Shihlin electric SF-GT Series Manual Manual

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Safety Instructions

When using Shihlin inverters, please follow the installation to ensure the safety of user and others.

The following instructions will be classified and described by icons：

It means dangerous instructions, and incorrect handling may result in death or severe

DANGER

injury.

It means caution instructions. Incorrect handling may result in injury or property

CAUTION

damage.

It means caution and execution need to be done. Please operate according to the

instructions.

DANGER

CAUTION



Inverters must be used on the location except corrosive gas, water, flammable

gas.



Please operate far from flammable substance or explosives.



Please do not lay the inverter on an intense trembling or shaking occasion.



Do not operate wires soaked under oil or water.



Prohibit touching any part in the inverter when power is ON to avoid electric

shock.



Three-phase power cannot be connected to terminal U/T1, V/T2, W/T3.



The terminal



Do not conduct wiring when the power is ON.



Do not conduct hi-pot test on internal components of the inverter, for

semiconductor is easily damaged by high voltage.



There are CMOS IC components on PCBAs which are especially sensitive to

static electricity. Please do not touch PCBAs before taking anti-static measures.



Even if the motor stops, a charge may still remain in the main circuit terminals of

the inverter with hazardous voltages.



Only qualified persons are allowed to install, wire and maintain the inverter.



After some functions are set, the motor may start immediately once power is ON.



Please choose the safe area to install the inverter, avoiding heat, direct sunlight,

moisture humidity and splashing of droplets.



When wiring between the inverter and motor is too long, it may damage the layer

insulation of the motor. A reactor can be mounted between inverter and motor,

avoiding insulation is damaged.



For the installation power system of rated voltage, it cannot be over 240V for 220

series; it cannot be over 480V for 440 series.



Only qualified personnel familiar with wiring is allowed to perform wiring.



For the installation direction and method, please refer to the regulations.



Make sure to use the temperature in a safe range.



Please follow the installation to use the voltage.



When there are problems in operation, please first unload the motor, after

zero-load operation is OK, and then connect to the machine.



Please confirm whether the inverter power is in line with the motor power.



Before running, please confirm whether the emergency switch can operate

normally.



Power wire, U, V, W wires and signal wire should not be stranded, but separately.



Please turn off the power if it is not used for a long time.

of the inverter must be correctly grounded.

Safety Instructions

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Summary of Contents for Shihlin electric SF-GT Series

