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E510 Table of Contents

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1. 510 3 510 4 Control Panel 7 RESET ENTER lt gt RUN RS485 7
2. _ 20 T 5 W 1 1 2 H i 4 LIT 224 6 8 84 207 8 15 350 1 13 78 355 1 13 98 Dimensions 200 5 7 9 3 53 187 5 7 38 Tim 192 5 7 58 E 86 3 89 Unit mm inch N W 174 6 85 6 0 24 3 7 2 IP66 NEMA 4X dimensions Frame 1 IP66 NEMA 4X Single Three phase 200V 0 5 1HP Single phase 200V 0 5 1HP Three phase 200V 2HP 400V 1 2HP Unit mm inch Dimensions E510 402 H3FN4S 3 54 Frame 2 IP66 NEMA Single Three phase 200 2 3HP Single phase 200 2 3HP Three phase 20
3. 0 100Hz 0 200Hz 0 50Hz 10V AI2 AGND Ratio A 10V AI2 AGND Ratio B 10V 2 AGND Ratio C gt Y Master Parameter Preset 00 12 100 00 12 200 00 12 50 04 16 1 04 16 1 04 16 1 Frequency B 200Hz upper limit Hz 100Hz Je x C 5Hz Analog Input Signal amp g Master gt m 4 52 05 00 Preset Speed Control mode Selection Range 0 Common Accel Decel 1 Individual Accel Decel for each preset speed 0 15 05 01 Preset Speed 0 Keypad Freq 05 02 Preset Speed 1 05 03 Preset 0 05 4 PresetSpeedS 1 1 0 05 05 5 0 05 06 __ J J 9 Preset Speed 8 Preset Speed 9 Preset Speed 10 Preset Speed 11 Preset Speed 12 Preset Speed 13 Preset Speed 14 Preset Speed 15 0 00 650 00 Hz Preset Speed 0 Acceleration time Preset Speed 0 Deceleration time Preset Speed 1 Acceleration time Preset Speed 1 Deceleration time Preset Speed 2 Acceleration time Preset Speed 2 Deceleration time Preset Speed 3 Acceleration time Preset Speed 3 Deceleration time Preset Speed 4 Acceleration time Preset Speed 4 Deceleration time Preset Speed 5 Acceleration
4. 3 42 3 6 2 Control circuit terminal description Terminal function Signal level Forward Stop Preset Multi function input terminal Reverse Stop Preset Multi function input terminal 24 VDC 8 mA Optical Preset 0 5 02 function terminal coupling signal Preset Speed1 5 03 Multi function input terminal Input impedance 3 3kO Preset Speed2 5 05 Multi function input terminal I P S6 Fault reset input Multi function input terminal NO 2 Multi function output Run Fault setting open Frequency Frequency Reached Auto Restart Momentary AC Power 55 NI Stop Block Stop Motor Overload Relay COMMON Protection Drive Overload iut Protection Over torque Threshold Level PME Preset Current level Reached Preset Brake Frequency Reached PID Feedback Signal Loss Final count value reached Initial count value recahed PLC Status Indicator PLC control mv ital signal common terminal JP1 Switching NPN 24VPower mv DOS 9 15 Max output current supply t COM Digital signal common terminal 1 Digital signal common terminal JP1 Switching PNP position Digital signal common terminal JP1 Switching PNP position position LS Built in Power for an external sp
5. 3 41 2 Single phase 200V 2 3HP 12 13 P BR T2 73 Single Three phase 200V 2 3HP Three phase 200V 5 400V 3 5HP L1 L 12 L3N P BR T1 T2 T3 Frame3 amp Frame4 Three phase 200V 7 5 20HP 400V 7 5 25HP L1 L2 L3 P 1 2 3 x m
6. Ground terminal 3 33 3 4 Specifications 3 4 1 Product Specifications 200V Class Single phase Model E510 coo H1F N4 S Horse power HP Suitable motor capacity KW 04 075 15 22 _ Rated output current A 3 4 45 75 405 _______ KVA 12 47 290 400 10 15 notom f 8s 12 16 239 _ Inverter net weight 1 65 1 65 momentary power esime S 20 24 20 2 0 _____1 jJ C 2 Frame Size 200V Class Single Three phase Model E510 oo0 H N4R 275 201 202 203 05 1 2 3 Suitable motor capacity KW 04 075 15 22 Ratedouputcuret 31 45 75 105 _______ 12 17 290 400 Input voltage range V Single Three Phase 200 240V 50 60HZ 10 15 Inverter net weight KG 16 16 25 25 Allowable momentary power loss time S 20 20 20 20 _____1 2 Frame Size 200VClass Three phase 202 T 205 T zos T zro us T 220 2 5 75 10 15 Ratedouputcuren A 7 5 17 5 26 35 48 64 29 204 274 Input voltage range V Three phase 200 240V 50 60HZ Allowable voltage fluctuation 10 15 Output v
7. D2 Unit mm inch N W 510 420 224 6 207 207 435 8 303 5 330 9 187 5 192 5 64 2 5 510 425 8 84 8 15 8 15 17 16 11 95 13 03 7 9 7 38 7 58 2 53 7 58 0 4 0 2n 137 7 3 49 Frame1 NEMA1 Single Three phase 200V 0 5 1HP Single 200V 0 5 1HP Three phase 200V 2HP 400V 1 2HP RE E E RESI E E T gt Unit mm inch Dimension
8. a 2 1 L m OM E W m w EE E lt r A EE VN lt Unit mm inch H2 mE 215 H3 E510 220 H3 2246 207 207 321 6 303 5 330 9 200 5 E510 420 H3 8 84 8 15 8 15 12 66 11 95 13 03 7 9 SS 425 H3 3 48 4 1 20 With Filter Three phase 400 20 25 1 III
9. N Front view Side view Side by side Installation Provide the necessary physical space and cooling based on the ambient temperature and the heat loss in the panel Extract fan CONTROL PANEL 5cm Note C 5 represets Fan 3 20 3 2 3 De rating Curves Curves below show the applicable output current de rate due to setting of carrier frequency and the ambient operating temperatures of 40 and 50 degrees 1 2 3 4 Single phase 200V 0 5 Single Three phase 200V 0 5 Three phase 200V 2 20HP 400V 1 25HP Rating Current In 100 SSE 90 N 70 60 50 2 4 6 8 10 12 14 16 Carrier Frequency KHz Note e De rate curve for ambient temperature of 40 degree e em 9 curve for ambient temperature of 50 degree C 3 21
10. Switch Fuse L1 L Power 912 input source Braking resistor d Main Switch Fuse witc L1 L T1 Power Inverter Induction AC 553 12 input output 2 Motor source 7 L L3 N Ground 1 Data 2 Data CON2 3 Data 4 RXDO 0 FWD RS485 5 TXDO o 6 1 Run Stop 6 Data D 0 9 52 Pin 1 to Pin 8 7 5V REV 510 8 GND R1A 5 Speed Control ds m Relay J 250 Output 0 2AV PNP R2A E Relay J 9 9 9 250 SF Output Disable Pod SG NPN Al2 E 10 Jo 0 710 o AM P 31 t Frequency Frequency indicator device E Er E 1 AO Indicator or PID input 1 0 MAE GND A 0 10VDC F 0 AGND E E i Indicates shield wire P Indicates twisted pair shield wire Shows main circuit o Shows control circuit 1 JP1 NPN PNP selection JP2 Al1 0710V 0 20mA selection JP3 AI2 0 10V 0 20mA selection Model 200V E510 2P5 H N4R E510 201 H N4R E510 202 H N4R E510 203 H N4R 3 39 3 5 3 Braking resistor
11. Option Switch Fuse b T1 Power Inverter Induction AC Power L2 input output 2 Motor source Ground 1 Datat 2 Data CON2 4 RXDO FWD 85485 5 TXD0 5 o 51 Run Stop 6 Data 5 S2 Pin 1 to Pin 8 7 5V REV Run Stop o 9 8 GND 88 R1A Speed Control 5 ds gt Relay J 250 VACHA Output 30VDC 1A 5 56 R1C 9 1 24 RIA E Relay 0 0 250 Output R2B 30VDC 1A 597 4 io SF Output Disable SG NPN Al2 10 O 0 710V AM P P 4l AO Frequency indicator device er NEA E Indicator m or PID input AGND i 07 10VDC P 1 pos 9 1 Indicates shield wire Indicates twisted pair shield wire Shows main circuit Shows control circuit 1 JP1 NPN PNP selection JP2 Al1 0710 0720 selection JP3 AI2 0710 0720 selection Model 200V E510 202 H3 N4 E510 205 H3 N4 E510 208 H3 N4 E510 210 H3 N4 E510 215 H3 N4 E510 220 H3 N4 400V E510 401 H3 F N4 S E510 402 H3 F N4 S E510 403 H3 F N4 S E510 405 H3 F N4 S E510 408 H3 F N4 S E510 410 H3 F N4 S
12. 60Hz Frequency 30Hz f7 30Hz 04 03 04 03 Bias Bias 0 0 2 0 OHz 2V 5V 10V V 50 ee 50 xim 100 ae 100 4 49 3 Offset bias set to 0 04 03 and effect of modifying Analog Gain 04 02 Bias type 04 04 and slope type 04 05 are shown in shown Fig 5 amp 6 Figures Figure6 opem pe pem pem oe oco oen Km m fo elem om m ox om ww Hz T Hz pper 60Hz Frequency 60Hz TORNO e 30Hz 30Hz 5V 10V V OV 5V 10V V 4 Various other examples of analog input scaling and modification are shown in following figures 7 8 9 amp 10 Figure om eo e e Figures occ oc el sm am i amon 04 03 Hz bias png Hz 0 las Frequency 100 60Hz 37 5Hz NEU 37 5Hz NO 0 50 30Hz 50 30Hz 0 2 0 2 gt 5V 10V V OV 5V 10V V Figure9 Figure10 wm aon al om om i nf awe ow o 3 Hz Upper Hz A 60Hz 4 Frequency 60 2 sa 04 03 18 26HZ gt 04 03 bias bias 0 0 1 81Hz 1V4V 10 4 sy 40V V 50 XE 50 100 100 4 50 04 11 Analog Output AO Function
13. ir e E jan III i gt i 2 Unit mm inch Dimensions N W Kg 3 57 3 19 3 19 6 44 6 02 5 87 5 55 1 89 0 17 0 17 3 45 2 1 20 Single Three phase 200 2 3HP Single phase 200 2 3HP Three phase 200V 5HP 400V 3 5HP S ee 1 09 JN W M ii 1 S VS eee inui 1 Unit
14. Parameters 00 05 00 06 4 03 06 03 07 10 2 Acc Dec Times 11 Disable Acc Dec 12 Alternative Run Source Select Parameters 00 02 00 03 13 Main Alternative Frequency Command Select Parameters 00 05 00 06 14 Rapid Stop controlled deceleration stop 15 Base Block Coast to stop Range 16 Disable PID Function Parameter Goup10 17 Reset 18 Enable Auto Run Parameter Goup6 19 Speed Search 20 Energy Saving V F 21 Reset PID integral value to Zero 22 Counter Input 23 Counter Reset 24 PLC Input 25 Pulse Input Width Measure S3 26 Pulse Input Frequenct Measure S3 27 Enable KEB Function 28 Fire mode function Valid for software issued after rev 1 1 Set up examples and descriptions for Parameters 03 00 to 03 05 are noted in the following pages sections 1 to 13 1 For setting parameters 03 00 03 05 to 0 1 External Run Stop Control refer to 00 04 1A 2 wire method Mode 1 Example FWD STOP and REV STOP from two inputs 51852 Set 00 04 0 1 03 002 0 FWD STOP S2 03 012 1 REV STOP 4 34 e 51 FWD STOP f 7 e 4 S2 REVISTOP COM E510 Hz FWD B gt T REV St ON OFF S2 OFF ON Note If both forward and reverse commands are it will be treated as
15. Unit mm inch Dimensions w w w 510 210 3 RO 408 H3 RARO 410 H3 186 9 176 175 260 9 249 8 273 197 415 3 7 36 6 92 6 89 10 27 9 83 10 75 7 76 EE 408 eee 410 H3F ee 415 H3F 3 47 2 az 4 5 4 5 0 18 0 18 gt gt O1 O1 4 1 20 Three phase 200 15 20 400 20 25
16. 1440 199 M4 oo 19 M4 ww 1442 1994 M49 wm 43 19 M44 wa 4 190 M4 145 199 M46 ora 190 M4 was ore 148 14 1909 19 149 159 102 149 ss o 1 App 2 2 08 12 08 16 11 08 11 13 14 14 14 18 11 17 14 22 MEN 221 L u w D a na EN EN o UNE m oe on me o W x waw 27721 qum m mmi NEN m HET EN MED p EE a E NEN content code content code 150 ___ 1929 l 7 1507 1519 ___ 1581 090 52 1522 3828 o 3612 152 3613 45 04 1400 3814 1526 15 15 15 27 1516 158 0 2 3 Appendix 3 E510 MODBUS Communication protocol 1 Communication Data Frame E510series inverter can be controlled by a PC or other controller with the Communication protocol Modbus ASCII Mode amp Mode RTU RS485 or RS232 Frame length maximum 80 bytes 1 1 Hardware installation Slave E510 Slave E510 Slave E510 Slave E510 Station 01 Stat
17. 3 5 3 15 29 185 0 3 NINININI gt gt gt 2 3 Chapter 3 Environment amp 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 NEMA 4X Depending on models Suitable Environment IP20 NEMA 1 type 10 50 inside distributor without dustproof cover paster Operating 10 40 C outside distributor with dustproof cover paster temperature IP66 NEMA 4X type 10 50 C If several inverters are installed in the same control panel ensure adequate spacing and provide the necessary cooling and ventilation for successful operation Storage 20 60 temperature Relative 95 without condensation Humidity Notice prevention of inverter freezing up Compliance with IEC 60068 2 78 Shock 1G 9 8m s for 20Hz and below 0 6G 5 88m s from 20Hz to 50Hz Compliance with IEC 60068 2 6 Installation site Install in an environment that will not have an adverse effect on the operation of the unit and ensure that there is no exposure to areas such as that listed below Direct sunlight Rain or moisture Cil mist and salt Dust lint fibbers small metal filings and Corrosive
18. LED FWD FWD FWD FWD FWD FWD FWD Y REV LED REV REV REV REV REV 4 7 4 2 Programmable Parameter Groups Group 08 Drive and Motor Protection Group 12 Digital Display amp Monitor Functions Group 13 Inspection amp Maintenance Functions Group 14 PLC Setting Function Group 15 PLC Monitoring Function 4 8 Factory D t R Description 0000 Setting 00 00 Control Mode Selection 1 Vector Mode Reserved Source Selection 2 Communication 3 PLC 1 External Run Stop Control O Forward Stop Reverse Stop 1 Run Stop Reverse Forward 2 3 Wire Control Mode Run Stop 0 UP DOWM of Keypad 1 Potentiometer on Keypad 2 External Al1 Analog Signal Input Main Frequency Command 3 External Al2 Analog Signal Input 6 0 1 External Run Stop Control Alternative Run Command Source Selection Operation Modes for 00 04 External Terminals Source Selection 4 External Up Down Frequency Control 5 Communication Setting Frequency 6 PID Ouput Frequency 7 Pulse Input 0 UP DOWM of Keypad 1 Potentiometer on Keypad 2 External Al1 Analog Signal Input Alternative Frequency 3 External Al2 Analog Signal Input 4 6 00 06 Command Source Selection 4 External Up Down Frequency Control 5 Communication Setting Frequency 6 PID Ouput Frequency OuputF
19. 01 03 _ Maximum Frequency Voltage Ratio ___01 04 Medium Frequency 00 01 05 Medium Frequency Voltage Ratio 2 00 01 6 Medium Frequency CC Range 0 0 100 0 01 09 Minimum Frequency Voltage Ratio 0000 0 0 100 0 gt Max output frequency depends on parameter 01 00 for 01 00 18 It can be set by parameter 01 02 gt For 01 00 18 the maximum output frequency will depending on parameter 00 12 frequency upper limit 4 31 01 03 01 05 Vmid2 01 07 Vmid1 01 09 1 01 08 01 06 01 04 01 02 650 00 2 01 10 Volts Hz Curve Modification Torque Boost 0 10 0 gt Inverter output V F curve settings for points can be adjusted by parameter 01 10 to improve the output torque gt Calculation of B C point voltage B point voltage Xb x maximum output voltage C point voltage Xc maximum output voltage Xb Xc see P4 30 When 01 10 0 the torque improvement is disabled V 1 2 5 3 0 50 60 Hz 01417 Start Frequency 0 00 10 00 Hz Slip Compensation Gain Range 0 05 10 00 s 0143 Mode Select Hane 0 Close Loop 9 11 Open Loop 4 32 02 00 __ Motor No Load Current 0 Patameter 02 01 0 1 Motor Rated Current 02 01 0 2 100 Motor Rated Slip Compensation 0 0 200 0
20. 14 05 Setting Value1 of T3 mode 7 O9999 __ _ Value1 of 4 mode 7 ees Jo 1449 Setting of T5 14 40 SetingValuetofT 10 9999 __ _ 14 11 Setting of T6 mode7 090999 L 14 12 SetingValuetof T7 10 9999 Setting Value1 of T7 mode 7 0 999 1444 SettingValuetofT8 10 9999 1445 Setting Value1 of T8 mode7 14 46 SettingValuetofC1 10 65535 14 17 SettingValuetofC2_ 05 6895 14 18 Setting Valet of C3 10 65535 14 19 Setting Value1 of C4 10 65535 0 1420 SetingValuetofC 10 65535 o 1 1 1421 Setting Valuet of C6 10 65535 1422 SettingValuetofC7 10 65535 1423 Setting fos Jo 4 24 Setting Valuet of AS o o 1425 _ Setting Value2 of AS1 10 65535 14 26 Setting Values 0486 setting Value1 of AS2 0 65535 Luz Seting 06 o 14 29 Setting of AS2 568 _ 14 30 Setting Value1 of AS3 10 65535 1431 Setting of AS3 06868 Jo 1 1 14 32 Setting Value3 of AS3 10 65535 14 33 Setting Value1 10 65535 Jo 14 34 Set ngValue2ofAS4 10 65535 Sett
21. 2 Step2 Remove terminal cover Step3 Wire amp Re install the cover Step4 Tighten the screws 3 12 c Three phase 200 7 5 10HP 400V 7 5 15 Frame 3 lt Step3 Wirie amp Re install the cover Step4 Tighten the screws 3 13 Frame 3 NEMA1 Lt 1 4 2 2 34 0 7 Uil IATE MEA Step3 Wirie amp Re install the cover Step2 Remove the terminal cover Step4 Tighten the screws 3 14 d Three phase 200V 15 20HP 400 20 25 Frame 4 4 22 E 24 EI ERST SLOTS gt f A i 2 Step1 Loosen screws Step2 Remove the terminal cover Step3 Wirie amp Re install the cover Step4 Tighten the screws 3 15 Frame 4 NEMA1 Step3 Wirie amp Re install the cover Step4 Tighten the screws 3 16 Three phase 400 20 25HP Frame 4 With Filter Step1 Loosen the screws 87 Step3 Wirie amp Re install the cover Step4 Tighten the screws 3 17 gt IP66 NEMA 4X Disassembly steps A i i 1 4 apa eon eee aa Step 1 Loosen the cover screws place the cover on the left side of the machine without removing i B
22. 06 32 ___ Auto_RunModeRunningDirectionO 06 33 _ Auto_RunModeRunningDirectiont 06 34 Auto_RunModeRunningDirection2 06 35 Mode Running Directions 0 06 36 RunModeRunningDirectiond 4 56 06 39 Auto_RunModeRunningDirection 06 41 Mode Running Direction 06 42 Running 0 06 43 RunModeRunningDirectioni 06 45 _ Auto_RunModeRunningDirectiont3 O 0 STOP 1 Forward 2 Reverse gt Auto Run sequencer mode has to be enabled by using one of the multifunctional inputs 51 to 56 and setting the relevant parameter 03 00 to 03 04 to selection 18 gt Various Auto Run sequencer modes can be selected by parameter 06 00 as listed above gt 15Auto Run sequencer modes can be selected by parameters 06 01 06 39 gt Auto Run frequency commands1 to 15 set with Parameters 06 01 06 07 gt gt gt Sequence run times are set with parameters 06 17 06 23 FWD REV Direction for each sequence can be set with parameters 06 33 06 39 Auto sequence 0 frequency is set from keypad by parameter 05 01 sequence run time and direction are set by parameters 06 16 and 06 32 Auto RUN Auto Sequencer examples are shown in the following pages Example 1 Single Cycle 06 00 1 4 The inverter will run for a single full cycle based on the specified number of sequences then it
23. 1548 Current Value of C3 0655 1549 Current Value of C4 0655 15 20 Current Value of C5 0655 1521 Current Value of C6 06535 15 22 CurrentValueofC7 0655 065535 Jo 15 24 CurrentValueofAS1 0655 15 25 CurentValueofAS2 _ 65585 15 26 CurentValueofAS3 0655 15 27 Current Value of 54 0 65535 0 15 28 Current Value of MD1 0655 15 20 Current Value of MD2 1 65585 065535 Jo 00535 Jo 06555 o 4 26 4 3 Parameter Function Description 0 V F Mode 1 Vector Mode To select the appropriate vector or V F control mode according to the load characteristics gt f V F mode is selected please set parameters group1 to comply with the load features gt Vector is best suited to control the general load or rapidly changed torque load 00 02 _ Command Source Selection 0 Keypad 1 External Run Stop Control 2 Communication 3 PLC gt Parameter 00 02 sets the inverter operation command source For switching between 00 02 and 00 03 use any of the external inputs S1 to S6 and set relavent parameters 03 00 03 05 to 12 Refer to parameter group3 for details Note 00 027 3 RUN key Enable the built in PLC run operation STOP key Enable the built in PLC stop operation 00 03 _ Alternative Run Command So
24. 02 03 Motor Rated Speed 0 39000 When load causes the actual motor speed to be reduced below the speed set by inverter output frequency Slip parameter 02 02 Slip compensation can be used correct the speed Output Current 02 00 02 01 02 00 Motor Motor synchronization speed Motor Rated Speed Slip compensation boost x 02 02 xRate motor slip Motor synchronization speed Rated speed 02 02 imate Value Japproximate Value Motor synchronization speed Motor synchronization speed Marked on the motor nameplate 120 Motor synchronization speed RPM Motor Poles xMotor rate frequency 50 60Hz 120 Example 4 poles 60Hz induction motor synchronization speed 1 x 60 1800 RPM Note 02 00 02 01 differs with the inverter capacities 13 00 It should be regulated according to actual conditions 02 04 Motor Rated Voltage 200 170 0 264 0 400V 323 0 528 0 02 05 Motor Rated Power 0 1 37 0 02 06 Motor Rated Frequency 0 650 0 02 07 Motor Pole Number 2 16 Auto Tune 02 14 AutoTune 1 Enable 02 15 Stator Resistance Gain Rang 02 16 RotorResistance Gain Ra 4 33 gt In vector mode selected by parameter 00 00 1 motor name plate data parameters 02 01 02 03 02 06 then activate the out auto tune function by setting paramet
25. INSTRUCTION MANUAL INVERTER 200V Class 0 4 15KW 0 5 20HP 400V Class 0 75 18 5KW 1 25HP TEC INVERTER E510 Series 0 0 1 Chapter 1 1 1 1 2 1 3 1 4 1 5 Chapter 2 2 1 2 2 2 3 Chapter 3 3 1 3 2 3 3 3 4 3 5 3 6 3 7 3 8 3 9 E510 Table of Contents Preface Preface Safety Precautions Before Power UP During Power UP Before Operation During Operation Inverter Disposal Part Number Definition Nameplate Data Model Part Number Standard Product Specification Environment amp Installation Environment Installation 3 2 1 Installation method 3 2 2 Installation space 3 2 3 De rating curves Wiring guidelines 3 3 1 Power Cables 3 3 2 Control Cable selection and Wiring 3 3 3 Wiring and EMC guidelines 3 3 4 Failure liability 3 3 5 Considerations for peripheral equipment 3 3 6 Ground connection 3 3 7 Inverter exterior Specifications 3 4 1 Product Specifications 3 4 2 General Specifications Standard wiring 3 5 1 Single phase 3 5 2 Single Three phase 3 5 3 Three phase Terminal Description 3 6 1 Description of main circuit terminals 3 6 2 Control circuit terminal description Outline Dimensions 3 7 1 IP20 NEMA1 dimensions 3 7 2 IP66 NEMA4 dimensions EMC filter disconnection The Dimension and Installation of Keypad 0 1 0 1 1 1 1 1 1 2 1 2 1 2 1 3 2 1 2 1 2 1 2 2 3 1 3 1 3 3 3 3 3 20 3 21 3 22 3 22 3 22 3 23 3 2
26. gt 70 Reserved eserved Over voltage at constant speed OC C Over current during accelerating OC A 3 3 Co EPR1 2 Inverter over speed OVSP Sequence input status 0 Terminais 1 04 ______ 4 Terminal 52 1 0 2 Terminal 53 1 ON 0 3 Terminal o4 1 ON 0 4 Terminal 55 1 0 5 56 1 ON 0 OFF Contact output Relay R1 1 ON 0 OFF Relay R2 1 ON 0 OFF F Reserved 6 2523 frequency command 100 1Hz Output frequency 100 1Hz 2525H Output voltage command 10 1V DC voltage command 1 1V Output current 10 1A Temperature Output torque PID feedback 100 fmax 10 1 PID input 10096 fmax 10 196 2 AVI input value 1000 10V 1 TM2 ACI input value 1000 10V 1 252bH 252FH reserved App3 7 4 3Read the data in the holding register 03H Master unit reads the contents of the holding register with the continuous number for the specified quantity 1 Limit number of read data 37 ASCII 17 2 Can only Continuous read the address of the same Group 3 Read data Quantity21 Example Read the SLAVE station No 01 E510 drive 5 frequency command ASCII Mode Instruction Message Response Message Normal Response Fault holding register 3 LRC CHECK END OAH NN
27. lt Left Shift used while changing the parameters or parameter Values RESET Use to Reset alarms or resettable faults Digital display amp LEDs LED Status lt RESET Dual function keys 4 1 4 1 2 Digital display Description Alpha numerical display format A 4 2 LED display examples Display 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 PID feedback Value Error display Analogue Current Voltage AI2 Range 0 1000 LED Status description LED Indicator light status Frequency Line speed Indicator Hz RPM ON while displaying frequency or linear speed ON while not Flashing while Menu mode indicator FUN displaying frequency fire mode or line speed enabled Flashing while FWD indicator ON while running stopped in FWD forward Forward mode Flashing while REV indicator ON while running stopped in REV reverse Reverse mode 4 3 4 1 3 Digital display set On power up digital display screens will be as shown below DSP FUN 2 2sec later T 2200 C 500 07207 Power supply frequency parameter User selectable display formats 0 High Low Each of the above 5 digits can be set to any of the selections below from 0 to 8 0 Disable display 1 output Current 2 output Voltage 3 D
28. 0 _ _ _ _ Input under the Function B Program Mode 5 The RESULT of MD1 Note if the RESULT is more P 24 7777 than 65535 Here can only display 65535 similarly if gt the RESULT less than lower limit of 0 5014 _ 4 ee ek Meca it 1 Ee cir Mr WM Multiplier value of V1 WORD _ 1 MDI Multiplier value of V2 654 7 ee ta oe io gt Multiplier value of 45 23 2 ae ae ame e s s Instruction code DIV module 1 4 4 88 Chapter 5 Troubleshooting and Maintenance 5 1 Error display and corrective action 5 1 1 Manual Reset and Auto Reset Faults which can not be recovered manually content Cause Corrective action Voltage too high when stopped Detection circuit malfunction Consult with the supplier 1 Check if the power voltage is correct 2 Replace the pre charge resistor or the fuse 3 Return the inverter The inverter is 1 Detection circuit malfunction Improve the ventilation overheated when 2 Ambient temperature too conditions if no result then stopped high or bad ventilation replace the inverter Voltage too low 2 Pre charge resistor or fuse when stopped burnt out 3 Detection circuit malfunction Display O OV _ 1 Power voltage too low OH 2 EEPROM problem
