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1. F438 F439 Reserved F460 All channel input mode 0 straight line mode 0 x 1 folding line mode F461 AD channel input mode 0 straight line mode 0 x 1 folding line mode F462 ALI insertion point A1 F400 F464 2 00V x voltage value F463 ALI insertion point A1 F401 F465 1 40 x setting value Z F464 AIl insertion point A2 F462 F466 3 00V x e voltage value pel F465 AIL insertion point A2 F463 F467 1 60 x 5 setting value F466 ALI insertion point A3 F464 F402 4 00V x e voltage value 5 F467 ALI insertion point A3 F465 F403 1 80 x E setting value e F468 AI2 insertion point Bl F406 F470 2 00V x E voltage value z F469 AD insertion point B1 F407 F471 1 40 x EE setting value F470 ALD insertion point B2 F468 F472 3 00V x voltage value F471 AI2 insertion point B2 F469 F473 1 60 x setting value F472 ALD insertion point B3 F470 F412 4 00V x voltage value F473 AI2 insertion point B3 F471 F413 1 80 x setting value Min frequency of input F440 0 00 F442 0 00K V pulse FI F441 Conesponding setting of oo yaz 1 00 Y FI min frequency F442 eo of input e449 50 00K 10 00K Y E ae a F443 Corresponding setting of 5 1 00 F441 2 00 2 00 y FI max freguency 5 F444 Reserved E Filtering constant of FI E F445 0100 0 Y m input pulse 5 FI channel OHz O F442Hz E dd frequency dead zone Positive Negative om y F447 F448 Reserved o 2 E F449 Men dial of output o oo so og 10 00K
2. Motor power kw 0 2 0 4 075 aes Product series 12 Optional function naming rule DFIYKBR l Mark Built in EMlfilter None None R Including built in EMI filter Mark Built in braking unit None None B Including built in braking unit Mark Operation panel with potentiometer None Local operation panel without potentiometer K Local operation panel with potentiometer Mark Operation panel type None Operation panel is not removable n Operation pane is removable to be controlled remotely Mark Scene bus type None No communication function Fl With MODBUS communication function Mark Structure code None Hanging type D Cabinet type E1000 13 Nameplate Taking for instance the E1000 series 0 75KW inverter with 1 phase input its nameplate is illustrated as Fig 1 1 ontvan URA DRIVES ELECTRIC CO LTD 1Ph single phase input 230V 50 60Hz Function MODEL E1000 0007S2 FIKBR input voltage range and rated frequency Symbol 3Ph 3 phase output 4 5A 0 75KW INPUT AC 1PH 230V 50 60Hz rated output current and power 3PH 0 75KW 4 5A 0 230V 0 50 650 0Hz output frequency range OUTPUT 0 50 650 0Hz Fig 1 1 Nameplate 14 Appearance The external structure of E1000 series inverter is classified into plastic and metal housings And wall hanging type is adopted Good poly car
3. TOT Drake resister Jumpar m Tnree phasa Input AC 400V 50 80Hz i Multifunctiona Relay Output Mutilunciortel 10A 125VAC Input Terminals 24 250VAC Multi Analog Signal Voltage Qulputt D 10V Mulli Analog signat Current Output2 0 20mA Multifunctional Output Terminats External Analog Basa Signal input Main Loop Terminais A o ContriLoopTarminais V Shisidad Cable 1 Please only connect power terminals L1 R and L2 S with power grid for single phase inverters 2 Remote control panels and 485 communication port should be connected with 4 core telephone wire They must not be used at the same time 3 485 communication port has built in standard MODBUS communication protocol Communication port is on the left side of inverter The sequence from top to down is 5V power B terminal A terminal and GND terminal 4 Inverter above 15kw has 8 multifunctional input terminals OPI OPS 15kw inverter and below 15kw has 6 multifunctional input terminals OP1 OP6 5 The contact capacity of 15kw and below 15kw inverter is 10A 125VAC 5A 250VAC 5A 30VDC contact capacity of bove 15kw is 12A 125VAC 7A 250VAC 7A 30VDC 18 E1000 IV Operation and Simple Running This chapter defines and interprets the terms and nouns describing the control running and status of the inverter Please read it carefully It will be helpful to your correct operation 4 1 Control mode Control mode of E1000 inverter is V F control
4. figure Introduction of terminals of power loop Terminal Terminals ME Terminal Function Description Marking Power Input R LI S L2 Input terminals of three phase 400V AC voltage R LI and S L2 Terminal TES terminals for single phase Output Terminal UVW Inverter power output terminal connected to motor di SEN s rh PE E Inverter grounding terminal Terminal PB External braking resistor Note no Terminals P or B for inverter i without built in braking unit P AN DC bus line output Rest Terminal Externally connected to braking unit P N P connected to input terminal P or DC of braking unit N connected to input terminal of braking unit N or DC P P Externally connected to DC reactor Wiring for control loop as follows A B TA TB TC DO1DO2 24V CM OP1 OP2 OP3 OP4 OPS OP6 OP7 OP8 10V AI1 AI2 GND AO1LAO2 Note 15KW inverters and below 15KW have no A B DO2 and OP7 OPS control terminal 13 E1000 3 3 Functions of control terminals The key to operate the inverter is to operate the control terminals correctly and flexibly Certainly the control terminals are not operated separately and they should match corresponding settings of parameters This chapter describes basic functions o combining relevant contents hereafter about Defined Functions of the Terminals f the control te
5. Forward running locking Mfr s value 0 Mode of direction setting 1 Reverse running locking Dur 2 Terminal setting The running direction is controlled by this function code together with other speed control mode which can set the running direction of inverter When auto circulation speed is selected by F500 2 this function code is not valid When speed control mode without controlling direction is selected the running direction of inverter is controlled by this function code for example keypad controls speed When speed control mode with controlling direction is selected the running direction of inverter is controlled by both modes The way is polarity addition for example one forward direction and one reverse direction make the inverter run reversely both forward directions make inverter run forward both reverse directions which equal to forward direction make inverter run forward Setting range 0 Memory of digital given External analog ALI External analog AI2 3 Pulse input given F203 Stage speed control Mfr s value 0 Main frequency source X Keypad potentiometer 7 Reserved Reserved 9 PID adjusting 10 MODBUS 1 2 4 5 No memory of digital given 6 8 Main frequency source is set by this function code 0 Memory of digital given 34 E1000 Its initial value is the value of F113 The frequency can be adjusted through the key up
6. Set E203 to 1 to select channel ALI Set E203 to 2 to select channel AD Coding Switch I Coding Switch3 Analog signal range Coding Switch2 Coding Switch4 Analog signal range OFF OFF 0 5V voltage OFF OFF O S5V voltage OFF ON 0 10V voltage OFF ON O 10V voltage ON ON O 20mA current ON ON O 20mA current ON refers to switching the coding switch to the top OFF refers to switching the coding switch to the bottom 295 E1000 V Function Parameters 5 1 Basic parameters F100 User s Password Setting range 0 9999 Mfr s value 8 When F107 1 with valid password the user must enter correct user s password after power on or fault reset if you intend to change parameters Otherwise parameter setting will not be possible and a prompt Err1 will be displayed Relating function code F107 Password valid or not F108 Setting user s password F102 Inverter s Rated Current A Setting range 1 0 800 0 Mfr s value Subject to inverter model F103 Inverter Power KW Setting range 0 27 500 0 Mfr s value Subject to inverter model Rated current and rated power can only be checked but cannot be modified F105 Software Edition No Setting range 1 00 10 00 Mfr s value Subject to inverter model Softward Edition No can only be checked but cannot be modified F107 Password Valid or Not Setting range 0 invalid 1 valid Mfr s v
7. Setting range 0 0 5V 1 0 10V Mfr s value 1 F423 AOI output range selecting F424 Corresponding frequency for lowest voltage of AOI output Setting range 0 0 F425 Mfr s value 0 05Hz F425 Corresponding frequency for highest voltage of AOI output Setting range FA24 F111 Mfr s value 50 00Hz F426 AOI output compensation Setting range 07712096 Mfr s value 100 AOI output range is selected by F423 When F423 0 AOI output range selects 0 5V and when F423 1 AOI output range selects 0 10V Correspondence of output voltage range 0 5V or 0 10V to output frequency is set by F424 and F425 For example when F423 0 F424 10 and F425 120 analog channel AOI outputs 0 5V and the output frequency is 10 120Hz AOI output compensation is set by F426 Analog excursion can be compensated by setting F426 Setting range 0 0 20mA 1 4 20mA F428 AO2 lowest corresponding frequency Setting range 0 0 F429 Mfr s value 0 05Hz F427 AO2 output range Mfr s value 0 F429 AO2 highest corresponding frequency Setting range F428 F111 Mfr s value 50 00 F430 AO2 output compensation Setting range 0O 120 Mfr s value 100 The function of AO2 is the same as AOI but AO2 will output current signal current signal of 0 20mA and 4 20mA could be selected by F427 Setting range 0 Running frequency Mana M F431 AOI analog output signal selecting 49
8. Target rotary speed is an integral number If it exceeds 9999 add a decimal point to it Current display A Voltage display U Count value Temperature H Linear speed L If it exceeds 999 add a decimal point to it If it exceeds 9999 add two decimal points to it and the like Setting range 0 Frequency function code 1 Keypad jogging 2 Target rotary speed F132 Display items of stop 4 PN voltage 8 PID feedback value 16 Temperature Mfr s value 0 2 4 6 32 Count values F133 Drive ratio of driven system Setting range 0 10 200 0 Mfr s value 1 00 F134 Transmission wheel radius 0 001 1 000 m Mfr s value 0 001 Calculation of rotary speed and linear speed For example If inverter s max frequency F111 50 00Hz numbers of motor poles F804 4 drive ratio F133 1 00 transmission shaft radius R 0 05m then Transmission shaft perimeter 2711 22x3 14x0 05 0 314 meter 29 E1000 Transmission shaft rotary speed 60x operation freguency numbers of poles pairs x drive ratio 60x50 2x1 00 1500rpm Endmost linear speed rotary speed x perimeter 1500x0 3 14 47 1 meters second F136 Slip compensation Setting range 0 1096 Mfr s value 0 Under V F controlling rotary speed of motor rotor will decrease as load increases Be assured that rotor rotate speed is near to synchronization rotary speed while motor with rated lo
9. V1 lt V2 lt V3 lt V4 lt V5 lt V6 F1 lt F2 lt F3 lt F4 lt F5 lt F6 As low frequency if the setting voltage is too high motor will overheat or be damaged Inverter will be stalling or occur over current protection Voltage 496 A V6 v5 v4 v3 v2 v1 F4 F5 ig 5 4 Polygonal Line Type F6 Fre Hz F152 Output voltage corresponding to turnover frequency Setting range 10 100 Mfr s value 100 This function can meet the needs of some special loads for example when the frequency outputs 300Hz and corresponding voltage outputs 200V supposed voltage of inverter power supply is 380V turnover frequency F118 should be set to 300Hz and F152 is set to 200 380 X100 52 6 And F152 should be equal to the integer value 53 Please take care nameplate parameters of motor If the working voltage is higher than rated voltage or the frequency is higher than rated frequency motor would be damaged 31 E1000 Setting range Mfr s value 0 2 7 5KW 2 10K 4K F153 Carrier frequency setting 11 15KW 2 10K 3K 18 5KW 45KW 2 6K 4K Above 55KW 2 4K 2K Carrier wave frequency of inverter is adjusted by setting this code function Adjusting carrier wave may reduce motor noise avoid point of resonance of mechanical system decrease leakage current of wire to earth and the interference of inverter When carrier wave frequency is low although carrier wave noise f
10. metal particles or metal powder Environment temperature within the scope of 10 C 50 C Please install inverter away from combustibles Do not drop anything into the inverter The reliability of inverters relies heavily on the temperature The around temperature increases by 10 C inverter life will be halved Because of the wrong installation or fixing the temperature of inverter will increase and inverter will be damaged 9 If inverter is installed in a control cabinet smooth ventilation should be ensured Installing vertically and inverter should be installed vertically If there are several inverters in one cabinet in order to ensure ventilation please install inverters side by side If it is necessary to install several inverters up and down please add heat insulation plate E1000 nverters are installed in the Fa Ng control cabinet Inverter The position of fan wrong example wo inverters emen EM ye wrong example Built in cold fan U e am e oe e 1 8 Precautions 1 8 1 Instructions for use Never touch the internal elements within 15 minutes after power off Wait till it is completely discharged 9 Input terminals R S and T are connected to power supply of 400V while output terminals U V and W are connected to motor Proper grounding should be ensured with grounding resistance not exceeding 40 separate grounding is required for mo
11. positive feedback 1 negative feedback 0 Positive feedback when feedback signal is higher than PID setting output frequency will increase automatically to balance PID adjusting Negative feedback when feedback signal is higher than PID setting output frequency will decrease automatically to balance PID adjusting Setting range 0 Given digital 1 ATI 2 AI2 3 Input pulse given 4 5 Reserved The given channel of reference source is set by FAOI When FA01 0 digital reference source is set by FA02 FAO2 Given Digit Reference Source 0 0 100 0 50 0 When FA01 0 reference source is controlled by keypad This parameter should be set The setting value of FA02 is the relative value it s benchmark value is max feeback value of the system FAO3 Feedback Source 0 AIL 1 AD 2 Input pulse frequency 4 5 Reserved 0 PID feeback channel is set by FAO3 FAOI Reference source FA04 Proportion Coefficient 0 0 100 0 20 0 FAO5 Integral Time 0 1 10 0S 2 0 FA06 Precision 0 0 20 0 0 1 FA07 Show Value of Min Feedback 0 9999 0 FA08 Show Value of Max Feedback 0 9999 1000 Dormancy function FA10 Dormancy function selection Setting range 0 Invalid 1 Valid 0 FALI Dormancy waking value Setting range 0 100 10 FA12 Feedback limit value Setting range 0 100 80 FA13 Dormancy delay time Setting range 0 300 0 S 60 0S FA14 Wake delay
12. 22 Count input terminal Mfr s value 2 23 Count reset terminal 24 30 reserved This parameter is used for setting the corresponding function for multifunctional digital input terminal Both free stop and external emergency stop of the terminal have the highest priority When pulse given is selected OP1 terminal is set as pulse signal input terminal automatically Note 15KW inverter and below 15KW has 6 multifunctional digital input terminals OP1 OP6 Table 5 3 Instructions for digital multifunctional input terminal 43 E1000 Value Function Instructions 0 No f nctloh Even if signal is input inverter will not work This function can be set by undefined terminal to prevent mistake action When running command is given by terminal or terminals 1 Running terminal combination and this terminal is valid inverter will run This terminal has the same function with run key in keypad When stop command is given by terminal or terminals combination 2 Stop terminal and this terminal is valid inverter will stop This terminal has the same function with stop key in keypad 3 Multistage speed terminal 1 4 Multistage speed terminal 2 15 stage speed is realized by combination of this group of 5 Multistage speed terminal 3 terminals See table 5 4 6 Multistage speed terminal 4 This terminal has the same function with
13. 380V F611 Energy Consumption Brake Point Setting range 200 1000 F612 Discharging percentage Setting range 07710026 o Mfr s value 80 Initial voltage of energy consumption brake point is set by F611 which of unit is V When DC bus voltage is higher than the setting value of this function energy consumption braking starts braking unit starts working E1000 After DC bus voltage is lower than the setting value braking unit stops working Discharging percentage of braking unit is set by F612 the range is 0 100406 5 8 Malfunction and Protection F700 Selection of terminal free stop mode Setting range 0 free stop immediately 1 delayed free stop Mfr s value 0 F701 Delay time for free stop and programmable terminal action Setting range 0 0 60 0S Mfr s value 0 0 Selection of free stop mode can be used only for the mode of free stop controlled by the terminal The related parameters setting is F201 1 2 4 and F209 1 When free stop immediately is selected delay time F701 will be invalid and inverter will free stop immediately Delayed free stop means that upon receiving free stop signal the inverter will execute free stop command after waiting some time instead of stopping immediately Delay time is set by F701 O controlled by temperature F702 Fancontrol mode 1 Do not controlled by temperature 2 controlled by running status Mf
14. E1000 0110T3 u 23 EG Air Cooling 8 0 Ei E1000 0150T3 15 32 E6 Air Cooling 8 2 ie 61 E1000 E1000 0185T3 18 5 38 C3 Air Cooling 19 E1000 0220T3 22 44 C3 Air Cooling 20 E1000 0300T3 30 60 C3 Air Cooling 22 5 E1000 0370T3 37 75 C5 Air Cooling 37 6 E1000 0450T3 45 90 C5 Air Cooling 38 6 gt E1000 0550T3 55 110 C5 Air Cooling 41 5 2 E E1000 0750T3 75 150 C6 Air Cooling 55 3 E1000 0900T3 90 180 C6 Air Cooling 56 E E E1000 1100T3 110 220 C7 Air Cooling 87 Ej 2 E1000 1320T3 132 265 C8 Air Cooling 120 E 3 E1000 1600T3 160 320 C8 Air Cooling 123 z E E1000 1800T3 180 360 C9 Air Cooling 125 a tz E1000 2000T3 200 400 CA Air Cooling 180 gt E1000 2200T3 220 440 CA Air Cooling 185 E1000 2500T3 250 480 CB Air Cooling 220 E1000 2800T3 280 530 CB Air Cooling 225 E1000 3150T3 315 580 CB Air Cooling 230 E1000 3550T3 355 640 CB Air Cooling 233 E1000 1100T3D 110 220 DO Air Cooling 160 E1000 1320T3D 132 265 DI Air Cooling 200 E1000 1600T3D 160 320 DI Air Cooling 202 E1000 1800T3D 180 360 DI Air Cooling 205 z E E1000 2000T3D 200 400 D2 Air Cooling 215 E1000 2200T3D 220 440 D2 Air Cooling 280 E E1000 2500T3D 250 480 D3 Air Cooling 350 ge E1000 2800T3D 280 530 D3 Air Cooling 380 gt E1000 3150T3D 315 580 D3 Air Cooling 385 3 E1000 3550T3D 355 640 D3 Air Cooling 445 E E E1000 4000T3D 40
15. F578 1 1 Multi stage speed 15 F518 F533 F548 F579 Note K4 is multi stage speed terminal 4 K3 is multi stage speed terminal 3 K2 is multi stage speed terminal 2 K1 is multi stage speed terminal 1 And 0 stands for OFF 1 stands for ON F324 Free stop terminal logic Setting range IM fr s value 0 positive logic valid for low level F325 External CIner Een cy stop 1 negative logic valid for high level IMfr s value 0 terminal logic F328 Terminal filtering times Setting range 1 100 IMfr s value 10 When multi stage speed terminal is set to free stop terminal 8 or external emergency stop terminal 9 logic level is set by this group of function codes When F324 0 and F325 0 positive logic and low level is valid when F324 1 and F325 1 negative logic and high level is valid 5 4 Analog Input and Output E1000 series inverters have 2 analog input channels and 2 analog output channels AI3 input channel is inside input channel for potentiometer on the keypad panel F400 Lower limit of All channel input Setting range 0 00 F402 Mfr s value 0 01 V F401 Corresponding setting for lower limit of All input Setting range 07 F403 Mfr s value 1 00 F402 Upper limit of All channel input Setting range FA00 10 00V Mfr s value 10 00V 45 E1000 Setting range Max 1 00 F401 2 00 e value 2 00 F403 Corresponding setting for upper limit
16. HF It stands for resetting process and will display target frequency after reset OC OCI OE Fault code indicating hardware over current software over current pr c OLI OL2 OH over voltage inverter over load motor over load over heat under voltage LU PFO PFI for input out phase for input and out phase for output respectively ESP During two line three line running mode stop reset key is pressed or extemal emergency stop terminal is closed ESP will be displayed F152 Function code parameter code 10 00 Indicating inverter s current running frequency or rotate speed and parameter setting values etc 50 00 Sparkling in stopping status to display target frequency Holding time when changing the running direction When Stop or Free Stop command is executed 0 the holding time can be canceled Output current 100A and output voltage 100V Keep one digit of decimal when current is below A100 U100 100A 11 E1000 III Installation amp Connection 3 1 Installation Inverter ngia be installed vertically as shown in Fig 3 1 Sufficient ventilation space should be ensured in its surrounding Clearance dimensions recommended are available from Table 3 1 for installing the inverter Table 3 1 Clearance Dimensions Inverter Model Clearance Dimensions Hanging lt 22kw A 150mm B gt 50mm Hanging 222kw A