Page 1 Safety Instructions Safety Instructions When using Shihlin inverters, please follow the installation to ensure the safety of user and others. The following instructions will be classified and described by icons： It means dangerous instructions, and incorrect handling may result in death or severe DANGER injury.
Page 2: Table Of Contents
Table of contents Table of contents TABLE OF CONTENTS 1. MANUAL GUIDE ............................5 2. DELIVERY CHECK ............................ 7 2.1 Nameplate Instruction ..........................7 2.2 Type Instruction ............................. 7 2.3 Order Code Description ......................... 7 3. SHIHLIN INVERTER INTRODUCTION ....................... 8 3.1 Electric Specification..........................
Page 3 Table of contents Table of contents 4.1.5 Operation flow charts for parameter setting mode with DU01 .............. 45 4.2 Basic Operation Procedures for Different Modes.................. 47 4.2.1 Basic operation procedures for PU mode (P.79=0 or 1) ................ 47 4.2.2 Basic operation procedures for external mode (P.79=0 or 2) ............... 47 4.2.3 Basic operation procedures for JOG mode (P.79=0 or 1) ..............
Page 4 Table of contents Table of contents 5.30 Remote Setting Function (P.61) ....................... 111 5.31 Zero Current Detection (P.62 and P.63) .................... 113 5.32 Retry Function (P.65, P.67, P.68, P.69) ..................... 114 5.33 Brake Selection (P.71) ........................116 5.34 Carrier Frequency (P.72)........................116 5.35 Stop or Reset Function Selection (P.75) ...................
Page 5 Table of contents Table of contents 5.74 Alarm History Parameters (P.288~P.291) ..................166 5.75 Accumulative Motor Operation Time Function (P.292 and P.293) ............167 5.76 Password Protection Function (P.294 and P.295) ................167 5.77 Motor Control Mode (P.300 and P.301)..................... 168 5.78 Motor Parameter (P.302~P.312) .......................
Page 6: Manual Guide
Please feel free to contact us if you have any question. Chapter 3 of this manual lists the detailed specifications of Shihlin Electric SF-GT Series inverters. Section 3.5 will guide you on how to install the inverters, with an emphasis on safety precautions that must be noted when using the inverters.
Page 7 Manual Guide Manual Guide 5. The difference between “on” and “turn on”: When explaining the function for the “multi-function control terminal”, two words “on” and “turn on” are often used: The word “on” is used to indicate that the external switch of the terminal is in close state, and thus it belongs to the description of the state.
Page 8: Delivery Check
Suitable motor: 1.5K = 1.5KW…… Input voltage 040:440V 3-PHASE Product series 2.3 Order Code Description Example: Customer requirement Order code Inverter specification SF-040-1.5K-GT(SF-GT series 440V 1.5kW inverter) SNKSF0401R5KGT SF-040-7.5K-GT(SF-GT series 440V 7.5kW inverter) SNKSF0407R5KGT SF-040-15K-GT(SF-GT series 440V 15kW inverter) SNKSF04015KGT...
Page 9: Shihlin Inverter Introduction
Shihlin Inverter Introduction Inverter Introduction 3. Shihlin Inverter Introduction 3.1 Electric Specification 3.1.1 440V Series Three-phase Model SF-040-□□□K-GT Applicable motor capacity(kW) Rated output capacity(kVA) Rated output current (A) Output Overload 120% 60 seconds (inverse time characteristics) current rating 150% 60 seconds (inverse time characteristics) Maximum output voltage Three-phase 380-480V Rated power voltage...
Page 10 Shihlin Inverter Introduction Inverter Introduction Model SF-040-□□□K-GT 18.5 18.5 Applicable motor capacity(kW) 18.5 Rated output capacity(kVA) Rated output current(A) Output 120% 60 seconds (inverse time characteristics) Overload current rating 150% 60 seconds (inverse time characteristics) Maximum output voltage Three-phase 380~480V Rated power voltage Three-phase 380~480V 50Hz / 60Hz...
Page 11 Shihlin Inverter Introduction Inverter Introduction Model SF-040-□□□K-GT Applicable motor capacity(kW) Rated output capacity(kVA) Rated output current (A) Output Overload 120% 60 seconds (inverse time characteristics) current rating 150% 60 seconds (inverse time characteristics) Maximum output voltage Three-phase 380~480V Rated power voltage Three-phase 380~480V 50Hz / 60Hz Power voltage permissible...
Page 12: General Specification (Inverter Characteristics)
Shihlin Inverter Introduction Inverter Introduction 3.2 General Specification (Inverter Characteristics) SVPWM control, V/F control, close-loop V/F control (VF+PG), Control method general flux vector control, sensorless vector control (SVC), close-loop vector control (FOC+PG), torque control (TQC+PG). Output frequency range 0.2~650Hz (The starting frequency setting range is 0~60Hz). If the frequency set value is below 100Hz, the resolution will be 0.01Hz.
Page 13 Shihlin Inverter Introduction Inverter Introduction Multi-function P.40 Inverter running (RUN), output frequency SO1-SE open collector detection (FU), Up to frequency (SU), SO2-SE P.129 output overload alarm (OL), zero current detection (OMD), alarm (ALARM), section detection A1-B1-C1 P.85 Multi-function (PO1), periodical detection (PO2), and Output relay output pause detection (PO3), inverter output (BP),...
Page 14: Appearance And Dimensions
Shihlin Inverter Introduction Inverter Introduction 3.3 Appearance and Dimensions 3.3.1 Frame AA 2*R3.1 Model Frame (mm) (mm) (mm) (mm) (mm) SF-040-1.5K-GT SF-040-2.2K-GT SF-040-3.7K-GT...
Page 15: Frame A/B
Shihlin Inverter Introduction Inverter Introduction 3.3.2 Frame A/B Model Frame (mm) (mm) (mm) (mm) (mm) SF-040-5.5K-GT SF-040-7.5K-GT SF-040-11K-GT SF-040-15K-GT SF-040-18.5K-GT SF-040-22K-GTS...
Page 16: Frame D/E/F
Shihlin Inverter Introduction Inverter Introduction 3.3.3 Frame D/E/F Model Frame (mm) (mm) (mm) (mm) (mm) (mm) (mm) SF-040-22K-GT SF-040-30K-GT SF-040-37K-GT SF-040-45K-GT SF-040-55K-GT SF-040-75K-GT SF-040-90K-GT SF-040-110K-GT SF-040-132K-GT...
Page 17: Frame G
Shihlin Inverter Introduction Inverter Introduction 3.3.4 Frame G Model Frame (mm) (mm) (mm) (mm) (mm) (mm) (mm) SF-040-160K-GT SF-040-185K-GT SF-040-220K-GT...
Page 18: Name Of Each Component
Shihlin Inverter Introduction Inverter Introduction 3.4 Name of Each Component 3.4.1 Nameplate and Model SF-040-1.5K-GT Style No. : Input : 4.5A 3PH AC380~480V 50/60Hz Output : 4.2A MAX 3PH AC380~480V 1.5KW IP20 FREQ. Range : 0.2~ 65 0Hz FN00001 Serial NO. MFG.
Page 19: Names Of The Components Of Frame A/B
Shihlin Inverter Introduction Inverter Introduction 3.4.3 Names of the Components of Frame A/B 1. The above figure corresponds to all the models of frame A and B. 2. Push down the latch on the top cover and pull the latch toward the front of the inverter to remove the top cover.
Page 20: Each Type Of Main Loop Terminals Arrangement
Shihlin Inverter Introduction Inverter Introduction 3.4.5 Each Type of Main Loop Terminals Arrangement ● Terminal arrangement Note: 1. Frame AA R/L1 S/L2 T/L3 U/T1 V/T2 W/T3 motor Power input 2. Frame A motor Power input 3. Frame B motor Power input 4.
Page 21: Installation And Wiring
Shihlin Inverter Introduction Inverter Introduction ● DC reactor connection remove DC reactor Note: Frame E and F corresponded inverters have built-in DC reactor. ● Brake unit connection Break Break uint resistance Note: Frame C, D, E and F corresponded inverters have no built-in brake unit. Brake units and brake resistors can be selected for use.
Page 22: Transportation
Shihlin Inverter Introduction Inverter Introduction 3.5.1 Transportation Take the pedestal when carrying and don’t only take the cover or any part of the inverter, otherwise it may drop down. 3.5.2 Stockpile Keep this product in the packaging before installation and when not in use. To change the frequency that meets the manufacturer’s warranty and maintenance conditions, please pay attention to the following regarding storage: 1.
Page 23 Shihlin Inverter Introduction Inverter Introduction wire should be distributed in different areas, parallel lines and interlaced lines are forbidden at close range(within 20cm), and especially don’t bundle up the two lines. If the signal cables must pass through the power lines, the two should keep 90 degree Angle. Interlace lines and banding together is also forbidden for the input and output line of power wire, especially on the occasions which noise filter is installed.
Page 24: Installation
Shihlin Inverter Introduction Inverter Introduction 3.5.4 Installation 1. Please install it upward. 2. Install the inverter with sufficient space at the surroundings. Inverter type Below 3.7k 5.5~55k Above 75 3. The ambient temperature shall not exceed 4. Install the inverter at a correct position in a the permissible value.
Page 25: System Wire Arrangement
Shihlin Inverter Introduction Inverter Introduction 3.5.5 System Wire Arrangement Please follow the specific Power power supply requirement supply FUSE/ NFB shown in this manual. There may be an inrush current during power up. Fuse/NFB Magnetic contactor Please refer to 3.7.1 and select the correct fuse /NFB.
Page 26: Terminal Wire Arrangement
Shihlin Inverter Introduction Inverter Introduction 3.5.6 Terminal Wire Arrangement Main circuit terminals Note 5 Control circuit terminals JUMPER Note 4 NFB/MCCB A.C. Three phase AC reactor power supply Reserved ( Jumper : ON ) Removed (Jumper : OFF) FILTER Main circuit Control circuit SINK SOURCE...
Page 27: Toggle Switch Introduction
Shihlin Inverter Introduction Inverter Introduction 3.5.7 Toggle Switch Introduction SW10 OPEN SW11 SW12 4-20mA 0-10V 0-10V SINK 0-10V 0-20mA 0-20mA SOURCE Switch Switch Explanation Remarks number state Input 4~20mA current signal into terminal 4-5 Cooperating with P.17, please Input 0~10V/0~5V voltage signal into terminal refer to page 93.
Page 28 Shihlin Inverter Introduction Inverter Introduction Note: 1. The multi-function control terminal of SF-GT series inverter can select the sink input approach or the source input approach via the toggle switch SW4. The diagram is as follows: SINK SOURCE No matter what kind of multi-function control terminal is, all of its outside wire arrangement can be considered as a simple switch.
Page 29 Shihlin Inverter Introduction Inverter Introduction If "Source Input” mode is selected, the function of the terminal is active when it is shorted with PC or connected with the external PLC. In this mode, the current flows into the corresponding terminal when it is “on". Terminal PC is common to the contact input signals. When using an external power supply for transistor, please use terminal SD as a common to prevent misoperation caused by leakage current.
Page 30: Main-Circuit Terminals And Control Terminals Introduction
Connect the enclosure of the inverter to ground. / For 440V series, special type of grounding shall be adopted. (Note 4) Note: 1. For SF-GT series of inverters, brake resistor is not included. For information related to braking resistor, please refer to section 3.4.5 and 3.7.3.
Page 31 Shihlin Inverter Introduction Inverter Introduction Terminal Terminal type Remarks and function description Terminal specification name The terminals are multi-function control terminals, their function Input impedance: 4.7 kΩ parameter P.80~P.84, P.86, P.126, P.550. (The Action current: 5mA SINK or SOURCE input approach can be Switch switched) Voltage range: 20~28VDC...
Page 32: Wiring Precautions
Shihlin Inverter Introduction Inverter Introduction Terminal Terminal type Remarks and function description Terminal specification name Minimum load: 4.7kΩ The output terminal of multi-function pulse. The external Maximum current: frequency counter or analog meter can be connected to Pulse output 50mA it to indicate the output frequency, current, etc.
Page 33 Shihlin Inverter Introduction Inverter Introduction 6. “Pressing connection terminals with insulated sleeve” shall be utilized for the wiring at the power source side and the load side. 7. In a short period after the power supply is shut off, high voltage still exists between terminals (+/P)-(-/N), so do not touch them within 10 minutes to avoid electric shock.
