Yaskawa vs 606v7 инструкция на русском - RukovodstvoRus.ru - инструкции пользования и руководства

Contents
Table of Contents
Troubleshooting
Bookmarks

Quick Links

VS-606V7 Series

INSTRUCTION MANUAL

COMPACT GENERAL-PURPOSE INVERTER

(VOLTAGE VECTOR CONTROL)

Upon receipt of the product and prior to initial operation, read

these instructions thoroughly, and retain for future reference.

YASKAWA

MANUAL NO. TOE-S606-11E

Related Manuals for YASKAWA VS-606V7 Series

Summary of Contents for YASKAWA VS-606V7 Series

Page 1: Instruction Manual

YASKAWA VS-606V7 Series INSTRUCTION MANUAL COMPACT GENERAL-PURPOSE INVERTER (VOLTAGE VECTOR CONTROL) Upon receipt of the product and prior to initial operation, read these instructions thoroughly, and retain for future reference. MANUAL NO. TOE-S606-11E…
Page 2: General Precautions

• To order a copy of this manual, or if your copy has been damaged or lost, contact your YASKAWA representative. • YASKAWA is not responsible for any modification of the product made by the user, since that will void the guarantee.
Page 3: Notes For Safe Operation

NOTES FOR SAFE OPERATION Read this instruction manual thoroughly before installation, operation, maintenance or inspection of the VS-606V7. In this manual, NOTES FOR SAFE OPERATION are classified as “WARNING” or “CAUTION.” WARNING Indicates a potentially hazardous situation which, if not avoided, could result in death or serious injury to personnel.
Page 4
WARNINGS FOR UL/cUL MARKING • Do not connect or disconnect wiring, or perform signal checks while the power supply is turned ON. • The Inverter internal capacitor is still charged even after the power supply is turnd OFF. To prevent electric shock, disconnect all power before servicing the Inverter.
Page 5
RECEIVING CAUTION (Ref. page) • Do not install or operate any inverter which is damaged or has missing parts. Failure to observe this caution may result in personal injury or equipment damage. ÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷16 MOUNTING CAUTION (Ref. page) • Lift the cabinet by the cooling fin. When moving the unit, never lift by the plastic case or the terminal covers.
Page 6
WIRING WARNING (Ref. page) • Only commence wiring after verifying that the power supply is turned OFF. Failure to observe this warning can result in an electric shock or a fire. ÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷÷24 • Wiring should be performed only by qualified personnel. Failure to observe this warning can result in an electric shock or a fire.
Page 7
CAUTION (Ref. page) • Verify that the inverter rated voltage coincides with the AC power supply voltage. Failure to observe this caution can result in personal injury or a fire. • Do not perform a withstand voltage test of the inverter. It may cause semi-conductor elements to be damaged.
Page 8
OPERATION WARNING (Ref. page) • Only turn ON the input power supply after replacing the digital operator/blank cover (optional). Do not remove the digital operator or the covers while current is flowing. Failure to observe this warning can result in an electric shock. •…
Page 9
CAUTION (Ref. page) • Never touch the heatsink since the temperature is very high. Failure to observe this caution can result in harmful burns to the body. • Since it is easy to change operation speed from low to high, verify the safe working range of the motor and machine before operation.
Page 10
WARNING (Ref. page) • Do not perform withstand voltage test on any part of the VS-606V7. This electronic equipment uses semiconductors and is vulnerable to high voltage. • Only authorized personnel should be permitted to perform maintenance, inspections or parts replacement. [Remove all metal objects (watches, bracelets, etc.) before operation.] (Use tools which are insulated against electrical shock.)
Page 11: Warning Display

WARNING DISPLAY A warning label is displayed on the front cover of the inverter, as shown below. Follow these instructions when handling the inverter. PLASTIC CASE TOP COVER STATUS INDICATOR LAMP NAMEPLATE WARNING DISPLAY QUALIFICATION MARK Warning Display…
Page 12: Table Of Contents

CONTENTS NOTES FOR SAFE OPERATION •••••••••••••••••••••••••••••• 1. RECEIVING ••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••• Checking the Name Plate ••••••••••••••••••••••••••••••••••••••••••••••16 2. IDENTIFYING THE PARTS •••••••••••••••••••••••••••••••••• 3. MOUNTING ••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••• Choosing a Location to Mount the Inverter•••••••••••••••••••••••••20 Mounting Dimensions••••••••••••••••••••••••••••••••••••••••••••••••••••21 Mounting/Removing Components ••••••••••••••••••••••••••••••••••••22 4. WIRING •••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••• Wiring Instructions ••••••••••••••••••••••••••••••••••••••••••••••••••••••••24 Wire and Terminal Screw Sizes•••••••••••••••••••••••••••••••••••••••25 Wiring the Main Circuit ••••••••••••••••••••••••••••••••••••••••••••••••••28 Wiring the Control Circuit •••••••••••••••••••••••••••••••••••••••••••••••29…
Page 13
Operating at low speed •••••••••••••••••••••••••••••••••••••••••••••••52 Adjusting speed setting signal ••••••••••••••••••••••••••••••••••••••53 Adjusting frequency upper and lower limits •••••••••••••••••••••••54 Using four accel/decel times ••••••••••••••••••••••••••••••••••••••••••55 Automatic restart after momentary power loss •••••••••••••••••••56 Soft-start characteristics ••••••••••••••••••••••••••••••••••••••••••••••••57 Torque detection •••••••••••••••••••••••••••••••••••••••••••••••••••••••••58 Frequency detection •••••••••••••••••••••••••••••••••••••••••••••••••••••59 Jump frequencies ••••••••••••••••••••••••••••••••••••••••••••••••••••••••61 Continuing operation by automatic fault reset •••••••••••••••••••••61 Operating coasting motor without trip •••••••••••••••••••••••••••••••62 Holding accel/decel temporarily ••••••••••••••••••••••••••••••••••••••63…
Page 14
Selecting Cooling Fan Operation •••••••••••••••••••••••••••••••••••••89 Using MEMOBUS (MODBUS) Communications ••••••••••••••••89 MEMOBUS(MODBUS) communications •••••••••••••••••••••••••••89 Communication specifications ••••••••••••••••••••••••••••••••••••••••90 Communication connection terminal ••••••••••••••••••••••••••••••••90 Procedure for communications with PLC ••••••••••••••••••••••••••90 Setting constants necessary for communication ••••••••••••••••91 Message format •••••••••••••••••••••••••••••••••••••••••••••••••••••••••92 Storing constants [Enter command] ••••••••••••••••••••••••••••••••98 Performing self-test ••••••••••••••••••••••••••••••••••••••••••••••••••••100 Using Energy-saving Control Mode ••••••••••••••••••••••••••••••••101 Energy saving search operation•••••••••••••••••••••••••••••••••••••103…
Page 15
7. MAINTENANCE AND INSPECTION •••••••••••••••• Periodical Inspection ••••••••••••••••••••••••••••••••••••••••••••••••••131 Part Replacement •••••••••••••••••••••••••••••••••••••••••••••••••••••131 8. FAULT DIAGNOSIS ••••••••••••••••••••••••••••••••••••••••••• Protective and Diagnostic Function •••••••••••••••••••••••••••••••••134 Troubleshooting••••••••••••••••••••••••••••••••••••••••••••••••••••••••••143 9. SPECIFICATION •••••••••••••••••••••••••••••••••••••••••••••••••• Standard Specifications (200V Class)••••••••••••••••••••••••••••••145 Standard Specifications (400V Class)••••••••••••••••••••••••••••••146 Standard Wiring••••••••••••••••••••••••••••••••••••••••••••••••••••••••••151 Sequence input connection with NPN/PNP transistor••••••••••154 Dimensions/Heat Loss •••••••••••••••••••••••••••••••••••••••••••••••••156 Recommended Peripheral Devices •••••••••••••••••••••••••••••••••158 Constants List ••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••160…
Page 16: Receiving

With digital operator (with potentiometer) 2.2kW 2.2kW Without digital operator (with blank cover) 3.0kW With digital operator (without potentiometer) 4.0kW 4.0kW Note: Contact your YASKAWA representatives Voltage Class for the type without heatsink. Single-phase 200VAC Three-phase 200VAC Three-phase 400VAC SPEC Specifications…
Page 17: Identifying The Parts

2. IDENTIFYING THE PARTS DIGITAL TERMINAL COVER OPERATOR WIRING HOLES FOR CONTROL FRONT CIRCUIT COVER TOP COVER WIRING HOLES NAME PLATE FOR MAIN CIRCUIT HEATSINK GROUND TERMINAL BOTTOM COVER COOLING FAN FAN COVER DIGITAL DIGITAL OPERATOR OPERATOR JVOP-140 JVOP-147 FREF FOUT IOUT MNTR…
Page 18
VS-606V7 inverters with the covers removed DIGITAL FREQUENCY SETTING POTENTIOMETER OPERATOR JVOP-140 FREF FOUT IOUT MNTR INPUT STATUS DISPLAY LAMP LO/RE PRGM POLARITY DSPL TERMINAL RESISTOR SWITCH FOR SWITCH DATA STOP ENTER RESET COMMUNICATION CIRCUIT VOLTAGE/CURRENT CHANGE SWITCH FOR ANALOG FREQUENCY REFERENCE INPUT CONTROL CIRCUIT TERMINAL 12 13 14…
Page 19
Main Circuit Terminal Arrangement Terminal arrangement of the main circuit terminal differs depending on the inverter model. ∗ CIMR-V7 C20P1 to 20P7, B0P1 to B0P4 R/L1 S/L2 T/L3 U/T1 V/T2 W/T3 ∗ CIMR-V7 C21P5, 22P2, B0P7, B1P5, 40P2 to 42P2 R/L1 S/L2 T/L3 U/T1 V/T2 W/T3 ∗…
Page 20: Mounting

3. MOUNTING Choosing a Location to Mount the Inverter Be sure the inverter is protected from the following conditions : ▫ Extreme cold and heat. Use only within the ambient temperature range : -10 to +50; (14 to 122,) for IP20 (open chassis type), -10 to +40˚C (14 to 105˚F) for NEMA 1 (TYPE 1), IP 20 (Top-closed type) ▫…
Page 21: Mounting Dimensions

Mounting Dimensions To mount the VS-606V7, dimensions as shown below are required. 30mm 30mm (1.18 in.) (1.18 in.) OR MORE OR MORE 100mm (3.94 in.) OR MORE 100mm (3.94 in.) OR MORE…
Page 22: Mounting/Removing Components

Mounting / Removing Components Removing and Mounting Digital Operator and Covers • Removing front cover Use a driver to loosen the screw on the front cover surface to direction 1 to remove it. Then press the right and left sides to direction 2 and lift the front cover to direction 3.
Page 23
• Removing digital operator After removing the front cover, lift the upper and lower sides (section A) of the right side of the digital operator to direction 1. • Mounting digital operator Mount the digital operator in the descending order of the above procedure for removal.
Page 24: Wiring

4. WIRING Wiring Instructions (1) Always connect the power supply (for main circuit inputs) and power input terminals R/L1, S/L2, and T/L3 (R/L1, S/L2 for single-phase) via a molded-case circuit breaker (MCCB) or a fuse. Never connect them to terminals U/T1,V/T2,W/T3, B1, B2, -, +1, or +2. The inverter may be damaged.
Page 25: Wire And Terminal Screw Sizes

(10) Voltage drop should be considered when determining wire size. Voltage drop can be calculated using the following equation: Phase-to phase voltage drop (V) = √  3 wire resistance (Ω/km) × wiring distance (m) × current (A) × 10 Select a wire size so that voltage drop will be less than 2% of the normal rated voltage.
Page 26
200V Class Single-phase Input Series Wire Tightening Terminal Model Screw Torque Applicable size Recommended size Type Symbol m (lb • • R/L1,S/L2,T/L3, CIMR- –,+1,+2,B1,B2, 0.8 to 1.0 M3.5 0.75 to 2 18 to 14 U/T1,V/T2,W/T3 (7.1 to 8.88) B0P1 R/L1,S/L2,T/L3, CIMR- –,+1,+2,B1,B2, 0.8 to 1.0…
Page 27
400V Class 3-phase Input Series Wire Tightening Terminal Model Screw Applicable size Recommended size Torque Type Symbol m (Ib • • R/L1,S/L2,T/L3, CIMR- –,+1,+2,B1,B2, 1.2 to 1.5 2 to 5.5 14 to 10 U/T1,V/T2,W/T3 (10.65 to 13.31) 40P2 R/L1,S/L2,T/L3, CIMR- –,+1,+2,B1,B2, 1.2 to 1.5 2 to 5.5…
Page 28: Wiring The Main Circuit

Wiring the Main Circuit L1 L2 L3 [Example of 3-phase, 400V class, 0.37kW inverters] MCCB or leakage breaker • Main circuit input power supply Grounding Always connect the power supply line to input terminals R/L1, S/L2, and T/L3 • Braking resistor connection (optional) [R/L1, S/L2 for single-phase inverters].
Page 29: Wiring The Control Circuit

Wiring the Control Circuit Only basic insulation is provided for the control circuit terminals. Additional insulation may be necessary in the end product. • Control Circuit terminals Pass the cable through wiring hole and connect. Be sure to mount the covers on the original position.
Page 30: Wiring Inspection

Open the front cover and verify that the strip length is 5.5mm (0.22in.). SCALE MA MBMC CONTACT OUTPUT S6 S7 P1 P2 R R FS FR FC S3 S4 SC PC S S AM AC RP Wiring Inspection After completing wiring, check the following : ▫…
Page 31: Operating The Inverter

5. OPERATING THE INVERTER Initial setting of control mode selection (n002) is set at V/f control mode. Test Run The inverter operates by setting the frequency (speed). There are four types of operation modes for the VS-606V7 : 1 Run command from the digital operator (potentiometer/digital setting). 2 Run command from the control circuit terminal.
Page 32: Selecting Rotation Direction

Operator Status Indicator Operation Steps Display Display 1. Turn ON the power supply. 6.00 FREF ALARM 2. Set constant n004 to 1. PRGM ALARM 3. Set the following constants. PRGM n019 : 15.0 (acceleration time) ALARM 15.0 n020 : 5.0 (deceleration time) 4.
Page 33: Operating The Digital Operator

Operating the Digital Operator All functions of the VS-606V7 are set by the digital operator. Below are descriptions of the display and keypad sections. DIGITAL OPERATOR JVOP-140 Data display section Display section Display section Function display LED’s LED switches to another function each time DSPL is pressed.
Page 34
Description of Status Indicator LEDs There are two LEDs on the middle right section of the face of the VS-606V7. The inverter status is indicated by various combinations of ON, BLINKING and OFF LEDs. RUN indicator and status indicator on the RUN button have the same function.
Page 35: Led Description

LED Description By pressing on the digital operator, each of the function LEDs can be DSPL selected. The following flowchart describes each function LED. Power ON Frequency reference setting/monitor (Hz) FREF Sets VS-606V7 operation speed. DSPL Output frequency monitor (Hz) If the VS-606V7 FOUT Displays frequency that VS-606V7 is…
Page 36
LOCAL / REMOTE Selection LO/RE This function switches the operation; operation using the digital operator including frequency setting with potentiometer, or that using the input terminals or through communications Setting can be changed by key. (Local) (Remote) DSPL Constant No. / data PRGM Sets and changes data using constant No.
Page 37
• Monitoring Following items can be monitored by U- constants. Constant Name Description Frequency reference Frequency reference can be monitored. U-01 (FREF) (Same as FREF) Output frequency Output frequency can be monitored. U-02 (FOUT) (Same as FOUT) Output current Output current can be monitored. U-03 (IOUT) (Same as IOUT)
Page 38: Data Reception Error Display

Input / Output terminal status Input terminal status 1: Terminal S1 is “closed.” 1: Terminal S2 is “closed.” 1: Terminal S3 is “closed.” 1: Terminal S4 is “closed.” 1: Terminal S5 is “closed.” 1: Terminal S6 is “closed.” 1: Terminal S7 is “closed.” Not used Output terminal status 1: Terminal MA-MC is “closed.”…
Page 39
Fault history display method When U-09 is selected, a four-digit box is displayed. The three digits from the right show the fault description, and the digit on the left shows the order of fault (from one to four). Number 1 represents the latest fault, and 2,3,4, in ascending order of fault occurrence.
Page 40: Simple Data Setting

Simple Data Setting Digital setting (Refer to 5. OPERATING THE INVERTER) and potentiometer setting are both available for simple accel/decel operation of the VS-606V7. Digital setting is set at the factory (n004=1). For the model with digital operator (with potentiometer) JVOP-140, factory setting is set by frequency setting potentiometer (n004=0).
Page 41: Programming Features

6. PROGRAMMING FEATURES Factory settings of the constants are shown as in the tables. Constant Set-up and Initialization Constant selection/initialization (n001) The following table describes the data which can be set or read when n001 is set. Unused constants among n001 to n179 are not displayed. n001 Setting Constant that can be set Constant that can be referred…
Page 42: Using V/F Control Mode

Using V/f Control Mode V/f control mode is preset at the factory. Control mode selection (n002)= 0: V/f control mode (initial setting) 1: Vector control mode Adjusting torque according to application Adjust motor torque by using “V/f pattern” and “full-range automatic torque boost”.
Page 43
• Typical setting of V/f pattern Set the V/f pattern according to the application as described below. For 400V class, the voltage values (n012, n015, and n017) should be doubled. When running at a frequency exceeding 50Hz/60Hz, change the maximum output frequency (n011).
Page 44
• Full-range automatic torque boost (when V/f mode is selected; n002=0) Motor torque requirement changes according to load conditions. Full- range automatic torque boost adjusts voltage of V/f pattern according to the requirement. The VS-606V7 automatically adjusts the voltage during constant-speed operation as well as during acceleration.
Page 45: Using Vector Control Mode

1: Vector control mode Precaution for voltage vector control application Since vector control needs motor constants, the YASKAWA standard motor constants have been set at the factory prior to shipment. Therefore, when an inverter exclusive-use motor is used or when a motor of any…
Page 46: Motor Constant Calculation

Select slip compensation status during regeneration: n113 Setting Slip correction during regenerative operation Disabled Enabled Motor constant calculation Following show an example of motor constant calculation. (1) Motor rated slip (n106) 120 × motor rated frequency (Hz)* – Motor rated speed (r/min)* Number of motor pole 120 / Number of motor pole (2) Line to neutral (per phase) (n107)
Page 47
V/f pattern during vector control Set V/f pattern as follows during vector control. The following examples are for 200V class motors. When using 400V class motors, double the voltage settings (n012, n015, n017). STANDARD V/F [MOTOR SPECIFICATION: 60Hz] [MOTOR SPECIFICATION: 50Hz] 60 (Hz) 50 (Hz) 0.8 2.5…
Page 48: Switching Local/Remote Modes

Switching LOCAL/REMOTE Modes The following functions can be selected by switching the LOCAL or REMOTE mode. To select RUN/STOP commands or frequency reference, change the mode in advance depending on the following applications. • LOCAL mode: Enables the digital operator for RUN/STOP c o m m a n d s a n d F W D / R E V r u n commands.
Page 49: Selecting Run/Stop Commands

Selecting Run/Stop Commands Switching LOCAL / REMOTE Modes (page 48) to select Refer to either the LOCAL mode or REMOTE mode. Operation method (RUN / STOP commands, FWD / REV run commands) can be selected by the following method. LOCAL mode When Lo (local mode) is selected for digital operator ON mode, LO / RE…
Page 50: Selecting Frequency Reference

