Page 1 Foreword Thank you for choosing POWTRAN PI9000 Series Frequency Inverter. This product made by POWTRAN is based on years of experience in professional production and sale, and designed for variety of industrial machinery, fan and water pump drive unit and IF heavy-duty grinding unit.
Page 2: Table Of Contents
Table of contents Foreword ....................... 1 Table of contents ....................2 Chapter 1.Inspection and safety precautions ............1 1-1. Inspection after unpacking ................1 1-1-1. Instructions on nameplate ................1 1-1-2. Model designation ..................1 1-2. Safety precautions ................... 2 1-3.
Page 3 5-1-2. F0 Group - Basic function group ..............38 5-1-3. F1 Gruop - Input terminals group ..............41 5-1-4. F2 Group - Output terminals group ............. 45 5-1-5. F3 Group - Start and stop control group ............47 5-1-6. F4 Group - V/F control parameters .............. 49 5-1-7.
Page 4 5-2-14. Extended parameter:FC.00-FC.02 ............153 5-2-15. Wobbulate, fixed-length and counting:E0.00-E0.11 ......... 154 5-2-16. Multi-stage command, simple PLC: E1.00-E1.51 ........156 5-2-17. PID function: E2.00-E2.27..............160 5-2-18. Virtual DI、Virtual DO:E3.00-E3.21 ............165 5-2-19. Motor parameters: b0.00-b0.35 ............... 170 5-2-20. Function code management:y0.00-y0.04 ..........174 5-2-21.
Page 5 8-6. Wiring Precautions: ..................198 8-7. Spare Circuit ....................199 Chapter 9 Maintenance and Repair ..............200 9-1. Inspection and Maintenance ................. 200 9-2. Parts for regular replacement................ 201 9-3. Storage ......................201 9-4. Capacitor..................... 201 9-4-1. Capacitor rebuilt ..................201 9-5.
Page 6 I-1 Communication protocol ................223 I-2 Check mode: ....................227 I-3 Definition of communication parameter address ..........229 Appendix II How to use universal encoder expansion card........235 II-1 Overview..................... 235 II-2 Description of mechanical installation and control terminals function .... 235 Appendix Ⅲ...
Page 7: Foreword
Chapter 1.Inspection and Safety Precautions Chapter 1.Inspection and safety precautions POWTRAN frequency inverters have been tested and inspected before leaving factory. After purchasing, please check if its package is damaged due to careless transportation, and if the specifications and model of the product are consistent with your order requirements.
Page 8: Table Of Contents
Chapter 1.Inspection and Safety Precautions 1-2.Safety precautions Safety precautions in this manual are divided into the following two categories: Danger: the dangers caused by failure to perform required operation, may result in serious injury or even death; Caution:the dangers caused by failure to perform required operation, may result in moderate injury or minor injury, and equipment damage;...
Page 9 Chapter 1.Inspection and Safety Precautions used wire shall refer to the recommendations of this manual. Otherwise it may cause an accident! ● Never directly connect braking resistor to the DC bus P(+) and P(-) terminals. Otherwise it may cause a fire! ●...
Page 10 Chapter 1.Inspection and Safety Precautions ● Do not start/stop the driver by switching on/off contactor. Otherwise cause damage to this unit! ● Do not perform repairs and maintenance for the live electrical equipment. Otherwise there is a risk of electric shock! ●...
Page 11: Precautions
Chapter 1.Inspection and Safety Precautions power factor If contactor is installed between power supply and inverter, the contactor is not allowed to start/stop the inverter. Necessarily Contactor or need to use the contactor to control the inverter start/stop, the switch used in interval should not be less than one hour.
Page 12: Scope Of Applications
Chapter 1.Inspection and Safety Precautions inverter alarm, even bombing. Therefore, firstly perform insulation short-circuit test for the initial installation of the motor and cable, routine maintenance often also need to perform such test. Note that the parts to be tested and the inverter shall be disconnected completely when testing.
Page 13: Chapter 2 Standard Specifications
Chapter 2 Standard Specifications Chapter 2 Standard specifications 2-1.Technical specifications Rated Rated Inverter Input output Rated input output Adaptive Base No. model voltage power(k current(A) current( motor PI9100-0R4G1 PI9100-0R7G1 0.75 0.75 1-phase 220V PI9100-1R5G1 ± 10% PI9100-2R2G1 PI9100-004G1 PI9200-5R5G1 PI9100-0R4G2 PI9100-0R7G2 0.75 0.75...
Page 14 Chapter 2 Standard Specifications Rated Rated Inverter Input output Rated input output Adaptive Base No. model voltage power(k current(A) current( motor PI9100-5R5G3 14.6 PI9100-7R5G3/ 7.5/11 20.5/26 17/25 7.5/11 9S4/9S4 PI9100-011F3 PI9200-011G3/ 9L1/9L1/9 PI9200-011F3/ 11/11/15 26/26/35 25/25/32 11/11/15 PI9200-015F3 PI9200-015G3/ 15/18.5 35/38.5 32/37 15/18.5...
Page 15 Chapter 2 Standard Specification Rated Rated Inverter Input output Rated input output Adaptive Base No. model voltage power(k current(A) current( motor PI9400-160G3/ 160/187 307/345 304/340 160/187 9P6/9P6 PI9400-187F3 PI9300-187G3/ 187/200 345/385 340/380 187/200 9C1/9C1 PI9300-200F3 PI9300-187G3/ 187/200 345/385 340/380 187/200 9C2/9C2 PI9300-200F3 PI9300-200G3/...
Page 16 Chapter 2 Standard Specifications Rated Rated Inverter Input output Rated input output Adaptive Base No. model voltage power(k current(A) current( motor PI9200-022F4 PI9200-022G4/ 22/30 41.7/57.4 40/55 22/30 9L2/9L2 PI9200-030F4 PI9200-030G4/ 30/37 57.4/66.5 55/65 30/37 9L3/9L3 PI9200-037F4 PI9200-037G4/ 37/45 66.5/81.7 65/80 37/45 9L3/9L3 PI9200-045F4...
Page 17 Chapter 2 Standard Specification Rated Rated Inverter Input output Rated input output Adaptive Base No. model voltage power(k current(A) current( motor PI9400-187G4/ 187/200 309.4/334.4 300/328 187/200 9P7/9P7 PI9400-200F4 PI9400-200G4/ 200/220 334.4/363.9 328/358 200/220 9P7/9P7 PI9400-220F4 PI9300-220G4/ 220/250 363.9/407.9 358/400 220/250 9C1/9C1 PI9300-250F4 PI9300-220G4/...
Page 18 Chapter 2 Standard Specifications Rated Rated Inverter Input output Rated input output Adaptive Base No. model voltage power(k current(A) current( motor PI9300-200F6 PI9300-187G6/ 187/200 210/235 198/215 187/200 9C1/9C1 PI9300-200F6 PI9400-187G6/ 187/200 210/235 198/215 187/200 9P7/9P7 PI9400-200F6 PI9300-200G6/ 200/220 235/247 215/245 200/220 9C2/9C2 PI9300-220F6...
Page 19 Chapter 2 Standard Specification PI9100/PI9200/PI9300/PI9400.
Page 20: Standard Specifications
Chapter 2 Standard Specifications 2-2.Standard specifications Items Specifications Single-phase 220V, 50/60Hz Three-phase 220V, 50/60Hz Voltage and frequency Three-phase 380V, 50/60Hz Three-phase 480V, levels 50/60Hz Three-phase 690V, 50/60Hz Allowable fluctuation Voltage:± 10% Frequency:± 5% High performance vector control inverter based on Control system V/F control, vector control W/O PG, vector control Control method...
Page 21 Chapter 2 Standard Specification Items Specifications 100.0% Jog Frequency Range: 0.00Hz to max. frequency; Jogging control Jog Ac/deceleration time: 0.0s to 6500.0s Achieve up to 16-speed operation through the control Multi-speed operation terminal Easy to realize closed-loop control system for the Built-in PID process control.
Page 22 Chapter 2 Standard Specifications Items Specifications Contact capacity :normally closed contact 5A/AC 250V ， normally open contact 3A/AC 250V ， Fault output 1A/DC 30V. Two-way analog output, 16 signals can be selected Analog such as frequency, current, voltage and other, output output signal range (0 to 10V / 0 to 20mA).
Page 23 Chapter 2 Standard Specification Items Specifications Speed start tracking The inverter automatically tracks motor speed after it method starts Parameter protection Protect inverter parameters by setting administrator function Password and decoding Monitoring objects including: running frequency, set frequency, bus voltage, output voltage, output current, output power, output torque, input terminal Running LED/OL...
Page 24: Dimensions
Chapter 2 Standard Specifications Items Specifications Cooling method Forced air cooling and natural air cooling 2-3.Dimensions 2-3-1.Appearance and installation holes size 上盖板 Top cover plate 操作面板 Operation panel Movable cover plate 活动盖板 Sealing guard 防护密封片控制电缆入口 Control cable inlet mounting position 安装位(可选) (optional) 整机固定孔...
Page 25 Chapter 2 Standard Specification Power Dimensions Installation size Power supply Type (kW) level phase 0.4 to 1.5 220V 174 108 Ø5.3 phase 0.4 to 1.5 220V phase 0.75 to 2.2 380V Power Dimensions Installation size Power supply Type (kW) level 209 138 Ø5.3 phase 220V...
Page 26 Chapter 2 Standard Specifications phase 220V phase 4.0 to 5.5 380V Power Dimensions Installation size Power supply Type (kW) level phase 220V phase 285 180 272 167 Ø5.5 220V 7.5 to 11 phase 380V...
Page 27: Pi9200 Series
Chapter 2 Standard Specification 2-3-3.PI9200 series 9L1 to 9L6 WARNING Read instruction manual carefully before installation and operation High voltage inslde. Maintenance shorld be performed by well-trained personel Make sure to connect the ground terminal before connecting orther terminals Perform maintenance or inspection after the charge LED turns off(fully discharged) Power Dimensions...
Page 28 Chapter 2 Standard Specifications Power Dimensions Installation size Power supply Type Base No. (kW) level 37 to 45 phase 262 460 200 Ø10 30 to 37 380V Power Dimensions Installation size Power supply Type Base No. (kW) level 55 to 93 phase 640 250 Ø10 45 to 75...
Page 29: Pi9300 Series
Chapter 2 Standard Specification 2-3-4.PI9300 series 9C1 to 9C3 1） 9C1 Power Dimensions Installation size Power supply Type Base No. (kW) level 200 to 250 phase 1300 600 395 550 280 Ø13 187 to 220 380V 2） 9C2 Power Dimensions Installation size Power supply...
Page 30: Pi9400 Series
Chapter 2 Standard Specifications 200 to 250 phase 1540 515 438 464.5 367 Ø13 187 to 220 380V 3） 9C3 Power Dimensions Installation size Power supply Type Base No. (kW) level 280 to 400 phase 1700 850 640 260 Ø13 250 to 355 380V 2-3-5.PI9400 series...
Page 31: Keyboard Size Diagram
Chapter 2 Standard Specification level 93 to 110 phase 660 250 Ø10 75 to 93 380V Power Dimensions Installation size Power supply Type Base No. (kW) level 132 to 187 phase 335 730 350 Ø10 110 to 160 380V Power Dimensions Installation size Power...
Page 32 Chapter 2 Standard Specifications JPR6E9100 size diagram: JP6D9200 keyboard case size diagram: Install keyboard case on the panel, opening square hole is required：（76±0.1）*（123±0.1）...
Page 33: Chapter 3 Keyboard
Chapter 3 Keyboard Chapter 3 Keyboard 3-1.Keyboard description JP6E9100 keyboard control panel JPR6E9100 keyboard control panel NOTE: The “R” in the “JPR6E9100” means keyboard with MCU. Figure 3-1 Operation panel display 3-2.Keyboard Indicators Indicator flag Name Running indicator light * ON: the inverter is working * OFF: the inverter stops Command indicator light That is the indicator for keyboard operation, terminal...
Page 34: Description Of Operation Panel Keys