29. Setting Freq 1 03 13 gt 03 13 03 14 Setting Freq 2 2 Preset Freq Reached Detection Range 03 14 RUN RUN RUN RUN Command N ON Relay Output gt ON 5 03 117 4 will be on as soon as the output frequency gt preset frequency reached Setting 03 13 4 43 When Output Frequency gt Preset Frequency Reached Setting 03 13 i Relay output will be ON Setting Freq 03 13 Output Freq 0 Time Output Freq 03 13 gt N p Setting Freq x RUN Run Command ON ON Relay Output 6 03 1172 5 RY will be on as soon as the output frequency lt Preset Frequency Reached Setting 03 13 When Output Freq Preset Freq Reached Setting 03 13 Relay output will Setting Freq 03 13 gt Output Freq 0 gt Output Freq Time 03 13 Freq RUN Command gt Relay Output ON ON ON 7 03 11 03 12 20 Zero Speed Out Frequency gt Minimum Frequency 01 08 Fmin On Out Frequency Minimum Frequency 01 08 Fmin Out Frequency 01 08 Fmin t Zero Speed 03 15 Preset output cu
30. 3 13 6 Auto Restart 7 Momentary AC Power Loss 8 Rapid Stop 9 Base Block 10 Motor Overload Protection OL1 Output Relay RY2 11 Drive Overload Protection OL2 1 Terminals 2 R2C 12 Over torque Threshold Level OL3 13 Preset Output Current Reached 03 15 16 14 Brake Control ON 03 17 18 15 PID Feedback Signal Loss 16 Final count value reached 3 22 23 17 Initial count value reached 3 22 23 18 PLC Status Indicator 00 02 19 PLC control 20 Zero Speed wa m Q OO 3 13 Frequency Reached Level 0 00 650 00 00 Frequency Reached Detection 0 00 30 00 2 00 Range Preset output current reached 0 1 15 0 Preset output Current detection 0 1 10 0 delay Time Brake Release 0 00 20 00 level Brake Engage 0 00 20 00 Level Normally open Relay Output function type 1 Normally close Internal external multi function input terminal selection Action to set the internal multi function input terminals Final preset Count reached 0 9999 Initial preset count reached 0 9999 Low Current detection selection 1 Enable 03 25 Low Current Detection Level 5 100 Low Current Detection Delay 03 27 Pulse Frequency 0 01 1 00 03 28 Pulse Frequency Gain 0 01 9 99 1400 indicates normally open NC indicates normally closed gt gt A N P C2 4 12 Factory D ipti R masr Analog Input S
31. Frame3 NEMA1 Three phase 200V 7 5 10HP 400V 7 5 15HP 2 0 510 210 3 186 9 175 291 7 36 6 89 11 47 TORIO 191 Unit mm inch Dimensions a 197 184 189 76 7 170 6 4 5 7 76 7 24 7 44 3 02 6 72 0 17 3 52 2 ms 4 NEMA1 Three phase 200 15 20 400 20 25
32. RY2 PLC are ON 1 2 PLC 42 06 Alarm Selections for Inverter Components Life Expectancy life alarm of inrush current suppression circuit is invalid life alarm of inrush current suppression circuit is valid life alarm of control circuit capacitors is invalid life alarm of control circuit capacitors is valid life alarm of main circuit capacitors is invalid life alarm of main circuit capacitors is valid Example set 12 06 00111 if inrush current suppression circuit or control circuit capacitors or main circuit capacitors is damaged display LIFE1 LIFE2 LIFE3 respectively Alerts the user that inverter needs repair Display of inrush current suppression circuit Range gt Once the inverter power on for 1000 times the counts value of the parameter will be decreased 1 If the counts value less than 30 inverter will display Life1 Display of control circuit capacitors Range gt the inverter operated 80 hours the value of the parameter will be decreased 1 If the counts value less 5 inverter will display Life2 12 11 Output current when Fault appeared Output voltage when fault appeared Output frequency when fault appeared 1214 12 15 Frequency command when fault appeared gt In addition to the main circuit capacitors above the theoretical value of life diagnosis are only for reference DC bus voltage
33. STOP 1B 2 wire method Mode 2 Example RUN STOP and REV FWD from two inputs 51 52 Set 00 04 1 1 03 00 0 RUN STOP S2 03 01 1 REV FWD 4 S1 RUNISTOP e 4 82 REVIFWD COM E510 Hz p T S1 ON 52 1 3 wire method Example Two separate push buttons for RUN amp STOP and two position switch for FWD REV Set 00 04 2 3 wire control mode then terminals S1 S2 and S3 are dedicated to this function and Preset selections for parameters 03 00 03 01 and 03 02 are not relevant 4 35 A T 0 0 1 RUN S2 STOP S3 FWD REV COM E510 Hz FWD gt T REV 1 52 E ON OFF 3 2 03 00 03 05 2 3 4 51 Preset speed selections Combination of any four terminals from 51 56 be used to select preset speeds 0 to 15 according to the table below Preset speed 0 15 and the related acceleration decelerating times should be set in parameter group 5 For example timing diagram refer to Group 5 description Function setting and state of any four A B C D of Preset terminal 51 56 Frequency A 2 B 3 3 4 OFF OF 05 17 OFF OF ON OFF 0503 05 21 s or OF ON 050 05 23 s or ON OFF OFF 05 05 05 25 5s or O
34. 1 0 300 0 Sec gt When direct run on power up is selected by 07 04 0 and the inverter 15 set to external run by 00 02 00 03 1 if the run switch is ON as power is applied the inverter will auto start It is recommend that the power is turned off and the run switch is also off to avoid possibility of injury to operators and damage to machines as the power is reapplied Note IF this mode 1 required all safety measures must be considered including warning labels gt When direct run on power up is disabled by 07 04 1 and if the inverter is set to external run by 00 02 00 03 1 if the run switch is as power is applied the inverter will not auto start and the display will flash with STP1 It will be necessary to turn OFF the run switch and then turn ON again to start normally DC Injection Brake Start Frequency Hz 0 10 10 00 Hz 07 07 DC Injection Brake Level 0 0 150 01 07 08 DC Injection Brake Time Seconds 0 0 25 5 Sec gt 07 08 07 06 set the DC injection brake duration and the brake start frequency as shown below Frequency RUN Command Run Stop 1 Coast to stop gt 07 09 0 After receiving stop command the motor will decelerate to stop according to setting of 00 15 deceleration time 1 gt 07 09 1 After receiving stop command the motor will free run Coast to stop 0 Normal Start 1 Speed Search gt 07 10 0 On starting the inverter
35. 2 xxxfl flow 420 Custom Units Line Speed Display Mode 0 65535 Rpm gt Set motor rated RPM in this parameter if required then the display will show this value when inverter output frequency reaches the motor name plate frequency 50Hz or 60 Hz as appropriate gt line speed display is linearly proportional to the output frequency 0 to 50Hz 0 60 Hz as appropriate Motor synchronous speed 120 x Rated frequency Number of poles 12 04 Custom Units Line Speed Display Mode 1 1 Drive Output Frequency is Displayed Line Speed is Displayed in Integer xxxxx Line Speed is Displayed with One Decimal Place xxxx x Line Speed is Displayed with Two Decimal Places xxx xx Line Speed is Displayed with Three Decimal Places xx xxx gt 12 0440 line speed is displayed while the inverter is running or stopped 4 72 12 05 Inputs and output Logic status display 51 to 56 amp RY1 2 Read only Panel read only gt When any 0151 56 is turned on corresponding segments on the digital display digits will be on gt When relay output RY1 RY2 are on the corresponding digit will be on as shown below Example 1 The following figure shows 12 05 display status when 51 53 55 56 Inputs are ON and 52 54 RY1 and RY2 are OFF 51 5253 5455 56 Example 2 The following figure shows 12 05 display status when 2 53 4 inputs are ON and 1 S5 S 6 are OFF but
36. Bye _ Ca 01 N3 NO N3 NO LU he iie N3 NO N3 NO N3 NO N3 NO Byte N3 NO gt Res Ww v3 0 0 vr ve vs AoSBh 9 2 12 o 0 ____ 4 5 7 X1 8 X1 X3 4 X5 x 6 X7 _____ __ X8 X9 ______ ____ __ 2 Y1 Y Y3 4 V1 V4 045 V9 V12 ____________ _ Address Ah X 14 __ 0 X3 ___ ee A02h X5 Ah 7 __ __ _ __ 7 Lo Xa A056h 1 2 3 4 5 6 1 1 8 9 X10 1 sss ___ 57 ___ 4 Y Y Y A057h A058h V1 V4 ______ ve _ _ 4 6 to AO5An xe 4 7 FUNCTION BLOCK 1 Timer 10Byte A200h A227h 8groups 7 Set value data types P2 _ 0 0 jo jojo 0 0 0 18 17 16 15 14 T3 _ A200h A204h A214h A218h A205h A209h A219h A21Dh A20Ah A20Eh A21Eh A222h A20Fh A213h A223h A227h 2 Counter 8Byte A228h A247h 8groups A228h A22Bh A22Ch A22Fh A230h A233h A234h A237h 3 Analog Compare A248h A25Fh 8groups Analog A248h A24Ah Analog5 A254h A256h Analog2 A24Bh A24Dh A
37. L gt _ 5 EL 4 the attached waterproof cable connector plug and tighten Note Waterproof rubber gasket is placed outside the machine 3 18 Step 3 Pass four wire input and output cable through two bottom cable glands and tighten Connect them in accordance with the internal mark Pass the control line through the top cable gland and tighten And then pass through the control line fixed beam splitter and tighten the control line in accordance with the internal mark Step 4 Reconfirm the internal cable and waterproof cable connector are locked close the cover and tighten it with screws to complete the installation 3 19 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 Single unit Installation Install the inverter verticality to obtain effective cooling CONTROL Fan PANEL ENTER lt READ ass 5 5cm je 1PH 220V 0 75kW DANGER Cut off the power and wait for 5 minutes before inspecting componen 5 CAUTION See manual before operation
38. Preset Speed2 Hz 05 04 Preset Speed3 Hz 05 05 Preset Speed4 Hz 05 06 Preset Speed5 Hz 0 00 650 00 Z 1 05 07 Preset Speed6 Hz 5000 Hz 05 09 Preset Speed8 Hz 000 Hz f 05 10 Preset Speed Hz 000 Hz 7 05 11 Preset Speed10 000 Hz 7 05 12 Preset Speed11 Hz 000 Hz 7 05 13 Preset Speed12 Hz 000 Hz 7 05 14 Preset Speed13 Hz 0 00 Hz 1 05 15 Preset Speed14 _ 000 Hz 05 16 Preset Speed15 Hz 000 Hz 05 18 Preset Speed0 Dectime 05 19 Preset Speedt Acctime 05 20 Preset Speed1 Dectime 05 21 Preset Speed2 Acctime 05 22 Preset Speed2 Dectime 05 23 Preset Speed3 Acctime 05 24 Preset Speed3 Dectime 05 25 Preset Speed4 Acctime 05 26 Preset Speed4 Dectime 05 28 Preset Speed5 Dectime 05 29 Preset Speed6 Acctime 05 31 Preset Speed7 Acctime 5 36 10 0 1 Speed10 Acctime Preset 10 0 1 opeed10 Dectime eo sec PIESEI 10 0 Sec 1 Speed11 Acctime 4 14 3 35 Preset Speed9 Acctime 3 E N Factor No Bang Unt Note uae ws see ot Speed11 Dectime Speed12 Acctime Speed12 Dectime Preset Speed13 Acctime Speed13 Dectime Speed14 Acctime Preset Speed14 Dectime 05 47 Preset Speed15 Acctime 05 48 Preset Speed15
39. RTU Mode Instruction Message Response Message Normal Response Fault SLAVE Address SLAVE Address 03H Function Code Error Code Address H D H holding Quantity register High 16 CRC 16 App3 8 4 4 LOOP BACK testing 08H The function code checks communication between MASTER and SLAVE The instruction message is returned as a response message without being changed Any value can be used for test codes or data ASCII Mode Instruction Message 3AH 30H SLAVE 31H Address 30H Function Code 38H 30H 30H Test Code 30H 30H 41H 35H 33H 31H LRC CHECK 42H Co N RTU Mode Instruction Message SLAVE Address Function Code Test 00H App3 9 Response Message Normal Response Message Normal Response Fault 3AH STX 30H SLAVE 31H Address Function Code LRC CHEC 0 38H 38H 32H 30H 37H 35H DH Response Fault Error Code 47H 4 5 Write holding register 06 Specified data are written into the several specified holding registers from the Specified respectively Example Set SLAVE station No 01 writeE510 drive frequency reference 60 0HZ ASCII Mode Instruction Message Response Message Normal Response Fault Address Address AH OH Function Code OH OH 2H 41H Start Address 31H DATA LRC CHECK END OAH OAH RTU Mode Instruction Message Response Message Normal Respon
40. Setinpvalu2ofMD O K0 65538 05 0 0 0 65535 4 76 gt MD1 MD4 is 4 Multiplication modules of built in PLC 15 00 02 15 01 CurrentvalueofTi mode7 15 02 __ 15 03 Current value of 2 7 15 04 CurrentvalueofTS 15 05 _ CurrentvalueofT3 mode7 15 06 __ CurrentvalueofT4 15 07 15 08 __ CurrentvalueofTS 15 09 CurrentvalueofT5 mode7 15 10 Cumentvalueof TU 15 11 15 12 Cumentvalueof TT 15 13 CumentvalueofTz mode7 0 0 0 0 00 15 14 jCumentvalueof TU 15 15 0 999 2 0 9999 1548 CurrentvalueofC3 15409 CumentvalueofCA 15 20 __ Currentvalue of C5 1521 Current value of C6 1522 CumentvalueofC7 1523 CurrentvalueofCB 0 65535 1524 Cumentvalueof AST 0 1525 CurmentvalueofAS2 1526 Current value of AS 1529 CumentvalueofMD2 0 0 0 0 15 30 CumentvalueofMD3 0 0 00 0 0 1531 Currentvalue of MD4 1532 jCumentvaueofTD 0 0 65535 Note TD 15 32 displays the current value of the current PLC program execution time spent in units of 5 4 77 4 4 Specification Description Built in PLC Function PLC programs can be developed on PC Windows base so
41. output current PID feedback input and output terminal Display status Heat sink temperature Program Version Fault Log LED Status Indicator Run Stop Forward Reverse and etc Protective Overload Protection Overload Protection eye to protect the motor and the inverter 150 1min Functions Over voltage 220V gt 410V 380V gt 820V Under Voltage 220V lt 190V 380V 380V oe et Inverter auto restart after a momentary power loss Loss Restart Stall prevention for Acceleration Deceleration Stall Prevention Operation Electronic Circuit Protection terminal Grounding Fault Electronic Circuit Protection 3 36 Protection for overheating of heat sink The carrier frequency decreasing with the temperature function fault output reverse prohibit prohibit for direct start after power up and error recovery oarameter lock up All frames include brake transistor 2 Standard built in RS485 communication Modbus Communication control One to one or One to many control Other protection features Operating temperature 10 50 1 Storage temperature 20 60 Humidity 95 RH or less no condensation Compliance with IEC 60068 2 78 Shock 20Hz or less 1G 9 8m s 20 50Hz 0 66 5 88m s Compliance with IEC 60068 2 6 Protection class IP20 NEMA1 IP66 NEMA4X Depending on models Environment Note1 IP20 NEMA 1 Type 10 50 C
42. 3 3 Wiring Guidelines 3 3 1 Power Cables Supply power cable must be connected to TM1 terminal block terminals L1 L L2 L3 N L1 L and L3 N for single phase 230V supply Motor cable must be connected to TM1 terminals T1 T2 T3 Warning Connection of supply line cable to terminals T1 T2 will result in serious damage to the drive components Example power connections Inverter with dedicated power line Power eo 4 5 Inverter m gt Install a Supply RFI filter or Isolation transformer when the power source is shared with other high power electrical equipment as shown below MCCB MCCB Power Inverter RO RFI Filter N eo O 3 3 2 Control Cable selection and Wiring Control cables should be connected to terminal block TM2 Choose power amp Control cables according to the following criteria gt Use copper wires with correct diameter and temperature rating of 65 70 C gt Minimum cable voltage rating for 200 type inverters should be 300VAC Minimum cable voltage rating for 400V type inverters should be 600 gt Route all cables away from other high voltage or high current power lines to reduce interference effects gt Use a twisted pair shielded cable and connect the shield screen wire to the ground terminal at the inverter end only Cable length should not exceed 50 meters Shielding sheath Protective covering Connect the shield to Do not connec
43. 3 59 3 9 2 Description of Protective Stickers If the user needs to apply the digital operator to remote control the attached protective stickers can be installed in the position of original operators to prevent unknown objects from attacking Step1 Loosen the four screws between Step 2 Take out the KEYPAD the operator panel and the inverter Step3 Mount the patch on the basis of the diagram whose adhesive surface is towards the position of slots apply the ligulate structure in the center to sticking inwards the bare PCB board which sealed the notch WN Here is the bottom of the slot L Here is the ligulate me i structure w u 1P
44. 600 0 800 0 V Regeneration avoidance voltage detection level if the bus voltage level is set too low then over voltage protection will not be reached but the actual deceleration time will be extended Regeneration Avoidance Frequency Limit 0 00 1500 gt Sets the regeneration avoidance frequency limit 4 71 Regeneration Avoidance Voltage Gain Range 0 200 oo 11 17 Regeneration Avoidance Frequency Gain gt 11 16 11 17 Representative responsiveness of Regeneration avoidance action increase the set value will improve the response to voltage changes on the bus but the output frequency may be unstable gt Set 11 16 as low as possible to reduce output frequency instability if this does not correct the instability then reduce the setting of parameter 11 17 1200 DisplayMode 0 0 MSD LSD 00000 88888 Each digit can be set from 0 to 8 as listed below 0 Disable display frequency amp parameters 1 output Current 2 output Voltage 3 DC voltage 4 Temperature 5 PID feedback 6 AM 7 Al2 81 Count Value gt MSD Most significant digit LSD Least significant digit gt Note MSD of parameter 12 00 sets the power on display other digits set user selected displays 2242 0400 PID Feedback Display format 0 Displayed in Integer xxx 1 One Decimal Place xx x 2 Two Decimal Places x xx 12 02 _ PID Feedback Display Unit Setting 0 xxx 1 xxxpb pressure
45. 8 Up frequency command 2 03 01 9 Down frequency command 03 06 A Hz Mode1 UP or DOWN input terminals are turned on for less than 2 sec for every On operation frequency changes by Hz 4 40 Hz Actual output frequency 1 E pm x 52 Mode 2 If UP or DOWN input terminals are turned for more than 2 sec the UP DOWN mode is restored output frequency ramps up or down as long as the input is kept ON Maximum A output frequency gt 2Sec t1 4 gt lt p lt lt gt gt 25 2 2 OFF S2 OFF ON 03 07 Up Down Keep Frequency Status after Stop Command 0 After a stop command in Up Down mode the preset frequency is held as the inverter stops and the UP Down function is disabled 1 After a stop command in Up Down mod the preset frequency is reset to 0 Hz as the inverter stops 2 After a stop command in Up Down mode the preset frequency is held as the inverter stops and the UP Down function remains enabled gt 03 07 0 Whenrun signal is removed Stop Command the output frequency is stored in parameter 05 01 Key pad Frequency gt 03 07 0 In stop mode since frequency can not be increased or decreased from Up Down terminals then keypad can be used to change the frequency by modifying parameter
46. CS L 31H ASCII App3 2 2 2 CRC CHECK CRC Check Code is calculated from SLAVE Address to end of the data The calculation method is illustrated as follow 1 Load a 16 bit register with FFFF hex all s1 Call this the CRC register 2 Exclusive OR the first 8 bit byte of the message with the low order byte of the 16 bit CRC register putting the result in the CRC register 3 Shift the CRC register one bit to the right toward the LSB Zero filling the MSB Extract and examines the LSB 4 If the LSB was 0 Repeat Steps 3 another shift If the LSB was 1 Exclusive OR the CRC register with the polynomial value 001 hex 1010 0000 0000 0001 putting the result in the CRC register 5 Repeat Steps 3 and 4 until 8 shifts been performed When this is done a complete 8 bit byteWill be processed 6 Repeat Steps 2 through 5 for next 8 bit byte of the message Continue doing this until all bytes have been processed The final content of the CRC register is the CRC value Placing the CRC into the message When the 16 bit CRC 2 8 bit bytes is transmitted in the message the Low order byte will be transmitted first followed by the high order byte For example if the CRC value is 1241 hex the CRC 16 Upper put the 41h the CRC 16 Lower put the 12h CRC calculation application program UWORD ch sum UBYTE long UBYTE BYTE i 0 UWORD wkg while long wkg r
47. define instruction 2 1 USB communication port pin define of pc side I 1 ul lt 2 Inverter can communicate with PC or other devices USB communication port RS485 communication port pin define of inverter side pin 1 pin 8 2 2 RS485 communication port instruction and pin define Nc NO NC voc Note 1 phase signal Pin1 amp Pin2 is differential mode data signal of RS485 2 VCC amp GND is the 5Vdc power supply provided by inverter internal power source 3 Notice 3 1 Please turn off the power before you connect the cable 3 2 Once inverter power off during communication PC software will show communication error 3 3 If there is something wrong during communication please check the wiring connection and restart the pc software 5 2 TECO Electric amp Machinery Ltd 3 1 Yuancyu St Nangang District Taipei City 115 Taiwan Tel 886 2 6615 91 1 1 Fax 886 2 6615 0933 http www teco com tw 04 2013 08 This manual may be modified when necessary because of improvement of the product modification or changes in specifications This manual is subject to change without notice
48. 01 004 18 01 02 50 hz 05 02 10 hz preset speed 05 19 5 s Acc time 05 20 20 s Dec time 05 19 x10 Hz Preset speed 1 Actual Acc time 01 02 1 5 Preset speed 1 Actual Dec time ae 4 s Multi speed run stop cycles with Individual accel decel times 05 00 1 Two modes are shown below 1 On Off run command Mode2 Continuous run command Mode1 Example 00 02 1 External Run Stop Control 00 04 1 Operation Mode Run stop forward reverse 1 03 00 0 RUN STOP 2 03 01 0 Forward Reserve S3 03 02 2 Preset speed 1 S4 03 03 3 Preset speed 2 v v Hz A 05 03 0304 FWD Preset 05 01 speed2 Preset EA speed1 Preset speedo ES E 4 gt 4 gt gt gt 4 gt lt gt C d f RUN _ STOP RUN STOP 2 OFF 3 54 OFF ON When the run command is On Off acceleration and deceleration times for each cycle can be calculated as below time unit is in seconds 4 54 05 17 x 05 01 es 05 18 x 05 01 05 19 x 05 02 05 20 05 02 01 02 01 02 01 02 01 02 gt Mode2 Example Continuous run command gt Set S1 fo
49. 03 28 Hz and the highest value is not more than the upper limit For example if the duty cycle of pulse input is 50 and the upper limit of frequency is 00 12 50Hz then F 50 50 1 25Hz For example if the frequency of pulse input is 25kHz then F 25 1 25kHz Note In this mode the frequency range of pulse input is 0 01 kHz to 10 00 kHz Pulse input can only select 53 and when 53 is the terminal of pulse input PLC output ground need to connect to COM from 2 22 03 00 03 05 27 Enable KEB Function Once the KEB enable input is activated the decelleration time to stop will be according to parameter 07 14 23 03 00 03 05 28 Fire Mode Function With Software revision issued before 1 1 gt The firemode function is enabled when 08 17 1 With Software revision issued after 1 1 gt firemode function works is enabled when 03 00 03 05 28 gt Once fire mode is activated following takes place 1 The operator panel indicates 2 The inverter will run at full soeed up to the maximum of inverter running frequency 3 None protectional functions including ES BB or stop signal sent by operation panel stop key can stop the inverter when entering into firemode usless the main power is lost or cut off or the inverter itself breaks down gt When inverter damage is caused by use of Fire Mode inverter will lose its warranty 03 06 Up Down Frequency Step 0 00 5 001 Hz Example 81 03 00