Page 34: Mini Jumper Instruction
Shihlin Inverter Introduction Inverter Introduction 3.6 Mini Jumper Instruction Main power isolated from earth: 1. If the inverter is supplied with a non-grounded power supply (IT power), the Mini Jumper must be cut off to prevent circuit damage (according to IEC61800-3) and reduce earth leakage current.
Page 35: Selection Of Peripheral Equipment
Applicable no-fuse Power electromagnetic Motor switch (NFB/MCCB) Inverter type source contactor (MC) capacity type capacity type (Shihlin Electric) (Shihlin Electric) SF-040-1.5K-GT 440V 2HP 4.8 kVA BM30SN3P10A S-P11 SF-040-2.2K-GT 440V 3HP 6.9 kVA BM30SN3P15A S-P21 SF-040-3.7K-GT 440V 5HP 10.4 kVA BM30SN3P20A S-P21 SF-040-5.5K-GT...
Page 36: Power Cable Specification / Pressing Connection Terminal Specification
Shihlin Inverter Introduction Inverter Introduction 3.7.2 Power cable specification / pressing connection terminal specification Pressing connection terminal Power cable specification specification (used by power cables) Power supply terminal Loading terminal Cables Inverter type (R/L1.S/L2.T/L3) (U/T1.V/T2.W/T3) Cables for power loading Crimping Tightening Crimping Tightening...
Page 37: Retrograde Brake Resistor
Shihlin Inverter Introduction Inverter Introduction 3.7.3 Retrograde Brake Resistor Inverter type Retrograde brake resistor specification 200W 320Ω or above SF-040-1.5K-GT 300W 160Ω or above SF-040-22K-GT(S) 500W 120Ω or above SF-040-3.7K-GT 1000W 75Ω or above SF-040-5.5K-GT 1200W 75Ω or above SF-040-7.5K-GT 2400W 50Ω...
Page 38: Reactor
Shihlin Inverter Introduction Inverter Introduction 3.7.4 Reactor  AC input reactor 3-Phase, 440V, 50/60Hz Recommended reactor Inverter type Shanghai Eagtop Type Shihlin Type SF-040-1.5K-GT ACL-0005-EISC-E5M6 SH-ACL-0004-05350 SF-040-2.2K-GT ACL-0007-EISC-E3M5 SH-ACL-0006-03710 SF-040-3.7K-GT ACL-0010-EISC-E2M8 SH-ACL-0010-02260 SF-040-5.5K-GT ACL-0015-EISH-E1M9 SH-ACL-0013-01540 SF-040-7.5K-GT ACL-0020-EISH-E1M4 SH-ACL-0019-01150 SF-040-11K-GT ACL-0030-EISH-EM93 SH-ACL-0026-00790 SF-040-15K-GT ACL-0040-EISH-EM70...
Page 39 Shihlin Inverter Introduction Inverter Introduction  AC output reactor 3-Phase, 440V, 50/60Hz Recommended reactor Rated Inverter type Inductance Shanghai Eagtop Type Shihlin Type current (mH) SF-040-1.5K-GT OCL-0005-EISC-E2M8 SH-OCL-0005-02800 SF-040-2.2K-GT OCL-0007-EISC-E1M9 SH-OCL-0007-01900 SF-040-3.7K-GT OCL-0010-EISC-E1M4 SH-OCL-0010-01400 SF-040-5.5K-GT OCL-0015-EISC-EM93 SH-OCL-0015-00930 0.93 SF-040-7.5K-GT OCL-0020-EISC-EM70 SH-OCL-0020-00700 0.70 SF-040-11K-GT...
Page 40 Shihlin Inverter Introduction Inverter Introduction  DC reactor specification 3-Phase, 440V, 50/60Hz Recommended reactor Rated Inverter type Inductance Shanghai Eagtop Type Shihlin Type curren (mH) t (A) SF-040-1.5K-GT DCL-0006-EIDC-E11M SH-DCL-0006-11000 SF-040-2.2K-GT SF-040-3.7K-GT DCL-0012-EIDC-E6M3 SH-DCL-0012-06300 SF-040-5.5K-GT DCL-0023-EIDH-E3M6 SH-DCL-0023-03600 SF-040-7.5K-GT DCL-0033-EIDH-E2M0 SH-DCL-0033-02000 SF-040-11K-GT DCL-0040-EIDH-E1M3 SH-DCL-0040-01300...
Page 41: Filter
Shihlin Inverter Introduction Inverter Introduction 3.7.5 Filter  AC input filter 3-Phase, 440V, 50/60Hz Rated Amps of Inverter type Types of filter reactor NF311A10/01 SF-040-1.5K-GT NF311A20/05 SF-040-2.2K-GT NF311A20/05 SF-040-3.7K-GT NF311A20/05 SF-040-5.5K-GT NF311A20/05 SF-040-7.5K-GT NF311A36/05 SF-040-11K-GT NF311A36/05 SF-040-15K-GT NF311A50/05 SF-040-18.5K-GT 18.5 NF311A50/05 SF-040-22K-GT(S) NF311A80/05...
Page 42: Primary Operation
Primary Operation Primary operation 4. Primary Operation 4.1 Operating Modes of the Inverter The operation modes are related to the reference source of the target frequency and the signal source of the motor starting. The Shihlin SF-GT TYPE inverter has a total of nine kinds operation modes,...
Page 43 Primary Operation Primary operation The reference Related Operation The signal source Values source of target Remarks parameters mode of motor starting frequency Communication Communication Communication mode External forward Combined DU01 operation and reverse Mode 1 panel terminals “External voltage / SW11 should be current signal”, when...
Page 44: The Flow Chart For Switching The Operation Mode Using Du01 Operation Panel
Primary Operation Primary operation 4.1.1 The flow chart for switching the operation mode using DU01 operation panel When P.79=0: When P.79 = 1: Note: 1. In “PU mode,” the indicating lamp will light up on the operation panel. 2. In “external mode,” indicating lamp will light up on the operation panel.
Page 45: Operation Flow Charts For Monitoring Mode With Du01
Primary Operation Primary operation 4.1.3 Operation flow charts for monitoring mode with DU01 Note: 1. In the “monitoring output frequency mode”, indicating lamp will light up, and the screen will display the current output frequency. 2. In the “monitoring output current mode”, indicating lamp will light up, and the screen will display the current output current.
Page 46: Operation Flow Charts For Parameter Setting Mode With Du01
Primary Operation Primary operation Press the MODE key to enter the frequency setting mode. Note: 1. Use to change the frequency when the inverter is running. 2. Indicating lamp will light up, but not under the frequency setting mode. 3. When setting the frequency under the PU mode, the set value can not exceed the upper frequency.
Page 47 Primary Operation Primary operation Note: 1.Neither Indicating lamp will light up under the parameter setting mode. 2. When entering the value of a parameter, make sure to press the key for longer than 1 second. 3. When the parameter is set as 99999, the actual corresponded CPU value will be 65535. Therefore, if the value is set below 99999, the CPU value will gradually decrease from 65535.
Page 48: Basic Operation Procedures For Different Modes
Primary Operation Primary operation 4.2 Basic Operation Procedures for Different Modes 4.2.1 Basic operation procedures for PU mode (P.79=0 or 1) Step Description Change the operation mode to PU mode, and indicating lamp will light up. Note: 1. When P.79=0, the inverter will first go into the external mode after the power is switched on or the inverter is reset.
Page 49: Basic Operation Procedures For Jog Mode (P.79=0 Or 1)
Primary Operation Primary operation Step Description Turn on STF or STR to run the motor. At this point, indicating lamp will light up, indicating that the motor is running. Note: 1. For setting up the starting terminals STF and STR, please refer to P.78 and multi-function terminal P.80~P.84、P.86、P.126、P.550 in Chapter 5.
Page 50: Basic Operation Procedures For Combined Mode 1 (P.79=4)
Primary Operation Primary operation 4.2.5 Basic operation procedures for combined mode 1 (P.79=4) Step Description In Combined Mode 1, indicating lamp will light up. Note: For selecting and switching the operation mode, please refer to Section 4.1. Enter the frequency setting mode and enter the target frequency into memory. Note: For detailed frequency setting procedures, please refer to Section 4.1.4.
Page 51: Basic Operation Procedures For Combined Mode 3 (P.79=6)
Primary Operation Primary operation 4.2.7 Basic operation procedures for combined mode 3 (P.79=6) The target frequency is determined by communication. When RL, RM, RH and REX of multi-speed stage levels are “on”, the target frequency is determined by combination of multi-speed stage levels (Please refer to ).
Page 52: Operation
Primary Operation Primary operation 4.3 Operation 4.3.1 Pre-operation checks and preparation Before starting the operation, the following shall be examined: 1. Check if the wiring is correct. Check especially the ac motor driver output terminals (U/T1, V/T2, W/T3), which cannot be connected to the power. Confirm that grounding terminal is well grounded.
Page 53: Trial Run
Primary Operation Primary operation 4.3.3 Trial run Check cables and abnormalities before the trial run. After power on, the inverter is in the external mode. 1. After power on, make sure that the indicating lamp power is on. 2. Connect a switch between STF and SD or STR and SD. 3.
Page 54: Parameter Description
Parameter Description Parameters 5. Parameter Description (1) Sensorless vector control and closed loop control 5.77 Motor Control Mode (P.300 and P.301)..................... 168 5.78 Motor Parameter (P.302~P.312) ....................... 171 5.79 Gain Adjustment at Speed Control (P.320~P.325) ................172 5.80 Torque limit range setting(P.326) ...................... 173 5.81 Feedback Control Parameters (P.350~P.359) ...................
Page 55 Parameter Description Parameters (9) Distribution and control of the external terminal’s function 5.23Multi-function Output (P.40, P.85, P.120, P.129, P.130) ..............102 5.24 Up-to-frequency Sensitivity (P.41) ....................104 5.25 Output Frequency Detection (P.42 and P.43) ..................104 5.26 AM1/HDO Terminal (P.54~P.56, P.64, P.74, P.187, P.190 and P.191) ..........105 5.27 AM2 Terminal (P.535 ~ P.538) ......................
Page 56 Parameter Description Parameters 5.76 Password Protection Function (P.294 and P.295) ................167 (17) The selection of the running mode and the operation site 5.38 Operation Mode Selection (P.79) ..................... 119 5.51 External Terminal Power Enable Function (P.158) ................136 (18) The communicational running and setting 5.16 Communication Function(P.32, P.33, P.36, P.48~P.53, P.153 and P.154) ..........
Page 57: Torque Boost
Parameter Description Parameters 5.1 Torque Boost (P.0, P.46) P.0 “Torque boost” P.3 “Base frequency ” P.46 “The second torque boost” P. 19 “Base frequency voltage” P. 47 “The second base frequency ” P. 80~P. 84 , P. 86, P.126, P.550 “Multi-function terminals selection”...
Page 58: The Rage Of The Output Frequency (P.1, P.2 And
Parameter Description Parameters 5.2 The Rage of the Output Frequency (P.1, P.2 and P.18) P.1 “Maximum frequency” P.13“Starting frequency” P.2 “Minimum frequency” P.18 “High-speed maximum frequency” ● The upper and lower limits of the output frequency can be restricted. Parameter Factory setting Setting range Remarks...
Page 59: Base Frequency And Base Frequency Voltage (P.3, P.19 And
Parameter Description Parameters 5.3 Base Frequency and Base Frequency Voltage (P.3, P.19 and P.47) P.3 “Base frequency” P. 14 “Load pattern selection” P.19 “Base frequency voltage” P . 80~P 84 , P.86, P.126 P.550 “Multi-function terminals selection” P.47 "The second base frequency" P.
Page 60: Multi-Speed (P.4~P.6, P.24~P.27 And
Parameter Description Parameters 5.4 Multi-speed (P.4~P.6, P.24~P.27 and P.142~P.149) P.4 “Speed 1 (high speed)” P.1 “Maximun frequency” P.5 “Speed 2 (medium speed)” P.2 “Minimum frequency” P. 29 “Acceleration /deceleration P.6 “Speed 3 (low speed)” curve selection ” P. 79 “Operation mode selection” P.24~P.27 “speed 4 to 7”...
Page 61: Acceleration / Deceleration Time (P.7, P.8, P.20, P.21,P.44 And
Parameter Description Parameters ameters P.24= P.25= P.26= P.27= P.142= P.143= P.144= P.145= P.146= P.147= P.148= P.149= Target 99999 99999 99999 99999 99999 99999 99999 99999 99999 99999 99999 99999 frequenc ○ ○ ○ ○ ○ ○ ○ ○ RL(P.6) ○ ○...
Page 62 Parameter Description Parameters Parameter Factory setting Setting range Remarks 5s (3.7Kw or below) 0~360s P.21=0 20s (5.5Kw or above) 0~3600s P.21=1 5s (3.7Kw or below) 0~360s P.21=0 10s (5.5~7.5kW) 30s (11kW or above) 0~3600s P.21=1 50Hz P.189=1 1~650Hz 60Hz P.189=0 The acceleration / deceleration time increment is 0.01s.
Page 63: Electronic Thermal Relay Capacity
Parameter Description Parameters 5.6 Electronic Thermal Relay Capacity (P.9) P.9 “Electronic thermal relay capacity” P.80~P.84, P.86,P.126, P.550 “Multi-function terminals selection” ● The “electronic thermal relay” uses the program of the inverter to simulate a thermal relay for preventing the motor from overheating. Parameter Factory setting Setting range...
Page 64: Dc Injection Brake (P.10, P.11 And
Parameter Description Parameters 5.7 DC Injection Brake (P.10, P.11 and P.12) P.10 “DC injection brake operation frequency” P.11 “DC injection brake operation time” P.12 “DC injection brake operation voltage” Parameter Factory setting Setting range Remarks 0~120Hz 0.5s 0~60s 4% (7.5kW or below) 2%(11kW~55kW) 0~30% 1% (75kW or above)
