PI8000 manual_综合)100202
Contents
1. Note DC 1 DC 2 Standard setting is short circuit if it is with external reactance please disconnect and then connect it 4 187 355kW 380V Main Circuit Terminals Section II Inspection amp Standby Circuit amp amp 6 O SO 6 19 j 6 6 9 e 10 e DC 1 DC 2 DC R L1 S L2 T L3 U T1 V T2 W T3 ew ae AA DC 1 DC 2 DC Chock AC Input Line DC 2 DC Braking Terminals Resistor Note The above KW categaries are for G type inverter Motor connection 2 4 2 PI8100 Main Circuit Terminals 1 7 5kWbelow 380V Main Circuit Terminals OO GOO Cee ee R L1 S L2 T L3 DC 1 DC 2 B2 U T1 V T2 WIT3 MAA AC Input Line B1 B2 Braking Resistor Motor connection Terminals DC 1 DC 2 DC Chock Note The above KW categaries are for G type inverter 2 4 3 Terminal Function Section I Inspection amp Standby Circuit DI3 DI3 Input Terminal DI4 DI4 Input Terminal DI5 DIS Input Terminal DI6 DI6 Input Terminal DI7 DI7 Input Terminal DIS DIS Input Terminal Enter a valid polarity can be controlled2. GOO EASED TA2 TC2 TB2 SPA SPB COM 24V PLC COM Al AI AIl 10V DA2 GND 2 5 1 2 8KSCB Control circuit terminal TC1 TBI COM SPA DIS DI3 DII COM PLC 424 10V GND 9069999999999 amp OG GO GO 1G TA1COM SPB DI6 DI4 DR Al Al Al DA2 DAI GND 2 6 Connection Precautions Don t install power factor capacitance or resistance capacitance absorbing device between the output terminals U V W of the frequency inverter Do not drop Metal scrap foam or lint into the frequency inverter otherwise the machine will be faulted To disassemble or replace the motor the input power supply must be turned off for the frequency inverter The motor or power supply can be switched on off only after the inverter stops its output In order to minimize the effect of electromagnetic interference a surge absorbing device should be installed if used electromagnetic contactor and relay etc is near to the frequency inverter For external control of frequency inverter a isolation device should be used for the control lines or screened cable should be used A screened c
3. PC Inverter Inverter Inverter Definition for Communication port B Communication port 1 2 3 4 5 6 7 8 B pins Communication B port GND 5V 485 485 485 485 5V GND signal EIA TIA T568A White White blue white orange White brown green green orange Blue Brown EIA TIA T568B White Orange Blue White green White brown Orange White Blue Brown Gree n Al Keyboard Connector ii E Cable cer jy Crystal Head RJ45 Data safety and reliability 129 Appendix I RS485 Communication Protocol The number of inverter can be connected is N more than 127 Though the length of communication cable can add up to 1300m considering the stability the length limit within 800m All the control signal cable use the screen cable and is linked to the signal terminal SH of RS485 Data packet using CRC vertical lengthy test frame detection to ensure data reliability completely isolated RS485 communication module to ensure reliable communications support hot swappable after modular access you can enter the work the system is tested in 6 kinds of baud rate 0 1200 1 2400 2 4800 3 9600 4 19200 5 38400 However if under deteriorating environmental conditions lowering the baud rate can improve the communication quality Interval time of sending from frame to frame is more than 50ms 4 Communication Protocol Communication architecture is inverter as a slave the computer as a host
4. 2 7 Standby circuit When the fault or trip of the inverter may cause great loss or accident please add the standby circuit Note confirm and test the running characteristic of the standby circuit in order to ensure the industrial phase and the converter phase are in the same direction MCC1 U ewan R R 3 PHASE S Tos o To 4J Hoo AC Power 0 Stoo oto Ss FD v loo ISo o w liyo NS o T T SUPPLY STO Interlock relay o To 13 Section II Operating Keyboard Section III Operating Keyboard 3 1 Operating keyboard 3 1 1 JPxC8000 Specification and function description Monitor Select 1 Numerical Display display the corresponding values of the function under query status display fault code under fault condi ti on display the object set byADO monitor select while running Reverse Lndication Light Alarm Indicat ON reverse indication Light OFF not reverse indication o FLASH reverse accelerating Forward Indication Light ON forward indication OFF not forward indication FLASH forward accelerating Positive And Negative Sign Indication Light just for monitor select Monitor Select 3 Numerical Display o 0 gt A00 Monitor Select 1 0 0 Monitor Select 2 Numerical Display H A01 Monitor Select 2 Pp
5. the dimension of apert C15453E01 EESEL re for installing keyboard in panel 119 Section VII Maintenance Section VIII Maintenance 8 1 Inspection and Maintenance Under normal working conditions in addition to daily inspection the frequency converter should be subject to regular inspection for example inspection for overhaul or as specified but at an interval of six months at most Please refer to the following table in order to prevent faults Check Creus Check item Check to be done Method Criterion D R point LED and LCD If there is any As per use y Display display abnormal display Visual cheek state If abnormal noise or N abnormal Cooling A Visual and y y Fan vibration is sound or system audible check Jy er produced vibration Surroundin Mui bete Check visually As per y Body conditons pa Aity cns by smelling and Sa 2 1 content harmful gas feeling Input P Measure at y output Voltage E input output R S T and U V hs per standard voltage is abnormal specifications terminal W terminals If the fastenings f come loose if any Check visually signs show overheat tighten the N abnormal Overall conditions discharging or too fastenings and Conditions high dust content or clean the related the air piping is parts y Main blocked circuit Ele
6. Falling edge Low e level Low e level FWD running Falling edge High e level Low e level REV running X X High e level STOP running 3 Three wire running control 2 FWD s e FWD REV E REV C STOP COM F05 1 F05 3 F05 4 Command FWD REV STOP Falling edge X Low e level FWD running X Falling edge Low e level REV running X X High e level STOP running 10 set the terminal status when the power up Power in an active state when the terminal state the drive to run immediately in some cases do not allow such situation happen set the terminal running command invalid when the power up then power on and after going through the terminal to set an invalid state 3S then running 036 037 038 039 040 041 042 043 044 045 046 DIL Input Terminal Function Selection DD Input Terminal Function Selection DB Input Terminal Function Selection DH Input Terminal Function Selection DD Input Terminal Function Selection DI6 Input Terminal Function Selection DI7 Input Terminal Function Selection DI8 Input Terminal Function Selection AIL Input Terminal Function Selection AL Input Terminal Function Selection AB Input Terminal Function Selection N function 0 Forward running FWD 1 Reverse running REV 2 3 line mode running STOP 3 Multi segment command 1 4 Multi segment command 2 5 Multi segment comma
7. 2 3 Wiring The wiring of frequency inverter includes two parts main circuit and control circuit The user must ensure correct connections according to the following connection diagram 2 3 1 PI8000 Diagram 1 Wiring diagram 11K W 15KW and below 8N3 Section II Inspection Standby Circuit DC Reactor Brake Unit O Fa Optional NCC DC 1 DC 2 81 B2 R o R L1 U T1 Qs PI8000 MS T 0 w 6 7o Q3 Inverter w r3 earthing E E s Farthing e Main Circuit Power Ditinput Termipat 7 Er Motor Q 4 Earthing Motor Control Circuit DH Input Termipat 5 Di2Tnput Termi It Dp O UST Hits teolaticn ue Di3Tnput Termipat Tea sc QJ ES O 0 DI3 2 RS485 ohm Did Input Termipat 3 Jcom Serial Commnication A SG Q4 vew m Deve ci Di4 1 2Shorted Drain output Interface need to be wv 5 enelised with the cami E COM befault configured to when Inverter be the bus sieeve S el 2 3Shorted Source output Communication card COM terminal JP1O shorted n Sy 24V Non Bus Terminal JP1Q Disconnect 1 E PE Dino Nok town Gta d y e Shorted Terminal used Lac Di5Tnput Termipa SE e LY Di5 Ee Fu Wiring required to mee EIA TIA 568A Di6Input Termipat la or EIA TIA 568B Standard Ot O DIS CC Di7Input Termipat RS485 8PRCO HS o 0 DI Di8Input Termipat
8. Inverter slowing down to stop braking start frequency stop the output PWM waveform to begin injection of DC current the current size by the shutdown of DC braking current setting braking time braking time set by the downtime Value is based on inverter rated current as the benchmark that is inverter rated current corresponds to 100 Setting process be sure to gradually increase from a small until adequate braking torque and can not exceed the motor rated current 4 setting i frequency A i time output i frequency stop brake wait time braking L 7 pi frequency i i stop braking time time RUN FF STOP SN 2 stop braking RUN STOP setting frequency time output 4 frequency braking L i frequency ee i time stop brake wait time setting forward i frequency reverse FOR REV command stop braking forward and reverse rotate 4 setting frequency braking Y 1 Ze frequency i i time output q frequency stop brake wait time braking PEED EUNT Gee ones frequency stop braking time time RUN STOP ON stop braking run state Deceleration stop 0 F32 Stop Setting Mode 0 N Free stop 1 35 When the frequency inverter receives the stop command it will set the parameters accordingly to this parameter to set the motor stop mode 0 deceleration to stop
9. f A w H bottom board SECTION A A HEIR bottom board back entry JKTXEZELI bottom entry Power Structur Shape Installation dimension Iiis kW eitem L Ww H A m d F 280 400 G 250 355 8NB 1700 850 492 640 260 O13 M 200 280 H 187 250 114 7 3 2 PI8100 Family 1 7N2 7N4 1 R2 65 7N2 Section VII Standard Specifications P t t Power ower type ype kW F 0 75 1 5 Single phase G 0 4 1 5 220v M 0 4 0 75 H 0 4 F 0 75 1 5 3 phase G 0 4 1 5 220v M 0 4 0 75 H 0 4 F 1 5 2 2 3 phase G 0 75 2 2 380v M 0 75 2 2 H 0 75 2 2 180 108 DIGITAL PANEL le p GOTO itp Sy ea 7N2 item Plastic panel 178 5 Section VII Standard Specifications 2 95 3 R2 65 7N3 Power Power type type kW F 2 2 4 Single phase G 2 2 4 220v M 1 5 2 2 H 0 75 1 5 F 2 2 4 3 phase G 2 2 4 220v M 1 5 2 2 H 0 75 1 5 F 4 5 5 3 phase G 4 5 5 380v M 4 5 5 H 4 150 138
10. 4 time 0 002 10 000s The parameter determines the integral regulation speed the regulation acts on the difference between PID feedback and getting value by PID regulator When the difference between PID feedback and getting value is 100 integral regulator continues to regulate output to P01xF13x12 5 Hz during the PID integral time single direction PID regulation ignores proportion and differential effect If the value is great the control is stable but response is slow if the value is little the system response is rapid but perhaps surge occurs P08 PID Sampling Period 0 002 10 000 s 0 010 Y Set Sampling period of feedback signal When set this parameter small the system response speed to the giving and feedback deviation is slow but control is stable When set this parameter low the system response speed to the giving and feedback deviation is slow but easy to cause vibration P09 Deviation Limit 0 0 20 0 5 0 Y Deviation limit effects system control accuracy and stability When the deviation of feedback singnal and giving signal lt deviation limit PID N regulation keep output stable When the deviation of feedback singnal and giving signal gt deviation limit PID regulates according to deviation update output P06 PID Differencial Time 0 000 10 000 s 0 000 Y P10 PID Fault Detect Time 0 0 3200 0 s 0 0 N PII PID Fault Detecte
11. The basic format description 1 start of frame Interval 2ms 2 Slave Address From the machine s local address through the A27 parameter settings can only have that uniquely identifies a network s local address Setting Range 1 127 00H 0 ID address is broadcast mailing address 128 255 reserved 3 Function Code Host to send commands from the machine to the command response l Function Code Categories 0x02 read slave fault record Frame start address Slave adress Function code Registers address CRC checksum frame end address Interval gt 2ms idle bit 1 bytes 1 bytes 2 bytes 2 bytes Interval gt 2ms idle bit Slave response Frame start address Slave adress Function code Registers address CRC checksum frame end address Interval gt 2ms idle bit 1 bytes 1 bytes 2 bytes 2 bytes Interval gt 2ms idle bit 0x03 read single register Host command 130 Appendix I RS485 Communication Protocol Appendix I RS485 Communication Protocol Frame start address Slave adress Function code Registers N CRC checksum frame end adress Frame start address Slave adress Function code Registers address CRC checksum frame end adress Interval gt 2ms idle bit 1 bytes 1 bytes 2 bytes 2 bytes Interval gt 2ms idle bit Interval 2m idle bit Libytes bytes bytes 2 bytes Interea 2m idle bit Slave response If slave response and get back to b
12. V TA 1K KH 16 an 3 lo M0v DC Default 2W l l SND JP5 Output signal 1 B Disconnect 0 10V DC Default xq Shorted 0 20mA DC m E PE Output signal 2 VR tI 10V 1K hh ara 2W TL 16 eno MORAN CMM E a _ E FE VR La tv 1K et Ala JP7 Mt 2W Li M Disconnect 0 10V DC TB1 719 GND I Shorted 0 20mA DC Default O Ek x TCi Y E pE 6 as Disconnect 0 10V DC Shorted 0 20mA DC Default L com Output signal 3 Output signal 4 5A 250VAC 5A 30VDC Section I Inspection Standby Circuit 2 4 Main Circuit Terminals G Series 2 4 1 PI8000 Main Circuit Terminals 1 IIkW I5kW 380V Main Circuit Terminals R L1 S L2 T L3 DC 1DC 2 B2 U T1 V T2 W T3 B1 Earthing AC Input Line B1 B2 Braking Resistor Motor connection Terminals DC 1 DC 2 DC Chock 2 18 5 22kW 380V Main Circuit Terminals 6 OOO Ol OlOlelo DC 1 DC 2 DC R L1 S IL2 T L3 U T1 V T2 W T3 AE DC 1 DC 2 DC Chock AC Input Line Motor connection DC 2 DC Braking Terminals Resistor 3 30 160kW 380V Main Circuit Terminals 6000000000 DC 1 DC 2 DC R L1 S L2 T L3 U T1 V T2 WT3 e LLL LL LLLI mm DC 1 DC 2 Dc chock AC Input Line Motor connection DC 2 DC Braking Terminals Resistor
13. 0 MFis defined as adding function key Under monitor menu adding function key MF can adding revise frequency F01 set Under parameter choosing menu adding function key MF can adjust parameter choice Under parameter revising menu adding function key MF can adjust parameter value 1 MFis defined as reducing function key Under monitor menu reducing function key MFcan reducing revise frequency FO1 set Under parameter choosing menu reducing function key MF can adjust parameter choice Under parameter revising menu reducing function key MF can adjust parameter value 2 MFis defined as free stopping key Pressing MF key is valid under monitor menu and parameter choosing menu inverter will be free stopping 3 MFis defined as FWD running key Pressing MF key is valid under monitor menu and parameter choosing menu inverter will be forward running 4 MFis defined as REV running key Pressing MF key is valid under monitor menu and parameter choosing menu nverter will be reverse running 5 MFis defined as forward JOG function key 52 Section V Parameter Function Table Pressing MF key is valid under monitor menu and parameter choosing menu inverter will be forward JOG running 6 MF is defined as reverse JOG function key Pressing MF key is valid under monitor menu and parameter choosing menu inverter will be reverse JOG running 7 MFis defined as JOG function key Pressing MF key is valid under monitor menu and parameter
14. 2 bytes 2ms idle code parameter bytes and write A 0x01 0 63 bit bit RAM o 0x02 0 71 H 0x03 055 Response command U 0x04 0 15 131 132 Appendix I RS485 Communication Protocol Appendix I RS485 Communication Protocol 0x26 0x36 set P 0x05 0 15 y13 product date year Valid operation Invalid operation i 14 product D function E 0x06 0 23 i E d Valid operation Invalid operation code parameter monin date C 0x07 0 47 and write y15 user decode Valid operation Invalid operation b 0x08 0 23 a EEPROM y16 user input Valid Valid n alid operation alid operation y 0x09 07 23 password P p L 0x0A 0 31 17 t T NOTE3 XX parem e ETOUP Valid operation Valid operation 0x00 Running command protection 0x01 Reserved status 1 R 0x10 0x02 Reserved status 2 0x03 Reserved status 3 NOTE 2 Fault record data Fault inquiry content data BIT 15 BIT 14 BIT 13 BIT 12 BIT NOTE4 0 N faul Faulty type 0x00 K F 0 N fault 0 N fault 0 confirmed fault Fault history record 1 Set frequency 0x01 ME ioo ne 1 decelerating fault 1 alarming fault 1 unconfirmed fault 0x02 Fault history record 2 0x00 Actual frequency 0x02 ault ist rv fecon it 11 BIT 10 BIT 9 BIT 8 BIT read the Faule history seconds Mi Actual current 0x03 F
15. A03 Monitor Select 3 LL 0H Parameter Setting Shift Key start to change parameter Functions value adjustments Modification bit fault was not confirmed on AL PANEL Fi REV o Multi function Key MF1 MF2 wr1 define functions through parameter A43 wr2 define functions through parameter A4 MIL AMD MF d MIL AMD MF define MIL AMD NE d function A43 A44 3 MF defined as forward fun A43 Add 4 MF defined as reverse function A43 Ad4 5 MF defined as Punctualit dynamic function A43 AM4 6 MF defined as Anti Jog function M3I AM ME M3 AME ME M3 ALES ME d as Jog function d as Up function d as Down function SET ESC STOP RESET Acceleration Select Parameter Setting Key press SET key and rotate JOG key while selecting parameter the parameter location changes to 10 finish and save the value Changes change the object under monitor Quit Key exit the revisement of parameter reture to displaying menu from submenu or functional menu ENTER have the same function with PRG gt P refer to explaination of key PRG P gt nvalid in the monitoring state Potentiometer Key under checking state the function items value has been in increment or decrement under revising state the edit bit of function items v
16. Set the keyboard for a given frequency of F01 Y Press the keyboard keys are transferred to run FWD M forward running irection of the moto Y Y Shut down after the motor parameter tuning Shut down power outages swap any two phase motor line N A y y b11 1 b11 2 Calculated using plate Static frequency converter measurement y b11 3 Measurement converter operation motor may be Y Press FWD self tuning start running safety he success of self tunin Y Choose FOOControl mode Y Y V F Control ensorles vector control 23 N Set the appropriate FO9 F10 acceleration and deceleration parameters F06 F07 torque control parameter Section IV Test Running According to parameter setting F06 V F boost mode Set F07 torque boost value setting F01 running frequency ensorless vector control adjust speed loopC01 C07 Turned around differential gain C09 C12 regulate motor parameters Y running parameters optimization Y observe running current and motor state top and test unning finish a Y upper torque setting Y parameters running optimiz Observe the moto
17. o DIB Digital Pulse Input Interface AS 24V PLC can be NS connected to JP 23shorted Default PAT TG PLC 24V or DAIV O 10V DC Drain Drive COM or use 2 GND L Lo com COM or us t2 snorted 1 rot outside power DA1C 0 20mADC E PE l PELA 24v 18 35V and fe bag 24V COM PHP PLC doesn t share I e h Source Drive BT com te same JE 2433 Started metal PAS aL eo PH S 1V 0 aribing Le 2 GND t E dl 411 2 shorted TO E PE DA1C 0 20mADC E PE M C JP3 VR L9 tov biu 10V 10V DC ESSE 1K Rt Alt 4 lo 10v DC Default ES 2w Lt Jp5 Kd GND Disconnect O 10V DC Default COM Shorted 0 20mA DC SPB VR COM 1K JP6 2W Rl Disconnect O 10V DC Shorted 0 20mA DC Default ATA TB2 u TC2 VR TA1 1K Je7 ALA A disconnect O 10V DC TB1 2w d Shorted 0 20mA DC Default Tw TCi Serial Communication B Interface Default keyboard t Analog Output DAT I 0 10V Maximum load current 5mA 0 20mA Maximum load impedance250 ohm I I yr I r1 Analog Output DA2 La 0 10V Maximum load current 5mA 0 20mA Maximum load impedauce 50 ohm NU T Output signal 1 Output signal 2 Output signal 3 5A 250VAC 5A 30VDC Output signal 4 5A 250VAC 5A 30VDC Section I Inspection Standby Circuit 2 Wiring diagram 18 5kW 355kW 8NA 8N5 8N6 8N7 8N8 8NA 8NB MCCB R o s Oo
18. 4 Define mode V Fcurve Can be customized appropriate curve according to the actual situation Ten Auto torque boost mode 0 Close Automatic torque boost 1 Open automatic torque boost Foy Trae boost 10 20 0 0 0 Y Value Torque Boost FO8 Cut off 0 00 Maximum frequency Hz 15 00 Y Frequency 29 Torque increase is mainly used to improve the low frequency torque characteristics under 30 Section V Parameter Function Table sensorless V F control mode Torque boost is too low weak low speed motor Torque boost is too high motor over excitation operation large inverter output current and low efficiency Set the torque converter to enhance the frequency below the cutoff frequency torque to enhance effective more than this to set the frequency torque increase is invalid voltage voltage motor rated motor rated voltage voltage IF Sean Frequency Cut off frequency Basic frequency voltage Cut off frequency Basic frequency down the torque curve torque boost Constant torque curve torque boost Section V Parameter Function Table F09 Accelerate Time 0 0 3200 0 S 10 0 Y maximum frequency upper limit frequency lower limit frequency 0 100 frequency set signal F13 Lower frequency the lower limit of the output frequency F14 Upper frequency the uppper limit of output frequency When the frequency setting command
19. 5 E OL Over load unsigned int cal_crcl6 unsigned char data unsigned int length 6 E UL Lower load 7 E PHI Input phase lose s unsigned int i crc_result Oxffff 8 E EEP EEPROM error 9 E ntC Over heat while length 0 E dAt Time limit fault 1 E Set External fault crc_result4 data 2 E Pld PID regulation fault for i 0 i lt 8 i 3 E OHt Motor over heat fault 4 E OL2 Motor over load falult if crc_result 0x01 5 E PG PG error 6 E PHo Output phase lose erc_result crc_result gt gt 1 10xa001 7 E COA Rs485 communication connect A fault else 8 E COb Rs485 communication connect B fault crc_result crce_result gt gt 1 9 E CAL Parameter Identification Failure crc result2 crc result amp Oxff 8 l crc result 8 135 136 Appendix I RS485 Communication Protocol Appendix II Instruction Of The Proportional Linkage Function return cre_result Appendix 2 Instruction of the proportional linkage function 1 proportional linkage function The proportion interaction host computer communication address 128 communications port A is the communication port of host computer Hn Communication port B can be used as the keyboard interface or a PC host computer interface a There is only one host inverter in one proportional linkage The host inverter control the running state the slave inverter follow the host s running state Communication Address 1 127 Both communication port A and communication port
20. A47 keyboard potentiometer setting value Display the value of potentiometer setting range A45 A46 Also can set diretly Setting range A45 A46 A48 keyboard potentiometer setting X1correspond to Y1 Keyboard potentiometer setting the starting point for the corresponding value Setting range 100 100 A49 keyboard potentiometer setting X2 correspond to Y2 Keyboard potentiometer settings corresponding to the value of the end Setting range 100 100 S00 setting frequency Displays the current size of the set frequency through the potentiometer setting Setting range F12xA48 F12xA49 e g F12 50 00Hz A45 0 A46 100 A47 Shows the value of potentiometer settings y01P Upload To K One 0 00 0 0 Times 1 Actual Fre 2 Motor AC y01P Upload To K Clearance y01P Upload To K 0 00 BP oo 9 008 0 0 1 Actual Fre 1 Actual Fre 2 Motor AC 2 Motor AC 0 100 Numerical size can be adjusted by potentiometer 1 when A48 0 A49 100 S00 Set Fre range 0 00Hz 50 00Hz 2 when A48 0 A49 50 S00 Set Fre range 0 00Hz 25 00Hz 3 when A48 100 A49 100 S00 Set Fre jrange 50 00Hz 50 00Hz Note when the motor is in 50 00 0Hz realise reverse another setting FA5Ten bit motor forward inverse as refer to F45 Parameter Description 20 1 Command priority Analog given positive and negative values on the F45 details Section III Op
21. Motor 1 Valid status Motor 2 39 Free stop Free stop machine 40 Up command Up order detail A38 A42 4l Down command Down order detail A38 A42 42 Auto run feature programs Cancle program running function canceled Automatic procedures to A 43 program running pause suspend operation 44 program running start mode program running start mode 45 program running stop mode program running stop mode 46 Edge triggered frequency inverter pulse counter 053 pulse count clearance Clearance 47 pulse count input Edge triggered set the pulse counter input terminal 48 before count lo ding Edge triggered pulse load preset counter 053 counts to 054 E Edge triggered pulse counter counts 055 maximum 49 upper count loading load 053 External fault input level triggered effective after 50 External fault signal input the system reported E Set failure 51 1 pump soft start Electric leverl spring control 1 pump soft start or stop 52 1 pump stop soft start control must use 2 terminal control stop 67 This parameter used to select every IO terminal is valid in which polarity and terminal running command is valid or not when power on 2 d 9 J g d 99 08 27 59 2 24 2 5 2 2 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 O4 E L DH O3 DI2 02 DI3 St DM unused DIS Al3 DI6 Al2 DI7 Al DI8 0 10 bit Input Terminal Polarity 12 15 bit Output
22. Motor running F45 Running Command prior 0100 N Direction x10 terminal keyboard 2 Prior command Analog given 1 positive and negative values Reverse allow reverse forbidden 0 X100 Reverse allow can reverse 1 I running time F33 F34 Linear Acceleration F37 Skip Frequency 1 Limit 0 00 Maximum frequency Hz 0 00 x F38 Skip Frequency 1 Upper 0 00 Maximum frequency Hz 0 00 Y F39 Skip Frequency 2 Limit 0 00 Maximum frequency Hz 0 00 Y F40 Skip Frequency 2 Upper 0 00 Maximum frequency Hz 0 00 Y F41 Skip Frequency 3 Limit 0 00 Maximum frequency Hz 0 00 Y 37 Bit used to change the direction of motor running 0 Forward command FWD is to let motor forward running 1 Forward command FWD is to let motor reverse running X10 bit Motor forward reverse running can be controled by the keyboard potentiometer and analog input input positive or negative value 0 Prior command terminal keyboard set frequency can be negative value but running direction decided by terminal and keyboard command 1 Prior command positive or negative value of analog input setting frequency positive value let motor forward running seting negative value let motor reverse running X100 bit motor reverse allow For some producing equipment the reverse may lead to damage to the equipment so this feature can be used to prevent motor reverse Inverter default forbidden revers
23. Noise filter The filter is used to restrain the conduction of electrical magnetic wave interference noise produced by the converter or shock the interferential form radio or momentary concussion The common size of 3 phase EMI noise filter is shown as following confirm the power supply is 3 phase three lines or 3 phase four lines or single phase Earthling wire is as short as possible try to place the filter near the converter Please choose EMI filter when the converter is used in residential area commercial area science area or other Please need to prevent magnetic interference or need meet CE UL and CSA standard Note If needing the filter please connect with our company 10 4 Connector It can cut off the supply power in action of the system protection function to prohibit fault enlarging But can t control the motor start or stop by connector 10 5 Braking Unit amp braking resistor There is braking unit inside when using B type frequency converter the maximum 124 Section IX Options braking torque is 50 Please choose braking resistor according to the following table Tope Converter Braking resistor Braking resistor power Q Power W 0 75 200 120 1 5 100 300 2 2 70 300 4 40 500 5 5 30 500 nd R 20 780 11 13 6 2000 15 10 3000 18 8 4000 22 6 8 4500 0 75 750 120 1 5 400 300 2 2 250 300 4 150 500 TR 5 5 100 500 dd 75 780 11 50 1000 15 40
24. The program is running in the single cycle according to the 7 segment of the speed running mode output I frequency 60Hz 50Hz 40Hz 30Hz 20Hz 10Hz 0 10Hz program running STOP imc Single circulation continuous running at step 7 speed Ten The running status when pause 0 The zero speed running when pause 1 Fixed speed running when the suspension Hundred run segment when stop 0 Stop with the parameters set when stop 1 Stop with the settings of start up Thousand Running segment when start up 0 Running at the speed when start up segment 1 Running at the speed before stop Example Hundred Stop with the parameters set when stop Thousand 0 Running at the speed when start up segment i output frequency F51 00 RUN STOP Example Hundred 0 Stop with the parameters set when stop Thousand Running at the speed before stop 4 output frequency FS1 01 RUN STOP 1X Example hundred 1 As start parameter is set to shut down Thousand 1 stop front end speeds Section V Parameter Function Table output frequency RUN STOP I Note atl the acceleration time at the acc time atl dt1 the deceleration time at the dcc time dtl at3 the acceleration tim at the acc time at3 dt3 the deceleration time at the dcc time dt3 7
