Lust SMARTDRIVE VF1000 M Series Operation Manual Download

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Operation Manual

MART

RIVE

VF1000

Series M

Frequency inverter 1.1 to 4 kW

s t o p

r e t u r n

s t a r t

e n t e r

VAL

S M A R T
C A R D

ANTRIEBSTECHNIK

Summary of Contents for SMARTDRIVE VF1000 M Series

Page 1: ...Operation Manual SMARTDRIVE VF1000 Series M Frequency inverter 1 1 to 4 kW stop return start enter VAL Hz SMART C A R D EN ANTRIEBSTECHNIK ...

Page 2: ... frequency inverter 1 x 230 V Version VF1205M 1 1 kW VF1207M 1 5 kW 3 x 400 460 V Version VF1404M 1 5 kW VF1406M 2 2 kW VF1408M 3 0 kW VF1410M 4 0 kW Applies as from software edition V 1 2 ID No 0809 21B 1 01 Issued January 2001 ...

Page 3: ...before starting work If you follow all the instructions you will save yourself much time and many questions during the commissioning stage It is essential to read this Operation Manual because both the inverter itself and further components of the system can be damaged by improper handling If after reading the Manual however you still have questions do please contract us as given below Lust Antrie...

Page 4: ...e operation of the inverter with the control unit KEYPAD KP100 and give information on the individual parameters According to the customer specific requirements on the frequency inverter there are also device versions with special functions The specifications which deviate from those of the standard device are marked in the appropriate descriptions The following pictograms for warning and instruct...

Page 5: ...stance EMC 2 3 2 3 Power connections 2 4 2 3 1 Mains connection 2 4 2 3 2 Motor connection 2 5 2 3 3 Braking chopper BR1 2 5 2 3 4 Motor temperature monitoring Design PTC PT1 2 6 2 4 Control connections 2 7 2 4 1 Specification 2 7 2 4 2 Function of the reference input FSINA 2 8 2 4 3 Control functions with STR STL 2 11 2 4 4 Control function via S1IND S2IND S3IND 2 12 2 4 5 MOP function with S1IND...

Page 6: ...n with KEYPAD KP100 4 6 5 Parameter list 5 1 5 1 Operating level 1 5 1 5 2 Operating level 2 Part 1 5 2 Operating level 2 Part 2 5 3 5 3 Inverter type dependent and nationally related parameters 5 4 6 Parameter description 6 1 6 1 Reference input 6 1 6 2 Actual values 6 4 6 3 Frequencies 6 6 6 4 Ramps 6 6 6 5 Characteristics 6 8 6 6 Special functions 6 9 6 7 Signal outlets 6 15 6 8 Program functio...

Page 7: ...BG 4 must be respectively observed Repairs to the equipment may only be carried out by the manufacture or by authorized workshops Unauthorized opening and unprofessional intervention can result in physical injury or material damage A 2 Intended use Inverters are components that are intended for installation in electrical systems or machines They should be basically only used for installation in co...

Page 8: ...ive inverters the applicable national accident prevention regulations e g VBG 4 should be observed Electrical installation should be carried out according to the applicable regulations e g cable diameter fusing grounding cable connection Additional details are contained in the documentation Electronic devices are not intrinsically fail safe The user himself shall be responsible for securing the dr...

Page 9: ...rotection IP20 With braking chopper power electronics without braking resistance in the device cooling body Operation Manual Design code when deviating from standard The design code is separated with a comma and can be arranged in any sequence Example VF1408M FA G16 More precise details can be found in the Data booklet VF1000 Housing design G16 IP20 With built in mains filter to comply with the li...

Page 10: ...A 8 A 4 Manufacturer s declaration for frequency inverter ...

Page 11: ...A 9 ...

Page 12: ...ed in this Manual have passed the test at the Carl Schenk AG Test Centre and fulfilled the stated European norms As an example the CE test certificate for the device VF1207M have been reproduced Details of the test itself can be ordered from Lust Antriebs technik GmbH ...

Page 13: ...A 11 ...