17. Source 2 AI2 3 Input pulse given 0 x 4 5 Reserved pao Pe Digt Reco 0100 0 50 0 V rg Source 5 0 AIL 1 A2 FA03 Feedback Source 2 Input pulse frequency 0 x E 3 5 Reserved 5 FA04 Proportion Coefficient 0 0 100 0 20 0 y e FAOS Integral Time 0 1 10 0S 2 0 N DE b FAOG Precision 0 0 20 0 0 1 Y FA07 Show value of min feedback 07 9999 0 Y FA08 Show value of max feedback 07 9999 1000 Y FAO9 Reserved AN DOM aim function O Invalid 1 Valid 0 selection FALI Dormancy waking 0 100 10 af value 87 E1000 FA12 Feedback limit value 0 100 80 Y FA13 Dormancy delay time 0 300 0 S 60 08 Y FAI4 Wake delay time 0 300 0 S 60 0S N FA15 FA30 Reserved Note x indicating that function code can only be modified in stop state y indicating that function code can be modified both in stop and run state A indicating that function code can only be checked in stop or run state but cannot be modified indicating that function code cannot be initialized as inverter restores manufacturer s value but can only be modified manually V8090L0010c 88
18. after fault occurs inverter will display fault code it must be reset manually pis Selfstarting delay time Setting range 0 1 3000 0 Mfr s value 60 0 F215 is the selftstarting delay time for F213 and F214 The range is from 0 1s to 3000 0s F216 Times of selfstarting in case of repeated faults Setting range 07 5 IMfr s value 0 F217 Delay time for fault reset Setting range 0 0 10 0 IMfr s value 3 0 F216 sets the most times of selfstarting in case of repeated faults If starting times are more than the setting value of this function code inverter will not reset or start automatically after fault Inverter will run after running command is given to inverter manually F217 sets delay time for fault reset The range is from 0 0 to 10 0S which is time interval from fault to resetting Foo Frequency memory after power down Setting range 0 invalid 1 valid IMfr s value 0 F220 sets whether or not frequency memory after power down is valid This function is valid for F213 and F214 Whether or not to memory running state after power down or malfunction is set by this function The function of frequency memory after power down is valid for main frequency and accessorial frequency that is given by digital Because the accessorial frequency of digital given has positive polarity and negative polarity it is saved in the function codes F155 and F156 F222 count memory selection Setting ra
19. is from 0 to rated output voltage 5 6 Multi stage Speed Control The function of multi stage speed control is equivalent to a built in PLC in the inverter This function can set running time running direction and running frequency E1000 series inverter can realize 15 stage speed auto circulating and 8 stage speed auto circulating Setting range 0 3 stage speed F500 Stage speed type 1 15 stage speed Mfr s value 1 2 Max 8 stage speed auto circulating In case of multi stage speed control F203 4 the user must select a mode by F500 When F500 0 3 stage speed is selected When F500 1 15 stage speed is selected When F500 2 max 8 stage speed auto circulating is selected when F500 2 auto circulating is classified into 2 stage speed auto circulating 3 stage speed auto circulating 8 stage speed auto circulating which is to be set by F501 Table 5 5 Selection of Stage Speed Running Mode F203 F500 Mode of Running Description 3 tage Speed The priority in turn is stage 1 speed stage 2 speed and stage 3 speed 4 0 Gl It can be combined with analog speed control If F207 4 3 stage contr speed control is prior to analog speed control 4 1 15 stage speed It can be combined with analog speed control If F207 4 15 stage control speed control is prior to analog speed control Max 8 stage speed Adjusting the Sune EE manually is not pu dn 2 stage 4 2
20. limit of AI3 input p414 Upper limit of AB F412 10 0V 10 0V y channel input r415 Comesponding setting forh t 1 00 F413 2 00 2 00 y upper limit of AI3 input iig ein 0 0 10 0 1 0 Y proportional gain K1 F417 AD filtering time constant 0 1 50 0 5 0 N F418 ALI channel OHz voltage 0 0 50V 0 00 4 dead zone Positive Negative E419 AD channel OHz voltage 0 0 50V 0 00 4 dead zone F420 AI3 channel OHz voltage 0 0 50V 0 00 4 dead zone F421 F422 Reserved F423 AOI output range selecting 0 0 5V 1 0 10V 1 Y Corresponding frequency F424 for lowest voltage of 0 0 F425 0 05Hz Y AOI output Corresponding frequency F425 for highest voltage of F425 FI111 50 00Hz V AOI output F426 AOI output compensation 01204 100 Y F427 AO2 output range 0 0 20mA 1 4 20mAJO y F428 AO2 lowest corresponding 0 0 F429 0 05Hz 4 frequency pan EMEN e F428 Flll o 50 00Hz Y corresponding frequency F430 AO2 output compensation 01204 100 Ni F431 AOI analog output 0 Running frequency o J signal selecting 1 Output current F432 A 2 analog output 2 Output voltage N signal selecting 3 5 Reserved Corresponding current for full F433 range of extemal voltmeter 0 01 5 00 times of rated x F434 Corresponding curent for full current 2 x range of extemal ammeter F435 F436 Reserved F437 Analog filter width 17 100 10 81 E1000
21. memory 1 External analog ALI 2 External analog AD 3 Pulse input given 4 Stage speed control F203 Main frequency source X 5 No memory by digital setting 0 x 6 Keypad potentiometer 7 8 Reserved 9 PID adjusting 10 MODBUS 0 Digital setting memory 1 External analog ALI NS 2 External analog AD P204 Accessorial frequency 3 Pulse input given 0 x source Y 4 Stage speed control 5 PID adjusting 6 Keypad potentiometer AI3 Reference for selecting A besssorial 2 0 Relative to max frequency F205 sorial frequency s x 1 Relative to frequency X 0 x range F206 Accessorial frequency Y range O 100 100 x 0 X 1 X Y 2 X or Y terminal switchover F207 Frequency source selecting 3 X or X Y terminal switchover 0 x 4 Combination of stage speed and analog 5 X Y o 6 X 50 O other type 1 two line type 1 Terminal 2 two line type 2 F208 two line three line 3 three line operation control 1 0 X operation control 4 three line operation control 2 5 start stop controlled by direction pulse Selecting the mode of 0 stop by deceleration time Hm stopping the motor 1 free stop 9 X F210 Frequency display accuracy 0 01 2 00 0 01 Y F211 Speed of digital speed control 0 01 100 00Hz S 5 00 Hz S Y F212 Direction memory 0 Invalid 1 Valid 0 Y F213 Belfstartingafterrepoweredon 0 invalid 1 valid 0 y F214 Pelfstarting after res
22. oem 010096 50 y E frequency width E P iH e pior Dr 0 1000A Rated current y current Characteristi t F311 A O 100 10 y hysteretic loop width Frequency arrival F312 0 00 5 00H 0 00 Y threshold J Count fi F313 ountTequency 1 65000 1 y divisions F314 Set count values F315 65000 1000 Y Designated t F315 esignated ir 500 y values 79 E1000 no function ALA 0 F316 pi ya 1 running terminal 11 Y i 2 stop terminal OP terminal function 3 multi stage speed terminal l E317 5 4 multi stage speed terminal 2 9 V setting z 5 multi stage speed terminal 3 F318 OP3 terminal function 6 multi stage speed terminal 4 i5 N a setting 7 reset terminal ze RI 8 free stop terminal z F319 pre erminal function 9 external emergency stop terminal 16 N S setting 0 acceleration deceleration 3 OP5 terminal function forbidden terminal F320 Lattin 1 forward run jogging 7 Y d 2i reverse run jogging OP6 terminal function Up ery ee HUM F321 nad 4 DOWN frequency decreasing terminal 8 y setting 5 FWD terminal 5 mi A 6 REV terminal Q F322 QP7 erminal function 17 three ine type input X terminal 1 x setting 8 acceleration deceleration time S switchover terminal 9 20 Reserved z 21 frequency source switchover zi F323 OPS terminal function pane 2
23. reset key in keypad 7 Reset terminal TOU Long distance malfunction reset can be realized by this function 8 Free stop terminal Inverter closes off output and motor stop process is not controlled by inverter This mode is often used when load has big inertia or there are no requirements for stop time This mode has the same function with free stop of F209 9 External emergency When external malfunction signal is given to inverter stop terminal malfunction will occur and inverter will stop 0 Acceleration deceleration Inverter will not be controlled by external signal except for stop forbidden terminal command and it will run at the current output frequency 11 forward run jogging Forward jogging running and reverse jogging running Refer to a F124 F125 and F126 for jogging running frequency jogging 2 IY EISE EHI e acceleration deceleration time 3 UP frequency increasing terminal When frequency source is set by digital given the setting 4 DOWN frequency frequency can be adjusted which rate is set by F211 decreasing terminal 5 FWD terminal When start stop command is given by terminal or terminals 3 combination running direction of inverter is controlled by 6 REV terminal ternal terminals 7 Three line input X FWD REV CM terminals realize three line control See terminal F208 for details 8 acceleration deceleration When this function is selected second acceleration deceleration time
24. the half time of 10 protection timed ON signal stops outputting after overload stops or pre alarm overload protection occurs After motor overloads ON signal is output after the half time of 11 motor overload pre alarm protection timed ON signal stops outputting after overload stops or overload protection occurs 12 stalling During accel decel process inverter stops accelerating decelerating because inverter is stalling and ON signal is output When inverter is powered on Protection function is not in action 13 Inverter is ready to run and inverter is ready to run then ON signal is output Indicating that inverter is running and ON signal is output When 14 In running status 2 inverter is running at OHZ it seems as the running status and ON signal is output 15 Beduency arial dis Indicating inverter runs to the setting target frequency and ON signal is output See F312 When testing temperature reaches 80 of setting value ON signal 16 overheat pre alarm is output When overheat protection occurs or testing value is lower than 80 of setting value ON signal stops outputting At E1000 17 over latent current output When output current of inverter reaches the setting overlatent current ON signal is output See F310 and F311 18 reserved reserved F303 DO output types selection Setting range 0 level output pulse output Mfr s value 0 When level output is se
25. time Setting range 0 300 0 S 60 0S Dormancy function is an energy saving mode when PID mode is selected F203 9 When FA10 1 if inverter runs at the min frequency for a period time set by FA13 inverter will output OHz to save energy and run lamp twinkles After inverter is awakened PID adjusting will go on Dormancy waking value is the percentage of max value of feedback channel For example AN2 channel is feedback channel which input voltage range is 0 10V when FA11 10 then waking value is 10V 10 1V When feedback value is lower than FALI negative feeback or higher than FALI positive feedback inverter is awakened and PID adjusting will go on Feedback limit value is the percentage of max value of feedback channel When feedback value is higher than negative feedback or lower than positive feedback the setting value of FAI2 inverter will immediately free stop Delay time before dormancy is set by FA13 Delay time before wake up is set by FA14 E1000 Appendix 1 Trouble Shooting When malfunction occurs to inverter don t run by resetting immediately Check any causes and get it removed if there is any Take counter measures by referring to this manual in case of any malfunctions on inverter Should it still be unsolved contact the manufacturer Never attempt any repairing without due authorization Table 1 1 Inverter s Common Cases of Malfunctions Fault Description Causes Countermeasures Hardw
26. 0 1 3000S Mfr s value For 0 2 3 7KW 8 0S For 5 5 30KW 50 0S F117 Second Deceleration Time S For above 37KW 90 0S Acceleration Time The time for inverter to accelerate from OHz to 50Hz Deceleration Time The time for inverter to decelerate from 50Hz to 0Hz The reference of setting accel decel time is set by F119 The second Acceleration Deceleration time can be chosen by multifunction digital input terminals F316 F323 Set the value of function code to 18 and select the second acceleration Deceleration time by connecting OP terminal with CM terminal Setting range 0 0 50 00Hz Mfr s value O 1 O max frequency See F119 The reference of setting accel decel time When F119 0 acceleration deceleration time means the time for inverter to accelerate decelerate from OHz 50Hz to 50Hz 0Hz When F119 1 acceleration deceleration time means the time for inverter to accelerate decelerate from OHz max frequency to max frequecy OHz F118 Turnover Frequency Hz Setting range 15 00 650 0 Mfr s value 50 00Hz Turnover frequency is the final frequency of V F curve and also is the least frequency according to the highest output voltage When running frequency is lower than this value inverter has constant torgue output When running frequency exceeds this value inverter has constant power output F120 Forward Reverse Switchover dead Time S Setting range 0 0 3000
27. 0 690 D4 Air Cooling 535 amp E1000 4500T3D 450 770 D5 Air Cooling 670 E1000 5000T3D 500 860 D5 Air Cooling 675 E1000 5600T3D 560 950 D5 Air Cooling 700 E1000 6300T3D 630 1100 D5 Air Cooling 700 E1000 0185T3R 18 5 38 E7 Air Cooling 24 5 2 E1000 0220T3R 22 44 E7 Air Cooling 25 5 E A E1000 0300T3R 30 60 E7 Air Cooling 28 S E1000 0370T3R 37 75 E8 Air Cooling 48 R E E1000 0450T3R 45 90 E8 Air Cooling 49 E di z E1000 0550T3R 55 110 E8 Air Cooling 52 z E E1000 0750T3R 75 150 E9 Air Cooling 66 5 E1000 0900T3R 90 180 E9 Air Cooling 67 5 62 E1000 Table 2 2 E1000 Types of Product Structure Structure External Dimension Mounting Mounting Remarks Code AxB BI xH Size WxL Bolt El 80x135 142 x138 70x128 M4 E2 106x150 157 x180 94x170 M4 T eg E3 106x170 177 x180 94x170 M4 2 B E4 138x152 159 x235 126x225 M5 B E5 156x170 177 x265 146x255 M5 E6 205x196 202 x340 194x330 MS E7 271x235x637 235x613 M6 E8 360x265x901 320x876 M8 E9 420x300x978 370x948 M10 C3 265x235x435 235x412 M6 ES C5 360x265x555 320x530 M8 E C6 410x300x630 370x600 MIO C7 516x326x760 360x735 M12 F C8 560x326x1000 390x970 MI2 ia C9 400x385x1300 280x1272 M10 CA 535x380x1330 470x1300 M10 CB 600x380x1580 545x1550 M10 DO 580x500x1410 410x300 M16 z D1 600x500x1650 400x300 M16 S D2 660x500x1850 450x300 M16 a D3 800x600x1950 520x340 M16 e D4 1
28. 000x550x2000 800x350 M16 ei DS 1200x600x2200 986x400 M16 Note 1 the unit is mm 4 a vn 01000 la zT 1000 88891298 A EN BELL Plastic Profile 63 E1000 BA Appendix3 Selection of Braking Resistance Applicable Motor Inverter Models Applicable Braking Resistance Power KW E1000 0002S2 0 2 E1000 000482 0 4 E1000 000782 0 75 150W 602 E1000 0015S2 1 5 E1000 0022S2 2 2 E1000 0007T3 0 75 80W 200Q E1000 0015T3 1 5 80W 150Q E1000 0022T3 2 2 E1000 0037T3 3 7 150W 150Q E1000 0040T3 4 0 E1000 0055T3 3 9 250W 1209 E1000 0075T3 TS 500W 120Q E1000 0110T3C 11 1KW 90Q E1000 0150T3C 15 1 5KW 80Q E1000 E1000 Appendix 4 Communication Manual Version 1 8 I General Modbus is a serial and asynchronous communication protocol Modbus protocol is a general language applied to PLC and other controlling units This protocol has defined an information structure which can be identified and used by a controlling unit regardless of whatever network they are transmitted You can read reference books or ask for the details of MODBUS from manufactures Modbus protocol does not require a special interface while a typical physical interface is RS485 II Modbus Protocol 2 1 Transmission mode 2 1 1 Format 1 ASCII mode Start Address Function Data LRC check End In
29. 2200mm B gt 75mm Cabinet 110 630kw C2200mm D gt 75mm 3 2 Connection e In case of 3 phase input connect R LI S L2 and T L3 terminals LI R and L2 S terminals for single phase with Fig 3 1 Installation Sketch power source from network and rh PE E to earthing U V and W terminals to motor anne jen e Motor shall have to be ground connected Orelse electrified motor causes interference e For inverter power lower than 15kw braking cell is also built in If the load inertia is moderate itis Ok to only connect braking resistance Power terminals sketch of inverter with single phase 230V 0 2 0 75KW d Li L2 P B U V W Grounding Input 230V For braking resistor Output Power terminals sketch of inverter with single phase 230V 1 5 2 2KW and three phase 400V 0 75KW 15KW m L RI IL2S L3T P B U V W Grounding Input 400V For braking resistor Output Note power terminals L1 R L2 S of single phase 230V 1 5KW and 2 2KW are connected to 230V of power grid L3 T is not connected The inverters below 11kw have no the terminal 12 E1000 Power terminals sketch of inverter with three phase 400V above 18 5KW EN 7 For Grounding DC choke biking nit Input 400V Output The figure is only sketch terminals order of practical products may be different from the above mentioned
30. 3 0 then inverter will stop after auto circulation is finished If F503 1 then inverter will run at the speed of the last stage after auto circulation is finished as follows e g F501 3 then inverter will run at auto circulation of 3 stage speed F502 100 then inverter will run 100 times of auto circulation F503 1 inverter will run at the speed of the last stage after the auto circulation running is finished After circulating Start auto Stage 1 Stage 3 1100 times Keep running at circulating running Speed Speed Stage 3 speed Figure 5 11 Auto circulating Running Then the inverter can be stopped by pressing stop or sending stop signal through terminal during auto circulation running F504 Frequency setting for stage 1 speed fr s value 5 00Hz F505 Frequency setting for stage 2 speed fs value 10 00Hz F506 Frequency setting for stage 3 speed fr s value 15 00Hz F507 Frequency setting for stage 4 speed fr s value 20 00Hz F508 Frequency setting for stage 5 speed fr s value 25 00Hz F509 Frequency setting for stage 6 speed Setting range fr s value 30 00Hz FI12 F111 F510 Frequency setting for stage 7 speed fr s value 35 00Hz F511 Frequency setting for stage 8 speed fr s value 40 00Hz F512 Frequency setting for stage 9 speed fr s value 5 00Hz F513 Frequency setting for stage 10 speed fr s value 10 00Hz F514 Frequency setting for stage 11 s
31. 4 d setting 22 Count input terminal E 23 Count reset terminal E 24 30 Reserved n F324 Free stop terminal logic Uu g D 0 positive logic valid for low level F325 rae mA stop 1 negative logic valid for high level 0 X terminal logic F328 Terminal filter times 17 100 10 y F329 330 Reserved Function Function Function Setting Rance Mfr s Change Section Code Definition 8 8 Value gt F400 ey An 0 00 F402 0 01V y Z Corresponding setting for D sponding setting fo ne e n lower limit of AII input piis pu y F402 paie au F400 10 00V 10 00V y Corresponding setting f E F403 omesponding SEDE 10T Max 1 00 F401 2 00 2 00 m upper limit of ALI input 5 2 yap a F404 All channel proportional 0 0 10 0 10 4 o gain KI E F405 AU filtering time constant 0 01 10 00 0 10 K F4og Lowerlimit of AD 0 00 F408 0 01V K E ans F407 Corresponding setting for 0 F409 1 00 4 lower limit of AD input 80 E1000 jndjng pue jndug sojeuy r4og Upper limit of A12 F406 10 00V 10 00V Y channel input Corresponding setting for M F409 upper limit of AI2 input Max 1 00 F407 2 00 2 00 V Pan AD channel 0 0 10 0 1 0 V proportional gain K2 F411 AD filtering time constant 0 1 50 0 5 0 Ni pap Loss MOL ADS 0 00 F414 0 05V y channel input Corresponding setting for F413 O F415 1 00 y lower
32. 4 2 Mode of torque compensation Linear compensation F137 0 Square compensation F137 1 User defined multipoint compensation F137 2 Auto torque compensation F137 3 4 3 Mode of frequency setting Please refer to F203 F207 for the method for setting the running frequency of the E1000 inverter 4 4 Mode of controlling for running command The channel for inverter to receive control commands including start stop and jogging etc contains three modes 1 Keypad keypad panel control 2 External terminal control 3 Modbus control The modes of control command can be selected through the function codes F200 and F201 4 5 Operating status of inverter When the inverter is powered on it may have four kinds of operating status stopped status programming status running status and fault alarm status They are described in the following 4 5 1 Stopped status If re energize the inverter if self startup after being powered on is not set or decelerate the inverter to stop the inverter is at the stopping status until receiving control command At this moment the running status indicator on the keypad goes off and the display shows the display status before power down 4 5 2 Programming status Through keypad panel the inverter can be switched to the status that can read or change the function code parameters Such a status is the programming status There are numbers of function parameters in the inverter By changing these parameters