25. feedback signal P03 Setting Signal Selection Set frequency by keyboard or RS485 0 All external analogy giving 1 AD external analogy giving 2 AD external analogy giving 3 Keyboard potentiometer giving 4 muti step digital voltage giving 5 Digital pulse set 6 When the inverter receives start command it can control output frequency automatically in the PID regulation mode after comparing the setting signal and feedback signal from terminal The process is explained as following setting signal 0 Gr feedback signal A setting signal feedback signal PI8000 PI8100 PID regulation 0 negative action when A is positive frequency rises and when A is negative frequency falls Y I o Y 5 3 Q 1 positive action when A is positive frequency falls and when A is negative frequency rises PID giving signal selection can select keyboard Rs485 potentiometer digital voltage digital pulse for giving signal P04 Keyboard Set Signal 0 0 100 0 50 0 Y When P03 is 4 the setting pressure set by the keyboard 0 0 100 0 is O to the maximum pressure respectively 83 84 Section V Parameter Function Table Section V Parameter Function Table POS PID integral time integral time 0 002 10 000 S 0 250 Y i difference time operation value
26. mode converter according to parameters set by the deceleration time to set the deceleration mode to slow down to the lowest frequencies to stop 1 Free stop mode inverter receive stop command immediately stop output according to the load inertia motor free run to stop F33 Jog 0 0 3200 0 s 1 0 N 36 Section V Parameter Function Table Section V Parameter Function Table F42 Skip Frequency 3 Upper 0 00 Maximum frequency Hz 0 00 Y During running to skip resonance produced by the immanent resonance point in the machine systems skip mode can do this At most three resonance points could be set to skip output frequency ae upper skip frequency 1 skip frequency 1 DN lower skip frequency 1 CIMA ens d upper skip frequency 2 Skip frequency 2 lower skip frequency 2 upper skip frequency 3 skip frequency 3 lower skip frequency 3 frequency setting signal Upper skip frequency and lower skip frequency define skip frequency range In the acceleration and deceleration process inverter output frequency can normally through skip frequency area Acceleration Time Jog F34 Deceleration 0 0 3200 0 s 1 0 N Time Jog direction forward 0 Jog direction reverse 1 Bit Jog direction direction determined by the main 2 terminal Jog end mode Stop Running 0 T
27. 0 100 stop Stop with the 1 settings of start up Running at the speed when start up 0 1000 segment Running at the speed before stop Bit Reserved 10 Program Running start 0 15 up segment 100 Program running end 0 15 segment Program Output signal valid HO Running sine 8ms 0 0710 Configuration Output signal valid 1 15 time 20ms Output signal valid 2 time 100ms Output signal valid 3 time 500ms A bit function reserved Ten Defining the program running start up segment Hundred Defining the end segment of the program running Thousand Defining valid time of program running output signal single cycle 0 Hoz Program Bit eae E 0000 Running Continuous Cycle 1 Bit Program running mode cycle 0 single cycle 1 continuous cycle 2 single cycle according to the 7 segment continuously runs receives STOP command and stop Program runs in three ways as follows Example 1 The program runs single cycle mode output frequency 60Hz 50Hz 40Hz 30Hz 20Hz 10Hz 0 10Hz time T1 T21 731 T4 T5 161 17 Single circulation Example2 The program running continuous cycle mode putput frequency 60Hz 50Hz 40Hz 30Hz 20Hz 10Hz 0 10Hz program running STOP Continuous circulation 73 74 Section V Parameter Function Table Example 3
28. 0 10v DC 1 2 DAtV 0 10v DC 1 2 shorted 1 2 shorted Sah PA CREER Ot 0 0 100 0 100 0 Y 2 17 DAIC 0 20mA DC 9 1 DA1C 0 20mA DC Upper Limit Output Caution Every terminal has choice of voltage output and current output the default setting is voltage Setting output When the voltage output is needed please connect JP1 JP2 and DA1V DA2V seeing the Output Content Giving Output Singla Range Value panel When the current output is needed please connect JP1 JP2 and DAIC DA2C N Reaction 0 N output N function 0 Setti Fault i 1 ee 1 0 Max frequency USE ME Frequency i E Over current inspection 2 Actual i i ctua 2 0 Max frequency Over load inspection 3 Frequency 7 7 Over voltage inspection 4 AcsliConent 3 0 200 corresponding parameter S03 percentage of Less voltage inspection 5 output curent O1 Output Signal Low load inspection 6 Option Output Voltage 4 0 200 corresponding parameter b02 b15 rate 021 02 Output Signal Over heat inspection 7 0 Y voltage of motor 022 Option 2 0 Y 23 O3 Output Signal Running state with command 8 1 Y DC Bus Voltage 5 0 1000VDC DC voltage ba Salat 024 Option 3 Abnormal PID feedback signal 9 8 Y IGBT 6 0 100 0 C e pue t Signal Motor state of REW running 0 Temperature Option 4 Arrival of setting the frequency 1 Output Power 7 0 200 Arrival of Upper frequency 2 Output RPM 8 0 Max RPM Arrival of Lower frequency 3 acmaya Or 9 0 200 torque Arrival of FDT setting frequency 1 1
29. 1 106 Section VII Standard Specifications Section VII Standard Specifications second slip R en V F control can automatically compensate for deterioration compensation Runnin s oru P Keyboard terminal communication method Starting signal Forward reverse jog parameter control direction forward jog and reverse jog Double Supports dual keyboard synchronous control independently keyboard port of each other Double and MFI MF2 can be customized as addition and subtraction multi function keys forward reverse forward jog and reverse jog emergency stop rise and fall and other 9 kinds of ways 4 parameter storages Control panel can be realized four groups of inverter parameters of upload download with manufacturers password to reset factory setting Running info At most display 3 monitoring parameters Select by A00 A01 A02 Store 5 groups error messages at most you can check the type of failure time when failure occurrs set frequency output mans Interrupt controller output a alt eset When the protection function is active you can automatically or manually reset the fault condition i Motor status display stop acceleration and deceleration Running status E constant speed the program running DC brake Built in PID regulator brake current flow in the premise however
30. 15 16 be configured to switch the source Auxiliary setting mode of frequency set 0 keyboard frequency setting frequency or RS485 change F01 kayboard setting frequency After multi digital voltage terminal effective switch change FO1keyboard setting 1 All the external analog setting Given the external analog 0 10V 10V 10V 0 20mA For detail please read the o group parameter 2 AD the external analog setting 3 AB the external analog setting Given the external analog 0 10V 0 20mA For detail please read the o group parameter 4 Keyboard potentiometer setting Keyboard potentiometer setting keyboard potentiometer for a given start and end values of the corresponding values can be positive role and negative effects For detail please read the A group parameter 5 Multi segment digital voltage setting 036 046 IO input terminal function set to 11 12 13 switch H47 H54 Multi digital voltage setting 100 Corresponding to the maximum frequency 6 Digital pulse set Digital pulse input frequency corresponding to set the frequency For detail please read 052 parameter Pulse input terminal and DIS terminal reseting After use digital pulse input o43set to O Otherwise the function settings will take effect can check the pulse input status 058 be limited to low speed pulse 7 PID regulation mode The completion of the main to the frequency of common analog feedback loop control Speed control accuracy requirements applic
31. 1500 Please choose POWTRAN BRAKING UNIT if you need more braking torque Please refer to the catalog of braking unit There is N braking unit inside the large capacity frequency converter Please choose POWTRAN BRAKING UNIT if you need braking 10 6 output EMI filter The fittings can restrain the disturbance noise and lead leak current produced in the output side 10 7 AC output reactor When the line from inverter to motor is longer than 20 meters it can restrain the over current caused by the distributing current and the wireless disturbance of the inverter 125 Section X Quality Assurance Section X Quality Assurance The product quality assurance is in accordance with the following regulations 1 The manufacturer should take responsibility for below specific elements 1 1 in domestic use as calculated from the date of shipment X shipped within one month should accept refund replacement and repair X shipped within three months should accept replacement and repair X ship packages within 12 months should accept repair 1 2 Goods exported overseas excluding China and shipped within six months the local seller is responsible for repair 2 regardless of when and where to use POWTRAN branded products are paid to enjoy life long service 3 all the distributors agency or production place of POWTRAN in whole China can provide after sales service for powtarn product their conditions of service as follo
32. 3 Press S or ENTER enter into y00 23 System FG parameter group to check Status 4 Through potentiometerSwitch to yO1P Upload To KI gt 5 Press e or IENTER enter into yO1 P Upload To K 7 Through potentiometer adjust to 5 parameter modify status 8 Finish the adjustment press ene speed for Clear memory area will display on ESC the LED if cancle the change press 9 Press ee to exit to previous menu 500061 FO 00 Set Fre dae F00 63 Basic FG 0B 0 0 tines MP P18000 Goo 1 Actual Fre 1 Actual Fre 2 Motor AC 2 Motor AC 0 0 y01P Upload To K y01P Upload To K 0 0088 0 0 prc 000B 0 0 1 Actual Fre mm 1 Actual Fre 2 Motor AC 2 Motor AC to adjust the value of resi vement Potentiometer 49 y00 23 System FG BPP 8000 cog 1 Actual Fre 2 Motor AC y00 Reset SP 0B 0 0 1 Actual Fre 2 Motor AC resolution ratio potentiometer is 0 05Hz 2 Range of set frequency can be set with the following parameters Parameter item Description F12 max frequency Inverter output maximum frequency allowed Setting range 10 00 320 00Hz A45 keyboard potentiometer setting X1 Keyboard potentiometer setting the start value Setting range 0 100 A46 keyboard potentiometer setting X2 Keyboard potentiometer setting the end value Setting range 0 100
33. 5 12 Y y07 Fault Record 5 tem parameter Upper ee sac dede 15 M These parameters register fault which happen in the last several times and can inquire about the value of Description LCD E Factory Modity monitor object at the time of fault by PRG and plus or minus key code unit A Keyboard diplay 7 segment LEDdisplay set limit The monitor object of fault state N action 0 0 Fault type Reset system parameter with 1 The fault code is expressed as following keyboard storagel Serial LED display Fault message Reset system parameter with eo E d 2 0 E OCP System is disturbed or impacted by instant over current Reset System keyboard storage 2 i E y00 EE Reset system parameter with a 0 N 1 E OCC Over current signal from current inspected circuit keyboard storage a3 2 E OCF Over current or over voltage signal from drive circuit Reset system parameter with 4 3 E OU Over voltage keyboard storage 4 4 E LU Under voltage Reset system parameter with factory ae tale 5 5 E OL Over load 0 N action 6 E UL Under load 1 Reset system parameter with keyboard storage 1 7 E PHI Phase loss 2 Reset system parameter with keyboard storage 2 8 E EEP EEPROM error 3 Reset system parameter with keyboard storage 3 9 EntC Ovrhest 4 Reset system parameter with keyboard storage 4 10 E dAt Time limit fault 5 Reset system parameter with factory set value When this parameter set valid all the function parameter reset to factory setting The parameters 1
34. B can be the communication port of slave inverter the slave inverter follow the host running and it can realize forced stopping by terminal or keyboard if need For this function the host computer should be set with the following parameters A28 Local communication address 128 For this function the slave computer should be set with the following parameters Keyboard set the fi F01 E oe Command from proportion linkage Host Rs485 Keyboard setting frequency or 0 RS485 AII the external analog setting 1 AD the external analog setting 2 F02 Frequency main set mode AD the external analog setting 3 Keyboard potentiometer setting 4 Multi segment digital voltage set 5 Digital Pulse Setting 6 Keyboard setting frequency or 0 RS485 AII the external analog setting 1 AD the external analog setting 2 kis Auxiliary setting mode of AD the external analog setting 3 frequency set Keyboard potentiometer setting 4 Multi segment digital voltage 5 setting Digital Pulse Set PID regulation mode 7 The main setting individual control 0 F04 relationship between main and auxiliary frequencies The auxiliary setting individual 1 control 137 Appendix V Converter Water Supply Controller Instruction main auxiliary 2 main auxiliary 3 Cmain auxiliary maximum 4 frequency Maximum main auxiliary 5 Minimum main auxiliary 6
35. Drivers Model e Input Spec I m RCE 39 380V 50 608 Output Spec e OUTPUT KW 8 5A 0 00 800 Oz POWTRAN TECHNOLOGY CQ LTD HTTP WWW POWTRAN COM MADE IY SUENZIBN CHINA Serial No amp Bar Code 1 1 4 Model description 2 PI 810 0 b 004 G 3 POWTRAN INVERTER Serial Name P1780 PI7800 Serial P1760 PI7600 Serial L e P1800 PI8000 Serial P1168 P1168 Serial Input voltage level 1 single phase 220V 2 3 phase 220V 3 3 phase 380V 4 3 phase 460V class code 5 3 phase 575V 6 3 phase 660V 0 normal configuration 9 3 phase 1140V 1 spetial 1 configuration 2 spetial 2 configuartion e _ Function Code _ type code General Type F Flow load a normal elided G General load b inhanced m mini M Middle load d single board e H Heavy load Applicable motor capacity eee Special Type NC e g 7R5 7 5KW Z JETDRIVE 110 110KW 1 2 Safety Precautions Never connect the A C power supply to the output terminals U V W of the frequency inverter Fix and lock the panel before supplying power so as to avoid the danger caused by the poor capacity or other components inside the inverter After the power supply is switched on do not perform wiring or check etc Don t touch the circuit boards or its parts or components in the inverter when it is powered so as to avoid danger of electric shock If the power suppl
36. END 24V COM PHP PLC doesn t share Source Drive 1 ice JP2 23 shorted Iefact DA LOTO HKP COM Ere i jq 010V DC any t 1 2 shorted TO E PE 1 DA1C 0 20mADC E PE gt A ies JP3 VR rq 10V O 17 v 0v oc SPA 1K E Alt 4do 0v DC Default f a T 2W Lg JP5 T gH GND O Disconnect 0 10V DC Default COM a lo Shorted 0 20mA DC SPB _ E PE VR TO tov com 1K mh 1 Al2 JP6 2w m Disconnect O 10V DC GND Shorted 0 20mA DC Default LC A2 T TB2 _ E PE a TC2 VR 10V AM 1K Al3 JP7 2W Disconnect 0 10V DC 7181 GND Shorted 0 20mA DC Default HAU TC1 Wiring required lo meet EIA TIA 568A or EIA TIA 568B Standard Analog Output DA1 0 10V Maximum load current 5MA 0 20mA Maximum load impedance250 ohm I r1 Analog Output DAZ Fg 0 10V Maximum load current mA 0 20mA Maximum load impedance250 ohm A T Output signal 1 Output signal 2 Output signal 3 5A 250VAC 5A 30VDC Output signal 4 5A 250VAC 5A 30VDC 2 3 2 PIS100 Diagram Section II Inspection amp Standby Circuit 1 Wiring diagram 11KW and below 7N2 7N3 7N4 DC Reactor Brake Unit e YN Fa Optional MCCB O O DC 1 DC 2 B1 B2 R o OR L1 u T1 S o S L2 PI8100 v T2 O T O 0S 0 OTI L3 Inverter W T3 Earthing Q e o9 Earthing Power Main Circuit Motor A Control Circuit DI1 Input Termina D s
37. Fre 2 Motor AC Times 2 Motor AC resi vement to adjust the value of resi vement Potentiometer FOlFre Set By K F lFre Set By K 0 00 BP 0 0 0 00 BB 0 0 1 Actual Fre 1 Actual Fre 2 Motor AC 2 Motor AC 16 Section III Operating Keyboard 3 22 Parameter upload to the keyboard Parameter Item Description N function 0 System parameter upload to the 1 memory areal in the keyboard System parameter upload to the 2 y01 parameter memory area2 in the keyboard upload to the System parameter upload to the 3 keyboard memory area3 in the keyboard System parameter upload to the 4 memory area4 in the keyboard Clear memory area in the 5 keyboard1 2 3 4 e g System parameter upload to the memory area3 in the keyboard 1 Under monitoring status press S into parameter group to check status 2 Through potentiometerS witch to y00 23 System FG 3 Press S or ENTER enter into y00 23 System FG parameter group to check Status 4 Through potentiometer Switch to yO1P Upload To Kj 5 5 Press S or IENTER enter into yO1 P Upload To K parameter modify status 7 Through potentiometer adjust value to be 3 8 Finish the adjustment press ene speed for upload will display on the LED if cancle the change press to escape to the modification status SC 9 Press LE to
38. IO function group start point end point start point end point is Saving after power down 0 it Cleared after power down 1 Keyboad i 7 A50 Potentiometer Savingaiterstoppoing i i 000 Y Control 10 Clear saving after stopping 1 command Clear saving at end of stopping 2 53 Upper group next group Limit ti ode Description LCD Setting range unit Default gt m Keyboard display 7 stepsLED display setting f revise ment 000 AI Input X1 0 100 0 0 0 001 AT Input X2 0 100 0 100 0 Y 002 AD Input X1 0 100 0 0 0 Y 003 AD Input X2 0 100 0 100 0 Y 54 Section V Parameter Function Table Section V Parameter Function Table 004 AB Input X1 0 100 0 0 0 005 AB Input X2 0 100 0 00 0 006 AI Input X1 Corresponding 100 0 100 0 0 0 Y Value Y 007 AIM Input X2 Corresponding 100 0 100 0 00 0 Y Value Y2 o08 AD Input X1 Corresponding 100 0 100 0 0 0 Y Value Y 009 AD Input X2 Corresponding 100 0 100 0 000 y Value Y2 o10 AI3 Input X1 Corresponding 100 0 100 0 0 0 Y Value Y oll AI3 Input X2 Corresponding 100 0 100 0 00 0 Y Value Y2 Under the situation Max frequency 50 00hz X1 0 Y1 0 frequency Y1 0 00Hz potentiometer 0V corresponding set frequency f Max X2 100 Y2 100 potentiometer 10V corresponding set frequency f Max frequenc
39. Low iesire when feedback pressure less than the low pressure E06 PS 6096 reached value of this parameter the I O output arrival g NEN a terminal select 26 then it will output arrival signal E07 Tamil gto Water 0000 Timing to water supply function invalid supply 4 Multi function constant pressure water supply pump specific parameters Keyboard E Parameter Display Setting Meaning E08 Timing shift 0 25 According to first start first stop principles to control alternation time i pump rotation rotation time of 0 25 hours electromagn When set up a station pump drive motor to switch E09 etic switching 0 500 from variable frequency industry frequency or from action delay industry frequency to variable frequency and set its electromagnetic switching action delay time is 0 5 seconds To set the determine time 100 seconds from inverter output frequency reaches the upper limit Pumps shift frequencies until increase pump drive motor or E10 EIER 100 judging time from inverter output frequency reaches the lower limit frequencies until decrease pump drive motor Constant Decelerating stop When the inverter failure the Pressure Water rotation switching way is from variable frequency Ell Supply 0000 A MR Configuration pump to industry frequency and the pump maintain the status Multi pump E12 configuration 1111 N 1 4 pumps are frequency controlled pump Milti pusips Multi pump control mode displays the status of each E13 status p
40. RS485 Communication Protocol NOTE 3 5 CRC checkup sum bit 15 BIT 14 BIT 13 BIT 12 BIT Data meaning data frame CRC checkup sum using 2 bytes Checkup sum all the CRC checkup sum in one data frame meaning reserve reserve reserve reserve Bit 11 BIT 10 BIT 9 BIT 8 BIT Valid setup and communications under normal circumstances the host command and slave responses are as follows meaning reserve reserve reserve reserve bit 7 BIT 6 BIT 5 BIT 4 BIT Host Command 0 N free stop 0 JOG stopping Host Registers CRC meaning 1 free stop reserve reserve Slave Setting 1 JOG running Frame start address command address checkup command address A data bit 3 BIT 2 BIT 1 BIT 0 BIT O reverse command Interval 2ms idle bit 0x08 0x06 0x0001 0x1388 OxD5C5 i 0 stop command meaning reserve 1 forward reserve 1 run command command Slave response NOTE 4 fault style code Registers j CRC Slave Host response Setting Serial Frame start address address checkup LED displa Fault message address codo data nmber spray SPAB sum 0 E OCP IGBT power driver protect and produce hardware interrupt Ina amb ie bit 0x08 0x06 SQ 0x1388 oe 1 E OCC OC signal from current self inspected circuit impact 2 E OCF OC signal from drive circuit 3 E OU Over voltage 4 E LU Lower voltage 5 Example of communication protocol
41. Reactor Brake Unit Optional MCCB DC 1 DC 2 B1 B2 Motor RO R LT U T1 s o S L2 PI8000 v T2 37 TE T L3 Inverter W T3 Earthing e i Earthing Power gt O O UELLE Motor OE 3 PG Appendix V Converter Water Supply Controller Instruction Appendix 4 Converter water supply controller instruction E00 function parameter setting definition 8 inverter power special power supply 13 stable voltage power 14 constant current power 1 pump constant pressure water supply 9 double pump constant pressure water supply A Extend functions supplement 1 E00 loading type 1 E00 8 variable frequency power P03 PID given signal selection you can set through the keyboard analog All pulse and other means to set a given voltage Given voltage is calculated as follows Given voltage 220VAC Given voltage setting 220x1 414 500 100 62 2 Frequency Power specific parameters Appendix V Converter Water Supply Controller Instruction safe and reliable When Feedback voltage is 100 the corresponding Hall voltage is SOOVAC Hall output voltage is 5V set 003 50 005 50 o P03 PID given signal selection you can set through the keyboard analog All pulse and other means to set a given voltage given voltage is calculates as follows When the given voltage 220VAC given voltage setting 220x1 414 500 100 62 2 Other PID parameters are adjusted according to the sit
42. S08 IGBT Test the temperature of IGBT in the c N Temperature C frequency S09 PID Set Point PID Adjust runme values of the N percentage of a given S10 PID Feedback PID Adjust run time values of the i N percentage of feed back Motor Output The percentage of actual output S11 N Frequency power of motor The output frequency of the motor the actual frequency of the motor x A36the regulate of the motor frequency Max display of the output frequency 2999 9 S12 Excitation Heft Set Motor s set excitation heft i N Value percentage S13 Excitation Heft Motor s actual excitation heft o Actual Value percentage 5 E S14 Torque Heft Set Value Motor set torque percentage Torque Heft Actual S15 E Value Motor actual torque hefts percentage 5 3 Basic function Group Upper group Next group Description LCD Setting Range Factory Change Code Keyboard Unit 7 Step LED Display Setting Limited Display V Fcontrol 0 F00 Control Mode Sensorless vector control 1 7 0 N Sensor feedback close loop vector 2 control Keyboard F01 Setting Lower frequency upper frequency Hz 50 00 Y Frequency 5 1 Menu Group G Code Description LCD Function Discription Quantity d S Monitor Function Monitor frequency current and other 16 16 0B Group monitor objects F Basic Function Frequency setting control mode 51 00 Group accelerationtime and deceleration time User Functi A ib Monitor protection communication setting 56 01 Gr
43. The proportion linkage control Select this function the slave unit would execute the command from the proportion linkage host unit Select this function can also use keyboard terminal RS485 to control the proportion linkage slave unit to run The proportion of linkage running after stop the proportion linkage slave unit with the keyboard terminal RS485 the slave unit will not run the proportion liknge host unit s command it needs once again to respond to host commands through the keyboard terminal RS485 or the proportion linkage host sends stop command so that slave unit could respond to run commands Beeline V Fcurve 0 Power of 1 2 V Fcurve 1 Power of 1 7 power 2 Bit V Fcurve Power of 2 3 V F Boost powerV Fcurve 0000 N FOG Mode Define mode V Fcurve 4 Close Automatic torque 0 10 boost Automatic torqueboost 1 100 Reserved 1000 Reserved Keyboard RS485 CAN 0 Running Keyboard terminal RS485 CAN 1 F05 Control RS485 CAN 2 0 Y Mode Terminal control 3 The proportion linkage control 4 1 Bit V F promote curve 0 Line V F curve Suitable for ordinary constant torque load 1 Power of 1 2 V F curve Appropriate torque down V F curve Suitable for liquid loads 2 Power of 1 7 V F curve Appropriate torque down V F curve Suitable for liquid loads 3 Power of 2 V F curve Torque down V F curve lt is suitable for fans pumps centrifugal load
44. V F curve on the base of rated output voltage 100 of frequency converter corresponding to F7 Ul4 V F Setting Frequency 8 Ul2 most frequency Hz 40 00 N User defined the eighth frequency value of V F curve corresponding to V8 UIS V F Setting Voltage 8 U13 100 80 N User defined the eighth voltage percentage of V F curve on the base of rated output voltage 100 of frequency converter corresponding to F8 5 8 PID parameter Upper group Next group Description 4 Set Range Factory Modify Code LCD Unit 7 Segment LED Display Set Limitation Display Unidirection Bit regulation Bidirection regulation Negative effect 0 10 Positive effect PID fault N action 0 PID a Configuration Warning amp Continuous running Warning amp Decelerating stop 100 Warning amp Free stop 3 1000 P01 PID Output Limit 0 100 96 100 Y The parameter defines the limited range of the output when using PID control Set frequency by keyboard or RS485 0 All external analogy giving 1 AD external analogy giving 2 Feedback Signal m P02 Selection AB external analogy giving 3 1 Y Keyboard potentiometer giving 4 multi step digital voltage giving 5 Digital pulse set 6 PID feedback signal selection can select keyboard Rs485 potentiometer digital voltage digital pulse for
45. X1000 bit UP DN control validity of adjustment 0 UP DN invalid ajustment 49 50 Section V Parameter Function Table bit UP acceleration mode 0 fix speed acceleration according to A41 fix speed To increase frequency every 200ms fix times acceleration according to fix times To increase frequency every triggering 0 DN deceleration mode 0 fix speed deceleration according to A42 fix speed To reduce frequency every 200ms fix times deceleration according to A42 fix times To reduce frequency every triggering 00 UP adjustment mode of adjusting speed ratio 0 UPN Adjustment Of N adjustment Speed Ratio 1 AIl Adjustment Of The Actual UP adjustment ratio percentage given by External Analog Giving AAT AIL 2 eae he Tue Actua UP adjustment ratio percentage given by A41 AI2 External Analog Giving 3 AD Adjustment Of The Actual UP adjustment ratio percentage given by External Analog Giving A41 AB 4 Adjustment Of Actual UP adjustment ratio percentage given by A41 Potentiometer Giving potentiometer Adjustment Of Actual UP adj io percentage given by A41 5 Multi steps Digital c ua a justment ratio percentage given by multi steps digital voltage Voltage X1000 bit DN adjustment mode of adjusting speed ratio N Adjustment Of 0 N adjustment Acceleration Time RE 1 AIl Adjustment Of The Actual DN adjustment ratio percentage given by External Analog Giving A42 A
46. adjustment of the external 2 bit analog giving AB adjustment of the external 3 analog giving Adjustment of keyboard Acceleration ni 4 potentiometer giving one Adjustment of Multi steps F48 Deceleration dieta rolas pig 5 0000 N Configuration Word N adjustment of decceleration 0 time AIl adjustment of the external 1 analog giving 10 AD adjustment of the external 2 analog giving AD adjustment of the external 3 analog giving Adjustment of keyboard 4 potentiometer giving 39 bit Acceleration time ajustment mode N Adjustment Of Acceleration Time N adjustment AII Adjustment Of The External Analog Giving Actual Acc time Acc time AIl giving percentage AD Adjustment Of The External Analog Giving Actual Acc time Acc time AD giving percentage AD Adjustment Of The External Analog Giving Actual Acc time Acc time AD giving percentage Adjustment Of Keyboard Potentiometer Giving Actual Acc time Acc time keyboard potentiometer giving percentage Adjustment Of Multi Stepes Digital Voltage Giving Actual Acc time Acc time Multi steps digital voltage giving percentage X10 bit Deceleration time ajustment mode N Adjustment Of Acceleration Time N adjustment AIl Adjustment Of The External Analog Giving Actual Acc time Dec time AIl giving percentage AD Adjustment Of The External Analog Giving Actual Acc time Dec time AD giv
