetic flux vector control.
Page 121 Basic settings Simple mode parameter list Selection method of General-purpose magnetic flux vector control Perform secure wiring. (Refer to section 3.2.) Set the motor. (Pr. 71) (Refer to page 5-12.) Motor Pr. 71 Remarks SF-JR Initial value Standard motor, high efficiency SF-HR —...
Page 122 Simple mode parameter list Basic settings 5.1.8 To exhibit the best performance of the motor performance (offline auto tuning) (Pr. 9, Pr. 71, Pr. 80, Pr. 82 to Pr. 84, Pr. 90, Pr. 96) The motor performance can be maximized with offline auto tuning. What is offline auto tuning? When performing general-purpose magnetic flux vector control, the motor can be run with the optimum operating characteristics by automatically measuring the motor constants (offline auto...
Page 123 Basic settings Simple mode parameter list NOTES This function is valid only when a value other than "9999" is set in Pr. 80 and General-pur- pose magnetic flux vector control is selected. You can copy the offline auto tuning data (motor constants) to another inverter with the PU (FR-PU07).
Page 124 Simple mode parameter list Basic settings Setting Select General-purpose magnetic flux vector control. (Refer to section 5.1.7.) Set "11" in Pr. 96 to tune motor constant (R1) without running the motor. It takes approxi- mately 9s until tuning is completed. Set the rated motor current (initial value is rated inverter current) in Pr.
Page 125 Basic settings Simple mode parameter list Execution of tuning CAUTION: Before performing tuning, check the monitor display of the operation panel or parameter unit (FR-PU04/FR-PU07) if the inverter is in the status for tuning. (Refer to Tab. 5-4.) When the start command is turned on under V/f control, the motor starts. When performing tuning or PU operation, press the RUN key of the operation panel or the FWD or REV key of the parameter unit (FR-PU04/FR-PU07).
Page 126 Simple mode parameter list Basic settings Monitor display during auto tuning Monitor is displayed on the operation panel and parameter unit (FR-PU04/FR-PU07) during tuning as below. The value displayed corresponds to the value of parameter 96. Parameter Unit Operation Panel Indication (FR-PU04/FR-PU07) Display Parameter 96 Setting...
Page 127 Basic settings Simple mode parameter list Return to normal operation When offline auto tuning ends, press the STOP/RESET key of the operation panel during PU op- eration. For external operation, turn off the start signal (STF signal or STR signal) once. This operation resets the offline auto tuning and the PU's monitor display returns to the normal indication.
Page 128 Simple mode parameter list Basic settings NOTES The motor constants measured once in the offline auto tuning are stored as parameters and their data are held until the offline auto tuning is performed again. An instantaneous power failure occurring during tuning will result in a tuning error. After power is restored, the inverter goes into the normal operation mode.
Page 129: Pu Operation Mode
Basic settings PU operation mode PU operation mode When operating the inverter via the parameter unit, the motor is started or stopped by the RUN key or the STOP/RESET key on the unit. The rated frequency value can thereby originate from various sources: ●...
Page 130: Set The Set Frequency To Operate
PU operation mode Basic settings 5.2.1 Set the set frequency to operate Example Performing operation at 30Hz Operation Display Screen at powering on The monitor display appears. PU indication is lit. Press the PU/EXT key to choose the PU operation mode. Turn the digital dial to show the frequency you want to set.
Page 131 Basic settings PU operation mode Change the acceleration time using Pr. 7 (refer to section 5.1.5) and the deceleration time using Pr. 8 (refer to section 5.1.5). The maximum output frequency is set in Pr. 1. (Refer to section 5.1.4.) NOTES Press the digital dial to show the set frequency.
Page 132: Use The Digital Dial Like A Potentiometer To Perform Operation
PU operation mode Basic settings 5.2.2 Use the digital dial like a potentiometer to perform operation ● Set "1" in Pr. 161 "Frequency setting/key lock operation selection". Example Change the frequency from 0Hz to 50Hz during operation. Operation Display Screen at powering on The monitor display appears.
Page 133: Use Switches To Give The Frequency Command (Multi-Speed Setting)
Basic settings PU operation mode 5.2.3 Use switches to give the frequency command (multi-speed setting) In frequency inverters of the FR-D700 SC series up to 15 frequency setpoints (and thus rpms and speeds) can be selected via the RH, RM, RL and REX terminals. Manually activated switch- es or relay outputs of a programmble logic controller (PLC), for example, can be used to select a frequency.
Page 134 PU operation mode Basic settings Operation Display Screen at powering on The monitor display appears. Change the Pr. 79 setting to "4". (Refer to section 4.3.3 for change of the setting.) "PU" display and "EXT" display are lit. Flickering Turn on the start switch RUN. When the frequency command is not given, "RUN"...
Page 135: Perform Frequency Setting By Analog Voltage Input
Basic settings PU operation mode 5.2.4 Perform frequency setting by analog voltage input In this type of setpoint selection a potentiometer is connected to the frequency inverter. The po- tentiometer is supplied with a voltage of 5V through terminal 10 of the frequency inverter. Inverter Power supply Motor...
Page 136 PU operation mode Basic settings Operation Display Screen at powering on The monitor display appears. Change the Pr. 79 setting to "4". (Refer to section 4.3.3 for change of the setting.) "PU" display and "EXT" display are lit. Turn on the start switch RUN. Flickering When the frequency command is not given, "RUN"...
Page 137: Perform Frequency Setting By Analog Current Input
Basic settings PU operation mode 5.2.5 Perform frequency setting by analog current input An external current source is connection to the frequency inverter for setpoint default setting. Inverter Power supply Motor AU signal Current signal source Operation (0/4–20mA DC) panel I0020206E Fig.
Page 138 PU operation mode Basic settings Operation Display Screen at powering on The monitor display appears. Change the Pr. 79 setting to "4". (Refer to section 4.3.3 for change of the setting.) "PU" display and "EXT" display are lit. Check that the terminal 4 input selection signal (AU) Flickering is on.
Page 139: External Operation
Basic settings External operation External operation When operating the inverter via external signals, the motor is started and stopped by external signals connected to terminals STF and STR of the inverter. Just as when operating using the parameter unit, the set frequency value may originate from various sources: ●...
Page 140 External operation Basic settings Operation Display Screen at powering on The monitor display appears. Change the Pr. 79 setting to "3". (Refer to section 4.3.3 for change of the setting.) "PU" display and "EXT" display are lit. Forward rotation Turn the start switch (STF or STR) on. The motor runs at the frequency set in the set Reverse frequency mode of the operation panel.
Page 141: Multi-Speed Setting) (Pr. 4 To Pr. 6)
Basic settings External operation 5.3.2 Use switches to give a start command and a frequency command (multi-speed setting) (Pr. 4 to Pr. 6) Up to 15 set frequency values can be selected via terminals RH, RM, RL and REX of the fre- quency inverter.
Page 142 External operation Basic settings Example Set "40Hz" in Pr. 4 "Multi-speed setting (high speed)" and turn on terminals RH and STF (STR)-PC to operate. Operation Display Power on → operation mode check For the initial setting, the inverter operates in the external operation mode "EXT"...
Page 143 Basic settings External operation Possible faults: ● The EXT lamp is not lit even when the PU/EXT key is pressed. – Switchover of the operation mode with is valid when Pr. 79 = 0 (initial value). ● 50Hz, 30Hz and 10Hz are not output from RH, RM and RL respectively when they are turned on. –...
Page 144: Perform Frequency Setting By Analog Voltage Input
External operation Basic settings 5.3.3 Perform frequency setting by analog voltage input In this type of setpoint selection a potentiometer is connected to the frequency inverter. The po- tentiometer is supplied with a voltage of 5V through terminal 10 of the frequency inverter. Inverter Power supply Motor...
Page 145 Basic settings External operation Operation Display Power on → operation mode check For the initial setting, the inverter operates in the external operation mode "EXT" when powering on. Check that the operation command indication is "EXT". If not displayed, press the PU/EXT key to change to the external "EXT"...
Page 146 External operation Basic settings Possible faults: ● The motor will not rotate. – Check that the EXT lamp is lit. The external operation mode is valid when Pr. 79 = 0 (initial value). Use the PU/EXT key to change into the external operation mode. –...
Page 147: Of Potentiometer (At 5V)
Basic settings External operation 5.3.4 Change the frequency (40Hz) of the maximum value of potentiometer (at 5V) Example The frequency of the maximum analog voltage of the potentiometer (at 5V) has to be changed from the initial setting of 50Hz to 40Hz. Set 40Hz in Pr. 125. Operation Display Turn the digital dial until P.125 (Pr.
Page 148: Perform Frequency Setting By Analog Current Input
External operation Basic settings 5.3.5 Perform frequency setting by analog current input An external current source is connected to the frequency inverter for setpoint default setting. ● Switch terminal STF (STR)-PC on to give a start command. ● Turn the AU signal on. ●...
Page 149 Basic settings External operation Operation Display Power on → operation mode check For the initial setting, the inverter operates in the external operation mode "EXT" when powering on. Check that the operation command indication is "EXT". If not displayed, press the PU/EXT key to change to the external "EXT"...
Page 150: Of Potentiometer (At 20Ma)
External operation Basic settings 5.3.6 Change the frequency (40Hz) of the maximum value of potentiometer (at 20mA) Example The frequency of the maximum analog current of the potentiometer (at 20mA) has to be changed from the initial setting of 50Hz to 40Hz. Set 40Hz in Pr. 126. Operation Display Turn the digital dial until P.126 (Pr.
Page 151: Parameter Overview
Parameter Parameter overview Parameter Parameter overview For simple variable-speed operation of the inverter, the initial setting of the parameters may be used as they are. Set the necessary parameters to meet the load and operational specifications. Parameter setting, change and check can be made from the operation panel. indicates simple mode parameters.
Page 152 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Set the frequency when the motor ✔ ✔ ✔ Base frequency 0.01Hz 50Hz 0–400Hz...
Page 153 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Rated Electronic thermal inverter ✔ ✔ ✔ 0.01A 0–500A Set the rated motor current. output O/L relay current...
Page 154 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Open input always Normally closed input (NC contact input specifications) External terminal: Normally closed ✔...
Page 155 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled 0–400Hz/ ✔ ✔ ✔ Frequency jump 1A 0.01Hz 9999 9999 0–400Hz/ ✔...
Page 156 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled 0/5/8–12/ Selects monitor to be displayed on 14/20/ the operation panel and parameter DU/PU main display ✔...
Page 157 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Set the full-scale value to output Frequency monitoring ✔ ✔ ✔ 0.01Hz 50Hz 0–400Hz...
Page 158 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled RH, RM, RL Frequency setting signal func- storage function tion Multi-speed —...
Page 159 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Thermal characteristics of a stand- ard motor Thermal characteristics of the Mit- subishi constant-torque motor Thermal characteristic of Mitsubi- shi high efficiency standard motor...
Page 160 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled The primary delay filter time con- stant for the analog input can be Input filter time ✔...
Page 161 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled 0.1–7.5kW Set the applied motor capacity. ✔ ✔ ✔ Motor capacity 0.01kW 9999 6-29...
Page 162 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Set the inverter station numbers when two or more inverters are connected to one personal compu- PU communication 0–31...
Page 163 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Without CR/LF PU communication ✔ ✔ ✔ CR/LF presence/ With CR absence selection With CR/LF Parameter values written by com-...
Page 164 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Terminal 2 frequency Set the frequency of terminal 2 ✔ ✔ 0.01Hz 50Hz 0–400Hz...
Page 165 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description ments value range tion page ✔: enabled —: disabled If the proportional band is narrow (parameter setting is small), the manipulated variable varies greatly with a slight change of the meas- ured value.
Page 166 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Japanese English German French PU display language ✔ — — 6-282 selection Spanish Italian...
Page 167 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Setting dial frequency set- ting mode Key lock mode invalid Setting dial potentiome- Frequency setting/key ter mode...
Page 168 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled 0/1/3/4/7/8/ 11–16/25/ 26/46/47/ 64/70/80/ 81/90/91/ 93/95/96/ 98/99/100/ 101/103/ 0/100: Inverter running 104/107/ RUN terminal function 1/101: Up to frequencych...
Page 169 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled 0–50% Used to set the rated motor slip. ✔ ✔ ✔ Rated slip 0.01% 9999...
Page 170 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Without output phase failure protection Output phase failure ✔ ✔ ✔ protection selection With output phase failure protection...
Page 171 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description ments value range tion page ✔: enabled —: disabled Invalid Magnitude of The setting increments when the ✔ ✔ ✔ frequency change 0,01 6-284...
Page 172 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description ments value range tion page ✔: enabled —: disabled Remote out- put data clear at powering Remote output data clear at Remote out- inverter reset put data...
Page 173 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description ments value range tion page ✔: enabled —: disabled Set the time taken to average the ✔ ✔ ✔ Current average time 0.1s 0.1–1.0s current during start bit output...
Page 174 Parameter overview Parameter Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description ments value range tion page ✔: enabled —: disabled Regeneration avoidance function invalid Regeneration Regeneration avoidance function ✔ ✔ ✔ avoidance operation is always valid selection...
Page 175 Parameter Parameter overview Para- Para- Para- Parameter meter meter meter copy clear clear Refer Func- Incre- Initial Setting Name Description tion ments value range page ✔: enabled —: disabled Parameters you can use for your own purposes. ✔ Free parameter 1 9999 0–9999 —...
Page 176: Adjust The Output Torque (Current) Of The Motor
Adjust the output torque (current) of the motor Parameter Adjust the output torque (current) of the motor Refer to Purpose Parameter that must be set Section Set starting torque manually Manual torque boost Pr. 0, Pr. 46, 6.2.1 Automatically control output current General-purpose magnetic flux Pr.
Page 177 Parameter Adjust the output torque (current) of the motor Starting torque adjustment The set value indicates the percentage of the maximum output voltage at 0Hz by which the out- put voltage is increased. The voltage increases in direct proportion to the frequency from the time of startup until the operating frequency and voltage have been reached.
Page 178 Adjust the output torque (current) of the motor Parameter NOTES The RT signal acts as the second function selection signal and makes the other second functions valid. (Refer to section 6.9.3.) The amount of current flows in the motor may become large according to the conditions such as the motor characteristics, load, acceleration/deceleration time, wiring length, etc., resul- ting in an overcurrent trip (OL (overcurrent alarm) then E.OC1 (overcurrent trip during acce- leration), overload trip (E.THM (motor overload trip), or E.THT (inverter overload trip).
Page 179 Parameter Adjust the output torque (current) of the motor 6.2.2 General-purpose magnetic flux vector control (Pr. 9, Pr. 71, Pr. 80) GP MFVC GP MFVC GP MFVC Large starting torque and low speed torque are available with general-purpose magnetic flux vector control.