33. 50Hz 50Hz 2 5V corresponds to OHz by setting the function of corresponding setting for upper lower limit of analog input The group function codes of F418 F419 and F420 set the voltage range corresponding to OHz For example when F418 0 5 F419 0 5 and F420 0 5 the voltage range from 2 5 0 5 2 to 2 5 0 5 3 corresponds to OHz So if F418 N F419 N and F420 N then 2 5XN should correspond to OHz If the voltage is in this range inverter will output OHz OHZ voltage dead zone will be valid when corresponding setting for lower limit of input is less than 1 00 E1000 series inverters have two analog output channels F437 Analog filter width Setting range 1100 Mfr s value 10 The greater the setting value of F437 is the steadier the detecting analog is but the response speed will decrease Please set it according to the actual situations F460 Allchannel input mode Setting range 0 straight line mode Mfr s value 0 1 folding line mode F461 AD channel input mode Setting range 0 straight line mode Mfr s value 0 1 folding line mode F462 AIl insertion point Al voltage value Setting range F400 F464 Mfr s value 2 00V F463 AIl insertion point A1 setting value Setting range F401 F465 Mfr s value 1 40 F464 AII insertion point A2 voltage value Setting range F462 F466 Mfr s value 3 00V F465 AIl insertion point A2 setting value Setting range F463 F467 Mfr s value 1 60
34. A speed auto circulating 3 stage speed auto circulating 8 stage auto circulating 3 ites speed auto circulating may be selected through setting the parameters F501 Selection of Stage Speed Under Setting range 2 8 Mfr s value 7 Auto circulation Speed Control 52 E1000 7 2 8 Setting range 07 9999 F502 Selection of Times of Auto circulation g rang x when the value is set to 0 the inverter Mfr s value 0 Speed Control AREE f will carry out infinite circulating F503 Status After Auto circulation Setting range A3 Mfr s value 0 Running Finished 0 Stop 1 Keep running at last stage speed If running mode is auto circulation speed control F203 4 and F500 2 please set the related parameters by F501 F503 That the inverter runs at the preset stage speed one by one under the auto circulation speed control is called as one time If F502 0 inverter will run at infinite auto circulation which will be stopped by stop signal If F502 gt 0 inverter will run at auto circulation conditionally When auto circulation of the preset times is finished continuously set by F502 inverter will finish auto circulation running conditionally When inverter keeps running and the preset times is not finished if inverter receives stop command inverter will stop If inverter receives run command again inverter will auto circulate by the setting time by F502 If F50
35. CONTENTS Ti Product Pm 1 1 1 Productmodelnamingtule 1 1 2 Optonalfunc onnamingnule 1 1 3 tNamepl te si sekeri iie inik e i er et qs 2 LA Appearances ie eee eene speed BEYE ek faves 2 1 5 TechnicalSpecificatlons 4 1 6 Designed Standards for Implementation 5 17 Safelnstructions meme 5 1 8 Precautions i ERE DEINER SEL N 6 1 9 ExaminattonandMaintenance 7 II Keypad panel e e oeste e ee PH EMT retta 8 21 Panellllustrations cssssssee na sata 8 2 2 Panel StUctre ss s0 eee e ee Re hn nn EK 9 2 3 Panel Operating csssssssessse 9 24 ParametersSetting 10 2 5 Function Codes Switchover In Between Code Groups 10 2 6 Panel Display eee RR ehe te Inns 11 III Installation amp Connection sssesee 12 3 1 Installation c2ccighseuereagaee rae oe e ien sesine en diz oet 12 3 2 Confiecti n zi sie e eet eee ERR INI a a ies 12 3 3 FunctonofControl Terminals 14 3 4 WiringRecommended 17 3 5 Lead Section Area of Protect Conductor grounding wire 17 3 6 OverallConnecton 18 IV Operation and Simple Running eee 19 Ve F nction P ramete
36. Code 100 400 Subject to inverter model F105 Software Edition No 1 00 10 00 Subject to inverter model F107 Password Valid or Not 0 invalid 1 valid 0 Y F108 Setting User s Password 07 9999 8 Y F109 Starting Frequency Hz 0 0 10 00Hz 0 00Hz V Fig Haane amin 001005 00 Y Frequency S Fill Max Frequency Hz v F113 650 0Hz 50 00Hz Y e F112 Min Frequency Hz 0 00Hz F113 0 50Hz Y z F113 Target Frequency Hz F111 F112 50 00Hz Y ro F114 I Acceleration Time 0 1 30008 O 505for0237KW Y 30 0S for 5 5 30KW g F115 1 Deceleration Time 0 1 3000S 60 08 for above 37KW Y z F116 2 Acceleration Time 0 1 30008 80S for0 2 3 7KW y P 50 0S for 5 5 30KW s F117 2 Deceleration Time 0 1 3000S 9008 for above 37KW y F118 Turnover Frequency 15 00 650 0Hz 50 00 x F119 Reference of settingO 0730 007 0 x accel decel time 1 O max frequency e Rever 0 0 3000S 0 08 Y Switchover dead Time f F121 Reserved F122 Reverse Running Forbidden O invalid 1 valid 0 X Minus frequency is valid in F123 the mode of combined speed O Invalid 1 valid 0 X control F124 Jogging Frequency F112 F111 5 00Hz y F125 Jogging Acceleration Time 0 1 3000S 0 2 3 7KW 5 0S V 5 5 30KW 30 0S F126 Jogging Deceleration Time 0 1 3000S Above37KW 60 0S V 75 E1000 SJ93j9ure eq seg F127 Skip Frequency A 0 00 650 0Hz 0 00Hz Y F128 Skip Width A 2 50Hz 0 00 V F129 Skip Fre
37. DEN 0 1 60 0 0 5 Y filtering constant F729 Undervoltage filtering 0 1 60 0 50 4 constant F730 Overheat protection 0 1 60 0 50 4 filtering constant pp bete overcurrent O Invalid 1 Valid 0 x protection Software over current rs protection Coefficient VITAN e x F739 Software over current A protection record F740 Reserved 86 E1000 Function Function Function Setting Range Mfr s Change Section Code Definition B B Value 8 SNC Setting range F800 Er S parameters 0 no parameter measurement 0 X en 1 Stator resistance parameter measurement F801 Rated power 0 2 1000KW x 3 F802 Rated voltage 1 440V x s z F803 Rated current 0 1 6500A x E H F804 Number of motor poles 27 100 4 X i F805 Rated rotary speed 1 30000 x id F806 Stator resistance 0 001 65 000 x F807 F809 Reserved F810 Motor rated frequency 1 0 650 0Hz 50 00 x F811 F830 Reserved F900 Communication 1 255 single inverter address 1 4 o Address 0 broadcast address e Communication Mode l ASCHE 2 RTU 4 J F901 3 3 Remote controlling keypad 5 s F902 Reserved 3 gt 3 A 0 no calibration 1 odd calibration 5 F903 Odd Even Calibration sven calibration 0 vV te 0 1200 1 2400 2 4800 3 F904 Baud Rate 3 9600 4 19200 5 38400 3 N 6 57600 F905 F930 Reserved FAO00 Polarity 0 posuve ee 0 x 1 negative feedback 0 Given Digit 1 ATI FA01 Reference
38. E1000 1 Output current F432 AO2 analog output signal selecting 2 Output voltage Mfr s value 1 35 Reserved Token contents output by analog channel are selected by F431 and F432 Token contents include running frequency output current and output voltage When output current is selected analog output signal is from 0 to twofold rated current When output voltage is selected analog output signal is from OV to rated output voltage 230V or 400V F433 Corresponding current for full range of external g volets Me rs Mfr s value 2 00 0175 00 times of rate F434 Corresponding current for full range of external enint Mfr s value 2 00 ammeter In case of F431 1 and AOI channel for token current F433 is the ratio of measurement range of external voltage type ammeter to rated current of the inverter In case of F432 1 and AO2 channel for token current F434 is the ratio of measurement range of external current type ammeter to rated current of the inverter For example measurement range of external ammeter is 20A and rated current of the inverter is 8A then F433 20 8 2 50 5 5 Pulse input output F440 Min frequency of input pulse FI Setting range 0 00 F442 Mfr s value 0 00K F441 Corresponding setting of FI mi orresponding seting of Y mm setting range 0 00 F443 Mfi s value 1 00 frequency F442 Max frequency of input pulse FI Setting range F440 50 00K Mfr s v
39. F111 and F112 Starting frequency should be lower than Max frequency set by F111 If starting frequency is lower than target frequency set by F113 starting frequency will be invalid 26 E1000 F111 Max Frequency Hz Setting range F113 650 0 Mfr s value 50 00Hz F112 Min Frequency Hz Setting range 0 00 F113 Mfr s value 0 50Hz Max frequency is set by FILI Min frequency is set by F112 The setting value of min frequency should be lower than target frequency set by F113 The inverter begins to run from the starting frequency During inverter running if the given frequency is lower than min frequency then inverter will run at min frequency until inverter stops or given frequency is higher than min frequency Max Min frequency should be set according to the nameplate parameters and running situations of motor The motor is forbidden running at low frequency for a long time or else motor will be damaged because of overheat F113 Target Frequency Hz Setting range F112 F111 Mfr s value 50 00Hz It shows the preset frequency Under keypad speed control or terminal speed control mode the inverter will run to this frequency automatically after startup F114 First Acceleration Time S Mfr s value For 0 2 3 7KW 5 0S 3 For 5 5 30KW 30 0S F115 First Deceleration Time S Setting range For above 37KW 60 0S F116 O Second Acceleration Time S
40. F300 15 and F301 15 threshold range is set by F312 For example when F301 15 target frequency is 20HZ and F312 2 the running frequency reaches 18Hz 20 2 ON signal is output by DOI until the running frequency reaches target frequency F313 Count frequency divisions Setting range 17 65000 Mfr s value 1 F314 Set count values Setting range F315 65000 Mfr s value 1000 F315 Designated count values Setting range 1 F314 Mfr s value 500 Count frequency divisions refer to the ratio of actual pulse input and inverter s count times i e Actual Pulse Input Inverter s Count Times Count Frequency Division e g when F313 3 inverter will count once for every 3 inputs of external pulse Set count values refer to a count width pulse output by the output terminal DOI terminal or relay programmed with reaching the set count values function when a certain number of pulses are input from OP1 Count will restart after the count value reaches set times As shown in Fig 5 6 if F313 1 F314 8 F301 8 DOL will output an instruction signal when OPI 42 E1000 inputs the 8 pulse Designated count values refer to an pulse output by the output terminal DOI or RELAY terminal programmed with reaching the set count values function when a certain number of pulses are input from OPI until count value reaches the set times As shown in Fig 5 6 if F313 1 F314 8 F315 5 F300 9 relay will
41. F466 AIl insertion point A3 voltage value Setting range F464 F402 Mfr s value 4 00V F467 AIl insertion point A3 setting value Setting range F465 F403 Mfr s value 1 80 F468 AD insertion point B1 voltage value Setting range F406 F470 Mfr s value 2 00V F469 AD insertion point B1 setting value Setting range F407 F471 Mfr s value 1 40 F470 AD insertion point B2 voltage value Setting range F468 F472 Mfr s value 3 00V F471 AI insertion point B2 setting value Setting range F469 F473 Mfr s value 1 60 F472 AD insertion point B3 voltage value Setting range F470 F412 Mfr s value 4 00V F473 AD insertion point B3 setting value Setting range F471 F413 Mfr s value 1 80 When analog channel input mode selects straight line please set it according to the paremeters from F400 to 48 E1000 F429 When folding line mode is selected three points AI B1 A2 B2 A3 B3 are inserted into the straight line each of which can set the according frequency to input voltage Please refer to the following figure According setting frequency 100 F400 AZ A3 F402 Fig 5 9 Folding analog with setting value F400 and F402 are lower upper limit of analog All input When F460 1 F462 2 00V F463 1 4 F111 50 F203 1 F207 0 then Al point corresponding frequency is F463 1 F111 20Hz which means 2 00V corresponding to 20Hz The other points can be set by the same way AD channel has the same setting way as AI
42. MSB Extract and examine the LSB 4 If the LSB was 0 Repeat Step 3 another shift E1000 If the LSB was 1 Exclusive OR the CRC register with the polynomial value A001 hex 1010 0000 0000 0001 5 Repeat Steps 3 and 4 until 8 shifts have been performed When this is done a complete 8 bit byte will have been processed When the CRC is appended to the message the low order byte is appended first followed by the high order byte 2 4 3 Protocol Converter It is easy to turn a RTU command into an ASCII command followed by the lists D 2 3 4 Use the LRC replacing the CRC Transform each byte in RTU command into a corresponding two byte ASCII For example transform 0x03 into 0x30 0x33 ASCII code for 0 and ASCII code for 3 Add a colon character ASCII 3A hex at the beginning of the message End with a carriage return line feed CRLF pair ASCII OD and 0A hex So we will introduce RTU Mode in followed part If you use ASCII mode you can use the up lists to convert 2 5 Command Type amp Format 2 5 1 The listing below shows the function codes code name description 03 Read Holding Registers Read the binary contents of holding registers in the slave Less than 10 registers once time 06 Preset Single Register Preset a value into holding register 2 5 2 Address and meaning The part introduces inverter running inverter status and related paramet
43. Mfr s value 0 00S Within forward reverse switchover dead time this latency time will be cancelled and the inverter will switch to run in the other direction immediately upon receiving stop signal This function is suitable for all the speed control modes except automatic cycle operation 27 E1000 This function can ease the current impact in the process of direction switchover F122 Reverse Running Forbidden Setting range 0 invalid 1 valid Mfr s value 0 When F122 1 inverter will only run forward no matter the state of terminals and the parameters set by F202 Inverter will not run reverse and forward reverse switchover is forbidden If reverse signal is given inverter will stop F123 Minus frequency is valid in the mode of combined speed control O Invalid 1 valid 0 In the mode of combined speed control if running frequency is minus and F123 0 inverter willrun at OHz if F123 1 inverter will run reverse at this frequency This function is controlled by F122 F124 Jogging Frequency Hz Setting range F112 F111 Mfr s value 5 00Hz F125 Jogging Acceleration Time S Setting range Mfr s value For 0 2 3 7KW 5 08 i For 5 5 30KW 30 0S F126 Jogging Deceleration Time S 9 3000 For above 37KW 60 0S There are two types of jogging keypad jogging and terminal jogging Keypad jogging is valid only under s
44. OP8 control terminal Wiring for digital input terminals Generally shield cable is adopted and wiring distance should be as short as possible When active signal is adopted it is necessary to take filter measures to prevent power supply interference Mode of contact control is recommended Digital input terminals are only connected by source electrode NPN mode or by drain electrode PNP mode If NPN mode is adopted please turn the toggle switch to the end of NPN Wiring for control terminals as follows 1 Wiring for positive source electrode NPN mode 8 o Inverter j Control K8 es OP8 d 15 E1000 2 Wiring for active source electrode NPN mode l Contred l jener I Bount 1 I l 1 If digital input control terminals are connected by drain electrode please turn the toggle switch to the end of PNP Wiring for control terminals as follows 3 Wiring for positive drain electrode PNP mode E1000 Wiring by source electrode is a mode most in use at present Wiring for control terminal is connected by source electrode before delivery user should choose wiring mode according to reguirement Instructions of choosing NPN mode or PNP mode 1 There is a toggle switch J7 near to control terminals Please refer to NPN Im PNP iz Fig 3 2 b 2 When turning J7 to NPN OP terminal is connected to CM When tu
45. X Setting range 0 other type F208 XP y Two line operation mode 1 Terminal p Two line operation mode 2 Mfr s value 0 two line three line i y three line operation mode 1 operation control three line operation mode 2 start stop controlled by direction pulse Un BLM R When selecting two line type or three line type F200 F201 and F202 are invalid Five modes are available for terminal operation control Note In case of stage speed control set F208 to 0 If F208 40 when selecting two line type or three line type F200 F201 and F202 are invalid FWD REV and X are three terminals designated in programming OP1 OP6 1 Two line operation mode 1 this mode is the most popularly used two line mode The running direction of mode is controlled by FWD REV terminals For example FWD terminal open stop closed forward running REV terminal open stop closed reverse running CM terminal common port 37 E1000 KI K2 Running command 0 0 Stop 1 0 Forward running 0 1 Reverse running 1 1 Stop 2 Two line operation mode 2 when this mode is used FWD is enable terminal the direction is controlled by REV terminal For example FWD terminal open stop closed running REV terminal open forward running closed r
46. Y s F450 Zero drift coefficient of 0 0 100 0 0 0 J output pulse frequency F451 Frequency gain of 0 00 10 00 1 00 V output pulse F452 Reserved 82 E1000 0 Running freguency Xe e 1 Output current F453 Output pulse signal 2 Output voltage 0 Y 37 5 reserved Function Function Function 2 5 Section Code Definition Setting Range Mfr s Value Change 0 3 stage speed Mo 1 15 stage speed F500 Stage speed type 2 Max 8 stage speed auto 1 x circulating Selection of Stage Speed F501 Under Auto circulation 27 8 7 Y Speed Control 07 9999 when the value F502 Selection of Times of Auto is set to 0 the inverter 0 J Circulation Speed Control will carry out infinite circulating Status after auto 0 Stop F503 circulation running 1 Keep running at last 0 N Finished stage speed pso4 MEN FH2 FI1 5 00Hz y z stage 1 speed J pso5 al m setting for F112 F111 10 00Hz y a stage 2 speed T PUT w F506 erime for F112 F111 15 00Hz y t stage 3 speed Ya F507 Frequency setting for F112 F111 20 00Hz J un stage 4 speed 2 F508 Frequency setting for F112 F111 25 00Hz 4 amp stage 5 speed a Pob al setting for FH2 FI1 30 00Hz y e stage 6 speed 5 EYE E pay e setting for F112 F111 35 00Hz y stage 7 speed a Frequency setting for F511 F112 F111 40 00Hz Y stage 8 speed ps 2 Ereguency setting for F112 F111 5 00Hz y sta
47. ad slip compensation should be adopted according to the setting value of frequency compensation Setting range 0 Linear compensation F137 Modes of torque compensation 1 Square compensation Mfr s value 3 2 User defined multipoint compensation 3 Auto torque compensation Mfr s value 0 2 3 7 5 5 5 30 4 Above 37 3 F138 Linear compensation Setting range 17 716 Setting range 1 1 5 2 1 8 F139 Square compensation 3 19 4 20 Mfr s value 1 To compensate low frequency torque controlled by V F output voltage of inverter while V CH low frequency should be compensated When F137 0 linear compensation is chosen and it is applied on universal constant torque load When F137 1 square compensation is chose and it is applied on the loads of fan or water pump When F137 2 user defined multipoint compensation is chosen and it is applied on the E t special loads of spin drier or centrifuge es This parameter should be increased when the US Uo te load is heavier and this parameter should be decreased when the load is lighter If the torque is elevated too much motor is easy to overheat and the current of inverter will be too high Please check the motor while elevating the torque When F137 3 auto torque compensation is chose and it can compensate low frequency torque automatically to diminish motor slip to make rotor rotary speed close to synchro rotary speed and to restrai
48. age DC over voltage over current Function over load current stall over heat external disturbance LED nixie tube showing present output frequency present rotate speed rpm present output Display current present output voltage present linear velocity types of faults and parameters for the system and operation LED indicators showing the current working status of inverter In an indoor location Prevent exposure from direct Equipment Location sunlight Free from dust tangy caustic gases flammable gases steam or the salt contented etc gt us Environment Temperature 10 C 50 C Conditions Envi Humidity Below 90 no water bead coagulation lt 9 lt lt Vibration Strength Below 0 5g acceleration Height above sea level 1000m or below E1000 Protection 1P20 level Applicable Moise 0 2 630KW 1 6 Designed Standards for Implementation IEC EN 61800 5 1 2003 Adjustable speed electrical power drive systems safety requirements IEC EN 61800 3 2004 Adjustable speed electrical power drive systems Part 3 EMC product standard including specific test methods 1 7 Safe instructions Please check the model in the nameplate of the inverter and the rated value of the inverter Please do not use the damaged inverter in transit Installation and application environment should be free of rain drips steam dust and oily dirt without corrosive or flammable gases or liquids