47. choosing menu inverter will be JOG running Running direction decided by F35 bit setting and terminal state 8 MF is defined as UP function key Pressing MF is always valid inverter will be UP control control parameter decided by A38 A42 9 MFis defined as Down function key Pressing MF is always valid inverter will be DOWN control control parameter decided by A38 A42 Section V Parameter Function Table 100 Reserved 1000 Reserved bit Saving state of potentiometer after power down 0 Saving after power down 1 Clearing saving after power down X10 bit keeping potentiometer set after stopping 0 keeping after stopping 1 Toclear saving after stop command 2 To cear saving at end of stopping A45 Keyboard Potentiometer X1 0 100 0 0 0 Y ASI Temperature Adjustment Of Motor 0 0 200 0 96 100 0 N The start point of value keyboard potentiometer set Being used to revise displaying of A54 motor temperature A46 Keyboard PotentiometerX2 0 100 0 100 0 Y A52 Over heat Temperature Of Motor 0 0 300 0 120 0 N The end point of value keyboard potentiometer set The Value Of Keyboard Potentiometer A47 0 0 100 0 Y Set Displaying value potentiometer set which can be revised by potentiometer under monitor menu Value potentiometer set can be regarded as analog of frequency giving set value max frequency keyboard potentiometer
48. e o DIGITAL PANEL 5 0001 n Ne a o o Qu ay a ER C Lo x i J fi 7N3 item Plastic panel 116 185 5 3 95 9 R2 75 Section VII Standard Specifications TNS Power type type ROE yp yp kW F 5 5 Single phase G 5 5 220v M 4 H 2 2 F 3 3 3 phase G 5 5 220v M 4 H 2 2 F 7 5 11 3 phase G 7 5 380v M 7 5 H 5 5 7 5 180 167 4 l J CESA P rov IT RM 5000 2 AAA Ae m co 1 1 id AMAS LI EM AT QR TONER INN 4 Dd iQ a 7 3 3 Keyboard size JP6C8000 7N4 item Plastic panel 117 Section VII Standard Specifications 33 70 24 5 18 DIGITAL PANEL 1 0 1 1 JP6E8000 33 70 24 5 18 DIGITAL PANEL 10 1 hu 1 JP6D8000 the dimension of keyboard rabbet 118 Section VII Standard Specifications 825 1225
49. function group P02 PID feedback signal selection AD is detected by analog and AI3 works as a redundant configuration to ensure the output voltage 143 2 E02 Starting delay time Feedback pressure lt given pressure starting pressure deviation Continuously exceed E02 start delay time the inverter will restart under in the standby mode This parameter is used to prevent the inverter frequent start stop 3 E04 Stop delay time If you set the frequency less than or equal shutdown frequency and exceed E04 shutdown delay time the inverter will change from running state into the stop and standby state The parameter set bigger the inverter will be easier to stop This parameter set to 0 it means the stop frequency and start stop pressure control are invalid E01 E02 E03 E04 parameter group are used to control system energy saving operation and control water pressure regulation in water supply systems For example 144 Appendix V Converter Water Supply Controller Instruction given pressure 50 Starting pressure deviation 10 starting pressure given pressure starting pressure deviation 40 stopping frequency 5Hz pressure 4 feedback pressure set pressure 50 start pressure 10 0 frequency ume A oe Sees ee i actual frequency upper frequency 777777 Ce Oe ENTE AA oP ye ae oY E stop pressure 3 lower frequency D Aa 0 i time 4 E05 High pressure arrival value When feedback p
50. goods 6 7 when the manufacture s brand trademark serial number nameplate and other damage or can not be recognized 6 8 if the buyer has not paid full money according to purchase agreement 6 9 the installation wiring operation maintenance or other use of objective reality can not be described to the company s service office Section X Quality Assurance Appendix I RS485 Communication Protocol 7 concerning refund replacement and repair services goods shall be returned powtran company after confirmed the attribution of responsibility then they are allowed to be returned or repaired 1 Use introduce Appendix 1 RS485 communication protocol This chapter introduces something about the install and handle of RS485 communication between inverter and PLC PC factory computer RS485 standard interface l Can communicate with all computer l Using multi drop link system can link more to 127 inverters Completely isolated and noise shield l The user would use all types of RS232 485 inverter if only the inverter had automatic RTS control function inside 2 Specification Communication function Items Specification Communication baud rate 38400 19200 9600 4800 2400 1200 bps is selectable Communication Protocol Modbus protocal RTU fomat Interface methods Asynchronism communication methods semi duplex the previous high byte low byte in the post and low effective b
51. increase DC bus voltage and surpass max voltage When you choose Over less voltage stall protection and it is valid Inverter detects DC side voltage if the voltage is too high the inverter to stop deceleration the output frequency remains unchanged until the DC side voltage is below the set value the inverter will re implement the deceleration With braking models and external braking resistor this function should be set to 0 predetermined value the dynamic braking will be implemented 2 general Type under any state when the inverter detected high voltage DC bus exceeds a predetermined value the dynamic braking will be implemented When the inverter is running on emergency deceleration state or load great fluctuation it may appear over voltage or over current This phenomenon is relatively prone to happen when the motor load inertia is heavy When inverterThe inverter internal DC bus detected voltage exceeds a certain value the output brake signal through an external braking resistor implement energy braking function Users can select inverter models with a braking function to apply this feature A09 Less Voltage Level 60 75 Standard DC bus voltage 70 Y The definition of allowed the lower limit voltage of normal working inverter DC side For some low power occasions inverter less voltage value can be appropriately put down in order to ensure the inverter normal working o Under normal
52. input pulse input digital Keyboard potentiometers Keyboard cable 8 core cable in line with EIA T568A EIA T568B standards 107 Fault info frequency output voltage output current running state running time IGBT temperature Double RS485 Rs485 port and an optional keyboard completely isolated Comminication port RS485 communication module CAN BUS Can select can bus module 16 segment At most 16 segments can be set use multi functional terminal speed toshiftor program runs 8 segment At most 8 segment running time can be set multi functional running time terminal can be used to shift 3 segment At most 8 acceleration speed can use the multi functional Speed acceleration e terminal to switch speed Seven Segmen gt t Speed At nost 7 segment speed configuration can be set multi functional terminal can be used to switch Configuration PID feedback Six kinds of ways keyboard three way analog input pulse PID signal input digital potentiometers PID giving Six kinds of ways keyboard three wayl analog input pulse signal input digital potentiometers a sor With the motor parameters parameter can be selected parameter identification automatic storage parameters 3identification Name plate calculation static measurement rotation Motor method measurements 5 name plate Rated frequency rated current rated voltage the number of parameters pole pairs rated speed 5 indentification N lo
53. it should be managed carefully Do inquire the factory when it happens Only the well trained personnel are allowed to use this unit and such personnel must read through the parts of this manual relating to the safety installation operation and maintenance before using the unit The safe operation of this unit depends on correct transport installation operation and maintenance Section I Inspection Standby Circuit Section II Installation amp Standby Circuit 2 1 Conditions for Use 1 Ambient temperature 10 C 40 C 2 Avoid electromagnetic interference and keep the unit away from the interference source 3 Prevent dropping water steam dust powder cotton fiber or fine metal powder from entering it 4 Prevent oil salt and corrosive gas from entering it 5 Avoid vibration 6 Avoid high temperature and moisture and avoid being wetted due to raining with the humidity below 90 RH not dewing 7 Prohibit the use in the dangerous environment where inflammable or combustible or explosive gas liquid or solid exists 2 2 Installation The frequency inverter must be installed by wall hooking in the indoor room with adequate ventilation with enough space left between it and the adjacent objects or damper walls surrounding it as shown in the below figure AIR 47 27
54. of this period Current tim e Water supply time Pressure given 0 H18 H47 H19 H48 2 H20 H49 3 H21 H50 4 H22 H51 5 H23 H52 6 H24 H53 7 H25 H54 7 E08 Timing shif alternation time Timing shif alternation time can control the pump s rotation mode and time When the timing shif alternation time is set to 0 0 hours it means cancel timing rotation function When the timing shif alternation time set between 0 1 to 3200 0 then after a stable operation for a while it will control the pump rotation at the principle of first start and first stop First start and first stop if want stop some pumps should firstly stop the first starting pump According first stop and first start principle to add or reduce pumps can help to ensure each pump has chance to run which can protect some pumps from being rust due to non run for a long time If user need keep each pump run at a average time then just need set the timing shif alternation time Order of adding pumps pump 1 5pump 2 pump 3 4 Order of reducing pups pump 4 pump 3 pump 2 pump 1 Same as currently pump 1 at working frequency pump 2 at working frequency pump 3 at variable frequency reduce pumps pump 1 at working frequency pump 2 at variable frequency then add pumps pump 1 at working frequency pump 2 at working frequency 4 pump at variable frequency reduce pump pump at working frequency pump 2 at variable frequency redu
55. segment in hex can be shifted by 036 046 Hundred bit Current running time segment 0 7 segment in hex can be shifted by 036 046 valid when program running KB Current digital voltage segment 0 7 segment in hex can by shifted by terminal 036 046 81 User defined the first frequency value of V F curve corresponding to V1 output voltage 4 max output V8 Fl F2 F3 F4 F5 F6 F7 F8 max rs output frequency frequency U01 V F Setting Voltage 1 0 U03 10 N frequency converter corresponding to Fl User defined the first voltage perce ntage of V F curve on the base of rated output voltage 100 of U02 V F Setting Frequency 2 U00 U04 Hz 10 00 N User defined the second frequency value of V F curve corresponding to V2 U03 V F Setting Voltage 2 U01 U05 20 N User defined the second voltage percentage of V F curve on the base of rated output voltage 100 of frequency converter corresponding to F2 U04 V F Setting Frequency 3 U02 U06 Hz 15 00 N User defined the third frequency value of V F curve corresponding to V3 U05 V F Setting Voltage 3 U03 U07 30 N User defined the third voltage percentage of V F curve on the base of rated output voltage 100 of frequency converter corresponding to F3 U06 V F Setting Frequency 4 U04 U08 Hz 20 00 N User defined the fourth frequency value of V F curve corres
56. set value Potentionmeter set value can be regarded as value of PID giving value of PID giving keybaord potentiometer set value N reaction for motor over heat Warning and runing 1 A53 Reaction For Motor Over heat Warning and 0 Y deceleration 2 stopping Warning and free 3 stopping When the displaying value of motor temperature A5 surpassed value A52 inverter will warn and react according to reaction for motor over heat A53 set A54 Display Of Motor Temperature 50 0 300 0 N A48 Keyboard Potentiometer X1 100 0 100 0 0 0 Y Corresponding Value Y1 A49 Keyboard Poientiometer X2 100 0 100 0 100 0 Y Corresponding Value Y2 i i End point End point corresponding value corresponding value Start point corresponding t value 1 1 Start point corresponding value i 1 1 1 1 1 1 i 1 1 1 1 L Y 1 1 1 The motor temperature value measured by optional accessory PT100 can be used for temperature measurement of other parts A55 Proportion Of Linkage Ratio 0 10 10 00 1 00 Y In application of proportion of linkage A55 setting is multiply ratio of that when slave inverter received setting frequency command from host inverter Setting this inverter as one slave inverter of system for proportion of linkage Frequency Keyboard F01 set proportion of linkage ratiox frequency S00 set _ by host inverter 5 5
57. the speed loop The range is 0 01 100s If the value is too great the control is stable but response is slow if the value is too little the system response is rapid but perhaps is unstable So it is necessary to consider the stability and the response speed at the same time when setting the value Col Speed loop Low Speed Ti 0 01 100 00 s 0 15 Y It defines the integral time of the speed loop low speed The range is 0 01 100 00s If the integral time is too great response is slow and the control of external disturbing signal become bad if the time is too little response is rapid but perhaps brings the surge C02 Speed loop Low Speed Td 0 000 1 000 s 0 000 Y It defines the differential time of the speed loop low speed segment and the range is 0 000 1 000s If the time is great enough the surge which is caused by P action when difference occurring can attenuate quickly But too great the surge will happen contrary When the time is little the attenuation function is little too C03 Speed loop Low Speed P 0 200 150 Y It defines the proportion gain of speed loop low speed segment And the range is 0 1000 If the gain is great the response is rapid but too great surge perhaps occurs if the gain is too little response is slower Speed loop Low Speed Shift C04 0 0 C08 Hz 7 00 Y Frequency It defines low speed loop switching frequ
58. to ensure adequate braking torque Overvoltage protection undervoltage protection overcurrent Xiverier protection overload protection over temperature protection protection over the loss of speed protection over voltage stall protection phase protection optional external fault communication error PID feedback signal abnormalities PG failure IGBT temperature Display current IGBT temperature desplay Protection averton tan The fan starting temperature can be set optional control Instant Less than 15 msec continuous operation power down Greater than 15 milliseconds Automatic detection of motor re start speed instantaneous power down re start Speed starting automatically track motor speed when inverter starts track method Parameter Protect inverter parameters by setting the password and pnr decoding function Can be customized into 47 kinds of functions to achieve 8 way switch forward reverse forward jog and reverse jog emergency input stop reset speed acceleration speed run time switch and pulse counting 3 way analog Can be defined as a switch input 19 inputs To allow for maximum input range 10V 10V 0 20mA 2 Way anol g Can achieve output range 0 10V 0 20mA output Virtual y e terminal Can be set to a virtual terminal using communication or amp inc os keyboard IO port and with the IO port status display In 6 main ways to 7 kinds of auxiliary to the way of the Frequency set keyboard three way analog
59. valid after 1 1 The polarity of electrical level is Setting terminal running mode by this parameter Bit set terminal running mode valid and the terminal is leakage souce driving mode X 047 default setting po arity Low electrical level or fal REV 63 Command can be used to express high or low electrical level rising or falling edge Running Control Mode Keyboard Running Control Prior Running Prior Direction Edge Trigger Valid Same Same E level Trigger Invalid Prior running Prior FWD 0 Two wire running control 1 FWD STOP ee FWD REV STOP E REV COM F05 1 or F05 4 F05 3 Command FWD REV FWD REV Falling edge X Low E Level X FWD running X Falling edge High E level Low E level REV running Rising edge Rising edge High E level High E level STOP running Two wire running control 2 RUN STOP oe FWD FWD REV REV COM F05 lor F05 4 F05 3 Command FWD REV FWD REV Falling edge Falling edge Low e level Low e level FWD running Falling edge Rising edge Low e level High e level REV running Rising edge X High e level X STOP running 2 Three wire running control 1 FWD s FWD REV e REV sTOP Le STOP COM F05 1 F05 3 F05 4 ing edge is Section V Parameter Function Table
60. 0 0 s 1 0 N Section V Parameter Function Table OG feedback signal is O exceed C31 set time system reports PG dropped fault Set speed to 0 or sert C31 to 0 don t check PG dropped fault 5 11 motor parameter MOT N measurement 0 Motor Parameter calculate by lable data 1 b11 0 N Measurement inverter static messurement 2 inverter rotation messurement 3 Upper group next group Description LCD Set range Factory Modify Code Unit Keyboard Display 7 Segment LED Display Set Limit Mot Rated b00 SS 0 00 Maximum frequency Hz 50 00 Y Frequency b01 Motor 1 Rated Current y09 50 100 A Y b02 Motor 1 Rated Voltage 100 1140 V Y b03 Motor 1 Pole pairs 1 8 P 2 Y b04 Motor 1 Rated Speed 500 5000 rpm 1480 Y b00 b04 are the motor s nameplate parameters which touch the precision Set the parameters according to the motor s nameplate b00 b04 motor nameplate in parameters it is necessary to re calculate motor parameters by using b11 Excellent vector control performance requires exact motor parameters Exact parameters are base on the correct setting of motor s rated parameters To assure the control performance please match the right motor as per the inverter s standard motor rated currentis limited between 30 120 of inverter rated current The rated current can be set but can t be more than the rated current of the inverter The pa
61. 0 seconds xminute 1 3200 0 minutes Xhour 2 3200 0 hours xday 3 3200 0 days H47 0 Segment Digital Voltage Giving 100 0 100 0 0 0 Y H48 1 Segment Digital Voltage Giving 100 0 100 0 10 0 Y H49 2 Segment Digital Voltage Giving 100 0 100 0 20 0 Y H50 3 Segment Digital Voltage Giving 100 0 100 0 30 0 Y H51 4 Segment Digital Voltage Giving 100 0 100 0 40 0 Y H52 5 Segment Digital Voltage Giving 100 0 100 0 50 0 Y H53 6 Segment Digital Voltage Giving 100 0 100 0 96 60 0 Y 79 80 Section V Parameter Function Table H54 H55 7 Segment Digital Voltage Giving 100 0 100 0 96 70 0 Y Digital voltage set function can analogy give frquency select by F02 F03 analogy give PID set or feedback select by PO2 P03 it cand be shifted by the input terminal 036 046 bit Current speed step 0 O0xF 10 Current acceleration 0 0x7 Y segment Multi speed N Status 100 Current running time 0 0x7 A 0x segment 1000 Current digit voltage 0 0x7 segment Section V Parameter Function Table 5 7 V Fcurve Group Upper group Next group Code Description LCD Keyboard Display Setting Range 7 Segment LED Display Unit Factory Setting Change Limit U00 V Fsetting Frequency 0 00 U02 Hz 5 00 Bit Current speed segment 0 16 segment In hex can be shift by 036 046 Ten bit Current acceleration segment 0 7
62. 00 0Hz maxmum frequency can Output be set between 10 00 and 800 0Hz frequency H type 0 00 2000 0Hz maxmum frequency can be set between 10 00 and 2000 0Hz V Fcontr Sensorless vector Sensor close loop control method ol control vector control Start torque d 0 25Hz 180 0 00Hz 180 18096 speed adjustable 1 100 1 200 1 2000 range speed stabilizing 40 5 0 2 0 02 precision waveform Asynchronous space vector PWM N class sub synchronous produce space vector PWM two phase optimization of space vector methods PWM Control Auto torque Achieve low frequency 1Hz and high output torque control under V F control mode Accelerate decelerate control Sub set S curve acceleration and deceleration mode maximum acceleration and deceleration time is 3200 days Long running time control 16 segments speed run maximum running time is 3200 days oe Digit 0 01Hz below 300Hz 0 1 Hz above 300Hz E alalogue 1 of maxmum frequency accuracy frequency Speed control tolerance 0 01 25 C 10 C accuracy V F curve Linear 1 2 times the power 1 7 times the power 2 times mode power user set 8 V F Curve G S type 150 rated current 1 minute rated current 200 0 1 second F rated current 120 1 minute 150 of rated current of Over load 01 d capability e SECO Z M T type rated current 180 1 minute 250 rated current of 0 1 second H rated current 25096 1 minute 300 rated current 0
63. 021 024 output signal options 021 preset counts to reach the maximum count output signal after the effective time setted by 051 022 counts to reach the ceiling and reached the maximum counter output signal after the effective time setted by 051 Counter pulse signal frequency range 0 100Hz Virtual Terminal 056 0000 F7FF 0000 Y Effective Selection This parameter is used to select a terminal whether each virtual terminal functionality is valid 95 d A3 A2 A1 4059 58 97 46 55 54 93 42 91 40 15 14 1342 1140 9 8 7 6 5 413 2 1 0 O4 E Di 03 DI2 02 DI3 Save a unuset DIS Al3 DI6 Al2 DI7 Al DI8 Setting 0 10 Virtual terminal valid choose 0 Actualinput terminal valid 1 Virtual input terminal valid 057 DI 4 Terminal Status 0000 1111 Y 058 D5 8 Terminal Status 0000 1111 Y 059 AII 3 Terminal Status 000 111 Y 060 Ol 4 Terminal Status 0000 1111 Y Make the actual terminal can only be effective check terminal state Make the Virtual terminal can only be effective through register check terminal state Section V Parameter Function Table Pulse output ratio 10 output signal range 0 500hz example PL1pulse output option 2 actual frequency PL1 pulse output ratio 10 Actual output pulse frequency actual frequency Max fr
64. 1 E Set External fault without factory setting will save the previous setting value 12 E Pld PID regulation fault 95 96 Section V Parameter Function Table 13 E OHt Motor over heat fault 14 E OL2 Motor over load fault 15 E PG PG error 16 E PHo Inverter output phase loss 17 E COA Rs485 communication terminal A fault 18 E COb Rs485 communication terminal B fault 19 E CAL Parameter indentification fault 1 set frequency at the time of fault The output frequency of the inverter at the time of fault 2 output frequency at the time of fault The output frequency of the inverter at the time of fault 3 output current at the time of fault The actual output current at the time of fault 4 output DC voltage at the time of fault The actual output voltage at the time of fault 5 running state at the time of fault The running state at the time of fault 6 running time at the time of fault The running time at the time of fault 7 Inverter IGBT temperature at the time of fault Inverter IGBT temperature LED display expresses the running state and explains as following Section V Parameter Function Table code serial grade product series set according to family code product serial voltage grade 80 0 3 series number 0 Flow load F 1 General load G 2 Middle load M 3 Heavy load H 6 TEXDRIVE S 7 WINDLASS T 8 JE
65. 32 250 110 210 93 170 8N8 P1800066 653 187 340 160 300 132 250 110 210 8NA PI8000 e003 200 380 187 340 160 300 132 250 8NA PI8000 e003 220 415 200 380 187 340 160 300 8NA PIS000 003 250 470 220 415 SNA PI8000 0003 280 520 250 470 200 380 187 340 8NB PI8000 e003 315 600 280 520 220 415 200 380 8NB PI8000 e003 355 640 315 600 250 470 220 415 8NB PI8000 e003 400 750 355 640 280 520 250 470 8NB 103 Light Load Standard Medium Heavy Load F Load G Load M H Structu Inverter type i Pr Ir Pc Ic Pz Iz Pu In re item kW A kW A kW A kW A Single phase voltage 220V 50 60Hz PIS1000 01 0 75 4 0 4 2 5 7N3 PI8 100 cea 1 5 7 0 75 4 0 4 2 5 7N3 PI8 100 c00a1 1 5 7 0 75 4 0 4 2 5 7N3 PI8100 eec1 2 2 10 2 2 10 ES 7 0 75 4 7N4 PIS100 01 4 16 4 16 2 2 10 1 5 7 7N4 PIS100 01 5 5 20 5 5 20 4 16 2 2 10 7N5 3 phase voltage 220V 50 60Hz PIS10000 02 0 75 4 0 4 2 5 7N3 PIS1000 02 1 5 7 0 75 0 4 2 5 7N3 PIS100 02 1 5 7 0 75 4 0 4 2 5 7N3 PIS10000 02 2 2 10 2 2 10 1 5 7 0 75 4 7N4 PIS1000 02 4 16 4 16 2 2 10 1 5 T 7N4 PIS1000 02 5 5 20 5 5 20 4 16 2 2 10 7N5 3 phase voltage 380V 50 60Hz PIS100 03 0 75 2 5 0 75 2 5 0 75 2 5 7N3 PIS100 03 1 5 3 7 1 5 3 7 1 5 3 7 1 5 3 7 7N3 PI8 100600053 2 2 5 2 2 5 2 2 5 2 2 5 7N3 PIS100 03 4 8 5 4 8 5 4 8 5 4 8 5 7N4 PI8100 03 5 5 13 5 5 13 5 5 13 7N4 PI8 10000053 7 5 16 7 5 16 7 5 16 5 5 13 7N5 PI8 100 e023 1 25 7 5 16 7N5 104 Section VII Standard Specifications 7 1 3 Table of rated current for differ
66. 4 Torque Arrival of FDT setting frequency 2 5 This parameter is used for setting upper lower limitation of DA1 DA2 output signal FDT frequency level inspection 6 57 58 Section V Parameter Function Table Arrival of preset counter value 17 Arrival of upper limit counter 18 Program running one period 19 completed Speed tricking mode inspecition 20 N command running state 21 REV running from inverter 22 command Deceleration running 23 Acceleration running 24 Arrival of high pressure 25 Arrival of low pressure 26 Arrival of inverter rate current 27 Arrival of motor rate current 28 Arrival of input frequency lower 29 limitation Arrival of current upper limitation 30 Arrival of current lower limitation 31 Setting aros Value Output Content Specification Explaination 0 N Function Setting 0 N output reaction but inverter can be controlled by theoretical terminal 1 Fault Warning Inverter at fault or after fault with unconfirmed status 2 Over Current Inspeciton Inverter met fault of over current d Over Load Inspeciton Inverter met fault of over load of heat protection 4 Over Voltage Inspeciton Inverter met fault of over voltage 3 Less Voltage Inspeciton Inverter met fault of less voltge 6 Lower Loa
67. 40 Appendix V Converter Water Supply Controller Instruction R L1 x y R 3 phase input Host Inverter PI8000 power supply s AL 380V 50 60Hz 7 SU T L3 1 Running Forward Command FWD DM 10V O 2 Running Reverse An QLH VR Command REV DI2 GND 1K 2W RPS Sean E y12 128 E IRS485 SG OQ LL E PE communication 1 O ena SG zn R L1 R 3 phase input power supply s So 380V 50 60H PI8000 Z NL 13 PA D 37 Forced Stoppin mE d DI1 Bi 38 Up Command 10V 0O DI2 AM 0 10V VR 39 Down Command Dis eno 6 2 Tu a T ey 1 y12 1 127 IRS485 SG L EPE deeem qd if elo vs SO 1 R 3 phase input ET i power supply S x S L2 ave Inverter 380V 50 6 PI8000 380V 50 60Hz T 3 E O A SE ES 37 Forced Stoppin a 7 DI 38 Up Command 10V O DI2 AM 0 10V VR 39 Down Command Dis eO Kw Rs485 SG O_4 y12 1 127 X E PE communicate 1 ort A S cube ame Ser 141 Appendix I PG Instruction Appendix 3 PG instruction 1 2 PI8000 PG V1 can use for 5V line driven encoder terminal function instruction Terminals functions A A B B Z Z Encoder signal input 5V Encoder power supply 5V GND Encoder earthing Terminal connections DC
68. 5 H03 1 Segment Speed Setting 1X Power regieney omne Hz 5 00 frequency Lower fi H04 2 Segment Speed Setting 2X UR MU OPREG Hz 30 00 frequency HOS 3 Segment Speed Setting 3X Lower frequency appe Hz 20 00 frequency Lower fi E H06 4 Segment Speed Setting 4X M MEL a Hz 30 00 frequency Lower fi H07 5 Segment Speed Setting 5X mete meg TEES Hz 40 00 frequency Lower fi z H08 6 Segment Speed Setting 6X O S a Hz 45 00 frequency Lower fi 5 H09 7 Segment Speed Setting 7X Mn AME Hz 50 00 frequency H10 8 Segment Speed Setting 8X Lower frequency SUEDE Hz 5 00 frequency Lower fi z H11 9 Segment Speed Setting 9X ee Md Hz 30 00 frequency HI2 10 Segment Speed Setting 10X Lower tegueney upper Hz 20 00 frequency Lower fi z H13 1 Segment Speed Setting 11X din c E Hz 30 00 frequency H14 12 Segment Speed Setting 12X Lower frequency natant Hz 40 00 frequency Lower fi E HIS 13 Segment Speed Setting 13X TN due MERE Hz 45 00 frequency Lower fi 7 H16 14 Segment Speed Setting 14X diu E E Hz 50 00 frequency H17 15 Segment Speed Setting 15X Tower frequency PBI Hz 50 00 frequency 76 Section V Parameter Function Table Set the frequency of program running and the running frequency of 7 segment speed respectively short circuit the multi terminal command 1 2 3 4 with COM combinatorially to realized the 16 segment speed acceleration speed OX speed is the regular run