Operating (RUN / STOP commands) by communications Setting constant n003 to 2 in REMOTE mode can give RUN / STOP commands by communication (MEMOBUS communications). For the command by communications, refer to page 89) Selecting Frequency Reference Frequency reference can be selected by the following methods. Setting by operator Select REMOTE or LOCAL mode in advance.
Page 51: Setting Operation Condition

Example of frequency reference by voltage signal n004 = 2 (initial setting : 1) FREQUENCY SETTING POWER MASTER SPEED +12V, 20mA (0 TO +10V) FREQUENCY REFERENECE FC(0V) 2KΩ Setting Operation Conditions Reverse run prohibit (n006) “Reverse run prohibit” setting does not accept a reverse run command from the control circuit terminal or digital operator.
Page 52: Operating At Low Speed

(n031) 60.0 Hz (n030) 55.0 Hz (n029) 50.0 Hz (n028) 45.0 Hz (n027) 40.0 Hz (n026) 35.0 Hz (n025) 30.0 Hz FREQUENCY (n024) 25.0 Hz REFERENCE TIME FWD (REV) RUN/STOP MULTI-STEP SPEED REF. 1 (TERMINAL S5) MULTI-STEP SPEED REF. 2 (TERMINAL S6) MULTI-STEP SPEED REF.
Page 53: Adjusting Speed Setting Signal

Adjusting speed setting signal To provide frequency reference by analog input of control circuit terminal FR or FC, the relationship between analog input and frequency reference can be set. FREQURNCY REFERENCE MAX. OUTPUT FREQUENCY GAIN MAX. OUTPUT FREQUENCY BIAS ( ) indicates the value when current (4mA) (20mA) (0mA)
Page 54: Adjusting Frequency Upper And Lower Limits

• To operate the inverter with frequency reference of 50% to 100% at 0 to 10V input MAX. FREQUENCY (100%) Gain n060 = 100 Bias n061 = 50 Adjusting frequency upper and lower limits • Frequency reference upper limit (n033) Sets the upper limit of the frequency reference in units of 1%.
Page 55: Using Four Accel/Decel Times

Using four accel/decel times ACCEL ACCEL DECEL DECEL TIME 2 TIME 2 TIME 4 TIME 4* ACCEL DECEL (n043) (n021) (n022) (n044) TIME 3 ACCEL TIME 1 (n041) TIME 1 DECEL (n020) OUTPUT (n019) TIME 3* FREQUENCY (n042) TIME FORWARD (REVERSE) RUN COMMAND MULTI-STEP SPEED REFERENCE…
Page 56: Automatic Restart After Momentary Power Loss

n018 setting Unit Setting range 0.1s 0.0-999.9s (999.9s or less) 1000-6000s (1000s or more) n018 0.01s 0.00-99.99s (99.99s or less) 0.1s 100.0-600.0s (100s or more) Notes: Constant n018 can be set during stop. If the value exceeding 600.0 s is set for the accel/decel time when n018 = 0 (in units of 0.1 s), “1”…
Page 57: Soft-Start Characteristics

Soft-start characteristics (n023) To prevent shock at machine start/stop, accel/decel can be performed in S- curve pattern. Setting S-curve selection S-curve characteristic not provided 0.2 s 0.5 s 1.0 s Note : S-curve characteristic time is the time from accel/decel rate 0 to a regular accel/decel rate determined by the set accel/decel time.
Page 58: Torque Detection

Torque detection If an excessive load is applied to the machine, output current increase can be detected to output alarm signals to multi-function output terminals MA, MB, P1 and P2. To output an overtorque detection signal, set output terminal function selection n057 to n059 to “overtorque detection”…
Page 59
• Overtorque detection function selection 1 (n096) Setting Description Overtorque detection not provided Detected during constant-speed running, and operation continues after detection. Detected during constant-speed running, and operation stops during detection. Detected during running, and operation continues after detection. Detected during running, and operation stops during detection.
Page 60: Frequency Detection

Frequency detection (n095) Effective when either of output terminal function selections n057, n058 or n059 are set to “frequency detection” (setting: 4 or 5). “Frequency detection” turns ON when output frequency is higher or lower than the setting of frequency detection (n095). •…
Page 61: Jump Frequencies

Jump frequencies (n083 to n086) This function allows the prohibition or “jumping” of critical frequencies so that the motor can operate without resonance caused by machine systems. This function is also used for dead band control. Setting the value to 0.00Hz disables this function.
Page 62: Operating Coasting Motor Without Trip

Operating coasting motor without trip To operate coasting motor without trip, use the speed search command or DC injection braking at start. • Speed search command Restarts a coasting motor without stopping it. This function enables smooth switching between motor commercial power supply operation and inverter operation.
Page 63: Holding Accel/Decel Temporarily

Holding accel/decel temporarily To hold acceleration or deceleration, input accel/decel hold command. The output frequency is maintained when the accel/decel hold command is input during acceleration or deceleration. When the stop command is input during accel/decel prohibition command input, accel/decel hold is released and operation ramps to stop. Set multi-function input selection (n050 to n056) to 16 (accel/decel prohibit).
Page 64: Using Frequency Meter Or Ammeter

Using frequency meter or ammeter (n066) Selects to output either output frequency or output current to analog output terminals AM-AC for monitoring. Description Setting Setting Output frequency Output current Main circuit DC voltage Torque monitor Output power Output voltage reference Frequency reference monitor In initial setting, analog voltage of approx.
Page 65: Using Analog Output (Am-Ac) As A Pulse Signal Output

Using analog output(AM-AC) as a pulse train signal output (n065) Analog output AM-AC can be used as a pulse train output (output frequency monitor, frequency reference monitor). Set n065 to 1 when using pulse train output. Constant No. Name Unit Setting range Initial setting n065…
Page 66
Peripheral devices must be connected according to the following load NOTE conditions when using pulse monitor output. The machine might damage when the conditions are not satisfied. Used as a sourcing output Load impedance Output voltage Load impedance VRL ( V ) ( kΩ…
Page 67: Reducing Motor Noise Or Leakage Current

Reducing motor noise or leakage current (n080) Set inverter output transistor switching frequency (carrier frequency). Metallic Noise Noise and Current Setting Carrier Frequency (kHz) from Motor Leakage (Hz) 12 fout (Hz) 24 fout Higher Smaller (Hz) 36 fout (kHz) (kHz) Larger audible (kHz)
Page 68
Factory setting varies according to inverter capacity (kVA). Initial Setting Maximum Continuous Capacity Voltage Class Reduced Current Output Current Carrier (kW) Setting Frequency 10kHz 0.25 10kHz —- 0.55 10kHz Single-phase 10kHz 7.5kHz 3-phase 7.5kHz 11.0 10.0 7.5kHz 17.5 16.5 0.37 7.5kHz 0.55 7.5kHz…
Page 69: Operator Stop Key Selection

(3) Set carrier frequency selection (n080) to either 1, 2, 3, 4 when using vector control mode. Do not set to 7, 8, or 9. (4) Carrier frequency is automatically reduced to 2.5kHz when Reducing carrier frequency selection at low speed ( n175 ) is set to 1 and the following conditions are satisfied: Output frequency ≤…
Page 70: Selecting Stopping Method

Selecting Stopping Method Selecting stopping method (n005) Selects the stopping method suitable for application. Setting Setting Description Deceleration to stop Coast to stop • Deceleration to stop Example when accel/decel time 1 is selected MIN. OUTPUT DECEL ACCEL FREQUENCY OUTPUT DECEL TIME 1 TIME 1 TIME 1…
Page 71: Applying Dc Injection Braking

• Coast to stop Example when accel/decel time 1 is selected OUTPUT ACCEL DECEL FREQUENCY TIME 1 TIME 1 COAST TO (n019) (n020) STOP TIME FWD (REV) RUN COMMAND * When frequency reference is changed during running. Upon removal of the FWD (REV) run command, the motor starts coasting. Applying DC injection braking •…
Page 72: Building Interface Circuits With External Devices

Building Interface Circuits with External Devices Using input signals Multi-function input terminal S1 to S7 functions can be changed when necessary by setting constants n050 to n056 respectively. The same value cannot be set to different constant settings. Setting Name Description Ref.
Page 73: Initial Setting

Initial setting Initial Setting Function Terminal n050 Forward run command (2-wire sequence) n051 Reverse run command (3-wire sequence) n052 External fault n053 Fault reset n054 Multi-step speed reference 1 n055 Multi-step speed reference 2 n056 JOG command Terminal function at 3-wire sequence selection When 0 is set at the terminal S3 (n052), terminal S1 becomes run command, terminal S2 becomes stop command, and terminal S3 becomes FWD/REV run command.
Page 74
(Example) Set n003 = 1, n004 = 2, n008 = 0. Open : Run by frequency reference from multi-function input terminal FR and run command from multi-function input terminals S1 to S7. Closed : Run by potentiometer frequency reference and run command from the digital operator.
Page 75
Notes : 1. When UP/DOWN command is selected, the upper limit speed is set regardless of frequency reference. Upper limit speed = Maximum output frequency (n011) Frequency reference upper limit (n033)/100 2. Lower limit value is either minimum output frequency (n016) or frequency reference lower limit (n034) (whichever is larger.).
Page 76: Using Multi-Function Analog Input

Using multi-function analog input ( n077, n078, n079 ) The input analog signal (0 to 10V or 4mA to 20mA) for the CN2 terminal of the JVOP-140 digital operator can be used as an auxiliary function for the main speed frequency reference input to the control circuit terminals (FR or RP).
Page 77
Analog input level 1 Auxiliary frequency reference (n077=1) 2 Frequency reference gain (n077=2) FREF2 FGAIN 100% 2.00 1.00 (4mA) (20mA) (4mA) (20mA) 100%=Max. output frequency(n011) 4 Output voltage bias (n077=4) 3 Frequence reference bias (n077=3) VBIAS FBIAS 100% n079 (20mA) (4mA) -n079 (4mA)
Page 78: Using Output Signals

Using output signals (n057, n058, n059) Multi-function output terminal MA, MB, P1 and P2 functions can be changed when necessary by setting constants n057, n058, and n059. • Terminal MA and MB functions: Set to n057 • Terminal P1 function: Set to n058 •…
Page 79
Initial setting of multi-function output terminal Terminals Initial Setting n057 MA, MB 0 (fault) n058 1 (in operation) n059 2 (Frequency agreed) • Frequency agreed signal (setting=2) RELEASE WIDTH DETECTION WIDTH ±2Hz ±4Hz OUTPUT FREQUNENCY FREQUENCY AGREED SIGNAL…
Page 80: Setting Frequency By Current Reference Input

Setting Frequency by Current Reference Input When setting frequency by inputting DIGITAL OPERATOR current reference (4-20mA or 0-20mA) JVOP-140 FREF FOUT IOUT MNTR from the control circuit terminal FR, LO/RE PRGM DSPL switch the DIP switch SW1 on the DATA STOP ENTER RESET…
Page 81
Current reference selection After changing DIP switch (V-I switch of SW2) to the “I” side, PRESS PRGM on the digital operator, then set the following constants. Current reference ( 4 to 20mA )..constant n004 = 3 Current reference ( 0 to 20mA )..constant n004 = 4 •…
Page 82: Frequency Reference By Pulse Train Input

Frequency Reference by Pulse Train Input Frequency reference can be set by pulse train input from the multi-function input terminal. • Input pulse specifications • Low-level voltage: 0.8V or less • High-level voltage: 3.5 to 32V • H duty: 30 to 70% •…
Page 83: Preventing Motor From Stalling (Current Limit)

Preventing Motor from Stalling (Current Limit) Automatically adjusts the output frequency and output current according to the load to continue operation without stalling the motor. • Stall prevention (current limit) level during acceleration (n093) Sets the stall prevention (current limit) level during acceleration in units of 1%.
Page 84: Stall Prevention During Running

• Stall prevention (current limit) level during running (n094) Sets the stall prevention (current limit) level during running in units of 1%. (Inverter rated current = 100%) Factory setting: 160% A setting of 200% disables the stall prevention (current limit) during running.
Page 85
n115 Setting Function Setting The stall prevention level becomes the level set for the constant n094 in all frequency areas. The following shows that the stall prevention level is automatically decreased in the constant output range (Max. frequency>Max. voltage output frequency). The lower limit is 40% of the set value of n094.
Page 86: Decreasing Motor Speed Fluctuation

Decreasing Motor Speed Fluctuation Slip compensation ( When n002 is set to 0 ) As the load becomes larger, motor speed is reduced and motor slip value is increased. The slip compensating function controls the motor speed at a constant value even if the load varies. When inverter output current is equal to the motor rated current (n036), the compensation frequency is added to the output frequency.
Page 87: Motor Protection

Motor Protection Motor overload detection The VS-606V7 protects against motor overload with a built-in electronic thermal overload relay. • Motor rated current (elctronic thermal reference current, n036) Set to the rated current value shown on the motor nameplate. Note : Setting to 0.0A disables the motor overload protective function. •…
Page 88
• General-purpose motor and inverter motor Induction motors are classified as general-purpose motors or inverter motors, based on their cooling capabilities. Therefore, the motor overload function operates differently between these two motor types. Example of 200V class motor Electronic Thermal Cooling Effect Torque Characteristics overload…
Page 89: Selecting Cooling Fan Operation

Selecting Cooling Fan Operation In order to increase lifetime, the cooling fan can be set to operate only when inverter is running. n039 = 0 (Initial setting) : Operates only when inverter is running (Continues operation for 1 minute after inverter is stopped.) : Operates with power ON Using MEMOBUS (MODBUS) Communications…
Page 90: Communications Connection Terminal

Communications connection terminal Use the following S+, S-, R+ and R- terminals for MEMOBUS communications. Change the termination resistor as shown below. At RS-422, RS-485 communications: Turn ON SW2 ON/OFF switch of only the inverter at the termination viewed from the PLC. RS-422A or RS-485 TERMINAL RESISTOR (1/2W, 120Ω)
Page 91: Setting Constants Necessary For Communication

Setting constants necessary for communication Communication related constants must be set for PLC communication. Constants n151 to n157 cannot be set by communication. Always set them before performing communication. Initial Constant Name Description Setting 0 : operator Run command 1 : control circuit terminals n003 selection 2 : MEMOBUS communication…
Page 92: Message Format

Message format Slave address For communications, the master (PLC) sends a command Function code to the slave (VS-606V7) and the slave responds to it. The configuration for sending and receiving is as shown to the Data right. The length of the data varies according to the contents of commands (functions).
Page 93
• Read out holding register contents [03H] Reads out the contents of the holding registers with the continuous numbers for the specified quantity. The contents of holding register is divided into the upper 8 bits and the lower 8 bits. They become the data items in response message in the order of numbers.
Page 94
• Writing to several holding registers [10H] Specified data are written into the several specified holding registers from the specified number, respectively. Written data must be arranged in a command message in the order of the holding register numbers: from upper eight bits to lower eight bits.
Page 95
Data • Reference Data (available to read out / write in) Register No. Description 0000H Reserved Run command 1 : Run 0 : Stop Reverse run 1 : Reverse run 0 : Forward run External fault 1 : Fault (EFO) Fault reset 1 : Reset command Multi-function input reference 1…
Page 96
• Monitor Data (available only for read out) Register No. Description Run command 1 : Run 0 : Stop Reverse run 1 : Reverse run 0 : Forward run Inverter operation ready 1 : Ready 0 : Not ready Fault 1 : Fault 0020H Data setting error…
Page 97
Register No. Description Operator function stop (STP) Sequence error (SER) Simultaneous FWD/REV run commands (EF) External baseblock (BB) Overtorque detection (OL3) Cooling fan overheat (OH) Main circuit overvoltage (OV) Main circuit undervoltage (UV) 002AH Cooling fan fault (FAN) Communications fault (CE) Option card communications error (BUS) Undertorque (UL3) Inverter overheat alert (OH3)
Page 98: Storing Constants [Enter Command]

Register No. Description 1 : “ON” 0 : “OFF” P1 ON” 1 : “ON” 0 : “OFF” 002DH 0 : “OFF” P2 ON” 1 : “ON” 3 — F (Not used) Frequency reference loss 1: Frequency reference loss 002EH (Not used) 002FH-0030H Reserved 0031H…
Page 99: Error Codes

VS-606V7 is 100,000; do not execute the ENTER command excessively. When a constant is changed from the digital operator, the constant data on the RAM is written to the non-volatile memory without ENTER command. Register number 0900H is used only for write-in. If this register is read- out, register number error (error code: 02H) occurs.
Page 100: Performing Self-Test

Performing self-test VS-606V7 is provided with a function to perform self-diagnosis for oper- ation check of the serial communication I/F circuit. This function is called self-test. In the self-test, connect the sending terminal with the receiving terminal in the communication section. It assures if the data received by VS-606V7 is not being changed.
Page 101: Using Energy-Saving Control Mode

The greater the energy-saving coefficient is, the greater the output volt- age becomes. When using a motor other than a Yaskawa standard motor, set the motor code corresponding to the voltage and capacity to n158. Then, change the setting of the energy-saving coefficient K2 (n140) by 5% so that the output power becomes the smallest.
Page 102
• Energy-saving voltage lower / upper limit (n141, n142, n159, n160) Sets the upper and lower limits of the output voltage. When the value calculated in the energy-saving control mode is larger than the upper limit (or smaller than the lower limit), the value is output as a voltage reference value.
Page 103: Energy Saving Search Operation

Energy-saving search operation In the energy-saving control mode, the max. applicable voltage is calculated using the output power. However, a temperature change or the use of another manufacturer’s motor will change the fixed constants, and the max. applicable voltage may not be emitted. In the search operation, change the voltage slightly so that the max.
Page 104
• Search operation power detection hold width (n161) When the power fluctuation is less than this value, the output voltage is held for 3 seconds. Then, the search operation mode is activated. Set the hold width in % of the power which is currently held. Constant Setting Initial…
Page 105: Motor Code

K2: n140 0.1 kW 481.7 0.2 kW 356.9 0.4 kW 288.2 0.75 kW 223.7 200V 1.5 kW 169.4 2.2 kW 156.8 YASKAWA 3.7 kW 122.9 General- purpose 0.2 kW 713.8 Motor 0.4 kW 576.4 0.75 kW 447.4 1.5 kW 338.8 400V 2.2 kW…
Page 106: Using Pid Control Mode

Using PID Control Mode For details of the PID control setting, refer to the block diagram of the Inverter’s internal PID control or the block diagram of the operator ana- log speed reference. PID Control Selection: n128 Constant Setting Initial Name Unit Range…
Page 107
Notes: 1.When selecting frequency reference from the control circuit terminal FR as the target or feedback value, the V-I switch of SW2 on the control circuit board must be selected depending on the input method (current or voltage input). 2.Never use the frequency reference from the control circuit terminal FR for both the target and feedback values.
Page 108
• Integral (I) Limit (n134) Constant Setting Initial Name Unit Range Setting n134 Upper limit of integral values 0 to 100 This constant prevents the calculated value of the integral control from exceeding the fixed amount.There is normally no need to change the set- ting.
Page 109
• PID Output Gain (n163) Constant Setting Initial Name Unit Range Setting n163 PID output gain Multiples 0.0 to 25.0 This constant adjusts the output gain. • PID Feedback Value Adjusting Gain (n129) Constant Setting Initial Name Unit Range Setting n129 Multiples 1.00…
Page 112: Using Constant Copy Function

