Instruction Manual
Contents
1. unit Table 3 2 F1000 G Types of Product Structure us re ou se Mounting Size Wx L u Remarks BO 105x120x150 94x139 M4 B2 125x140x170 114x160 M5 Dy B3 143x148x200 132x187 M5 Es B4 162x150x250 145x233 M5 Be B5 200x160x300 182x282 M6 C1 225x220x340 160x322 M6 C2 230x225x380 186x362 M6 z C3 265x235x435 235x412 M6 C4 314x235x480 274x464 M6 T C5 360x265x555 320x530 M8 g C6 411x300x630 370x600 M10 B C7 516x326x760 360x735 M12 YE C8 560x326x1000 390x970 M12 DO 580x500x1500 410x300 MI6 DI 600x500x1730 400x300 M16 Q z D2 660x500x1950 450x300 M16 2 D3 800x600x2045 520x340 M16 ar D4 1000x550x2000 800x350 M16 F1000 G SOTOTOLO Yantai Huifeng Electronics Co Ltd Add No Fu 11 Huanghe Rd YTETDZ Yantai China P C 264006 Tel 0535 6391102 Fax 0535 6395279 Email Leo HFinverter com Website www HFinverter com2. F1000 G auto circulation speed control is further divided into auto circulation of two stage speed auto circulation of three stage speed auto circulation of seven stage speed subject to F211 Refer to Table 6 1 Table 6 1 Selection of Multi Speed Control Mode F204 F210 Operation Mode Remarks Start stop is not controlled by Start and Run signals priority level s 3 stage Speed successively I stage 2 stage and 3 stage speed 3 stage speed 1 0 controlcan be used withanalog signal speed control for combined Control speed control 3 stage Speed Control takes priority of analog signal speed control Start stop is not controlled by Start and Run signals 7 stage 1 1 7 stage Speed speed control can be used with analog signal speed control for Control combined speed control 7 stage Speed Control takes priority of analog signal speed control Manual adjustment is not allowed to adjust the running frequency 1 Auto circulation The running frequency can be set by parameter setting as 2 stage Speed Control speed auto circulation 3 stage speed auto circulation 7 stage speed auto circulation F211 Selection of Stage Speed Under 3 f Setting Range 2 7 Mfr s Value 7 Auto circulation Speed Control F212 Selection of Times of Auto z s Setting Range 0 9999 Mfr s Value 0 circulation Speed Control F213 Statu
3. b Press Run and inverter will run to Jogging lig ak dogg ng Operation Frequency Keypad Jogging will be canceled by pressing Mode again In case of terminal jogging make Jogging terminal like OP1 connected to CM and inverter will run to the jogging frequency Notel Stalling Adjusting and F120 is invalid in mode of jogging operation F127 F129 Skip Frequency A B Hz Setting Range O 400 0 Mfr s Value OHz F128 F130 Skip Area A B Hz Setting Range 2 5 Mfr s Value 0 5 System resonance will occur around a certain frequency point during motor running This parameter is set specifically to avoid resonance When output frequency reachs the setting value of automatically run by tripping off this Skip Frequency this parameter inverter will F1000 G Skip Area referes to the difference value between upper and lower frequencies of the skip frequency e g with skip frequency of 20Hz and skip area of 0 5Hz automatic tripping off will happen when inverter has its output within 19 50 20 5Hz as FI F2 in Fig 5 2 This function is invalid during acceleration deceleration process n Fig 5 2 Skip Frequency F131 Disphy Setting Range 0 Frequency 1 Rotate Speed Mfr s Value 0 Contents 2 Linear Velocity 3 Output Voltage 4 Output Current Bree F132 Numbers of Motor Poles Setting Range 2 100 Mf
4. Stal usting Mrene sai Ba gaas B35 Stalling Adjusting when I L I stalling is canceled the time of er A 4 4 4 4 4 frequency raising will be the a A l I ET a quitng time of Stalling ou Adjusting EL ten fen F532 ad SE Fig 9 3 indicates the process of Stalling Adjusting gt a Ip is initial overload current Fig9 3 Stalling Adjusting When output current is higher than this value the inverter will judge the fluctuation removing time If current does not become smaller during the fluctuation removing time F530 then the Stalling Adjusting start b After Stalling Adjusting starts to work decelerate as per the time Stalling Adjusting works Deceleration Time F531 before dropping to the Lower Frequency Limit F532 of Stalling Adjusting if current drops below Ij the inverter will judge the fluctuation removing time F533 when Stalling Adjusting quits If current remains below I within this time then quit Stalling Adjusting c If current rises above I before completely quiting Stalling Adjusting Stalling Adjusting will continue to work The inverter will judge the protection time F535 of 37 F1000 G Stalling Adjusting when current continues to rise and frequency keeps dropping until it reaches the Lower Frequency Limit F532 of Stalling Adjusting If the current remains high during this time overload protection will occur 92 Timing Control
5. H H in the meantime Once the exernal interruption signal is canceled then inverter will restore its running after Reset e g F408 17 OPI is set to be external interuption terminal Make an instant connection with CM inverter will have free stop and indicate H H at the same time Interruption will be canceled after Reset All F408 F415 are set to 18 at time of Coding Speed Control As external binary digits input terminals OP1 OP8 cannot be used for other purpose Refer to 6 2 5 for Coding Speed Control 8 2 Definable Output Terminal F416 Token Output of Relay Mfr s Value 0 F417 Token Output of Terminal OUT1 Setting Range O 12 Mfr s Value 3 F418 Token Output of Terminal OUT2 Mfr s Value 3 Output terminal including state terminal OUT and relay output Terminals TA TB and TC can be defined with 12 optional functions for each Normally TA TC are normally open while TB TC are normally close voltage between OUT and CM is 12V 3L F1000 G When relay works TA TC will close and TB TC will be disconnected As OUT state overturns the voltage with CM becomes 0 from 12V Two definable output terminals allow for functions with the same definition The functions of the definable output terminal are as follows Table 8 2 Optional Functions of the Definable Output Terminals F416 F417 F418 Significance
6. P F ERR input out phase for nput and extemal interference respectively It shows O after reset H H Interruption code indicating external intrruption signal input and showing 0 after reset F152 Function code parameter code 10 00 Indicating inverter s curent running frequency or rotate speed and parameter setting values etc 10 00 Sparkling in stopping status to display target frequency except for analog signals speed control holding time when changing the rotating direction When Stop or Free Stop command is ecxcuted 0 the holding time canbe cancekd Output current 100A and output voltage 100V Keep one digit of decimal when cunent is below A100 U100 100A Errl Indicating error Itshows when parameters are modified wrong password or no password is entered 3 1 Installation Inverter should 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 22KW A2 150mm B 50mm Hanging gt 22KW A2 200mm B gt 75mm Cabinet 110 400KW C 200mm D gt 75mm 32 Connection In case of 3 phase input connect Hanging R S and T terminals R and T e terminals for single phase with Riiizsis lo losia ation Sketc
7. to select required function code Flic 3 To read data set in the function code ED 4 Jor w To modify data an To show corresponding target frequency by z 5 flashing after saving the set data To display the current function code File 2 4 Function Codes Switchover in between Code Groups This has more than 140 parameters function codes available to user divided into 9 sections as indicated in Table 2 3 F1000 G 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 Reserved F600 F660 6 Run Control Mode F200 F260 2 Timing control and Multi Speed F700 F760 7 Parameters F300 F360 3 protection function Terminal Functi i Dafniton on F4000 F460 4 N va of E8000 F860 8 V F Control F500 F560 5 Communication F900 F960 9 As parameters setting costs time due to numerous function codes such function is specically designed as Function Code Switchover in a Code Group or between Two Code Groups so that parameters setting become convenient and simple Press Mode key so that the keypad controller will display function code If press A or W key then function code will circularly keep increasing or decreasing by degrees within the group if press again the stop reset key function code will change circularly betw