69. 9 and F10 E16 is the voltage increasing time the definition of the output voltage increasing time is from 9999 corresponds to 999 9 seconds E17 is the voltage decreasing time the definition of the output voltage decreasing time is from 9999 corresponds to 999 9 seconds Voltage increasing decreasing time just used to adjust the accelerate decelerate time of output frequency when the inverter running After the stopping command sent the controller will stop the frequency output when the output frequency decelerate to Ohz Us 0 9999 E18 S Max output voltage 0 parameter 3 User 0 9999 E18 piis The max output voltage 0 For safety and reliability to ensure that the output voltage to bear the load within the system we need to define the maximum output voltage If the system highest voltage 250VAC Then a maximum output voltage 250x1 414 500 100 70 7 E18 707 For safety and reliability to ensure that the output voltage to bear the load within the system we need to define the maximum output voltage If the system highest withstand voltage 250VAC Then a maximum output voltage 250 E18 250 2 E00 13 Voltage regulation power In this mode connect AD AI3 to Hall then measure the output voltage and use 2 Halls to do redundant work to ensure the output voltage will not exceed the Hall voltage limitation In this mode the following parameters should be adjusted PID
70. ALI CAL3 N output inverter Keyboard figures area show CAL2 inverter with output under static state Keyboard figures area show CAL4 inverter with output the motor forward in high speed Keyboard figures area show END measuring the end Keyboard figures area show E CAL the measurement process errors Process can be measured through the STOP key to stop Set this parameter the motor parameters will be determined dynamically Be sure the motor is without load N load operation Before setting be sure to run well prepared the motor will run in high speed during the measurement Measurement is completed b11 return to 0 The measured parameters will select parameters on the base of b10 motor parameters which is automatically saved to the b05 b09 or b18 b22 Note Before auto messure the motor parameter must input motor rated parameter b00 b04or b13 17 correctly 94 Section V Parameter Function Table Section V Parameter Function Table Please regulate accelerating and deceleration time or torque increasing parameter if there is N action 0 over current or over voltage faults while auto messurement Reset system parameter with When automatic regulation motor should be in stop sta
71. F ON ON Command 2 Multiterminal speed opp opr ogg orF oN ON ON ON Command 3 Multiterminal speed oN oN ON ON ON ON ON ON H18 0 Segment Running Time TO 0 0 3200 0 s 2 0 Y H19 1 Segment Running Time T1 0 0 3200 0 s 2 0 Y H20 2 Segment Running Time T2 0 0 3200 0 s 2 0 Y H21 3 Segment Running Time T3 0 0 3200 0 s 2 0 Y H22 4 Segment Running Time T4 0 0 3200 0 s 2 0 Y H23 5 Segment Running Time T5 0 0 3200 0 s 2 0 Y H24 6 Segment Running Time T6 0 0 3200 0 s 2 0 Y H25 7 Segment Running Time T7 0 0 3200 0 s 2 0 Y Actual running time equals to the set multi segment running time multiples a time which is times of speed running time and such actual running time decided by the tens digit of H40 H46 Please refer to H40 H46 TI H26 1 Segment Acceleration Time atl 0 0 3200 0 s 10 0 Y H27 1 Segment Deceleration Time dtl 0 0 3200 0 s 10 0 Y H28 2 Segment Acceleration Time at2 0 0 3200 0 s 10 0 Y H29 2 Segment Deceleration Time dt2 0 0 3200 0 s 10 0 Y 78 Section V Parameter Function Table Section V Parameter Function Table H30 3 Segment Acceleration Time at3 0 0 3200 0 s 0 0 Y H31 3 Segment Deceleration Time dt3 0 0 3200 0 s 0 0 Y H32 4 Segment Acceleration Time at4 0 0 3200 0 s 0 0 Y H33 4 Segment Deceleration Time dt4 0 0 3200 0 s 0 0 Y H34 5 Step Acceleration Ti
72. F05 Running control mode Proportional linkage control 4 Select this function the slave inverter will follow the command of host inverter to run after select this function it can also use keyboard terminal and RS485 to control the slave inverter s running In the proportion of linkage during operation if control by the keyboard terminal RS485 control once the slave inverter stopped the slave will N longer respond to the host command if need the slave once again to respond to host commands it should control through the keyboard terminal and RS485 or after the host sends cease and desist commands then the slave will respond the command again to run A28 communication address 17127 A29 Baud rate Same as host Same as host 0 10 10 00 A30 gommunication format A55 Proportional linkage factor 020 2 During the proportional of linkage Me running state of slave inverter is controlled by the host inverter 0 Slave inverter F01 pr Slaver S00 actual set frequ ncy slave FO1 frequency give and secondary amend ascend descend adjusting OE end 2 Proportion linkage application Cases Features of proportional function 1 the host inverter using the potentiometer to control the system speed and use the terminals to control the forward reverse running 2 the slave follows the host running the proportional linkage factor is 1 00 3 after get the running speed comma
73. Fio REV ALARM Y o o o wur A 0 gt owt r 4 B 8 0 ed bor L o 3 a A O os H Le Do N Multi function Key MF1 MF2 wr1 define functions through parameter A43 wr2 define functions through parameter A44 M3 AMD MF defined Mz ME defined A44 2 ME defined A44 3 MF defined as forward function A43 AMd 4 MF defined as reverse function M3IAMS MF defined as Punctuality dynamic function A43 A44 6 MF defined as Anti og function A43 AM4 7 MF defined as Jog function M3I AME MF defined as Up function A43 Ad4 9 MF defined as Down function Eso STOP RESET Acceleration Selec Setting Key press SET key and rotate JOG key while selecting parameter the parameter location changes to 10 i finish and save the value Quit Key changes change the object under monitor t Parameter ENTER have the same function with PRG gt refer to explaination of key PRG D gt Invalid in the monitoring state Potentiometer Key under checking state the function items value has been in increment or decrement under revising state edit bit of function it value has been in increment or decrement under monitoring setting frequency to increase or decrease rward running key drive forward running exit the revisement of
74. For information about other product please visit our website http www powtran com CONTENTS Forewords Contents Section I Inspection and Safety Precautions 1 Section II Installation amp Standby Circuit 4 Section WI Operating keyboard ccccccnnnnnoncconcncnnnonananannnnos 14 Section IV Test running AAA AA 22 Section V Parameter function table sssssssss 25 Section VI Fault Diagnosis and Solutions 100 Section VII Standard Specifications cccccnnnncoocccnnnnnnnnnnannns 103 Section VII Maintenance Ja ii tt 120 Section IX Options dentario gasa 122 Section X Quality Assurance cooonnoooccccnncccnnnnnnanannnononcnnnnannnns 126 Appendix l RS485 communication protocol 128 Appendix 2 Instruction of the proportional linkage function 138 Appendix 3 PG instructiON ccccnnnnoonconnnnnnnnnnnnanannnnnonnnnnannnns 142 Appendix 4 Converter water supply controller instruction 143 Section I Section I Inspection amp Safety Precautions Inspection amp Safety Precautions POWTRAN PI8000 frequency inverters have been tested and inspected before leaving the manufacturer Before unpacking the product please check if its package is damaged due to careless transportation and if the specifications and type of the product complies with the order Please contact the supplier of POWTRAN products
75. Foreword Thank you very much for purchasing PI8000 PI8100 Family Frequency Inverters This family is designed based on the experience of POWTRAN Company in the professional manufacture and sale of the products and suitable for general purpose machine fan pump drive high frequency drive and heavy load machine This User s Manual provides the users with the instructions on the installation parameter setting fault diagnosis routine maintenance and necessary precautions Please read the Manual carefully before the installation of the product in order to ensure that it can be correctly installed and operated This product adopts the advanced sensorless vector control technology combined with the application of inverter technology in China features to achieve high performance V F control dead time compensation auto torque upgrade Slip Compensation and high performance non sense vector control and high performance speed sensorless vector control This User s Manual includes PI8000 PI8100 the general purpose control and special purpose control The general purpose control ha F G M and H The special purpose control has S T and Z F FLOW LOAD G GENERAL LOAD M MEIDDLE LOAD H HEAVY LOAD S TEXDRIVE T WINDLASS Z JETDRIVE Please contact the local dealers or directly contact our company Please keep this user s manual in good condition for it will be helpful to the repair maintenance and applications in the future
76. ID set value PID set value 26 xP12 A10 PID feedback value PID feedback value 26 xP12 If PID feedback 10V corresponding 4 0Mpa pressure if need A09 A10 to display actual value only need to set P12 0 04 85 86 Section V Parameter Function Table E09 Electromagnetic Switch Action Delay 0 000 10 000 0 500 E10 Pumps Shift Judging Time 0 9999 Ell Constant Pressure Water Supply Configuration bit Decelerating stop Variable St di PM frequency pump stop Free stop Keep current Pumps S situation status when fault occurs SIP pean stop 100 Variable frequency to working Alternation frequency shift mode Variable frequency to stop 1000 Pump status Keep status keep Stop reset 0000 Section V Parameter Function Table 5 9 Extention parameters Upper group Next group Description Set Range 5 Factory Modify Code LCD Unit 7 Segment LED Display Set Limit Keyboard Display General 0 Pump 1 Fan 2 Injection machine 3 Textile machine 4 Hoist machine 5 Kowtow Machine 6 E00 Load Type belt conveyor T 0 N Variable frequency power 8 Multi pumps constant 9 pressure water supply Reserved 10 Reserved 11 Torque control 12 Voltage regulation power 13 Current regulation power 14 E01 Starting Fe
77. IL 2 AD Adjustment Of The Actual DN adjustment ratio percentage given by External Analog Giving A42 AD 3 AD Adjustment Of The Actual DN adjustment ratio percentage given by External Analog Giving A42 AD 4 Adjustment Of Actual DN adjustment ratio percentage given by Potentiometer Giving A42 potentiometer Adjustment OA Actual DN adjustment rati tage given b ctua adjustment ratio percentage given by 3 as Digital A42 multi steps digital voltge Voltage 51 Section V Parameter Function Table A40 UP DN Adjustment Value 300 00 300 00 0 00 Frequency after adjustment set frequency UP DN adjustment value A41 UP Adjustment Ratio 0 01 20 00 Hz 0 01 Fix speed To increase frequency every 200ms Fix times To increase frequency every triggering A42 DN Adjustment Ratio 0 01 20 00 Hz 0 01 Fix speed To reduce frequency every 200ms Fix times To reduce frequency every triggering MF is defined as adding 0 function key MF is definded as reducing 1 function key MFis defined as free stopping 2 key MFis defined as FWD running 3 key A The Definition Of d is defined as REV running 4 s A44 Multifunction Keys Mos g 1 MF1 And MF2 5 function key MF is defined as reverse JOG 6 function key MF is defined as JOG function 7 key MFis defined as UP function 8 key MF is defined as Down function 9 key The user defined keyboard can define MF key functions
78. O DC Reactor Brake Unit Earthing ro e Power Dit Input Termipat ri ae e YN Fa Optional O O DC 1 DC42 DC Motor R L1 U T1 sca PI8000 Wire T L3 Inverter WS TA O Farthing Main Circuit otor Control Circuit Isolation RS485 Comunication Taterface 120 ohm 1 2W enclosed with the card when Inverter be the bus terminal JP10 shorted Non Bus Terminal JP10 Disconnect DH Di2Tmput Termigat OTTO D2 JP DISTnput Termipat DE bmw GARS SG Di4input Termipat Du 3 cou erial Communication A SG 1 I 1 2Shorted Drain output Tntfrface need Lo be Drain Drive TI Wo Dr codfigured to RS485 5V a El COM 2 3shortod Source output Cofminication card COM o ry 24V TA Board torninetion 1 E PE Waco vact ot ta DI5Tnput Termi 5a o T DIS DIG Input Termiga J O L rQ DI6 DiZinput Termipat eie qa CEPS DI8Input Termigat o DIB Digital Pulse Tnput Serial Communication B Tnterface Interface Default keyboard cH 24V PLC can be connected to JP1 2 3 shorted Default DAT Wn TQ PLC 24V or 37 DAtv 0 10v DC Drain Drive COM or use 2 GND LLO com El 11 2 shorted 1 outside power DA1C 0 20mADC E PE PELA 24v 18 35V and
79. O1P Upload To KI 5 Press or ENTER enter into yOO Reset SP parameter modify status 7 Through potentiometer adjust to 3 8 Finish the adjustment cancle the change press press che speed for download will display on the LED if ESC gt SC 9 Press L to exit to previous menu S00 Set Fre 0 00 1 Actual Fr 2 Motor AC 2 Motor AC t Y r y00 Reset 5 0 00 l Actual Fr 2 Motor AC y00 Reset SP y00 Reset SP y00 Reset SP 000 0 0 0 00 0 0 0 00 0 0 1 Actual Fre 1 Actual Fre 1 Actual Fre Potentiometer J F00 63 Basic FG y00 23 System FG 0 0 BPPisooo Goo Boro 609 e 1 Actual Fre 1 Actual Fre 2 Motor AC 2 Motor AC 2 Motor AC 2 Motor AC P Donload K Download y00 Reset SP USE MEMORY 3RD finished 000 BB 0 0 100 END 0 adjust the alue of esi vement P 1 Actual Fre 2 Motor AC P STOP END 18 Section III Operating Keyboard e g 2 Clear memory area in the keyboard1 2 3 4 La 1 Under monitoring status press into parameter group to check status Section III Operating Keyboard 3 2 4 F02 the main set mode of set frequency is set to 4 keyboard potentiometer setting 1 Under monitoring status Through otentiometer adjust the frequency the 2 Through potentiometerSwitch to y00 23 System FG
80. Pump switch to output frequency teaches the upper limit frequencies E10 3 100 until increase pump drive motor or from inverter judge the time ae output frequency reaches the lower limit frequencies until decrease pump drive motor Constant Shutdown When the inverter failure the rotation Pressure Water itchi is f iable f Ei Supply 0 switching way is from variable frequency pump to Configuration industry frequency and the pump maintain the status PUEDE N 1 3 pumps are frequency controlled puny E12 configuration 0000 E se pups q y pump pump 4 is soft starter controlled pump Multi pump Multi pump control mode displays the status of E13 status 1112 PE PE IDEE each pump E14 Soft start Pump Multi pump control mode set the control mode of Control each pump i currently set to Full Stop O constant pressure water suppl IO parameters Value read On Setting Parameter Keyboard Value Meanings Display 021 O1 input signal 25 High pressure arrival 159 160
81. Set Frequency 2 0 029 Hz 0 00 Y 031 FDT Inspection Range 0 00 5 00 Hz 0 00 Y 033 Arrival Of Current 034 032 20 Y Lower Limitation When the choice of output signal 021 024 is set as14 inverter output frequency arrives at or surpass FDT set frequency 1 the corresponding signal output terminal will react When inverter output frequency is below of frequency 1 FDT set the corresponding signal output terminal will not react When the choice of output signal 021 024 is set as15 inverter output frequency arrives at or surpass FDT set frequency 3 the corresponding signal output terminal will react When inverter output frequency is below of frequency 3 FDT set the corresponding signal output terminal will not react When the choice of output signal 021 024 is set as16 inverter will firstly inspect FDT set freuqnecy 1 then inverter output frequency arrives at or surpass FDT set frequency 1 the corresponding signal output terminal will react After terminal reaction inverter will inspect FDT set frequency 2 When inverter output frequency is below of frequency 2 FDT set the corresponding signal output terminal will not react 031 frequency inspection range This parameter is used to define inspection range When the difference of actual frequency and inspected frequency has surpassed inspection range terminal will output react e g FDT set frequency 1 as 35Hz FDT set frequency 2 as 30Hz Frequency inspection range is 0 the
82. T Pressure Feedback 0 E PE 485 E PE T 4 20mA Pressure Transmitter Module das SG SG WSC7315 se sc J13 E gt B ta E E B amp E 2 E T N N m e E is u En n L Hh El E y S y E S A E Ee Es e 24V 5 3 3 B8 F 35 3 3 Q 40 7 2 z 2 z 2 2 M 410 co SH NAN OOM TTT HoH COS KOR 00 00 09 lt p 200 IO MAD AD AMO MOD 00 MO A4 Md ud hd hd hd hl hd h o td nd o hd ee h h hd M nd BA h hd l number frequency number 2 Frequency number 3 frequency number 4 Soft starting conversion control pump conversion control pump conversion control pump pump sewage supply water supply water supply water NOTE PF power frequency FC frequency conversion Parameter settings D loading types with a constant pressure water supply function Appendix V Converter Water Supply Controller Instruction Display Multi pump constant pressure water supply need constant pressure water supply interface board while E00 Loading type 2 realize 4 pump constant pressure water supply pump function Q PID adjust in constant pressure water supply Keyboard Parameter Display Setting Meanings F01 Keyboard set 0 Keyboard set the frequency Ohz frequency F02 a EUR MAE 0 Keyboard set frequency or RS485 set frequency set mode Frequency F03 secondary set 7 PID adjusting mode mode elationship F04 between main and auxiliary 2 main auxiliary se
83. TDRIVE Z family code 80 8000 serial 81 8100 serial input voltage level 1 single phase 220V 2 three phase 220V 3 three phase 380V 4 three phase 460V 5 three phase 575V 6 three phase 660V 9 three phase 1140V y12 Software Version N A 100 A official version B specialized version C beta version e version number y13 Product Date Year YYYY N Product Date 14 MMDD N y Month Day 0 9999 Set range y15 User Decode Input Record password wrongly Display g F Y input times info In the state of locked parameter LED displays the times of error input There are three input limit if input is wrong in continuous three times the systems will prohibit input of the password It can prevent testing password in an illegal way and need restart the machine to input again Once the input is right in any time during three times input limit the parameter is unlocked 0 9999 Set range N password or yl6 User password key in decodeanputis deco Display 5 d Y correct inf Parameter code cn lock in The parameter sets the password and the range is 0 9999 After setting the password parameter locks and keyboard displays code if the password is unlocked or password input is right the keyboard will display deco Set password to 0 reset user password s
84. Terminal Polarity Low level valid closed 0 0 Low level valid closed Falling edge valid rising edge invalid High level valid disconnected 1 1 High level valid cut off Rising edge valid falling edge invalid 048 Input Terminal Teponse 0 001 30 000 E 0 005 Y Time 0 68 Section V Parameter Function Table Section V Parameter Function Table pipe But Terminal Reponse 0 001 30 000 s 0 005 Y Time 1 048 049 define Input terminal reponse time through 050 select the reponse time according theterminal o50 Input Jenal Reponse 0 07FF 0 Y Time Selection 048 049 define Input terminal reponse time through 050 select the reponse time according theterminal The delay time of the input terminal is valid to the close and cut off action Set the parameter choose Input terminal reponse time according every terminal 21059 28 27 26 2 2 23 2 2 29 t0p9 8 7 6 5 4 3 2 1 0 pa I DH DI2 DIS DI4 DI5 DI6 DI7 DI8 Al Al2 AIS Setting 0 10 the polarity of input terminal 1 Clear up Hundred Define the status of the counter after power on 0 Reload after power on 1 Clear up after power on 2 Keep the status of the previous count Thousand Define 021 024 is set to reach the preset count or counts to reach the maximum output signal delay time 0 Count period when reach this digital keep this statu
85. able should be used as the signal connection line for input command and must be routed separately as well and it had better be installed far from the main circuit When the carrier frequency is less than 3kHz the distance between the 11 Section II Inspection amp Standby Circuit frequency inverter and motor must not be greater than 50 meters maximum When it is above 4kHz this distance should be reduced The cable for this connection had better be laid in metal conduit X If the frequency inverter is equipped with peripheral devices such as filter reactor first measure its insulation resistance to the earth with 1000V megohm meter and ensure the resistance value is not below 4MQ X Ifthe frequency inverter must be started frequently don t switch off its power supply and the operator must start or stop the inverter by using the COM FWD of the control terminal or Keyboard or RS485 in order to avoid damage to the bridge rectifier X Don t connect A C input power to the output terminals U V W of the frequency inverter X In order to prevent unexpected accidents earthing terminal E or must be grounded to the earth securely the grounding resistance should be below 100Q The cable size should be greater than half of below mentioned corresponding cable size otherwise current leakage will happen possibly X For wiring of main circuit please ref
86. able to the general occasions The given value can be given through the keyboard can also be given through the analog Analog feedback can represent the pressure flow temperature Details see the P group of parameters The completion of the main to the frequency of common analog feedback loop control Speed control accuracy requirements applicable to the general occasions For a given value can be given through the keyboard can also be given through the analog Analog feedback can represent the pressure flow temperature Details see the P group of parameters Through 036 046 IO input terminal set to 17 18 19 be configured to switch the source for a given Keyboard setting frequency or RS485 0 Auxiliary Al the external analog setting 1 Setting Mod F03 X ms Vote AD the external analog setting 2 0 Y Frequency AD the external analog setting 3 4 Keyboard potentiometer setting ratio The main setting individual control 0 The Relationship The auxiliary setting individual control 1 Between main auxiliary 2 FO4 yan main auxiliary 3 b 0 Y im 2 Cmain auxiliary maximum Setting 4 frequency Frequency Maximum main auxiliary 5 27 28 Section V Parameter Function Table Section V Parameter Function Table Minimum main auxiliary Main given and auxiliary given set frequency relations Main given value
87. acceleration time F09 Acceleration time Velocity S addition and subtraction characteristic time F10 x F22 Constant deceleration S characteristics time F10 F10 x F22 F10 x F23 And reduction rate of S characteristic time F10 x F23 All deceleration time F10 deceleration time i slip compensation invalid 0 F24 V F Control Slip 0 N Compensation slip compensation valid 1 0 Slip compensation function is invalid 1 Run in the V F control method the slip compensation function effectively Slip compensation value to adjust the following parameters to ensure stable speed under load fluctuations and heavy load C09 Low Slip Gain C10 Low Slip switching frequency C11 High Speed Slip Gain Slip C12 high speed switching frequency Minimum Running F25 0 00 maximum frequency Hz 0 00 N Frequency Asynchronous space vector PWM 0 Waveform Schloss subse h F19 Generation epless amp subsection synchronous space 1 1 N vector PWM Mode two phase optimization space vector PWM 2 The set frequency lower than the minimum running frequency the converter will stop that is when the set frequency is less than the minimum running frequency are determined that the set frequency is 0 Minimum running frequency and lower frequency relationship is as follows PWM wave produce mode 0 Asynchronous space vector PWM 33 34 Sec
88. ad current stator resistance rotor resistance stator parameters inductance mutual inductance Environment 10 C 40 CC 40 50 C derating between the use is temperature increased by 1 C rated output current decrease of 1 m 40 C 70 C temperature Environment Porn eee 5 95 N condensation humidity Height vibratio n 0 2000 meters 1000 meters above derating use increased by 100 m rated input decreased Application Mounted vertically inside the control cabinet with good 108 Section VII Standard Specifications Section VII Standard Specifications location ventilation do not allow the level or other installation method The cooling medium is air Installed in the absence of direct sunlight N dust N corrosive and explosive gas N oil 7 3 Sharp Size 7 3 1 PI8000 family 3 phase voltage 380 415V 50 60Hz mist N steam N drip environment Cooling i r e 1 8N2 8N7 method Forced air cooling and natural air cooling 3 w b H d van d ieee Ses e i imr moen Bac 5253 e 1 eje A ee t i 1 8N2 Power Structu Shape Installation dimension Wire kW reitem L Ww H a b d F 15 18 5 G 11 15 8N3 360 235 207 340 150 010 M 7 5 11 H 7 5 11 2 8N3 Power Structu Shape Installation dimension Wh
89. al output frequency50 00Hz Gain Speed surveillance A35 100 0 the pole of the 25 combination of vector control and V F control strategies appropriately adjusts motor parameters obtain high performance control effect suitable for a inverter driving a motor occasions suitable for a inverter driving multiple motors occasions suitable for the inverter as a variable frequency power supplies 1 Sensorless vector control 26 Section V Parameter Function Table Section V Parameter Function Table High performance speed sensorless vector control need to set the appropriate electrical parameters or the motor parameter tuning truly achieved the decoupled AC motor so that operational control of DC motors 2 Sensor feedback close loop vector control Suitable for high precision speed control of occasions it is need to install PG card and install pulse encoder shaft in the motor or mechanical equipment The keyboard for a given operating frequency the frequency can be any one between lower frequency and upper frequency to the upper frequency F02 F03 setting to 0 Involved in setting frequency calculation Multi segment digital voltage setting 5 Digital Pulse Set 6 PID regulation mode J Keyboard setting frequency or RS485 0 AII the external analog setting 1 Frequency AD the external analog setting F02 Main Set AD the external analog setting 0 Y Mode Keyboard potentio
90. alue has been in increment or decrement under monitoring setting frequency to increase or decrease Forward running key drive forward running Reset Stop Key drive stop runni ng Exception Reset fault confirmation 14 Section III Operating Keyboard 3 1 2 JPxE8000 Keyboard Specification and function description Monitor Select 1 Numerical Display display the corresponding values of the function under query status display fault code under fault condi ti on display the object set byADO monitor select while running Positive And Negative Sign Indication Light just for mnitor select Parameter Setting Shift Key start to change parameter Functions value adjustments Modification bit Reverse ON Indication Light Alarm Indication everse indication Light not reverse indication ON faul ty Data Unit Prompt Light composed of three indication located on the right side of the isplay status Monitor Select 2 Numerical Disp e PELAS reverse accelerating OFF to the six units indicate FLA revi ous the unit of the parameters displayed by Forward Indication Light fault was not LED Dhi forward indication confir ned the correspondence is as following OFF not forward indication UNT ur FLASH forward accelerating pa pe Lm Ln DISTAL PANEL i al i al
91. and auxiliary given value can be added up subtracted multiplied maximum minimum calculation O group parameters can be adjusted to coordinate the main given and auxiliary given proportion to meet the requirements of the system fine tuning and bias ti fmax fsetting frequency fauxiliary f main fone f mai n ro setting frequency is The relationship between main give and auxiliary given fmax a A A fmax t fmi n fauxiliary 2 fmain bee A E ES fauxiliary feet ting frequency meee fsetting frequency Mai n Auxiliary t Main Auxiliary The Max Frequency fmax 77 maxj 7 fsetting bod fauxiliary fmai n 7 pe pe z z fsetti ng frequency fyyi qj ary pa fmai n am a t Maximum Main amp Auxiliary t Minimum Main Auxiliary Stop and running command control mode 0 keyboard RS485 CAN Control 1 keyboard Terminal RS485 CAN Control control terminal edge trigger falling edge of the implementation of the Forward command FWD Reverse command REV rising edge of the implementation of the STOP command 2 RS485 CAN Control Under this function only free stop funciont is valid under the keyboard control other operation control is invalid 3 Terminal control Level trigger Under this function only free stop funciont is valid under the keyboard control other operation control is invalid 4
