Delixi SD100 Series Instruction Manual

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Thank you for choosing the SD100 series inverter.

Please read the Manual carefully before using the SD100 series inverter (the

Product) and follow it strictly in use in order to use the Product correctly; otherwise,

functioning error, fault, reduced life or even personal injury may occur! As a

standard appendix, the Manual should be kept properly for further inspection and

maintenance of the Product.

In addition to the operation instructions, the Manual also provides wiring

diagrams for your reference. For any query or special requirements for the Product,

please contact our local offices or dealers, or directly call our Headquarters customer

service center to enjoy the best service. The Manual is subject to changes without a

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Foreword

Table of Contents

Troubleshooting

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Summary of Contents for Delixi SD100 Series

Page 1 Foreword Thank you for choosing the SD100 series inverter. Please read the Manual carefully before using the SD100 series inverter (the Product) and follow it strictly in use in order to use the Product correctly; otherwise, functioning error, fault, reduced life or even personal injury may occur! As a standard appendix, the Manual should be kept properly for further inspection and maintenance of the Product.
Page 2: Table Of Contents
Table of Contents Table of Contents Chapter 1 Safety Running & Precautions ..............1 1.1 Acceptance ....................1 1.2 Precautions of Safety Running ..............2 Chapter 2 Product Information ..................4 2.1 Data and Naming Rules of Nameplate ............4 2.2 Technical Specification ................. 5 2.3 Product List ....................
Page 3 Table of Contents 7.1 Common Functions ................... 189 7.2 Application Cases ..................216 Chapter 8 RS-485 Communication of SD100 Series Inverter ........ 225 Chapter 9 Troubleshooting ..................233 9.1 Faults & Troubleshooting of Inverter ............233 9.2 Diagnosis & Troubleshooting of Motor Faults ......... 238 Appendix 1 Regular Maintenance &...
Page 4: Chapter 1 Safety Running & Precautions
Chapter 1 Safe Running & Precautions Chapter 1 Safety Running & Precautions Make sure to read the Manual carefully prior to installation, running, maintenance and inspection of the Product. Make sure to read this chapter carefully before using the Product in order to keep safety.
Page 5: Precautions Of Safety Running
Chapter 1 Safe Running & Precautions 1.2 Precautions of Safety Running 1. The Product should be installed and maintained by professional technicians only. 2. The Product’s rated voltage must be consistent with AC power voltage grade; otherwise, personal injury or fire hazard may occur.
Page 6 Chapter 1 Safe Running & Precautions 2. Please consider the bearing capacity of mechanical devices before running the Product above 50Hz. 3. When the Product’s frequency output meets the resonance point of load device, such resonance point can be evaded by setting the hopping frequency of the Product.
Page 7: Chapter 2 Product Information
Chapter 2 Product Information Chapter 2 Product Information 2.1 Data and Naming Rules of Nameplate Nameplate data: Taking Model SD100-T4B-G2R2P3R7 as example: Page 4...
Page 8: Technical Specification
Chapter 2 Product Information 2.2 Technical Specification Item Specification V/F control Control mode Split ring vector control (SVC) Frequency Digital quantity: 0.02% accuracy Analog quantity: 0.1% Control V/F curve Linear, square, random V/F Type G Machine: 150% rated current: 60s; 180% rated current: 3s Overload capability...
Page 9 Chapter 2 Product Information Item Specification potentiometer, external analog quantity, set figure, set pulse, multi-segment instruction, simplified PLC, communication, operation results, etc. 14 torque sources, including set figure, external analog Torque source quantity, pulse, multi-segment instruction, communication, operation results. Acceleration/de 4 groups of straight lines (select and switch terminals by celeration time acceleration/deceleration time), S curve 1, S curve 2...
Page 10 Chapter 2 Product Information Item Specification the logic results can be equivalent to the digital input terminal functions, outputted through multi-function output terminals. 2 built-in timers, to collect the timing input signals and Built-in timer realize output of timing signals. The built-in timer can be used independently or jointly.
Page 11: Product List
Chapter 2 Product Information 2.3 Product List Rated Rated Input Rated Output Adaptive Inverter Model Capacity Current (A) Current (A) Motor (kW) (kVA) S2 (single-phase 220V,50/60Hz) SD100-S2-G0R4 SD100-S2B-G0R4 SD100-S2-G0R75 0.75 SD100-S2B-G0R75 0.75 SD100-S2-G1R5 15.7 SD100-S2B-G1R5 15.7 SD100-S2-G2R2 10.0 SD100-S2B-G2R2 10.0 Rated Capacity Rated Input Rated Output...
Page 12: Appearance & Installation Dimensions
Chapter 2 Product Information 2.4 Appearance & Installation Dimensions Page 9...
Page 13: Daily Maintenance
Chapter 2 Product Information 2.5 Daily Maintenance 2.5.1 Daily Maintenance The Product should undergo daily and regular maintenance to avoid potential failures or reduced life when the internal elements are aged due to the ambient temperature, humidity, dust and vibration. Daily inspection items: Page 10...
Page 14 Chapter 2 Product Information A. Whether motor running sound has abnormal changes. B. Whether motor has vibration during running. C. Whether the Product’s installation environment is changed. D. Whether the Product’s cooling fan is running normally. Daily cleaning: A. Make sure the Product is clean. B.
Page 15 Chapter 2 Product Information delivery. The Company’s products may enjoy life-long paid services regardless of its procurement time and location. The Company’s nationwide sales, production and agents can offer after-sales services for the product based on the following service conditions: A.
Page 16: Chapter 3 Installation & Wiring Of Inverter
Chapter 3 Installation & Wiring of Inverter Chapter 3 Installation & Wiring of Inverter 3.1 Selection of Installation Location & Space 3.1.1 Selection of Installation Location: 1. Avoid direct sunlight. Do NOT use the Product outdoors directly. 2. Do NOT use the Product in places with corrosive gas and Caution liquid.
Page 17 Chapter 3 Installation & Wiring of Inverter 3.1.2 Selection of Installation Space: The Product should be reserved with an enough cooling space during vertical installation, to ensure effective cooling Installation Space of the Product 1. The product with open frame (IP00) and enclosed wall-mounting (IP20) should have the same clearance at the top/bottom and lateral sides.
Page 18: Wiring Of Peripheral Equipment And Optional Parts
Chapter 3 Installation & Wiring of Inverter 3.2 Wiring of Peripheral Equipment and Optional Parts Standard wiring method for peripheral equipment and optional parts of the Product: 3.3 Wiring of Main Circuit 3.3.1 Wiring Diagram and Precautions of Main Circuit This section introduces the wiring of the Product’s main circuit.
Page 19 Chapter 3 Installation & Wiring of Inverter Danger 3. Make sure the Product’s rated voltage is consistent with input power voltage. 4. Do NOT carry out voltage withstand test to the Product. 5. Make sure to fasten the terminal screws according to the specified fastening torque.
Page 20 For example: NV series of Mitsubishi Electric (manufactured in or after 1988). CDM1 series circuit breaker manufactured by Delixi Group. 3. Installation of magnetic contactor It can also be installed when magnetic contactor (MC) is not installed at the power side of inverter.
Page 21 Chapter 3 Installation & Wiring of Inverter 3.3.3 Precautions of Wiring at Main Circuit Output Side 1. Connection of output terminal and load Connect Phase U, V and W of output terminal to Phase U, V and W of motor outgoing line, send forward running instruction to verify the forward rotation of this motor (CCW: Anticlockwise rotation when being observed from the load side of motor).
Page 22 Chapter 3 Installation & Wiring of Inverter 9. Countermeasures for radio noise The radio noise, which can be generated by the input/output line and the inverter, can be reduced by setting noise filter at both ends of input/output end and using shielded cable for connecting the iron box of inverter.
Page 23: Wiring Of Control Circuit
Chapter 3 Installation & Wiring of Inverter 3.4 Wiring of Control Circuit 3.4.1 Terminal Arrangement and Wiring Diagram of Control Circuit (The P24V terminal (if any) has the same functions with +24V terminal) The wiring diagram for SD100 main circuit and control circuit is shown below (Connect L1/L2 for Type S2 Machine, or connect R/S/T for Type T4 Machine) Note: (The P24V terminal (if any) has the same functions with +24V terminal) Page 20...
Page 24 Chapter 3 Installation & Wiring of Inverter 3.4.2 Functions of Control Circuit Terminal The functions of control circuit terminal are introduced in table below. Wiring is conducted according to the functions of each terminal. Item Terminal Terminal Name Function Description Digital input 1 Standard terminal...
Page 25 Chapter 3 Installation & Wiring of Inverter Item Terminal Terminal Name Function Description RS485 communication positive signal Terminal of SD100 expansion terminal Communicati card. Communication wiring on terminal RS485 terminal of RS485 communication negative signal terminal 3.4.3 Wiring Instructions of Control Circuit The control circuit, which must be arranged separately from the main circuit, strong-current circuit (relay contact 220V circuit), must be twisted shielded wire or twisted pair shielded wire.
Page 26 Chapter 3 Installation & Wiring of Inverter Wiring of common anode of dry contact Sink type wiring Page 23...
Page 27 Chapter 3 Installation & Wiring of Inverter Source type wiring Only the following two wiring methods are supported by DI5 and DI6: The common cathode of dry contact of internal power supply is shown in the left picture below, while the NPN sink type wiring of internal power supply is shown in the right picture below: 4.
Page 28 Chapter 3 Installation & Wiring of Inverter Internal power supply 5. Wiring instructions of T1 output terminal circuit AC circuit The surge voltage absorption circuit should be mounted when inductive load is being driven (such as electromagnetic relay and contactor), such as RC absorption circuit (the leakage current should be lower than the holding current of controlled contactor or relay), as shown in picture below: DC circuit...
Page 29: Grounding
Chapter 3 Installation & Wiring of Inverter 3.5 Grounding 1. Grounding resistance: Grade 200V: 100Ω or lower Grade 400V: 10Ω or lower 2. The Product should not have shared grounding with electric welding machine, electric motor or other high-current electrical equipment. Make sure all grounding wires in conductor are paved separately with the conductors of high-current electrical equipment.
Page 30: Chapter 4 Keyboard Operation & Running
Chapter 4 Keyboard Operation & Running Chapter 4 Keyboard Operation & Running 4.1 Selection of Operation Mode The Product provides three control modes, including keyboard operation, terminal running and communication running, which can be selected by users according to the site environment and operation requirements. For details, please refer to 7.1.
Page 31: Operation Method Of Keyboard