8. F1000 G Nolage orcunertambe signs input make Stat top control mik direction terminal analog sina It is essential to correctly and flexibly use control terminals for the een of inverter Of course control terminal are not used separately but together with corresponding parameter setting User can make a flexible use of the basic functions of control terminals with reference to the relevant descriptions in the rest of this manual 4 1 Function of Control Terminal Table 4 1 Function of Control Terminal Tamil Class Name Function Sigs The value between this terminal and CM during running is For function ofthese azi tunning Signal OV and 12V when it stops outputterminak please ref r to mfr s TA TC common point TB TC normally closed contact value it can be TB Output Relay Contact TA TC normally open contact contact current not changed by UP exceeding 2A Voltage not exceeding 250 VAC modifying the TC Signal parameter FM Running Real time output 0 SV or 0 10V when connected to cymometer its cathode Frequency connected to V3 ti 2 ki gt IM Gurrent Display Real time output 00 20mA when connected to ammetershowing inverter s output current 1 phase inverter has no this function SV self contained power source available inside inverter for its own use it can Self Contained k a VI s only be used for
9. F416 F417 F418 Significance 0 Fault Protection Token Output 4 DC Braking Token Output Over Latent Frequency Token Output of Accel Decel 1 Token Output 5 Time Switchover 2 Free Stop Token Output 6 12 Function Reserved 3 Running Token Output F416 F417 0 as inverter has fault protection OC OE PF PO OL and OH etc this terminal will work F416 F417 1 as running frequency is above the setting value of F119 this terminal will work As the running frequency is below the setting value this terminal restores its state F416 F417 2 this terminal will work at time of Free Stop F416 F417 3 this terminal will work when inverter runs this terminal will restore its state when inverter stops F416 F417 4 this terminal will work when inverter is in the state of DC braking F416 F417 5 this terminal will work when Acceleration Deceleration Time Switches 8 3 Special Output Terminal F419 Duty Ratio of Brake Signal Setting Range O 100 Mfr s Value 80 This parameter is used to set the duty ratio of this brake signal The single phase inverters have no the function F420 Lowest Frequency at Max FM IM Hz Setting Range F112 400 0 Mfr s Value 50 00Hz F421 FM Output Range Selection Setting Range 0 0 SV 1 00 10V Mfr s Value 0 F422 FM Output Compensation Setting Range 0 120 Mfr s Value 100 OO SV and OL 10V are available
10. GB HFinverter ISO9001 Certified Huifeng Inverters F1000 G Seri es O 47 400KW Instruction Manual DESIGN WITH INDIVIDUATION SERVICE WITH ADDED VALUE CONTENTS I Product H Nameplate nee RE AE neues 1 2 Model IlustratiOn ee kean orn ek ER ER Re eee GR ek EES 1 1 3 Appearance nase aka rn 1 1 4 Technical Specifications ccc cece eee ER ek ee ene es 2 1 5 Designed Standards for Implementation 3 1 6 Pr CIHUAONS erreso nene en E ee kay en av AS 3 TE Operation Panel u ein GE SE ES a 5 2 1 Panel Ilustrations ororoonnonnonnerenrenrenrennernennennene 5 2 27 PanelOperatine s ke varer Gr ee ied 6 2 3 Parameters Setting issie eek eke GR ee Re Ee ee ee een nenn 6 24 Function Codes Switchover in between Code Groups 6 25 Panel Display Se eee kaze Seire 8 IH Installation Connection ossec siessen oaa aa eia 9 3 Installation EE E EI E E konpa ee ize 9 352 Connection nee seh EEA N 9 3 3 Wiring Recommended iese ie ee ee EE Re ER ee Re Re 11 3 4 Overall Connection and Three Line Connection 11 IWeOperation 2 2 00 a EEE eee ad 12 4 1 Function of Control Terminal c sense 13 4 2 Coding Switch 2 2sessesssesseessesssessneeneesee nennen nenn 14 4 3 Main Functions eroeroennvrannennenaenaerennennennennennenneneene 14 Vi Basie Parameters is es GE Ge EG st aze a ER a eee is 16 VI Ope
11. Reverse F330 1 F336 0 F300 F306 F312 F318 F324 F330 F336 Setting Range Direction is given respectively for the 1 stage speed up to 7 stage speeds These parameter s only work in auto circulation running A Mfr s Value 0 4 3 7K W 5 08 F301 F307 F313 F319 F325 F331 F337 Setting Range 5 5 30KW 30 08 Multi Speed Acceleration Time S 0 1 3000 37 400KW 60 08 Acceleration time is given respectively for the 1 stage speed up to 7 stage speeds l Mfr s Value F302 5 00 F308 10 00 332 F338 tting Range F302 F308 F314 F320 F326 F332 Setting Range Sus Multi Speed Running Frequency Hz F1120 F111 F332 30 00 F338 35 00 Running frequency is given respectively for the 1 stage speed up to 7 stage speeds f Mfr s Value 0 4 3 7KW 5 0S F303 F309 F315 F321 F327 F333 F339 Setting Range 5 5 30KW 30 08 Multi Speed Running Time S 0 10 3000 370 400KW 60 08 Running time is given respectively for 1 stage speed up to 7 stage speeds These parameters only work in auto circulation running a i Mfr s Value 0 4 3 7KW 5 0S F304 F310 F316 F322 F328 F334 F340 Setting Range 5 57 30KW 30 08 Multi Speed Deceleration Time S 0 1 3000 37 400KW 60 08 Deceleration Time is given respectively for the 1 stage speed up to 7 stage speeds These parameters only work in auto circulation running F305 F311 F317 F323 F329 F335 F341 Setting Range Multi Spee
12. Timing Control mainly refers to Timing of Free Stop and Timing Action of the corresponding output terminal E g F700 Selection of Free Stop Mode Setting Rang 0 Immedate fiee stop 1 Delayed fiee stop Mfr s Value 0 F701 Action Dehy Time of Free Stop and Output Terminal S Setting Range 0 0 60 0 Mfr s Vale 0 Selection of Free Stop Mode is only used for Free Stop mode of terminal control When selecting Immediate Free Stop delay time F701 will not work when delay time is 0 i e F701 0 it works as immediate free stop Delayed Free Stop means that inverter will not stop immediately upon receiving the signal of Free Stop but will wait for some time before implementing the command of Free Stop delay time is subject to F701 When F701 gt 0 delay time is valid and the corresponding output terminal will carry out its delay action or delay overturn as per this time Fan control mode O controlled by termperature F702 only valid for the l controlled by inverter s Mft s Value power 90 400kw power F702 0 Fan s run is controlled by the radiator Fun will be run if inverter s termperature is up to stated temperature F702 1 Fan will run when power is supplied to the inverter And fan will not stop until pwer off 9 3 Programmable Protection Function 9 3 1 Under Voltage Protection and Out Phase Protection F708 Function Selectio
13. defined as per ops Free Sto This terminal is connected to CM during running inverter mfr s value and P will realize free stop may also be OP6 Forward When this terminal is connected to CM inverter will run er sea other Function Command forward ae y Operation Reverse When this terminal is connected to CM inverter will modifying OP7 parameters Command reverse ops Fault Resetting Make this terminal connected to CM in fault state to reset inverter Commn Control Power r CM Port Soares ME Ground for 12 V power source and other control signal F1000 G 4 2 Coding Switch Ared two digit coding switch SW1 is available around inverter s control terminal block as shown in Fig 4 1 The function of coding switch is to select the input range O 5V O 10V of input Terminal V2 for voltage type analog signals and must be used together with Function Code F209 F209 is used to select the input channal of analog signals to be interpreted as 0 sel ect V2 Camel F209 1 Reserved 2 Sel ect I2 Channel Fig 4 1 Coding Switch Fig 4 2 shows how the coding switch of inverter selects the range of analog signals The black blocks in the diagram indicate the position of SW1 Select Channel V2 in the mode of analog signals speed control the different position of coding switch can be chosen O 5V or OG 10V Please note that coding switch can only be used in mode Fig 4 2 of analog signals speed control and signal of