Using Constant Copy Function Constant copy function The VS-606V7 standard digital operator JVOP-140 can store constants for one inverter. A backup power supply is not necessary since EEPROM is used. Constant copy function is possible only for the inverters with same product series, power supply specifications and control mode (V/f control or vector control).
Page 113
Constant No. Name Unit Setting Range Initial Setting rdy: READY rEd: READ Constant copy CPy: COPY vFy: VERIFY n176 function vA: Inverter selection capacity display Sno: Software No. display • Prohibiting constant read selection (n177) Select this function to prevent accidentally overwriting the constants stored in EEPROM or in the digital operator.
Page 114: Read Function

READ function Reads out the constants in batch from the inverter and stores them in EEPROM inside the digital operator. When the read-out is executed, the previously stored constants data in the EEPROM are cleared and replaced with the newly entered constants. [Example] Store the constants read out from the inverter, in the EEPROM inside the digital operator.
Page 115: Copy Function

COPY function Writes the constants stored inside the digital operator in batch to the inverter. Write-in is possible only for the inverters with same product series, power supply specifications and control mode (V/f control or vector control). Therefore, writing from 200 V class to 400 V class (or vice versa), from V/f control mode to vector control mode (or vice versa), and from VS-606V7 to VSmini J7 are not possible.
Page 116
[ Example ] Write the constants from EEROM inside the degital operator to the inverter Explanation Operator display N001 • Enable the settings for the • Press DSPL to light [PRGM] constants n001 to n179. (Can be a different constant No.) 1 (Lit) •…
Page 117: Verify Function

VERIFY function Collates the constants stored in the digital operator with the constant in the inverter. As well as write-in, VERIFY is possible only for the inverters with same product series, power supply specifications and control mode (V/f control or vector control). When the constants stored in the digital operator correspond to those in the inverter, vFy is displayed by blinking, then End is displayed.
Page 118: Inverter Capacity Display

Operator display Explanation N01 1 (Blinks) (When n011 is • Display the unmatched • Press ENTER. constant No. unmatched) • Press ENTER. 60. 0 (Blinks) • Display the constant value in the inverter. • Press key. 50. 0 (Blinks) • Display the constant value in •…
Page 119: Software No. Display

Operator display Explanation N001 • Enable the setting for the • Press DSPL to light [PRGM]. constans n001 to n179. • Press ENTER to display the (Can be a different constant No.) 1 (Lit) set value. • Change the set value to 4 by (Can be a different constant No.) 4 (Bl inks) Pressing…
Page 120: Display List

Display List Operator Description Corrective action display Lit: Setting for constant copy function selection enabled Lit: READ selected Blinks: READ under execution Lit: Writing (COPY) selected Blinks: Writing (COPY) under execution Lit: VERIFY selected Blinks: VERIFY under execution Lit: Inverter capacity display selected Lit: Software No.
Page 121: Function Outline

Unit selection for Frequency Reference Setting/Display Constants and monitor display for which selection of unit function is valid Item Contents Frequency reference 1 to 8 (Constants n024 to n031) Frequency reference Jog frequency reference (Constant n032) constants Frequency reference 9 to 16 (Constants n120 to n127) Frequency reference display (FREF) Output frequency display (FOUT) Monitor display…
Page 122
Constant n035 Description Setting • Set the display value at 100% of frequency reference (set value of Fmax(n011)) at 1st to 4th digit of n035. By a number of 4th digit of n035, set the position of decimal point. By 1st to 4th digit of n035, set a 3-digits figure excluding decimal point. Number of 4th digit.
Page 123: Selecting Processing For Frequency Reference Loss (N064)

Selecting Processing for Frequency Reference Loss (n064) Use this setting to select the processing performed if the level of the frequency reference signal from the control circuit terminals suddenly drops. Constant n064 Setting Description Processing for frequency reference loss disabled. Processing for frequency reference loss enabled.
Page 124: Input/Output Open-Phase Detection

Input/Output Open-phase Detection Constant No. Name Setting Range Initial Setting Input Open-phase Setting unit: 1% Detection Level Setting range: 0 to 100%*1 n166 400.0 V/100% (200 V Class) 800.0 V/100% (400 V Class) Input Open-phase Setting unit: 1 s Detection Time Setting range: 0 to 255 s*2 n167 Output Open-phase…
Page 125: Undertorque Detection

Undertorque Detection An alarm signal can be output to a multi-function output terminal (MA, MB, P1, or P2) when the load on the machine side suddenly becomes lighter (i.e., when an undertorque occurs). To output an undertorque detection signal, set the output terminal function selection in n057, n058, or n059 to 8 (undertorque detected, NO contact) or 9 (undertorque detected, NC contact).
Page 126
Underorque detection level (n118) Sets the undertorque detection current level in units of 1%. (Inverter rated current = 100%) when detected by torque is selected, motor rated torque becomes 100%. Initial setting = 10% Undertorque detection time (n119) If the time for which the motor current is less than the undertorque detection level (n118) is longer than the undertorque detection time (n119), the undertorque detection function operates.
Page 127: Using Inverters For Elevating Machines

Using Inverters for Elevating Machines When using the VS-606V7 for elevating machines such as elevators and cranes, make sure that the brake holds and observe the following precautions for safe operation. Brake ON/OFF Sequence • For the holding brake’s ON/OFF sequence, use the following inverter output signals according to the set control mode.
Page 128
• Sequence Circuit Configuration and Timing Chart Examples For the AC sequence circuit, connect the signal between P1 and Holding brake PC to the sequence circuit with a auxiliary relay coil INVERTER VS-606V7 relay. +24V Fault contacts Design the sequence so that the (Forward run) Sequence hoiding brake contact is open…
Page 129
Stall Prevention During Deceleration If connecting a braking resistor to discharge regenerative energy, be sure to set the stall prevention during deceleration (n092) to 1. If the stall prevention during deceleration (n092) is set to the initial NOTE value 0 (Enabled), the motor may not stop within the specified decelerating time.
Page 130
When a contactor is installed between the inverter and the motor, enable the I/O open-phase protection (n166 to n169). For more information on using Inverters exclusively for elevators or cranes, contact your Yaskawa representatives or the nearest Yaskawa sales office.
Page 131: Maintenance And Inspection

7. MAINTENANCE AND INSPECTION Periodical Inspection Periodically inspect the inverter as described in the following table to prevent accidents and to ensure high performance with high-reliability. Location to Check Check For Solution Terminals, unit Connection hardware is Properly seat and tighten mounting screws, properly seated and hardware.
Page 132: Replacement Of Cooling Fan

Replacement of cooling fan • Inverter of W-dimension (width) 68mm (2.68 inches), 140mm (5.51inches), and 170mm (6.69 inches) 1. Removal (1) Press the right and left clicks of the fan cover to direction 1, and then pull them to direction 2 to remove the fan cover from the inverter unit.
Page 133
• Inverter of W-dimension (width) 108mm (4.25 inches) 1. Removal (1) Remove the front cover and terminal cover, and then remove the cooling fan connector (CN10). (2) Press the right and left clicks of the fan cover to direction 1, and COOLING FAN WIRE pull the fan cover to direction 2…
Page 134: Fault Diagnosis

8. FAULT DIAGNOSIS Protective and Diagnostic Function This section describes the alarm and fault displays, explanations for fault conditions and corrective actions to be taken if the VS-606V7 malfunctions. < Corrective actions for models with blank cover > 1. Input fault reset or cycle the power supply OFF and ON. 2.
Page 135: Corrective Actions Of Models With Digital Operator

<Corrective Actions of Models with Digital Operator> : ON : BLINKING : OFF Alarm Display and Contents Alarm Display Causes and Inverter Explanation Digital RUN (Green) Corrective Actions Status Operator ALARM (Red) Check the following : UV (Main circuit low voltage) Main circuit DC voltage •…
Page 136
Alarm Display Causes and Inverter Explanation Digital RUN (Green) Corrective Actions Status Operator ALARM (Red) OP? (Constant setting Check the setting values. error when the constant setting is performed through the MEMOBUS communications) OP1: Two or more values are set for multi- function input selection.
Page 137
Alarm Display Causes and Inverter Explanation Digital RUN (Green) Corrective Actions Status Operator ALARM (Red) BB (External baseblock) Check the external circuit Baseblock command at (sequence). multi-function terminal is active, the inverter output is shut OFF (motor coasting). Blinking Temporary condition is cleared when input command is removed.
Page 138: Causes And Corrective Actions

Fault Display and Contents Fault Display Causes and Inverter Explanation Digital RUN (Green) Corrective Actions Status Operator ALARM (Red) • Short circuit or OC (Overcurrent) grounding at inverter Inverter output current output side momentarily exceeds approx. 250% of rated • Excessive load GD current.
Page 139
Fault Display Causes and Inverter Explanation Digital RUN (Green) Corrective Actions Status Operator ALARM (Red) UV2 (Control power Cycle power. supply fault) If the fault remains, Voltage fault of control replace the inverter. power supply is detected. • Excessive load OH (Cooling fin overheat) Temperature rise •…
Page 140: Fault Display

Fault Display Causes and Inverter Explanation Digital RUN (Green) Corrective Actions Status Operator ALARM (Red) • Open phase of input (Main circuit voltage fault) supply The main circuit’s DC • Occurrence of momentary voltage oscillated in an power loss irregular way when not in •…
Page 141
Fault Display Causes and Inverter Explanation Digital RUN (Green) Corrective Actions Status Operator ALARM (Red) EF1: External fault input Check the external circuit command from control (sequence). circuit terminal S1 EF2: External fault input command from control circuit terminal S2 EF3: External fault input command from control circuit terminal S3…
Page 142
Fault Display Cauces and Inverter Explanation Digital RUN (Green) Corrective Actions Status Operator ALARM (Red) Communication option card self diagnostic error Option card fault Communication option card Replace the option card. model code error Protective Operation Communication option card Output is DPRAM error shut OFF and motor…
Page 143: Troubleshooting

Troubleshooting Trouble Cause Corrective Actions The motor does not The operation method selection is Set the run command (n003) to operate when an wrong. Control Circuit Terminal. external operation The run command (n003) is not set signal is input. to Control Circuit Terminal. A 3-wire sequence is in effect.
Page 144
Trouble Cause Corrective Actions The motor speed is The stall prevention level during Check if the stall prevention level unstable. running is too low. during running (n094) is set to an The motor speed Because the stall prevention level appropriate value. fluctuates when during running (n094) is too low, the operating with a…
Page 145: Specification

9. SPECIFICATIONS Standard Specifications (200V Class) Voltage Class 200V single- / 3-phase 20P1 20P2 20P4 20P7 21P5 22P2 24P0 phase Model CIMR-V7 C???? Single- B0P1 B0P2 B0P4 B0P7 B1P5 B2P2 B4P0 phase Max. Applicable Motor Output 0.25 0.55 ∗ Inverter Capacity(kVA) Rated Output 17.5 Current(A)
Page 146: Standard Specifications (400V Class)

200V single- / 3-phase Voltage Class 20P1 20P2 20P4 20P7 21P5 22P2 24P0 phase Model CIMR-V7 C???? Single- B0P1 B0P2 B0P4 B0P7 B1P5 B2P2 B4P0 phase Motor Overload Electronic thermal overload relay Protection Motor coasts to a stop at approx. 250% of inverter rated Instantaneous current Overcurrent…
Page 147
200V single- / 3-phase Voltage Class 20P1 20P2 20P4 20P7 21P5 22P2 24P0 phase Model CIMR-V7 C???? Single- B2P2 B4P0 B0P1 B0P2 B0P4 B0P7 B1P5 phase Status Indicator RUN and ALARM provided as standard LED’s Digital Operator Available to monitor frequency reference, (JVOP-140) output frequency, output current Main circuit: screw terminals…
Page 148: Standard Specifications (400V Class)

Standard Specifications (400V Class) Voltage Class 400V 3-phase 40P2 40P4 40P7 41P5 42P2 43P0 44P0 phase Model CIMR-V7 C???? Single- — — — — — — — phase Max. Applicable Motor Output 0.37 0.55 Inverter Capacity(kVA) Rated Output Current(A) Max. Output Voltage(V) 3-phase, 380 to 460V (proportional to input voltage) Max.
Page 149
400V 3-phase Voltage Class 40P2 40P4 40P7 41P5 42P2 43P0 44P0 phase Model CIMR-V7 C???? Single- — — — — — — — phase Motor Overload Electronic thermal overload relay Protection Motor coasts to a stop at approx. 250% of inverter rated Instantaneous current Overcurrent…
Page 150
400V 3-phase Voltage Class 40P2 40P4 40P7 41P5 42P2 43P0 44P0 phase Model ∗ CIMR-V7 C???? Single- – – – – – – – phase Status Indicator RUN and ALARM provided as standard LED’s Digital Operator Available to monitor frequency reference, (JVOP-140) output frequency, output current Main circuit: screw terminals…
Page 151: Standard Wiring

Standard Wiring THERMAL BRAKING DC REACTOR OVERLOAD RESISTOR (OPTIONAL) RELAY (OPTIONAL) SHORT-CIRCUIT BAR* MCCB R/L1 FOR SINGLE-PHASE. S/L2 U/T1 USE R/L1 AND S/L2. T/L3 V/T2 FORWARD RUN/STOP W/T3 REVERSE RUN/STOP EXTERNAL FAULT (NO CONTACT) FAULT RESET MULTI- MULTI-STEP FUNCTION MULTI-FUNCTION SPEED REF.
Page 152
Connection Example of Braking Resistor Use sequencer to break OVERLOAD RELAY TRIP CONTACT power supply side on BRAKING overload relay trip RESISTOR contact MCCB L1(R) 3-PHASE MOTOR POWER N/L2(S) U/T1 SUPPLY L3(T) V/T2 W/T3 THRX OFF BRAKING RESISTOR UNIT OVERLOAD RELAY TRIP CONTACT THRX MA MC FAULT CONTACT…
Page 153: Terminal Description

Terminal Description Type Terminal Name Function (Signal Level) Use main circuit power input. R/L1, AC power supply (Use terminals R/L1 and S/L2 for single-phase S/L2, input inverters. Never use terminal T/L3.) T/L3 U/T1, Inverter output Inverter output V/T2, W/T3 Braking resistor B1, B2 Braking resistor connection connection…
Page 154: Sequence Input Connection With Npn/Pnp Transistor

Sequence input connection with NPN/PNP transistor When connecting sequence inputs(S1 to S7) with transistor, turn the rotary switch SW1 depending on the polarity(0V common: NPN side, +24V common: PNP side). Factory setting: NPN side Sequence connection with NPN transistor (0V common) VS-606V7 Forward run / stop Reverse run/ stop…
Page 155
Sequence connection with PNP transistor (+24V common) VS-606V7 Forward run / stop Reverse run / stop External fault (NO) External power Multi- Fault reset supply function +24V input Multi-step speed reference 1 Multi-step speed reference2 JOG command +24V…
Page 156: Dimensions/Heat Loss

Dimensions / Heat Loss (0.33) Fig. 1 (0.33) Fig. 2…
Page 157
Dimensions in mm (inches)/mass in kg (lb) / Heat Loss (W) Heat Loss (W) Voltage Capacity Mass Heatsink Fig. Unit Total class (kW) 13.0 (2.68) (5.04) (2.99) (2.20) (4.65) (0.20) (1.32) 0.25 10.3 18.0 (2.68) (5.04) (2.99) (2.20) (4.65) (0.20) (1.32) 0.55 15.8…
Page 158: Recommended Peripheral Devices

17.5 MCCB type NF30 (MITSUBISHI) Magnetic contactor type HI HI-7E HI-7E HI-7E HI-7E HI-10- HI-10- HI-20E (YASKAWA CONTROL) Fuse ( UL Class RK5 ) • 200V single-phase V7 * * V7 * * V7 * * V7 * * V7 * *…
Page 159
Surge suppressors Surge Suppressors Model Code No. Specifications Coils and relays DCR2- 250VAC 50A22E Large size magnetic contactors C002417 0.5µF 200Ω 200V Control relays 250VAC MY-2,-3 (OMRON) 230V 10A25C C002482 0.1µF 100Ω HH-22, -23(FUJI) MM-2, -4 (OMRON) • Ground fault interrupter: Select a ground fault interrupter not affected by high frequencies.
Page 160: Constants List

Constants List • Addition of constants accompanied by the upgraded software version The constants marked with #1, #2, and #3 are applicable for the following upgraded software version Nos.: #1: Applicable for software version No. VSP 010015 or later #2: Applicable for software version No. VSP 010020 or later #3: Applicable for software version No.
Page 161
First Functions (Constants n001 to n049) Register No. for Setting Setting Initial User Ref. Name Trans- Range Unit Setting Setting Page mission 001 0101H Password 0 to 4, 6, 12,13 0102 0, 1 Control mode selection (Note 6) (Note 1) (Note 6) Run command 0103 0 to 3…
Page 162
Register No. for Setting Setting Initial User Ref. Name Trans- Range Unit Setting Setting Page mission 0.01Hz (less than 100Hz) / 0.00Hz 011A Frequency reference 3 0.00 to 400.0Hz 0.1Hz (100Hz or more) 0.01Hz (less than 100Hz) / 011B Frequency reference 4 0.00Hz 0.00 to 400.0Hz 0.1Hz (100Hz or…
Page 163
Second Functions (Constants n050 to n079) Register No. for Setting Setting Initial User Ref. Name Trans- Range Unit Setting Setting Page mission Multi-function input 1 to 25, 26#3, 0132 selection 1 (Terminal S1) 27#3 0133 Multi-function input 1 to 25, 26#3, selection 2 (Terminal S2) 27#3 Multi-function input…
Page 164
Register No. for Setting Setting Initial User Ref. Name Trans- Range Unit Setting Setting Page mission 014D Multi-function analog 0 to 4 input function Multi-function analog 014E input signal selection 014F Frequency reference 0 to 50% bias(FBIAS) value Third Functions (Constants n080 to n119) Register No.
Page 165
Register No. for Setting Setting Initial User Ref. Name Trans- Range Unit Setting Setting Page mission Speed search deceleration 0165 0.1 to 10.0s 0.1s 2.0s time Speed search operation 0166 0 to 200% 150% level 0167 Torque compensation gain 0.0 to 2.5 Torque compensation 0.3s 0168…
Page 166
Fourth Functions (Constants n120 to n179) Register No. for Setting Setting Initial User Ref. Name Trans- Range Unit Setting Setting Page mission 0.01Hz (less than 100Hz) / 0.00Hz 120 0178 Frequency reference 9 0.00 to 400.0Hz 0.1Hz (100Hz or more) 0.01Hz (less than 100Hz) / 0.00Hz…
Page 167
Register No. for Setting Setting Initial User Ref. Name Trans- Range Unit Setting Setting Page mission Selection of PID 0188 0 to 2 feedback loss detection PID feedback loss 0189 0 to 100% detection level PID feedback loss 018A 0.1s 0.0 to 25.5 detection time Energy-saving control…
Page 168
Register No. for Setting Setting Initial User Ref. Name Trans- Range Unit Setting Setting Page mission Motor code 019E 0 to 70 (Note 7) (Energy-saving control) Upper voltage limit for energy- 019F 0 to 120% 120% saving control (At 60Hz) Upper voltage limit for energy- 01A0 0 to 25%…
Page 169
Notes: 1. Not initialized by constant initialization. 2. Upper limit of setting range and initial setting are doubled at 400V class. 3. Changes depending on inverter capacity. Refer to the next page. 4. Changes depending on inverter capacity. Refer to page 67. 5.
Page 170
< 400V class 3-phase Name Unit – Inverter capacity – 0.37kW 0.55kW 1.1kW 1.5kW 2.2kW 3.0kW 4.0kW n036 Motor rated current – Torque compensation n105 – 11.0 11.7 19.3 19.3 iron loss n106 Motor rated slip – Line to neutral Ω…
Page 171
NOTES…
Page 172
NOTES…
Page 173: Revision History

Revision History The revision dates and numbers of the revised manuals are given on the bottom of the back cover. MANUAL NO. TOE-S606-11E © Printed in Japan August 2003 98-06 Revision number Date of Date of original printing publication Rev. Date of printing Section Revised Content…
Page 174
Rev. Date of printing Section Revised Content Chapter 6 Revision: Description of using four acceleration/ deceleration time patterns Addition: Description of orvertorque/ undertorque detection function selection 2 Addition: Setting 6 Frequency Reference Monitor, for analog output terminals Addition: Monitor data 0029AH, 002AH, and 002EH Addition: Description of the processing method for frequency reference loss…
Page 176
TAIPEI OFFICE 9F, 16, Nanking E. Rd., Sec. 3, Taipei, Taiwan Phone 886-2-2502-5003 Fax 886-2-2505-1280 SHANGHAI YASKAWA-TONGJI M & E CO., LTD. 27 Hui He Road Shanghai China 200437 Phone 86-21-6553-6060 Fax 86-21-5588-1190 BEIJING YASKAWA BEIKE AUTOMATION ENGINEERING CO., LTD.

