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TECO E510s Series Instruction Manual

TECO E510s Series Instruction Manual

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Quick setting-up manual (78 pages)

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Page 2: Table Of Contents
E510s Instruction Manual Table of Contents Chapter 0 Preface ....................... 0-1 0.1 Preface ........................0-1 Chapter 1 Safety Precautions ................1-1 1.1 Before Power Up..................... 1-1 1.2 During Power Up ....................1.3 Before Operation ....................1.4 During Operation ....................1.5 Maintenance, Inspection and Replacement ........... 1.6 Disposal of the Inverter ..................
Page 3 3.3.1 Power cables ....................3-18 3.3.2 Control cable selection and wiring ............3-19 3.3.3 Wiring and EMC guidelines ..............3-20 3.3.4 Failure liability ....................3-21 3.3.5 Considerations for peripheral equipment ..........3-22 3.3.6 Ground connection ..................3-23 3.3.7 Single / Multi Pump Dedicated Wiring Diagram ........
Page 4 4.1.6 LCD keypad ..................... 4-9 4.1.7 Keypad menu structure ................4-10 4.1.8 Monitoring mode ..................4-11 4.1.9 Programming mode ................... 4-12 4.1.10 Auto-tune mode ..................4-14 4.2 Parameters ......................4-16 4.3 Description of parameters ................. 4-61 4.4 Built-in PLC function ..................4-242 4.4.1 Basic command ..................
Page 5 6.2 Electromagnetic contactor circuit breaker ............6-2 6.3 Fuse specification ....................6-3 6.4 Fuse specification(UL model recommended) ..........6-4 6.5 Brake resistor ......................6-5 6.6 Input noise filter ..................... 6-6 6.7 Accessories ......................6-7 Appendix 1 Instructions for UL ................AP 1-1 Appendix 2 E510s parameter data .................
Page 6: Chapter 0 Preface
Chapter 0 Preface 0.1 Preface To extend the performance of the product and ensure personnel safety, please read this manual thoroughly before using the inverter. Should there be any problem in using the product that cannot be solved with the information provided in the manual, contact Our’s technical or sales representative who will be willing to help you.
Page 7: Chapter 1 Safety Precautions
Chapter 1 Safety Precautions 1.1 Before Power Up Danger Make sure the main circuit connections are correct Single phase L1(L),L3(N), Three  phase L1(L),L2,L3(N) are power-input terminals and must not be mistaken for T1,T2 and T3. Otherwise, inverter damage can result. Caution ...
Page 8: Before Operation
RCD is required to be in compliance with the protection norm of B-type leakage  current. Please check and test emergency stop circuits after wiring. (Installer is responsible  for the correct wiring.) Never touch any of the input or output power lines directly or allow any input of ...
Page 9: During Operation
Reduce the carrier frequency (parameter 11-01) If the cable from the inverter to  the motor is greater than 80 ft (25m). A high-frequency current can be generated by stray capacitance between the cables and result in an overcurrent trip of the inverter, an increase in leakage current, or an inaccurate current readout Caution When the power is applied, inverter will show the voltage rating on display for 2...
Page 10: Disposal Of The Inverter
Make sure power to the inverter is disconnected before disassembling the  inverter. Only authorized personnel should perform maintenance, inspection, and  replacement operations. (Take off metal jewelry such as watches and rings and use insulated tools.) Caution The Inverter can be used in an environment with a temperature range from 14° ...
Page 11: Chapter 2 Model Description
Chapter 2 Model Description 2.1 Nameplate Data 2.2 Model Identification 2.2.1 Inverter Model Name Identification C D E H I J A：Product F：Standard voltage H-J：Horse Power 1： Inverter 1： 100-120V 0P5： 0.5HP 2： SERVO 2： 200-240V 001： 3： 4： 380-480V 075：...
Page 12: Invrter Product Name Identification
2.2.2 Inverter Product Name Identification E510 - 2 - 0 1 - S H - 1 - F 2：Standard Voltage S：510s series 1：Phase 2： 200-240V 1： Single phase 4： 380-480V 3： Three phase Blank： Single/Three phase 01：Horse Power H：Standard Product F：EMC Filter P5：...
Page 13: Standard Product Specification
2.3 Standard Product Specification IP20 type 200V Class Supply Horse Model TECO Product Motor function Frame filter voltage power Name Name (kW) size (VAC) (HP) 1/3 Phase 11-201-20-2P5-00 E510-2P5-SH ◎ ◎ 200~240V 11-201-20-201-00 E510-201-SH 0.75 ◎ ◎ +10% ~ 11-201-20-202-00 E510-202-SH ◎...
Page 14 IP20 type 400V Class Supply Horse Model Product Motor function Frame filter voltage power Name Name (kW) size (VAC) (HP) 11-201-43-401-00 E510-401-SH3 0.75 ◎ ◎ 11-201-43-402-00 E510-402-SH3 ◎ ◎ 11-201-43-403-00 E510-403-SH3 ◎ ◎ 11-201-43-405-00 E510-405-SH3 ◎ ◎ 11-201-43-408-00 E510-408-SH3 ◎ ◎...
Page 15: Environment
Chapter3 Environment & Installation 3.1 Environment Installation environment has a direct effect on the correct operation and the life expectancy of the inverter, Install the inverter in an environment complying with the following conditions： Protection Protection class IP20 / NEMA 1 & IP66 Suitable Environment IP20 / NEMA 1 type：(please refer the ambient temperature and rating current curves in section 3.4.3)
Page 16 To comply with UL standards, use UL approved copper wires (rated 75° C) and round crimp terminals (UL Listed products) as shown in table below when connecting to the main circuit terminals. TECO recommends using crimp terminals manufactured by NICHIFU Terminal Industry Co., Ltd and the terminal crimping tool recommended by the manufacturer for crimping terminals and the insulating sleeve.
Page 17: Specifications
Tighting Torque for Terminals TM1(Power Terminal) Wiring Size Tighting Torque Model mm 2 kgf.cm lbf.in Frame 1(200V) 0.96 Frame 1(400V) 14-12 2.5-10 0.96 Frame 2(200V) 14-12 2.5-4 18.4 15.9 Frame 2(400V) 14-8 2.5-10 18.4 15.9 Frame 3 12-6 4-16 24.5 21.2 Frame 4 24.5...
Page 18 Wiring specifications Model No. Case Frame Total weight Input wiring Output wiring 11-301-21-2P5-30 Frame 1, 14 AWG 14 AWG 1.9 kg 11-301-21-201-30 174 x 91 x 149 mm (2.5 mm (2.5 mm 11-301-21-202-30 Frame 2, 14 – 8 AWG 14 – 8 AWG 2.8 kg 11-301-21-203-30 198 x 129 x 150 mm...
Page 19: Installation
3.2 Installation 3.2.1 Installation method IP20 / NEMA 1 standard installation  (a) 200V 0.5HP~1HP / 400V 1HP~2HP / 200V 2HP(Three phase) ￭ IP20 Step1：Remove the terminal cover Step2：Wire & Re-install cover Step3：Put the terminal cover back...
Page 20 ￭ NEMA1 Step1：Remove the terminal cover Step2：Wire&Re-install the cover Step3：Put the terminal cover back...
Page 21 (b) 200V 2HP(single/three phase) / 200V 3HP~20HP / 400V 3HP~25HP ￭ IP20 Step1：Loosen the screws Step2：Remove the terminal cover Step3：Wirie&Re-install the cover Step4：Tighten the screws...
Page 22 ￭ NEMA1 Step1：Loosen the screws Step2：Remove the terminal cover Step3：Wirie&Re-install the cover Step4：Tighten the screws...
Page 23 (c) 200V 25HP / 400V 30HP Step1: Loosen the screws Step2: Remove the terminal cover Step3：Wirie&Re-install the cover Step4：Tighten the screws...
Page 24 (d) 200V 30HP~40HP / 400V 40HP~75HP Step1: Loosen the screws Step2: Remove the terminal cover Step3：Wirie&Re-install the cover Step4：Tighten the screws 3-10...
Page 25 (e) 400V 20HP~75HP(with EMC filter) Step1: Loosen the screws Step2: Remove the terminal cover Step3：Wirie&Re-install the cover Step4：Tighten the screws 3-11...
Page 26: Installation Space
3.2.2 Installation space Provide sufficient air circulation space for cooling as shown in examples below. Install the Inverter on surfaces that provide good heat dissipation。 Frame1 models：2P5/201/202(three phase)/401/402 Distributor Distributor inside inside 12cm 12cm Front view Side view Side by side installation： Provide te necessary physical space and cooling based on the ambient temperature and the heat loss in the panel.
Page 27: External View
3.2.3 External View 3.2.3.1 IP20/NEMA 1 (a) 200V 0.5HP~1HP / 400V 1HP~2HP / 200V 2HP(3PH) ￭ IP20 ￭ NEMA1 3-13...
Page 28 (b) 200V 2HP(1/3PH) / 200V 3HP~20HP / 400V 3HP~25HP ￭ IP20 ￭ NEMA1 3-14...
Page 29 (c) 200V 25HP / 400V 30HP (d) 200V 30HP~40HP / 400V 40HP~75HP 3-15...
Page 30 Interior layout ￭ (a) 200V 0.5HP~1HP / 400V 1HP~2HP / 200V 2HP(three phase) Operator panel TM2 terminal RJ45 communication port TM1 terminal Ground terminal (b) 200V 2HP(single/three) / 200V 3HP~20HP / 400V 3HP~25HP Operator panel TM2 terminal RJ45 communication port TM1 terminal Ground terminal 3-16...
Page 31 (c) 200V 25HP / 400V 30HP (d) 200V 30HP~40HP / 400V 40HP~75HP Operator panel RJ45 communication port terminal terminal Ground terminal ￭ Warning label (a) 200V 0.5HP~20HP / 400V 1HP~25HP (b) 200V 25HP~40HP / 400V 30HP~75HP 3-17...
Page 32: Wiring Guidelines
3.3 Wiring Guidelines 3.3.1. Power cables： L1(L)、L2、L3(N) for three phase input models.  L1(L) and L3(N) for single phase input models. (L2 terminal will be removed)  Motor cable must be connected T1, T2, T3 of TM1 terminals.  Power cables should be selected by the following conditions： Only can use copper wires, and the diameter needs to use 105 degrees Celsius level.
Page 33: Control Cable Selection And Wiring
3.3.2 Control cable selection and wiring Control cables should be connected to terminal block TM2, Choose power & Control cables according to the following criteria： Use copper wires with correct diameter and temperature rating of 65/70°C  Minimum cable voltage rating for 200V type inverters should be 300VAC. Minimum cable ...
Page 34: Wiring And Emc Guidelines
3.3.3. Wiring and EMC guidelines For effective interference suppression, do not route power and control cables in the same  conduit or trunking To prevent radiated noise, motor cable should be put in a metal Conduit. Alternatively an  armored or shielded type motor cable should be used Motor cable and signal lines of other control equipment should be at the least 30 cm ...
Page 35: Failure Liability
3.3.4. Failure liability Teco bears no responsibility for any failures or damaged caused to the inverter if the recommendations in this instruction manual have not been followed specifically points listed below： If a correctly rated Fuse or Circuit breaker has not been installed between the power ...
Page 36: Considerations For Peripheral Equipment
3.3.5 Considerations for peripheral equipment Ensure that the supply voltage is correct. A molded-case Power circuit breaker or fused disconnect must be installed between the AC source and the inverter Use a molded-case circuit breaker that conforms to the rated voltage and current of the inverter. Do not use the circuit breaker as the run/stop switch for Circuit the inverter.
Page 37: Ground Connection
3.3.6 Ground connection Inverter ground terminal must be connected to installation ground correctly and according to the required local wiring regulations Ground cable size must be according to the required local wiring regulations. Ground  connection should be as short as possible Do not share the ground of the inverter with other high current loads (Welding machine, ...
Page 38: Single / Multi Pump Dedicated Wiring Diagram
3.3.7 Single / Multi Pump Dedicated Wiring Diagram PUMP Wiring Diagram for Pressure Sensor of Voltage Type Single Pump：： Multi-Pump 00-02 = 1 (Control Circuit Terminal); 04-00 = 0 (0~10V) 00-02 = 1 (Control Circuit Terminal); 04-00 = 0 (0~10V) 10-00 = 0 (Target Source: KeyPad);...
Page 39 PUMP Wiring Diagram for PressureSensor of Current Type Single Pump： Multi-Pump： Master 00-02 = 1 (Control Circuit Terminal); 04-00 = 1 (4~20mA) 00-02 = 1 (Control Circuit Terminal); 04-00 = 1 (4~20mA) 10-00 = 0 (Target Source: KeyPad); 10-01 = 2 (Feedback Source: AI2) 10-00 = 0 (Target Source: KeyPad);...
Page 40 Notes3: Refer to parameter 23-31 for the actions in parallel connection modes. Notes4: In the wiring of multi-pump current type pressure sensor, it is required to adjust Slave to be 04-07=252.0% and 04-08=-25.0% Notes5: In multi-pump operation, if one of the inverter does not Power ON, the 24V of connection is also need to disconnect to avoid magnetoresistance effect.
Page 41: Specifications
3.4 Specifications 3.4.1 Product specifications 200V Class：Single phase M od el： E510-□ □ □ -SH 1F Horse power (HP) Suitable motor capacity (KW) 0.75 Rated output current (A) 10.5 Rated capacity (KVA) 2.90 4.00 Input voltage range(V) S i n g l e p ha s e： 2 0 0~ 24 0 V , 5 0/ 60 H z Allowable voltage fluctuation -15%~+10% Output voltage range(V)
Page 42 Model：E510-□ □ □ -SH 3 Horse power (H P) HD/N D Suitable motor capacity (kW) 18.5/22 22/30 30/37 HD/N D Rated output current ( A) 73/80 85/110 115/138 HD/N D Rated capacity ( KVA) 27.8/30.1 32.4/41.9 43.8/52.6 Input voltage range(V) Three phase：200~240V,50/60H z Allowable voltage fluctuation -15%~+10%...
Page 43 M od el： E510-□ □ □ - SH 3(F) Horse power (H P) HD/N D Suitable motor capacity (kW) 22/30 30/37 HD/N D Rated output current ( A) 45/58 60/73 HD/N D Rated capacity ( KVA) 34.3/44.2 45.7/55.6 Input voltage range(V) Three phase : 380~480V,50/60H z Allowable voltage fluctuation + 10% -15%...
Page 44 6. If control mode (00-00) is set to 2 (SLV mode) and maximum frequency (01-02) is larger than 80Hz, the carrier frequency range is 2~8kHz. The following table shows maximum output frequency for each control mode. Duty Cycle Control Mode Other Setings Max.
Page 45: General Specifications
3.4.2 General specifications E510s Item Control mode V/F, SLV, PMSLV control mode Output Frequency 0.01～599.00Hz Starting Torque 150% / 1Hz (SLV mode)，150% / 3Hz(V/F mode) Digital input：0.01Hz Frequency resolution Analog input：0.06Hz/60Hz Keypad：set directly with ▲▼keys or the VR on the keypad Frequency External input terminals：...
Page 46: De-Rating Curve
Built-in RS485 communication for one to one or one to many. Built-in BACnet communication for building control. Communication control (Ex：Fire protection system, Air conditioning system, Monitoring system and Access control system) IP20/NEMA1 type： Operating temperature -10~50°C(without sticker or upper dust cover) -10~40°C(with sticker or upper dust cover) Storage temperature -20～60℃...
Page 47 Frame2 (Three phase 200V 3HP) Frane 5/6 (Three 200V 25HP) Frame 5/6 (Three phase 200V 30HP、40HP) 3-33...
Page 48 Frame 1/2/3 (Three phase 400V 1HP~5HP, 10HP, 20HP~25HP) Frame 3 (Three phase 400V 8HP) Frame 3 (Three phase 400V 15HP) 3-34...
Page 49 Frame 5 (Three phase 400V 30HP) Frame 6 (Three phase 400V 40HP~50HP) Frame 6 (Three phase 400V 60HP~75HP) 3-35...
Page 50: Capacitor Reforming Guide After Long Storage
3.4.4 Capacitor Reforming Guide After Long Storage For correct performance of this product after long storage before use it is important that Inverter Capacitors are reformed according to the guide below： Storage Procedure to re-apply voltage time ≦1year Apply rated voltage of inverter in the normal way Between Apply rated voltage of inverter(Note1) to the product for one hour before using the 1-2 years...
Page 51: Standard Wiring
3.5 Standard Wiring AGND 3-37...
Page 52: Terminal Description
3.6 Terminal description 3.6.1 Description of main circuit terminal Terminal symbol TM1 function description L1(L) Single phase： L1(L)/L3(N) Main power input, Single/Three phase： L1(L)/L2/L3(N) L3(N) Three phase： L1/L2/L3 Inverter output, connect to U/V/W terminals of motor Externally connected braking resistor (Please see the braking resistors reference on chapter 6) Ground terminal Main power terminal of Single phase 200V Class 0.5~1HP...
Page 53 Main power terminal of Single/Three phase 200V Class 2~3HP  L1(L) L2 L3(N) P Main power terminal of Single/Three phase 200V Class 2~3HP, Three phase 200V Class 5HP and  Three phase 400V Class 3~5HP Main power terminal of Three phase 200V Class 7.5~20HP and Three phase 400V Class 7.5~20HP ...
Page 54: Description Of Control Circuit Terminal
3.6.2 Description of control circuit terminal Type Terminal Function Signal level 24 VDC, 8 mA photocoupler isolation. (The max. input Digital Please refer to group3 (digital input functions) for voltage is 30 Vdc, input Input default setting and setting range. resistance is 4.3kΩ) High Logic: 13V Low Logic: 10V...