14. external use as powersource for voltage control signal with ower Source e current limit below 20mA In case of analog signals speed control voltage signal is input from this terminal va Voltage Voltage Analog Voltage input range 0 5V or 0 10V grounding V3 When potentiometer is Control Signals Input Port used for speed control this terminal is connected to iput signals and grounding to V3 Cautious V2 and keypad potentiometer cannot be used at the same time N Grounding end of external control signal voltage control signal or cunent source vo Power soute control signal also 5V powersource ground of this inverter Ground j Guinent Input Port for Incase ofanalog signals speed control current signal is input fro mthis terminal Curent input 2 Control Gurrent Analog range 20mA grounding V3 if4 20mA input lower limit of analog signals input can Signals be adjusted through parameter setting 12V a a Power 12 1 5V grounding CM current for external use below 100mA Functi This terminal is connected to CM inverter will run by OP1 Ne Jogging Terminal jogging Jogging function of the terminal works both in Stop and Run states The function of OP2 i 2 e e Speed Multi Speed Normally these three terminals are defined to be three stage these Input OP3 Setti Control Terminal speed or seven stage speed transfer terminals and may ako terminals is OP4 mg Ontrof termina use them forother function control
15. for frequency meter connected to Terminal FM F420 means the minimum corresponding running frequency within the range OD 5V or OL 10V at FM s max output value When running frequency is greater than or equal to this preset frequency FM will have its max output When running frequency is smaller than this preset frequency FM will have its output voltage proportional to the 99 F1000 G running frequency E g if F421 0 F420 60Hz FM will have an output of SV when running frequency gt 60Hz if running frequency 30Hz then FM 2 5V F422 is used to compensate for FM s output error and compensation value shall be fixed based on the actual measuring F423 FM IM Output Parameter Selection Setting Range 0 0 10 0 Mfr s Value 2 0 F424 IM Output Compensation Setting Range O 120 Mfr s Value 100 F425 IM Output Range Selection Setting Range 0 0 20mA 1 4 20mA Mfr s Value 0 Setting Range 0 Output Frequency Display F426 FM Function Selection 1 Output Current Display Mfr s Value 0 Setting Range 0 Output Frequency Display F427 IM Function Selection Mfr s Value 1 1 Output Current Display Terminal IM will output O 20mA signal as per the changes of inverter s output current between IM and V3 F423 is used to rectify the display accuracy of FM IM s external ammeters with various measuring ranges If IM is externally connected to an ammeter with an inpu
16. s Function Selection 2 Braking during stop 3 Braking both before start amp during stop Initial Frequency of a F515 DC Braking 1 00 5 00 1 00 Vv F516 DC BrakingVoltage 00 60 10 M A ps 7 Braking Duration go 10 0 0 5 v S Before Starting z F518 Stop Braking Duration 0 00 10 0 0 5 v d F519 F524 Reserved F525 Selection Function of ognvalid 1 Valid 0 x Stalling Adjusting Stalling Adjusting F526 Function During O Invalid 1 Valid 0 x Accelerationion Stalling Adjusting F527 Function During O Invalid 1 Valid 0 x Running Stalling Adjusting F528 Function in During O Invalid 1 Valid 0 x Deceleration Stalling Adjusting F529 Function during O Invalid 1 Valid 0 x Stopping Fluctuation Removing F530 Time When Stalling 0 1 50 0 1 0 Vv Setting Starts z P 5 0S for 0 4 3 7KW ps31 Time for Stalling 5174500 30 08 for 551 30KW v Adjusting to Start 60 08 for 37 400KW Lower Frequency F532 Limit of Stalling F112 F111 5 00 Vv Settin SOM ps33 FimctuationRemoving o 50 0 1 0 v Time When Stalling 49 F1000 G on A gt 5 08 for 0 4 3 7KW F534 Quiting Time of Stalling 177 150 0 30 08 for 53 30KW v Adjusting 60 08 for 37 400KW Protection Time of F535 Stalling Adjusting 0 0 100 0 4 0 Vv F536 F560 Reserved F600 F660 Reserved Selection of Free 0 Immediate free stop ru Stop
17. s Value Mfr s Value 0 When there is any confusion with inverter s parameters manufacturer s default value should be restored just by setting F160 to 1 F160 shall have its value set to 0 automatically when restoring manufacturer s value is completed Restoring manufacturer s value will not work for the function code in the Change column of the Appendix 2 marked with O These function codes are properly preset before delivered Please do not change the parameter of these function codes mop an fo Ee Fig 5 3 Restoring Manufacturer s Values MI F1000 G i Running mode is fixed by basic Dion ie of seed gool ge ji i VI erati extra speed control start stop produced by keypad speed control terminal 1 OJ peration Control a viv control multi control analog 6 1 Parameters Setting F200 Start Control Setting Range 0 Keypad control 1 Terminal control 2 4 Reserved Mir s Value 0 Setting Range 0 No additional start function F201 Additional yi gen n Keypad ene Mfr s Value 0 Start Control 2 Terminal control 3 4 Reserved Keypad Control means that start command will be given by the RUN key on the keypad Terminal Control means that start command will be given by the defined RUN terminal F200 and F201 can be used in combination Inverter will be started by making the defined start term
18. therefore have the running frequency of 128 255 x50 25 10Hz 6 2 6 Computeror PLC Control F204 5 Compute or PLC control is adopted for inverters Function Code F900 F903 and F904 will 24 F1000 G be set as the address parity check and Baud rate of inverter respectively For the relevant data of computer and PLC please refer to user s manual and communication protocol 6 2 7 Multi Speed Control see next chapter 6 2 8 Example of Speed Control Selection If F200 0 F201 0 F202 0 F203 0 F204 3 F205 0 F206 2 then the operation control mode analog signals or potentiometer will control output frequency and the Run and Stop Reset keys on the keypad will control Run and Stop The direction will be given by the defined Forward Terminal and Reverse Terminal by electrical level If F413 13 OP6 will be Forward Terminal F414 14 OP7 will be Reverse Terminal The inverter will have forward corotation when OP6 is connected with CM and reverse corotation when OP7 is connected with CM OP6 and OP7 cannot be connected with CM at the same time peed ie nn running time ell speed on the status of 3 stage speed combination of the three terminals frequency and running icontrol ed ill be used for 7 stage speed control SE Per Setting ENE Mfr s Value F300 0 F306 1 de F312 0 F318 1 F324 0 Multi Speed Running Direction 0 Forward 1
19. 000 G0015S2B 25 F1000 G0185T3C 16 F1000 G1320T3D 90 F1000 G0015XS2B 2 5 F1000 G0220T3C 16 F1000 G1600T3D 120 F1000 G0022S2B 4 0 F1000 G0300T3C 25 F1000 G2000T3D 160 F1000 G0007T3B 1 5 F1000 G0370T3C 25 F1000 G2200T3D 240 F1000 G0015T3B 2 5 F1000 G0450T3C 35 F1000 G2500T3D 270 F1000 G0022T3B 2 5 F1000 G0550T3C 35 F1000 G2800T3D 270 F1000 G0037T3B 2 5 F1000 G0750T3C 60 F1000 G3150T3D 290 F1000 G0040T3B 2 5 F1000 G0900T3C 60 F1000 G3550T3D 325 F1000 G0055T3B 4 F1000 G1100T3C 90 F1000 G4000T3D 325 3 4 Overall Connection and Three Line Connection Refer to next figure for overall connection sketch for F1000 G series inverters Wiring mode is available for various terminals whereas not every terminal needs connection when applied ZZE ico gt IN IE i RuertopOQupt 0 GontolLopOput L Basic Wiring Diagram F1000 G Three Line Connection can fulfill start stop control by using parameter setting and termmal definition as indicated in the right Figure IfF200 1 F202 1 start stop command will be excuted by terminals respectively F409 6 OP2 is defined as running terminal HE F410 7 OP3 is defined as stop terminal When OP2 or OP3 are oo connected with CM terminal it will control inverter s start and stop respectively Take care that these two terminals cannot be connected to CM at the same time Three Line Connection