Page 14: ...n its installed condition Installation information is given in the diagram below to aid the achievement of optimum installation You will achieve correct EMC installation 1 Necessary cable lengths 0 3 m Important For further information see Chapter 2 RB RB 41 42 43 44 45 46 n c 23 29 36 21 22 23 24 25 26 33 34 35 26 47 48 49 50 51 52 RS232 RS485 W V U L3 L1 M 3 K1 SI L1 L2 L3 PE 3 x 400 460VAC SI S...

Page 15: ...and DC link coupling W V U PE PE L3 N L2 L1 RB RB 41 42 43 44 45 46 n c 23 29 36 21 22 23 24 25 26 33 34 35 26 47 48 49 50 51 52 13 stop return start enter VAL Hz SMART C A R D 12 3 6 8 9 2 1 4 11 10 7 5 17 15 SN V 10000 Gerät Typ Netz Ausg 16 14 Accessories see data booklet VF1000 Designs see data booklet VF1000 9 Terminal X1 power connections 10 KEYPAD plug 11 EMC ground clamps for cable screen ...

Page 16: ...15 20 3 x 400 460 10 15 Mains frequency f Hz 50 60 10 Connection diameter A mm max 2 5 Recom fusing I AT 1 x 16 1 x 16 3 x 10 3 x 10 3 x 16 3 x 16 Assymetry of mains volt U 3 maximum General Operating mode 2 quadrats 4 quadrats 2 Peak braking power2 PSp kW 1 65 max Cyclical braking mode2 Peff W 90 Power loss3 PV W 65 82 80 100 120 150 Efficiency3 η 95 95 95 95 95 95 Ambient conditions Cooling air ...

Page 17: ... G H VF1205M VF1404M 32 5 4 8 φ 330 315 69 260 112 40 245 VF1406M VF1410M 32 5 4 8 φ 3442 315 69 260 112 40 245 All dimensions in mm 1 For level assembly see Chapter 1 4 Device assembly 2 Devices have a fan on their bottom side also applies for all VF1000M devices equipped with integrated mains filter 3 Accessories see data booklet VF1000 ...

Page 18: ...the device during installation of the inverter This could result in destruction of the device Installation distances Among other factors the size of the cabinet is related to the power losses of the inverter see power table In order to avoid over heating in the cabinet it is essential that the appropriate installation distances are observed This guarantees safe long term operation A 100 mm B 50 mm...

Page 19: ...ref input 23 Ground Control unit ref point 24 STR Start clockwise input 25 STL Start counter clockwise input 26 UV Control voltage 24 V DC 29 SOUTF Digital freq output 33 S1IND Prog digital input 34 S2IND Prog digital input 35 S3IND Prog digital input 36 SOUTA Prog analog output 41 S1OUT Break contact of relay 1 42 Cent spring of relay 1 43 Make contact of relay 1 44 S2OUT Break contact of relay 2...

Page 20: ...ne X EMC ground clamps for easy installation of cable screen VF1404M VF1406M VF1408M VF1410M wait 2 minutes after mains off X1 Power connections L1 L2 L3 Mains connection 3 x 400 460 V U V W Motor connection 3 x 400 460 V X2 Connection for DC link coupling X2 RB Connection for ext braking resistor X3 Socket for control unit KEYPAD KP100 X4 51 52 Motor PTC connection1 X5 Connection terminal for 47 ...

Page 21: ... is complied with The motor cable the mains cable and the control cables should be separated from each other and screened The device should be screwed onto a well grounded mounting plate A toothed washer Z must be placed under each of the fixing screws of the device so that the inverter housing has good contact to the mounting plate The screen of the mains and motor cable is clamped in place direc...

Page 22: ...on is not possible Caution Due to the high current flows 3 5 mA the use of fault current breakers on their own is not permissible Hence a ground line is urgently prescribed The mains fusing must be laid out according to the current loading of the connecting cable according to DIN 57100 see recommendation in the power table When using circuit breakers only those with triggering characteristics B or...

Page 23: ...V 2 3 3 Braking chopper BR1 In general If the rotor speed is greater than the corresponding stator speed rotary field of the inverter the motor feeds energy back into the inverter In this braking mode the inverter brakes the motor by means of the DC link capacitors absorbing the braking energy BR1 design In this design a braking resistance is built into the device s heat sink which is connected vi...