Chapter 3 Keyboard frequency unit current unit HzAV voltage unit speed unit percentage 3-3.Description of operation panel keys Sign Name Function * Enter into the modified status of main menu Parameter * Esc from functional parameter modification Setting/Esc Key * Esc submenu or functional menu to status menu *Choose displayed parameter circularly under Shift Key running or stop interface;...
Page 35 Chapter 3 Keyboard setting(level 3). The operation is as following: Power-on Shutdown parameter display Change parameter group First-level menu display ENTER Change function parameter selection Second-level menu display Change function parameter ENTER ENTER value Third-level menu display Figure 3-2 Display status and operation processes Description: Back to the level 2 menu from level 3 menu by PRG key or ENTER key in the level 3 operation status.
Page 36: The Way To Read Parameters In Various Status
3-4-4.Motor parameter auto tunning Choose vector control, one must input the motor‟s parameters in the nameplate accurately before running the inverter. PI9000 series frequency inverter will match the motor‟s standard parameters according to its nameplate. The vector control is highly...
Page 37 Chapter 3 Keyboard accurately for the good control performance. Motor parameter auto tunning steps are as follows: Firstly select command source (F0.11=0) as the comment channel for operation panel, then input the following parameters according to the actual motor parameters (selection is based on the current motor): Motor Parameters...
Page 38: Chapter 4 Commissioning
Chapter 4 Commissioning Chapter 4 Commissioning Commissioning Select control manner (Set F0.00) Correctly motor encoder Correctly motor parameters parameters (Set b0.00-b0.05, b0.28, etc) F0.00=? (Set b0.00-b0.05) Vector control W/ PG Vector control W/O PG V/F control Select appropriate ac/deceleration time Select appropriate (Set F0.13, F0.14) ac/deceleration time...
Page 39 Chapter 4 Commissioning ● Firstly confirm that AC input power supply voltage shall be within inverter rated input voltage range before connecting power supply to the inverter. ● Connect power supply to the R, S and T terminals of the inverter. ●...
Page 40: Chapter 5 Function Parameter
Chapter 5 Function parameter Chapter 5 Function parameter 5-1.Menu grouping Note: “★”: In running status, can not modify the parameter setting “●”: The actual testing data, can not be modified “☆”: In stop and run statuses, both can be changed; “▲”: “Factory parameter”, no change about it.
Page 41: D0 Group - Monitoring Function Group
Chapter 5 Function parameter Code Parameter name Functional Description Reference page Keyboard and To set key and display function display parameters To set Jog, jump frequency and Auxiliary function other auxiliary function group parameters Fault and To set fault and protection protection parameters Communication...
Page 42 Chapter 5 Function parameter Factory Reference No. Code Parameter name Setting range setting page d0.00 Running frequency Actual output frequency 0.01Hz d0.01 Set frequency Actual set frequency 0.01Hz Detected value for DC bus d0.02 DC bus voltage 0.1V voltage Inverter output d0.03 Actual output voltage voltage...
Page 43 Chapter 5 Function parameter Factory Reference No. Code Parameter name Setting range setting page Feedback PG feedback speed, to an d0.19 0.1Hz speed(unit:0.1Hz) accuracy of 0.1hz Remaining run time Remaining run d0.20 display, it is for timing run 0.1Min time control Linear speed calculated from angular speed and...
Page 44: F0 Group - Basic Function Group
Chapter 5 Function parameter Factory Reference No. Code Parameter name Setting range setting page Position information calculated from when ABZ d0.33 ABZ position incremental feedback encoder is adopted Encoder Z-phase signal d0.34 Z signal counter count Display run, stand by and d0.35 Inverter status other statuses 1.G type (constant torque...
Page 45 Chapter 5 Function parameter Parameter Factory Referen No. Code Setting range name setting ce page Frequency 1: 0.1Hz ★ F0.02 command 2: 0.01Hz resolution Frequency ★ F0.03 source master 0 to 9 setting Frequency ★ F0.04 source auxiliary 0 to 9 setting Reference 0.
Page 46 Chapter 5 Function parameter Parameter Factory Referen No. Code Setting range name setting ce page 0.Keyboard control (LED off) 1.Terminal block control (LED 2.Communications command control (LED flashes) Command 3. Keyboard control+ ☆ F0.11 source selection Communications command control 4. Keyboard control+ Communications command control+ Terminal block control...
Page 47: F1 Gruop - Input Terminals Group
Chapter 5 Function parameter Parameter Factory Referen No. Code Setting range name setting ce page Depend Carrier ☆ F0.18 0.5kHz to 16.0kHz s on Frequency models Maximum 50.00H ★ F0.19 output 50.00Hz to 320.00Hz frequency 0: F0.21 setting 1: AI1 Upper limit 2: AI2 ★...
Page 48 Chapter 5 Function parameter Factory Referenc No. Code Parameter name Setting range Change setting e page DI2 terminal function ★ F1.01 selection DI3 terminal function ★ F1.02 selection F1.03 DI4 terminal function ★ selection F1.04 DI5 terminal function ★ selection F1.05 DI6 terminal function ★...
Page 49 Chapter 5 Function parameter Factory Referenc No. Code Parameter name Setting range Change setting e page F1.17 Minimum input setting -100.00% to ☆ 0.0% for AI curve 2 +100.0% F1.18 Maximum input for ☆ F1.16 to +10.00V 10.00V AI curve 2 F1.19 Maximum input -100.00% to ☆...
Page 50 Chapter 5 Function parameter Factory Referenc No. Code Parameter name Setting range Change setting e page Minimum pulse input -100.00% to ☆ F1.27 0.0% frequency setting +100.0% Maximum pulse input ☆ F1.28 F1.26 to 100.00kHz 50.00 kHz frequency Maximum pulse input -100.00% to ☆...
Page 51: F2 Group - Output Terminals Group
Chapter 5 Function parameter Factory Referenc No. Code Parameter name Setting range Change setting e page 108. F1.38 DI2 delay time 0.0s to 3600.0s 0.0s ★ 109. F1.39 DI3 delay time 0.0s to 3600.0s 0.0s ★ 110. Define the input 0:unrepeatable ★...
Page 52 Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 117. SPB terminal output ☆ F2.00 0 to 1 mode selection Switching quantity 118. ☆ F2.01 output function selection Relay 1 output 119. ☆ F2.02 function selection (TA1.TB1.TC1) 120.
Page 53: F3 Group - Start And Stop Control Group
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 130. SPA output delay ☆ F2.13 0.0s to 3600.0s 0.0s time 131. Relay 2 output delay ☆ F2.14 0.0s to 3600.0s 0.0s time Units digit: SPB switching quantity 0: positive logic 1: anti-logic...
Page 54 Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page speed 2: start from maximum frequency Rotate speed tracking method 139. F3.02 Speed tracking ☆ 1 to 100 value 140. F3.03 Start frequency 0.00Hz to 10.00Hz 0.00Hz ☆...
Page 55: F4 Group - V/F Control Parameters
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page deceleration A 2: S curve acceleration and deceleration B 0.0% to (100.0% to 151. F3.14 Proportion of S ★ 30.0% F3.15) curve start-section 152. 0.0% to (100.0% to F3.15 Proportion of S ★...
Page 56: F5 Group - Vector Control Parameters
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 163. Overexcitation ☆ F4.10 0 to 200 gain Oscillation 164. ☆ F4.11 0 to 100 suppression gain V/F separation 165. ☆ F4.12 0 to 8 voltage source V/F separation 166.
Page 57: F6 Group - Keyboard And Display
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page Upper limit digital 176. setting for lower ☆ F5.08 0.0% to 200.0% 150.0% torque under speed control mode Vector control 177. ☆ F5.09 50% to 200% 150% differential gain 178.
Page 58 Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 188. Load speed display ☆ F6.04 0.0001 to 6.5000 3.0000 coefficient 0:0 decimal places 189. Decimal places for 1:1 decimal places ● F6.05 load speed display 2:2 decimal places 3:3 decimal places 190.
Page 59: F7 Group - Auxiliary Function Group
Chapter 5 Function parameter 5-1-9.F7 Group - Auxiliary function group Refere Factory No. Code Parameter name Setting range Change setting page 0.00Hz to ☆ F7.00 Jog running frequency F0.19(maximum 6.00Hz 202. frequency) F7.01 Jog acceleration time 0.0s to 6500.0s 203. 5.0s ☆...
Page 60 Chapter 5 Function parameter Refere Factory No. Code Parameter name Setting range Change setting page Depends ☆ F7.13 Deceleration time 4 0.0s to 6500.0s 215. on models Switching frequency 0.00Hz to F0.19 point between ☆ F7.14 (maximum 0.00Hz 216. acceleration time 1 and frequency) acceleration time 2 Switching frequency...
Page 61 Chapter 5 Function parameter Refere Factory No. Code Parameter name Setting range Change setting page detection width frequency) 0.00Hz to F0.19 Frequency detection ☆ F7.26 (maximum 50.00Hz 228. value (FDT2) frequency) 0.0% to 100.0% Frequency detection ☆ F7.27 5.0% 229. (FDT2 level) hysteresis value (FDT2) Random arrivals...
Page 62 Chapter 5 Function parameter Refere Factory No. Code Parameter name Setting range Change setting page 0.0% to 300.0% Random arrivals current ☆ F7.37 (rated motor 0.0% 239. 1 width current) 0.0% to 300.0% Random arrivals current ☆ F7.38 (rated motor 100% 240.
Page 63: F8 Group - Fault And Protection
Chapter 5 Function parameter Refere Factory No. Code Parameter name Setting range Change setting page 0.00Hz to awakens ☆ F7.48 Dormancy frequency 0.00Hz 250. frequency(F7.46) ☆ F7.49 Dormancy delay time 0.0s to 6500.0s 0.0s 251. AI1 input voltage ☆ F7.50 0.00V to F7.51 3.1V 252.
Page 64 Chapter 5 Function parameter Chan Parameter Factory Reference No. Code Setting range name setting page 256. Overcurrent ☆ F8.00 0 to 100 stall gain Overcurrent 257. ☆ F8.01 stall protection 100% to 200% 150% current 258. 0: Disable Motor overload ☆...
Page 65 Chapter 5 Function parameter Chan Parameter Factory Reference No. Code Setting range name setting page Number of 266. ☆ F8.10 0 to 32767 automatic fault reset Fault DO action 267. 0: OFF selection during ☆ F8.11 1: ON automatic fault reset 268.
Page 66 Chapter 5 Function parameter Chan Parameter Factory Reference No. Code Setting range name setting page abnormal( Err.16 )(same as units digit) Units digit: encoder/PG card abnormal (Err.20) 0: Free stop 1： Switch to and then stop at the selected mode 2：Switch to continue to run Tens digit: function code...
Page 67 Chapter 5 Function parameter Chan Parameter Factory Reference No. Code Setting range name setting page of the rated motor frequency, and then continue running, automatically restore to the set frequency for when the load drop does not happen. Ten thousands digit: PID feedback loss when running (Err.31) ( same as F8.17 units digit)
Page 68 Chapter 5 Function parameter Chan Parameter Factory Reference No. Code Setting range name setting page action selection Recovery judgment 283. ☆ F8.27 voltage of 50.0% to 100.0% momentary power cut Recovery voltage 284. ☆ F8.28 judgment time 0.00s to 100.00s 0.50s of momentary power cut...
Page 69: F9 Group - Communication Parameter
Chapter 5 Function parameter 5-1-11.F9 Group - Communication parameter Factory Change Reference No. Code Parameter name Setting range setting page Units digit:MODBUS Tens digit:Profibus- 292. ☆ F9.00 Baud rate Hundreds 6005 digit:Reserve Thousands digit:CAN bus baudrate 0: no parity (8-N-2) 1: even parity (8-E- 293.