20. 103 Inverter s Power 0 400 400 0 TAS myers A power value F104 Reserved F105 Software Version No A Inverter s Input 0 Single phase roe Voltage Type 1 3 phase A p107 Output Voltage 10 100 100 x Proportion F1080 F110 Reserved F111 Max Frequency E113 400 0 50 00 x ive Limit 2 F112 Min Frequency Limit 0 500 F113 0 50 x e F113 Target Frequency F112 F111 10 00 x in st 5 08 for 0 4 3 7KW 2 F114 z Acceleration dap 3000 30 08 for 55 30KW x z me 60 08 for 37 400KW st A 5 08 for 0 4 3 7KW 5 F115 2 Deceleration 0 10 3000 30 08 for 5 5 30KW x z me 60 08 for 37 400KW i 5 08 for 0 4 3 7KW A nd F116 a Acceleration 010 3000 30 08 for 55 30KW x me 60 08 for 37 400KW nd e 5 08 for 0 4 3 7KW F117 Deceleration 9 19 3000 30 08 for 55 30KW x me 60 08 for 37 400KW F118 Turnover 15 000 400 0 50 00 x Frequency F119 Latent Frequency F112 F111 5 00 x Dead Time of Switch F120 Between Corotation 0 00 3000 0 0 x and Reverse F121 Stop Mode 0 Stop by deceleration 0 x Selection time _1 Free stop F122 Reserved 43 F1000 G 0 Invalid jogging 3 4 Reserved F123 Jogging Function function 1 x 1 Valid jogging function F124 Jogging Frequency F112 F111 5 00 v Jogging 5 08 for 0 4 3 7KW F125 Acceleration 0 1 3000 30 08 for 5 5 30KW Vv Time 60 08 for 37 400KW ed 5 08 for 0 4 3 7KW F126 ee Bik us 0 10 3000 30 08 fo
21. 230 Precision of Frequency Showing Hz Setting Range 0 010 2 00 Mfr s Value 0 01Hz The change gradient of frequency or speed can be changed by adjusting the value of F230 If F230 0 03 and inverter shows a rotate speed F131 1 then the rotate speed will be increased or decreased by one round each time when A W keys are pressed The corresponding frequency will then have a change of 0 03Hz each time Setting Range 0 Normal F231 Speed of Frequency Change 1 Slow 2 Fast Mfr s Value 0 In case of keypad speed control and terminal speed control pressA W keys or terminals UP and DOWN without releasing to control the change of frequency 6 2 Basic Modes of Speed Control With the help of Basic Speed Control Mode Additional Speed Control Mode Stop Mode Additional Stop Mode Start Mode Additional Start Mode Direction Giving Mode F200 F206 numerous various modes of speed control can be produced through free combination including mutual control by keypad and analog signal i e joint control by keypad and terminal block User may have more options for speed control through parameter setting based on his own requirements Hereunder are a few basic operation control modes and operation modes of joint control 6 2 1 Keypad Speed Control F204 0 Keypad speed control is the most basic mode of speed control Press Run to start inverter
22. Control 3 Analog speed control 4 Coding speed control 5 Upper computer control 0 No additional start HR function 5 F205 ao VEE 1 Keypad speed control 0 x P 2 Multi speed control m 3 Termina I speed control Aa F206 Direction Given og 5 0 x S F07 F208 Reserved 0 V2 channel F209 nn Eh i 1 Reserved 0 x o igna input hanne 2 12 channel 0 3 stage speed running F210 Mabie n 1 7 stage speed running 0 x Types a Qa 2 Auto circulating running a z 5 Selection of Stage Speed Under Auto F211 circulation Speed 207 7 x Control Selection of Times of F212 Auto irculation op 9999 0 x Speed Control Status After Auto 0 Stop F213 circulation Running 1 Run at the speed of 0 x Finished last stage F214 F229 Reserved Precision of F230 Frequency SMV 0 01 2 00 0 01 x Speed of Frequency 0 Normal Pal Change 1 Slow___2Fast li F232 F260 Reserved st F300 l Speed A O Forward 1 Reverse 0 Vv 2 Running Direction SE it Speed 5 08 for 04 3 7KW 5 5 F301 A on Ti 0 10 3000 30 0S for 5 50 30KW Vv z L cceleration Time 60 08 for 37 400KW eg 1 Speed 2a F302 Running F112 F111 5 00 v Frequency 45 F1000 G 1 Speed 5 08 for 0 4 3 7KW s prpWweIgBg poadS DINRIA F303 Running Ti 0 1 3000 30 08 for 5 5 30KW unnng Lime 60 08 for 37 400KW a 5 08 for 0 4 3 7KW F304 a a 0 10 3000 30 08 for 5 5 30KW eceleration
23. Mode 1 Delayed free stop a ki Action Delay Time F701 of Free Stop and 0 0 60 08 0 0 x Output Terminal Fan control mode O controlled by only valid for the termperature Ei power 90 400kw I controlled by 2 inverter s power F703 F707 Reserved F m Function Selection y z F708 of Under Voltage OInvalid 1 Valid Setting Value va Under Voltage Q F709 Protection Voltage 2000 400 Setting Value O 5 n Filtering Constant e F710 of Under voltage 0 00 60 0 Setting Value O 5 Function Selection F711 of Out phase O Invalid 1 Valid Setting Value O z Filtering Constant y 3 F712 of Out phase 0 0 60 0 Setting Value S F7130 F714 Reserved F715 Overload Duration O 100 08 Setting Value O 5 e Overload e gt F716 Coefficient 0 00 1 8 Setting Value O Overload ON 60 08 Ni n F717 Interruption A Setting Value O png verses Rated O0 10004 Setting Value o Current Current F719 Compensation 0 00 2 0 Setting Value O Coefficient Relative Overload F720 Value I 4 Setting Value O F721 F760 Reserved gt F800 LowerLimitof om 1023 20 v pu Analog Input E55 mi 323 Fso UpperLimitof o0 1023 1000 v eee Analog Input eo Ta F802 F805 Reserved F1000 G fade Analog Input og 100 0 v Compensation Corresponding Frequency of Lower 5 ERO Limit of Analog OU F111 0 2 x Signal 5 Relation Between 25 Analog Changes 0 Direct proportion ons F808 K 0 x aS and Output 1 Invers
24. Time 60 08 for 37 400KW F305 Speed Inter val 0 00 3000 0 0 nd F306 2 e ats 0 Forward Reverse 1 Running Direction nd 5 08 for 0 4 3 7KW F307 2 kwa 0 10 3000 30 08 for 5 30KW Acceleration Time 60 08 for 37 400KW nd F308 2 Speed F1120 F111 10 00 Running Frequency m 5 08 for 0 4 3 7KW F309 nn 0 17 3000 30 08 for 5 5 30KW unning l me 60 08 for 37 400KW a 5 08 for 0 4 3 7KW Bit a ken a 0 10 3000 30 08 for 5 5 30KW eceleration Time 60 08 for 37 400KW F311 2 SpeedInterval 0 0 3000 0 0 rd F312 a Sp ed i 0 Forward 1 Reverse 0 Running Direction r 5 08 for 0 4 3 7KW F313 F N m 0 10 3000 30 08 for 5 5 30KW cceleration Time 60 08 for 37 400KW 3 Speed F314 Running F112 F111 15 00 Frequency r 5 08 for 0 4 3 7KW F315 an 0 10 3000 30 08 for 5 30KW Running Time 60 08 for 37 400KW 5 08 for 0 4 3 7KW F316 nn a 0 10 3000 30 08 for 55 30KW eceleration Time 60 08 for 37 400KW F317 3 SpeedInterval 0 00 3000 0 0 th F318 2 Speed RE 0 Forward 1 Reverse I Running Direction th 5 08 for 0 4 3 7KW F319 ka at 0 10 3000 30 08 for 55 30KW cceleration Time 60 08 for 37 400KW th F320 Speed F1120 F111 20 00 Running Frequency th 5 0S for 0 4 3 7KW F321 ae 0 10 3000 30 08 for 55 30KW Running Time 60 08 for 37 400KW i 5 08 for 0 4 3 7KW F322 ki De 0 10 3000 30 08 f r5 5 30KW Deceleration Time 60 08 for 37 400KW F323 4 Speed Interval 0 00 3000 0 0 th F324 5 Speed 0 Forward I Revers
25. ad check drive ratio increase inverter s capacity igh supply voltage too high check if rated voltage is input DC load inertia too big A pi s O E add braking resistance optional Over Volta ge deceleration time too short 4 KS p pere os l increase deceleration time motor Inertia rise again Out Phase PA SAN check if power input is normal PE Protection out phase with input power check if parameter setting is correct E F PO Under Voltage input voltage on the low side A heck if supply voltage is normal Protection check if parameter setting is correct environment temperature too improve ventilation Radiator high radiator too dirty clean air inlet and outlet and radiator OF Overheat install place not good for install as required ventilation fan damaged change fan CB Contactor does Too low voltage of power network check the voltage not suck AC contactor damaged check the AC contactor Motor wrong wiring check input output and control line not wrong setting check parameter setting l Running too heavy load increase inverter s output capacity Power Line Current short circuit at input side iS heck input line ee Trips Too Big too small capacity with check air switch capacity p 8 switch motor overload reduce load No P F protection for single phase and three phase under 3 7KW C B protection only for cabinet type inverters from 110KW to 400KW Table 1 2 M
26. alfunction Motor Malfunction and Counter Measures Items to Be Checked Counter Measures Motor not Running Wrong Direction of Motor Running Supply voltage is on or normal Normal with U V W 3 phase output Locked rotor with motor Panel with trouble indication U V W wiring correct Get connected with power Check wiring Disconnect and Reconnect Reduce load Check against Table 1 1 To correct wiring 42 F1000 G Motor Turning but Speed Change not Possible Wiring correct for lines with given frequency Correct setting of running mode Too big with load To correct wiring To correct setting Reduce load Motor Speed Too High or Too Low Motor s rated value corrrect Drive ratio correct Max output frequency value correct Check if voltage between motor terminals too high Check motor nameplate data Check speed change mechanism Check setting Check V F Characteristic value Motor Running Too big load Too big with load change Reduce load reduce load change increase capacity Unstable Single phase or 3 phase for power Out phase Reactor to be added for single phase power input Appendix 2 Zoom Table of Function Code Function Function Function ki a Section Code Definition Setting Range Mfr s Value Change F100 User s Password Og 9999 8 Vv F101 F102 Reserved F
