Alpha 6000S series User Manual
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Alpha 6000S series User Manual

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  • Page 2: Preface

    Preface Preface Thank you for using ALPHA6000S, ALPHA6000V, ALPHA6700S series inverters. This series of inverters adopt the most advanced inverter current vector control technology, low-speed rated torque output, ultra-quiet and stable operation and built-in or external PG functions, can easily achieve closed-loop control. They are characterized by diverse control modes, up to 36 perfect protection and alarm functions, on-line monitoring and on-line adjustment of a variety of parameters, built-in RS-485 communication interface, flexible operation, and can satisfy various needs of users.
  • Page 3 Foreword Danger!  This equipment contains dangerous voltage ,Not accord with the warning or breach this manual operation. Electric shock can cause serious or fatal injury. Only qualified personnel shall wire the drive.  Please cut off the power before wiring and inspecting. It is not permissible to touch PCB or interior components before battery control lamp goes off or until 5 minutes after the power has been removed.

  • Page 4: Table Of Contents

    Table of Contents Contents Preface..............................1 Chapter 1 Purchase Inspection......................6 1.1 Unpacking Inspection..................... 6 1.2 Naming Rule........................6 1.3 Nameplate of Inverter..................... 7 Chapter 2 Installation and Wiring....................8 2.1 External Dimension and Installation Dimension (See Appendix 1)......8 2.2 Mounting Place Requirements and Management............8 2.2.1 Installation Location....................
  • Page 5 Table of Contents Chapter 4 Parameter Index......................48 Chapter 5 Detailed Function Introductions..................90 5.1 Basic Function (Group P0)................... 90 5.2 Start/Stop Control (Group P1)..................94 5.3 Auxiliary Operation (Group P2)................. 103 5.4 I/O Terminal Ctrl (Group P3)..................108 5.5 Analog and pulse function (Group P4)............... 125 5.6 PLC Operating (Group P5)..................
  • Page 6 Table of Contents Appendix 1 External Dimension and Installation Dimension(Unit: mm)........ 187 Appendix 2 Technical Specifications..................195 Appendix 3 Recommendation for Selection of the Main Circuit Output Cable.......197 Appendix 4 Use of MODBUS Communication............... 198 Appendix 5 Keypad Installation Dimension (Unit: mm)............212 Appendix 6 LCD Keypad Use Instruction................214 A6.1 LCD Keypad Instruction..................214 A6.2 LCD Use Instruction....................

  • Page 7: Chapter 1 Purchase Inspection

    Chapter 1 Purchase Inspection Chapter 1 Purchase Inspection 1.1 Unpacking Inspection All inverters have passed the strict tests before delivery. After unpacking, please check if the product was damaged by careless transport, the product specification, and model is complied with the order, and if it has a quality check passed mark.

  • Page 8: Nameplate Of Inverter

    Chapter 1 Purchase Inspection 1.3 Nameplate of Inverter On the right side of the bottom plate of inverter, there is a nameplate, which marks the model and rated value of inverter. See the following Figure: Inverter model Adaptive motor model Rated input voltage, current, frequency Rated output voltage, current,...

  • Page 9: Chapter 2 Installation And Wiring

    Chapter 2 Installation and Wiring Chapter 2 Installation and Wiring External Dimension and Installation Dimension (See Appendix 2.2 Mounting Place Requirements and Management Attention ·Don’t carry the inverter by its cover. The cover cannot support the weight of the inverter and may drop. ·Please install the inverter on a strong support, failing which the inverter may fall off.

  • Page 10: Ambient Temperature

    Chapter 2 Installation and Wiring  Derating use must be considered when the inverter is installed at high altitude, greater than 1000 m. This is because the cooling effect of inverter is deteriorated because of the thin air. Derating 6% per 1000 m higher of the altitude.

  • Page 11: Main Circuit Wiring

    Chapter 2 Installation and Wiring 2.4 Main Circuit Wiring 2.4.1 The Main Circuit Terminals Arrangement and wiring Input power Braking resistor Ground wire Electric motor Fig. 2-2 Wiring of terminals of major loops of S2R4GB ~ S2R75GB models Table 2-1 Function and description of terminals of major loops of S2R4GB~S2R75GB Terminal Terminal name and function symbol...
  • Page 12 Chapter 2 Installation and Wiring Ground wire Input power Braking resistor Electric motor Fig. 2-4 Wiring of terminals of major loops of 3R75GB ~ 3004GB models Table 2-3 Function and description of terminals of major loops of 3R75GB~3004GB Terminal symbol Terminal name and function R.S.T Three-phase AC 380V input terminal...
  • Page 13 Chapter 2 Installation and Wiring braking resistor cables Notes: When a DC reactor is not connected, the supplied short circuit sheet should be short-circuited with "P1" and "+ / B1" PE conductor core and shield layer Braking unit Braking Reactor Motor Input power resistor Fig.
  • Page 14 Chapter 2 Installation and Wiring Lower wiring board Upper wiring board Braking unit (external, optional) Input power Reactor (built-in, Electric motor Braking unit standard) (external, optional) Fig. 2-7 Terminals of major loops of 3160G ~ 3355G models Lower wiring board Upper wiring board Braking unit (external, optional)

  • Page 15: Main Circuit Wiring Operation

    Chapter 2 Installation and Wiring Notes: When a DC reactor is not connected, the supplied short circuit sheet should be short-circuited with "P1" and "+" 2.4.2 Main Circuit Wiring operation When the motor is running, please make sure if it is in positive rotation while the motor receives positive rotation command.

  • Page 16: Control Circuit Connection

    Chapter 2 Installation and Wiring The longer the distance between the inverter and the motor, the higher the carrier frequency would be, and the greater the high harmonic leakage current of the cables would be. Leakage current has a negative impact to inverters and Equipment nearby, so reduce leakage current as little as possible.
  • Page 17 Chapter 2 Installation and Wiring BRB BRC 24V1 PLC1 COM1 COM1 CME1 Fig. 2-13 Terminal arrangement of extension board (optional for 35R5GB and above models) In order to reduce interference and attenuation of control signal, the length of control cables should be limited in 50m and away from power cables for more than 30cm.
  • Page 18 Chapter 2 Installation and Wiring Catego Terminal Description of terminal Name Specification label function Multi-function input It can be defined as a terminal 1 multi-function on-off input terminal through Multi-function input programming, please see terminal 2 Section 5.4 of Chapter V Function Description of Input Opto-coupler isolation input Terminals of I/O Terminal...
  • Page 19 Chapter 2 Installation and Wiring Catego Terminal Description of terminal Name Specification label function multi-function on-off output output terminal through Range of operating voltage: 0V~26V Open collector output programming, please see Maximum output current: 50mA Section 5.4 of Chapter V Function Description of Y terminals are exclusive for 35R5GB Output Terminals of I/O...

  • Page 20: Wiring Of Control Circuit Terminals

    Chapter 2 Installation and Wiring Catego Terminal Description of terminal Name Specification label function output terminal Y1 multi-function output leaving the factory terminal Y1 Internal isolation between CME and Common port of Common port of output terminals Isolated to GND, and short connected CME1 multi-function output Y2~Y3 of IO...
  • Page 21 Chapter 2 Installation and Wiring In 35R5GB and above models, analog output terminal AO1 /AO2 external connecting analog meter can indicate a variety of physical quantities. Slide switch SW2/SW5 select the output voltage (0/2 ~ 10V) or the output current (0/4 ~ 20mA).
  • Page 22 Chapter 2 Installation and Wiring +24V +24V 24V1 PLC1 - DC - DC X1 ~ X6 X7 ~ X10 COM1 Fig. 2-19 Connection diagram while using an external Fig. 2-20 Connection diagram while using outside power supply (control board) power supply (extension board) NOTE: Remove the short jumper JP1 connecting NOTE: Remove the short jumper JP1 connecting internal PLC and 24V...
  • Page 23 Chapter 2 Installation and Wiring External controller External controller 外部控制器 外部控制器 24V1 24V DC 24V DC COM1 PLC1 Near-end of shield 屏蔽线近端接地 Near-end of shield 屏蔽线近端接地 line is grounded line is grounded Fig. 2-23 Connection diagram while using drain Fig. 2-24 Connection diagram while using drain electrode of internal + 24V power supply (control electrode of internal + 24V power supply (extension board)
  • Page 24 Chapter 2 Installation and Wiring External controller External controller 外部控制器 外部控制器 9 ~ 30V 9 ~ 30V 24V1 24V DC 24V DC COM1 PLC1 Near-end of shield 屏蔽线近端接地 屏蔽线近端接地 Near-end of shield line is grounded line is grounded Fig. 2-27 Connection diagram while using drain Fig.
  • Page 25 Chapter 2 Installation and Wiring 3) Multi-function output terminals / Pulse output terminal DO as pulse output can use the internal 24V power supply and the wiring is shown in Figure 2-31. +24V +24V Digital frequency 数字频率计 statistics Fig. 2-31 Digital pulse output connection mode 1 of multi-function output terminals 4) Multi-function output terminals / Pulse output terminal DO as Pulse output can also use the external, 9~30V, power supply and the wiring is shown in Figure 2-32 +24V...
  • Page 26 Chapter 2 Installation and Wiring 6) Multi-function output terminals Y1, Y2, Y3 also can use external power (9~30V) with the connection modes as shown in Fig. 2-35(control board) and Fig. 2-36(extension board). +24V +24V 24V1 DC 9 ~ 30V DC 9 ~ 30V Y2 Y3 Relay 继电器...
  • Page 27 Chapter 2 Installation and Wiring Upper computer RS232/RS485 converter Pin No. Signal Terminal name Description of terminal Shielded cable Positive terminal of 5V Enclosure power supply Inverter Negative terminal of 5V power supply RS485 communication interface Terminal name Description of terminal Terminal name Description of terminal Negative terminal of...
  • Page 28 Chapter 2 Installation and Wiring ● Description of keypad interface Keypad connection interface CN5 on the control board adopts 8PIN drop-out lines with fool-proof ports. Users can customize extended keypad cable according to actual needs. But the keypad extension cable does not exceed 15 m, because when it exceeds 15 m, normal work cannot be guaranteed.