Page 55 Jumper function description Jumper Symbol Function Signal reference Note NPN input NPN/PNP Factory default setting selectable PNP input 0-20mA / 4-20mA Analog signal Set parameter External signal type 00-05/00-06 to 2 or 3 JP2 /JP3 selection (External analog input) to become effective 0/2-10V Analog signal...
Page 56: Outline Dimensions
3.7 Outline dimensions  IP20 dimensions 200V Class single phase：0.5HP~1HP 200V Class three phase：2HP 400V Class three phase：1HP~2HP Dimensions in mm (inch) Net Weight Inverter Model in kg/(lbs) 151.4 90.6 80.5 80.5 E510-2P5-SH 1.6/(3.5) (3.57) (3.17) (3.17) (6.46) (6.02) (1.85) (0.19) (5.96) 151.4...
Page 57 200V Class single/three phase：2HP 400V Class three phase：3~25HP 200V Class three phase：3~20HP Net Weight Dimensions in mm (inch) Inverter Model Kg/(lbs) 152.4 147.4 128.7 187.6 177.6 197.5 48.2 E510-202-SH 2.5/(5.5) (5.07) (4.65) (4.65) (7.39) (6.99) (7.78) (5.8) (1.9) (0.19) 152.4 147.4 128.7 187.6...
Page 58 Dimensions in mm (inch) Net Weight Inverter Model Kg/(lbs) 202.6 197.6 186.9 260.9 249.8 76.7 E510-415-SH3 6.5/(14.3) (7.98) (7.36) (6.89) (6.93) (10.27) (9.83) (10.75) (7.78) (3.02) (0.26) 202.6 197.6 186.9 260.9 249.8 76.7 E510-408-SH3F 6.7/(14.8) (7.98) (7.36) (6.89) (6.93) (10.27) (9.83) (10.75) (3.02)
Page 59 200V Class three phase：30~40HP 400V Class three phase：40~75HP Net Weight Dimensions in mm (inch) Inverter Model Kg/(lbs) 269.8 286.5 E510-230-SH3 24/(66.1) (11.28) (8.66) (8.66) (20.67) (19.88) (10.62) (0.13) 269.8 286.5 E510-240-SH3 24/(66.1) (11.28) (8.66) (8.66) (20.67) (19.88) (10.62) (0.13) 269.8 286.5 E510-440-SH3 24/(66.1)
Page 60  NEMA 1 dimensions 200V Class single phase：0.5~1HP 400V Class three phase：1~2HP 200V Class three phase：2HP Dimensions in mm (inch) Inverter Model Weight in Kg/(lbs) 151.4 90.6 80.5 186.2 189.2 120.5 E510-2P5-SH 1.8/(3.9) (5.96) (3.57) (3.17) (7.33) (7.45) (1.85) (4.74) (0.19) 151.4 90.6...
Page 61 200V Class single phase/three phase：2HP 400V Class three phase：3~25HP 200V Class three phase：3~20HP Dimensions in mm (inch) Inverter Model Weight in kg/(lbs) 152.4 147.4 128.7 210.6 213.6 48.2 121.1 E510-202-SH 2.7/(5.9) (5.06) (4.65) (8.29) (8.41) (5.8) (1.9) (4.77) (0.19) 152.4 147.4 128.7 210.6...
Page 62 Dimensions in mm (inch) Inverter Model Weight in kg/(lbs) 202.6 197.6 186.9 293.5 76.7 170.6 E510-408-SH3 6.9/(15.2) (7.98) (7.36) (6.89) (11.47) (11.56) (3.02) (6.72) (0.26) (7.78) 186.9 293.5 202.6 197.6 76.7 170.6 E510-410-SH3 6.9/(15.2) (7.36) (6.89) (11.47) (11.56) (7.98) (7.78) (3.02) (6.72) (0.26)
Page 63 Dimensions in mm (inch) Inverter Model Weight in Kg/(lbs) 267.1 235.6 381.5 262.1 E510-420-SH3F 13.8/(30.4) (10.52) (9.28) (7.09) (15.75) (15.02) (10.32) (2.44) (9.33) (0.16) 267.1 235.6 381.5 262.1 E510-425-SH3F 13.8/(30.4) (10.52) (9.28) (7.09) (15.75) (15.02) (10.32) (2.44) (9.33) (0.16) 318.2 313.2 267.6 E510-430-SH3F...
Page 64: Emc Filter Disconnection
3.8 EMC filter disconnection EMC filter may be disconnected： Inverter drives with built-in EMC filter are not suitable for connection to certain type of supply systems, such as listed below; in these cases the RFI filter can be disabled. In all such cases consult your local electrical standards requirements. IT type supply systems (ungrounded) &...
Page 65: The Dimensions And Installation Of Operator Panel
3.9 The dimension and installation of operator panel 3.9.1 Description of dimension and installation (IP20/NEMA1) The operator panel has a LED display and can be removed for remote installation. Installation and dimension information are as follows： Dimension  Surface installation diagram ...
Page 66: Description Of Protective Cover
3.9.2 Description of protective cover For remote installation of the operator panel, to avoid ingress of dust, use the supplied protective cover. Step2：Take out the operator panel Step1 ： Loosen the four screws of the operator panel Step3：Mount the self-adhesive protective cover as per diagram below. Push into position to locate. Here is the bottom of the slot Here is the ligulate...
Page 67: Chapter 4 Software Index
Chapter 4 Software Index 4.1 Keypad description 4.1.1 Operator panel functions Type Item Functions Frequency Display, Parameter, voltage, Current, Temperature, Main digital Fault messages. displays Hz/RPM： ON, when the frequency or line speed is displayed. OFF, when parameters are displayed. Digital display FWD：...
Page 68 4.1.2 Dgital display description Alpha numerical display format Digit Letter Letter Symbol ° Digital tube lights flashing instructions Actual output frequency Set frequency Digits are lit Continually Preset digits flashing Selected digit flashing...
Page 69 LED display examples Display Description In stop mode shows the set frequency In run mode shows the actual output frequency Selected Parameter Parameter Value Output Voltage Output Current in Amps DC Bus voltage Temperature PID feedback Value, based on setting value of 12-01 Error display, please refer the contents in chapter 5 Analogue Current / Voltage AI1 / AI2 .
Page 70: Led Display Setup
LED status description LED indicator light status LED indicator flashing status Frequency / Line ON while displaying frequency or linear speed Hz/RPM speed Indicator ON while not Menu mode displaying Flashing while fire frequency or line mode enabled indicator speed Flashing while ON while running FWD indicator...
Page 71 Example1：Set parameter 12- 00=【10000】to obtain display format shown below. Example 2. Set parameter 12- 00=【12345】 to obtain the display format shown below Increment/ Decrement key functions： ▲ ▼ “ ”/ “ ”： Short time press Long time press Quick pressing of these kwys will increment or decrement the selected digit by one. Extended pressing will increment or decrement the selected digit continuously.
Page 72: Example Of Keypad Operation
4.1.4 Example of keypad operation Example 1：Modifying parameters...
Page 73 Example 2：Modifying the frequency from keypad in run and stop modes Modify frequency in stopping Modify frequency in operating Power supply Power supply 3sec later 3sec later Short ▲ press Set frequency display Set frequency display once Press RUN once Press <...
Page 74: Operation Control
4.1.5 Operation control...
Page 75: Lcd Keypad
4.1.6 LCD keypad JN5-OP-A02 LCD display ( ) built-in internal memory can upload or download from one inverter to another one, please refer the functions of LCD keypad. LED indicators for inverter status FAULT： LED on when a fault or alarm is active. FWD：...
Page 76: Keypad Menu Structure
4.1.7 Keypad menu structure Main menu  The E510s inverter parameters consists of four main modes. The DSP/FUN key is used to switch between these modes. (Please refer Fig.4.1.7.1) Power On Power Up View inverter status, signals and fault data Monitor Mode Assess to available parameter groups Parameter Group Mode...
Page 77: Monitoring Mode
4.1.8 Monitoring Mode In monitor mode inverter signals can be monitored such as output frequency, output current and output voltage, etc…) as well as fault information and fault trace. See Fig.4.1.8.1. Fig.4.1.8.1 Monitoring Mode 4-11...
Page 78: Programming Mode
4.1.9 Programming Mode In programming mode inverter can be read or changed. Please refer Fig.4.1.9.1。 Monitoring Mode Power ON Monitor Freq Ref 12-16=000.00Hz 12-17=000.00Hz 12-18=000.00Hz Parameter Parameter Group Parameter Edit Mode Selection Mode Group Mode READ Edit 00-00 READ ENTER ENTER Group Control Method...
Page 79 Fig.4.1.9.2 Parameter group setting Use ▲(up)/▼(down) key or <(left) key to change the parameter setting value, when you press  READ/ENTER key, setting value will be saved and then display will flash again after a few seconds. 4-13...
Page 80: Auto-Tune Mode
4.1.10 Auto-tune mode In the auto-tune mode, motor parameters can be calculated ans set automatically based on the selected control mode. See Fig.4.1.10.1 for keypad navigation。 Fig.4.1.10.1 Auto-tune Mode Notes： Use the up and down keys to scroll though the auto-tuning parameter list. Depending on the selected control mode in parameter 00-00, part of auto-tuning parameters will not be accessible.
Page 81 (d) The RUN LED (in the upper left corner of the RUN key) will be lit during auto-tuning. The LCD display shows “>>>” or "Atund" during the auto-tuning process. Press the STOP key on the keypad to abort the auto-tuning operation。 In case of an auto-tuning fault, a fault message and the uncompleted message are displayed on the keypad.
Page 82: Parameters
4.2 Parameters Parameter group Group Name Group 00 Basic Parameters Group 01 V/F Control Parameters Group 02 IM Motor Parameters Group 03 External Digital Input and Output Parameters Group 04 External Analog Input and Output Parameters Group 05 Multi-Speed Parameters Group 06 Automatic Program Operation Parameters Group 07...
Page 83 Group 00 Basic Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute 0：V/F 00-00 Control Mode Selection 2：SLV 5：PMSLV Motor’s Rotation 0：Forward 00-01 Direction 1：Reverse 0：Keypad Main Run Command 1：External Terminal (Control Circuit) 00-02 Source Selection 2：Communication Control (RS-485) 3：PLC 0：Keypad Alternative Run Command...
Page 84 Group 00 Basic Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute 0：by Current Frequency Command Initial Frequency 00-10 1：by 0 Frequency Command Selection (keypad mode) 2：by 00-11 00-11 Initial Frequency Setpoint 0.00-599.00 50/60 00-12 Frequency Upper Limit 0.00-599.00 00-13 Frequency Lower Limit 0.00-599.00...
Page 85 Group 01 V/F Control Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute 01-00 Volts/Hz Patterns 0~FF Maximum Output Frequency of 01-02 4.8~599.0 50.0/60.0 Hz Motor 1 Maximum Output Voltage of 200V：0.1~255.0 230.0 01-03 Motor 1 400V：0.2~510.0 400.0 Middle Output Frequency 2 of 01-04 0.0~599.0...
Page 86 Group 02 IM Motor Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute 02-00 No-Load Current of Motor1 0.01~600.00 Lower limit： 10% Inverter rated current (V/F) 02-01 Rated Current of Motor1 25% Inverter rated current (SLV) Upper limit： Based on inverter capacity Rated Rotation Speed of 02-03...
Page 87 Group 03 External Digital Input and Output Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute 0：Forward/Stop Command 1：Reverse/Stop Command 2：Multi-Speed/Position Setting Command 0 Multifunction Input 03-00 3：Multi-Speed/Position Setting Command 1 Terminal S1 4：Multi-Speed/Position Setting Command 2 5：Multi-Speed/Position Setting Command 3 6：Forward Jog Run Command 7：Reverse Jog Run Command 8：UP Frequency Increasing Command...
Page 88 Group 03 External Digital Input and Output Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute Up/Down frequency 03-06 0.00~5.00 step 0：When Up/Down is used, the preset frequency is held as the inverter stops, and the UP/Down function is disabled 1：When Up/Down is used, the preset frequency Up/Down Keep is reset to 0 Hz as the inverter stops.
Page 89 Group 03 External Digital Input and Output Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute 37：Detection Output of PID Feedback Loss 54：Turn on short-circuit braking 55：Low Current Detection Relay (R2A-R2B) 03-12 59：OH Detection Output Frequency Detection 03-13 0.0~599.0 Level Frequency Detection...
Page 90 Group 04 Analog signal inputs / Analog output Control mode Code Parameter Name Setting Range Default Unit Attribute 0：AI1 0~10V AI2 0~10V / 0~20mA 1：AI1 0~10V AI2 4~20mA / 2~10V 04-00 Analog Input Signal Type 2：AI1 2~10V AI2 0~10V / 0~20mA 3：AI1 2~10V AI2 4~20mA / 2~10V AI1 Signal Scanning and...
Page 91 Group 05 Preset Frequency Selection Control mode Code Parameter Name Setting Range Default Unit Attribute 0：Accel/Decel 1~4 apply to all speeds Preset Speed Control 05-00 1：Individual Accel/Decel for each preset Mode Selection speed 05-01 * Preset Speed 0 0.00~599.00 5.00 05-02 * Preset Speed 1 0.00~599.00 5.00...
Page 92 Group 05 Preset Frequency Selection Control mode Code Parameter Name Setting Range Default Unit Attribute 05-34 Preset Speed 8-Dec time 0.1~6000.0 10.0 05-35 Preset Speed 9-Acc time 0.1~6000.0 10.0 05-36 Preset Speed 9-Dec time 0.1~6000.0 10.0 05-37 Preset Speed 10-Acc time 0.1~6000.0 10.0 05-38 Preset Speed 10-Dec time 0.1~6000.0 10.0...
Page 93 Group 06 Automatic Program Opera Control mode Code Parameter Name Setting Range Default Unit Attribute 0：Disabled 1：Execute a single cycle operation mode. Restart speed is based on the previous stopped speed. 2：Execute continuous cycle operation mode. Restart speed is based on the previous stopped speed.
Page 94 Group 06 Automatic Program Opera Control mode Code Parameter Name Setting Range Default Unit Attribute * Frequency Setting of 06-11 0.00~599.00 Operation-Stage 11 * Frequency Setting of 06-12 0.00~599.00 Operation-Stage 12 * Frequency Setting of 06-13 0.00~599.00 Operation-Stage 13 * Frequency Setting of 06-14 0.00~599.00 Operation-Stage 14...
Page 95 Group 06 Automatic Program Opera Control mode Code Parameter Name Setting Range Default Unit Attribute 0：Stop Operation Direction Selection of 06-32 1：Forward Speed Stage 0 2：Reverse 0：Stop Operation Direction Selection of 06-33 1：Forward Speed Stage 1 2：Reverse 0：Stop Operation Direction Selection of 06-34 1：Forward Speed Stage 2...
Page 96 Group 07 Start/Stop Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute Momentary Power Loss and 0：Disable 07-00 Restart 1：Enable 07-01 Fault Reset Time 0~7200 Number of Auto Restart 07-02 0~10 Attempts 0：Enable Reset Only when Run Command is Off 07-03 Reset Mode Setting 1：Enable Reset when Run Command is On or Off...
Page 97 Group 07 Start/Stop Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute 0：Start With Speed Search Start-up Mode Selection of SLV 07-26 Coast to Stop 1：Normal Start 0：Start With Speed Search Start Selection after Fault During 07-27 SLV Mode 1：Normal Start 0：Start With Speed Search 07-28 Start after External BaseBlock...
Page 98 Group 08 Protection Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute xxx0b：Stall prevention is enabled in acceleration. xxx1b：Stall prevention is disabled in acceleration. xx0xb：Stall prevention is enabled in deceleration. xx1xb：Stall prevention is disabled in deceleration. Stall Prevention x0xxb：Stall prevention is enabled in operation 08-00 0000b...
Page 99 Group 08 Protection Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute 0：Deceleration to Stop when Over Torque is Detected. Selection of 08-14 1：Display Warning when Over Torque is Over-Torque Action Detected. Go on Operation. 2：Coast to Stop when Over Torque is Detected Level of Over-Torque 08-15 0~300...
Page 100 Group 08 Protection Parameters Control mode Code Parameter Name Setting Range Default Unit Attribute 0：Disable 08-48 Selection of Fire Mode 1：Enable Multi-Function Input 0：Reset after Power Off 08-49 Terminal Status of Fire 1：Reset after Terminal Removed Mode Multi-Function Terminal xxx0b：S6 A Contact 08-50 0000b Status of Fire Mode...
Page 101 Group 09 Communication Parametes Control mode Code Parameter Name Setting Range Default Unit Attribute INV Communication 09-00 1~32 Station Address 0：MODBUS Communication 09-01 1：BACnet Mode Selection 3：PUMP in Parallel Connection 2：4800 Baud Rate Setting 3：9600 09-02 (bps) 4：19200 5：38400 0：1 Stop Bit 09-03 Stop Bit Selection 1：2 Stop Bit 0：No Parity...
Page 102 Group 10 PID Parameters Control Mode Code Parameters Setting Range Default Unit Attribute 0：Keypad given 1：AI1 given 2：AI2 given 10-00 PID Target Value Source Setting 3：Communication given 4：10-02 given 0：Keypad given 1：AI1 given PID Feedback Value Source 10-01 2：AI2 given Setting 3：Communication given 10-02 PID Target Value...