Chapter 4 Keyboard Operation & Running normal. The indicator of digital operation keyboard should be on when power supply is connected. Cut off power supply immediately if any problem is found. 4.2.3 Inspection in Operation Process In operation process, check if: A.
Page 32 Chapter 4 Keyboard Operation & Running Hole Size of Pull-out Keyboard: 77.5mm*59mm Dimensions of Pull-out Keyboard: 83.5mm*65mm 4.3.2 Data Monitoring Mode 1. Cycle monitoring mode In monitoring mode, press >> button to change the display item, in order to check the current status of the Product. 16 contents of shutdown time can be displayed circularly at most in shutdown status.
Page 33 Chapter 4 Keyboard Operation & Running and reverse running are valid in keyboard control mode only. 4.3.4 Method of Viewing/setting Parameters (via Numeric Keyboard) Note: Do NOT change the data in the following cases. 1. Parameters which are unalterable while the Product is running. (Refer to function parameter table) 2.
Page 34: Display Mode Of Function Code
Chapter 4 Keyboard Operation & Running 4.4 Display Mode of Function Code The Product provides 3 function code display modes: Basic mode, user mode and verification mode. Basic mode (F0.1.01=0) The prefix of function code is ‘F’ in basic mode. The display of function code parameter is decided by function code F0.1.24 Its ones unit, tens place, hundreds place and thousands place correspond to each function code group.
Page 35: Chapter 5 Function Parameter Table
Chapter 5 Function Parameter Table Chapter 5 Function Parameter Table Introduction to function parameter table: 1. The Product’s function code parameters can be divided into 9 groups by function and each group contains multiple small groups. Each group includes several function codes which can be set as different values.
Page 36: Group F0 Of Inverter Information And Fault Information
Chapter 5 Function Parameter Table 5.1 Group F0 of Inverter Information and Fault Information Group F0.0: Basic Information of Inverter Factory Function Change Name Set Range Default Code Restriction Value Group F0.0: Basic Information of Inverter 0: V/F control Read F0.0.00 Control mode display ●...
Page 37 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 0: Invalid 1: Forward inching 2: Reverse inching Set function of keyboard ★ F0.1.03 3: Forward/reverse switch JOG key 4: Switch of keyboard control channel 5: Reverse running F0.1.04 Reserved...
Page 38 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 00: Random PWM is invalid ☆ F0.1.16 Random PWM depth 01~10: Random depth of PWM carrier ☆ F0.1.17 AVR function 0: Valid 1: Invalid H.0001~H.FFFF Bit00: Running frequency (Hz) Bit01: Given frequency (Hz) Bit02: Output current (A)
Page 39 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value parameter H.0001~H.FFFF Bit00: Set frequency (Hz) Bit01: Busbar voltage (V) Bit02: Input terminal status Bit03: Output terminal status Bit04: VF1 voltage (V) Bit05: VF2 voltage (V) Bit06: Actual counting LED shutdown display Bit07: Actual length...
Page 40 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 0: Not display Group F7 1: Display Group F7 Hundreds place: 0: Not display correction parameter group F4.1 1: Display correction parameter group F4.1 Thousands place: Reserved Ten thousands place: Reserved 00: No operation 01: Clear record information...
Page 41 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 1: Constant speed overcurrent 2: Acceleration overcurrent 3: Deceleration overcurrent 4: Constant speed overvoltage 5: Acceleration overvoltage 6: Deceleration overvoltage 7: Module fault 8: Under-voltage 9: Inverter overload 10: Motor overload 11: Input missing phase...
Page 42: Group F1 Of Motor Control Basic Parameters
Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value F0.2.04 Fault current 1 ● Busbar voltage F0.2.05 ● faulty condition Input terminal status 1 at F0.2.06 ● fault condition Output terminal status 1 F0.2.07 ●...
Page 43 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Group F1.0: Setting of Motor Control Basic Parameters 0: V/F control 1: Open loop vector control 2: Reserved ★ F1.0.00 Control mode 3: Intelligent selection as 0 or 1 (see F0.0.00 for the actual control mode) 0: Enable...
Page 44 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Given keyboard power-off memory) 1: Given by keyboard (power-off memory) Given keyboard potentiometer 3: Given by external terminal VF1 4: Given by external terminal VF2 Selection of frequency 5: Given by PULSE (DI6) ★...
Page 45 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Lower frequency Max. ★ F1.0.14 Upper limit frequency 50.00 frequency Offset of upper limit ☆ F1.0.15 000.00~Max. frequency 0.00 frequency ☆ F1.0.16 Lower limit frequency 000.00~Upper limit frequency 0.00 ☆...
Page 46 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Model ☆ F1.0.38 Deceleration period 4 0000.0s~6500.0s Switching frequency ☆ F1.0.39 point between F1.0.41~Max. frequency acceleration 1 and 2 Switching frequency ☆ F1.0.40 point between F1.0.42~Max.
Page 47 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value < 75kW) 0000.1A~6553.5A (inverter power ≥75kW) ★ F1.1.05 Motor rated speed 00001rpm~65535rpm Model Motor overload ☆ F1.1.06 00.20~10.00 1.00 protection level 00: No action Parameter identification ★...
Page 48 Chapter 5 Function Parameter Table V/F point 2 Voltage of broken line ★ F1.2.04 000.0%~100.0% V/F point 2 Frequency of broken line ★ F1.2.05 F1.2.03~Motor rated frequency 0.00 V/F point 3 Voltage of broken line ★ F1.2.06 000.0%~100.0% V/F point 3 00.0% (auto torque boost) ☆...
Page 49: Group F2 Of Motor Control Parameter And Fault Protection
Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 5: Given by communication 6: MIN(VF1, VF2) 7: MAX(VF1, VF2) 8: Operation result 3 9: Operation result 4 10: Standby torque source 1 11: Standby torque source 2 ☆...
Page 50 Chapter 5 Function Parameter Table Group F2.1: Torque Control Factory Function Change Name Set Range Default Code Restriction Value Group F2.1 Torque Control Select speed/torque 0: Speed control ★ F2.1.00 control mode 1: Torque control 0: Given by figure (F2.1.02) 1: Given by external terminal VF1 2: Given by external terminal VF2 Given...
Page 51 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value ★ F2.2.05 Speed tracking KP 0~1000 ★ F2.2.06 Speed tracking KI 0~1000 Speed tracking ☆ F2.2.07 0.00s~10.00s Model demagnetization time Speed tracking min. ☆ F2.2.08 000.00Hz~10.00Hz 1.50 frequency...
Page 52 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Tens place: Feedback loss Hundreds place: Customized fault Thousands place: Customized fault 2 Ten thousands place: Power-on time reached Selection fault Ones place: Running period ☆...
Page 53 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Missing phase protection 0: Disable ☆ F2.3.09 of input 1: Enable Sensitivity input 01~10 (lower value, higher ☆ F2.3.10 missing phase protection sensitivity) Missing phase protection 0: Disable ☆...
Page 54: Group F3 Of External Terminal
Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Running frequency of ☆ F2.3.29 000.01Hz~Max. frequency 50.00 fire hazard 5.4 Group F3 of External Terminal Group F3.0: External Input Terminal DI Factory Function Change Name Set Range Default...
Page 55 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value acceleration/deceleration 25: PID pause 26: PLC status reset 27: Swing frequency pause 28: Counter input 29: Counter reset 30: Length counting input 31: Length reset 32: Disable torque control 33: PULSE input 34: Immediate DC braking...
Page 56 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Corresponding set value ☆ F3.0.16 -100.0%~100.0% 100.0 of PULS max. input ☆ F3.0.17 PULS filtering time 00.00s~10.00s 0.10 00: Used as normal analogue Function Terminal quantity ★...
Page 57 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value expansion card Y01 1: Inverter running in progress 2: Fault shutdown output ☆ F3.1.01 Select T1 relay function Frequency level detection △/☆ FDT1 output Select function of relay 4: Frequency reached F3.1.02 expansion...
Page 58 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 42: Timing of Timer 1 reached 43: Timing of Timer 2 reached 44: Timing of Timer 1 reached 45: Fire hazard mode 46: Reserved 47: Reserved 48: Reserved 49: Reserved Synchronize...
Page 59 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value ☆ F3.2.02 Max. input of Curve 1 F3.2.00~10.00V 10.00 Corresponding set value ☆ F3.2.03 -100.0%~100.0% 100.0 of Curve 1 max. input ☆ F3.2.04 VF1 filtering time 00.00s~10.00s 0.10 ☆...
Page 60 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Corresponding set value ☆ F3.2.19 -100.0%~100.0% 100.0 of Curve 3 max. input ☆ F3.2.20 Min. input of Curve 4 00.00V~F3.2.22 0.00 Corresponding set value ☆ F3.2.21 -100.0%~100.0% -100.0...
Page 61: Group F4 Of Auxiliary Function And Aiao Curve Correction
Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 18: Operation result 2 19: Operation result 3 20: Operation result 4 Analog output ☆ F3.3.03 -100.0%~100.0% offset ☆ F3.3.04 Analog FM1 output gain -10.00~10.00 1.00 Analog output...
Page 62 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value current 000.0%: No detection ☆ F4.0.13 Output current overrun 000.1%~300.0% Detection delay ☆ F4.0.14 000.00s~600.00s current overrun ☆ F4.0.15 Current level detection 1 000.0%~300.0% Detection width ☆...
Page 63: Group F5 Of Simplified Plc And Virtual Relay
Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value point 1 Corresponding set value ☆ F4.1.01 potentiometer -100.0%~100.0% correction point 1 Voltage input ☆ F4.1.02 potentiometer correction F4.1.00~10.00V 10.0 point 2 Corresponding set value ☆...
Page 64 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 2: Continuous cycle 3: Cycle for N times ☆ F5.0.01 Cycle number N 00000~65000 Ones place: Selection of power-off memory 0: Power-off no memory 1: Power-off memory Tens place: Selection of non-fault Selection ☆...
Page 65 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value ☆ F5.0.24 Stage 10 running period 0000.0s~6500.0s ☆ F5.0.25 Stage instruction 11 -100.0%~100.0% ☆ F5.0.26 Stage 11 running period 0000.0s~6500.0s ☆ F5.0.27 Stage instruction 12 -100.0%~100.0% ☆...
Page 66 Chapter 5 Function Parameter Table Group F5.1: Virtual Relay and Built-in Logic Factory Function Change Name Set Range Default Code Restriction Value Group F5.1 Virtual Relay and Built-in Logic Control over 0: This relay’s input is decided by ★ F5.1.00 intermediate delay relay its control word A 1: This relay’s input is decided by...
Page 67 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 6~9: Reserved 10~14: M1~M5 15~16: VF1, VF2 17~19: Standby 20~79: Output function 00~59 of corresponding multi-function output terminal thousands place thousands place: Input 2 selection 0~5: DI1~DI6 6~9: Reserved 10~14: M1~M5...
Page 68 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Ones place: M1 Tens place: M2 Hundreds place: M3 Thousands place: M4 Ten thousands place: M5 Ones place: Timing control of Timer 1 Tens place: Timing control of Timer 2 0: Timer running 1: Controlled by timer input...
Page 69 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 7: Judgment of greater than and equal to 8: Integral 9~F: Reserved Ones place: Operation 1 Tens place: Operation 2 Hundreds place: Operation 3 Thousands place: Operation 4 Multiplication setting coefficient has no decimal...
Page 70 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value Tens place: Operation 2 Hundreds place: Operation 3 Thousands place: Operation 4 Thousands place, hundreds place, tens place and ones place: Address of operation 1 input A thousands place: Input...