Page 70: Fa Group - Torque Control Parameters
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 0:Modbus communication card 1:Profibus 299. Communication card ☆ F9.07 communication card type 2:Reserved 3:CAN bus communication card 5-1-12.FA Group - Torque control parameters Factory Change Reference No.
Page 71: Fb Group - Control Optimization Parameters
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page Torque control 0.00Hz to 305. ☆ FA.05 forward maximum F0.19(maximum 50.00Hz frequency frequency) Torque control 0.00Hz to F0.19 306. ☆ FA.06 backward maximum (maximum 50.00Hz frequency frequency) 307.
Page 72: E0 Group - Wobbulate, Fixed-Length And Counting
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 0: Invalid 316. 1 to 10: PWM ☆ Fb.08 Random PWM depth carrier frequency random depth 317. Fb.09 Deadband time ☆ 100% to 200% 150% adjustment 5-1-14.FC Group - Extended parameter group...
Page 73: E1 Group - Multi-Stage Command, Simple Plc
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 330. E0.09 Specified count ☆ 1 to 65535 1000 value E0.10 Reduction 0 ： invalid ； 331. ☆ frequency pulse 1~65535 number E0.11 Reduction 332. 0.00Hz～F0.19(max ☆...
Page 74 Chapter 5 Function parameter Change Reference Factory No. Code Parameter name Setting range setting page ☆ 344. -100.0% to E1.11 11-stage speed setting 0.0% 100.0% ☆ 345. -100.0% to E1.12 12-stage speed setting 0.0% 100.0% ☆ 346. -100.0% to E1.13 13-stage speed setting 0.0% 100.0% ☆...
Page 75 Chapter 5 Function parameter Change Reference Factory No. Code Parameter name Setting range setting page 354. 1 stage ac/deceleration ☆ E1.21 0 to 3 time selection 355. 0.0s(h) to ☆ E1.22 2 stage running time T2 0.0s(h) 6500.0s(h) 356. 2 stage ac/deceleration ☆...
Page 76 Chapter 5 Function parameter Change Reference Factory No. Code Parameter name Setting range setting page 368. 8 stage ac/deceleration ☆ E1.35 0 to 3 time selection 369. 0.0s(h) to ☆ E1.36 9 stage running time T9 0.0s(h) 6500.0s(h) 370. 9 stage ac/deceleration ☆...
Page 77: E2 Group - Pid Function
Chapter 5 Function parameter Change Reference Factory No. Code Parameter name Setting range setting page 382. 15 stage ac/deceleration ☆ E1.49 0 to 3 time selection 0: S (seconds) 383. E1.50 Simple PLC run-time ☆ 1: H (hours) unit 0: Function code E1.00 reference 1: Analog AI1 reference...
Page 78 Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 0 to 8 387. E2.02 PID feedback source ☆ 0: positive 388. ☆ E2.03 PID action direction 1: negative 389. PID setting feedback ☆ E2.04 0 to 65535 1000 range...
Page 79: E3 Group – Virtual Di、Virtual Do
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 0: no switching 1: switching via 404. PID parameter terminals ☆ E2.19 switching conditions 2: automatically switching according to deviation. 405. PID parameter ☆ E2.20 0.0% to E2.21 20.0% switching deviation 1...
Page 80 Chapter 5 Function parameter Refere Factory No. Code Parameter name Setting range Change setting page 413. Virtual VDI1 terminal ★ E3.00 0 to 50 function selection 414. Virtual VDI2 terminal ★ E3.01 0 to 50 function selection 415. Virtual VDI3 terminal ★...
Page 81 Chapter 5 Function parameter Refere Factory No. Code Parameter name Setting range Change setting page Panel potentiometer 422. ★ E3.09 as a function selection 0 to 50 of DI Units digit：AI1 0:High level effectively 1:Low level effectively 423. AI as DI effective Tens digit:AI2(0 to ★...
Page 82: B0 Group - Motor Parameters
Chapter 5 Function parameter Refere Factory No. Code Parameter name Setting range Change setting page 430. E3.17 VDO1 output delay ☆ 0.0s to 3600.0s 0.0s time 431. E3.18 VDO2 output delay ☆ 0.0s to 3600.0s 0.0s time 432. E3.19 VDO3 output delay ☆...
Page 83 Chapter 5 Function parameter Refere Parameter Factory No. Code Setting range name setting page 0.001Ω to 65.535Ω (inverter 442. Asynchronous Motor power <= 55kW) ★ b0.07 motor rotor 0.0001Ω to 6.5535Ω parameters resistance (inverter power> 55kW) 0.01mH to 655.35mH 443. Asynchronous Motor (inverter power <= 55kW)
Page 84: Y0 Group - Function Code Management
Chapter 5 Function parameter Refere Parameter Factory No. Code Setting range name setting page 0: no operation 1: asynchronous motor parameters still auto tunning 2: asynchronous motor parameters comprehensive Motor 451. auto tunning ★ b0.27 parameter auto 11: Synchronous motor tunning parameters self-learning with load...
Page 85 Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page 0: no operation 1: restore default parameter values, not including motor parameters 2: clear history 3: restore default parameter values, including motor parameters 4: backup current user parameters 501: restore from backup user parameters...
Page 86: Y1 Group - Fault Query
Chapter 5 Function parameter Factory Change Reference No. Code Parameter name Setting range setting page group display selection(the same above) Tens thousands digit: L group display selection(the same above) Units digit:User‟s customization parameter display selection Personality 0:not display 463. ☆ y0.03 parameter group 1:display...
Page 87 Chapter 5 Function parameter Refer Parameter Factory Change No. Code Setting range ence name setting page 0: No fault 1: Inverter unit protection 2: Acceleration overcurrent 3: Deceleration overcurrent 4: Constant speed overcurrent 5: Acceleration overvoltage 6: Deceleration overvoltage 7: Constant speed overvoltage 8: Control power failure 9: Undervoltage 10: Inverter overload...
Page 88 Chapter 5 Function parameter Refer Parameter Factory Change No. Code Setting range ence name setting page 467. Type of the ● y1.01 second fault Type of the 468. ● y1.02 third(at last) fault Frequency of 469. ● y1.03 the third(at last) fault Current of 470.
Page 89 Chapter 5 Function parameter Refer Parameter Factory Change No. Code Setting range ence name setting page 477. y1.11 Reserve 478. y1.12 Reserve Frequency of 479. ● y1.13 the second fault Current of 480. ● y1.14 the second fault Bus voltage ●...
Page 90: Function Parameter Description
Chapter 5 Function parameter Refer Parameter Factory Change No. Code Setting range ence name setting page Bus voltage 491. ● y1.25 of the first fault Input 492. terminal ● y1.26 status of the first fault Output 493. terminal ● y1.27 status of the first fault y1.28...
Page 91 Chapter 5 Function parameter d0.04 Output current (A) 0.01A Effective value for Actual motor current d0.05 Output power (kW) 0.1kW Calculated value for motor output power d0.06 Output torque (%) 0.1% Motor output torque percentage d0.07 DI input status DI input status, this value is a hexadecimal digits. The table listed each input terminal status sequence for each bit: 0 to 10 Input terminal status...
Page 92 Chapter 5 Function parameter AI2 input voltage value Panel potentiometer d0.11 0.01V voltage (V) Panel potentiometer input voltage value d0.12 Count value Actual pulse count value in counting function d0.13 Length value Actual length in fixed length function d0.14 Actual speed Motor Actual running speed display d0.15 PID setting...
Page 93: Basic Function Group: F0.00-F0.27
Chapter 5 Function parameter Master frequency setting d0.27 0.01Hz display Frequency set by F0.03 master frequency setting source Auxiliary frequency d0.28 0.01Hz setting display Frequency set by F0.04 auxiliary frequency setting source d0.31 Synchro rotor position 0.0° Current position angle of synchronous motor rotor d0.29 Command torque (%) 0.1%...
Page 94 Chapter 5 Function parameter Vector control without PG Vector control ★ F0.00 Motor control mode with PG V/F control 0： Vector control without PG Refers to the open-loop vector control for high-performance control applications typically , only one inverter to drive a motor. 1: Vector control with PG Refers to the closed-loop vector control, motor encoder client must be installed , the drive must be matching with the same type of PG encoder card .
Page 95 Chapter 5 Function parameter setting Simple PLC program setting PID control setting Remote communications setting Select inverter master reference frequency input channels. There are 10 master reference frequency channels in all: 0: Keyboard set frequency (F0.01, UP/DOWN can be modified, power-down without memory) Initial value for the set frequency is F0.01 "preset frequency"...
Page 96 Chapter 5 Function parameter combination of DI terminal correspond to the different set frequency value. PI9000 can set up more than 4 multi-stage command terminals and 16 statuses, and any 16 "multi-stage commands "can be achieved correspondence through E1 group function code, the "multi- stage command"...
Page 97 Chapter 5 Function parameter function input terminals UP, DOWN) on the keyboard, adjust directly on the basis of master frequency source. 2) When the frequency source auxiliary setting is set to analog input reference (AI1, AI2, panel potentiometer) or pulse input reference, the frequency source auxiliary setting range for the set 100% can be set by F0.05 and F0.06.
Page 98 Chapter 5 Function parameter Switch between frequency source auxiliary setting arithmetic result master and auxiliary Arithmetic relationship Tens master digit auxiliary frequency source Master+auxiliary Master-auxiliary Max(master, auxiliary) Min (master, auxiliary) Master*auxiliary/ maximum frequency Frequency source reference is achieved by compounding frequency source master setting and frequency source auxiliary setting Units digit: frequency source selection: 0: Frequency source master setting...
Page 99 Chapter 5 Function parameter 2: MAX (master and auxiliary) take the largest absolute value in frequency source master setting and frequency source auxiliary setting as command frequency. 3: MIN (master and auxiliary) take the smallest absolute value in frequency source master setting and frequency source auxiliary setting as command frequency.
Page 100 Chapter 5 Function parameter Communications command control+ Terminal block control Select inverter control command input channel. Inverter control commands include: start, stop, forward, reverse and jog, etc. ("LOCAL / REMOTE" lights out); 0: keyboard control Operate command control by using RUN, STOP/RESET Keys on the operation panel. ("LOCAL / REMOTE"...
Page 101 Chapter 5 Function parameter channel. When command source has the available frequency source for bundling, in the valid period of command source , the set frequency source by F0.03 to F0.07 is no longer valid. ☆ F0.13 Acceleration time 1 0.00s to 6500s ☆...
Page 102 Chapter 5 Function parameter carrier frequency, the equipped leakage protective device may cause malfunction or overcurrent. When running at the low carrier frequency, the above-mentioned phenomenon are opposite. There are different responds to carrier frequency for the different motors. The best carrier frequency can be obtained based on the Actual situation adjustment.
Page 103: Input Terminals: F1.00-F1.46
5-2-3.Input terminals: F1.00-F1.46 PI9000 series inverter of below 11KW is equipped with 6 multi-function digital input terminals, the inverter of above 11KW is equipped with 8 multi-function digital input terminal (of which DI5 can be used as a high-speed pulse input terminal ), and 2 analog input terminals.