  • Page 29: Wiring Of Inverter For Basic Operation

    Chapter 2 Installation and Wiring 2.6 Wiring of Inverter for Basic Operation Braking resistor 制动电阻 (external, optional) (外接、选配件) Circuit breaker 断路器 Single phase 单相 220V 50/60HZ Analog output 模拟量输出 0/4~20mA current signal 0/4 ~ 20mA 0/4 ~ 20mA电流信号 Multi-function input 0/2~10V voltage signal 多功能输入选择1 0/2 ~ 10V...
  • Page 30 Chapter 2 Installation and Wiring Braking resistor 制动电阻 (external, optional) (外接、选配件) Circuit 断路器 breaker Three-phase 三相 380V 50/60HZ Analog output 模拟量输出 0/4~20mA current signal 0/4 ~ 20mA 0/4 ~ 20mA电流信号 0/2~10V voltage signal Multi-function input 多功能输入选择1 0/2 ~ 10V 0/2 ~ 1 0V电压信号 selection 1 Multi-function input 多功能输入选择2...
  • Page 31 Chapter 2 Installation and Wiring Braking resistor DC reactor (external,optional) (external,optional) P1 +/B1 Circuit breaker Three-phase 380V 50/60HZ Multi-function input 0/4 ~ 20mA selection 1 Multi-function input 0/2 ~ 10V selection 2 Analog output Multi-function input 0/4 ~ 20mA current signal selection 3 Multi-function input 0/2 ~ 10V voltage signal...
  • Page 32 Chapter 2 Installation and Wiring DC reactor (externally Brake unit and braking resistor connected ALPHA6000S-3132G (external,optional) and the following options) Circuit breaker Three-phase 380V 50/60HZ Multi-function input 0/4 ~ 20mA selection 1 Multi-function input 0/2 ~ 10V selection 2 Analog output Multi-function input selection 3 0/4 ~ 20mA current signal...
  • Page 33 Chapter 2 Installation and Wiring Wiring Attention  Be sure the input power supply of the inverter is cut off then you can remove or replace the motor.  Be sure the inverter has stopped output then you can switch the motor or the power supply. ...

  • Page 34: Chapter 3 Operation

    Chapter 3 Operation Chapter 3 Operation Only turn on the input power supply after replacing the front cover. Do not remove the cover while the inverter is powered up. When the retry function is selected, do not approach the inverter or the load, since DANGER it may restart suddenly after being stopped.

  • Page 35: Description Of Button Function

    Chapter 3 Operation In monitoring status, the LED will display the content of current monitoring object. At abnormal state It will display the fault code when the inverter falls to run and show the warn code when the inverter is warning. At normal state, it will display the object selected by parameter group PC.

  • Page 36: Description Of Led Digitals And Indicators

    Chapter 3 Operation Table 3-2 Keypad menu Name of key Key functions Enter or exit programming mode. In monitoring mode, press PRG/ESC key to switch to programming mode. First, enter function group, and press ENTER key to enter function code and function parameters progressively; press PRG/ESC, it Programming/Ex will enter function parameters, then function code, function group, next monitoring state, exit step by step like this;...

  • Page 37: Display State Of Keypad

    Chapter 3 Operation Table 3-3 Description of state indicators Indicator Display state The current state of the inverter indicated Stop Running RUN Running-state LCDs Flicker Zero frequency operation Reverse rotation or not run Normally on Stable positive rotation FWD Forward running direction indication Quick flash Acceleration and deceleration of positive rotation...
  • Page 38 Chapter 3 Operation keypad will go to programming state, to see the details, please see the parameter values of group PE. To reset the STOP inverter, press the key or control terminals or serial communication. If the fault signal is still exist, the RESET keypad will keep the fault code displaying and the indicator TRIP lighting R U N...

  • Page 39: Operation Method Of Keypad

    Chapter 3 Operation operation can be carried out by pressing key, and it can exit by pressing key. ENTER Second-level First-level Third-level menu menu menu Shutdown state parameter display or operation state Editing mode parameter display or fault alarm display Figure 3-4 Display menus of programming state 3.1.5 Operation method of keypad Here are some examples of how to run the inverter by the keypad:...
  • Page 40 Chapter 3 Operation Setting of function code parameters: (example of changing Jog acceleration time, function code P2.01 from 6.0s to 3.2s) Display P 2.00 -P 0- -P 2- P 2.01 0.00 006.0 003.0 of LED P R G Operation E N T E R E NT E R E N T E R E S C...

  • Page 41: Run Command Mode Select

    Chapter 3 Operation display display operation operation Confirm JOG key acts Enter editing While pressing the Press ENTER function code as UP key, mode, display Shift key and JOG key to enter and enter the press JOG key the first-level key at the same display of second-level...

  • Page 42: Check Points Before Running

    Chapter 3 Operation P0.03 to 12) , the inverter will come into Wobble frequency operation. The Wobble frequency running parameters can be modified in parameter group P6. By selecting a multi-function terminal and setting the value to 46, connecting the terminal to terminal “COM”, Wobble frequency operation state can be reset (For details please see Chapter IV Function of P3) ...
  • Page 43 Chapter 3 Operation O p e r a t i o n m o d e o f i n v e r t e r Y E S JOG active JOG running Y E S PID termianl PID running active Y E S Wobble frequency...

  • Page 44: Operation Of Initial Power On

    Chapter 3 Operation 3.3.4 Operation of initial power on Please follow technical requirements provided in this manual for wiring and connections. After correct wiring and checking power supply, power on air switch of AC power on input side of the inverter to supply power to the inverter, the contactor operates normally.

  • Page 45: First Test Run Operation

    Chapter 3 Operation S t a r t w i r i n g a s t h e r e q u i r e m e n t s t a t e d i n t h i s m a n u a l w i r i n g i s r i g h t .
  • Page 46 Chapter 3 Operation Start 开始 确认接线正确后上电 Power on after correct wiring Recovery factory parameters 恢复出厂参数(设置PF.02=3) (set PF.02 = 3) Set fundamental frequency P0.09, maximum output voltage 按照电机铭牌设定基本频率P0.09、最大输出电压P0.1 P0.16, motor parameters P0.14, PA.01-PA.04 (PA.15-PA.18) in 6、电机参数P0.14、PA.01-PA.04(PA.15-PA.18) accordance with the motor nameplate. Control manner select 选择控制方式...

  • Page 47: Commissioning Of Keypad

    Chapter 3 Operation 3.4 Commissioning of keypad Assume that the inverter need to run forward at 30.00 Hz at first, then run reverse at the same frequency. Using the keypad can take the following steps to realize the task: A typical operation pattern using the keypad: Fo rward 3 0 .0 0 H z Rev erse...
  • Page 48 Chapter 3 Operation Sequence of terminal operation: Forward 30.00Hz Power Frequency Running Stop setting Figure 3-16 Sequence of terminal operation Operation steps: Figure 3-17 Flow chart of running and stop operation by terminal...