Page 180 Adjust the output torque (current) of the motor Parameter Selection method of general-purpose magnetic flux vector control Perform secure wiring. (Refer to section 3.2.) Set the motor (Pr. 71) (refer to page 5-12). Motor Pr. 71 Remarks SF-JR Initial value Standard motor Mitsubishi High efficiency...
Page 181 Parameter Adjust the output torque (current) of the motor Control method switching by external terminals (X18 signal) ● Use the V/f switchover signal (X18) to change the control method (V/f control and General- purpose magnetic flux vector control) with external terminal. ●...
Page 182: Slip Compensation (Pr. 245 To Pr. 247)
Adjust the output torque (current) of the motor Parameter 6.2.3 Slip compensation (Pr. 245 to Pr. 247) The inverter output current may be used to assume motor slip to keep the motor speed constant. Initial Refer to Name Setting Range Description Parameters referred to Value Section...
Page 183 Parameter Adjust the output torque (current) of the motor 6.2.4 Stall prevention operation (Pr. 22, Pr. 23, Pr. 48, Pr. 66, Pr. 156, Pr. 157) This function monitors the output current and automatically changes the output frequency to prevent the inverter from coming to trip due to overcurrent, overvoltage, etc. It can also limit stall prevention and fast-response current limit operation during acceleration/de- celeration, driving or regeneration.
Page 184 Adjust the output torque (current) of the motor Parameter Block diagram Pr. 22 Stall prevention operation invalid Pr. 48 Stall prevention operation level Output frequency Pr. 23, Pr. 66 I001883E Fig. 6-3: Stall prevention block diagram Setting of stall prevention operation level (Pr. 22) Set in Pr.
Page 185 Parameter Adjust the output torque (current) of the motor Stall prevention operation signal output and output timing adjustment (OL signal, Pr. 157) When the output current exceeds the stall prevention operation level and stall prevention is ac- tivated, the stall prevention operation signal (OL signal) turns on for longer than 100ms. When the output current falls to or below the stall prevention operation level, the output signal turns off.
Page 186 Adjust the output torque (current) of the motor Parameter Setting of stall prevention operation in high frequency range (Pr. 22, Pr. 23, Pr. 66) During high-speed operation above the rated motor frequency, acceleration may not be made because the motor current does not increase. If operation is performed in a high frequency range, the current at motor lockup becomes smaller than the rated output current of the inverter, and the protective function (OL) is not executed if the motor is at a stop.
Page 187 Parameter Adjust the output torque (current) of the motor Set two types stall prevention operation levels (Pr. 48) Turning RT signal on makes Pr. 48 "Second stall prevention operation current" valid. For the terminal used for RT signal input, set "3" in any of Pr. 178 to Pr. 182 "Input terminal func- tion selection"...
Page 188 Adjust the output torque (current) of the motor Parameter Limit the stall prevention operation and fast-response current limit operation according to the operating status (Pr. 156) Refer to the following table and select whether fast-response current limit operation will be per- formed or not and the operation to be performed at OL signal output: Stall Prevention Operation Level OL Signal Output...
Page 189 Parameter Adjust the output torque (current) of the motor NOTES When the load is heavy or the acceleration/deceleration time is short, stall prevention is activated and acceleration/deceleration may not be made according to the preset acceleration/deceleration time. Set Pr. 156 and stall prevention operation level to the optimum values.
Page 190: Limit The Output Frequency
Limit the output frequency Parameter Limit the output frequency Refer to Purpose Parameters that must be set Section Set upper limit and lower limit of output Maximum/minimum frequency Pr. 1, Pr. 2, 6.3.1 frequency Pr. 18 Perform operation by avoiding machine Frequency jump Pr.
Page 191 Parameter Limit the output frequency Set the minimum frequency Use Pr. 2 "Minimum frequency" to set the lower limit of the output frequency. NOTES When Pr. 15 "Jog frequency" is equal to or less than Pr. 2, the Pr. 15 setting has precedence over the Pr.
Page 192 Limit the output frequency Parameter 6.3.2 Avoid mechanical resonance points (frequency jumps) (Pr. 31 to Pr. 36) When it is desired to avoid resonance attributable to the natural frequency of a mechanical sys- tem, these parameters allow resonant frequencies to be jumped. Refer to Name Initial Value...
Page 193 Parameter Limit the output frequency The following diagrams show how the jump point is selected. The diagram on the left shows a sequence in which the jump takes place at the end of the area to be jumped, for which the lower frequency must be entered first.
Page 194: Set V/F Pattern
Set V/f pattern Parameter Set V/f pattern Refer to Purpose Parameters that must be set Section Set motor ratings Base frequency, Base frequency voltage Pr. 3, Pr. 19, 6.4.1 Pr. 47 Select a V/f pattern according to Load pattern selection Pr.
Page 195 Parameter Set V/f pattern Set two kinds of base frequencies (Pr. 47) Use the second base frequency when you want to change the base frequency, e.g. when using multiple motors by switching between them by one inverter. Pr. 47 "Second V/f (base frequency)" is valid when the RT signal is on. NOTES The RT signal acts as the second function selection signal and makes the other second functions valid.
Page 196: Load Pattern Selection (Pr. 14)
Set V/f pattern Parameter 6.4.2 Load pattern selection (Pr. 14) You can select the optimum output characteristic (V/f characteristic) for the application and load characteristics. Initial Refer to Name Setting Range Description Parameters referred to Value Section For constant torque load Torque boost 6.2.1 Second torque...
Page 197 Parameter Set V/f pattern Constant-torque load application (Pr. 14 = 2 oder 3) Set "2" when a vertical lift load is fixed as power driving load at forward rotation and regenerative load at reverse rotation. Pr. 0 "Torque boost" is valid during forward rotation and torque boost is automatically changed to "0%"...
Page 198: Frequency Setting By External Terminals
Frequency setting by external terminals Parameter Frequency setting by external terminals Refer to Purpose Parameters that must be set Section Make frequency setting by combina- Multi-speed operation Pr. 4–Pr. 6, 6.5.1 tion of terminals Pr. 24–Pr. 27 Pr. 232–Pr. 239 Perform jog operation Jog operatio Pr.
Page 199 Parameter Frequency setting by external terminals Operation is performed at the frequency set in Pr. 4 when the RH signal turns on, Pr. 5 when the RM signal turns on, and Pr. 6 when the RL signal turns on. Frequency from speed 4 to speed 15 can be set according to the combination of the RH, RM, RL and REX signals.
Page 200 Frequency setting by external terminals Parameter Fig. 6-17: Connection example Forward rotation I001127E NOTES The priorities of the frequency commands by the external signals are "jog operation > multi- speed operation > terminal 4 analog input > terminal 2 analog input". (Refer to section 6.15 for the frequency command by analog input.) Valid in external operation mode or PU/external combined operation mode (Pr.
Page 201: Jog Operation (Pr. 15, Pr. 16)
Parameter Frequency setting by external terminals 6.5.2 Jog operation (Pr. 15, Pr. 16) Jog operation is used to setup the machine.The frequency and acceleration/deceleration time for Jog operation can be set. As soon as the frequency inverter receives the start signal, the mo- tor is accelerated at the frequency entered in parameter 15 (jog frequency) using the preset ac- celeration/brake time (parameter 16).
Page 202 Frequency setting by external terminals Parameter Fig. 6-19: Jog operation signal timing chart frequency Forward rotation Pr. 20 Pr. 15 Pr. 16 Reverse rotation I001324C Operation Display Screen at powering on Confirm that the external operation mode is selected. (EXT indication is lit) If not displayed, press the PU/EXT key to change to the external operation mode If the operation mode still does not change, set Pr.
Page 203 Parameter Frequency setting by external terminals JOG operation from PU Selects Jog operation mode from the operation panel and PU (FR-PU04/FR-PU07). Operation is performed only while the start button is pressed. Fig. 6-21: Inverter Connection example for jog operation performed from PU Power Motor supply...
Page 204 Frequency setting by external terminals Parameter NOTES When Pr. 29 "Acceleration/deceleration pattern selection" = "1" (S-pattern acceleration/ deceleration A), the acceleration/deceleration time is the period of time required to reach Pr. 3 "Base frequency". The Pr. 15 setting should be equal to or higher than the Pr. 13 "Starting frequency setting". The JOG signal can be assigned to the input terminal using any of Pr.
Page 205: Remote Setting Function (Pr. 59)
Parameter Frequency setting by external terminals 6.5.3 Remote setting function (Pr. 59) Even if the operation panel is located away from the enclosure, you can use contact signals to perform continuous variable-speed operation, without using analog signals. Description Initial Setting Refer to Name Parameters referred to...
Page 206 Frequency setting by external terminals Parameter Remote setting function When using the remote setting function, following frequencies can be compensated to the fre- quency set by RH and RM operation according to the operation mode. During external operation (including Pr. 79 = 4): external frequency command other than multi-speed settings During external operation and...
Page 207 Parameter Frequency setting by external terminals NOTES The range of frequency changeable by RH (acceleration) and RM (deceleration) is 0 to max- imum frequency (Pr. 1 or Pr. 18 setting). Note that the maximum value of set frequency is (main speed + maximum frequency). The set frequency is clamped at (main speed + Pr.
Page 208 Frequency setting by external terminals Parameter During jog operation or PID control operation, the remote setting function is invalid. Set frequency = 0Hz ● Even when the remotely-set frequency is cleared by turning on the RL (clear) signal after turn off (on) of both the RH and RM signals, the inverter operates at the remotely-set frequency stored in the last operation if power is reapplied before one minute has elapsed since turn off (on) of both the RH and RM signals.
Page 209: Acceleration And Deceleration
Parameter Acceleration and deceleration Acceleration and deceleration Refer to Purpose Parameters that must be set Section Motor acceleration/deceleration time Acceleration/deceleration times Pr. 7, Pr. 8, 6.6.1 setting Pr. 20, Pr. 44, Pr. 45 Starting frequency Starting frequency and start-time hold Pr.
Page 210 Acceleration and deceleration Parameter Acceleration time setting (Pr. 7, Pr. 20) Use Pr. 7 "Acceleration time" to set the acceleration time required to reach Pr. 20 "Acceleration/ deceleration reference frequency" from 0Hz. Fig. 6-27: Acceleration/deceleration time Pr. 20 Pr. 7 Pr.
Page 211 Parameter Acceleration and deceleration Set two kinds of acceleration/deceleration times (RT signal, Pr. 44, Pr. 45) Pr. 44 and Pr. 45 are valid when the RT signal is on. Switching the parameter sets allows you to operate motors with different specifications and capabilities with the frequency inverter. When "9999"...
Page 212: Starting Frequency And Start-Time Hold Function
Acceleration and deceleration Parameter 6.6.2 Starting frequency and start-time hold function You can set the starting frequency and hold the set starting frequency for a certain period of time. Set these functions when you need the starting torque or want to smooth motor drive at a start. Refer to Name Initial Value...
Page 213 Parameter Acceleration and deceleration Start-time hold function (Pr. 571) This function holds the time set in Pr. 571 and the output frequency set in Pr. 13 "Starting frequency". This function performs initial excitation to smooth the motor drive at a start. Forward rotation Output frequency [Hz]...
Page 214: Acceleration And Deceleration Pattern (Pr. 29)
Acceleration and deceleration Parameter 6.6.3 Acceleration and deceleration pattern (Pr. 29) You can set the acceleration/deceleration pattern suitable for application. Initial Setting Refer to Name Description Parameters referred to Value Range Section Linear acceleration/deceleration Base frequency 6.4.1 Acceleration time 6.6.1 S-pattern acceleration/deceleration A Acceleration/deceleration Deceleration time...
Page 215 Parameter Acceleration and deceleration S-pattern acceleration/deceleration A (Pr. 29 = 1) Used when acceleration/deceleration must be made in a short time to a high-speed range of not lower than base frequency. In this acceleration/deceleration pattern, Pr. 3 "Base frequency" (fb) is the inflection point of the S-pattern (refer to Fig.
Page 216: Selection And Protection Of A Motor
Selection and protection of a motor Parameter Selection and protection of a motor Refer to Purpose Parameters that must be set Section Motor protection from overheat Electronic thermal O/L relay/ Pr. 9, Pr. 51, 6.7.1 PTC thermistor protection Pr. 561 Constant torque motor Applied motor Pr.
Page 217 Parameter Selection and protection of a motor Electronic thermal O/L relay (Pr. 9) Set the rated current [A] of the motor in Pr. 9. (When the power supply specification is 400V/ 440V 60Hz, set the 1.1 times the rated motor current.) Set "0"...
Page 218 Selection and protection of a motor Parameter NOTES Fault by electronic thermal relay function is reset by inverter power reset and reset signal input. Avoid unnecessary reset and power-off. Install an external thermal relay (OCR) between the inverter and a motor when operating several motors by one inverter, or when using a multi-pole motor or specialized motor.
Page 219 Parameter Selection and protection of a motor Set two different electronic thermal O/L relays (Pr. 51) Use this function when running two motors of different rated currents individually by a single in- verter. (When running two motors together, use external thermal relays.) Set the rated current of the second motor to Pr.
Page 220 Selection and protection of a motor Parameter Electronic thermal relay function prealarm (TH) and alarm signal (THP signal) The alarm signal (THP) is output and electronic thermal relay function prealarm (TH) is dis- played when the electronic thermal O/L relay cumulative value reaches 85% of the level set in Pr.
Page 221 Parameter Selection and protection of a motor PTC thermistor protection (Pr. 561) Terminal 2 and terminal 10 are available for inputting of motor built-in PTC thermistor output. When the PTC thermistor input reaches to the resistance value set in Pr. 561, inverter outputs PTC thermistor operation error signal (E.PTC) and trips.
Page 222: Applied Motor (Pr. 71, Pr. 450)
Selection and protection of a motor Parameter 6.7.2 Applied motor (Pr. 71, Pr. 450) Setting of the used motor selects the thermal characteristic appropriate for the motor. Setting is required to use a constant-torque motor. Thermal characteristic of the electronic thermal relay function suitable for the motor is set.
Page 223 Parameter Selection and protection of a motor NOTE For the FR-D740-120SC and 160SC, the Pr. 0 "Torque boost" and Pr. 12 "DC injection brake operation voltage" settings are automatically changed according to the Pr. 71 setting as fol- lows. Pr. 71 0, 3, 23, 40, 43 1, 13, 50, 53 Pr.
Page 224 Selection and protection of a motor Parameter 6.7.3 To exhibit the best performance of the motor performance (offline auto tuning) (Pr. 71, Pr. 80, Pr. 82 to Pr. 84, Pr. 90, Pr. 96) The motor performance can be maximized with offline auto tuning. What is offline auto tuning? ●...
Page 225 Parameter Selection and protection of a motor ● This function is valid only when a value other than "9999" is set in Pr. 80 and General- purpose magnetic flux vector control is selected. ● You can copy the offline auto tuning data (motor constants) to another inverter with the PU (FR-PU07).