Page 104 Chapter 5 Function parameter DI6 terminal function F1.05 0 to 51 selection DI7 terminal function F1.06 0 to 51 selection DI8 terminal function F1.07 0 to 51 selection F1.08 Undefined F1.09 Undefined These parameters are used to set the digital multi-function input terminal, the optional functions are shown in the following table: Function Description...
Page 105 Chapter 5 Function parameter parameters, wobbulate frequency parameters, and PID parameters. This terminal signal disappears, the inverter reverts to the previous state of running before parking. When the signal is sent to the inverter, the inverter External fault normally reports fault Err.15, and performs troubleshooting open input according to fault protection action (for details, please refer to the function code F8.17).
Page 106 Chapter 5 Function parameter When PLC pauses and runs again, this terminal is PLC status reset used to reset the inverter to the initial state of simple PLC. When the inverter outputs at center frequency. Wobbulate pause Wobbulate will pause Counter input Input terminal of the count pulse Counter reset...
Page 107 Chapter 5 Function parameter setting preset frequency Switch between When the terminal is active, the frequency source frequency source B is replaced with the preset frequency (F0.01) auxiliary setting preset frequency Reserve Reserve When DI terminal (E2.19 = 1) is used to switch PID parameters, if the terminal is invalid, PID PID parameter switching parameters use E2.13 to E2.15;...
Page 108 Chapter 5 Function parameter （ order Jog running order，direction set through F7.54 F7.54 ） Note: “Superscript ”means software version of C3.00 and above with MCU keyboard have such function. Table 1 Function description of multi-stage command The 4 multi-stage command terminals can be combined as 16 status, these 16 status have 16 command set values.
Page 109 Chapter 5 Function parameter 15-stage speed E1.15 setting 15X When multi-speed is selected as frequency source, the 100.0% of function code E1.00 to E1.15 corresponds to maximum frequency F0.19. Multi-stage command is used for the function of multi-speed, also for PID reference source to meet the need to switch between different reference values.
Page 110 Chapter 5 Function parameter In the mode, DIx terminal is used as running enabled, while DIy terminal is used to determine running direction. The terminal function is set as follows: Terminals Set value Description Forward run (FWD) Reverse run (REV) Of which, DIx and DIy are the multi-function input terminals of DI1 to DI10, the level is active.
Page 111 Chapter 5 Function parameter direction is determined by the state of DIy. The terminal function is set as follows: Terminals Set value Description Forward run (FWD) Reverse run (REV) Three-wire operation control To run, firstly close DIn terminal, the motor run signal is generated by the ascendant edge of DIx, the motor direction signal is generated by DIy status To stop, you must disconnect DIn terminal signals Of which, DIx, DIy and DIn are the multi-function input terminals of DI1 to DI10, DIx is for active pulse, DIy and DIn are for...
Page 112 Chapter 5 Function parameter AI1 input filter time is used to set AI1 software filter time, When the on-site analog quantity is easily interfered, please increase the filter time to stabilize the detected analog quantity, but the greater filter time, the slower analog detection response, the proper setting method depends on the actual application.
Page 113 Chapter 5 Function parameter Minimum input value ☆ F1.20 0.00V 0.00V to F1.22 for AI curve 3 Minimum input ☆ F1.21 0.0% -100.00% to 100.0% setting for AI curve 3 Maximum input for AI ☆ F1.22 10.00V F1.20 to 10.00V curve 3 Maximum input ☆...
Page 114 Chapter 5 Function parameter The function code is used to set analog quantity and its corresponding setting when the analog input voltage is less than the set Minimum Input. Units digit, tens digit and hundreds digit the function code respectively correspond to the analog input AI1, AI2, panel potentiometer.
Page 115 Chapter 5 Function parameter setting (0 to 1, as above) DI4 terminal active status Thousands setting (0 to 1, as digit above) DI5 terminal active status thousands setting (0 to 1, as digit above) DI6 terminal active Units digit status setting High level active Low level active DI7 terminal...
Page 116 Chapter 5 Function parameter 0: Unrepeatable Two different multi-function input terminals can not be set to the same function. 1: Repeatable Two different multi-function input terminals can be set to the same function. Keyboard ☆ F1.41 0.00% 0～100.00% potentiometer X1 Keyboard potentiometer set value start point Keyboard ☆...
Page 117: Output Terminals: F2.00-F2.19
Chapter 5 Function parameter bits keep Stop keep Stop order zero clear Stop over zero clear Hundre Reserve d bits Thousa Reserve nd bits “Superscript ”means software version of C3.00 and above with MCU Note: keyboard have such function. 5-2-4.Output terminals: F2.00-F2.19 Change Factory Code...
Page 118 Chapter 5 Function parameter Fault output (fault When the inverter occurs failure and shutdown) stops, and outputs ON signal. Frequency level Please refer to the instructions of function detection FDT1 output code F7.23, F7.24 Please refer to the instructions of function Frequency arrival code F7.25 Outputs ON signal when the inverter is in...
Page 119 Chapter 5 Function parameter arrival frequency reaches the lower limit frequency (shutdown without Outputs OFF signal when the inverter is in the output) state of stop Undervoltage status Outputs ON signal when the inverter is in output the undervoltage condition Communication Please refer to communication protocol.
Page 120 Chapter 5 Function parameter When the inverter occurs failure and Alarm output continues to run, the inverter alarms output. When the motor temperature reaches Motor F8.35 (motor overheat pre-alarm threshold), overtemperature pre- the output ON signal. (Motor temperature by warning d0.41 view) Outputs ON signal when the inverter's Current running time...
Page 121 Chapter 5 Function parameter Reserve Frequency source 0～max output frequency main set Maximum output ☆ F2.09 0.01kHz to 100.00kHz 50.00kHz frequency of high-speed pulse SPB terminal is selected as pulse output, the function code is used to select the maximum value of output pulse. SPB switching quantity ☆...
Page 122: Start And Stop Control: F3.00-F3.15
Chapter 5 Function parameter status when the digital output terminal is connected with the corresponding common terminal, active when disconnected; ☆ F2.16 DA1 zero bias coefficient -100.0% to +100.0% 0.0% ☆ F2.17 DA1 gain -10.00 to +10.00 1.00 ☆ F2.18 DA2 zero bias coefficient -100.0% to +100.0% 0.00% ☆...
Page 123 Chapter 5 Function parameter Start from zero speed Start from maximum frequency Rotate speed tracking method For the shortest time to complete the process of speed tracking, select the speed mode for inverter tracking motor : 0: track downward from the frequency that power outage happens Usually select this mode.
Page 124 Chapter 5 Function parameter reference frequency of 10.00Hz. Start DC braking ★ F3.05 current/pre-excitation 0% to 100% current Start DC braking ★ F3.06 0.0s 0.0s to 100.0s time/pre-excitation time Start DC braking, generally is used to stop and then restart the motor. Pre-excitation is used to create magnetic field for asynchronous motor and then start the motor to improve the response speed.
Page 125 Chapter 5 Function parameter Output frequency Initial frequency of stop DC braking Time Effective value of output voltage Waiting time of stop DC braking(t1) Stop DC braking amount Time Stop DC braking time(t2) Running command Schematic diagram of stop DC braking time Dynamic braking ☆...
Page 126: V/F Control Parameters: F4.00-F4.14
Chapter 5 Function parameter occasion that requires to gently start or stop, such as elevators, conveyor belts, etc.. The function code F3.14 and F3.15 respectively defined the proportion of S curve start-section and the proportion of S curve end-section 2: S curve acceleration and deceleration B In the mode of S curve acceleration and deceleration B, the motor rated frequency fb is always the inflection point of S curve.
Page 127 Chapter 5 Function parameter This group of function code is only valid to V/F control, invalid to vector control. V/F control is suitable for fans, pumps and other universal loads, or one inverter with multiple motors, or for the applications that inverter power is significantly different from the motor power.
Page 128 Chapter 5 Function parameter 0.00Hz to F0.19 Torque boost cut-off ★ F4.02 15.00Hz (maximum frequency) frequency Torque boost is mainly used to improve the characteristics of the torque low-frequency under V/F control mode. If the torque boost is too low, the motor will work at the lower speed and power.
Page 129 Chapter 5 Function parameter meet: V1 <V2 <V3, F1 <F2 <F3. The setting of multi-point V/F curve is as shown in below figure. In the sate of low frequency, if the voltage is set to a higher value, which may cause motor overheating even burned, the inverter may appear overcurrent stall or overcurrent protection.
Page 130: Vector Control Parameters: F5.00-F5.15
Chapter 5 Function parameter increase gain value when the motor has obvious oscillation, the greater gain, the more obvious the suppression of oscillation. When using the function of oscillation suppression, which requires that the motor's rated current and no-load current parameters must be accurate, otherwise V/F oscillation suppression is ineffective.
Page 131 Chapter 5 Function parameter PIparameter F5.00 F5.01 F5.03 F5.04 Frequency of instruction F5.02 F5.05 PI parameter diagram Converter working in different frequency can choose different speed ring PI parameters. Operating frequency is less than the switching frequency 1 (F5.02), speed ring PI control parameters for F5.00 and F5.01.
Page 132: Keyboard And Display: F6.00-F6.19
Chapter 5 Function parameter ☆ 0.0% to 200.0% F5.08 150.0% Limit digital setting In speed control mode, the maximum value of inverter output torque is controlled by the torque upper limit source. F5.07 is used to select the setting source of torque limit, when it is set by analog, high- speed pulse or communication, the set 100% corresponds to F5.08, the 100% of F5.08 is the inverter's rated torque.
Page 133 Chapter 5 Function parameter Factory Change Code Parameter name Setting range setting limits STOP/RESET key is enabled only in keyboard operation STOP/RESET key mode ☆ F6.00 functions STOP/RESET key is enabled under operation mode Running status ☆ F6.01 0000 to FFFF 001F display parameters 1 DO Output...
Page 134 Chapter 5 Function parameter Setting frequency (Hz) Length PLC range Bus voltage Load speed DI input situation PID setting DO output situation High speed pulse AI1 voltage input frequency (Hz) AI2 voltage Remain Remain Remain Remain Count value If the above parameters need to be displayed on operation, firstly set its position to 1, and then set at F6.03 after converting the binary number to the hexadecimal number.