Page 24: ...or use of thermal circuit breaker Klixon Specification PTC and PT1 design Terminal voltage UMAX 7 5 V Current IMAX 3 mA Switching threshold RST 3600 Ω nominal Reactivation value RWST 1600 Ω Only PTC design Switching point with short circuit RK 50 Ω Note In the PTC or PT1 design the device is supplied with an installed resistance 100Ω on Cl X4 51or 52 When connecting a motor PTC or thermal circuit ...

Page 25: ...eviation 2 5 from final value Software filter up to123 ms LOW 5 V HIGH 5 V max 30 V Pulse width 10 ms min Deviation 0 8 LOW 7 V High 14 V max 30 V Current intake at 24 V 10 mA max SPS compatible 24 V logic against ground Hardware filter 3 3 ms Not short circuit proof switching current 12 mA LOW Impulse LOW Level approx 1 V Pulse Pause Ratio 1 1 6 fold output frequency with stand still HIGH 24 V in...

Page 26: ... A Connection of a potentio meter 4 7 10 kΩ Ω Ω Ω Ω Adaption Jumper position A 04 FSSEL 0 factory setting External voltage reference 0 2 10 V DC Adaption Jumper position A 0 10 V Jumper position B 2 10 V 04 FSSEL 0 factory setting External current reference 0 4 20 mA Adaption Jumper position C 0 20 mA Jumper position D 4 20 mA 04 FSSEL 0 factory setting 21 22 FSIN X6 2 23 J1 J6 D J1 J6 C 21 22 FSI...

Page 27: ...ter description FSINA F digital frequency reference input 04 FSSEL Function 0 Analog input active adaption via jumper rail J1 J6 1 2 No function 3 FSIN as frequency input 0 to 1 kHz active 4 FSIN as frequency input 0 to 10 kHz active 5 FSIN as PWM input 20 to 100 active 6 FSIN as PWM input 0 to 100 active 7 FSIN not active reference via KP100 CTRL menu 8 Reference preset via interface 9 to 16 Refe...

Page 28: ...MIN FMAX 0 10 kHz Adaption Jumper position E 04 FSSEL 4 Amplitude 10 V max Impulse width 10 µs min External frequency reference default with PWM Signal Scaling 20 100 FMAX Adaption Jumper position E 04 FSSEL 5 Scaling 0 100 FMAX Adaption Jumper position E 04 FSSEL 6 21 22 FSIN X6 2 23 J1 J6 E Condition PWM basic frequency 0 9 8 kHz For further details see Chapter 6 1 Reference input Position of ju...

Page 29: ... when an STL or STR control signal and a reference for the rotary field frequency of at least 0 5 Hz 0 1 V at FSIN are available STOP The inverter stops when the STL or STR control signals are returned The connected motor comes to a halt by itself i e without braking BRAKING STOP The inverter brakes the motor until STOP when two control signals are simultaneously available at STL and STR When both...

Page 30: ...e below relates to the factory settings Parameter 31 KSEL 0 data set selector Truth table S1IND S2IND S3IND Speed reference Factory setting 0 0 0 FSIN Analog input FMAX 50 Hz 1 0 0 20 FF2 1 27FF2 2 FF2 5 Hz 3 Hz 0 1 0 23 FF3 FF3 15 Hz 1 1 0 24 FF4 FF4 30 Hz 0 0 1 25 FF5 FF5 3 Hz 1 0 1 26 FF6 FF6 0 Hz 0 1 1 30 FF7 FF7 50 Hz 1 1 1 22 FMAX1 29 FMAX2 FMAX 50 Hz Note the settiing of 04 FSSEL Example of...

Page 31: ...ach data set has a total of l8 parameters which can be set individually see parameter description The truth table below refers to parameter 31 KSEL 2 data set selector Ramp changeover As a consequence of the data set changeover option the inverter has 2 ramp pairs available The following sequence diagram illustrates the function of the ramp changeover with 31 KSEL 2 For more detailed information s...