50. 11 03 Carrier Frequency Reduction by temperature rise 0 Disable 1 Enable gt When inverter heat sink temperature rises above 80 C the Carrier Frequency is reduced by 4K gt When the temperature falls below less than 70 C Carrier Frequency is reset to default gt Temperature can be displayed by setting parameter 12 00 04000 Temperature 80 70 gt 0 2 T Carrier 4 10K m gt 0 t1 t2 T 4 69 11 04 _ S Curve 1 11 05 _ S Curve 2 5 Dec 3 11 06 gt Use Curve parameters where a smooth acceleration or deceleration action is required this will prevent possible damage to driven machines by sudden acceleration deceleration Actual output frequency AY RUN command RUN Note gt Regardless of the stall prevention period actual acceleration and deceleration time preset acceleration deceleration time S curve time Please set the required individual S curve times in the parameters 11 04 11 07 gt When 5 time 11 04 11 07 is set as 0 the S curve function is disabled gt calculation of S curve time is based on the Maximum output frequency of motor 01 02 Please refer to the parameter 00 14 00 15 00 16 00 1 7 11 08 Skip frequency 1 11 09 Skip frequency 2 1140 Skip frequency 3 0 00 650 00 Hz MA
51. 11 03 12 are met relay contact will open Otherwise it will be closed 03 20 Internal External Multi Function Input Terminal Selection 0 gt Parameter 03 20 decides internal external multi function input terminals If the internal multi function input terminal is selected the corresponding contact is set 1 if the external multi function input terminal is selected the corresponding contact is set 0 The definition of bits in 03 20 03 20 0 0 0 0 0 0 0 The external multi function input terminal external control use 56 55 54 53 52 51 1 The internal multi function input terminal Match the status of 03 21setting For example It is required to select the internal multi function input terminal by 2 4 and 6 Parameter 03 21 decides connect or disconnect 1 S3 S5 decides exernal multi function input terminal external control use and then set 03 20 101010 Summing up the inputs 03 20 42 32 8 2 42 on the basis of setting Action to Set the Internal Multi Function Input Terminals Range 0 63 gt The parameter of 03 02 is to determine opening and closing of multi function input terminals The definition of bits in 03 21 03 21 0 0 0 0 0 0 0 The internal multi function input terminals disconnect 56 55 54 53 52 51 1 The internal multi function input terminals connect For example it is required S2 and S4 to connect 51 53 55 56 to disconnect and then set 03 21 001010 Summing up th
52. 13 The minimum time to consider the feedback signal loss is determined 10 14 Integration Limit Value 0 109 gt 10 14 the Limiter to prevent the PID from saturating 4 67 10 15 Integral Value Resets to Zero when Feedback Signal Equals the Target Value 0 Disable 1 After 1 Sec 30 After 30 Sec Range 1 30Sec gt 10 15 0 As PID feedback value reaches the set point the integrator will not be reset to 0 gt 10 15 1 30 As PID feedback value reaches set point reset to 0 1 30 seconds and inverter stops The inverter will run again when the feedback value differs from the set point value Allowable Integration Error Margin Unit 1 Unit 1 8192 Range 0 100 gt 10 16 0 100 unit value Restart the tolerance after the integrator reset to 0 10 17 1020 PID Wake Up Function Delay Time 0 0 25 5 Sec gt When PID output frequency is less than the sleep threshold frequency and exceeds the time of sleep delay the inverter will decelerate to 0 and enters PID sleep mode gt When PID output frequency is larger than the Wake up threshold frequency inverter will enter the PID mode again as shown in the timing diagram below A Hz Wake 10 19 frequency Sleep 10 17 frequency gt PID output frequency Actual output frequency 1021 MaxPIDFeedbackLevel 00 1022 ___ Min PID Feedback Level gt Examp
53. 20 0515H 05 21 0516H 05 22 0518H 05 24 0519H 05 25 051AH 05 26 051BH 05 27 051DH 05 29 051EH 05 30 051FH 05 31 0520H 05 32 0521H 05 33 0522H 05 34 0523H 05 35 0524H 05 36 Register Function _ Register No Function _ Register No Function Group04 _ T T 0526H 05 38 NENNEN 44 44 44 4 4 M Register Function Register Function Register Function MA _ Group07 Group08 07 00 07 01 07 02 07 03 07 04 07 05 07 06 07 07 07 08 07 09 07 10 07 11 07 12 07 13 07 14 45 0640H 066 onn 0624 488 0643H 0639 _ o2 15 Register Function Register Function Register Function Group07 Group08s 0645H 06201 _ NENNEN ____ 0616H 06 22 067 0628 NENNEN 0648H 4 NENNEN 06 25 ostan 0626 _ 06 27 0628 06 29 06 30 S 05 06 32 1 6 33 020 0622 54 06 35 0624M 0636 _ NENNEN 57 06381 59 0640 J o o6 42 J o 06 43 062CH 06 45 06 46 s 062FH 06 47 16 Register Function Register No Function Register No Function 0900H 09 00 10 00 11 00 0902 09 02 OA02H 10 02 2 11 02 11 03 11 04 11 05 11 07 11 08 ____
54. Bit Current state Timer Bit Last state Counter Bit Current state Last state Ladder Component Arrangement mode X1 X12 Contact Component Y1 Y4 Component V1 V12 Vertical line Xl X5 X9 Y V1 V5 V9 X2 X6 X10 Y2 V2 V6 V10 X3 X7 X11 Y3 V7 4 X8 X12 4 V4 V8 V12 App4 2 Code the EEPROM RAM Arrangement A Ladder Part Note byte H High byte Code C1 x 3 C2 C1 N1 L N1 CO N1 C2 lt CO N1 L C3 CO _____ L 3 2 Co CO 2 CO Y2 L C2 C1 L v2 Vi V10 ________ reserve L 4 3 Page Page Address AO0Ah App4 4 Address A014h A01Dh V9 V12 reseve _ A028h A029h A02Ah A02Bh _ A02Fh V1 V4 A031h V9 V12 reseve 2 3 4 5 6 7 8 9 1 4 Y Y Y Y nosh oo w 6 C3 C2 C1 __ KByte C2 Ct Byte X5 Byte C2 Ct 2 6 Byte Ao35bh X7 Byte C2 0 ss e 6302 A036h X9 C2
55. CPU Illegal External noise Interrupt Abnormal fluctuations in the Input phase Loss circuit voltage Low current detection Input current Low current detection level Occurrence of lacking phase at Inverter output side Output phase loss 1 Set a longer deceleration time 2 Add a brake resistor or brake module 3 Add a reactor at the power input side If it often occurs please Consult with the supplier 1 Check the main circuit power supply wiring 2 Check the power supply voltage Set the level according to the actual situation 1 Check Output cables wiring is disconnected or the connection error occurred 2 Determine resistance between the lines 3 Check whether the terminals are loose Faults which can be recovered manually but not automatically OC Overcurent C Ol Detection circuit malfunction Consult with the supplier during stop Display content Cause Corrective action _ O 1 Consider increasing Motor overload Motor capacity loading too large Consider increasing the inverter capacity Inverter overload Excessive Load 1 Increase the inverter capacity 2 Set 8 15 8 16 as needed 1 Load too large 2 the setting of 8 15 8 16 too small Over torque 1 Power voltage too low 2 Power voltage varies widely fluctuates 1 power quality 2 Consider adding a reactor at the power input side 1 Load may b
56. Circuit Capacitors is Invalid xx xx Life Alarm of Main Circuit Capacitors is Valid 8 Input Count value 4 23 er Factory D R No mm Unt Note 42 07 Detect Main Circuit Reserved Capacitors Display of Inrush Current 0 100 100 Suppression Circuit Display of Control Circuit 0 400 Capacitors Reserved Output Current when A Fault Appeared Output Voltage when wae Fault Appeared Output Frequency when Hz Fault Appeared DC Bus Voltage when V ac Fault Appeared Frequency Command when Hz Fault Appeared Fault Log Latest 3 Faults Accumulated Inverter 0 23 Operation Time 1 Accumulated Inverter Operation Time 2 Accumulated Inverter 0 Power On time Operation Time Mode 1 Operation time O Enable all Functions 1 Preset Speeds from 05 01 to 05 15 Can t be Changed 2 All Functions be Changed Except for Preset speeds from 05 01 to 05 15 3 Disable All Functions Except 13 06 13 07 Parameter Lock Code 00000 65535 m Reset Drive to Factory 1150 Reset to Factory Setting 50Hz System Parameter Lock Factory D R Setting 1160 Reset Factory Setting 60 Hz System 00000 1112 Reset PLC 4 24 Em Mam 14 00 SettingValuetof sf 9999 14 02 Setting Valuet of T2 0 99 fo ____ 14 03 Setting ValuetofT2 mode7 0 99 1404 SetingValuetofT3 099 _ Jo j
57. E510 415 H3 F N4 S E510 420 H3 F N4 S E510 425 H3 F N4 S 3 40 3 6 Terminal Description 3 6 1 Description of main circuit terminals Terminal symbols 1 Function Description Main power input Single phase L1 L L3 N Single Three phase L1 L L2 L3 N Three phase L1 L2 L3 Braking resistor connection terminal Used in applications when it is required to stop a high inertia load rapidly refer to specifications of the braking resistor 1 Single phase 200V 0 5 1HP L1 L 12 L3 N 12 T3 s p Note the screw on L2 terminal is removed for the single phase input supply models Single Three phase 200V 0 5 1HP Three phase 200V 2HP 400V 1 2HP 12 L3 N 11 T2 T3 7 LES ER er S lt M Z Se A
58. Example2 Modifying frequency from keypad run and stop modes Modify frequency in stopping aVVV Vp Power Supply 2sec later Short time press lt RESET once Short time press lt RESET once Short time press lt RESET once Ssec later Modify bit lt hundred 1 gt or long time press READ ENTER once 4 Y Y Y Modify frequency in operating 4 Y Y Y Y Power supply 2sec later 4 Y Y Y Y 9 LJ C P AESA AN f LES n gt e Set frequency display Actual frequency Short time press lt RESET once gt Modify bit lt unit gt Short time press lt RESET once Modify bit lt ten gt Short time press lt RESET once 412 Short time press A once Modify bit lt hundred 1 gt Long time press READ ENTER once Actual frequency Without pressing the button lt ENT After 5 seconds to return Note frequency command setting will be limited to the range set by parameters for lower amp upper frequency 4 6 4 1 5 Operation Control A lt lt gt 4 Stop Actual output frequency TENE A 4 REV FWD Run REV Stop on Y rw
59. Faulty EEPROM Replace EEPROM Communication Communication disruption Check the wiring error Current Sensor Current sensor error or l Consult with the supplier detection error circuit malfunction Faults which be recovered manually and Display content Corrective action 1 Acceleration time too short 1 Set a longer acceleration 2 The capacity of the motor time exceeds the capacity of 2 Replace inverter with one the inverter that has the same rating Short circuit between the as that of the motor motor coil and the case 3 Check the motor Short circuit between 4 Check the wiring motor wiring and ground 5 Consult with the supplier module damaged Over current at acceleration 1 Increase the capacity of Over current at Transient load change the inverter fixed speed 2 Transient power change 2 Install inductor on the power Supply input side Over current at The preset deceleration time is Set a longer deceleration deceleration too short time 1 Short circuit between the motor coil and the case Over current at 2 Short circuit between motor start coil and ground 3 the IGBT module damaged 1 Inspect the motor 2 Inspect the wiring 3 Consult with the supplier 5 1 1 Deceleration time setting too short or excessive load inertia 2 Power voltage varies widely fluctuates Excessive Voltage during operation deceleration
60. Gain a Regeneration Avoidance Frequency Gain 11 14 100 11 17 0 200 100 4 22 1 Factory R e ommon _ me ag men 1 One Decimal Place xx x 00000 88888 Each digit can be set from 0 to 8 as listed below 0 Default Display Frequency and Parameters 1 Output Current Extended Display Mode 2 Output Voltage 00000 1 0 2 Two Decimal Places 3 DC Voltage 1 xxxpb pressure 1 2 xxxfl flow 4 Temperature Custom Units Line Speed 0 65535 1500 1800 Value 5 PID Feedback 0 Drive Output Frequency is Displayed 1 Line Speed Integer Xxxxx 2 Line Speed One Decimal Place Custom Units Line Speed XXXX X 4 Display Mode 3 Line Speed Two Decimal Places XXX XX 4 Line Speed Three Decimal Places XX XXX 6 Analog Signal Input f Inputs and Output Logic Status Display 4 51 56 RY1 and RY2 PID Feedback Display Format PID Feedback Display Unit Setting 7 Analog Signal Input 2 xxxxO Life Alarm of Inrush Current Suppression Circuit is Invalid xxxx1 Life Alarm of Inrush Current Suppression Circuit is Valid xxxOx Life Alarm of Control Circuit Alarm Selections for Inverter Capacitors is Invalid 00000 4 Components Life Expectancy xxx1x Life Alarm of Control Circuit Capacitors is Valid xxOxx Life Alarm of Main
61. JP2 JP3 selection to 2 or 3 external 0 10VDC 2 10VDC analog input to become effective Analog signal 3 44 3 7 Outline Dimensions mm inch 0 04 0 40 0 004 0 40 1 97 0 01 1 97 4 0 01 4 7 87 0 02 7 87 15 75 0 03 3 7 1 IP20 NEMA1 dimensions Frame IP20 Single Three phase 200V 0 5 1HP Single phase 200V 0 5 1HP Three phase 200V 2HP 400V 1 2HP W 2a T TEC
62. LOC 1 Press A or Y while 00 05 00 06 gt 0 or running at preset speed 2 Attempt to modify the Parameter Can not be modified during operation refer to the parameter list 1 00 13 is within the range of 11 08 11 11 or 11 09 11 11 11 10 11 11 2 00 12 00 13 1 Control command sent during communication 2 Attempt to modify the function 09 02 09 05 during communication 1 Wiring error 2 Communication parameter setting error 3 Incorrect communication protocol 1 Attempt to modify the function 13 00 13 08 2 Voltage and current detection circuit is abnormal 5 3 1 Adjust 13 06 2 Adjust 11 00 1 The A or is available for modifying the parameter only when 00 05 00 06 0 2 Modify the parameter in STOP mode Modify 11 08 11 10 or 11 11 Set 00 12 gt 00 13 Issue enable command before communication Set parameters 09 02 09 05 function before communication Check hardware and wiring Check Functions 09 00 09 05 reset is not possible please consult with the supplier 5 1 3 Special conditions Fault Description Zero speed Fail to start directly On power up Keypad Stop Operated when inverter external Control mode External Rapid stop External base PID feedback Auto tuninig error Fire Mode Occurs when preset frequency lt 0 1Hz If the inverter is set for external terminal control mode 00 02 00 03 1 an
63. Model Part Number E510 2 5 1 45 Supply voltage 2 200V Class 4 400V Class Structure 5 IP66 Built in VR Switch IP66 N4R IP66 Built in VR Blank IP20 Horsepower 200V Class EMC Filter F Built in Blank None Power supply 1 Single phase 3 Three phase Specification H Standard Type 2 1 2 3 Standard Product Specification IP20 NEMA 1 Type voltage Vac 510 2 5 1 1 ph 41095 1596 E510 203 H1F 50 60 Hz 10 15 50 60 Hz 200 240V 41096 1596 wm 3ph 380 480V 10 15 V Built in X None 2 2 IP66 NEMA 4X E510 2P5 H1FN4S E510 201 H1FN4S E510 202 H1FN4S E510 203 H1FN4S E510 220 H3N4 V Built in X None Supply voltage Vac 1 ph 1096 1596 50 60Hz 3 ph 200 240V 1096 1596 50 60 2 3 ph 10 15 50 60Hz HOLEN os o4 01 1 I CO 75 3 s 3 20 15 3 pi 075 1 075 1 2 is o 1 2 15 1 3 22 0 2 3 22 2 5 37 2 75 55 01 3 75 55 3 _ _0 75 3 75 3 5 it
64. SettingvaluetofT2 mode7 1404 3 6 14 05 SetingvaluetofT3 mode7 4 06 jSetingvalueofTA 44 09 Setting valuet of T5 mode7 44 10 SetingvauelofT o 14 12 SetingvauelofT7 O j 14 13 SetingvaluelofT7 mode7 OC 14 14 SetingvauelofTB gt 11 1858 TIMER of built in PLC 14 18 SetingvaluelofCS3 O O O O OOS o 7 14 19 Setting valuet of C4 14 20 Settingvaluet of C5 7 14 27 Settingvaluetof C6 7 14 22 Settingvaluet of C7 7 14 22 Settingvaluetof CB _ 5585 __ 0 65535 gt C1 C8 is 8 COUNTER of built in PLC 1424 SetingvauetofAS 14 25 Setingvaue2ofAS 8 O 1426 Setingvaue3ofAS oO 1428 Setingvalu2ofAS2 oO 14 22 Setingvalu3ofAS2 O 1430 SetinpvauefofAS3 O 1431 Setingvaue2ofAS3 O 1432 Setingvaue3ofAS3 O 1433 Setting valuet of ASS 14 34 Setting value2 of ASA 1 35 Setting value3 of AS 10655551 __ 2 0 65535 gt 51 94 is 4 Modified modules of built in PLC 14 36 Setting value1 of MD1 1438 __ Setting value3 of MD1 000000 14 39 j SetingvalueofMD2 14 40 Setingvalu2of MDZ 14 41 jSettingvalueSofMD2 1442 QjSetingvaluel 1443 Setinpvaue2ofMD3 1 oO 14 44 Setinpvalu3ofMD3 O O 1445 Setting valuetofMD4 O 14 46
65. Structure Outlook E510 Frame 1 E510 Frame 2 TE Control Panel 11 T Hz RPM FWD REV FUN FWD ye DSP REV FUN eel E ENTER 41 v n RESET i ENTER FWD DSP REV FUN f 2 STOP 2 ee 510 201 200V 0 75kW t WE 49 49 Gp RZA 87 2 All AIZ 89485 1 J J fas F Fw m x Rif mIG Sc IOV
66. Time Setting 5 s je Running Time Setting 6 s je Running Time Setting 7 aan s je Running Time Setting 8 s je Running Time Setting 9 Auto Run Mode Running Time Setting 0 0 10 2 CD D CD D CD D 2 CD D 4 16 R Description ange Setting Auto_ Run Mode Running Time Setting 0 0 Sec 11 Auto_ Run Mode Running Time Setting 0 0 Sec 12 Auto_ Run Mode Running Time Setting 0 0 Sec 13 Auto_ Run Mode Running Time Setting 0 0 Sec 14 Auto_ Run Mode Time Setting 0 0 Running Direction 0 Running Direction 1 Running Direction 2 Running Direction 3 Running Direction 4 Running Direction 5 Auto_ Run Mode 06 38 0 Running Direction 6 Running Direction 7 1 Forward Running Direction 8 Running Direction 9 Running Direction10 Running Direction 11 Running Direction12 Running Direction13 Running Direction 14 2 Running Direction 15 Frequency of the step 0 is set by parameter 05 01 keypad frequency 06 27 06 28 06 30 06 31 e do o D e e e o 4 17 1 No 8 07 00 Momentary Power Loss 0 Momentary Power Loss and Restart Disable and Restart 1 Power Loss and Restart Enable Time 07 02 Number of Auto Restart 0 10 Attem
67. VR NAR Protection class IP66 with built in VR without power switches N4S Protection class IP66 with built in power switches and 3 35 3 4 2 General Specifications 510 Control Mode V F Control Vector Control Output Frequency 0 01 650 00Hz Speed Control Range Setting resolution Keypad Set directly with A keys or the VR on the Frequency keypad External Input Terminlas 0 2 10 Al2 0 4 20mA input Multifunction input up down Setting frequency by communication method frequency by communication method Lower and upper frequency limits 3 skip settings stop button run stop button External terminals Operation set Multi operation mode2 3 wire selection Jog operation Run signal by communication method V F curve poer fixed curves and one customized curve Carrier Carrier frequency ___ 1 deceleration cone 4 off S curve eer Main Control Features Multifunction Setting Frequency limit 00 Frequency limit 00 5 functions refer to description on group3 Overload Detection 16 preset speeds Auto run Acc Dec Switch 2 Stages Main Alt Main features run Command select Main Alt Frequency Command select PID control torque boost V F start Frequency Fault reset Firemode Display parameter parameter value frequency line speed DC voltage output voltage
68. accelerates from 0 to target frequency in the set time gt 07 10 1 On starting the inverter accelerates to target frequency from the detected speed of motor 07 11 Starting method for auto restart after fault Range 0 Speed Search 1 Normal Start gt 07 11 0 When auto restarting the inverter will detect the rotating speed of the motor The Motor will be controlled to accelerate from the present speed to the target speed gt 07 11 1 The inverter restart from 0 speed to set frequency in acceleration time when auto restart 4 60 07 12 Power loss ride trough time Range gt Power loss ride through allows continued operation after momentary power failure as long as the power has recovered within the set time in parameter 07 12 otherwise Inverter will trip with LVC fault due to power loss gt power recovery the inverter will carry out a speed search function after which the inverter output Frequency is ramped up the running frequency before the power failure Power loss recovery time setting depends on the Inverter rating the range will be from 1 to 2 secs gt When 07 00 0 Power loss ride through is disabled gt When 07 00 1 If the power loss time is less than setting in 07 12 the drive will restart with speed search after 0 5 seconds delay and there is no limits on the number of restarts Caution If there is a long power loss loss time exceeds the set value of parameter 07 12 while power
69. after communication timeout gt Time out detection time 00 0 25 5sec setting 00 0 sec disable time out function 09 08 Error 6 verification time gt When communication error time gt 09 08 setting keypad display shows ERR6 Ende 0 Stop in deceleration time 1 and show COT after communication timeout 9 1 Stop free run mode and show after communication timeout 2 Stop in deceleration time 2 and show COT after communication timeout 09 09 Drive Transmit Delay Time ms This parameter is used to set the converter to receive data from the sending date to the beginning of the time Master ___ Slave Slave ___ Master PLC INV E510 INV E510 PLC PLC Command Inverter response Information information p 3 5 Characters 09 09 set value 4 65 PID block diagram A 152 i Delay device Postive gt P 10 05 gt 10 10 10 03 0 Or stop value limiter Reset Negative gt 10009 gt 1044 P 10 15 gt Y 3 4 Offset 10 03 Wak 10 07 gt 1009 PID Limit PID frequency 00 12 output a 10 03 ee 10 01 I
70. content code content code content 00 00 02 08 04 03 05 27 on f ___ ____ 0m 0o vo 0X v 039 ____ 08 o 03 0o 024 o 03 oo 0245 o 039 on 00 o 03 or s wy 0n 09 09 039 7 015 09 o 04 01 00 09 04 007 06 0 O9 04 90 O0 04 oz n ot 0912 or wow 03 14 05 09 03 15 05 10 content code content code content code content 06 28 06 40 09 04 12 02 14 25 on 00 o 2 090 124 Mm 099 125 ns 044 ow 12 9 os 00 2 9 os 100 128 9 op 3100 149 3 134 99 wo 10 14 9 wap 022 was 145 oa 400 9 was 145 was 19 9 war 190 M4
71. e Terminals Correct requirement Any broken wires 5x9 Wiring Any damage to the wire insulation Voltage Measure the Voltage must Improve input Bi Mu Aui voltage with a conform with voltage if 9 multi tester the spec necessary Circuit boards and components Any contamination or damage to printed Clean circuit circuit board replace the ae Discolored overheated circuit board or burned parts Visual check Correct Any unusual odor or component leakage condition Capacitor Any deformity inventar protrusion Any dust or debris No short Power circuit or component Check resistance Measure with a broken circuit Consult with between each terminals multi tester the supplier three phase output Replace capacitor or Peripheral device Whether something Nose Visual smells stench or check insulator breaks Replacement Whether rheostat wiring rheostat or connector are Visual check damaged No Check contacts and abnormalities Electromagnetic 9 Replacement abnormality Contactor Contactor Unusual vibration and hearing check noise Reactor Is there Replacement abnormalities Reactor Cooling System Consult with the supplier Unusual vibration and Visual or Cocina tar noise hearing check debris Correct cooling Clean up Excessive d
72. if restarted Frequency of the step 0 is set by parameter 05 01 keypad Frequency 06 01 _ 1 _ 2 Auto _ Mode Frequency Command 3 Auto _ Run Mode Frequency Command 4 Auto Mode Frequency Command 5 Auto _ Mode Frequency Command 6 Auto _ Run Mode Frequency Command 7 Auto _ Run Mode Frequency Command 8 Auto Run Mode Frequency Command 9 Auto _ Run Mode Frequency Command 10 Auto _ Run Mode Frequency Command 11 Auto _ Run Mode Frequency Command 12 Auto Run Mode Frequency Command 13 Auto _ Run Mode Frequency Command 14 06 15 Auto Run Mode Frequency Command 15 0 00 650 00 Hz 06 16 Auto_ RunModeRunningTimeSettingo 06 19 Run Running Time Settings 06 20 Mode Running Time Setting4 0 06 21 _ Auto_ Run Mode Running Time Settings 06 22 Run Mode Running Time Settings ________ 06 23 _ Auto_Run Mode Running Time Setting 06 24 _ Auto_ Run Mode Running Time Settings 06 25 _ Auto_ Run Mode Running Time Setting9 ____ 06 26 Run Mode Running Time 0 ________ 06 29 _ Auto Run Mode Running TimeSettingl3 06 30 Auto_ Run Mode Running Time 06 31 Auto Run Mode Running Time Setting45 0 00 3600 01 0 00 3600 0