27. alue or fault code 4LBDs indicate working status RUN s lighting while running FWD s lighting when working forward and FRQ s lighting when showing frequency Press Mode for function code and set for original parameters A andY keys can be used to select function codes and parameters G a Press set again to confirm In the mode of keypad control A and p VY keys can also be used for dynamic speed control Run and AN We e Min Max Stop Reset keys control start and stop Press Stop Reset key to Operation Panel eset inverter in fault status Potentiometer can be used for manual speed control in mode o analog signals control External potentiometer or external analog signal can also be used LED shows mnning frequency flashing target frequency function code parameter value or fault code 4LBDs indicate working status RUN is lighting while running FWD is lighting when working forward and FRQ is lighting when showing frequency ress Mode for function code and set for original parameters A andY keys can be used to select function codes and parameters Press set again to confirm In the mode of keypad control A and hue a Rm VY keys can also be used for dynamic speed control Run and Stop Reset keys control start and stop Press Stop Reset key to TE in fault status Operation Pa
28. as 8 Acceleration Deceleration 9 10 19 22 Function Reserved Forbidden terminal F1000 G Run Stop and Reset terminal singals are all pulse signals and are not restricted by the types of signals F400 F407 If Acceleration Deceleration Forbidden terminals is connected with CM during acceleration deceleration inverter will stop acceleration deceleration and maintain its current running frequency if this terminal is disconnected from CM acceleration deceleration will continue This function is only limited to keypad speed control terminal speed control and analog signal speed control Terminal UP is equivellent to A key on the keypad and Terminal DOWN to W key applicable for terminal speed control Forward terminal Reverse terminal and Direction terminal cannot be defined at the same time If the terminal of acceleration deceleration time switchover is connected with CM during acceleration deceleration inverter will start the second acceleration deceleration time If this terminal is disconnected from CM and the first acceleration deceleration time will be used This function is only restricted to keypad speed conotrol terminal speed control and analog signal speed control If receiving interruption signal input by the external interruption terminal during operation inverter will make an immediate stop of output and indicate
29. carrier wave frequency This inverter will automatically start random carier wave PWM control below 3KHz for purpose of reducing the noise at low carrier wave frequency Torque Compensation Curve and Carrier Wave Frequency should be well matched in actual application Torque compensation can be higher comparatively when there is a higher carrier wave frequency torque compensation can be lower comparatively when there is a lower carrier wave frequency However higher power inverter is not advisable to adopt a higher carrier wave frequency or higher torque compensation curve The following value range is recommended for F502 and F512 F502 3 8 F512 1000 6000 9 1 2 DC Braking Setting Range F514 DC Braking Function 4 ne et Selection 2 Braking during stopping 3 Braking before start amp during stop F515 Initial Frequency of DC Braking Hz Setting Range 1 00 5 00 Mfr s Value 1 00Hz F516 DC Braking Voltage V Setting Range O 60 Mfr s Value 10V F517 Braking Duration Before Starting S Setting Range 0 0 10 0 Mfr s Value 0 58 F518 Stop Braking Duration S Setting Range 0 0 10 0 Mfr s Value 0 58 In case where a blower fan is used adopting Hz Braking before Starting will ensure that the fan stays in a static state before starting Parameters related to DC Braking F515 545 F516 F517 and F518 interpreted as follows a F515 Initial fre
30. d Inter val S 0 1 3000 It is the interval that the speed of one stage is going to convert to the speed of next stage If it is 0 it indicates an immediate switchover Mfr s Value 0 0 7 2 Multi Speed Control and Joint Speed Control 7 2 1 Three Stage Speed Control F204 1 F210 0 Three Stage Speed are the three speeds properly preset inside the inverter their frequency value acceleration deceleration time can be modified through setting parameters Make the defined Three Stage Speed Terminal 1 Three Stage Speed Terminal 2 and Three Stage Speed Terminal 3 connected with CM then you can get F1000 G 1 stage 2 stage and 3 stage speeds The priority order for the three speeds goes from high to low speed and 3 stage speed The speed with a higher priority level may interrupt the one with a lower priority level e g when running at the 2 stage speed if three stage speed Terminal 1 is connected with CM inverter may interrupt the 2 stage speed and start the 1 stage speed Until the call signal for the 1 stage speed is canceled it will not return to the 2 d stage speed eg F409 0 Terminal OP2 is defined as 3 Stage Speed Terminal 1 and connected with CM which will execute 1 stage speed F410 1 Terminal OP3 is defined as 3 Stage Speed Terminal 2 and connected with CM which will execute 2 stage speed F411 2 Terminal OP4 is define
31. d as 3 Stage Speed Terminal 3 and connected with CM which will execute 3 stage speed 29 pi stage speed 2 stage 7 2 2 7 Stage Speed Control F204 1 F210 1 7 Stage Speeds are the seven speeds properly preset inside the inverter their frequency values acceleration deceleration time can be modified through parameters and gotten by the defined 7 stage Speed Terminal 1 7 stage Speed Terminal 2 and 7 stage Speed Terminal 3 The seven stages speed can be respectively gotten according to the state combination of making these three terminals connect or disconnect with CM F409 0 F410 1 F411 2 Terminals OP2 OP3 and OP4 will be defined as 7 stage Speed Terminal 1 7 stage Speed Terminal 2 and 7 stage Speed Terminal 3 respectively Refer to Table 7 1 for their combined transfer signal Table 7 1 Calling Modes of Seven Stage Speeds 7 stage Speed 0 0 0 0 1 1 1 1 Terminal 1 7 stage Speed Terminal 2 0 0 1 1 0 0 1 1 7 stage Speed 0 n 0 n 0 l 0 n Terminal 3 Transfer Speed Stop 1 stage stage 3 stage 4 stage 5 stage 6 stage 7 stage Note 1 indicates input signal terminal is connected with CM 0 shows input signal terminal is disconnected from CM 7 2 3 Coordinate Speed Control with Aanalog signal and 3 stage Speed 27 F1000 G F204 3 F205 2 F210 0 Analog signal speed control can be operated
32. e 0 Running Direction AG S Speed 5 08 for 0 4 3 7KW F325 Acceleration Ti 0 10 3000 30 08 for 5 5 30KW Vv cceleration Time 60 08 for 37 400KW Ep Speed F326 F1120 F111 25 00 Vv Running Frequency th 5 08 for 0 4 3 7KW F327 gt Speed 0 10 3000 30 08 for 5 50 30KW v Running Time 60 08 for 37 400KW th 5 08 for 0 4 3 7KW F328 2 m 0 10 3000 30 08 for 55 30KW v Deceleration Time 60 08 for 37 400KW F329 5 Speed Interval 0 0 3000 0 0 Vv th F330 ki Speed DER 0 Forward 1 Reverse 1 Vv Running Direction th 5 08 for 0 4 3 7KW z F331 x er en 0 10 3000 30 08 for 55 30KW v cceleration Time 60 08 for 37 400KW om F332 ER F1120 F111 30 00 v A Running Frequency Gi Speed 5 08 for 0 4 3 7KW 2 F333 S Ps a 0 10 3000 30 08 for 55 30KW v unmg MING 60 08 for 37 400KW D 5 th 5 08 for 0 4 3 7KW 5 F334 4 Do a 0 17 3000 30 08 for 5 30KW v 3 eceleration Time 60 08 for 37 400KW a F335 6 Speed Interval 0 0 3000 0 0 v th F336 7 op AA 0 Forward I Reverse 0 Vv Running Direction th 5 08 for 0 4 3 7KW F337 7 De 0 10 3000 30 08 for 55 30KW v Acceleration Time 60 08 for 37 400KW th F338 Mn F1120 F111 35 00 v Running Frequency th 5 08 for 0 4 3 7KW F339 ee ae 0 10 3000 30 08 for 55 30KW v Running Time 60 08 for 37 400KW th 5 08 for 0 4 3 7KW F340 La Ke fi 0 10 3000 30 08 for 5 5 30KW V ecele