Page 226 Selection and protection of a motor Parameter Before performing offline auto tuning Check the following before performing offline auto tuning. ● Make sure general-purpose magnetic flux vector control (Pr. 80) is selected. (Tuning can be performed even under V/f control selected by turning on X18.) ●...
Page 227 Parameter Selection and protection of a motor Execution of tuning CAUTION: Before performing tuning, check the monitor display of the operation panel or parameter unit (FR-PU04/FR-PU07) if the inverter is in the status for tuning (refer to Tab. 6-9). When the start command is turned on under V/f control, the motor starts. When performing tuning or PU operation, press the RUN key of the operation panel or the FWD or REV key of the parameter unit (FR-PU04/FR-PU07).
Page 228 Selection and protection of a motor Parameter Display during tuning Monitor is displayed on the operation panel and parameter unit (FR-PU04/FR-PU07) during tun- ing as below. The value displayed corresponds to the value of parameter 96. Parameter Unit Operation Panel Indication (FR-PU04/FR-PU07) Display Pr.
Page 229 Parameter Selection and protection of a motor Return to normal operation When offline auto tuning ends, press the STOP/RESET key of the operation panel during PU op- eration. For external operation, turn off the start signal (STF signal or STR signal) once. This op- eration resets the offline auto tuning and the PU's monitor display returns to the normal indica- tion.
Page 230 Selection and protection of a motor Parameter NOTES The motor constants measured once in the offline auto tuning are stored as parameters and their data are held until the offline auto tuning is performed again. An instantaneous power failure occurring during tuning will result in a tuning error. After power is restored, the inverter goes into the normal operation mode.
Page 231: Motor Brake And Stop Operation
Parameter Motor brake and stop operation Motor brake and stop operation Refer to Purpose Parameters that must be set Section Motor braking torque adjustment DC injection brake Pr. 10–Pr. 12 6.8.1 Improve the motor braking torque Selection of a regenerative brake Pr.
Page 232 Motor brake and stop operation Parameter Operation frequency setting (Pr. 10) When the frequency at which the DC injection brake operates is set to Pr. 10, the DC injection brake is operated when this frequency is reached during deceleration. Fig. 6-39: When Pr.
Page 233 Parameter Motor brake and stop operation Operation voltage (torque) setting (Pr. 12) Use Pr. 12 to set the percentage to the power supply voltage. When Pr. 12 = 0%, the DC injection brake is not operated. (At a stop, the motor coasts.) When using the constant-torque motor (SF-JRCA) and energy saving motor (SF-HR, SF-HRCA), change the Pr.12 setting as follows: Constant-torque motor SF-JRCA:...
Page 234: Selection Of A Regenerative Brake (Pr. 30, Pr. 70)
Motor brake and stop operation Parameter 6.8.2 Selection of a regenerative brake (Pr. 30, Pr. 70) ● When making frequent starts/stops, use the optional high-duty brake resistor (FR-ABR) and brake unit (FR-BU2) to increase the regenerative brake duty. ● Use a power regeneration common converter (FR-CV) for continuous operation in regen- eration status.
Page 235 Parameter Motor brake and stop operation When a high power factor converter (FR-HC) is used and automatic restart after instan- taneous power failure function is made valid. ● When automatic restart after instantaneous power failure function of both the FR-HC and inverter is made valid (when avalue other than "9999"...
Page 236: Stop Selection (Pr. 250)
Motor brake and stop operation Parameter 6.8.3 Stop selection (Pr. 250) Used to select the stopping method (deceleration to a stop or coasting) when the start signal turns off. Used to stop the motor with a mechanical brake, etc. together with switching off of the start signal.
Page 237 Parameter Motor brake and stop operation Use Pr. 250 to set the time from when the start signal turns off until the output is shut off. When any of "1000" to "1100" is set, the output is shut off after (Pr. 250 − 1000)s. The output is shut off when the time set in Pr.
Page 238: Function Assignment Of External Terminals
Function assignment of external terminals Parameter Function assignment of external terminals Refer to Purpose Parameters that must be set Section Assign function to input terminal Input terminal function selection Pr. 178–Pr. 182 6.9.1 Set MRS signal (output shutoff) to nor- MRS input selection Pr.
Page 239 Parameter Function assignment of external terminals Input terminal function assignment Refer to Setting Terminal Function Related Parameters Page Pr. 59 = 0 Pr. 4–Pr. 6, Pr. 24–Pr. 27, Low-speed operation command 6-48 (initial value) Pr. 232–Pr. 239 Pr. 59 ≠ 0 Remote setting (setting clear) Pr.
Page 240 Function assignment of external terminals Parameter NOTES Changing the terminal assignment using Pr. 178 to Pr. 182 may affect the other functions. Please make setting after confirming the function of each terminal. Same function can be assigned to two or more terminals. In this case, the logic of terminal input is OR.
Page 241: Inverter Output Shutoff Signal (Mrs Signal, Pr. 17)
Parameter Function assignment of external terminals 6.9.2 Inverter output shutoff signal (MRS signal, Pr. 17) The inverter output can be shut off from the MRS signal. The logic of the MRS signal can also be selected. Initial Setting Refer to Name Description Parameters referred to...
Page 242 Function assignment of external terminals Parameter MRS signal logic inversion When Pr. 17 is set to "2", the MRS signal (output stop) can be changed to the normally closed (NC contact) input specification. When the MRS signal turns on (opens), the inverter shuts off the output.
Page 243: Selection Signal (Rt, Pr. 155)
Parameter Function assignment of external terminals 6.9.3 Condition selection of function validity by second function selection signal (RT, Pr. 155) You can select the second function using the RT signal. For the RT signal, set "3" in any of Pr. 178 to Pr. 182 to assign the function. The second function has the following applications: ●...
Page 244: Start Signal Selection (Terminal Stf, Str, Stop, Pr. 250)
Function assignment of external terminals Parameter 6.9.4 Start signal selection (Terminal STF, STR, STOP, Pr. 250) You can select the operation of the start signal (STF/STR). Used to select the stopping method (deceleration to a stop or coasting) when the start signal turns off.
Page 245 Parameter Function assignment of external terminals Fig. 6-48: Inverter 2-wire type connection (Pr. 250 = 8888) Start signal Forward/reverse signal Time I001149E NOTES When Pr. 250 is set to any of "0 to 100, 1000 to 1100", the motor coasts to a stop if the start command is turned off.
Page 246 Function assignment of external terminals Parameter 3-wire type (terminals STF, STR and STOP) A three-wire type connection is shown below. The start self-holding selection becomes valid when the STOP signal is turned on. In this case, the forward/reverse rotation signal functions only as a start signal. If the start signal (STF or STR) is turned on and then off, the start signal is held and makes a start.
Page 247 Parameter Function assignment of external terminals Start signal selection Setting Inverter Status Pr. 250 = 0–100s/9999 Pr. 250 = 1000–1100s/8888 Stop Stop Reverse rotation Forward rotation Forward rotation Stop Reverse rotation Tab. 6-14: Start signal selection FR-D700 SC EC 6 - 97...
Page 248: Output Terminal Function Selection (Pr. 190, Pr. 192, Pr. 197)
Function assignment of external terminals Parameter 6.9.5 Output terminal function selection (Pr. 190, Pr. 192, Pr. 197) You can change the functions of the open collector output terminal and relay output terminal. Initial Refer to Name Initial Signal Setting Range Parameters referred to Value Section...
Page 249 Parameter Function assignment of external terminals Setting Related Refer to Terminal Function Operation Source Sink Parameters Page Logic Logic Output when the electronic thermal relay function cumu- lative value reaches 85%. Electronic thermal O/L relay (Electronic thermal relay Pr. 9, Pr. 51 6-70 pre-alarm function protection (E.THT/...
Page 250 Function assignment of external terminals Parameter Setting Related Parame- Refer to Terminal Function Operation Source Sink ters Page Logic Logic Output when any of the con- trol circuit capacitor, main cir- cuit capacitor and inrush Life alarm Pr. 255–Pr. 259 6-272 current limit circuit or the cooling fan approaches the...
Page 251 Parameter Function assignment of external terminals Inverter operation ready signal (RY) and inverter running signal (RUN) When the inverter is ready to operate, the output of the operation ready signal (RY) is on. It is also on during inverter running. When the output frequency of the inverter rises to or above Pr.
Page 252 Function assignment of external terminals Parameter Alarm output signal (ALM) If the inverter comes to trip, the ALM signal is output. (Refer to section 7.1.) Inverter alarm occurrence (output shutoff) Time Reset ON Reset processing (about 1s) I001797E Fig. 6-52: Alarm signals NOTE The ALM signal is assigned to the ABC contact in the default setting.
Page 253: Detection Of Output Frequency (Su, Fu, Pr. 41 To Pr. 43)
Parameter Function assignment of external terminals 6.9.6 Detection of output frequency (SU, FU, Pr. 41 to Pr. 43) The inverter output frequency is detected and output to the output signal. Initial Setting Refer to Name Description Parameters referred to Value Range Section Up-to-frequency...
Page 254 Function assignment of external terminals Parameter Output frequency detection (FU, Pr. 42, Pr. 43) The output frequency detection signal (FU) is output when the output frequency reaches or ex- ceeds the Pr. 42 setting. This function can be used for electromagnetic brake operation, open signal, etc.
Page 255 Parameter Function assignment of external terminals 6.9.7 Output current detection function (Y12, Y13, Pr. 150 to Pr. 153, Pr. 166, Pr. 167) The output power during inverter running can be detected and output to the output terminal. Initial Setting Refer to Name Description Parameters referred to...
Page 256 Function assignment of external terminals Parameter Zero current detection (Y13, Pr. 152, Pr. 153) 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 or relay output terminal.
Page 257: Remote Output Function (Rem, Pr. 495, Pr. 496)
Parameter Function assignment of external terminals 6.9.8 Remote output function (REM, Pr. 495, Pr. 496) You can utilize the on/off of the inverter’s output signals instead of the remote output terminal of the programmable logic controller. Initial Setting Refer to Name Description Parameters referred to...
Page 258 Function assignment of external terminals Parameter When Pr. 495 = "0" (initial value) or "10", performing a power supply reset (including a power failure) clears the REM signal output. (The ON/OFF states of the terminals are as set in Pr. 190, Pr.
Page 259: Monitor Display And Monitor Output Signals
Parameter Monitor display and monitor output signals 6.10 Monitor display and monitor output signals Refer to Purpose Parameters that must be set Section Display motor speed Speed display and speed setting Pr. 37 6.10.1 Set speed Change PU monitor display data Monitor display/ Pr.
Page 260 Monitor display and monitor output signals Parameter Output Frequency Set Frequency Pr. 37 Frequency Setting Parameter Setting Monitor Monitor (initial value) 0.01–9998 Machine speed Machine speed Machine speed Tab. 6-18: Setting range of parameter 37 Machine speed conversion formula: Pr. 37 × frequency/60Hz Hz is displayed in 0.01Hz increments and machine speed is in 0.001.
Page 261: Monitor Display Selection Of Du/Pu And Terminal Am (Pr. 52 Pr. 158, Pr. 170, Pr. 171, Pr. 268, Pr. 563, Pr. 564, Pr. 891)
Parameter Monitor display and monitor output signals 6.10.2 Monitor display selection of DU/PU and terminal AM (Pr. 52, Pr. 158, Pr. 170, Pr. 171, Pr. 268, Pr. 563, Pr. 564, Pr. 891) The monitor to be displayed on the main screen of the control panel and parameter unit (FR-PU04/FR-PU07) can be selected.
Page 262 Monitor display and monitor output signals Parameter Monitor description list (Pr. 52) ● Set the monitor to be displayed on the operation panel and parameter unit (FR-PU04/ FR-PU07) in Pr. 52. ● Set the monitor to be output to the terminal AM (analog output (0 to 10V DC voltage output)) in Pr.
Page 263 Parameter Monitor display and monitor output signals Pr. 52 Terminal AM Opera- Types of Monitor Unit Pr. 158 (AM) Description Full Scale Value tion Main panel Monitor Adds up and displays the inverter operation time. You can check the numbers of Actual operation —...
Page 264 Monitor display and monitor output signals Parameter NOTES By setting "0" in Pr. 52, the monitoring of output speed to alarm display can be selected in sequence by the SET key. When the operation panel is used, the displayed units are Hz and A only and the others are not displayed.
Page 265 Parameter Monitor display and monitor output signals Display set frequency during stop (Pr. 52) When "100" is set in Pr. 52, the set frequency and output frequency are displayed during stop and operation respectively. LED of Hz flickers during stop and is lit during operation. Parameter 52 During running/stop During stop...
Page 266 Monitor display and monitor output signals Parameter Operation panel I/O terminal monitor When Pr. 52 is set to "55", the I/O terminal states can be monitored on the operation panel. The I/O terminal monitor is displayed on the third monitor. The LED is on when the terminal is on, and the LED is off when the terminal is off.
Page 267 Parameter Monitor display and monitor output signals Cumulative energizing time and actual operation time monitor (Pr. 171, Pr. 563, Pr. 564) Cumulative energization time monitor (Pr. 52 = "20") accumulates energization time from ship- ment of the inverter every one hour. On the actual operation time monitor (Pr.
Page 268 Monitor display and monitor output signals Parameter 6.10.3 Reference of the terminal AM (analog voltage output) (Pr. 55, Pr. 56) Analog voltage output from the terminal AM is available. Set the reference of the signal output from terminal AM. Initial Setting Refer to Name...
Page 269 Parameter Monitor display and monitor output signals Current monitoring reference (Pr. 56) Set the current to be referenced when the current monitor (inverter output current, etc.) is se- lected for terminal AM display. Set the full scale value when outputting the current monitor from terminal AM.
Page 270: Terminal Am Calibration [C1 (Pr.901)]
Monitor display and monitor output signals Parameter 6.10.4 Terminal AM calibration [C1 (Pr.901)] By using the operation panel or parameter unit, you can calibrate terminal AM to full scale de- flection. Initial Setting Refer to Pr. No. Name Description Parameters referred to Value Range Section...
Page 271 Parameter Monitor display and monitor output signals Calibrate the terminal AM gain in the following procedure: Connect an 0–10V DC voltmeter to inverter terminals AM and 5, taking care to correct with the correct polarity. AM is positive. Set Pr. 158 to select the monitor signal you want to output to analog output AM (refer to page 6-118).
Page 272 Monitor display and monitor output signals Parameter How to calibrate the terminal AM when using the operation panel The following example shows how to calibrate the maximum value of the AM terminal to the 50Hz output frequency. This operation is performed in PU mode. Operation Display (When Pr.