Page 103 Group 10 PID Parameters Control Mode Code Parameters Setting Range Default Unit Attribute 0：No Allowing Reversal Output 10-25 PID Reversal Output Selection 1：Allow Reversal Output PID Target Acceleration/ 10-26 0.0~25.5 Deceleration Time 10-27 PID Feedback Display Bias -99.99~99.99 10-28 PID Feedback Display Gain 100.00 0.00~100.00 0：Disable...
Page 104 Group 10 PID Parameters Control Mode Code Parameters Setting Range Default Unit Attribute 10-49 Differential Time (D) of Fire Mode 0.00~10.00 0.00 Group 11 Auxiliary Parameters Control Mode Code Parameters Setting Range DefaultUnit Attribute 0：Allow Forward and Reverse Rotation 1：Only Allow Forward Rotation 11-00 Direction Lock Selection 2：Only Allow Reverse Rotation 0：Carrier Output Frequency Tuning...
Page 105 Group 11 Auxiliary Parameters Control Mode Code Parameters Setting Range DefaultUnit Attribute Amount DC Voltage Filter Fall 11-34 0.1~10.0 Amount DC Voltage Filter 11-35 10.0 0.0~99.0 Deadband Level Frequency gain of OV 11-36 0.050 0.000~1.000 Prevention Frequency limit of OV 11-37 5.00 *0.00~599.00...
Page 106 * If the maximum output frequency of motor is over 300HZ, the frequency resolution is changed to 0.1Hz Note：The parameter of 11-01 can be changed during run operation, the range is 1~16KHz. Group 12 Monitoring Parameters Control Mode Code Parameters Setting Range Default Unit Attribute...
Page 107: Control Mode
Group 12 Monitoring Parameters Control Mode Code Parameters Setting Range Default Unit Attribute 0：OPEN 1：CLOSE Input Terminal(S8) Input Terminal(S7) Input Terminal(S6) Input Terminal(S5) Input Terminal(S4) Input Terminal(S3) Input Terminal(S2) Input Terminal(S1) Output Terminal(PLC) Output Terminal(DO1) Output Terminal(R2) Output Terminal(R1) LED display is shown as below no input Correspondences to input and output Output Current of...
Page 108 Group 12 Monitoring Parameters Control Mode Code Parameters Setting Range Default Unit Attribute (PID target value - PID feedback) (100% corresponds to the maximum frequency set by 01-02 or 01-16) Display output of the PID controller 12-37 PID Output (100% corresponds to the maximum frequency set by 01-02 or 01-16) Display the target value of the PID controller...
Page 109 Group 13 Maintance Parameters Control Mode Code Parameters Setting Range Default Unit Attribute Inverter Capacity 13-00 ---- *3*4 Selection 13-01 Software Version 0.00-9.99 *3*4 13-02 Fault Record Cumulative 13-03 0~23 *3*4 Operation Hours 1 Cumulative 13-04 0~65534 *3*4 Operation Hours 2 Selection of 0：Cumulative time in power on 13-05...
Page 110 Group 14 PLC Setting Parameters Control Mode Code Parameters Setting Range Default Unit Attribute 14-00 T1 Set Value 1 0~9999 14-01 T1 Set Value 2 (Mode 7) 0~9999 14-02 T2 Set Value 1 0~9999 14-03 T2 Set Value 2 (Mode 7) 0~9999 14-04 T3 Set Value 1 0~9999...
Page 111 Group 14 PLC Setting Parameters Control Mode Attribute Code Parameters Setting Range Default Unit 1~65534 14-38 MD1 Set Value 3 0~65534 14-39 MD2 Set Value 1 0~65534 14-40 MD2 Set Value 2 1~65534 14-41 MD2 Set Value 3 0~65534 14-42 MD3 Set Value 1 0~65534 14-43 MD3 Set Value 2 1~65534...
Page 112 Group 15 PLC Monitoring Parameters Control Mode Code Parameters Setting Range Default Unit Attribute 15-00 T1 Current Value1 0~9999 15-01 T1 Current Value 2 (Mode7) 0~9999 15-02 T2 Current Value 1 0~9999 15-03 T2 Current Value 2 (Mode7) 0~9999 15-04 T3 Current Value 1 0~9999 15-05 T3 Current Value 2 (Mode7) 0~9999...
Page 113 Group 16 LCD Function Parameters Control Mode Code Parameters Setting Range Default Unit Attribute V/F SLV 5~43 Main Screen 16-00 when using LCD to operate, the monitored item *1*7 Monitoring displays in the first line. (default: frequency command) 5~43 Sub-Screen 16-01 when using LCD to operate, the monitored item *1*7...
Page 114 Group 16 LCD Function Parameters Control Mode Code Parameters Setting Range Default Unit Attribute V/F SLV 0：Do not allow to read inverter parameters Selection of or save them to the operator. 16-08 Allowing 1：Allow to read inverter parameters Reading and save to the operator. Selection of 0：Keep operating when LCD operator is removed.
Page 115 Group 17 Automatic Tuning Parameters Control Mode Code Parameter Name Setting Range Default Unit Attribute 0：Rotation Auto-tuning 1：Static Auto-tuning 2：Stator Resistance Measurement 3：Reserved V/F：2 Mode Selection of 17-00 4：Loop Tuning SLV：6 Automatic Tuning* 5：Rotation Auto-tuning Combination (item: 4+2+0) 6：Static Auto-tuning Combination (item: 4+2+1) Motor Rated Output 17-01...
Page 116 Group 18 Slip Compensation Parameters Control mode Code Parameters Setting Range Default Unit Attribute Slip Compensation Gain at VF：0.00 18-00 0.00~2.50 Low Speed. SLV：*** Slip Compensation Gain at 18-01 -1.00~1.00 High Speed. 18-02 Slip Compensation Limit 0~250 Slip Compensation Filter 18-03 0.0~10.0 Time...
Page 117 Group 20 Speed Control Parameters Control Mode Code Parameters Setting Range Default Unit Attribute 20-00 ASR Gain 1 0.00~250.00 20-01 ASR Integral Time 1 0.001~10.000 20-02 ASR Gain 2 0.00~250.00 20-03 ASR Integral Time 2 0.001~10.000 20-04 ASR Integral Time Limit 0~300 0：PI speed control will be enabled only in constant speed.
Page 118 Group 21 Torque And Position Control Parameters Control mode Code Parameters Setting Range Default Unit Attribute 21-05 Positive Torque Limit 0~300 21-06 Negative Torque Limit 0~300 Forward Regenerative 21-07 0~300 Torque Limit Reversal Regenerative 21-08 0~300 Torque Limit 4-52...
Page 119 Group 22 PM Motor Parameters Control Mode Code Parameters Setting Range Default Unit Attribute 22-00 PM Motor Rated Power 0.00~600.00 22-02 PM Motor Rated Current 25%~200% inverter rated current 22-03 PM Motor‘s Pole Number 2~96 Poles PM Motor’s 22-04 0~60000 1500 Rotation Speed PM Motor’s Maximum...
Page 120 Group 23 PUMP & HVAC Function Parameters Control Mode Code Parameters Setting Range Default Unit Attribute V/F SLV 0: Disable 1: PUMP 23-00 Function Selection 2: HVAC 3: Compressor 0: Single Pump Setting of Single & 1: Master Multiple Pumps and 23-01 2: Slave 1 Master &...
Page 121 Group 23 PUMP & HVAC Function Parameters Control Mode Code Parameters Setting Range Default Unit Attribute V/F SLV Time of Loss Pressure 23-18 Sec O 0.0 ~ 600.0 Detection Proportion of Loss 23-19 0 ~ 100 Pressure Detection 23-22 Slave Trip Frequency 45.00 0.00 ~ 599.00 Direction of Water...
Page 122 Group 23 PUMP & HVAC Function Parameters Control Mode Code Parameters Setting Range Default Unit Attribute V/F SLV Maximum Pressure 23-71 10.00 PSI O 0.10~650.00 Setting Switching Time of 0: Hour 23-72 Alternation in Parallel 1: Minute Slave Wake-Up 0: Disable 23-73 Selection 1: Enable...
Page 123 Attachment 1：Different factory setting and maximum setting value of each models When 11-01 <= 8K, When 11-01 > 8K, Whether 12-41 SLV initial value(18-00) Model Frame the maximum output the maximum output displayed inverter (Low speed slip of SLV mode (Hz) of SLV mode (Hz) temperature? compensation...
Page 124 The maximum The maximum Initial value of Initial value of Initial value of Factory setting value of 11-01 in value of 11-01 in Model 21-05~21-08 20-08 (ASR 00-14~00-17 of 11-01 in HD mode HD mode (Torque limit) filter time) 00-23~00-27 HD mode (SLV control (Other control...
Page 125 The function of Low Voltage Start： Wiring diagram： Inverter R/L1 Single phase S/L2 UPS or Battery T/L3 Specifications of single phase UPS and Battery 440V Class 207~380Vac, or 292~537Vdc S1~S8 Input terminal of low voltage start function 24VG Timing chart of Electromagnetic contactor Contactor 1 and 3 will b3 enable before the backup power is powered on, contactor 2 needs to keep opened.
Page 126 Enhance the Riding Confort of Elevator If there is any uncomfortable feeling during acceleration and deceleration period when you take the elevator. Please try to adjust the parameters as follows. Output Frequency DC injection braking at stop (When you use PG vector control, 11-06 it will be zero control) 11-05...
Page 127: Description Of Parameters
4.3 Description of parameters Group 00 Basic Parameters 00- 00 Control Mode Selection 【0】: V/F Range 【2】: SLV 【5】: PMSLV The inverter offers the following control modes：  00-00 Mode Information Application Value General Purpose applications which do not V/F Control without PG require high precision speed control, auto-tuning is not required.
Page 128 00- 01 Motor’s Rotation Direction 【0】：Forward Range 【1】：Reverse Use the FWD/REV key to change motor direction when Run Command Selection  (00-02=0) is set to keypad control. 00- 02 Main Run Command Source Selection 【0】：Keypad 【1】：External Terminal (Control Circuit) Range 【2】：Communication Control (RS-485) 【3】：PLC (1) 00-02=0：Keypad...
Page 129 00- 04 Alternative RUN Command Selection 【0】：Forward/Stop-Reverse/Stop Range 【1】：Run/Stop- Reverse/ Forward 【2】：3 Wire Control Mode - Run/Stop 00-04 is valid when run command is set to external mode by 00- 02/00- 03 =1.  Set 00-04=【0/1】first, before setting (03- 00~03- 05) to【0】or【1】. ...
Page 130 Terminal S1 must be closed for a minimum of 50ms to activate operation, please refer  below. Figure 4.3.3 3-wire operation 00- 05 Main Frequency Command Source Selection 00- 06 Alternative Frequency Command Source Selection 【0】：Up/Down of Keypad 【1】：Potentiometer on Keypad 【2】：External AI1 Analog Signal Input 【3】：External AI2 Analog Signal Input Range...
Page 131 Figure 4.3.4 Analog input as main frequency reference command Note： When analog current input signal connectes to AI2, please set JP3 to I (default setting) and set 04-00=0~3 (AI2=0~20mA / 4～20mA)。 When analog voltage input sognal connectes to AI2, please set JP3 to V (default setting) and set 04-00=0~3 (AI2=0~10V / 2~10V)。...
Page 132 00- 07 Main and Alternative Frequency Command modes 【0】：Main frequency Range 【1】：Main frequency + alternative frequency When 00-07=0, the frequency source is set by the Main frequency parameter 00-05.  When 00-07=1, The frequency command will be the result of setting of main and alternative ...
Page 133 Figure 4.3.6 Frequency reference upper and lower limits 00-14 Acceleration time 1 Range 【0.1~6000.0】 Sec 00-15 Deceleration time 1 Range 【0.1~6000.0】 Sec 00-16 Acceleration time 2 Range 【0.1~6000.0】 Sec 00-17 Deceleration time 2 Range 【0.1~6000.0】 Sec 00-21 Acceleration time 3 Range 【0.1~6000.0】...
Page 134 Table 4.3.1 Acceleration/Deceleration Time Selection Accel/decel time 1 Acceleration Deceleration (Set 03-00 to 03-05=10) Time Time Taccc1(00-14) Tdec1(00-15) Taccc2(00-16) Tdec2(00-17) 0 : OFF 1 : ON Figure 4.3.7 Didital input S5 switch between Tacc1/Tacc2 and Tdec1/Tdec2 B. Switch of Acceleration/Deceleration time according to motors 03-00~03-06 set to 40 (Switching between motor 1/motor 2), it can switch motors by digital input.
Page 135 00- 26 Emergency stop time Range 【0.1~6000.0】 Sec When emergency stop input is activated the inverter will decelerate to a stop using the Emergency stop time  When digital input set to 14, inverter will decelerate to stop by emergency stop time (00-26). ...
Page 136 Maximum Horsepower Special circumtances output frequency 220V 1~10HP, 440V 1~15HP 150Hz 220V 15~20HP, 440V 20HP 110Hz 440V 25HP 100Hz 220V 25~40HP, 440V 30~75HP, 11-01 set to 8KHz(included) or below 100Hz 220V 25~40HP, 440V 30~75HP, 11-01 set to 8KHz or higher 80Hz Note：In normal duty mode only applies to control modes V/F .
Page 137 Group 01 V/F Control Parameters 01- 00 Volts/Hz Patterns Range 【0~FF】 Make sure to set the inverter input voltage parameter 01-14  There are three ways to set V/F curve：  (1) 01-00 = 0 to E：Choose any of the 15 predefined curves (0 to E) (2) 01-00 =0F：Use 01-02~01-09 and 01-12~01-13, with voltage limit (3) 01-00 = FF：Use 01-02~01-09 and 01-12~01-13, without voltage limit.
Page 138 Table 4.3.3 2P5 - 2HP V/F curve selection (200V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High (50Hz Starting Default Torque setting) 60Hz Starting (60Hz Saturation Torque Default 60Hz setting.) High 50Hz Starting Saturation Torque 72Hz...
Page 139 Table 4.3.4 3 - 30HP V/F curve selection (200V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High (50Hz Starting Default Torque setting) 60Hz (60Hz Starting Saturation Default Torque 60Hz 60Hz setting.) High 50Hz Starting Saturation Torque...
Page 140 Table 4.3.5 40HP and above V/F curve selection (200V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High (50Hz Starting Default Torque setting) 60Hz Starting (60Hz Saturation Torque Default 60Hz 60Hz setting) High 50Hz Starting Saturation Torque...
Page 141 Table 4.3.6 2P5- 2HP V/F curve selection (220V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting Saturation...
Page 142 Table 4.3.7 3 - 30HP V/F curve selection (220V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz ( 60Hz Starting Saturation Torque Default 60Hz 60Hz setting ) 50Hz Starting...
Page 143 Table 4.3.8 40HP and above V/F curve selection (220V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting 60Hz ( 60Hz Starting Saturation Torque Default 60Hz 60Hz setting ) 50Hz Starting Saturation...
Page 144 Table 4.3.9 2P5 - 2HP V/F curve selection (230V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) (1),(F) 15.5...
Page 145 Table 4.3.10 3 - 30HP V/F curve selection (230V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting...
Page 146 Table 4.3.11 40HP and above V/F curve selection (230V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque (0),(F) 50Hz 50Hz High 15.7 ( 50Hz (Hz) 0 1.3 Starting Default Torque setting ) 60Hz ( 60Hz Starting Saturation Torque Default...
Page 147 Tbale 4.3.12 2P5 - 2HP V/F curve selection (380V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting...
Page 148 Table 4.3.13 3 - 30HP V/F curve selection (380V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting...
Page 149 Table 4.3.14 40HP and above V/F curve selection (380V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting...
Page 150 Table 4.3.15 - 2HP V/F curve selection (400V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting Saturation...
Page 151 Table 4.3.16 3 - 30HP V/F curve selection (400V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting...
Page 152 Table 4.3.17 40HP and above V/F curve selection (400V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque (0),(F) 50Hz 50Hz High 27.3 ( 50Hz 15.5 (Hz) 0 1.3 Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque...
Page 153 Table 4.3.18 - 2HP V/F curve selection (415V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting Saturation...
Page 154 Table 4.3.19 3 - 30HP V/F curve selection (415V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting...
Page 155 Table 4.3.20 40HP and above V/F curve selection (415V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque (0),(F) 50Hz 50Hz High 28.3 ( 50Hz (Hz) 0 1.3 Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque...
Page 156 Table 4.3.21 - 2HP V/F curve selection (440V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting Saturation...
Page 157 Table 4.3.22 3 - 30HP V/F curve selection (440V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting...
Page 158 Table 4.3.23 40HP and above V/F curve selection (440V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting...
Page 159 Table 4.3.24 - 2HP V/F curve selection (460V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting) 60Hz Starting ( 60Hz Saturation Default Torque 60Hz 60Hz setting ) 50Hz Starting Saturation...
Page 160 Table 4.3.25 3 - 30HP V/F 曲線 (460V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque 50Hz 50Hz High ( 50Hz Starting Default Torque setting ) 60Hz ( 60Hz Starting Saturation Torque Default 60Hz 60Hz setting ) 50Hz Starting Saturation...
Page 161 Table 4.3.26 40HP and above V/F curve selection (460V) Type Specification 01-00 V/F curve Type Specification 01-00 V/F curve Starting Torque (0),(F) 50Hz 50Hz High 31.4 ( 50Hz 17.8 (Hz) 0 1.3 Starting Default Torque setting ) 60Hz Starting ( 60Hz Saturation Default Torque...