  • Page 49: Chapter 4 Parameter Index

    Chapter 4 Parameter Index Chapter 4 Parameter Index Notes: “○”means that the parameters can be changed during inverter running and stop state; “×”means that the parameters cannot be changed during running; “*” means that the actually measured value or fixed parameters cannot be changed; “-”...
  • Page 50 Chapter 4 Parameter Index MODB Functi Factory Parameter LCD display Setting range Mod. on code setting address 0: Frequency setting source 1 1: Frequency setting source 2 2: MIN (frequency setting source 1, frequency setting source 2) 3: MAX (frequency setting source 1, frequency setting source 2) 4: Frequency setting source 1 +...
  • Page 51 Chapter 4 Parameter Index MODB Functi Factory Parameter LCD display Setting range Mod. on code setting address 3004GB and below: MAX [50.00Hz, upper limit frequency, set frequency, multi-stage frequency, jumping Maximum output Maximum frequency] ~ 650.0Hz P0.10 50.00Hz × 010A frequency frequency 35R5GB and above:...
  • Page 52 Chapter 4 Parameter Index P1: Start-stop control Function MODBUS Parameter LCD display Setting range Factory setting Mod. code address 0: Start from the start frequency 1: First brake (excitation), and then start at the start frequency 2: Rotating speed tracking (must be connected to PG or rotating speed tracking P1.00...
  • Page 53 Chapter 4 Parameter Index Function MODBUS Parameter LCD display Setting range Factory setting Mod. code address S curve S curve 10.0-80.0 % (acceleration and P1.09 ascending ascending deceleration time) 60.0% 0209 ○ segment time segment P1.08+P1.09≤90% 0: Deceleration stop P1.10 Stop mode Stop mode 1: Free stop...
  • Page 54 Chapter 4 Parameter Index Function MODBUS Parameter LCD display Setting range Factory setting Mod. code address Operation Instantaneous selection after power failure 0: Failure to actuate P1.22 ○ 0216 instantaneous operation 1: Slowdown running stop alarm selection Rate of deceleration Deceleration during rate of...
  • Page 55 Chapter 4 Parameter Index P2: Auxiliary run Function Factory MODBU Parameter name LCD display Setting range Mod. code setting S address 0.10Hz~upper limit P2.00 Jog frequency Jog frequency 5.00Hz 0300 ○ frequency 22kW and Power ≤ 132kW below: Jog acceleration 0.1~3600s P2.01 acceleration...
  • Page 56 Chapter 4 Parameter Index Function Factory MODBU Parameter name LCD display Setting range Mod. code setting S address Hopping Hopping frequency P2.12 frequency 0.00~15.00Hz 0.00Hz 030C × amplitude amplitude Multi-stage Multi-stage P2.13 5.00 Hz 030D frequency 1 frequency 1 Multi-stage Multi-stage P2.14 8.00 Hz...
  • Page 57 Chapter 4 Parameter Index Function Factory MODBU Parameter name LCD display Setting range Mod. code setting S address 0: Automatic mode P2.36 Cooling fan control Fan control 1: Running after power 0324 × Wiring Wiring direction of 0: Positive sequence P2.37 direction of 0325...
  • Page 58 Chapter 4 Parameter Index P3: Switching value I / O terminal control This page is only for 3004GB and below models Function Factory MODBUS Parameter LCD display Setting range Modify address code setting 0: Closing is active Mode of terminal Mode of 1: Open is active (normally P3.00...
  • Page 59 Chapter 4 Parameter Index This page is only for 3004GB and below models Function Factory MODBUS Parameter LCD display Setting range Modify address code setting normally open 38: EH1 external fault normally closed 39: EI0 external interrupt normally open 40: EI1 external interrupt normally closed 41: Stopping state plus DC braking...
  • Page 60 Chapter 4 Parameter Index This page is only for 3004GB and below models Function Factory MODBUS Parameter LCD display Setting range Modify address code setting P3.08 Reserve Reserve 0408 P3.09 Reserve Reserve 0409 P3.10 Reserve Reserve 040A P3.11 Reserve Reserve 040B P3.12 Reserve...
  • Page 61 Chapter 4 Parameter Index This page is only for 3004GB and below models Function Factory MODBUS Parameter LCD display Setting range Modify address code setting 9: PLC cycle completion indication 10: Completion of readiness for operation of inverter (RDY) 11: Free stopping 12: Auto restart 13: Timing reaching 14: Counting reaching output...
  • Page 62 Chapter 4 Parameter Index This page is only for 35R5GB and above models Functi Factor Parameter LCD display Setting range addres code setting 0: Closing is active Mode of terminal Mode of 1: Open is active (normally P3.00 0400 × action terminal action open / normally closed is...
  • Page 63 Chapter 4 Parameter Index This page is only for 35R5GB and above models Functi Factor Parameter LCD display Setting range addres code setting 37: EH0 external fault normally open 38: EH1 external fault normally closed 39: EI0 external interrupt normally open 40: EI1 external interrupt normally closed 41: Stopping state plus DC...
  • Page 64 Chapter 4 Parameter Index This page is only for 35R5GB and above models Functi Factor Parameter LCD display Setting range addres code setting measurement Phase B pulse input phase X7 terminal X7 terminal P3.07 × 0407 function function X8 terminal X8 terminal P3.08 ×...
  • Page 65 Chapter 4 Parameter Index This page is only for 35R5GB and above models Functi Factor Parameter LCD display Setting range addres code setting 6: upper and lower limits of wobble frequency 7: Inverter is in zero speed operation 8: Simple PLC stage operation completion indication 9: PLC cycle completion...
  • Page 66 Chapter 4 Parameter Index This page is only for 35R5GB and above models Functi Factor Parameter LCD display Setting range addres code setting (ULP)
  • Page 67 Chapter 4 Parameter Index Functi Factory Parameter LCD display Setting range setting addres code Frequency P3.26 reaching FAR FAR width 0.00~10.00Hz 2.50Hz ○ 041A detection width 0.00-maximum P3.27 FDT level FDT level 50.00Hz 041B ○ frequency P3.28 FDT lag FDT lag 0.00~10.00Hz 1.00Hz ○...
  • Page 68 Chapter 4 Parameter Index P4: Analog and pulse input and output terminals Function Factory MODBUS Parameter LCD display Setting range Mod. address code setting Analog Analog nonlinear 0: No 1: AI1 P4.00 nonlinear 0500 × selection 2: AI2 3: Pulse selection Input value of AI1 AI1 minimum...
  • Page 69 Chapter 4 Parameter Index Function Factory MODBUS Parameter LCD display Setting range Mod. address code setting Corresponding Minimum -100.0%~100.0% physical quantity of corresponding Reserve for 3004GB P4.17 0.0% ○ 0511 input value of AI3 physical quantity and below models minimum analog of AI3 P4.16~10.00V Input value of AI3...
  • Page 70 Chapter 4 Parameter Index Function Factory MODBUS Parameter LCD display Setting range Mod. address code setting P4.28 AO1 Gain AO1 Gain -10.00~10.00 1.00 051C ○ -10.00~10.00 P4.29 AO2 Gain AO2 Gain 1.00 ○ 051D Reserve for 3004GB P4.30 AO3 Gain AO3 Gain 1.00 051E...
  • Page 71 Chapter 4 Parameter Index P5: PLC run Facto Functi Parameter LCD display Setting range settin addres code 0: Single cycle 1 1: Single cycle 2 (keeping P5.00 Program run mode Program run mode 0600 × the final value) 2: Continuous cycle 0: Start running from the first stage 1: Continue to run at the...
  • Page 72 Chapter 4 Parameter Index Facto Functi Parameter LCD display Setting range settin addres code Setting of program Program running P5.19 ○ 0613 running on T1 stage setting 1 Setting of program Program running P5.20 0614 ○ running on T2 stage setting 2 Setting of program Program running...
  • Page 73 Chapter 4 Parameter Index P6: Cut-to-length and textile wobble frequency Functi Factory Parameter LCD display Setting range setting addres code Max (0.000,-P6.06) (fixed length P6.00 Set length Set length stopping function is inactive) ~ 0.000 m ○ 0700 65.53 m Actual 0.000 ~ 65.53 m (save after power P6.01...
  • Page 74 Chapter 4 Parameter Index Stochastic Stochastic P6.18 swing ratio swing ratio 0.1~10.0 0712 ○...
  • Page 75 Chapter 4 Parameter Index P7: PID control Functi Parameter Factory difi LCD display Setting range name setting cati addres code 0: PID digital setting 1: AI1 terminal 2: AI2 terminal PID setting PID setting 3: Terminal AI3 (reserve for P7.00 0800 ×...
  • Page 76 Chapter 4 Parameter Index Functi Parameter Factory difi LCD display Setting range name setting cati addres code Analog PID Analog PID P7.07 1.0~1000.0 100.0 ○ 0807 setting range setting range Speed Speed P7.08 0~24000rpm 0rpm 0808 ○ digital setting digital setting Proportional P7.09 Scale factor 1...
  • Page 77 Chapter 4 Parameter Index P8: Vector control parameters Functi Factory difi Parameter LCD display Setting range setting cati addres code 0.0~500.0% 100.0% corresponds to the Pre-excitation motor no-load current; the Pre-excitation current response time is set in P1.04 P8.00 current 100.0% 0900 ×...
  • Page 78 Chapter 4 Parameter Index Functi Factory difi Parameter LCD display Setting range setting cati addres code Torque Torque P8.16 deceleration 0.00~120.0s 0.50s ○ 0910 deceleration time time Estimated low Estimated low P8.17 speed slip speed slip 50.0%~200.0% 130.0% ○ 0911 compensation compensation Estimated high...
  • Page 79 Chapter 4 Parameter Index P9: V / F control parameter Setting range Factory Functi setting difi Parameter name LCD display cati addres code 0: Constant torque 0A00 × characteristic curve 0 1: Lower torque characteristic curve 1 (2.0) 2: Lower torque V / F curve V / F curve characteristic curve 2...
  • Page 80 Chapter 4 Parameter Index Setting range Factory Functi setting difi Parameter name LCD display cati addres code 0: Failure to actuate 0A10 × 1: Run all the time P9.16 AVR function AVR function 2: Not act only during deceleration Overmodulation Overmodulatio 0: Invalid 1: Valid 0A11...
  • Page 81 Chapter 4 Parameter Index PA: motor parameters Functi Factory difi Parameter name LCD display Setting range setting cati addres code 0: Use motor 1 PA.00 Motor selection Motor selection × 0B00 1: Use motor 2 Number of poles of Number of PA.01 2~56 0B01...
  • Page 82 Chapter 4 Parameter Index Functi Factory difi Parameter name LCD display Setting range setting cati addres code Saturation coefficient Saturation PA.24 0.0%~100.0% ○ 0B18 1 of motor 2 coefficient 1 Saturation coefficient Saturation PA.25 0.0%~100.0% 0B19 ○ 2 of motor 2 coefficient 2 Saturation coefficient Saturation...
  • Page 83 Chapter 4 Parameter Index Pb: MODBUS communication Functi Factory difi Parameter name LCD display Setting range setting cati addres code 0: 1200bps 1: 2400bps Baud rate Baud rate Pb.00 2: 4800bps 3: 9600 bps × 0C00 selection selection 4: 19200bps 5: 38400bps Pb.01 Local address Local address...
  • Page 84 Chapter 4 Parameter Index Functi Factor Parameter name LCD display Setting range addres code setting Set speed Set speed PC.06 0: Not displayed 1: Displayed 0D06 ○ (R / min blink) (R / min blink) Running line Running line PC.07 speed speed 0: Not displayed 1: Displayed...
  • Page 85 Chapter 4 Parameter Index Functi Factor Parameter name LCD display Setting range addres code setting 0.1~999.9% Line speed = operating frequency × PC.23 (non-PG) Line speed = mechanical speed × PC.23 (PG) Line speed Line speed 100.0 PC.23 Set line speed = set frequency 0D17 ○...
  • Page 86 Chapter 4 Parameter Index Pd: protection and fault parameters Function Modif MODBU Parameter name LCD display Setting range Setup code ication S address 0: Failure to actuate 1: Common motor (with low speed compensation) Motor overload Overload 2: Variable frequency Pd.00 protection mode protection...
  • Page 87 Chapter 4 Parameter Index Function Modif MODBU Parameter name LCD display Setting range Setup code ication S address installing braking resistor) 1: Allowed 3004GB and below: 110.0 220V ~ 150.0% of the bus models: Overvoltage stall Overvoltage stall voltage 120% Pd.11 ×...
  • Page 88 Chapter 4 Parameter Index Function Modif MODBU Parameter name LCD display Setting range Setup code ication S address 1: The control terminal is closed 2: Output current exceeds the set point or control terminal is closed 3: Timing cycle execution Stall action Stall action Pd.25...
  • Page 89 Chapter 4 Parameter Index PE: Run history record Function Parameter Factory Modif MODBU LCD display Setting range code name setting ication S address 0: NULL 1: Uu1 bus undervoltage 2: Uu2 control circuit undervoltage 3: Uu3 poor charging circuit 4: OC1 acceleration overcurrent 5: OC2 deceleration overcurrent 6: OC3 constant speed overcurrent...
  • Page 90 Chapter 4 Parameter Index Function Parameter Factory Modif MODBU LCD display Setting range code name setting ication S address frequency frequency PE.02 when the 0~upper limit frequency 0.00Hz 0F02 when a fault latest fault occurs occurs Output Output current current PE.03 when the 0 ~ 2 times of the rated current...
  • Page 91 Chapter 4 Parameter Index PF: Parameter protection and product identification information Function Factory MODBUS Parameter name LCD display Setting range Modify address code setting 0: No password PF.00 User password User password 1000 ○ Other: Password protection 0: All parameters are allowed to be rewritten 1: Except for setting frequency Parameter...
  • Page 92 Chapter 5 Detailed Function Introductions Chapter 5 Detailed Function Introductions 5.1 Basic Function (Group P0) P0.00 Menu display mode Setting range: 0~1 [0] 0: Standard menu 1: Check mode menu Notes:  Pressing “FWD/REV” will switch the direction, and change the value of this parameter P0.08. But the changed direction only takes effect currently.
  • Page 93 Chapter 5 Detailed Function Introductions  Tips: The changed value of P0.02 by keypad digital encoder will be active immediately. If press "ENTER" key, the value will be stored into the inverter’s internal EEPROM and will not be lost even power-off the inverter. When P0.03is set to 1: if P3.18 is set to2, the changed value of P0.02 by keypad digital encoder will be saved when power loss.
  • Page 94 Chapter 5 Detailed Function Introductions setting source 2) source 2) 4: Frequency setting source 1+Frequency setting 5: Frequency setting source 1-Frequency setting source 2 source 2 6: Frequency setting source 1 x Frequency setting 7: Frequency setting source 1÷Frequency setting source 2 source 2 9: Frequency setting source2 ×...
  • Page 95 Chapter 5 Detailed Function Introductions Setting range: 3004GB and below: 0.10 ~ 650.0Hz 35R5GB and above: P0.09 fundamental frequency 0.10~400.0Hz Setting range: 3004GB and below: MAX [50.00Hz, upper limit frequency, set P0.10 maximum output frequency, multi-stage frequency, hopping frequency] ~ 650.0Hz [50.00Hz] frequency 35R5GB and above: MAX [50.00Hz, upper limit frequency, set frequency, multi-stage frequency, hopping frequency] ~ 400.0Hz [50.00Hz]...
  • Page 96 Chapter 5 Detailed Function Introductions upper limit frequency, and not less than the lower limit frequency. This function is commonly used to ensure that the motor operates at the allowable frequency in order to avoid misoperation or accidents of mechanical system or inverter caused by unintended causes.
  • Page 97 Chapter 5 Detailed Function Introductions  Brake first and then start: Inverter adds some DC braking power to load first, and then startup. As shown in Figure. 5-1-1. Starting mode 1 is suitable for small inertia load which is running forward or reverse while the inverter is in stop state, such as fan load.
  • Page 98 Chapter 5 Detailed Function Introductions Operation Freq. Detect motor's speed and direction Time Motor speed Time Output voltage Time Power Figure. 5-1-2 Rotating speed tracking restart  Starting process includes the start of inverter power on, power recover, external fault reset, and restart after coast-to-stop.
  • Page 99 Chapter 5 Detailed Function Introductions Figure. 5-1-3 Starting frequency and starting time  Tips: 1. Starting frequency is not restricted by the frequency lower limit. 2. If reference frequency is lower than starting frequency during acceleration, the inverter will run at zero-speed P1.03 DC braking current at start This value depends on the inverter model [0.0%] P1.04 DC braking time at start...
  • Page 100 Chapter 5 Detailed Function Introductions 设定频率 frequency Starting frequency Starting preset frequency 启动频率保持时间 启动预置频率保持时间 hold time hold time Figure 5-1-4 Start frequency and Start preset frequency schematic diagram  Tips: When starting preset frequency is less than the starting frequency or starting preset holding frequency time is 0, the starting preset frequency is invalid.
  • Page 101 Chapter 5 Detailed Function Introductions Running Freq.(Hz) ③ ③ ② ② ① ① Time Acc Time Dec Time Figure.5-1-6 S-curve acceleration/deceleration P1.08 Time of S-curve initial Setting range: 10.0~50.0% [20.0%] P1.09 Time of S-curve rising Setting range: 10.0~80.0% [60.0%] Notes: ...
  • Page 102 Chapter 5 Detailed Function Introductions Setting range: 0~MIN (50.00, Frequency upper limit) P1.11 DC braking frequency at stop [2.00Hz] P1.12 DC braking waiting time at stop Setting range: 0.00~10.00s [0.00s] P1.13 StoppingDC braking current setting source Setting range: 0~5 [0] 0: Digital setting 1: Terminal AI1 2: Terminal AI2...
  • Page 103 Chapter 5 Detailed Function Introductions This function will start up after inverter received stop command. Usually, it is used to improve the stop precision and not for deceleration braking in common running. If faster stop required, braking energy regeneration unit should be fitted, or the inverter that has the function of brake energy regeneration should be selected.
  • Page 104 Chapter 5 Detailed Function Introductions alarm 0: Failure to actuate 1: Slowdown running P1.23 Rate of deceleration during Setting range: 0.00 ~ - maximum frequency [10.00Hz /s] instantaneous stop deceleration running Notes:  If undervoltage occurs at the time of stopping, it only give an alarm of Uu, at this time, the motor cannot be started.
  • Page 105 Chapter 5 Detailed Function Introductions 5.3 Auxiliary Operation (Group P2) P2.00 Jog Frequency Setting range: 0.10~Frequency upper limit [5.00Hz] P2.01 Acc time of Jog Setting range: 0.1~3600s [6.0/20.0s] P2.02 Dec time of Jog Setting range: 0.0~3600s [6.0/20.0s] Notes:  P2.00~P2.02 define the related parameters of Jog. ...
  • Page 106 Chapter 5 Detailed Function Introductions Operation Freq.(Hz) Time Figure. 5-2-2 FWD/REV switching time P2.04 Frequency lower limit deal mode Setting range: 0~3 [0] 0: Run at Frequency lower limit 1: Run at zero-speed. 2: Stopping 3: Zero speed operation Notes: ...
  • Page 107 Chapter 5 Detailed Function Introductions P2.05 Frequency departure setting Setting range: 0.00~2.50Hz [0.10Hz] Notes:  Prevent analog setting fluctuation leading joggling of output frequency. When the frequency setting source is terminal AI or pulse input, it takes effect only when the set frequency changes and the variation range exceeds the set range.
  • Page 108 Chapter 5 Detailed Function Introductions Figure. 5-2-5 Jump Frequency  The inverter can set three jump frequency points, and the jump frequency bandwidth can overlap or nesting. If overlapped, the range broadens. When all three jump frequency set to 0.00 Hz, the jump function will be disabled.
  • Page 109 Chapter 5 Detailed Function Introductions  When the inverter is in unusual stopping state or terminal forced stopping state, it should be stopped according to P2.34 abnormal deceleration stopping time, is subject to the limit of stop mode (P1.10).  the default units of acceleration and deceleration time is s, the acceleration and deceleration time can be reduced or enlarged to 10 times by modifying P2.35 acceleration and deceleration time multiplying factor.