Источник

Contents
Table of Contents
Troubleshooting
Bookmarks

Quick Links

VS-606V7 Series

INSTRUCTION MANUAL

COMPACT GENERAL-PURPOSE INVERTER

(VOLTAGE VECTOR CONTROL)

Upon receipt of the product and prior to initial operation, read these instructions

thoroughly and retain them for future reference.

YASKAWA

MANUAL NO. TOE-S606-11.2H

Related Manuals for YASKAWA VS-606V7 Series

Summary of Contents for YASKAWA VS-606V7 Series

Page 1: Instruction Manual

YASKAWA VS-606V7 Series INSTRUCTION MANUAL COMPACT GENERAL-PURPOSE INVERTER (VOLTAGE VECTOR CONTROL) Upon receipt of the product and prior to initial operation, read these instructions thoroughly and retain them for future reference. YASKAWA MANUAL NO. TOE-S606-11.2H…
Page 2: General Precautions

PREFACE Yaskawa’s VS-606V7 is a small and simple Inverter; as easy to use as a contactor. This instruction manual describes installation, maintenance, inspection, troubleshooting, and specifications of the VS-606V7. Read this instruction manual thoroughly before operation. YASKAWA ELECTRIC CORPORATION General Precautions •…
Page 3: Notation For Safety Precautions

NOTATION FOR SAFETY PRECAUTIONS Read this instruction manual thoroughly before installation, operation, mainte- nance, or inspection of the VS-606V7. In this manual, safety precautions are classified as either warnings or cautions and are indicated as shown below. WARNING Indicates a potentially hazardous situation which, if not avoided, may result in death or serious injury.
Page 4
PRECAUTIONS FOR UL/cUL MARKING • Do not connect or disconnect wiring, or perform signal checks while the power supply is turned ON. • The Inverter internal capacitor is still charged even after the power supply is turned OFF. To prevent electric shock, disconnect all power before ser- vicing the Inverter, and then wait at least one minute after the power sup- ply is disconnected.
Page 5
RECEIVING THE PRODUCT CAUTION (Ref. page) • Do not install or operate any Inverter that is damaged or has missing parts. Failure to observe this caution may result in injury or equipment damage. MOUNTING CAUTION (Ref. page) • Lift the Inverter by the heatsinks. When moving the Inverter, never lift it by the plastic case or the terminal cover.
Page 6
WIRING WARNING (Ref. page) • Only begin wiring after verifying that the power supply is turned OFF. Failure to observe this warning may result in an elec- tric shock or a fire. • Wiring should be performed only by qualified personnel.
Page 7
CAUTION (Ref. page) • Verify that the Inverter rated voltage coincides with the AC power supply voltage. Failure to observe this caution may result in personal injury or a fire. • Do not perform a withstand voltage test on the Inverter.
Page 8
OPERATION WARNING (Ref. page) • Only turn ON the input power supply after con- firming that the Digital Operator or blank cover (optional) are in place. Do not remove the Digital Operator or the covers while current is flowing. Failure to observe this warning may result in an elec- tric shock.
Page 9
WARNING (Ref. page) • If an alarm is reset with the operation signal ON, the Inverter will restart automatically. Reset an alarm only after verifying that the operation sig- nal is OFF. Failure to observe this warning may result in injury. •…
Page 10
CAUTION (Ref. page) • If using an Inverter with an elevator, take safety measures on the elevator to prevent the eleva- tor from dropping. Failure to observe this caution may result in injury. • Do not perform signal checks during operation. The machine or the Inverter may be damaged.
Page 11
MAINTENANCE AND INSPECTION WARNING (Ref. page) • Never touch high-voltage terminals on the Inverter. Failure to observe this warning may result in an elec- trical shock. • Disconnect all power before performing mainte- nance or inspection, and then wait at least one minute after the power supply is disconnected.
Page 12
CAUTION (Ref. page) • The control PCB employs CMOS ICs. Do not touch the CMOS elements. They are easily damaged by static electricity. • Do not connect or disconnect wires, connectors, or the cooling fan while power is applied to the circuit.
Page 13: Warning Label

WARNING LABEL A warning label is provided on the front cover of the Inverter, as shown below. Follow the warnings when handling the Inverter. Top Cover (in case of 5.5/7.5 kW) Plastic Case Status Indicators Nameplate Warning Label Location Warning Labels Example of 5.5 kW for 400 V…
Page 14: Warranty Information

Repairs If a Yaskawa product is found to be defective due to Yaskawa workman- ship or materials and the defect occurs during the warranty period, Yaskawa will provide a replacement, repair the defective product, and provide shipping to and from the site free of charge.
Page 15
Exceptions Any inconvenience to the customer or damage to non-Yaskawa products due to Yaskawa’s defective products whether within or outside the war- ranty period are NOT covered by this warranty. RESTRICTIONS • The VS-606V7 was not designed or manufactured for use in devices or systems that may directly affect or threaten human lives or health.
Page 16: Table Of Contents

CONTENTS NOTATION FOR SAFETY PRECAUTIONS — — — — — — 2 1. Receiving the Product — — — — — — — — — — — — — — — — — — — 20 Checking the Nameplate — — — — — — — — — — — — — — — — — — — — — — — — — — — 21 2.
Page 17
Function Indicator Description- — — — — — — — — — — — — — — — — — — — — — — — 47 MNTR Multi-function Monitoring — — — — — — — — — — — — — — — — — — — — — — 48 Input/Output Terminal Status — — — — — — — — — — — — — — — — — — — — — — — — — 50 Data Reception Error Display — — — — — — — — — — — — — — — — — — — — — — — — 50 Simple Data Setting — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — 52…
Page 18
Jump Frequencies (n083 to n086) — — — — — — — — — — — — — — — — — — — — 76 Continuing Operation Using Automatic Retry Attempts (n082) — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — 77 Operating a Coasting Motor without Tripping — — — — — — — — — — — — — 77 Holding Acceleration/Deceleration Temporarily — — — — — — — — — — — 78 Using Frequency Meter or Ammeter (n066) — — — — — — — — — — — — — — 79…
Page 19
Using Energy-saving Control Mode — — — — — — — — — — — — — — — — — — — 125 Energy-saving Control Selection (n139) — — — — — — — — — — — — — — — — 125 Energy-saving Search Operation- — — — — — — — — — — — — — — — — — — — — 126 Motor Code — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — 129 Using PID Control Mode- — — — — — — — — — — — — — — — — — — — — — — — — — — 130…
Page 20
8. Fault Diagnosis — — — — — — — — — — — — — — — — — — — — — — — 165 Protective and Diagnostic Functions — — — — — — — — — — — — — — — — — — 165 Corrective Actions of Models with Blank Cover — — — — — — — — — — 165 Corrective Actions of Models with Digital Operator — — — — — — — — 166 Troubleshooting — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — 178…
Page 21: Receiving The Product

1. Receiving the Product Do not install or operate any Inverter that is damaged or CAUTION has missing parts. Failure to observe this caution may result in injury or equipment damage. After unpacking the VS-606V7, check the following. • Verify that the model number matches your purchase order or packing slip.
Page 22: Checking The Nameplate

With Digital Operator (with potentiometer) 3.7 kW Without Digital Operator (with blank cover) 5.5 kW With Digital Operator (without potentiometer) 7.5 kW Note: Contact your Yaskawa representatives for models without heatsinks. Voltage Class Single-phase 200 VAC Three-phase 200 VAC Three-phase 400 VAC…
Page 23: Identifying The Parts

2. Identifying the Parts Digital Operator Terminal Cover Wiring Holes for Control Circuit Front Cover Wiring Holes Nameplate for Main Circuit Heatsink Bottom Cover Ground Terminal Cooling Fan Fan Cover Digital operator Digital operator Blank cover (with potentiometer) (without potentiometer) In models without a JVOP-140 JVOP-147…
Page 24
2. Identifying the Parts VS-606V7 Inverters with the Covers Removed Frequency Setting Potentiometer Inverter Operation Status Indicators Terminal Resistor Switch for Input Polarity Communication Circuit Switch Voltage/Current Change Switch for Analog Frequency Reference Input Short-circuit Control Circuit Terminal Block Main Circuit Terminal Block Ground Terminals Example for 3-phase (200 V Class, 1.5 kW) Inverter Frequency Setting Potentiometer…
Page 25
Main Circuit Terminal Arrangement The terminal arrangement of the main circuit terminals depends on the Inverter model. CIMR-V7∗T20P1 to 20P7, B0P1 to B0P4 CIMR-V7∗T21P5, 22P2, B0P7, B1P5, 40P2 to 42P2 CIMR-V7∗T23P7, B2P2, 43P0, 43P7 CIMR-V7∗TB3P7 CIMR–V7∗T25P5, 27P5, 45P5, 47P5 R/L1 S/L2 T/L3 B2 U/T1 V/T2 W/T3…
Page 26: Mounting

3. Mounting 3. Mounting Choosing a Location to Mount the Inverter Be sure the Inverter is protected from the following conditions. • Extreme cold and heat. Use only within the specified ambient tem- perature range: −10 to 50°C for IP20 (open chassis type), −10 to 40°C for NEMA 1 (TYPE 1) •…
Page 27: Mounting Dimensions

Mounting Dimensions To mount the VS-606V7, the dimensions shown below are required. 100 mm or more 100 mm or more Max. Applicable Voltage Class Length a Motor Capacity (kW) 200 V Single-phase 3.7 kW or less 30 mm min. 3-phase 400 V 3-phase 5.5 kW 200 V 3-phase…
Page 28: Mounting/Removing Components

3. Mounting • The same space is required horizontally and vertically and right and left for both Open Chassis (IP00, IP20) and NOTE Enclosed Wall-mounted (NEMA 1) Inverters. • Always remove the top and bottom covers before install- ing a 200 or 400 V Class Inverter with an output of 5.5/7.5 kW in a panel.
Page 29: Mounting The Terminal Cover

• Inverters with Width of 180 Use a screwdriver to loosen the screw (section B) on the termi- nal cover surface. (This screw can not be removed to prevent loss.) Then press the right and left sides in direction 1 and lift the terminal cover in direction Mounting the Terminal Cover Mount the terminal cover by…
Page 30: Removing The Bottom Cover

3. Mounting Removing the Bottom Cover • Inverters with Width of 108 mm, 140 mm or 170 mm After removing the front cover and the terminal cover, tilt the bottom cover in direction 1 with section A as a supporting point.
Page 31: Wiring

4. Wiring • Only begin wiring after verifying that the power sup- WARNING ply is turned OFF. Failure to observe this warning may result in an electric shock or a fire. • Wiring should be performed only by qualified per- sonnel.
Page 32
4. Wiring emergency stop by using the external terminals. Delayed response may cause injury or damage the machine. Wiring Instructions NOTE 1. Always connect the power supply for the main circuit inputs to the power input terminals R/L1, S/L2, and T/L3 (R/L1, S/L2 for single-phase power) via a molded-case circuit breaker (MCCB) or a fuse.
Page 33: Wire And Terminal Screw Sizes

wire size. Voltage drop can be calculated using the following equa- tion: Phase-to-phase voltage drop (V) × wire resistance (Ω/km) × wiring distance (m) × current (A) × 10 Select a wire size so that voltage drop will be less than 2% of the normal rated voltage.
Page 34
4. Wiring 2. Main Circuits 200 V Class 3-phase Input Inverters Model Terminal Symbols Screws Tightening Wires Torque Applicable Size Recommended Type N•m Size CIMR- R/L1, S/L2, T/L3, M3.5 0.8 to 1.0 0.75 to 2 18 to 14 600 V vinyl- V7∗T -, +1, +2, B1, B2, sheathed or…
Page 35
200 V Class Single-phase Input Inverters Model Terminal Symbols Screws Tightening Wires Torque Applicable Size Recommended Type N•m Size CIMR- R/L1, S/L2, T/L3, M3.5 0.8 to 1.0 0.75 to 2 18 to 14 600 V vinyl- V7∗T -, +1, +2, B1, B2, sheathed or B0P1 U/T1, V/T2, W/T3…
Page 36
4. Wiring 400 V Class 3-phase Input Inverters Model Terminal Symbols Screws Tightening Wires Torque Applicable Size Recommended Type N•m Size CIMR- R/L1, S/L2, T/L3, 1.2 to 1.5 2 to 5.5 14 to 10 600 V vinyl- V7∗T -, +1, +2, B1, B2, sheathed or 40P2 U/T1, V/T2, W/T3…
Page 37: Wiring The Main Circuits

Wiring the Main Circuits [Example of 3-phase, 400 V class, 0.2 kW Inverters] MCCB or Leakage Breaker Grounding • Main Circuit Input Power Supply Always connect the power supply line to input terminals R/L1, S/L2, and T/L3 (R/L1, S/ L2 for single-phase Inverters). Never connect them to terminals U/T1, V/T2, W/T3, B1, B2, −, +1, or +2.
Page 38
4. Wiring • Braking Resistor Connection (Optional) To connect the braking resistor, cut the protector on terminals WARNING B1 and B2. To protect the braking resistor from overheating, install a ther- mal overload relay between the braking resistor and the Inverter.
Page 39: Wiring The Control Circuits

Wiring the Control Circuits Only basic insulation is provided for the control circuit terminals. Additional insulation may be necessary in the end product. • Control Circuit Terminals Pass the cable through wiring hole to connect it. Always mount the cover in its original position. Contact Output SW1 can be changed according to sequence input signal (S1 to S7) polarity.
Page 40: Wiring Inspection

4. Wiring • Keep the screwdriver vertical to the Inverter. NOTE • Refer to Page 32 for tightening torques. 5.5 mm The wire sheath strip length must be 5.5 mm. Open the front cover and verify that the strip length is 5.5 mm. 5.5mm Scale CONTACT OUTPUT…
Page 41: Operating The Inverter

5. Operating the Inverter The Control Mode Selection (n002) is initially set to V/f control mode. • Only turn ON the input power supply after confirm- WARNING ing that the Digital Operator or blank cover (optional) are in place. Do not remove the Digital Operator or the covers while current is flowing.
Page 42: Test Run

5. Operating the Inverter Test Run The Inverter operates when a frequency (speed) is set. There are four operating modes for the VS-606V7: 1. RUN command from the Digital Operator (potentiometer/digital set- ting) 2. RUN command from the control circuit terminals 3.
Page 43
Operation Steps Operator Function Status Display Indicators Indicators 1. Turn the potentiometer fully counter- 0.00 FREF clockwise, and then turn the power ON. ALARM 2. F/R will lit. Select FOR or REV RUN using the (Forward) keys. ALARM Never select REV when reverse run is prohibited.
Page 44: Selecting Rotation Direction

5. Operating the Inverter Selecting Rotation Direction It is possible to select the direction in which the motor rotates when the FORWARD RUN command is executed. The motor rotates in the opposite direction when the REVERSE RUN command is executed. n040 Description Setting…
Page 45: Operating The Digital Operator

Operating the Digital Operator All functions of the VS-606V7 are set using the Digital Operator. Below are descriptions of the display and keypad sections. JVOP-140 Digital Operator Data Display Section Indicator/Display Section Function Indicators Indicators switch to another function each time is pressed.
Page 46: Description Of Status Indicators

5. Operating the Inverter Description of Status Indicators There are two Inverter operation status indicators on the middle right section of the face of the VS-606V7. The combinations of these indica- tors indicate the status of the Inverter (ON, flashing, and OFF). RUN indicator and status indicator on the button have the same func- tion.
Page 47
For details on how the status indicators function for Inverter faults, refer to Chapter 8. Fault Diagnosis. If a fault occurs, the ALARM indicator will lit. The fault can be reset by turning ON the FAULT RESET sig- NOTE nal (or by pressing the key on the Digital Operator) with the operation signal OFF, or by turning OFF the power supply.
Page 48: Function Indicator Description

5. Operating the Inverter Function Indicator Description By pressing on the Digital Operator, each of the function indi- cators can be selected. The following flowchart describes each function indicator. Power ON Frequency reference setting/monitoring (Hz) Sets VS-606V7 operating speed. Output frequency monitoring (Hz) Displays frequency that VS-606V7 is If the VS-606V7 loses currently outputting.
Page 49: Mntr Multi-Function Monitoring

If the VS-606V7 is LOCAL/REMOTE Selection stopped after it has This function switches the operation; operation changed to any of using the Digital Operator including frequency setting with potentiometer, operation using the these modes during input terminals, or operation through communications. operation, it changes Setting can be changed using the key.
Page 50
5. Operating the Inverter Monitoring The following items can be monitored using U constants. Constant Name Unit Description U-01 Frequency Reference Frequency reference can be monitored. (Same as FREF) (FREF)* U-02 Output Frequency Output frequency can be monitored. (Same as FOUT) (FOUT)* U-03 Output current can be monitored.
Page 51: Input/Output Terminal Status

In vector control mode, “—” will be displayed. * 4. Applicable only for Inverters of 5.5 kW and 7.5 kW (200-V and 400-V Classes). * 5. Refer to the next page for data reception error. * 6. Displayed in units of 0.1% when less than 100% and in units of 1% when 100% or more.
Page 52
5. Operating the Inverter Fault History Display Method When U-09 is selected, a four-digit box is displayed. The three digits from the right show the fault description, and the digit on the left shows the order of fault (from one to four). Number 1 represents the most recent fault, and numbers 2, 3, 4 represent the other faults, in ascending order of fault occurrence.
Page 53: Simple Data Setting

Simple Data Setting Digital setting (refer to 5. Operating the Inverter) and potentiometer setting are both possible for simple acceleration/deceleration operation of the VS-606V7. Digital setting is set at the factory (n004=0). For the model with JVOP- 147 Digital Operator (without potentiometer), factory setting is set by frequency setting potentiometer (n004=1).
Page 54
5. Operating the Inverter Data setting by frequency setting potentiometer Operation Steps Operator Function Status Display Indicators Indicators 1. Turn ON the power supply. 0.00 FREF ALARM DSPL PRGM 2. Press to make lit, then PRGM set constant n004 to 1. ALARM 3.
Page 55: Programming Features

6. Programming Features Factory settings of the constants are shaded in the tables. After wiring is complete, be sure to make the following settings before oper- ation. Hardware Make the following settings before the Inverter is turned ON. Item Ref. Sequence input signal (S1 to S7) polarity selection Voltage reference / current reference input selection of control circuit terminal FR…
Page 56: Constant Setup And Initialization