Page 162 01- 02 Base frequency of motor 1 Range 【4.8~599.0】Hz 01- 03 Maximum output voltage of motor 1 200V：【0.1~255.0】V Range 400V：【0.2~510.0】V 01- 04 Middle output frequency 2 of motor 1 Range 【0.0~599.0】Hz 01- 05 Middle output voltage 2 of motor 1 200V：【0.0~255.0】V Range 400V：【0.0~510.0】V...
Page 163 Figure 4.3.12 Custom V/F Curve For low torque or high speed applications, the motor may overheat. Make sure to provide  adequate cooling when operating the motor under these conditions for a longer period of time If the automatic torque boost function is enabled (parameter 01-10), the applied motor voltage ...
Page 164 01-10 Torque compensation gain Range 【0.0~2.0】 01-11 Selection of Torque Compensation Mode 0：Mode 0 Range 1：Mode 1 Torque compensation gain (01-10) In V/F mode the inverter automatically adjusts the output voltage to adjust the output torque  during start or during load changes based on the calculated loss of motor voltage. Torque compensation gain (01-10) can adjust in the running time.
Page 165 01-15 Torque compensation time Range 【0~10000】ms Set the torque compensation delay time in milliseconds.  Only adjust in the following situations：  ①. Increase the value when experiencing motor vibration. ②. Decrease the value when motor torque response is too slow. 01- 16 Maximum output frequency of motor 2 Range...
Page 166 Group 02 IM Motor Parameters 02- 00 No-load current of motor 1 Range 【0.01~600.00】A 02- 01 Rated current of motor 1 Lower limit: 10% rated current of V/F mode, 25% rated current of SLV mode Range Upper limit: According to inverter’s rated current 02-03 Rated rotation speed of motor1 Range...
Page 167 Motor rated current (02-01)  Set the motor rated current according to the motor nameplate. (1) The value of 02-01 needs to be greater than the value set in parameter 02-00, otherwise warning message "SE01" out of range error will be displayed. (2) In V/F control mode, slip compensation function will be active whn output current is greater than motor no load current.
Page 168 Im : 02-09 Excitation Current Ks1: 02-10 Motor Core Saturation Coefficients 1 Ks2: 02-11 Motor Core Saturation Coefficients 2 Ks3: 02-12 Motor Core Saturation Coefficients 3 Motor core loss (02-13)  Set motor core loss as the percentage of the motor rated power Note：In V/F mode motor core loss (o2-13) is used to for torque compensation.
Page 169 Motor line to line resistance (02-15)  Refer to figure 4.3.15, Y-equivalent model an induction motor Figure 4.3.15 Y-equivalent model an induction motor No-load motor voltage (02-19)  Parameter determines the rated flux during motor rated rotation in SLV control mode. Set the value of this parameter to the same value as parameter 17-08.
Page 170 Rated speed in the nameplate is 1700 rpm, then (3) Adjusting motor slip will change the rotor resistance parameter. The motor slip is adjusted depending on the motor performance. (4) When inverter is performing auto-tune successful, the parameters of group 2 will be updated by group 17, please refer to group 17 for the details.
Page 171 Group 03 External Digital Input and Output Parameters 03- 00 Multi-function input terminal S1 03- 01 Multi-function input terminal S2 03- 02 Multi-function input terminal S3 03- 03 Multi-function input terminal S4 03- 04 Multi-function input terminal S5 03- 05 Multi-function input terminal S6 【0】：...
Page 172 Figure 4.3.16 Multi-function digital input and related parameters Table 4.3.27 Multi-function digital input setting ( 03-00 to 03-05 ) (“O”：Enable, “X”：Disable) Function Control Mode Value Description Name LCD Display Forward/Stop 2- wire Forward/Stop command 2-Wire (FWD-RUN) command (ON：Forward operation command). 2- wire Reverse/Stop command Reverse/Stop command 2-Wire (REV-RUN) (ON：Reverse operation command).
Page 173 Function Control Mode Value Description Name LCD Display External Baseblock Command (rotation Ext. BB ON：Inverter base interdiction freely to stop) PID control disable PID Disable ON：PID control disabled Fault reset (Reset) Fault Reset Fault reset Auto Run Mode Enable ON：Auto run mode enable(06-00) Speed Search (from the ON：...
Page 174 Function Control Mode Value Description Name LCD Display KEB Acceleration KEB Accel. ON：KEB acceleration start Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Forced Frequency Run Forced Frequency Run ON：Forced Frequency Run Enable Reserved Reserved...
Page 175 Figure 4.3.28 Multi-speed operation selection Multi-function digital input (S1 to S6) Speed Multi-speed Multi-speed Multi-speed Multi-speed Frequency selection frequency frequency 3 frequency 2 frequency 1 frequency 0 reference Frequency command 0( 05-01) or main speed frequency frequency reference 1 ( 05-02) *3 Frequency command 2 ( 05-03) Frequency command 3 ( 05-04) Frequency command 4 ( 05-05)
Page 176 Figure 4.3.18 9-speed timing diagram *1：When 00-05=1, multi-speed frequency reference is set by analog input AI1 or AI2. When 00-05=0, multi-speed frequency reference is set by 05-01. (8) Forward jog run command (03-0X=06) (9) Reverse jog run command (03-0X=07)  Jog command has a higher priority than other frequency reference commands. ...
Page 177 For the examples of UP/DOWN control wiring and operation, please refer to figure 4.3.19 and  figure 4.3.20。 Fugure 4.3.19 UP/DOW and operation example Figure 4.3.20 Up / Down command timing diagram When the Forward Run command is active and the UP or Down command is momentarily ...
Page 178 (12) Acceleration/deceleration 1 selection (03-0X=10) Refer to the "multi-function digital input terminals select acceleration / deceleration time” .  (13) Inhibit Acceleration/deceleration command (03-0X=11) Operation of inhibit Acceleration/deceleration function, please refer figure 4.3.21。  The frequency reference value is saved when the acceleration/deceleration inhibit command is ...
Page 179 During run： When an external base block command is activated, the keypad displays "BBn BaseBlock (Sn)", indicating the inverter output is turned off (n indicates the digital input number 1 – 8). Upon removing the base block signal, the motor will run at the frequency reference. If speed search from frequency reference is active the inverter output frequency starts from the frequency reference and searches for the coasting motor speed and continue to operate.
Page 180 (20) Auto run mode enable (03-0X=18) Digital input set to “18”, auto run mode function will be enabled, please refer to group 06.  (21) Speed Search 1 (from the maximum frequency) (03-0X=19) (22) Energy saving enabled (03-0X=20) Manual energy savings function is set with parameters 11-12 and 11-18, for the manual energy ...
Page 181 (29) Local/Romote selection (03-0X=27) Switch the inverter frequency reference source between Local (keypad) or Remote (control  circuit terminals or RS485). Use parameter 00-05 (Main frequency command source selection) and 00-02 (Run command selection) to select the remote source. Local/Remote function can be set by one of digital inputs (S3~S6), and be switched by ...
Page 182 (33) Speed search 2 (03-0X =34) (34) Switching between motor 1 and motor 2 (03-0X =40) (35) Fire mode (03-0X=47) When input is active (03-00~03-05=47) disables all inverter warning and hardware protections.  This function is commonly used in commercial applications where the inverter controls an exhaust fan and needs run to destruction in case of a fire.
Page 183 (40) PID Control Disable 2 (03-0X=66) (41) External Fault (03-0X=68) When this function is enabled, inverter will stop running and motor will coast to stop.  When digital input (S3) set to external fault, keypad will display “EF3 Ext. Fault (S3)”. ...
Page 184 Mode 3： When 03-06≠0, and the turned on period is greater than 2 secs, frequency will be changed by acceleration/deceleration time. Note： Difference of acceleration frequency △H1： t1： Input terminal turned on time of acceleration time Difference of deceleration frequency △H2：...
Page 185 03- 07 UP/DOWN Keep Frequency Status after Stop Command 【0】：When UP/DOWN is used, the preset frequency is held as the inverterstops, and the UP/DOWN function is disable. 【1】：When UP/DOWN is used, the preset frequency is reset to 0 Hz as the Range inverter stops.
Page 186 03-11 Relay (R1A-R1C) output 03-12 Relay (R2A-R2C) output 【0】： During Running 【1】： Fault Contact Output 【2】： Frequency Agree 【3】： Setting Frequency Agree (03-13 ± 03-14) 【4】： Frequency Detection 1 (≧ 03-13, hysteresis range is the setting value of 03-14) 【5】： Frequency Detection 2 (≦03-13, hysteresis range is the setting value of 03-14) 【6】：...
Page 187 Table 4.3.29 Function table of multi-function digital output Function Control mode Value Contents Name LCD display During Running Running ON：Dring running (Run command is ON) ON：Fault contact output (except CF00 and Fault Contact Output Fault CF01) ON：Frequency agree (frequency agree width Frequency Agree Freq.
Page 188 Function Control mode Value Contents Name LCD display Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Motor 2 Selection Motor 2 Selection ON：Switch to Motor 2 Reserved Reserved Reserved Reserved...
Page 189 Output is active when the output frequency falls within the frequency detection width  (03-14) of the set frequency detection level (o3-13) (4) Setting Frequency Agree (03-13 ± 03-14) (03-1X=3) Output is active when the output frequency falls within the frequency detection width ...
Page 190 (16) PID Feedback Signal Loss (03-1X=15) Output is active when PID feedback signal loss.  (17) PLC Status Indicator (03-1X=18) Output is active when operation command parameter 00-02 is set to PLC control.  (18) PLC Control (03-1X=19) Output is controlled by the PLC logic. ...
Page 191 functions 1 to 6.  The time charts of the frequency agree detection operation are shown in table 4.3.30. Detection operation of frequency Function Description confirmation Freq  Output is active when the output Output Reference Frequency 03-14 frequency falls within the frequency reference minus the frequency time Frequency...
Page 192 Detection operation of frequency Function Description confirmation 03-15 Current Agree Level Range 【0.1~999.9】A 03-16 Delay Time of Current Agree Detection Range 【0.1~10.0】 Sec When 03-11=13 and then when the output current > 03-15, output relay will active.  03-15：The suggest setting value is 0.1 to motor rated current. ...
Page 193 Time diagram for 03-17 ≥ 03-18 is shown below.  03- 19 Relay (R1A-R2B) Type 【xxx0b】：R1 A Contact 【xxx1b】：R1 B Contact Range 【xx0xb】：R2 A Contact 【xx1xb】：R2 B Contact If 03-19=0, When the set conditions of 03-11,03-12 are met , relay contact is closed. ...
Page 194 Example： S2、S4、S6 terminal decided to internal multi-function terminal (decided by 03-21) S1、S3、S5 terminal decided to external multi-function terminal (remote control) Please set 03-20=101010, summarized the total value of 03-20 is 42 (32+8+2=42). 03- 21 Action to Set The Internal Multi-Function Input Terminals Range 【0~63】...
Page 195 03-24 Output Under Current Detection 【0】：Invalid Range 【1】：Valid 03-25 Output Under Current Detection Level Range 【0~999.9】A 03-26 Output Under Current Detection Delay Time Range 【0.0~655.34】 Sec If 03-11=55, when output current ≦ 03-25, output relay is active.  When 03-25=0, the function will be disabled. ...
Page 196 03-27 Pulse Frequency Selection (S3) Range 50~25000Hz 03- 28 Pulse Frequency Gain Range 【0.0~1000.0】% 03- 30 Pulse Input Selection 【0】：General Pulse input Range 【1】：PWM There are two ways for pulse input selection：  (1) General pulse input： PI=Cutoff frequency divided by pulse input scale set by 03-27, corresponding to the maximum output frequency of motor 1 (01-02).
Page 197 03-27=200Hz (Pulse Frequency) 03-28=100.0~1000% (Pulse Input Gain) When PWM input with different duty, the ouput frequency of display will be different. When 200Hz pulse with 50% duty, 00-12=60.00, 03-28=100.0, keypad display will be  50% ×60.00=30.00Hz， When 200Hz pulse with 30% duty, 00-12=60.00, 03-28=200.0, keypad display will be ...
Page 198 Group 04 Analog Signal Inputs / Analog Output 04- 00 Analog Input Signal Type 【0】: AI1 0~10V / 0~20mA AI2 0~10V / 0~20mA 【1】: AI1 0~10V / 0~20mA AI2 2~10V / 4~20mA Range 【2】: AI1 2~10V / 4~20mA AI2 0~10V / 0~20mA 【3】: AI1 2~10V / 4~20mA AI2 2~10V / 4~20mA 04- 01...
Page 199 +10V Related Parameters 04-00 (Analog input signal type) 0~10V, -10V~+10V 04-02 (AI1 gain) AI 1 04-03 (AI1 bias) 04-05 (AI1 slope) 04-06 (AI2 signal scanning and filtering time) 0~10V / 0~20mA 04-07 (AI2 gain) AI 2 04-08 (AI2 bias) 4-20mA / 2 -10V 04-10 (AI2 slope) Figure 4.3.35 Analog inputs and related parameters Please refer fig 4.3.36 for gain and bias operations.
Page 200 04-11 AO function setting 【0】：Output frequency 【1】：Frequency command Range 【2】：Output voltage 【3】：DC voltage 【4】：Output current 04-12 AO gain Range 【0.0~1000.0】% 04-13 AO bias Range 【-100.0~100.0】% 04-15 AO Slope 【0】：Positive Range 【1】：Nagetive 04-16 Proportio Gearing function 【0】：Disable Range 【1】：Enable For the analog output and related parameters, please refer to figure 4.3.50. Figure 4.3.50 Analog outputs and related parameters (1) Analog output adjustment (04-12, 04-13)。...
Page 201 (2) Analog output terminal function selection (04-11)。 Please refer to the following table 4.3.33。  Table 4.3.33 Selection of analog output terminals function (04-11) 04-11 Monitoring Control Mode Function parameter Parameters (Keypad display) PMSLV setting 12 Group Output Freq 12-17 Freq Ref 12-16 Output Voltage...
Page 202 04-20 AO signal scanning and filtering time Range 【0.00~0.50】Sec Setting of parameter 04-20 is used for filtering momentary change in analog output signal.  When it is enabled, system response will lower down and interference protection will enhance. 04-22 AO Voltage Correction Selection Range 【0~1】...
Page 203 Group 05 Preset Frequency Selection 05- 00 Preset Speed Control Mode Selection 【0】：Acceleration and deceleration time 1 ~ 4 used. Range 【1】：Use independent acceleration and deceleration time for each multi-speed setting. 05- 01 Preset Speed 0 05- 02 Preset Speed 1 05- 03 Preset Speed 2 05- 04...
Page 204 05- 38 Preser Speed 10-Dec time 05- 39 Preser Speed 11-Acc time 05- 40 Preser Speed 11-Dec time 05- 41 Preser Speed 12-Acc time 05- 42 Preser Speed 12-Dec time 05- 43 Preser Speed 13-Acc time 05- 44 Preser Speed 13-Dec time 05- 45 Preser Speed 14-Acc time 05- 46...
Page 205 Acceleration/Deceleration calculation of mode 1： 05-03 05-02 Preset speed2 05-01 Preset speed1 Preset speed0 command STOP STOP STOP Example： (05-17 ) x(05 -01) (05-18)x(05-01) (05-19)x(05-02) ,b = 01 -02 01-02 01-02 4-139...
Page 206 Acceleration/Deceleration calculation of mode 2： 4-140...
Page 207 Group 06 Automatic Program Operation 06- 00 Auto Run Mode Select 【0】：Disable 【1】：Execute a single cycle operation. Restart speed is based on the previous stopped speed. 【2】：Execute continuous cycle operation. Restart speed is based on the previous cycle stop speed. 【3】：After completion of a single cycle, the on-going operation speed is based on the speed of the last stage.
Page 208 Range 【0.0~6000.0】Sec 06- 16 Operation time setting of speed-stage 0 06- 17 Operation time setting of speed-stage 1 06- 18 Operation time setting of speed-stage 2 06- 19 Operation time setting of speed-stage 3 06- 20 Operation time setting of speed-stage 4 06- 21 Operation time setting of speed-stage 5 06- 22...
Page 209 Auto Run examples are shown as following. (1) Single cycle (06-00=1,4) The inverter will run for a single full cycle based on the specified number of sequnces, thenit will stop. In this example, 4 sequences are set, three in forward direction and one in reverse direction.
Page 210 (3) Auto Run Mode for Single Cycle (06-00=3,6) The speed of final step will be held to run. (The final step must be put in stage 15) All other parameters are set same as “Example 1” shown above. Freq. 06-02 50 Hz 06-01 30 Hz...
Page 211 Group 07 Start/Stop Parameters 07- 00 Momentary power loss and restart 【0】：Disable Range 【1】：Enable 07- 01 Fault reset time Range 【0~7200】 Sec 07- 02 Number of restart attempts Range 【0~10】 07- 03 Reset Mode Setting 【0】：Enable Reset Only when Run Command is Off Range 【1】：Enable Reset when Run Command is On or Off When 07-00=1, If the input power supply due to sudden increase in supply demand by...
Page 212  Fault reset time (07-01) Restart time of momentary power loss is the same as Fault reset time. 07-01 <07-18：Automatic restart time interval is set by minimum baseblock time (07-18). 07-01> 07-18：Automatic restart time interval is set by fault reset time (07-01). Note: Automatic restart time interval is time of 07-18 plus 07-01 and delay time of peed search (07-22).
Page 213 Please refer to figure 4.3.56 for the automatic restart operation. Figure 4.3.56 Auto-restart operation Reset Mode Setting (07-03)  When 07-03=0, after inverter fault detection, the input power must be turned off and then turn on to perform reset function. Otherwise, inverter can not be restarted. (When 00-02=1, reset mode function is active) Note：...