  • Page 110: I/O Terminal Ctrl (Group P3)

    Chapter 5 Detailed Function Introductions 0: Null 1: Full P2.41 expanded PG output frequency dividing ratio (reserve Setting range: 1~128 [1] for 3004GB and below models) P2.42Extended PG pulse number per turn (reserve for Setting range: 1~9999 [1000] 3004GB and below models) P2.43 Extended PG direction setting (reserve for 3004GB Setting range: 0.1 [0] and below models)
  • Page 111 Chapter 5 Detailed Function Introductions  Open valid: Signal is disabled if the control terminal and COM terminal are short-circuited. (Normally open and normally close are not limited) 3004GB and below models: P3.01 P3.01 Multi-function input selection Terminal Setting range: 0~79 [1] P3.02 P3.01 Multi-function input selection Terminal Setting range: 0~79 [2] P3.03 P3.01 Multi-function input selection Terminal...
  • Page 112 Chapter 5 Detailed Function Introductions Table 5-3-1 Multi-function Input Menu Setting Function Setting Function NULL: No defined FWD: Running Forward REV: Running Reverse F/R: Running direction HLD: self-hold selection RST: reset FC: Setting frequency selection FJOG: JOG FWD RJOG: JOG REV DOWN UP/DOWN Reset FRE: Coast-to-stop...
  • Page 113 Chapter 5 Detailed Function Introductions Setting Function Setting Function Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Anti rotor-blocking command (reserve) Zero servo command(reserve) PID output is forced to 0 Command channel switch to Keypad PID integral time reset control Single phase speed measurement pulse or...
  • Page 114 Chapter 5 Detailed Function Introductions 7: Setting frequency selection  FC frequency setting options: If the "FC frequency setting options" is "enable function terminals", the frequency set point is determined by P0.06 running frequency setting combination 2; if this function terminal is inactive, the frequency set point is determined by P0.05 running frequency setting combination 1.
  • Page 115 Chapter 5 Detailed Function Introductions Reference Freq.(Hz) Frequency setting1+Frequency setting 2 UP/DOWN Terminal Run UP/DN reference amplitude Frequency setting 2 Run command UP command DOWN command STOP command Figure. 5-3-3 UP/DOWN combination operation NOTES: The terminal UP / DOWN is active only when P0.03 = 8 and when the inverter is in running state. Operation Freq.(Hz) UP/DN reference amplitude UP/DOWN...
  • Page 116 Chapter 5 Detailed Function Introductions  Use the terminal to perform DC braking to the system during the stopping process for accurate positioning of the motor. Braking starting frequency, braking waiting time, brake current are defined in P1.11 ~ P1.14; the braking time is bigger one between the time defined by P1.15 and the effective duration of the control terminal, which is as shown in Fig.
  • Page 117 Chapter 5 Detailed Function Introductions Table 5-3-2 Multi-stage frequency Selected frequency Legend Frequency Operation Freq setting Multi-stage frequency 1 Multi-stage frequency 2 Multi-stage frequency 3 Multi-stage frequency 4 Multi-stage frequency 5 Multi-stage frequency 6 Multi-stage frequency 7 Multi-stage frequency 8 Multi-stage Time frequency 9...