Page 71: Group P6 Of Pid And Communication Control
Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 0: The input has operation via unsigned number 1: The input has operation via signed number Thousands place, hundreds place, tens place and ones place: Address of operation 3 input B thousands place:...
Page 72 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 4: Given by PULSE (DI6) 5: Given by communication Given multi-segment instruction terminal 7: Given by simplified PLC 8: Operation result 1 9: Operation result 2 10: Operation result 3 11: Operation result 4 ☆...
Page 73 Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value ☆ F6.0.15 PID switch deviation 2 F6.0.14~100.0% ☆ F6.0.16 PID initial value 000.0%~100.0% initial value ☆ F6.0.17 000.00~650.00s maintaining period 000.0%: No judgment of feedback feedback loss ☆...
Page 74: Group F7 Of Customized Function
Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value 0: No check (8-N-2) 1: Even parity check (8-E-1) ☆ F6.1.01 Data format 2: Odd parity check (8-O-1) 3: No check (8-N-1) 000: Broadcasting address ☆...
Page 75: Group F8 Of Manufacturer Parameters
Chapter 5 Function Parameter Table Factory Function Change Name Set Range Default Code Restriction Value ☆ F7.0.13 User function 13 U0.0.00 ☆ F7.0.14 User function 14 U0.0.00 ☆ F7.0.15 User function 15 U0.0.00 ☆ F7.0.16 User function 16 U0.0.00 ☆ F7.0.17 User function 17 U0.0.00...
Page 76 Chapter 5 Function Parameter Table Function Name Description Unit Code Output torque while inverter is running, percentage F9.0.05 Output torque 0.001 of motor rated torque F9.0.06 Output power Output power while inverter is running 0.1kW Input terminal F9.0.07 Check if input terminal has signal input status Output terminal...
Page 77 Chapter 5 Function Parameter Table Function Name Description Unit Code F9.0.45 F9.0.46 Operation result 1 Check the value of operation result 1 F9.0.47 Operation result 2 Check the value of operation result 2 F9.0.48 Operation result 3 Check the value of operation result 3 F9.0.49 Operation result 4 Check the value of operation result 4...
Page 78: Chapter 6 Parameter Description
Chapter 6 Parameter Description Chapter 6 Parameter Description 6.1 Group F0 of Inverter Parameters and Fault Information Group F0.0 Basic Information of Inverter Factory Function Name Set Range Default Code Value 0: V/F control Read F0.0.00 Control mode display 1: Open-loop vector control only This function code is read only and displays the actual control mode of inverter.
Page 79 Chapter 6 Parameter Description This function code is used by manufacturer and user to check the rated voltage of inverter. Factory Function Name Set Range Default Code Value Read F0.0.04 Inverter rated current 000.00~6500.0A only This function code is used by manufacturer and user to check the rated current of inverter.
Page 80 Chapter 6 Parameter Description The function code above is used by manufacturer and user to check the accumulated running period in fire mode. For details, please refer to P2.3.29 (fire hazard mode) description. Note: No warranty will be provided when F0.0.11 fire mode is enabled and run for over 5min Group F0.1 Basic Setting of Inverter Factory...
Page 81 Chapter 6 Parameter Description Display the modified parameters only (the parameter is modified when parameter value in function code is different from the factory default value). The prefix of function code is ‘C’ in verification mode. Note: The relative parameters have the same meaning whether the prefix of function code is ‘F’...
Page 82 Chapter 6 Parameter Description 0, RUN key on board has forward running, while JOG key has reverse running. Note: Forward inching and reverse inching function can be valid in any running control mode, while switch of forward/reverse control and reverse running function are valid in keyboard control mode only (i.e.
Page 83 Chapter 6 Parameter Description to normal undervoltage point. For Type T4 machine, the undervoltage point =350V*F0.1.07/100. So, the default value is 350V. For Type S2 machine, the undervoltage point =200V*F0.1.07/100. So, the default value is 200V. The Product’s undervoltage point can be slightly adjusted by changing F0.1.07. Generally, no adjustment is required.
Page 84 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value 0: Rotation during running F0.1.11 Fan control 1: Constant rotation 2: Controlled by temperature The function code is used for selecting the action mode of cooling fan. When F0.1.11=0, the fan will rotate while the Product is running and stop rotation when the Product is stopped.
Page 85 Chapter 6 Parameter Description This function code can change the PWM modulation mode in actual running process by changing the value of 0 and 1 above. The preset modulation mode is low-frequency carrier limitation, complete 3-phase modulation and asynchronous modulation under VF control, which means, the hundreds place is 0, tens place is 1, ones place is 0 and the set value acquired is 0010.
Page 86 Chapter 6 Parameter Description H.0001~H.FFFF Bit00: Running frequency (Hz) Bit01: Given frequency (Hz) Bit02: Output current (A) Bit03: Output voltage (V) Bit04: Busbar voltage (V) Bit05: Output torque (%) Bit06: Output power (kW) Running display parameter Bit07: Input terminal status F0.1.18 H.001F 1 of LED...
Page 87 Chapter 6 Parameter Description Auto switch time of LED 000.0: No switch F0.1.20 running display parameter 000.1s~100.0s Function code F0.1.18 and F0.1.19 decide the LED display contents when the Product is under running status. Function code F0.1.20 decides the display period of Parameter 1 and 2. When function code F0.1.20 is set as 0, it will display the set parameter of F0.1.18 only;...
Page 88 Chapter 6 Parameter Description The corresponding position should be set 1, this binary number should be converted to hexadecimal and set in F0.1.19, in order to display the parameters above during running Factory Function Name Set Range Default Code Value H.0001~H.FFFF Bit00: Set frequency (Hz) Bit01: Busbar voltage (V)
Page 89 Chapter 6 Parameter Description The format of specific display content is as follows: LED Shutdown Display Parameters The corresponding position should be set 1, this binary number should be converted to hexadecimal and set in F0.1.21, in order to display the parameters above in shutdown status Factory Function...
Page 90 Chapter 6 Parameter Description Ones place: Customized display of decimal points 0: 0 decimal point 1: 1 decimal point 2: 2 decimal points 3: 3 decimal points Tens place: Customized display of value source 0: Decided by hundreds place of customized display control word 1: Decided by set value of F0.1.22,...
Page 91 Chapter 6 Parameter Description Hundreds place Display value = Frequency ×F0.1.22 of F0.1.23 Display value = Frequency × Calculation result 1÷10000 Display value = Frequency × Calculation result 2÷10000 Display value = Frequency × Calculation result 3÷10000 Display value = Frequency × Calculation result 4÷10000 F0.1.22 The set value 0.0000~0.0099 of F0.1.22...
Page 92 Chapter 6 Parameter Description function code F0.1.01=0. Factory Function Name Set Range Default Code Value 00: No operation 01: Clear record information Restore default parameter, excluding electric parameter, correction group and password group Parameter Restore default parameters, F0.1.25 initialization excluding electric parameters and password group 30: Backup current parameters of user 60: Restore user backup parameters...
Page 93 Chapter 6 Parameter Description F0.1.26 is given by user password. The password protection function is valid when any non-zero 5-digit figure is given. Please keep the set user password properly, for it will display “-----” when entering the menu in the next time, and the user needs to enter password correctly in order to view and modify the function parameters.
Page 94 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value 21: Customized fault 1 22: Customized fault 2 23: Power-on time reached 24: Running period reached 25: Reserved 26: Parameter read/write error 27: Motor overheat 28: Speed major deviation 29: Motor overspeed 30: Initial position error 31: Current detection fault...
Page 95 Chapter 6 Parameter Description Function Name Parameter Description Code When output terminal corresponding binary digit is 1 and OFF is 0. Then, the binary number is converted to decimal number for display. Inverter status 1 at F0.2.08 Used by manufacturer fault condition Power-on period 1 F0.2.09...
Page 96: Group F1 Of Motor Basic Control Parameters
Chapter 6 Parameter Description 6.2 Group F1 of Motor Basic Control Parameters Group F1.0 Basic Parameter Setting of Motor Control Factory Function Name Set Range Default Code Value 0: V/F control 1: Open loop vector control 2: Reserved F1.0.00 Control mode 3: Intelligent selection as 0 or 1 (see F0.0.00 for the actual control mode)
Page 97 Chapter 6 Parameter Description When inverter model F8.0.01 is modified, F0.0.00 will change to 0, i.e. VF control When F1.1.01 (rated power) is modified, F0.0.00 will change to 0, i.e. VF control When F1.1.02 (rated frequency) is modified, F0.0.00 will change to 0, i.e. VF control When F1.1.03 (rated voltage) is modified, F0.0.00 will change to 0, i.e.
Page 98 Chapter 6 Parameter Description running control mode. When F1.0.03 is set as 2, the running direction will be decided by the multi-function input terminal. The terminal signal is valid and direction is reverse when multi-function input terminal function is 37. Note: The motor running direction will be recovered to the original status when default factory parameters are recovered.
Page 99 Chapter 6 Parameter Description 0: Given by keyboard (no power-off memory) The initial value of set frequency, which is given by function code F1.0.12, can be changed through ▲, ▼ of keyboard or UP/DOWN of terminal. When the Product is powered on again after power-off, the set frequency will be recovered to the set value of F1.0.12.
Page 100 Chapter 6 Parameter Description 8: Given by PID control The set frequency is given by the calculated frequency of PID control. The relevant parameters (F6.0.00~F6.0.20) in “PID control group” should be set when the set frequency is given by the calculated frequency of PID control. 9: Given by communication The set frequency is given by upper computer through communication.
Page 101 Chapter 6 Parameter Description Function Factory Name Set Range Code Default Value 0: Frequency source A 1: Frequency source B 2: Frequency A+B 3: Frequency A-B 4: Max. value of A, B F1.0.07 Select frequency source 5: Min. value of A, B 6: Standby frequency source 1 7: Standby frequency source 2 8: Terminals are switched in 8...
Page 102 Chapter 6 Parameter Description source B frequency 1: Relative to frequency source Regulating variable F1.0.09 frequency source B during 000%~150% superposition When the Product’s set frequency is given by frequency A+B or frequency A-B, A is the primary given value while B is auxiliary given value by default. This function code F1.0.09, which decides the size for regulation degree of frequency source B, is the percentage relative to the range of frequency source B (set by function code F1.0.08).
Page 103 Chapter 6 Parameter Description 0: Given by figure (F1.0.14) 1: Given by external terminal 2: Given by external terminal 3: Given by multi-segment Upper limit frequency instruction terminal F1.0.13 source 4: Given by PULSE (DI6) 5: Given by communication 6: Operation result 1 7: Operation result 2 8: Operation result 3 9: Operation result 4...