Page 214 07- 06 DC Injection Braking Start Frequency Range 【0.0~10.0】Hz The braking act according to the different control modes (00-00), please refer to the following  descriptions When control mode is V/F or SLV (00-00 = 0, 2)：  It start DC injection braking by the time 07-16. Deceleration to stop is according to 07-06 and ...
Page 215 07- 07 DC Injection Braking Level Range 【0~100】% 07- 08 DC Injection Braking time Range 【0.00~100.00】Sec 07- 16 DC injection braking time at start Range 【0.00~100.00】Sec Set parameter 07-06, 07-08 and 07-16 for DC injection braking related function.  When inverter executes speed search function, DC injection braking function should be ...
Page 216 (1) 07-09=0：Deceleration to stop When a stop command is issued, the motor will decelerate to the minimum output frequency  (01-08) Fmin and then stop. Deceleration rate depends on the deceleration ime (factory default is 00-15). When the output frequency reaches the DC braking stop frequency (07-06) or the minimum ...
Page 217 (3) 07-09=2：DC braking to stop When a stop command is issued, the inverter will turn off the output (Baseblock) and after the  minimum Baseblock time (07-18) has expired activate DC braking (07-07). The DC braking time (t ) of Figure 4.4.60 is determined by the value of 07-08 (DC Braking ...
Page 218 07- 10 Speed Search Mode Selection 【0】：Disable Range 【1】：Execute speed search once 【2】：Speed Search Start 0：The inverter start to run from the lowest output frequency but it won’t limit the other functions of trigger speed search. 1：The inverter executes a speed search at power on when entering first run command. It start the motor from found frequency.
Page 219 Refer to the following figure 4.3.63。 Figure 4.3.63 Minimum B.B time and momentary power loss time Minimum base block time (07-18) is also used to for the DC braking function  Set the minimum base block time required (07-18).  Increase minimum Baseblock time if over-current "OC"...
Page 220 The speed search cannot be used when the motor rated power is greater than the inverter  rated power. In V / F mode, it is necessary to perform a static auto-tune.  In SLV mode, it is necessary to perform a rotational auto-tune. Perform a static auto-tune when ...
Page 221 (2) 07-24=0, disable direction-detection speed search： Speed search is executed using speed search operating current defined in parameter 07-20. In case speed search is not successful (e.g. motor speed is too low) a speed search time-out warning is displayed. Set 07-19 to value greater than 0 to enable DC braking at speed search if a time-out occurs frequently.
Page 222 (b) Speed search in recovery period of momentary power failure Momentary power loss Minimum b.b. time (07-18) Run command Search command (07-18) Speed search decel time (07-21) Output frequency V/f during speed search Return to voltage at normal operation Voltage recovery time (07-23) Output voltage Output current (07-20)
Page 223 (4) Set the pre-excitation time (07-37) based on the electrical time constant T2 07- 38 Pre-excitation level Range 【50~200】% (1) Use the pre-excitation initial level (07-38) to provide a higher excitation current during the pre-excitation time (07-37), which will increase the speed and stability for motors. (2) In order to quickly magnetize the motor, reduce the pre-excitation time (07-37) and set the pre-excitation level (07-38) to a high level.
Page 224 Group 08 Protection Parameters 08- 00 Stall prevention function 【xxx0b】：Stall prevention function is enabled during acceleration. 【xxx1b】：Stall prevention function is disabled during acceleration. 【xx0xb】：Stall prevention function is enabled during deceleration. 【xx1xb】：Stall prevention function is disabled during deceleration. 【x0xxb】：Stall prevention function is enabled during operation. Range 【x1xxb】：Stall prevention function is disabled during run.
Page 225 Please refer fig.4.3.67 for stall prevention during acceleration. Figure 4.3.67 Stall prevention during acceleration (4) If the motor is used in the constant power (CH) region, the stall prevention level (08-01) is automatically reduced to prevent the stall. (5) Stall prevention level during acceleration (Constant horsepower) Parameter 08-21 is the stall prevention limit value in Constant Horsepower region.
Page 226 Stall prevention level can be set by 08-02, see table 4.3.34。 Table 4.3.34 Stall prevention level Inverter model 08-02 default value 200V class 385VDC 400V class 770VDC Please refer fig.4.3.69 for stall prevention during deceleration. When external braking function is starting (braking resistor or braking module), stall prevention during deceleration function (08-00 to xx1xb) is disabled.
Page 227 08- 05 Selection for motor overload protection (OL1) 【xxx0b】：Motor overload is disabled 【xxx1b】：Motor overload is enabled 【xx0xb】：Cold start of motor overload 【xx1xb】：Hot start of motor overload Range 【x0xxb】：Standard motor 【x1xxb】：Special motor 【0xxxb】：Reserved 【1xxxb】：Reserved (1) Please set motor overload protection function by parameter 08-05 according to currently motor.
Page 228 (2) When 08-07=1, The inverter is supplied by power, the fan start to run. If inverter stop to run longer than 08-30, the fan start to stop. (3) When 08-07=2, The inverter is supplied by power, the fan start to run. (4) When 08-08=3, The fan will not run.
Page 229 08- 14 Selection of over-torque action 【0】：Deceleration to stop when over-torque is detected. Range 【1】：Displays warning when over-torque is detected. Continue operation. 【2】：Coast to stop when over-torque is detected 08- 15 Level of over-torque detection Range 【0~300】% 08- 16 Time of over-torque detection Range 【0.0~10.0】Sec The over torque detection function monitor the inverter output current or motor torque and...
Page 230 08- 24 Operation Selection of External Fault 【0】：Deceleration to Stop Range 【1】：Coast to Stop 【2】：Continous Operation When multi-function digital input terminal is set to 25 (the external fault) and this terminal  signal is triggered off, parameter 08-24 (Operation Selection of External Fault) can be selected to stop it.
Page 231 (5) The resistor (PTC) conform the British Standards Institution： When Tr is 150 ℃in Class F and is 180℃ in Class H  Tr-5℃：R ≦ 550Ω，put R in formula (1), the V value by calculation is the value of 08-43. ...
Page 232 08 - 49 Multi-Function Input Terminal Status of Fire Mode 【0】: Reset after Power Off Range 【1】: Reset after Terminal Removed When 08-49=0, pelase disconnect the power first, remove external trigger signal and then  connect the power. When 08-49=1, no need to disconnect the power, inverter will become to normal mode, run ...
Page 233 08 - 51 Motor Speed Setting Source of Fire Mode 【0】：Fire Mode Speed (08-52) Range 【1】：PID Control 【2】：AI2 When 08-51=0, motor speed setting will follow 08-52. If the value of 08-52 is 100%, inverter  output frequency will follow the value of 01-02. When 08-51=1, motor speed setting will follow PID control;...
Page 234 08 – 56 Detection Level of Fire Mode AI2 Signal Range 【0~100】% 08 - 57 Delay Time of Fire Mode AI2 Signal Loss Range 【0.0~10.0】Sec 08 - 58 Selection of Fire Mode AI2 Signal Loss 【0】：Keep Running Range 【1】：Fire Mode Speed(08-52) 【2】：Max.
Page 235 Group 09 Communication Parameters 09- 00 INV Communication Station Address Range 【1~254】 09- 01 Communication Mode Selection 【0】：MODBUS Range 【1】：BACNet 09- 02 Baud Rate Setting (bps) 【2】：4800 【3】：9600 Range 【4】：19200 【5】：38400 09- 03 Stop Bit Selection 【0】：1 stop bit Range 【1】：2 stop bits 09- 04 Parity Selection...
Page 236 controller uses RTU format, it can not support communication data bit of 7 bit data. (09-05=1). Modbus (RS-485) communication specification： Items Specifications Interface RS-485 Communication period Asynchronous (start - stop synchronization). Baud rate：4800, 9600, 19200 and 38400 bps. Data Length：8 bits (Fixed). Communication parameters Parity：options of none, even and odd bit.
Page 237 Communication Data Bit Selection(09-05)  09-05= 0：8 bits data 09-06= 1：7 bits data RS-485 communication error detection time(09-06)  Stop selection of RS-485 communication failure(09-07)  09-07= 0：Deceleration to stop by deceleration time (00-15) 09-07= 1：Coast to stop 09-07= 2：Deceleration to stop using the deceleration time of 00-26 (emergency stop time) 09-07= 3：Keep running(warning message only, press the stop button to stop operation) Communication fault tolerance count(09-08) ...
Page 238 Group 10 PID Parameters 10- 00 PID target value source setting 【0】：Keypad given 【1】：AI1 given Range 【2】：AI2 given 【3】：Communication given 【4】：Use 10-02 setting When 10-00=0  Keypad can adjust the PID target value. When 10-00=1 or 2  The source of signal is proportional to be corresponding to PID target via analog input terminal. For example：...
Page 239 【0xxxb】：PID output 【1xxxb】：PID output + Frequency Command PID target value source setting (10-00)/PID feedback value source setting(10-01).  Please confirm parameter 04-00 conform the need (0~10V or 4~20mА), if AI2 as PID target or PID feedback. And switch SW2 from control board to the input type (V or I), please refer to wiring diagram for more detail.
Page 240 PID Adjustments  P control： The error signal (deviation) between the input command (set value) and the actual control value (feedback). This error signal or deviation is amplified by the proportional gain (P) to control the offset between the set value and the feedback value. I control：...
Page 241 (2) Basic PID control(10-03=x0xxb) This is the basic type of PID control. Refer to the figure 4.3.79. Figure 4.3.79 Basic PID control PID Setup:  Enable PID control by parameter 10-03, PID target value (10-00) and PID feedback value (10-01). (1) Select PID trget value：PID target value selection(10-00) 10-00=0：Keypad given 10-00=1：Analog AI1 given (default)
Page 242 PID Control Setting  PID control block disgram, the following figure shows PID control block diagram. Figure 4.3.81 PID control block diagram PID Tunning, use the following procedures to start PID control  (1) Enable PID control Set 10-03 to a value greater than "xxx0b"). ...
Page 243 PID Limit(10-23)  Used to limit the output of the PID control. Maximum output frequency is 100%. PID Output gain(10-24)  Used to adjust the compensation. Use parameter 10-24 to adjust the compensation to output frequency. PID reversal output selection(10-25) ...
Page 244 (3) Reduce long-period oscillation Adjust the integral time (I) in case of long-periodical system oscillation. (4) Reduce short-period oscillation Before Output Adjusting the differential time (D) and proportional (P) gain when experiencing After short-periodical oscillation. 10-11 PID feedback loss detection selection 【0】：Disable Range 【1】：Warning...
Page 245 Figure 4.3.82 PID feedback loss detction 10-15 Integral Value Resets to Zero when Feedback Signal Equals the Target Value 【0】：Disable Range 【1】：1 Sec 【30】：30 Sec (Range：0 ~ 30 Sec) When 10-15=0, As PID feedback reaches the set point, the integrator will not be reset to 0. ...
Page 246 Refer to figure 4.3.83 (a), (b) and (c) for PID sleep/wakeup operation： Figure 4.3.83 (a) PID control block diagram Figure 4.3.83 (b) Timing diagram PID sleep / wakeup Figure 4.3.83 (c) Timing diagram of PID sleep compensation/ wakeup 10-40=0, refer to Figure 4.3.83(b) ...
Page 247 While sleep mode is active and the motor has stopped, the internal PID control is still in operating. When the reference frequency increases and exceeds the wakeup frequency parameter 10-19 for the time specified in the wakeup delay time parameter 10-20, the inverter will restart and the output frequency will ramp up to the reference frequency.
Page 248 10-30 Upper Limit of PID Target Range 【0 ~ 100】% 10-31 Lower Limit of PID Target Range 【0 ~ 100】% Target value of PID will be limited to the range of upper & lower limit of PID target.  10- 33 Maximum Value of PID Feedback Range 【1~10000】...
Page 249 Group 11 Auxiliary Parameters 11-00 Direction Lock Selection 【0】：Allow forward and reverse rotation Range 【1】：Only allow forward rotation 【2】：Only allow reverse rotation If motor operation direction is set to 1 or 2, the motor can only operate in that specific ...
Page 250 11-02 Soft PWM Function Selection 【0】：Disable Range 【1】：Soft PWM 11-02=1：Soft PWM  Soft PWM control can improve the metal noise produced by the motor, more comfortable for the human ear. At the same time, Soft PWM also limits RFI noise to a minimum level. The default setting of Soft PWM control is disabled.
Page 251 11-08 Jump Frequency 1 11-09 Jump Frequency 2 11-10 Jump Frequency 3 Range 【0.0~599.0】Hz 11-11 Jump Frequency Width Range 【0.0~30.0】Hz These parameters allow “jumping over” of certain frequencies that can cause unstable  operation due to resonance within certain applications. Prohibit any operation within the jump frequency range.
Page 252 Manual energy saving gain (11-12)  (1) When manual energy savings is enabled, output voltage of inverter will be determined by parameter 11-12, output voltage is percentage gain times the V/F voltage. (2) Manual energy saving control uses the voltage recovery time (07-23) to change the output voltage.
Page 253 11- 38 Deceleration start voltage of OV prevention 230V：【200~400】V Range 400V：【400~800】V 11- 39 Deceleration end voltage of OV Prevention 230V：【300~400】V Range 400V：【600~800】V 11- 40 OV Prevention Selection 【0】：Disable 【1】：OV prevention Mode 1 Range 【2】：OV prevention Mode 2 【3】：OV prevention Mode 3 Over-voltage suppression is used for the application of likely causing to energy recharge.
Page 254 Figure 4.3.91 OVP Operatrion When 11-40=1：OV Prevention Mode 1  (1) DC voltage filter is used to provide a stable reference value for determining the change in DC voltage change during regenerative operation. Adjust the DC voltage filtering increase rate parameter 11-33 (DC Voltage Filter Rise ...
Page 255 (3) When the inverter is stopped, the deceleration rate can be set with parameter 00-15(Tdec1). In case the DC voltage is too high, the inverter will decelerate based on the OVP deceleration time as shown in figure 4.3.92 Set DC-bus voltage in parameter 11-38 (start voltage of OVP deceleration) and set OVP ...
Page 256 KEB Deceleration Time (11-47)  (1) When 11-47=0, KEB function is disabled. (2) Set 11-47 (KEB deceleration time) from 0.0 to 25.5. KEB Detection Level (11-48）  If the DC-bus voltage falls below the value set in 11-48, the KEB is activated and the inverter starts decelerating according to the value set in 11-47.
Page 257 11- 61 Time Parameter of Preventing Oscillation Range 【0~100】 Adjust the response of oscillation function. (Time parameter of adjust preventing  oscillation function delay.) 11- 62 Selection of Preventing Oscillation 【0】：Mode 1 Range 【1】：Mode 2 【2】：Mode 3 When 11-62=0 (Mode1) and 1 (Mode 2)：The response to preventing oscillation is slower. ...
Page 258 11- 69 Gain of Preventing Oscillation 2 Rang 【0.00~200.00】% Adjust the response of Gain of Preventing Oscillation 3  If occur vibration with motor in ND mode, please increase by 0.01 unit to set. 11- 70 Upper Limit of Preventing Oscillation 2 Rang 【0.01~100】% It is required to limit the preventing oscillation 3 upper limit within the setting value.
Page 259 Group 12 Monitoring Parameters 12- 00 Display Screen Selection (LED) (Highest bit) 0 0 (Lowest bit) The value range if each bit is 0~8 from the highest bit to the lowest bit 【0】：No display 【1】：Output current 【2】：No display Range 【3】：DC busvoltage 【4】：heatsink temperature 【5】：PID feedback 【6】：AI1 value...
Page 260 12- 05 Status display of digital input terminal (LED / LCD) Range Read-only Terminal S1~S6 are represented using two segments of each digit. Segment turns on when  input is active. Example 1： S1/S3/S5/S6 are ON, S2/S4 are OFF, 12-05 will turn on when RY1 without output. (LED) S2 S3 S4 S5 Example 2：...
Page 261 12- 43 Inverter Status (LED/LCD) Range Read Only（Only on keypad display） 12-43 Inverter status definition (some different with communication redister 2520H)  Bit 0 : Inverter Ready 1 : Ready 0 : Not ready yet Bit 1 : During Running 1 : Operation 0 : Stop 1 :“ON”...
Page 262 Group 13 Maintenance Parameters 13- 00 Inverter Capacity Selection Range ---- Inverter Model 13- 00 Display Inverter Model 13- 00 Display E510s-2P5 E510s-401 E510s-201 E510s-402 E510s-202 E510s-403 E510s-203 E510s-405 E510s-205 E510s-408 E510s-208 E510s-410 E510s-210 E510s-415 E510s-215 E510s-420 E510s-220 E510s-425 E510s-225 E510s-430 E510s-230 E510s-440...
Page 263 13- 07 Parameter Lock Key Code Range 【00000~65534】 When parameter lock key code is enabled (13- 07>0), all parameter except main frequency  can’t be modified. Only unlock the key code, modify the parameters is allowable. Setting parameter lock key number example： ...