Page 273 Parameter Operation selection at power failure 6.11 Operation selection at power failure Refer to Purpose Parameters that must be set Section At instantaneous power failure Automatic restart operation after instanta- Pr. 30, Pr. 57, 6.11.1 occurrence, restart inverter without neous power failure/flying start Pr.
Page 274 Operation selection at power failure Parameter Initial Setting Refer to Name Description Parameters referred to Value Range Section The motor starts at the starting fre- Acceleration time 6.6.1 quency when MRS (X10) turns on then Starting frequency 6.6.2 Regenerative function off.
Page 275 Parameter Operation selection at power failure Automatic restart after instantaneous power failure operation (Pr. 30, Pr. 162, Pr. 299) ● Without frequency search When Pr. 162 = "1" (initial value) or "11", automatic restart operation is performed in a reduced voltage system, where the voltage is gradually risen with the output frequency unchanged from prior to an instantaneous power failure independently of the coasting speed of the motor.
Page 276 Operation selection at power failure Parameter ● With frequency search When "0 (initial value) or 10" is set in Pr. 162, the inverter smoothly starts after detecting the motor speed upon power restoration. (The motor capacity should be equal to or one rank lower than the inverter capacity.) When using the frequency search, perform offline autotuning.
Page 277 Parameter Operation selection at power failure NOTES Speed detection time (frequency search) changes according to the motor speed (maximum 100ms). Frequency search errors can occur if the output capacity of the frequency inverter is one or more classes higher than that of the motor or if the motor is a special model (e.g. with a fre- quency rating above 60Hz).
Page 278 Operation selection at power failure Parameter ● Restart operation at every start When Pr. 162 = "10" or "11", automatic restart operation is also performed every start, in addition to the automatic restart after instantaneous power failure. When Pr. 162 = "0", automatic restart operation is performed at the first start after power supply-on, but not performed at the second time or later.
Page 279 Parameter Operation selection at power failure Frequency search gain (Pr. 298), offline auto tuning (Pr. 96) When automatic restart after instantaneous power failure operation (with frequency search) is valid at V/f control, perform offline auto tuning. Perform offline auto tuning during V/f control in the following order to set Pr.
Page 280 Operation selection at power failure Parameter Execution of tuning CAUTION: Before performing tuning, check the monitor display of the operation panel or parameter unit (FR-PU04/FR-PU07) if the inverter is in the status for tuning. (Refer to Tab. 6-9). When performing tuning or PU operation, press the RUN key of the operation panel. Start the tuning in external operating mode by connecting the STF or STR terminal with the PC terminal (positive logic) or the SD terminal (negative logic).
Page 281 Parameter Operation selection at power failure Monitor display during auto tuning Monitor is displayed on the operation panel and parameter unit (FR-PU04/FR-PU07) during tun- ing as below. The value displayed corresponds to the value of parameter 96. Parameter Unit Operation Panel Indication (FR-PU04/FR-PU07) Display Pr.
Page 282 Operation selection at power failure Parameter If offline auto tuning ended in error (see the table below), frequency search gain are not set. Per- form an inverter reset and restart tuning. Error Display Error Cause Remedy Force end Set "21" in Pr. 96 and perform tuning again. Inverter protective function operation Make setting again.
Page 283 Parameter Operation selection at power failure CAUTION: Before activating the automatic restart after power failure function please make sure that this mode is supported for the drive and permitted for your configuration. 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.
Page 284: Power Failure-Time Deceleration-To-Stop Function (Pr. 261)
Operation selection at power failure Parameter 6.11.2 Power failure-time deceleration-to-stop function (Pr. 261) When a power failure or under voltage occurs, the inverter can be decelerated to a stop or can be decelerated and re-accelerated to the set frequency. Initial Setting Refer to Name...
Page 285 Parameter Operation selection at power failure Power failure stop mode (Pr. 261 = 1) If power is restored during power failure deceleration, deceleration to a stop is continued and the inverter remains stopped. To restart, turn off the start signal once, then turn it on again. Power supply During deceleration at...
Page 286 Operation selection at power failure Parameter Operation continuation at instantaneous power failure function (Pr. 261 = 2) When power is restored during deceleration after a power failure, acceleration is made again up to the set frequency. Pr. 261 = 2 When power is restored during deceleration.
Page 287 Parameter Operation selection at power failure Power failure deceleration signal (Y46 signal) The Y46 signal is on during deceleration at an instantaneous power failure or during a stop after deceleration at an instantaneous power failure. After a power failure stop, the inverter can not start even if power is restored the start command is given.
Page 288: Operation Setting At Alarm Occurrence
Operation setting at alarm occurrence Parameter 6.12 Operation setting at alarm occurrence Refer to Purpose Parameters that must be set section Recover by retry operation at alarm Retry operation Pr. 65, 6.12.1 occurrence Pr. 67–Pr. 69 Do not input/output phase failure Input/output phase failure protection Pr.
Page 289 Parameter Operation setting at alarm occurrence Retry operation automatically resets a fault and restarts the inverter at the starting frequency when the time set in Pr. 68 elapses after the inverter is tripped. Retry operation is performed by setting Pr. 67 to any value other than "0". Set the number of re- tries at fault occurrence in Pr.
Page 290 Operation setting at alarm occurrence Parameter Using Pr. 65 you can select the alarm that will cause a retry to be executed. No retry will be made for the alarm not indicated. Alarm Parameter 65 Setting Display Name for Retry ✔...
Page 291: Input/Output Phase Failure Protection Selection (Pr. 251, Pr. 872)
Parameter Operation setting at alarm occurrence 6.12.2 Input/output phase failure protection selection (Pr. 251, Pr. 872) You can choose whether to make Input/output phase loss protection valid or invalid. You can disable the output phase failure function that stops the inverter output if one of the in- verter output side (load side) three phases (U, V, W) opens.
Page 292: Earth (Ground) Fault Detection At Start (Pr. 249)
Operation setting at alarm occurrence Parameter 6.12.3 Earth (ground) fault detection at start (Pr. 249) You can choose whether to make earth (ground) fault detection at start valid or invalid. Earth (Ground) fault detection is executed only right after the start signal is input to the inverter. Protective function will not activate if an earth (ground) fault occurs during operation.
Page 293: Energy Saving Operation
Parameter Energy saving operation 6.13 Energy saving operation Refer to Purpose Parameters that must be set Section Energy saving operation Energy saving operation and optimum Pr. 60 6.13.1 excitation control 6.13.1 Optimum excitation control (Pr. 60) Without a fine parameter setting, the inverter automatically performs energy saving operation. This inverter is optimum for fan and pump applications.
Page 294: Motor Noise, Emi Measures, Mechanical Resonance
Motor noise, EMI measures, mechanical resonance Parameter 6.14 Motor noise, EMI measures, mechanical resonance Refer to Purpose Parameters that must be set Section Reduction of the motor noise Carrier frequency and Soft-PWM selection Pr. 72, Pr. 240, 6.14.1 Measures against EMI and leakage Pr.
Page 295 Parameter Motor noise, EMI measures, mechanical resonance PWM carrier frequency automatic reduction function (Pr. 260) When Pr. 260 = "0" (initial value), the carrier frequency becomes constant (Pr. 72 setting) independently of the load, making the motor sound uniform. When continuous operation is performed at 85% or more of the inverter rated current with the carrier frequency of the inverter set to 3kHz or more (Pr.72 ≥...
Page 296: Speed Smoothing Control (Pr. 653)
Motor noise, EMI measures, mechanical resonance Parameter 6.14.2 Speed smoothing control (Pr. 653) Vibration due to mechanical resonance influences the inverter control, causing the output cur- rent (torque) unstable. In this case, the output current (torque) fluctuation can be reduced to ease vibration by changing the output frequency.
Page 297: Frequency Setting By Analog Input (Terminal 2, 4)
Parameter Frequency setting by analog input (terminal 2, 4) 6.15 Frequency setting by analog input (terminal 2, 4) Refer to Purpose Parameters that must be set Section Selection of voltage/current input Analog input selection Pr. 73, Pr. 267 6.15.1 (terminal 2, 4) Perform forward/reverse rotation by analog input.
Page 298 Frequency setting by analog input (terminal 2, 4) Parameter Selection of analog input specifications For the terminal 2 for analog voltage input, 0 to 5V (initial value) or 0 to 10V can be selected. Ei- ther voltage input (0 to 5V, 0 to 10V) or current input (4 to 20mA initial value) can be selected for terminal 4 used for analog input.
Page 299 Parameter Frequency setting by analog input (terminal 2, 4) Refer to the following table and set Pr. 73 and Pr. 267. The half-tone screened areas indicate the main speed setting. Terminal 4 Pr. 73 Terminal 2 Polarity Reversible AU Signal 0–10V (initial 0–5V...
Page 300 Frequency setting by analog input (terminal 2, 4) Parameter Perform operation by analog input voltage The frequency setting signal inputs 0 to 5V DC (or 0 to 10V DC) to across the terminals 2-5. The 5V (10V) input is the maximum output frequency. The power supply 5V can be input by either using the internal power supply or preparing an external power supply.
Page 301 Parameter Frequency setting by analog input (terminal 2, 4) Perform operation by analog input current When the pressure or temperature is controlled constant by a fan, pump, etc., automatic operation can be performed by inputting the output signal 0/4 to 20mA of the adjuster to across the terminals 4-5.
Page 302: Input Filter Time Constant (Pr. 74)
Frequency setting by analog input (terminal 2, 4) Parameter 6.15.2 Input filter time constant (Pr. 74) If the set point signal (terminal 2 or 4) is an unstable signal or contains noise you can filter out the instability or noise by increasing the setting value of Pr. 74. Initial Setting Refer to...
Page 303: Pr. 125, Pr. 126, Pr. 241, C2 (Pr. 902) To C7 (Pr. 905)]
Parameter Frequency setting by analog input (terminal 2, 4) 6.15.3 Bias and gain of frequency setting voltage (current) [Pr. 125, Pr. 126, Pr. 241, C2 (Pr. 902) to C7 (Pr. 905)] You can set the magnitude (slope) of the output frequency as desired in relation to the frequency setting signal (0 to 5V DC, 0 to 10V DC or 0/4 to 20mA DC).
Page 304 Frequency setting by analog input (terminal 2, 4) Parameter Change the frequency at maximum analog input (Pr. 125, Pr. 126) Set a value to Pr. 125 (Pr. 126) when changing only the frequency setting (gain) of the maximum analog input power (current). (C2 (Pr. 902) to C7 (Pr. 905) setting need not be changed.) Analog input bias/gain calibration [C2 (Pr.
Page 305 Parameter Frequency setting by analog input (terminal 2, 4) Initial value 50Hz Gain Pr. 125 Bias (Pr. 902) 100% Frequency setting signal C3 (Pr. 902) C4 (Pr. 903) I001191E Fig. 6-83: Signal adjustment of terminal 2 Initial value 50Hz Gain Pr. 126 Bias (Pr.
Page 306 Frequency setting by analog input (terminal 2, 4) Parameter Analog input display unit changing (Pr. 241) The level display for the analog signal connected to terminal 2 or terminal 4 can be switched between a % display and a display in V or mA. Depending on the terminal input specification set to Pr.
Page 307 Parameter Frequency setting by analog input (terminal 2, 4) Frequency setting signal (current) bias/gain adjustment method 1. Method to adjust any point by application of voltage (current) to across the terminals 2-5 (4-5). The following example illustrating the procedure assumes that Pr. 241 is set to "0": Operation Display Confirmation of the RUN indication and...
Page 308 Frequency setting by analog input (terminal 2, 4) Parameter 2. Method to adjust any point without application of a voltage (current) to across terminals 2-5 (4-5). (This example shows how to change from 4V to 5V, assuming that Pr. 241 is set to "1".) Operation Display Confirmation of the RUN indication and...
Page 309 Parameter Frequency setting by analog input (terminal 2, 4) 3. Method to adjust only the frequency without adjustment of a gain voltage (current). (The gain frequency is changed from 50Hz to 40Hz.) Operation Display Turn the digital dial until P.125 (Pr. 125) or P.126 (Pr.
Page 310: Misoperation Prevention And Parameter Setting Restriction
Misoperation prevention and parameter setting restriction Parameter 6.16 Misoperation prevention and parameter setting restriction Refer to Purpose Parameters that must be set Section Limit reset function Reset selection/ Pr. 75 6.16.1 Make alarm stop when PU is disconnected PU detection/ disconnected PU stop selection Stop from PU...
Page 311 Parameter Misoperation prevention and parameter setting restriction Reset selection You can select the enable condition of reset function (RES signal, reset command through com- munication) input. When Pr. 75 is set to any of "1, 3, 15, 17", a reset can be input only when the inverter is tripped. NOTES When the reset signal (RES) is input during operation, the motor coasts since the inverter being reset shuts off the output.
Page 312 Misoperation prevention and parameter setting restriction Parameter PU stop selection In any of the PU operation, external operation and network operation modes, the motor can be stopped by pressing the STOP key of the PU. When the inverter is stopped by the PU stop function (refer to section 4.3 "Operation panel") in the external operation mode, "PS"...
Page 313 Parameter Misoperation prevention and parameter setting restriction Restarting method when stop was made by pressing the STOP key from the PU during external operation ("PS" is displayed) Operation panel After the motor has decelerated to a stop, turn off the STF or STR signal. Press the PU/EXT key to change to the PU operation mode.
Page 314 Misoperation prevention and parameter setting restriction Parameter Restart (PS reset) method when PU stop (PS display) is made during PU operation PU stop ("PS" display) is made when the motor is stopped from the unit where control command source is not selected (operation panel, parameter unit (FR-PU04/FR-PU07 or FR-PA02) in the PU operation mode.
Page 315: Parameter Write Selection (Pr. 77)
Parameter Misoperation prevention and parameter setting restriction 6.16.2 Parameter write selection (Pr. 77) You can select whether write to various parameters can be performed or not. Use this function to prevent parameter values from being rewritten by misoperation. Initial Setting Refer to Name Description...
Page 316 Misoperation prevention and parameter setting restriction Parameter Write parameters during operation (Pr. 77 = 2) Parameters can always be written. The following parameters cannot be written during operation if Pr. 77 = 2. Stop operation when changing their parameter settings. Parameter Name Stall prevention operation level compensation factor at double speed...
Page 317: Reverse Rotation Prevention Selection (Pr. 78)
Parameter Misoperation prevention and parameter setting restriction 6.16.3 Reverse rotation prevention selection (Pr. 78) In some applications (fans, pumps) it is necessary to ensure that the motor cannot be reversed. This can be achieved with Pr. 78. Initial Setting Refer to Name Description Parameters referred to...
Page 318: Extended Parameter Display (Pr. 160)
Misoperation prevention and parameter setting restriction Parameter 6.16.4 Extended parameter display (Pr. 160) Parameter 160 allows access to certain parameters via the control panel and the parameter unit Initial Setting Refer to Name Description Parameters referred to Setting Range Section Displays only the simple mode parame- Jog frequency 6.5.2...