73. in mode gt When 00 10 0 the initial frequency will be current frequency gt When 00 10 1 initial frequency will be 0 gt When 00 10 2 initial frequency will be as set by parameter 00 11 00412 Frequency Upper ___ 0 01 65000 Hz Range 0 01 650 00 Hz 0043 Frequency Lower limit 0 00 649 99 Hz When 00 13 and the command frequency are both set to 0 00 if RUN is pressed Stpo is displayed When Frequency command is higher than preset in 00 13 inverter output will ramp up from 0 00 to the command frequency gt When 00 13 0 and the frequency command value lt 00 13 inverter output will ramp up from preset in lower limit to the command frequency Hz a Frequency Upper Limit Frequency Lower limit 4 28 004400 Acceleration Time 1 0 1 3600 0 5 00 15 Deceleration Time 1 Range 0 1 3600 0 s Acceleration Time 2 0 1 3600 0 s 00 17 Deceleration Time 2 0 1 3600 0 s Preset Acceleration and Deceleration times set by above parameters are the time taken for the output frequency to ramp up or ramp down between the Upper and the lower frequency limits gt Actual acceleration and deceleration time is calculated as follows isecen ee Maximum output frequency _ Pet 00 SEG y Maximum output frequency Hz Maximum output Frequency Set frequency The minimum starti
74. liquid and gas Electromagnetic interference from sources such as welding equipment Radioactive and flammable materials Excessive vibration from machines such as stamping punching machines add a vibration proof pads if necessary Non IP66 NEMAAX protection class drive should prevent the invasion of dust cotton and small metal shavings Non IP66 NAMEAX protection class drive should prevent exposure to rain or moisture VN Vv V NN Tightening torque for terminals TM1 TM2 Model Cable Size Tightening torque Cable Size torque mm AWG Nm Plasa 24 3 1 Electrical ratings of terminals Power Specification Voltage Volt Current A 0 5 1 200V 240V Frame 12 360 480 S Frame2 380 480 200V 240V 3 4 7 5 10 15 20 25 480 0 The maximum rms symmetrical short circuit ratings are as follows Device Rating Short circuit Maximum Rating A Voltage Volt 220V 0 5 20 5000 440V 5000 3 2 Installation 3 2 1 Installation method 3 2 1 1 IP20 NEMA 1 standard installaion a Single Three phase 200V 0 5 1HP Single phase 200V 0 5 1HP Three phase 200V 2HP 400V 1 2HP Frame1 NEMA1 TER 1PH 220V 0 TER A PANOR w m m gt C b Single Three phase 200V 2 3HP Single phase 200V 2 3HP Three phase 200V 5HP 400V 3 5HP Fr
75. mm inch N W E510 202 H 2 5 E510 203 H 2 5 E510 202 H1F 2 5 245 128 7 118 118 187 6 177 6 133 8 141 8 48 2 4 5 4 5 5 2 5 07 4 65 4 65 7 39 6 99 5 27 5 58 1 9 0 18 0 18 ESES S 5 07 4 65 4 65 7 39 6 99 5 27 5 58 1 9 0 18 0 18 E510 405 H3 2 5 E510 403 H3F 2 5 E510 405 H3F 2 5 3 46 Frame3 1 20 Three phase 200 7 5 10HP 400 7 5 15HP 560 H2 an H D 40
76. output with 03 2 ms count value reached 03 22 5 counts 18 03 00 03 05 23 Pulse input Counter Reset When anyone of the extermal terminals S1 to S6 set to 23 and turned on the pulse input counter value will be cleared and c0000 will be displayed For the pulse counter to be enabled again this input must be turned off 19 03 00 03 05 24 PLC Input When anyone of the extermal terminals 51 to 56 24 and turned the PLC program inputs will be enabled 20 03 022 25 Pulse Input Width Measure S3 When 03 02 25 S3 is the input port of pulse width measurement functions Parameters setting and applying are as the followings 00 05 7 Pulse input is the source of frequencies 03 02 25 5315 the pulse input width measurement 03 27 0 01 1 00 kHz pulse input frequency 03 28 0 01 9 99 The caculating formula of the frequency duty cycle upper limit frequency 03 28 Hz and the highest value is not more than the upper limit Note In this mode the frequency range of pulse input is 0 01 kHz to 1 00 kHz 4 39 21 03 02 26 Pulse Input Frequency Measure 53 When 03 02 26 53 is the input port of the frequency measurement function Parameters setting and applying are as the followings 00 05 7 Pulse input is source of frequencies 03 02 26 S3 is the pulse input frequency measurement 03 28 0 01 9 99 When pulse input frequency is set to f Hz the frequency of AC motor drive is F f
77. overspeed damage 3 24 3 3 5 Considerations for peripheral equipment Grounding Circuit Breaker amp RCD Magnetic contactor AC reactor for power quality improvement Input noise filter Inverter Motor Ensure that the supply voltage is correct A molded case 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 the inverter Residual Current Circuit Breaker RCD Current setting should be 200mA or above and the operating time at 0 1 second or longer to prevent malfunctions Normally a magnetic contactor is not needed A contactor can be used to perform functions such as external control and auto restart after power failure Do not use the magnetic contactor as the run stop switch of the inverter When 200 400 inverter with rating below 15KW is connected to a high capacity power source 600KVA or above then an AC reactor can be connected for power factor improvement and reducing harmonics E510 inverter has a built in filter to Class first Environment CategoryC2 To satisfy the required EMC regulations for your specific application you may require an additional EMC filter Connect the single phase power to Terminals L1 L L3 N Warning Connecting the input ter
78. phase 200V 0 5 1HP Three phase 200V 2HP 400V 1 2HP E510 Frame 1 Mounting hole Operator Panel Heat sink Name plate label Warning label Bar code label Terminal cover E510 Frame 1 NEMA1 Mounting Hole Operator Panel Heat sink Name plate label Warning label Bar code label Terminal cover 3 27 b Single Three phase 200 2 3HP Single phase 200 2 3HP Three phase 200 5 400V 3 5 E510 Frame2 Mounting hole Operator Panel Heat sink Name plate label Warning label Bar code label Terminal cover E510 Frame2 NEMA1 Mounting hole Operator Panel Heat sink Name plate label Warning label Bar code label Terminal cover 2 Fan cover NEMA1 box 3 28 Three phase 200 7 5 10HP 400 7 5 15HP E510 Frame 3 Fan cover Mounting hole Heat sink Operator Panel Name plate label Warning label Bar code label Terminal cover 510 3 NEMA1 Mounting hole Heat sink Operator Panel Name plate label Warning label Bar code label Terminal cover cover 1 3 29 Three phase 200 15 20HP 400 20 25HP E510 Frame 4 Fan cover gt Ro La gt TS Operator Panel Mounting hole Heat sink Warning label Name plate label Terminal cover Bar code label E510 Frame 4 NEMA1 Operator Panel i
79. ranges of the motor and the associated machinery gt Risk of electric shock The DC link capacitors remain charged for five minutes after power has been removed It is not permissible to open the equipment until 5 minutes after the power has been removed gt The Inverter should be used in environments with temperature range from 14 104 F or 10 to 50 C and relative humidity of 95 10 50 C without dustproof cover paster 10 40 C with dustproof cover paster Make sure that the power is switched off before disassembling or checking any components Please dispose of this unit with care as an industrial waste and according to your required local regulations gt capacitors of inverter main circuit and printed circuit board are considered as hazardous waste and must not be burnt gt plastic enclosure and parts of the inverter such as the cover board will release harmful gases if burnt Chapter 2 Number Definition 2 1 Nameplate Data Inverter Model amp Motor Rating MODEL E510 401 H3F MOTOR RATING 4HP 0 75kW C Input Power Specifications INPUT AC 3 PH 50 60Hz 380 480 10 15 42 Output Power Specifications OUTPUT AC 3 PH 0 650Hz 0 480V 2 IP20 202 lt lt lt P N Barcode S N Barcode 1 46 160 IND CONT EQ TECO Electric amp Machinery Co Ltd Em UU 2 2
80. when fault appeared 4 73 Drive Horsepower Code Range Inverter Model 13 00 show Inverter Model 13 00 show 2P5 _ 510 401 41 2001 1 _ 510 402 42 0 510 202 22 E510 40 XXX 43 E510 203 XXX 203 1 510 405 405 E510 205 XXX 25 510 408 408 28 ____ ____ 2 ___ 25 4 20 45 510 2 5 510 201 510 208 510 210 510 215 510 220 Software Version Range Fault Log Display Latest 3 faults Range gt Last three faults are stored a stack and whenever there is a new fault the previous faults are pushed down the stack So the fault stored in 2 xxx will be transferred to 3 xxx and the one in 1 xxx to 2 xxx The recent fault will be stored in the empty register 1 xxx gt Use Up Aand Down Y keys to scroll between the fault registers gt Pressing reset key when parameter 13 02 is displayed then all three fault registers will be cleared and the display for each register will change to 1 2 3 gt E g fault log content is 1 0C C this indicates the latest fault is OC C etc Accumulated Inverter Operation Time 1 13 03 13 04 Accumulated Inverter Operation Time 2 13 05 Accumulated Inverter Operation Time Mode 0 Power on time Range 9 1 Operation time gt When the operation time recorded in accumulator 1 Pa
81. without dustproof cover paster 10 40 C with dustproof cover paster IP66 NEMA 4X Type 10 50 C 3 37 3 5 Standard wiring 3 5 1 Single phase Braking resistor Option 71 BR Main Switch Fuse Ti _ L1 L Power Inverter source input output Motor CE Ground 1 2 4 RXDO FWD RS485 5 TXD0 Run Stop 6 Data Pin 1 to 8 7 5V REV Run St 8 GND 5 8 Speed Control 554 5 Relay J R1B 250 Output 5 aye 30VDC 1A COM NPN PNP ROA Relay 0 0 250 Output disable NPN 2 B O 0 ION o All E 3 gt __ Frequency Frequency indicator device 2 B 7 11 w t 9 AP 0710VDC i QAGND Indicates shield wire Indicates twisted pair shield wire Shows circuit Shows control circuit 1 JP1 NPN PNP selection 2 1 0710 0720 selection JP3 AI2 0710 0720 selection Model 200V E510 2P5 H1 F N4S E510 201 H1 F N4S E510 202 H1 F N4S E510 203 H1 F N4S 3 38 Single phase power input
82. 0 03 1 to set the inverter run mode to External multifunction inputs 03 11 Multifunction Output Relay RY 1 functions Terminals 03 12 Multifunction Output Relay RY 2 functions Terminals R2B R2A 2 0 1 Fault 2 Set Frequency within the preset range refer to 03 14 31 Set Frequency reached As set by 3 13 3 14 refer to 03 13 03 14 4 Output Frequency Detection 1 gt 03 13 refer to 03 13 5 Output Frequency Detection 2 lt 03 13 refer to 03 13 6 Auto restart 7 Momentary AC Power Loss refer to 07 00 8 Rapid Stop Decelerate to Stop 9 Base Block Stop Mode 10 Motor Overload Protection OL1 11 Drive Overload Protection OL2 12 Over Torque Threshold Level OL3 13 Preset Current level Reached refer to 03 15 03 16 14 Preset Brake Frequency Reached refer to 03 17 03 18 15 PID Feedback Signal Loss 16 Final count value reached 3 22 23 17 Initial count value reached 3 22 23 18 PLC status indicator 00 02 19 PLC control 20 Zero Speed Frequency Reached Level 0 00 650 00 Hz 03 44 Frequency Reached Detection Range 0 00 30 00 Hz Output relay RY function descriptions 1 03 11 03 12 0 will be ON with Run signal 2 03 11 03 12 1 RY will be ON with inverter Faults 3 03 11 03 12 2 RY will be ON when Preset frequency 03 13 Preset frequency
83. 00 05 00 06 6 frequency command source is output of the PID Note 00 05 Main Frequency Command Source and 00 06 Alternative Frequency Command Source 4 27 can not be the same Otherwise panel will display 2 00 07 Main and Alternative Frequency Command Modes Range 0 Main or Alternative Frequency 1 Main Frequency Alternative Frequency gt When 00 07 0 the frequency source is set by the Main frequency parameter 00 05 Default or by the Alternative frequency parameter 00 06 Use any of the external terminals S1 to S6 and set the relevant parameter 03 00 to 03 05 13 to switch from Main to Alternative source gt When 00 07 1 The frequency command will be the result of setting of main and alternative frequencies 00 08 Communication Frequency Command 0 00 650 00 Hz This parameter can be used to set frequency command gt This parameter can be used to read the set frequency in communication mode gt This parameter is only effective in the communication mode 00 09 Frequency Command save on power down Communication mode Eos 0 Disable 9 11 gt 00 09 0 Keypad frequency is saved gt 00 09 1 Frequency set by communication is saved 00 20 Initial Frequency Selection 0 By Current Freq Command 1 By Zero Freq Command 2 00 11 00 2141 ___ Initial Frequency gt This parameter is only effective
84. 05 01 gt Set03 07 1 Up down frequency mode inverter will ramp up from OHz Run command and Ramp down to 0 Hz on stop command 03 08 Multifunction terminals S1T S6scantime Range 1i 2012ms S O Multifunction input terminal On Off periods will be scanned for the number of cycles according to the set value in parameter 03 08 If the signal status for ON or OFF period is less than the set period it will be treated as noise Scan period unit is 2ms gt Use this parameter if unstable input signal is expected however setting long scan time periods results in slower response times Note Terminal SF is for safety switch SF can cut off the inverter voltage output 4 41 03 09 51 55 Input Type Selection 4 NC xxxx0 S1 NO xxxx1 S1 NC xxx0x S2 NO xxx1x S2 NC xx0xx S3 NO xx1xx S3 NC x0xxx S4 NO x1xxx S4 NC 0xxxx 5 NO 1xxxx S5 NC 03 10 S6 Input Type Selection NO amp NC xxxx0 56 NO 1 S6 gt NO Normally open NC Normallly closed Select as required For selecting Normally Open NO or Normally Closed NC set the relevant digit in parameter 03 09 03 10 to 0 or 1 as required gt Itis necessary to set the external multi function input terminal setting to 1 as 03 20 corresponding terminal so it makes sense on the setting of corresponding terminal position oet Parameter 03 09 first before you use the Parameters 00 02 0
85. 0V5HP 400V 3 5HP ae Unit mm inch Dimensions Kg H2 D2 E 3379 218 4 235 2 amp E E510 202 HN4R 5 98 E510 202 H1FN4S 337 9 218 4 235 2 79 8 337 9 235 2 337 9 235 2 5 98 E510 203 HN4R E510 203 H1FN4S E510 205 H3N4 E510 401 H3 E510 401 H3FN4S E510 402 H3 5 98 5 98 5 98 337 9 337 9 337 9 337 9 337 9 5 98 5 98 5 98 NIT NI N NI NIN IPN AASA eE E510 402 H3FN4S 5 98 3 55 Frame 3 66 4X Three phase 200V 8 20HP 400V 8 25HP Ao ICL oa Unit mm inch Dimensions 3 56 3 8 Filter Disconnection EMC filter 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 amp certain supply systems for medical equipment For ungrounded supply systems If the filter is not disconnected the supply system becomes connected to Earth through the Y capacitors on the filter circuit This could result in danger and damage to the Drive Remove steps 1 using a screwdriver to remove the front cover 2 use screwdriver to loosen the screw 3 using a screwdriver to remove short film 4 use screwdriver to tighten the screws Note Disconnectin
86. 20 25 SCHAFFNER FS42500 50 99 6 3 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 Electrical Shock Hazard Do not operate equipment with covers removed Failure to comply could result in death or serious injury The diagrams in this section may show drives without covers or safety shields to show details Be sure to reinstall covers or shields before operating the drives and run the drives according to the instructions described in this manual Always ground the motor side grounding terminal Improper equipment grounding could result in death or serious injury by contacting the motor case Do not touch any terminals before the capacitors have fully discharged Failure to comply could result in death or serious injury Before wiring terminals disconnect all power to the equipment The internal capacitor remains charged even after the power supply is turned off After shutting off the power wait for at least the amount of time specified on the drive before touching any components Do not allow unqualified personnel to perform work on the drive Failure to comply could result in death or serious injury Installation maintenance inspection and servicing must be performed only by authorized personnel familiar with installation ad
87. 4 3 25 3 26 3 27 3 34 3 34 3 36 3 38 3 38 3 39 3 40 3 41 3 41 3 43 3 45 3 45 3 54 3 57 3 58 Chapter 4 4 1 4 2 4 3 4 4 5 5 1 5 2 5 3 5 4 5 5 Chapter 6 6 1 6 2 6 3 6 4 6 5 Appendix 1 Appendix 2 Appendix 3 Appendix 4 Appendix 5 3 9 1 Description of dimension and installation 3 9 2 Description of Protective Stickers Software Index Keypad Description 4 1 1 Operator Panel Functions 4 1 2 Digital display Description 4 1 3 Digital display setup 4 1 4 Example of Keypad Operation 4 1 5 Operation Control Programmable Parameter Groups Parameter Function Description Specification Description on Built in PLC Function 4 4 1 Basic Instruction Set 4 4 2 Function of Basic Instructions 4 4 3 Application Instructions Troubleshooting and Maintenance Error Display and Corrective Action 5 1 1 Manual Reset and Auto Reset 5 1 2 Keypad Operation Error Instruction 5 1 3 Special conditions General troubleshooting Troubleshooting of the Inverter 5 3 1 Quick troubleshooting of the Inverter 5 3 2 Troubleshooting for OC OL error displays 5 3 3 Troubleshooting for OV LV error 5 3 4 Motor not running 5 3 5 Motor Overheating 5 3 6 Motor runs unbalanced Routine and periodic inspection Maintenance Peripheral Components Reactor Specifications Electromagnetic Contactor circuit breaker Fuse Specification Brake Resistor Noise filter Instructions for UL E510 Parameter Setting List E510 MOD
88. 4 MD1 MDA T1 T8 C1 C8 V 1 7 V7 count Setting reference comparison value Lower Limit AS1 ASA MD1 MDA T1 T8 C1 C8 V 1 V7 count Output terminals of analog comparator G1 G4 Analog Comparison Mode 1 3 1 Analog comparator mode 1 Os 9 ON Input under the Ladder Program Mode a T Because present input Gb esee Value 0 3 lt lower limit 4 0 so Glis ON 1 d The present value of Timer 1 is 0 3 TI 0 3 e Lower limitis 20 N The number of Analog target value of G1 is 1 comparision G1 G8 determined by the 1 4 present value of T1 2 Analog comparator mode 2 gt ON 3 Analog comparator mode 3 s s 6 4 85 4 Running Instruction Symbol Running mode could be set via OFF FWD ON REV Preset Speed could be set via 11 19 set on set on or V3 V4 V5 constant V3 V4 V5 Instruction code of operation F1 F8 Total 8Groups Sample Input under the Ladder Program Mode ON OFF of controls the Run Stop status of F1 7 s 7 I 1 N 7 PX 22 7 N I l I S Scu A TIT When Inverter operating 1 The input terminal of F1in theladder 4 program mode should 1 2 4 86 5 DEC module Description Calcu
89. 4 and status of External run switch Caution After any power loss if the Run mode is set to External by parameter 00 02 71 and if Direct start on power up is also selected by parameter 07 04 70 please note that the inverter will run on resumption of power To ensure safety of operators and to avoid any damages to the machinery all necessary safety measure must be considered including disconnection of power to the inverter Rang 10 10 0 2022 07 022 0 The inverter will not auto restart after trips due to fault 07 02 0 07 012 0 After a trip due to fault the inverter will run with half frequency before power loss and restarts after an internal delay of 0 5 seconds gt 07 02 0 07 01 0 After a fault trip the inverter will run with half frequency before power loss and restart with a delay according the preset in parameter 07 01 gt Note Auto restart after a fault will not function while DC injection braking or decelerating to stop 07 03 Reset Mode Setting 0 Enable Reset Only when Command is 1 Enable Reset when Run Command is On or Off gt 07 03 0 Once the inverter is detected fault please turn Run switch and then On again to perform reset otherwise restarting will not be possible 07 04 Direct Running on Power Up Range 0 Enable Direct Running on Power Up 1 Disable Direct Running on Power Up 07 05 Delay ON Timer Seconds
90. 5 Comparison list between parameter and register Note Parameter register No GGnnH GG means Group number nn means Parameter number for example the address of Pr 08 03 is 0803H the address of Pr 10 11 is No No 02 01 02 05 0008 0006 0106H 01246 0206 0206 007 0 7 07 0207HM 0207 ____ 04 Reserved 0213 ___ 000 ____ 00 14 02H 054 LO00FH 0045 020EH 0545 ___ OOOH 0046 Jonon 0216 oH 0 202 0 48 0 42 0 9 5 0014 00 20 13 Register Function Group04 0300 03 00 0400 04 00 0301 03 01 0401 04 01 0302 03 02 0402 04 02 0303H 03 03 0403H 04 03 0304H 03 04 0404 04 04 0305H 03 05 0405H 04 05 0306H 04 06 0307H 04 07 0308H 04 08 0309H 04 09 03 10 040 04 10 030BH 04 11 030CH 04 12 030DH 04 13 030EH 04 14 030FH 04 15 0310H 03 16 0311H 03 17 0312H 0848 0313H 03 19 0314 03 20 0315H 03 21 0316H 03 22 i ____ 0323 0318 03 24 ws 0319H 03 25 W sss 031AH 03 26 Xu ___ _____ Register Function Register No ter No Function 0 0500 05 00 0501H 05 01 0503H 05 03 0504H 05 04 0506H 05 06 0507H 05 07 0508H 05 08 0509H 05 09 050BH 05 11 050CH 05 12 050DH 05 13 050EH 05 14 050FH 05 15 0510H 05 16 0511H 05 17 0513 05 19 0514 05
91. 7 06 18 06 31 RUN Command RUN 1 to S6 auto run RUN enable Example 485 Auto Run Mode 06 002 1 3 After a restart continues to run from the unfinished step Auto Run Mode 6 002 4 6 After a restart it will begin a new cycle 4 58 47 Command stop Command stop run Output Output Frequency Frequency begin a new cycle Output Frequency x Continue running from unfinished step gt ACC DEC time in Auto run mode will be according to the setting of 00 14 00 15 or 00 16 00 17 gt For Auto sequence 0 run frequency will be according to keypad frequency set by parameter 05 01 Parameters 06 16 and 06 32 are used to set the sequence Run time and Run direction 0 Momentary Power Loss and Restart Disable 1 Momentary Power Loss and Restart Enable gt the power supply due to sudden increase in supply demand by other equipment results in voltage drops below the under voltage level the inverter will stop its output at once gt When 07 00 0 power loss the inverter will not start gt When 07 00 1 Aafter a momentary power loss inverter will restart with half frequency before power loss and there is no limitation on number of restarts gt power loss as long as the inverter CPU power is not completely lost the momentary power loss restart will be effective restart will be according to setting of parameters 00 02 amp 07 0
92. AllBias 0 100 04 04 AMBiasSeletion O gt 04 05 5 2 04 06 Al2 signal verification Scan Rate Cd Range 1 200 2msee 00 02 4 7 2 0 10001 440 APSIope 0 Positive 1 Negative gt Set 04 01 and 04 06 for analog signal verification Inverter reads the average values of A D signal once per 04 01 04 06 x 2ms Set scan intervals according to the application and with consideration for signal instability or interference effects on the signal by external sources Long scan times will result in slower response time 4 A8 Al1 Analog Voltage input scaling examples by adjusting Gain Bias 4 Slope parameters 04 02 04 05 1 Positive Bias type 04 04 0 and effects of modifying Bias amount by parameter 04 03 and Slope type with parameter 04 05 are shown in Fig 1 amp 2 Figure Figure2 cer ors oro owes mx m o o jp wm o a won om sm m 04 03 Hz 04 03 Hz Bias Upper Bias 100 60Hz ee ee ae Frequency 100 60Hz ee eR 50 30Hz 50 30Hz gt 0 0 gt OV 5V 10V V OV 5 10V V 2 Negative Bias type and effects of modifying Bias amount by parameter 04 03 and Slope type with parameter 04 05 are shown in Fig 384 Figure3 Figure4 10602 peos peo Hz Hz