Page 32: ...sed or lowered by the ratio of the offset Base value Offset 04 FSSEL 17 18 19 20 21 22 Reset offset with x x x S1IND 1 S2IND 1 Reset offset with x x braking ramp RSTOP Retain offset when x x power off EEPROM memory Explanation of diagrams in examples Input active Input inactive Braking ramp with counter clockwise rotation Braking ramp with clockwise rotation Acceleration ramp with clockwise rotati...

Page 33: ... Offset Offset Base t n STL S1IND S2IND RACC1 RDEC1 FMAX FSIN 1 Example Direction of rotation with STL and STR The setting parameter applies 04 FSSEL 17 18 19 20 21 22 Note When reversing the signals at STL and STR must overlap by at least 0 5 s FMAX FMAX FSIN 0 Offset t n STL S1IND STR Base n FSIN Offset RACC1 RDEC1 RDEC1 RACC1 S2IND Base ...

Page 34: ...reduction of the base value to 0 Hz the drive comes to a stand still however the condition should not be confused with a stop command If the base value is raised while the S2IND signal is at hand the drive is restarted to new base value with old offset Key Only possible with 04 FSSEL 17 18 19 20 Offset is retained Only possible with 04 FSSEL 21 22 Offset is reset 0 n FMAX FSIN t STL S1IND Base old...

Page 35: ...e during power off the drive does not start The drive does not accelerate to the base value until after a new STL edge If an automatic restart required after power return the auto start function must be activated in the parameter 72 STRT see Chapter 6 Key Offset is saved with power off only possible with 04 FSSEL 19 20 Offset is lost with power off with 04 FSSEL 17 18 21 22 0 t n FMAX FSIN Offset ...

Page 36: ...e 6 20 S2OUT stand by Relay output The make contact Kl 44 45 is closed as soon as the pre charging is completed after power on and there is no fault The make contact Kl 44 45 is opened as soon as a fault arises or the mains is switched off Programming Both outputs can be set to one of 10 different functions with the KEYPAD or via the interface The function description relates to the following fact...

Page 37: ...upplies 24 V impulses 6 LOW impulses are issued per 1 Hz rotary field frequency at the frequency output At stand still the output is at 24 V FSIN SOUTF 5 Hz 30 Hz constant 5 260Hz 30 1560Hz linear 260 Hz 1560 Hz constant 1 Position of jumpers J1 J6 at device top side see layout plan Chapter 1 23 29 36 SOUTA PWM X6 1 J1 J6 1 Programming The outputs SOUTA and SOUTF can be programmed with KEYPAD or v...

Page 38: ...ation corresponds to VDE 0884 Protective low voltage Driver power RS485 31 participants removal 1000 m Bus termination not installed Transmission rate fixed 9600 Baud C12 design The VF1000 Series M inverters in this design have a potential free interface connection RS232 The inverters can be operated via this interface according to the LUSTBUS data transmission protocol Terminal assignment see Fig...

Page 39: ...ve An external 24V DC power supply is necessary to operate the interface No Function 1 LED RC green 2 LED RD red 3 LED BA green 4 LED U green 5 X7 IBS input 6 X8 IBS output 7 Kl 54 input 24 V 8 Kl 53 GND The screen connection is via the plug casing Connection assignment IBS output Des Function IBS input 9pin socket 9 pins 1 DO Data Out 1 2 DI Data In 2 3 COM Ground 3 5 5 V Supply 6 DO Data Out 6 7...

Page 40: ... of a CAN Bus coupling CAN The Bus Interface is isolated The bus is connected via two 9 pin Sub D plugs in accordance with CiA Draft Standard 102 V2 0 The inverters can be driven in a network with CAL protocol Technical data Des VF1000M CAN Bus acc to ISO 11898 Participant number maximum 30 Power supply ext VDD 24 VDC 10 Current intake I 100 mA max Transmission rate up to 1 M Baud Transmission and...

Page 41: ... J11 The screen connection is via the plug casing Note No jumpers plug in bridges are inserted in the jumper rail J7 J11 They are enclosed with the device in a separate bag Connection assignment CAN output D SUB 9 pin socket CAN output D SUB 9 pin plug 1 6 2 7 3 8 4 9 5 5v GND CAN CAN_L CAN_H GND ADR2 ADR0 24V ADR1 1 6 2 7 3 8 4 9 5 5v GND CAN CAN_L CAN_H GND ADR2 ADR0 24V ADR1 X7 X8 Address preal...