Page 319: Password Function (Pr. 296, Pr. 297)
Parameter Misoperation prevention and parameter setting restriction 6.16.5 Password function (Pr. 296, Pr. 297) Registering 4-digit password can restrict parameter reading/writing. Initial Refer to Name Setting Range Description Parameters referred to Setting Section Select restriction level of parameter Parameter write 6.16.2 1–6/101–106 reading/ writing when a password is...
Page 320 Misoperation prevention and parameter setting restriction Parameter Password lock/unlock (Pr. 296, Pr. 297) ● Lock Set parameter reading/writing restriction level (Pr. 296 ≠ 9999). Restriction of Password Pr. 296 Pr. 297 Display Unlock Error 1 to 6 No restriction Always „0“ Displays error count 101 to 106 Restricted at fifth error...
Page 321 Parameter Misoperation prevention and parameter setting restriction Parameter operation during password lock/unlock Password Unlocked Locked registered Parameter operation Pr. 296 ≠ 9999 Pr. 296 = 101–106 Pr. 296 ≠ 9999 Pr. 296 = 9999 Pr. 297 = 0–4 Pr. 297 = 5 Pr.
Page 322: Selection Of Operation Mode And Operation Location
Selection of operation mode and operation location Parameter 6.17 Selection of operation mode and operation location Refer to Purpose Parameters that must be set Section Operation mode selection Operation mode selection Pr. 79 6.17.1 Started in network operation mode Operation mode at power on Pr.
Page 323 Parameter Selection of operation mode and operation location Operation mode basics The operation mode is to specify the source of inputting the start command and set frequency of the inverter. ● Select the "external operation mode" when performing operation by basically using the control circuit terminals and providing potentiometers, switches, etc.
Page 324 Selection of operation mode and operation location Parameter Switching the operation mode External operation Switching from the PU Switching from the network Press Switch to the external operation mode from the the PU to light Press network. Switch to the network operation mode from the network.
Page 325 Parameter Selection of operation mode and operation location Operation mode selection flow In the following flowchart, select the basic parameter setting and terminal connection related to the operation mode: START Connection Parameter Setting Operation Where is the start command source? From external (STF/STR terminal) Where is the frequency set? From external (Terminal 2, 4,...
Page 326 Selection of operation mode and operation location Parameter External operation mode (Pr. 79 = 0, 2) Select the external operation mode when performing operation by providing a frequency setting potentiometer, start switch, etc. externally and connecting them to the control circuit terminals of the inverter.
Page 327 Parameter Selection of operation mode and operation location PU operation mode (Pr. 79 = 1) Select the PU operation mode when applying start and speed command by only the key oper- ation of the operation panel (FR-PU04/FR-PU07). Also select the PU operation mode when making communication using the PU connector.
Page 328 Selection of operation mode and operation location Parameter PU/external combined operation mode 1 (Pr. 79 = 3) Select the PU/external combined operation mode 1 when applying frequency command from the operation panel or parameter unit (FR-PU04/FR-PU07) and inputting the start command with the external start switch.
Page 329 Parameter Selection of operation mode and operation location Switch-over mode (Pr. 79 = 6) While continuing operation, you can switch between the PU operation, external operation and network operation (NET operation). Operation Mode Switching Switching Operation/Operating Status External operation ⇒ PU operation Select the PU operation mode with the operation panel or parameter unit.
Page 330 Selection of operation mode and operation location Parameter PU operation interlock (Pr. 79 = 7) The PU operation interlock function is designed to forcibly change the operation mode to ex- ternal operation mode when the PU operation interlock signal (X12) input turns off. This function prevents the inverter from being inoperative by the external command if the mode is accidentally left unswitched from the PU operation mode.
Page 331 Parameter Selection of operation mode and operation location Switching of operation mode by external terminal (X16) When external operation and operation from the operation panel are used together, use of the PU-external operation switching signal (X16) allows switching betwen the PU operation mode and external operation mode during a stop (during a motor stop, start command off).
Page 332 Selection of operation mode and operation location Parameter Switching of operation mode by external terminal (X65, X66) When Pr. 79 = any of "0, 2, 6", the operation mode switching signals (X65, X66) can be used to change the PU or external operation mode to network operation mode during a stop (during a motor stop or start command off).
Page 333 Parameter Selection of operation mode and operation location When switching from network operation mode to external operation mode: Set Pr. 79 to "0" (initial value), "2", "6" or "7". (At the Pr. 79 setting of "7", the operation mode can be switched when the X12 (MRS) signal turns on.) Set "0"...
Page 334: Operation Mode At Power On (Pr. 79, Pr. 340)
Selection of operation mode and operation location Parameter 6.17.2 Operation mode at power on (Pr. 79, Pr. 340) When power is switched on or when power comes back on after instantaneous power failure, the inverter can be started up in network operation mode. After the inverter has started up in the network operation mode, parameter write and operation can be performed from a program.
Page 335 Parameter Selection of operation mode and operation location Specify operation mode at power on (Pr. 340) Depending on the Pr. 79 and Pr. 340 settings, the operation mode at power on (reset) changes as described below: Operation Mode at Power on, Power Pr.
Page 336: Start Command Source And Frequency Command Source During Communication Operation (Pr. 338, Pr. 339, Pr. 551)
Selection of operation mode and operation location Parameter 6.17.3 Start command source and frequency command source during communication operation (Pr. 338, Pr. 339, Pr. 551) When the RS485 communication with the PU connector or communication option is used, the external start command and frequency command can be made valid. Command source in the PU operation mode can be selected.
Page 337 Parameter Selection of operation mode and operation location Selects the command source of the PU operation mode (Pr. 551) Any of the operation panel or PU connector can be specified as the command source in the PU operation mode. In the PU operation mode, set Pr. 551 to "2" when executing parameter write, start command or frequency command during the RS485 communication with PU connector.
Page 338 Selection of operation mode and operation location Parameter Controllability through communication Operation Mode Oper- External/PU External/PU ation Condition combined combined Command External Loca- (Pr. 551) PU Operation Operation Operation NET Operation Operation tion Mode 1 Mode 2 (Pr. 79 = 3) (Pr.
Page 339 Parameter Selection of operation mode and operation location Operation at alarm occurrence Operation Mode External/PU External/PU Condition combined combined Alarm Definition External (Pr. 551) PU Operation Operation Operation Operation Operation Mode 1 Mode 2 (Pr. 79 = 3) (Pr. 79 = 4) Inverter fault —...
Page 340 Selection of operation mode and operation location Parameter Selection of control source in network operation mode (Pr. 338, Pr. 339) As control sources, there are the operation command source that controls the signals related to the inverter start command and function selection and the speed command source that controls the signals related to frequency setting.
Page 341 Parameter Selection of operation mode and operation location Communication Operation 0: NET 1: External Command Source (Pr. 338) Operation Location Remarks Communication Speed Command Selection 0: NET Exter- Exter- 0: NET Exter- Exter- Source (Pr. 339) Pr. 79 ≠ 7 Output stop Combined External...
Page 342 Selection of operation mode and operation location Parameter Switching of command source by external terminal (X67) In the network operation mode, the command source switching signal (X67) can be used to switch the start command source and speed command source. Set "67"...
Page 343: Communication Operation And Settings
Parameter Communication operation and settings 6.18 Communication operation and settings Refer to Purpose Parameters that must be set Section Communication operation from Initial setting of computer link Pr. 117–Pr. 124 6.18.2 PU connector communication (PU connector) Modbus-RTU communication Pr. 117, Pr. 118, 6.18.6 specification Pr.
Page 344 Communication operation and settings Parameter PU connector communication system configuration and wiring ● Connecting the PU to the inverter Fig. 6-97: Inverter Connecting the PU to the PU connector connector FR-PU07 RJ-45-connector FR-A5CBL I001829E ● Connecting a computer to a single inverter Fig.
Page 345 Parameter Communication operation and settings ● Combination of computer and multiple inverters Station 0 Station 1 Station n connector connector connector RS485 interface Distributor Distributor Distributor Terminating resistor FR-A5CBL FR-A5CBL BUS System Distributor FR-RJ45-HUB10 Inverter Inverter RJ-45 RJ-45 Inverter 1 Inverter Inverter connector...
Page 346 Communication operation and settings Parameter Connection with RS485 computer ● Wiring of one RS485 computer and one inverter Inverter PU connector Computer side terminals Cable connection and signal direction Receive data Receive data Send data Send data 0,2 mm² or more Signal ground I001938E Fig.
Page 347 Parameter Communication operation and settings Two-wire type connection If the computer is 2-wire type, a connection from the inverter can be changed to 2-wire type by passing wires across reception terminals and transmission terminals of the PU connector pin. Fig. 6-103: Inverter Two-wire type connection Transmission...
Page 348 Communication operation and settings Parameter 6.18.2 Initial settings and specifications of RS485 communication (Pr. 117 to Pr. 120, Pr. 123, Pr. 124, Pr. 549) Used to perform required settings for RS485 communication between the inverter and personal computer. Use PU connector of the inverter for communication. ●...
Page 349 Parameter Communication operation and settings 6.18.3 Operation selection at communication error occurrence (Pr. 121, Pr. 122, Pr. 502) Initial Setting Refer to Name Description Parameters referred to Value Range Section Number of retries at data receive error occurrence Acceleration time 6.6.1 If the number of consecutive errors exceeds the permissi- Deceleration time...
Page 350 Communication operation and settings Parameter Retry count setting (Pr.121) Set the permissible number of retries at data receive error occurrence. (Refer to page 6-211 for data receive error for retry.) When data receive errors occur consecutively and exceed the permissible number of retries set, an inverter trips (E.PUE) and a motor stops (as set in Pr.
Page 351 Parameter Communication operation and settings Signal loss detection (Pr. 122) If a signal loss (communication stop) is detected between the inverter and master as a result of a signal loss detection, a communication fault (E.PUE) occurs and the inverter trips (as set in Pr.
Page 352 Communication operation and settings Parameter Stop operation selection at occurrence of communication fault (Pr. 502) Stop operation when retry count excess (Mitsubishi inverter protocol only) or signal loss detec- tion error occurs can be selected. Pr. 502 Operation Indication Fault Output 0 (initial value) Coasts to stop.
Page 353 Parameter Communication operation and settings Fig. 6-108: Fault Fault removal occurrence Operation when Pr. 502 setting is "2" Communication fault Decelerates to stop Time Fault display Display (E.PUE) Fault output (ALM) I001836E NOTES The fault output indicates fault output signal (ALM signal) or alarm bit output. When the setting was made to provide a fault output, the fault description is stored into the faults history.
Page 354: Communication E²Prom Write Selection (Pr. 342)
Communication operation and settings Parameter 6.18.4 Communication E²PROM write selection (Pr. 342) When parameter write is performed from the inverter PU connector parameters storage device can be changed from E²PROM + RAM to RAM only. When changing the parameter values fre- quently, set "1"...
Page 355: Mitsubishi Inverter Protocol (Computer Link Communication)
Parameter Communication operation and settings 6.18.5 Mitsubishi inverter protocol (computer link communication) You can perform parameter setting, monitor, etc. from the PU connector of the inverter using the Mitsubishi inverter protocol (computer link communication). Communication specifications Related Item Description Parameters Communication protocol Mitsubishi protocol (computer link) Pr.
Page 356 Communication operation and settings Parameter Communication procedure Data communication between the computer and inverter is made in the following procedure: Computer When data is read ⇓ Data flow Inverter Inverter ⇓ Data flow Computer When data is written I000030C Fig. 6-109: Schematic diagram of data exchange If a data error is detected and a retry must be made, execute retry operation with the user program.
Page 357 Parameter Communication operation and settings ● Data writing format Communication request data from the computer to the inverter Number of Characters Format Inverter Instruction station Data code check number Inverter Instruction station Data code check number Inverter Instruction station Data code check number...
Page 358 Communication operation and settings Parameter ● Data reading format Communication request data from the computer to the inverter Number of Characters Format Inverter Waiting Instruction station Sum check code time number Reply data from the inverter to the computer (no data error detected) Number of Characters Format Inverter...
Page 359 Parameter Communication operation and settings Data definitions ● Control codes Signal Name ASCII Code 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) Tab.
Page 360 Communication operation and settings Parameter ● 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. Example 1 Binary code Station Instruction Data check number...
Page 361 Parameter Communication operation and settings ● 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. Inverter Error Error Item Error Definition Code Operation The number of errors consecutively detected in commu- Computer NAK error...
Page 362 Communication operation and settings Parameter ● Response time Data sending time (Refer to the following formula) Inverter data processing time = Waiting time Data check time (setting × 10ms) (Depends on the Computer instruction code (see Tab. 6-56)) ⇓ Data flow Inverter Time Inverter...
Page 363 Parameter Communication operation and settings Instructions for the program When data from the computer has any error, the inverter does not accept that data. Hence, in the user program, always insert a retry program for data error. All data communication, e.g. run command or monitoring, are started when the computer gives a communication request.
Page 364 Communication operation and settings Parameter Port open Communication setting Time out setting Send data processing Data setting Sum code calculation Data transmission Receive data waiting Receive data processing Data retrieval Screen display Fig. 6-114: General flowchart NOTES Always set the communication check time interval before starting operation to prevent haz- ardous conditions.
Page 365 Parameter Communication operation and settings Setting items and set data After completion of parameter setting, set the instruction codes and data then start communi- cation from the computer to allow various types of operation control and monitoring. Number Read/ Instruction of Data Item Data Description...
Page 366 Communication operation and settings Parameter Number Read/ Instruction of Data Item Data Description Code Digits Write (Format) Set frequency (RAM) Read set frequency/speed from RAM or E²PROM. H0000 to HFFFF: Set frequency in 0.01Hz increments (B, E/D) Read Speed increments 1/0.001 Set frequency (E²PROM) (when Pr.
Page 367 Parameter Communication operation and settings Number Read/ Instruction of Data Item Data Description Code Digits Write (Format) Refer to the instruction code of the parameter (B, E/D) list (appendix) and write and/or read parame- Read H00 to H63 ter values as required. (B, E2/D) When setting Pr.
Page 368 Communication operation and settings Parameter Example When reading the C3 (Pr. 902) and C6 (Pr. 904) settings from the inverter of station No. 0. Computer Send Data Inverter Send Data Description Set "H01" to the extended link parameter. ENQ 00 FF 0 01 82 ACK 00 Set "H01"...
Page 369 Parameter Communication operation and settings ● Special monitor selection numbers. Refer to section 6.10.2 for details of the monitor description. Data Description Unit Data Description Unit 0.01Hz — Output frequency/speed Output terminal status 0.001 Output current 0.01A Cumulative energization time Output voltage 0.1V Actual operation time...