92. arameter group N 0B00 Y A01 Monitor 2 X1000 X100 X10 bit 0B01 Y A02 Monitor 3 00 0B 0 63 0x00 0x3 F 0B02 Y Code Keyboard display Parameter Function Parameter N 16 Hexadecimal group N spec Input S Monitor Function Group 0B S 0 16 0x00 0x10 F Basic Function Group 00 F 0 60 0x00 0x3C A User Function Group 01 A 0 56 0x00 0x38 o IO Function Group 02 o 0 61 0x00 0x3D Multi step Speed PLC H EEES 03 H 0 56 0x00 0x38 Group U V F Curve Group 04 U 0 16 0x00 0x10 P PID Function Group 05 P 0 13 0x00 0x0D E Extend Function Group 06 E 0 14 0x00 0x0E Speed Loop P t C Pee shes ween 07 C 0 32 0x00 0x20 Group b Motor Parameter Group 08 b 0 23 0x00 0x17 y System Function Group 09 y 0 18 0x00 0x12 That parameter N should be 16 hex input Monitorl will be valid when first power on and which decide keyboard display content 42 Section V Parameter Function Table Section V Parameter Function Table Such as monitor 1 S01 actual frequency A00 0x0B01 o Monitor 2 057 DI1 4 terminal status A0120x0239 Monitor 3 H55 multi steps speed status AO2 0x0337 Over Less Voltage Stall N 0 Protection Y 1 Overvoltage Stall A04 110 140 Standard bus voltage 96 120 Y Protection Voltage 0 This function invalid 1 This function valid When the inverter deceleration as the motor load inertia motor will produce feedback voltage to inverter inside which will
93. arks ZK air switch KM contactor JR thermo relay M motor 5 Water supply control mode When several pumps supply water meanwhile because of the different time daytime and night different season winter and summer the variation of the water flow is great To save energy and protect the equipment please run pumps as many as you need and stop pumps as many as you do not need Inverter will confirm the number of the running pumps according to the requirement of the pressure close loop control In the set range only one pump is controlled by the inverter at the same time If the timing shift interval time is set 0 05 100 00 when the related running time is stable inverter inverter will shift up the pumps according to stop first or open first to ensure each pump has the chance to run and avoid the pump rusted because of long time N use After the pumps run to the upper and lower arrive the adding pumps or reducing pumps time inverter will add or redcue the pumps according to stop first or open first to ensure each pump can run and avoid the pump rusted because of long time N use 6 Soft start pump control mode Set the soft start pump by El2 and through the input terminals 036 046 respectively controlled soft start pump start and stop 153 Appendix V Converter Water Supply Controller Instruction Soft start pump terminal control stop first Soft start pump is not controlled by constant pressure water supply system Soft start pump ca
94. ault history record 4 x 0 NJOG fault record i AO De voltage 0x04 meanning reserved reserved reserved ault history record 5 0x03 1 JOG running 0x04 Running status 5912 0x05 bit 7 BIT 6 BIT 5BIT 4BIT Running time 0x06 cd A 0 fr lower frequenc upper frequenc E IGBT temperature 0x07 a d P ii i q x 00 stopping 01 accelerating A not arriving not arriving E meaning P 10 decelerating 1 arrive lower 1 arrive upperer ae 11 running in a even speed frequency frequency NOTE 1 bit 3 BIT 2 BIT 1 BIT 0 BIT 0x06 0x16 writing operation A 0 running reverse 0 V F control Function 0x03 0x13 reading operation DAAE cade ObebtucH meaning le annie forward reserve reserve 1 SV control 00 reset the fact SC tti UR Return 0 Only can write into 5 setting 01 upload t n a P a R B Return 0 Invalid operation onto keyboa y02 latest fault record Valid operation Invalid operation Empt RT 00H at record f x 2 d New record 01H Invalid operation ault history recor Confirmed 02H record 08 i Fa it d Return 0 Valid operation reset fault recor 09 rated output adi Ea ES Valid operation Invalid operation curreni 10 rated output y dh ee ES Valid operation Invalid operation 80 0 3 Famil Functi I lta yll products series je A IA a Invalid operation serial code level The number should be decimalization y12 soft ware version Valid operation Invalid operation 133 134 Appendix I RS485 Communication Protocol Appendix I
95. by 047 DI1 DI4Drive model can be controled by JP4 Above 11KW DI5 DIS Drive model can be controled by PLC output terminal DI8can as digital pulse input Below 11KW DI5 DI6 Drive model can be controled by PLC output terminal DI6 can as digital pulse input PLC PLCControl Terminal PLCControl DI5 DI8 Drive model Drain Drive PLCconnect 24 VDC or externa lpower Source Drive PLC connect COM Assistant Power 24V Power positive COM Common The biggest output 24V 200mA Can not connect COM with GND in any situation Output signal SPA COM Output signal 1 SPB COM Output signal 2 Open Collector signal when the output action 24VDC 50mA Common terminal COM the output function can set by 021 022 TA1 TB1 TC1 Output signal 3 TA1 TClopen TB1 TClclose the output function can set by 023 TA2 TB2 TC2 Output signal 4 TA2 TC2open TB2 TC2close the output function can set by 024 Terminal Description Functions R L1 Power input for Connected to 3 phase power S L2 i frequency inverter Single input connected to R T T L3 Grounding point Grounded to the earth B1 B2 Connection point for Connect brake resistance braking resistance U TI V T2 3 Phase Output Connected to 3 phase motor W T3 DC 1 DC DC Bus output Connect the brake resistance DC 1 DC 2 DC reactance Connect DC reactance 2 5 Control Circuit Te
96. ce pump pump 1 at variable frequency add pump pump at working frequency pump 3 at variable frequency add pump pump 1 at industry frequency pump 3 at industry frequency pump 4 at variable frequency Add pump pump 1 at industry frequency pump 3 at industry frequency pump 4 at industry frequency pump 2 at variable frequency 8 E09 Electromagnetic switch action delay Electromagnetic switch action delay time when set up a pump drive motor to switch from variable frequency to industry frequency or from industry frequency to variable frequency This is to avoid inverter output frequency meet with the AC power supply and occur short circuit caused because electromagnetic switch action too slow 9 E10 Pumps shift judging time 146 Appendix V Converter Water Supply Controller Instruction To set the determine time from inverter output frequency reaches the upper frequency until increase pump drive motor or from inverter output frequency reaches the lower frequency until decrease pump drive motor Time setting is based on the pressure change speed if it is within the scope of N oscillation occurred the time set i is the shorter the better inverter will control E12 constant pressure water supply pump 10 E11 Constant pressure water supply configuration Bit Stop mode 0 Decelerating stop When the inverter fails all the pumps in turn stop 1 variable frequency stop When the inverter failure the variable frequency pumps sto
97. circuits for energy buffer and interchange and PCBs For continuous use under normal conditions these parts can be replaced according to the following table and the operating environment loads and the current state of frequency converter Part name Interval for replacement Cooling fan 1 3 years Filtering capacitor 4 5 years PCB printed circuit board 5 8 years 8 3 Storage The following actions must be taken if the frequency converter is not put into use immediately after delivery to the user and need to keep well for the time being or stored for a long time 7 Stored in a dry and adequately ventilated place without dust and metal powder at the temperature specified in the specifications X Ifthe frequency converter is not put into use after one year a charge test should be made so as to resume the performance of the filtering capacitor of main circuit in it For charging a voltage regulator should be used to slowly increase the input voltage of the frequency converter until it reaches the rating and the charge should last more than 1 2 hours This test should be made at least once a year X Don t perform breakdown test at random for this test will cause shorter life of the frequency converter The insulation test must be performed after the insulation resistance is measured with a 500 volt megaohm and this value must not be less than 4MQ 8 4 Measuring and Judgment X If the current is measured w
98. condition keeping default setting N 0 Power off A10 Power down Tracking Options tracking mode d 0 Y Startup tracking 2 mode All Power down tTracking Time 0 0 20 0 S 0 0 Y I DC voltage i i i time output frequency time Invalid 0 A05 Auto Stablize Voltage Valid 1 4 0 Y Valid usless for s 2 deceleration CPU automatically detect the inverter DC bus voltage and to make real time optimized processing when the grid voltage fluctuate the output voltage fluctuation is very small the V F curve characteristic has always been close to setting state of rated input voltage o 0 function inalid 1 function Valid 2 function Valid but useless for deceleration This parameter is used to select the inverter tracking mode 0 N speed tracking means to start tracking from 0 Hz 1 power down tracking When the inverter instantaneous power off and re start the motor will continue running with current speed and direction If the power off time is longer than A11 set time the inverter will not re start power on again 2 Startup tracking means that when power on inverter will first inspect motor direction and speed and then driving motor with current speed and direction Set startup tracking function power off tracking function is still valid motor rotate N S speed speed od input i
99. ctrolytic If there is abnormal Check visually N abnormal capacitance appearance condition Current conductin If the parts come Check visuall N abnormal g leads or blocks loose any condition Terminals If the screws or bolts Tighten the N abnormal come loose loose screws or condition Lalt D means daily check and R means regularly check means need daily check or regularly check For inspection do not disassemble or shake the parts without reason and still less pull off the plug in parts at random Otherwise the unit will not operate normally or can not enter the mode of fault display or causes faults of components or even parts of the main switch components IGBT module is damaged If measuring is necessary the user should note that much different results will be gained possibly if the measuring is performed with different instruments It is recommended that the input voltage be measured with pointer type voltmeter output voltage with rectification voltmeter input and output current with tong test ammeter and power with electrically driven wattmeter 120 gt Section VII Maintenance 8 2 Periodically Replaced Parts In order to ensure the operation reliability of the frequency converter in addition to regular maintenance and inspection all the parts suffering long term mechanical wear should be replaced at a regular interval which includes all cooling fans and the filtering capacitors of main
100. d 0 0 100 0 10 0 N Value 0 000 1 000s The parameter determines the regulation intensity the regulation acts on the change ratio of the difference between PID feedback and getting value by PID regulator When the change ratio of the difference between PID feedback and getting value is 100 in the differential time PID regulator regulates output to P01xF13x12 5 Hz single direction PID regulation ignores proportion and integral effect If the value is great the greater the intensity is the system surge is to occur more easily Set P10 to 0 0 for N fault inspection When PID feedback signal lt P11 set PID fault inspection value last PlOset time regard it as PID regulation fault P12 PID Display Range 0 00 100 00 1 00 Y P07 PID Proportion Gain 0 1000 0 100 0 Y 0 100 0 The parameter difines regulation intensity of PID regulator the larger the P is the more the intensity is When proportion gain is 100 and the difference between PID feedback and getting value is 100 PID regulator s output is PO1xF13x12 596 Hz single direction PID regulation ignores differential and integral effect Proportion gain is the parameter decides PID regulator s response extent If the gain is great the response is rapid but if too great the surge will occur the gain is little the response will lag 4 difference i time boi operation value i M time A09 P
101. d Inspection Inverter met fault of lower load 7 Over Heat Inspeciton Inverter met fault of over heat Running State Of 8 RUN d Inverter is under running state of command Command Ab 1 PID Feedback 9 E p Cedae PID feedback signal is abnormal Signal 59 Section V Parameter Function Table Motor State Of REW f i 0 Motor is reverse running Running Arrival Of Setti 1 E ETE Arrive at set frequency Frequency Arrival Of U 2 ux PS Arrive at upper frequency Frequency Arri f 1 3 AR a Arrive at lower frequency frequency Arrival Of FDT Set 4 m E Arrive at frequency 1 FDT set Frequency 1 Arrival Of FDT Set 5 ho Arrive at frequency 2 FDT set Frequency 2 6 Inspection Level Of FDT FDT frequency levels to meet the inspection Frequency conditions o29 031 7 Arrival Of Preset 3 Present counting value arrives at preset counting value Counting Value 8 Arrival Of Counting Present counting value arrives at upper limitation of Value Upper Limitation counting value P Ruuning O 9 ne Preise Program runs one period to complete Inspection In Speed 20 ae pes Inverter is under speed trick state the valid time is A11 NC d Runni 21 IRE Inverter is under N command running state State REW Command Of i 22 Inverter is under reverse running command Inverter 23 Deceleration Running Inverter is under deceleration running 24 Acceleration Running Inverter is u
102. e Under PID regulated power supply mode the voltage acceleration and deceleration time is controlled by PID parameters it won t affect by voltage acceleration and deceleration time Voltage regulation power specific parameters N name Range unit Description Factory setting Us El6 T 0 9999 s Voltage increasing time 0 parameter 1 Us 0 9999 E17 n Voltage decreasing time 0 parameter 2 N name scope unit meanings Factory setting E16 User parameter 1 0 9999 Voltage increasing time 0 E17 User parameter 2 0 9999 Voltage decreasing time 0 In regulated power supply mode the output and input voltage are both adjustable The increasing time and decreasing time of output voltage is adjusted by F09 and F10 E16 is the voltage increasing time the definition of the output voltage increasing time is from 9999 corresponds to 999 9 seconds E17 is the voltage decreasing time the definition of the output voltage decreasing time is from 9999 corresponds to 999 9 seconds Voltage increasing decreasing time just used to adjust the accelerate decelerate time of output frequency when the inverter running After the stopping command issued the controller will stop the frequency output when the output frequency decelerate to Ohz In Voltage regulation power mode the output and input voltage are both adjustable The increasing time and decreasing time of output voltage is adjusted by F0
103. e When the 38 Section V Parameter Function Table Section V Parameter Function Table motor running direction opposes to equipment required direction you can exchange the wiring of any two inverter output terminals to let equipment forward running direction is consistent with motor running 0 reverse forbidden 1 reverse allow 0 0 60 0S S 0 N F46 Pass 0 Stopping Time Setting this parameter to achieve the motor forward to reverse or from reverse running to forward the waiting time of motor speed being zero Adjustment of Multi steps 5 digital voltage giving Acceleration time xS 0 Acceleration time min 1 100 LT Acceleration time xh 2 Acceleration time day 3 Deceleration time xS 0 Deceleration time min 1 1000 Deceleration time xh 2 Deceleration time day 3 i output frequency CORO i go running time x1 0 F47 Frequency Multiple Setting iG i 0 N x 0 Set frequency display accurat 0 01 Hz With this accuracy F12 Maximum frequency setting range 10 00 320 00Hz 1 Set frequency display accurat 0 1Hz with this accuracy F12 Maximum frequency setting range 100 0 800 0Hz After setting this parameter there must be reset F12 maximun frequency N adjustment of acceleration 0 time AIl adjustment of the external 1 analog giving AD
104. e reach and exceed the high High pressure pressure reached value of this parameter the I O E05 8096 j JT arrival output terminal select 25 then it will output arrival signal Tow NONIS when feedback pressure less than the low pressure E06 arrival press 60 reached value of this parameter the I O output terminal select 26 then it will output arrival signal E07 Regular ume 0000 Regular time water supply function invaid water supply Multi function constant pressure water supply pump specific parameters 037 DI2 input terminal function 39 Free parking selection 038 DB input terminal function 59 Manual rotation command selection 039 DI4 input terminal function 60 Timing of water supply time zero selection 040 DIS input terminal function 35 Pump 3 soft starting selection 041 DI6 input terminal function 56 Pump 3 stopping selection Keyboard F Parameter Display Setting Meaning E08 E08 regular 0 25 According first start first stop principles to control rotation interval pump rotation rotation time of 0 25 hours Electromagnetic When set up a station pump drive motor to switch E09 switching action 0 500 Hom variable frequency ity frequency or fom delay industry frequency to variable frequency and set its electromagnetic switching action delay time is 0 5 seconds To set the determine time 100 seconds from inverter
105. ear saving saving after stopping X10 bit Stop command to clear saving A38 UP DN Cleared at the end of stopping 0000 Control mM One direction adjustment X100 bit Double direction adjustment X1000 Invalide adjustment bit Valide ajustment A39 UP DN Time bit UP fix speed UP fix times 10 DN fix speed DN fix times 100 UP N adjustmentof speed ratio AIl adjustment of the external analog giving AD adjustment of the external analog giving AD adjustment of the external analog giving adjustment of Potentiometer giving Adjustment of multi steps digital voltage 1000 DN N adjustmentof speed ratio AIl adjustment of the external analog giving AD adjustment of the external analog giving AB adjustment of the external analog giving adjustment of Potentiometer giving Adjustment of multi steps digital voltage 0000 bit UP DN control saving state after power down 0 power down to save 1 power down to clear X10 bit UP DN control saving after stopping 0 Keeping afer stopping 1 Stop command to clear saving 2 Cleared at the end of stopping X100 bit UP DN control direction of adjustment 0 one direction adjustment it is one direction adjustment within 0 max frequency range 1 double direction adjusment it is FEW and REW adjustment within 0 max frequency range
106. elow function code it means communications Frame start address Slave adress Function code Registers address CRC checksum frame end adress abnormal Interval 2ms idle bit 1 bytes 1 bytes 2 bytes 2 bytes Interval 2ms idle bit OxAO Invalid operation setting under this state is invalid OxAl function code is invalid Ox13 Read multiple registers 0xA2 Fault record is empty Host command OxA3 register address is invalid Slave Function Register Register Register add CRC o Frame start address frame end adress OxA4 gt slave 1S busy EEPROM delay adress code N add 1 n checksum 0xA5 administrator restricted Interval gt 2ms idle 1 bytes E Interval 2ms idle enl 1 bytes 1 bytes 2 bytes 2 bytes 2 bytes OxA6 set value is beyond limit bi bi z 0xA7 CRC checksum error OxA8 frame format error Slave response Slave Function Register Register data Register data CRC Frame start address frame end adress ic q adress code N 1 n checksum 4 Register Address a M Tod east Sine ale the register address includes two bytes data setting is constituted by a two byte x 1 bytes 1 bytes 2 bytes 2 bytes 2 bytes bit Function code Register Address high by
107. ency the parameter and switching frequency at high speed optimize Speed loop PID parameter C05 Speed Loop High Speed Ti 0 01 100 00 s 0 50 Y It defines integration time of High speed section of the speed loop Range is 0 01 100 00s integration time too large and unresponsive external interference control variation becomes weak integration time is small the reaction speed oscillation occurs when it is too small C06 Speed Loop High Speed Td 0 000 1 000 s 0 000 Y It defines the differential time of the speed loop high speed segment and the range is 0 000 1 000s If the time is great enough the surge which is caused by P action when difference occurring can attenuate quickly But too great the surge will happen contrary When the time is little the attenuation function is little too C07 Speed Loop High Speed P 0 100 150 Y It defines the proportion gain of speed loop high speed section range from 0 1000 Gain is large response speed but too large gain will occur vibration if the gain is small the reaction lag Speed Loop And High speed C08 a Switching Frequency C04 max frequency Hz 30 00 Y It defines Intergral time of speed loop high speed the parameter and switching frequency at low speed optimize the speed loop PID parameter C09 Low speed Slip Gain 0 200 100 Y low speed segment slip comp
108. ency allowed is also the setting basis of acceleration deceleration time This parameter setting you should consider characteristics of the motor speed and capacity Lower F13 0 00 Upper frequency Hz 0 00 N Frequency F14 Upper Frequency Lower frequency Upper frequency Hz 50 00 N 31 This function is chiefly used to improve the possible noise and vibration during the operation of frequency converter When carrier frequency is higher the output current has better wave the torque is great at lower frequency and the motor produces light noise So it is very suitable for use in the applications where great torque is output at low frequency quietly But in these applications the damage to the switches of main components and the heat generated by the inverter are great the efficiency is decreased and the output capacity is reduced At the same time more serious radio interference is resulted and special attention must be paid for application where very low EMI is needed and filter option can be used if necessary Another problem for application of high carrier frequency is the increase of capacitance leakage current The protector for leakage current may invalidate function and over current is also possibly caused When low carrier frequency is applied the case is almost contrary to the above mentioned one Different motor has different reflection to the carrier frequency The best carrier frequency is ga
109. ens Jog end mode reset to the F35 Jog Mode former state before jog i 000 N Setting Jog end and acceleration deceleration time reset to the 0 set acceleration and ho ated deceleration time bet r jog Jog end and acceleration deceleration time save the set 1 acceleration and deceleration time before jog F36 Dd Lower frequency upper frequency Hz 6 00 Y F43 Preset Frequency 0 00 Max frequency Hz 0 00 Y F44 Preset Frequency Working Time 0 0 60 0 S 0 0 Y Jog acceleration and deceleration time to configure the definition of the same section of acceleration deceleration time Jog the direction of movement of bits determined by the F35 when moving the command does not contain Jog fixed direction the direction will be moving inch F35 digit specified direction This bit is set to 2 inch of movement from the terminal or the current direction of the direction of the decision Jog running after the end of the 10 identified by the F35 Jog acceleration and deceleration time can be determined through the F35 s hundred jog at the end had been maintained output frequency Fmax After inverter startup it firstly run with preset frequency running time is preset frequency time then t will run with given frequency Jog run will not be effective by preset frequency Direction command forward command FWD let motor 0 Bit forward running Direction command forward command FWD let motor reverse 1
110. ensation gain Low Speed Slip Switching Frequency C10 0 C12 Hz 5 00 Y 2 frequency Pump 2 stop 0 Pump 2 run in variable 1 10 frequency Pump 2 run in working 2 frequency Pump 3 stop 0 Pump 3 run in variable 1 100 frequency Pump 3 run in working 2 frequency Pump 4 stop 0 Pump 4 run in variable 1 1000 frequency Pump 4 run in working 2 frequency P lst 0 Bit ump 1 stop Pump 1 soft start 1 10 Pump 2 stop 0 Ela Soft Starting Pump 2 soft start 1 0000 y Pump Control Pump 3 stop 0 100 Pump 3 soft start 1 1000 Pump 4 stop 0 Pump 4 soft start 1 U Y EIS in 0 9999 0 Parameter 0 Us Y E16 Wi 0 9999 0 Parameter 1 E 0 9999 E17 User 0 Y Parameter 2 0 9999 E18 User 0 Y Parameter 3 User 0 9999 Y i Parameter 4 bi E 0 9999 E20 User 0 Y parameter 5 E 79999 E21 User 0 999 0 Y Parameter 6 0 9999 E22 User 0 Y Parameter 7 E 0 9999 E23 User 0 Y Parameter 8 7 Please check appendix 4 for the detailed extention parameter instruction 5 10 Speed loop parameter SPD Upper group Next group Description LCD Set Range Factory Modify Code Unit Keyboard Display 7 Segment LED Display Set Limit Low speed sement slip compensation switching frequency 89 Cll High Speed Slip Gain 0 200 100 Y 90 Section V Parameter Function Table Section V Parameter Function Table High speed segment slip compensation gain Torque accelerate time Torque acccelerate time fro
111. ent specifications Section VII Standard Specifications 7 2 Standard specification G F H S Z T M von 2m mp mme Power Current Current Current Current Current Current kW A A A A A A 0 4 2 5 2 5 0 75 4 4 2 3 2 5 E 2 1 5 3 7 3 7 2 2 10 10 5 5 4 16 16 8 5 8 5 5 20 13 11 7 5 30 16 15 11 42 25 22 17 15 15 55 32 27 22 18 18 5 70 38 34 26 22 22 80 45 40 33 28 30 110 60 55 41 35 37 130 75 65 52 45 45 160 90 80 62 52 55 200 110 100 76 63 75 260 150 130 104 86 93 320 170 147 117 98 110 380 210 180 145 121 132 420 250 216 173 150 160 550 300 259 207 175 187 600 340 300 230 198 200 660 380 328 263 218 220 720 415 358 287 240 250 470 400 325 270 280 520 449 360 330 315 600 516 415 345 355 640 570 430 370 400 690 650 520 430 500 860 800 650 540 105 boost function Items Specifications Single phase 200 240V 50 60Hz Three phase 200 240V 50 60Hz Voltage and Three phase 380 415V 50 60Hz Three phase frequency 440 460V 50 60Hz Power Three phase 575 V 50 60Hz Three phase 660V 50 60Hz Three phase 1140V 50 60H Allowable Fluctuation voltage 15 frequency 5 range Control system high performance vector control inverter based on 32 bit DSP G F Z S T M type 0 00 8
112. equency 500hz PL2 pulse output option 3 actual current PL2 pulse output ratio 20 Actual output ratio frequency Actual current percentage 200 1000hz When F00 control model 2 close loop vector control the function is invalid Output Set Value Output Signal Range Definition No action 0 No output Set frequency 1 0 Max frequency Actual 2 0 Max frequency frequency 0 200 corresponding paramerter S03 output Actual current 3 current percentage 0 200 correlation parameter b02 b15 rated Output voltage 4 voltages of motor DC bus voltage 5 0 1000VDC fiii IGBT 6 0 100 0 C temperature Output power 7 0 20096 Output torque 8 0 Max torque Actual t SAO 9 0 200 torque value 5 6 Multi speed PLC Group No action 0 Set frequency 1 Actual frequency 2 Actual current 3 o61 PLI Pulse Output Output voltage 4 0 062 PL2 Pulse Output DC bus voltage 5 E 0 IGBT temperature 6 Output power 7 Output rpm 8 Actual torque 9 063 PL1 Pulse Output Ratio 1 20 10 064 PL2 Pulse Output Ratio 1 20 10 PL1 PL2 Provide two way isolated pulse output signal it can analogy multiple output signals 71 Last group Next group Discription LCD Setting range Factory Change Code Unit Keyboard 7 segment LED Display setting limite display PLC Cancle 0 Bit 7 ic Multi speed as sa 1 i xt x Co