  • Page 118: Fault Relay

    Chapter 5 Detailed Function Introductions  EI0 - External interrupt signal normally open / EI1 - External interrupt signal normally close: During operating, the inverter stops its output and runs at zero-speed when it receives external interrupt signal. Once the signal is removed, the inverter will start and resume normal operation. Please refer to note of EH0 and EH1 above.
  • Page 119 Chapter 5 Detailed Function Introductions Fig. 5-3-7 Timing driving input Counter's trig signal input  This terminal is used for pulse input to the internal counter of the inverter. The highest pulse frequency is 650 Hz. The present counting value can be saved when power off. Counter clear ...
  • Page 120 Chapter 5 Detailed Function Introductions Explanation:  The filter time constant digital filtering process on the input signal, in order to prevent the influence of the interference signal on the system stablility.  If the filter time constant is too large, the control is stable, but control response is bad; if the filter time constant is small, the response is fast, but the control may not be stable.
  • Page 121 Chapter 5 Detailed Function Introductions Fig. 2 图 2 Fig. 1 图 1 Fig. 4 Fig. 3 图 3 图 4 Setting range: 0.01~99.99Hz/s [1.00Hz/s] P3.16 Terminal UP/DN rate Setting range:0.00~Frequency upper limit [10.00Hz] P3.17 UP/DN reference amplitude Notes:  Terminal UP/DN rate is used to define the change rate of reference frequency that is changed by terminal UP/DN.
  • Page 122 Chapter 5 Detailed Function Introductions Table 5-3-4 Multi-function Terminal Output Value Corresponding function Functional description NULL When the inverter is in operation mode, the terminal output is active FAR frequency arrival Refer to P3.26 frequency reaching detection width FDT frequency See P3.27, P3.28 frequency detection value and frequency detection lag detection correlation description...
  • Page 123 Chapter 5 Detailed Function Introductions Corresponding function Functional description When the signal level of the analog signal is less than the minimum value or Abnormality of analog higher than the maximum value of the signal continuously for 500ms, the signal 1 terminal output is active When the signal level of the analog signal is less than the minimum value or Abnormality of analog...
  • Page 124 Chapter 5 Detailed Function Introductions Table 5-3-6 STEP Indication of number of steps of program running Steps of program running P3.25 Cut-to-length reaching terminal output hold time Setting range: 0.0 ~ 3.0s [1.0s] (3004GB and below models) Notes:  3004GB and below models: P3.25 is used to set this function, otherwise it is used for selection of output function terminal of relay 2, please see the above description for details;...
  • Page 125 Chapter 5 Detailed Function Introductions Operating Freq.(Hz) Reference Detection width Freq. Time FAR signal Time Figure. 5-3-8 FAR detection diagram P3.27 FDT level Setting range: 0.00~Maximum frequency [50.00Hz] P3.28FDT lag Setting range: 0.00~10.00Hz [1.00Hz]  Note When the output frequency reaches a certain preset frequency (frequency detection threshold), Y terminal output will be valid.
  • Page 126 Chapter 5 Detailed Function Introductions when switching between power frequencies and frequency conversion of multiple motor, as shown in Fig. 5-3-10. Operating Freq.(Hz) Frequency upper limit Frequency lower limit Time FDTH Delay time EDTL Delay time FDTH FDTL Figure. 5-3-10 FDTH/FDTL P3.31Torque detection reference Setting range: 0.0~200.0% [100.0%] Notes:...
  • Page 127 Chapter 5 Detailed Function Introductions P3.33 Preset timing arriving Setting range: 0.0~6553.0 [0.0] Notes:  When the timing is equal to this value, the terminal output is active, as shown in Fig. 5-3-7.  The unit of P3.33 timing is identified by function terminal 53; the cumulative time of timing is cleared only when terminal 49 is inactive, otherwise it remains original.
  • Page 128 Chapter 5 Detailed Function Introductions AI2 maximum analog P4.10 AI2 Analog input filter time constant Setting range: 0.01~50.00s [0.05s] P4.11 Minimum pulse input value (pulse input terminal) Setting range: 0.00 kHz~P4.13 [0.00 kHz] P4.12 Corresponding physical quantity of input value of Setting range: -100.0%~100.0% [0.0%] minimum pulse quantity P4.13 Maximum pulse input value (pulse input...
  • Page 129 Chapter 5 Detailed Function Introductions Phys ical value corres ponding to Max analog value Input% Phys ical value corres ponding to Min analog value Input% Min analog Max analog value (V) value (V) Figure. 5-4-1 Analog input linear curve Note 2: ...
  • Page 130 Chapter 5 Detailed Function Introductions 7: Output power (0 ~ 2 times of the rated 6: Output torque (0 ~ 2 times of the rated motor torque) power) 8: Bus voltage (0 ~ 1000V) 9: AI1 (0 ~ 10V / 0 ~ 20mA) eleven: AI3 (0~10V corresponds to 10: AI2 (0 ~ 10V / 0 ~ 20mA) -10V~10V) (reserve for 3004GB and below...

  • Page 131: Plc Operating (Group P5)

    Chapter 5 Detailed Function Introductions 5.6 PLC Operating (Group P5) Setting range: 0~2 [2] P5.00 PLC Operating mode 1: Single cycle 2 (holding the final value) 0: Single cycle 1 2: Continuous operation Notes:  Single cycle 1 The inverter stops automatically after one cycle of operation and will start when receiving RUN command again.
  • Page 132 Chapter 5 Detailed Function Introductions Running frequency (Hz) Time Run command Figure. 5-5-2 Holding the frequency after single cycle  Continuous operation The inverter will start next cycle of operation automatically after completing one cycle of PLC operation until receiving stop command. As shown in Figure. 5-5-3.
  • Page 133 Chapter 5 Detailed Function Introductions Running frequency (Hz) 运行频率(Hz) Time 时间 f3-f12 f3-f12 T13 T14 T14 T15 T3-T12 T3-T12 First cycle Second cycle 第一次循环 第二次循环 Run command 运行命令 Stop command 停机命令 Figure. 5-5-3 Continuous operation of PLC P5.01 PLC restarting mode selection Setting range: 0~2 [0] 0: Restart from first step 1: Continue from the step where the inverter stops...
  • Page 134 Chapter 5 Detailed Function Introductions  Continue to run at the operation frequency at the moment of interrupt StoppingStopping during running (caused by stop command or failure), the inverter not only automatically records the run time of the current phase, but also records the running frequency at the time of stoppingstopping.
  • Page 135 Chapter 5 Detailed Function Introductions Setting range: 0.0~3600 [10.0] P5.10 Operating Timing T7 Setting range: 0.0~3600 [10.0] P5.11 Operating Timing T8 Setting range: 0.0~3600 [10.0] P5.12 Operating Timing T9 Setting range: 0.0~3600 [10.0] P5.13 Operating Timing T10 Setting range: 0.0~3600 [10.0] P5.14 Operating Timing T11 Setting range: 0.0~3600 [10.0] P5.15 Operating Timing T12...

  • Page 136: Cut-To-Length Function And Wobble Frequency Operating (Group P6)

    Chapter 5 Detailed Function Introductions Setting range: 0.1 [0] P5.34 PLC record clear Setting range: 0~15 [0] P5.35 Record of PLC steps Setting range: 0.0~3600 [0.0] P5.36Operating time of this step Notes:  Record of PLC steps (P5.35) records the steps that the PLC currently operating at. ...
  • Page 137 Chapter 5 Detailed Function Introductions Operation Freq.(Hz) Operation according to inverter's preset Dec time Time(S) Actual Length Preset length Time(S) Run command Actual Length clearing Command Figure. 5-6-1 Fixed length control diagram 1  The time when the inverter slows down can be adjusted by setting the deceleration point. When the motor inertia is greater, the deceleration point can be appropriately reduced to make the motor run slowly in advance;...
  • Page 138 Chapter 5 Detailed Function Introductions If P6.00 is set to 0, function of stop at fixed length is disabled, but the calculated length is still effective. The setting value must increase 200.0mm when P6.06 is modified by MODBUS communication. The corresponding relation between communication value and actual used value (which can be displayed on the keypad) is as follows: Reality used value (displayed on the keypad)) = Communication setting –...
  • Page 139 Chapter 5 Detailed Function Introductions operating P6.11 amplitude of oscillation Setting range: 0.0 ~ 50 % (relative to P 0.02) [0.0 %] P6.12 step frequency Setting range: 0.0 ~ fifty % (relative to P6.11) [0.0 %] P6.13 step time Setting range: 5~50ms [5ms] P6.14 Wobble frequency cycle Setting range: 0.1~999.9s [10.0s] P6.15 Swing ratio...