Page 370 Communication operation and settings Parameter ● Fault data Refer to section 7.1 for details of alarm description. Data Description Data Description Data Description No fault present E.FIN E.PUE E.OC1 E.ILF E.RET E.OC2 E.OLT E.CPU E.OC3 E.BE E.CDO E.OV1 E.GF E.IOH E.OV2 E.LF E.AIE...
Page 371 Parameter Communication operation and settings ● Run command Instruction Item Bits Description Example Code b0: AU (current input selection) Example 1: H02 (Forward rotation) b1: Forward rotation start b2: Reverse rotation start b3: RL (low speed) command b4: RM (middle speed) Example 2: H00 (Stop) b5: RH (high speed) b6: RT (second function...
Page 372 Communication operation and settings Parameter ● Inverter status monitor Instruction Item Bits Description Example Code b0: RUN (inverter running) Example 1: H02 (During forward rotation) b1: Forward rotation b2: Reverse rotation Inverter b3: SU (up to frequency) status b4: OL (overload) Example 2: H80 (Stop at alarm occurrence) monitor b5: —...
Page 373 Parameter Communication operation and settings ● Multi command HF0 Sending data format from computer to inverter Number of Characters Format Inverter Instruc- Wai- Send ceive station tion code Data 1 Data 2 ting data data check time type number (HF0) type Reply data from the inverter to the computer (no data error detected) Number of Characters...
Page 374 Communication operation and settings Parameter 6.18.6 Modbus-RTU communication (Pr. 117, Pr. 118, Pr. 120, Pr. 122, Pr. 343, Pr. 549) Using the Modbus RTU communication protocol, communication operation or parameter setting can be performed from the PU connector of the inverter. Initial Setting Refer to...
Page 375 Parameter Communication operation and settings Communication specifications Related Item Description Parameters Communication protocol Modbus-RTU protocol Pr. 549 Conforming standard EIA-485 (RS485) — Number of inverters connected 1 : N (maximum 32 units), setting is 0 to 247 stations Pr. 117 Communication speed Can be selected from 4800/9600/19200 and 38400bps Pr.
Page 376 Communication operation and settings Parameter Outline The Modbus protocol is the communication protocol developed by Modicon for PLC. The Modbus protocol performs serial communication between the master and slave using the dedicated message frame. The dedicated message frame has the functions that can perform data read and write.
Page 377 Parameter Communication operation and settings Message frame (protocol) Communication method Basically, the master sends a query message (question) and the slave returns a response mes- sage (response). When communication is normal, Device Address and Function Code are cop- ied as they are, and when communication is abnormal (function code or data code is illegal), bit 7 (= 80h) of Function Code is turned on and the error code is set to Data Bytes.
Page 378 Communication operation and settings Parameter Message format types The message formats corresponding to the function codes in Tab. 6-68 will be explained. ● Read holding register data (H03 or 03) Can read the description of system environment variables, real-time monitor, alarm history, and inverter parameters assigned to the holding register area.
Page 379 Parameter Communication operation and settings Example To read the register values of 41004 (Pr. 4) to 41006 (Pr. 6) from the slave address 17 (H11). Query message Slave Function Starting Address No. of Points CRC Check Address (8 bits) (8 bits) (8 bits) (8 bits) (8 bits)
Page 380 Communication operation and settings Parameter ● Write multiple holding register data (H06 or 06) You can write the description of system environment variables and inverter parameters assigned to the holding register area. (Refer to the register list on page 6-236). Query message Slave Function...
Page 381 Parameter Communication operation and settings ● Function diagnosis (H08 or 08) A communication check can be made since the query message sent is returned unchanged as a response message (function of subfunction code H00). Subfunction code H00 (Return Query Data). Query message Slave Function...
Page 382 Communication operation and settings Parameter ● Write multiple holding register data (H10 or 16) You can write data to multiple holding registers. Query message Slave Func- Starting No. of Byte Data CRC Check Address tion Address Registers Count (8 Bits) n ×...
Page 383 Parameter Communication operation and settings ● Read holding register access log (H46 or 70) A response can be made to a query made by the function code H03 or H10. The starting address of the holding registers that succeeded in access during previous communication and the number of successful registers are returned.
Page 384 Communication operation and settings Parameter ● Error response An error response is returned if the query message received from the master has an illegal function, address or data. No response is returned for a parity, CRC, overrun, framing or busy error. NOTE No response message is sent in the case of broadcast communication also.
Page 385 Parameter Communication operation and settings To detect the mistakes of message data from the master, they are checked for the following er- rors. If an error is detected, an alarm stop will not occur. Error Item Error Definition Inverter Side Operation The data received by the inverter differs from Parity error the specified parity (Pr.
Page 386 Communication operation and settings Parameter Modbus registers ● System environment variable Register Definition Read/Write Remarks 40002 Inverter reset Write Any value can be written 40003 Parameter clear Write Set H965A as a written value. 40004 All parameter clear Write Set H99AA as a written value. 40006 Write Set H5A96 as a written value.
Page 387 Parameter Communication operation and settings Definition Control Input Instruction Inverter Status Stop command RUN (inverter running) Forward rotation command Forward rotation Reverse rotation command Reverse rotation SU (up to frequency) RH (high speed operation command) OL (overload) RM (middle speed operation command) RL (low speed operation command) FU (frequency detection) RT (second function selection)
Page 388 Communication operation and settings Parameter ● Real-time monitor Refer to section 6.10.2 for details of the monitor description. Register Description Unit Register Description Unit Output frequency/ Cumulative 40201 0.01Hz/1 40220 Speed energizing time 40202 Output current 0.01A 40223 Actual operation time 40203 Output voltage 0.1V...
Page 389 Parameter Communication operation and settings ● Parameter Parameters Register Parameter Name Read/Write Remarks Refer to the parameter list The parameter number + 41000– 0–999 (Tab. 6-1) for the parameter Read/write 41999 41000 is the register number. names. Terminal 2 frequency setting bias C2 (902) 41902 Read/write...
Page 390 Communication operation and settings Parameter ● Fault history Register Definition Read/Write Remarks 40501 Fault history 1 Read/write 40502 Fault history 2 Read 40503 Fault history 3 Read Being 2 bytes in length, the data is stored as "H00 ". The error code can be referred to in the 40504 Fault history 4 Read...
Page 391 Parameter Communication operation and settings Communication error count (Pr. 343) You can check the cumulative number of communication errors. Parameter Setting Range Minimum Setting Range Initial Value (Read only) Tab. 6-86: Number of communication errors NOTE The number of communication errors is temporarily stored into the RAM. As it is not stored into the E²PROM, performing a power supply reset or inverter reset clears the value to 0.
Page 392: Special Operation
Special operation Parameter 6.19 Special operation Refer to Purpose Parameters that must be set Section Perform process control such as PID control Pr. 127–Pr. 134, 6.19.1 pump and air volume. Pr. 575–Pr. 577 Dancer control PID control (dancer control setting) Pr.
Page 393 Parameter Special operation Initial Setting Refer to Pr. No. Name Description Parameters referred to Value Range Section PID control Set the frequency at which the control is automatically Remote function 6.5.3 0–400Hz automatic changed to PID control. selection 9999 switchover Analog input 6.15.1 9999...
Page 394 Special operation Parameter PID control basic configuration Inverter Motor Manipulated Pr. 133 or variable terminal 2 Kp 1+ +Td S • Ti S • Set point 0–5V DC PID operation Terminal 4 (0–10V DC) Feedback signal (measured value), 4–20mA DC (0–5V DC, 0–10V DC) Kp: Proportionality constant;...
Page 395 Parameter Special operation PD action A combination of P action (P) and differential control action (D) for providing a manipulated var- iable in response to deviation speed to improve the transient characteristic. Fig. 6-121: Set point Operation example for proportional changes of measured value Deviation Measured...
Page 396 Special operation Parameter Reverse action Increases the manipulated variable fi (output frequency) if deviation X = (set point − measured value) is positive, and decreases the manipulated variable if deviation is negative. Deviation Set point X>0 Cold → fi increased Set point Hot →...
Page 397 Parameter Special operation Connection diagram The following graphic shows a typical application: Pr. 128 = 20 Pr. 182 = 14 Pr. 190 = 15 Pump Power supply Forward rotation Reverse rotation PID control selection RH (X14) 2 wire type Upper limit (FUP) RUN Setting Potentiometer...
Page 398 Special operation Parameter I/O signals and parameter setting Set "20 or 21" in Pr. 128 to perform PID operation. Set "14" in any of Pr. 178 to Pr. 182 to assign PID control selection signal (X14) to turn the X14 signal on. When the X14 signal is not assigned, only the Pr. 128 setting makes PID control valid.
Page 399 Parameter Special operation Terminal Signal Function Description Parameter Setting used Upper limit Output to indicate that the meas- Pr. 128 = 20, 21 Pr. 131 ≠ 9999 output ured value signal exceeded the upper limit value (Pr. 131). Set "15" or "115" to any of Pr.
Page 400 Special operation Parameter PID control automatic switchover control (Pr. 127) For a fast system start-up at an operation start, the system can be started up in normal operation mode only at a start. When the frequency is set to Pr. 127 "PID control automatic switchover frequency" within the range 0 to 400Hz, the system starts up in normal operation mode from a start until Pr.
Page 401 Parameter Special operation PID monitor function The PID control set point, measured value and deviation value can be displayed on the oper- ation panel and output from terminal AM. Integral value indicating a negative % can be displayed on the deviation monitor. 0% is dis- played as 1000.
Page 402 Special operation Parameter Calibration example 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 to 5V). Start Determination of set point Set the room temperature to 25°C...
Page 403 Parameter Special operation Set point input calibration Apply the input voltage of 0% set point setting (e.g. 0V) across terminals 2-5. Enter in C2 (Pr. 902) the frequency which should be output by the inverter at the deviation of 0% (e.g. 0Hz). In C3 (Pr.
Page 404 Special operation Parameter NOTES If the multi-speed (RH, RM, RL, REX 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. If the setting is as follows, PID control becomes invalid. Pr. 79 "Operation mode selection" = 6 (switchover mode).
Page 405: Dancer Control (Pr. 44, Pr. 45, Pr. 128 To Pr. 134)
Parameter Special operation 6.19.2 Dancer control (Pr. 44, Pr. 45, Pr. 128 to Pr. 134) Performs PID control by feedbacking the position detection of the dancer roller, controlling the dancer roller is in thespecified position. Initial Setting Refer to Pr. No. Name Description Parameters referred to Value...
Page 406 Special operation Parameter Dancer control block diagram Acceleration/deceleration of main speed Main speed command Target frequency deviation Acceleration/ Limit deceleration PID control Dancer roll setting point Pr. 133 PID set point PID feedback Convert to 0 to 100% Potentiometer Terminal 4 Dancer roll position detection I001840E Fig.
Page 407 Parameter Special operation Dancer control overview Performs dancer control by setting "40" to "43" in Pr. 128 "PID action selection". The main speed command is the speed command of each operation mode (external, PU, Network). Performs PID control by the position detection signal of the dancer roller, then the result is added to the main speed command.
Page 408 Special operation Parameter I/O signals and parameter setting Set "40 to 43" in Pr. 128 to perform dancer control. Set "14" in any of Pr. 178 to Pr. 182 to assign PID control selection signal (X14) to turn the X14 signal on. When the X14 signal is not assigned, only the Pr. 128 setting makes dancer control valid.
Page 409 Parameter Special operation NOTES Changing the terminal function using any of Pr. 178 to Pr. 182, Pr. 190, Pr. 192 or Pr. 197 may affect the other functions. Make setting after confirming the function of each terminal. When the Pr. 267 setting was changed, check the voltage/current input switch setting. Differ- ent setting may cause a fault, failure or malfunction.
Page 410 Special operation Parameter Parameter details When ratio (Pr. 128 = 42, 43) is selected for addition method, PID control × (ratio of main speed) is added to the main speed. The ratio is determined by the Pr. 125 "Terminal 2 frequency setting gain frequency"...
Page 411 Parameter Special operation Output signal Output terminal assignment during dancer control (PID control) operation PID signal turns on during dancer control (PID control) or at a stop by PID control (in the status PID operation being performed inside) (The signal is off during normal operation.) For the terminal used for PID signal output, assign the function by setting "47 (positive logic) or 147 (negative logic)"...
Page 412 Special operation Parameter Dancer roller position detection signal adjustment When terminal 4 input is voltage input, 0V is minimum position and 5V (10V) is maximum position. When current is input, 4mA is minimum position and 20mA is maximum position (initial value).
Page 413 Parameter Special operation NOTES In normal PID control, PID control is stopped when multi-speed operation signal (RH, RM, RL, REX signal) or JOG signal is input. In dancer control, however, PID control continues handling the signals as the main speed. During dancer control, Second acceleration/deceleration time of Pr.
Page 414: Traverse Function (Pr. 592 To Pr. 597)
Special operation Parameter 6.19.3 Traverse function (Pr. 592 to Pr. 597) Die Funktion ermöglicht den Betrieb mit einer zyklischen Änderung der Ausgangsfrequenz. Die Funktion wird beispielsweise in der Textilindustrie bei Wickelvorgängen verwendet. Initial Setting Refer to Pr. No. Name Description Parameters referred to Value Range...
Page 415 Parameter Special operation When the starting command (STF or STR) is switched on, the output frequency accelerates to the set frequency f0 according to the set acceleration time in Pr. 7. When the output frequency reaches f0, traverse operation can be started by switching the X37 signal on, then the frequency accelerates to f0 + f1.
Page 416 Special operation Parameter ≠ NOTES When the traverse function and S-pattern acceleration/deceleration (Pr. 29 0), vare selec- ted, S-pattern acceleration/deceleration is performed only in the areas where operation is performed in normal Acceleration and deceleration time (Pr. 7, Pr. 8). For acceleration/dece- leration during traverse operation, linear acceleration/deceleration is made.
Page 417 Parameter Special operation 6.19.4 Regeneration avoidance function (Pr. 665, Pr. 882, Pr. 883, Pr. 885, Pr. 886) This function detects a regeneration status and increases the frequency to avoid the regener- ation status. Possible to avoid regeneration by automatically increasing the frequency and continue opera- tion if the fan happens to rotate faster than the set speed due to the effect of another fan in the same duct.
Page 418 Special operation Parameter Regeneration avoidance function (Pr. 882, Pr. 883) When the regeneration status is serious, the DC bus voltage rises and an over voltage alarm (E.OV ) may occur. When this bus voltage rise is detected and the bus voltage level reaches or exceeds Pr.
Page 419 Parameter Special operation Limit regeneration avoidance operation frequency (Pr. 885) You can limit the output frequency compensated for (increased) by the regeneration avoidance function. The frequency is limited to the output frequency (frequency prior to regeneration avoidance op- eration) + Pr. 885 "Regeneration avoidance compensation frequency limit value" during accel- eration or constant speed.