Page 264 13- 08 Restore factory setting / Initialize 【1】：2 wires initialization (50Hz) (220V/380V) 【2】：2 wires initialization (60Hz) (220V/380V) 【3】：2 wires initialization (50Hz) (230V/400V) 【4】：2 wires initialization (60Hz) (220V/460V) 【5】：2 wires initialization (50Hz) (220V/415V) Range 【6】：2 wires initialization (60Hz) (230V/400V) 【7】：2 wires initialization (50Hz) (220V/440V) 【8】：2 wires initialization (60Hz) (220V/440V) 【9】：2 wires initialization (60Hz) (220V/380V) 【10】：2 wires initialization (60Hz) (220V/380V)
Page 265 13-08=6：2 wires initialization (230V/400V)  (1) Multi-function digital input terminal S1 controls forward operation / stop command, and S2 controls reverse operation / stop command. Refer to figure 4.3.1. (2) Inverter input voltage (01-14) is automatically set to 230V (220V calss) or 400V (440V calss). (3) When 01-00 (V/F curve) = F, 01-02 will automatically set to 60Hz.
Page 266 13- 10 Parameter Password Function 2 Range 【0~9999】 13- 51 Clear Cumulative Operation Hours 【0】：Disable to Clear Cumulative Operation Hours Range 【1】：Clear Cumulative Operation Hours 4-200...
Page 267 Group 14 PLC Parameters 14- 00 T1 set value 1 14- 01 T1 set value 2 (mode 7) 14- 02 T2 set value 1 14- 03 T2 set value 2 (mode 7) 14- 04 T3 set value 1 14- 05 T3 set value 2 (mode 7) 14- 06 T4 set value 1...
Page 268 14- 36 MD1 set value 1 14- 37 MD1 set value 2 14- 39 MD2 set value 1 14- 40 MD2 set value 2 14- 42 MD3 set value 1 14- 43 MD3 set value 2 14- 45 MD4 set value 1 14- 46 MD4 set value 2 Range...
Page 269 Group 15 PLC Monitoring Parameters 15- 00 T1 Current Value1 15- 01 T1 Current Value 2 (Mode7) 15- 02 T2 Current Value 1 15- 03 T2 Current Value 2 (Mode7) 15- 04 T3 Current Value 1 15- 05 T3 Current Value 2 (Mode7) 15- 06 T4 Current Value 1 15- 07...
Page 270 Group 16 LCD Function Group 16- 00 Main Screen Monitoring Range 【5~43】 16- 01 Sub-Screen Monitoring 1 Range 【5~43】 16- 02 Sub-Screen Monitoring 2 Range 【5~43】 At power-up the inverter shows two monitor section on the display, main monitor section and ...
Page 271 16-03 Set / displayed contents 0.01 Hz 0.01 % (maximum output frequency 01-02=100%) Frequency display unit is RPM 3- 39 Reserved Set the decimal point by using the fifth place i.e. □ □□□□ Sets full display scaling excluding decimals Set the number of decimal places 00040 - 09999：...
Page 272 16- 07 Copy Function Selection 【0】：Do not copy parameter 【1】：Read inverter parameters and save to the keypad Range 【2】：Write the keypad parameters to inverter 【3】：Compare parameters of inverter and keypad 16- 08 Selection of allowing reading 【0】：Do not allow to read inverter parameters and save to the keypad Range 【1】：Allow to read inverter parameters and save to the keypad LCD digital operator can be used to store and retrieve parameters...
Page 273  READ：Copy inverter parameters to the keypad Steps LCD Display (English) Description Select the copy function group (16) from the group menu. Press the Read / Enter key and select parameter (16-07) copy selection. Press the Read / Enter key to display the data setting / read screen (LCD display is inversed).
Page 274 WRITE：Copy Keypad parameters to the Inverter Steps LCD Display (English) Description Select the copy function group (16) from the group menu. Press the Read / Enter key and select parameter (16-07) copy sel. Press the Read / Enter key to display the data setting / read screen (LCD display is inversed).
Page 275 Verify：Compare Inverter Parameters against Keypad Parameters  Steps LCD Display (English) Description Select the copy function group (16) from the  group menu. Press the Read / Enter key and select parameter  (16-07) copy sel. Press the Read / Enter key to display the data ...
Page 276 Group 17 Automatic Tuning Parameters 17- 00 Mode selection of automatic tuning 【0】：Rotational auto-tuning 【1】：Static auto-tuning 【2】：Stator resistance measurement Range 【3】：Reserved 【4】：Loop tuning 【5】：Rotational Auto-tuning Combination (Item: 4+2+0) 【6】：Static Auto-tuning Combination (Item: 4+2+1) 17- 01 Motor rated output power Range 【0.00~600.00】kW 17- 02 Motor rated current...
Page 277 Rotational auto-tuning (17-00=0)  Inverter can provide higher quality for motors. After executing Rotational auto-tuning (17-00), Excitation current of motor 1 (02-09)、Core saturation coefficient 1 of motor 1(02-10)、Core saturation coefficient 2 of motor 1 and Core saturation coefficient 3 of motor 1 (02-12) will renew the value.
Page 278 Number of poles (17-06)  Set the motor pole number with its range is 2~16 poles. (even) Motor no-load voltage (17-08)  (1) Motor no-load voltage is mainly used in SLV mode, set to value 10~50V lower than the input voltage to ensure good torque performance at the motor rated frequency.
Page 279 Example 1： Motor rated voltage (440V/60Hz) is higher than the inverter input voltage (380V/50 Hz). Output Inverter Voltage 440V 380V/50Hz 440V/60Hz 17-03 Output Frequency 17-04 60Hz Rated frequency (for motor nameplate) Motor rated frequency (for auto-tuning operation) Motor rated voltage (for auto-tuning operation) Rated voltage (for motor nameplate) Figure 4.3.98 Rated voltageand frequency settings Step 1：...
Page 280 (3) Vector type rotational auto-tuning (17-14=1) applies the special IM motor that will shake without loading for V/F mode. This function applies for high speed motor. If execute VF type rotational auto-tuning (17-14=0) unsuccessfully, try Vector type rotational auto-tuning (17-14=1) again. (4) Vector type rotational auto-tuning (17-14=1) measures no-loading current of motor by inner current vector method.
Page 281 Group 18 Slip Compensation Parameters Slip compensation gain at low speed 18- 00 Range 【0.00~2.50 】 Slip compensation gain at high speed 18- 01 Range 【-1.00~1.00】 18- 02 Slip compensation limit Range 【0~250】% 18- 03 Slip compensation filter Range 【0.0~10.0】Sec Regenerating slip compensation selection 18- 04 【0】：Disable...
Page 282 Figure 4.3.99 Slip compensation output frequency Slip compensation gain at high speed (18-01)  (1) It is not required to adjust the Slip compensation gain at high speed if the motor is loaded. (2) After adjusting parameter 18-00 it is recommended to increase the reference frequency and check the motor speed.
Page 283 Slip compensation limit (18-02)  (1) Sets slip compensation limit in constant torque and the constant power operation (Figure 4.3.100) (2) When 18-02 is 0%, the slip compensation limit is disabled. Slip Compensation Limit 01-02 × 18-02 01-12 18-02 base (01-12) (01-02) Figure 4.3.100 Slip compensation limit...
Page 284 The impact of 18-00 on the torque and the speed are shown in figure 4.3.101 Figure 4.3.101 18-00 Effect on the torque and speed FOC (Flux Orient Control) delay time (18-05)  (1) In the SLV mode, the slip compensation of the magnetic flux depends on the torque current and excitation current.
Page 285 Group 20 Speed Control Parameters 20- 00 ASR gain 1 Range 【0.00~250.00】 20- 01 ASR integral time 1 Range 【0.001~10.000】Sec 20- 02 ASR gain 2 Range 【0.00~250.00】 20- 03 ASR integral time 2 Range 【0.001~10.000】Sec 20- 04 ASR integral time limit Range 【0~300】% 20- 07...
Page 286 The following figure an overview of the automatic speed regulator (ASR) block.  SLV control mode： (1) The ASR function adjusts the output frequency to control the motor speed to minimize the difference between the frequency reference and actual motor speed. (2) The ASR controller in SLV mode uses a speed estimator to estimate the motor speed.
Page 287 Figure 4.3.112 ASR gain setting (SLV mode) Tune the speed control gain  During ASR gain tuning, the multi-function analog output (AO1 terminal) can be used to monitor the output frequency and motor speed (as shown in figure 4.3.112)。 SLV mode gain tuning (20-00~20-03 , 20-09~20-18) ...
Page 288 (11) Setting a low gain for the speed estimator (small proportion (P) gain and high integral (I) time) decreases the bandwidth of the speed feedback, may improve speed feedback interference resulting in a more stable system. (12) The default values for the ASR can be used in most applications, no adjustment is required. Adjusting the low-pass filter time and speed estimator gains requires a good understanding of the overall system.
Page 289 ASR integral limit (20-04)  Setting a small value may prevent system response when the load suddenly changes. ASR main delay time (20-08).  (1) Does not require to be adjusted for general purpose applications. (2) When the set value of 20-08 is set high, the speed response will be reduced, but the system is more stable.
Page 290 Group 21 Torque Limit Parameters 21- 05 Positive torque limit Range 【0~300】% 21- 06 Negative torque limit Range 【0~300】% 21- 07 Forward regenerating torque limit Range 【0~300】% 21- 08 Reversal regenerating torque limit Range 【0~300】% In SLV and PMSLV control mode, there are four torque limits that can be set separately： ...
Page 291 Group 22 PM Motor Parameters 22- 00 PM Motor Rated Power Range 【0.00~600.00】kW 22- 02 PM Motor Rated Current Range 25%~200% inverter’s rated current 22- 03 PM Motor’s Pole Number Range 【2~96】Poles 22- 04 PM Motor’s Rated Rotation Speed Range 【0~60000】RPM 22- 05 PM Motor’s Maximum Rotation Speed...
Page 292 22- 10 PM SLV Start Current Range 【20.0 ~ 200.0】% 22- 11 I/F Mode Start Frequency Switching Point Range 【1.0 ~ 20.0】% 22- 14 Armature Resistance of PM Motor Range 【0.001 ~ 30.000】Ω 22- 15 D-axis Inductance of PM Motor Range 【0.01 ~ 300.00】mH 22- 16...
Page 293  PM Motor Tuning (22-21) WARNING! The inverter and motor may start unexpectedly during Auto-Tuning, which could result in death or serious injury. Make sure the area surrounding of the motor and load are clear before proceeding with Auto-Tuning. (1) Please set 00-00=5 and then set 22-21=1, before selecting PM motor tuning, enter the motor data (22-00)~(22-06) according to the motor nameplate and the number of encoder pulses (20-27).
Page 294 Group 23 Pump & HVAC Function Parameters 23- 00 Function Selection 【0】: Disable 【1】: Pump Range 【2】: HVAC 【3】: Compressor Refer the wiring diagram of single/multi-pump in chapter 3.3.  Select function of pump or HVAC via parameter 23-00. This function is enabled if PID ...
Page 295 23- 04 Pump Pressure Command Source 【0】: Set by 23-02 Range 【1】: Set by AI Pressure command source is given the value set by 23-02 (Operation Pressure Setting) or AI.  Refer to parameter 10-00 for the setting of AI terminal. 23- 05 Display Mode Selection 【0】: Display of Target and Preesure Feedback...
Page 296 Table 4.3.17 Guide for PID parameter adjustment Main Feature Increase Setting Value Decrease Setting Value Proportional (Pros) Increase response time (Pros) Reduce jittering Increase Gain (P) (Cons) Might cause pump jittering (Cons) Slow down response stabilized time (Pros) Fast response For smooth Integral (Pros) Smooth output frequency...
Page 297 23- 11 Sleep Time of Constant Pressure Range 【0.0~255.5】Sec When the inverter finishes counting the sleep time (23-11), the output frequency falls  downward at the deceleration time (00-15) and gets into sleep status. Parameter 23-10 (sleep frequency of constant pressure) is dedicated by the pump and it is not applied to parameter 10-17 (start frequency of PID sleep).
Page 298 23- 13 Warning Time of High Pressure Range 【0.0 ~ 600.0】Sec When pressure feedback value is higher than maximum pressure limit, warning time of high  pressure starts to count. If pressure feedback value is lower than maximum pressure limit during counting time, the warning time will recount and the inverter will display the warning signal of HIPb when the warning time ends.
Page 299 23- 17 Fault Stop Time of Low Pressure Range 【0.0 ~ 600.0】Sec When the warning signal of low pressure occurs and pressure feedback value is lower than  minimum pressure limit, stop time of low pressure starts to count. If pressure feedback value is higher than minimum pressure limit during counting time, the stop time will recount and the inverter will display stop error signal of LPbFt when the stop time ends.
Page 300 23-23 Direction of Water Pressure Detection 【0】: Upward Detection Range 【1】: Downward Detection 23- 24 Range of Water Preesure Detection Range 【0.00 ~ 65.00】PSI When upward detection of water pressure starts, water pressure will slightly increase. At this  time, it may cause shortly pressure fluttering or instability if water consumption continues. It is recommended to reduce the range of water pressure detection (23-24) but it will extend the time of inverter jumping into sleep without water consumption or with mild water consumption.
Page 301 Fig. 4.3.108 Diagram for download detection of water pressure When downward detection of water pressure starts, the output frequency will decelerate with  the deceleration time of water pressure detection (23-27). Water pressure reduces with the deceleration when water consumption continues and pressure feedback value rises if the value is lower than that of target pressure value (23-02) - range of water pressure detection (23-24).
Page 302 23- 28 Foreced Run Command Range 【0.00 ~ 599.00】Hz This function is enabled when PID mode (10-03) is selected. Pump will not depend on the  feedback to make any PID output adjustment and runs the frequency of 00-05 (Frequency command) when multi-function digital input (S1~S6) is set to 16 (PID control disable).
Page 303 Fig. 4.3.109 Dual pumps start up process Dual pumps are enabled during this time. Master starts up first and Slave is in standby to enter constant-pressure operation. Large water consumption results in the higher operation frequency of Master. If water pressure is not lower than the tolerance range of constant-pressure and the operation time is not over the detection time (23-30), Slave is still in standby.
Page 304 Diagram of sleep stop alternative selection action Note: Dual pumps are enabled during this time. Higher operation pressure occurs, Master keeps operation and Slave output frequency decreases. Master operation frequency maintains 60Hz. If water pressure doesn’t decrease to the target constant pressure and Slave continuously decreases to the set trip frequency (23-22), Slave detection time (23-30) starts and Slave decelerates to stop.
Page 305 23-35=3, Timer alternately selected and sleep stop alternately selected will be enabled at the  same time. 23-35=4, When master stop running and the slave need to run, please set 23-35=4, and no  exchange between Master and Slave. 23-37 Leakage Detection Time Range 【0.0~100.0】Sec...
Page 306 When 23-37=0.0 (sec), switch off this function.  When pump is at shutdown state, pressure will drop over time if pipeline leaks. Inverter will  keep sleep state if pressure variation is lower than the value of parameter 23-38 in every detection time (23-37) and pump will restart if pressure variation is larger than that of 23-38 or pressure tolerance range is over the value of parameter 23-39 in the detection time.
Page 307 23-73 Slave Wake-up Selection 【0】Disable Range 【1】Enable When multiple pumps are in parallel and the requirements of slave wake-up can not be  achieved in tolerance range, user can set parameter 23-73=1 and refer to the following conditions to wake up Slave. (1) Master is in full speed operation (01-02 maximum output frequency) but pressure feedback value can not achieve the target pressure value.
Page 308: Built-In Plc Function
Built-in PLC function The PLC ladder logic can be created and downloaded by TECO DriveLink software. 4.4.1 Basic Command NO / NC   Inputs I1I8 / i1i8 Outputs Q1Q2 / q1q2 Auxiliary command M1MF / m1mF Special registers V1~V7...
Page 309: Basic Command Function
4.4.2 Basic command function ◎ D（d）command function Example 1： I1─D ───[ Q1 New scanning cycle Example 2： i1─d ───[ Q1 i1 is the inverse logic of I1 New scanning cycle NORMAL( -[ ) Output ◎ I1───[Q1 Output ◎ SET（  ） I1───...
Page 310 P mode output ◎ i1───PQ1 i1 is the inverse logic of I1 4- 244...
Page 311: Application Functions
4.4.3 Application functions 1. Counter Function Counter mode (1 ~ 4)  UP/Down counting modes can be set by (I1 ~ f8). OFF: Count up (0, 1, 2, 3…)  ON: Count down (…3,2,1,0) Use (I1~f8) to reset counting value ON: Internal count value is reset and counter output ...
Page 312 Example： Input from ladder program C3 input pulse counter is [C3] determined by I1 and i2. [Q1] [M2] Input from the function program Internal Up/down counting Counter Value C3 turns ON when the counter value reaches the set Value and at the same 0000 time, the C3 input in the ladder program turns ON as well.
Page 313 (1) Counter mode 3 is similar to the counter mode 1, with the exception that the counter value is saved when the drive is powered down and reloaded at power up. (2) Counter mode 4 is similar to the counter mode 2, with the exception that the counter value is saved when the drive is powered down and reloaded at power up.
Page 314 Timer mode description： (1) Timer mode 1 (ON-delay Timer mode 1) Example： (2) Timer mode 2 (ON-delay Timer mode 2) Reset internal Timer reset timer value Internal timer value Internal timer value = 0 and output Timer start T=t1+t2 When the set value is reached, the timer output turns on (T1 to T8) Reset timer and output T= timer set value...
Page 315 (3) Timer mode 3 (OFF-delay Timer mode 1) Timer start When the set value is reached, the timer output turns on (T1 to T8) Reset timer and output T= timer set value (4) Timer mode 4 (OFF-delay Timer mode 2) (5) Timer mode 5 (FLASH Timer mode 1) 4- 249...
Page 316 (6) Timer mode 6 (FLASH Timer mode 2) (7) Timer mode 7 (FLASH Timer mode 3) 4- 250...