113. equency setting is wrong Check F03 F04 Potentiom Control mode setting is wrong Check F05 eter can t ET regulate Frequency setting is wrong Check F03 F04 LED monitor indicates error KeyRESET or terminal for fault reset learn and fix message the fault according to the fault info N voltage in terminals DC 1 vals The and DC42 Check the voltage at R S or T and charging circuit motor does Check the control mode and frequency parameter t U V or W terminals produce N d M a A no Check the terminal condition if it is operated by an rotate output or abnormal output external terminal Re start after powering down Remember the set operating state or free run Check the load condtion and confirm the model Too much load on the motor selection is right Fault display E OCP System is disturbed or instant over current Fault display E OCC OC signal from current self inspected citcuit impact Fault display E OCF OC signal from drive circuit Motor over current and current exceed 3 times of Fault display E OC3 motor s rated current Over Over current during Reset or modify the parameters of the c rrent acceleration functions F09 F20 F21 E OC Over current during deceleration Reset or modify the parameters of the functions F10 F22 F23 During starting the low frequency jitter over current Modify F06 setting Over current during operation Check the load change and eliminate it Over current during starting or operation
114. er to national rule X Capacity of the motor should be equal to or smaller than that of the inverter X Specification of MCCB electric cable and contractor In out Cable Rated Operational Copper Current Of Contractor Type MCCB A Core A mm2 voltage 380V or 220V PI8100 R40G2 10A 1 5 10 PI8100 R75G2 16A 245 10 PI8100 1R5G2 20A 2 5 16 PI8100 2R2G2 32A 4 20 PI8100 004G2 40A 6 25 PI8100 5R5G2 63A 6 32 PI8000 7R5G2 100A 10 63 PI8000 011G2 125A 10 95 PI8000 015G2 160A 25 120 PI8000 018G2 160A 25 120 PI8000 022G2 200A 25 170 PI8000 030G2 200A 35 170 PI8000 037G2 250A 35 170 PI8000 045G2 250A 70 230 PI8000 055G2 315A 70 280 PI8000 R75G3 10A 1 5 10 PI8000 1R5G3 16A 1 5 10 PI8000 2R2G3 16A 2 5 10 PI8000 _004G3 25A 2 5 16 PI8000 5R5G3 25A 4 16 PI8000 7R5G3 40A 4 25 PI8000 01163 63A 6 32 12 Section II Inspection Standby Circuit PI8000 015G3 63A 6 50 PI8000 018G3 100A 10 63 PI8000 _022G3 100A 10 80 PI8000 _030G3 125A 16 95 PI8000 _037G3 160A 25 120 PI8000 _045G3 200A 35 135 PI8000 _055G3 250A 35 170 PI8000 075G3 315A 70 230 PI8000 _093G3 400A 70 280 PI8000 110G3 400A 95 315 PI8000 132G3 400A 95 380 PI8000 160G3 630A 150 450 PI8000 187G3 630A 185 500 PI8000 200G3 630A 240 580 PI8000 220G3 800A 150 2 630 PI8000 250G3 800A 150 2 700 PI8000 280G3 1000A 185 2 780 PI8000 315G3 1200A 240 2 900 PI8000 355G3 1280A 240 2 960 PI8000 400G3 1380A 185 3 1035 PI8000 500G3 1720A 185 3 1290
115. erating Keyboard 3 2 5 F02 the main set mode of set frequency is set to 1 AI1 external analog given 1 Under monitoring status Through external analog input terminal All adjust the frequency the resolution ratio is 0 01Hz 2 Set the frequency range can be set with the following parameters Parameter Item Description F12 most frequency Inverter speed adjustment s allowed maximum output frequency Setting range 10 00 320 00Hz 000 Al input X1 Keyboard potentiometer setting the start value Setting range 0 100 001 AIl input X2 Keyboard potentiometer setting the end value Setting range 0 100 006 AIl input X1 correspond to Y1 Keyboard potentiometer setting the starting point for the corresponding value Setting range 100 100 007 AIl input X2 correspond to Y2 Keyboard potentiometer settings corresponding to the value of the end Setting range 100 100 S00 frequency setting Display the frequency Through out analog input terminal All adjust the frequency Setting range F12x006 F12x007 Example F12 50 00Hz 000 0 001 100 1 When 006 0 007 100 S00 Set Fre range 0 00Hz 50 00Hz Z i 2 When 006 0 007 50 S00 Set Fre range 0 00Hz 25 00Hz 3 When 006 100 007 100 S00 Set Fre range 50 00Hz 50 00Hz Note When the motor is in 50 00 0Hz realise reverse another setting IF45Ten bit motor forward r
116. eration process when the motor current surpass value A16 set motor will decelerate according to deceleration time A15 set until current below value A16 set In operation process when the motor surpass value A17 set motor will run with this speed until current below value A17 set Deceleration current limitation is prior of constant speed limitation This function is to protect motor overheating when motor does not use thermal relay Inverter using some parameters to calculate motor temperature rise at the same time to determine whether the use of current caused motor overheat When you choose electronic thermal protection function the drive output is shutdown after overheating detected also shows information of protection 0 N selecting this function 1 Select this function A24 Electronic Thermal Protection Grade 120 250 Y This is current grade set by inverter analyzing motor overheat result When current reach multiple of motor rated current and this parameter Inverter will protect motor within one minute The actual overheat protection current is A24 times of rated current within that one minute This parameter default setting of F series is 120 G S series is150 Z M T sries is 180 H series is 250 protect time 4 20min 5min 1min 0 2s A25 Fault Reset Times 0 10 0 Y N protection of phase lost 0 Xt Output Phase Lose Warning and constant runni
117. erminal Polarity 0000 F7FF 0000 Y frequency set 20 MSS timing running 1 21 MSS timing running 2 Synthetic Forward torque limit switch See C 22 MSS timing running 3 parameter set C15 23 Operation control mode shift 1 24 Operation control mode shitt 2 Synthesis of 8 run time switch See H parameter set 25 Operation control mode shift 3 26 Forward torque limit shift 1 27 Forward torque limit switch 2 Synthesis of reverse torque limit switch See C 28 Forward torque limit shift 3 parameter set C15 Group 29 Reverse torque limit shift 1 30 Reverse torque limit shift 2 Synthesis of reverse torque limit switch See C 31 Reverse torque limit shift 3 parameter set C16 Group Vector control mode speed control mode and torque control mode switching 22 Torqu speed shift Disconnected status Speed Control Closed Status torque control Detail C parameter set C18 33 Edge triggered the fault occurred on the current Fault reset command failure to confirm or not confirm 34 FWD JOG command electromotion forward running command 35 REV JOG command Electric reverse running command JOG command as F35 Electric running the command direction set a 36 ur R setting direction in accordance with F35 37 Acceleration and deceleration To maintain the current state to prohibit the forbid commandr acceleration and deceleration movements Motor 1 2 change 38 Motor 1 2 shift Invalid status
118. essuie 0 0 100 0 10 0 Y Deviation Starting Del E02 ro id 0 0 3200 0 s 5 0 Y Time E03 Stop Frequency 0 50 00 Hz 5 00 N E04 Stop Delay Time 0 0 3200 0 s 5 0 Y High Pressure E05 Arrival Value 0 100 0 90 0 Y E06 TOW eee 0 100 0 Y 10 0 Y Arribal Value i i Timing invalid 0 bit water Valid 1 supply Set according to 0 imi Pressure P03 E07 Timing To Supply 10 Ies 0000 Y Water giving Set according to 1 H47 H54 100 Timing Circle mode 0 mode Single circle 1 1000 Current timing step Timing Shift E08 RO Ae 0 0 3200 0 o 00 N Alternation Time u E12 Multi pumps Congfiguration bit Pump 1 invalid Pump 1 variable frequency to control pump Pump 1 soft starts to control pump Pump 2 invalid Pump 2 variable frequency to control pump Pump 2 soft starts to control pump 100 Pump 3 invalid Pump 3 variable frequency to control pump Pump 3 soft starts to control pump 1000 Pump 4 invalid Pump 4 variable frequency to control pump Pump 4 soft starts to control pump 1111 87 E13 Multi pumps Status Bit Pump stop Pump 1 run in variable frequency 0000 88 Section V Parameter Function Table Section V Parameter Function Table Pump run in working C00 Filter Time Of Speed loop 2 200 ms 10 It defines the filter time of
119. et after re electrify status is decode Corresponding parameter group protection Parameter Group after set password yl Protection Set to 0 change is not allowed E 0000 Y Set to 1 change is allowed The First Bit Of The Second Bit Of The Third Bit The Fourth Bit Of LED LED LED Of LED wid BAS F forward F forward state A accelerating reverse forward state D decelerating compartmentatio running in a even stop n code E S S stop state speed command S stop state N action 0 y08 Fault Record Reset 0 Y Reset 1 0 N action the fault records retains 1 the fault records resets y09 Rated Output Current 0 1 1000 0 A N Inverter rated output current yl0 Rated Input Voltage 100 1140 V N The rated input voltage of the inverter It would be set as per inverter input voltage level before leaving factory 80 0 3 yll Product Series N Family Product Input voltage 97 98 Section V Parameter Function Table O N Ea F group A group o group H group U group P group E group C group b group y group Section VI Fault Diagnosis amp Solutions Section VI Fault Diagnosis amp Solutions 6 1 Problems and solutions 99 Problems Possible causes Solutions Keyboard Control mode setting is wrong Check F05 can not control Fr
120. etting interval of fault reset time When inverter met fault and stopped outputting and when it inspected without fault time is longer than fault reset time Inverter will automatically implement fault reset A27 Fan Startup Temperature 0 0 60 0 C 0 0 Y This parameter used to set temperature of fan startup When actual temperature is higher thanset temperature fan will startup N warning for 0 communication fault icati Warning and runnin 1 A31 Communications 8 8 0 Y Troubleshooting Warning and decelerating 2 stop Warning and free stopping 3 0 N inspection A32 Delay Inspection Time s 10 Y 1 250 late inpsection A28 This Inverter Communication Address 1 128 8 Y This Inverter communication address it is the only code to differentiate from other inverters Setting range 1 127 is slave inverter address that can receive command and send out this inverter state Seeing attachment 1 for detailed specification The proportion of linkage function The proportion of linkage host inverter This inverter communcaiton address 128 Communication interface A is set as host inverter communication interface for proportion of linkage Communication interface B can be treated as keyboard interface or PC Host Computer Interface The proportion of linkage slave inverter This inverter communication address 1 127 Communication interface A and B both can be set as comm
121. everse as 1 Command priority Analog given positive and negative values on the F45 details see F45 Parameter Description 21 Section IV Test Running Section IV Test Running Failure occurred when test running please anomalies and Countermeasures against 6 1 fault diagnosis processing trouble shooting Inverter parameters have a strong adaptive ability in general b11 1 calculation of electrical parameters with the name plate on this basis a little manual adjustment can get you high performance vector control Only when the motor completely without the load can set b11 3 motor rotation measurements Before the electrical parameter measurement finished inverter can have the ourput voltage any time please ensure the safety 22 test running Section IV Test Running rated input voltage range Y power voltage inverter in the y power supply connect to the correct grounded then supply power RST of inverter confirm Y Confirmed the inverter motor power reset the power matches to the factory value of y00 5 v Select motor parameters moto with motor nameplate set of p current rated voltage the number of pole pairs motor speed r parameters set in accordance arameters rated power rated y Set the appropriate acceleration and deceleration time the motor maximum frequency F12 the fundamental frequency F15 Y
122. exit to previous menu Potentiometer 00 Set Fre F00 63 Basic FG y00 23 System FG 0 00 0 0 s B Piso00 Goo E 609 1 Actual Fre 1 Actual Fre 1 Actual Fre 2 Motor AC 2 Motor AC 2 Motor AC y01P Upload To K y01P Upload To K y01P Upload To K 0 00 0 0 0 00 0 0 0 00 0 0 1 Actual Fre 1 Actual Fre 1 Actual Fre 2 Motor AC 2 Motor AC 2 Motor AC to adjust the value of resi vement Potentiometer y01P Upload To y01P Upload To K upload y01P Upload To K COE o use memory 3RD Finistes 0600 B 0 0 1 Actual Fre 100 END 1 Actual Fre 2 Motor AC STOP END 2 Motor AC 17 Section II Operating Keyboard 3 2 3 Reset system parameters Parameter Item Description N function 0 memory areal in the keyboard to reset system 1 parameter memory area2 in the keyboard to reset system 2 y00 Reset system parameter parameters memory area3 in the keyboard to reset system 3 parameter memory area4 in the keyboard 1to reset system 4 parameter Use the factory setting reset system parameter e g 1 memory area3 in 1 Under monitoring status press the keyboard 1 to reset system parameter Ld into parameter group to query status 2 Through potentiometerSwitch to y00 23 System FG 3 Press S or ENTER enter into y00 23 System FG parameter group to query Status 4 Through potentiometer Switch to y
123. f displaying after adjustment is 2999 9 A37 Keyboard Lock Function Options 0 OFF OFF Y Baud rate is 0 1200 Baud rate is 1 2400 Baud rate is 2 4800 A29 Baud Rate E 3 Y Baud rate is 3 9600 Baud rate is 4 19200 Baud rate is 5 38400 The baud rate of communication interface A can be set accordingly The baud rate of communication interface B is fixed 19200bps 8 N 1 for RTU 0 8 N 2 for RTU 1 8 E 1 for RTU 2 A30 Communication Format 0 Y 8 0 1 for RTU 3 8 E 2 for RTU 4 8 0 2 for RTU 5 Seeing attachment for detailed specification 47 0 2 2 1 0 t FWD STOP PRG SET ESC MF1 MF2 Potentiometer key SET ESC in Keyboard can activate and cancel keyboard lock function 48 Section V Parameter Function Table Section V Parameter Function Table To lock which key will be decided by corresponding parameter 1 UP DN valid adjustment Set 0 10 bit Keyboard locked state 0 Unlock FWD key i Lock FWD key 0 Unlock STOP key Lock STOP key 0 Unlock PRG key Lock PRG key 0 unlock SET key 3 Lock SET key 0 Unlock ESC key E 1 Lock ESC key 0 Unlock MF1 key 1 Lock MF1 key 0 Unlock MF2 key i 1 Lock MF2 key 0 Unlock potentiometer 1 1 Lock potentiometer Power down to save Power down to cl
124. from time to time Check if there is slight short circuit or grounding 100 Section VI Fault Diagnosis amp Solutions Section VI Fault Diagnosis amp Solutions Check the earthing wire screened cable grounding the static electricity If not the components may be damaged Disturbance and terminals Lower the load or enlarge b04 b14 in the allowable Too much load load range or enlarge A24 to raise the thermal Over load protection level E OL A Modify b04 b14 in case of the motor over load Inappropriate parameter is set allowed Check voltage is right or not Rower E the Frequency inverter rated voltage setting is right or imi not Over voltage Too fast deceleration Modify F10 E OU The load hastos much naria Reduce the load inertia or raise the capacity of frequency converter or add a braking resistor Checking voltage is normal or not Too low power voltage Frequency inverter rated voltage setting is right or Low not voltage Add options of capacitor boxes ELU Power off transiently The line has too small capacity or great rush current exists on Make renovation on power supply system the lines Too high ambient temperature Improve ambient conditions Overheat E OHt Check A27 reduce fan starting tamperaturer when Cooling fans do not work there is fan control The carrier frequency is too hi Check the setting value of function F16 igh Note X Sw
125. here is large energy feedback from load the excessive energy compensation may cause inverter over voltage fault Set A12 100 to cancel power off frequency dropping function condition N torque inspection 0 Warning and runnin 1 A20 Over Torque l 8 8 i 0 Y Inspected Action Warning and decelerating stop 2 Warning and free stopping 3 A21 Over Torque Grade 10 250 150 Y Over T A237 Posee cedi 0 0 60 0 s 0 1 Y Inspection Time Motor output current surpass value A21 set Over torque inspection will be force and the system will show OL2 fault N 0 A23 Electronic Thermal Relay Protection Selection i 1 Y N 0 Al4 Current Limit 1 Y Y 1 A15 Limit Fall Time 0 1 3200 0 s 3 0 Y A16 Limit Deceleration Protection Point 10 250 Y A17 Limit Fix speed Protection Point 10 250 Y Series Current limitaiton Corresponding parameter F 120 A17 130 A16 150 A17 170 A16 170 A17 Meee 190 A16 H 250 A17 270 A16 Current limitation function can effectively restrain over current caused by motor load fluctuation in the process of acceleration and deceleration or constant speed operation This function will be good effect for V F control mode Under protection of current lost speed state the motor speed will drop so it is not adapted by systme which is not allowed to automatically drop speed In op
126. if any problems are found 1 1 Inspection after Unpacking Inspect that the contents are complete one Operation Manual Check the nameplate on the side of the frequency inverter to ensure that the product you have received is right the one you ordered 1 1 1 Instructions on name plate giving 132kW 380V as example E POWIRAN cc AC Motor Drivers Model TYP P17800 13263 Input Spec SOURCE 3d 380V 50 60H Output Spec OUTPUT 132KW 250A 0 00 800 0Hz POWTRAN TECHNOLOGY CQ LTD HTTP VIN POWTRAN COM MADE TY SHENZHEN CHINA Serial No amp Bar Code 1 1 2 Model designation PI 800 0 b 132 G 3 POWTRAN INVERTER Serial Name gt PI780 PI7800 Serial P760 PI7600 Serial PI800 PI8000 Serial Input voltage level PI168 P168 Serial 1 single phase 220V 2 3 phase 220V 3 3 phase 380V 4 3 phase 460V class code 5 3 phase 575V 6 3 phase 660V 0 normal configuration 9 3 phase 1140V 1 spetial 1 configuration 2 spetial 2 configuartion Le Function Code 1 type code General Type F Flow load a normal elided G General load b inhanced m mini M Middle load d single board H Heavy load Applicable motor capacity eee Special Type S TEDRE e g 7R5 7 5KW Z JETDRIVE 110 110KW Section II Inspection amp Standby Circuit 1 1 3 Name plant Instruction 2 E POWIRAN cC AC Motor
127. ilter Time 0 00 2 00 s 0 10 Y ol4 AD Input Filter Time 0 00 2 00 s 0 10 Y 55 Filter time constant of analog signal input that is 0 00 2 00s If time parameter is set too long the changement of setting frequency will be stable but responsing speed will be slow If time parameter is set too short the changement of setting frequency will not be stable but responsing speed will be quick ol5 DAI Output Terminal N reaction 0 g Y 016 DA2 Output Terminal Setting frequency 1 2 Y 56 Section V Parameter Function Table Section V Parameter Function Table Actual frequency 2 4 the corresponded Actual current 3 output frequency Output voltage 4 E DC bus voltge 5 l IGBT temperature 6 H i i Output power 4 cds 10 0 20 0 50 0 100 0 Voltage Current Output RPM 8 OV OmA 10V 20mA Actual value of torque 9 paces DAI Adjustment OF If DAI output 1 5V voltage setting parameter as 017 10 0 018 50 0 017 MOM 0 0 100 0 0 0 Y If DA2 output 4 20mA current setting parameter as 019 20 0 020 100 0 Lower Limit Output j DA1 DA2 Skipping thread ile conil 0 0 100 0 100 0 Y d Upper Limit Of Output DA2 Adjustment Of JP1 2 8 shorted Default JP2 2 3 shorted Default 1 0 0 100 0 0 0 Y 37 37 E 019 ower Limit Output o 1 2 DAtv
128. ine kW reitem L WwW H a b d F 22 30 G 18 5 22 8N4 410 264 242 390 165 O10 M 15 18 5 H 11 15 3 8N4 109 110 4 5 6 8N5 8N6 8N7 Section VII Standard Specifications Section VII Standard Specifications Power Structu Shape Installation dimension lps kW jreitem L Ww H a b d 2 8NA F 37 45 p W _ G 30 37 M 22 30 8N5 560 300 243 540 200 010 H 18 5 22 Type Power Structur Shape Installation dimension e rales F 55 75 G 45 55 M 37 45 8N6 660 365 293 640 250 010 H 30 37 T Power Structur Shape Installation dimension e w leitem L Ww H a e d F 93 110 G 75 93 M 55 75 8N7 710 455 293 690 350 010 H 45 55 Power Structur Shape Installation dimension Te w ener ERES aaa F 132 160 G 110 132 MEL Osa ad oe Loa dira piae sap Lr TONIO Ol H 75 93 MN IMA 111 22 2 635 112 Section VII Standard Specifications Power Structur Shape Installation dimension lps kW e item L Ww H a n d F 187 250 G 160 220 8NA 1540 515 443 465 367 013 M 132 187 H 110 160 113 Section VII Standard Specifications
129. ined after regulation according to actual conditions The higher the motor capacity is the lower the carrier frequency should be selected The company reserves the right to limit maximum carrier frequency as following 32 Section V Parameter Function Table Section V Parameter Function Table The relation between carrier frequency and Motor Noise Electric disturbance Switch dissipation is expressed as following 1 Stepless amp subsection synchronous space vector PWM 2 two phase optimization space vector PWM F20 S Curve Start Time At The Acceleration Step 0 0 50 0 0 0 Y F21 S Curve Stop Time At The Acceleration Atep 0 0 50 0 0 0 Y F22 S Curve Start Time At The Deceleration Step 0 0 50 0 0 0 Y F23 S Curve Stop Time At The Deceleration Step 0 0 50 0 0 0 Y eater Motor Noise Electric disturbance Switch dissipation Frequency 1 0KHz A Big Small Small 8 0KHz 1 1 1 Small Big Big 16 0KHz The relationship of the carrier frequency and power Power kW 0 4 18 5 22 30 37 55 75 110 132 200 220 WE Carrier Frequency 8 0K 7 0K 4 0K 3 6K 3 0K 2 5K Hz Note Carrier frequency is bigger the temperatuer of the machine is higher Carrier kH p 7 Freauency 0 0 4 0 0 0 y Adjustment Z Range N automatic adjustment 0 Carrier Bit eis Frequency automatic adjustment Mode 1 T Adjustmen
130. ing percentage AD Adjustment Of The External Analog Giving Actual Acc time Dec time AD giving percentage 40 Section V Parameter Function Table Actual Acc time Dec time keyboard potentiometer 4 Adjustment Of Keyboard giving percentage Potentiometer Giving Actual Acc time Dec time Multi stepes digital voltage 5 Adjustment Of Multi giving percentage Steps Digital Voltage X100 X1000 bit The unit of Acc and Dec time when program running on 0 step speed Section V Parameter Function Table xDay 3 3200 0 Day F50 Energy Saving Running Percentage 30 100 100 N Acc and Dec X1000 Range e g F09 F10 3200 0 time X100 bit xS 0 3200 0 S xMin 1 3200 0 Min xH 2 3200 0 h xDay 3 3200 0 Day Running direction 0 forward bit z P a Running direction 1 Running reverse F49 Configuration Running time xS 0 0000 N Word i Running time xMin 1 Running time xH 2 Running time xDay 3 This parameter describes the minimum output voltage of the percentage of energy saving operation In the constant speed operation the inverter can be automatically calculated the best output voltage by the load conditions In the process of acceleration and deceleration is not to make such calculations Power saving function is by lowering the output voltage and improve power factor to achieve the purpose of
131. is higher than the upper frequency the operating frequency will be the upper frequency When the frequency setting command below the lower frequency the operating frequency is lower frequency Start the motor that in the status of stopping the inverter outputs accelerate starting from OHz accordance with the step 1 acceleration time towards the upper or the setting frequency to accelerate when motor Stop the operating frequency decelerate according to deceleration time down to OHz F10 Decelerate Time 0 0 3200 0 S 10 0 Y F09 Accelerate time accelerate time from 0Hz to maximum frequency F10 Decelerate time decelerate time from maximum frequency to 0Hz output frequency Fmax RR H running time F09 F10 Linear Acceleration Basi Fis 5 00 Maximum frequency Hz 50 00 N Frequency Fii Percentage Of 50 110 100 Y Output Voltage Corresponding to different fundamental frequency of the motor select this function The basic V F characteristic curve is as below The percentage of the actual output voltage and the rated output voltage Used to adjust the output voltage output voltage inverter rated output voltagexpercentage of output voltage Vout Un 1 base maximum Fout frequency frequency Carrier kH F16 1 0 16 0 Y Frequency Z piz Maximum 10 00 320 00 Hz 50 00 N Frequency Inverter output maximum frequ
132. it pre emptive Data fumula 1 start bit 8 data bits 1 stop bit N parity bit 1 start bit 8 data bits 1 stop bit even parity bit 1 start bit 8 data bits 1 stop bit odd parity bit 1 start bit 8 data bits 2 stop bit N parity bit 1 start bit 8 data bits 2 stop bit even parity bit 1 start bit 8 data bits 2 stop bit odd parity bit Slave address Slave addresses can be set up 1 127 0 for broadcast address host address 128 for the proportion of linkage Communication connect A Terminals SG SG shield SH Default 19200bps Communication connect B RJ45 8 core shielded cable fixed 19200bps N parity bit 3 Communication connection Definition for Communication port A l Link RS485 communication cables to inverter control terminals SG SG When using RS232 485 transform connect Inverter SG to RS485 T Inverter SG to RS485 T 127 128 Appendix I RS485 Communication Protocol After Confirming connection again turn on inverter power If connection is right set communication parameters as following A26 baud rate 0 1200 1 2400 2 4800 3 9600 4 19200 5 38400 A27 current inverter communication address 1 127 If there are more than 1 inverters don t use the same number When using RS485 running control methods set FO5 0 1 2 Keypad RS485 CAN Match register 1200hm 1 4W RS485 T converter T
133. itch off the power supply and do not touch the PCBs and any parts inside in five minutes after the charging indicator light CHARGE goes off Ensure the capacitance has been discharged completely by measuring with the instrument before work inside Otherwise there is a danger of electric shock X Do not touch the PCB or IGBT and other internal parts unless actions have been taken to prevent 101 102 Section VII Standard Specifications Section VII Standard Specifications 7 1 Specification 7 1 1 PIS000 Specification Section VII Standard Specifications 7 1 2 PI8100 Specification Light Load Standard Load Medium Heavy Load Inverter F G Load M H Structure type Pr Ir PG Ic PM IM PH Iu item KW A KW A KW A KW A 3 phase voltage 380V 50 60Hz P1800066 53 15 32 1 25 7 5 16 7 5 16 8N3 P1800066 053 18 5 38 15 32 11 25 11 25 8N3 PI8000 e003 22 45 18 5 38 15 32 11 25 8N4 PI8000 e003 30 60 22 45 18 5 38 15 32 8N4 P1800066 053 37 75 30 60 22 45 18 5 38 8N5 PIS000 03 45 90 37 75 30 60 22 45 8N5 PI8000 e003 55 110 45 90 37 75 30 60 8N6 PI8000 0003 75 150 55 110 45 90 37 75 8N6 PI8000 e003 93 170 75 150 55 110 45 90 8N7 PI8000 e003 110 210 93 170 75 150 55 110 8N7 PI8000 e003 132 250 110 210 93 170 75 150 8N8 PI8000 e003 160 300 1
134. ith the general instrument imbalance will exists for the current at the input terminal Generally differing by not more than 10 is normal If it differs by 30 inform the factory to replace the rectification bridge or check if the error of three phase input voltage is above 5V X If the three phase output voltage is measured with a general multi meter the reading is not accurate due to the interference of carrier frequency and only for reference 121 Section IX Options Section IX Options The series can acquire the peripheral equipment by user because of the different using condition and requirement See the wiring diagram as below mH MCCB or ELCB AC input reactance Input EMI filter connector Connector P18000 inverter Output EMI filter AC output reactance Motor 10 1 MCCB OR ELCB As power switch of the inverter MCCB or ELCB can protect supply power but can t 122 Section IX Options control inverter to run or stop 10 2 AC reactance AC reactance is able to restrain the high harmonic wave of converter input current and improve converter s power factor obviously It s recommended that AC reactance will be used in the following condition X The capacity of power source is ten times more than the capacity of converter 7 SCR load or power factor compensated device with ON OFF is connected with the same power supply X Unbalanced 3 phase voltage is bigger more than 3 The c
135. leration time seconds 0 7 H45 4 Segment Speed Acceleration time munites 1 100 H46 Configuration Acceleration time hours 2 Word PARE d sc X 5 Segment Speed cceleration time ays 3 Configuration Deceleration time seconds 0 Word 1000 on Deceleration time xmunites 1 0000 0000 0000 0000 0000 0000 0000 I KKK speed 6 Segment Speed Deceleration time hours 2 Configuration Word 7 Segment Speed Deceleration time days 3 Configuration Word In program multi speed running the digit parameters decide the direction of each Running Direction Setting Value forward 0 reverse 1 When running control mode FO5 0 1 2 these parameters decide the direction of each speed When running control mode F05 3 the setting value and terminal FWD REV decide the direction of each speed together FWD is prior FWD 1 FWD 1 g Setting Running Running Value direction direction forward reverse 0 reverse forward 1 Ten bit Unit of program running multi segment speed running time Running Time Tens bit Range e g H18 H25 3200 0 xseconds 0 3200 0 seconds xminutes 1 3200 0 minutes Xhours 2 3200 0 hours xdays 3 3200 0 days Hundred bit K bit Unit of program running multi segment speed acc deleration runnin Acceleration KB P Range e g H26 H39 3200 0 Decelatationtime 100 xsecond 0 3200