Page 104 Chapter 6 Parameter Description 8: Operation result 3 9: Operation result 4 The upper limit frequency is decided by the internal operation module after calculation and setting. For details of operation module, please refer to description of function code F5.1.26~F5.1.39. The operation results can be checked through function code F9.0.46~F9.0.49 Note: The upper limit frequency should not be set as negative value;...
Page 105 Chapter 6 Parameter Description normal running when it is above the min. output frequency, or enter running based on the set mode of F1.0.18 when it is below the min. output frequency. Factory Function Name Set Range Default Code Value 0: Run at the min.
Page 106 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value F1.0.21 Hopping frequency 1 000.00~Max. frequency 000.00 F1.0.22 Hopping frequency 2 000.00~Max. frequency 000.00 Range hopping F1.0.23 000.00~Max. frequency 000.00 frequency Hopping frequency is a function that can make the Product’s hopping frequency evade the load resonance area of drive system.
Page 107 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value Action benchmark 0: Running frequency F1.0.25 frequency Given 1: Given frequency keyboard during running This function code determines the frequency correction method when keyboard ▲, ▼ key or terminal UP/DOWN has action, and whether has increase/decrease based on the running frequency or given frequency.
Page 108 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value Reference frequency 0: Max. frequency F1.0.27 acceleration/deceleration 1: Given frequency period 2: 100Hz Unit 0: 1s F1.0.28 acceleration/deceleration 1: 0.1s period 2: 0.01s 0: Max. frequency The acceleration/deceleration period, which is between frequency 0 and the max.
Page 109 Chapter 6 Parameter Description T1 is the set value of function code F1.0.29. The slope of output frequency in this period will gradually increase from zero. T2 is the set value of function code F1.0.30. The slope of output frequency in this period will gradually decrease to zero.
Page 110 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value Switching frequency point 000.00Hz~Max. F1.0.39 000.00 between acceleration 1 and 2 frequency Switching frequency point 000.00Hz~Max. F1.0.40 000.00 between deceleration 1 and 2 frequency Switching frequency point 000.00Hz~Max. F1.0.41 000.00 between acceleration 2 and 3...
Page 111 Chapter 6 Parameter Description Relative max. frequency F1.0.50 Swing frequency amplitude 000.0%~100.0% 000.0 F1.0.51 Jump amplitude 00.0%~50.0% 00.0 F1.0.52 Swing frequency period 0000.1s~3000.0s 0010.0 Rise time swing F1.0.53 000.1%~100.0% 050.0 frequency triangle wave The function codes above are used for swing frequency control. Group F1.1 Motor Parameter Setting Function Factory Default...
Page 112 Chapter 6 Parameter Description is too high, especially that the Product’s rated current is higher than that of motor. When F1.1.06=01.00, the motor overload protection level is 100% motor rated current. Function Factory Name Set Range Code Default Value 0: No action Control over parameter 1: Static identification F1.1.07...
Page 113 Chapter 6 Parameter Description Function code F1.1.10~F1.1.14 is the intrinsic parameter of AC asynchronous motor. There are certain requirements for motor parameters, especially the vector control, regardless of VF/ control or vector control; the value of F1.1.10~F1.1.14 must be very close to the intrinsic parameter of motor and the vector control performance can be better when parameters are more accurate.
Page 114 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value Frequency of broken line F1.2.01 000.00Hz~F1.2.03 000.00 V/F point 1 Voltage of broken line V/F F1.2.02 000.0%~100.0% 000.0 point 1 Frequency of broken line F1.2.03 F1.2.01~F1.2.05 000.00 V/F point 2 Voltage of broken line V/F F1.2.04 000.0%~100.0%...
Page 115 Chapter 6 Parameter Description Make compensation to the output voltage in low-frequency working area, in order to make compensation to the low-frequency torque characteristic of V/F control. Generally, the default factory value can meet the requirements; otherwise, overcurrent fault may occur when compensation is too high. It is recommended to increase this parameter when load is heavy while motor has insufficient low-frequency torque.
Page 116 Chapter 6 Parameter Description This function code is the response time when making slip compensation to VF control of asynchronous machine; the response will be slower when this function code increases, or be faster when this function code decreases; however, oscillation may occur easily when this function code is too low.
Page 117 Chapter 6 Parameter Description The function codes above can select different velocity ring PI parameters at different running frequencies of the Product. The velocity ring PI regulation parameter will be F1.3.00 and F1.3.01 when the running frequency is lower than switch frequency 1 (F1.3.02), or the speed ring parameter will be F1.3.03 and F1.3.04 when the running frequency is higher than switch frequency 2 (F1.3.05).
Page 118 Chapter 6 Parameter Description 3: Given by multi-segment instruction terminal 4: Given by PULSE (DI6) 5: Given by communication 6: MIN (VF1, VF2) 7: MAX(VF1, VF2) 8: Operation result 1 9: Operation result 2 10: Operation result 3 11: Operation result 4 0: Given by figure (F1.3.08) The upper limit of vector control torque is given by the set value of function code F1.3.08...
Page 119 Chapter 6 Parameter Description The upper limit of vector control torque is given by the lower input between VF1 and VF2. 7: MAX(VF1, VF2) The upper limit of vector control torque is given by the higher input between VF1 and VF2. 8: Operation result 1 9: Operation result 2 10: Operation result 3...
Page 120: Group F2 Of Motor Control Parameters And Fault Protection
Chapter 6 Parameter Description Note: For integral controller of velocity loop, the integral time is not taken as dimension, but the integral gain is set directly. The entire control loop may have oscillation when velocity loop PI gain is too high; the PI proportional gain or integral gain can be reduced manually in case of current oscillation or large torque ripple.
Page 121 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value Over-modulation F2.0.07 100%~120% coefficient This function code is the overmodulation coefficient of output voltage in case of weak magnetism area. The voltage and current harmonic will increase along with the function code.
Page 122 Chapter 6 Parameter Description 5: Given by communication 6: MIN(VF1, VF2) 7: MAX(VF1, VF2) 8: Operation result 1 9: Operation result 2 10: Operation result 3 11: Operation result 4 12: Standby torque source 1 13: Standby torque source 2 0: Given by figure (F2.1.02) The torque is given by the set value of function code F2.1.02 1: Given by external terminal VF1...
Page 123 Chapter 6 Parameter Description 8: Operation result 1 9: Operation result 2 10: Operation result 3 11: Operation result 4 The set torque is decided by the operation result that passes calculation and setting of internal operation module. For details of operation module, please refer to description of function code F5.1.26~F5.1.39.
Page 124 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value 0: Direct startup F2.2.00 Starting mode 1: Speed tracking startup 2: Braking restart 0: Direct startup The Product starts running from the starting frequency. 1: Speed tracking startup The Product will firstly judge the motor speed and direction, then start at the tracked motor frequency and realize smooth and impact-free startup of revolving motor.
Page 125 Chapter 6 Parameter Description running directions; the velocity tracking has small current and high speed. However, parameter identification is required. Refer to function code F1.1.07 for the details of parameter identification. Note: This function code applies only if startup mode is speed tracking startup (i.e.
Page 126 Chapter 6 Parameter Description Min. frequency of velocity F2.2.08 000.00Hz~10.00Hz 1.5HZ tracking When the search frequency is below the value of F2.2.08, the motor is considered as static startup status and it will be switched to normal startup mode directly. This value should not be too low; otherwise, it may lead to tracking failure. Function Factory Default Name...
Page 127 Chapter 6 Parameter Description braking when reaching the DC braking period that is set in F2.2.15 to complete the shutdown process. Set the waiting time F2.2.13 of DC braking at shutdown properly to prevent the fault, such as overcurrent of DC braking at high speed. The DC braking current at shutdown F2.2.14 is the percentage of motor rated current;...
Page 128 Function Factory Default Name Set Range Code Value 0: Free shutdown 1: Stop by shutdown mode 2: Continue operation Selection Ones place: Motor overload fault Tens place: Input missing phase F2.3.03 00000 protection Hundreds place: Output missing action phase Thousands place: External fault Ten thousands place: Communication error 0: Free shutdown...
Page 129 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value Hundreds place: Initial position error Thousands place: Reserved Ten thousands place: Reserved This function code F2.3.03~F2.3.06 is used for setting the action after the Product gives out alarm of fault. Each bit in selection of fault protection action corresponds to one fault protection.
Page 130 Chapter 6 Parameter Description running frequency when the Product gives out alarm of fault. It is the percentage of the max. frequency. Function Factory Default Name Set Range Code Value Missing phase protection of 0: Disable F2.3.09 input Enable Sensitivity of input missing 01~10 (lower value, F2.3.10...
Page 131 Chapter 6 Parameter Description Have short circuit detection to output before each running. The Product will report Err38 fault in case of output short circuit. Manual reset is not allowed when this fault occurs. The fault can be eliminated after powering on again. When Err38 fault occurs, the user can remove the connection cable between the Product and motor, use VF to control running without connecting motor, to see if Err38 fault occurs;...
Page 132 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value F2.3.17 Selection of load loss 0: Invalid 1: Valid protection F2.3.18 Detection level of load 00.0%~100.0% (motor 010.0 loss rated current) F2.3.19 Detection time of load 0.0s~60.0s 01.0 loss The function code F2.3.17 is used for setting whether load drop function is valid.
Page 133 Chapter 6 Parameter Description detected by the Product, exceed the corresponding velocity of velocity detection value F2.3.20 and the last period exceeds velocity detection period F2.3.21. Function Factory Default Name Set Range Code Value Detection value F2.3.22 00.0%~50.0% major velocity deviation Detection period 00.0: No detection...
Page 134 Chapter 6 Parameter Description recovered. 0: Fire hazard mode 0 F2.3.28 Selection of fire hazard mode 1: Fire hazard mode 1 2: Fire hazard mode 2 Running frequency of fire F2.3.29 000.01Hz~Max. frequency 50.00 hazard When DI terminal is selected as function 61 (fire hazard function), it is recommended to set F2.3.01 (waiting interval of fault auto reset) above 10S, in order to improve the Product’s service life.
Page 135: Group F3 Of External Terminal
Chapter 6 Parameter Description Product will shut down after the faults of Err01, Err02, Err03, Err04, Err05, Err06, Err07, Err08, Err09, Err16, Err17, Err34 and Err38, the faults will reset automatically after waiting for the period of F2.3.01 but the Product will not have auto startup;...