Page 42: ...rameter b a jumper rail J7 11 on the top of the device see Fig c c via coding plug ADR0 ADR1 ADR2 see Fig b J11 J10 J9 J8 J7 Address ADR2 ADR1 ADR0 0 0 0 0 0 0 0 0 0 0 1 1 0 0 0 1 0 2 0 1 0 0 0 8 1 1 1 0 1 29 Note 0 Jumper not inserted 1 Jumper inserted J12 is unassigned Assignment of the jumper position X7 X8 J12 J11 J10 J9 J8 J7 Fig c ...

Page 43: ...D is write protected ERR92 Error with plausiblity check ERR93 SMARTCARD not readable inverter servo controller type incorrect ERR94 SMARTCARD not readable parameter incompatible ERR96 Connection to SMARTCARD interrupted ERR97 SMARTCARD data invalid CS Test ERR98 Insufficient memory on SMARTCARD only MC6000 Acknowledge error by pressing stop return key 3 Operating and error diagnosis 3 1 Display Po...

Page 44: ...nt cut off Check drive motor cable short circuit U f characteristics 4 times E OV Excess voltage Check mains drive Motor generator braking chopper 5 times E OLM Motor overloaded Check drive motor ventilation I t switching off 6 times E OLI Inverter overloaded Check drive ventilation I t switching off 7 times E OTM Motor temperature Motor overloaded check instal lation conditions too high 8 times E...

Page 45: ... 966 137 3 4 Motor inverter overload protection I t monitoring The I t monitoring provides electronic motor protection and inverter protection against high thermal loading The trigger characteristic can be taken from the diagram The details relate to an output frequency of 50 Hz It should be noted that with continuous operation with frequencies 40 Hz the motor requires forced ventilation Rule of t...

Page 46: ...scrolling within the menu structure 4 Stop return key Stop Menu CTRL interrupt or quit selected menu 5 Start enter key Starting Menu CTRL confirming or selecting menu 6 SMARTCARD Chip cards data memory storing the device setting 7 Connecting cable Maximum length 0 30 m Mechanics Dimensions WxHxD mm 62x158x21 Weight g 100 Type of protection VBG4 IP20 Ambient temperature T C 0 40 stop return start e...

Page 47: ...save device setting with the SMARTCARD PARA CTRL CARD VAL stop return start enter stop return start enter stop return start enter stop return start enter 4 2 2 Key functions The arrow keys enable the selection of menu branches and enable their modification Pressed once they cause a jump to the next menu branch or parameter or the smallest possible alteration of a para meter value If a key is kept ...

Page 48: ...arameter No 13 VAL menu Shows actual values e g frequency voltage current 14 PARA menu Changing parameter setting 15 CTRL menu Controlling motor via KEYPAD 16 CARD menu Loading saving device setting with the SMARTCARD 17 Phys unit at item 20 shows V A VA with automatic assignment 18 Phys unit at item 20 displays h min 1 with automatic assignment 19 Phys unit at item 20 displays Hz s Hz s with auto...

Page 49: ... g FMIN1 arrow key to next actual value parameter Change parameter setting in offline mode inverter stop Scan new actual value Read parameter setting in online mode inverter start B A C D VAL VAL Hz VAL V VAL V start enter start enter stop return stop return PARA PARA Hz PARA Hz PARA Hz start enter start enter start enter stop return A B C D ...

Page 50: ...OCK SC write protect UNLCK cancel write protect Frequency set value KEYPAD selected with start enter key preset e g 10 Hz Start function Activation of the MOP Function ended error free function see next page A B C D CTRL CTRL CTRL Hz start enter start enter start enter stop return CARD CARD CARD CARD start enter start enter start enter stop return stop return MOP Function D C A B ...

Page 51: ...rter follows the increase with acceleration ramp Reduce speed reference with arrow keys Inverter follows the reduction with the braking ramp With 0 0 Hz the inverter changes the direction of the rotary field Increase speed reference counter clockwise to 10 Hz for example In addition sign indicates counter clockwise Press stop return key inverter brakes the motor to stand still The MOP function is ...