136. llocation Direction Ten decided by 0 H40 H46 72 Section V Parameter Function Table Section V Parameter Function Table Direction decised by Terminal and 1 keyboard Deceleration and acceleration time decised by Hundred H26 H39 P of acceleration Heceleration is 1 Hed by terminal Running time decised by 0 H18 H25 Running time decised by 1 terminal Thousand A bit Program running functions intelligent To use the program to run PLC functionality requires setting the bit to 1 Multi segment speed run only need to set the corresponding multi stage 036 046 speed switching can be used without the need to set this parameter 0 PLC program runs Cancel 1 PLC program runs intelligent Ten Define program runs or direction settings of multi segment speed running 0 the direction decided by the H40 H46 1 The directiondecided by the keyboard or terminal Hundred Define program runs or acceleration and deceleration time settings of multi segment speed running 0 deceleration time decided by the H26 H39 1 The acceleration and deceleration time determined by terminal Thousand Set running time of defined program running 0 running time decided by the H18 H25 1 Running time decided by terminal Mode One cycle 2 command running The zero speed 0 10 running when pause Fixed speed running 1 when the suspension Stop with the parameters set when
137. m 0 to 300 0 High Speed Slip Switching Frequency C12 C10 max frequency Hz 30 00 Y C22 Torque Deceleration Time 0 0 200 0 S 1 0 Y High speed segment slip compensation switching frequency Torque decelerate time Torque decelerate time from 300 0 to 0 Low Speed Exitation 0 100 30 Y Compensation C23 Under low speed compensate exitation quantity increase torque feature in case of meetingthe requirement try to make it lower could reduce the motor heatingup caused by magnetic path full C24 Current Loop Ti 0 9999 ms 500 Y Define the current loop intergral time When Intergral time is too long response is inactive the alibity to control external jamming becomes weak When intergral time is short response is fast if too short vibration will occur C25 Current Loop P 0 1000 100 Y Define current loop proportion gain When select big gain response fast but too big will occur vibration when select low gain response lag C26 PG Electronic Gear A 1 5000 1 Y C27 PG Electronic Gear B 1 5000 1 Y When encoder and motor is in different shaft can calculate current motor speed according to encoder and gear ratio Electronic gear A for denominator B for molecule C28 PG Pulse 300 9999 2500 N PG pulse quantity used set value is
138. me at5 0 0 3200 0 s 0 0 Y H35 5 Segment Deceleration Time dt5 0 0 3200 0 s 0 0 Y H36 6 Segment Acceleration Time at6 0 0 3200 0 s 0 0 Y H37 6 Segment Deceleration Time dt6 0 0 3200 0 s 0 0 Y H38 7 Segment Acceleration Time at7 0 0 3200 0 s 0 0 Y H39 7 Segment Deceleration Time dt7 0 0 3200 0 s 0 0 Y Set the Acc Dec time of 7 steps respectively They determine the time needed to reach the speed respectively depending on the acceleration time for acceleration or on the deceleration time for deceleration but the time is not the actual time needed Actual acc dec time equals to the set acc dec time multiples atime multiple which is decided by the hundreds and thousands digit of H40 H46 Please refer to H40 H46 Definite acceleration and deceleration time for multi step speed OUlput Ska Sas ee ee frequency ex Tr jt T ET Pt at2 time Definition of multi step speed acceleration deceleration time Remark atl 1 segment acceleration time at2 2 segment acceleration time dt2 2 segment deceleration time dt3 3 segment deceleration time 1 Segment Speed jc Running direction forward 0 Configuration Running direction reverse 1 Word Running time Xseconds 0 2 Segment Speed H40 Configuration i Running time xmunites 1 H41 Word Running time xhours 2 H42 3 Segment Speed Running time days 3 1 H43 Configuration H44 Word Acce
139. meter setting Multi segment digital voltage setting AJJAJ N Digital Pulse Setting The main mode of the frequency running frequency 0 keyboard setting frequency or RS485 change F01 keyboard setting frequency Multi digital voltage terminal effective exchange change FO1keyboard setting value 1 All the external analog setting Given the external analog 0 10V 10V 10V 0 20mA For detail please read the o group parameter 2 AD the external analog setting 3 AD the external analog setting Given the external analog 0 10V 0 20mA For detail please read the o group parameter 4 Keyboard potentiometer setting Keyboard potentiometer setting keyboard potentiometer for a given start and end values of the corresponding values can be positive role and negative effects For detail please read the A group parameter 5 Multi segment digital voltage setting 036 046 IO input terminal function set to 11 12 13 switch H47 H54 Multi digital voltage setting 100 Corresponding to the maximum frequency 6 Digital pulse setting Digital pulse input frequency Corresponding to the setting frequency For detail please read the 052 group parameter Pulse input terminal and DIS terminal reset after using the digital pulse input 043set to 0 Otherwise the function settings will take effect the pulse input on status of 058 can be checked be limited to low speed pulse Through 036 046 IO input teminal set to 14
140. n be used as sewage pumps and fire pumps 7 Constant water supply system parameters 1 loading types with constant water supply function P ny Keyboard display setting Meanings E00 Starting pressure 1 Single Pump constant pressure water supply N need deviation the constant pressure water supply interface board Multi pump constant pressure water supply need E00 Sune Pressure 9 constant pressure water supply interface board while deviation g realize 4 pumps constant pressure water supply 2 PID adjusting in constant water supply system Keyboard A A Parameter Display Setting Meanings F01 Keyboard set 0 Keyboard set the frequency Ohz frequency F02 Frequency main 0 Keyboard set frequency or RS485 set frequency set mode Frequency F03 auxiliary set 7 PID adjusting mode mode main and F04 auxiliary 2 main auxiliary set mode frequencies set POO PID configure 0000 single way the negative regulator failure is not action P02 Feedback signal 1 3 External analog feedback signal given by the select All AI2 AB Given signal Given signal can select the keyboard Rs485 P03 0 6 A SA m select potentiometers digital voltage digital pulse etc PID integration P05 time Setting according the site i i Setting according the site P06 BID differential g 8 time i Setting according the site P07 HE proportional a g 8 gain P09 Deviation Limit Setting according the site i Se
141. nd 3 6 Multi segment command 7 Multi segment speed command 1 8 Multi segment speed command 9 Multi segment speed command 3 0 Multi segment digital voltage 1 1 Multi segment voltage 2 2 Multi segment voltage 3 3 The main set mode 1 of set 4 frequency The main set mode 2 of set 5 frequency oc00000000000o KKK KKK KKK KK 64 Section V Parameter Function Table Section V Parameter Function Table The main set mode 3 of set frequency a The auxiliary setting mode 1 of 17 frequency set The auxiliary setting mode 2 of 18 frequency set The auxiliary setting mode 3 of 19 frequency set MSS time running 1 20 MSS time running 2 21 MSS time running 3 22 Operation control mode shift 1 23 Operation control mode shift 2 24 Operation control mode shift 3 25 Forward torque limit shift 1 26 Forward torque limit shift 2 27 Forward torque limit shift 3 28 Reverse torque limit shift 1 29 Reverse torque limit shift 2 30 Reverse torque limit shift 3 31 Torque speed shift 32 fault reset command 33 FWD JOG command 34 REV JOG command 35 JOG order as F35setting 36 Acceleration and deceleration 37 prohibition command Motor 1 2 shift 38 Free stop 39 Up command 40 Down command 41 Automation program running 42 fuction cancel Automation program running st
142. nd from host inverter the slave will store this command into to F01 4 the slave actual frequency is set through the keyboard or through terminal ascend descend adjusting 5 the slave actual frequency is set through potentiometer adjusting 6 the slave actual frequency F01 slave potentiometer adjusting A40 The proportional linkage host settings F02 Frequency main set mode AII external analog setting A28 Communication address Host 128 A29 Baud rate 3 9600bps A30 Communication format 0 036 DII input terminal function 1 forward running 139 Appendix II Instruction Of The Proportional Linkage Function 037 DD input terminal function 2 reverse running The proportional linkage slave settings F02 Frequency main set keyboard set the frequency or Rs485 0 F03 Bust dia ass All external analog setting 1 F04 relationship between main and mam tAn j auxiliary frequencies F05 Running control mode Proportional linkage control 4 A28 Communication address 17127 A29 Baud rate Same as host inverter A30 Communication format Same as host inverter 036 DII input terminal function 37 forced stopping 037 DR input terminal function 38 Up command 038 DB input terminal function 39 Down command A43 Multi function key MF1 8 MF key is appointed to be Up command A44 Multi function key MF2 9 MFkey is appointed to be Down System wire connections 1
143. nder acceleration running 25 Arrival Of High Pressure Arrival at hight pressure 26 Arrival Of Low Pressure Arrival at low pressure 27 oe ee Arrival at inverter rate current Current Arrival Of Motor Rate 28 Arrival at motor rate current Current 60 Section V Parameter Function Table Arrival Of Input 29 Ficquensy Lower Present set frequency is less than frequency lower erin limitation Limitation Arrival Of Current NON 30 ENNIO Arrive at current of upper limitation Upper Limitation Arrival Of Current RE 31 ES Arrive at current of lower limitation Lower Limitation Section V Parameter Function Table output frequency FDT1 35Hz FDT2 30Hz FDT frequency setting 1 arrived OFF ON OFF ON l i time FDT frequency f level detect OFF ON OFF ON _ l o time FDT frequency i 1 inspection level OFF ON OFF ON _ time ON means signal will react OFF means signal will not react 0o32 Arival Of Current 033 200 120 Y Upper Limitation 0 32 000 S 0 025 Output Signal Delay 1 026 Output Signal Delay 2 0 32 000 E 0 Y 027 Output Signal Delay 3 0 32 000 S 0 028 Output Signal Delay 4 0 32 000 S 0 025 028 defines 021 024 output signal reaction delay time unit is S Output signal cut off action without delay 029 FDT Set Frequency 1 030 Max frequecy Hz 0 00 Y 030 FDT
144. ng 1 i y Protection Warning and deceleration 2 Warning and free stopping 3 Grade Of Phase Los ATOS CU a E 10 100 30 Y Protection When ratio of unbalance 3phase output surpass A19 Grade of phase lose protection the inverter output phase lose protection i will action and the system display fault PH O Output frequency less than 2 00Hz there is N output phase lose protection Phase lost protection grade max current difference between phases which will be according to load In the inverter operation process Over Current expressed by OC Over Voltage by OU inverter can automatically recover and run with state of preceding fault Recovering times will be according to this parameter It can set 10 times at most When this parameter is set 0 inverter will not automatically recover after meeting fault But if relay in DC main circuit meet fault MCC or less votage LU fault inverter will automatically recover without limitation Restarting from fault and normally running over 36s inverter will automatically recover fault reset times preset Restarting from fault and normally running over 36s inverter will automatically recover to display monitor parameter 45 46 Section V Parameter Function Table Section V Parameter Function Table After 10 s of meeting fault inverter will not recover fault reset function A26 Fault Reset Time 0 5 20 0 S 1 0 Y S
145. ning mode setting source can be adjusted by F02 F03 and other parameters running time is controlled by the H18 Terminal multi segment speed is defined as follows shorted with COM it is ON disconnected then it is OFF Speed OX IX 2X 3x 4X 5x 6X 7X Terminal Multiterminal speed OFF ON OFF ON OFF ON OFF ON Command 1 Multiterminal speed OFF OFF ON ON OFF OFF ON ON Command 2 Multiterminal speed OFF OFF OFF OFF ON ON ON ON Command 3 Multiterminal speed OFF OFF OFF OFF OFF OFF OFF OFF Command 4 8X 9X 10X 11X 12X 13X 14X 15X Section V Parameter Function Table Acceleration and deceleration time and the direction of running 0X 7X 8X 15X 0X 7X Direction controlled by parameter 8X 15X Direction H00 controlled by keyboard 10 0X 7X Direction controlled P and terminal by keyboard and terminal 0X 7Xdeceleration and accelertation time 8X 15Xdeceleration H00 controlled by parameter and accelertation time 100 0X 7X deceleration and controlled by keyboard accelertation time and terminal controlled by terminal 0X 7Xrunning time H00 controlled by paremeter 8X 15Xrunning time 1000 0X 7Xrunning time controlled by terminal controlled by terminal Command 4 Multiterminal speed opp on orf ON OFF ON OFF ON Command 1 Multiterminal speed opp opr on ON OFF OF
146. o 1 19 DH DI2Input Termina Ton RSIS oO DI2 D MM aee Communication Interface DI3Input Terminal M ew Er M Hee Inter Di4 input Termina 3 cou RS485 se A 1 2W o 0 DI4 1 2Shorted Drain output Serial Communication A Lec Cariclosed with the card Drain Drive TI Osa when Inverter be the bus Source Driv 11 COM 2 3Shorted Source output terminal JP10 shorted ESPERTI Pda eth Way Non Bus Terminal JP10 Disconnect LJ Dl5Input Termina Mm SS o 0 pis TO EPE DIS Laput Terminap O I rO DIB digital Pulse Input Wiring required to mcer EIA TIA 568A or EIA TIA 568B Standard H I i2av PLO can be RS485 8P8C tot connected Lo Serial Commmication B Interface D sin Dive EISE i PLC 24V or Default keyboard Interface ain Driv COM or use Fg outside power jpi 2 8 shorted Clefaul ODAT babe 24v 18 35V and 3 DAtV 0 10V DC NET Analog Output DA1 CIVI 24V COM np enp 0 10V Maximum load current SMA LILA pie gt a ee shorted 0 20mA Maximum load impedance250 olun re doesn t share 1 DA1C 0 20mA DC l Source Drive EGF A E PEJLA_ E SOTO PES gt We ae the sano Oot AA Se TA artbing le 14 A 1O II F E PE B 2 3 shorted Defaut tPA OT Analog Output DA Vat tis JOA 0 10V DC onp LY 0 10V Maximum load current SmA VR I 10V 1 411 2 shorted 0 20mA Maximum load impedance 20 ohn tot gal t0V 10V Dc DAIC 0 20mADC E PE
147. ommon size of AC input reactance Section IX Options 4 9D FR URP Sharp size Inverter standard Size mm Gross Capacity Weight Voltage kW A B E D E F kg 0 75 155 125 95 7 89 60 3 0 1 5 155 125 95 7 89 60 3 0 2 2 155 125 95 7 89 60 3 0 4 155 125 95 gi 89 60 3 5 5 5 155 125 100 F 89 60 3 5 200V 7 5 155 125 112 7 89 70 4 0 230V 11 155 125 112 7 89 70 6 0 15 180 140 112 8 90 80 8 0 18 5 180 140 112 8 90 90 8 0 22 180 140 112 8 90 90 8 0 30 230 175 122 10 160 90 12 0 37 230 175 132 10 160 100 15 0 123 45 230 175 150 10 160 110 23 0 55 230 175 160 10 160 120 23 0 75 285 220 230 14 180 130 30 0 0 75 155 125 95 7 89 60 3 0 L5 155 125 95 7 89 60 3 0 22 155 125 95 7 89 60 3 0 4 155 125 95 7 89 60 3 5 5 5 155 125 100 7 89 60 3 5 7 5 155 125 112 7 89 70 4 0 11 155 125 112 7 89 70 6 0 15 180 140 112 8 90 80 8 0 18 5 180 140 112 8 90 90 8 0 380V 22 180 140 112 8 90 90 8 0 460V 30 230 175 122 10 160 90 12 0 37 230 175 132 10 160 100 15 0 45 230 175 150 10 160 110 23 0 55 230 175 160 10 160 120 23 0 75 285 220 230 14 180 130 30 0 110 285 250 230 14 210 140 33 0 160 360 260 230 14 210 140 40 0 200 360 270 230 14 210 140 45 0 250 400 330 240 14 240 140 55 0 315 400 350 285 14 270 160 90 0 10 3
148. ontrol the multiple pumps water supply system effectively 2 Operation and connection notice T itis power frequency motor probable thermal relay must be used to protect motor AC contactor with machinery chain equipment should be used between the power frequency bypass and inverter output of aside the motor lock logically on the electri control circuit to avoid the short circuit of the power frequency and inverter output which damage the inverter and equipments O The phase order of the power frequency to the motor should be the same with the phase order of the inverter output to avoid the motor reverse Please confirm the phase order and operate When wiring the control signal of the inverter please leave it away with the driving line and do not make them in the same wire otherwise it will lead wrong action Screen cable is used for Pressure set signal and pressure feedback signal 3 Dimension 3 1 Dimension of water supply control card 148 Appendix V Converter Water Supply Controller Instruction 3 2 Dimension of water supply controller 149 Appendix V Converter Water Supply Controller Instruction 3 D fixed plate C e C C 7 O rower x x x D Ed 0 ido oido cido giai 0 To E e PON E O power fixed plate 0 as A aos ea ls 0 fixed plate 154 93 XL8 55 7 E e al 105 the
149. op 43 Program running start mode 44 Program running stop mode 45 Pulse counter clearance 46 Pulse counter input 47 Counter loading 48 Upper counter loading 49 External fault signal input 50 1 pump soft start 51 1 pump stop 52 2 pump soft start 53 2 pump stop 54 3 pump soft start 55 3 pump stop 56 4 pump soft start 57 4 pump stop 58 hand rotate command 59 Timing water supply change to 60 zero Setning Output Detail Specification Explainati utput Detai ecification Explaination Value E P E 0 N function N function 1 Forward command FWD Can be set to edge triggered Forward command FWD or level triggered 2 Reverse command REV Can be set to edge triggered Reverse command REV or level triggered 3 Three line running STOP 035 setting 3 line running STOP function 4 Multi speed command 1 5 Multi speed command 2 6 Multi speed command 3 Synthesis of 16 multi speed settings See H 7 Multi speed command 4 parameter Group 8 multi acceleration command 1 A a Synthesis of 8 acceleration settings See H parameter 9 multi acceleration command 2 Group 0 multi acceleration command 3 1 multi segment digital voltage 1 2 multi segment digital voltage 2 Synthesis of 8 digital voltage settings See H 3 multi segment digital voltage 3 parameter Group 4 The main set mode 1 of set frequency 5 a Synthesized frequency given to the way the main frequency switch See F parameter gro
150. or nameplate parameters b00 b04 automatic calculation b05 b09 and other electrical parameters the advantage does not require power on self tuning suitable for general purpose Y series of four pole motor the other type motor can be adjusted based on this parameter 2 Inverter static measurement If the motor parameters can not be measured without load you can choose static frequency converter measurement Make sure that motor in a static static after static measurement it can be manually adjusted some parameters optimal control The b11 is set to 2 the inverter automatically start parameter determination Keyboard figures area show RUN waiting to run the command start the measurement Keyboard figures area show CALI inverter without output Keyboard figures area show CAL2 inverter with output static state Keyboard figures area show END measuring ends Keyboard figures area show E CAL the measurement process errors Process can be measured through the STOP key to stop 3 Inverter rotation measurement Motor can be measured without load can choose the rotation measurement Measurements started make sure the motor is static Static measurement converter the output DC voltage pay attention to safety The b11 is set to 3 the inverter automatically start parameter determination Keyboard figures show that the regional show RUN waiting to run the command start the measurement Keyboard figures area show C
151. orque giving gain e g C15 forward torque giving method 4 keyboard pretentimometer giving when keyboard pretentimometer giving A47 100 C17 200 0 C13 forward torque upper 100 x200 0 200 0 Speed control 0 C18 Speed Torque Control Shift 0 Y Torque control 1 F00 control method is to selecte senseless vector control or sensor feedback close loop vector control can change speed or torque control through input terminal After setting IP terminal change keyboard set invalid only for query C19 Forward Speed Limit 0 00 Maxmum frequency 50 00 Y Forward speed limit when torque control C20 Reverse Speed Limit 0 00 Maxmum frequency 50 00 Y Reverse speed limit when torque control C21 Torque Acceleration Time 0 0 200 0 S 1 0 Y 91 i When motor forward phase A leads 0 C30 PG Rotating P 0 Y Direction When motor forward phase A leads 1 phase A phase A phase B phase B phase A is forward phase B is forward Encoder rotating direction refer to the motor forward direction 0 When motor forward phase A leads set C272 0 1 When motor forward phase B leads set C27 1 Note above parameters are valid when with encoder PG need to layout PG card If needed please contact our company 92 Section V Parameter Function Table C31 PG Dropped Inspection Time 0 0 1
152. os POR G aS EH r gy he noH PES 2 Su Ds g2 25 gm 25 24V 3 BE Ez B8 83 89 E ge D 3E 3 2 52 dg BS Sa SE Sa ra YJ10 E a4 zd ze a5 zs AR COM Hum NAN NMM THT HHH COS logro o c0 c6 Lo z382 222 792 382 292 HHS zmo 738939 A4 hd nd he hd n bd ud nd R4 h et hd et d hd nd hed h et et d Q o number 1 frequency supply water number 2 frequency conversion control pump conversion control pump supply water conversion cont supply water 152 number 3 Frequency trol pump number 4 Sofi starting pump sewage Appendix V Converter Water Supply Controller Instruction System diagram ZKI KMI y 1 y 11 R 12 s P1800 INVERTER zu RI L3 T A 1 cm ZK2 vt m A HA i ass v T A Module 24V COM KM3 A NO 1 industrial frequency Le tT oe ao 485 T0 gt nS NO 1 inverter frequency Module t KM4 E KM3 Inverter water supply controller T E H TMN NO 2 industrial frequency Md WSC RS485 ft y et ME y AN NO 2 inverter frequency y E x NO 3 industrial frequency Le KMS y NO 3 inverter frequency oe 7 NO 4 industrial frequency gt JR3 KM6 NO 4 inverter frequency A HA MN gt ITENS KM2 KM4 KM Gey an m mw len e KMI KM2 KM3 KM4 KM5 KM6 b 4 4 n 4 4 Rem
153. oup o IO Function Group Analog digital input output function 61 02 Multi speed PLC H RE Multi speed running PLCrunning 56 03 Group U V F Curve Group User defined V Fcurve 16 04 PID Functi P E Internal PID parameter setting 13 05 Group E Extend Gunction Constant pressure water supply and other 24 06 Froup functions setting Speed ring function 2 C Current ring speed running PGparameter 32 07 group Mot t b SPADA Motor parameter setting 23 08 group System Function Parameter reset fault query product 18 09 y Group information parameter protection 5 2 Monitor function Next group Description LCD Setting Range d Factory Change Code Unit Keyboard Display 7 Step LED Display Setting Limited ti t l setti S00 Setting Frequency y CAE LE Hz N frequency S01 Real Frequency current inverter real output frequency Hz N S02 Motor real Current Valid value of motor actual current A N S03 Percentage of Motor The percentage of actual motor o N Current current and rated current i S04 DC Bus Voltage Detection value of DC bus voltage V N S05 The Output Voltage The real output voltage V N S06 Motor Real Speed Motor real running speed N Control mode choose setting 0 2 0 V Fcontrol It is not sensitive to motor parameters can be used as power supply for motor control using the Under running the real speed of the motor 60xthe real output frequency Gain Speed surveillance pole of the motor Example the re
154. p running the industry frequency working pumps keep running Stop industry frequency working pump need to use the 036 046 input terminals of free stop commands or multi function keys MF1 MF2 of keyboard is set to 2 free parking function 2 Free stop When the inverter fails all the pumps free stop tens bit Pumps status when fault occurs 0 maintaining the status when inverter fault occurs stop the current pump the other pump to maintain the current status 1 all pumps stop When the inverter fails all the pumps free stop Hundred bit Alternation shift mode O Variable frequency to industry frequency when increase the frequency controlled pump to the industry frequency then it will perform rotational switch or soft starter control l Variable frequency to stop after the current variable frequency controlled pump stopped it will perform rotational switch or soft starter control Thousand bit Pump maintain the status 0 keep status after multi pump constant pressure water supply shut down maintain all pumps in the current order of first starter first stop l stop Reset Multi pump constant pressure water supply stoop according to E12 multi pump configuration to re sort the order of first start first stop 147 Appendix V Converter Water Supply Controller Instruction B Converter water supply controller instruction 1 Application It is special appendix for multiple pumps which run with PI7000 family inverter to c
155. parameter reture to displaying menu from submenu or functional menu Reset Stop Key drive stop runni ng Exception Reset fault confirmtion 15 Section II Operating Keyboard 3 2 Example for Parameters set 3 2 1 F01 keyboard set the frequency from 50 00Hz to 25 00Hz Under monitoring status press J into parameter group to query status Through potentiometer S witch to F00 63 Basic FG Press F or ENTER enter into F00 63 Basic FG parameter group to query status Through potentiometerSwitch to FO1Fre Set by K Press 9E or ENTER enter into F01 Fre Set by K parameter modify status Through La or ENTER adjust the value is modified bit Through potentiometerHas been modified to adjust the bit values oo AD tn FW NK S Finish the adjustment press shir cancle the change press ee to escape to the modify status 9 Press ee to exit to previous menu SOCOM FO JO S00 Set Fre One F00 63 Basic FG Or F00 Control Mode 0 00 BW 00 Times l pie000 600 ENTER 0 00 BP 00 1 Actual Fre 1 Actual Fre One 1 Actual Fre 2 Motor AC 2 Motor AC Times 2 Motor AC Potentiometer Functional adj ust ment item FOlFre Set By K 0 00 BP 0 0 1 Actual Fre 2 Motor AC F lFre Set By K FOlFre Set By K 0 00 BB 0 0 ENTER 0 00 BP 0 0 1 Actual Fre One 1 Actual
156. ponding to V4 U07 V F Setting Voltage 4 U05 U09 40 N User defined the fourth voltage percentage of V F curve on the base of rated output voltage 100 of frequency converter corresponding to F4 U08 V F Setting Frequency 5 U06 U10 Hz 25 00 N User defined the fifth frequency value of V F curve corresponding to V5 U09 V F Setting Voltage 5 U07 UII1 50 N User defined the fifth voltage percentage of V F curve on the base of rated output voltage 100 of frequency converter corresponding to F5 U10 V F Setting Frequency 6 U08 U12 Hz 30 00 N User defined the sixth frequency value of V F curve corresponding to V6 Ull V F Setting Voltage 6 U09 U13 60 N 82 Section V Parameter Function Table User defined the sixth voltage percentage of V F curve on the base of rated output voltage 100 of frequency converter corresponding to F6 Section V Parameter Function Table U12 V F Setting Frequency 7 U10 U14 Hz 35 00 N User defined the seventh frequency value of V F curve corresponding to V7 U13 V F Setting Voltage 7 Ul1 U15 70 N PID abnormity treatment 1 Warning amp Continuous running continue ruuning after abnormity feedback signal 2 Warning Decelerating stop decelerate and stop after abnormity feedback signal 3 Warning amp Free stop free stop after abnormity feedback signal User defined the seventh voltage percentage of
157. power down l power frequency power control frequency conversion motor i speed search Invalid 0 A06 Dynamic Braking option Security Type 1 0 Y General Type 2 A07 Hysteresis voltage 0 10 2 Y A08 we Braking 110 140 Standard bus voltage 130 Y 0 Invalid 1 Security Type Only in the inverter deceleration process and detected high voltage DC bus exceeds a output output frequency frequency power down track state start track state 65 100 standard DC A12 Power Down Frequency Drop Point ajo 75 Y bus voltage A13 Power Down Frequency Drop Time 0 1 3200 0 s 5 0 Y Correctly setting this parameter can let inverter does not less voltage stop in case of instantaneous 43 44 Section V Parameter Function Table Section V Parameter Function Table power off When the DC bus voltage drop to frequency drop point A12 set inverter will decelerate according to deceleration time A13 set and stop outputting power to load Meanwhile inverter will use load feedback energy to compensate DC bus voltage dropping and keep inverter working in short time Power down frequency drop time actually is deceleration time of frequency dropping after power off If this value set is too large the load feedback energy is small then inverter can not compensate for voltage dropping in DC if this value set is too small and t