93. BUS Communication protocol E510 PLC Communication protocol JN5 CM USB instruction manual II 3 58 3 60 4 1 4 1 4 1 4 2 4 4 4 5 4 7 4 8 4 27 4 78 4 78 4 79 4 80 5 1 5 1 5 1 5 3 5 4 5 5 5 6 5 6 5 8 5 9 5 10 5 11 5 12 5 12 5 14 6 1 6 1 6 1 6 2 6 2 6 3 1 1 2 1 1 4 1 5 1 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 Precautions The inverter is an electrical product For your safety there are symbols such as Danger Caution in this manual as a reminder to pay attention to safety instructions on handling installing operating and checking the inverter Be sure to follow the instructions for highest safety Indicates a potential hazard that could cause death or serious personal injury if misused Indicates that the inverter or the mechanical system might be damaged if misused Hisk of electric shock The DC link capacitors remain charged for five minutes after power has been removed It is not permissible to open the equipment until 5 minutes after the power has been removed i E Do not make any connections when th
94. C voltage 4 Temperature 5 PID feedback 6 Al1 7 Al2 8 count Value The highest bit of 12 00 sets the power on the display other bits set the selected display from range 0 7 as listed above Example1 Set parameter 12 00 10000 to obtain display format shown below Wm EUN R 4 Y Y Y Y display Power supply Output 2sec later hea f n 2 EV eS iJ J Set frequency Example 2 Set parameter 12 00 12345 obtain display format shown below DC voltage lt 3 gt PIDfeedback Output Voltage lt 2 gt 2sec later mE Display Power supply Parameter Set Frequency Increment Decrement key functions Short time press Long time press gt T2 gt Quick pressing of these keys will Increment Decrement the selected digit by Extended pressing will Increment or Decrement the selected digit continuously 4 1 4 Example of keypad operation Example1 Modifying Parameters Frequency rer time press DSP FUN once AVA Short time press 00 01 nn ni Short time Short time press press A a gt press A READ ENTER once 86558 piiga Short time press READ ENTER 412 4 5
95. Dectime inti Factory D t R Setting 0 Disabled 1 Single cycle Continues to run from the Unfinished step if restarted 2 Periodic cycle Continues to run from the unfinished step if Auto Run Mode restarted Selection 3 Single cycle then holds the speed Of final Sequencer step to run Continues to run from the unfinished step if restarted 4 Single cycle Starts a new cycle if restarted 5 Periodic cycle Starts a new cycle if restarted 6 Single cycle then hold the speed of final step to run Starts a new cycle if restarted Frequency Command 1 ade Frequency Command 2 Frequency Command 3 Frequency Command 4 and Frequency Command 5 we Re Seng UE Hote Frequency Command 6 Frequency Command 7 Auto _ Run Mode 0 00 Frequency Command 8 pens ee 0 00 Hz 1 Frequency Command 9 Auto _ Run Mode Frequency 0 00 Command10 Auto _ Run Mode Frequency Command 0 00 11 _ 0 00 12 _ 0 00 13 Auto _ Mode 06 17 06 18 Em N IL N L N N N N X Frequency Command 0 00 14 _ Run Mode Frequency Command 0 00 15 Running Time Setting O Running Time Setting 1 Running Time Setting 2 EDEN 2 Running Time Setting 3 anes 2 Running Time Setting 4 eae 2 Running
96. Detection Range 03 14 is reached 4 42 When Output Freq Preset Freq Reached Setting 03 13 Preset Freq Reached Detection Range 03 14 Relay Output will be ON Hz Preset Freq Reached A 03 13 03 14 ELIT f Preset Freq Reached Detection Range 03 14 Output Freq gt Time 03 13 03 14 ee A Y Preset Freq Reached Setting 03 13 Preset Freq Reached Detection Range 03 14 Command gt Relay Output Example Sets 03 13 30 and 03 14 5 Relay will ON when output frequency reached 25Hz to 4 03 112 RY will be ON when preset frequency level 03 13 preset Frequency Detection Range 03 14 is reached When Freq Detection Range Lower Limit Setting Freq Freq Detection Range Upper Limit And Detection Range Lower Limit lt Output Freq Freq Detection Range Upper Limit Relay output will be ON CAllowable tolerance 0 01 Hz Freq Detection Range Upper Limit Setting Freq 2 Y 03 13 03 14 gt fN 2 Reached Detection J 7 N 03 13 __ Range 03 14 N Setting Freq 1 03 13 03 14 c Freq Detection Range Lower Limit Time 03 13 03 14
97. FA Skip frequency range frequency band 0 00 30 00 Hz Skip frequency parameters can be used to avoid mechanical resonance in certain applications Example 11 08 10 00 Hz 11 09 20 00 Hz 11 10 30 00 Hz 11 11 2 00 Hz 10Hz 2Hz 8 12Hz 20Hz 2 2 18 22 2 Skip frequency 30Hz 2Hz 28 32Hz d 11 11 11 10 11 09 11 08 11 12 Energy Saving Gain 0 100 11 13 Regeneration Avoidance Operation Selection 0 Regeneration avoidance function invalid 1 Regeneration avoidance function is always valid 2 Regeneration avoidance function is valid during constant speed Regeneration avoidance operation During excessive energy regeneration the Vpn DC bus voltage will Increase and lead to 4 70 over voltage to avoid over voltage due to regeneration the output frequency be increased Regeneration avoid ance can be set according to the selections above Example Regeneration avoidance during acceleration Set value of 11 14 outputfre quency Hz In Regeneration avoidance operation Example Regeneration avoidance during constant speed Set value of 11 14 outputfre quency Hz In Regeneration avoidance operation Example Regeneration avoidance during deceleration Set value of 11 14 outputfre quency Hz In Regeneration avoidance operation 11 14 Regeneration Avoidance Operation Level 200 300 0 400 0 400V
98. H 220V 0 75KW J ERR etor 5 minutos before N iius cd us NN ul 3 60 Chapter 4 Software Index 4 1 Keypad Description 4 1 1 Operator Panel Functions REV FUN FREQ stor 5 10 Main digital displays Frequency Display Parameter voltage Current Temperature Fault messages Hz RPM ON when the frequency or line speed is displayed OFF when the parameters are displayed FWD ON while the inverter is running forward Flashes while stopped REV ON while the inverter is running reverse Flashes while stopped FUN ON when the parameters are displayed OFF when the frequency is displayed Variable FREQ SET Used to set the frequency Resistor Increment parameter number and preset Values ______ ______ Decrement parameter number and preset Values Kevs FWD REV FWD Forward Run a Dual function keys REV Reverse Run Keypad DSP FUN DSP Switch between available displays 8 Dual function keys FUN Used to examine the parameter content buttons READ ENTER Used to display preset Value of parameters and for saving Dual function keys the changed parameter Values
99. Integral Value Resets to Zero 0 Disabled when Feedback Signal Equals 1 After 1 Second the Target Value 30 After 30 Second 0 30 Allowable Integral value Error 0 100 Margin Units 1 Unit 1 8192 0 17 PID Sleep Frequency Level 0 00 650 00 PID Sleep Function Delay Time 0 0 25 5 00 Sec PID Wake up frequency Level 0 00 650 00 10 00 0 PID Wake up function Delay Time 0 0 25 5 PID Feedback SettingLevel 0 999 10 7 Min PID Feedback Setting Level 0 999 0 __ 4 21 0 Reverse Command is Enabled 1 Reverse Command is Disabled Carrier Frequency kHz 1 16 Reverse Operation Control Factory D t R escription ange Setting unit 0 ModeO 3Phase PWM modulation 1 Mode1 2Phase PWM modulation 2 Mode2 2Phase Random PWM Modulation Carrier Mode Selection Carrier Frequency Reduction by Temperature Q Disabled NIN Rise 1 Enabled 1 07 SkpFrequeny1 0 00 65000 0 00 Skip Frequency 2 0 00 65000 0 00 Frequency 3 0 00 65000 0 00 Hz Skip Frequency Range Barwn ow Mode 0 Invalid 11 13 Regeneration Avoidance 1 Vaild Selecti 2 Only in The Constant Speed Regeneration Avoidance 200V 300 0 400 0 Operation level 400V 600 0 800 0 760 0 Regeneration Avoidance Frequency Limit Compensation 9 99 15 00 Regeneration Avoidance Voltage
100. N OF ON 05 06 05 27 OFF ON OFF 05 07 05 29 4 36 3 03 00 03 05 6 71 Forward Reverse JOG When input terminal is to function 6 and is turned on inverter will work jog forward mode When an input terminal is set to function 7 and is turned on inverter will work in jog reverse mode Note If jog forward and jog reverse function is enabled at the same time inverter will enter stop mode 4 03 00 03 05 8 9 UP DOWN When an input terminal is set to function 8 and turned on frequency command will increased according to the UP DOWN and increment decrement step set in parameter 03 06 If the input is kept on continuously the frequency command increases accordingly until the upper frequency limit is reached When an input terminal is set to function 9 and is turned on frequency command decreases according to the UP DOWN increment decrement step set in parameter 03 06 If the input is kept on continuously the frequency command decreases accordingly and in relation to settings for parameter 03 06 and 3 07 until Zero speed is reached Refer to group 3 parameter description lt Note The UP DOWN target frequency is determined by the time that the signal is kept on including the acceleration deceleration time 5 03 00 03 05 10 2 Acc Dec time When an input terminal is set to function 10 and is turned on the actual acceleration and deceleration time will be according
101. Selection 0 Output Frequency 1 Frequency Command 2 Output Voltage 3 DC Bus Voltage 4 Output Current Example Set 04 11 required according to the table below 04 11 T ECT ud TIE Wd KW a 0 XmaX2 04 11 Xmsx pd 0 aor TOV UE 0 1000 04 13 Bias 0 100 AO Bias Selection 0 positive 1 Negative 04 15 AO Slope 0 positive 1 Negative 0446 Gai 0 Invalid 1 Effective Select the Analog output type for the multifunction analog output on terminal TM2 as required by parameter 04 11 Output format is 0 10V dc The output voltage level can be scaled and modified by parameters 04 12 to 04 15 If necessary gt The modification format will be same as the examples shown previously for Analog Voltage Input parameters 4 02 to 4 05 Note the max output voltage is 10V due to the hardware of the circuit Use external devices that require a maximum of 10V dc signal F Gain Functions F Gain function provides the facility for setting the frequency reference to more than one inverter set by a master potentiometer then the master frequency can be scaled by three individual potentiometers for each inverter as show in the diagram below To use this function set Parameter 04 16 21 and set parameter 00 05 2 external Analog input and AI2 will be the scaling potentiometer 4 51
102. ____________ __ __ 1010 ____ _____ 1110 ____ _______ 10 11 0BOBH 11 12 11 13 ________ __ __ 1014 ___ 1114 11 15 11 16 0A12H 10 18 1 7 11 10 17 0B11H 11 17 1022 17 Register Function _ Register No Function Register No Function _ Group15 Note 12 00 13 00 2 15 32 22 mop 1209 109 Co 1200 1304 4205 mos 1209 mos C moy moy um j oce maa j j oco es Note The communication address of Group 14 15 can be found in E510 PLC communication protocol except 15 32 App3 18 Appendix4 PLC Communication Protocol E510 PLC MEMORY MAP Timer mode Set Value data type A2B8h word selection The final output detection judgement for ladder A400h reserve Timer Bit T1 T8 preserve __ j preserve __ j Auxiliary relay 4 preserve __ j Note Akada 8 3 4 1 Trigger detection judgement forFunction Encoder Bit Analog Bit Timer
103. ame2 Screw M4 Screw M4 i qu N K Screw 4 jim Screw 4 c Three phase 200V 7 5 10HP 400V 7 5 15 Frame3 Screw M4 Screw M4 Y M ef Screw M4 AN Screw 4 E d Three phase 200 15 20HP 400V 20 25HP Frame4 Screw M5 Screw 5 Screw 5 A Screw M5 Three phase 400V 20 25HP With Fliter Models Frame4 Screw M5 3 6 3 2 1 2 IP66 NEMA standard installaion a Single Three phase 200V 0 5 1HP Single phase 200V 0 5 1HP Three phase 200V 2HP 400V 1 2HP Screw M5 5 2 S AD GER Screw M6 Screw M5 3 5HP Screw M6 3 7 c Three phase 200V 8 20HP 400 8 25HP T 3 8 Disassembly and assembly steps As follows gt P20 NEMA 1 Disassembly steps a Single Three phase 200V 0 5 1HP Single phase 200V 0 5 1HP Three phase 200V 2HP 400V 1 2HP Frame Step3 Wire amp Re install the cover Step4 Tighten the screws 3 9 Frame 1 NEMA1 ar a o9 A Step3 Wire amp Re install the cover Step4 Tighten the screws 3 10 b Single Three phase 200V 2 3HP Single phase 200V 2 3HP Three phase 200V 400V 3 5HP Frame 2 w bi P A n UY t a Step3 Wirie amp Re install the cover Step4 Tighten the screws 3 11
104. closed then the inverter will restart H Danger Prior to use ensure that all risks and safety implications are considered When the momentary power loss ride through is selected and the power loss is short the inverter will have sufficient stored power its control circuits 10 function therefore when the power is resumed the inverter will automatically restart depending on the setup of parameters 07 00 amp amp 7 01 1 3 Before Operation gt Make sure the inverter model and rating are the same as that set in parameter 13 00 Note On power up the supply voltage set in parameter 01 01 will flash on the display for 2 seconds 1 4 During Operation gt Do not connect or disconnect the motor during operation Otherwise It may cause the inverter to trip or damage the unit gt avoid electric shock do take the front cover off while power is gt The motor will restart automatically after stop when auto restart function is enabled In this case care must be taken while working around the drive and associated equipment The operation of the stop switch is different than that of the emergency stop switch The stop switch has to be activated to be effective Emergency stop has to be de activated to become effective gt not touch heat radiating components such as heat sinks and brake resistors gt The inverter can drive the motor from low speed to high speed Verify the allowable speed
105. d direct start is disabled 07 04 1 The inverter cannot be started and will flash STP1 The run input is active at power up refer to descriptions of 07 04 If the Stop key is pressed while the inverter is set to external control mode 00 02 00 03 1 then STP2 flashes after stop Release and re activate the run contact to restart the inverter When external rapid stop input is activated the inverter will decelerate to stop and the display will flash with E S message When external base block input is activated the inverter stops immediately and then the display will flash with b b message PID feedback loss is detected Motor nameplate data Input errors Emergency stop is activated while auto tuning Software rev below 1 1 the fire mode functions when 08 17 1 Software ver 1 1 and firemode functions when 03 00 03 05 28 The diplay on the keypad indicates FIrE Under fire mode function the inverter will run at full speed 5 4 5 2 General troubleshooting Status Checking point Motor rune 15 the wiring for the output Wiring must match U V and W terminals of terminals correct the motor Is the wiring for forward and direction ng Check for correct wiring reverse signals correct 15 the wiring for the analog de poe frequency inputs correct Check for correct wiring not be UnG OV operation Moge Check operation mode of the operator regulates Is the load too exc
106. e inputs 03 21 10 8 2 10 on the basis of setting 4 A6 03 22 Count Reaches the Set 0 0996 Range 0 9999 03 22is applied to set the count value of the internal counter which can be a trigger point from any one of multi function terminal 81 56 is set 22 While the count value reaches it will recount gt If it cannot reach the setting value of 03 22 during the process of counting and would like homing to recount it can make the homing command on counter from any one of multi function terminal 51 56 are set 23 gt status of count value is controlled by the setting of 12 00 0008 Please refer to the following diagram If 03 117 17 is the reaching instruction of designated counter 03 22 4 the count value is the reaching set and 03 23 2 the designated count value is the reaching set will on when the count value is accumulated to two times and homing will not be set when the trigger point is removed until the count value is accumulated to four times If 03 12 16 RY2 is the reaching instruction of designated counter and 03 22 74 the count value is the reaching setting RY2 will be on when the count value is accumulated to four times and homing will be set when the trigger point is removed E C0001 0002 C0003 C0004 C0000 C0001 0002 C0003 value o counter Such as setting 12 00 00008 The following two chart comparises explain the specified value of count
107. e inverter is powered on Do not check parts and signals on circuit boards during the inverter operation Do not disassemble the inverter or modify any internal wires circuits or parts Ensure that the Inveter Ground terminal is connected correctly Do not perform a voltage test on parts inside the inverter High voltage can destroy the semiconductor components Do not connect T1 T2 and terminals of the inverter to any AC input power supply CMOS ICs on the inverter s main board are susceptible to static electricity Do not touch the main circuit board Chapter 1 Safety Precautions 1 1 Before Power Up Danger gt 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 11 12 and T3 Otherwise inverter damage can result gt The line voltage applied must comply with the inverter s specified input voltage See the nameplate gt avoid the front cover from disengaging or other damge do not carry the inverter by its covers Support the drive by the heat sink when transporting Improper handling can damage the inverter or injure personnel and should be avoided To avoid the risk of fire do not install the inverter on a flammable object Install on nonflammable objects such as metal This product provides the 24V for internal use only do not use as the power supply sources for other external components such as sensor
108. e motor will run for 1 minute only gt heat sink cooling function will not be as effective when the motor runs at low speed The thermal relay action level will decline at the same time The curve 1 will change to curve 2 E08 41300 Over torque detection Control 0 Over torque detection is not valid 1 Detected after the set frequency 2 Detect when running 0 Stop output after over torque detection Free run stop 1 Continue to run after over torque detection Display only OL3 08 15 Over Torque Detection Level 30 300 08 16 Over Torque Detection Time Range Range 0 Invalid 1 Effective Over Torque is detected when the output torque level exceeds the level set in Parameter 08 15 Inverter rated torque is 10096 and if it is detected for a duration of time which is set in parameter 08 16 gt When 08 142 0 If there is over torque the inverter coasts to stop and flashes OL3 It is necessary to press RESET or signal reset from input terminal to continue to run gt When 08 142 1 If there is over torque the inverter can continue to run and flashes OL3 until the output torque is less than the 08 15 set value Parameter 03 11 12 Multifunction output terminal 12 the output terminal signal will be set for over torque condition X Note Over torque detection will be enabled only when parameter 08 13 is set to options 1or 2 warning Selection of Fire Mode by se
109. e relay Timing up output T1 T8 _ 3 Enable reset relay OFF OFF t Target value set in the timer OFF ON ON ON OFF Timing enable relay Timing up output 1 8 3 Enable reset relay OFF ON OFF t Target value set in the timer 4 83 4 Timer Mode 4 OFF Delay Timer Mode2 Enable reset relay Enable reset relay Present value 0 Timer starts operating Present value 0 OFF OFF Timing enable relay on OFF Timing up output 8 OFF ON t Enable reset relay OFF t Target value set in the timer 5 Timer Mode 5 FLASH Timer Mode 1 Enable reset relay Enable reset relay Present value 0 Timer starts operating Present value 0 Timing enable relay Timing up output T1 T8 Target value set in the timer 6 Timer Mode 6 FLASH Timer Mode 2 Enable reset relay Enable reset relay Present value 0 Timer starts operating Present value 0 Timing enable relay Timing up output T1 T8 Enable reset relay t Target value set in the timer 7 Timer Mode 7 FLASH Timer Mode 3 Enable reset relay Timer starts operatin Enable reset relay Present value 0 Present value 0 Timing enable relay aloe Timing up output 1 8 4 84 3 Analog comparator Wm Analog comparison mode 1 3 Selection of the input comparison G AS1 AS4 MD1 MD4 T1 T8 C1 C8 V up limit Setting reference comparison value Upper Limit AS1 ASA
110. e reserved register 4 2 Monitor Data Only for reading Register No Bit otate Signal Operation state 1 Run 0 5 state 1 Run 0 Stop state 1 Reverse 0 Forward SS operation prepare state 1 ready 0 Abnormal 1 Abnormal 0000020 1 Abnormal En I NN DATA setting error Error App3 5 Register No 2521H 2522 Content The inverter is normal ver current during decelerating OC D Inverter over heat N Over current stop N eserved Under voltage LV Under voltage during LV C Over voltage OV ver voltage at constant speed OV C 4 nverter over heat during running stop at 0 Hz STPO External BB bb Direct start disable STP1 Io a X e 15 O IO io o N lo Co cd CTER PDER Control panel emergency stop STP2 eypad operation error Err EPR arameter setting error Err2 OL3 Err4 Communication failure nverter over load OL2 e Err5 ommunication failure Err6 Motor over load OL1 gt Err7 External bb E S mmy Err8 LOC eserved gt O U O OO W IW IM NM NM IS NW NH IN JIN IOI j gt 0 IN
111. e the following diagram Accel Decel amp Enable Disable timing diagram using terminal S1 and parameter 03 00 11 RUN 51 ON OFF 7 03 00 03 05 12 Main Alternative Run Source Select When an input terminal is set to function 12 and is turned on the run command source is according to parameter 00 03 Alternative Run source If the Input is off it will be according to 00 02 Main run source 8 03 00 03 05 13 Main Alternative Frequency Source Select When an input terminal is set to function 13 and is turned on the frequency source is according to parameter 00 06 Alternative Frequency the Input is off it will be according to 00 05 Main Frequency Source 9 03 00 03 05 14 Rapid Stop controlled deceleration stop When an input terminal is set to function 14 and is turned inverter decelerates to stop according to deceleration time 2 10 03 00 03 05 15 Base Block Coast to stop When an input terminal is set to function 15 and is turned on inverter output is turned off 4 38 11 03 00 03 05 16 Disable PID Function When an input terminal is to function 16 and is turned on PID functions is disabled if it is turned off PID function is enabled again 12 03 00 03 05 17 Reset When a failure that can be manually reset occurs turn on a terminal with function 171 the failure will be reset Same
112. e too large 2 Check if the set speed is correct Voltage too low during operation Motor rotating too Rotation speed and the set speed value vary widely The life of the inrush current Suppression circuit alarm LIFE2 The life of I _ Capacitor Control E Return the inverter for repair Circuit alarm 5 2 Inrush current suppression Return the inverter for repair circuit is damaged Main Circuit Capacitor life expectancy alarm Output side ground Fault Capacitor Main Circuit is damaged While output is connected to ground and grounding current flow through the circuit output of inverter will be stopped this protect function is set by 08 18 Return the inverter for repair 1 heck the motor winding resistance for failures 2 Check the motor cable for ground short circuits 5 1 2Keypad Operation Error Instruction Cause Corrective action Display content 1 Parameter already locked 2 Motor direction locked LII 3 Parameter password 13 07 enabled Keypad error available in failed Parameter conflict operation error Parameter setting Modification of parameter is not communication Communication 1 Attempt to modify frequency parameter while 13 0620 2 Attempt to reverse direction when 11 0071 3 Parameter 13 07 enabled set the correct password will show