6. Programming Features Constant Setup and Initialization Constant Selection/Initialization (n001) If n001=5, a Run command can be received even WARNING while changing a constant. If sending a Run command while changing a constant, such as during a test run, be sure to observe all safety precautions. Failure to observe this warning may result in injury.
Page 57
appears on the display for one second and the set data NOTE returns to its initial values in the following cases. 1. If the set values of Multi-function Input Selections 1 to 7 (n050 to n056) are the same 2. If the following conditions are not satisfied in the V/f pat- tern setting: Max.
Page 58: Using V/F Control Mode

6. Programming Features Using V/f Control Mode V/f control mode is preset at the factory. Control Mode Selection (n002) = 0: V/f control mode (factory setting) 1: Vector control mode Adjusting Torque According to Application Adjust motor torque by using the V/f pattern and full-range automatic torque boost settings.
Page 59
Typical Setting of the V/f Pattern Set the V/f pattern according to the application as described below. For 400-V Class Inverters, the voltage values (n012, n015, and n017) should be doubled. When running at a frequency exceeding 50/60 Hz, change the Maximum Output Frequency (n011). Note: Always set the maximum output frequency according to the motor char- acteristics.
Page 60
6. Programming Features Full-range Automatic Torque Boost (when V/f Mode is Selected: n002=0) The motor torque requirement changes according to load conditions. The full-range automatic torque boost adjusts the voltage of the V/f pat- tern according to requirements. The VS-606V7 automatically adjusts the voltage during constant-speed operation, as well as during accelera- tion.
Page 61: Using Vector Control Mode

1: Vector control mode Precautions for Voltage Vector Control Application Vector control requires motor constants. The Yaskawa standard motor constants have been set at the factory prior to shipment. Therefore, when a motor designed for an Inverter is used or when a motor from any…
Page 62: Motor Constant Calculation

6. Programming Features • If the speed is less than the target value, increase the slip compensa- tion gain. • If the speed is more than the target value, reduce the slip compensa- tion gain. Adjustment of the Slip Compensation Time Constant (n112) is normally not required.
Page 63: V/F Pattern During Vector Control

Set n106 (Motor Rated Slip), n036 (Motor Rated Current), n107 (Motor Line-to-neutral Resistance), and n110 (Motor No-load Current) accord- ing to the motor test report. To connect a reactor between the Inverter and the motor, set n108 to the sum of the initial value of n108 (Motor Leakage Inductance) and the externally mounted reactor inductance.
Page 64: Switching Local/Remote Mode

6. Programming Features When operating with frequency larger than 60/50 Hz, change only the Max. Output Frequency (n011). Constant output or Constant torque variable output n012 =200 V Base point n013 n011 =60 or 50 Hz =90 Hz Switching LOCAL/REMOTE Mode The following functions can be selected by switching LOCAL or REMOTE mode.
Page 65: How To Select Local/Remote Mode

How to Select LOCAL/REMOTE Mode When LOCAL/REMOTE When LOCAL/REMOTE switching function is not switching function is set set for multi-function for multi-function input input selection selection (When 17 is not set (When 17 is set for for any of constants any of constants n050 to n056) n050 to n056)
Page 66: Remote Mode

6. Programming Features REMOTE Mode 1. Select remote mode. There are following two methods to select remote mode. • Select rE (remote mode) for the selection. • When the local/remote switching function is selected for the multi-function input selection, turn OFF the input terminal to select remote mode.
Page 67: Local Mode

LOCAL Mode Select command method using constant n008. n008=0: Enables using the potentiometer on the Digital Operator (factory setting). The factory setting for models with the Digital Operator without a potentiometer (JVOP-147) is n008=1. =1: Enables digital setting on the Digital Operator. [Setting can be stored in Frequency Reference 1 (n024)].
Page 68: Setting Operation Conditions

6. Programming Features Setting Operation Conditions Reverse Run Prohibit (n006) The Reverse Run Prohibit setting disables accepting a reverse RUN command from the control circuit terminal or Digital Operator. This set- ting is used for applications where a reverse RUN command can cause problems.
Page 69: Operating At Low Speed

(n031) 60.0 Hz (n030) 55.0 Hz (n029) 50.0 Hz (n028) 45.0 Hz (n027) 40.0 Hz (n026) 35.0 Hz (n025) 30.0 Hz Frequency (n024) 25.0 Hz reference Time FWD (REV) RUN/STOP Multi-step speed ref. 1 (terminal S5) Multi-step speed ref. 2 (terminal S6) Multi-step speed ref.
Page 70: Adjusting Speed Setting Signal

6. Programming Features Adjusting Speed Setting Signal The relationship between the analog inputs and the frequency reference can be set to provide the frequency reference as analog inputs to control circuit terminal FR or FC. Frequency Reference ( ) indicates the value when a current (4 mA) (20 mA) reference input is selected.
Page 71: Adjusting Frequency Upper And Lower Limits

• To operate the Inverter with a frequency reference of 50% to 100% at an input voltage of 0 to 10 V Max. frequency (100%) 10 V Gain n060 = 100 Bias n061 = 50 Adjusting Frequency Upper and Lower Limits •…
Page 72
6. Programming Features By setting a multi-function input selection (either of n050 to n056) to 11 (acceleration/deceleration time selection 1) or 27 (acceleration/deceler- ation time selection 2), the acceleration/deceleration time is selected by ON/OFF combinations of acceleration/deceleration time selection 1 and acceleration/deceleration time selection 2 (terminals S1 to S7).
Page 73: Momentary Power Loss Ridethrough Method (N081)

n018 Settings Unit Setting Range n018 0.1 s 0.0 to 999.9 s (999.9 s or less) 1000 to 6000 s (1000 s or more) 0.01 s 0.00 to 99.99 s (99.99 s or less) 0.1 s 100.0 to 600.0 s (100 s or more) Note: Constant n018 can be set while stopped.
Page 74: S-Curve Selection (N023)

6. Programming Features * 1. Hold the operation signal to continue operation after recovery from a momentary power loss. * 2. When 2 is selected, the Inverter restarts if power supply voltage recovers while the control power supply is held. No fault signal is output.
Page 75: Torque Detection

Torque Detection If an excessive load is applied to the machine, an increase in the output current can be detected to output an alarm signal to multi-function out- put terminal MA, MB, P1, or P2. To output an overtorque detection signal, set one of the output terminal function selections n057 to n059 for overtorque detection (Setting: 6 (NO contact) or 7 (NC contact)).
Page 76: Frequency Detection Level (N095)

6. Programming Features 3. To stop the Inverter and generate a fault at overtorque detection, set n096 to 2 or 4. At detection, the Digital Operator will display an fault (ON). Overtorque Detection Level (n098) Set the overtorque detection current level in units of 1%. (Inverter rated current = 100%) When detection by torque is selected, the motor rated torque becomes 100%.
Page 77: Jump Frequencies (N083 To N086)

Frequency Detection 1 Output frequency ≥ Frequency Detection Level n095 (Set n057, n058 or n059 to 4.) Release Width −2Hz Frequency Detection Level [Hz] (n095) Output Frequency Frequency Detection Signal Frequency Detection 2 Output frequency ≤ Frequency Detection Level n095 (Set n057, n058 or n059 to 5.) Release Width…
Page 78: Continuing Operation Using Automatic Retry Attempts

6. Programming Features Continuing Operation Using Automatic Retry Attempts (n082) When the fault retry function is selected, stand clear of WARNING the Inverter or the load. The Inverter may restart sud- denly after stopping. (Construct the system to ensure safety, even if the Inverter should restart.) Failure to observe this warn- ing may result in injury.
Page 79: Holding Acceleration/Deceleration Temporarily

Timechart at SEARCH Command Input FWD (REV) RUN Command 0.5 s Min. SEARCH Command Speed Agreement Max. Output Frequency or Detection Frequency Reference at Run Command Input Output Frequency Min. Baseblock Speed Time (0.5 s) Search Operation The deceleration time for speed search operation can be set in n101. If the setting is 0, however, an initial value of 2.0 s will be used.
Page 80: Using Frequency Meter Or Ammeter (N066)

6. Programming Features Timechart for ACCELERATION/DECELERATION HOLD Command Input FWD (REV) RUN Command ACCELERATION/ DECELERATION HOLD Command Frequency Reference Output Frequency FREQUENCY AGREE Signal Note: If a FWD (REV) RUN command is input at the same time as an ACCELERATION/DECELERATION HOLD command, the motor will not operate.
Page 81: Calibrating Frequency Meter Or Ammerter (N067)

In factory setting, analog voltage of approx. 10 V is output when output frequency (output current) is 100 %. Output Frequency (Output Current) Frequency Meter 100 % Analog monitor gain can be set by n067. 10 V Analog Output Calibrating Frequency Meter or Ammerter (n067) Used to adjust analog output gain.
Page 82
6. Programming Features n065 Setting n065 Setting Description Analog monitor output Pulse monitor output (Output frequency monitor) Pulse train signal can be selected by setting in n150. n150 Setting Description Output 1440 Hz/Max. frequency (n011) frequency 1F: Output frequency × 1 monitor 6F: Output frequency ×…
Page 83
Peripheral devices must be connected according to the fol- lowing load conditions when using pulse monitor output. NOTE The machine might damage when the conditions are not satis- fied. Used as a Sourcing Output Output Voltage Load Impedance Load VRL (V) (kΩ) Impedance +5 V…
Page 84: Reducing Motor Noise Or Leakage Current Using Carrier Frequency Selection (N080)

6. Programming Features Reducing Motor Noise or Leakage Current Using Carrier Fre- quency Selection (n080) Set the Inverter output transistor switching frequency (carrier fre- quency). Setting Carrier Frequency (kHz) Metallic Noise and Noise from Current Motor Leakage 12 fout (Hz) 24 fout (Hz) Higher 36 fout (Hz)
Page 85
If the set value is 7, 8, or 9, the carrier frequency will be multiplied by the same factor as the output frequency. n080=7 fc=Carrier Frequency 2.5 kHz fc=12 fout 1.0 kHz fout=Output Frequency 83.3 Hz 208.3 Hz n080=8 fc=Carrier Frequency 2.5 kHz fc=24 fout 1.0 kHz…
Page 86
6. Programming Features Voltage Capacity Factory Setting Maximum Reduced Class (V) (kW) Continuous Current Setting Carrier Frequency Output Current (kHz) 200 V Single- phase or 3-phase 400 V 3-phase 0.75 14.8 * Reduction of the current is not necessary. 1. Reduce the continuous output current when changing the NOTE carrier frequency to 4 (10 kHz) for 200 V Class (1.5 kW or more) and 400 V Class Inverters.
Page 87: Operator Stop Key Selection (N007)

2. If the wiring distance is long, reduce the Inverter carrier frequency as described below. Wiring Distance Up to 50 m Up to 100 m More than 100 m between Inverter and Motor Carrier Fre- 10 kHz or less 5 kHz or less 2.5 kHz or less quency (n080 (n080=1, 2, 3, 4,…
Page 88: Selecting The Stopping Method

6. Programming Features Set the processing when the STOP key is pressed during operation either from a multi-function input terminal or communications. Setting Description The STOP key is effective either from a multi- function input terminal or communications. When the STOP key is pressed, the Inverter stops ac- cording to the setting of constant n005.
Page 89: Applying Dc Injection Braking

ates because the frequency reference is set lower than the Min. Output Frequency (n016) when the FWD (REV) RUN command is ON. If the deceleration time is short or the load inertia is large, an overvoltage (OV) fault may occur at deceleration. In this case, increase the decelera- tion time or install an optional Braking Resistor.
Page 90
6. Programming Features n016 Min. Output Frequency n090 DC Injection Braking Time at Stop When coasting to a stop is specified in the Stopping Method Selection (n005), DC injection braking is not applied when stopping.
Page 91: Building Interface Circuits With External Devices

Building Interface Circuits with External Devices Using Input Signals The functions of multi-function input terminals S1 to S7 can be changed as necessary by setting constants n050 to n056. The same value cannot be set for more than one of these constants. Setting Name Description…
Page 92
6. Programming Features Setting Name Description Ref. ACCELERATION/ DECELERATION HOLD command LOCAL/REMOTE selection Communications/control cir- cuit terminal selection Emergency stop fault, Inverter stops for an emergen- NO contact input cy stop signal input according to the Stopping Method Selec- Emergency stop alarm, tion (n005).
Page 93
Factory Settings Terminal Factory Setting Function n050 FORWARD RUN command (2-wire sequence) n051 REVERSE RUN command (2-wire sequence) n052 External fault (NO contact input) n053 Fault reset n054 Multi-step speed reference 1 n055 Multi-step speed reference 2 n056 JOG command Terminal Functions for 3-wire Sequence Selection When 0 is set for terminal S3 (n052), terminal S1 is the RUN command, terminal S2 is the STOP command, and terminal S3 is the FWD/REV…
Page 94
6. Programming Features Example: Set n003=1, n004=2, n008=0. Open: Run according to the frequency reference from multi-function input terminal FR and RUN command from multi-function input terminals S1 to S7. Closed: Run according to the potentiometer frequency reference and RUN command from the Digital Operator. UP/DOWN Commands (Setting: n056 = 34) When the FWD (REV) RUN command is ON, acceleration/deceleration is enabled by inputting the UP or DOWN signal from multi-function…
Page 95: Using The Multi-Function Analog Inputs (N077, N078, N079)

Note: 1. When UP/DOWN commands are selected, the upper limit speed is set regardless of frequency reference. Upper limit speed = Maximum Output Frequency (n011) × Frequency Reference Upper Limit (n033)/100 2. Lower limit value is either the Minimum Output Frequency (n016) or the Frequency Reference Lower Limit (n034) (whichever is larger.).
Page 96
6. Programming Features Multi-function Input Selection (n077) Name Unit Setting Factory Range Setting n077 Multi-function Input Selection 0 to 4 n077 Settings Setting Function Description Disabled The multi-function input is disabled. Auxiliary frequency When frequency reference 2 is select- reference (FREF2) ed using the multi-step speed referenc- es, the input analog signal for the CN2 terminal will be the frequency refer-…
Page 97
Analog Input Level 1. Auxiliary Frequency Reference 2. Frequency Reference Gain (n077=1) (n077=2) FREF2 FGAIN 100% 2.00 1.00 10 V 10 V (4 mA) (20 mA) (4 mA) (20 mA) 100%=Max. Output Frequency (n011) 3. Frequency Reference Bias (n077=3) 4. Output Voltage Bias (n077=4) VBIAS FBIAS 100 V…
Page 98: Using Output Signals (N057, N058, N059)

6. Programming Features Using Output Signals (n057, n058, n059) The functions of multi-function output terminals MA, MB, P1 and P2 can be changed as necessary by setting constants n057, n058, and n059. • Terminal MA and MB functions: Set in n057 •…
Page 99
Setting Name Description Ref. Reverse run Closed during reverse run. Speed search Closed when Inverter conducts a speed search. Data output from com- Operates multi-function output termi- munications nal independently from Inverter opera- tion (by MEMOBUS communication) PID feedback loss Closed during PID feedback loss Frequency reference Closed during frequency reference loss…
Page 100: Setting Frequency By Current Reference Input

6. Programming Features Setting Frequency by Current Reference Input When setting frequency by input- ting current reference (4-20 mA or 0-20 mA) from the control circuit terminal FR, switch the DIP switch SW2 on the control circuit board to “I” side. Never input voltage reference to control circuit terminal FR NOTE when DIP switch SW2 is switched to “I”…
Page 101
Current Reference Selection After changing DIP switch (V-I switch of SW2) to the “I” side, press on the Digital Operator, then set the following constants. PRGM Current reference (4 to 20 mA)..constant n004 = 3 Current reference (0 to 20 mA)..constant n004 = 4 •…
Page 102: Frequency Reference By Pulse Train Input

6. Programming Features Frequency Reference by Pulse Train Input Frequency reference can be set by pulse train input from the control cir- cuit terminals. • Input pulse specifications • Low-level voltage: 0.8 V or less • High-level voltage: 3.5 to 13.2 V •…
Page 103: Preventing The Motor From Stalling (Current Limit)

Preventing the Motor from Stalling (Current Limit) This function automatically adjusts the output frequency and output cur- rent according to the load to continue operation without stalling the motor. Stall Prevention (Current Limit) Level during Acceleration (n093) Sets the stall prevention (current limit) level during acceleration in units of 1%.
Page 104
6. Programming Features In the constant output area (output frequency > Max. Voltage Output Frequency (n013)), the stall prevention (current limit) level during acceleration is automatically decreased using the following equa- tion. Stall prevention (current limit) level during acceleration in constant output area Max.
Page 105: Stall Prevention During Operation

Motor Current Decreases frequency to prevent the motor from stalling. n094 At start of acceleration, the output current hysterisis is approx. 5% of Inverter rated Time current. Output Frequency 100 ms Time Stall Prevention during Operation Stall Prevention Above Base Speed During Run (n115) The stall prevention level can be decreased automatically in the constant output range.
Page 106
6. Programming Features Acceleration/Deceleration Time Selection during Stall Pre- vention (n116) With this function, Acceleration Time 2 (n021) and Deceleration Time 2 (n022) can be fixed as the acceleration/deceleration time when moving to prevent stalling during operation. Constant Name Unit Setting Factory Range…
Page 107: Decreasing Motor Speed Fluctuation

Decreasing Motor Speed Fluctuation Slip Compensation (n002 = 0) As the load becomes larger, the motor speed is reduced and the motor slip value is increased. The slip compensating function controls the motor speed at a constant value even if the load varies. When the Inverter output current is equal to the Motor Rated Current (n036), the compensation frequency is added to the output frequency.
Page 108: Motor Protection

6. Programming Features Motor Protection Motor Overload Detection The VS-606V7 protects against motor overload with a built-in electonic thermal overload relay. Motor Rated Current (Electronic Thermal Reference Current, n036) Set the rated current value shown on the motor nameplate. Note: Setting n036 to 0.0 A disables the motor overload protective function. Motor Overload Protection Selection (n037, n038) n037 Electronic Thermal Characteristics…
Page 109
Example for 200 V-Class Motors Cooling Effect Torque Characteristics Electronic Thermal Over- load Effective when operated at ror (motor over- 60 s 50/60 Hz from Short-term load protection) commercial occurs when Continuous Torque rating power supply continuously operated at 50/ 60 Hz or less at 100% load.
Page 110: Selecting Cooling Fan Operation

6. Programming Features Selecting Cooling Fan Operation In order to increase the life of the cooling fan, the fan can be set to oper- ate only when Inverter is running n039 = 0 (Factory setting): Operates only when Inverter is running (Continues operation for 1 minute after Inverter is stopped.) Operates with power ON…
Page 111: Communications Specified

Communications specified Interface RS-422, RS-485 Synchronization Asynchronous (Start-stop synchronization) Communication Baud rate: Selected from 2400/4800/9600/19200 bps Parameters Data length: 8 bits fixed Parity: Selected from even/odd/none Stop bits: 1 bit fixed Communication MEMOBUS (MODBUS) (RTU mode only) Protocol Max. Number of 31 units (When using RS-485) Inverters that Can be Connected…
Page 112: Setting Constants Necessary For Communication

6. Programming Features Procedure for Communications with PLC The following shows the procedure for communications with PLC. 1. Connect the communication cable between the PLC and the VS- 606V7 with the power supply turned OFF. 2. Turn the power ON. 3.
Page 113: Message Format