49. al speed control in mode of analog signals control External potentiometer or external analog signal can also be used gt Press Fun for function code and set for original parameters T and V keys can be used to select function codes and parameters Press set again to confirm In the mode of keypad control Aand V keys can also be used for dynamic speed control Run and Stop Reset keys control start and stop Press Stop Reset key to Operation panel reset inverter in fault status BBBH Stop Reset keys control start and stop Press Stop Reset key to J reset inverter in fault status p Operation So se LED shows running frequency flashing target frequency function code parameter value or fault code ALEDs indicate working status RUN is lighting while running FWD is lighting when working forward and FRQ is lighting when showing frequency Press Fun for function code and set for original parameters A gt and V keys can be used to select function codes and parameters Press set again to confirm In the mode of keypad control Aand L Wkeys can also be used for dynamic speed control Run and panel m ad Operation Panels in Two Kinds Instructions for operation panel 1 Operation panels of below 15KW can not b
50. ally When the load Checking under with is increased to 50 and 100 keep the inverter run for a load period respectively to check if the system is running normally Carry out overall inspection over the inverter during running to check if there is any abnormality In case of any abnormality stop and check the inverter immediately Check if the motor is running stably if the rotary direction of the motor is correct if there is any abnormal vibration or noise when the motor is running if the acceleration deceleration Checking during process of the motor is stable if the output status of the inverter and the display of keypad panel is correct if the blower fan is run normally and if there is any abnormal vibration or noise In case of any abnormality stop the inverter immediately and check it after switching off the power supply 4 9 Illustration of basic operation Illustration of inverter basic operation we hereafter show various basic control operation processes by taking a 7 5kW inverter that drives a 7 5kW three phase asynchronous AC motor as an example The parameters indicated on the nameplate of the motor are as follows 4 poles rated power 7 5KW rated voltage 400V rated current 15 4A rated frequency 50 00HZ and rated rotary speed 1440rpm running 4 9 1 Operation processes of frequency setting start forward running and stop with keypad panel 1 Connect the wires in accordance with Figure 4 1 After having checked
51. alue 0 F108 Setting User s Password Setting range 0 9999 Mfr s value 8 When F107 is set to 0 the function codes can be changed without inputting the password When F107 is set to 1 the function codes can be changed only after inputting the user s password by F100 The user can change User s Password The operation process is the same as those of changing other parameters Input the value of F108 into F100 and the user s password can be unlocked Note When password protection is valid and if the user s password is not entered F108 will display 0 F109 Starting Frequency Hz Setting range 0 00 10 00 Mfr s value 0 00 Hz F110 Holding Time of Starting Frequency S Setting range 0 0 10 0 Mfr s value 0 0 The inverter begins to run from the starting frequency If the target frequency is lower than starting frequency F109 is invalid The inverter begins to run from the starting frequency After it keeps running at the starting frequency for the time as set in F110 it will accelerate to target frequency The holding time is not included in acceleration deceleration time Starting frequency is not limited by the Min frequency set by F112 If the starting frequency set by F109 is lower than Min frequency set by F112 inverter will start according to the setting parameters set by F109 and F110 After inverter starts and runs normally the frequency will be limited by frequency set by
52. alue 10 00K F443 Corresponding setting of FI max Setting range Max 1 00 Mffr s value 2 00 frequency F441 2 00 dco F445 Filtering constant of FI input pulse Setting range 07100 Mfr s value 0 Setting range 0 F442 Mfr s value 0 00 Positive Negative e F446 FI channel OHz freguency dead zone Min frequency of input pulse is set by F440 and max frequency of input pulse is set by F442 For example when F440 0K and F442 10K and the max frequency is set to 50Hz then input pulse frequency 0 10K corresponds to output frequency 0 50Hz Filtering time constant of input pulse is set by F445 The greater the filtering time constant is the more steady pulse measurement but precision will be lower so please adjust it according to the application situation Corresponding setting of min frequency is set by F441 and corresponding setting of max frequency is set by F443 When the max frequency is set to 50Hz pulse input 0 10K can corresponds to output frequency 50Hz 50Hz by setting this group function codes Please set F441 to 0 and F443 to 2 then OK corresponds to 50Hz 5K corresponds to OHz and 10K corresponds to 50Hz The unit of corresponding setting for max min pulse frequency is in percentage 96 If the value is greater than 1 00 it is positive if the value is less than 1 00 it is negative If the running direction is set to forward by F202 then 0 5K corresponding to the minus frequency w
53. apacity 150 rated current 60 seconds Auto torque promotion Manual Torque Promotion Torque Elevating 0 1 30 0 VV VF Control VFC 3 kinds of modes beeline type square type and Mode e under defined V F curve DC Braking DC braking frequency 1 0 5 0 Hz braking time 0 0 10 0s Jogging frequency range min frequency max frequency J Control SEE EO jogging acceleration deceleration time 0 1 3000 0s Auto Circulating Running and Auto circulating running or terminals control can realize multi stage speed running 15 stage speed running Built in PID adjusting Easy to realize a system for process closed loop control Potentiometer or external analog signal 07 5 V 0 10V Frequency Setting 0 20mA keypad terminal A V keys external control logic and automatic circulation setting Start Stop Control Terminal control keypad control or communication control Operation 3 kinds of channels from keypad pz inal e 2 s E ypad panel control terminal and Fonchon Running Command Channels series communication port Frequency Source Frequency sources given digit given analog voltage given analog current and given series communication port i Flexible implementation of 5 kinds of accessorial frequency Accessorial frequency Source fine adjustments and frequency compound Optional Built in EMI filter built in braking unit Modbus communication telecontrol panel Protection Input out phase Output out phase input under volt
54. are RE prolong acceleration time O C too short 2 pro One me Overcurrent Bi aoe oie ol E whether motor cable is broken Software E g check if motor overloads OS Overcurrent locked ME with motof reduce V F compensation value Inverter TERE reduce load check drive ratio O Overload load tooiheavy increase inverter s capacity Motor kia g reduce load check drive ratio Cf Overload load tor heavy increase inverter s capacity DC Par mi high check if rated voltage is input O E 8 add braking resistance optional Over Voltage deceleration time too short motor inertia rise again increase deceleration time Input eT check if power input is normal REL Out Phase outphase Withiimput power check if parameter setting is correct Output e check if wire of motor is loosen RES Out phase Motor 1s broken check if motor is broken Under Voltage check if supply voltage is a xi 5 supply voltage is normal LU Protection ipe voltage on the low side check if parameter setting is correct environment temperature too high S proye M entilation A Pini t clean air inlet and outlet and Radiator radiator too dirty pu O H N radiator Overheat install place not good for xo i T EUN Us install as required ventilation fan damaged 5 2 change fan T3 i La age A 1 i ah ERRI Password is When password function is valid please set password correctly wrong password i
55. be switched over by selecting F207 For example switching PID adjusting and normal speed control switching stage speed and analog given switching PID adjusting and analog given and so on 3 The acceleration deceleration time of stage speed is set by function code of corresponding stage speed time When combined speed control is adopted for frequency source the acceleration deceleration time is set by F114 and F115 4 When stage speed control is valid the accel decel time of stage speed is executed firstly After inverter is powered on and stage speed control is invalid the time of F114 and F115 is executed If stage speed signal is cancelled in the process of running the accel decel time of stage speed is also valid 5 The mode of automatic cycle speed control is unable to combine with other modes 6 When F207 2 main frequency source and accessorial frequency source can be switched over by terminals if main frequency is not set to be under stage speed control accessorial frequency can be set to be under automatic cycle speed control F204 5 F500 0 Through the defined swtichover terminal the control mode defined by X and automatic cycle speed control defined by Y can be freely switched 7 If the settings of main frequency and accessorial frequency are the same only main frequency will be valid 8 When F207 6 F205 0 and F206 100 then X Y 50 X 100 50 F111 when F207 6 F205 1 and F206 100 then X Y 50 X 100 50
56. be used as the power supply power supp y supply for voltage control signal with current restricted below 20mA When analog speed control is adopted the voltage signal is input through Voltage analog this terminal The range of voltage input is 0 10V grounding GND All n 7 BADEN input port When potentiometer speed control is adopted this terminal is connected with center tap earth wire to be connected to GND Input When analog speed control is adopted the voltage or current signal is si P al input through this terminal The range of voltage input is 0 5V or 0 10V igna Voltage Current and the current input is 0 20mA input resistor is 5000 grounding AD E al E GND If the input is 4 20mA it can be realized through adjusting analog input port lparameter F406 2 The voltage or current signal can be chosen by coding switch See table 4 2 and 4 3 for details the current channel 0 20mA is chosen before delivery Self contained Ground terminal of external control signal voltage control signal or GND Power current source control signal is also the ground of 10V power supply of supply Ground this inverter 24V Power Control power o Power 24 1 5V grounding CM current is restricted below 50mA for supply supply external use When this terminal is in the valid state the Tape M inverter will have jogging running The The functions of input OPI Digital Hoge inal jogging function of this terminal is valid terminals shall be defined i
57. bon materials are adopted through die stamping for plastic housing with nice form good strength and toughness Taking E1000 0007S2 for instance the external appearance and structure are shown as in below Fig Keypad Controller n N Vent Hole 5 y MER Control Terminal azarirri CU Ej Power Terminal N Mounting Hole Heatsink E1000 Metal housing uses advanced exterior plastic spraying and powder spraying process on the surface with elegant colour and with detachable one side door hinge structure adopted for front cover convenient for wiring and maintenance Taking E1000 0185T3R for instance its appearance and structure are shown as in right Fig Keypad Control Unit 2 Front Panel 3 Wampiate 4 Power Terminal 5 Mounting Screw 6 Fater wiring terminal T outet Hole 8 Mounting Holes E1000 1 5 Technical Specifications Tablel 1 Technical Specifications for E1000 Series Inverters Items Contents Input Rated Voltage Range 3 phase 400V 15 single phase 230Vx1596 npu E Rated Frequency 50 60Hz O t Rated Voltage Range 3 phase 0 400V 3 phase 0230V ii Freguency Range 0 50 650 0Hz Carrier F 2000 10000Hz Fixed carrier wave and random carrier wave arrier Freguenc a y can be selected by F159 Input Frequency Resolution Digital setting 0 01Hz analog setting max frequency X 0 1 Control Mode VVVE control Overload C
58. can be selected and set through function codes F131 and F132 Through the Fun key it can switch over repeatedly and display the parameters of stopped status or running status The followings are the description of operation method of displaying the parameters under stopped status and running status 1 Switching of the parameters displayed under stopped status Under stopped status inverter has five parameters of stopped status which can be switched over repeatedly and displayed with the keys Fun and Stop Reset These parameters are displaying keypad jogging target rotary speed PN voltage PID feedback value and temperature Please refer to the description of function code F132 2 Switching of the parameters displayed under running status Under running status eight parameters of running status can be switched over repeatedly and displayed with the keys Fun These parameters are displaying output rotary speed output current output voltage PN voltage PID feedback value temperature count value and linear speed Please refer to the description of function code F131 4 7 Operation process of measuring motor stator resistance parameters The user shall input the parameters accurately as indicated on the nameplate of the motor prior to selecting auto torque compensation F137 3 Inverter will match standard motor stator resistance parameters according to these parameters indicated on the nameplate To achieve better contro
59. celerate until the output current is lower than initial value of stalling current adjusting In case of stalling during stable speed running the frequency will drop If the current returns to normal during dropping the frequency will return to rise Otherwise the frequency will keep dropping to the minimum frequency and the protection OL will occur after it lasts for the time as set in F610 Initial value of stalling voltage adjusting is set by F609 when the present voltage is higher than rated voltage F609 stalling voltage adjusting function is valid Stalling voltage adjusting is valid during the process of deceleration including the deceleration process caused by stalling current Over voltage means the DC bus voltage is too high and it is usually caused by decelerating During the process of deceleration DC bus voltage will increase because of energy feedback When DC bus voltage is higher than the initial value of stalling voltageand F607 1 then stalling adjusting function is valid Inverter will temporarily stop decelerating and keep output frequency constant then inverter stops energy feedback Inverter will not decelerate until DC bus voltage is lower than the initial value of stalling voltage Stalling protection juding time is set by F610 When inverter starts stalling adjusting function and continues the setting time of F610 inverter will stop running and OLI protection occurs Mfr s value Three phase 710V Single phase
60. cessorial frequency Y When F207 0 the frequency is set by main frequency source When F207 1 X Y the frequency is set by adding main frequency source to accessorial frequency source X or Y can not be given by PID When F207 2 main frequency source and accessorial frequency source can be switched over by frequency source switching terminal When F207 3 main frequency given and adding frequency given X4 Y can be switched over by frequency source switching terminal X or Y can not be given by PID When F207 4 stage speed setting of main frequency source has priority over analog setting of accessorial frequency source only suitable for F203 4 F204 1 When F207 5 X Y the frequency is set by subtracting accessorial frequency source from main frequency source If the frequency is set by main frequency or accessorial frequency PID speed control can not be selected When F207 6 X Y 50 the frequency is given by both main frequency source and accessorial frequency source X or Y can not be given by PID Note 1 When F203 4 and F204 1 the difference between F207 1 and F207 4 is that when F207 1 frequency source selecting is the addition of stage speed and analog when F207 4 frequency source selecting is stage speed with stage speed and analog given at the same time If stage speed given is canceled and 36 E1000 analog given still exists inverter will run by analog given 2 Frequency given mode can
61. ction only one inverter can have communication with PC PLC Should two or more than two inverters upload data at the same time then bus competition will occur which will not only lead to communication failure but higher current to certain elements as well 3 Grounding and Terminal Terminal resistance of 120 Q will be adopted for terminal of RS485 network to diminish the reflection of signals Terminal resistance shall not be used for intermediate network 71 E1000 No direct grounding shall be allowed for any point of RS485 network All the eguipment in the network shall be well grounded via their own grounding terminal Please note that grounding wires will not form closed loop in any case master The distance should f be less than 0 5M Terminal Resistor Connecting Diagram of Terminal Resistance Please think over the drive capacity of PC PLC and the distance between PC PLC and inverter when wiring Add a repeaters if drive capacity is not enough All wiring connections for installation shall have to be made when the inverter is disconnected from power supply V Examples Egl In RTU mode change acc time F114 to 10 0s in NO 01 inverter Query Register Register Preset Preset R Address Function P CRC Lo CRC Hi Address Hi Address Lo Data Hi Data Lo 01 06 Ol OE 00 64 E8 1E Function code F114 Value 10 0S Normal Response Re
62. delivery and user could set corresponding parameters without entering password Table 2 2 Steps for Parameters Setting Steps Keys Operation Display 1 Press Fun key to display function code all 2 Press Up or Down to select required function code Fil 3 To read data set in the function code 5 0 4 To modify data 50 To show corresponding target frequency by flashing 5 after saving the set data Bun To display the current function code Fild The above mentioned step should be operated when inverter is in stop status 2 5 Function Codes Switchover in between Code Groups It has more than 300 parameters function codes available to user divided into 10 sections as indicated in Table 2 3 Table 2 3 Function Code Partition Function Group Function Group Group Name Code Range No Group Name Code Range No Basic Parameters F100 F160 1 Subsidiary function F600 F630 6 Timing control and ni F200 F230 2 protection function F700 F740 7 Multi functional Parameters of tlie mot input output terminal F300 F330 3 arameters of the motor F800 F830 8 Analog signals of Communication input output F400 F439 4 function F900 F930 9 Pulse of input output F440 F460 4 PID parameter setting FA00 FA30 10 Multi stage speed parameters F500 F580 5 As parameters setting costs time due to numerous fu
63. digital given Its initial value is the value of F113 The frequency can be adjusted through the key up or down or through the up down terminals No memory of digital given means that the target frequency will restore to the value of F113 after stop no matter the state of F220 6 Keypad Potentiometer AI3 The frequency is set by the potentiometer on the control panel 9 PID adjusting When PID adjusting is selected the running frequency of inverter is the value of frequency adjusted by PID Please refer to instructions of PID parameters for PID given resource PID given numbers feedback source and so on 10 MODBUS The main frequency is given by MODBUS communication Setting range 0 Memory of digital given 1 External analog AIL F204 Accessorial fi ecessonia TequencY 2 Externa analog AI2 3 Pulse input given Mfr s value 0 S Y Source 4 Stage speed control 5 PID adjusting 6 Keypad potentiometer AI3 When accessorial frequency Y is given to channel as independent frequency it has the same function with main frequency source X When F204 0 the initial value of accessorial frequency is set by F155 When accessorial frequency controls speed independently polarity setting F156 is not valid When F207 1 or 3 and F204 0 the initial value of accessorial frequency is set by F155 the polarity of accessorial 35 E1000 frequency is set by F156 the init
64. e pulled out Please select AA or A6 control panel to relize remote control which is connected by 4 core telephone wire 2 Operation panels of above 18 5KW can be pulled out which is connected by 8 core net cable 2 2 Panel structure 1 structure diagram B He y E1000 IS io gt 3 D 2 Structure size Unit mm Code A B C D H Opening size AA 76 52 72 48 24 73 49 A6 124 74 120 70 26 121 71 2 3 Panel Operating All keys on the panel are available for user Refer to Table 2 1 for their functions Table 2 1 Uses of Keys Keys Names Remarks Fun Fun To call function code and switch over display mode Set To call and save data La J Up To increase data speed control or setting parameters v Down To decrease data speed control or setting parameters Run To start inverter To stop inverter to reset in fault status to change function codes in a code Stop or reset group or between two code groups E1000 2 4 Parameters Setting This inverter has numerous function parameters which the user can modify to effect different modes of operation control User needs to realize that if user sets password valid F107 1 user s password must be entered first if parameters are to be set after power off or protection is effected i e to call F100 as per the mode in Table 2 2 and enter the correct code User s password is invalid before