Page 135 Chapter 5 Function parameter Control panel ● F6.11 software version Software version number number F6.12 to Reserve F6.14 0:keypad (single row LED) ● F6.15 Keyboard type selection 1:big keyboard (double row LED) 1Kbit/10 10bit/1bit 0bit d0.0 ● F6.16 Monitor selection 2 paramete paramete r number...
Page 136 Chapter 5 Function parameter UP key is defined DOWN function DOWN key defined as subtract function defined free stop DOWN key defined Forward running DOWN key defined Reverse running ☆ F6.19 DOWN key Multifunction key definition 2 defined Forward Jog running DOWN key defined Reverse...
Page 137: Auxiliary Function: F7.00-F7.54
Chapter 5 Function parameter Under the parameter selection menu, The subtract function keysadjust the parameter selection Under the parameter modify menu, the subtract function keys adjust the parameter value. Multifunction key is defined free stop key. The key is effective under Parameter selection monitor menu, the inverter is free stop.
Page 138 Chapter 5 Function parameter 0.00Hz ☆ F7.06 0.00Hz F0.19(maximum Jump frequency range frequency) When the set frequency is in the jump frequency range, the Actual operating frequency will run at the jump frequency close from the set frequency . The inverter can avoid mechanical resonance point of load by setting jump frequency.
Page 139 Chapter 5 Function parameter ☆ F7.12 Acceleration time 4 0.0s to 6500.0s ☆ F7.13 Deceleration time 4 0.0s to 6500.0s PI9000 provides 4 groups of deceleration time, respectively F0.13\F0.14 and the above 3 groups of deceleration time. The 4 groups of deceleration time are defined exactly the same, please refer to the instructions of F0.13 and F0.14.
Page 140 Chapter 5 Function parameter 输出频率 Hz Output frequency Forward 正转 Time 时间 t Reversal 死区时间 Deadband 正反转死区时间示意图 Schematic diagram of the deadband of forwad and reverse Allow ☆ F7.17 Reverse rotation control Prohibit For certain production equipments, the reverse rotation may result in damage to the equipment, the function can disable the reverse rotation.
Page 141 Chapter 5 Function parameter multifunction digital DO outputs ON signal. ☆ F7.22 Start protection This parameter is related to the security protection of the inverter. If this parameter is set to 1, if the time run command is effective when power on (for exampl e, the terminal run command is closed before power on), the drive does not respond to the ru n command, you must firstly cancel the run command , after run command is again effective the drive response.
Page 142 Chapter 5 Function parameter Output Output 输出频率 Hz Frequency Frequency Set frequency 设定频率 Detection amplitude 检出幅值 time t 频率到达 Frequency 检测信号 reaches detection signal time t 频率到达检出幅值示意图 Schematic diagram of frequency arriva l detection amplitude The inverter's multifunction output DO will output ON signal when the inverter's operating frequency is in a certain range of target frequency This parameter is used to set the frequency arrival detection range, the parameter is the percentage of maximum frequency.
Page 143 Chapter 5 Function parameter running 运行频率 frequency 频率检出宽度 Frequency detection range Random arrivals frequency 任意到达频率频率检出宽度 Time 时间 t 任意到达频率 Random arrivals frequency 检测信号 DO 或 detection signal DO or 继电器 relay 任意到达频率检测示意图 Schematic diagram of random arrivals frequency detection When the inverter's output frequency randomly reaches the range of the detected value(positive or negative), the multi-function DO will output ON signal.
Page 144 Chapter 5 Function parameter Output current Overrun value of output current F7.34 Time Output current overrun detection signal Time Output current overrun detection delay time F7.35 Schematic diagram of output current overrun detection signal When the inverter's output current is more than or overrun the detection point and lasts for longer than the delay time of software overcurrent point detection, the inverter's multifunction DO will output ON signal.
Page 145 Chapter 5 Function parameter When the inverter radiator temperature reaches the temperature, the inverter multifunction DO will output "Module Temperature Arrival" ON signal. Fan running only when running ☆ F7.41 Cooling fan control always running Used to select the cooling fan mode, if you select 0, the fan will run when the inverter is running, but in the stop state of inverter, if the radiator temperature is above 40 degrees, the fan will run, otherwise the fan will not run.
Page 146: Fault And Protection:f8.00-F8.35
Chapter 5 Function parameter inverter multi-functional DO will output "AI1 input overrun"signal, so as to indicate whether the AI1 input voltage is within the set range or not. F7.52 to Reserve F7.53 Bits Jog direction Forward reverse Determine the direction from the main termina End running state by...
Page 147 Chapter 5 Function parameter in the current operating frequency, and then continues to ac/decelerate upon the decline of the output current. Overcurrent stall gain is used for adjusting inhibition overcurrent capability during ac/deceleration. The greater this value, the stronger inhibition overcurrent capability Under the premise that the overcurrent does not occur, the best is the smaller gain setting.
Page 148 Chapter 5 Function parameter voltage In the process of the inverter deceleration, when the DC bus voltage exceeds the overvoltage stall protection voltage/the energy consumption brake voltage, the inverter stops deceleration and maintains at the current operating frequency(if F3.12 is not set to 0, the braking signal is outputted the energy consumption brake can be implemented by an external braking resistor.) and then continues to decelerate upon decline of the bus voltage Overvoltage stall gain is used for adjusting inhibition overvoltage capability during...
Page 149 Chapter 5 Function parameter When fault self-recovery restart uptime over an hour later, it will restore the original setting of automatic fault reset. Fault action selection ☆ F8.11 during automatic fault reset If the inverter automatic fault reset function is set, F8.10 can be used to set whether DO action is active or not during the automatic fault reset Automatic ☆...
Page 150 Chapter 5 Function parameter Continue to run Input phase loss(Fault ID Err.12 )(same as units Tens digit digit) Output phase loss(Fault Hundreds ID Err.13 )(same as units digit digit) External fault(Fault ID Thousand Err.15 )(same as units s digit digit) Communication abnormal(Fault ID thousands...
Page 151 Chapter 5 Function parameter Free stop Stop at the selected mode Decelerate to 7% of the rated frequency of motor and continue to run, automatically return to the set frequency to run if the load drop does not happen. PID feedback loss when running(Fault thousands Err.31 )( same as F8.17...
Page 152 Chapter 5 Function parameter frequency set by F8.24. When "abnormal spare frequency" is selected, the value set by F8.25 is the percentage of the maximum frequency Invalid Momentary power ☆ Deceleration F8.26 action Deceleration and stop selection Voltage protection of ☆...
Page 153 Chapter 5 Function parameter Recovery voltage judgment time of momentary power cut F8.28 Bus voltage Judgment voltage of momentary power cut action F8.29 Time Running frequency deceleration Voltage protection of (F8.26=1 : momentary power out F8.27 Time Deceleration time Recovery acceleration time Deceleration time Running frequency Voltage protection of...
Page 154: Communications Parameters: F9.00-F9.07
Chapter 5 Function parameter Load drop ☆ F8.31 10.0% 0.0% to 100.0% (rated motor current) detection level Load drop ☆ F8.32 1.0s 0.0s to 60.0s detection time If the load drop protection function is active, when the inverter output current is less than the load drop detection level (F8.31)and the duration is longer than the load drop detection time(F8.32), the inverter output frequency is automatically reduced to 7% of the rated frequency.
Page 155 Chapter 5 Function parameter 4800BPS 9600BPS 19200BPS 38400BPS 57600BPS 115200BPS Profibus- Tens digit 115200BPS 208300BPS 256000BPS 512000BPS Hundreds digit Reserve Thousands digit CAN bus baudrate No parity (8-N- Even parity (8- E-1) ☆ F9.01 Data format Odd parity (8- O-1) No parity(8-N- 1 to 250, 0 for broadcast ☆...
Page 156: Torque Control Parameters:fa.00-Fa.07
Chapter 5 Function parameter MODBUS protocol Tens digit Profibus PPO1 format PPO2 format PPO3 format PPO5 format 0.01A Communication read ☆ F9.06 current resolution 0.1A 0:Modbus communication card 1:Profibus communication Communication card ☆ F9.07 card type 2:Reserved 3:CAN bus communication card 5-2-12.Torque control parameters:FA.00-FA.07 Factory...
Page 157: Control Optimization Parameters: Fb.00-Fb.09
Chapter 5 Function parameter reference MIN(AI1, AI2) MAX(AI1, AI2) Torque digital setting ☆ FA.02 -200.0% to 200.0% 150% under torque control mode FA.01 is used to select the torque setting source, there are eight torque setting modes in all. The torque setting adopts the relative value, the 100.0% corresponds to the rated torque of inverter.
Page 158 Chapter 5 Function parameter manner Enable Enable Quick Current Limiting function, which can minimize the overcurrent fault of inverter , and ensure the uninterrupted operation of inverter. If the drive is in the state of fast current limiting for a long period of time , the inverter may be damaged by overheating and others, this case is not allowed, so the inverter will alarm fault with fault ID Err.40, it indicates that the inverter exists overload and needs to be shut down.
Page 159: Extended Parameter:fc.00-Fc.02
Chapter 5 Function parameter which may reduce the control performance. Generally do not need to be modified. optimization Vector optimization Optimization ★ Fb.05 without mode mode 1 selection Optimization mode 2 Upper limiting ☆ Fb.06 12.00Hz frequency for DPWM 0.00Hz to 15.00Hz switching Asynchronous modulation...
Page 160 Chapter 5 Function parameter Slave output frequency = Master setting frequency * Proportional linkage coefficient + UP/DOWN Changes. ☆ FC.02 0.0 to 100.0 PID start deviation If the absolute value of deviation between PID setting source and feedback source is greater than of the parameter, the inverter starts only when PID output frequency is greater than the wake-up frequency to prevent the repetition of the inverter starts.
Page 161 Chapter 5 Function parameter This parameter is used to determine the baseline of the swing 0: relative to center frequency(F0.07 frequency source) For the variable swing system. The swing varies with the change of center frequency (the set frequency) 1: relative to maximum frequency(F0.19) For the fixed swing system, the swing is fixed ☆...
Page 162: Multi-Stage Command, Simple Plc: E1.00-E1.51
Chapter 5 Function parameter The count value needs to be sampled through the multi-function digital input terminal. In some applications, the related input terminal function shall be set to "Counter Input"(function 25), when the pulse frequency is higher, DI5 port must be used . When the count value reaches the set count value(E0.08), the multifunction digital DO will output "Set Count Value Arrival"...