Constant Name Description Factory Setting n153 MEMOBUS Slave Setting range: 0 to 32* Address n154 MEMOBUS BPS 0: 2400 bps Selection 1: 4800 bps 2: 9600 bps 3: 19200 bps n155 MEMOBUS Parity 0: Even parity Selection 1: Odd parity 2: No parity n156 Transmission…
Page 114
6. Programming Features • Function code: Command codes (See below.) Func- Function Reference Message Response Message tion Code Minimum Maximum Minimum Maximum Hexa- (Byte) (Byte) (Byte) (Byte) decimal Reading holding register contents Loop back test Write in several holding registers •…
Page 115
(Example) Reads out status signal, fault contents, data link status and frequency reference from the VS-606V7 (slave 2). Response Message Response Message Reference Message (at normal operation) (at fault occurrence) Slave address Slave address Slave address Function code Function code Function code Upper Number of data*…
Page 116
6. Programming Features • Writing to Several Holding Registers (10H) Specified data are written into the several specified holding registers from the specified number, respectively. Written data must be arranged in a reference message in the order of the holding register numbers: from upper eight bits to lower eight bits.
Page 117
Data • Reference Data (available to read out/write in) Register Description 0000H Reserved RUN command 1: Run 0: Stop Reverse run 1: Reverse run 0: Forward run External fault 1: Fault (EFO) Fault reset 1: Reset command Multi-function input reference 1 (Function selected by n050) Multi-function input reference 2 (Function selected by n051) 0001H Multi-function input reference 3 (Function selected by n052)
Page 118
6. Programming Features • Simultaneous Broadcasting Data (available only for write in) Register Description RUN command 1: Run 0: Stop Reverse run 1: Reverse run 0: Forward run (Not used) 0001H (Not used) External fault 1: Fault (EFO) Fault reset 1: Fault reset command (Not used) Frequency reference 30000/100 % fixed unit…
Page 119
Register Description Overcurrent (OC) Overvoltage (OV) Inverter overload (OL2) Inverter overheat (OH) (Not used) (Not used) PID feedback loss (FbL) External fault (EF, EFO), Emergency stop (STP) 0021H Hardware fault (FXX) Motor overload (OL1) Overtorque detection (OL3) Undertorque detection (UL3) Power loss (UV1) Control power fault (UV2) MEMOBUS communications timeover (CE)
Page 120
6. Programming Features Register Description (Not used) (Not used) 0029H Input open phase (PF) Output open phase (LF) (Not used) Operation function stop (STP) Sequence error (SER) Simultaneous FWD/REV run commands (EF) External baseblock (BB) Overtorque detection (OL3) Cooling fan overheat (OH) Main circuit overvoltage (OV) Main circuit undervoltage (UV) 002AH…
Page 121
Register Description 1: Run Zero-speed 1: Zero-speed Frequency agreed 1: Agreed Minor fault (Alarm is indicated) 1: Output frequency ≤ (n095) Frequency detection 1 1: Output frequency ≥ (n095) Frequency detection 2 Inverter operation ready 1: Ready Undervoltage detection 1: Undervoltage detection Baseblock 1: Inverter output baseblock 002CH…
Page 122: Storing Constants [Enter Command] (Can Be Written Only.)

6. Programming Features Register Description PID feedback value (100 % /Input equivalent to max. output frequency ; 0038H 10/1 % ; without sign) 0039H PID input value (±100 %/±Max. output frequency ; 10/1 % ; with sign) 003AH PID output value (±100 %/±Max. output frequency ; 10/1 % ; with sign) 003BH- Reserved 003CH…
Page 123
While the constant is being stored after an ENTER CAUTION command was issued, response to the commands or data input with the keys on the Digital Operator (JVOP-140) becomes poor. Be sure to take some mea- sures for an emergency stop by using the external ter- minals (setting the external terminal to run command priority, or setting the multi-function input terminal to external fault, external baseblock or emergency stop).
Page 124: Error Code

6. Programming Features Error code Error Contents Code Function code error • Function code from PLC is other than 03H, 08H, or 10H. Improper register number • No register numbers to be accessed have been registered. • ENTER command “0900H” that is an exclusive-use register for write-in was read out.
Page 125: Performing Self-Test

Performing Self-test VS-606V7 is provided with a function to perform self-diagnosis for operation check of the serial communication I/F circuit. This function is called self-test. In the self-test, connect the sending terminal with the receiving terminal in the communication section. It assures if the data received by VS-606V7 is not being changed.
Page 126: Using Energy-Saving Control Mode

The greater the enegy-saving coefficient is, the greater the output volt- age becomes. When using a motor other than a Yaskawa standard motor, set the motor code corresponding to the voltage and capacity in n158. Then, change the setting of the energy-saving coefficient K2 (n140) by 5% to mini- mize the output power.
Page 127: Energy-Saving Search Operation

Energy-saving Voltage Lower/Upper Limits (n141, n142, n159, n160) Set the upper and lower limits of the output voltage. When the value calculated in the energy-saving control mode is larger than the upper limit (or smaller than the lower limit), the limit value is output as the voltage reference.
Page 128
6. Programming Features Search Operation Voltage Limit (n144) Limits the range where the voltage is controlled. The constant is set in % for 200-V/400-V Inverters. The search operation is not performed when n144 is set to 0. Constant Name Unit Setting Factory Range…
Page 129
Search Operation Power Detection Hold Width (n161) When the power fluctuation is less than this value, the output voltage is held for 3 seconds, and then, the search operating mode is started. Set the hold width as a percentage of the power that is currently held. Constant Name Unit…
Page 130: Motor Code

The Energy-saving Coefficient K2 (n140) is set to a value that corre- sponds to the Motor Code (n158). Motor Type Voltage Capacity Motor Code: Energy-saving Class n158 Coefficient K2: n140 Yaskawa 200 V 0.1 kW 481.7 General- 0.2 kW 356.9 purpose Motor 0.4 kW 288.2…
Page 131: Using Pid Control Mode

Motor Type Voltage Capacity Motor Code: Energy-saving Class n158 Coefficient K2: n140 Yaskawa 200 V 0.1 kW 481.7 Inverter 0.2 kW 356.9 Motor 0.4 kW 300.9 0.75 kW 224.7 1.5 kW 160.4 2.2 kW 138.9 3.7 kW 106.9 5.5 kW 84.1…
Page 132: Pid Control Selection (N128)

6. Programming Features PID Control Selection (n128) Constant Name Unit Setting Factory Range Setting n128 PID Control Selection 0 to 8 Setting Function PID Output Characteristics Disabled. Enabled: Deviation is subject to derivative control. Forward Enabled: Feedback signal is subject to derivative control. Enabled: Frequency reference + PID output, and devia- tion are subject to derivative control.
Page 133
n164 Setting Description Control circuit terminal FR (Voltage 0 to 10 V) Control circuit terminal FR (Current 4 to 20 mA) Control circuit terminal FR (Current 0 to 20 mA) Operator terminal: Voltage 0 to 10 V Operator terminal: Current 4 to 20 mA Pulse train Note: 1.
Page 134
6. Programming Features Proportional Gain (P), Integral Time (I), Derivative Time (D) (n130, n131, n132) Adjust the response of the PID control with the proportional gain (P), integral time (I), and derivative time (D). Constant Name Unit Setting Factory Range Setting n130 Proportional Gain (P)
Page 135
Primary Delay Time Constant for PID Output (n135) Constant Name Unit Setting Factory Range Setting n135 Primary Delay Time 0.1 s 0.0 to 10.0 Constant for PID Out- Constant n135 is the low-pass filter setting for PID control outputs. There is normally no need to change the setting. If the viscous friction of the mechanical system is high or if the rigidity is low causing the mechanical system to resonate, increase the setting so that it is higher than the resonance frequency period.
Page 136
6. Programming Features PID Feedback Loss Detection (n136, n137, n138) Constant Name Unit Setting Range Factory Setting n136 Selection for PID 0: No detection of Feedback Loss De- PID feedback loss tection 1: Detection of PID feedback loss, operation contin- ued: FbL alarm 2: Detection of PID feedback loss,…
Page 138
6. Programming Features…
Page 139: Using Constant Copy Function

Using Constant Copy Function Constant Copy Function The VS-606V7 standard JVOP-140 Digital Operator can store constants for one Inverter. A backup power supply is not necessary because EEPROM is used. The constant copy function is possible only for the Inverters with the same product series, power supply specifications, and control mode (V/ f control or vector control).
Page 140
6. Programming Features Constant Name Unit Setting Range Factory Setting n176 Constant rdy: READY Copy Func- rEd: READ tion Selection CPy: COPY vFy: VERIFY vA: Inverter capacity display Sno: Software No. display Prohibiting Constant Read Selection (n177) Select this function to prevent accidentally overwriting the constants stored in EEPROM in the Digital Operator.
Page 141: Read Function

READ Function Reads out the constants in batch from the Inverter and stores them in EEPROM inside the Digital Operator. When the read-out is executed, the previously stored constants data in the EEPROM are cleared and replaced with the newly entered constants. Example: Storing Constants from Inverter in EEPROM in Operator Explanation Operator Display…
Page 142: Copy Function

6. Programming Features Explanation Operator Display • Execute read-out • Change the constant No. (READ) using the by pressing the Constant Copy key. Function Selec- (Lit) • Press to dis- ENTER tion (n176). play the set value. • Change the set value to (Lit) rEd by pressing the key.
Page 143
Press to stop the COPY function. STOP/RESET The following constants are not written if the Inverter capacities differ. Constant No. Name Constant No. Name n011 to n017 V/f Settings n108 Motor Leakage Inductance n036 Motor Rated Current n109 Torque Compensation Volt- age Limiter n080 Carrier Frequency Selection…
Page 144: Verify Function

6. Programming Features Explanation Operator Display • Execute write-in • Change the constant No. (COPY) using to n176 by pressing the the Constant key. Copy Function (Lit) • Press to dis- ENTER Selection (n176). play the set value. (Lit) • Change the set value to CPy by pressing the key.
Page 145
Constants added with software version upgrades will be displayed when VERIFY is performed for VS-606V7 Inverters without the additional constants and VS-606V7 Inverters with the additional constants. The constants added with each software version upgrade are shown in the following table. Software No.
Page 146: Inverter Capacity Display

6. Programming Features Explanation Operator Display • Execute VERIFY • Change the constant No. by Constant to n176 by pressing the Copy Function key. Selection (n176). (Lit) • Press to display ENTER the set value. • Change the set value to (Lit) vFy by pressing the key.
Page 147
Explanation Operator Display • Enable the • Press to lit DSPL setting for (May be a different constant No.) constants n001 PRGM (Lit) to n179. (May be a different set value.) • Press to display ENTER (Flashes) the set value. •…
Page 148: Software No. Display

6. Programming Features Software No. Display The software number of the Inverter for which constants are stored in the Digital Operator is displayed. Example: Displaying Software No. of Inverter for which Constants are Stored in EEPROM in Digital Operator Explanation Operator Display •…
Page 149
Operator Description Corrective Action Display Lit: Inverter capacity display selected. Lit: Software No. display selected. Lit: READ, COPY (writing), VERIFY complet- Flashes: Attempt made to execute READ Confirm the necessity to execute READ, then while Constant Read Selection Pro- set Constant Read Selection Prohibit (n177) to hibit (n177) is set to 0.
Page 150: Unit Selection For Frequency Reference Setting/Display

6. Programming Features Unit Selection for Frequency Reference Setting/ Display Constants and Monitor Displays for Which Selection of Unit Function is Valid Item Contents Frequency refer- Frequency References 1 to 8 (Constants n024 to n031) ence constants Jog Frequency Reference (Constant n032) Frequency References 9 to 16 (Constants n120 to n127) Monitor display Frequency Reference Display (FREF)
Page 151
n035 Settings Setting Description • Setting unit: 0.01 Hz (less than 100 Hz), 0.1 Hz (100 Hz and more) • Setting range Min {Fmax (n011) × Frequency Reference Lower Limit (n034) to Fmax (n011) × Frequency Reference Upper Limit (n033), 400 Hz} •…
Page 152: Selecting Processing For Frequency Reference Loss

6. Programming Features Note: 1. The frequency reference constants and monitor display data for which this selection of the unit is valid are stored in the Inverter in units of Hz. The units are converted as shown below: Frequency reference constants Setting/Display Constant n035 Data for monitor display…
Page 153: Input/Output Open-Phase Detection

Input/Output Open-phase Detection Constant Name Unit Setting Range Factory Setting n166 Input 0 to 100 % Open-phase 400.0 V/100 % Detection Level (200 V Class) 800.0 V/100 % (400 V Class) n167 Input 0 to 255 s Open-phase Detection Time n168 Output 0 to 100 %…
Page 154: Undertorque Detection

6. Programming Features Undertorque Detection An alarm signal can be output to a multi-function output terminal (MA, MB, P1 or P2) when the load on the machine side suddenly becomes lighter (i.e., when an undertorque occurs). To output an undertorque detection signal, set the output terminal funci- ton selection in n057, n058, or n059 to 8 (undertorque detected, NO contact) or 9 (undertorque detected, NC contact).
Page 155
Undertorque Detection Level (n118) Sets the undertorque detection current level in units of 1 %. (Inverter rated current=100 %) When detected by torque is selected, motor rated torque becomes 100 %. Factory setting=10 % Undertorque Detection Time (n119) If the time for which the motor current is less than the undertorque detection level (n118) is longer than the undertorque detection time (n119), the undertorque detection function operates.
Page 156: Using Inverter For Elevating Machines

6. Programming Features Using Inverter for Elevating Machines If using an Inverter with an elevator, take safety mea- CAUTION sures on the elevator to prevent the elevator from drop- ping. Failure to observe this caution may result in injury. When using the VS-606V7 for elevating machines such as elevators and cranes, make sure that the brake holds and observe the following pre- cautions for safe operation.
Page 157
Releasing Width -2 Hz Output Frequency Time n095 Frequency Detection Level 1 • Sequence Circuit Configuration and Timing Chart Examples For the AC sequence cir- cuit, connect the signal Holding Brake Inverter VS-606V7 Auxiliary Relay Coil between P1 and PC to the +24V Fault Contacts MA sequence circuit with a…
Page 158: Stall Prevention During Deceleration

6. Programming Features • For a variable speed operation by an analog signal, set the Frequency Reference Selection (n004) to a value from 2 to 4. Stall Prevention During Deceleration If connecting a braking resistor to discharge regenerative energy, be sure to set the stall prevention during deceleration (n092) to 1.
Page 159: External Baseblock Signal

When a contactor is installed between the Inverter and the motor, enable the I/O open-phase protection (n166 to n169). For more information on using Inverters exclusively for elevators or cranes, contact your Yaskawa representatives or the nearest Yaskawa sales office.
Page 160: Using Mechatrolonk-Ii Communications

6. Programming Features Using MECHATROLONK-II Communications MECHATROLONK-II can be used with the SI-T/V7 option unit. For details, refer to VS-606V7 OPTION UNIT MECHATROLINK COM- MUNICATIONS INTERFACE UNIT INSTRUCTIONS (TOBPC73060003). The following constants are used for communications error settings for SI-T/V7. Constant Name Unit…
Page 161: Maintenance And Inspection

7. Maintenance and Inspection • Never touch high-voltage terminals on the Inverter. WARNING Failure to observe this warning may result in an electrical shock. • Disconnect all power before performing mainte- nance or inspection, and then wait at least one minute after the power supply is disconnected.
Page 162: Periodic Inspection

7. Maintenance and Inspection Periodic Inspection Periodically inspect the Inverter as described in the following table to prevent accidents and to ensure high performance with high reliability. Location to Check for Solution Check Terminals, In- Improper seating or Properly seat and tighten verter mounting loose connections in hardware.
Page 163: Part Replacement

Part Replacement Inverter’s maintenance periods are given below. Keep them as guide- lines. Part Replacement Guidelines Part Standard Replacement Method Replacement Period Cooling fan 2 to 3 years Replace with new part. Smoothing capacitor 5 years Replace the Inverter unit with new one.(Determine need by inspection.) Breaker relays Replace the Inverter unit with new…
Page 164: Replacement Of Cooling Fan

7. Maintenance and Inspection Replacement of Cooling Fan Inverters with Width of 68 mm, 140 mm, 170 mm, or 180 mm 1. Removal 1. Press the right and left catches on the fan cover in direction 1, and then pull them in direction 2 to remove the fan cover from the Inverter.
Page 165
Inverters with Width of 108 mm 1. Removal 1. Remove the front cover and terminal cover, and then remove the cooling fan con- nector (CN10). 2. Press the right and left catches on the fan cover in direction 1, and pull the fan cover in direc- tion 2 to remove it from the Inverter.
Page 166: Fault Diagnosis

8. Fault Diagnosis 8. Fault Diagnosis Protective and Diagnostic Functions This section describes the alarm and fault displays, the fault conditions, and the corrective actions to be taken if the VS-606V7 malfunctions. Inverter alarms are classified into alarm display and fault display. Alarm display:When a minor fault occurs in the Inverter, the Digital Operator flashes the display.
Page 167: Corrective Actions Of Models With Digital Operator

Corrective Actions of Models with Digital Operator : ON : Flashing : OFF Alarm Display Alarm Displays and Meaning Alarm Display Inverter Description Causes and Status Corrective Actions Digital RUN (Green) Operator ALARM (Red) UV (Main circuit low volt- Detected as Check the following: an alarm •…
Page 168
(n128) are both set to a value other than 0. OP9: The setting of the In- verter capacity does not coincide with the Inverter. (Contact your Yaskawa representa- tive.) OL3 (Overtorque detec- • Reduce the load, and increase the acceleration/ tion) deceleration time.
Page 169
Alarm Display Inverter Description Causes and Status Corrective Actions Digital RUN (Green) Operator ALARM (Red) UL3 (Undertorque de- Detected as • Check the setting in n118. an alarm • Check the operating con- tection) only. Fault ditions, and remove the When V/f mode is selected: contact out- cause.
Page 170
8. Fault Diagnosis Alarm Display Inverter Description Causes and Status Corrective Actions Digital RUN (Green) Operator ALARM (Red) CE (MEMOBUS) com- Detected as Check the following: an alarm • Communicaiton devices munications fault only. Fault or communication sig- contact out- nals.
Page 171: Fault Display

Fault Display Fault Displays and Meanings Fault Display Inverter Description Causes and Corrective Status Actions Digital RUN (Green) Operator ALARM (Red) OC (Overcurrent) Protective Operation is restored, if no Operation fault is found, after confirming Inverter output current mo- Output is the following: mentarily exceeded approx.
Page 172
8. Fault Diagnosis Fault Display Inverter Description Causes and Corrective Status Actions Digital RUN (Green) Operator ALARM (Red) Protective OV (Main circuit 1. Regenerative energy is Operation overvoltage) large. Output is • The setting of decelera- Main circuit DC voltage level turned OFF tion time is too short.
Page 173
Fault Display Inverter Description Causes and Corrective Status Actions Digital RUN (Green) Operator ALARM (Red) OH (Heatsink overheat) Protective • Excessive load Operation • Improper V/f pattern set- Temperature increased be- Output is ting cause of Inverter overload op- turned OFF •…
Page 174
8. Fault Diagnosis Fault Display Inverter Description Causes and Corrective Status Actions Digital RUN (Green) Operator ALARM (Red) Protective OL1 (Motor overload) • Check the load size or V/f Operation pattern setting (constants Motor overload protection op- Output is n011 to n017). erated by built-in electronic turned OFF •…
Page 175
Fault Display Inverter Description Causes and Corrective Status Actions Digital RUN (Green) Operator ALARM (Red) OL3 (Overtorque detec- Protective • Check the driven Operation machine and correct the tion) Output is cause of the fault, or V/f mode: Inverter output cur- turned OFF increase the value of con- rent exceeded the preset val-…
Page 176
8. Fault Diagnosis Fault Display Inverter Description Causes and Corrective Status Actions Digital RUN (Green) Operator ALARM (Red) Protective UL3 (Undertorque de- • Check the setting in Operation tection) n118. Output is • Check the operating When V/f mode is selected: turned OFF conditions, and remove The Inverter’s output current…
Page 177
PROM or AD converter) fault remains, replace the Digital Operator or Inverter. CPF-11 Control circuit is not com- bined with correct software. Combination error (Contact your Yaskawa rep- resentative.) Communication option • Option card fault. • Replace the option card.
Page 178
8. Fault Diagnosis Fault Display Inverter Description Causes and Corrective Status Actions Digital RUN (Green) Operator ALARM (Red) STP (Emergency stop) Stops ac- Check the following: cording to • NO/NC contact selec- The Inverter stopped accord- constant. tion (constant). ing to constant n005 after re- •…
Page 179: Troubleshooting