65. eck if wirings are ageing Check whether screws on each terminals are fastened Check whether inverter is corrosive 1 9 2 Replacement of wearing parts The wearing parts include cooling fan and electrolytic capacitors The life of the fan usually is 2 3 years Users should change the cooling fan according to all running time of inverter Cooling fan could be damaged because bearing is damaged and fan blades are aging Users could check fan blades for cracks or check the abnormal vibration noise when starting Users could change fan according to abnormal phenomena The useful life of electrolytic capacitors is 4 5 years Users should change the electrolytic capacitors according to all running time of inverter Capacitors could be damaged because the power supply is unstable the environment temperature is high frequent over load occurs and electrolyte is ageing By checking whether there is leakage of liquid or the safety valve bulges out or the static electricity and insulated resistor is ok users could change the capacitor according to these phenomena 1 9 3 Storage Please put the inverter in the packing case of manufacture If inverter is stored for long time please charge the inverter within half a year to prevent the electrolytic capacitors damaged The charging time should be longer than 5 hours 1 9 4 Daily Maintenance Environment temperature humidity dust and vibration would decrease the life of inverter So dai
66. equency 20Hz Skip Width 0 5Hz inverter will skip automatically when output is peve enlase Figure 5 2 Skip Frequency Time t 28 E1000 Inverter will not skip this frequency span during acceleration deceleration 0 Current output frequency function code 1 Output rotary speed 2 Output current 4 Output voltage F131 Running Display Items 8 PN voltage 16 PID feedback value 32 Temperature Mfr s value 0 1 2 4 8 15 64 Count values 128 Linear speed Single phase 0 2 0 75KW inverters have no the function of temperature display Selection of one value from 1 2 4 8 16 32 64 and 128 shows that only one specific display item is selected Should multiple display items be intended add the values of the corresponding display items and take the total values as the set value of F131 e g just set F131 to be 19 1 2 16 if you want to call current output rotary speed output current and PID feedback value The other display items will be covered As F131 255 all display items are visible of which freguency function code will be visible whether or not it is selected Should you intend to check any display item just press the Fun key for switchover Refer to the following table for each specific value unit and its indication Whatever the value of F131 is set to corresponding target frequency will flash under stopped status
67. er defined voltage point 4 010026 45 X F148 User defined frequency point 5 F146 F150 30 00 x F149 User defined voltage point 5 0 100 63 F150 User defined frequency point 6 F148 F118 40 00 x F151 User defined voltage point 6 01006 81 F152 Output voltage corresponding tol 10 100 100 x s turnover freguency c 0 2 7 5KW 2 10K 4K eya pal F153 Carrier frequency setting 1177 KW 210K 3K x E 18 5KW 45KW 2 6K 4K F4 Above 55KW 2 4K 2K 3 0 Invalid 1 Valid c F154 Automatic voltage rectification 2 Invalid during deceleration 0 x amp process n F155 Digital accessorial frequency setting OSFLLI 0 x F156 Digital accessorial frequency polarity ord 0 x setting F157 Reading accessorial frequency A F158 Reading accessorial frequenc polarity Random carrier wave frequency 0 Control speed normally F159 selection 1 Random carrier wave frequency F160 Reverting to manufacturer values one E p mamie Devas 0 x 1 Reverting to manufacturer values 0 Keypad command 1 Terminal command f F200 Source of start command 2 Keypad Terminal 0 x S 3 MODBUS 4 Keypad 5 Terminal MODBUS va 0 Keypad command Q 1 Terminal command 5 F201 Source of stop command 2 Keypad Terminal 0 x a 3 MODBUS 4 Keypad z Terminal MODBUS 0 Forward running locking a F202 Mode of direction setting 1 Reverse running locking 0 x 2 Terminal setting E1000 POWN 0 9uo Suruunq 0 Digital setting
68. er is stopped resetted and repowered on if inverter starts running but no direction signal inverter will run according the memoried direction F213 Selfstarting after repowered on Setting range 0 invalid 1 valid Mfr s value 0 F214 Selfstarting after reset Setting range 0 invalid 1 valid Mfr s value 0 Whether or not to start automatically after repowered on is set by F213 F213 1 Selfstarting after repowered on is valid When inverter is power off and then powered on again it will run automatically after the time set by F215 and according to the running mode before power down If F220 0 frequency memory after power down is not valid inverter will run by the setting value of F113 F213 0 after repower on inverter will not run automatically unless running command is given to inverter Whether or not to start automatically after fault resetting is set by F214 When F214 1 if fault occurs inverter will reset automatically after delay time for fault reset F217 After resetting inverter will run automatically after the selfstarting delay time F215 If frequency memory after power down F220 is valid inverter will run at the speed before power down Otherwise inverter will run at the speed set by F113 In case of fault under running status inverter will reset automatically and self start In case of fault under 39 E1000 stopped status the inverter will only reset automatically When F214 0
69. ers setting Description of rules of function codes parameters address 1 Use the function code as parameter address General Series High order byte 01 0A hexadecimal Low order byte 00 50 max range hexadecimal Function code range of each partition is not the same The specific range refers to manual For example F114 display on the board parameter address is 010E hexadecimal F201 display on the board parameter address is 0201 hexadecimal Note in this situation it allows to read six function codes and write only one function code Some function codes can only be checked but cannot be modified some function codes can neither be checked nor be modified some function codes can not be modified in run state some function codes can not be modified both in stop and run state In case parameters of all function codes are changed the effective range unit and related instructions shall refer to user manual of related series of inverters Otherwise unexpected results may occur 2 Use different parameters as parameter address The above address and parameters descriptions are in hexadecimal format for example the decimal digit 4096 is represented by hexadecimal 1000 68 E1000 1 Running status parameters Parameters Address Parameter Description read only 000 Output freguency 001 Output voltage 002 Output current 003 Pole numbers control mode high order byte
70. et 0 invalid 1 valid 0 Y F215 __ Selfstarting delay time 0 1 3000 0 60 0 N Times of selfstarting in case of PAIS repeated faults bec 9 y F217 Delay time for fault reset 0 010 0 3 0 Y F218 F219 Reserved F220 Frequency memory after 0 invalid 1 valid 0 d power down invalid 1 vali F221 Reserved F222 ountmemory selection Setting range 0 Invalid 1 Valid 0 Y F223 F230 Reserved 78 E1000 Function Function Function 3 Mfr s Section Code Definition Setting Range Value Change 0 no function 1 inverter fault protection F300 Relay token output 2 over latent frequency 1 1 V 3 over latent frequency 2 4 free stop 5 inverter running status 1 F301 DO1 token output 6 DC braking 14 V 7 acceleration deceleration time switchover 8 Reaching the Set Count Value 9 Reaching the Designated z Count Value 0 inverter overload pre alarm g 1 motor overload pre alarm T 2 F302 DO2 token output 12 Stalling 5 5 3 Inverter is ready to run S 4 inverter running status 2 3 5 frequency arrival output 6 Over heat pre alarm z 7 over latent current output E Soi 8 reserved e F303 Output types 0 level output pulse output 0 Y 3 selection E F304 F306 Reserved Characteristic e F307 s gt FI12 F111 10 00Hz Y 5 frequency 1 Characteristic F308 2 FII2 FI11 50 00Hz Y c frequency 2 Py Characterist 5 paa
71. everse running CM terminal common port KI K2 Running command N 0 0 Stop o 0 1 Stop KI o FWD 1 0 Forward running Kz p REV 1 1 Reverse running CM 3 Three line operation mode 1 In this mode X terminal is enable terminal the direction is controlled by FWD terminal and REV terminal Pulse signal is valid Stopping command is enable by opening X terminal SB3 stop button SB2 forward button SB1 reverse button 4 Three line operation mode 2 In this mode X terminal is enable terminal running command is controlled by FWD terminal The running direction is controlled by REV terminal and stopping command is enable by opening X terminal SB1 Running button SB2 Stop button KI direction switch Open stands for forward running close stands for reverse running 38 E1000 5 Start stop controlled by direction pulse FWD terminal impulse signal forward stop REV terminal impulse signal reverse stop CM terminal common port Note when pulse of SBI triggers inverter will run forward When the pulse triggers again inverter will stop running When pulse of SB2 triggers inverter will run reverse When the pulse triggers again inverter will stop running F209 Selecting the mode of stopping Setting range et Mfr s value 0 the motor 0 stop by deceleration time 1 free stop When the stop signal is i
72. eypad t Terminal3d MODBUS 0 Digital setting memory 1 External analog ALI 2 External analog AD 3 Pulse input given F203 Main frequency source X 4 Stage speed control 0 5 No memory by digital setting 6 Keypad potentiometer 7 8 Reserved 9 PID adjusting 10 MODBUS F900 Inverter Address 1 255 1 570 E1000 F901 Modbus Mode Selection 1 ASCII mode 1 2 RTU mode 3 Remote controlling keypad Only for inverter power below 15KW F903 Parity Check Selection 0 No checkout 0 1 Odd 2 Even F904 Baud Rate 0 1200 1 2400 2 48003 9600 3 4 192005 38400 6 57600 Please set functions code related to communication consonant with the PLC PC communication parameters when inverter communicates with PLC PC IV Physical Interface 4 1 Interface instruction Communication interface of RS485 is located on the most left of control terminals marked underneath with A and B 4 2 Structure of Field Bus PLC PC Field Bus WAI snes gt pnpy UEUIUIO 0 9uo Inverter Connecting Diagram of Field Bus RS485 Half duplex communication mode is adopted for E2000 series inverter Daisy chain structure is adopted by 485 Bus line Do not use spur lines or a star configuration Reflect signals which are produced by spur lines or star configuration will interfere in 485 communications Please note that for the same time in half duplex conne
73. f F806 will be updated automatically after normal completion of stator resistance parameter measurement of the motor The inverter will restore the parameter value of F806 automatically to default standard parameters of the motor each time after changing F801 rated power of the motor If it is impossible to measure the motor at the site input the parameters manually by referring to the known parameters of a similar motor 5 10 Communication Parameter 1 255 single inverter address 0 broadcast address 1 ASCH 2 RTU F901 Communication Mode 3 Remote controlling keypad Only for 1 inverter power below 15KW Setting range 0 no calibration F903 Odd Even Calibration 1 odd calibration 0 2 even calibration F900 Communication Address Setting range F904 Baud Rate 0 1200 1 2400 2 4800 3 3 9600 4 19200 5 38400 6 57600 Please set F901 to 3 to select remote controlling keypad the keypad of inverter will automatically close E1000 for saving energy If the keypad of inverter and remote controlling keypad need work at the same time please connect OPS terminal to CM terminal When inverter works steadily please disconnect OPS with CM in case malfunction F904 9600 is recommended for baud rate which makes run steady Communication parameters refer to Appendix 4 5 11 PID Parameters When F203 or F204 selects PID adjusting this group function is valid FAO0 Polarity 0
74. frequency source is digital setting memory F204 0 F155 and F156 are considered as initial set values of accessorial frequency and polarity direction In the mode of combined speed control F157 and F158 are used for reading the value and direction of accessorial frequency For example when F203 1 F204 0 F207 1 the given analog frequency is 15Hz inverter is required to run to 20Hz In case of this requirement user can push UP button to raise the frequency from 15Hz to 20Hz User can also set F155 5Hz and F160 0 0 means forward 1 means reverse In this way inverter can be run to 20Hz directly F159 Random carrier wave selection Setting range 0 Not allowed 1 allowed Mfr s value 1 When F159 0 inverter will modulate as per the carrier wave set by F153 When F159 1 inverter will operate in mode of random carrier wave modulating Note when random carrier wave is selected output torque will increase but noise will be loud When the 32 E1000 carrier wave set by F153 is selected nosie will be reduced but output torque will decrease Please set the value according to the situation Setting range F160 Reverting to manufacturer values 0 Not reverting to manufacturer values Mft s value 0 1 Reverting to manufacturer values When there is disorder with inverter s parameters and manufacturer values need to be restored set F160 1 After Reverting to manufacturer values
75. ge 9 speed ps 3 Frequency setting for F112 F111 10 00Hz y stage 10 speed F514 Frequency setting for F112 F111 15 00Hz N stage 11 speed F515 Frequency setting for F112 F111 20 00Hz NI stage 12 speed F516 Frequency setting for F112 F111 25 00Hz 4 stage 13 speed ps 7 omens setting for F112 F111 30 00Hz y stage 14 speed pig Freauency setting for F112 F111 35 00Hz y stage 15 speed 83 E1000 Acceleration time setting for 0 2 3 7KW 5 0S F519 F533 the speeds from Stage 1 to 0 1 3000S 5 5 30KW 30 0S Y stage 15 Above 37KW 60 0S Deceleration time setting for 0 2 3 7KW 5 0S F534 F548 the speeds from Stage to 0 1 3000S 5 5 30KW 30 0S V stage 15 Above 37KW 60 0S Running directions of fopward r naie F549 F556 stage speeds from Stage 1 met 0 Y i 1 reverse running to stage 8 Running time of stage F557 F564 speeds from Stage 1 to 0 13000S 1 0S Y stage 8 Stop time after finishing F565 F572 stages from Stage 1 to 0 030008 0 08 Y stage 8 Running directions of o forwadd rani F573 F579 stage speeds from Stage 9 t i 0 Y to stage 15 1 reverse running stage 15 F580 Reserved Function Function oy PEON Function Definition Setting Range Mfr s Value Change Section Code 0 not allowed E 3 1 braking before starting F600 Ps Ee ee 2 braking during stopping 0 y CIC 3 braking during starting and stopping Initial Frequency f
76. ge Setting range 1 440V F803 Rated current Setting range 0 1 6553A F804 Number of motor poles Setting range 2 100 4 F805 Rated rotary speed Setting range 17430000 F810 Motor rated frequency Setting range 1 0 650 0Hz 50 00 Please set the parameters in accordance with those indicated on the nameplate of the motor Excellent control performance of vector control requires accurate parameters of the motor Accurate parameter derives from correct setting of rated parameters of the motor F800 0 no parameter measurement Please set the parameters F801 F805 and F810 correctly according to those indicated on the nameplate of the motor After being powered on it will use default stator resistance parameters of the motor see the values of F806 according to the motor power set in F801 F800 1 stator resistance parameter measurement In order to ensure dynamic control performance of the inverter please set F801 805 and F810 correctly prior to stator resistance parameters testing Press the Run key on the keypad to display TEST After self checking is completed relevant parameters of the motor will be stored in function code F806 and F800 will turn to O automatically Note In order to test motor stator resistance parameters correctly please set the information of the motor F801 F805 and F810 correctly according to the nameplate of the motor F806 Stator resistance Setting range 0 001 65 00Q The set value o
77. gister Register Response Response Address Function 4 CRC Lo CRC Hi Address Hi Address Lo Data Hi Data Lo 01 06 Ol OE 00 64 ES 1E Function code F114 Normal Response Abnormal Response Address Function Abnormal code CRC Lo CRC Hi Ol 86 04 43 A3 The max value of function code is 1 Slave fault Eg2 Read output frequency output voltage output current and current rotate speed from NO 2 inverter Host Query 72 E1000 e Funeton First Bee First Register PEE Register CRC CRG Address Hi Address Lo count Hi count LO Lo Hi 02 03 10 00 00 04 40 FA Communication Parameters Address 1000H Slave Response E E E e eal a E 02 03 08 13 88 01 90 00 3C 02 00 82 F6 Output Frequency Output Voltage Output Current Numbers of Pole Pairs Control Mode NO 2 Inverter s output frequency is 50 00Hz output voltage is 400V output current is 6 0A numbers of pole pairs are 2 and control mode keypad control Eg3 NO 1 Inverter runs forwardly Host Query Register Register Write Write Address Function f CRC Lo CRC Hi Hi Lo status Hi status Lo 01 06 20 00 00 01 43 CA Communication parameters address 2000H Forward running Slave Normal Response Write Write Register Register Address Function CRC Lo CRC H
78. i Hi Lo status Hi status Lo 01 06 20 00 00 01 43 CA Normal Response Slave Abnormal Response Address Function Abnormal Code CRC Lo CRC Hi 01 86 01 83 AO The max value of function code is 1 Illegal function code assumption Eg4 Read the value of F113 F114 from NO 2 inverter Host Query Register Register Register Register CRC CRC Address Function E Address Hi Address Lo Count Hi Count LO Lo Hi 02 03 01 0D 00 02 54 07 Communication Parameter Address F10DH 73 Numbers of Read Registers E1000 Slave Normal Response The first The first The second The second Byte CRC CRC Address Function parameters parameters parameters parameters i count t Jj Lo Hi status Hi status Lo status Hi status Lo 02 03 04 03 E8 00 78 49 61 The actual value is 10 00 The actual value is 12 00 Slave Abnormal Response Address Function Code Abnormal Code CRC Lo CRC Hi 02 83 08 BO F6 The max value of function code is 1 Parity check fault 74 E1000 Appendix 5 Zoom Table of Function Code Function Function Function gt Section Code Definition Setting Range Mfr s Value Change F100 User s Password 07 9999 8 Y F102 JInverter s Rated Current A 1 0 800 0 Subject to inverter model bs F103 Inverter Power KW 0 20 650 0 Subject to inverter model F104 Inverter Power
79. ial frequency of DC braking DC braking will start to work as inverter s output frequency is lower than this value b F602 DC braking voltage The bigger value will result in a quick braking However motor will overheat with too big value c F604 Braking duration before starting The time lasted for DC braking before inverter starts d F605 Braking duration when stopping The time lasted for DC braking while inverter stops DC braking as shown in Figure 5 9 Note during DC braking because motor does not have self cold effect cause by rotating it is in the state of easy over heat Please do not set DC braking voltage too high and do not set DC braking time to long Setting range 0 invalid 1 valid Mace F607 Selection of Stalling Adjusting Function F608 Stalling Current Adjusting 76 Setting range 60200 Mfr s value 160 F609 Stalling Voltage Adjusting 26 Setting range 60200 Mfr s value 140 F610 Stalling Protection Judging Time Setting range 0 1 3000 0 Mfr s value 5 0 Initial value of stalling current adjusting is set by F608 when the present current is higher than rated current F608 stalling current adjusting function is valid During the process of deceleration stalling current function is invalid During the process of acceleration if output current is higher than initial value of stalling current adjusting and F607 1 then stalling adjusting function is valid Inverter will not ac
80. ial value of accessorial frequency and the polarity of accessorial frequency can be checked by F157 and F158 When the accessorial frequency is given by analog input ALI AD the setting range for the accessorial frequency is set by F205 and F206 When the accessorial frequency is given by keypad potentiometer the main frequency can only select stage speed control and modbus control F203 4 10 Note accessorial frequency source Y and main frequency source X can not be same i e they can not use the same frequency given channel Setting range 0 Relative to max frequency Mfr s value 0 1 Relative to frequency X F205 Reference for selecting accessorial frequency source Y range F206 Accessorial frequency Y range Setting range 010026 Mfr s value 100 When combined speed control is adopted for frequency source F206 is used to confirm the relative object of the setting range for the accessorial frequency F205 is to confirm the reference of the accessorial frequency range If it is relative to main frequency the range will change according to the change of main frequency X Setting range OX 1 X Y 2 X or Y terminal switchover 3 X or X Y terminal switchover 4 Combination of stage speed and analog 5 X Y 6 X Y 50 F207 Frequency source selecting Mfr s value 0 Select the channel of setting the frequency The frequency is given by combination of main frequency X and ac