113. eed potentiometer 10V Max current 2mA Multifunctional analog input available JP2 switching voltage or 250VAC 1A 30VDC 1A AM current input 10V Max current 2mA Voltage JP2 Switching AV1 position Input impedance 153 Current JP2 Switching position The analog input Multifunctional analog input available JP3 switching voltage or signal current input 0 10 0 20mA Voltage JP3 cut to AV2 position Input impedance 153KQ Current JP3 cut to Al2 position AGND The analog common terminal D Shielding wire connecting terminal The earth Multifunctional analog output terminal 3 0 10V Max current 2mA AGND The analog common terminal Safety Terminal SF is for safety switch SF can cut off the inverter Control circuit terminal 91 53 55 SF 24V All RIA Rib RIG 52 94 90 SG AGND 10V 3 43 JUMPER function description NPN Input NPN PNP JP 1 Factory defult setting PNP Input 0 20 4 20 Set parameters External signal type Analog signal 00 05 00 06
114. ent A Inductance mH 208 30 0 0 35 Specification Model 510 Current A Inductance mH 25 BA 6 2 Electromagnetic Contactor Circuit Breaker Molded case circuit Magnetic contactor MC Model 510 00 breaker made made by TECO by TECO O 2P5 1 TO 50E10A O TO 50E 10A 2141 1 TOS0E20 2 CN 11 20 5 O 210 TOIOSOA CNS 215 TO 400810A CN50 20 7 170 005104 amp x 4 0 TO 0E30 O 45 2 40 710 0504 5 ____ Po 710 055 2 6 1 6 3 Fuse Specification 229517304 60 45 1 70A 60VAC 40 IR 425 7 100A 00VAC I0KA LR 6 4 Brake Resistor Model Brake Cell Motor Specification F510 coo Capacity Parallel Parallel XXX Model Number KW W 0 Number 2P5 0 4 60 200 8 200 70 201 0 75 60 200 8 200 70 Minimum Resistor W Q TBU 430 Note Formula for brake resistor W Vpnb Vpnb ED Rmin 1 W braking resistor power Watts 2 Vpnb braking voltage 220V 380VDC 440V 760VDC 3 ED braking effective period 4 Rmin braking resistor rated ohms 6 5 Noise filter voltage 3 200V 096 05001 00 15 20 _ 097 08004 00 30400 7 5 10 15 096 05001 00
115. ention Level in 50 200 200 Run Mode Over Voltage 08 04 Prevention 350 0 390 0 700 0 780 0 b Level in Run Mode Electronic Motor 0 Enable Electronic Motor Overload Protection 08 05 Overload Protection 1 Disable Electronic Motor Overload Protecti 0 Operation Mode Disable Electronic Motor Overload Protection 0 Coast to Stop After Overload Protection is Operation After 08 06 Overload Protection is Activated 0 Activated 1 Drive Will Not Trip when Overload Protection is Activated OL1 0 Auto Depends on temp 08 07 Over Heat Protection 1 Operate while in RUN Mode cooling fan control 2 Always Run 3 Disabled 0 AVR Function Enable 1 AVR Function Disable 2 AVR Function Disable for Stop 3 AVR Function Disable for Deceleration 4 AVR Function Disabled for Stop and Regulation Deceleration 5 When VDC gt 360V AVR Function is Disabled for Stop and Deceleration Input Phase Loss 0 Disabled 08 10 Output Phase Losts 0 Disabled 0 Protection 1 Enabled 0 Overload protection Standard Motor rm 1 Overload protection Inverter Duty Motor 0 Motor Overload Protection for General loads Motor Overload OL 103 150 for 1 Minutes Protection Curve 1 Motor Over load Protection for HVAC Fan amp Pump OL 113 123 for 1 Minutes 1 Base on the percentage of inverter rated current 4 19 POPE Factory D t R escri
116. er and counter value The width of the trigger signal should be large Count value reaches the specified timing than 2ms diagram such as setting 03 11217 RY1 03 22 4 03 23 2 Set count to reach timing diagram such as setting 03 12 16 RY2 03 22 4 03 24 Low Current Detection Setting Range 0 disable 1 enable 03 25 Low Current Detection Level 5 100 03 26 Low Current Detection Delay Time 0 0 50 05 gt When 03 24 1 if output current lt low current detection level after a detection time set by 03 26 the keypad display will show error ud c 03 27 Pulse Frequency 0 01 1 00 Pulse Frequency Gain 0 01 9 99 4 47 04 00 Analog Voltage amp Current Input Selections 11 12 12 0 10 0 20 0 10 0 20 0 10V 0 20 2 10 4 20 2 10 4 20 0 10 0 20 2 10 4 20 2 10 4 20 gt Use JP2 JP3 to set analog signal type to voltage or current input Parameter 04 00 must set according to JP2 JP3 setting Analog input scaling formula as shown below Current Input Mode _ AI 0 20mA Hz aay 12 AI 4 20mA oo oy 00 12 1 gt 4 20 4 Voltage Input Mode V v AI 0 10V Hz 00 12 F Hz _ 20 Al 2 10V PME qm 12 V 22 04 01 AM Signal Verification Scan Rate Range 1 20002msec 0 1000 04 03 jJ
117. er 02 14 1 gt Auto tune function will set the inverter to run with the specific motor connected to obtain the best motor performance gt During the Auto tune AT will be displayed the inverter and there will be an automatic motor parameter mearurments which will be stored in parameters 02 15 02 16 gt After successful auto tune function the display will show End and the display will return to command frequency display Parameter 02 14 will reset to 0 gt Auto tune function must be carried out again if the motor is replaced 03 00 Multifunction Input Term S1 03 01 Multifunction Input Term 2 x 0 03 02 Multifunction Input Term 50 03 03 Multifunction Input Term 4 __03 04 Multifunction Term 95 03 05 MultifunctionInputTerm S6 0 0 0 Forward Stop Command Parameters 00 02 00 03 1 00 04 1 Reverse Stop Command Parameters 00 02 00 03 1 00 04 2 Preset Speed 0 Parameter 5 02 3 Preset Speed 1 Parameter 5 03 4 Preset Speed 2 Parameter 5 05 5 Preset Speed 3 Parameter 5 09 6 JOG Forward Command Parameters 00 18 00 20 7 JOG Reverse Command Parameters 00 18 00 20 8 Up Command Parameters 00 05 00 06 4 03 06 03 07 9 Down
118. erate through the digital keypad 5 5 5 3 Troubleshooting of the Inverter 5 3 1 Quick troubleshooting of the Inverter INV Fault Is fault known Symptoms other than burn out damage or fuse meltdown in the inverter Is the main circuit G B T intact Apply the power Are displays and indicators of the operating unit working normally NO Is LED lit NO pr charge resistor YES 5 the DC input voltage YES controlling the power NO Check terminas ang correct WEN YES 2 Rd Suen NO Consult with the supplier NO correct YES Replace control board to next page and digital operating unit Is the error eliminated after replacing control board Any fault display Perform detailed check and NO I I onsult with the supplier 5 6 5 Check Inverter parameters Perform parameter initializations opecify operation control mode Does the FWD or REV LED light flash YES oet up frequency command Is the frequency value displayed on the display YES Are there voltage outputs at terminals U V and W Connect the motor to run Is there any fault display Are output currents of each ohase even YES The inverter is OK Perform detailed check and consult with the supplier 5 7 5 3 2 Troubleshooting for OL error dis
119. essive Reduce the load Motor Confirm motor specifications running poles voltage correct speed too Is the gear ratio correct Confirm the gear ratio high or too 5 the setting of the highest low output frequency correct Confirm the highest output frequency 15 the load too excessive Reduce the load 1 Minimize the variation of the load Motor speed Does the load vary excessively 2 Consider increasing the capacities of the varies inverter and the motor unusually 1 Consider adding an AC reactor at the power Is the input power erratic 15 input side if using single phase power 2 there phase 1055 2 Check wiring if using three phase power Is the power connected to the 1 Is the power applied correct L1 L L2 and L3 N 2 Turn the power OFF and then ON again terminals 3 Make sure the power voltage 1 correct is the charging indicator lit 4 Make sure screws are secured firmly 15 there voltage across the output terminals T1 T2 and T3 Turn the power OFF and then ON again Reduce the load so the motor will run Motor can not run Are there any abnormalities in the inverter See error descriptions to check wiring and Is there a forward or reverse run correct if necessary command Has the analog frequency signal 5 INDUL SIRA 5 2 15 voltage of frequency input correct 15 the operation mode setting corect Op
120. f voltage and current modes share two parameters of DC braking frequency 07 06 and DC braking time 07 08 Parameters 1 07 15 is used to select DC braking mode voltage mode or current mode 2 07 16 is used to set the DC braking level in the voltage mode 08 00 Trip Prevention Selection xxxx0 Enable Trip Prevention During Acceleration xxxx1 Disable Trip Prevention During Acceleration xxx0x Enable Trip Prevention During Deceleration xxx1x Disable Trip Prevention During Deceleration Range 0 Enable Trip Prevention in Run Mode xx1xx Disable Trip Prevention Run Mode x0xxx Enable over voltage Prevention Run Mode x1xxx Disable over voltage Prevention in Run Mode 08 01 Trip Prevention Level During Acceleration 50 2001 gt Trip prevention adjustment level during acceleration to prevent over current OC A trips gt prevention during acceleration is enabled and an over current occurs due to the load then the acceleration is interrupted until the over current level is dropped below the setting in 08 01 then the acceleration is resumed 08 02 Trip Prevention Level During Deceleration 50 200 gt Trip prevention adjustment level during deceleration to prevent over Voltage OV C trips gt prevention during deceleration is enabled and an over voltage occurs during stopping due to the load then the deceleration is interrupted until the over voltage level is dropped below
121. ftware or PDA WinCE base software for download to E510 E510 Inputs and outputs can be set for PLC functionality Soeed functions can be set using the built in PLC functionality PLC function is selected by setting inverter Run mode by parameter 00 00 3 Inputs be set by parameters 03 00 03 05 24 PLC Application 4 4 1 Basic Instruction Set PE ft fv fe A Input Instruction 1 16 11 46 Output Instruction Q Q Q1 Q2 qt q2 SpecialRegister 1 Counter Instruction 1 1 Timer Instruction T J T Instruction s Instruction ADD DEC Instruction AS Mul DIV Instruction MD j 4 __ Description for Special Register V1 Setting Frequency Range 0 1 650 0 2 V2 Operation Frequency Range 0 1 650 0 2 V3 Al1 Input Value Range 0 1000 V4 AI2 Input Value Range 0 1000 V5 Keypad VR Input Value Range 0 1000 V6 Operation Current Range 0 1 999 9 VT Torque Value Range 0 1 200 0 Other Upper differential Lower differential Instruction Symbol Differential Instruction d mif ET Instruction RESET Instruction 1 Instruction Open circuit status Short circuit Off status e Connection symbol Description Connecting left and right Components es left right and uppe
122. function as the Reset button on keypad 13 03 00 03 05 18 Auto Run Mode When an input terminal is set to function 18 the programmable auto sequencer function is enabled Refer to description of parameter group 6 14 03 00 03 05 19 Speed Search Stop When starting the inverter detects the current speed of the motor and then accelerates from the current speed to target speed 15 03 00 03 05 20 Energy saving operation FAN PUMP or other high inertia loads need greater starting torque but once the operational speed is reached they need much less torque In this mode the output voltage to the motor is reduced to match the required torque demand hence providing a saving in energy The output voltage gradually declines as the input is ON It will gradually increase to the original voltage when the input is OFF The acceleration and deceleration speed of energy saving operation is the same as the speed of speed search 16 03 00 03 05 21 Reset PID Integral value to Zero When the extermal terminals S1 to S6 set to 22 after turning it on then off once the counter value increases by 1 17 03 052 22 Pulse Input When the extermal terminals S1 to S6 set to 22 after turning it on then off once the counter value increases by 1 Indication value 0000 0001 c0002 c0003 0004 0005 c0001 0002 12 00 28 Pulse Input Multi function input terminal ams 72 The trigger timing can t Signal
123. g the EMC filter link will disable the filter function please consult your local EMC standards requirement 3 57 3 9 The Dimension and Installation of Keypad 3 9 1 Description of dimension and installation The operator is LED type which can be pulled outwards The description of dimension and installation is shown as the followings Dimension OO 14 7 3 58 Disk installation diagram The depth of each screw M3 is greater than the screw holes of 6mm 42 2 015 Here is the slot to connect line of RJ45 63 020 15 2903015
124. icity didn t keep Mode 3 Count value locked Off electricity keep Mode 4 Count value unlocked Off electricity keep 1 Counter Mode 1 1 1 Input count pulse 2 OFF ON OFF ON 3 ON OFF ON 6 Sample Input under the Ladder Program Mode 2 2 S 9 1 2 a Input count pulse 2 3 ON 6 Note When the target value is reached C3 ON The input point C3 in the Ladder program The ON OFF of C3 input count Pulse is controlled by and 12 should be ON ON OFF ON OFF ON ON OFF Under this Mode the counting present value appeared will be greater than 20 unlike theMode 1 in which the value is locked at 20 1 The counter Mode 3 is similar to the counter Mode 1 except that the former can save the value after the power is cut off and continue counting when the power is turned on at the next time 2 The counter Mode 4 is similar to the counter Mode 2 except that the former can 4 81 memory the recorded value after the power is cut off and continu counting when the power is turned on at the next time Model amp 2 111122 Mode3 amp 4 Input count pulse Power switch 6 2 Timer Timi
125. ignal Type 0 d n 20mA 0 10V 0 20mA Select AI1 AI2 AION aA _ 0 10V 0 20mA 2 10 4 20 2 10 4 20 0 2 2 40V 4 20mA 0 10 0 20 20mA FRE gni 1 2 10 4 20mA 2 10V 4 20mA 04 01 Signal Verification Scan Rate Ko H 50 2 04 02 Gan 50 00 10 04 03 04 04 Alt Bias Selection 04 07 2 94 08 LAD Bias 04 09 2 Bias Selection 0 Positive 1 Negative __ 0 Slope Positive i Negative O 0 Output Frequency 1 Frequency Command 04 11 Analog Output AO Mode 2 Output Voltage 0 1 3 4 Motor Current 100 rated current 04 12 Analog Output AO Gain 04 13 Analog Output Bias 0 100 4 4 4 0 Jaja 04 14 Bias Selection 0 Positive o 04 15 AO O Postie 4 Negative Jo 04 16 F Gain Function 0 Invaid tt Effective J J 4 13 _ Factory D t R w m 0 Accel Decel Preset Speed Control Accel Decel 1 or 2 apply to all speeds Mode Selection 1 Individual Accel Decel for each preset speed 0 15 apply to the selected preset speeds Preset Speed 0 Keypad Freq 15 15 Preset Speed1 Hz 05 03
126. ing Value3 of AS4 0 65635 Jo 14 36 Setting Value1 of MD 0685 1 d _ 14 37 Set ngValue2of MD 0506895 1 d Setting Value3 of MD1 1 65535 Ja 14 39 Setting of MD2 10 65535 1 d 14 40 Setting of MD2 10 65535 1 d _ 14 41 Setting 1688 1 14 42 Setting Value1 of MD3 05065885 1 Setting Value2 of MD3 0 656 Ja 14 44 Setting Value3 of MD3 16885 1 1 1 1445 Setting Value1 of MD4 0 6535 Ji J J 4446 Setting Value of MD4 cess t 14 47 Set ngValue3of MD4 11 65535 1 1 1 4 25 m Factor 15 00 CurrentValueofT1 0 9999 __ _ ___ 15 01 Current Value of T1 mode 7 7 0 9909 021 142 15 02 CurentValueofT2 7 0 9999 021 442 oz 15 04 CurentValueof T3 0 9999 NEN 15 05 Current Value of T3 mode7 0 9999 0214 44 15 06 CurentValueofT4 0 9999 __ _ 15 07 Current Value of T4 mode 7 0 9999 0 15 08 CurrentValueofT5 0 9999 021 142 15 09 Current Value of T5 mode 7 0 9999 021 442 15 10 CurentValueofT 7 0 9999 021 4142 15 11 Current Value of 6 7 770 9999 021 142 15 12 Current Value of T7 0 9999 021 142 0 9999 o OUT _ 15 14 CurrentValueofT8 0 9999 __ _ 4515 CurenVaeofTS mode7 o 1546 CurrentValueofC1 0655 065535 Jo
127. ion 02 Station 03 Station FE Option Card Option Card Option Card Option Card The network is terminated at each end with an external terminating resistor 1200 1 4w 1 2 Data format ASCII MODE Start bit 3AH Communication Address Station 2 digit ASCII Code Function Code command 2 digit ASCII Code command Start byte Command Start Address Data length The length of the command Data length a Data length 4 digit ASCII Code Data length LRC Check Code LRC Check Lo 2 digit ASCII Code END Hi End Byte END Lo END Hi CR ODH END Lo App3 1 MASTER PLC etc send request to SLAVE whereas response to SLAVE MASTER eres The signal receiving is illustrated here The data length is varied with the command Function Function Code DATA CRC CHECK Signal Interval The interval should be maintained at 10ms between command signal and request 1 3 SLAVE Address Broadcast to all the drivers 01H to the No 01 Drivers OFH to the No 15 Drivers 10H to the No 16 Drivers and so Max to 32 20H 1 4 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 2 CMS Checksum and time out definition 2 1 LRC CHECK ex ADDRESS 01H FUNCTION 03H COMMAND 01H DATA LENGTH OAH OF H true complement Checksum CS H 46H ASCII
128. justment and maintenance of AC drives Do not perform work on the drive while wearing loose clothing jewelry or lack of eye protection Failure to comply could result in death or serious injury Remove all metal objects such as watches and rings secure loose clothing and wear eye protection before beginning work on the drive Do not remove covers or touch circuit boards while the power is on Failure to comply could result in death or serious injury Fire Hazard Tighten all terminal screws to the specified tightening torque Loose electrical connections could result in death or serious injury by fire due to overheating of electrical connections Do not use an improper voltage source Failure to comply could result in death or serious injury by fire Verify that the rated voltage of the drive matches the voltage of the incoming power supply before applying power Do not use improper combustible materials Failure to comply could result in death or serious injury by fire Attach the drive to metal or other noncombustible material NOTICE Observe proper electrostatic discharge procedures ESD when handling the drive and circuit boards Failure to comply may result in ESD damage to the drive circuitry Never connect or disconnect the motor from the drive while the drive is outputting voltage Improper equipment sequencing could result in damage to the drive Do not use unshielded cable for control wiring Failure to co
129. lation results RESULT addend V1 AS1 AS4 MD1 MD4 1T1 T8 C1 C8 V1 V7 constant addend V2 AS1 AS4 MD1 MD4 11 T8 C1 C8 V1 V7 constant filamentous V3 AS1 AS4 MD1 MD4 11 T8 C1 C8 V1 V7 constant RESULT V1 V2 V3 Sample Input under the Ladder Program Mode ro icd EMI i Y ON OFF of I1 controls the Run Sto n ASI lt 1 CON status of ASI 1 1 l Miis coil error gt if the RESULT is more than the Nees upper limit 65535 or Below the lower limit 0 _ _ _ _ Input under the Function Program Mode RESULT of AS1 Note if the RESULT is more _ 777 than 65535 Here can only display 6553555 the RESULT is less than lower limit of 0 4 87 6 MUL DIV module multiplierA AS1 AS4 MD1 MD4 T1 T8 C1 C8 V1 V7 constant divisor AS1 AS4 MD1 MD4 T1 T8 C1 8 1 7 constant Error signal coil output NOP 1 Instruction code of MUL DIV module multiplierB AS1 ASA MD1 MD4A T1 T8 C1 C8 V1 V7 constant RESULT V1 V2 V3 Sample Input under the Ladder Program Mode mA ON OFF of controls Run Sto MD1 l P status of MD1 Q1 is coil error gt if the RESULT is more than the upper limit 65535 or Below the lower limit
130. ld wiring terminals not located within the motor circuit shall be marked to indicate the proper connections that are to be made to each terminal and indicate that copper conductors rated 75 C are to be used B Drive Short Circuit Rating This drive has undergone the UL short circuit test which certifies that during a short circuit in the power supply the current flow will not rise above value Please see electrical ratings for maximum voltage and table below for current The MCCB and breaker protection and fuse ratings refer to the preceding table shall be equal to or greater than the short circuit tolerance of the power supply being used e Suitable for use on a circuit capable of delivering not more than A RMS symmetrical amperes for Hp Hp in 240 480 V class drives motor overload protection mmm mE Horse Power Hp Current A Voltage V 1 50 5 000 240 480 Appendix 1 Instructions for UL Drive Motor Overload Protection Set parameter 02 01 motor rated current to the appropriate value to enable motor overload protection The internal motor overload protection is UL listed and in accordance with the NEC and CEC B 02 01 Motor Rated Current Setting Range Model Dependent Factory Default Model Dependent The motor rated current parameter 02 01 protects the motor and allows for proper vector control when using open loop vector or flux vector control methods 00 00 1 The motor protection parameter 08 05 is
131. le If 10 21 100 and 10 22 50 and the unit for the range from 0 to 999 will be defined with the parameters setting of 12 02 actual feedback value variation range will be scaled to 50 and 100 only for display as Shown below 999 10 21 100 10 22 50 gt Min 0 100 0 0 2V AmA 10V 20mA 4 68 11 00 Prevention of Reverse operation Range 0 Reverse command is enabled 1 Reverse command is disabled 11 00 1 the reverse command 1 disabled NEU TUI I P Range While IGBT driven inverter can provide low noise working environment the high frequency devices have carrier frequency waveform cutting it may interfere with external electronic device even caused vibration when connected with motor then need to adjust the carrier frequency 11 02 Cariermodeseletion 0 mode0 3 phase PW M modulation 1 Carrier mode1 2 phase PW M modulation 2 Carrier mode2 2 phase randomized PW M modulation Mode 0 3 phase PWM Modulation Three Output transistors on at the same time Full Duty Mode 1 2 phase PWM Modulation Two output transistors on at the same time 2 3 Duty gt Mode 2 Random PWM Modulation This modulation method will use 3 phase PWM and 2 phase PWM modulation in a random mode Heat Torque UE d 3 PWM 100 1 2 Phase PWM 66 6 2 Randomized PWM pe Weel Medium Medium Medium Medium amp mode
132. loss ride through function is selected by 07 0071 and also the Run command is set to external switch 00 02 71 to avoid any danger to persons on power recovery must ensure that the power and Run switch are in off position 07 13 Main Circuit Low Voltage Detection Range 220V Class 150 0 210 0 440V Class 300 0 420 0 07 14 Kinetic Energy Back up Deceleration Time KEB Range 0 0 Disable 0 1 25 0 KEB Deceleration Time gt 07 14 0 KEB function disable gt 07 1420 KEB function enable Example 220V system External power Signal when 03 00 03 05 27 2 51 56 Voltage When 07 1470 gt Voltage below 190V function work T 0 gt Decelerationg 07 14 Note 1 When 07 1440 the momentary power loss and restart is disabled the inverter will function 2 When input power is turned off CPU detects the DC bus Voltage and as soon as DC bus Voltage becomes lower than190V 220V system 380V 440V system then the KEB function is activated 3 When KEB function is enabled the inverter decelerate to zero by 07 14 and the inverter stop 4 IF the power on signal enabled during the KEB function the inverter accelerate to original frequency 4 61 07 15 DC Break Select 0 Current Mode 1 Voltage Mode Note DC braking functions o
133. minals T1 T2 and T3 to AC input power will damage the inverter Output terminals T1 T2 and T3 are connected to U V and W terminals of the motor To reverse the motor rotation direction just swap any two wires at terminals T1 T2 and T3 Ground the Inverter and motor correctly Ground Resistance for 200V power 100 Ohms Ground Resistance for 400V power 10 Ohms Three phase induction motor Voltage drop on motor due to long cable can be calculated Volts drop should be lt 1090 Phase to phase voltage drop V 1 3 xresistance of wire O km xlength of line m xcurrentx107 3 25 3 3 6 Ground connection Inverter ground terminal must be connected to installation ground correctly and according to the required local wiring regulations gt gt gt gt 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 high power motors Ground each unit separately Ensure that all ground terminals and connections are secure Do not make ground loops when several inverters share a common ground point Note Please leave at least 5cm while installing inverter side by side in order to provide enough cooling space a Correct b Correct c Incorrect 3 26 3 3 7 Inverter exterior 3 3 7 1 IP20 NEMA 1 exterior a Single Three phase 200V 0 5 1HP Single