33. e of F800 gradually until meeting the requirements c Parameter F806 is used for fine adjustment of inverter s running frequency Corresponding Frequency to the Lower Limit as the value of F807 is higher than Lower Frequency Limit F112 inverter will still keep running at a certain frequency even if a min analog value is input Analog Speed Control a As F808 0 direct ratio between input analog and output frequency i e O 5V or oD 10V or 0 20mA corresponds to O upper limiting frequency b As F808 1 inverse proportion between input analog quantity and output frequency i e 5 OV or 10 OV or 20 OmA corresponds to O upper limiting frequency 41 F1000 G Appendix I 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 Fault Description Inverter s Common Cases of Malfunctions Causes too short acceleration time Countermeasures prolong acceleration time whether motor cable is broken 0 C Overcurrent short circuit at output side check if motor overloads locked rotor with motor 3 reduce V F compensation value O L Overload load too heavy eee lo
34. e proportion va Frequency F809 F860 Reserved Inverter s Q F900 Address 00 254 1 x 3 F901 F902 Reserved 3 0 No checkout Fo03 Parity Check 194d 0 x m Selection 2 Even S E 0 1200 Baud Rate 1 2400 A F904 Selection 2 4800 x S 3 9600 F905 F960 Reserved Note x indicating that function code can only be modified in stop state V 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 51 F1000 G Appendix 3 Products amp Structures F1000 G series inverter has its power range between 0 4 110KW Refer to Tables 3 1 and3 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 3 1 Product Summary of F1000 G EN Brum esse GOE Remans F1000 G0004S2B 0 4 2 5 BO Self cooling Sa F1000 G0007S2B 0 75 4 5 BO Air Cooling E F1000 G0007XS2B 0 75 4 5 BO Air Cooling F F1000 GOO15S2B 1 5 7 B2 Air C
35. een two code groups when operating the A or W key e g when function code shows F111 DGT indicator will be on Press A W key function code will keep increasing or decreasing by degrees within F100 F160 press stop reset key again DGT indicator will be off When pressing A W key function codes will change circularly among the 9 code groups like F211 F311 F911 F111 Refer to Fig 2 2 The sparkling 10 00 is indicated the corresponding target frequency values Enter correct user s password currently showing1 00 J _DGT Off Digday EE oe On Fig 2 2 Swtich over ina Code Goup or between Different Code Goups F1000 G 2 5 Panel Display Table 2 4 Items and Remarks Displayed on the Panel Items Remarks This Item will be displayed when you press Mode in stopping status which indicates HF 0 jogging operation is valid HF LHF2 This Item will be displayed when you press Mode in running status And press Set to j display relevant contents HF 1 HF 2 HF 3 and HF 4 correspond to output HF 3 HF 4 current output voltage rotate speed and linear velocity respectively HF It stands for resetting process and will display 0 after reset O C O E O L O Fault code indicating over cunent over voltage over bad over heat under voltage for H P O
36. en Corotation and this holding waiting time can be terminated and inverter will immediately switch over to and run in another direction This function is fit for allmodes of speed 16 F1000 G control except auto circulating running This function can alleviate the current impact during direction switch process with manufacturer s setting value at OS F121 Stop Mode Setting Range 0 Stop at Deceleration Time 1 Free Stop Mfr s Value 0 Free Stop means that motor will have free running with an immediate output cutoff and stop by friction upon receiving the stop command This function can be used for stop operation in mode of keypad control and interrupting direction signal operation in mode of terminal control F123 Jogging Function Setting Range 0 Invalid jogging function 1 Valid jogging function Mfr s Value 1 F124 Jogging Frequency Hz Setting Range F112 F111 Mfr s Value 5 00Hz F125 Jogging AccekrationTime S Setting Range F126 Jogging DecekrationTime S 0 1 3000 Mfr s Value 0 4 3 7KW 5 0S 5 5 30K W 30 0S 37 400K W 60 0S It includes keypad jogging and terminal jogging Keypad jogging is only valid in stop state while terminal jogging works both in run and stop states Jogging operation on the keypad in stop state a Press Mode key to display HF 0 and press Set to confirm showing 0
37. for F1000 G Series Inverter Maintenance Cooling fan 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 regularly Replace inverter s cooling fan starting contactor relay regularly Check if all terminal wiring screws are fastened and if wirings are aging Special Warning Never touch high voltage terminals inside the inverter to avoid any electric shock 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 job is allowed Two forms and specifications of keypa d controllers are available or six key esides the function of stop and fault reset si key can also be used to switch over de in a gode group or between go Operation panel and monitor screen are both fixed on keypad controller Two kinds of controllers with and without potentiometer are available for F1000 G series inverters and each keypad controller has two kinds of size Refer to note for Fig2 1 2 1 Panel Illustration The panel covers three sections data display section status indicating section and keypad operating section as shown in Fig 2 1 LED shows mmning frequency flashing target frequency function code parameter v
38. g values of torque compensation curve Tunover Output may incur current impact during starting process and u fear Es 2 1 Torque Promotion Curve may further result in inverter s over current protection Asmaller torque compensation curve should be selected when inverter has a bigger power Carrier Wave Frequency should also be considered when selecting Torque Compensation Curve Normally compensation curve can be increased to a certain extent with a high carrier wave frequency l Mfr s Value Setting Range 0 4 3 7KW 1000 10000 0 41 3 7KW 1000 5 5 30KW 10007 9000 5 57 30K W 1000 370 110K W 1000 6000 37 110KW 1000 Motor will have a lower electromagnetic noise with a higher carrier wave frequency F512 Setting Carrier Wave Frequency But inverter will have its temperature increased and output torque decreaed Normally there will be significant reduction with motor noise when carrier wave frequency is higher than SKHz Carrier wave frequency can be set as 7000 for low power below 7 5KW inverters where mute running is required It is recommended that carrier wave frequency should not be set above 6KHz for a high power inverter F1000 G Recommended setting range for carrier wave frequency 1000 6000 On Torque Compensation and Carier Wave Frequency The output torque and carrier capacity of an inverter are closely related with Torque Compensation Curve and
39. ile wall 5 hanging type and cabinet type for metal 2 housing 3 i 1 K eypad Controler Good poly carbon materials are adopted rok through die stamping for plastic housing er sink Mounting Hole r Terminal with nice form good strength and T toughness Taking F1000 G0015XS2B for instance 1 MiiiasisAssAppearance of Plastic Housing F1000 G the external appearance and structure are shown as in Fig 1 3 Process of low sheen and silk screen printing are adopted on the housing surface with soft and pleasant gloss Meanwhile metal housing uses advanced exterior plastic sprayng and powder spraying process on the surface with elegant color Taking 1 Keypad Control Unit 2 Front Panel 3 Vent 4 Body 5 Control Terminal 6 Power Terminal F1000 G0220T3C for instance its appearance and structure are shown as in Fig 1 4 with detachable one side door hinge structure adopted for front cover convenient for wiring and maintenance 1 4 Technical Specifications Table1 1 Technical Specifications for F1000 G Series Inverters Items Contents 3 phase 380V 15 Input eee Range single phase 220V 15 Rated Frequency 50 60Hz Cait Rated Voltage Range 3 phase O 380V 3 phase 00 220V utpu Frequency Range 0 50 400 0Hz Control Mode Linear V F control space voltage vector random PWM Frequency Resolution Max 0 01Hz adjustment allowed Torque Promotion Torque P