Page 136 Chapter 6 Parameter Description F3.0.05 (multi-segment DI5 terminal function 0~61 instruction terminal selection F3.0.06 DI6 terminal function 0~61 08 (free shutdown) selection F3.0.07~ Reserved F3.0.10 The function codes above can be used for setting the functions of digital input terminals. The available functions are as shown in table below: Function Description Value...
Page 137 Chapter 6 Parameter Description Multi-segment instruction terminal 2 Multi-segment instruction terminal 3 Multi-segment instruction terminal 4 Realize remote fault reset through this Fault reset (RESET) terminal. It has the same function with RESET key on keyboard. When this terminal is valid, the Product will enter deceleration shutdown, but all running Pause running parameters will be recorded.
Page 138 Chapter 6 Parameter Description When this terminal is valid, the Product’s Disable output frequency will not be affected by acceleration/deceleration external signals (except shutdown command) PID control is invalid temporarily; the Product will keep running at the current Pause PID output frequency without making PID adjustment of frequency source.
Page 139 Chapter 6 Parameter Description The Product can have deceleration shutdown External parking terminal according to deceleration time 4 through this terminal in any running control mode When the ones place of F6.0.28 is 1 (i.e. integral separation is valid) and this terminal is valid, then integral adjustment function is Pause PID integral paused, while the proportional adjustment...
Page 140 Chapter 6 Parameter Description When the timing of internal timer is controlled by this terminal, the terminal will Timer input terminal 2 control the timing start or stop of timer. Refer to description of function code F5.1.23 When clearing of internal timer is controlled by this terminal, this terminal will be valid Timer clear terminal 1 and timer will be reset.
Page 141 Chapter 6 Parameter Description Multi-segment F5.0.07 instruction 2 Multi-segment F5.0.09 instruction 3 Multi-segment F5.0.11 instruction 4 Multi-segment F5.0.13 instruction 5 Multi-segment F5.0.15 instruction 6 Multi-segment F5.0.17 instruction 7 Multi-segment F5.0.19 instruction 8 Multi-segment F5.0.21 instruction 9 Multi-segment F5.0.23 instruction 10 Multi-segment F5.0.25 instruction 11...
Page 142 Chapter 6 Parameter Description Min. value of A, B (equals to F1.0.07=5) Standby frequency source 1 (equals to F1.0.07=6) Standby frequency source 2 (equals to F1.0.07=7) Attached Table 3 Function Description of Acceleration/deceleration Selection Terminal Termi Termi Acceleration/decelerat Corresponding Parameters nal 2 nal 2 ion Selection...
Page 143 Chapter 6 Parameter Description anti-interference capability when the DI input terminal can have false action easily due to interference. However, the response of DI terminal may slow down when this filtering time increases. Function Factory Name Set Range Code Default Value Terminal change rate of F3.0.12 00.001Hz/s~65.535Hz/s...
Page 144 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value 00: Inputted as normal analog Function of Terminal VF1 quantity F3.0.18 as digital input 01~61: Function of digital input terminal 00: Inputted as normal analog Function of Terminal VF2 quantity F3.0.19 as digital input...
Page 145 When low level valid is selected, it will be invalid when corresponding DI terminals are connected or valid when they are disconnected. Note: DI5~D6 are terminals on the SD100 series IO expansion card. Group F3.1 Group DO of External Output Terminal...
Page 146 Factory Function Name Set Range Default Code Value 11: PLC circle completed Accumulated running period reached 13: Frequency restricted in progress Torque restricted progress 15: Running readiness 16: VF1>VF2 17: Upper limit frequency reached 18: Lower limit frequency reached output after shutdown) 19: Under-voltage status output...
Page 147 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value reached 36: Output current out of limit 37: Lower limit frequency reached (output after shutdown) 38: Alarm output 39: PLC stage completed Current running time reached 41: Fault output (no output of under-voltage) 42: Timing of Timer 1 reached 43: Timing of Timer 2 reached...
Page 148 Function Description Value The multi-function output terminal has no No function function There’s output frequency (can be zero) and Inverter running output ON signal when the inverter is under progress running status Output ON signal when the Product has fault Fault shutdown output and shutdown Frequency level detection...
Page 149: Upper Limit
Function Description Value reaches the torque limit value Output ON signal when the Product’s main circuit and control circuit power supply are Running readiness stabilized, no fault information is detected by the Product and the Product is under running status Output ON signal when the input value of VF1>VF2 VF1 is higher than that of VF2...
Page 150 Function Description Value reaches the set timing Output ON signal when the value of analog VF1 input is higher than the set value (VF1 VF1 input out of limit input upper limit) of function code F4.0.20 lower than the set value (VF1 input lower limit) of function code F4.0.19 Output ON signal when the Product is under...
Page 151 Chapter 6 Parameter Description Function Description Value the set time of function code F5.1.25 Fire hazard mode Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Synchronize intermediate The same with action of M1 relay M1 Synchronize intermediate The same with action of M2 relay M2 Synchronize intermediate The same with action of M3...
Page 152 Chapter 6 Parameter Description This function code is used for defining whether using YO/FMP terminal as pulse output or open collector. When it is used as pulse output (i.e. F3.1.08=0), please refer to description of function code F3.3.02 for the detailed functions, and the max. frequency of output pulse is decided by function code F3.1.09.
Page 153 Chapter 6 Parameter Description The function codes above are used for setting the relationship between analog input and its corresponding value. It is straight-line relationship. The analog quantity should be calculated according to “Max. input of Curve 1” when the analog input voltage is higher than the given “Max. input of Curve 1” (F3.2.02);...
Page 154 Chapter 6 Parameter Description Ten thousands place: Input resolution of keyboard potentiometer 0:00.01Hz 1:00.02Hz 2:00.05Hz 3:00.10Hz 4:00.20Hz 5:00.50Hz 6:01.00Hz (keyboard potentiometer is invalid) The ones place and tens place of this function code are used for selecting the corresponding given curve of analog input VF1 and VF2 respectively. Any of 4 curves can be selected as the 2 analog inputs.
Page 155 Chapter 6 Parameter Description F3.2.17 Corresponding set value of -100.0%~100.0% input of Curve 3 deflection 060.0 point 2 F3.2.18 Max. input of Curve 3 F3.2.16~10.00V 10.00 F3.2.19 Corresponding set value of -100.0%~100.0% 100.0 Curve 3 max. input The functions and use methods of Curve 3 are roughly the same with those of Curve 1 and 2 (please refer to description of Curve 1).
Page 156 Chapter 6 Parameter Description Group F3.3 Group AO of External Output Terminal Function Factory Name Set Range Code Default Value F3.3.00 Set analog output FM1 0~20 F3.3.01 Set analog output FM2 F3.3.02 Given FMP output (Terminal YO/FMP is used as FMP, i.e. F3.1.08=0) The function code F3.3.00 and F3.3.01 define the function of analog output FM1 and FM2 respectively.
Page 157: Group F4 Of Auxiliary Function And Aiao Curve Correction
Chapter 6 Parameter Description Operation result 1 -1000~1000 Operation result 2 0~1000 Operation result 3 -1000~1000 Operation result 4 0~1000 Function Factory Default Name Set Range Code Value F3.3.03 Analog FM1 output offset -100.0%~100.0% 000.0 F3.3.04 Analog FM1 output gain -10.00~10.00 01.00 F3.3.05...
Page 158 Chapter 6 Parameter Description Function Code Name Set Range Factory Default Value Accumulative running F4.0.01 0h~65000h 00000 reaches set time This function code is used for setting the Product’s accumulated running period. The Product’s multi-function output terminal will output ON signal when the actual accumulated running period reaches the set value of function code F4.0.01.
Page 159 Chapter 6 Parameter Description The Product’s multi-function output terminal will output ON signal when the Product’s output frequency exceeds certain value, and this value is called frequency detection FDT1. The Product’s multi-function output terminal will output OFF signal when its output frequency is lower than certain value of frequency detection FDT1, and this value is called FDT1 lag frequency.
Page 160 Chapter 6 Parameter Description frequency 1. The corresponding function of multi-function output terminal is output of Frequency 1 reached (26). See description of diagram below: Detection width frequency = Detection width of randomly reached frequency 1 (F4.0.08) × Max. frequency (F1.0.11) Function Factory Default Name...
Page 161 Chapter 6 Parameter Description T: Delay of zero current detection Function Factory Default Name Set Range Code Value 000.0%(no detection) F4.0.13 Output current overrun 200.0 000.1%~300.0% Detection delay of current F4.0.14 000.00s~600.00s 000.00 overrun The Product’s multi-function output terminal will output ON signal when the Product’s running current is higher than the set value of function code F4.0.13 and the last period exceeds the set value of function code F4.0.14;...
Page 162 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value F4.0.15 Current level detection 1 000.0%~300.0% 100.0 Detection width of current F4.0.16 000.0%~300.0% 000.0 level 1 The Product’s multi-function output terminal will output ON signal when the Product’s running current is within the positive/negative detection width of current level detection 1, or output OFF signal when the Product’s running current is outside the positive/negative detection width of current level detection 1.
Page 163 Chapter 6 Parameter Description The Product’s multi-function output terminal will output ON signal when the input value of analog VF1 is lower than the set value of function code F4.0.19. The corresponding function of multi-function output terminal is VF1 input below lower limit (21) or VF1 input overrun (31).
Page 164 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value F4.0.26 Set length 00000m~65535m 01000 F4.0.27 Actual length 00000m~65535m 00000 F4.0.28 Pulses per meter 0000.1~6553.5 0100.0 The function codes above are used for fixed length control. For details, please refer to 7.1.9 (fixed length function) Function Factory Default...
Page 165 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value F4.1.05 VF1 measured voltage 1 0.500V~4.000V 2.000 F4.1.06 VF1 display voltage 1 0.500V~4.000V 2.000 F4.1.07 VF1 measured voltage 2 6.000V~9.999V 8.000 F4.1.08 VF1 display voltage 2 6.000V~9.999V 8.000 F4.1.09 VF2 measured voltage 1 0.500V~4.000V...
Page 166: Group F5 Of Simplified Plc And Virtual Relay
Chapter 6 Parameter Description voltage into the corresponding function codes above and the Product will carry out auto correction. 6.6 Group F5 of Simplified PLC and Virtual Relay Group F5.0 Multi-speed and Simplified PLC Factory Function Name Set Range Default Code Value 0: Shutdown after finishing...
Page 167 Chapter 6 Parameter Description Hundreds place: Selection of fault shutdown memory 0: Fault shutdown no memory 1: Fault shutdown memory PLC power-off memory: Record the running stage and frequency of PLC before power-off and continue running from the memory stage in the next power-on. The PLC process will be restarted after each power-on when power-off no memory is selected.