Page 52: ... to 11 1 5 Abbrev Name Unit Setting range Page Factory Customer setting 1 MODE Operating mode 0 to 3 6 1 1 Frequencies 20 FF2 1 Fixed frequency 2 Hz 0 0 to 999 0 6 7 3 21 FMIN1 Minimum frequency Hz 0 0 to 999 0 6 7 0 22 FMAX1 Maximum frequency Hz 4 0 to 999 0 6 7 50 23 FF3 Fixed frequency 3 Hz 0 0 to 999 0 6 7 15 24 FF4 Fixed frequency 4 Hz 0 0 to 999 0 6 7 30 25 FF5 Comparative freq S2OUT Hz 0 0 ...

Page 53: ... Ramps 31 KSEL Data set selector 0 to 3 6 8 0 32 RACC1 1st acceleration ramp Hz s 0 1 to 999 0 6 9 20 33 RDEC1 1st delay ramp Hz s 0 1 to 999 0 6 9 20 34 RACC2 2nd acceleration ramp Hz s 0 1 to 999 0 6 9 80 35 RDEC2 2nd delay ramp Hz s 0 1 to 999 0 6 9 80 36 RSTOP STOP delay ramp Hz s 0 0 to 999 0 6 9 0 Characteristics 38 THTDC Shut down delay s 0 0 to 120 0 6 10 0 39 VHTDC DC retaining voltage 1 ...

Page 54: ... 25 to 150 IN 6 16 Signal outputs 61 SOUTA Frequency analog 0 to 14 6 17 9 output 62 S1OUT Output 1 digital 0 to10 6 18 10 63 S2OUT Output 2 digital 0 to10 6 18 7 67 FST Filter time constants 0 to 4 6 18 2 69 KOUTA SOUTA scaling 0 to 200 6 19 100 Program functions 71 PROG Special programs 0 to 4 6 19 0 72 STRT Start options 0 to 7 6 19 0 74 PWM Modulation frequency 0 to 2 6 20 0 75 OPT1 Option 1 0...

Page 55: ...r factor I R comp 18 18 VF1404M 53 KIXR 6 14 Corr factor I R comp 12 12 VF1406M 53 KIXR 6 14 Corr factor I R comp 8 8 VF1408M 53 KIXR 6 14 Corr factor I R comp 8 8 VF1410M 54 KSC 6 14 Corr factor slip comp 6 7 6 7 VF1205M 54 KSC 6 14 Corr factor slip comp 6 6 VF1207M 54 KSC 6 14 Corr factor slip comp 6 6 VF1404M 54 KSC 6 14 Corr factor slip comp 5 3 5 3 VF1406M 54 KSC 6 14 Corr factor slip comp 5 ...

Page 56: ...eter description Total range 01 MODE 1 Operating level 1 Commissioning level 01 MODE 2 Operating level 2 Operating and control function 01 MODE 3 Operating level 3 Interfaces and special param 01 MODE 0 Operating level 0 Only SIO mode 6 1 Reference input 04 FSSEL Frequency reference selector Offers the selection between various types of reference analog frequency or PWM signal and their origin KEY...

Page 57: ... FSSEL FF2 FF3 FF4 FF5 FF6 FF7 FMAX S1IND 1 0 0 0 0 0 S2IND stop return start enter VAL Hz SMART C A R D M 67 FST 29 FMAX2 0 Hz 28 FMIN2 21 FMIN1 94 MAXF 22 FMAX1 20 100 0 100 8 FSIN 1 S3IND 0 1 0 1 1 0 1 0 1 0 0 1 0 1 1 1 1 1 RS485 9 FF2 10 FF3 11 FF4 12 FF5 13 FF6 14 FMINx 15 FMAXx 16 FF7 RS232 ...

Page 58: ...mper rail J1 J6 04 FSSEL 5 FSIN operates as clock input for impulse width modulated signal FMIN 20 PWM FMAX 100 PWM see Fig 6 2 The basic signal of the PWM signal must be 0 9 8 kHz adaption via J1 J6 04 FSSEL 6 FSIN operates as clock input for impulse width modulated signals FMIN 0 PWM FMAX 100 PWM see Fig 6 2 The basic frequency of the PWM signal must be 0 9 8 kHz adaption via jumper rail J1 J6 0...