81. ill cause reverse running or vice versa O Hz frequency dead zone is set by F446 E1000 Input pulse 0 10K can correspond to output frequency 50Hz 50Hz SK corresponds to 0Hz by setting the function of corresponding setting for max min input pulse frequency The function code F446 sets the input pulse range corresponding to OHz For example when F446 0 5 the pulse range from 5K 0 5K 4 5K to 5K 0 5K 5 5K corresponds to OHz So if F446 N then 54N should correspond to OHz If the pulse is in this range inverter will output OHz OHZ voltage dead zone will be valid when corresponding setting for min pulse frequency is less than 1 00 Corresponding setting orresponding setting frequency frequency 100 0 100 0 0 0 100 0 0K 10K Fig 5 10 correspondence of pulse input and setting The unit of corresponding setting for max min input pulse frequency is in percentage If the value is greater than 1 00 it is positive if the value is less than 1 00 it is negative e g F441 0 5 represents 50 The corresponding setting benchmark in the mode of combined speed control pulse input is the accessorial frequency and the setting benchmark for range of accessorial frequency which relatives to main frequency F205 1 is main frequency X corresponding setting benchmark for other cases is the max frequency as illustrated in the right figure A F441 1 setting benchmark Fig 5 11 Pulse input and se
82. ing the keypad panel 1 Operation process of setting the parameters through keypad panel A three level menu structure is adopted for setting the parameters through keypad panel of inverter which enables convenient and quick searching and changing of function code parameters Three level menu Function code group first level menu Function code second level menu Set value of each function code third level menu 2 Setting the parameters Setting the parameters correctly is a precondition to give full play of inverter performance The following is the introduction on how to set the parameters through keypad panel Operating procedures Press the Fun key to enter programming menu Press the key Stop Reset the DGT lamp goes out Press A and V the function code will change within the function code group The first number behind F displayed on the panel is 1 in other words it displays F1xxat this moment 3 Press the key Stop Reset again the DGT lamp lights up and the function code will change within the code group Press A and V to change the function code to F113 press the Set key to display 50 00 while press A and V to change to the need frequency 4 Press the Set key to complete the change 4 6 2 Switching and displaying of status parameters Under stopped status or running status the LED digitron of inverter can display status parameters of the inverter Actual parameters displayed
83. is done F160 values will be automatically changed to 0 Reverting to manufacturer values will not work for the function codes marked o in the change column of the parameters table These function codes have been adjusted properly before delivery And it is recommended not to change them Goo Ee cens ed e Cox esos 153 E da Figure 5 3 Reverting to manufacturer values 33 E1000 5 2 Operation Control Setting range F2 So of start 0 Keypad command Mfr s value 0 urce of sta r s value mind 1 Terminal command 2 Keypad Terminal 3 MODBUS 4 Keypad Terminal MODBUS F201 Setting range 0 Keypad command 1 Terminal command 2 Keypad Terminal 3 MODBUS 4 Keypad Terminal MODBUS Source of stop Mfr s value 0 command F200 and F201 are the resource of selecting inverter control commands Inverter control commands include starting stopping forward running reverse running jogging etc Keypad command refers to the start stop commands given by the Run or stop reset key on the keypad Terminal command refers to the start stop command given by the Run terminal defined by F316 F323 When F200 3 and F201 3 the running command is given by MODBUS communication When F200 2 and F201 2 keypad command and terminal command are valid at the mean time F200 4 and F201 4 are the same Setting range F202 0
84. is pole numbers low order byte is control mode 004 Bus line voltage 005 Drive ratio inverter status High order byte is drive ratio low order byte is inverter status E1000 Inverter status 00 Standby mode Ol Forward running 02 Reverse running 04 Over current 0C 05 DC over current OE 06 Input Out phase PF1 07 Frequency Over load OL1 08 Under voltage LU 09 Overheat OH 0A Motor overload OL2 OB Interference ERR OC LL OD External Malfunction ESP OE ERRI OF ERR2 10 ERR3 11 ERR4 2 Control commands Parameters Address Parameters Description write only 2000 Command meaning 0001 Forward running no parameters 0002 Reverse running no parameters 0003 Deceleration stop 0004 Free stop 0005 Forward jogging start 0006 Forward jogging stop 0007 Reserved 0008 Run no directions 0009 Fault reset 000A Forward jogging stop OOOB Reverse jogging stop 2001 Lock parameters 0001 Relieve system locked remote control locked 0002 Lock remote control any remote control commands are no valid before unlocking Note 1 Command types of 2000 do not belong to every inverter models 2 Illegal Response When Reading Parameters 69 E1000 Command Description Function Data Slave parameters response The highest oder byte changes into 1 Command meaning 0001 Illegal function code 0002 Illegal address 0003 Illegal data 0004 Slave faul
85. ke into consideration the environment conditions temperature humidity etc and heat radiation of the inverter to check whether they can satisfy the requirements See Chapters I IL III Wiring of the inverter Checking before getting energized Checking immediately after energized Inputting the parameters indicated on the motor s nameplate correctly and measuring the motor stator resistance parameters Setting running control parameters Checking under no load Wiring of input and output terminals of the main circuit wiring of grounding wiring of switching value control terminal analog terminal and communication interface etc Make sure that the voltage of input power supply is correct the input power supply loop is connected with a breaker the inverter has been grounded correctly and reliably the power cable is connected to the power supply input terminals of inverter correctly R L1 S L2 terminals for single phase power grid and R LI S L2 and T L3 for three phase power grid the output terminals U V and W of the inverter are connected to the motor correctly the wiring of control terminals is correct all the external switches are preset correctly and the motor is under no load the mechanical load is disconnected from the motor Check if there is any abnormal sound fuming or foreign flavor with the inverter Make sure that the display of keypad panel is normal without any fault alarm message I
86. l performance the user may start the inverter to measure the motor stator resistance parameters so as to obtain accurate parameters of the motor controlled The stator resistance parameters of the motor can be measured through function code F800 For example If the parameters indicated on the nameplate of the motor controlled are as follows numbers of motor poles are 4 rated power is 7 5KW rated voltage is 400V rated current is 15 4A rated frequency is 50 00HZ and rated rotary speed is 1440rpm operation process of measuring the parameters shall be done as described in the following 20 E1000 1 In accordance with the above motor parameters set the values of F801 to F805 correctly set the value of F801 7 5 F802 400 F803 15 4 F804 4 and F805 1440 respectively 2 In order to ensure dynamic control performance of the inverter set F800 1 i e select stator resistance parameter measurement Press the Run key on the keypad and the inverter will display TEST after few seconds self checking is completed motor stator resistance parameters will be stored in function code F806 and F800 will turn to 0 automatically 4 8 Operation process of simple running Table 4 1 Process Brief Introduction to Inverter Operation Process Operation Reference Installation and operation environment Install the inverter at a location meeting the technical specifications and requirements of the product Mainly ta
87. lected all terminal functions in table 5 2 can be defined by F301 When pulse output is selected DOI can be defined as high speed pulse output terminal The max pulse frequency is SOKHz The related function codes are F449 F450 F451 F452 F453 F307 Characteristic frequency 1 Mfr s value 10Hz Setting range F112 F111Hz F308 Characteristic frequency 2 Mfr s value 50Hz F309 Characteristic frequency width Setting range O 100 IMfr s value 50 When F300 and F301 2 3 and token characteristic frequency is selected this group function codes set characteristic frequency and its width For example setting F301 2 F307 10 F309 10 when running frequency is greater than or equal to F307 DO1 will be in action When running frequency is lower than 10 10 10 9Hz DO1 will be disconnected F310 Characteristic current Setting range 07 1000A IMfr s value Rated current F311 Characteristic current width Setting range O 100 IMfr s value 10 When F300 F301 and F302 17 and token characteristic current is selected this group function codes set characteristic current and its width For example setting F301 17 F310 100 F311 10 when current of inverter is greater than or equal to F310 DOI will be in action When inverter current is lower than 100 100 10 90A DOI will be disconnected 12 Frequency arrival threshold Setting range 0 00 5 00Hz IMfr s value 0 00 When
88. ltage before Starting Setting range 0 60 Mfr s value 10 F603 DC Braking Voltage During Stop F604 Braking Lasting Time Before Starting Setting range 0 0 10 0 Mfr s value 0 5 F605 Braking Lasting Time During Stopping When F600 0 DC braking function is not allowed Hz When F600 1 braking before starting is valid After the right starting signal is input inverter starts DC braking After braking is finished inverter will run F601 from the initial frequency In some application occasion such as fan motor is running at a low speed or in a reverse status if inverter starts immediately OC malfunction will occur Adopting braking before starting will ensure that the fan stays in a static state before starting to avoid this malfunction During braking before starting if stop signal is given inverter will stop by deceleration time v When F600 2 DC braking during stopping is Mel DC Braking selected after output frequency declines to initial frequency for DC braking the rotating motor is stop by 54 F604 F605 E1000 DC braking During the process of braking during stopping if start signal is given DC braking is finished and inverter Will start If stop signal is given during the process of braking during stopping and inverter has no response DC braking during stopping still goes on Parameters related to DC Braking F601 F602 F604 and F605 interpreted as follows a F601 Init
89. ly maintenance is necessary to inverter Daily inspecting Inspecting for noise of motor when it is working Inspecting for abnormal vibration of motor when it is working Inspecting for the installing environment of inverter Inspecting for the fan and inverter temperature Daily cleaning Keep the inverter clean Clean surface dust of inverter to prevent dust metal powder oily dirt and water from dropping into the inverter Inspecting for the fan and inverter temperature Daily cleaning Keep the inverter clean Clean surface dust of inverter to prevent dust metal powder oily dirt and water from dropping into the inverter Ts E1000 II Keypad panel Keypad panel and monitor screen are both fixed on keypad controller Two kinds of controllers with and without potentiometer are available for E1000 series inverters Refer to note for Fig2 1 2 Panel Illustration The panel covers three sections data display section status indicating section and keypad operating section as shown in Fig 2 1 m E END LED shows running frequency flashing target frequency function RN parameter value or fault code RUN FWD DGT FRQ EURA B B B B 4LEDs indicate working status RUN is lighting while running FWD is 2 crm eec when working forward and FRQ is lighting when showing frequency _ Potentiometer can be used for manu
90. mA current speed control Another switches states and mode of control speed are as table 4 2 6 There is a red four digit coding switch SW1 near the control terminal block of above 15 KW inverter as shown in Figure 4 5 The function of coding switch is to select the input range 0 5V 0 10V 0 20m lt A of analog input terminal AIl and AD In actual application select the analog input channel through F203 AIl channel default value is 0 10V AI2 channel default value is 0 20mA Another switches states and mode of control speed are as table 4 3 7 Close the switch OP3 the motor starts forward running 8 The potentiometer can be adjusted and set during running and the current setting frequency of the inverter can be changed 9 During running switch off the switch OP3 then close OP4 the running direction ofthe motor will be changed 10 Switch off the switches OP3 and OP4 the motor will decelerate until it stops running 11 Switch off the air switch and power off the inverter Set F203 to 2 to select channel AI2 Coding Switch 1 Coding Switch 2 Mode of Speed Control OFF OFF 0 5V voltage OFF ON 0 10V voltage ON ON 0 20mA current ON refers to switching the coding switch to the top OFF refers to switching the coding switch to the bottom l SWI Fig 4 5 Table 4 2 The Setting of Coding Switch and Parameters in the Mode of Analog Speed Control Table 4 3
91. n case of any abnormality switch off the power supply immediately Make sure to input the parameters indicated on the motor nameplate correctly and measure the motor stator resistance parameters to get the best control performance Set the parameters of the inverter and the motor correctly which mainly include target frequency upper and lower frequency limits acceleration deceleration time and direction control command etc The user can select corresponding running control mode according to actual applications With the motor under no load start the inverter with the keypad or control terminal Check and confirm running status of the drive system Motor s status stable running normal running correct rotary direction normal acceleration deceleration process free from abnormal vibration abnormal noise and foreign flavor Inverter status normal display of the data on keypad panel normal running of the fan normal acting sequence of the relay free from the abnormalities like vibration or noise In case of any abnormality stop and check the inverter immediately 21 See Chapter III See Chapters I III See Appendix 1 and Appendix 2 See description of parameter group F800 F830 See description of parameter group See Chapter IV E1000 After successful test run under no load connect the load of drive system properly Start the inverter with the keypad or control terminal and increase the load gradu
92. n motor vibration Customers should set correctly motor power rotary speed numbers of motor poles motor rated current and stator resistance Please refer to the chapter Operation process of measuring motor stator resistance parameters F140 User defined frequency point FI Setting range 0 F142 Mfr s value 1 00 F141 User defined voltage point V1 Setting range 07710026 Mfr s value 4 E1000 F142 User defined frequency point F2 Setting range FI40 F144 Mfr s value 5 00 F143 User defined voltage point V2 Setting range 0 100 Mfr s value 13 F144 User defined frequency point F3 Setting range F142 F146 Mfr s value 10 00 F145 User defined voltage point V3 Setting range 07710026 Mfr s value 24 F146 User defined frequency point F4 Setting range F144 F148 Mfr s value 20 00 F147 User defined voltage point V4 Setting range 0 100 Mfr s value 45 F148 User defined frequency point F5 Setting range F146 F150 Mfr s value 30 00 F149 User defined voltage point V5 Setting range 0 100 Mfr s value 63 F150 User defined frequency point F6 Setting range F148 F118 Mfr s value 40 00 F151 User defined voltage point V6 Setting range 07710026 Mfr s value 81 Multi stage V F curves are defined by 12 parameters from F140 to F151 The setting value of V F curve is set by motor load characteristic Note
93. nction codes such function is specially designed as Function Code Switchover in a Code Group or between Two Code Groups so that parameters setting become convenient and simple Press Fun key so that the keypad controller will display function code If press A or W key then 10 E1000 function code will circularly keep increasing or decreasing by degrees within the group if press the stop reset key again function code will change circularly between two code groups when operating the A or W key e g when function code shows F111 and DGT indicatoris on press A VW key function code will keep increasing or decreasing by degrees within F100 F 160 press stop reset key again DGT indicator will be off When pressing A Y key function codes will change circularly among the 10 code groups like F211 F311 FA11 F111 Refer to Fig 2 2 The sparkling 50 00 is indicated the corresponding target frequency values Enter correct user s sword currently p Display showingS0 00 Display A Fig2 2 Swich over in a Code Group or between Different Code Groups 2 6 Panel Display Table 2 4 Items and Remarks Displayed on the Panel Items Remarks This Item will be displayed when you press Fun in stopping status which indicates jogging HF 0 operation is valid But HF 0 will be displayed only after you change the value of F132
94. nge 0 Invalid 1 Valid Mfr s value 0 F220 sets whether or not count memory is valid Whether or not to memory counting values after power down or malfunction is set by this function Table 5 1 Combination of Speed Control b Memory External 2 External 3 Pulse input4 Terminal 5 PID 6Keypad F204 of digital analog All analog AI2 given stage speed adjusting potentiometer F203 setting control AI3 0 Memory of Digital setting O bi ks S o External analog ATI O Oo 2 pad analog T Y o A A o 3 Pulse input given O o 4 Terminal Stage speed control bg 7 7 o Ni i 5 Digital setting o A E o 6 Keypad potentiometer AI3 x M o 9 PID adjusting o o 10 MODBUS N e gt e e Intercombination is allowable O Combination is not allowable The mode of automatic cycle speed control is unable to combine with other modes If the combination includes the mode of automatic cycle speed control only main speed control mode will be valid 40 E1000 5 3 Multifunctional Input and Output Terminals 5 3 1 Digital multifunctional output terminals F300 Relay token output F301 DOI token output F302 DO token output Setting range 0 18 Refer to table 5 2 for detailed instructions IMfr s value 1 IMfr s value 14 IMfr s value 5 E1000 inverter has one m
95. nput stopping mode is set by this function code F209 0 stop by deceleration time Inverter will decrease output frequency according to setting acceleration deceleration curve and decelerating time after frequency decreases to 0 inverter will stop This is common used stopping type F209 1 free stop After stop command is valid inverter will stop output Motor will free stop by mechanical inertia F210 Frequency display accuracy Setting range 0 01 2 00 Mfr s value 0 01 Under keypad speed control or terminal UP DOWN speed control frequency display accuracy is set by this function code and the range is from 0 01 to 2 00 For example when F210 0 5 UP DOWN terminal is pressed at one time frequency will increase or decrease by 0 5Hz This function is valid when inverter is in the running state When inverter is in the standby state no matter what value of this function code is frequency will increase or decrease by 0 01Hz F211 Speed of digital speed control Setting range 0 01 100 0Hz S Mfr s value 5 00 When UP DOWN terminal is pressed frequency will change at the setting rate The Mfr s value is 5 00Hz s F212 Direction memory Setting range 0 Invalid 1 Valid Mfr s value 0 This function is valid when three line operation mode 1 F208 3 is valid When F212 0 after inverter is stopped resetted and repowered on the running direction is not memorized When F212 1 after invert