Page 65: Starting Frequency
Parameter Description Parameters 5.8 Starting Frequency (P.13) P.13 “Starting frequency” P.2“Minimum frequency” ● When the motor starts up, the instantaneous output frequency of the inverter is called “starting frequency”. Parameter Factory setting Setting range Remarks 0.5Hz 0~60Hz <Setting> • If the target frequency of the inverter is lower than the setting value of P.13, the motor will not run.
Page 66 Parameter Description Parameters Parameter Factory setting Setting range Remarks P.14=4~13 are different VF curve 0~13 options. 0~650Hz 0~100% 99999 0~650Hz, 99999 0~100% 99999 0~650Hz, 99999 0~100% 99999 0~650Hz, 99999 0~100% 99999 0~650Hz, 99999 0~100% <Setting> • If P.14=4, suppose that P.19=220V, P.98=5Hz and P.99=10%, when the inverter is running at 5Hz, the output voltage equals P.19×P.99＝220V×10%＝22V.
Page 67 Parameter Description Parameters P.14=4 P.14=5 P.19 P. 19 P.169 P.167 P.165 Output frequency P.163 P.99 P.98=3.0 When P.14 = 5, the value of A is 7.1% (Note 2). P.3 Output frequency (Hz) P.168 P.98 P.162 P.164 P.166 Whether it is high startup torque or descending torque, they are due to the set values (Note 1).
Page 68: Jog Mode (P.15 And
Parameter Description Parameters 5.10 JOG Mode (P.15 and P.16) P.15 “JOG frequency” Related parameters P.16 “JOG acceleration / deceleration time” P.20 “Acceleration/deceleration reference frequency” P.21“Acceleration/deceleration ● In JOG mode, the output frequency is the set value time increments” of P.15, and the acceleration / deceleration time is the set value of P.15.
Page 69 Parameter Description Parameters ● When the motor starts or target frequency is adjusted (increasing) under a heavy load, the motor speed is often unable to follow the output frequency closely. If the motor speed is lower than the output frequency, the output current will increase to improve the output torque. However, if the difference between the output frequency and the motor speed is too great, the motor torque will decrease, a phenomenon known as “stall”.
Page 70: Output Frequency Filter Constant
Parameter Description Parameters Current Level 120% (P.22) deceleration time acceleration time according to P.220 according to P.220 Output frequency Time Note: 1.When P.300=3 for sensorless vector control is selected from P.300 control method, P.22 will be used for the torque limited horizontal operation. 2.
Page 71 Parameter Description Parameters P.258 “S pattern time at the end of Deceleration” Related parameters P. 3 “ Base frequency” P. 7 “ Acceleration time ” P. 8 “ Deceleration time ” P. 20 “Acceleration / deceleration reference frequency” P. 44 “The second acceleration time ” P.
Page 72 Parameter Description Parameters P.20 Time • When P.29=1, “S pattern acceleration /deceleration curve 1” An acceleration slope is constructed by the combination of P.7 and P.3. A deceleration slope is constructed by the combination of P.8 and P.3. The acceleration / deceleration curve has an S-shape change according to the “acceleration / deceleration slope”.
Page 73 Parameter Description Parameters Time Note: this pattern can effectively reduce motor vibration during the acceleration / deceleration, and thus prevent the belts and gears from broken. • When P.29=3, “S pattern acceleration /deceleration curve 3” Output frequency P.256 P.257 P.255 P.258 time Starting...
Page 74: Regenerative Brake (P.30 And
Parameter Description Parameters P.256 Acceleration / deceleration reference frequency (P.20) Fre2 P.256/2 P.255 Linear acceleration P.255/2 (P.7 or P.44) Starting frequency Fre1 （P.13） The acceleration time being set T1 = (P.20 - P.13) * P.7 / P.20 The actual acceleration time T2= T1 + (P.255 + P.256) * (P.20 - P.13) / 2 / P.20 So T1 = (60 - 0.5) * 5 / 60 = 4.96s (the actual acceleration time of linear acceleration) The actual acceleration time T2 = 4.96 + (0.2 + 0.2) * (60 - 0.5) / 2 / 60 = 5.16s Note: All calculations of acceleration/deceleration time are based on P.20.
Page 75: Carrier Operation Selection(P.31) V/F
Parameter Description Parameters 5.15 (P.31) V/F Carrier Operation Selection P.31 “Carrier operation selection” ● Soft-PWM is a control method that turns motor noises into pleasant complex tones. ● Motor noise modulation control is when the inverter varies its carrier frequency from time to time during the operation.
Page 76 Parameter Description Parameters ● When the communication parameters are revised, please reset the inverter. The SF-GT inverters have two communication protocols for selection, namely, Shihlin protocol and Modbus protocol. Parameter P.32, P.36, P.52, P.55 and P.153 are suitable for both protocols.
Page 77 RS-232 RS- 485 DATA- converter RS- 232 RS- 485 SW10 SW10 SW10 computer Station number 1 Station number 2 Station number 3 Inverter 1 Inverter 2 Inverter 3 ● SF-GT series inverters have two types of communication protocols: Shihlin communication...
Page 78 Parameter Description Parameters protocol and MODBUS communication protocol. Note: Please switch the SW10 on the inverter farthest from the computer to 120. 2. Shihlin communication protocol ● Automatically switch the position machine and the inverter to ASCII codes (hexadecimal) for communication. ●...
Page 79 Parameter Description Parameters ①. Data of the communication request sent by the position machine to the inverter. Data number Format Check Inverter code Reference Waiting (Data station Data symbol code time write-in) number check Check Inverter code Reference Waiting (Data station symbol code...
Page 80 Parameter Description Parameters *1). Control code ASCII ASCII signal Content signal Content Code Code NULL(Empty) Acknowledge(No data error) Start of Text(Data begin) Line Feed(Change line) End of Text(Data end) Carriage Return Enquiry(Communication Negative Acknowledge request) (Data errors) *2). Set the waiting time between 0 and 15 with a 10ms unit. Example: 5  50ms *3).
Page 81 Parameter Description Parameters (hexadecimal) are termed as the Sum Check Code. ● Communication example Example 1. The position machine sends a forward rotation reference to the inverter: Step 1. Use the position machine to send a FA reference in Format A: Inverter station Reference Waiting...
Page 82 Parameter Description Parameters Inverter station number H30 H30 Step 3. The position machine requests the inverter for reading the value P.195 using Format Inverter station Reference code Waiting Check code number time Sum check H30 H30 H35 H46 H30 H42 First 195 minus 100 equals to 95, then convert 95 to H5F hexadecimal digits.
Page 83 Parameter Description Parameters Example 5. Write P.195 into 500 (this parameter range is set between 0 and 400) Step 1 to 2: Omitted (same as Step 1 and 2 of Example 3); Step 3: The position machine requests the inverter to write 500 in P.195 in Format A: Inverter station Reference Waiting...
Page 84 Parameter Description Parameters (4). Broadcast The Master will assign the address 0, and the slave will send the message to all the Slaves. Once receiving a message from the Master, all the Slaves will execute the requested function without responding to the Master. 2).
Page 85 Parameter Description Parameters ASCII mode's LRC check value calculation: LRC check is simpler and it is used in the ASCII mode for checking the content of the message domain, excluding the colon at the beginning and the line change enter symbol at the end.
Page 86 Parameter Description Parameters (2). Data write-in (H06) Address Function Start Address Write-in data Mode Start Check Stop ASCII 2char 2char 4char 4char 2char 0D 0A >=10ms 1byte 1byte 2byte 2byte 2byte >=10ms Regular response Address Function Start Address Write-in data Mode Start Check...
Page 87 Parameter Description Parameters Message Content 1) Address Set up the address for the to-be delivered message; 0 for invalid. 2) Function code 3) Starting address Set up the starting address of the register to be engaged in the write-in function. 4) Number of register Set up the number of register for reading.
Page 88 Parameter Description Parameters Address Function*2) Error code Mode Starting Check Stop H80+function * 3) ASCII 2char 2char 2char 2char 0D 0A >=10ms 1byte 1byte 1byte 2byte >=10ms Message Content 1) Address Set up the address for the to-be delivered message; 0 for invalid. 2) Function code The function code set for the main equipment + H80 3) Error code...
Page 89 Parameter Description Parameters Step 1: The position machine modifies the mode of the inverter. Mode Starting Address Function Starting address Write-in data Check Stop ASCII H30 H31 H30 H36 H31H30 H30 H30 H30 H30 H30 H30 H45 H39 0D 0A >=10ms 8D 0A >=10ms...
Page 90 Parameter Description Parameters P.0~P.11.Starting address is H0000. Mode Starting Address Function Starting address Number of registers Check Stop ASCII H30 H31 H30 H33 H30H30 H30 H30 H30 H30 H30 H43 H46 H30 0D 0A >=10ms 45 CF >=10ms Step 2. After receiving and processing the data without error, the inverter will send a reply to the position machine: Mode Starting...
Page 91 Parameter Description Parameters 4. The list of communication references ● The following references and data are set for carrying out assorted operation control and monitoring. Shihlin Modbus protocol Modbus Item Reference Data content and function description Reference address code code H0000: Communication mode；...
Page 92 Parameter Description Parameters Shihlin Modbus protocol Modbus Item Reference Data content and function description Reference address code code The corresponding monitoring value of each Modbus Address is as follows: H1014: external terminal input state H1015: external terminal output state H1016: 2-5 terminal input voltage H1017: 4-5 terminal input current/voltage H1018: AM1-5 terminal output voltage/current H1019: DC bus voltage...
Page 93 Parameter Description Parameters Shihlin Modbus protocol Modbus Item Reference Data content and function description Reference address code code H0000~HFDE8(Two decimal points EEPROM H1009 Frequency when P.37=0; One decimal point setup H1002 when non-zero.) Output frequency H1003 H0000~H9C40(Same as above) Output current H1004 H0000~HFFFF(two decimal points) Output voltage...
Page 94 Parameter Description Parameters Shihlin Modbus protocol Modbus Item Reference Data content and function description Reference address code code For P.0~P.699, the data range and the position of the decimal point, please Parameter read-out H00~H63 refer to the parameter table. The H0000 MODBUS address of each parameter corresponds to the hexadecimal digit...
Page 95 Parameter Description Parameters ● Parameter restoration condition table P.21, P.125, P.188~P.199, Communication P.300~P.326 Data Parameter P P.292, P.293, Other P Error Parameter P content operation communication parameter P parameters codes (Note) excluded H5A5A P.999 H9966 P.999 Communication H9696 Communication H55AA HA5A5 P.999 Note：Communication P parameters include P.32, P.33, P.36, P.48~P.53, P.79, P.153 and P.154.
Page 96: Communication Mode Operating Instruction And Speed Instruction Selection
Parameter Description Parameters 5.17 Communication mode operating instruction and speed instruction selection(P.35) P.35 “Communication mode operating instruction and speed instruction selection” Parameter Factory setting Setting range Remarks <Setting> •When P.79=3, select communication mode: If P.35=0, operating instruction and speed instruction is set by communication; If P.35=1, operating instruction and speed instruction is set by external.
Page 97: Function Selection Of Hdi Terminal And Analog Terminal
Parameter Description Parameters 5.19 Function Selection of HDI Terminal and Analog Terminal (P.500, P.501, P.502, P.503) P.500 “Function selection of terminal 2-5” P.501 “Function selection of terminal 4-5” P.502 “Function selection of terminal 1-5” P.503 “Function selection of terminal HDI” Parameter Factory setting Setting range...
Page 98: The Voltage Signal Selection Across Terminal 2-5 And Target Frequency