40. inal connected to CM when using terminal control F202 Stop Control Setting Range 0 Keypad Control 1 Terminal Control Mfr s Value 0 2 4 Reserved Setting Range 0 No Additional stop function F203 Additional 1 Keypad control a Stop Control 2 Terminal control Mrs Value 0 3 4 Reserved Keypad Control means that stop command will be given by the Stop key on the keypad Terminal Control means that stop command will be given by the defined Stop terminal F202 and F203 can be used in combination Inverter will be stopped by making the defined stop terminal connected to CM when using terminal control A Setting Range 0 Keypad Speed Control 1 Multi speed Control gt Kr lt Basit ME 2 Terminal Speed Control 3 Analog Signal Speed Control y Speed Control 4 Coding Speed Control 5 Computer or PLC Control Value 0 F205 Additional Mode Setting Range 0 No Additional Speed Control Mode 1 Keypad Mfr s of Speed Control SpeedControl 2 Multi speed Control 3 Terminal Speed Control Value 0 Keypad Speed Control means that running frequency will be set with the A Y keys on the keypad Terminal Speed Control means that running frequency will be set with the defined UP DOWN terminals and Multi speed Control refers to three stage Speed Control Seven stage Speed Control and auto circulation s
41. minal respectively in the mode of pulse i e an instant connection between forward terminal and CM give forward signal and another instant connection between reverse terminal and CM will give reverse signal When F206 4 forward and reverse are given by the defined direction terminal in the mode of level i e connection between direction terminal and CM give reverse signal and forward signal is given when disconnected from CM When F206 5 forward and reverse are given by the defined direction terminal in the mode of pulse i e instant connection between direction terminal give forward signal instant connection for one more time give reverse signal When delivered by the manufacturer Terminal OP6 has the signal of forward and OP7 the signal of reverse Voltage analog signal 0 5V and OO 10V are input through V2 channel the different position of coding switch SW1 can be chosen O 5V or OO 10V Current input signal O 20mA is input through I2 channel with grounding of V3 F210 Multi Speed Setting Range 0 3 stage speed control 1 7 stage speed control Types 2 Auto circulation speed control MESYE In case of multi speed control F204 1 choice must be made from 3 stage speed control seven stage speed control or auto circulation speed control of which
42. minal Function Definition Setting Range 0 22 Mfr s Value F408 3 F409 0 F410 1 FANN 2 F412 5 F4130 13 F414 14 F415 4 Functions of Terminals OP 1 OP8 shall be defined separately Only one function code is available to define each terminal Table 8 1 Optional Functions of Definable Input Terminal F408 F415 Interpretation F408 F415 Interpretation 0 This terminal is defined as 11 This terminal is defined as terminal of 3 stage 7 stage speed terminal 1 UP frequency increase by degrees 1 This terminal is defined as 12 This terminal is defined as terminal of 3 stage 7 stage speed terminal 2 DOWN fiequency decrease by degrees This terminal is defined as This terminal is defined as 2 13 3 stage 7 stage speed terminal 3 Forward terminal 3 This terminal is defined as 14 This terminal is defined as jogging terminal Reverse terminal 4 This terminal is defined as 15 This terminal is defined as Reset terminal Direction terminal 5 This terminal is defined as Free 16 This terminal is defined as Accekration Stop terminal Devekration Time Switchover terminal 6 This terminal is defined as 17 This terminal is defined as External Run terminal Interruption terminal 7 This terminal is defined as 18 This terminal is defined as Coding Speed Stop terminal Control input terminal This terminal is defined
43. n of Under Voltage Setting Range O Invalid 1 Valid Mfr s Value Setting Value F709 Under Voltage Protected Voltage V Setting Range 200 400 Mfr s Value Setting Value F710 Filtering Constant of Under Voltage Setting Range 0 0 60 0 Mfr s Value Setting Value F711 Function Selection of Out phase Setting Range O Invalid 1 Valid Mis Value Setting Value F712 Filtering Constant of Out phase Setting Range 0 0 60 0 Mfr s Value Setting Value Under Voltage means too low voltage at AC input Out Phase means lack of phase of the input 3 phase power Filtering constant of Under Voltage Out Phase signals are used to remove F1000 G interference to avoid mis protection The greater the setting values are the longer the constants of filtering time and the better filtering effect 9 3 2 Overload Protection F715 Overload Duration S Setting Range 0 0 100 0 Mfr s Value Setting Value F716 Overload Coefficient Setting Range 0 0 1 8 Mfr s Value Setting Value F717 Overload Interruption Time S Setting Range 0 0 60 0 Mfr s Value Setting Value F718 Inverter s Rated Current A Setting Range 1 0 1000 Mfr s Value Setting Value F719 Current Compensation Coefficient Setting Range 0 0 2 0 Mfr s Value Setting Value F720 Relative Overload Value Setting Range I 4 Mfr s Value Setting Value Inverter will have ove
44. nel External Dimensions 52x 76 17 50 ig 2 ration Panels in Two Kinds Opening Dimensions 49x 73 O 68x 100x 17 O 65x 97 F1000 G 2 2 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 Mode Mode To call function code and switch over display mode Set To call and save data Up To increase data speed control or setting parameters Down To decrease data speed control or setting parameters To start inverter to call jogging operation to call auto circulating Run operation to switch over display mode dE Ike To stop inverter to reset in fault status to change function codes in a code group or between two code groups Stop or reset 2 3 Parameters Setting This mverter has numerous function parameters which the user can modify to effect different modes of operation control User needs to realize that 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 Default value at manufacturer for user s password is 8 Table 2 2 Steps for Parameters Setting Steps Keys Operation Display 1 Press Mode key to display function code Fog 2 Jor Ly Press Up or Down
45. nute F137 Frequency Memory Setting Range 0 Invalid frequency memory 1 Valid frequency memory Mfr s Value 0 Frequency memory will only automatically memorize the frequency values that user adjusts in mode of keypad or terminal speed control F138 Auto Start of Analg Signa Speed Setting Range O Autostait 1 Press Run to start Mfr s Value 0 F1000 G Auto start of analog signal speed control means in mode of analog signal speed control inverter will automatically run without the signals of RUN once analog signal is input F139 Auto Start After Power Resupplied or Reset Setting Range 0 Invalid 1 Valid Mfr s Value 0 Auto start after power resupplied or reset means whether there will be auto start after power resupplied or fault reset in the mode of keypad speed control or terminal speed control If invalid is selected inverter can only operate after Run signal is given F140 Start by the Terminal Direction Signal Setting Range 0 Invalid 1 Valid Mfi s Value 0 Start by Terminal Direction Signal means a direction signal given externally can be used to start inverter directly without giving a separate Run signal in case of keypad speed control terminal speed control or their combined speed control F160 Restore Mfr s Setting Range 0 Not Restoring Mfr s Value Value 1 Restoring Mfr
46. onnected to DC reactor Wiring for control loop as follows A The following sketch is the control terminals of inverters with single phase 0 4KW and 0 75KW our nv cuforfor OP3 OP4 OP5 OP6 OP7 OP8 V1 v2 v3 FM D TA TB TC B The following sketch is the control terminals for single phase 0 4KW 0 75KW built in braking cell 1 5KW and 1 5KW built in braking cell inveters A B OUT 12V CM OP1 0P2 OP3 OP4 OP5 OP6 OP7 OPS V1 V2 V3 R FM IM TA TB TC C The following sketch is the control terminals for single phase 2 2KW inveters OUT OPS OP6 OP7 12V OP1 OP2 OP3 D The following sketch is the control terminals for three phase 0 75 2 2KW inverters A B OUT 12V CM OP1 OP2 OP3 OP4 OP5 OP6 OP7 lors VI V2 V3 R FM TA TB TC E The following sketch is the control terminals for three phase 3 7 400KW inverters OP4 OP5 OP6 OP7 OP8 VI V2 V3 FM IM TA TB TC F1000 G 3 3 Wiring Recommended Table 3 2 Wiring for Power Loop Inverter Model me inverter ae Inverter ra Arami Model Ares mm Model Ares mm F1000 G000482B 1 5 F1000 G0075T3B 4 F1000 G1320T3C 90 F1000 G0007S2B 2 5 F1000 GO110T3C 6 0 F1000 G1600T3C 120 F1000 G0007XS2B 2 5 F1000 G0150T3C 10 F1000 G1100T3D 90 F1