Page 168 Chapter 6 Parameter Description F5.0.23 Stage instruction 10 -100.0%~100.0% 000.0 F5.0.24 Stage 10 running period 0000.0s~6553.5s 0000.0 F5.0.25 Stage instruction 11 -100.0%~100.0% 000.0 F5.0.26 Stage 11 running period 0000.0s~6553.5s 0000.0 F5.0.27 Stage instruction 12 -100.0%~100.0% 000.0 F5.0.28 Stage 12 running period 0000.0s~6553.5s 0000.0 F5.0.29...
Page 169 Chapter 6 Parameter Description Function Factory Name Set Range Code Default Value direction 0: Default direction 1: Reverse direction The ones place of stage attribute decides the acceleration/deceleration time of simplified PLC running in all stages. The tens place of stage attribute decides the frequency source of simplified PLC running or multi-segment instruction in all stages.
Page 170 Chapter 6 Parameter Description hundreds place of control word C. Please refer to description of function code F5.1.07~F5.1.11 For details, please refer to 7.1.12 (programming function of simplified internal relay) Function Factory Name Set Range Code Default Value 0: Set as 0 1: Set as 1 Ones place: M1 Control word A of...
Page 171 Chapter 6 Parameter Description Factory Function Name Set Range Default Code Value 00~09: DI1~DI10 10~14: M1~M5 15~16: VF1, VF2 17~19: Standby 20~79: Output function 00~59 of corresponding multi-function output terminal thousands place thousands place: Input selection 00~09: DI1~DI10 10~14: M1~M5 15~16: VF1, VF2 17~19: Standby 20~59: Output function 00~39 of...
Page 172 Chapter 6 Parameter Description The tens place and ones place of function codes above are used for setting the action direction of intermediate relay after acquiring the logic operation result, i.e. the execution action (it can correspond to any of digital input function); while the thousands place and hundreds place are used for controlling the relay corresponding to bit that is 2 of F5.1.00 (it can correspond to any type of multi-function output terminal).
Page 173 Chapter 6 Parameter Description 2: Negation control by timer input terminal 1 3: Controlled by timer input terminal 2 4: Negation control by timer input terminal 2 Hundreds place: Timer 1 clearing control Thousands place: Timer 2 clearing control 0: Controlled by timer clearing terminal 1: Controlled by timer clearing terminal Ten thousands place: Timing unit 0: Second...
Page 174 Chapter 6 Parameter Description The function code F5.1.24 and F5.1.25 are used for setting timing of Timer 1 and 2 respectively. Function Factory Name Set Range Code Default Value 0: No operation 1: Add 2: Subtraction 3: Multiplication 4: Division 5: Judgment of being greater than Operation...
Page 175 Chapter 6 Parameter Description 9: Division setting coefficient has 4 decimal places A: Division setting coefficient has no decimal place B: Division setting coefficient has 1 decimal place C: Division setting coefficient has 2 decimal places D: Division setting coefficient has 3 decimal places E: Division setting coefficient has 4 decimal places...
Page 176 Chapter 6 Parameter Description thousands place: Input operation mode 0: The input has operation via unsigned number 1: The input has operation via signed number Operation 1 F5.1.30 setting 00000~65535 00001 coefficient The function codes above are used for setting the input address and setting coefficient of operation 1.
Page 177 Chapter 6 Parameter Description unsigned number 1: The input has operation via signed number Operation F5.1.33 2 setting 00000~65535 00001 coefficient Thousands place, hundreds place, tens place and ones place: Address of operation 3 input A Ten thousands place: Input operation Operation F5.1.34 00000...
Page 178: Group F6 Of Pid Control And Communication Control
Chapter 6 Parameter Description unsigned number 1: The input has operation via signed number Operation F5.1.39 4 setting 00000~65535 00001 coefficient The function codes above are used for setting the input address and setting coefficient of operation 2, 3, 4. For details, please refer to description of function code F5.1.28~F5.1.30.
Page 179 Chapter 6 Parameter Description 4: Given by PULSE (DI6) The PID given value is given by the high-speed pulse frequency of digital input terminal DI6 (terminal function can be undefined). The corresponding relationship between high-speed pulse frequency and PID given value can be given by function code F3.0.13~F3.0.16 and they have straight-line relationship.
Page 180 Chapter 6 Parameter Description 6: MAX[VF1, VF2] 7: MIN[VF1, VF2] Multi-segment instruction terminals are switched above 9: Operation result 1 10: Operation result 2 11: Operation result 3 12: Operation result 4 0: Given by external terminal VF1 1: Given by external terminal VF2 The PID feedback value is given by analog input terminal 2: VF1-VF2 The PID feedback value is given by analog VF1-VF input...
Page 181 Chapter 6 Parameter Description VF1+VF2 (equivalent to F6.0.02=3) Given by PULSE (equivalent to F6.0.02=4) Given by communication (equivalent to F6.0.02=5) MAX[VF1,VF2] (equivalent to F6.0.02=6) MIN[VF1,VF2] (equivalent to F6.0.02=7) 9: Operation result 1 10: Operation result 2 11: Operation result 3 12: Operation result 4 The PID feedback value is decided by the operation result that passes calculation and setting of internal operation module.
Page 182 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value F6.0.05 Proportional gain KP1 000.0~100.0 020.0 F6.0.06 Integral time TI1 00.01s~10.00s 02.00 F6.0.07 Differential time TD1 00.000s~10.000s 00.000 The regulation volume and response speed will increase along with the increase of proportional gain KP1, but the system oscillation may occur if the value is too high.
Page 183 Chapter 6 Parameter Description F6.0.11 Integral time TI2 00.01s~10.00s 02.00 F6.0.12 Differential time TD2 00.000s~10.000s 00.000 The function codes above have the same function with function code F6.0.05~F6.0.07. Please refer to the description of F6.0.05~F6.0.07 Function Factory Default Name Set Range Code Value 0: No switch...
Page 184 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value F6.0.16 PID initial value 000.0%~100.0% 000.0 PID initial value hold F6.0.17 000.00~650.00s 000.00 period When the Product is started, firstly accelerate to the PID initial value according to the normal acceleration, maintain running at the PID initial value status, then make PID regulation after passing the time given by F6.0.17.
Page 185 Chapter 6 Parameter Description Function Factory Default Name Set Range Code Value 0: No operation F6.0.20 PID shutdown operation 1: Operation This function code is used for setting whether PID has operation when the Product is under shutdown status 0: No operation PID operation is entered when the Product is running, or PID operation is not entered (this is selected in general) when the Product has shutdown 1: Operation...
Page 186 Chapter 6 Parameter Description of feedback and stability of inverter frequency output, but the fast response of system can be reduced. PID output filtering time: Set the time to reduce the sudden change of inverter frequency output, but the fast response of system can be reduced. Function Factory Default Name...
Page 187 Chapter 6 Parameter Description When “Continue integral” (i.e. tens place of F6.0.28 is 0), the integral regulation function of PID will be engaged in regulation. Group F6.1 Communication Control Function Factory Name Set Range Code Default Value Ones place: MODBUS baud rate 0: 1200 1: 2400 2: 4800...
Page 188: Customized Group F7 Of User Parameters
Chapter 6 Parameter Description This function code is the treatment method in case of communication fault. 6.8 Customized Group F7 of User Parameters Group F7.0 Basic Parameter Group Factory Function Name Set Range Default Code Value F7.0.00 User function 0 U0.1.01 U0.1.01 F7.0.01...
Page 189: Group F8 Of Manufacturer Functions
Chapter 6 Parameter Description 6.9 Group F8 of Manufacturer Functions Group F8.0 Manufacturer Parameters Function Factory Default Name Set Range Code Value F8.0.00 Manufacturer password 00000~65535 00000 This function code is manufacturer password input and displays the specific function code of manufacturer. It should not be operated by user. 6.10 Group F9 of Monitoring Parameters Group F9.0 Basic Monitoring Parameters The parameter group F9 is used for monitoring the information of inverter...
Page 190 Function Name Description Unit Code F9.0.13 Check the inverter actual length that is Actual length used for fixed length purpose F9.0.14 Product of PID given value and PID set PID given value feedback range F9.0.15 Product of PID feedback value and PID PID feedback set feedback range F9.0.16...
Page 191 Chapter 6 Parameter Description Function Name Description Unit Code F9.0.46 Operation result 1 Check the value of operation result 1 F9.0.47 Operation result 2 Check the value of operation result 2 F9.0.48 Operation result 3 Check the value of operation result 3 F9.0.49 Operation result 4 Check the value of operation result 4 F9.0.50...
Page 192: Chapter 7 Common Functions & Application Cases
Chapter 7 Common Functions & Application Cases Chapter 7 Common Functions & Application Cases 7.1 Common Functions 7.1.1 Start/stop Control The Product has 3 start/stop control modes: Keyboard control, terminal control and communication control. 1. Keyboard Control (Set F1.0.04=0) Press “RUN” key on keyboard to start the Product, or press “STOP” key to stop the Product.
Page 193 Chapter 7 Common Functions & Application Cases Two-line type mode 2 (Set F3.0.00=1) The motor forward/reverse running is decided by any two DIx and DIy terminal of multi-function terminal, in which, DIx terminal is used as running enabling terminal, while DIy is terminal for confirming running direction, and their level is valid.
Page 194: Startup Mode
Chapter 7 Common Functions & Application Cases ● Three-line type control mode 2 (Set F3.0.00=3) The motor forward/reverse running is decided by any three DIx, DIy and DIn terminal of multi-function terminal, in which, DIn terminal is used as running enabling terminal;...
Page 195 Chapter 7 Common Functions & Application Cases frequency hold time (F1.0.20), and then accelerates to the given frequency according to the selected acceleration. ● Speed tracking startup (Set F2.2.00=1) The Product starts speed tracking according to the speed tracking mode given in speed tracking mode F2.2.02.
Page 196: Shut Down Mode
Chapter 7 Common Functions & Application Cases 2. Shutdown Mode The Product has 2 shutdown modes: Deceleration shutdown and free shutdown ● Deceleration shutdown (Set F2.2.11=0) When shutdown instruction is valid, the Product will reduce the output frequency according to the deceleration time selected, and realize shutdown when the output frequency is reduced to 0.
Page 197 Chapter 7 Common Functions & Application Cases 7.1.3 Acceleration/Deceleration Mode The Product provides 3 acceleration/deceleration modes according to the load characteristics and requirements of acceleration/deceleration time: Straight line, S curve 1 and S curve 2, which can be selected through function code F1.0.26. Besides, the unit of acceleration/deceleration time can be adjusted and be set through function code F1.0.28.
Page 198 Chapter 7 Common Functions & Application Cases 7.1.5 Running Frequency Control The Product provides two input channels of frequency sources, i.e. frequency source A and B, which can have independent running or be combined according to calculation. Each frequency source has 14 selections, in order to greatly satisfy the requirements for selecting different frequencies at site.