134. mply may cause electrical interference resulting in poor system performance Use shielded twisted pair wires and ground the shield to the ground terminal of the drive Appendix 1 Instructions for UL NOTICE Do not modify the drive circuitry Failure to comply could result in damage to the drive and will void warranty Teco 15 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 Failure to comply could result in damage to the drive UL Standards The UL cUL mark applies to products in the United States and Canada and it means that UL has performed product testing and evaluation and determined that their stringent standards for product safety have been met For a product to receive UL certification all components inside that product must also receive UL certification UL 5 LISTED UL cUL Mark UL Standards Compliance This drive is tested in accordance with UL standard UL508C and complies with UL requirements To ensure continued compliance when using this drive in combination with other equipment meet the following conditions m Installation Area Do not install the drive to an area greater than pollution severity 2 UL standard B Main Circuit Terminal Wiring UL approval requires crimp terminals when wiring the drive s main circuit te
135. n is positive the output frequency increases and vice versa For 10 03 3 or 4 If the deviation is positive the output frequency decreases vice versa 10 04 Feedback Gain Coefficient 0 00 10 00 gt 10 04 is the calibration gain Deviation set point feedback signal 10 04 Proportional Gain Range 0 0 10 0 gt 10 05 Proportion gain for P control 10 06 Integral Time 0 0 100 0 Sec gt 10 06 Integrate time for control 10 07 Range 0 00 10 00 Sec gt 10 07 Differential time for D control 10 08 PID Offset 0 Positive Direction Range 1 Negative Direction PID Offset 1009 0 109 10 08 10 09 Calculated PID output is offset by 10 09 the polarity of offset is according to10 08 Range 100 2555 gt 10 10 Update time for output frequency Feedback Loss Detection Mode 0 Disable 1 Enable Drive Continues to Operate After Feedback Loss an 2 Enable Drive STOPS After Feedback Loss gt 10 11 0 Disable gt 10 112 1 On feed back loss detection continue running and display PDER gt 10 11 2 feed back loss detection stop and display PDER Feedback Loss Detection Level Range 10 12is the level for signal loss Error Set point Feedback value When the error is larger than the loss level setting the feedback signal is considered lost Feedback Loss Detection Delay Time Range 0 0 25 5 Sec 10
136. nalog6 A257h A259h Analog3 A24Eh A250h Analog7 A25Ah A25Ch Analog4 A251h A253h Analog8 A25Dh A25Fh App4 8 4 Control Instruction 12Byte A260h A28Fh 8groups Control1 A260h A265h Control2 A266h A26Bh Controls A278h A27Dh_ Controle A27Eh A288h Controls _ A26Ch A27ih A284n A289h Contro4 A272h A277h A28Ah A28Fh 5 Add Subtract 1Obytes A290h A2A3h 4groups Add Subtract1 A290h A294h Add Subtract2 A295h A299h Add Subtract3 A29An A29Eh Add Subtract4 A29Fh A2A3h 6 Multiply Divide 10bytes A2A4h A2B7h 4groups Multiply Dividet A2A4h A2A8h Multiply Divide2 A2A9h A2ADh Multiply Divide3 A2AEh A2B2h Multiply Divide4 A2B3h A2B7h App4 9 7 PLC RUN2A600h CLEAR MEMORY 2A601h RUN amp STOP CLEAR PLC MEMORY RS PLC Operation instruction Bit 0 0 PLC stop 1 PLC Run PLC ALL MEMORY CLEAR Bit 0 0 Disable 1 Enable App4 10 Appendix 5 JN5 CM USB instruction manual 1 Model number and specification 1 1 Model number and function instruction JN5 CM USB can transform the communication format from USB to RS485 Inverter can communicate with PC or other devices via USB communication port 1 2 Dimensions of JN5 CM USB 1800 1 5 5 1 2 Communication port and
137. ncy 0 00 10 00 ee de 01 12 Slip compensation gain 0 05 10 00 0 10 01 13 Mode Select 0 0 1 Mode1 Jo ee Factory D t R 02 00 Motor No Load Current 0 02 01 0 1 NENNT 02 01 Motor Rated 1 0 2 100 Motor rated Slip 0 0 200 0 fe Compensation 02 03 Motor rated speed 0 39000 200V 170 0 264 0 0204 Motor rated voltage 400V 323 0 528 0 220 0 440 0 02 05 Motor rated power 0 1 37 0 02 06 Motor rated frequency 0 650 0 0 60 0 Motor pole number 2 16 02 08 02 13 Auto Tune 0 Disable 1 Start Auto tune function 02 15 Stator resistance gain ee 11 02 16 Rotor resistance gain j 4 10 03 00 Multifunction Input Term 51 Command 0 03 01 Multifunction Input Term 52 1 Reverse Stop Command 1 03 02 Multifunction Input Term 53 2 PresetSpeed 0 5 02 J2 03 03 Multifunction Input Term 54 3 Preset Speed 16 03 3 03 04 Multifunction Input Term 55 4 Speed 2 0 J4 5 Preset Speed 3 5 09 6 Jog Forward Command 7 Jog Reverse Command 8 Up Command 9 Down Command 10 Acc Dec 2 11 Acc Dec Disabled 12 Main Alternative run source select 13 Main Alternative Frequency Command select 14 Rapid Stop Decel to stop 15 Base Block 16 Disabl PID Functi
138. ng frequency 0 Q E Actual acc time Actual dec time Acc time x Dec time T 00 14 00 15 00 18 Jog Frequency 1 00 25 00 Hz 00 39 Jog Acceleration Time Range 00 20 Jog Deceleration Time Range gt The JOG function is operational by using the multi function input terminals S1 to 56 and setting the relevant parameters 03 00 03 05 6 JOG FWD or 7 JOG REV Refer to parameter group 3 4 29 01 00 _ Volts Hz Patterns gt Set 01 00 to one of the following preset selections 0 17 according to the required application gt Parameters 01 02 01 09 are not applicable gt Six fixed patterns are shown below 1 8 50 Hz systems and 9 17 for 60 Hz General Use 1 52 5 50 650 Hz 50 650 Hz 5 2 lt D L Decreasing torque 50 650 Hz 60 650 Decreasing torque 50 650 Hz 60 650 Hz 4 30 100 is the maximum output voltage point preset settings will be table below 2201 0 1 _____ 2 J 11054 1 855 2 o 4 115 22 406 5 1206 5 11 2 120 9 ____ 44 2856 Setting 01 00 18 provides a flexible V F curve which can be selected by experienced users by setting parameters 01 02 01 09 0 01 VIF Max Voltage S 200V 170 0 264 0 400V 323 0 528 0 V 01 02 Maximum Frequency
139. ng unit gt Use 11 8 to RESET the timing value the counter is reset to zero and OFF OFF the counter continues to count the counter continues to OFF the counter continues to count Timing Value Target setting Timing Values AS1 AS4 MD1 MD4 T1 T8 C1 C8 V1 V7 count The code of the Timer 1 T8 total 8 groups 1 Timer Mode 1 ON Delay Timer Mode Enable reset relay 4 Enable reset relay Present value 0 gt Timer starts operating Preseniwaluc 0 OFF ON OFF t Timing up output CTI T8 CIE 5 Timing enable relay t Target value set in the timer 4 82 Sample Input under the Ladder Program Mode n operating T5 gt 01 Input under function Program Mode Timing unit 0 1sec Timer Model When the time reaches to the target value 2 2 10 0 sec T5 is ON pee 1 gt 000 0 d 010 0 OTs p value in timer Present value in mer 2 Timer Mode 2 ON Delay Timer Mode2 Enable reset relay 4 Enable reset relay Present value 0 Timer starts operating Present value 0 ON OFF Timing enable relay t2 t t1 t2 Timing up output 8 ON OEE 3 Enable reset relay OFF ON OFF t Target value set in the timer 3 Timer Mode OFF Delay Timer Mode Present value 0 gt Timer starts operating Present value 0 OFF ON OFF Timing enabl
140. oltage range V Three phase 0 240V _______ 11 205 33 42 57 70 ______ 46 25 65 6 5 10 1 104 Allowable momentary power loss time S __2 0 20 20 2 0 2 0 20 Frame Size input current is calculated value at full rated output current 3 34 400VClass Three phase Model E510 couo H3 F N4 S Horse power HP Suitable motor capacity KW 075 15 22 37 Rated output current 23 38 52 88 Rated capacity KVA 17 29 40 67 5109 1524 ________ 42 56 73 116 ______ 47 17 25 25 Allowable momentary power loss time 5 20 20 20 20 IP20 NEMA1 IP66 NEMA4X Depending on models FemeSze ______ ___1 2 510 4 408 410 415 420 425 Hosepowr H 75 40 15 20 25 Suitable motor capacity KW 55 75 11 15 185 Rated output current A 13 0 17 5 24 40 Rated capacity KVA 9 9 133 191 274 34 1096 1596 aray as hverernetweight KG 67 67 67 _ gt aa IP20 NEMA1 IP66 NEMA4X Depending on models Frame Size input current is calculated value at full rated output current F Built in filter N4 Protection class IP66 without built in power switches and
141. on 17 Fault Reset 18 Auto Run Mode Enable 19 Speed Search 20 Energy Saving only V F 21 Reset PID integral value to Zero 22 Counter Input 23 Counter Reset 24 PLC Input 25 Pulse Input Width Measure S3 26 Pulse Input Frequenct Measure S3 2 Enable KEB Function 28 Fire mode function Valid for software issued after rev 1 1 03 06 Up Down frequency step 0 00 5 00 0 00 0 When Up Down is used the preset frequency is held as the inverter stops and the UP Down function is disabled 03 07 Up Down Keep Frequency Status 1 When Up Down is used the preset after Stop Command frequency is reset to 0 Hz as the inverter stops 03 05 Multifunction Input Term S6 N 2 When Up Down is used the preset frequency is held as the inverter stops and the UP Down is available 03 08 51 56 scan confirmation 1 200 Number of Scan cycles 0 51 xxxx1 S1 NC 0 52 1 52 NC 51 5 switch type select 0 53 xx1xx S3 NC 54 NO 1 54 NC 55 55 NC 03 10 56 switch type select xxxx0 S6 1 56 NC 00000 Output Relay RY 0341 Terminals R1A R1B 0 ma gt gt Factory D t R escription ange Setting 1 Fault 2 Setting Frequency Reached 3 Frequency Reached Set by 3 13 3 14 4 Output Frequency Detection1 gt 13 5 Output Frequency Detection2 lt
142. peed This will avoid longer than required deceleration time 08 08 4 AVR function disabled for stop and deceleration 08 08 5 When VDC gt 360V 200V class or gt 740 400 class AVR function is disabled for stop and deceleration 08 09 Input Phase Loss Protection Range 0 Disabled 1 Enabled gt When 08 09 1 phase loss warring message is displayed 08 10 Output phase lost protection Range 0 Disabled 1 Enabled gt When 08 10 1 On output phase loss warning message LF is displayed 08 11 Motor type selection 0 Electronic relays protect standard motor 4 63 11 Electronic relays protect inverter duty motor Motor Overload Protection Curve Selection 0 Constant Torque OL 103 150 for 1 Minute 1 Variable Torque OL 113 123 for 1 Minute gt When 08 11 0 Set 02 06 as the rated frequency of the motor gt When 08 12 01 Overload protection for motors used in general purpose applications as long as the load demand is less than 103 of the rated current the motor continues to run If the load is larger than 150 rated current the motor will run for 1 minute only Refer to following curve1 on page 4 61 gt When 08 12 1 Overload protection for motors used in HVAC applications FAN PUMP so on as long as the load demand is less than 113 of the rated current the motor continues to run If the load is larger than 123 rated current th
143. plays The inverter displays OC OL errors Is the main circuit I G B T working YES Replace faulty circuit 2 Any visual abnormalities Apply power Replace the current controller Replace G B T 15 the current detector OK Any abnormal indications Input operation command Is FWD LED illuminated YES Input frequency command Is the output frequency of the operating unit displayed YES Is there Voltage at U V and W output terminals Connect the motor to run Any fault values displayed NO Is the output current of each phase even YES The inverter output is OK Replace control board The inverter is faulted Perform detailed check 5 8 5 3 3 Troubleshooting for OV LV error The inverter displays OV LV 15 the main circuit fuse intact Consult with the supplier zZ Q YES Any visual abnormalities NO Apply power Any abnormal indications Consult with the supplier Input operation command Is FWD LED still illuminated after flash NO Consult with the supplier YES Input frequency commands Is the output frequency of the operating unit displayed NO Replace the control board Replace the control board YES Is there Voltage at 1 2 3 output terminals YES Connect the motor to run NO Any abnormal value NO Is the current on all phases even YES NO The in
144. ption ange Setting 0 Over Torque Detection Disabled 1 Detected After the Setting Frequency 2 Detected When Running 0 Stop Output After Over Torque Detection Over torque protection Free Run to Stop action 1 Continue Running After Over Torque Over Torque Detection Control Detection Display only OL3 Over Torque Detection 30 300 Level Over Torque Detection 0 0 25 0 Time O Disabled 08 17 Fire Mode 1 Enabled 0 Disabled 1 Enabled Notes Regarding fire mode function please refer to the conditions below 1 Before the software rev 1 1 the fire mode 1 funtional when 08 17 1 08 16 08 18 Ground Fault Detection After the software 1 1 the firemode is functional when 03 00 03 05 28 2 3 The display will indicate FIrE 4 Under fire mode function the inverter will run at full speed Factory D t Assigned Communication 1 32 O RTU Code Station Number RTU ASCII Code Selection 2 1 ASCII Code 0 4800 1 9600 Baud Rate Setting bps 2 19200 2 bps 128 3 38400 0 1 Stop Bit B 299 1 2 Stop Bits 0 Without Parity Parity Selection 1 With Even Parity 2 With Odd Parity 0 8 Data Data Format Selection 1 7 Bits Data 09 06 in Time Out 00 25 5 Detection Time 0 Deceleration to Stop 00 15 Deceleration Time 1 Communication Time Out 1 Coast to Stop Operation Selection 2 Deceleration to Stop 00 17 Deceleration Time 2 3 Con
145. pts 0 Enable Reset Only when Run Command is Off 07 03 Reset Mode Setting 1 Pn Reset when Run Command is On or 07 04 Direct Running on 0 Direct run on power up Power Up 1 Disable Direct run on power up 07 05 Delay ON Timer 1 0 300 0 DC Injection Brake Start 07 06 Frequency Hz In Stop 0 10 10 00 1 5 Hz Mode DC I Brake _ 07 08 Time Seconds 0 0 25 5 0 5 In Stop Mode 0 Deceleration to stop 07 09 Stopping Method 1 Coast to stop o 07 10 Starting Methods 0 Normal Start 1 Speed Search 07 11 TURNO 0 Speed Search 1 Normal start restart after fault Power Loss Ride Main Circuit Low 190 0 3 07 14 Kinetic Energy Back up 9 995 9 KEB Deceleration Time Sec Deceleration Time 07 15 DC Break Select 0 Current Mode 1 Voltage Mode 1 __ Voltage 4 18 t R Setting Enable Trip Prevention During Acceleration Disable Trip Prevention During Acceleration Enable Trip Prevention During Deceleration Disable Trip Prevention During Trip Prevention Deceleration 08 00 221 Enable Trip Prevention in 01000 9 Disable Prevention Run Mode Enable Over Voltage Prevention in Run Mode Disable Over Voltage Prevention in Run Mode 08 01 Prevention Bevel 50 200 200 During Acceleration 08 02 Prevention adu 50 200 200 During Deceleration 08 03 Trip Prev
146. r Components JConnecting left right upper and lower Components Connecting left right and lower Components 4 4 2 Function of Basic Instructions Function D d Command Sample 1 11 0 T Q1 I1 OFF ON OFF D OFF ON OFF lt gt One complete scan period 1 Sample 2 i1 d Q1 D ON OFF 1s the reverse phase of 11 il ON OFF ON di OFF ON OFF lt gt One complete scan period Q1 OFF ON OFF NORMAL Output I1 Q1 n OFF ON OFF Q1 OFF ON OFF SET Output 4 Q1 ON OFF 01 RESET Output 1 n OFF ON OFF ON OFF P Output i1 PQ1 OFF on oN OFF 1s the reverse phase of 11 Q1 ON OFF ON OFF 4 79 4 4 3 Application Instructions 1 Counter Mode 133 Counting Mode 1 4 Use f8 to set counting up or down OFF counting up 0 1 2 3 4 ON counting down 3 2 1 0 gt Use F8 to RESET the counting value ande OFF OFF the counter continues to count 6 jPresentCounting Value Target Setting Value AS1 AS4 MD1 MD4 T1 T8 C C8 V1 V7 count 0 65535 e ode of the counter C1 total EN groups Mode 1 The count value is locked to the set value Off electricity didn t keep Mode 2 Count value unlocked Off electr
147. r Continuous Run gt Set S2 For Forward Reverse direction selection gt Set multi function terminals 53 54 4 S5 for setting three different preset speeds Hz A 05 03 speed2 FWD Preset i Speed1 Preset i speed3 Preset 1 i Preset speed5 5 gt T gt lt gt f Preset g speed4 RUN RUN STOP comman 52 S3 OFF ON OFF ON OFF ON ON S4 OFF OFF ON ON OFF OFF OFF S5 OFF OFF OFF OFF ON ON OFF When the run command is continuous acceleration and deceleration times for each segment can be calculated as below 05 17 05 01 05 19 05 02 05 01 05 21 05 03 05 02 01 02 01 02 01 02 05 24 05 03 05 04 05 26 05 05 05 25 x 05 05 01 02 01 02 01 02 _ 05 28 05 05 05 27 05 06 05 28 05 06 g 01 02 hz 01 02 01 02 777 4 55 06 00 Auto Run sequencer mode selection Disabled Range Single cycle Continues to run from the unfinished step if restarted Periodic cycle Continues to run from the unfinished step if restarted Single cycle then holds the speed of final step to run Continues to run from the unfinished step if restarted Single cycle Starts a new cycle if restarted Periodic cycle Starts a new cycle if restarted Single cycle then hold the speed of final step to run Starts a new cycle
148. rameter 13 03 reaches 24 hours gt recorded value in accumulator 2 parameter 13 04 changes to 1 day and the value in accumulator 1 is reset to OOOO 13 6 __ Parameter Lock 0 0 Enable all Functions 1 Preset speeds 05 01 05 15 cannot be changed 2 All Functions cannot be changed Except 05 01 05 16 3 Disable All Function Except 13 06 When the 13 07 00000 not set a password you can adjust the parameters 05 01 05 016 from 13 06 gt When a parameter lock key number is entered in parameter 13 07 For any parameter modification the key number has to be entered See following Parameter lock key setting example 4 74 gt Setting Parameter lock key number example Step1 Ist entr Bie Step2 gt A Set Password successfully Key code password unlock Password failed to lift 13 11 HUE a UO Password successfully lifted 13 08 Reset Drive to Factory Settings 1150 Reset to factory setting 50Hz system 1160 Reset to factory setting 60 Hz system 1112 RESET PLC When a Parameter lock key number has been entered in parameter 13 07 This key number must be entered first before parameter 13 08 capable to be used 4 75 14 00 jSetingvalueof Tl 0 14 01 SettingvaluetofT1 mode7 1 14 02 jSetingvalueiofT2 14 03
149. re cable 6 Separate Protective Earth wire routed outside motor cable separated be at least 100mm this 15 the preferred method specially for large outout cables and long length Multi core screened 3 core amp protective earth can be used for small power and short length 7 Connect the cable shield by a good 360 termination and connect to the motor protective earth terminal This link must be as short as possible 8 Motor Earth terminal Protective Earth 3 23 3 3 4 Failure liability gt 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 gt correctly rated Fuse or Circuit breaker has not been installed between the power source and the inverter gt contactor a phase capacitor burst absorber and LC RC circuits have been connected between the inverter and the motor gt incorrectly rated three phase squirrel cage induction motor has been used Note When one inverter is driving several motors the total current of all motors running simultaneously must be less than the rated current of the inverter and each motor has to be equipped with a correctly rated thermal overload relay 1 Only Intended For Use In A Pollution Degree 2 Environment or equivalent 2 Since there is no over speed protection there will be no liablity due to
150. requency Wain 0 Main or Alternative Frequency Erecuency Command 1 Main Frequency Alternative Frequency 0 00 650 00 4 Save Power Down 1 Enable O by Current Frequency Command 1 by 0 Frequency Command 00 07 2 Initial Frequency Selection keypad mode 2 by 00 11 00 11 Initial Frequency Setpoint 0 00 650 00_ 50006000 Hz 00 12 Frequency Upper Limit ____ 0 01 650 00 50 00 60 00 Hz 00 13 Frequency Lower Limit 0 00 649 99 00 14 Acceleration Time 1 04 36000 i 00 15 DecelerationTimet 04 600 10 0 5 7 00 16 Acceleration Time2 0 1 36000 100 sec 1 1 00 19 Jog Acceleration Time 04 255 05 Sec i 00 20 Jog Deceleration Time 9125 Ter Factory D t R Setting cS 01 00 Volts Hz Patterns 200V 170 0 264 0 V F Max voltage 400V 323 0 528 0 220 0 440 0 01 02 Max Frequency 7 020 6000 500060404 Hz 01 03 Frequency Voltage 00 100 19090 01 04 Mid Frequency2 _________ 010 65000 25003000 Hz 01 05 Frequency Voltage 2 __ 0 0 1000 50 a ae 1 01 07 Frequency Voltage 1 00 1 00 200 rss Ferree Volts Hz Curve Modification 100 Torque Boost 01 11 VIF start Freque
151. rminals 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 Closed Loop Crimp Terminal Size 510 F RILI SL2 TIL3 UT1 VT2 WT3 Screws Model No Machine No MedelNo 2 1 14 M3 5 R2 3 5 3 3 12 4 R3 5 4 TIC 3 5 2 1 14 M3 5 R2 3 5 20 530 NihfuNHi 9 55 OO M m 2206 8225 415 8 4 8 5 8 5 s sag Ms Res mes Appendix 1 Instructions for UL Recommended Input Fuse Selection _________ FeueAmpreRaing 200 V Class Single Three Phase Drives 220 000 Drive Model E510 Manufacturer Bussmann FERRAZ SHAWMUT Model Fuse Ampere Rating A 400 V Class Three Phase Drives 401 XXXX Bussmann 10CT 690V 10A 402 XXXX Bussmann 16CT 690V 16A 403 XXXX Bussmann 16CT 690V 16A 405 XXXX Bussmann 25ET 690V 25A 408 XXXX Bussmann 40FE 690V 40A 410 XXXX Bussmann 50FE 690V 50A 415 XXXX Bussmann 63FE 690V 63A 420 XXXX Bussmann 80FE 690V 80A 425 XXXX FERRAZ SHAWMUT 5005100 4 500V 100A Motor Overtemperature Protection Motor overtemperature protection shall be provided in the end use application B Field Wiring Terminals input and output fie
152. rrent reached 0 1 15 0 03 6 Preset output Current detection delay Time 0 1 10 0 Sec gt 03 117 13 will be on as soon as the output current value gt preset current setting 03 15 03 15 Setting range 0 1 15 0 Amps as required according to the rated motor current 4 44 gt 03 16 Setting range 0 1 10 0 unit seconds 100 A load 03 15 b 03 16 Fixed T Value gi i gt 4 100msec 09 11 ON RY output 03 18 Brake Engage Level gt 03 11 14 gt In accelerating mode RY will be ON as soon as the actual output frequency reaches the external Brake release level set in parameter 03 17 gt In decelerating mode RY will be OFF as soon as the actual output frequency reaches the external Brake engage level set in parameter 03 18 Timing diagram for 03 17 lt 03 18 is shown below Hz 03 18 03 17 RUN command RUN STOP 03 11 14 ON OFF Timing diagram for 03 17 2 03 18 is shown below 4 45 Hz 03 17 03 18 gt RUN STOP 03 11 14 ON OFF Relay Output Status Type 03 19 Range 0 A Normally open 1 B Normally close gt When 03 19 0 gt When the set conditions of 03 11 03 12 are met relay contact is closed otherwise it will be open gt When 03 19 1 gt When set conditions of 03
153. s om oe qo 3 E5B10 200u H _ EO 2P5 H1F FREE 90 65 80 5 186 2 189 2 149 137 8 1408 41 2 1205 4 33 3 57 3 17 7 33 7 45 5 87 5 42 5 54 1 62 4 74 0 17 510 401 33 _ GRE 402 H3 EET 401 H3F 402 H3F 3 50 2 NEMA1 Single Three phase 200 2 3HP Single 200 2 3HP Three phase 200V 5HP 400V 3 5HP aA L zZ _ w _ El E Unit Dimensions Ito TEBIEBBE EUN 510 203 au 128 7 118 3 210 6 213 6 149 133 8 141 8 461 1211 4 5 5 06 4 66 8 29 8 41 5 87 5 27 5 58 1 81 4 77 0 18 510 403 93 _ E 510 405 3 51