Page 59: ... 17 with following supplement With simultaneous activation of S1IND and S2IND the reference is reset to the base reference Reference offset 0 04 FSSEL 191 Has the same function as 04 FSSEL 17 with following supplement With preset reference offset and mains off this offset is saved until it is modified or reset via S1IND and S2IND 04 FSSEL 201 Has the same function as 04 FSSEL 18 and 19 04 FSSEL 21...

Page 60: ... bit model see Fig 6 3 09 BARG 11 STAT A generating current B current limiting value reached IS 110 IN C 12 F 25 FF5 D reference reached Fig 6 3 09 BARG 66 SIN A S2OUT active B S1OUT active C S2IND active D S1IND active 10 G Scaled frequency Displays the actual output frequency 12 F multiplied with the factor from parameter 86 KG no decimal fractions or physical units being displayed 10_G 12_F 86_...

Page 61: ...urrent A Displays the actual effective phase current After an error shut down the actual value existing immediately before shut down is saved Hold Function 16 PW Effective power W Displays the effective power from the inverter 17 VZK DC link voltage VDC Displays the actual DC link voltage After a error shut down the actual value existing immediately before shut down is saved Hold Function 18 TIME ...

Page 62: ...an be selected via S1IND 1 S2IND 1 and S3IND 0 25 FF5 Fixed frequency FF5 Hz Frequency thresholds for programmable outputs S1OUT S2OUT and S3OUT also see 62 S1OUT 63 S2OUT 64 S3OUT As reference can be selected via S1IND 0 S2IND 0 and S3IND 1 26 FF6 Fixed frequency FF6 Hz Frequency threshold for data set changeover at 31 KSEL 1 As reference can be selected via S1IND 1 S2IND 0 and S3IND 1 27 FF2 2 2...

Page 63: ...ver inactive Standard factory setting data set 1 remains 1 Changeover to 2nd data set Heavy load start up if 12 F 26 FF6 2 Changing over data sets Varying operation with S2IND from 2 motors to 1 inverter 3 Changing over to 2nd data set Drive with rotation direction with counter clockwise STL active dependent load Two data sets with following parameters are available Parameter Data set 1 Data set 2...

Page 64: ...a set see Fig 6 4 36 RSTOP Stop ramp Hz s With activated stop ramp 36 RSTOP 0 the inverter after setting of the control inputs STR and STL to 0 carries out a deceleration ramp with a gradient of 36 RSTOP see Fig 6 5 Subsequent maintenance of the DC current is possible with 38 THTDC 0 With 36 RSTOP 0 the motor comes to a halt by itself if STL and STR are set to 0 DS1 Data set 1 DS2 Data set 2 Fig 6...

Page 65: ...tage frequency characteristics 4 quadratic voltage frequency characteristics Fig 6 6 42 VB1 Voltage increase Parameter of the 1st data set Voltage at frequency of 0 Hz Raising the torque in the start up range See also Fig 6 6 43 FN1 Rated frequency Hz Parameter of the 1st data set Frequency point at which the inverter achieves the rated output voltage setting from 44VN1 See also Fig 6 6 44 VN1 Rat...

Page 66: ... Motor data Type plate 50 IN 51 COS and 52 NN entered for the load characteristics The purpose of the I R compensation is to produce a constant torque and reduced heating of the motor coil This is achieved by transplacing the load characteristics as determined by the characteristics parameters by an amount U determined by the effective current See Fig 6 7 IW 15 IW Effective current IN 50 IN Motor ...

Page 67: ...ed current Rated load B IW 0 Idling C Non compensated characteristics Fig 6 7 Ratio of the I R compensation I R Ratio of the slip compensation SK Fig 6 8 2 VB FN 0 100 F VB FN 50 I R SK 0 U UN F 1 VB FN VB FN A B C ...

Page 68: ... The slip compensation becomes effective at characteristics point VB FN It increases linearly from 0 at frequency VB FN up to 100 at frequency 2 VB FN Furthermore it is effective up to 100 See Fig 6 8 The entry of the frequency is only limited by parameter 94 MAXF The frequency correction is determined from the formula In the base range IW 15 IW Effective current INU Inverter rated current FN Para...