Page 163 Chapter 5 Function parameter 4-stage speed ☆ E1.04 0.0% -100.0% to 100.0% setting 4X 5-stage speed ☆ E1.05 0.0% -100.0% to 100.0% setting 5X 6-stage speed ☆ E1.06 0.0% -100.0% to 100.0% setting 6X 7-stage speed ☆ E1.07 0.0% -100.0% to 100.0% setting 7X 8-stage speed...
Page 164 Chapter 5 Function parameter After the inverter completes a single cycle, it will automatically maintain the frequency and direction of the last stage. 2: circulating After the inverter completes a cycle, it will automatically start next cycle, and stop till the stop command is given.
Page 165 Chapter 5 Function parameter ☆ E1.18 0 stage running time T0 0.0s(h) to 6500.0s(h) 0.0s(h) ☆ E1.19 0 to 3 0 stage ac/deceleration time ☆ E1.20 0.0s(h) to 6500.0s(h) 0.0s(h) 1 stage running time T1 ☆ E1.21 0 to 3 1 stage ac/deceleration time ☆...
Page 166: Pid Function: E2.00-E2.27
Chapter 5 Function parameter ☆ E1.44 0.0s(h) to 6500.0s(h) 0.0s(h) 13 stage running time T13 13 stage ac/deceleration time ☆ E1.45 0 to 3 selection ☆ E1.46 0.0s(h) to 6500.0s(h) 0.0s(h) 14 stage running time T14 14 stage ac/deceleration time ☆...
Page 167 Chapter 5 Function parameter output frequency so as to stabilize the controlled value at the position of the target value. Suitable for flow control, pressure control and temperature control and other process control applications. Td*s+1 Target PID output control amount amount Feedback amount Flow diagram of process PID principle...
Page 168 Chapter 5 Function parameter MIN (|AI1|, |AI2|) This parameter is used to select the process PID feedback signal channel. The feedback value of process PID is also a relative value, the setting range is from 0.0% to 100.0%. Positive ☆ E2.03 PID action direction Negative...
Page 169 Chapter 5 Function parameter E2.10 is used for filtering the PID output frequency, the filter will weaken the sudden change of the inverter output frequency, but it will also bring the response performance of the process closed loop system. 0.0%: not judged feedback loss PID feedback loss ☆...
Page 170 Chapter 5 Function parameter entire run, it is required to use different PID parameters under different conditions. This group of function codes is used to switch between two groups of PID parameters. Which the setting method for regulator parameter(E2.16 to E2.18) is similar to the parameter(E2.13 to E2.15).The two groups of PID parameters can be switched by the multi- functional digital DI terminal, can also be switched automatically according to the PID deviation.If you select the multi-functional DI terminal, the multi-function terminal function...
Page 171: Virtual Di、Virtual Do:e3.00-E3.21
Chapter 5 Function parameter initial value ☆ E2.24 0.00s 0.00s to 360.00s hold time When the inverter starts, PID output is fixed at PID initial value(E2.23), and then continuous for the PID initial value hold time(E2.24), at last PID begins operation of the closed-loop adjustment.
Page 172 Chapter 5 Function parameter Factory Change No. Code Parameter name Setting range setting limit Virtual VDI3 499. ★ E3.02 terminal function 0 to 50 selection Virtual VDI4 500. ★ E3.03 terminal function 0 to 50 selection Virtual VDI5 501. ★ E3.04 terminal function 0 to 50...
Page 173 Chapter 5 Function parameter Factory Change No. Code Parameter name Setting range setting limit VD1 whether valid is decided by E3.05 Virtual VDI2（0 Tens digit to 1, same as above） Virtual VDI3（0 Hundreds digit to 1, same as above） Virtual VDI4（0 Thousands digit to 1, same as above）...
Page 174 Chapter 5 Function parameter Factory Change No. Code Parameter name Setting range setting limit AI1 terminal as a 504. ★ E3.07 0 to 50 function selection of DI AI2 terminal as a 505. ★ E3.08 0 to 50 function selection of DI 506.
Page 175 Chapter 5 Function parameter Factory Change No. Code Parameter name Setting range setting limit With the physical internal Virtual VDO2 sub DIx 509. ☆ E3.12 output function selection See F2 group physical DO 1to40 output option With the physical internal Virtual VDO3 sub DIx 510.
Page 176: Motor Parameters: B0.00-B0.35
Chapter 5 Function parameter Factory Change No. Code Parameter name Setting range setting limit 516. VDO3 output ☆ E3.19 0.0s to 3600.0s 0.0s delay time 517. VDO4 output ☆ E3.20 0.0s to 3600.0s 0.0s delay time 518. VDO5 output ☆ E3.21 0.0s to 3600.0s 0.0s...
Page 177 Chapter 5 Function parameter rated current. This parameter can be used to determine the inverter's overload protection capacity and energy efficiency for the motor. It is used for the prevention of overheating caused by the self-cooled motor at low speed , or to correct for protecting the motor when the little change of the motor characteristics may affect the changes of the motor capacity.
Page 178 Chapter 5 Function parameter inductance (inverter power <= 55kW) 0.001mH to 65.535mH (inverter power> 55kW) Synchronous counter ★ b0.14 0.1V to 6553.5V EMF coefficient b0.15 to Reserve b0.26 No operation Asynchronous motor parameters still auto tunning Asynchronous motor parameters comprehensive Motor parameter auto ★...
Page 179 Chapter 5 Function parameter When synchronous motor and the load can not be disengaged, have to choose synchronous self-learning with load, in this process motor running at speed of 10rpm. Before synchronous motor parameters self-learning with load, correct motor type and motor nameplate parameters b0.00 ~ b0.05 should be set.
Page 180: Function Code Management:y0.00-Y0.04
Chapter 5 Function parameter Encoder installation ★ b0.30 0.00 to 359.90 0.00 angle Current detection compensation for setting inverter control，if it is set too large which may cause performance degradation. The parameter is only valid to synchronous motors control, and it is valid to ABZ incremental encoder, UVW incremental encoder, rotational transformer, wire-saving UVW encoder, while invalid to sine and cosine encoders.
Page 181 Chapter 5 Function parameter Restore the factory initialization parameters, including motor parameters Clear history Restore default parameter values, including motor parameters Backup current user parameters Restore user backup parameters Clear keyboard storage area upload parameter to keyboard storage area upload parameter to keyboard storage area download parameters...
Page 182 Chapter 5 Function parameter 12: upload parameter to keyboard storage area 2 Upload the parameters of the inverter to the keyboard storage area 2 21: download the parameters from keyboard storage 1 area to the storage system Download the parameters from keyboard storage 1 to inverter 22:download the parameters from keyboard storage 2 area to the storage system Download the parameters from keyboard storage 2 to inverter Note: “Superscript...
Page 183: Fault Query:y1.00-Y1.30
Chapter 5 Function parameter 0:not displays 1:displays Modifiable Function code ☆ y0.04 modification Not modifiable properties User can set whether function code parameter can be modified or not, so as to prevent the risk that function parameters are altered unexpectedly. If the function code is set to 0, all function code can be modified;...
Page 184 Chapter 5 Function parameter Output phase loss Module overheating External fault Communication abnormal Contactor abnormal Current detection abnormal Motor auto tunning abnormal Encoder/PG card abnormal Parameter read and write abnormal Inverter hardware abnormal Motor short to ground Reserve Reserve Running time arrival Custom fault 1 Custom fault 2 Power-on time arrival...
Page 185 Chapter 5 Function parameter Bus voltage of the last fault voltage of ● y1.05 third fault Input terminal status of the last fault, the order Input BIT9 BIT8 BIT7 BIT6 BIT5 BIT4 BIT3 BIT2 BIT1 BIT0 terminal ● y1.06 status When the input terminal is ON, the third corresponding binary bits is 1, OFF is 0, all...
Page 186 Chapter 5 Function parameter fault When the input terminal is ON, the corresponding binary bits is 1, OFF is 0, all DI status is converted to the decimal number for display. Output terminal status of the last fault, the order is: BIT4 BIT3 BIT2...
Page 187 Chapter 5 Function parameter terminal order is: status BIT4 BIT3 BIT2 BIT1 BIT0 first Reserve REL2 REL1 fault When the output terminal is ON, the corresponding binary bits is 1, OFF is 0, all DI status is converted to the decimal number for display.
Page 188: Chapter 6 Emc (Electromagnetic Compatibility)
Chapter 6 EMC (Electromagnetic Compatibility) Chapter 6 EMC (Electromagnetic Compatibility) 6-1.Definition Electromagnetic compatibility refers to the ability that the electric equipment runs in an electromagnetic interference environment and implements its function stably without interferences on the electromagnetic environment. 6-2.EMC standard In accordance with the requirements of the Chinese national standard GB/T12668.3, the inverter must comply with the requirements of electromagnetic interference and anti- electromagnetic interference.
Page 189: Remedies For The Interferences From The Surrounding Electromagnetic
Chapter 6 EMC (Electromagnetic Compatibility) 3) It is recommended that the output power cables of the inverter shall use shield cables or steel pipe shielded cables and that the shielding layer shall be grounded reliably, the lead cables of the equipment suffering interferences shall use twisted-pair shielded control cables, and the shielding layer shall be grounded reliably.
Page 190: Precautions On Installing Emc Input Filter At The Input End Of Power Supply
Chapter 6 EMC (Electromagnetic Compatibility) current to the earth, and the other is leakage current between the cables. 1) Factors of affecting leakage current to the earth and its solutions: There are the distributed capacitance between the lead cables and the earth. The larger the distributed capacitance, the larger the leakage current;...
Page 191: Chapter 7 Troubleshooting
Chapter 7 Troubleshooting Chapter 7 Troubleshooting PI9000 can provide effective protection when the equipment performance is played fully. The following faults may appear in the process of use, please refer to the following table to analyze the possible causes and then trouble shoot. In case of damage to the equipment and the reasons that can not solved, please contact with your local dealers/agents, or directly contact with the manufacturers to seek solutions.
Page 192 Chapter 7 Troubleshooting No. Fault ID Failure type Possible causes Solutions 6.the motor that is rotating is 6.select Speed Tracking started unexpectedly. Start or restart after stopping the motor. 7.suddenly increase the load in the process of acceleration. 7.cancel the sudden load 8.the type selection of inverter 8.choose the inverter with is small...
Page 193 Chapter 7 Troubleshooting No. Fault ID Failure type Possible causes Solutions decelerating. or install braking resistor. 3.the deceleration time is too 3.increase the deceleration short time 4.didn't install braking unit 4.install braking unit and and braking resistor brake resistor 1.there is external force to 1.cancel the external force Constant drag the motor to run when...