Parameter Description Parameters 5.20 The Voltage Signal Selection across Terminal 2-5 and Target Frequency (P.38, P.73) P.38 “The maximum output frequency (the target frequency is set by the input signal across terminal 2-5)” Related parameters P.73 “The selection of voltage signal P.
Page 99 Parameter Description Parameters Max output frequency 60Hz Parameter setting: P. 38 = 60 Hz Max operation frequency P. 73 = 1 Voltage signal selection P. 500 = 1 Frequency command is selected 30Hz Example 2: The value of P.73 needs to be changed if the terminal 2-5 connects to negative voltage.
Page 100: The Input Signal Selection Across Terminal 4-5 And The Target Frequency
Parameter Description Parameters 5.21 The Input Signal Selection across Terminal 4-5 and the Target Frequency (P.17, P.39) P.39 “The maximum operation frequency of terminal 4-5 (the target Related parameters P. 79 “Operation mode selection” frequency is set by the input signal P.
Page 101 Parameter Description Parameters <Setting> P.17 = 1,2 P.17 = 0 P.501 = 1 frequency P.501 = 1, frequency P.39 command is selected command is selected P.39 Input voltage signal Input current signal across terminal 4-5 across terminal 4-5 20mA Note: 1. In “external mode”, “combined mode 2" or “combined mode 4”, if AU is “on” and P.501=1, target frequency of the inverter will be set by the input signal across terminal 4-5.
Page 102: The Voltage Signal Selection Across Terminal 1-5 And The Target Frequency
Parameter Description Parameters 5.22 The Voltage Signal Selection across Terminal 1-5 and the Target Frequency(P.509, P.530) P.509 “The maximum operation frequency of terminal 1-5 (the target frequency is set by the input signal of terminal 1-5)” Related parameters P.530 “The selection of voltage signal P.
Page 103: Multi-Function Output
Parameter Description Parameters 5.23Multi-function Output (P.40, P.85, P.120, P.129, P.130) P.40 “Multi-function output terminal SO1-SE function selection” P.85 “Function selection for multi-function relay A1-B1-C1” P.120 “Output signal delay time” P.129 “Function selection for multi-function output terminal SO2-SE” P.130 “Function selection for multi-function relay A2-B2-C2” Parame Factory Setting...
Page 104 Parameter Description Parameters Parame Factory Setting Remarks setting range 1). When P.120=0 and the setting requirements of P.40 (P.85, 0.1~ P.129~P.130) is met, the signal will output directly. 3600s 2). When P.120=0.1~3600 and the setting requirements of P.40 (P.85, P.129~P.130) is met, the signal will output after a setting delay time. <Setting>...
Page 105: Up-To-Frequency Sensitivity
Parameter Description Parameters 5.24 Up-to-frequency Sensitivity (P.41) Related parameters P.41 “Up-to-frequency sensitivity” P.40 “Muti-function output terminal SO1-SE function selection ” P. 85 “ Function selection for multi-function relay A1-B1-C1 ” P.129 “ Function selection for multi-function output terminal SO2-SE” P.130 “Function selection for multi-function relay A2-B2-C2" Parameter Factory setting Setting range...
Page 106: Am1/Hdo Terminal (P.54~P.56, P.64, P.74, P.187, P.190 And
Parameter Description Parameters <Setting> • If P.42=30 and P.43=20, then SO2 will send signals when the forward rotation output frequency exceeds 30Hz or when the reverse rotation output frequency exceeds 20Hz. • If P.42=30 and P.43=99999 (factory default), then SO2 will send out signals when the forward or reverse rotation output frequency exceeds 30Hz.
Page 107 Parameter Description Parameters Factory Setting Parameter Remarks setting range Output frequency, frequency display reference P.55 is 100%. Output current, current monitoring reference P.56 is 100%. Output DC bus voltage, the OV level is 100%. Output the temperature rising accumulation rate of inverter, the NTC level is 100%.
Page 108 Parameter Description Parameters Corresponding to 100% of Corresponding to 100% of the function set by P.54 the function set by P.54 20mA Figure 1. AM1-5 output 0~10V voltage Figure 2. AM1-5 output 0~20mA current FM Pulse frequency Corresponding to 100% of the function set by P.54 2300Hz 20mA...
Page 109 Parameter Description Parameters display the FM correction index. Press to adjust the value of P.187. The screen will display a progressively increase of the FM correction index. Press for more than 1 second, and the pointer will move upward. Press to adjust the value of P.187 downward, and the screen will display a progressively decrease of the FM correction index.
Page 110: Am2 Terminal
Parameter Description Parameters 5.27 AM2 Terminal (P.535 ~ P.538) P.535 “AM2 output bias” P.536 “AM2 output gain” P.537 “AM2 terminal function P.538 “AM2 output terminal selection” selection” Parameter Factory setting Setting range Remarks 0~2500 Factory default value 0~2500 Factory default value Refer to P.54 0~10V voltage is selected to be outputted from the terminal AM2...
Page 111 Parameter Description Parameters <Setting> • Once the driving power is interrupted while the motor is still running, voltage output will be stopped instantly. When the power is recovered and P.57=99999, the inverter will not restart automatically. When P.57=0.1~30, the motor will coast for a while (the set value of P.57) before the inverter restarts the motor automatically.
Page 112: Input Signal Filter Constant
Parameter Description Parameters 5.29 Input Signal Filter Constant (P.60, P.528, P.529) P.60 “2-5 Input signal filter constant” P.529 “1-5 Input signal filter constant” P.528 “4-5 Input signal filter constant” Parameter Factory setting Setting range Remarks 0~2047 0~2047 0~2047 <Setting> • When the running frequency is set by a voltage signal or a current signal, the voltage / current signal would be processed by an A/D converter.
Page 113 Parameter Description Parameters <Setting> Output P. 61 ＝1 、2 frequency P. 61 ＝1 (Hz) P. 61 ＝2 、3 P. 61 ＝3 Time Acceleration(RH) Deceleration (RM) Clear (RL) Forward rotation(STF) Power supply *external target frequency (except multi-speed) or PU target frequency •...
Page 114: Zero Current Detection (P.62 And
Parameter Description Parameters Note: 1. The frequency can be varied by RH (acceleration) and RM (deceleration) between 0 and (the maximum frequency – frequency set by the main speed). The output frequency is limited by P.1. Output frequency Setting frequency Acceleration（RH）...
Page 115: Retry Function
Parameter Description Parameters <Setting> • Assume the inverter's rated is full-loaded, the current is 20A, P.62=5% and P.63=0.5s, then when the output current is smaller than 20×5%=1A and exceeding 0.5s, OMD will send out signals. See the figure below: full load current level 100% P.62 ）...
Page 116 Parameter Description Parameters Factory Setting Parameter Remarks setting range When P.65=0, retry is invalid. When alarm occurs, the voltage output is stopped, and all the inverter functions are disabled. When P.65=1, in case of “over-voltage between +/P and -/N”, the voltage output is stopped. After a period of waiting time (the set value of P.68), the inverter will perform the retry function.
Page 117: Brake Selection
Parameter Description Parameters 5.33 Brake Selection (P.71) P.71 “Idling braking and linear braking selection” Parameter Factory setting Setting range Remarks 0, 1 <Setting> • P.71=0 is now idling braking. The inverter will terminate the output immediately after the stop sign is pressed, and the motor will be “racing”. The motor idling breaking time Operation...
Page 118 Parameter Description Parameters <Setting> • The higher the carrier frequency, the lower the motor acoustic noise. Unfortunately, it will result in greater leakage current and larger noises generated by the inverter. • The higher the carrier frequency, the more energy dissipated, and the higher the temperature of the inverter.
Page 119: Stop Or Reset Function Selection
Parameter Description Parameters 5.35 Stop or Reset Function Selection (P.75) P.75 “Stop or reset function selection” Parameter Factory setting Setting range Remarks 0, 1 <Setting> STOP RESET STOP • When P.75=0, it is only suitable for the PU and H2 mode (combined mode 2). Press RESET stop the operation.
Page 120: Forward/Reverse Rotation Prevention Selection
Parameter Description Parameters • If P.77=4，there is password(P.295). In the condition of lock, other parameters besides only-read ones can not be read; In the condition of no password set or password unlocked, the situation is the same with P.77=0 5.37 Forward/Reverse Rotation Prevention Selection (P.78) P.78 “Forward/reverse rotation prevention selection”...
Page 121: Multi-Function Terminal Function Selection
Parameter Description Parameters 5.39 Multi-function Terminal Function Selection (P.80~P.84, P.86, P.126, P.550) P.80~P.84, P.86, P.126, P.550 “Multi-function terminal function selection” Relevant Corresponding Factory Setting Function Value Function description Remarks Parameters terminal setting range name In “external mode”, programmed “combined mode 1”, operation or “combined mode mode, it is...
Page 122 Parameter Description Parameters Relevant Corresponding Factory Setting Function Values Function name Remarks Parameters terminal setting range description In “external mode" and when EXJ is “on”, the target frequency is 0~40， set byP.15, 43~53， (External JOG) and the 55~56 acceleration deceleration time is set by P.16.
Page 123 Parameter Description Parameters Relevant Corresponding Factory Setting Function Values Function description Remarks Parameters terminal setting range name In “external mode”, it is used with RUN. The Forward inverter has a /reverse STF/STR reverse rotation rotation when STF/STR is control “on”, but a forward signal rotation when STF/STR is “off”.
Page 124 Parameter Description Parameters Relevant Corresponding Factory Setting Function Values Function description Remarks Parameters terminal setting range name Automatic switchover frequency GP_BP between inverter commercial power-supply operation. Manual switch to commercial power supply The motor has a reverse rotation when signal STF/STR integrated into the +STOP...
Page 125 Parameter Description Parameters Relevant Corresponding Factory Setting Values Function name Function description Remarks Parameters terminal setting range The signal sent, external PID_OFF terminal stopping calculation PID enable stops once Reserve Initial curling ROLL_1 radius selection terminal 1 Initial curling ROLL_2 radius selection terminal 2...
Page 126 Parameter Description Parameters Note: 1. The default value are P.80=2(RL)，P.81=3(RM)，P.82=4(RH)，P.83=0(STF)，P.84=1(STR)，P.86=30(RES)，P.1 HDI_FRQ 26=5(AU)，P.550=57( 2. If the setting of P.80~P.84, P.86, P.126 and P.550 are changed, the functions of the terminals are modified too. For example, when P.80 is equal to 2, the M0 terminal is used for RL. When P.80 is changed to 8, than the M0 terminal function will be changed to RT, i.e., the second function selection terminal.
Page 127 Parameter Description Parameters (4). Three-wire control mode 2 (with self-maintenance function): K1 is for the STOP function that is normally close. When it is open, the inverter will stop. K2 is the RUN signal that is normally open. It indicates that pulse signal is active, i.e., jog is valid. For the direction changing signal (STF/STR), the parameter corresponds to the external terminals is 39.
Page 128: Multi-Function Terminal Input Negative/Positive Logic
Parameter Description Parameters torque limit turns to Torque reference, and speed reference turns to speed limit. When return torque control back to speed control, Torque reference turns to torque limit, and speed limit turns to speed reference. If you operate the switch of speed control/ torque control, please be in the mode of closed-loop vector speed control (P.300=4) and set P.400=0.
Page 129: Multi-Function Output Terminal Positive/Negative Logic
Parameter Description Parameters × × × × × × P.87= 0 Note：1. When “STF” and “SFR” terminals are set as negative logic, but signal is not connected with SD, with power on, inverter will input and drive motor operate. So it is dangerous, you must pay attention to it. 5.41 Multi-Function Output Terminal Positive/Negative Logic (P.88) Multi-Function Output Terminal Positive/Negative Logic P.88 “...