Page 69: ... INU Inverter rated current IN 50 IN Motor rated current COS 51 COS cos ϕ The correction factor can be either entered or calculated by the inverter The calculation is started when 49 SC 1 and 54 KSC 0 The synchronous speed for the calculation is determined from the rated frequency 43 FN1 The calculated value is automatically stored under 54 KSC 55 ISEL Actual control selector Decimal The actual co...

Page 70: ...ng frequency 57 FILIM When the phase current subsides to below 100 of 56 ILIM the inverter accelerates the motor further with the ramp 32 RACC1 the same applying for braking The frequency can then be raised up to 94 MAXF see Fig 6 9 Current controlled start up 55 ISEL 2 Operation as above with following difference Once the current limit of 125 of 56 ILIM has been exceeded the ramp 32 RACC1 does no...

Page 71: ...n trigger time see diagram shut down with the error message E OLM Motor protection The setting of the I t trigger current must be in accordance with the motor rated current Thus even motors with smaller power outputs than the device rated power are sufficiently protected from overloading Independently from the parameter 59 TRIP the inverter has a I t monitoring device which corresponds to one sett...

Page 72: ...evice rated current SOUTF 24V not active 6 SOUTA 0 10V Effective power scaled to 100 of the device rated power SOUTF 24V not active 9 WE SOUTA as 61 SOUTA 1 SOUTF 6 fold output frequency 12 SOUTA as 61 SOUTA 4 SOUTF 6 fold output frequency 13 SOUTA as 61 SOUTA 5 SOUTF 6 fold output frequency 14 SOUTA as 61 SOUTA 6 SOUTF 6 fold output frequency Comment If the outputs SOUTA and SOUTF simultaneously ...

Page 73: ...r DC hold active 5 active as long as rotary field frequency 12 F 0 6 active as soon as reference reached 7 active if rotary field frequency 12 F 25 FF5 8 active if apparent current 14 IS 110 59 TRIP current limit reached 10 active after an error shut down Factory setting 62 S1OUT 10 63 S2OUT 1 6 8 Program functions 67 FST Filter time constants Decimal Determines the filter time constants for analo...

Page 74: ... factory setting A e g Europe according to design 71 PROG 0 2 changed significance of the control terminals STR 0 clockwise STL 1 START STR 1 counter clockwise STL 0 STOP 4 as 1 however factory setting B e g USA 72 STRT Starting options Decimal 72 STRT Function 0 No starting option active factory setting 1 Autostart after mains on with STL or STR bypassed 2 Synchronisation to running motor 3 Autos...

Page 75: ...otary field frequency The synchronisation functions in both rotation directions Rotation direction block 72 STRT 4 With this start option rotation counter clockwise with respect to the inverter is blocked in every case This means that the counter clockwise rotation direction can neither be activated by the control input STL nor by the CTRL menu 74 PWM Switching frequency Decimal Parameter 74 PWM d...

Page 76: ... the parameterization menu PARA 89 PSW2 Pass word 2 Decimal Determines the pass word for control via KEYPAD CTRL menu 91 TYPE Inverter type Decimal Issues the type of the identifed end level All min max values and factory settings of the voltage and current dimensions which must be entered absolutely depending for example from VF1207M 44 VN1 230 V factory setting VF1406M 44 VN1 400 V factory setti...

Page 77: ...ecimal 0 1h Stores the last error message Representation Error No Error time see table 0 1 h 6 Min max 1 5 h is reset after each error message Possible error messages No Significance 1 time Error in computer component 2 time Low voltage no entry in 95 ERR1 98 ERR4 3 time Excess current short circuit or earthed after mains on 4 time Excess voltage 5 time I t Motor 6 time I t Inverter 7 time Excess ...

Page 78: ...We reserve the right to make technical changes IDNo 0809 21B 1 01 EN01 01 LustAntriebstechnikGmbH Gewerbestr 5 9 D 35633 Lahnau Phone 496441966 0 Fax 49 6441966 137 ...

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