154. s electronic components etc otherwise it will cause adverse situation When disconnecting the remote keypad turn the power off first to avoid any damage to the keypad or the inverter his product is sold subject to EN 61800 3 and EN 61800 5 1 In a domestic environment this product may cause radio interference in which case the user may be required to apply corrective measures Motor over temperature protection is not provided Work on the device system by unqualified personnel or failure to comply with warnings can result in severe personal injury or serious damage to material Only suitably qualified personnel trained in the setup installation commissioning and operation of the product should carry out work on the device system Only permanently wired input power connections are allowed 1 2 During Power Up gt When the momentary power loss is longer than 2 seconds the inverter will not have sufficient stored power for its control circuit Therefore when the power is re applied the run operation of the inverter will be based on the setup of following parameters e Run parameters 00 02 or 00 03 e Direct run on power up Parameter 07 04 and the status of external run switch Note the start operation will be regardless of the settings for parameters 07 00 07 01 07 02 H Danger Direct run on power up If direct run on power up is enabled and inverter is set to external run with the run FWD REV switch
155. s i Mounting hole Heat sink Warning label Name plate label Terminal cover Bar code label NEMA1 box 3 30 Three phase 400 20 25HP E510 Frame 4 With Filter Fan cover Operator Panel Mounting hole Heat sink Warning label Name plate label Terminal cover Bar code label EMC Filter 3 3 2 IP66 NEMA 4X exterior Single Three phase 200V 0 5 1HP Single phase 200V 0 5 1HP Three phase 200V 2 400V 1 2HP E510 Frame 1 IP66 NEMA 4X With Without VR and power switches depending on the model Mounting hole Heat sink seg Display Front cover Operator Name plate label Voltage label VR Screw Bottom cover Switch handle Mounting hole Power switch waterproof cable connector plug 3 31 6 Single Three phase 200V 2 3HP Single phase 200 2 3HP Three phase 200V5HP 400V 3 5HP E510 Frame 2 IP66 NEMA 4X With Without knobs and switches depending on the model Heat sink Mounting hole 7 Display Bottom cover Operator VR Voltage label Power switch Front cover Switch handle Screw waterproof cable connector plu c Three phase 200V 8 20HP 400V 8 25HP plug E510 Frame 3 IP66 NEMA 4X With Without knobs and switches depending on the model Mounting hole Heat sink Front cover Bottom cover 7 5 Display Operator VR Power switch Voltage label Switch handle Screw waterproof cable connector plug 3 32 Interior
156. se Fault SLAVE Address SLAVE Address 06H 06H Function Code Start rt Error Code Address App3 10 4 6 Write several holding registers 10H Specified data are written into the several specified holding registers from the Specified number respectively Note 1 Limit number of read data RTU 35 ASCII 15 2 Can only Continuous read the address of the same Group 3 Read data Quantity21 Example Set SLAVE station No 01 E510 drive as forward run at frequency reference 60 0HZ ASCII Mode Instruction Message Response Message Normal Response Fault STX STX ru 30H AVE 30H SLAVE Address Address 31H Address Function 31H Function 39H Function Code 30H Code 30H Code A1H Error Code 30 30 31H 35H Start 32H 2 55 CHECK NX I Start Address 30H 30H Quantity Quantity 30H 32H 30H DATA Number 30H 30H First 20H DATA 31H 30H 30H 32H gt CHECK 37H Next 30H CHECK 11 Instruction Message Response Message Normal Response Fault SLAVE SLAVE Address SLAVE Address 01H Address Star Star Address Low Address Low CRC 16 CDH Quantity Quantity 02H Low 02H 32H First m DATA Low Next High DATA Low High h 16 2 Low BOH Low BOH DATA Numbers are the actual number timers 2 App3 12
157. set as factory default Set 02 01 to the full load amps FLA stamped on the nameplate of the motor The operator must enter the rated current of the motor 02 01 in the menu during auto tuning B Motor Overload Protection Selection The drive has an electronic overload protection function OL1 based on time output current and output frequency which protects the motor from overheating The electronic thermal overload function is UL recognized so it does not require an external thermal overload relay for single motor operation This parameter selects the motor overload curve used according to the type of motor applied Overload Protection Settings Variable Torque OL 130023 for 1 Minute 08 11 0 Standard Motor protection 0811 4 Inverter duty motor protection Sets the motor overload protection function in 08 group according to the applicable motor Setting 08 05 0 Disables the motor overload protection function when two or more motors are connected to a single inverter Use an alternative method to provide separate overload protection for each motor such as connecting a thermal overload relay to the power line of each motor setting 08 12 0 To protect the general mechanical load as long as the load 15 less than 103 rated current the motor continue to run The load is larger than 15096 rated current the motor will run for 1 minute Refer to following curve 1 Setting 08 12 1 To protec
158. t HVAC load FANPUMP so on as long as the load is less than 113 rated current the motor continue to run The load is larger than 123 rated current the motor will run for 1 minute Setting 08 11 0 For motors without a forced cooling fan general purpose standard motor the heat dissipation capability is lower when in low speed operation 08 11 1 For motors with a forced cooling fan inverter duty or V F motor the heat dissipation capability is not dependent upon the rotating speed To protect the motor from overload by using electronic overload protection be sure to set parameter 02 01 according to the rated current value shown on the motor nameplate Refer to the following Motor Overload Protection Time for the standard motor overload protection curve example Setting 08 12 0 Minute 5 0 1 0 103 113 123 150 Current Motor Overload Protection Time The heat sinking function will not be as effective when the motor run at low speed So the thermal relay action level will decline at the same time The curve 1 will change to curve 2 08 06 Motor Overload Operation Selection BPescplon O Coast to Stop After Overload Protection is Activated ee Drive Will Not Trip when Overload Protection is Activated OL1 Appendix 2 E510 parameter setting list Address Parameter Setting Parameter Setting Parameter Setting Parameter Setting code content code
159. t this end Inverter ground terminal 3 22 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 For effective suppression of noise emissions the cable armor or shield must be grounded at both ends to the motor and the inverter ground These connections should be as short as possible Motor cable and signal lines of other control equipment should be at the least 30 cm apart E510 has a built in Class A EMC filter to first Environment Restricted Category C2 Typical Wiring 1 Protective Earth Conductor Conductor size for enclosure amp Back plate must comply with the local electrical standards Min 10mm 2 Back plate Galvanised steel Unpainted 3 Ferrite core Output reactor ferrite cores can be used to reduce radiated noise due to long motor cables If ferrite core is used loop motor wires 3 times round the core Install core as close to the inverter as possible Output reactors provide additional benefit of reducing dv dt for protection of motor windings 4 Metal Cable clamp no more than 150mm from the inverter Note If no enclosure amp back plate 15 used then connect the cable shield by a good 360 degree termination to the Inverter output terminal E 5 Screened Shielded four co
160. tages between U V V W W U balanced YES Y N Is the load fluctuating VE Reduce the load fluctuation or add a flywheel NO Inspect the mechanical YE system Any mechanical vibration or gear backlash NO INV faults 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 Checking Details period Methods Criteria Remedies Environment amp Ground connection Temperature Confirm the Measure with 222 14 120 Ambient temperature and thermometer ambient or in Humidity conditions at humidity at the machine and hygrometer Below relocate the the installation 5 drive toa 95 RH materials in the vicinity screws Installation Measure the Improve the E 16 grounding resistance with grounding if resistance correct below 1000 a multi tester needed 5 12 Terminals amp Wiring eres terminals Connection Any damage to the viene a OE Check with a Installation terminals and screwdriver requirement remove rust mum
161. the inverter continues to run display flash with OL1 until the current falls below the overload level The heat sinking function will not be as effective when the motor run at low speed So the thermal action level will decline at the same time The curve 1 will change to curve 2 Minute 5 0 1 0 103 113 123 150 Current 08 07 OH Over Heat Protection Range 0 Auto Depends on heat sink temp 1 Operate while in RUN mode 2 Always Run 3 Disabled v 08 07 0 Cooling fan runs as the inverter detects temperature rise 08 07 1 Cooling fan runs while the inverter is running 08 07 2 Cooling fan runs continuously 08 072 Cooling fan is Disabled 08 08 AVR function 08 08 AVR function enable AVR function disable AVR function disable for stop AVR function disable for Deceleration AVR function disabled for stop and Deceleration when VDC gt 360 740V gt AVR function is disabled for stop and Deceleration v v v v v Automatic voltage regulator function provides a level of output voltage stability when there is input voltage instability So when 08 08 0 Input voltage fluctuations will not effect the output voltage 08 08 1 Input voltage fluctuations will cause fluctuations on output voltage 08 08 2 AVR is disabled during stopping to avoid an increase in stopping time 08 08 3 AVR is disabled only during deceleration from one speed to another s
162. the setting in 08 02 then the deceleration is resumed 08 03 Trip Prevention Level During Continuous Run Mode 50 200 Trip prevention adjustment level during continuous Run to prevent over current OC C trips gt prevention during continuous Run is enabled and an over current occurs due the load such as sudden transient load then the output frequency is reduced by decelerating to a lower speed until the over current level is dropped below the preset in 08 03 then the output frequency accelerates back to the normal running frequency 08 04 Over Voltage Prevention Level During Run Mode 350 0VDC 390 0VDC 200V class 700 0VDC 780 0VDC 400V class gt Over voltage prevention level be set by parameter 08 04 when necessary When the DC bus voltage is higher than the level set in 08 04 the over voltage fault will occur 08 05 Electronic Motor Overload Protection Operation Mode OL 1 Range 0 Enable Electronic Motor Overload Protection 1 Disable Electronic Motor Overload Protection E 0 Coast to Stop After Overload Protection is Activated 1 Drive Will Not Trip when Overload Protection is Activated OL 1 gt 08 06 0 overload condition the inverter coast to stop as the thermal relay detects the overload and the display will flash reset Press the Reset key or use an external reset to continue to run 4 62 gt 08 06 1 On overload condition
163. time Preset Speed 5 Deceleration time Preset Speed 6 Acceleration time Preset Speed 6 Deceleration time Preset Speed 7Acceleration time Preset Speed 7 Deceleration time Preset Speed 8Acceleration time Preset Speed 8 Deceleration time Preset Speed 9Acceleration time Preset Speed 9 Deceleration time Preset Speed 10Acceleration time Preset Speed 10 Deceleration time Preset Speed 11Acceleration time Preset Speed 11 Deceleration time Preset Speed 12Acceleration time Preset Speed 12 Deceleration time Preset Speed 13Acceleration time Preset Speed 13 Deceleration time Preset Speed 14Acceleration time Preset Speed 14 Deceleration time 05 47 Preset Speed 15Acceleration time 05 48 Preset Speed 15 Deceleration time Range 0 1 3600 0 Sec Range 05 17 05 27 05 37 4 53 gt When 05 00 0 Accel Decel 1 2 by parameters 00 14 00 15 00 16 00 17 apply to all speeds gt When 05 00 1 When 05 00 1 Individual Accel Decel apply to each preset speed 0 15 Parameters 05 17 to 05 48 gt Formula for calculating acceleration and deceleration time Time of or 2 x Preset Frequency Max Frequency Time of Accel1 or 2 x Preset Frequency Max Frequency Actual Acc time Actual Dec time gt Maximum output frequency parameter 01 02 when programmable V F is selected by 01 00 18 gt Maximum output frequency 50 00 hz or 60 00 hz when preset V F patterns are selected by 01 004 18 Example
164. tinue Operating Error 6 Verification Time 1 20 Drive Transmit Delay Time ms 5 65 09 00 4 20 Factory D t R Demon Setting Unit Potentiometer on Keypad Analog Signal Input Analog Signal Input 2 Frequency Set by Communication PID Target Value Selection When 00 03 00 04 6 This Function is Enabled Keypad Frequency Parameter 10 02 0 Potentiometer on Keypad 1 Analog Signal Input 2 10 01 PID Feedback Value Selection Analog Signal Input 12 2 1 3 Frequency Set by Communication 10 02 PID Target Keypad Input 00 00 00 0 Disabled 1 Deviation D Control FWD Characteristic Feedback Control PID Mode Selection FWD Characteristic Deviation D Control Reverse Characteristic Feedback Control Reverse Characteristic 10 04 Feedback Gain Coefficient 0 00 10 00 __ 1 10 05 Proportional ___ 0 7100 104 10 06 Integral Time ___ 00 1000 100 10 07 Derivative Time 000 100 1000 1 PlDOffsetAdust 0 109 02 Output Lag Filter Time _ 00 25 7 702 se 0 Disabled losc Dedo 1 Enabled Drive Continues to Mode Operate After Feedback Loss 2 Enabled Drive STOPS Feedback Loss Detection Level After Feedback Loss Feedback Loss Detection Delay Time Integration Limit Value 0 109 1
165. to the time for 274 Accel Decel set in parameters 00 16 and 00 17 if the input is turned off the acceleration and deceleration times will be according to the default accel decal 1 set in parameters 00 14 amp 00 15 Example 00 12 Frequency upper limit 50HZ Defaults 03 00 Termina S1 8 03 06 up down frequency 0 00 14 accelerating time 1 5 00 16 accelerating time 2 10S Defaults When s1 is ON for 5 s the actual accelerating time of inverter will be 2 5s Explain Hz 50Hz Frequency upper limit 0 10s accelerating T Diagram a time 2 Diagram a Target frequency is determined by the Frequency upper limit the on time and accelerating time 2 upper frequncy SOHz time of 1 x 5S 25Hz Target frequency acceleranting time2 X 10 4 37 Hz 50 2 frequency 25Hz target frequency 0 Actual 5S accelerating T Diagram b accelerating time 1 time 1 Diagram b The actual accelerating time target frequenc E 25Hz accelerating time 50Hz actual accelerating time 22355 upper frequency 6 03 00 03 05 11 Disable Acc Dec function When an input terminal is set to function 11 and is turned on acceleration and deceleration function will be disabled and the frequency at the time is maintained constant speed mode If the input is turned off acceleration and deceleration function is enabled again For an example se
166. tting parameter 08 17 Use of this mode for any specific application must be considered carefully and all safety implications must be taken into account as all protection features of the inverter will be disabled and the unit will continue to operate until its possible destruction All liabilities for the use of this function will remain user s responsibility 08 18 Ground Fault Detection Range 0 Invalid 1 Effective ON dectection of Ground fault if 08 18 1 fault message GF will be displayed Note this function is only available for inverter Frames 3 4 4 64 09 00 Assigned Communication Station Number 1 321 gt 09 00 to sets the communication station number when there is more that one unit on communication network Up to 32 Slave units can be controlled from one master controller such as a PLC 09 01 RTU code ASCII code Selection 1 ASCII 09 02 BaudRateSetng bps ULU 0 0 0 0 0 0 0 4800 11 9600 2 19200 3 38400 09 03 Stop Bit Selection Range 0 1 stop bit 1 2 stop bits 09 04 Parity Selection 0 No Parity Range 1 Even Parity 2 Odd Parity Data Format Selection Range 0 8 bit data 1 7 bit data gt Set 09 01 09 05 to configure communication format before starting communication 09 06 Communication time out detection time Range 00 255 s 00 09 07 Communication time out operation selection 3 Keep running and show COT
167. urce Selection 0 0 1 External Run Stop Control 2 Communication Parameter 00 03 sets the inverter Alternative Run operation source For switching between 00 02 and 00 03 use any of the external inputs 51 to S6 and set the relavent parameter 03 00 03 05 to 12 Refer to parameter group3 for details 00 04 Operation Modes for External Terminals 0 Forward Stop Reverse Stop 1 Run Stop Reverse Forward 2 3 Wire Control Mode Run Stop gt 00 04 is valid when run command is set to external mode by 00 02 00 03 71 2 Wire Operation Mode Set 00 04 0 1 first before setting 03 00 03 04 to 0 or 1 00 04 0 Set external terminals 03 00 to 03 05 function to 0 for FWD Stop or Set to 1 for REV Stop 00 047 1 Set external terminals 03 00 to 03 05 function to 0 for Run Stop or Set to 1 for FWD REV 3 Wire Operation Mode 00 04 2 Terminals S1 S2 S3 are used in a combination to enable 3 wire run stop mode Settings for 03 00 03 01 03 02 will not be effective refer to group 03 Main Frequency Command Source Selection Alternative Frequency Command Source Selection Up Down of Keypad Potentiometer on Keypad External AI1 Analog Signal Input External AI2 Analog Signal Input External Up Down Frequency Control Communication Setting Frequency PID Output Frequency Pulse Input Parameter 00 05 00 06 sets the inverter frequency command source gt When
168. ust or debris debris or dust TEE Is the ventilation path Clear the Ventilation Path blocked Visual check Visual check Hog dll 5 13 5 5 Maintenance To ensure long term reliability follow the instructions below to perform regular inspection 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 Maintenance Check List gt Ensure that temperature and humidity around the inverters is as required in the instruction manual installed away from any sources of heat and the correct ventilation is provided gt replacement of a failed or damaged inverter consult with the local supplier gt Ensure that the installation area is free from dust and any other contamination gt Check and ensure that the ground connections are secure and correct gt Terminal screws must be tight especially on the power input and output of the inverter gt perform any insulation test on the control circuit 2 Insulation test Method Single Phase Three Phase L1 CL T1 T T L3 N T1 Re er SERGE L1 L Power 12 Inverter 2 Source oem 13 N T3 e 9 Dielectric Withstand Dielectric Withstand Voltage Test Voltage Test Chapter6 Peripherals Components 6 1 Reactor Specifications Curr
169. verter s output is OK Perform detailed check and consult with the supplier 5 3 4 Motor not running The motor can not run Is MCCB On YES Can be turned On NO Short circuited wiring 1 The power is abnormal 2 wiring Are voltages between power terminals correct YES Is LED lit NO INVfault YES The operation switch is set to RUN position Is the operation switch UN YES Are there outputs between the U V and W terminals of the motor NO INVfault YES Are outputs between U V W the NO INVfault same YES 1 Motor 2 Motor faults 3 Incorrect wiring 5 10 5 3 5 Motor Overheating Motor Overheating Is load or current exceeding YES onsider reducing the load and increasing the specified value the capacities of the inverter and motor NO E Sliow Speed YES Selectthe motor again for a long time Is motor voltage between U V V W W U correct PN taun YES there any deterrence preventing cooling of the YES Clear the deterrence D ec YES Correct the bad connection and the motor motor 5 11 5 3 6 Motor runs unbalanced Motor runs unbalanced Is the acceleration NO Increase the Acc Dec time time correct Reduce load Increase capacities of INV and the motor D INV faults Does it happen during eceleration Are the output vol
170. w D 10 07 Feedback 2 value I t 12 00 display PID feedback 10 03 10 22 10 00 PID target value selection Potentiometer on Keypad External Analog Signal Input External AI2 Analog Signal Input Target Frequency set by Communication method Set from keypad by parameter 10 02 10 00 selections are only effective when frequency source selection is set to PID by parameters 00 05 00 067 6 10 01 PID feedback value selection 0 Potentiometer on Keypad 1 External AI1 Analog Signal Input 2 External AI2 Analog Signal Input 3 Communication setting Frequency Note 10 00 and 10 01 can not be set to the same value 10 02 PID Keypad Input Range 0 0 100 0 10 03 PID Mode Selection a 4 Characteristic 10 03 1 target detected value is derivative controlled in unit time set parameter 10 07 gt 10 03 2 Feed back detected value is derivative controlled in unit time set in parameter 10 07 gt 10 03 3 Deviation target value detected value is derivative controlled in unit time set in parameter 10 07 If the deviation is positive the output frequency decreases vice versa gt 10 03 4 Feed back detected value is derivative controlled in unit time set in parameter 10 07 If the deviation is positive the output frequency decreases vice versa Note 4 66 For 10 03 1 or 2 If the deviatio
171. will stop In this example 4 sequences are set three in forward direction and one in Reverse Auto Run Mode 06 00 1 or 4 Frequency 05 01 15 Hz 06 01 30 Hz 06 02 50 Hz 06 03 20 Hz Sequence Run Time 06 16 20 06 17 25 06 18 30 06 19 40 Direction 06 32 1 06 33 1 06 34 1 FWD 06 35 2 REV Unused Sequence Parameters 06 04 06 15 0 06 20 06 31 0 06 36 06 47 0 Hz 06 02 gt T RUN command RUN 1 2 51 to 56 auto run enable ON Example 2 Periodic Cycle Run Mode 06 00 2 or 5 The inverter will repeat the same cycle periodically All other Parameters are set same as Example 1 shown above 4 57 06 02 06 02 06 01 06 01 05 01 x 05 01 06 16 06 17 06 18 06 03 06 16 0647 06 18 06 03 06 19 06 19 RUN Command RUN 1 to S6 auto Run enable ON u Example 3 Auto Run Mode for Single Cycle 06 002 3 or 6 The speed of final step will be held to run Auto Run Mode 06 00 or 61 Frequency 05 01 15 Hz 06 01 30 Hz 06 02 50 Hz 06 15 20 Hz Sequence Run Time 06 16 20 s 06 17 25 s 06 187 301 s 06 317 40 s Direction 06 32 1 06 33 1 06 34 1 06 47 11 FWD Unused Sequence Parameters 06 04 06 15 0 Hz 06 19 06 30 0 06 35 06 46 0 Hz 06 02 06 16 06 1
172. xdbuff for i 0 1 lt 8 i if 0x0001 wkg wkg gt gt 1 0xa001 else wkg wkg gt gt 1 return 3 3 Error code ASCII Mode RTU Mode SLAVE Address G Address Exception 1 52 Function e CRC 16 CDH Exception LRC Check Under communication linking the driver responses the Exception Code and send Function Code AND 80H to main system if there is error happened 51 Function Code Error 53 Data Amount Error Writing Mode Error App3 4 4 Inverter Control 4 1 Command Data Readable and Writable Regum me 2500H Reseved 020000000 0000 0 Stop 4 Command Reverse 0 Forward jema ero 3 FaitRese 4 og Forward Command 1 Jog Foward 5 og Reverse Command 1 Jog Reverso 2501H Relay R1 ON 0 OFF 2 226 Multi function 51 0 7 Multi function 2 0 OFF 8 function CommandS3 OFF Multi function CommandS4 1 A function CommandS5 1 ON 0 B Multi function Commands6 1 0 OFF Reserved 2502H 250H Frequency Command 2503 251 Reseved Note Write in zero for Not used BIT do not write in data for th

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