Page 130: The Inverter Model
Parameter Description Parameters Factory Setting Parameter Remarks setting range Slip compensation is forbidden. 0~10 The compensation value is 3% of the target frequency when P.89 = 10. 5.43 The Inverter Model (P.90) P.90 “The inverter model” ● P.90 is used to show the type and capacity of inverter, and the parameter can only be read. P.90 = Applicable motor capacity: please refer to the following table...
Page 131: Programmed Operation Mode
Parameter Description Parameters and P.95 and P.96 (the third set). Parameter Factory setting Setting range Remarks 91~96 99999 0~650Hz, 99999 99999: invalid Output frequency (Hz) P.91 P.92 P.93 P.94 P.95 P.96 <Setting> • For example: assuming P.91=45 and P.92=50; If the target frequency ≦ 4 5Hz, then the steady output frequency=the target frequency. If 45Hz ≦...
Page 132 Parameter Description Parameters Factory Setting Parameter Remarks setting range The minimum increment of run time is 1 minute. 0, 1 The minimum increment of run time is 1 second. 101~108 0.1~3600s 0~600s P.21=0 111~118 0~6000s P.21=1 0~225 0: Cycle function invalid; 1~8: Run circularly 0, 1 131~138...
Page 133: Operation Panel Monitoring Selection
Parameter Description Parameters • When P.122 is 1~8, it is the initial sectional speed at the beginning of the cycle. For example: When P.122=3, the inverter will run circularly from the third section to the eighth section after it finishes its running from the first section to the eighth section.
Page 134: The Selection Of Positive And Reverse Rotation Dead Time
Parameter Description Parameters P.110 “Operation panel monitoring selection” Factory Setting Parameter Remarks setting range When the inverter starts, the operation panel enters the monitoring mode automatically, and the screen displays the output frequency. When the inverter starts, the screen of the operation panel displays the target frequency.
Page 135: Zero-Speed Function
Parameter Description Parameters Output frequency The positive rotation Time The dead time of positive and reverse rotation The reverse rotation 5.48 Zero-Speed Function (P.151~P.152) P.151 “Zero-speed control function selection” P.152 “Voltage instruction at zero-speed control” ● Make sure that P.13 (Start frequency) is set to zero when using this function. Setting Parameter Factory setting...
Page 136: External Terminals Filter Adjusting Function
Parameter Description Parameters ● When the value of P.155 is nonzero, the function of over torque detection is selected. ● When the output current exceeds the detection level of over torque (P.155) and the detection time of over torque (P.156), then inverter alarm OL2 will go off and the inverter will stop the operation.
Page 137: External Terminal Power Enable Function
Parameter Description Parameters high-speed pulse. And the actual delay time is P.157*2ms. For example, if P.157=100, the actual delay time is 200ms. 5.51 External Terminal Power Enable Function (P.158) P.158 “External terminal power enable” Parameter Factory default value Setting range •...
Page 138: Multi-Function Display
Parameter Description Parameters 5.53 Multi-Function Display (P.161) P.161 “Multi-function display selection” Factory Setting Parameter Remarks setting range Output voltage. (V) Voltage between P and N terminals. (V) Temperature rising accumulation rate of inverter. (%) Target pressure of the constant pressure system. (%) Feedback pressure of the constant pressure system.
Page 139: Pid Parameters 1
Parameter Description Parameters 5.54 PID Parameters 1 (P.170~P.183, P.223~P.225, P.241) P.170 “PID function selection” P.171 “PID feedback control method selection” P.172 “PID proportion Gain” P.172 “PID proportion Gain” P.182 “Integral upper limit” P.173 “PID Integral Gain” P.183 “Deceleration step length with P.174 “PID Differential Gain”...
Page 140 Parameter Description Parameters Param Factory Setting Remarks eter setting range PID function non-selected Parameter P.225 sets target value Take the input of Take the input of terminal 2-5 as terminal 0~3,12,13, target source feedback source 21,23,31,3 Take the input of Single Take the input of digit...
Page 141 Parameter Description Parameters Factory Setting Parameter Remarks setting range 0~100% 0~600s Free stop 0, 1, 2 Decelerate and stop Continue to run when the alarm goes off 0~100% 0~255s 0~100% 40Hz 0~120Hz When the deviation value accumulated with the integral 0~200.0 time, an upper limit for deviation accumulation should be 100.0%...
Page 142 Parameter Description Parameters Note: 1.The range of default setting is 0.1~5V. If there is a mismatch between the default setting range and the user’s range, P.223 and P.224 can be set and P.170 must be set at last to unify the range. 2.
Page 143 Parameter Description Parameters =P.172 contravariance U/T1 R/L1 e(t) V/T2 limit filter =P.173 P.182 S/L2 W/T3 T/L3 =P.174 Output Target PID module frequency value Feedback value feedback quantity convertor ● When the output frequency reaches the value of P.3*P.182, the feedback value will be less than the product of the target value and P.172.
Page 144 Parameter Description Parameters the target feel-back value Revival level feedback P.179 below actually P.179 Minishing the Output output frequency frequency gradually Outage level Revival Outage process proccess • PID gain easy setting: (1)After changing target, response is slow ---Increase P-gain (K =P.172) response is quick but unstable ---Decrease P-gain (K...
Page 145: Terminal Disconnection Handling Function
Parameter Description Parameters 5.55 4-5 Terminal Disconnection Handling Function (P.184) P.184 “4-5 terminal disconnection handling” Parameter Factory setting Setting range Remarks <Setting> • When P.184=0, the inverter will decelerate to 0Hz when disconnected. After reconnecting the inverter, the inverter will accelerate to the corresponding frequency. •...
Page 146 Parameter Description Parameters Factory Setting Parameter Remarks setting range operation frequency = basic frequency - auxiliary frequency (given by the 4-5 terminal) operation frequency = given by the terminal 2-5 as the proportion linkage signal operation frequency = given by the terminal 4-5 as the proportion linkage signal operation frequency = given by the terminal 1-5 as the proportion linkage signal...
Page 147: Sf-Gt Types Selection
Parameter Description Parameters 5.57 SF-GT Types Selection (P.186) P.186 “SF-GT Types Selection” Parameter Factory setting Setting range Remarks Normal Duty(ND)， apply to the fans and water pump type duty. Heavy Duty(HD)， apply to other duties， such as：constant torque type. <Setting> For example: If setting Normal Duty, execute the following steps: 1.
Page 148: Terminal Input Signal
Parameter Description Parameters Setting Minimum Parameter Name range value Base frequency 0~650Hz 0.01Hz P.20 Acceleration / deceleration reference frequency 1~650Hz 0.01Hz The maximum operation frequency (the target frequency P.38 1~650Hz 0.01Hz is set by the input signal of terminal 2-5) The maximum operation frequency (the target frequency P.39 1~650Hz...
Page 149 Parameter Description Parameters P.513 “The maximum input negative Related parameters P.38 “The maximum output voltage of terminal 2-5” frequency of terminal 2-5” P. 73 “The selection of voltage signal across terminal 2-5 ” P. 80~P. 84 , P. 86 “Multi-function terminals selection” P.500 “Function selection of terminal 2-5”...
Page 150 Parameter Description Parameters P.195 P.194 The signal magnitude of terminal 2-5 The value The value of A of B Example 1.2: Set the value of P.194 and P.195, then set P.192 and P.193. The figure is shown as follows: P.195 P.194 The signal magnitude of terminal 2-5...
Page 151 Parameter Description Parameters Example 3: This example is used by the industry for operating the ac motor drive. The goal is to have the set potentiometer equals to 10Hz when rotating to the far left. In other words, when activating, the lowest output of the ac motor drive has to be 10Hz. Other frequencies can be adjusted by the industry freely.
Page 152 Parameter Description Parameters P.38=60Hz Max operation frequency 60Hz P.192=1V, P.193=10V The minimum/maximum input positive voltage of terminal 2-5 P.194=0%, P.195=90% The setting corresponding to the 54Hz minimum/maximum positive voltage of terminal 2-5 P.510=0%, P.511=90% The setting corresponding to the minimum/maximum negative voltage of terminal 2-5 P.512=1V, P.513=10V The minimum/maximum input negative voltage of terminal 2-5 P.139 = 0% The bias rate of 2-5 voltage signal...
Page 153 Parameter Description Parameters P.38=60Hz Max operation frequency 60Hz P.192=0V, P.193=10V The minimum/maximum input Forward positive voltage of terminal 2-5 rotation area P.194=0%, P.195=100% The setting corresponding to the minimum/maximum positive voltage of terminal 2-5 30Hz P.510=0%, P.511=-100% The setting corresponding to the minimum/maximum negative voltage of terminal 2-5 P.512=0V, P.513=10V The minimum/maximum input negative voltage of terminal 2-5...
Page 154: Terminal Input Signal
Parameter Description Parameters 5.61 4-5 Terminal Input Signal (P.196~P.199, P.505) P.196 “The setting corresponding to current/voltage of 4-5 terminal” minimum current/voltage P.505 “The bias rate termianl 4-5” current/voltage signal” P.197 “The setting corresponding to Related parameters P.39 “The maximum operation maximum current/voltage frequency of terminal 4-5”...
Page 155: Terminal Input Signal
Parameter Description Parameters 5.62 1-5 Terminal Input Signal (P.506，P.514~P.521) P.506 “The bias rate of 1-5 voltage P.519 “The setting corresponding to signal” the maximum negative voltage of P.514 “The setting corresponding to terminal 1-5” the minimum positive voltage of P.520 “The minimum input negative terminal 1-5”...
Page 156: Backlash Compensation Function Selection And Acceleration And Deceleration Interrupt Waiting
Parameter Description Parameters 5.63 Acceleration and Backlash Compensation Function Selection and Deceleration Interrupt Waiting Function(P.229~P.233) P.229 “Backlash compensation function selection and acceleration and deceleration interrupt waiting function” P.230 “Interrupt frequency at acceleration” P.231 “Interrupt time at acceleration” P.232 “Interrupt frequency at deceleration” P.233 “Interrupt time at deceleration”...
Page 157: Triangular Wave Function
Parameter Description Parameters Backlash compensation function Output frequency P.232 P.230 P.13 time P.231 P.233 Note: 1. The setting of the backlash compensation will only prolong the acceleration/deceleration time during the period of interruption. 2. This function is only valid under the V/F mode; i.e., it is effective when P.300 = 0. ●Acceleration and Deceleration Interrupt Waiting Function When P.229=2, start acceleration and deceleration interrupt waiting function.
Page 158: Dc Brake Function Before Starting
Parameter Description Parameters Parameter Factory setting Setting range Remarks 0~25% 0~50% 0~50% 0~360s/0~3600 s When P.21=0, unit P.238 and P.239 is 0.01s. When P.21=1, unit P.238 0~360s/0~3600 s and P.239 is 0.1s. <Setting> • If P.234 “Triangular wave function selection” is “1” and triangular wave operation signal (TRI) is turned on, triangular wave function will be valid.
Page 159: Options For Stopping The Cooling Fan
Parameter Description Parameters Parameter Factory setting Setting range Remarks 0.5s 0~60s 4% (7.5kW or below) 2%(11kW~55kW) 0~30% 1% (75kW or above) <Setting> • If P.242=0, DC injection brake function is not available before starting. If P.242=1, DC brake injection function is selected before starting. When the output frequency reaches the starting frequency P.13, a DC voltage (the set value of P.244) will be injected into the motor windings by the inverter, which is used to lock the motor rotor.
Page 160: Modulation Coefficient
Parameter Description Parameters • When P.245=1 or 11, turning on the power will turn on the fan. When the power is turned off, the fan will be off, too. • When P.245=2 or 12, the fan will be turned on if the temperature of the heat sink is higher than 40℃.