  • Page 140: Pid Control (Group P7)

    Chapter 5 Detailed Function Introductions 5.8 PID Control (Group P7) P7.00 Source given 1 Setting range: 0~6 [0] P7.01 Source given 2 Setting range: 0~6 [0] 0: PID digital given 1: Terminal AI1 2: Terminal AI2 3: Terminal AI3 (Reserved for 3004GB and the below) 4: Pluse input 5: Serial communication 6: Line speed(reserve)
  • Page 141 Chapter 5 Detailed Function Introductions P7.06 Analog PID Digital Giving Setting Range: -P7.07~P7.07 [0.0] P7.07 Analog PID Given Range Setting Range: MAX (1.0, |P7.06|) ~1000.0 [100.0] Notes:  When analog feedback is adopted, digital setting of the keypad giving quantity can be realized. The value is the actual physical quantity and should match with the range.
  • Page 142 Chapter 5 Detailed Function Introductions P7.22 Dormancy threshold Setting range: 0.0~999.9 [0.0] Explanation:  If the residual between feed and feedback value is smaller than residual margin, PID regulation will stop and the PID output maintain constant. As shown in Figure. 5-7-1. ...

  • Page 143: Vector Control Mode(Group P8)

    Chapter 5 Detailed Function Introductions P7.26 Sleep Delay Setting range: 0~999s [120s] P7.27 Sleep Threshold Setting range: 0~Frequency upper limit [20.00Hz] P7.28 Wakeup Threshold Setting range: 0.0~999.9 [3.0] Notes:  The function is used to stop the variable pump (all auxiliary pumps are stopped) when the flow is zero. In this case, if the frequency of the variable pump is lower than the “sleep threshold parameter”, delay will be initiated.
  • Page 144 Chapter 5 Detailed Function Introductions PI parameter PI参数 P8.04、 P8.05 P8.01、 P8.02 频率Hz Frequency HZ P8.03 P8.06 Figure 5-8-1 PI parameters schematic diagram  You can adjust the speed dynamic response characteristics of vector control by setting the speed regulator proportional coefficient and integral time.
  • Page 145 Chapter 5 Detailed Function Introductions  When the setting is 1, frequency inverter outputs according to the setting torque. At this time, the output frequency automatically matches with the load speed, but limited by the Upper limit frequency limit. When the load speed is greater than the upper limit frequency, the frequency inverter output frequency is limited.
  • Page 146 Chapter 5 Detailed Function Introductions P8.20 Zero servo initial frequency Setting range: 0.00~10.00Hz [0.30Hz] (reserve) P8.21 Zero servo gain (reserve) Setting range:1. 0~99.99(G5) [1.00] P8.22Zero servo tolerance (reserve) Setting range: 0~16383 [10] Notes: Parameters related to zero-servo are reserved temporarily. P8.23 Zero-speed Torque Boosting Setting range: 0.0~50.0% [0.0%] P8.24 Zero-speed Threshold...

  • Page 147: V/F Control (Group P9)

    Chapter 5 Detailed Function Introductions 5.10 V/F Control (Group P9) P9.00 V/F curves setting Setting range: 0~4 [0] 0: Constant Torque Characteristic Curve 0 1: Reduction Torque Characteristic Curve 1 (2.0) 2: Reduction Torque Characteristic Curve 2 3: Reduction Torque Characteristic Curve 1 3 (1.2) (1.5) P9.01 V/F frequency value F1 Setting range: 0.0~P9.03 [10.00Hz]...
  • Page 148 Chapter 5 Detailed Function Introductions Figure. 5-9-2 V/F-curve defined by user P9.07Torque boost mode Setting range: 0.0~30.0% [0.0%] Notes:  To make up for the low-frequency torque characteristic, certain boost compensation can be made for the output voltage. When the function code is set as 0.0%, it is at the V/F control mode; when it is not set as 0, it is at the manual torque boost mode, as showed in Figure 5-9-3.
  • Page 149 Chapter 5 Detailed Function Introductions Notes:  The motor’s slip changes with the load torque, which results in the variance of motor speed. The inverter output frequency can be adjusted automatically through slip compensation according to the load torque. Therefore, the electrical characteristics of the mechanical hardness are improved. As shown in Figure. 5-9-4. Freq.
  • Page 150 Chapter 5 Detailed Function Introductions linear interpolation if the frequency is out range of 5Hz to 50Hz. The setting value is made by the percentage of motor rated voltage. Figure. 5-9-5 Energy saving voltage lower limit  In the energy saving control mode, the optimum voltage is calculated according to load power, and the voltage is supplied to the load.

  • Page 151: Motor Parameters (Group Pa)

    Chapter 5 Detailed Function Introductions  Tips: When the slip compensation and the droop control cannot be effective concurrently, the slip compensation will enjoy the higher priority. Load Belt Inverter 1 Inverter 2 Figure 5-9-6 Droop Control Motor Characteristic P9.19 Output voltage offset source Setting range: 0~5 [0] 0: Digital setting 1: Terminal AI1...
  • Page 152 Chapter 5 Detailed Function Introductions PA.04 Rating Current of Motor 1 Setting range : 0.1~999.9A [Based on Motor Type] Notes:  PA.01~PA.04 are used to set the parameters of the controlled motor 1. To ensure the control performance, please do set relevant values correctly according to parameters on the motor nameplate. ...
  • Page 153 Chapter 5 Detailed Function Introductions The parameters setting of motor 2. The detailer settings are the same as motor 1. The settings are valid after the PA.00 is set to 2. PA.29 Motor parameter setting Setting range: 0~2 [0] 0: No operation 1: Static parameter setting 2: Rotation parameter setting Notes...

  • Page 154: Modbus Communication (Group Pb)

    Chapter 5 Detailed Function Introductions 5.12 MODBUS Communication (Group Pb) The series of frequency inverters can conduct the serial communication via the MODBUS communication protocol and the programmable logic controller (PLC). MODBUS consists of a controlling PLC and 1-31 frequency inverters of this series.

  • Page 155: Display Control (Group Pc)

    Chapter 5 Detailed Function Introductions Pb.05 MODBUS frequency reference unit Setting range: 0.1 [0] 0: 0.01Hz 1: 0.1Hz Notes:  The frequency unit can be selected for the PLC frequency command.  The output frequency resolution rate for this series of frequency inverters is 0.01Hz. When the frequency command unit of the function code Pb.05 is selected as 0, i.e.
  • Page 156 Chapter 5 Detailed Function Introductions Notes:  When PC.03 is set as 1, the output current will be displayed in the monitoring state and the unit is A. If it is set as 0, the target will not be displayed. PC.04 Frequency Setting (Hz Flickering) Setting Range: 0, 1 [1] 0: non-displayed...
  • Page 157 Chapter 5 Detailed Function Introductions 0: No display 1: Display Notes:  If PC.11 is set to 1, output voltage will be displayed in monitoring state, and the unit indicator “V” will be lit up. If it is set to 0, output voltage will not be displayed. ...
  • Page 158 Chapter 5 Detailed Function Introductions Figure 5-12-1 Terminal State Indication PC.20 Actual length (m) Setting range: 0.1 [0] 0: No display 1: Display Notes:  If PC.20 is set to 1, the actual length will be displayed in monitoring state, and all unit indicators will be off. If it is set to 0, actual length will not be displayed.

  • Page 159: Protection And Fault Parameters (Group Pd)

    Chapter 5 Detailed Function Introductions Actual length/Preset length 0.001~65.53m 5.14 Protection and Fault Parameters (Group Pd) Pd.00 Motor overload protection mode selection Setting range: 0~3 [1] 0: Disabled 1: Common motor (with low speed compensation) 2: Variable frequency motor (without low speed compensation) 3: Sensor Protection (Immediate Over-threshold Protection) Notes: ...
  • Page 160 Chapter 5 Detailed Function Introductions Time Motor overload protective 100% coefficient 1 min Output current 100% 200% Figure. 5-13-1 Motor overload protection curve Adjustment can be determined according to the following formula: Allowed Max. Load Current ×100% Motor Overload Protective Coefficient Value = Rating Output Current of Frequency Inverter Among it, “Allowed Max.
  • Page 161 Chapter 5 Detailed Function Introductions  Tips: 1. For setting of the overload pre-alarm detection level\detection time, it should be generally ensured that the pre-alarm occurs earlier than the overload protection action of frequency inverter. 2. Within the overload pre-alarm detection time, if the working current is less than the overload pre-alarm detection level, the overload pre-alarm detection time inside the inverter will be reset.
  • Page 162 Chapter 5 Detailed Function Introductions Output Freq.(Hz) Acc/Dec 4 Output Current(%) Time(s) Time(s) Figure. 5-13-4 constant speed Operation Pd.10 Over-voltage at stall Setting range: 0.1 [1] function selection 0: Disabled (The proposed option, when braking resistor is mounted) 1: Enabled Pd.11 Over-voltage point at Setting Range: 120.0~150.0% busbar voltage stall...
  • Page 163 Chapter 5 Detailed Function Introductions Output Freq.(Hz) Time(s) Bus voltage(%) Time(s) Deceleration Figure. 5-13-5 Deceleration Pd.12 Input Phase Loss Detection Benchmark Setting range:1~100% [100%] Pd.13 Input Phase Detection Time Setting range:2~255s [10s] Notes:  With this function, the input phase loss or the serious imbalance of the input three phases can be detected to protect the frequency inverter.
  • Page 164 Chapter 5 Detailed Function Introductions  Notes:  Only three faults including OC, Ou and GF can be reset automatically.  The three faults in operation can be reset automatically according to the set times Pd.18 and interval Pd.19. During the resetting interval, output is blocked and the inverter operates with zero frequency. The inverter will operate with the startup manner after automatic resetting is finished.

  • Page 165: Running History Record (Group Pe)

    Chapter 5 Detailed Function Introductions  Compared with the software current-limiting function, hardware current-limiting responds more quickly. Thus, it is suggested that hardware current-limiting function not be cancelled. 5.15 Running History Record (Group PE) PE.00 Type of latest fault Setting range: Table 5-14-1 [NULL] PE.01 Output frequency at last fault Setting range: 0~Frequency upper limit [0.00Hz] PE.02 Reference frequency at last fault...