Page 317 3、 Analog comparator function Symbol Description Analog comparator mode (1~3)  Input comparison value selection (AS1~AS4,MD1~MD4,T1~T8,C1~C8,V1~V7)  Current analog input value  Set the reference comparison value (Upper limit)  (AS1~AS4,MD1~MD4,T1~T8,C1~C8,V1~V7, constant ) Set the reference comparison value (lower limit) ...
Page 318 4. Operation control function Symbol Description Forward /Reversal control can be set by ( I1~f8 ) OFF：Forward(FWD)  ON：Reversal(REV) Speed terminal control can be set by ( I1~f8 ) OFF：Operation based on  set frequency  ON：Operation based on frequency of speed  Set frequency (can be constant or V3、V4，V5 ) ...
Page 319 5. Summation and subtraction functions RESULT（calculation result）= V1+ V2- V3 Symbol Description Calculation result : RESULT  Addend V1(AS1~AS4,MD1~MD4,T1~T8,C1~C8,V1~V7, constant )  Addend V2(AS1~AS4,MD1~MD4,T1~T8,C1~C8,V1~V7, constant )  Subtrahend V3(AS1~AS4,MD1~MD4,T1~T8,C1~C8,V1~V7, constant )  Coil output of error signal (M1~MF)  Addition and subtraction modes number (AS1~AS4) ...
Page 320: Chapter 5 Troubleshooting And Fault Diagnostics
Chapter 5 Troubleshooting and Fault Diagnostics 5.1 General 5.1.1 Fault detection function Table 1 Fault information and possible solutions LED display Description Cause Possible solutions  Acceleration / Deceleration time is too short. Over Current  Extend acceleration / The inverter output ...
Page 321 LED display Description Cause Possible solutions  Deceleration time set too  Increase deceleration time short, resulting in regenerative  Reduce input voltage to energy flowing back from motor comply with the input Over voltage to the inverter. voltage requirements or ...
Page 322 LED display Description Cause Possible solutions  Motor overheating  The surrounding temperature Motor  The input of PTC of motor is too high. Check the surrounding  overheating (Positive Temperature  The input of PTC (Positive temperature of motor. Coefficient ) exceeds the Temperature Coefficient ) Check the MT and GND...
Page 323 Safety 3 Error Transformer voltage output of Replace the power board  STO terminal 3 error inverter is not stable. Contact with TECO  External Reset Modbus  fault 0 Modbus communication 0x2501 bit External fault (Modbus) communication 0x2501 2= "1"...
Page 324 LED display Description Cause Possible solutions External fault 4 External Fault (Terminal S4) External Check the fault reason  fault 5 External Fault External Fault Input Terminal Reset external fault of  (Terminal S5) digital input External fault 6 External Fault (Terminal S6) Motor Performrotational or...
Page 325 LED display Description Cause Possible solutions  Check if the proportion of  Since proportion of loss pressure FBLSS loss pressure (23-19) is set (23-19) is enabled and over high, correctly. the inverter trips to fault. Thus, PID Feedback Signal Loss ...
Page 326 Table 2 Warning/Self-diagnosis and Corrective actions LED display Description Cause Possible solutions DC bus voltage exceeds  Deceleration time set too short,  Increase deceleration time OV (flash) the OV detection level： resulting in regenerative energy  Reduce input voltage to Over voltage 200V class：410Vdc flowing back from motor to the...
Page 327 LED display Description Cause Possible solutions Inverter thermal Inverter  Check V/f curve. overload protection  Voltage setting V/F mode too overload  Replace inverter with larger tripped. high, resulting in rating. If an inverter overload over-excitation of the motor. occurs 4 times in five ...
Page 328 LED display Description Cause Possible solutions bb4 (flash) External External base block baseblock (Terminal S4) bb5 (flash) External baseblock External base block (Terminal S5) bb6 (flash) External External base block baseblock (Terminal S6) EF9 ( flash ) error of Forward run and reverse forward/reve run are active within 0.5 Forward run and reverse run...
Page 329 LED display Description Cause Possible solutions V/f curve  V/F curve setting error. error 01-02(Fmax) > 01-12 (Fbase) V/f curve setting error. Check V/F parameters > 01-06 (Fmid1) 01-08(Fmin) 01-16(Fmax2) > 01-24(Fbase2) > 01-20(Fmid1) > 01-22(Fmin2) PID selection  10-00 and10-01 set to 1(AI1) or error set to 2(AI2) ...
Page 330 LED display Description Cause Possible solutions EF5 ( flash ) External fault (Terminal External fault S5) Active when 03-04= (S5) 25, and Inverter external fault selection 08-24=2. EF6 ( flash ) External fault External fault (Terminal (S6) S6) Active when 03-05= 25, and Inverter external fault selection 08-24=2.
Page 331 LED display Description Cause Possible solutions EEPROM  Restore factory setting, Save Error  EEPROM circuit failure then cut off the power and The data save in EEPROM  Parameter check error after power on again. is wrong. power on ...
Page 332 Warning Message (LCD display only) LCD display Description Cause Possible solutions Operator Copy Error Inverter data transmission Parameters can not Check operator and error, can not upload the upload to operator control connection data to operator  The control mode in the Operator Write operator does not match Error...
Page 333: General Troubleshooting
5.2 General Troubleshooting Status Checking point Remedy Is the wiring for the output Wiring must match U, V, and W terminals of the Motor runs in terminals correct? motor. wrong Is the wiring for forward and direction Check for correct wiring. reverse signals correct? Is the wiring for the analog Check for correct wiring.
Page 334: Troubleshooting Of The Inverter
5.3 Troubleshooting of the Inverter 5.3.1 Quick troubleshooting of inverter INV Fault Is fault known? Symptoms other than burn Any Symptoms of burn Check burnt and out, damage, or fuse out and damage? damaged parts meltdown in the inverter? Is the main circuit DM Fault signal? Consult with the supplier intact?
Page 335 From previous page Check Inverter parameters Perform parameter initializations Specify operation control mode Does the FWD or REV Replace the control LED light flash? board Set up frequency command Is the frequency value Replace the control displayed on the display? board Are there voltage outputs at Replace the control...
Page 336: Troubleshooting For Oc、Ol Error Display
5.3.2 Troubleshooting for OC、OL error display The inverter displays OC, OL errors Is the main circuit I.G.B.T Replace I.G.B.T working Replace faulty circuit Any visual abnormalities? board Apply power Is the current detector Replace the current Any abnormal indications? controller Input operation command Replace control board Is FWD LED illuminated?
Page 337: Troubleshooting For Ov、Lv Error Display
5.3.3 Troubleshooting for OV, LV error display The inverter displays OV, LV Is the main circuit fuse intact? Consult with the supplier Any visual abnormalities? Consult with the supplier Apply power Any abnormal indications? Consult with the supplier Input operation command Is FWD LED still illuminated after flash Consult with the supplier Input frequency commands...
Page 338: Motor Not Running
5.3.4 Motor not running The motor can not run Is MCCB On? Can MCCB be turned On? Short circuited wiring 1.The power is abnormal Are voltages between power terminals correct? 2.Incorrect wiring Is LED lit? INVfault The operation switch is set to 　...
Page 339: Motor Overheating
5.3.5 Motor overheating M o to r O v e rh e a tin g Is lo a d o r c u rre n t e x c e e d in g C o n s id e r re d u c in g th e lo a d a n d in c re a s in g Y E S th e s p e c ifie d v a lu e ? th e c a p a c itie s o f th e in v e rte r a n d m o to r...
Page 340: Motor Runs Unbalanced
5.3.6 Motor runs unbalanced Motor runs unbalanced Does it happen Is the acceleration Increase the Acc/ Dec time during eceleration? time correct? Reduce the load.Increase capacities of INV and the motor. Are the output voltages between U-V,V-W,W-U INV faults balanced? Reduce the load fluctuation Is the load fluctuating? or add a flywheel.
Page 341: Auto-Tuning Error
5.3.7 Auto-tuning Error When a fault occurs during auto-tuning of a standard AC motor, the display will show the “AtErr” fault and the motor stops. The fault information is displayed in parameter 17-11. Refer to Table 10.4.1, for fault information during tuning, cause and corrective action. Table 3 Auto-tuning fault and corrective actions Error Description...
Page 342: Routine And Periodic Inspection
5.4 Routine and periodic inspection To ensure stable and safe operation, check and maintain the inverter at regular intervals. Use the checklist below to carry out inspection. Disconnect power after approximately 5 minutes to make sure no voltage is present on the output terminals before any inspection or maintenance.
Page 343 Checking period Items Details Methods Criteria Remedies Daily 1Year protrusion Clean Any dust or debris ◎ components No short circuit Power Check resistance or broken component Measure with Consult with between each circuit in ◎ a multi-tester the supplier terminals three-phase output Peripheral device...
Page 344: Maintenance
5.5 Maintenance To ensure long-term reliability, follow the instructions below to perform regular inspection. Turn the power off and wait for a minimum of 5 minutes before inspection to avoid potential shock hazard from the charge stored in high-capacity capacitors. 1.
Page 345: Chapter 6 Peripherals Components
Chapter 6 Peripherals Components 6.1 Reactor specifications Specification Model：E510-□ □ □ -SXXX Current (A) Current (A) 19.0 25.0 0.71 0.53 33.0 0.35 42.0 0.265 0.18 0.13 0.13 0.09 0.07 Specification Model：E510-□ □ □ -SXXX Current Current 17.0 1.42 23.0 1.06 31.0 0.53 0.42...
Page 346: Electromagnetic Contactor Circuit Breaker
6.2 Electromagnetic contactor circuit breaker Molded-case circuit Magnetic contactor (MC) Model：E510-□ □ □ -SXXX breaker made by TECO made by TECO TO-50E 15A 201/202 TO-50E 20A CN-11 203/205 TO-50E 30A TO-50E 50A CN-18 TO-100E 60A CN-25 TO-100E 100A CN-50 TO-100E 100A...
Page 347: Fuse Specification
6.3 Fuse specification Model：E510-□ □ □ -SXXX Fuse Types 2P5/201 15A, 300VAC 202/203/205 30A, 300VAC 208/210 60A, 300VAC 215/220 100A, 300VAC 200A, 300VAC 250A, 300VAC 300A, 300VAC 5 A, 600VAC 10A, 600VAC 15A, 600VAC 20A, 600VAC 408/410 40A, 600VAC 415/420 70A, 600VAC 100A, 600VAC 120A, 600VAC...
Page 348: Fuse Specification(Ul Model Recommended)
6.4 Fuse specification (UL model recommended) Model Manufacture Type Rating E510-2P5/201-SH1(F) Bussmann 20CT 690V 20A E510-202-SH1(F) Bussmann 30FE 690V 30A E510-203-SH1(F) Bussmann 50FE 690V 50A E510-2P5/201-SH3 Bussmann 20CT 690V 20A E510-202-SH3 Bussmann 20CT 690V 20A E510-203-SH3 Bussmann 30FE 690V 30A E510-205-SH3 Bussmann 50FE...
Page 349: Brake Resistor
6.5 Brake resistor Braking Dimension of Braking Minimum Model Specifications of Braking Resistor Unit Braking Resistor Torque Resistance Number of Braking (LxWxH) HP KW Model (Ω ) (Ω ) Resistor 150W/200Ω 0.5 0.4 JNBR-150W200 1000 (251x28x60) 150W/200Ω 0.75 JNBR-150W100 1000 220V (251x28x60) 150W/100Ω...
Page 350: Input Noise Filter
Braking Dimension of Braking Minimum Model Specifications of Braking Resistor Unit Braking Resistor Torque Resistance Number of Braking (LxWxH) HP KW Model (Ω ) (Ω ) Resistor 1500W/40Ω JNBR-1R5KW40 1500 3000 (615x60x110) 1200W/32Ω 25 18.5 JNBR-4R8KW32 4800 4800 (535x60x110) 1200W/27.2Ω JNBR-4R8KW27R2 4800 27.2 4800...
Page 351: Accessories
6.7 Accessories Accessories Instruction Model Note JN5-CM-01M JN5-CM-02M Connection Operator extension cable JN5-CM-03M cable JN5-CM-05M RJ45 to USB connecting cable JN5-CM-USB 1.8m Profibus communication card JN5-CMI-PDP Integrated TCP-IP communication card JN5-CMI-TCPIP communication DeviceNet communication card JN5-CMI-DNET card CANopen communication card JN5-CMI-CAN JN5-NK-SE01 For Frame 1...
Page 352 (2) NEMA1 option Inverter can reach NEMA1 protection level when NEMA1 options installed.  Name Model Note JN5-NK-SE01 For frame 1 models JN5-NK-SE02 For frame 2 models NEMA1 options JN5-NK-SE03 For frame 3 models JN5-NK-SE04 For frame 4 models *Frame 5/6 models already built-in NEMA1 design (3) Copy unit (JN5-CU) Parameters can be copied from one inverter to other inverters.
Page 353 Installation dimensions of copy unit  (4) LCD Operator (JN5-OP-A02) Installation dimensions of LCD keypad display (5) Keypad holder (JN5-KEYBOX) Remote keypad can be installed more easily by this option. ...
Page 354 Installation dimensions of keypad holder  (6) Integrated communication card (a) PROFIBUS communication card For wiring example and communication setup refer to JN5-CMI-PDP communication option manual. (b) DEVICENET communication card For wiring example and communication setup refer to JN5-CMI-DNET communication option manual. 6-10...
Page 355 (c) CANOPEN communication card For wiring example and communication setup refer to JN5-CMI-CAN communication option manual. (d) TCP-IP communication card For wiring example and communication setup refer to JN5-CMI-TCPIP communication option manual. (7) RJ45 to USB connecting cable (1.8m) JN5-CM-USB has the function of converting USB communication format to RS485 to achieve the ...
Page 356: Safety Precautions
Appendix 1 Instructions for UL Appendix 1 Instructions for UL Safety Precautions  DANGER Electrical Shock Hazard Do not connect or disconnect wiring while the power is on. Failure to comply will result in death or serious injury. WARNING Electrical Shock Hazard Do not operate equipment with covers removed.
Page 357 Failure to comply could result in damage to the drive and will void warranty. Teco is not responsible for any modification of the product made by the user. This product must not be modified. Check all the wiring to ensure that all connections are correct after installing the drive and connecting any other devices.
Page 358: Ul Standards Compliance
UL approval requires crimp terminals when wiring the drive’s main circuit terminals. Use crimping tools as specified by the crimp terminal manufacturer. Teco recommends crimp terminals made by NICHIFU for the insulation cap. The table below matches drives models with crimp terminals and insulation caps. Orders can be placed with a Teco representative or directly with the Teco sales department.
Page 359 Appendix 1 Instructions for UL Closed-Loop Crimp Terminal Size Drive Model Wire Gauge mm2 (AWG) Terminal Crimp Terminal Tool Insulation 11-301(series) R/L1, S/L2, T/L3 U/T1, V/T2, W,T3 Screws Model No. Machine No. Model No. 11-301-21-2P5-30 2 (14) M3.5 R2-3.5 Nichifu NH 1/9 TIC 2...
Page 360 Appendix 1 Instructions for UL Recommended Input Fuse Selection Fuse Type Drive Model Manufacturer: Bussmann / Ferraz Shawmut 11-201/11-301 Model Fuse Ampere Rating 11-201-20-2P5-00 Bussmann 20CT 690V / 20A 11-201-20-201-00 Bussmann 20CT 690V / 20A 11-201-20-202-00 Bussmann 32FE 690V / 32A 11-201-20-203-00 Bussmann 50FE...
Page 361 Appendix 2 E510s Parameter Data Customer Model Application Phone No. Address Parameter Value Parameter Value Parameter Value Group 0 Group 1 Group 2 0 – 00 1 – 00 2 – 00 0 – 01 1 – 01 2 – 01 0 –...
Page 362 Parameter Value Parameter Value Parameter Value Group 3 Group 4 Group 5 3 – 00 4 – 00 5 – 00 3 – 01 4 – 01 5 – 01 3 – 02 4 – 02 5 – 02 3 – 03 4 –...
Page 363 Parameter Value Parameter Value Parameter Value Group 5 Group 6 Group 6 5 – 33 6 – 00 6 – 41 5 – 34 6 – 01 6 – 42 5 – 35 6 – 02 6 – 43 5 – 36 6 –...
Page 364 Parameter Value Parameter Value Parameter Value Group 7 Group 8 Group 9 7 – 00 8 – 00 9 – 00 7 – 01 8 – 01 9 – 01 7 – 02 8 – 02 9 – 02 7 – 03 8 –...
Page 365 Parameter Value Parameter Value Parameter Value Group 7 Group 8 Group 9 8 – 47 8 – 48 8 – 49 8 - 50 8 - 51 8 – 52 8 – 53 8 – 54 8 – 55 8 – 56 8 –...
Page 366 Parameter Value Parameter Value Parameter Value Group 10 Group 11 Group 11 10 – 00 11 – 00 11 – 46 10 – 01 11 – 01 11 – 47 10 – 02 11 – 02 11 – 48 10 – 03 11 –...
Page 367 Parameter Value Parameter Value Parameter Value Group 12 Group 13 Group 14 12 – 00 13 – 00 14 – 00 12 – 01 13 – 01 14 – 01 12 – 02 13 – 02 14 – 02 12 – 03 13 –...
Page 368 Parameter Value Parameter Value Parameter Value Group 15 Group 16 Group 17 15 – 00 16 – 00 17 – 00 15 – 01 16 – 01 17 – 01 15 – 02 16 – 02 17 – 02 15 – 03 16 –...