Page 199 Chapter 7 Common Functions & Application Cases 7.1.6 Multi-segment Speed Function The Product can switch 16 segments of speeds through different combinations of multi-segment instruction terminals. The missing setting bit is calculated by status 7.1.7 Simplified PLC Product segments speed maximally;...
Page 200 Chapter 7 Common Functions & Application Cases function F4.0.24 0: Given by figure (F4.0.25) 1: Given by external terminal VF1 Selection timing 2: Given by external terminal VF2 running period (Corresponding F4.0.25 of analog input range) F4.0.25 Timing running period 0000.0 min~6500.0 min 0000.0 The Product is provided with built-in timing function to realize timing running.
Page 201 Chapter 7 Common Functions & Application Cases 7.1.9 Fixed Length Function Factory Function Name Set Range Default Code Value F4.0.26 Given length 00000m~65535m 01000 F4.0.27 Actual length 00000m~65535m 00000 F4.0.28 Pulses per meter 0000.1~6553.5 0100.0 The Product is provided with built-in fixed length function to realize fixed length control.
Page 202 Chapter 7 Common Functions & Application Cases 7.1.10 Counting Function Factory Function Name Set Range Default Code Value F4.0.29 Given count value 00001~65535 01000 F4.0.30 Designated count value 00001~65535 01000 The Product’s counting function has 2-stage signal output, i.e. given count value reached and designated counting reached.
Page 203 Chapter 7 Common Functions & Application Cases 7.1.11 Distance Control Function Function Code Name Set Range Factory Default Value F4.0.31 Set distance 1 -3200.0~3200.0 0000.0 F4.0.32 Set distance 2 -3200.0~3200.0 0000.0 F4.0.33 Pulses per distance 000.00~600.00 000.00 The Product is provided with built-in distance control function. The corresponding function of digital input terminal should be set as “Encoder Phase A input”...
Page 204 Chapter 7 Common Functions & Application Cases 7.1.12 Programming Function of Simplified Internal Relay The Product is provided with 5 virtual intermediate delay relays to collect the physical signals from the Product’s digital input terminals, as well as the virtual signals from multi-function output terminal (00~59);...
Page 205 Chapter 7 Common Functions & Application Cases Function Set Value of Function Description Code Ones Place Input 1 rising edge When Input 1 rising edge is true, validness is set as the logic result is true valid When Input 2 rising edge is true, Input 2 rising edge the logic result is false validness is set as...
Page 206 Chapter 7 Common Functions & Application Cases By combining the example above, set F5.1.03 (control word B of M2) =01022, refer to description of function code F5.1.03: M2=DI2&&DI3, as shown in diagram below: The equivalents are shown in diagram below: Combining the examples above, set the tens place and ones place of F5.1.08 (correspond to control word C of M2) as 01 (corresponding function of digital input terminal), then M2 function is forward rotation.
Page 207 Chapter 7 Common Functions & Application Cases 7.1.13 Functions of Internal Timer The Product has 2 built-in timers to realize startup, shutdown timing and timer reset through the digital input terminal. Signals can be outputted through multi-function output terminal when timing is reached. The timer will start counting when signal of timer input terminal (terminal function 48~49) is valid.
Page 208 Chapter 7 Common Functions & Application Cases 7.1.14 Functions of Internal Operation Module The Product is provided with one built-in 4-way operation module that can collect the data (value after removing decimal point) from two function codes of the Product, to realize simple operation, and finally output the operation results to the special application scenarios.
Page 209 Chapter 7 Common Functions & Application Cases Corresponding Function Set value of Function Description Code When Address A data >Address B Judgment being greater data, the unsettled operation result is than 1; otherwise, it is 0 When Address A data = Address B Judgment data, the unsettled operation result is being equal to...
Page 210 Chapter 7 Common Functions & Application Cases Correspon Function ding Set Function Description Code value of places Multiplication setting coefficient Unsettled operation result × operation decimal setting coefficient÷10000 places Division setting Unsettled operation result ÷ operation coefficient has no setting coefficient decimal place Division setting...
Page 211 Chapter 7 Common Functions & Application Cases Operation Result Direction Operation Result Range Operation result indicates the -Max. frequency ~ Max. frequency (remove given frequency decimal point) Operation result indicates the 0~Max. frequency (remove decimal point) given upper frequency Operation result indicates PID -1000~1000 means -100.0%~100.0% given value Operation result indicates PID...
Page 212 Chapter 7 Common Functions & Application Cases The description above equals to: Operation result = (Value in F9.0.09 + Value in F9.0.10) ÷2 When F5.1.27= H.00A0, the description above equals to: Operation result = (Value in F9.0.09 + Value in F9.0.10) ÷ Value in F0.0.02 When F1.0.00=1, then Operation result = (Value in F9.0.09 + Value in F9.0.10) ÷...
Page 213 Chapter 7 Common Functions & Application Cases Relative max. frequency F1.0.50 Swing frequency amplitude 000.0%~100.0% 000.0 F1.0.51 Jump amplitude 00.0%~50.0% 00.0 F1.0.52 Swing frequency period 0000.1s~3000.0s 0010.0 Rise time swing F1.0.53 000.1%~100.0% 050.0 frequency triangle wave The swing frequency can improve the control performance of equipment in some scenarios, such as winding equipment of textile and chemical fiber, to improve the uniformity and evenness of spindle winding.
Page 214: Analog Input
Chapter 7 Common Functions & Application Cases Note: The swing frequency output frequency is restrained by the upper limit frequency and lower limit frequency. 7.1.17 Use of Analog Input/output 1. Analog Input The Product supports 2-way analog input; in which, VF1 can be voltage signal or current signal, while VF2 can be voltage input signal only.
Page 215 Chapter 7 Common Functions & Application Cases sampling value of VF port can be checked in function code F9.0.09, F9.0.10. See description of diagram below: Note: The Product’s analog input is based on 0V~10V by default. When input is 0mA~20mA, it can be equalized as 0V~10V. When input is 4mA~20mA, it can be equalized as 2V~10V.
Page 216: Digital Input
Chapter 7 Common Functions & Application Cases 7.1.18 Use of Digital Input/output 1. Digital Input The Product is fitted with 4 digital input ports by default and numbered DI1~DI4; besides, it can be added with 2 digital input terminals, which are numbered DI5~DI6, by connecting IO expansion card;...
Page 217 The application of using upper computer for controlling inverter running via communication increases along with the wide application of auto control, and communication with SD100 series inverter can be established by using RS485 network. As the Product’s control board has no communication interface, the external communication expansion card should be connected and be programmed on upper computer, in order to realize communication.
Page 218 Chapter 7 Common Functions & Application Cases motor, in order to realize good control performance and running efficiency. The known motor parameters can be manually inputted in F1.1.10~F1.1.14; otherwise, parameter identification and control should be carried out. Parameter identification control includes static identification and complete identification.
Page 219: Application Cases
Chapter 7 Common Functions & Application Cases Steps of motor parameter identification: 1. Please confirm the status of motor when it can be separated from load completely, and make sure the motor will not affect other relevant equipment during rotation. 2.
Page 220 Chapter 7 Common Functions & Application Cases The following parameters are the common parameters of dual-pump function which should be set by customer (please firstly input 100 to F0.1.25 before user has debugging of dual-pump function) Function Name Description Code Range Selection Start via RUN key on panel (default)
Page 221 Chapter 7 Common Functions & Application Cases 7.2.2 Ball Mill Common parameters of ball mill (please input 102 into F0.1.25 before debugging of ball mill) Function Name Set Range Factory Default Value Code 0: Basic mode (prefix is ‘F’) F0.1.01 Display mode 1: User mode (prefix is ‘U’) 2: Verification mode (prefix is ‘C’)
Page 222 Chapter 7 Common Functions & Application Cases 7.2.3 Constant-pressure Water Supply Control (F0.1.25 =101) 1. Common wiring diagram Note: Pull J5-1 (VF1 dial switch) to U side for remote pressure gauge, or pull J5-1 to I side for pressure transmitter. 2.
Page 223 Chapter 7 Common Functions & Application Cases as follows: When F0.1.25 F1.0.05=8 F0.1.18=H.C015 F0.1.21=H.0C02 F5.1.00=11111 is set as 101, F5.1.02=780 F5.1.03=790 F5.1.04=11106 F5.1.05=38376 right F5.1.06=21132 F5.1.09=14 F5.1.24=900 F5.1.25=100 parameters F5.1.26=H.7353 F5.1.27=H.0505 F5.1.28=6004 F5.1.29=5124 will F5.1.30=1000 F1.0.16=1000 F5.1.34=6004 F5.1.35=5125 automatically. F5.1.36=1000 F5.1.31=9015 F5.1.32=9046 F5.1.37=9048...
Page 224 Chapter 7 Common Functions & Application Cases Function Name Description Code Value feedback F9.0.15 Display PID feedback (display value) No operation Backup current parameters of user Recover factory F0.1.25 Recover backup parameters of user default value Recover factory default parameters of constant-pressure water supply function Pump Control Parameters Pump function invalid...
Page 225 Chapter 7 Common Functions & Application Cases The regulation volume and response speed will increase along with the increase of proportional gain KP1, but the system Proportional gain F6.0.05 020.0 oscillation may occur if the value is too high. The system will have higher stability but lower response when KPI value is decreased.
Page 226 Chapter 7 Common Functions & Application Cases Monitoring Contents of Shutdown Status Monitoring Contents of Running Status: 7.2.4 Local/remote Control (F0.1.25 =104) When 104 is inputted in F0.1.25, the following parameters are set as follows: When F0.1.25 F1.0.04=1 F1.0.05=2 F1.0.06=4 F1.0.07=8 is set as 104, F3.0.01=0...
Page 227 Chapter 7 Common Functions & Application Cases 3. DI1 is local start/stop button (connect to start, or disconnect to shut down) 4. DI2 is remote start/stop button (connect to start, or disconnect to shut down) 5. DI3 is local/remote switch button (connect to enter remote mode, disconnect to enter local mode) The following parameters are common parameters which should be set by customer (please input 104 into F0.1.25 firstly before user has debugging of...
Page 228: Chapter 8 Rs-485 Communication Of Sd100 Series Inverter
Chapter 8 RS-485 Communication of SD100 Series Inverter Chapter 8 RS-485 Communication of SD100 Series Inverter 1. Introduction to RS-485 Communication Terminal of SD100 Series Inverter The external communication expansion card must be connected to realize communication, for the Product’s control board has no RS-485 communication terminal.
Page 229 Chapter 8 RS-485 Communication of SD100 Series Inverter 3. Introduction to Standard MODBUS Communication Format 3.1 Character Structure (8-N-2, F6.1.01=0) Data bit Stop bit Start Stop bit (8-E-1, F6.1.01=1) Stop bit Start Even Data bit parity check (8-O-1, F6.1.01=2) Even...
Page 230 Chapter 8 RS-485 Communication of SD100 Series Inverter Master station reply: Data address in case of 06 function code (16-bit hexadecimal umber), data bit in case of 03 function code (8-bit hexadecimal number) DATA Master station sending: Data contents in case of 06 function code...