  • Page 166: Protection Of Parameters (Group Pf)

    Chapter 5 Detailed Function Introductions 2: dEc Decelerate 3: con constant PE.06 Fault History 1 (Last One) Setting range: Table 5-14-1 [NULL] PE.07 Fault History 2 Setting range: Table 5-14-1 [NULL] PE.08 Fault History 3 Setting range: Table 5-14-1 [NULL] Notes: ...
  • Page 167 Chapter 5 Detailed Function Introductions -PF- PF.00 0000 1000 1000 1200 1200 1230 1230 1234 PF.00 Display ENTER >> >> >> ENTER ENTER operation Menu Turn Menu Go into Turn Shift Shift Shift Turn Turn Enter to level 2 right 2 level 3 user right 1...
  • Page 168 Chapter 5 Detailed Function Introductions  When PF.02 is set as 1, all fault records of PE.00~PE.08 in Group PE will be cleared to facilitate debugging and fault analysis by the user.  When PF.02 is set as 2, the ex-factory values will be reset (except the operation history records, user password setting and motor parameters).

  • Page 169: Chapter 6 Troubleshooting

    Chapter 6 Troubleshooting Chapter 6 Troubleshooting 6.1 Troubleshooting When the inverter has detected a fault, the keypad will display the fault code, and the inverter will stop PWM output and come into fault state. In the fault indicator TRIP will flicker, the fault relay will output the programming function and the motor will coast to stop.
  • Page 170 Chapter 6 Troubleshooting Fault Name of Protection Possible Cause to Fault Countermeasure Display insulation  Check the load  Increase the acceleration  Abnormal load or deceleration time  The acceleration or appropriately deceleration time is set to  be too short Check the input power Overcurrent with the ...
  • Page 171 Chapter 6 Troubleshooting Fault Name of Protection Possible Cause to Fault Countermeasure Display  The frequency inverter output exceeds the motor overload value  The V/F curve is  Reduce the load inappropriate  Adjust the V/F curve and  The power grid voltage is the torque boost Motor overloaded...
  • Page 172 Chapter 6 Troubleshooting Fault Name of Protection Possible Cause to Fault Countermeasure Display  Check the output Output phase loss or  Output R,S & T phase loss connection line imbalance or imbalance  Check the motor and cable insulation ...

  • Page 173: Warning Display And Explanation

    Chapter 6 Troubleshooting 6.2 Warning display and explanation After action of warning function, warning code is flickered display, but the inverter is not in fault-protecting state: PWM output will not be closed off, fault relay will not act. In addition, the inverter would automatically return to prevenient operation state after the warning signal disappeared.
  • Page 174 Chapter 6 Troubleshooting Table 6-3 Motor fault and corrective measure Fault Check Content Corrective Measures  Be connected to the power supply  Disconnect the power supply and then be Check whether the power is supplied to the The motor connected to it again.
  • Page 175 Chapter 6 Troubleshooting Fault Check Content Corrective Measures There is too Mechanical resonance  Adjust the leaping frequency large The machine legs are not even  Adjust the machine legs vibration with the The three-phase outputs are imbalanced  Check the frequency inverter output motor...

  • Page 176: Chapter 7 Peripheral Equipment

    Chapter 7 Peripheral Equipments Chapter 7 Peripheral Equipment 7.1 Peripheral Equipment Connection Diagrams Isolating switch 隔离开关 Breaker or fuse 断路器或熔断器 Contactor 接触器 AC Input Reactor 交流输入电抗器 Input EMI Filter 输入EMI滤波器 Braking resistor 制动电阻 ALPHA5000 Output EMI Filter 输出EMI滤波器 AC Output Reactor 交流输出电抗器...
  • Page 177 Chapter 7 Peripheral Equipments Isolating switch Breaker or fuse Contactor AC Input Reactor Input EMI Filter DC Reactor Braking Unit Braking resistor Output EMI Filter AC Output Reactor Motor Figure 7-2 3018GB~3500G Peripheral Equipment Connection Diagram...

  • Page 178: Function Of Peripheral Equipment

    Chapter 7 Peripheral Equipments 7.2 Function of Peripheral Equipment Table 7-1 Function of Peripheral Equipment Peripheral * Braking Unit Equipment * AC Breaker Contactor *EMI Filter and Braking & Optional Reactor resistor Elements It is used reduce the radio disturbance caused It is used to cut It is used to cut...

  • Page 179: Emi Filter

    Chapter 7 Peripheral Equipments Power Current Inductance Power Current Inductance Voltage (V) Voltage (V) (kW) (mH) (kW) (mH) 0.42 0.03 0.32 0.03 0.26 0.025 7.2.2 EMI Filter EMI filter is used to restrain transmit of Electromagnetic Interference (EMI) and external radio interference; including instant impulsion and surge Table 7-3 Three-phase three-wire EMI filter selection Major Parameters of Filter...

  • Page 180: Leakage Protector

    Chapter 7 Peripheral Equipments point be connected to the main control circuit. In Table 7-4 are the guiding data. The user can select the different resistance values and power according to the actual conditions (however, the resistance value cannot be less than the recommended value in the table, while the power can be determined by referring to the calculation result).

  • Page 181: Capacitor Box

    Chapter 7 Peripheral Equipments inverters. Sometimes, it may cause malfunction of the leakage protection circuit. In the above cases, not only the carrier frequency should be reduced appropriately, the lead wire should be shortened and the output reactor should be installed, but also the leakage protector should be installed. When the protector is installed, attention should be paid to the following points: The leakage protector should be installed at the input side of frequency inverter and had better behind the breaker.

  • Page 182: Inspection And Maintenance

    Chapter 8 Maintenance Chapter 8 Maintenance Danger Please do not touch the terminals of frequency inverter, which are provided with the high voltage. There is the danger of electric shock. Before power is supplied, please do install the terminal casing well. When the casing is dismantled, please do cut off the power supply.

  • Page 183: Regular Maintenance

    Chapter 8 Maintenance Table 8-1 Content and Notice for Daily Maintenance & Inspection Inspection Inspection Part Inspection Content Judgment Standard Item Determine according to the use state (e.g. when nothing is Whether the display is displayed after power is Display LED Monitor abnormal.
  • Page 184 Chapter 8 Maintenance During the inspection, elements cannot be dismantled or shaken freely. Moreover, connectors cannot be pulled out freely. Otherwise, the frequency inverter may not be able to run normally or may enter the fault display state. Even, element faults may be caused or the main switch element IGBT module or other elements may be damaged. When measurement is required, it should be noted that results with great difference may be got with different instruments.

  • Page 185: Regularly-Replaced Elements

    Chapter 8 Maintenance 输 入 电 源 Figure 8-1 Recommended Connection Method for Main Circuit Electric Measurement Table 8-3 Instruction on Main Circuit Electric Measurement Input Output Item Intermediate (Power supply) (Motor) terminals Link Measuring Current Power Volt Current Power Volt Voltmeter instrument...

  • Page 186: Storage And Protection

    Chapter 8 Maintenance carried out for internal electronic elements of the frequency inverter. The life of these electronic elements varies with the environment and conditions where the inverters are used. Generally, if the inverter is used continuously, the elements can be replaced according to the following table, which also depends on the use environment, load conditions and inverter state, and other specific conditions.
  • Page 187 Chapter IX Quality Assurance Chapter 9 Quality Guarantees The quality guarantees of this product follows the regulations below: The guarantee scope involves only the frequency inverter body. The guarantee period, starting from the date when it is delivered from the company, is 12 months after the product is purchased but is not beyond 24 months after the manufacture date on the nameplate.

  • Page 188: Appendix 1 External Dimension And Installation Dimension(Unit: Mm)

    Appendix 1 External Dimension and Installation Dimension(Unit: mm) Appendix 1 External Dimension and Installation Dimension(Unit: mm) Specifications S2R4GB/S2R75GB 141.5 130.5 S21R5GB/S22R2GB 3R75GB/31R5GB/32R2GB 3004GB 179.5 114.5...
  • Page 189 Appendix 1 External Dimension and Installation Dimension(Unit: mm) Specification 35R5GB, 37R5GB...
  • Page 190 Appendix 1 External Dimension and Installation Dimension(Unit: mm) Specifications 3011GB, 3015GB 3018G, 3022G 3030G, 3037G 3045G, 3055G 3075G, 3093G 3110G, 3132G...
  • Page 191 Appendix 1 External Dimension and Installation Dimension(Unit: mm) Installation dimension for three-phase 380V 160-355KW standard inverter (with the base): Specifications 3160G-X, 3185G-X, 3200G-X, 3-φ1 4-φ1 1380 1360 3220G-X 3250G-X, 3280G, -X 3-φ1 4-φ1 1535 1515 3315G-X, 3355G-X...
  • Page 192 Appendix 1 External Dimension and Installation Dimension(Unit: mm) Installation dimension for three-phase 380V 160-355KW standard inverter (wall type): Specification 3160G-V, 3185G-V, 3200G-V, 3220G-V 1056 1026 6-φ14 3250G-V, 3280G-V, 1210 1180 6-φ14 3315G-V, 3355G-V...
  • Page 193 Appendix 1 External Dimension and Installation Dimension(Unit: mm) Installation dimension for three-phase 380V 400-500KW standard inverter: Specifications 3400G-X, 3500G-X 1000 1800 4-φ22 Installation dimension for three-phase 380V 160-500KW slim-shape inverter:...
  • Page 194 Appendix 1 External Dimension and Installation Dimension(Unit: mm) Hanging plugs are optional according the installation need Specifications 3160G, 3185G 1600 3200G, 3220G 3250G, 3280G 1800 3315G, 3355G Installation dimension for three-phase 380V 400-500KW slim-shape inverter:...
  • Page 195 Appendix 1 External Dimension and Installation Dimension(Unit: mm) 3400G, 3500G 2000...