Troubleshooting Trouble Cause Corrective Actions The operation method selection The motor does not Set the RUN command (n003) to operate when an Control Circuit Terminal. is wrong. external operation The RUN command (n003) is not set signal is input. to Control Circuit Terminal. A 3-wire sequence is in effect.
Page 180
8. Fault Diagnosis Trouble Cause Corrective Actions The motor speed is The stall prevention level during Check if the Stall Prevention Level unstable. The motor during Running (n094) is set to an running is too low. speed fluctuates when appropriate value. Because the Stall Prevention Level operating with a light during Running (n094) is too low, the…
Page 181: Specifications

9. Specifications Standard Specifications (200 V Class) Voltage Class 200 V single-/3-phase Model 3-phase 20P1 20P2 20P4 20P7 21P5 22P2 23P7 25P5 27P5 CIMR- V7∗T Single-phase B0P1 B0P2 B0P4 B0P7 B1P5 B2P2 B3P7 Max. Applicable Motor Output 0.75 Inverter Capacity (kVA) Rated Output Current 17.5 Max.
Page 182
9. Specifications Voltage Class 200 V single-/3-phase Model 3-phase 20P1 20P2 20P4 20P7 21P5 22P2 23P7 25P5 27P5 CIMR- V7∗T Single-phase B0P1 B0P2 B0P4 B0P7 B1P5 B2P2 B3P7 Acceleration/ 0.00 to 6000 s Deceleration Time (Acceleration/deceleration time are independently programmed.) Braking Torque Short-term average deceleration torque 0.1, 0.25 kW: 150% or more…
Page 183
Voltage Class 200 V single-/3-phase Model 3-phase 20P1 20P2 20P4 20P7 21P5 22P2 23P7 25P5 27P5 CIMR- V7∗T Single-phase B0P1 B0P2 B0P4 B0P7 B1P5 B2P2 B3P7 Multi-function Seven of the following input signals are selectable: Forward run com- Input mand, reverse run command, forward/reverse run (3-wire sequence), fault reset, external fault, multi-step speed operation, JOG command, acceleration/deceleration time select, external baseblock, SPEED SEARCH command, ACCELERATION/DECELERATION HOLD com-…
Page 184
9. Specifications Voltage Class 200 V single-/3-phase Model 3-phase 20P1 20P2 20P4 20P7 21P5 22P2 23P7 25P5 27P5 CIMR- V7∗T Single-phase B0P1 B0P2 B0P4 B0P7 B1P5 B2P2 B3P7 Open chassis (IP20, IP00): −10 to 50°C Ambient Temperature Enclosed wall-mounted NEMA 1 (TYPE 1): −10 to 40°C (not frozen) Humidity 95% or less (non-condensing) −20 to 60°C…
Page 185: Standard Specifications (400 V Class)

Standard Specifications (400 V Class) Voltage Class 400 V 3-phase Model 3-phase 40P2 40P4 40P7 41P5 42P2 43P0 43P7 45P5 47P5 CIMR- V7∗T Single-phase Max. Applicable Motor Output 0.75 Inverter Capacity (kVA) Rated Output Current 14.8 Max. Output Voltage (V) 3-phase, 380 to 460 V (proportional to input voltage) Max.
Page 186
9. Specifications Voltage Class 400 V 3-phase Model 3-phase 40P2 40P4 40P7 41P5 42P2 43P0 43P7 45P5 47P5 CIMR- V7∗T Single-phase Motor Overload Protec- Electronic thermal overload relay tion Instantaneous Motor coasts to a stop at approx. 250% or more of Inverter rated current Overcurrent Overload Motor coasts to a stop after 1 minute at 150% of Inverter rated output…
Page 187
Voltage Class 400 V 3-phase Model 3-phase 40P2 40P4 40P7 41P5 42P2 43P0 43P7 45P5 47P5 CIMR- V7∗T Single-phase Status Indica- RUN and ALARM provided as standard indicators tors Digital Operator Provided for monitor frequency reference, output frequency, output cur- (JVOP-140) rent Terminals…
Page 188
9. Specifications * 7. NEMA 1 of 0P1 to 3P7 is optional, while NEMA 1 of 5P5 and 7P5 is pro- vided as standard. * 8. Temperature during shipping (for short period).
Page 189: Standard Wiring

Standard Wiring DC Reactor Thermal (Optional) Overload Braking Resistor (Optional) Relay Short-circuit bar *1 MCCB − Power Supply R/L1 U/T1 For Single- phase. S/L2 V/T2 Use R/L1 and S/L2. T/L3 W/T3 Grounding FORWARD RUN/STOP REVERSE RUN/STOP EXTERNAL FAULT (NO CONTACT) FAULT RESET MULTI-STEP SPEED REF.
Page 190
9. Specifications Connection Example of Braking Resistor Overload Relay Trip Contact Braking Resistor * 3-phase Power Motor Supply Fault Contact * Disable stall prevention during deceleration by setting n092 to 1 when using a Braking Resistor Unit. The motor may not stop within the deceleration time if this setting is not changed.
Page 191
Type Terminal Name Function (Signal Level) Multi-function input Photocoupler Factory setting closed:FWD run open: Stop selection 1 insulation, 24 VDC, 8 mA Multi-function input Factory setting closed:REV run open: Stop selection 2 Multi-function input Factory setting: External fault selection 3 (NO contact) Multi-function input Factory setting: Fault reset…
Page 192
9. Specifications Type Terminal Name Function (Signal Level) Communications MEMOBUS RS-485/422 MEMOBUS input (+) communications protocol 19.2 kbps max. Run through RS-485 or RS-422. Communications input (-) Communications output (+) Communications output (-) * 1. DC power supply input terminal is not applied to CE/UL standard. * 2.
Page 193: Sequence Input Connection With Npn/Pnp Transistor

Sequence Input Connection with NPN/PNP Transistor When connecting sequence inputs (S1 to S7) with transistor, turn the rotary switch SW1 depending on the polarity (0 V common: NPN side, +24 V common: PNP side). Factory setting: NPN side Sequence Connection with NPN Transistor (0 V Common) VS-606V7 Forward run/stop Reverse run/stop…
Page 194
9. Specifications Sequence Connection with PNP Transistor (+24 V Common) VS-606V7 Forward run/stop Reverse run/stop External fault (NO) External Multi- power Fault reset function supply Multi-step speed input reference 1 +24V Multi-step speed reference 2 command SW1 NPN +24 V…
Page 195: Dimensions/Heat Loss

Dimensions/Heat Loss Fig. 1 Fig. 2…
Page 196
9. Specifications Fig. 3 Dimensions in mm/Mass in kg/Heat Loss (W) Voltage Capaci- Mass Heat Loss (W) Fig. class ty (kW) Heat- Unit Total sink 200 V 13.0 3-phase 10.3 18.0 15.8 12.3 28.1 0.75 28.4 16.7 45.1 53.7 19.1 72.8 60.4 34.4…
Page 197
Voltage Capaci- Mass Heat Loss (W) Fig. class ty (kW) Heat- Unit Total sink 200 V 10.4 14.1 single- phase 12.3 20.0 15.8 16.1 31.9 0.75 28.4 23.0 51.4 53.7 29.1 82.8 64.5 49.1 113.6 98.2 78.2 176.4 400 V 13.7 23.1 3-phase…
Page 198: Recommended Peripheral Devices

9. Specifications Recommended Peripheral Devices It is recommended that the following peripheral devices be mounted between the AC main circuit power supply and VS-606V7 input termi- nals R/L1, S/L2, and T/L3. • MCCB (Molded-case Circuit Breaker)/Fuse: Always connect for wiring protection. •…
Page 199
VS-606V7 Model V7** V7** V7** V7** V7** V7** V7** B0P1 B0P2 B0P4 B0P7 B1P5 B2P2 B3P7 Fuse (UL Class RK5) 10 A 20 A 20 A 40 A 50 A • 400 V 3-phase VS-606V7 Model V7** V7** V7** V7** V7** V7** V7**…
Page 200
9. Specifications • AC and DC Reactor: Install an AC reactor to connect to a power supply transformer of large capacity (600 kVA or more) or to improve power factor on the power supply side. • Noise Filter: Use a noise filter exclusively for Inverter if radio noise generated from the Inverter causes other control devices to malfunction.
Page 201: Constants List

Constants List • Addition of Constants Accompanied by the Upgraded Software Version #1: Applicable for software version Nos.VSP010028, VSP010106 or later. First Functions (Constants n001 to n049) No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set-…
Page 202
9. Specifications No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 0112 Selecting Setting Unit for Ac- 0, 1 celeration/deceleration Time 0113 Acceleration Time 1 0.00 to 6000 s Depend on 10.0 s n018 setting 0114…
Page 203
No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 011F Frequency Reference 8 0.00 to 400.0 0.01 Hz 0.00 Hz (less than 100 Hz)/ 0.1 Hz (100 Hz or more) 0120 Jog Frequency…
Page 204
9. Specifications No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 0130 Frequency reference bias -99.9% to 0.1% 0.0% value (UP/DOWN command 100.0% (n011/ 100%) 0131 Analog frequency reference 0.1% to 0.1% 1.0%…
Page 205
No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 0140 Frequency Reference Loss 0, 1 Detection Selection 0141 Monitor Output Type 0, 1 0142 Monitor Item Selection 0 to 6 0143 Monitor Gain…
Page 206
9. Specifications Third Functions (Constants n080 to n119) No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 0150 Carrier Frequency Selection 1 to 4, 7 to 9 (Note 4) 0151 Momentary Power Loss…
Page 207
No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 0160 Overtorque Detection Func- 0 to 4 tion Selection 1 0161 Overtorque/Undertorque De- 0, 1 tection Function Selection 2 0162 Overtorque Detection Level 30% to 200%…
Page 208
9. Specifications No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 0172 Number of Transmission Cy- 2 to 10 cle Error Detection (For SI-T/ 0173 Stall Prevention Above Base 0, 1 Speed During Run 0174…
Page 209
No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 017E Frequency Reference 15 0.00 to 400.0 0.01 Hz 0.00 Hz (less than 100 Hz)/0.1 Hz (100 Hz or more) 017F Frequency Reference 16…
Page 210
9. Specifications No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 0192 Search Operation Voltage 0.1% to 10.0% 0.1% 0.2% Step at 5% 0195 Pulse Train Input Scaling 100 to 3300 1 = 10 Hz 2500…
Page 211
No. Register Name Setting Range Setting Unit Factory Change User Ref. No. for Setting during Set- Page Trans- Opera- ting mission tion 01A9 Output Open-phase Detection 0.0 to 2.0 s 0.1 s 0.0 s Time 01AA ENTER command operation 0, 1 selection (MEMOBUS com- munications) 01AB…
Page 212
9. Specifications Name V/f Control Vector Con- Mode trol Mode (n002 = 0) (n002 = 1) n014 Mid. Output Frequency 1.5 Hz 3.0 Hz n015 Mid. Output Frequency Voltage *1 *2 12.0 V 11.0 V n016 Min. Output Frequency 1.5 Hz 1.0 Hz n017 Min.
Page 213
• 200 V Class Single-phase Name Unit Factory Setting Inverter Capacity 0.1 kW 0.2 kW 0.4 kW 0.75 kW 1.5 kW 2.2 kW 3.7 kW n036 Motor Rated Current 14.1 n105 Torque Compensation 11.1 11.8 Iron Loss n106 Motor Rated Slip Ω…
Page 214: 10 Conformance To Ce Markings

(machines or installations) conform to the European Standards. Requirements for Conformance to CE Markings Low Voltage Directive VS-606V7 Series Inverters satisfy testing for conformance to the Low Voltage Directive under the conditions described in European Standard EN50178. Requirements for Conformance to the Low Voltage Directive VS-606V7 Series Inverters must satisfy the following conditions in order to conform to the Low Voltage Directive.
Page 215: Emc Directive

• For 400 V Class Inverters, always ground the supply neutral to con- form to CE requirements. EMC Directive VS-606V7 Series Inverters satisfy testing for conformance to the EMC Directive under the conditions described in European Standard EN61800-3. Installation Method…
Page 216
10 Conformance to CE Markings Installation and Wiring of Inverter and Noise Filter (Model: CIMR-V7 20P1 to 27P5), (Model: CIMR-V7 40P1 to 45P5) L1 L2 L3 Control Panel Metal Mounting Plate 3-phase Noise Filter Grounding Face Inverter Shielded Grounding Cable Face Motor cable: 20 m max.
Page 217
Installation and Wiring of Inverter and Noise Filter (Model: CIMR-V7 B0P1 to B4P0) Control Panel Metal Mounting Plate Single-phase Noise Filter Grounding Face Inverter U V W Shielded Grounding Cable Face Motor cable: 20 m max.
Page 218: Emc Noise Filter

10 Conformance to CE Markings EMC Noise Filter Volt- Inverter Noise Filter (Manufacturer: RASMI) Model Class CIMR- φd Model No. Num- Rated Mass Dimensions Y×X ber of Current (kg) W×L×H Phases 71 × 169 × 45 51 × 156 200 V B0P1 RS1010-V7 B0P2…
Page 219
The EMC-compliant V7 Series noise filter is footprint type. φd C I M R — V 7 A to Z : Specifications A to Z : Type…
Page 220: Revision History

Revision History The revision dates and numbers of the revised manuals are given on the bottom of the back cover. MANUAL NO. TOE-S606-11.2 Printed in Japan October 1999 99-06 Revision number Date of Date of original printing publication Date of Rev.
Page 221
Date of Rev. Section Revised Content Printing June 2003 Chapter 6 Addition: Description of overtorque/ undertorque detection function selection 2 Addition: Description of undertorque detection Janualy 2004 Endsheet on Addition: Revision history back cover August 2004 Addition: Details of 5.5/7.5 kW In- verters August 2004 Back cover…
Page 222
Date of Rev. Section Revised Content Printing January 2005 Chapter 9 Addition:・Following items in the Standard Wiring diagram ・Part that describes se- quence input as open collector ・Multi-function analog in- put CN2 ・Following constants in the constant list ・n063 ・n114 Revision: Note for software version for large-capacity Inverters in the constant list…
Page 223
Yaskawa representatives or the nearest Yaskawa sales office beforehand. This product has been manufactured under strict quality-control guidelines. However,…

Источник

Заказать Yaskawa vs-606v7

Купить Yaskawa vs-606v7 в компании Олниса можно оптом или в розницу. Доставим Yaskawa vs-606v7 в любой регион России. Можем предложить точный аналог. Работаем напрямую с производителем, не используя посредников.

Yaskawa – один из крупнейших производителей электроники, успешно реализующий свои товары на рынке с 1915 года. Сейчас Yaskawa Electric владеет сетью торгово-промышленных предприятий не только в Японии – месте основания предприятия – но и еще в 24 странах. Фирма обеспечивает своих клиентов продукцией высокого качества, предоставляет новейшие технологии и услуги заказчикам по всему миру.

Инвертор Yaskawa vs 606v7.

Инвертор Yaskawa vs 606v7 представляет собой устройство, которое преобразует постоянный ток в переменный, и также может менять величину напряжения или оставлять ее прежней. Устройство является генератором периодического напряжения, благодаря которому можно получить ток с любыми нужными значениями.

Инверторы могут работать в одном из трех режимов: длительная работа, перегрузка и пуск. Первый соответствует номинальной мощности устройства, во втором инверторы могут создавать в два раза большую мощность, чем номинальная не более получаса, в третьем – отдают повышенную мощность в течение нескольких секунд.

Модель Yaskawa vs 606v7 – это компактный преобразователь тока, имеющий большой спрос и множество функциональных возможностей, которые позволяют применять его во всех видах задач промышленного производства. В нем заложен принцип векторного управления, который позволяет обеспечивать пуск двигателей с повышенной нагрузкой, и поддерживает их стабильную работу с минимальной частоты вращения.

Преимущества Yaskawa vs 606v7.

Конструкция преобразователя очень тщательно продумана: на устройстве есть панель управления, кнопки пуска и остановок. Замена вентилятора, охлаждающего систему, также проста и удобна. Инвертор может выполнять следующие функции и имеет множество преимуществ:

после того, как напряжение пропадает, устройство перезагружается автоматически;
перегрузка и отсутствие нагрузки всегда контролируются;
параметры прибора настраиваются автоматически;
доступна функция перезапуска после того, как возникли возможные ошибки;
есть функция обхода резонансных частот;
устройство не представляет сложностей в монтаже и эксплуатации при следовании приложенной к нему инструкции;
с операторской панели можно копировать и считывать данные.

Высокое качество устройства.

Данный производитель всегда стремится повысить качество своей продукции, поэтому инвертор Yaskawa vs 606v7 гарантирует безопасное использование устройства на протяжении всего срока его службы и дает гарантию качества на 1 год. Это относится и к комплектующим приобретенного изделия.

Купить Yaskawa vs 606v7.

Сайт нашей компании предоставляет широкий ассортимент преобразователей тока, включая Yaskawa vs 606v7. Мы гарантируем доставку качественной и оригинальной продукции по всей России и СНГ. Длительная гарантия действует на все представленные к ознакомлению товары.

Источник

002 — Allen Bradley PowerFlex4 Руководство пользователя (94)_rus.pdf 1.19 MB

Руководство пользователя на русском языке 94 страницы.

003 — ALTIVAR 18 Инструкция (31)_rus.pdf 453.74 KB

Инструкция к частотным преобразователям «ALTIVAR 18 » на русском языке 31 страница.

003 — ALTIVAR 18 Руководство (127)_eng.pdf 804.83 KB

Руководство по эксплуатации ALTIVAR 18 на английском языке 127 страниц.

003 — ALTIVAR 28 — Руководство по эксплуатации (48)_rus 860.81 KB

Руководство по эксплуатации для частотного преобразователя «Altivar 28». На русском языке 48 страниц.

003 — ALTIVAR 31 — Руководство по программированию (77)_rus.pdf 1.82 MB

Инструкция по программированию инвертора Altivar 31. На русском языке 77 страниц.

003 — ALTIVAR 31- Руководство по эксплуатации (17)_rus.pdf 689.52 KB

Руководство по эксплуатации и схема подключения для инверторов Altivar 31. На русском языке 17 страниц.

003 — ALTIVAR 312 Руководство по программированию (120)_rus 2.4 MB

Руководство по программированию частотного преобразователя ALTIVAR 312. а русском языке 120 страниц.

003 — ALTIVAR 58 — каталог и тамже размеры и вес (97)_rus 1.95 MB

Каталог. Там можна найти размеры и вес частотника. Всего 97 страниц на русском языке.