Page 420: Useful Functions
Useful functions Parameter 6.20 Useful functions Refer to Purpose Parameters that must be set Section Increase cooling fan life Cooling fan operation selection Pr. 244 6.20.1 To determine the maintenance time Inverter part life display Pr. 255–Pr. 259 6.20.2 of parts. Maintenance output function Pr.
Page 421: Display Of The Life Of The Inverter Parts (Pr. 255 To Pr. 259)
Parameter Useful functions 6.20.2 Display of the life of the inverter parts (Pr. 255 to Pr. 259) Degrees of deterioration of main circuit capacitor, control circuit capacitor, cooling fan and in- rush current limit circuit and can be diagnosed by monitor. When any part has approached the end of its life, an alarm can be output by self diagnosis to pre- vent a fault.
Page 422 Useful functions Parameter Life alarm display and signal output (Y90 signal, Pr. 255) Whether any of the control circuit capacitor, main circuit capacitor, cooling fan and inrush current limit circuit has reached the life alarm output level or not can be checked by Pr. 255 "Life alarm status display"...
Page 423 Parameter Useful functions Pr. 255 Bits Inrush Current Main Circuit Control Circuit Cooling Fan Life (decimal) (binary) Limit Circuit Life Capacitor Life Capacitor Life ✔ ✔ ✔ ✔ 1111 ✔ ✔ ✔ 1110 — ✔ ✔ ✔ 1101 — ✔ ✔...
Page 424 Useful functions Parameter Control circuit capacitor life display (Pr. 257) The deterioration degree of the control circuit capacitor is displayed in Pr. 257 as a life. In the operating status, the control circuit capacitor life is calculated from the energizing time and temperature of the inverter’s heatsink, and is counted down from 100%.
Page 425 Parameter Useful functions Turning the power on during measuring before LED of the operation panel turns off, it may re- main in "measuring" (Pr. 259 = 2) status. In such case, carry out operation from step NOTE For the accurate life measuring of the main circuit capacitor, perform after more than 3 hrs passed since the turn off of the power as it is affected by the capacitor temperature.
Page 426: Maintenance Timer Alarm (Pr. 503, Pr. 504)
Useful functions Parameter 6.20.3 Maintenance timer alarm (Pr. 503, Pr. 504) When the cumulative energizing time of the inverter reaches the parameter set time, the main- tenance timer output signal (Y95) is output. "MT" is displayed on the operation panel. This can be used as a guideline for the maintenance time of peripheral devices.
Page 427: Current Average Value Monitor Signal (Pr. 555 To Pr. 557)
Parameter Useful functions 6.20.4 Current average value monitor signal (Pr. 555 to Pr. 557) The average value of the output current during constant speed operation and the maintenance timer value are output as a pulse to the current average value monitor signal (Y93). The pulse width output to the I/O module of the PLC or the like can be used as a guideline due to abrasion of machines and elongation of belt and for aged deterioration of devices to know the mainte- nance time.
Page 428 Useful functions Parameter The pulse output of the current average value monitor signal (Y93) is shown below. From acceleration to constant speed operation Output frequency Time 1 cycle (20s) Next cycle Data output mask time End pulse When the speed has changed to constant from output as low pulse shape acceleration/deceleration, Y93 signal is not output for 1 to 16.5s...
Page 429 Parameter Useful functions Setting of the Pr. 555 "Current average time" The average output current is calculated during Hi output of start bit (1s). Set the time taken to average the current during start bit output in Pr. 555. Setting of Pr. 557 "Current average value monitor signal output reference current" Set the reference (100%) for outputting the signal of the current average value.
Page 430 Useful functions Parameter NOTES Mask of data output and sampling of output current are not performed during acceleration/ deceleration. When the speed is changed to acceleration/deceleration from constant speed during start bit output, the data is judged as invalid, the start bit is output as high pulse shape for 3.5s, and the end signal is output as low pulse shape for 16.5s.
Page 431: Free Parameters (Pr. 888, Pr. 889)
Parameter Useful functions 6.20.5 Free parameters (Pr. 888, Pr. 889) Parameters you can use for your own purposes. You can input any number within the setting range "0" to "9999". For example, the number can be used: ● As a unit number when multiple units are used. ●...
Page 432: Setting For The Parameter Unit And Operation Panel
Setting for the parameter unit and operation panel Parameter 6.21 Setting for the parameter unit and operation panel Refer to Purpose Parameters that must be set Section Selection of rotation direction by the RUN key rotation direction selection Pr. 40 6.21.1 RUN key of the operation panel Switch the display language of the...
Page 433 Parameter Setting for the parameter unit and operation panel 6.21.3 Operation panel frequency setting/key lock operation selection (Pr. 161) The digital dial of the operation panel can be used like a potentiometer to perform operation. The key operation of the operation panel can be disabled. Initial Setting Refer to...
Page 434: Magnitude Of Frequency Change Setting (Pr. 295)
Setting for the parameter unit and operation panel Parameter 6.21.4 Magnitude of frequency change setting (Pr. 295) When setting the set frequency with the digital dial, frequency changes in 0.01Hz increments in the initial status. Setting this parameter increases the magnitude of frequency which changes according to the rotated amount of the digital dial, improving operability.
Page 435: Buzzer Control (Pr. 990)
Parameter Setting for the parameter unit and operation panel 6.21.5 Buzzer control (Pr. 990) You can make the buzzer "beep" when you press the key of the parameter unit (FR-PU04/ FR-PU07). Initial Setting Refer to Pr. No. Name Description Parameters referred to Value Range Section...
Page 436 Setting for the parameter unit and operation panel Parameter 6 - 286...
Page 437 Troubleshooting Troubleshooting Frequency inverter FR-D700 SC EC has a multitude of protective functions which protect the dri- ve and the inverter from damage in case of a fault. When an alarm occurs in the inverter, the pro- tective function is activated bringing the inverter to an alarm stop and the PU display automat- ically changes to any of the following error (alarm) indications.
Page 438: List Of Alarm Display
List of alarm display Troubleshooting List of alarm display Refer to Operation Panel Indication Name Page E--- Faults history 7-19 HOLD Operation panel lock LOCD Password locked Error message Er1 to Er4 Parameter write error Err. Inverter reset Stall prevention (overcurrent) Stall prevention (overvoltage) Regenerative brake prealarm Electronic thermal relay function prealarm...
Page 439 Troubleshooting List of alarm display Refer to Operation Panel Indication Name Page E.LF Output phase loss 7-13 E.OHT External thermal relay operation 7-13 PTC thermistor operation 7-14 E.PTC E.PE Parameter storage device fault 7-14 E.PUE PU disconnection 7-14 E.RET Retry count excess 7-15 Fault E.
Page 440: Causes And Corrective Actions
Causes and corrective actions Troubleshooting Causes and corrective actions Error Message A message regarding operational troubles is displayed. Output is not shutoff. Operation Panel HOLD Indication Name Operation panel lock Operation lock mode is set. Operation other than STOP/RESET is made invalid. (Refer to Description section 4.3.4.) Check point...
Page 441 Troubleshooting Causes and corrective actions Operation Panel Indication Name Calibration error Description Analog input bias and gain calibration values are too close. Corrective action Check the settings of C3, C4, C6 and C7 (calibration functions). (Refer to section 6.15.3.) Operation Panel Indication Name Mode designation error...
Page 442 Causes and corrective actions Troubleshooting Warnings When the protective function is activated, the output is not shut off. FR-PU04 Operation Panel Indication FR-PU07 Name Stall prevention (overcurrent) During When the output current of the inverter exceeds the stall prevention oper- acceleration ation level (Pr.
Page 443 Troubleshooting Causes and corrective actions FR-PU04 Operation Panel Indication FR-PU07 Name PU Stop Stop with the STOP/RESET key of the PU is set in Pr. 75 "Reset selection/disconnected Description PU detection/PU stop selection". (For Pr. 75, refer to section 6.16.1.) Check point Check for a stop made by pressing the STOP/RESET key of the operation panel.
Page 444 Causes and corrective actions Troubleshooting FR-PU04 Operation Panel — Indication FR-PU07 Name Undervoltage If the power supply voltage of the inverter decreases, the control circuit will not perform nor- mal functions. In addition, the motor torque will be insufficient and/or heat generation will Description increase.
Page 445 Troubleshooting Causes and corrective actions Fault When a fault occurs, the inverter trips and a fault signal is output. FR-PU04 Operation Panel E.OC1 OC During Acc Indication FR-PU07 Name Overcurrent shut-off during acceleration When the inverter output current reaches or exceeds approximately 200% of the rated cur- Description rent during acceleration, the protective circuit is activated and the inverter trips.
Page 446 Causes and corrective actions Troubleshooting FR-PU04 Operation Panel E.OC3 OC During Dec Indication FR-PU07 Name Overcurrent shut-off during deceleration or stop When the inverter output current reaches or exceeds approximately 200% of the rated Description inverter current during deceleration (other than acceleration or constant speed), the protec- tive circuit is activated and the inverter trips.
Page 447 Troubleshooting Causes and corrective actions FR-PU04 Operation Panel E.OV3 OV During Dec Indication FR-PU07 Name Regenerative overvoltage shut-off during deceleration or stop If regenerative energy causes the inverter's internal main circuit DC voltage to reach or Description exceed the specified value, the protective circuit is activated to stop the inverter output. The circuit may also be activated by a surge voltage produced in the power supply system.
Page 448 Causes and corrective actions Troubleshooting FR-PU04 Operation Panel E.FIN H/Sink O/Temp Indication FR-PU07 Name Fin overheat If the heatsink overheats, the temperature sensor is actuated to stop the inverter output. The FIN signal can be output when the temperature becomes approximately 85% of the Description heatsink overheat protection operation temperature.
Page 449 Troubleshooting Causes and corrective actions FR-PU04 Operation Panel E.BE Br. Cct. Fault Indication FR-PU07 Name Brake transistor alarm detection/internal circuit error When a brake transistor alarm has occurred due to the large regenerative energy from the Description motor etc., the brake transistor alarm is detected and the inverter trips. In this case, the inverter must be powered off immediately.
Page 450 Causes and corrective actions Troubleshooting FR-PU04 Fault 14 Operation Panel E.PTC Indication FR-PU07 PTC activated Name PTC thermistor operation Inverter trips when resistance of PTC thermistor connected between terminal 2 and termi- Description nal 10 is more than the value set in Pr. 561. This protective function does not function when Pr.
Page 451 Troubleshooting Causes and corrective actions FR-PU04 Operation Panel E.RET Retry No Over Indication FR-PU07 Name Retry count excess If operation cannot be resumed properly within the number of retries set, this function trips the inverter. Description Functions only when Pr. 67 "Number of retries at fault occurrence" is set. When the initial value (Pr.
Page 452 Causes and corrective actions Troubleshooting Fault 14 FR-PU04 Operation Panel E.AIE Indication FR-PU07 Analog in error Name Analog input fault Appears if voltage(current) is input to terminal 4 when the setting in Pr. 267 "Terminal 4 Description input selection" and the setting of voltage/current input switch are different. Check point Check the setting of Pr.
Page 453: Reset Method Of Protective Function
Troubleshooting Reset method of protective function Reset method of protective function Eliminate the cause of the error before you reset the inverter. Note that the internal thermal in- tegrated value of the electronic thermal relay function and the number of retries are cleared (erased) by resetting the inverter.
Page 454: Led Display
LED display Troubleshooting LED display In contrast to the LC display on the (optional) parameter unit FR-PU04/FR-PU07, alphanumeric characters are displayed on the LED display of the control panel in a somewhat simplified form. There are the following correspondences between the actual alphanumeric characters and the digital characters displayed on the operation panel.
Page 455: Check And Clear Of The Fault History
Troubleshooting Check and clear of the fault history Check and clear of the fault history Check for the fault history Monitor/frequency setting Parameter setting Operation panel is used for Parameter setting change operation Faults history Procedure for displaying the faults history and the status values for the time of the fault Eight past faults can be displayed with the digital dial.
Page 456 Check and clear of the fault history Troubleshooting Clearing procedure The fault history can be cleared by setting "1" in Er.CL "Faults history clear". (The fault history is not cleared when "1" is set in Pr. 77 "Parameter write selection".) Operation Display Screen at powering on...
Page 457: Check First When You Have Troubles
Troubleshooting Check first when you have troubles Check first when you have troubles 7.6.1 Motor does not start Refer to Check points Possible Cause Countermeasures Page Power ON a moulded case circuit breaker (MCCB), an earth leakage circuit breaker Appropriate power supply voltage is not (ELB), or a magnetic contactor (MC).
Page 458 Check first when you have troubles Troubleshooting Refer to Check points Possible Cause Countermeasures Page Increase Pr. 0 setting by 0.5% increments Pr. 0 "Torque boost" setting is improper while observing the rotation of a motor. 6-26 when V/F control is used. If that makes no difference, decrease the setting.
Page 459: Motor Or Machine Generates Abnormal Noise
Troubleshooting Check first when you have troubles 7.6.2 Motor or machine generates abnormal noise Refer to Check points Possible Cause Countermeasures Page Input signal Take countermeasures against EMI. 3-44 Disturbance due to EMI when frequency Increase the Pr. 74 "Input filter time con- command is given from analog input (ter- Parameter stant"...
Page 460: Motor Generates Heat Abnormally
Check first when you have troubles Troubleshooting 7.6.4 Motor generates heat abnormally Refer to Check points Possible Cause Countermeasures Page Motor fan is not working Clean the motor fan. — (Dust is accumulated.) Improve the environment. Motor Phase to phase insulation of the motor is Check the insulation of the motor.
Page 461: Acceleration/Deceleration Is Not Smooth
Troubleshooting Check first when you have troubles 7.6.7 Acceleration/deceleration is not smooth Refer to Check points Possible Cause Countermeasures Page Acceleration/deceleration time is too Increase acceleration/deceleration time. 6-59 short. Torque boost (Pr. 0, Pr. 46) setting is Increase/decrease Pr. 0 "Torque boost" improper under V/f control, so the stall setting value by 0.5% increments to the 6-26...
Page 462: Speed Varies During Operation
Check first when you have troubles Troubleshooting 7.6.8 Speed varies during operation When the slip compensation is selected, the output frequency varies between 0 and 2Hz as with load fluctuates. This is a normal operation and not a fault. Refer to Check points Possible Cause Countermeasures Page...
Page 463: Operation Mode Is Not Changed Properly
Troubleshooting Check first when you have troubles 7.6.9 Operation mode is not changed properly Refer to Check points Possible Cause Countermeasures Page Check that the STF and STR signals are Input signal Start signal (STF or STR) is ON. OFF. When either is ON, the operation 6-172 mode cannot be changed.