96. nput ogging terminal fynder both at stopped and running status This per manufacturer s value terminal can also be used as high speed pulse 3 control E Other functions can also d input port The max frequency is 50K a a be ehani OP2 LA External When this terminal is in the valid state ESP dh e m EIDE Emergency Stop malfunction signal will be displayed funton codes 14 E1000 OP3 EWD Terminal nen Ke isin the valid state inverter will run forward OP4 REV Terminal When this terminal is in the valid state inverter will run reversely OPS Recerienninal Make this terminal valid under fault status to reset the inverter OP6 Free stop Make this terminal valid during running can realize free stop OP7 Running terminal When this terminal is in the von state inverter will run by the acceleration time Ops St p terminal Mate this terminal valid during running can realize stop by the deceleration time Grounding of Common 7 CM u control power The grounding of 24V power supply and other control signals p supply ape 485 Positive polarity of Standard TIA EIA 485 RS 485 communic differential signal HIS Communication protocol Modbus Ano ation Negative polarity of jupe B terminals Differential signal Communication rate 1200 2400 4800 9600 19200 38400 57600bps Note 15KW inverters and below 15KW have no A B DO2 and OP7
97. of ALI input F404 AIl channel proportional gain KI Setting range 0 0 10 0 Mfr s value 1 0 F405 AIl filtering time constant Setting range 0 1 10 00 Mfr s value 0 10 In the mode of analog speed control sometimes it requires adjusting coincidence relation among upper limit and lower limit of input analog analog changes and output frequency to achieve a satisfactory speed control effect Upper and lower limit of analog input are set by F400 and F402 For example when F400 1 F402 8 if analog input voltage is lower than 1V system judges it as 0 If input voltage is higher than 8V system judges it as 10V Suppose analog channel selects 0 10V If Max frequency F111 is set to 50Hz the output frequency corresponding to 1 8V is 0 50Hz The filtering time constant is set by F405 The greater the filtering time constant is the more stable for the analog testing However the precision may decrease to a certain extent It may require appropriate adjustment according to actual application Channel proportional gain is set by F404 If 1V corresponds to 10Hz and F404 2 then 1V will correspond to 20Hz Corresponding setting for upper lower limit of analog input are set by F401 and F403 If Max frequency F111 is 50Hz analog input voltage 0 10V can correspond to output frequency from 50Hz to 50Hz by setting this group function codes Please set F401 0 and F403 2 then OV corresponds to 50Hz 5V corresponds to OH
98. ongitudinal Redundancy Check LRC It is performed on the ASCII message field contents excluding the colon character that begins the message and excluding the CRLF pair at the end of the message The LRC is calculated by adding together successive 8 bit bytes of the message discarding any carries and then two s complementing the result A procedure for generating an LRC is 1 Add all bytes in the message excluding the starting colon and ending CRLF Add them into an 8 bit field so that carries will be discarded 2 Subtract the final field value from FF hex all 1 s to produce the ones complement 3 Add 1 to produce the twos complement 2 4 2 RTU Mode Cyclical Redundancy Check CRC The CRC field is two bytes containing a 16 bit binary value The CRC is started by first preloading a 16 bit register to all 1 s Then a process begins of applying successive 8 bit bytes of the message to the current contents of the register Only the eight bits of data in each character are used for generating the CRC Start and stop bits and the parity bit do not apply to the CRC A procedure for generating a CRC 16 is 1 Load a 16 bit register with FFFF hex all 1 s Call this the CRC register 2 Exclusive OR the first 8 bit byte of the message with the high 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
99. or down or through the up down terminals Memory of digital given means after inverter stops the target frequency is the running frequency before stop If the user would like to save target frequency in memory when the power is disconnected please set F220 1 i e frequency memory after power down is valid 1 External analog ALI 2 External analog AI2 The frequency is set by analog input terminal All and AD The analog signal may be current signal 0 20mA or 4 20mA or voltage signal 0 5V or 0 10V which can be chosen by switch code Please adjust the switch code according to practical situations refer to fig 4 4 and table 4 2 When inverters leave the factory the analog signal of ATI channel is DC voltage signal the range of voltage is 0 10V and the analog signal of AI2 channel is DC current signal the range of current is 0 20 mA If 4 20mA current signal is needed please set lower limit of analog input F406 2 which input resistor is 500OHM If some errors exist please make some adjustments 3 Pulse input given When frequency is given by pulse input the pulse is only input by OPI terminal The max pulse frequency is 50K The related function code are F440 F446 4 Stage speed control Multi stage speed control is selected by setting stage speed terminals F316 F322 and function codes of multi stage speed section The frequency is set by multi stage terminal or automatic cycling frequency 5 No memory of
100. or DC F601 Braking 1 00 5 00 1 00 Y DC Braking Voltage before M F602 pom 0 60 10 Y gt F603 ye Voltage During 0 60 10 J top X Braking Lasting Time me PO E F604 Before Starting 0 0 10 0 0 5 Y ADA i pogs Pee Cone Time 0 0 10 0 0 5 Y pi During Stopping 5 F606 Reserved F E ei e Stalling O invalid 1 valid O y 5 Adjusting Function a Stalling Current F608 Adjusting 90 60200 160 Y Stalling Voltage F609 Adjusting 94 60200 140 Y peig Sie Protection Judging 0 1 3000 0 5 0 y Time Energy Consumption Brake Single phase 380V FOU Point li Three phase 710V A F612 Discharging percentage 01006 80 F613 F630 Reserved 84 E1000 e d n D n Setting Range Mfr s Value Change Selection of terminal 0 free stop immediately Fie free stop mode 1 delayed free stop o Delay time for free stop F701 and programmable 0 0 60 0s 0 0 V terminal action O controlled by temperature F702 Fan control mode 1 Do not controlled by temperature Mfr s value 2 x 2 Controlled by running status me z F703 Setting fan control 0 100 C 35 C x 5 temperature ome peroane sacos TE 5 Motor Overloading 2 g x S Fus pre alarm Coefficient 2071907 BUR 2 Inverter Overloading m F706 i 1207 190 150 x 5 Coefficient ge adi F707 Motor Qverloading 20 100 100 x d Coefficient 26 Record of The Late
101. ord of The Latest Malfunction Type Setting range F709 Record of Malfunction Type for Last but One 2 hardware over current OC 3 over voltage OE F710 Record of Malfunction Type for Last but Two 4 input out phase PF1 E1000 5 inverter overload OL1 6 under voltage LU 7 overheat OH 8 motor overload OL2 motor Err2 17 output out phase PFO 11 external malfunction ESP 13 studying parameters without 16 software over current OC1 F711 Fault Frequency of The Latest Malfunction F712 Fault Current of The Latest Malfunction F713 Fault PN End Voltage of The Latest Malfunction F714 Fault Frequency of Last Malfunction but One F715 Fault Current of Last Malfunction but One F716 Fault PN End Voltage of Last Malfunction but One F717 Fault Frequency of Last Malfunction but Two F718 Fault Current of Last Malfunction but Two F719 Fault PN End Voltage of Last Malfunction but Two F720 Record of overcurrent protection fault times F721 Record of overvoltage protection fault times F722 Record of overheat protection fault times F723 Record of overload protection fault times F724 Input out phase Setting range 0 invalid 1 valid Mfr s value 1 F725 Undervoltage Setting range 0 invalid 1 valid Mfr s value 1 F726 Overheat Setting range 0 invalid 1 valid Mfr s value 1 F727 Outp
102. output an instruction signal when OPI inputs the 55 pulse relay will output an instruction signal until reaching set count times 8 1 2 3 4 5 6 7 8 1 OPI Input DOI a ae Relay Fig 5 6 Set Count times amp Designated Count Times 5 3 2 Digital multifunctional input terminals Setting range 0 no function IMfr s value 1 running terminal 2 stop terminal 3 multi stage speed terminal 1 M 4 multi stage speed terminal 2 5 6 7 8 9 F316 OPI terminal function setting 317 OP2 terminal function setting fr s value 9 multi stage speed terminal 3 multi stage speed terminal 4 reset terminal free stop terminal external emergency stop terminal F319 OP4 terminal function setting 10 acceleration deceleration forbidden terminal Mfr s value 16 11 forward run jogging 12 reverse run jogging Me 3 UP frequency increasing terminal F320 OPS terminal function setting 14 DOWN frequency decreasing terminal 15 FWD terminal 16 REV terminal 17 three line type input X terminal 18 acceleration deceleration time switchover terminal IF322 OP7 terminal function setting 19 20 Reserved IMfr s value F318 OP3 terminal function setting IMfr s value 15 Mfr s value 7 F321 OP6 terminal function setting IMfr s value 8 1 freguency source switchover terminal F323 OPS terminal function setting
103. peed fr s value 15 00Hz SISISISISIS E S E S SI8 F515 Frequency setting for stage 12 speed fr s value 20 00Hz 53 E1000 F516 Frequency setting for stage 13 speed Mfr s value 25 00Hz F517 Frequency setting for stage 14 speed Mfr s value 30 00Hz F518 Frequency setting for stage 15 speed Mfr s value 35 00Hz ep A ve setting for the Setting range Mfr s value s s from Stage age gt 2 0 130005 0 2 3 7KW 5 08 F534 F548 Deceleration time setting for the Setting range 5 5 30KW 30 0S speeds from Stage to Stage 15 0 1 3000S Above 37KW 60 0S F549 F556 Setting range Running directions of stage speeds from Stage 1 0 forward running Mfr s value 0 to Stage 8 1 reverse running F573 F579 Setting range Running directions of stage speeds from stage 9 0 forward running Mfr s value 0 to stage 15 1 reverse running F557 564 Running time of stage speeds Setting range from Stage 1 to Stage 8 0 13000S e 1 05 F565 F572 Stop time after finishing stages Setting range ES f from Stage 1 to Stage 8 0 0 3000S Mars yeller 5 7 Auxiliary Functions Setting range 0 not allowed F600 DC Braking Function Selection 1 braking before starting Mfr s value 0 2 braking during stopping 3 braking during starting and stopping F601 Initial Frequency for DC Braking Setting range 1 00 5 00 Mfr s value 1 00 F602 DC Braking Vo
104. quency B 0 00 650 0Hz 0 00Hz Y F130 Skip Width B 2 50Hz 0 00 V 0 Present output frequency function code 1 Current output rotary speed 2 Output current J 4 Output voltage pom 4 F131 Running Display Items 8 PN voltage 0 1 2 4 8 15 16 PID feedback value 32 Temperature 64 Count values 128 Linear speed frequency function code 1 Keypad jogging 2 Target rotary speed F132 Display items of stop M PN voltage 24 4 6 Y 8 PID feedback value 16 Temperature 32 Count values F133 Drive Ratio of Driven System 0 10 200 0 1 0 Y F134 Iransmission wheel radius 0 001 1 000 m 0 001 Y F135 Reserved F136 Slip compensation 071096 0 x 0 Linear compensation 1 Square compensation 2 User defined multipoint F137 Modes of torque compensati P 3 X erdum E compensation 3 Auto torque compensation 0 2 3 7 5 F138 Linear compensation 17 16 5 5 30 4 gt Above 37 3 1 1 5 2 1 8 F139 Square compensation B 19 4 20 1 x F140 User defined frequency point 1 O F142 1 00 x F141 User defined voltage point 1 0 100 4 x F142 User defined frequency point 2 FI40 F144 5 00 x F143 User defined voltage point 2 010026 13 x 76 E1000 F144 User defined frequency point 3 F142 F146 10 00 F145 User defined voltage point 3 0 100 24 x F146 User defined frequency point 4 F144 F148 20 00 F147 Us
105. r s value 2 F703 Setting fan control temperature Setting range 0 100 C Mfr s value 35 C When F702 0 fan will run if radiator s temperature is up to setting temperature which is set by F703 When F702 1 fan will run when power is supplied to the inverter And fan will not stop until inverter is powered off When F702 2 fan will run when inverter begins running When inverter stops fan will stop until radiator s temperature is lower than 45 C Fan control temperature is set by F703 the temperature is set by manufacture User can only check it Single phase 0 2 0 75kw inverters do not have this function F702 and F703 are invalid F704 Inverter Overloading pre alarm Coefficient Setting range 50 100 Mfr s value 80 F705 Motor Overloading pre alarm Coefficient Setting range 50 100 Mfr s value 80 F706 Inverter Overloading Coefficient Setting range 1207 190 Mfr s value 150 F707 Motor Overloading Coefficient 96 Setting range 20 100 Mfr s value 100 Overloading Coefficient F706 the ratio of overload protection current and rated current whose value shall be subject to actual load Motor overloading coefficient F707 when inverter drives lower power motor please set the value of F707 by below formula in order to protect motor Actual motor power Motor Overloading Coefficient X10026 Matching motor power F708 Rec
106. rminals The users may operate the control terminals by Table 4 3 Functions of Control Terminals Terminal Type Description Function Multifunctional When the token function is valid the value DOL inal 1 between this terminal and CM is OV when the output terminal 1 verter is stopped the value is 24V z When the token function is valid the value he functions of output f Multifunctional Senis eh A DO2 inal 2 between this terminal and CM is OV when the terminals shall be defined output terminal 4 nverter is stopped the value is 24V er manufacturer s value TA TC is a common point TB TC are normally Their initial state may be TB Output closed contacts TA TC are normally open changed through signal contacts The contact capacity of 15kw and below changing function codes Relay contact sk inverter is 10A 125VAC SA 250VAC xis TC 5A 30VDC contact capacity of bove 15kw is 12A 125VAC 7A 250VAC 7A 30VDC AOI Running It is connected with frequency meter or speedometer externally and its frequency minus pole is connected with GND See F423 F426 for details P It is connected with ammeter externally and its minus pole is connected e Current display jim GND See F427 F430 for details Analog Internal 10V self contained power supply of the inverter provides power Self contained 10V power nnl to the inverter When used externally it can only
107. rning J7 to PNP OP terminal is connected to 24V Fig 3 2 Toggle Switch J7 3 J7 is on the back of control PCB of single phase 0 2KW 0 75KW i 3 4 Wiring Recommended Inverter Model Lead Section Arealn m Inverter Model Lead Section Area mmr E1000 0002S2 1 0 E1000 0550T3 35 E1000 0004S2 1 5 E1000 0750T3 50 E1000 0007S2 2 5 E1000 0900T3 70 E1000 0015S2 2 5 E1000 1100T3 70 E1000 0022S2 4 0 E1000 1320T3 95 E1000 0007T3 1 5 E1000 1600T3 120 E1000 0015T3 2 5 E1000 1800T3 120 E1000 0022T3 2 5 E1000 2000T3 150 E1000 0037T3 2 5 E1000 2200T3 185 E1000 0040T3 2 5 E1000 2500T3 240 E1000 0055T3 4 0 E1000 2800T3 240 E1000 0075T3 4 0 E1000 3150T3 300 E1000 0110T3 6 0 E1000 3550T3 300 E1000 0150T3 10 E1000 4000T3 400 E1000 0185T3 16 E1000 4500T3 480 E1000 0220T3 16 E1000 5000T3 520 E1000 0300T3 25 E1000 5600T3 560 E1000 0370T3 25 E1000 6300T3 720 E1000 0450T3 35 3 5 Lead section area of protect conductor grounding wire Lead section area S of U V W mm Minimum lead section area S of 7 PE E mm S X16 16 S X 35 35 lt S S 16 S 2 17 E1000 3 6 Overall Connection and Three Line Connection Refer to next figure for overall connection sketch for E1000 series inverters Wiring mode is available for various terminals whereas not every terminal needs connection when applied Note Braking unit Choke
108. rom motor will increase the current leaked to the earth will decrease The wastage of motor and the temperature of motor will increase but the temperature of inverter will decrease When carrier wave frequency is high the situations are opposite and the interference will raise When output frequency of inverter is adjusted to high frequency the setting value of carrier wave should be increased Performance is influenced by adjusting carrier wave frequency as below table Carrier wave frequency Low gt High Motor noise Loud gt Low Waveform of output current Bad Good Motor temperature High Low Inverter temperature Low gt High Leakage current Low gt High Interference Low gt High F154 Automatic voltage rectification seting range UM a wad Mfr s value 0 2 Invalid during deceleration process This function is enable to keep output voltage constant automatically in the case of fluctuation of input voltage but the deceleration time will be affected by internal PI adjustor If deceleration time is forbidden being changed please select F154 2 FI55 Digital accessorial frequency setting Setting range 0 F111 Mfr s value 0 F156 Digital accessorial frequency polarity setting Setting range 0 or 1 Mfr s value 0 F157 Reading accessorial frequency F158 Reading accessorial frequency polarity Under combined speed control mode when accessorial
109. s set wrong Measurement m Do not connect motor when ERR2 parameters E pm please connect motor correctly wrong measuring parameters Current Current alam elena exists before check if control board is connected ERR3 malfunction dnd SIE a with power board well before running amp ask for help from manufacture ERR4 Coren zer Flat cable is loosened check the flat cable manlf endos Current detector is broken ask for help from manufacture e No P F1 protection for single phase and three phase under 4 0KW 60 Table 1 2 Malfunction E1000 Motor Malfunction and Counter Measures Items to Be Checked Counter Measures Motor not Running Wiring correct Setting correct Too big with load Motor is damaged Malfunction protection occurs Get connected with power Check wiring Checking malufunction Reduce load Check against Table 1 1 Wrong Direction of Motor Running U V W wiring correct Parameters setting correct To correct wiring Setting the parameters correctly Motor Turning but Wiring correct for lines with given frequency To correct wiring Speed Change not Correct setting of running mode Possible 8 Too big with A ad g To correct setting Reduce load Motor s rated value correct Drive ratio Check motor nameplate data Check Motor Speed Too correct Inverter parameters are set the setting of drive ratio Check High or Too Low incorrected Check if inverter ou
110. st Setting range F708 Malfunction Type 2 hardware over current OC A amp 3 over voltage OE e i 4 input out phase PF1 5 F709 Record of Malfunction 5 inverter overload OL1 A Type for Last but One 6 under voltage LU 7 overheat OH 8 motor overload OL2 11 external malfunction ESP F710 Record of Malfunction 13 studying parameters without N Type for Last but Two motor Err2 16 software over current OC1 17 output out phase PFO Fault Frequency of The EM Latest Malfunction 3 Fault Current of The E FH Latest Malfunction A Fault PN End Voltage of A Pie The Latest Malfunction 5 A Fault Frequency of Last S Fat Malfunction but One s Izd Fault Current of Last lm Ee Malfunction but One gt 2 Fault PN End Voltage of F716 Last Malfunction but One s a Fault Frequency of Last a FIF Malfunction but Two A e Fault Current of Last Q FTIR Malfunction but Two 5 mmo Fault PN End Voltage of 5 FE Last Malfunction but Two s Record of overcurrent Fi protection fault times A 85 E1000 Record of overvoltage FIM protection fault times a F722 Record of overheat protection fault times Record of overload 1 23 protection fault times A F724 Input out phase 0 invalid 1 valid 1 X F725 Undervoltage 0 invalid 1 valid 1 x F726 Overheat O invalid 1 valid 1 gt F727 Output out phase 0 invalid 1 valid 0 O F728 o ppw PUE
111. switchover terminal time is valid See F116 and F117 for the second acceleration deceleration time 9 Reserved Reserved 20 Reserved Reserved 21 frequency source When F207 2 main frequency source X and accessorial frequency Switchover terminal source Y can be switched over by frequency source switching terminal When F207 3 X and X Y can be switched over by frequency source switching terminal 22 Count input terminal Built in count pulse input terminal 23 Count reset terminal Reset terminal count value to zero 24 30 Reserved Reserved 44 E1000 Table 5 4 Instructions for multistage speed K4 K3 K2 Kl Frequency setting Parameters 0 0 0 0 None None 0 0 0 Multi stage speed 1 F504 F519 F534 F549 F557 F565 0 0 1 0 Multi stage speed 2 F505 F520 F535 F550 F558 F566 0 0 1 Multi stage speed 3 F506 F521 F536 F55 1 F559 F567 0 1 0 0 Multi stage speed 4 F507 F522 F537 F552 F560 F568 0 1 0 Multi stage speed 5 F508 F523 F538 F553 F561 F569 0 1 1 0 Multi stage speed 6 F509 F524 F539 F554 F562 F570 0 1 1 Multi stage speed 7 F5 10 F525 F540 F555 F563 F57 1 0 0 0 Multi stage speed 8 F511 F526 F541 F556 F564 F572 0 0 Multi stage speed 9 F512 F527 F542 F573 0 1 0 Multi stage speed 10 F513 F528 F543 F574 0 1 Multi stage speed 11 F514 F529 F544 F575 1 0 0 Multi stage speed 12 F515 F530 F545 F576 1 0 Multi stage speed 13 F516 F531 F546 F577 1 1 0 Multi stage speed 14 F517 F532 F547