003 — ALTIVAR58 — руководство по программированию (59)_rus 1.93 MB

Руководство по программированию частотника ALTIVAR 58. На русском языке 59 страниц.

004 — Danfoss VLT 2800 Manua(120)_rus.pdf 3.1 MB

Руководство к частотному преобразователю Danfoss VLT 2800. На русском языке 120 страниц.

004 — DANFOSS VLT5000 (223)_rus 8.17 MB

Инструкция на русском языке

004 — Инструкция по эксплуатации_FC300(98)_rus .pdf 3.31 MB

Инструкция по эксплуатации к частотному преобразователю DANFOOS FC300. На русском языке 98 страниц.

004 — Руководство для проэктирования_FC300 (196)_rus.pdf 3.33 MB

Руководство для проэктирования к частному преобразователю DANFOOS FC300. На русском языке 196 страниц.

004 — Руководство по программированию_FC300(219)_rus.pdf 4.52 MB

Руководство по программированию к частотному преобразователю DANFOOS FC300. На русском языке 219 страниц.

006 — FUJI AF300 E11 Manual (146)_engl 2.01 MB

Инструкция к частотному преобразователю FUJI AF300 E11 на английском языке 146 страниц (отдельно есть перевод параметров на русском языке)

006 — FUJI AF300E$ (Instruction book GEI_100211G) (134)_engl 1.02 MB

Инструкция к частотному преобразователю FUJI AF-300E$ GE на английском языке 134 страницы. Отдельно на русском языке есть таблица праметров для программирования преобразователя.

006 — FUJI FRENIC FRN-G11S (188)_rus 3.67 MB

Инструкция на русском языке 188 страниц к частотнику FUJI FRN-G11S

006 — FUJI FRENIC 5000G9S_P9S Инструкция (128)_engl 16.21 MB

Инструкция к частотному преобразователю FUJI FRENIC 5000G9S_P9S. На английском языке 128 страниц

006 — FUJI FRENIC 5000P9S (101)_немец 2.21 MB

Инструкция к частотнику FUJI FRENIC 5000P9S на немецком языке — 101 страница.

007 — HITACHI L100 Manual (163)_engl 3.38 MB

HITACHI L100 Instruction Manual на английском языке 163 страницы.

007 — HITACHI L100 Инструкция (76)_rus 1.02 MB

Инструкция к частотному преобразователю HITACHI L100 на русском языке 76 страниц.

007 — HITACHI L200 Инструкция (276)_rus 6.5 MB

Инструкция к частотному преобразователю HITACHI L200 на русском языке 276 страниц.

007 — HITACHI L200 Руководство по эксплуатации (124)_rus 2.23 MB

HITACHI L200 Руководство по эксплуатации 124 страницы на Русском языке.

007 — HITACHI J300 — Инструкция по эксплуатации (109)_rus 1.39 MB

Инструкция по эксплуатации к частотному преобразователю HITAGHI J300 на русском языке 109 страниц.

007 — HITACHI L100 Инструкция (76)_rus 1.02 MB

Инструкция для частотного преобразователя HITACHI L100 на русском языке 76 страниц.

007 — Hitachi L300P Руководство (103)_rus.pdf 2.4 MB

Инструкция к частотному преобразователю HITACHI L300P на русском языке.

007 — HITACHI SJ100 Instruction manual (213)_engl 5.02 MB

Инструкция к частотному преобразователю HITACHI SJ100 на английском языке 213 страниц.

007 — HITACHI SJ300 Manual (130)_rus 2.15 MB

Инструкция к частотному преобразователю Hitachi SJ300 на русском языке.

007 — HITCHI J300 Instruction Manual (130)_engl 693.04 KB

Инструкция к частотному преобразователю HITCHI J300 на английском языке 130 страниц.

009 — LENZE SMD инструкция по эксплуатации (24)_rus 1.29 MB

Инструкция на русском языке 24 страницы.

011 — Magnetek GPD 505 Manual (151)_eng 2.03 MB

Инструкция к частотному преобразователю Magnetek GPD 505 на английском языке 151 страница.

011 — Magnetek GPD205 Техническое реководство (88)_eng.pdf 905.9 KB

Техническое руководство по частотным преобразователям Magnetek GPD205. Файл на английском языке из 88 страниц.

012 — MITSUBISHI FR_A240 Инструкция (124)_eng.pdf 8.41 MB

Инструкция к частотному преобразователю Mitsubishi FR-A240E на английском языке 128странец. При необходимости могу сделать таблицу настроек параметров на русском.

012 — MITSUBISHI FR-A044 — Инструкция (167)_eng.pdf 9.28 MB

Инструкция к частотным преобразователям серии MITSUBISHI FR-A044, на английском языке 167 страниц.

012 — MITSUBISHI FR-A044 Руководство (167)_eng.pdf 9.28 MB

Инструкция на частотные преобразователи MITSUBISHI FR-A044. На английском языке 167 страниц.

012 — MITSUBISHI FR-A500 Инструкция (186)_rus.pdf 2.56 MB

Инструкция на русском языке из 186 страниц

012 — MITSUBISHI FR-E500 Инструкция (194)_rus.pdf 2.8 MB

Инструкция на русском языке, 194 страницы.

012 — MITSUBISHI FR-E520 ( E540 ) Руководство по эксплуатации (278)_rus.pdf 4.5 MB

Руководство по эксплуатации частотных преобразователей Mitsubishi FR-E520 (E540). На русском языке 278 страниц.

012 — MITSUBISHI FR-E700 Руководство по установке (28)_rus.pdf 1.2 MB

Руководство по установке к частотному преобразователю MITSUBISHI FR E740. На русском языке 28 страниц.

012 — Mitsubishi FR-E700_Руководство (310)_eng.pdf 17.87 MB

Инструкция к частотным преобразователям Mitsubishi FR-E700. Файл на английском языке из 310 страниц.

012 — MITSUBISHI FR-F700 руководство по установке(24)_rus 1.09 MB

Руководство по установке частотного преобразователя MITSUBISHI FR-F700. На русском языке 24 страницы.

012 — MITSUBISHI FR-F740 руководство по эксплуатации(506)_rus 13.83 MB

Руководство по эксплуатации частотного преобразователя MITSUBISHI FR-F740 . На русском языке 506 страниц.

012 — MITSUBISHI FR-S500 (E500)(F700)(A700) — Руководство для начинающего (108)_rus.pdf 2.71 MB

Руководство для начинаючего. На русском языке 108 страниц.

012 — Mitsubishi FR-S500 Руководство по эксплуатации (84)_rus.pdf 1.72 MB

Руководство по эксплуатации частотных преобразователей Mitsubishi FR-S500. Файл на русском языке, 84 страницы.

015 — IDM G5+SERIES Руководство пользователя_engl.pdf 1.75 MB

Руководство пользователя на английском языке.

015 — OMRON 3G3JV SYSDRIVE_Руководство пользователя (161)_rus.pdf 2.08 MB

Руководство пользователя на частотные преобразователи OMRON 3G3JV. Текст на русском языке 161 страница.

015 — OMRON F7 Быстрый старт (146p) (169)_rus.pdf 5.29 MB

015 — OMRON F7 Quick start(146p) (169)_rus.pdf

015 — OMRON F7 Руководство по эксплуатации (367)_rus.pdf 9.68 MB

Руководство по експлуатации на русском языке (367 страниц).

015 — OMRON V7 Руководство пользователя (247)_rus.pdf 5.32 MB

Руководство пользователя по Инверторам OMRON V7 на русском языке 247страниц.

015 — OMRON VS Mini J7 Руководство пользователя (176)_rus.pdf 3.1 MB

Руководство пользователя на русскоя языке 176 страниц.

016 — SAFTRONICS FP5_GP5 Руководство (101)_eng.pdf 5.23 MB

Руководство по эксплуатации на английском языке 101 страница. (Дополнительно имеется таблица настройки параметров на русском языке).

016 — Saftronics FP5- GP5 Техническое руководство (108)_eng.pdf 1.31 MB

Техническое руководство на английском языке 108 страниц.

016 — Saftronics PC7 Руководство (225)_eng.pdf 2.19 MB

Руководство к частотному преобразователю SAFTRONICS PC7. На английском языке 225 страниц. На русском языке можно почитать инструкцию от частотного преобразователя OMRON V7. Эти частотники очень похожи друг на друга.

017 — Combivert F4C Руководство по программированию (278)_rus 8.16 MB

Siemens Combivert KEB F4C — Руководство по программированию на русском языке 278 страниц.

017 — MIKROMASTER MM440 Руководство по эксплуатации(140)_rus 5.85 MB

Руководство по эксплуатации к частотному преобразователю Siemens MM440 на русском языке 140 страниц.

017 — MM440_Описание параметров (169)_rus 2.04 MB

Описание параметров к частотному преобразователю Siemens Micromaster MM440. На русском языке 169 страниц.

017 — SIEMENS MM420 — Руководство по эксплуатации (130)_rus 6.87 MB

Руководство по эксплуатации к частотному преобразователю SIEMENS MM420. На русском языке 130 страниц.

017 — Siemens SED2 Руководство (81)_rus 2.1 MB

Инструкция к частотному преобразователю Siemens SED2 81 страница на Русском языке.

019 — TOSHIBA G3 (134)_eng.pdf 1.64 MB

Инструкция к частотному преобразователю «Toshiba G3» на английском языке.

019 — Toshiba Tosvert VF-S11 Инструкция (258)_rus 3.79 MB

Toshiba Tosvert VF-S11 Инструкция 258 страниц на русском языке

019 — TOSHIBA VF-S9 (198)_engl 4 MB

TOSHIBA VF-S9 инструкция на английском языке 198 страниц.

020 -COMMANDER SK — Расширенное руководство пользователя (202)_rus.PDF 5.68 MB

Расширенное руководство пользователя, на русском языке 202 страницы.

020 — Commder_SE Руководство пользователя (86)_rus 1.19 MB

Руководство пользователя к частотному преобразователю CONTROL TECHNIQUES COMANDER SE на русском языке 86 страниц.

020 — Commder_SE Руководство пользователя (86)_rus 1.19 MB

Инструкция к частотному преобразователю COMANDER SE фирмы CONTROL TECHNIQUES. На русском языке 86 страниц.

022 — Yaskawa P7 Руководство пользователя (252)_eng.pdf 3.85 MB

Руководство пользователя на частотные преобразователи Yaskawa P7. Состоит из 252 страниц на английском языке

022 — Yaskawa VS-606 V7 Краткая инструкция (23)_rus .pdf 3.66 MB

Краткая инструкция на русском языке к частотным преобразователям Yaskawa VS-606 V7.

022 — YASKAWA F7 Руководство по эксплуатации (374)_rus.pdf 6.95 MB

Руководство по эксплуатации YASKAWA F7 на русском языке 374 страницы.

022 — Yaskawa GPD315 V7 Руководство (162)_eng.pdf 2.13 MB

Руководство на частотные преобразователи «Yaskawa GPD315 V7». На английском языке 162 страницы.

022 — Yaskawa GPD506_P5 Техническое руководство (168)_eng 3.68 MB

Техническое руководство к частотным преобразователям серии GPD506/P5 фирм Yaskawa и Magnetek (168 страниц на английском языке)

022 — Yaskawa J7 Техническое руководство (96)_eng 3.21 MB

Техническое руководство к инверторам серии J7. На английском языке 96 страниц.

022 — Yaskawa V7 and V74X Drives Техническое руководство (155)_eng.pdf 2.45 MB

Руководство по експлуатации к частотным преобразователям Yaskawa V7, на английском языке 155страниц. Очень похожая на нее, Инструкция к частному преобразователю OMRON V7 (на русском языке), отличается только некоторыми параметрами. Инструкция на OMRON находится в вкладке «ИНСТРУКЦИИИ ПОЧАСТОТНИКАМ».

022 — Yaskawa V7 and V74X Инструкция (64)_eng.pdf 3.44 MB

Инструкция на частотные преобразователи серии Yaskawa V7 and V74X. На английском языке 64 страницы.

022 — Yaskawa V7 and V74X Руководство (158)_eng.pdf 2.23 MB

Инструкция к частотным преобразователям Yaskawa V7, на английском языке 158страниц. Очень похожая на нее, Инструкция к частному преобразователю OMRON V7 (на русском языке), отличается только некоторыми параметрами.

022 — YASKAWA V7 Инструкция по быстрому запуску (29)_rus.pdf 3.57 MB

Руководство по быстрому запуску частотных преобразователей » YASKAWA V7 «, на русском языке 29 страниц.

022 — Yaskawa VS Mini J7 Инструкция (117)_eng.pdf 2.06 MB

Инструкция на частотные преобразователи » Yaskawa VS Mini J7 «. Состоит из 117страниц на англйском языке

022 — Yaskawa VS Mini Руководство (77)_eng.pdf 2.95 MB

Руководство по эксплуатации частотных преобразователей Yaskawa VS Mini. Файдл на английском языке 77 страниц.

022 — Yaskawa VS mini, J7 and V7 Инструкция (76)_eng.pdf 2.64 MB

Инструкция на частотные преобразователи Yaskawa VS mini, J7 and V7. На английском языке 76 страниц.

022 — Yaskawa VS-606 V7 Инструкция (174)_eng.pdf 1.75 MB

Инструкция на частотные преобразователи Yaskawa VS-606 V7. На английском языке 174 страницы.

022 — Yaskawa VS-606-V7 Руководство (166)_eng.pdf 3.96 MB

Руководство по експлуатации к частотным преобразователям Yaskawa VS, на английском языке 166страниц. Очень похожая на нее, Инструкция к частному преобразователю OMRON VS (на русском языке), отличается только некоторыми параметрами. Инструкция на OMRON находится в вкладке «ИНСТРУКЦИИИ ПОЧАСТОТНИКАМ».

023 — NORDAC SK 700E Руководство по эксплуатации (120)_rus 14.63 MB

Руководство по эксплуатации к частотному преобразователю NORDAC SK 700E на русскоя языке 120 страниц.

028 — INVT CHE100_manual (125)_engl 1.86 MB

Инструкция к частотному преобразователю INVT CHE100 125 страниц на Английском языке.

028 — INVT CHE100_manual (125)_engl 1.86 MB

Инструкция на английском языке 125 страниц.

028 — INVT CHF100 (42)_rus 1.48 MB

Краткая инструкция к частотному преобразователю INVT CHF100 на Русском языке.

030 — Drivecon XT Series Instruktion Manual (120)_engl 2.76 MB

Drivecon XT Series. Инструкция на английском языке 120 страниц. На русском языке имеется много инструкций для частотника VACON, это тоже самое.

030 — Drivecon XT Service Manual (59)_engl 2.12 MB

Drivecon XT. Service Manual (59)_engl.

030 — VACON — Преобразователи чачтоты серии NXP-C (108)_rus 3.63 MB

Преобразователи чачтоты VACON серии NXP/C. На русском языке 108 страниц.

030 — VACON NX Руководство по прикладным программам (266)_rus 3.55 MB

VACON NX. Руководство по прикладным программам на русском языке 266 страниц.

800 — EFECTOR500 PN-2224 — датчик давления 10атм (4)_rus 100.77 KB

EFECTOR500 PN-2224 — датчик давления

800 — EFECTOR500 PN-2224 — Инструкция по эксплуатации (20)_rus.PDF 367.92 KB

Инструкция по эксплуатации к датчику давления (регулятору давления) EFECTOR500 PN-2224. На русском языке 20 страниц.

801 — XMLG_каталог датчиков 710.74 KB

Характеристики датчиков серии XMLG

997 — Файл настроек частотника FR-E540 616 B

Файл с параметрами для частотника Mitsubishi FR-E540. Открывается программой «VFD Setup 3.11 «. Частотник настроен для работы в амплитудно-частотном режиме от сети 380В. Тепловая защита двигателя отключена. Режим управления терминальный (т.е. от внешних выключателей и потенциометра). Максимальная частота 50Гц. Время разгона/торможения 5 сек.

998 — Как подключить частотник FR-E540 к порту RS485 881.12 KB

Как подключить частотник FR-E540 к порту RS485

999 — Что такое частотник и зачем он нужен.mht 203.19 KB

Эта статья для людей, чья специальность не предполагает глубоких знаний в области электропривода, но в силу обстоятельств которые вынуждены с ним столкнуться. Здесь можно будет найти некоторые ответы на вопросы что такое частотник и как устроен электродвигатель.

Источник

Quick Links

INSTRUCTION MANUAL

Related Manuals for YASKAWA VS-606V7 Series

Summary of Contents for YASKAWA VS-606V7 Series

Page 1: Instruction Manual

Page 2: General Precautions

Page 3: Notes For Safe Operation

Page 11: Warning Display

Page 12: Table Of Contents

Page 16: Receiving

Page 17: Identifying The Parts

Page 20: Mounting

Page 21: Mounting Dimensions

Page 22: Mounting/Removing Components

Page 24: Wiring

Page 25: Wire And Terminal Screw Sizes

Page 28: Wiring The Main Circuit

Page 29: Wiring The Control Circuit

Page 30: Wiring Inspection

Page 31: Operating The Inverter

Page 32: Selecting Rotation Direction

Page 33: Operating The Digital Operator

Page 35: Led Description

Page 38: Data Reception Error Display

Page 40: Simple Data Setting

Page 41: Programming Features

Page 42: Using V/F Control Mode

Page 45: Using Vector Control Mode

Page 46: Motor Constant Calculation

Page 48: Switching Local/Remote Modes

Page 49: Selecting Run/Stop Commands

Page 50: Selecting Frequency Reference

Page 51: Setting Operation Condition

Page 52: Operating At Low Speed

Page 53: Adjusting Speed Setting Signal

Page 54: Adjusting Frequency Upper And Lower Limits

Page 55: Using Four Accel/Decel Times

Page 56: Automatic Restart After Momentary Power Loss

Page 57: Soft-Start Characteristics

Page 58: Torque Detection

Page 60: Frequency Detection

Page 61: Jump Frequencies

Page 62: Operating Coasting Motor Without Trip

Page 63: Holding Accel/Decel Temporarily

Page 64: Using Frequency Meter Or Ammeter

Page 65: Using Analog Output (Am-Ac) As A Pulse Signal Output

Page 67: Reducing Motor Noise Or Leakage Current

Page 69: Operator Stop Key Selection

Page 70: Selecting Stopping Method

Page 71: Applying Dc Injection Braking

Page 72: Building Interface Circuits With External Devices

Page 73: Initial Setting

Page 76: Using Multi-Function Analog Input

Page 78: Using Output Signals

Page 80: Setting Frequency By Current Reference Input

Page 82: Frequency Reference By Pulse Train Input

Page 83: Preventing Motor From Stalling (Current Limit)

Page 84: Stall Prevention During Running

Page 86: Decreasing Motor Speed Fluctuation

Page 87: Motor Protection

Page 89: Selecting Cooling Fan Operation

Page 90: Communications Connection Terminal

Page 91: Setting Constants Necessary For Communication

Page 92: Message Format

Page 98: Storing Constants [Enter Command]

Page 99: Error Codes

Page 100: Performing Self-Test

Page 101: Using Energy-Saving Control Mode

Page 103: Energy Saving Search Operation

Page 105: Motor Code

Page 106: Using Pid Control Mode

Page 112: Using Constant Copy Function

Page 114: Read Function

Page 115: Copy Function

Page 117: Verify Function

Page 118: Inverter Capacity Display

Page 119: Software No. Display

Page 120: Display List

Page 121: Function Outline

Page 123: Selecting Processing For Frequency Reference Loss (N064)