Page 464: Motor Current Is Too Large
Check first when you have troubles Troubleshooting 7.6.11 Motor current is too large Refer to Check points Possible Cause Countermeasures Page Torque boost (Pr. 0, Pr. 46) setting is Increase/decrease Pr. 0 "Torque boost" improper under V/f control, so the stall setting value by 0.5% increments to the 6-26 prevention function is activated.
Page 465: Speed Does Not Accelerate
Troubleshooting Check first when you have troubles 7.6.12 Speed does not accelerate Refer to Check points Possible Cause Countermeasures Page Start command and frequency command Check if the start command and the fre- — are chattering. quency command are correct. The wiring length used for analog fre- quency command is too long, and it is Perform analog input bias/gain calibration.
Page 466: Unable To Write Parameter Setting
Check first when you have troubles Troubleshooting 7.6.13 Unable to write parameter setting Refer to Check points Possible Cause Countermeasures Page Stop the operation. Operation is being performed (signal STF Input signal When Pr. 77 = "0" (initial value), write is 6-165 or STR is ON).
Page 467: Meters And Measuring Methods
Troubleshooting Meters and measuring methods Meters and measuring methods NOTE For further information about measurements at the inverter refer to section 8.2. Since voltages and currents in the primary and secondary side of the inverter include harmonics, different meters indicate different measured values. When the inverter-to-motor wiring length is large, especially in the 400V class, large-capacity models, the meters and CTs may generate heat due to line-to-line leakage current.
Page 468: Measurement Of Powers
Meters and measuring methods Troubleshooting 7.7.1 Measurement of powers Use digital power meters (for inverter) or an electro-dynamometer type meter, measure the pow- er in both the input and output sides of the inverter using the two- or three-wattmeter method. As the current is liable to be imbalanced especially in the input side, it is recommended to use the three-wattmeter method.
Page 469: Measurement Of Voltages And Use Of Pt
Troubleshooting Meters and measuring methods 7.7.2 Measurement of voltages and use of PT Inverter input side As the input side voltage has a sine wave and it is extremely small in distortion, accurate meas- urement can be made with an ordinary AC meter. Inverter output side Since the output side voltage has a PWM-controlled rectangular wave, always use a rectifier type voltmeter.
Page 470: Use Of Ct And Transducer
Meters and measuring methods Troubleshooting 7.7.4 Use of CT and transducer A CT may be used in both the input and output sides of the inverter, but the one used should have the largest possible VA ability because an error will increase if the frequency gets lower. When using a transducer, use the effective value calculation type which is immune to harmonics.
Page 471: Inspection
Maintenance and inspection Inspection Maintenance and inspection The inverter is a static unit mainly consisting of semiconductor devices. Daily inspection must be performed to prevent any fault from occurring due to the adverse effects of the operating en- vironment, such as temperature, humidity, dust, dirt and vibration, changes in the parts with time, service life, and other factors.
Page 472: Daily And Periodic Inspection
Inspection Maintenance and inspection 8.1.3 Daily and periodic inspection Interval Inspection Corrective Action at Alarm Description Item Occurrence Surrounding Check the ambient temperature, humidity, dirt, ✔ Improve environment environment corrosive gas, oil mist , etc. ✔ Check for unusual vibration and noise. Check alarm location and retighten Overall unit Check for a smear like adhered foreign material...
Page 473 Maintenance and inspection Inspection Interval Inspection Corrective Action at Alarm Description Item Occurrence ✔ 1) Check that display is normal. Contact the manufacturer Indication ✔ 2) Check for stain. Clean Stop the device and contact the ✔ Meter Check that reading is normal. manufacturer.
Page 474: Display Of The Life Of The Inverter Parts
Inspection Maintenance and inspection 8.1.4 Display of the life of the inverter parts The self-diagnostic alarm is output when the life span of the control circuit capacitor, cooling fan and each parts of the inrush current limit circuit is near to give an indication of replacement time. For the life check of the main circuit capacitor, the alarm signal (Y90) will not be output if a meas- uring method using Parameter 259 is not performed.
Page 475: Checking The Inverter And Converter Modules
Maintenance and inspection Inspection 8.1.5 Checking the inverter and converter modules Disconnect the external power supply cables (R/L1, S/L2, T/L3) and motor cables (U, V, W). Prepare a tester. (Use 100Ω range.) Change the polarity of the tester alternately at the inverter terminals R/L1, S/L2, T/L3, U, V, W, P/+ and N/−, and check for continuity.
Page 476: Cleaning
Inspection Maintenance and inspection 8.1.6 Cleaning Always run the inverter in a clean status. When cleaning the inverter, gently wipe dirty areas with a soft cloth immersed in neutral detergent or ethanol. CAUTION: Do not use solvent, such as acetone, benzene, toluene and alcohol, as they will cause the inverter surface paint to peel off.
Page 477 Maintenance and inspection Inspection WARNING: Switch the power off before replacing fans. Since the inverter circuits are charged with voltage even after power off, replace fans only when the inverter cover is on the inverter to prevent an electric shock accident. ●...
Page 478 Inspection Maintenance and inspection ● Reinstallation of the fan After confirming the orientation of the fan, reinstall the fan so that the arrow on the left of "AIR FLOW" faces up. Fig. 8-4: Orientation of the fan AIR FLOW Fan side face I001864E NOTE Installing the fan in the opposite air flow direction can cause the inverter life to be shorter.
Page 479 Maintenance and inspection Inspection Smoothing capacitors A large-capacity aluminum electrolytic capacitor is used for smoothing in the main circuit DC section, and an aluminum electrolytic capacitor is used for stabilizing the control power in the control circuit. Their characteristics are deteriorated by the adverse effects of ripple currents, etc. The replacement intervals greatly vary with the ambient temperature and operating conditions.
Page 480: Measurements On The Main Circuit
Measurements on the main circuit Maintenance and inspection Measurements on the main circuit This section describes the measurement of the main circuit voltages, currents, powers and in- sulation resistance. Please follow as well the instructions for measuring instruments and measuring methods in section 7.7.
Page 481: Measurement Of Voltages And Currents
Maintenance and inspection Measurements on the main circuit 8.2.3 Measurement of voltages and currents Since voltages and currents in the primary and secondary side of the inverter include harmonics, different meters indicate different measured values. When the inverter-to-motor wiring length is large, especially in the 400V class, large-capacity models, the meters and CTs may generate heat due to line-to-line leakage current.
Page 482 Measurements on the main circuit Maintenance and inspection Measuring Points and Instruments Measuring Item Measuring Point Remarks (Reference Measurement Value) Instrument Power supply Across Moving-iron type Commercial power supply voltage V1 R/L1-S/L2, AC voltmeter Within permissible AC voltage fluctuation S/L2-T/L3, (Refer to appendix A) T/L3-R/L1 Power supply...
Page 483 Maintenance and inspection Measurements on the main circuit Measuring Item Measuring Point Remarks (Reference Measurement Value) Instrument Frequency Across 2 (positive) Moving-coil type 0 to 10V DC, 4 to 20mA "5" is setting signal and 5 (Tester and such common may be used) Across 4 (positive) (Internal resist-...
Page 484 Measurements on the main circuit Maintenance and inspection 8 - 14...
Page 485: A.1 Specifications
Appendix Specifications Appendix Specifications A.1.1 1-phase, 200V class Model FR-D720S- SC-EC 0.75 Rated motor capacity [kW] Output capacity [kVA] Rated current [A] 10.0 200% of rated motor capacity for 0.5s; 150% for 60s Overload current rating 3-phase AC, 0V to power supply voltage Voltage 150% 100%...
Page 486: Phase, 400V Class
Specifications Appendix A.1.2 3-phase, 400V class Model FR-D740- SC-EC 0.75 Rated motor capacity [kW] 12.2 Output capacity [kVA] 12.0 16.0 Rated current [A] (1.4) (2.6) (4.3) (6.0) (9.6) (14.4) (19.2) 200% of rated motor capacity for 0.5 s; 150% for 60 s Overload current rating 3-phase AC, 0V to power supply voltage Voltage...
Page 487: A.2 Common Specifications
Appendix Common specifications Common specifications FR-D700 SC Specification Control system V/f control, optimum excitation control, general-purpose magnetic flux vector control Modulation control Sine evaluated PWM, Soft PWM Output frequency range 0.2–400Hz 0.06Hz/0–50Hz (terminal 2, 4: 0–10V/10bit) Analog input 0.12Hz/0–50Hz (terminal 2, 4: 0–5V/9bit) Frequency setting 0.06Hz/0–50Hz (terminal 4: 0–20mA/10bit) resolution...
Page 488 Common specifications Appendix FR-D700 SC Specification You can select from among output frequency, motor current (steady), output voltage, frequency setting, cumulative energization time, actual operation time, converter output voltage, regenerative brake duty, electronic thermal relay function load factor, output current peak value, , Operating status converter output voltage peak value, motor load factor, PID set point, PID measured value, PID deviation, inverter I/O terminal monitor, output power, cumulative power, motor thermal load...
Page 489: A.3 Outline Dimension Drawings
Appendix Outline dimension drawings Outline dimension drawings A.3.1 FR-D720S-008SC to 042SC Capacity plate Inverter Type FR-D720S-008SC to 014SC 80.5 FR-D720S-025SC 142.5 FR-D720S-042SC 162.5 All dimensions in mm I002041E Fig. A-1: Dimensions FR-D720S-008SC to 042SC FR-D700 SC EC A - 5...
Page 490: A.3.2 Fr-D720S-070Sc And Fr-D740-012Sc To 080Sc
Outline dimension drawings Appendix A.3.2 FR-D720S-070SC and FR-D740-012SC to 080SC Capacity plate FR-D740-012SC and 022SC are not provided with the cooling fan. Inverter Type FR-D720S-070SC 155.5 FR-D740-012SC, 022SC 129.5 FR-D740-036SC 135.5 FR-D740-050SC 155.5 FR-D740-080SC 165.5 All dimensions in mm I002009E Fig.
Page 491: A.3.3 Fr-D720S-100Sc
Appendix Outline dimension drawings A.3.3 FR-D720S-100SC Capacity plate All dimensions in mm I002041E Fig. A-3: Dimensions FR-D720S-100SC FR-D700 SC EC A - 7...
Page 492: A.3.4 Fr-D740-120Sc And 160Sc
Outline dimension drawings Appendix A.3.4 FR-D740-120SC and 160SC Capacity plate All dimensions in mm I002010E Fig. A-4: Dimensions FR-D740-120SC and 160SC A - 8...
Page 493: A.3.5 Parameter Unit Fr-Pu07
Appendix Outline dimension drawings A.3.5 Parameter unit FR-PU07 Panel cut dimension drawing 4–Ø4 All dimensions in mm I001638E Fig. A-5: Parameter unit FR-PU07 NOTES When installing the FR-PU07 on the enclosure, etc., remove screws or fix the screws to the FR-PU07 with M3 nuts.
Page 494: A.3.6 Parameter Unit Fr-Pa07
Outline dimension drawings Appendix A.3.6 Parameter unit FR-PA07 Panel cut dimension drawing All dimensions in mm I0001953E Fig. A-6: Parameter unit FR-PA07 A - 10...
Page 495: A.4 Parameter List With Instruction Codes
Appendix Parameter list with instruction codes Parameter list with instruction codes In the initial setting status, simple mode parameters and extended parameters can be displayed. Set Pr. 160 as required. So check the setting of Pr. 160 if parameters are not shown or change the setting of Pr.
Page 496 Parameter list with instruction codes Appendix Control Mode-based Instruction Code Correspondence Table General- Para- Refer Customer Function Name Purpose meter to Page Setting V/f Control magnetic Flux Vector Control ✔ ✔ Frequency ✔ ✔ DC injection brake operation Time 6-81 injection brake ✔...
Page 497 Appendix Parameter list with instruction codes Control Mode-based Instruction Code Correspondence Table General- Para- Refer Customer Function Name Purpose meter to Page Setting V/f Control magnetic Flux Vector Control ✔ ✔ DU/PU main display data selection 6-111 Monitor ✔ ✔ Frequency monitoring reference functions 6-118...
Page 498 Parameter list with instruction codes Appendix Control Mode-based Instruction Code Correspondence Table General- Para- Refer Customer Function Name Purpose meter to Page Setting V/f Control magnetic Flux Vector Control ✔ ✔ PU communication station number 6-198 6-224 ✔ ✔ PU communication speed ✔...
Page 499 Appendix Parameter list with instruction codes Control Mode-based Instruction Code Correspondence Table General- Para- Refer Customer Function Name Purpose meter to Page Setting V/f Control magnetic Flux Vector Control ✔ ✔ Watt-hour meter clear Cumulative 6-111 monitor clear ✔ ✔ Operation hour meter clear ✔...
Page 500 Parameter list with instruction codes Appendix Control Mode-based Instruction Code Correspondence Table General- Para- Refer Customer Function Name Purpose meter to Page Setting V/f Control magnetic Flux Vector Control ✔ ✔ Magnitude of frequency change setting 6-284 ✔ ✔ Password lock level Password 6-169 function...
Page 501 Appendix Parameter list with instruction codes Control Mode-based Instruction Code Correspondence Table General- Para- Refer Customer Function Name Purpose meter to Page Setting V/f Control magnetic Flux Vector Control Reduce ✔ ✔ mechanical Speed smoothing control 6-146 resonance ✔ ✔ —...
Page 502 Parameter list with instruction codes Appendix Control Mode-based Instruction Code Correspondence Table General- Para- Refer Customer Function Name Purpose meter to Page Setting V/f Control magnetic Flux Vector Control – — Parameter for manufacturer setting. Do not set. (922 – 923) ✔...
Page 503: A.5 Specification Change
Appendix Specification change Specification change A.5.1 SERIAL number check Check the SERIAL number indicated on the inverter rating plate or package (refer to section 1.2). The SERIAL consists of: ● 1 version symbol, ● 2 numeric characters or 1 numeric character and 1 alphabet letter indicating year and month Last digit of the production year is indicated as the Year, and the Month is indicated by 1 to 9, X (October), Y (November), and Z (December).
Page 504 Specification change Appendix A - 20...
Page 507 Appendix Index Index Cooling system ......2-10 Cumulative power meter AC reactor ......3-43 clear .
Page 508 Index Appendix Fault history Maintenance ......8-1 clear ......7-19 Maintenance timer read .
Page 509 Appendix Index Speed display Parameter ......6-109 Parameter Stall prevention clear ......4-17 Parameter .
Page 510 Index Appendix A - 24...
Page 512 Phone: +370 (0)5 / 232 3101 Fax: +380 (0)44 / 494-33-66 Fax: +370 (0)5 / 232 2980 Mitsubishi Electric Europe B.V. /// FA - European Business Group /// Gothaer Straße 8 /// D-40880 Ratingen /// Germany Tel.: +49(0)2102-4860 /// Fax: +49(0)2102-4861120 /// [email protected] /// www.mitsubishi-automation.com...

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