112. th control terminals 1 Connect the wires in accordance with Figure 4 3 After having checked the wiring successfully switch on the air switch and power on the inverter Note 2K 5K potentiometer may be adopted for setting external analog signals For the cases with higher requirements for precision please adopt precise multiturn potentiometer and adopt shielded wire for the wire connection with near end of the shielding layer grounded reliably AC400V D mmm Figure 4 3 Wiring Diagram 3 24 2 Press the Fun key to enter the programming menu E1000 3 Study the parameters of the motor the operation process is the same as that of example 1 4 Set functional parameters of the inverter D Enter F203 parameter and set it to 1 select the mode of frequency setting of analog All O 10V voltage terminal Enter F208 parameter and set it to 1 select direction terminal set OP6 to free stop set OP3 to forward running set OP4 to reverse running to control running 5 There is a red two digit coding switch SWI near the control terminal block of 15 KW inverter and below 15kw as shown in Figure 4 4 The function of coding switch is to select the voltage signal 05 V 0 10V or current signal of analog input terminal AD current channel is default In actual application select the analog input channel through F203 Turn switches 1 to ON and 2 to ON as illustrated in the figure and select 0 20
113. the user can realize different control modes 4 5 3 Running status The inverter at the stopped status or fault free status will enter running status after having received operation command The running indicator on keypad panel lights up under normal running status 4 5 4 Fault alarm status The status under which the inverter has a fault and the fault code is displayed Fault codes mainly include OC OE OLI OL2 OH LU PFI representing over current over voltage inverter overload motor overload overheat input undervoltage input out phase and respectively For trouble shooting please refer to Appendix I to this manual Trouble Shooting 4 6 Keypad panel and operation method Keypad panel keypad is a standard part for configuration of E1000 inverter Through keypad panel the user may carry out parameter setting status monitoring and operation control over the inverter Both keypad panel and display screen are arranged on the keypad controller which mainly consists of three sections data display section status indicating section and keypad operating section There are two types of keypad controller with potentiometer or without potentiometer for inverter For details please refer to Chapter II of 19 E1000 this manual Keypad panel It is necessary to know the functions and how to use the keypad panel Please read this manual carefully before operation 4 6 1 Method of operat
114. the wiring successfully switch on the air switch and power on the inverter AC 400V Figure 4 1 Wiring Diagram 1 2 Press the Fun key to enter the programming menu 3 Measure the parameters of motor stator resistance parameter 1 Enter F801 parameter and set rated power of the motor to 7 5kW Enter F802 parameter and set rated voltage of the motor to 400V Enter F803 parameter and set rated current of the motor to 15 4A Enter F804 parameter and set number of poles of the motor to 4 Enter F805 parameter and set rated rotary speed of the motor to 1440 rpm 22 E1000 Enter F800 parameter and set it to 1 to allow measuring the parameter of the motor Press the Run key to measure the parameters of the motor After completion of the measurement and relevant parameters will be stored in F806 For the details of measurement of motor parameters please refer to Operation process of measuring the motor parameters in this manual and Chapter XII of this manual 4 Set functional parameters of the inverter Enter F203 parameter and set it to 0 G Enter F111 parameter and set the frequency to 50 00Hz Enter F200 parameter and set it to 0 select the mode of start as keypad control DEnter F201 parameter and set it to 0 select the mode of stop as keypad control G Enter F202 parameter and set it to 0 select forward locking 5 Press the Run key to start the inverter 6 During running c
115. tnote Note 2 Illegal response 0004 appears below two cases 1 Do not reset inverter when inverter is in the malfunction state 2 Do not unlock inverter when inverter is in the locked state 2 5 3 Additional Remarks Expressions during communication course Parameter Values of Frequency actual value X 100 General Series Parameter Values of Frequency actual value X 10 Medium Frequency Series Parameter Values of Time actual value X 10 Parameter Values of Current actual value X 10 Parameter Values of Voltage actual value X 1 Parameter Values of Power actual value X 100 Parameter Values of Drive Ratio actual value X 100 Parameter Values of Version No actual value X 100 Instruction Parameter value is the value sent in the data package Actual value is the actual value of inverter After PC PLC receives the parameter value it will divide the corresponding coefficient to get the actual value NOTE Take no account of radix point of the data in the data package when PC PLC transmits command to inverter The valid value is range from 0 to 65535 III Function Codes Related to Communication Function Code Function Definition Setting Rang Mfr s Value 0 Keypad command 1 Terminal command F200 Source of start command 2 Keypad Terminal 0 3 MODBUS 4 Keypad Terminal MODBUS 0 Keypad command 1 Terminal command F201 Source of stop command 2 Keypad t Terminal 0 3 MODBUS 4 K
116. too short OC protection of the inverter may occur 8 Switch off the switches OP3 and OP4 the motor will decelerate until it stops running 9 Switch off the air switch and power off the inverter 4 9 3 Operation process of jogging operation with keypad panel 1 Connect the wires in accordance with Figure 4 1 After having checked the wiring successfully switch on the air switch and power on the inverter 2 Press the Fun key to enter the programming menu 3 Study the parameters of the motor the operation process is the same as that of example 1 4 Set functional parameters of the inverter Enter F132 parameter and set it to 1 select keypad jogging Enter F200 parameter and set it to 0 select the mode of running command control as keypad operation Enter F124 parameter and set the jogging operation frequency to 5 00Hz Enter F125 parameter and set the jogging acceleration time to 30S Enter F126 parameter and set the jogging deceleration time to 30S Enter F202 parameter and set it to 0 select forward running locking 5 Press and hold the Run key until the motor is accelerated to the jogging frequency and maintain the status of jogging operation 6 Release the Run key The motor will decelerate until jogging operation is stopped 7 Switch off the air switch and power off the inverter 4 9 4 Operation process of setting the frequency with analog terminal and controlling the operation wi
117. topped status F132 including of displaying items of keypad jogging should be set Terminal jogging is valid under both running status and stopped status f Carry out jogging operation through the keypad under stopped status a Press the Fun key it will display HF 0 b Press the Run key the inverter will run to jogging frequency if pressing Fun key again keypad jogging will be cancelled In case of terminal jogging make F124 uoinonasui uone1edo BuibBo Bumowoy Jogging Operation jogging terminal such as OPI connected to CM and inverter will run Figure 5 1 Jogging Operation to jogging frequency The rated function codes are from F316 to F323 Jogging Acceleration Time the time for inverter to accelerate from OHz to SOHz Jogging Deceleration Time the time for inverter to decelerate from 50Hz to OHz FI27 F129 Skip Frequency A B Hz Setting range 0 00 650 0 Mfr s value 0 00Hz F128 F130 A Skip Width A B Hz Setting range 2 5 Mfr s value 0 0 Systematic vibration may occur when the motor Output is running at a certain frequency This parameter is Frequency set to skip this frequency Hz The inverter will skip the point automatically F129 iL when output frequency is equal to the set value of d this parameter p Skip Width is the span from the upper to the lower limits around Skip Frequency For example Skip Fr
118. tor and inverter Grounding with series connection is forbidden Load switch is forbidden at output while inverter is in operation AC reactor or and DC reactor is recommended when your inverter is above 37KW There should be separate wiring between control loop and power loop to avoid any possible interference Signal line should not be too long to avoid any increase with common mode interference It shall comply with the requirements for surrounding environment as stipulated in Table 1 1 Technical Specifications for E1000 Series Inverter 1 8 2 Special Warning Never touch high voltage terminals inside the inverter to avoid any electric shock Before inverter is powered on please be sure that input voltage is correct Please do not connect input power supply onto U V W or 7 terminals Please do not install inverter directly under sunshine do not block up the cooling hole ibi E1000 All safety covers should be well fixed before inverter is power connected to avoid any electric shock Only professional personnel are allowed for any maintenance checking or replacement of parts No live line work is allowed 1 9 Maintenance 1 9 1 Periodic Checking Cooling fan and wind channel should be cleaned regularly to check whether it is normal remove the dust accumulated in the inverter on a regular basis Check inverter s input and output wiring and wiring terminals regularly and ch
119. tput voltage parameters setting Check V F is abnormal Characteristic value Motor Running Too big load Too big with load change Reduce load reduce load change increase capacity Unstable Out phase Motor malfunction Correct wiring Check input wring Selecting Power Trip Wiring current is too high matching air switch Reduce load checking inverter malfunction Appendix 2 Products amp Structures E1000 series inverter has its power range between 0 2 630KW Refer to Tables 2 1 and 2 2 for main data There may be two or more than two kinds of structures for certain products Please make a clear indication when placing your order Inverter should operate under the rated output current with overload permitted for a short time However it shall not exceed the allowable values at working time Table 2 1 Product Summary of E1000 Motel men lemmate Coe Moe p e E1000 000282 0 2 1 5 El Self cooling 1 36 L E1000 0004S2 0 4 25 El Air cooling 14 E Fi E1000 0007S2 0 75 4 5 El Air Cooling 1 43 E a E1000 0015S2 1 5 7 E2 Air Cooling 2 0 d E E1000 002282 22 10 E3 Air Cooling 2 28 8 E1000 0007T3 0 75 2 E2 Air Cooling 2 0 4 E1000 0015T3 1 5 4 E2 Air Cooling 2 0 a E1000 0022T3 22 6 5 E2 Air Cooling 2 0 gt E1000 0037T3 3 7 8 E4 Air Cooling 3 02 E E1000 0040T3 4 0 9 E4 Air Cooling 3 02 E E1000 0055T3 5 5 12 E5 Air Cooling 4 2 gE E1000 0075T3 7 5 17 ES Air Cooling 44 E
120. ts dc rede e cene ERA RE RR CERA IRE Ra 26 5 1 Basic Parameters erpen eerten e edere gener eses 26 52 OperationControl 34 5 3 Multifunctional Input and Output Terminals 41 5 4 AnaloginputandOutput 45 5 5 Pusleinputandoutput 50 56 Multi stageSpeedControl 52 57 AuxlaryFunc ons 54 58 Malfunc onandProtecton 56 59 Parametersofthemotor 58 5 10 Communicationparameters 58 DLL PID parameters ieri ese eee tette 59 Appendix 1 Trouble Shooting ek daki Man 60 Appendix 2 ProductsandStructurelist 61 Appendix 3 SelectionofBrakingResistance 65 Appendix 4 CommunicationManual 66 Appendix 5 ZoomTableofFunct onCode 75 E1000 I Product This manual offers a brief introduction of the installation connection for E1000 series inverters parameters setting and operations and should therefore be properly kept Please contact manufacturer or dealer in case of any malfunction during application 1 1 Product model naming rule E1000 0007 S2 Input power type S2 means single phase 230VAC T3 means three phase 400VAC Relation Mark 0002 0004 0007
121. tting value B F443 1 setting benchmark C F440 F F442 E D 2 F446 F449 Max frequency of output pulse FO Setting range 0 00 50 00K Mfr s value 10 00K F450 Zero drift coefficient of output pulse g Setting range 0 0 100 0 Mfr s value 0 0 frequency F451 Frequency gain of output pulse Setting range 0 00 10 00 Mfr s value 1 00 51 E1000 Setting range 0 Running freguency F453 Output pulse signal 1 Output current Mfr s value 0 2 Output voltage 37 5 reserved When DOI is defined as high speed pulse output terminal the max frequency of output pulse is set byF449 If b stands for zero drift coefficient k stands for gain Y stands for actual output of pulse frequency and X stands for standard output then Y Kx b Standard output X is the token value corresponding to output pulse min max frequency which range is from zero to max value 100 percent of zero drift coefficient of output pulse frequency corresponds to the max output pulse frequency the set value of F449 Frequency gain of output pulse is set by F451 User can set it to compensate the deviation of output pulse Output pulse token object is set by F453 For example running frequency output current and output voltage etc When output current is displayed the range of token output is 0 2 times of rated current When output voltage is displayed the range of token output
122. ultifunctional relay output terminal Inverters of 15KW and below 15KW have one multifunctional digital output terminals without DO2 terminal inverters above 15KW have two multifunctional digital output terminals Table 5 2 Instructions for digital multifunctional output terminal Value Function Instructions 0 no function Output terminal has no functions 1 inverter fault protection When inverter works wrong ON signal is output 2 over latent frequency 1 Please refer to instructions from F307 to F309 3 over latent frequency 2 Please refer to instructions from F307 to F309 4 free stop Under free stop status after stop command is given ON signal is output until inverter completely stops 5 in running status 1 Indicating that inverter is running and ON signal is output DC braking Indicating that inverter is in the status of DC braking and ON signal is output 7 acceleration deceleration Indicating that inverter is in the status of acceleration deceleration time switchover time switchover 8 Reaching the Set Count This terminal will be action when inverter carries the external Value count instruction and count value reaches the set value of F314 9 Reaching the Designated This terminal will be action when inverter carries the external Count Value count instruction and count value reaches the set value of F315 deter overload After inverter overloads ON signal is output after
123. urrent frequency of the inverter can be changed by pressing A or V 7 Press the Stop Reset key once the motor will decelerate until it stops running 8 Switch off the air switch and power off the inverter 4 9 2 Operation process of setting the frequency with keypad panel and starting forward and reverse running and stopping inverter through control terminals 1 Connect the wires in accordance with Figure 4 2 After having checked the wiring successfully switch on the air switch and power on the inverter AC400V Figure 4 2 Wiring Diagram 2 2 Press the Fun key to enter the programming menu 3 Study the parameters of the motor the operation process is the same as that of example 1 4 Set functional parameters of the inverter Enter F203 parameter and set it to 0 select the mode of frequency setting to digital given memory kEnter F111 parameter and set the frequency to 50 00Hz Enter F208 parameter and set it to 1 select two line control mode 1 Note when F208 40 F200 F201 and F202 will be invalid 5 Close the switch OP3 the inverter starts forward running 6 During running current frequency of the inverter can be changed by pressing A or V 23 E1000 7 During running switch off the switch OP3 then close the switch OP4 the running direction of the motor will be changed Note The user should set the dead time of forward and reverse running F120 on the basis of the load If it was
124. ut out phase Setting range 0 invalid 1 valid Mfr s value 0 F728 Input out phase filtering constant Setting range 0 1 60 0 Mfr s value 0 5 F729 Undervoltage filtering constant Setting range 0 1 60 0 Mfr s value 5 0 F730 Overheat protection filtering constant Setting range 0 1 60 0 Mfr s value 5 0 Undervoltage refers to too low voltage at AC input side Out phase supply refers to out phase of three phase power Undervoltage out phase signal filtering constant is used for the purpose of eliminating disturbance to avoid mis protection The greater the set value is the longer the filtering time constant is and the better for the filtering effect F737 Software over current protection Setting range O Invalid 1 Valid Mfr s value 0 Coefficient F738 o Software over cument protection Setting range 0 50 3 00 Mfr s value 2 0 F739 Software over current protection record Software over current protection Coefficient equals to the ratio of software over current value with inverter rated current In running status F738 can not be changed When over current occurred OC is displayed 57 E1000 5 9 Parameters of the Motor Setting range F800 Motor s parameters selection 0 no parameter measurement Mfr s value 0 1 Stator resistance parameter measurement F801 Rated power Setting range 0 2 1000KW F802 Rated volta
125. value 1 00 F408 Upper limit of AI2 channel input Setting range F406 10 00V Mfr s value 10 00V NETS ve Setting range 7 F409 Corresponding setting for upper limit of AD input Max 1 00 F407 2 00 Mfr s value 2 00 F410 AQP channel proportional gain K2 Setting range 0 0 10 0 Mfr s value 1 0 F411 AD filtering time constant Setting range 0 1 10 00 Mfr s value 0 10 F412 Lower limit of Al3 channel input Setting range 0 00 F414 Mfr s value 0 05V F413 Corresponding setting for lower limit of Al3 input Setting range O F415 Mfr s value 1 00 47 E1000 F414 Upper limit of AI3 channel input Setting range F412 10 0V Mfr s value 10 0V F415 Corresponding setting for upper limit of Al3 input Setting range Max 1 00 F413 2 00 Mfr s value 2 00 F416 AB channel proportional gain KI Setting range 0 0 10 0 Mfr s value 1 0 F417 AT3 filtering time constant Setting range 0 1 10 00 Mfr s value 0 10 The function of AD and AT3 is the same with AII F418 ATI channel OHz voltage dead zone Setting range 0 0 50V Positive Negative Mfr s value 0 00 F419 AL channel OHz voltage dead zone Setting range 0 0 50V Positive Negative Mfr s value 0 00 F420 AD channel OHz voltage dead zone Setting range 0 0 50V Positive Negative Mfr s value 0 00 Analog input voltage 0 5V can correspond to output frequency
126. verter Function Data Data Data High order Low order Return Line Feed OX3A Address Code Length 1 N byte of LRC byte of 0X0D 0X0A LRC 2 RTU mode Start Address Function Data CRC check End Inverter Function Low order byte High order byte T1 T2 T3 T4 N data T1 T2 T3 T4 Address Code of CRC of CRC 2 1 2 ASCII Mode In ASCII mode one Byte hexadecimal format is expressed by two ASCII characters For example 31H hexadecimal data includes two ASCII characters 3 33H 1 31H Common characters ASCII characters are shown in the following table Characters 0 V 2 3 4 S 35 ASCII Code 30H 31H 32H 33H 34H 35H 36H 37H Characters 8 9 A B C D E FP ASCII Code 38H 39H 41H 42H 43H 44H 45H 46H 2 1 3 RTU Mode In RTU mode one Byte is expressed by hexadecimal format For example 31H is delivered to data packet 2 2 Baud rate Setting range 1200 2400 4800 9600 19200 38400 57600 2 3 Frame structure ASCII mode Byte Function 1 Start Bit Low Level 66 E1000 7 Data Bit 0 1 Parity Check Bit None for this bit in case of no checking Otherwise 1 bit 1 2 Stop Bit 1 bit in case of checking otherwise 2 bits 2 RTU mode Byte Function 1 Start Bit Low Level 8 Data Bit 0 1 Parity Check Bit None for this bit in case of no checking Otherwise 1 bit 1 2 Stop Bit 1 bit in case of checking otherwise 2 bits 2 4 Error Check 2 4 1 ASCII mode L
127. z and 10V corresponds to 50Hz The unit of corresponding setting for upper lower limit of input is in percentage If the value is greater than 1 00 it is positive if the value is less than 1 00 it is negative e g F401 0 5 represents 5046 If the running direction is set to forward running by F202 then 0 5V corresponding to the minus frequency will cause reverse running or vice versa Corresponding setting Frequency 100 0 0 0 AI OmA 46 Corresponding setting Frequency 100 0 AI Fig 5 6 correspondence of analog input to setting The unit of corresponding setting for upper lower limit of input is in percentage If the E1000 value is greater than 1 00 it is positive if the B value is less than 1 00 it is negative e g F401 0 5 represents 50 The corresponding setting benchmark in the mode of combined All speed control analog is the accessorial frequency and the setting benchmark for range of accessorial frequency which relatives to main A frequency F205 1 is main frequency X corresponding setting benchmark for other cases is the max frequency as illustrated in the right figure A F401 1 setting value B F403 1 setting value C F400 D F402 F406 Lower limit of AD channel input Setting range 0 00 F408 Mfr s value 0 01 V F407 Corresponding setting for lower limit of AD input Setting range 0 F409 Mfr s

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