Page 161 Parameter Description Parameters <Setting> • P.249 is used to switch the frequency from inverter operation to commercial power supply operation. Between starting and P.249 inverter operation, an output frequency greater than P.249 will automatically change the inverter operation to commercial power supply operation.
Page 162 Parameter Description Parameters frequency operation switchover signal CS is selected. Warning: 1. MC1 and MC2 must be mechanically interlocked; the running direction of the inverter operation and the commercial power supply operation should be consistent. 2. Use the commercial power operation switchover function under the external operation mode.
Page 163: Maintenance Alarm Function
Parameter Description Parameters 3. With action sequence for the automatic switchover sequence series (P.249≠99999, P.250 ≠ 99999). Output P.249 frequency P.250 Setting time frequency Actual motor speed time During the automatic switchover, A: P.247 MC switchover interlocking time; B: P.248 starting waiting time;...
Page 164: Regeneration And Avoidance Function
Parameter Description Parameters 5.70 Regeneration and Avoidance Function (P.267~P.272) P.267“Regeneration and avoidance operation selection” P.268“Regeneration and avoidance DC bus voltage level” P.269“Regeneration and avoidance detection sensitivity at deceleration” P.270“Regeneration and avoidance frequency compensation limit value” P.271“Regeneration and avoidance action accommodation coefficient 1” P.272“Regeneration and avoidance action accommodation coefficient 2”...
Page 165 Parameter Description Parameters Original Setting Parameter Designation Parameter Specification Value Range Regeneration avoidance by bus Regeneration voltage change ratio is invalid and avoidance Set sensitivity to detect the bus P.269 detection voltage change ratio sensitivity at Setting 1 to 5 deceleration Detection sensitivity low to high Regeneration...
Page 166: Input Phase Failure Protection
Parameter Description Parameters 5.71 Input Phase Failure Protection (P.281) P.281 “Input Phase Failure Protection” ● The inverter has built-in input protection from phase failure. When P.281 is set to 1, input out of phase, the inverter will alarm IPF; When P.281 is set to 0, the function will be cancelled.
Page 167: Short Circuit Protection Function
Parameter Description Parameters 5.73 Short Circuit Protection Function (P.287) P.287 “Short circuit protection function selection” Parameter Factory setting Setting range Remarks <Setting> • Set P.287 to 0 to cancel the output end short-circuits protection function. • When P.287 is set to 1, if the output end is short, the operation panel will display the “SCP” abnormal alarm and the inverter will stop the output.
Page 168: Accumulative Motor Operation Time Function (P.292 And
Parameter Description Parameters If both P.288 and P.290 are 0, P.289 and P.291 will be displayed as 0. Abnormal code corresponded alarm condition: Abnormal Alarm Abnormal Alarm Abnormal Alarm Abnormal Alarm Abnormal Alarm code type code type code type code type code type...
Page 169: Motor Control Mode (P.300 And
Parameter Description Parameters <Setting> • P.294 is the parameter that provides the decrypt function. P.294 will be zero if the decryption is successful. Use P.295 to set the password. Enter the initial password into P.294 to decrypt the parameter password and to modify or to set up various parameters.
Page 170 Parameter Description Parameters panel will flicker and display “TUN”. If the measurement fails, the operation panel will flicker “FAL” for three seconds and then return to normal display. • For executing the system inertia auto-tuning function, set P.301 to 4 in the mode of closed loop vector control and set the inertia self-learning torque P.631 and P.632 respectively, then press the forward rotation or the reverse rotation key.
Page 171 Parameter Description Parameters • Procedures for motor parameter auto-tuning are presented below: Confirm the wiring (please refer to 3.5.6) Set motor parameter （P.302~P.307 ） P.301 1 ，2 Press the forward/reverse rotation key Restore display and start to measure, the operation after 3s panel of DU01 will display “TUN”...
Page 172: Motor Parameter
Parameter Description Parameters does not permit auto-tuning, set P.301 to 2 (static measurement) if motoring is running. 3. Sensorless vector control: Auto-tuning function can be used to enhance the control function. Before setting P.300 to 3 or 4, first set the motor parameters or the auto-tuning function to improve the control accuracy.
Page 173: Gain Adjustment At Speed Control
Parameter Description Parameters stopped, the motor parameter will carry out auto-tuning. Then press on the keyboard panel for the inverter to automatically calculate the following parameter: P.308~P.312. • The users can use the motor's nameplate to calculate the two parameters. The motor nameplate parameters used in the calculation are: rated voltage U, rated current I, rated frequency f and power factor η...
Page 174: Torque Limit Range Setting
Parameter Description Parameters frequency is between the switching frequency 1 and the switching frequency 2, the two PI parameters switch linearly. PI parameters P320/P321 P323/P324 Frequency command P322 P325 The diagram of the two PI parameter variation • P.320/P.323 is used to set the proportion gain of speed control.(Set the value slightly larger to better follow changes on the speed reference and to reduce speed change due to external interference.) •...
Page 175: Feedback Control Parameters
Parameter Description Parameters 5.81 Feedback Control Parameters (P.350~P.359) P.350 “Number 1 of pulses per P.355 “Number 2 of pulses per revolution of the encoder” revolution of the encoder” P.351 “Encoder input mode setup 1” P.356 “Encoder input mode setup 2” P.352 “PG signal abnormality (zero P.357 “Dividing frequency output speed) detection time”...
Page 176 Parameter Description Parameters not available. • P.351 and P.356 are applied for setting up the encoder’s input mode. The following encoder input modes are used as some examples: 0: No function; 1: Phase A/B pulse train, Phase A is 90° ahead of Phase B and is forward rotation. Forward Reverse 2: Phase A/B pulse train, Phase B is 90°...
Page 177: Torque Control Parameters
Parameter Description Parameters 5.82 Torque control parameters (P.400~P.407) P.400 “The torque control parameter” P.405 “Torque setting source” P.401 “Torque reference” P.406“Selection of speed limit” P.402“Speed limit” P.407 “Unidirectional Speed Limit P.403 “Speed limit bias” Bias” P.404 “Torque filter coefficient” Factory Parameter Setting range Remarks...
Page 178 Parameter Description Parameters rated torque; Ρ According to the motor rated torque method: T N.M = ω rad/s P(W) is on the basis of P.302, ω(rad/s) can be worked out according to the parameter 2π×P.307 。 P.307: rad/s • Input Value Polarity The direction of motor output torque depends on the polarity of the Torque reference and it has nothing to do with Run command.
Page 179: Hdi Terminal Input Signal
Parameter Description Parameters Operating Condition Run Command Forward Reverse Forward Reverse Forward Reverse Forward Reverse Torque Reference Direction Speed Limit Direction Normal Operation Forward Reverse Forward Reverse Direction Normal Speed Limit P.402 P.402 P.402 P.402 P.403 P.403 P.403 P.403 (P.407=0,P.406=0) + P.403 + P.403 + P.403...
Page 180: Ptc
Parameter Description Parameters Note: 1. When P.550 =57 and the toggle switch SW11 is switched to HDI, the HDI input function is valid. 2. The frequency computing method of HDI input signal is similar to 2-5 analog input, the formula is P.1 * ((P.525-P.524)*(P.523-P.522)/(the input frequency–...
Page 181 Parameter Description Parameters Factory Setting Parameter Remarks setting range The tension control is invalid Open-loop torque control mode (in the mode of close-loop vector control) Close-loop speed control mode Close-loop torque control mode (in the mode of close-loop vector control) Constant line speed control mode Wind-up Roll-down...
Page 182: Tension Setting
Parameter Description Parameters • P.601 is used to select the curling mode which can be combined with the switching terminal of wind-up and roll-down. If the switching terminal of wind-up and roll-down is inactive, the set of actual curling mode is the same with the function mode. If it is valid, the set of the actual curling mode is the same with the switching terminal of wind-up and roll-down.
Page 183: Curling Radius Calculation
Parameter Description Parameters equipment, the tension can be set by communication. There are two ways to realize communication setting of tension: 1) Change value of P.605, then P.604 shall be set to 0; 2) Set the tension through communication address 100CH, P.604 shall be set to 2 and the communication address shall be set between 0 and 30000.
Page 184 Parameter Description Parameters Factory Parameter Setting range Remarks setting 0 Calculation through line speed Calculation through thickness accumulation (the encoder on side of the motor), the pulse signal is connected to the A1/B1 on PG03 card. Calculation through thickness accumulation (the encoder on the side of curling shaft), the pulse signal is connected to the high-speed pulse input terminal HDI.
Page 185 Parameter Description Parameters current line speed and the inverter output frequency. The equation is as follows: = × × D (i V) / (π n) Wherein D is the curling radius, I is the mechanical transmission ratio, V is the line speed, n is the motor speed.
Page 186 Parameter Description Parameters (P.611). • P.617 is used to set the curling radius filtering coefficient to avoid fast change of curling radius calculation (or input) result. • P.618 is used to display the current curling radius in real time. It is able to know the current actual curling radius through the parameter.
Page 187: Line Speed Input
Parameter Description Parameters 5.88 Line Speed Input (P.627~P.630) P.627 “Line speed input source” P.628 “Maximum line speed” P.629 “Minimum line speed for curling radius calculation” P.630 “Actual line speed” Factory Parameter Setting range Remarks setting No line speed input The analog value or pulse input The communication setting 1000.0m/min 0.1~6500.0m/min The maximum line speed Minimum line speed for curling radius...
Page 188: Parameters Of Material Supply Interrupt Auto Detection
Parameter Description Parameters 5.90 Parameters of Material Supply Interrupt Auto Detection (P.637~P.640) P.637 “Material supply interrupt auto P.639 “Material supply interrupt auto detection function selection” detection error range” P.638 “Material supply interrupt auto P.640 “Material supply interrupt auto detection minimum line speed” detection judgment delay”...
Page 189: Pid Parameters 2
Parameter Description Parameters 5.91 PID Parameters 2 (P.641~P.644) P.641 “Proportional gain P2” P.644 “Auto adjustment basis for PID P.642 “Integral time I2” parameters” P.643 “Differential time D2” Factory Setting Parameter Remarks setting range This gain determines the proportion controller’s impact on feedback deviation.
Page 190: Pre-Drive Control Parameters
Parameter Description Parameters process. • The relationship between PID auto adjustment basis and PID parameters is shown as following diagram: PID Paraneters P172/P173/P174 P641/P642/P643 Auto adjustment basis for PID parameters The minimum Adjustment basis The maximum adjustment basis during the process adjustment basis 5.92 Pre-drive control parameters (P.645~P.647)
Page 191 Parameter Description Parameters • To enhance productivity, generally, the winding shaft will be switched without stopping the machine (auto winding up and rolling down the material). To realize the smooth and well-off auto roll alternation and avoid causing too large shock, it is necessary to rotate the wind-up roll (roll-down roll) in advance and the rotating line speed shall be consistent with the line speed of the materials in operation (V1≈V2).
Page 192: Tension Compensation