  • Page 196: Appendix 2 Technical Specifications

    Appendix 2 Technical Specifications Appendix 2 Technical Specifications Item Specifications Rating Input Voltage & Single-Phase: 200~240V 50/60Hz Frequency Three-Phase: 380~440V 50/60Hz Single-Phase 220V: 176~264V, frequency<±5% Allowed Input Voltage Three-phase 380V: 304~456V, voltage imbalance rate < 3%, frequency< Working Range ±5% Type S2R4GB S2R75GB...
  • Page 197 Appendix 2 Technical Specifications Item Specifications Braking Torque the additional braking resistor can reach 125% Voltage/Frequency 4 types of fixed V/F characteristics are optional; any V/F characteristic can be Characteristic set; with the PG V/F control overvoltage, undervoltage, current limit, overcurrent, overload, electronic thermal relay, overheat, overvoltage stalling, load short circuit, earthing, Protection Function undervoltage protection, input phase loss, output phase loss, earthing and...

  • Page 198: Appendix 3 Recommendation For Selection Of The Main Circuit Output Cable

    Appendix 3 Recommendation for Selection of the Main Circuit Output Cable Appendix 3 Recommendation for Selection of the Main Circuit Output Cable Maximum Distance of Output Line (m) Power Cable Voltage Without the Output Reactor With the Output Reactor Grade Specification (kW) Non-shielded...

  • Page 199: Appendix 4 Use Of Modbus Communication

    Appendix 4 Use of MODBUS Communication Appendix 4 Use of MODBUS Communication ALPHA6000S/ ALPHA6000Vcan use the programmable logic controller (PLC) and other upper devices to conduct the data exchange through MODBUS-RTU communication protocol.  Constitution of MODBUS Communication The communication data busbar is a main controller (PLC) and 1~31 frequency inverters. The signal is transmitted from the main controller and the frequency inverter responds to it.
  • Page 200 Appendix 4 Use of MODBUS Communication 4. Cut off the power supply and wait until keypad display disappears completely. 5. Switch on the power supply again. 6. Conduct the communication with PLC.  Setting of Communication Parameters To communicate with PLC, communication-related parameters should be set. In the following table, only Pb.01 (ID Number) and Pb.04 (response delay time) can be revised during operation to facilitate debugging, which becomes effective immediately, while the rest parameters cannot be revised during operation.
  • Page 201 Appendix 4 Use of MODBUS Communication After the communication function Function Name of Ex-factory Setting Range Revision is selected, MODBUS Code Parameter Setting can be written into the register 0: Digital setting 1: Terminal AI1 2: Terminal AI2 Stop DC 3: Terminal AI3 (Reserved for Braking 3004GB and the below)
  • Page 202 Appendix 4 Use of MODBUS Communication After the communication function Function Name of Ex-factory Setting Range Revision is selected, MODBUS Code Parameter Setting can be written into the register 0: Terminal AI1 Motor 1: Terminal AI2 protection 2: Terminal AI3 (Reserved for Pd.02 sensor ×...
  • Page 203 Appendix 4 Use of MODBUS Communication  Command Formatting During communication, the main controller (PLC, etc) gives commands to ALPHA6000S/ALPHA6000V, and the frequency inverters respond to them. The process constitutes the information transmission & receiving as showed in the right figure. As the command function content varies, the length of data will vary as well.
  • Page 204 Appendix 4 Use of MODBUS Communication else crc=crc>>1 ; crc^=0xa001 ; ulenth-=1 ; uptr++; return(((crc&0x00FF)<<8)|((crc&0xFF00)>>8));  Example of Command Application [03H] Reading of Single-character Command: read the single-character record content from the specified code. The record content is divided into high 8 bits and low 8 bits and becomes part of the response content in order. Example: read the state of frequency inverter 1 Command Content Normal Response Content...
  • Page 205 Appendix 4 Use of MODBUS Communication [08H] Loop Test Command: the command content is fed back originally in the form of response and is used for test of signal transmission and returning between the main controller and the frequency inverter. Arbitrary values can be used as the test code and data.
  • Page 206 Appendix 4 Use of MODBUS Communication Command Content Normal Response Content Abnormal Response Content Frequency Inverter Frequency Inverter Frequency Address Address Inverter Address Command Code Command Code Command Code High Bit High Bit Abnormality Start Start Code Address Address Low Bit Low Bit High Bit High Bit...
  • Page 207 Appendix 4 Use of MODBUS Communication  List of Data: Command Data (writable) MODBUS Name Content Address 0000H ( Reserved) Operation Command 1: Operation 0: Stop Reverse Command 1: Reverse 0: Forward External Fault 1: External Fault (EFO) Fault Resetting 1: Fault Resetting Command Multi-functional Input Command 1 (P3.01 X1Terminal Function)
  • Page 208 Appendix 4 Use of MODBUS Communication MODBUS Name Content Address Output voltage bias, data scope 0-1000 corresponding to 0.0~100.0%, 100.0% corresponding to the 000BH maximum output voltage Motor protection sensor input passage 000CH Braking torque setting, data scope 0-1000 corresponding to 0.0~100.0%, 100.0% corresponding twice of 0012H the rating motor torque 0013-001FH...
  • Page 209 Appendix 4 Use of MODBUS Communication MODBUS Name Content Address Multi-functional Output Command 3 (1: Y2 ON 0: OFF) Reserved for 3004GBand the below Multi-functional Output Command 4 (1: TA ON 0: OFF) Multi-functional Output Command 5 (1: BR ON 0: OFF) Reserved for 3004GBand the below Multi-functional Output Command 6 (1: Y3 ON...
  • Page 210 Appendix 4 Use of MODBUS Communication MODBUS Name Content Address 0023H Before the frequency command compensation 0024H After the frequency command compensation 0025H AI1 Analog Input (V), 0~10.00V corresponding to 0~1000 0026H AI2 Analog Input (V) , 0~10.00V corresponding to 0~1000 0027H Output Current (A) 0028H...
  • Page 211 Appendix 4 Use of MODBUS Communication MODBUS Name Content Address 0030H AO3 Analog Output (V) 0~10.00V corresponding to 0~1000 (Reserved for 3004GB and the below) 0031H DC Main Bus Voltage 0032H Output Torque 0033H Current Rotating Speed 0034H Set Rotating Speed 0035H Operating Linear Speed 0036H...
  • Page 212 Appendix 4 Use of MODBUS Communication Function Code Form Parameter Modbus Register Address(HEX) Code(DEC) Pb.00~Pb.08 0C00H~ 0C08H PC.00~PC.23 0D00H~ 0D17H Pd.00~Pd.34 0E00H~ 0E22H PE.00~PE.12 0F00H~ 0F0CH PF.00~PF.12 1000H~ 100CH (For parameter extending) (1100H~FFFFH)  Modbus Address Encoding Method: Refer to the function codes in the function code form. High 8 bit HI= function group number + 1; low 8 bit LO= function code.

  • Page 213: Appendix 5 Keypad Installation Dimension (Unit: Mm)

    Appendix 5 Keyboard Installation Dimension (Unit: mm) Appendix 5 Keypad Installation Dimension (Unit: mm) Figure A5-1 S2R4GB~3004GB Keypad Installation Dimension...
  • Page 214 Appendix 5 Keyboard Installation Dimension (Unit: mm) Figure A5-1 Keypad Installation Dimension for 35R5GB and the Above...

  • Page 215: Appendix 6 Lcd Keypad Use Instruction

    Appendix 6 LCD Keyboard Use Instruction Appendix 6 LCD Keypad Use Instruction A6.1 LCD Keypad Instruction A6.1.1 View of LCD Keypad R U N F W D R E V R E M O T E T R I P Operation State Indicator Light 运行状态指示灯...
  • Page 216 Appendix 6 LCD Keyboard Use Instruction Chinese instruction, the meaning of a function code can be displayed directly when the user doesn’t understand it. The keypad is connected with the frequency inverters of 35R5GB and the above. As for the functions, it is completely compatible with the LED keypad operation.
  • Page 217 Appendix 6 LCD Keyboard Use Instruction Frequency Inverter Stop and Operation State Display  REMOTE TRIP REMOTE TRIP REMOTE TRIP Pre-compensation Pre-compensation Pre-compensation 补偿前频率 补偿前频率 补偿前频率 Frequency Frequency Frequency 0. 00 Hz 30.00 Hz 0. 00 Hz 0.00Hz 0.00 Hz 30.00 Hz >>...
  • Page 218 Appendix 6 LCD Keyboard Use Instruction Function Code Edition State:  Primary Secondary Tertiary Menu Menu Menu Pre-compensation Function Group: P0 Frequency Digital Setting Function Code: P0.02 Frequency Basic Functions 50.00 Hz Frequency Digital Setting 50.00 Hz Stop State Parameter Display or Operation Edition State State Parameter Display...

  • Page 219: A6.3 Lcd Contrast Adjustment

    Appendix 6 LCD Keyboard Use Instruction Function Code Parameter Setting Pre-compensation Function Code: P2.00 Function Code: P2.01 Jogging Acceleration 补偿前频率 功能组:P0 功能组:P2 功能码:P2.00 功能码:P2.01 点动加速时间 Function Group: P0 Function Group: P2 Frequency Jogging Operation Jogging Acceleration Time 显示 0.00 Hz 基本功能...

  • Page 220: Appendix 7 Frequency Inverter Warranty Card

    Appendix 7 Guarantee Sheet Appendix 7 Frequency Inverter Warranty Card Frequency Inverter Warranty Card Name of User: Address of User: Contact Person: Tel.: P.C.: Fax: Type: Serial No.: Date of Purchase: Date of Fault: Fault Details Motor: Pole Application of Motor: Fault Occurrence Time: power supply no-load load...

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