Page 231 Chapter 8 RS-485 Communication of SD100 Series Inverter length Example 0005H 1388H 949DH Format of command string replied and written by slave station: Character Slave Write Function Data Name Address Command Code Contents Check Address Character 1Byte 1Byte 2Byte 2Byte...
Page 232 Chapter 8 RS-485 Communication of SD100 Series Inverter 4. Definition of Parameter Address of Communication Protocol The Product has many function codes and some non-function parameters, of which the specific read/write attribute is as follows Function code F1~F8 Readable and writable...
Page 233 Chapter 8 RS-485 Communication of SD100 Series Inverter Function Parameter Definition Function Description Code Address 0003H Forward inching 0004H Reverse inching 0005H Free shutdown 0006H Deceleration shutdown 0007H Fault reset Frequency instruction or upper limit frequency source (percentage of the max. frequency, no...
Page 234 Chapter 8 RS-485 Communication of SD100 Series Inverter Function Parameter Definition Function Description Code Address External fault Communication error Inverter overheat Inverter hardware error Motor-to-ground short circuit Motor identification error Motor load drop PID feedback loss Customized fault 1 Customized fault 2...
Page 235 Chapter 8 RS-485 Communication of SD100 Series Inverter Example 2: Given frequency of 1# inverter (no memory) The given frequency of 1# inverter is 100.00% of the max. frequency The method is as follows: Remove the decimal point of 100.00 and it will be...
Page 236: Chapter 9 Troubleshooting
Chapter 9 Troubleshooting Chapter 9 Troubleshooting 9.1 Faults & Troubleshooting of Inverter Fault Description Details Troubleshooting Display Err00 No fault ● Check if the Product’s output circuit has short circuit ●Check if input voltage is too low; ● Check if load has sudden output current Overcurrent...
Page 237 Chapter 9 Troubleshooting ● Check if motor and line have short circuit, grounding or they are too long; ● Carry parameter Output current exceeds Overcurrent identification; the overcurrent value Err03 during ●Extend the deceleration time; during deceleration deceleration ●Check if input voltage is too low; running of the Product ●...
Page 238 Chapter 9 Troubleshooting ● Inspect the resistance of motor Module auto protection coil Module Err07 is triggered by external ●Inspect motor insulation fault fault of the Product ● Inverter module has breakdown damage ● ● Check if power cable has good contact;...
Page 239 Chapter 9 Troubleshooting ● Inspect external communication circuit ● Upper computer has operation Communication error of Communic error Err14 the Product or other ation error ● Communication parameter device setting error ● Communication protocol inconsistent; ● Inspect the running conditions and ventilation of fan;...
Page 240 Chapter 9 Troubleshooting Fault Description Details Troubleshooting Display Fault 1 signal given by user through ● Check if customized fault 1 Customized Err21 multi-function terminal condition is eliminated, then reset fault 1 or PLC programming function Fault 2 signal given by user through ●...
Page 241: Diagnosis & Troubleshooting Of Motor Faults
Chapter 9 Troubleshooting The Product’s running current high ●Check if motor has overload or Fast current continuously blockage; Err34 limiting exceeds allowed ● Check if the Product has timeout period current insufficient capacity limitation Motor ● Make sure the Product is switching Motor is switched while Err35...
Page 242 Chapter 9 Troubleshooting correct? properly Connect the Phase U, Whether wiring of Terminal U, V and V and W of motor Motor W is correct? lead wire reverse accordingly. rotation Whether the running input signal of Change the wiring forward/reverse rotation is correct? Whether the wiring of given frequency Change the wiring circuit is correct?
Page 243: Appendix 1 Regular Maintenance & Inspection Method
Appendix 1 Regular Maintenance & Inspection Method Appendix 1 Regular Maintenance & Inspection Method Frequenc Inspection Item Inspection Standard Method Temperatu Whether there’s dust? -10~+40° Thermom Whether C, no dust. eter Refer ambient √ Humidity: Hygrome precautions temperature humidity condensati Recorder are proper? on below...
Page 244 Appendix 1 Regular Maintenance & Inspection Method Whether conductor rusted? √ Visual inspection No fault Whether wiring sheath is damaged? Whether there’s √ Visual inspection No fault damage? Inspect Digital Loosen the Product and measure the resistance impedance multimet √ between R, S, <->...
Page 245 Appendix 1 Regular Maintenance & Inspection Method Whether resistor No fault Visual insulation has The error inspection Digital must damage Disconnect multimete Whether √ within resistor r/analog wiring ±10% and measure tester display resistor it with meter damage (open resistance circuit) Measure the Whether each...
Page 246: Appendix 2 Guidance For Selecting Optional Parts
Appendix 2 Guidance for Selecting Optional Parts Appendix 2 Guidance for Selecting Optional Parts This series of product can be mounted with peripheral equipment by user as required. A2.1 AC reactor ACL The AC reactor can suppress the higher harmonics of inverter input current and improve the power factor of the Product.
Page 247 Appendix 2 Guidance for Selecting Optional Parts The Product’s panel is fitted with elaborate and convenient operation key. User may purchase the extended cable in order to move the keyboard to other places outside the Product and put forward the demand when placing an order. The distance between operation keyboard and the main engine should be within 10m, for serial communication is adopted between the operation keyboard and the main engine.
Page 248 Appendix 2 Guidance for Selecting Optional Parts Resistance of Power of Inverter Type Braking Unit Model Braking Resistor Braking (Ω) Resistor (W) S2 (single-phase 220V) Built-in, allowed max. SD100-S2-G0R4 current is 8A Built-in, allowed max. SD100-S2B-G0R4 current is 8A Built-in, allowed max.
Page 249: Appendix 3 Emc (Electro Magnetic Compatibility)
Appendix 3 EMC (Electro Magnetic Compatibility) Appendix 3 EMC (Electro Magnetic Compatibility) 3.1 Definition of Terms 3.1.1 EMC (electro magnetic compatibility), which refers to the normal operation capability of electrical and electric equipment in environment with electromagnetic interference, no release of electromagnetic interference to other local equipment or system, in order to prevent the capability of other equipment to realize functions stably, includes two requirements: On one hand, the electromagnetic interference generated by equipment to the environment during normal running should not...
Page 250: Peripheral Accessories
Appendix 3 EMC (Electro Magnetic Compatibility) 3.2.2.2 The system (machine or device) mounted with the Product should also be provided with mark EC and finally undertaken by the customer of system assembly. The customer should confirm whether the system (machine and device) conforms to Europe directive and requirements of EN 61800-3 C2.
Page 251 Appendix 3 EMC (Electro Magnetic Compatibility) metal ground of installation cabinet, have good conductive continuity; otherwise, it may have risk of electric shock and severely affect the EMC effects. The ground of filter and inverter PE end should be connected to the same public ground; otherwise, it may severely affect the EMC effects.
Page 252 Appendix 3 EMC (Electro Magnetic Compatibility) 3.3.2.3 Amorphous magnet ring (common mode suppressor/zero phase reactor) Wrap magnet ring on input line R/S/T or output line U/V/W of drive to improve the EMC performance. 3.3.2.4 Install AC input reactor on power input end The AC input reactor, which is mainly used for reducing the harmonic in input current, is installed externally as the optional accessory.
Page 253 Appendix 3 EMC (Electro Magnetic Compatibility) Diagram Model of Output Reactor ACR-0005-2M80-0.4S 6*11 ACR-0007-2M00-0.4S 6*11 ACR-0010-1M40-0.4S 6*11 ACR-0015-0M94-0.4S 6*11 ACR-0020-0M70-0.4S 6*11 ACR-0030-0M47-0.4S 6*15 ACR-0040-0M36-0.4S 6*15 Table 4 Diagram Table of AC Input Reactor (unit: mm) (Note: The reactor dimension table is for reference only. The actual installation dimension is subject to real product) 3.3.2.4 Install AC Output Reactor at Inverter Output Side It depends on the realities whether installing AC output reactor at the Product’s...
Page 254 Appendix 3 EMC (Electro Magnetic Compatibility) P:OCR-0007-1M00-0.4SC G:OCR-0007-1M00-0.4SC SD100-T4B-G2R2P3R7 P: OCR-0010-0M70-0.4SC G:OCR-0010-0M70-0.4SC SD100-T4B-G3R7P5R5 P: OCR-0015-0M47-0.4SC 0.47 SD100-T4B-G5R5P7R5 G:OCR-0015-0M47-0.4SC 0.47 P: OCR-0020-0M35-0.4SC 0.35 G:OCR-0020-0M35-0.4SC 0.35 SD100-T4B-G7R5P011 P: OCR-0030-0M23-0.4SC 0.23 G:OCR-0030-0M23-0.4SC 0.23 SD100-T4B-G011P015 P: OCR-0040-0M18-0.4SC 0.18 G:OCR-0040-0M18-0.4SC 0.18 SD100-T4B-G015P18R5 G:OCR-0050-0M14-0.4SC 0.14 Table 6 Type Selection of AC Output Reactor (3-phase 380V~440V) Fig.
Page 255: Appendix 4 Sd100-Io Expansion Card
Appendix 4 SD100-IO Expansion Card Appendix 4 SD100-IO Expansion Card 1. Introduction The SD100-IO expansion card is developed by Delixi Hangzhou Inverter Co., Ltd. for expanding the SD100 series IO ports. Specification Name Description 2-way digital input (DI5~DI6) SD100-IO 1-way analog input (VF2)
Page 256: Appendix 5 Rs485 Communication Expansion Card
Appendix 5 RS485 Communication Expansion Card Appendix 5 RS485 Communication Expansion Card 1. Introduction The communication expansion card should be installed to realize communication, for the Product has no communication function. The specific model is as follows: Specification Name Description SG+: 485 communication positive signal terminal SD100 communication...
Page 257: Appendix 6 Sd100-Io2-1 Expansion Card
Appendix 6 SD100-IO2-1 Expansion Card Appendix 6 SD100-IO2-1 Expansion Card 1. Introduction The SD100-IO2-1 expansion card is developed by Delixi Hangzhou Inverter Co., Ltd. for expanding the SD100 series IO ports. Specification Name Description 2-way digital input (DI5~DI6) 1-way open collector output (Y3)
Page 258: Appendix 7 Sd100-Io2-2 Expansion Card
Appendix 7 SD100-IO2-2 Expansion Card Appendix 7 SD100-IO2-2 Expansion Card 1. Introduction The SD100-IO2-2 expansion card is developed by Delixi Hangzhou Inverter Co., Ltd. for expanding the SD100 series IO ports. Specification Name Description SD100-IO2-2 SD100-IO2-2 1-way open collector output (Y3) expansion card 2.
Page 259: Appendix 8 Sd100-Io2-3 Expansion Card
Appendix 8 SD100-IO2-3 Expansion Card Appendix 8 SD100-IO2-3 Expansion Card 1. Introduction The SD100-IO2-3 expansion card is developed by Delixi Hangzhou Inverter Co., Ltd. for expanding the SD100 series IO ports. Specification Name Description SD100-IO2-3 SD100-IO2-3 2-way digital input (DI5~DI6) expansion card 2.
Page 260: Appendix 9 Sd100-Io3-1 Expansion Card
Appendix 9 SD100-IO3-1 Expansion Card Appendix 9 SD100-IO3-1 Expansion Card 1. Introduction The SD100-IO3-1 expansion card is developed by Delixi Hangzhou Inverter Co., Ltd. for expanding the SD100 series IO ports. Specification Name Description 2-way digital input (DI5~DI6) Multi-function relay...
Page 261: Appendix 10 Sd100-Io3-2 Expansion Card
Appendix 10 SD100-IO3-2 Expansion Card Appendix 10 SD100-IO3-2 Expansion Card 1. Introduction The SD100-IO3-2 expansion card is developed by Delixi Hangzhou Inverter Co., Ltd. for expanding the SD100 series IO ports. Specification Name Description SD100-IO3-2 Multi-function relay output SD100-IO3-2 expansion card (T2A, T2B, T2C) 2.

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