Parameter Description Parameters • In the process of auto roll alternation, when the torque memory enable signal is valid, the replacing lower roll inverter will control the torque according to the memory torque at first. And then after the delay time set by P.647, the output torque will be increased according to the torque increase proportion set by P.646.
Page 193: Alarm History Clear
Parameter Description Parameters 0~60000mm Material width 0.0% 0.0%~50.0% Friction compensation coefficient <Setting> • When the tension control adopts the open loop torque mode, during the system acceleration/deceleration, additional torque shall be provided to overcome the rotation inertia of the whole system. Otherwise, too small tension upon wind-up acceleration and too large tension upon deceleration, or too large tension upon roll-down acceleration and too small tension upon deceleration will be caused.
Page 194: Restoration Of The Parameters To The Default Values (P.998 And
Parameter Description Parameters 5.96 Restoration of the Parameters to the Default Values (P.998 and P.999) P.998 “Restoring all parameters to default values” P.999 “Restoring some parameters to default values” ● Once P.998 is read-out (after the read-out, the screen will display ) and rewritten-in, all the parameters will be restored to the default values except P.21, P.90, P.188, P.189, P.285, P.286, P.292 and P.293.
Page 195: Inspection And Maintenance
Maintenance and Inspection Maintenance and Inspection 6. Inspection and Maintenance In order to avoid malfunction and security problems resulting from device aging caused by environmental factors such as temperature, oil fog, dust, vibration, humidity and etc., “daily inspection” and “periodical inspection” are necessary. Note: The installation, wire arrangement, dismounting, and maintenance can only be done by qualified electricians.
Page 196: Regular Replacement For Some Components
Maintenance and Inspection Maintenance and Inspection 6.3 Regular Replacement for Some Components Standard replacing Items Description time For the axle of a fan, the standard lifetime is about 10 – Cooling fan 2 years 35 thousand hours. Assuming that the fan operates 24 hours per day, the fan should be replaced every 2 years.
Page 197: Igbt Module Test
Maintenance and Inspection Maintenance and Inspection 6.6 IGBT Module Test Before conducting the IGBT module test, first dismount the external wires from the main-circuit terminals. Then set the multi-meter to the ohm-testing position. Positive Negative Positive Negative Normal result Normal result voltage voltage voltage...
Page 198: Appendix 1 Parameter Table
Appendix 1 Parameter Table Parameter Table Appendix 1 Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value Model-based Torque boost 0~30% 0.1% (Note 1) 120Hz (55kW or below) Maximum frequency 0~120Hz 0.01Hz 60Hz (75kW or above) Minimum frequency...
Page 199 Appendix 1 Parameter Table Parameter Table Minimum User Parameter Default Reference Name Setting Range Setting Setting Number Value Page Unit Value The selection of currnt/voltage P.17 signal across terminal 4-5 High speed maximum P.18 120~650Hz 0.01Hz 120Hz frequency P.19 Base frequency voltage 0~1000V, 99999 0.1V 99999...
Page 200 Appendix 1 Parameter Table Parameter Table Minimum User Parameter Reference Name Setting Range Setting Default Value Setting Number Page Unit Value The maximum operation frequency (the target frequency 50Hz/60Hz P.39 1~650Hz 0.01Hz is set by the input signal of (Note 2) terminal 4-5) Multi-function output terminal P.40...
Page 201 Appendix 1 Parameter Table Parameter Table Minimum User Parameter Reference Name Setting Range Setting Default Value Setting Number Page Unit Value 5s(7.5kW or below) P.58 Restart cushion time 0~60s 0.1s 10s(11kW~55kW) P109 20s(75kW or above) P.59 Reserved P.60 Input signal filter constant P111 0~2047 Remote setting function...
Page 202 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value HDO output terminal P.74 0~9000 P105 selection Stop or reset function P.75 P118 selection P.76 Reserved Parameters write P.77 0~2, 4 P118 protection...
Page 203 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value P.97 Reserved P.98 Middle frequency 1 0~650Hz 0.01Hz Output voltage 1 of middle P.99 0~100% frequency P.100 Minute/second selection 0, 1 P130 Runtime of Section 1 in...
Page 204 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value Acceleration/deceleration time P.117 0~600s/0~6000s 0.01s/0.1s P130 of Section 7 Acceleration/deceleration time P.118 0~600s/0~6000s 0.01s/0.1s P130 of Section 8 The dead time of positive and P.119 0~3000s 0.1s...
Page 205 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value P.146 Speed 12 0~650Hz , 99999 0.01Hz 99999 P.147 Speed 13 0~650Hz , 99999 0.01Hz 99999 P.148 Speed 14 0~650Hz , 99999 0.01Hz 99999...
Page 206 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value Output voltage 5 of middle P.169 0~100% frequency P.170 PID function selection P138 0~3,12,13,21,23,31,32 PID feedback control method P.171 0, 1 P138 selection...
Page 207 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value The setting corresponding to 0.1% P.195 the maximum positive voltage -100.0%~100.0% 100.0% P147 of terminal 2-5 The setting corresponding to 0.1% P.196 the minimum current/voltage of...
Page 208 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value Amplitude compensation for P.237 0~50% 0.1% P156 acceleration 0~360s P.238 Amplitude acceleration time 0.01 s/0.1s P156 /0~3600 s 0~360s P.239 Amplitude deceleration time 0.01 s/0.1s...
Page 209 Appendix 1 Parameter Table Parameter Table Minimum User Parameter Reference Name Setting Range Setting Default Value Setting Number Page Unit Value S pattern time at the end of 0~25s/0~250s, P.258 0.01s/0.1s 99999 Deceleration 99999 P.259 Speed unit selection 0, 1 P.260 Over torque detection selection 0, 1...
Page 210 Appendix 1 Parameter Table Parameter Table Minimum User Parameter Reference Name Setting Range Setting Default Value Setting Number Page Unit Value Accumulative motor operation time P.293 0~9999day 1day P167 (days) P.294 Decryption parameter 0~65535 P167 P.295 Password setup 2~65535 P167 P.300 Motor control mode selection P168...
Page 211 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value Torque limit range level under 0~400% P.326 200% P173 0.1% vector control Number 1 of pulses per revolution P.350 1~20000 2500 P174...
Page 212 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value The setting corresponding to the P.511 maximum negative voltage of -100.0%~100.0% 0.1% 0.0% P147 terminal 2-5 The minimum input negative P.512 0~10V 0.01V...
Page 213 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value P.529 1-5 Input signal filter constant 0~2047 P111 The selection of voltage signal P.530 P101 across terminal 1-5 0~31 P.532 PTC filter coefficient P179...
Page 214 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value P.613 Initial curling radius source P182 1~10000mm 1 mm 100 mm P.614 Initial curling radius 1 P182 P.615 Initial curling radius 2 1~10000mm 1 mm 100 mm...
Page 215 Appendix 1 Parameter Table Parameter Table User Parameter Minimum Reference Name Setting Range Default Value Setting Number Setting Unit Page Value Material supply interrupt auto P.640 0.1~60.0s 0.1s 2.0s P188 detection judgment delay 1~100 P.641 Proportional gain P2 P189 P.642 Integral time I2 0~100s P189...
Page 216 Appendix 1 Parameter Table Parameter Table Note: 1.The torque boost, motor rated current and stator resistance values are shown in the table as follows: Inverter type SF-040-1.5K-GT SF-040-2.2K-GT SF-040-3.7K-GT SF-040-5.5K-GT SF-040-7.5K-GT SF-040-11K-GT SF-040-15K-GT SF-040-18.5K-GT SF-040-22K-GT(S) SF-040-30K-GT SF-040-37K-GT SF-040-45K-GT SF-040-55K-GT SF-040-75K-GT SF-040-90K-GT SF-040-110K-GT SF-040-132K-GT...
Page 217: Appendix 2 Alarm Code List
Appendix 2 Alarm Code List Alarm Code List Appendix 2 Alarm Code List Code Screen Display Cause Troubleshooting Under-voltage for power supply Provide a normal power supply The reset function “RES” Shut off “RES” is on Ensure firm connection ERROR Bad connection between between the operation panel the operation panel and...
Page 218 Appendix 2 Alarm Code List Alarm Code List Code Screen Display Cause Troubleshooting IGBT module thermal Avoid prolonged inverter operation Overheated accumulation relay operation when overloaded. IGBT module Check whether the set value of P.9 is correct or not Electronic thermal relay (according to the externally Overheated operation...
Page 219 Appendix 2 Alarm Code List Alarm Code List Code Screen Display Causes Troubleshooting Serious peripheral Reduce peripheral interference. electromagnetic interference Abnormal CPU Reduce motor load. Over-loaded motor Stall prevention Increase P.22 value. and protection Check whether the inverter output Output-end short circuit has short circuit (e.g., the motor Short circuit wiring).
Page 220 Appendix 2 Alarm Code List Alarm Code List Code Screen Display Causes Troubleshooting Too large speed Please refer to the feedback control Too large speed deviation parameter description deviation under under closed-loop control for P.350~P.354. closed-loop control Reduce motor load The motor is over heat Overheated 2.
Page 221: Appendix 3 Troubles And Solutions
Appendix 3 Troubles and Solutions Troubles and Solutions Appendix 3 Troubles and Solutions Troubles Check points Check whether the power supply voltage between Terminals R/L1, S/L2 and T/L3 is normal. Main circuit Check whether the Power light is on. Check whether the wiring between the inverter and the motor is correct.
Page 222: Appendix 4 Optional Equipment
Appendix 4 Optional Equipment Optional equipment Appendix 4 Optional Equipment 1. Expansion board (Please set the parameters according to the expansion board and the function) 1). PG03 expansion card Name Explanation 1. Supplied by the noumenon Power source 2. supply 5V and 12V (±5%) power supply in the meantime, the maximum supply is 200mA 、B1、...
Page 223 Appendix 4 Optional Equipment Optional equipment 2). PG04 expansion card Name Explanation 1. Supplied by the noumenon 2. Supply 5V and 12V (±5%) power supply in the meantime, the maximum supply is Power source 500mA 3. R1-R2 excitation source 7Vrms, 10KHz ，S2 1.
Page 224 Appendix 4 Optional Equipment Optional equipment 2. Operation panel, operation panels’ fixed base and the data transmission line ： DU01S DU01 operation panel set(operation panel(DU01) fixed base(GMB01)) Description on the ordering code: Model Item Name Ordering Code DU01S DU01 operation panel set SNKDU01S ).
Page 225: Appendix 5 European Specification Compatibility Description
Appendix 5 European Specification Compatibility Description Specification description Appendix 5 European Specification Compatibility Description This inverter qualifies the CE label. Specifications: LOW VOLTAGE DIRECTIVE 2006/95/EC ELECTROMAGNETIC COMPATIBILITY DIRECTIVE 2004/108/EC 1. Electromagnetic compatibility command (EMC): (1). EMC compatibility description: For system integration, inverter is not a functionally independent device unit. It is usually a unit in the control box.
Page 226 Appendix 5 European Specification Compatibility Description Specification description CE Certification Statement...
Page 227 Appendix 5 European Specification Compatibility Description Specification description...
Page 228: Revision Record
Revision Record Revision Record Revision Record Published Edition of the Revision Content Date Manual 2013.08 V1.00 First Edition Modification 1. Modify input data range of communication on torque reference H100D 2. Modify the instruction of external terminals filter P.157. 3. Modify the instruction of P.245. 4.

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Sf-040-1.5k-gt Sf-040-2.2k-gt Sf-040-3.7k-gt Sf-040-5.5k-gt Sf-040-7.5k-gt Sf-040-11k-gt ... Show all

Shihlin electric SF-GT Series Manual Manual

1 Manual Guide

2 Delivery Check

3 Shihlin Inverter Introduction

4 Primary Operation

5 Parameter Description

6 Inspection and Maintenance

Appendix 1 Parameter Table

Appendix 2 Alarm Code List

Appendix 3 Troubles and Solutions

Appendix 4 Optional Equipment

Appendix 5 European Specification Compatibility Description

Revision Record

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