Page 194 Chapter 7 Troubleshooting No. Fault ID Failure type Possible causes Solutions 4.the three-phase input power existing problems in the is not normal peripheral line 1.the lead wires from the 1.eliminate peripheral inverter to the motor is not faults normal 2.check the motor's three- 2.the inverter's three phase Output phase Err.13...
Page 195 Chapter 7 Troubleshooting No. Fault ID Failure type Possible causes Solutions 1.the motor parameters was 1.correctly set motor not set according to the parameter according to the Motor Err.19 nameplate nameplate parameter auto tunning fault 2.the identification process of 2.check the lead wire from parameter is timeout the inverter to the motor 1.replace the encoder...
Page 196 Chapter 7 Troubleshooting No. Fault ID Failure type Possible causes Solutions or the motor stall occurs check the motor and its mechanical conditions 2.the type selection of inverter is small 2.choose the inverter with large power level Change current motor through Switch motor Switch motor after the Err.41...
Page 197: Chapter 8 Installation And Spare Circuit
Chapter 8 Installation and Spare Circuit Chapter 8 Installation and spare circuit 8-1.Operating environment (1) Environmental temperature -10℃ to 50℃ Above 40℃,the capacity will decrease 3% by each 1℃.So it is not advisable to use inverter above 50℃ (2) Prevent electromagnetic interference, and away from interference sources. (3) Prevent the ingress of droplets, vapor, dust, dirt, lint and metal fine powder.
Page 198: Wiring Diagram(< 11Kw)
Chapter 8 Installation and Spare Circuit 8-3-1.Wiring diagram(< 11kW) Main Circuit Control Circuit Note：software version of C3.00 and above have J16 function.
Page 199: Wiring Diagram(11Kw To 15Kw)
Chapter 8 Installation and Spare Circuit 8-3-2.Wiring diagram(11kW to 15kW) Main Circuit Control Circult Note：software version of C3.00 and above have J16 function.
Page 200: Wiring Diagram(18.5Kw To 355Kw)
Chapter 8 Installation and Spare Circuit 8-3-3.Wiring diagram(18.5kW to 355kW) Main Circuit Control Circult Note：software version of C3.00 and above have J16 function.
Page 201: Main Circuit Terminal (G Type)
Chapter 8 Installation and Spare Circuit Main circuit terminal (G type) 8-4. 8-4-1.PI9000 main circuit terminal Main circuit terminal(<15KW, 380V) W/T3 R/L1 S/L2 T/L3 RB U/T1 V/T2 Ground terminals Output end of power Braking Input end of power DC reactor resistor Main circuit terminal(18.5kW to 160kW, 380V)(Left In, Right Out) U/T1 V/T2 W/T3...
Page 202: Function Description Of Main Circuit Terminal
Chapter 8 Installation and Spare Circuit 8-4-2.Function description of main circuit terminal Terminals Name Description R/L1 Connect to three-phase power Inverter input S/L2 supply, single-phase connects to R, terminals T/L3 Ground terminals Connect to ground Braking resistor P+, RB Connect to braking resistor terminals U/T1 V/T2...
Page 203 Chapter 8 Installation and Spare Circuit 2.Input impedance: 20kΩ with voltage input, 510Ω with current input. Digital input 1 1.Opto-coupler isolation, compatible with bipolar input Digital input 2 2.Input impedance: 4.7kΩ Digital input 3 3.Voltage range with level input: 9V to 30V Digital input 4 4 .
Page 204: Arrangement Of Control Circuit Terminals
Chapter 8 Installation and Spare Circuit 8-5-2.Arrangement of control circuit terminals 1. 9KLCB board control circuit terminals 2. 9KSCB board control circuit terminals 8-6.Wiring Precautions: Danger Make sure that the power switch is in the OFF state before wiring operation, or electrical shock may occur! Wiring must be performed by a professional trained personnel, or this may cause damage to the equipment and personal injury!
Page 205: Spare Circuit
Chapter 8 Installation and Spare Circuit ※ In order to minimize the effects of electromagnetic interference, it is recommended that a surge absorption device shall be installed additionally when electromagnetic contactor and relay is closer from the inverter. ※ External control lines of inverter shall adopt isolation device or shielded wire. ※...
Page 206: Chapter 9 Maintenance And Repair
Chapter 9 Maintenance and Repair Chapter 9 Maintenance and Repair 9-1.Inspection and Maintenance During normal use of the inverter, in addition to routine inspections, the regular inspections are required (e.g. the overhaul or the specified interval, and the interval shall not exceed 6 months), please refer to the following table to implement the preventive measures.
Page 207: Parts For Regular Replacement
Chapter 9 Maintenance and Repair The different instruments may come to different measurement results when measuring. It is recommended that the pointer voltmeter shall be used for measuring input voltage, the rectifier voltmeter for output voltage, the clamp-on ammeter for input current and output current, and the electric wattmeter for power.
Page 208: Measuring And Readings
Chapter 9 Maintenance and Repair --50% rated power 2 hours, -- 75% rated power 2hours, -- Last 100% rated power 2hours. Instruction of using adjustable power to charge the frequency inverter: The adjustable power is decided by the frequency inverter input power, for the single phase/3 phase 220v frequency inverter, we uase 220v AC/2A Regulator.
Page 209: Chapter 10 Options
Chapter 10 Options Chapter 10 Options User can additionally install peripheral devices based on the different application conditions and requirements for this series of product, and its wiring diagram is as follows: Three-phase AC power Please use the power supply meeting the specifications of the inverter.
Page 210: Options
Chapter 10 Options 10-1.Options If the extended function (such as RS485 card, PG card, etc.)for other functional modules is needed, please specify the functional module card you want when ordering. 10-2.Molded case circuit breaker (MCCB) or earth leakage circuit breaker (ELCB) MCCB or ELCB as the power switch of the inverter also plays a protective role to the power supply.
Page 211 Chapter 10 Options Dimensions Inverter specifications Size(mm) Gross weight(kg) Voltage Capability(kw) 0.75 220V 18.5 12.0 15.0 23.0 23.0 30.0 0.75 380V 480V 18.5 12.0 15.0 23.0...
Page 212: Noise Filter
10-6.Braking unit and braking resistor Frequency inverter PI9000 series: 220V 7.5kW and below models & 380V 15kW and below models, there is built-in braking unit, the maximum braking torque is 50%. Refer the table below to match the braking resistors. 220V 11kW and above models &...
Page 213: Output Emi Filter
Chapter 10 Options 0.75 380V 1000 1500 10-7.Output EMI filter It is used to inhibit noise interference and leakage current generated in the inverter output side. 10-8.AC output reactor When the connection wire from the inverter to the motor is longer (over 20 meters), it is used to inhibit overcurrent caused due to the distributed capacitance.
Page 214: Input Filter(690V)
Chapter 10 Options NFI- 390/200/90 260/185 NFI- 55 to 75 400/200/90 260/185 NFI- 340/190/90 180/175 NFI- 110 to 132 380/210/90 180/195 NFI- 380/210/90 180/195 NFI- 470/260/128 165/245 10-9-2.Input filter(690V) Dimensions Installatio L/W/H(mm) n size Model Voltage(V) Power(KW) Current(A) weight(kg) W1/H1 (mm) NFI- 0.75 to 1.5...
Page 215: Output Filter
Chapter 10 Options NFI- 215 to 250 14.2 470/245/128 165/245 10-10.Output filter 10-10-1.Output filter(380v) Dimensions Installation L/W/H(mm) size Model Voltage(V) Power(KW) Current(A) weight(kg) W1/H1 (mm) NF0- 0.75 to 1.5 0.75 135/105/44 51/95 NF0- 2.2 to 4 1.25 202/86/58 184/60 NF0- 5.5 to 7.5 1.47 202/86/58...
Page 216: Input Ac Choke
Chapter 10 Options NF0- 0.75 to 1.5 0.75 135/105/44 51/95 NF0- 2.2 to 4 1.25 202/86/58 184/60 NF0- 5.5 to 7.5 1.47 202/86/58 184/60 NF0- 11 to 15 2.35 215/100/70 200/70 NF0- 18.5 to 22 2.37 215/100/70 200/70 NF0- 2.73 261/100/90 243/70 NF0-...
Page 217 Chapter 10 Options ACL- 0010- 2.67 2.00% 91/65/6*11 EISC- E1M5B ACL- 0015- 3.45 2.00% 0.93 95/61/6*15 EISH- E1M0B ACL- 0020- 3.25 2.00% 95/61/6*15 EISH- EM75B ACL- 0030- 5.13 2.00% 0.47 95/80/6*15 EISH- EM60B ACL- 0040- 5.20 2.00% 0.35 95/80/6*15 EISH- EM42B ACL- 0050-...
Page 218 Chapter 10 Options ACL- 0250- 22.1 2.00% 0.056 182/96/11*18 ELSH- E65UB ACL- 0290- 28.3 2.00% 0.048 214/100/11*18 ELSH- E50UB ACL- 0330- 28.3 2.00% 0.042 214/100/11*18 ELSH- E50UB ACL- 0390- 31.8 2.00% 0.036 243/112/12*20 ELSH- E44UB ACL- 0490- 43.6 2.00% 0.028 243/122/12*20 ELSH- E35UB...
Page 219: Input Ac Choke(690V)
Chapter 10 Options 10-11-2.Input AC choke(690V) Voltage Inductance(mH) Installatio Rated drop(V) n size Model Voltage(V) Power(KW) Current(A) weight(kg) D1/W1/A *B(mm) ACL- 4.00% ACL- 4.00% ACL- 4.00% 0010 ACL- 4.00% 0015 ACL- 4.00% 0020 ACL- 4.00% 0030 ACL- 4.00% 0040 ACL- 18.5 4.00% 0050...
Page 220: Output Ac Choke
Chapter 10 Options ACL- 4.00% 0530 ACL- 4.00% 0600 ACL- 4.00% 0660 ACL- 4.00% 0800 ACL- 1000 4.00% 1000 ACL- 1250 4.00% 1200 ACL- 1600 4.00% 1600 10-12.Output AC choke 10-12-1.Output AC choke(380V) Voltage Inductan Installation size Rated Model Voltage(V) Power(KW) drop(V) ce(mH) D1/W1/A*B(m...
Page 221 Chapter 10 Options OCL- 0040- 0.50% 0.18 95/80/6*15 ELSC- EM18 OCL- 0050- 18.5 0.50% 0.14 95/80/6*15 ELSC- EM14 OCL- 0060- 0.50% 0.12 120/72/8.5*20 ELSC- EM12 OCL- 0080- 0.50% 0.087 120/72/8.5*20 ELSC- E87U OCL- 0090- 0.50% 0.078 120/72/8.5*20 ELSC- E78U OCL- 0120- 0.50% 0.058...
Page 222: Output Ac Choke(690V)
Chapter 10 Options OCL- 0490- 36.6 0.50% 0.014 243/113/12*20 EISH- E14U OCL- 0530- 36.6 0.50% 0.013 243/113/12*20 EISH- E13U OCL- 0600- 43.5 0.50% 0.012 243/128/12*20 EISH- E12U OCL- 0660- 0.50% 0.011 243/128/12*20 EISH- E4U0 OCL- 0800- 60.8 0.50% 0.0087 260/175/12*20 EISH- E5U0 OCL-...
Page 223 Chapter 10 Options OCL- 2.00% 0030 OCL- 2.00% 0040 OCL- 18.5 2.00% 0050 OCL- 2.00% 0060 OCL- 2.00% 0080 OCL- 2.00% 0090 OCL- 2.00% 0120 OCL- 2.00% 0150 OCL- 2.00% 0200 OCL- 2.00% 0250 OCL- 2.00% 0290 OCL- 2.00% 0330 OCL- 2.00% 0390...
Page 224: Dc Choke
Chapter 10 Options 10-13.DC choke Inductance(mH) Installation Rated size Model Voltage(V) Power(KW) Current(A) weight(kg) D1/W1/A*B( DCL- 0003- 63/47/5.4*9 EIDC- E28M DCL- 0003- 63/47/5.4*9 EIDC- E28M DCL- 0006- 63/60/5.4*9 EIDC- E11M DCL- 0006- 63/60/5.4*9 EIDC- E11M DCL- 0012- 80/70/6*11 EIDC- E6M3 DCL- 0023- 87/70/6*11...
Page 225 Chapter 10 Options DCL- 0065- 111/85/8.4*13 EIDH- DCL- 0078- 111/85/8.4*13 EIDH- DCL- 0095- 0.54 111/85/8.4*13 EIDH- EM54 DCL- 0115- 0.45 125/90/9*18 EIDH- EM45 DCL- 0160- 0.36 100/98/9*18 EIDH- EM36 DCL- 0180- 0.33 100/98/9*18 PIDH- EM33 DCL- 0250- 0.26 176/115/11*18 EIDH- EM26 DCL- 0250-...
Page 226: Specifications Of Circuit Breakers, Cables And Contactors
Chapter 10 Options 10-14.Specifications of circuit breakers, cables and contactors Input line/output line Circuit Rated operational current A of contactor Model breaker(A) (voltage 380V or 220V) (Copper cable) R40G2 R75G2 1R5G2 2R2G2 004G2 5R5G2 7R5G2 100A 011G2 125A 015G2 160A 018G2 160A 022G2...
Page 227 Chapter 10 Options 045G3 200A 055G3 250A 075G3 315A 093G3 400A 110G3 400A 132G3 400A 160G3 630A 187G3 630A 200G3 630A 220G3 800A 150x2 250G3 800A 150x2 280G3 1000A 185x2 315G3 1200A 240x2 355G3 1280A 240x2 400G3 1380A 185x3 1035 500G3 1720A 185x3...
Page 228: Chapter 11 Warranty