158. r current excitation component torque fluctuation component 24 sensor vector control adjust speed loopC01 C07 Turned around differential gain regulate motor parameters Upper torque setting C13 C14 Set PG pulses C28 PG directions C30 running Observe motor speed S06 parameters optimization Observe the motor current excitation component torque fluctuation component top and tes unning finis a Section V Parameter Function Table Section V Parameter function table Section V Parameter Function Table motor b03 b16 2 the real speed of the motor 1500rpm When stop based Residual voltage test motor speed renew speed 500ms The real speed 60xresidual frequencyxGain Speed surveillance the pole of the motor Max display of motor real speed 9999rpm S07 Total Running Time The total running time for every time hour N When the ouptput the frequency inverter calculated the running time Total running time can be cleared up automatically with A33 selecting reboot or continue accumulation after reboot Total running time of the units can be changed by parameter A34 you can choose hours or days as the unit
159. rameter confirms the OL protection capability of the motor and energy saving running To prevent self cooled motor form overheat when running in a low speed and the motor capacity change when motor character change little the user can correct the parameter to protect the motor The number of motor pole pairs such as the four pole motor the number of pole pairs is set to 2 b05 Motor 1 N Load Current 0 0 b01 A Y b06 Motor Stator Resistance 0 000 30 000 ohm Y b07 Motor 1 Rotor Resistance 0 000 30 000 ohm Y b08 Motor 1 Stator Inductance 0 0 3200 0 mH Y b09 Motor 1 Mutual Inductance 0 0 3200 0 mH Y b05 b09 can by input by motor actual parameters value also can define motor parameterby b11 parameter messure function and save automatically If know the correct motor parameter can input by hand When b11 is 1 2 3 the system calculates and measuresautomatically b05 b09 is the motor s basic electric parameters these parameters is essential to achieve vector control calculation Motor 1 0 b10 Motor Selection 0 N Motor 2 1 The system can select any group motor parameters Motor parameter messurement modify and save to corresponding motor parameter area automatically 93 Set whether the measurement of electrical parameters in order to b10 motors choose motor as an example 0 N measurement 1 Calculate by lable data According to the mot
160. ressure reach and exceed the high pressure reached value of this parameter the I O output terminal select 25 then it will output arrival signal 5 E06 low pressure reached value When feedback pressure less than the low pressure reached value of this parameter the I O output terminal select 26 then it will output arrival signal 6 E07Low pressure arribal value Bit Timing water supply 0 Timing water supply function is invalid 1 Timing water supply function is valid Tens digit pressure giving O the pressure given during regular pressure water supply is set according PID given value selecting P03 1 the pressure given during regular pressure water supply is set according the current corresponding H47 H54 digital voltage given hundred digital timing mode 0 cycle mode Start to time from start running after it reached the setting time the inverter will automatically move to the next period of time set after the end of a loop it will automatically re start from the first paragraph 0 then cycle to run 1 single cycle Start to time from start running after it reached the setting time the inverter will automatically move to the next period of time set after the end of a loop the inverter will stop and wait for the next running command 145 Appendix V Converter Water Supply Controller Instruction Thousand digit the current regular time When the water supply time set 0 it means cancel the water supply time setting
161. rminals 2 5 1 Control Circuit Terminals Description Classify Terminal Description Functions Input DII DII Input Terminal Multi functions input terminal For signal DI2 DI2 InputTerminal details Please read 036 046 9 Analog input signal 10V GND power 10V 50mA GND All Voltage input signal JP5 cut JP3 1 2 10V 10V JP5 cut JP3 2 3 0 10V JP5 connect 0 20mA can be regulated 000 001 Set the input voltage current range 006 007 Set the input signal corresponding to set value AI2 Current input signal JP6cut 0 10V JP6connect 0 20mA can be regulated 002 003can set input voltage current arrange 008 009 Set the input signal corresponding to set value AI3 Current feed back input signal JP7cut 0 10V JP7connect 0 20mA can be regulated 004 005 can set input voltage current arrange olO0 oll Set the input signal corresponding to set value 10 Section II Inspection amp Standby Circuit JP1 1 2 0 20mA DAI More function analog JP12 3 0 10VDC output 1 ol5 Set analog output analog functions JP2 1 2 0 20mA More function analog JP22 3 0 10VDC Dak output 2 ol6 Set analog output analog functions 2 5 2 Control circuit terminal 2 5 1 1 8KLCB Control circuit terminal TA1 TCI TBICOM DI8 DI7 DI6 DIS DI4 DI3 DD DII 10V DAI GND CSCS SES SOS 9 99 9 Q9
162. s valid direct the change of the count 1 the valid time of the output signallOms when reach this count fixed keep the output status valid 10ms 2 the valid time of the output signal 100ms when reach this count fixed keep the output status valid 100ms 3 the valid time of the output signal 500ms when reach this count fixed keep the output status valid 500ms Maximum Pulse Input 052 0 1 50 0 KHz 20 0 Y Frequency 0 048 input terminal reponse time 0 1 049 input terminal reponse time 1 Circle counter operating 0 Bit Single cycle counter running Arrive at upper counter value 0 and reload Ten Arrive at upper counter value and clear savings Power on to reload 0 051 Counter Hundred Power on to clear savings E 0 Y Collocation B power on to keep previous 2 count status Count period 0 Output signal valid time 20ms 1 s Output signal valid time 2 ii 100ms Output signal valid time 3 500ms This parameter define the most pulse input frequency of analog setting frequency Input high signal frequency only through multi function input terminal Di8 as the pulse input terminal input pulse setting frequency according the the most input upper limit input pulse setting frequency most input pulse frequency o52according the most output frequency F12 Pulse input frequency f pulse corresponding setting frequency f set formula f set f pulse o52xF12 P
163. saving energy this parameter determines the minimum value of reducing of output voltage This parameter is set to 100 then energy saving function will take off When energy saving function in effect Actual output voltage value of inverter The inverter rated output voltagexThe percentage of output voltage xoutput voltage percentage of energy saving operation output voltatge V Unit adjustment of actual running time Itis only valid on program running bit Program running on multi speed running period Set bit to running direction of 0 step speed Running driection Setting value Forward 0 Reverse 1 When running control mode F05 0 1 2 control direction of 0 step speed When running control mode F05 3 Setting the value and terminal FWD REV run jointly decide the direction of 0 step speed FWD priority FWD 1Irunning REV 1running A du E ees Setting value direction direction FWD REV 0 REW FWD 1 10 unit of time running on 0 step speed Running time X10 bit Range e g H18 H25 3200 0 xS 0 3200 08 xMin 1 3200 0Min xH 2 3200 0H 41 100 75 frequency Hz 5 4 User Function Group Upper group Next group Spec LCD Setting Range Default Change Code Keyboard Unit i 7 Steps LED Display Setting Limits Display A00 Monitor 1 Parameter group N P
164. signal output terminal will react as below Current Inspection 034 0 033 3 Y Range 61 When the choice of output signal 021 024 is set as 30 and inverter output frequency arrived or surpasseed of o32 034 the corresponding output signal terminal will react When the inverter output frequency is less than 032 034 The corresponding output signal terminal will not react When the choice of output signal 021 024 is set as 31 and inverter output frequency arrived or less than 033 034 the corresponding output signal terminal will react When the inverter output frequency is more than 033 034 The corresponding output signal terminal will not react 034 is used to define current inspection range When the difference of actual current and inspected current has surpassed inspection range The output terminal will react current percentage 0322120 120 033220 03423 20 current upper limitation current lower limitation time ON means signal will react OFF means signal will not react Terminal Two wire running control 1 0 035 E bit 0x013 N Control Mode Two wire running control 2 1 62 Section V Parameter Function Table X10 bit power on running Three wire running control 1 2 Three wire running control 2 3 Terminal command is invalid 0 after power on running Terminal command is
165. size of fixed plate Note The fixed plate can be fixed by any mounting hole in the figure 4 Connection of water supply controller with inverter 4 1 Istall RS485 on the control card the installation of the RS485 is showed below 7K RS485_S with 8KLCB 150 Appendix V Converter Water Supply Controller Instruction 7K RS485 With 8KSCB 4 2 Connection of water supply controller with inverter the communniction cable and power cable are connected as below 151 Appendix V Converter Water Supply Controller Instruction DC Reactor Brake Unit NY Optional MCCB DC 1 DC 2 B1 B2 Motor R o R L1 u t M s o S L2 V T2 i PI8000 T o T L3 inverier W T3 Earthing I Main Circuit E Power Control Circuit Earthing Runing Forwad Stop lt o Motor Free Stop 5 o_ 0 na Hang Chango water umi 0 DB return to zer o Di4 COM ADAV Er 10V VR e iE ne AlZ 1K O EE ete Sa m ND T Sewage Start PA o 9 DIS aS Pressure Sewage Stop SX bie E PE f Setting Fire Pump Start 9 o DI7 JP Fire Pump Stop So Die J os Prossuro F i E PE 485 E PE 4 20mA Pr Module Transmitter SG SG WSC7315 SG SG T 3 Sg T B 8 E E z 2 f E E Ej E E E gt S c J13 gt El S E 2 i fa 5 me B S E a a Z E a Es m ales QR Ns na Ny S
166. t automatic adjustment Fixed mode 0 Mode Ten Nc automatic adjustment random mode 1 F17 Carrier frequency adjustment range 0 0 4 0kHz Actual Carrier frequency adjustment range 1 0 16 0kHz F18 Carrier frequency adjustment Mode Bit Carrier frequency automatic adjustment mode 0 N automatic adjustment Carrier frequency according F16 to set o 1 automatic adjustment Mode The carrier frequency automatically adjusts the model 10 can select random mode and fixed pattern Ten Stochastic adjustment mode 0 automatic adjustment Fixed mode Load current gt 80 Carrier frequency F16 F17 Load current lt 60 Carrier frequency F16 F17 1 automatic adjustment random mode Load current gt 80 Carrier frequency F16 F17 F16 Load current lt 60 Carrier frequency F16 F16 F17 setting frequency 1 setting frequency 2 running time S curve acceleration deceleration 1 indicat that the slope of the output frequency from 0 to the max 2 indicat that the slope of the output frequency at constant segment 3 indicat that the slope of the output frequency is reduced to 0 from the max Such as setting the S curve acceleration and deceleration acceleration and deceleration time from 0Hz to the maximum frequency is calculated as follows Plus acceleration S characteristic time F09 x F20 Constant extra acceleration S characteristic time F09 F09 x F20 F09 x F21 Minus acceleration S characteristic time F09 x F21 Full
167. t mode frequencies given F05 Running control 3 Terminal control mode P00 PID configure 0000 single way the negative regulator failure is not action P02 Te signal 3 External analog feedback signal given by the AB selec Give signal P03 2 External analog given by AD select P05 FP c 0 250 Setting according the site time P06 Fn diferential 0 Setting according the site time P07 dd proportional 100 0 Setting according the site P09 Deviation Limit 5 0 Setting according the site P12 PID Display 16 adjust according actual requirement display the Range actual pressure value is160 0 it means1 6Mpa Constant pressure water supp ly specific parameters Paramete r Value Read On Keyboard Setting Value Meanings Keyboard A Parameter Display Setting Meanings E01 Starting pressure 10 Starting pressure deviation is 10 deviation E02 Starting time 2 0 Starting delay time is second delay 157 158 Appendix V Converter Water Supply Controller Instruction Appendix V Converter Water Supply Controller Instruction select 1 022 O2 input signal DRE 26 Low pressure arrival select 2 023 O3 input signal elect 3 1 Fault input alarm 036 DIL input terminal function 1 FWD selection E03 Shutdown 15 00 shutdown at frequency 15HZ frequency E04 Shutdown nme 2 0 shutdown time is 2 second delay hen feedback pressur
168. te Register Address low byte 1 1 Parameter group Parameter serial number Y x e F 0x00 0 63 0x06 write to slave a single register power down does not save s A A 0x01 0 63 0x26 write to slave a single register power down save o 0x02 0 71 Host Command H 0x03 0755 Frame start address Slave adress Function code Register address Register data CRC checksum frame end adress U 0x04 0 15 xl a Interval gt 2ms idle bit 1 bytes 1 bytes 2 bytes 2 bytes 2 bytes Interval gt 2ms idle bit P 0x05 0 15 Slave response 0x03 0x13 E 0x06 0 23 Frame start address Slave adress Function code Register address Register data CRC checksum frame end adress read Slave C 0x07 0 47 function code Interval gt 2ms idle bit 1 bytes 1 bytes 1 bytes 2 bytes 2 bytes Interval 2ms idle bit parameter b 0x08 0 23 y 0x09 0 23 L Ox0A 0 31 0x16 Write multiple registers to the slave power down does not save S Ox0B 015 NOTE 2 0x36 Write multiple registers to the slave power down save 0x00 Running status Host Command k iis 0x01 Reserved status 1 Frame Register Register Register Register 0x02 Reserved status 2 Slave Function Register CRC frame end start N data 1 add n datan 0x03 Reserved status 3 adress code add 1 checksum adress High byte address 0x06 0x16 set Parameter group A A Low byte data A ata Interval 1 bytes a Interval gt slave function F 0x00 0 63 1 i m 2ms idle 1 bytes 2 bytes 2 bytes 2bytes 2 bytes
169. the pulse quantity when motor rotates for a circle N PG break protection 0 255 Action When PG Warning and keeping running 1 i i Break Warning and deceleration stop 2 Warning and free stop 2 Set the brake method when detect PG break 0 N PG break protection 1 Warning and keeping running 2 Warning and deceleration stop 3 Warning and free stop C13 Upper Froward Torque 0 0 300 0 200 0 Y This parameter is a ratio that is the user can set the maximum forwarding torque C14 Upper Reverse Torque 0 0 300 0 200 0 Y This parameter is a ratio that is the user can set the maximum reversing torque Sey by keyboard or RS485 0 Allexternal alalogy giving 1 AD external alalogy giving 2 F dT Set C15 iro read E AD external alalogy giving 3 0 Y ode Keyboard potentiometer giving 4 muti step digital voltage giving 5 Digital pulse set 6 Keyboard set or RS485 0 All external alalogy giving 1 AD external alalogy giving 2 Reverse Torque Set m C16 Mode AD external alalogy giving 3 0 Y Keyboard potentiometer giving 4 muti step digital voltage giving 5 Digital pulse set 6 C17 Torque Set Gain 0 0 300 0 200 0 Y Froward torque set mode and reverse torque set mode can select keyboard RS485 potentiometer digital voltage digital pulse for giving signal 0 keyboard set set by C13 C14 1 6 C13 forward torque upper set value percentagexC17 torque giving gain C14 reverse torque upper set value percentagexC17 t
170. tion V Parameter Function Table Section V Parameter Function Table set frequency ry set frequency lowerlimt 7 X 22L Minimum 44 222 frequency frequency Minimum L lower limit E H frequency i frequency i 2 i E Time du WE i actual fr quency lower limit i Minimum i des NZ MS fre frequency i H E quency l Minimum i DET lower limit dl E i TN i Ludo frequency frequency M AA A op e Time Time Minimum frequency lower frequency Minimum frequency gt lower frequency DC Braking F26 Current When 0 135 100 Y Starting Braking Time F27 M 0 0 60 0 s 00 Y When Starting When frequency Inverter starting the first injection of DC current the current size is determined by starting to set when the DC braking current and braking time braking time from the start to set Value is based on inverter rated current as the benchmark that is inverter rated current corresponds to 100 During setting process be sure to gradually increase until adequate braking torque and can not exceed the motor rated current output frequency start up braking time RUN STOP ON start up braking pag Stop When The De 0 135 100 Braking Current F29 Stop And Braking Wait 0 0 60 0 A 00 Time F30 Brake Time Stop 0 0 60 0 s 0 0 Y Stop And Brake Starti F31 Spore SS COSE 0 00 most frequency Hz 0 00 Y Frequency
171. tting according the site P12 PID Display g 8 Range 3 Constant pressure water supply special parameters Parameter Keyboard Setting Meanings 154 Appendix V Converter Water Supply Controller Instruction Appendix V Converter Water Supply Controller Instruction select Output signal 021 024 Pee ens 26 Low pressure arrival select 036 046 Inp NAM 5 Pump 1 soft start function select 036 046 inp t terriinal 52 Pump 1 stop function select 036 046 b ii terminal 53 Pump 2 soft starter function select 036 046 inp Mena 54 Pump 2 stop function select 036 046 inp t terminal 55 Pump 3 soft starter function select 036 046 Tapa termin l 56 Pump 3 stop function select 036 046 inp Mte 57 Pump 4 soft state function select 036 046 a uet 58 Pump 4 stop function select 036 046 Input terminal 59 Manual shift command function select 036 046 LATUM 60 Timing of water supply time zero function select Display E01 Starting Pres 10 Starting pressure deviation is 10 deviation E02 Starting ume 2 0 Starting delay time is second delay E03 Stop frequency 15 00 stop at frequency 15HZ E04 stop time delay 2 0 Stop time is 2 second Hich este feedback pressure reach and exceed the value of this E05 8 Press 80 parameter the I O output terminal select 25 then it arrival value s gt will output arrival signal
172. tus keyboard memory areal Vector Control Ctarting Not inspection R1 0 Reset system parameter with 2 b12 0 N Inspection R1 Inspection R1 1 Parameter Upload To keyboard memory area2 y0l Keyboard Reset system parameter with 0 N b13 Motor 2 Rated Frequency 0 00 Maxmum frequency Hz 50 00 Y y keyboard memory area3 3 b14 Motor 2 Rated Current y09 50 100 A Y Reset system parameter with 4 b15 Motor 2 Rated Voltage 100 1140 V Y keyboard memory area4 7 Clear up keyboard memory area b16 Motor 2 Pole Pairs 1 8 2 Y 5 1 2 3 4 b17 Motor 2 Rated Speed 500 5000 P 1480 Y 0 N action m 1 Reset system parameter with keyboard memory areal b18 Motor 2 N Load Current 0 0 b14 A X 2 Reset system parameter with keyboard memory area2 b19 Motor 2 Stator Resistance 0 000 30 000 oh Y 3 Reset system parameter with keyboard memory area3 m J 4 Reset system parameter with keyboard memory area4 Motor 2 Rotator oh b20 0 000 30 000 Y 5 Clear up keyboard memory area 1 2 3 4 Resistance m ui y02 Lastest Fault record Lastest fault record number 0 Y b21 Motor 2 Stator Inductance 0 0 3200 0 H Y y03 Fault Record 1 b22 Motor 2 Mutual ere m d i y04 Fault Record 2 Mz FIPRGUfILA V Ji Inductance i i H Press PRG and A V key the y05 Fault Record 3 K Y The 2nd group motor parameters can be set by system The difination is same with group 1 frequency crrent and running status of y06 Fault Record 4 fault time can be known
173. ulse input analog setting input most pulse frequency 052 according 100 096 Pulse input frequency f pulse corresponding analog p set formula p_set f_pulse o52x100 0 053 Current Counter Status 0 9999 0 054 Preset Counter Setting 0 055 0 Y Upper Limit Counter Setting 055 054 9999 9999 Y Bit Control count mode 0 Circulate count Arrive at upper counter value ouput the arrival pulse output terminal setting 1 single circulate count after arrive at upper counter value output the arrival pulse stop running Ten Operating after circulate mode reach upper limit count 0 Reload When the pulse signal of the input terminal satisfy with the preset condition Yi terminal output the corresponding indication 1 DiX X 1 8 terminal is set to pulse count input and set 054 055 DiX X 1 8 terminal is set to pulse counter clearance terminal moves the counter is cleared DiX X 1 8 terminal is set to preset count loaded terminal moves the counter load preset counts DiX X 1 8 terminal is set to the maximum counts loading terminal moves the counter load the maximum counts Dix cuina 9 1 2 3 4 5 6 3 4 5 6 3 021 054 i 054 gt Te gt Te 022 i i 055 055 the thousand of O51 sett 2 TE TE 69 70 Section V Parameter Function Table 2
174. ump Lud pump Soft start Pump Multi pump control mode set the control mode of E14 0000 Control each pump currently set to Full Stop 5 constant pressure water supply IO parameter Keyboard P Parameter Display Setting Meanings 021 024 Output signal 25 High pressure arrival 155 8 Application Guide 3 Pumps constant pressure water supply sewage pump 1 pump configurations variable frequency pump 3 units 15kW 1 unit sewage pump 15kW 2 The set pressure 0 8Mpa 3 pressure gauge options pressure transmitter DC 4 20mA output 1 6Mpa 4 Inverter choice PI8000 015F3 and WSC_RS485 water supply board 5 Hardware Connection 156 1 Appendix V Converter Water Supply Controller Instruction L Reactor Brake Unit S dila Optional MCCB o d CC BCH DC 2 B1 B Motor R o 0 0 _O RIL u t M s o S L2 V T2 p QM i PI8000 s ES Inverter 2 Earthing e Main Circuit Power f Control Circuit Earthing Runing Forwad M Motor Stop oo oH Free Stop d o TQ DI2 JP4 tang Change ll t a ICOM return to 45 Q 3 o D14 1 2 Drain vuiput COM 2astorrse source outeur 10V 24V sips VR ZO E PE o Al2 1K US GND e Sewage Start Xo DIS UD Pressure Sewage Stop E PE E Setting o DIe ine Fire Pump Start oo DI7 Fire Pump Stop So Di8 a
175. unication interface of slave inverter for the proportion of linkage Seeing appendix 2 for detailed specification When communication time between interface A or B surpassed A32 delayt inspection time the system will warn according to A31 setting After power on nterface without communication will not implement warning Auto clear to zero after power 0 Total Running Time on A33 1 Y Setting Continue to accumulate 1 running time after power on The set for whether accumulating time of inverer running 0 Auto clear to zero after power on 1 Continue to accumulate running time after power on Unit Of Total hour 0 A34 0 Y Running Time Day 1 The set for unit of accumulation running time only for display of running time 0 unit hour display range 0 3200 0 hour unit day display range 0 3200 0 day A35 Motor Output Speed Adjustment 0 1 1000 0 100 0 Y Using for displaying adjustment of motor actual running speed Seeing A00 A02 monitor options 6 motor actual running speed Setting 100 corresponding display unit rpm The max speed of displaying after adjustment is 9999 A36 Adjustment Of Motor Output Power 0 1 1000 0 100 0 Y Used for displaying motor ouput power of adjustment Seeing A00 A02 monitor options 11 motor output power Setting 100 corresponding display unit The max ouput power o
176. up 6 The main set mode 3 of set frequency 7 The auxiliary setting mode 1 of frequency set 1 The auxiliary setting mode 2 of Synthesized frequency secondary to the way a given 8 frequency set switch See F parameter set 9 The auxiliary setting mode 3 of 65 66 Section V Parameter Function Table Section V Parameter Function Table priority Need to set E01 load model 9 E12 1pump is soft start control pump 53 2 pump soft start Electric leverl spring control 2 pump soft start or stop soft start control must use 2 terminal control stop 54 2 pump stop priority Need to set E01 load model 9 E12 2pump is soft start control pump 55 3pump soft start Electric leverl spring control 3 pump soft start or Stop soft start control must use 2 terminal control stop 56 3 pump stop priority o Need to set E01 load model 9 E12 3pump is soft start control pump 57 4 pump start Electric leverl spring control 4 pump soft start or stop Soft start control must use two terminal control stop 58 4 pump stop has the priority Need setting E01 load style 9 E12 4 pump is soft start control pump 59 Hand change order electric level spring automation multi pump constant water changed 60 the period of time water supply electric level spring the period of time water supply change to zero change to zero 047 Input T
177. ws 3 1 we provide a 3 level inspection service on the local selling place including troubleshooting 3 2 all services comply with the related after sale service terms and conditions stated on the agency agreement between powtran and distributors 3 3 buyers can pay to any Powtran agent if need any after sales services whether or not the warranty 4 if this product has some quality problem or product liability accidents we will take the responsibility to terms 1 1 or 1 2 at most if users need more liability guarantee please apply for insurance company in advance to insure your own property insurance 5 the product s warranty period is one year from the date of shipment 6 in the case of the following causes of failure even in the warranty period is also a paid repair 6 1 incorrect operation depending on the use of manual or modified without permission to repair the problems caused 6 2 the problems caused by using the inverters beyond its standard specifications requirement 6 3 damage caused by drop down or improper handling 6 4 inverters components aged or failure caused by improper environment 6 5 due to an earthquake fire wind and water disasters lightning abnormal voltage or other natural disasters and disasters accompanied by the damage caused 6 6 the damage during transport Note The mode of transport designated by the customer the company s help on behalf of the procedures for handling the transfer of
178. y Y2 50 00Hz Y2 100 Y1 0 AILAD AI3 X1 20 Y1 0 frequency Y 1 0 00Hz X2 50 Y2 50 frequency Y2 25 00Hz Y1 0 AILAI2 AB X1 0 Y1 20 frequency Y 1 10 00Hz X2 50 Y2 50 potentiometer 2V potentiometer 5V Y2 50 L 222222 Let potentiometer OV potentiometer 5V yA m X2 100 x X1 0 corresponding set frequency f Max corresponding set frequency f Max X11 xi 20 80 100 x 10V X2 50 corresponding set value f Max corresponding set value f Max frequency xY2 25 00Hz DM 41 4 80 10V Y2 50 Y1 20 AIL AD AI3 X1 0 Y1 10096 frequency Y1 50 00Hz X2 100 Y2 10096 frequencyxY2 50 00Hz potentiometer 0V potentiometer 5V X1 0 X2 50 100 corresponding set X frequency f Max corresponding set frequency f Max yd 100 X2 Y2 Y2 100 E za Oj AIL AI2 AI3 Hec DUO 50 100 x 5V 10V X1 0 Y1 100 X1 Y1 Skipping thread of AI1 AI2 AB3 respectively are JP3 JP5 JP6 JP7 seeing the following detailed specification JP3 O Pu 10V 10V DC f 3 2 0 10V DC Default JP5 JP6 JP7 O Disconnect O 10V DC 1 Disconnect 0 10V DC 1 O Shorted 0 20mA DC Default Shorted 0 20mA DC Default Disconnect 0 10V DC Shorted 0 20mA DC Default o12 All Input Filter Time 0 00 2 00 s 0 10 Y 013 AD Input F
179. y is switched off do not touch the PCB or other parts inside the inverter within 5 minutes after the keyboard indicator lamp goes off and you must check by using the instrument that the inverter has completely discharged all its capacity before you start to work inside the inverter Otherwise there will be the danger of electric shock The static electricity in human body will cause serious damage to the MOS field effect transistor in the inverter Please keep your hands away from the PCB IGBT and other internal parts before taking actions to prevent static electricity Otherwise faults may be caused In use the earthing terminal E or of the frequency inverter must be grounded to the earthing connections correctly and securely according to the national electrical safety specifications and other applicable standards Section I Inspection and safety precautions X Please don t shut off the unit by turning off the power supply Turn off the power supply after the motor has stopped its operation X Meet CE standard with EMI filter 1 3 Application X Powtran inverter is generally applied to 3 phase AC asynchronism motors X Powtran inverter is applied to the admisive occasion the occasion where is not admissive may lead to fire electric shock explosion and so on X If the inverter seizes up when it is applied to the equipment which may lead danger e g lift tools of transportation aviation system saftety equipment etc
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