Page 369 Parameter Value Parameter Value Parameter Value Group 18 Group 20 Group 21 18 – 00 20 – 00 21 – 00 18 – 01 20 – 01 21 – 01 18 – 02 20 – 02 21 – 02 18 – 03 20 –...
Page 370 Parameter Value Parameter Value Parameter Value Group 23 Group 22 23 – 00 22 – 00 23 – 01 22 – 01 23 – 02 22 – 02 23 – 03 22 – 03 23 – 04 22 – 04 23 –...
Page 371 Appendix 3 Modbus Protocol Description Communication Connection and Data Frame The inverter can communicate with a PC or PLC via RS485 or RS232 using the Modbus RTU or Modbus ACSII protocol. The maximum frame length is 80 bytes. Network Connection Slave E510s Slave E510s Slave E510s...
Page 372 Data Format Frame FOR ASCII MODE STX(3AH) Start Bit = 3AH Address Hi Communication Address(Station): Address Lo 2-digit ASCII Code Function Hi Function Code (command): Function Lo 2-digit ASCII Code Command Start Address Command Start Address Command Start byte: Command Start Address 4-digit ASCII Code Command Start Address Data length...
Page 373: Function Code
 Function Code 03H：Read the register contents 06H：Write a WORD to register 08H：Loop test 10H：Write several data to register (complex number register write)  Checksum Calculation ex. ADDRESS FUNCTION COMMAND DATA LENGTH ------------------------------------------ 0FH------------2’s complement Checksum = CS(H) 46H (ASCII) CS(L) 31H (ASCII) CRC Check：...
Page 374: Error Code
 CRC calculate program UWORD ch_sum ( UBYTE long , UBYTE *rxdbuff ) { BYTE i = 0; UWORD wkg = 0xFFFF; while ( long-- ) { wkg ^= rxdbuff++; for ( i = 0 ; i < 8; i++ ) { if ( wkg &...
Page 375  Register and Data Format Command Data (Read/Write) Register No. Content 2500H Reserved Operation Command 1 : Run 0 : Stop Reverse Command 1 : Reverse 0 : Forward External Fault 1 : Fault Fault Reset 1 : Reset Reserved Reserved Multi-function Comm S1 1 :“ON”...
Page 376  Monitor Data (Read-only) Register No. Content Operation 1 : Run 0 : Stop Direction 1 : Reverse 0 : Forward Inverter ready 1 : ready 0 : unready Fault 1 : Abnormal Warning 1 :“ON” Zero Speed 1 :“ON” Is440V 1 :“ON”...
Page 377 Register No. Content Reserved STO2 PID Feedback Error STO3 Keypad Removed Reserved TOL(External Overload) STO1 Reserved Reserved Reserved Terminal S1 Terminal S2 Terminal S3 Terminal S4 Terminal S5 Terminal S6 Reserved Reserved 2522H Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Frequency command (0.01Hz) 2523H...
Page 378 Register No. Content Reserved Reserved Reserved Reserved VRYE STP0 Reserved SE01 Reserved Reserved SE02 Reserved STP2 SE03 Reserved RUNER Reserved Reserved LOPb Reserved SE05 HIPb Reserved HPERR Reserved Digital Output State 2529H AO1 (0.00V ~ 10.00V) 252AH Reserved 252BH AI 1 Input (0.1%) 252CH AI 2 Input (0.1%) 252DH...
Page 379  Read Holding Register [03H] Read consecutive holding registers. The address of the first holding register is specified in the protocol Example: Read frequency command from the inverter with node address 1. ASCII Mode Command Message Response Message (Normal) Response Message (Error) Node Node Node Address...
Page 380  Loop back test [08H] Check the communication between the master and the follower (inverter). The data used can be arbitrary. ASCII Mode Command Message Response Message (Normal) Response Message (Error) Node Node Node Address Address Address Function Function Function Exception code Test Code...
Page 381  Write Single Holding Register [06H] Write single holding register. The register address of the holding register is specified in the message. Example: Write a 60.00Hz frequency command to node address 1. ASCII Mode Command Message esponse Message (Normal) Response Message (Error) Node Node Node...
Page 382  Write Multiple Holding Register [10H] Write multiple holding registers. The address of the first holding register is specified in the message. Example: Write a 60.00Hz frequency command to node address 1 and enable FWD run command. ASCII Mode Command Message Response Message (Normal) Response Message (Error) Node...
Page 383 RTU Mode Command Message Response Message (Normal) Response Message (Error) Node Address 01 H Node Address Node Address Function Function Function Exception High High Exception code Starting Starting code Register Register High CRC-16 Number of High Number of High Registers Registers Number of DATA High...
Page 384 Parameter Data Function Register No Function Register No Function Register No Group 0 Group 1 Group 2 0 – 00 0000H 1 – 00 0100H 2 – 00 0200H 0 – 01 0001H 1 – 01 0101H 2 – 01 0201H 0 –...
Page 385 Function Register No Function Register No Function Register No Group 3 Group 4 Group 5 3 – 00 0300H 4 – 00 0400H 5 – 00 0500H 3 – 01 0301H 4 – 01 0401H 5 – 01 0501H 3 – 02 0302H 4 –...
Page 386 Function Register No Function Register No Function Register No Group 5 Group 6 Group 6 5 – 48 0530H 6 – 00 0600H 6 – 41 0629H 6 – 01 0601H 6 – 42 062AH 6 – 02 0602H 6 – 43 062BH 6 –...
Page 387 Function Register No Function Register No Function Register No Group 7 Group 8 Group 9 7 – 00 0700H 8 – 00 0800H 9 – 00 0900H 7 – 01 0701H 8 – 01 0801H 9 – 01 0901H 7 – 02 0702H 8 –...
Page 388 Function Register No Function Register No Function Register No Group 7 Group 8 Group 9 8 – 42 082AH 8 – 43 082BH 8 – 44 082CH 8 – 45 8 – 46 8 – 47 8 – 48 0830H 8 –...
Page 389 Function Register No Function Register No Function Register No Group 10 Group 11 Group 11 10 – 19 0A13H 11 – 19 0B13H 11 – 65 0B41H 10 – 20 0A14H 11 – 20 0B14H 11 – 66 0B42H 10 – 21 0A15H 11 –...
Page 390 Function Register No Function Register No Function Register No Group 12 Group 13 Group 14 12 – 04 0C04H 13 – 04 0D04H 14 – 04 0E04H 12 – 05 0C05H 13 – 05 0D05H 14 – 05 0E05H 12 – 06 0C06H 13 –...
Page 391 Function Register No Function Register No Function Register No Group 12 Group 13 Group 14 12 – 82 0C52H 14 - 46 0E2EH 12 - 83 0C53H 14 - 47 0E2FH Function Register No Function Register No Function Register No Group 15 Group 16 Group 17...
Page 392 Function Register No Function Register No Function Register No Group 18 Group 20 Group 21 18 – 00 1200H 20 – 00 1400H 21 – 00 1500H 18 – 01 1201H 20 – 01 1401H 21 – 01 1501H 18 – 02 1202H 20 –...
Page 393 Function Register No Function Register No Group 22 Group 23 22 – 00 1600H 23 – 00 1700H 22 – 01 1601H 23 – 01 1701H 22 – 02 1602H 23 – 02 1702H 22 – 03 1603H 23 – 03 1703H 22 –...
Page 394 BACnet Specifications Description Inverter E510s model is built-in standard BACnet MS/TP communication protocol structure to meet the demand of automatic communication equipment. Control or monitor E510s via BACnet to be allowable to read and modify specific parameter. E510s includes the following supports of standard objects： Inverter Objects Analog Output Analog Value...
Page 395 Analog Analog Analog Digital Digital Digital Inverter Proerty Input Output Value Input Output Value (DEV) (AI) (AO) (AV) (BI) (BO) (BV) Polarity Inactive_Text Active_Text BACnet Object Properties： This section provides the predetermined configuration of the inverter. User can achieve the optimizazed situation at any necessary modification.
Page 396 Object Name Description Unit Classification Range Motor R-HP Motor rated power horsepower Motor R-RPM Motor rated rotation speed No Units AI10 Motor R-Hz Motor rated frequency AI11 CarrierFreq Carrier frequency KiloHertz 4-16 AI12 Comm Station INV communication station No Units 1-254 AI13 BaudRate...
Page 397 Table 5 Analog value property list (Read/Write) Object Name Description Unit Classification Range PID-P Gain Proportional gain (P) No Units 0-10 PID-I Time Integral time (I) No Units 0-100 PID-D Time Differential time (D) No Units 0-10 Table 6 Digital input property list (Read) Object Name Description Unit...
Page 398 Appendix 4 PLC Communication Protocol E510s PLC MEMORY MAP Ladder Code(0-20 Line) A000h~A063h 50words Ladder Code(21-40 Line) A064h~A0C7h 50words Ladder Code(41-60 Line) A0C8h~A12Bh 50words Ladder Code(61-80 Line) A12Ch~A18Fh 50words Timer Code A200h~A24Fh 40words Counter Code A250h~A28Fh 32words Analog Code A290h~A2BFh 24words Operation control instruction A2C0h~A31Fh...
Page 399 PLC Operation Instruction RUN&STOP A600h Clear all memory A601h Cipher Address AA01h Protection Status AA03h Ladder Component Arrangement Mode X1-X12：Contact Component Y1-Y4：Coil Component V1-V12：Vertical Line AP 4-2...
Page 400 Code in the EEPROM/RAM Arrangement A. Ladder Part (L：Low byte / H：High byte) Page Address Location Code A000h A001h A002h A003h A004h A005h A006h A007h A008h A009h A00Ah A00Bh A00Ch A00Dh A00Eh A00Fh V1~V4 A010h V5~V8 A011h V9~V12 V12 V11 V10 A012h Reserved A013h...
Page 401 Page Address Location Page Address Location A014h A028h A015h A029h A016h A02Ah A017h A02Bh A018h A02Ch A019h A02Dh A01Ah A02Eh A01Bh A02Fh A01Ch A030h A01Dh A031h A01Fh A032h A020h A033h A021h A034h A021h A035h A022h A036h A023h A037h A024h V1~V4 A038h V1~V4 A025h...
Page 402 Page Address Location Code A064h ( Byte ) A065h ( Byte ) A066h ( Byte ) A067h ( Byte ) A068h ( Byte ) A069h ( Byte ) A06Ah ( Byte ) A06Bh ( Byte ) A06Ch ( Byte ) A06Dh ( Byte ) A06Eh...
Page 403 Page Location Page Location Address Address A078h A08Ch A079h A08Dh A07Ah A08Eh A07Bh A08Fh A07Ch A090h A07Dh A091h A07Eh A092h A07Fh A093h A080h A094h A081h A095h A082h A096h A083h A097h A084h A098h A085h A099h A086h A09Ah A087h A09Bh V1~V4 V1~V4 A088h A09Ch V5~V8...
Page 404 Page Start Address Length（word） A0C8h 10 WORD A0DCh 10 WORD A0F0h 10 WORD A0104h 10 WORD A0118h 10 WORD A012Ch 10 WORD A0140h 10 WORD A0154h 10 WORD A0168h 10 WORD A017Ch 10 WORD AP 4-7...
Page 405 B. FUNCTION BLOCK 1. Timer (10Byte)----- A200h~A24Fh (8 groups) Mode7 set value data types flag P2 A371h Timer1 A200h~A209h A228h~A231h Timer5 Timer2 A20Ah~A213h A232h~A23Bh Timer6 Timer3 A214h~A21Dh A23Ch~A245h Timer7 Timer4 A21Eh~A227h A246h~A24Fh Timer8 2. Counter (8Byte)----- A250h~A28Fh (8 groups) Counter1 A250h~A257h Counter5 A270h~A277h...
Page 406 4. Operation Control Instruction (12Byte)----- A260h~A28Fh (8 groups) Control1 A2C0h~A2CBh Control5 A2F0h~A2FBh Control2 A2CCh~A2D7h Control6 A2FCh~A307h Control3 A2D8h~A2E3h Control7 A308h~A313h Control4 A2E4h~A2EFh Control8 A314h~A31Fh 5. Add-Subtract (10bytes)-----A320h~A347h (4 groups) Add-Subtract1 A320h~A329h Add-Subtract2 A32Ah~A333h Add-Subtract3 A334h~A33Dh Add-Subtract4 A33Eh~A347h 6. Multiply-Divide (10bytes)----- A2A4h~A2B7h (4 groups) Multiply-Divide1 A348h~A351h Multiply-Divide2...
Page 407 Appendix 5 JN5-CM-USB Instruction 1. Model & Specification 1.1 Instruction JN5-CM-USB has the function of converting USB communication format to RS485 to achieve the inverter communication control being similar with PC or other control equipment with USB port. 1.2 Exterior(Unit：mm) 1.3 Connecting ...
Page 408 2. USB interface cable pin definition 2.1 RS232/USB interface USB interface, connects with PC or other USB interface devices 2.2 RS485/RJ45 interface 2.3 RS485/RJ45 pin definition Pin No., Define Note： A/B phase signal (pin1&pin2) is differential mode data signal of RS485. VCC&GND is the +5Vdc power supply provided by inverter internal power source.
Page 409 Appendix 6：Accessories Accessories Model Description Note JN5-CB-01M 1 meter JN5-CB-02M 2 meters IP20 Digital operator extension cable Cables JN5-CB-03M 3 meters JN5-CB-05M 5 meters JN5-CM-USB RJ45 to USB connecting cable 1.8 meters Mechanical device consisting of anti-dust cover JN5-NK-SE01 Frame 1 on the upper part and wiring box on the JN5-NK-SE02 Frame 2...
Page 410 INVERTER 11-301 series Safety stop function instruction manual CONTENTS 1. General description ..................1 2. Installation and wiring ................2 3. Example of safety system configuration ..........5 4. Test and checking failure ................7 5. Safety parameters of 11-301 ..............8...
Page 411 CAUTION The information of this manual is merely a guide for proper installation. TECO Electric Co. cannot assume responsibility for the compliance or the noncompliance to any code, national, local or otherwise for the proper installation of this equipment. A hazard of personal injury and/or equipment damage exists if codes are ignored during installation.
Page 412 Introduction This document describes the main design specification of the E510s Safe Torque Off ( STO ) and the requirements for its installation and integration within safety related applications. The correct Installation and integration of the E510s STO is the responsibility of the Installer and it is expected that the installer follows the safety guide and is a trained technician and experienced in the design of safety systems.
Page 413 3. Product Information 3.1 Product models & range 230V single Phase. IP 20 0.40 ~ 2.2KW. (3hp)  400V three phase. IP20 0.75 ~ 55 KW. (75hp)  Power Voltage Current Model Horsepower Specification (Volt) 0.5/1 200V~240V Frame1 380V~480V...
Page 414 3.3 Model Identification A B – CDE – F – G – HIJ – K - L A：Product F：Standard voltage H-J：Horse Power 1： Inverter 1： 100-120V 0P5： 0.5HP 2： SERVO 2： 200-240V 001： 3： 4： 380-480V 075：...
Page 415 STO Activated IGBT outputs are shut down Electromechanical. Without STO function No SIL. Stop Category 0 Motor Speed Coasts to zero Fig 1. Safe torque Off Stop Category 0 to EN60204-1 Caution Function by itself The STO is not an Emergency Stop and may be used as part of an ...
Page 416: Control Terminals
Electromechanical. Without STO function SIL 2. Stop Category 0 Integrated STO FUNCTION SIL 2. Stop Category 0 6. Terminal designation & interface 6.1 Power & Control terminals. Frame 1. Terminal layout is shown as a typical example. ...
Page 417 6.2 Control terminals & wiring R2A R2B R1A R1B R1C 24V AI1 S(+) S(-) SF2 COM AGND Safety Terminals. SF1 / SF2 & SG (Common). Remove the jumper link for external interface Terminal Description Rating Symbol Safety Input 1 &...
Page 418 Safety Input logic & Status TECO 11-301 safety stop function prevents a drive from supplying rotational energy to motors. Dual safety channels “S1” and “S2” cut off the gate-drive power for IGBT to turn off. Diagram below shows the basic block diagram design of the safety and interface for the safety inputs.
Page 419: Installation And Wiring
CAUTION The following information is merely a guide for proper installation. TECO Electric & Machinery Co. cannot assume responsibility for the compliance or the noncompliance to any code, national, local or otherwise for the proper installation of this equipment. A hazard of personal injury and/or equipment damage exists if codes are ignored during installation.
Page 420 CAUTION In order to meet safety stop, an approved safety relay unit to ISO13849-1 safety category 3. In addition, all other components with in the safety stop loop shall be ‘safety approved’ types. WARNING To avoid an electric shock hazard, insert the magnetic contactor (MC) between power source and drive.
Page 421 Safety Input Status Table below shows the logic level status for external safety interface, internal circuit and drive output. Table.3 Truth table of Safety related signals External Safety Internal safety circuit Drive Output +24VDC Safety Input Status logic Status Motor...
Page 422 Diagnostic Safety stop function protection mechanisms： Safety stop terminal (S1-S2-SC)contact short wire, Disable safety stop mode, Motor running； 1. When S1-SC open and S2-SC short, at this time, protection signal will cut off driver unit enable pin, IGBT none PWM signal, motor free run; 2.
Page 423 Safety design and specifications of 11-301 STO design main requirements Safety Function Requirement Specification SIL2 Initiating devices User connected sensor or other safety devices Hazard Rotation of the motor (To be derived from hazard assessment) Consequence Human harm or damage to machinery.
Page 424 REVISIONS Date Manual Number Revision May 2017 4KA72X645T01 First edition ...

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