Chapter 11 Warranty Chapter 11 Warranty The product quality shall comply with the following provisions: 1. Warranty terms 1-1. The product from the user the date of purchase, the warranty period of 12 months (limited to domestic market). 1-2. Export products and non-standard products warranty period is 12 months or according to the agreement of warranty execution.
Page 229: Appendix I Rs485 Communication Protocol
Appendix I Appendix I RS485 Communication protocol I-1 Communication protocol I-1-1 Communication content This serial communication protocol defines the transmission information and use format in the series communication Including: master polling( or broadcast) format; master encoding method, and contents including: function code of action, transferring data and error checking.
Page 230 Appendix I 9K-RS485_S connect to 9KLCB control board 9K-RS485_S connect to 9KSCB control board  Link RS485 communication cables to inverter control terminals (SG+), (SG-).  When using RS485 transform, connect Inverter “SG+” to RS485 “T+”, Inverter “SG-” to RS485 “T-”. ...
Page 231 Appendix I  F9.00 baud rate 0：300, 1：600, 2：1200, 3：2400, 4：4800, 5：9600;6： 19200;7：38400;8：57600;9：115200  F9.02current inverter communication address 1~247 (If there are more than 1 inverters, don‟t use the same number);  When using RS485 running control methods, set F0.11=2,choice RS485 running control method Match register 120ohm 1/4W...
Page 232 Appendix I result in an error, because the value in the final CRC field is not right. RTUframe format : Frame header START Time interval of 3.5characters Slave address ADR Communication address: 1 to 247 Command code CMD 03: read slave parameters；06: write slave parameters Data content DATA(N-1) Data content DATA(N-2) Data content: address of function code parameter, numbers of...
Page 233: I-2 Check Mode
Appendix I When F9.05 is set to 1: Byte number Data F002H high-order Data F002H low-order Data F003H high-order Data F003H low-order CRC CHK low-order CRC CHK values are to be calculated CRC CHK high-order Command Code: 06H, write a word. For example:Write 5000(1388H)into the address F00AH of the inverter with slave address 02H.
Page 234 Appendix I 8-bit data in each character is valid to the CRC, the start bit and stop bit, and parity bit are invalid. During generation of the CRC, each eight-bit character is exclusive OR(XOR) with the register contents separately, the result moves to the direction of least significant bit(LSB), and the most significant bit(MSB) is filled with 0.
Page 235: I-3 Definition Of Communication Parameter Address
Appendix I I-3 Definition of communication parameter address The section is about communication contents, it‟s used to control the operation, status and related parameter settings of the inverter. Read and write function-code parameters (Some functional code is not changed, only for the manufacturer use or monitoring): the rules of labeling function code parameters address: The group number and label number of function code is used to indicate the parameter address:...
Page 236 Appendix I 100B AI2 voltage 100C Reserve 100D Count value input 100E Length value input 100F Load speed 1010 PID setting 1011 PID feedback 1012 PLC step 1013 High-speed pulse input frequency, unit: 0.01kHz 1014 Feedback speed, unit:0.1Hz 1015 Remaining run time 1016 AI1 voltage before correction 1017...
Page 237 Appendix I Command word address Command function 0001: Forward run 0002: Reverse run 0003: Forward Jog 2000 0004: Reverse Jog 0005: Free stop 0006: Deceleration and stop 0007: Fault reset Inverter read status: (read-only) Status word address Status word function 0001: Forward run 3000 0002: Reverse run...
Page 238 Appendix I Command address Command content 2004 0 to 7FFF indicates 0％ to 100％ Inverter fault description: Inverter fault address: Inverter fault information: 0000: No fault 0001: Inverter unit protection 0002: Acceleration overcurrent 0003: Deceleration overcurrent 0004: Constant speed overcurrent 0005: Acceleration overvoltage 0006: Deceleration overvoltage 0007: Constant speed overvoltage...
Page 239 Appendix I 0000: No fault 0001: Password error 0002: Command code error 0003: CRC check error 0004: Invalid address 8001 0005: Invalid parameters 0006: Invalid parameter changes 0007: System locked 0008: EEPROM in operation F9 Group - Communication parameter description 6005 Baud rate Default...
Page 240 Appendix I 0.0 s Communication Default timeout time F9.04 0.0 s(invalid) Setting range 0.1 to 60.0s Communication time-out parameter is not valid when the function code is set to 0.0s. Whenthe function code is set to valid, if the interval time between one communication and the next communication exceeds the communication time-out time, the system will report communication failure error (Fault ID Err.16).
Page 241: Appendix Ii How To Use Universal Encoder Expansion Card
Appendix II Appendix II How to use universal encoder expansion card (applicable for all series of Powtran frequency inverters) II-1 Overview PI9000 is equipped with a variety of universal encoder expansion card (PG card), as an optional accessory, it is necessary part for the inverter closed -loop...
Page 242 Appendix II Maximum 500kHz frequency ≤7V Input differential signal amplitude PI9000_PG1 terminal signals Label no. Description Encoder output A signal positive Encoder output A signal negative Encoder output B signal positive Encoder output B signal negative Encoder output Z signal positive Encoder output Z signal negative Output 5V/100mA...
Page 243 Appendix II signal positive Encoder output Z signal negative Encoder output P signal positive Encoder output P signal negative Encoder output V signal positive Encoder output V signal negative Encoder output W signal positive Encoder output W signal negative Output 5V/100mA power Power ground Rotational transformer PG...
Page 244 Appendix II negative COSLO Rotary transformer feedback COS negative OC PG card(PI9000_PG5) PI9000_PG5 specifications User interface Terminal block Spacing 3.5mm Screw Slotted Swappable Wire gauge 16-26AWG Maximum 100KHz frequency PI9000_PG5 terminal description Label no. Description Encoder output A signal Encoder output B signal Encoder output Z signal...
Page 245: Appendix Ⅲ Description On Proportion Linkage Function
Appendix III Appendix Ⅲ Description on proportion linkage function (this function available in C2.08 and above) Ⅲ-1.Function Proportional linkage master: Communication address of master =248 Proportional linkage slave: Communication address of slave =1 to 247 If you want to use proportion linkage function, master parameters setting as follows: F9.00 Same as slave...
Page 246 Appendix III Frequency source master F0.03 2: Analog AI1 setting setting DI1 input terminal F1.00 1. FRW run command function selection DI2 input terminal F1.01 2. REV run command function selection F9.00 Baud rate 6005 Communication address Proportional linkage F9.02 of this unit master 248 F9.03...
Page 247 Appendix III (L1) U (T1) Master 380V 50/60Hz S (L2) V (T2) Inverter 3-phase input W (T3) T (L3) PI9000 1： FRW run command +10V 2： 0 +10V REV run command 1K/2W E(PE) RS485 Communication Card (L1) U (T1) Slave 380V 50/60Hz S (L2) V (T2)
Page 248: Appendix Iv Can Bus Communication Card Use Description
Appendix IV Appendix IV CAN bus communication card use description IV-1.Overview CAN bus communication card is suitable for all series of PI9000 frequency inverters.Protocol details,please refer to《CAN bus communication protocol》 document. IV-2.Mechanical installation and terminal functions IV-2-1 Mechanical installation modes: Diagram 2.1 CAN bus communication card ‟s installation on SCB Diagram 2.2 CAN bus communication card‟s installation on LCB IV-2-2 Terminal function...
Page 249 Appendix IV Terminal Class Terminal Name Description Symbol CANH communication CANcommunication input interface terminal terminal CANL CAN communication communicat power ground CANcommunication power output terminal CAN communication output power...
Page 250: Appendix V Profibus-Dp Communication Card Use Description
Appendix V Appendix V Profibus-DP communication card use description V-1.Outline 9KDP1 meet the international standard PROFIBUS fieldbus, powtran technology 9K series inverter use it together to achieve the drive to become a part of fieldbus complete control of real fieldbus. Before using this product, please carefully read this manual V-2.Terminal function...
Page 251: V-2-3.Led Indicator Functions
Appendix V PC232R PC 232 receiving end RREST ARM Reset Digital Ground Table 2.3 PC Communication Terminal Function V-2-3.LED Indicator Functions LED Indicator Function Definition Description If DP card and drive interfaces Green Power Indicator connected, the inverter after power LED should be in the steady state DP Card and inverter connected to the normal state of the LED is lit,...
Page 252: Warranty Card
Warranty Card Sincerely thank you purchase Powtran products ! This product has passed the strict quality inspection by Powtran. According to the instructions of this warranty card, Powtran will be responsible for free maintenance for all hardware failures caused by product quality problem under normal use during the warranty period.
Page 253: Warranty Card
Warranty Card Sincerely thank you purchase Powtran products ! This product has passed the strict quality inspection by Powtran. According to the instructions of this warranty card, Powtran will be responsible for free maintenance for all hardware failures caused by product quality problem under normal use during the warranty period.
Page 254 Customer Feedback Form of Powtran Inverter Failure Dear Customer: please fill out the form below in details so that we may better serve you: Load and control situation Frequency Electrical range Rated motor power current under normal and poles working □Fan□Textile...
Page 255 Maintenance records: Full name of maintenance agency 1st time Address Zip Code Maintenance Signature voucher of the number serviceman Full name of maintenance agency Address Zip Code time Maintenance Signature voucher of the number serviceman Full name of maintenance agency Address Zip Code time...
Page 256 Product Information Feedback Dear user: Thank you for your interest in and purchasing Powtran products! In order to better serve you, we want to be able to timely get your personal information and the related information of the purchased Powtran products so as to understand your current and future further demand to Powtran products, we would appreciate your valuable feedback.

Powtran PI9000 series User Manual

Chapter 1.Inspection And Safety Precautions

Chapter 2 Standard Specifications

Chapter 3 Keyboard

Chapter 4 Commissioning

Chapter 5 Function Parameter

Chapter 6 EMC (Electromagnetic Compatibility)

Chapter 7 Troubleshooting

Chapter 8 Installation and Spare Circuit

Chapter 9 Maintenance and Repair

Chapter 10 Options

Chapter 11 Warranty

Appendix I RS485 Communication Protocol

Appendix II How to Use Universal Encoder Expansion Card

Appendix Ⅲ Description on Proportion Linkage Function

Appendix IV CAN Bus Communication Card Use Description

Appendix V Profibus-DP Communication Card Use Description

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