47. ooling Eg F1000 G0015XS2B 1 5 7 B2 Air Cooling F1000 G0022S2B 2 2 10 B3 Air Cooling a F1000 G0007T3B 0 75 2 B2 Air Cooling F1000 G0015T3B 1 5 4 B2 Air Cooling F1000 G0022T3B 2 2 6 5 B2 Air Cooling z F1000 G0037T3B 3 7 8 B4 Air Cooling a F1000 G0040T3B 4 0 9 B4 Air Cooling Ga a F1000 G0055T3B 5 5 12 B5 Air Cooling 2 F1000 G0075T3B 7 5 17 B5 Air Cooling F1000 G0110T3C 11 23 Cl Air Cooling F1000 G0150T3C 15 32 C2 Air Cooling 3 F1000 G0185T3C 18 5 38 C3 Air Cooling 8 F1000 G0220T3C 22 44 C3 Air Cooling F1000 G0300T3C 30 60 C4 Air Cooling F1000 G0370T3C 37 75 C5 Air Cooling a F1000 G0450T3C 45 90 C5 Air Cooling F1000 G0550T3C 55 110 C6 Air Cooling F1000 G0750T3C 75 150 C6 Air Cooling Ga F1000 G0900T3C 90 180 C7 Air Cooling 52 F1000 G F1000 G1100T3C 110 220 C7 Air Cooling F1000 G1320T3C 132 265 C8 Air Cooling F1000 G1600T3C 160 320 C8 Air Cooling F1000 G1100T3D 110 220 DO Air Cooling F1000 G1320T3D 132 265 DI Air Cooling 3 F1000 G1600T3D 160 320 DI Air Cooling g F1000 G2000T3D 200 400 D2 Air Cooling 5 F1000 G2200T3D 220 440 D2 Air Cooling z F1000 G2500T3D 250 490 D3 Air Cooling F1000 G2800T3D 280 550 D3 Air Cooling S F1000 G3150T3D 315 620 D3 Air Cooling F1000 G3550T3D 355 700 D3 Air Cooling F1000 G4000T3D 400 800 D4 Air Cooling Note The X in the F1000 G0007XS2B and F1000 G0015XS2B is built in braking
48. peed control with reference to Parameter F210 Analog Signal Speed Control refers to the speed control by adopting anaolog signals of OO SV OO 10V or OO 20mA See F209 F1000 G Coding Speed Control refers to the running frequency given to the inverter by combinations of various switch statuses of Terminals OP 1 OP8 Setting Range 0 Lock corotation 1 Lock reverse F206 2 Given direction of forward and reverse terminals level Direction 3 Given direction of forward and reverse terminal pulse Mfr s Value 0 4 Given direction of direction terminal level Given 5 Given direction of direction terminal pulse When F206 0 or 1 running direction is decided internally not controlled by external signal If a terminal is defined as one to control direction then its signal form level or pulse shall only depend on Function Code F206 without being controlled by F400 F407 signal type of terminal F209 Selection of Analog Setting Range 0 V2 Channel 1 Reserved Signal Input Channel 2 12 Channel O 20mA MES Valdeso When F206 2 forward and reverse are set by the defined forward terminal and reverse terminal in the mode of level i e valid when connected to CM and invalid when disconnected and inverter will stop as well When F206 3 forward and reverse are given by the defined forward terminal and reverse ter
49. power source from network and PE E to earthing U V and W terminals to motor e Motor shall have to be ground connected e External braking cell may be considered for inverter with single phase input if load inertia is too large for the built in braking cell e _ For inverter with 3 phase input and power lower than 15kw braking cell is also built in If the load inertia is moderate it is Ok to only connect braking resistance with built in braking cell Q Q O Q fe ap O Q Q ert 380V braking resistance DC reactor as braking unit The figure is only sketch terminals order of practical products may be different 380V I F1000 G from the above mentioned figure Please pay attention when connecting wires Introduction of terminals of power loop Terminals Ne Terminal Function Description arking Power Input RST Input terminals of three phase 380V AC voltage R and Terminal ante T terminals for single phase Output U VW Inverter power output terminal connected to motor Terminal er PE E Inverter grounding terminal or connected to ground PB External braking resistor Note no Terminals P or B for inverter without built in braking unit DC bus line output externally connected to braking Braking resistor Terminal P N P connected to input terminal P of braking unit or terminal N connected to input terminal of braking unit N or terminal P P Externally c
50. put signal of other control equipment Analog signal are input through Terminal V2 potentiometer of keypad or Terminal 12 The input ports of analog signal are selected by F209 with three kinds of signals for analog input OQ 5V O 10V and OQ 20mA Input of O 5V and O 10V may also be obtained through external potentiometer the different position of coding switch SW1 can be chosen 0 5V or OO 10V e g F204 3 F209 0 voltage analog signal is input from Port V2 and grounding is V3 F204 3 F209 1 Reserved F204 3 F209 2 current analog signal 0 20mA is input from Port I2 and grounding is V3 6 2 5 Coding Speed Control F204 4 Eight bit binary digits data are indicated by the different combination of switching states of Terminals OP1 OP8 of which OP8 is the highest bit and OP1 the lowest bit It is prescribed that the terminal connected with CM gives I in binary digit and 0 in binary digit if disconnected from CM Eight bit binary digits input through OP1 OP8 are converted into digits of decimal system through CPU The value of decimal system is divided by 255 and multiplied inverter s upper limiting frequency Then we will have the actual output frequency of coding speed control E g Upper Limiting Frequency F111 50Hz Terminal OP8 and Terminal CM will be connected and the rest of terminals will be disconnected Enter binary digits 10000000 ie digits of decimal system 128 We will
51. quency of DC braking DC braking will start to work as inverter s output frequency is lower than this value b F516 DC braking voltage The bigger F517 F518 value will result in a quicker braking However motor will overheat with too big value Bied DC Braking c F517 Braking duration before starting The time lasted for DC braking before F1000 G inverter starts d F518 Braking duration when stopping The time lasted for DC braking while inverter stops Refer to Fig 9 2 for DC braking process 9 1 3 Stalling Adjusting F525 Selecting Function of Stalling Adjusting Setting Range O lnvalid 1 Valid Mfr s Value 0 F526 Stalling Adjusting Function during Acceleration Setting Range O Invalid 1 Valid Mfr s Value 0 F527 Stalling Adjusting Function during Running Setting Range O Invalid 1 Valid Mfr s Value 0 F52 Stalling Adjusting Function during Decekration Setting Range O Invalid 1 Valid Mfr s Value 0 F5 Stalling Adjusting Function during Stopping Setting Range O Invalid 1 Valid Mfr s Value 0 F530 Fluctuation Removing Time when Stalling Setting Starts S Setting Range 0 1 50 0 Mfr s Value 1 0 Mfr s Value F531 Time for Stalling Adjusting to 0 4 3 7KW 5 0S Start 9 Setting Range 0 1 150 0 5 50 30K W 30 0S 370 400K W 60 0S F532 Lower Frequency Limit of Stall Settng Hz Setting Range F112 F111 Mfr s Value 25 00 F533 Fl
52. r s Value 4 F133 Drive Ratio of Driven System Setting Range 0 10 200 0 Mfr s Value 1 00 F134 Range of Linear Velocity Setting Range 1 60000 Mfr s Value 1800 F131 0 running frequency Hz F131 1 theoretic rotate speed of shaft end of driven system rpm F131 2 theoretic linear velocity of shaft end of driven system F131 3 output voltage V F131 4 output current A No matter what values F131 is set corresponding target frequencies will be sparklingly showed on the panel when inverter is stopped Calculation on rotate speed and linear velocity When inverter operates at max frequency limit the setting value of F134 shall equal to the product of loaded rotate speed of shaft and its perimeter with unit subject to user E g max frequency limit F111 50 00Hz number of motor poles F132 4 drive ratio F133 1 00 radius of drive shaft R 50mm then Perimeter of drive shaft 2mr 2 X 3 14 X 50 314 mm Rotate speed of drive shaft 60X running frequency number of pole pairs X drive ratio 60x 50 2x 1 00 1500rpm shaft linear velocity rotate speed X perimeter 1500 x 314 471000 mm minute If calculation result exceeds the range of F134 1 60000 unit conversion will be required Should a precision of 0 1m min is needed F134 4710 can be set If a value of 1869 is indicated then it means that the current linear velocity is 1869 decimeter per mi
53. r 5 30KW v Deceleration Time 60 08 for 37 400KW F127 Skip Frequency A 0 00 400 0 0 00 x F128 Skip Area A 25 0 5 x F129 Skip Frequency B 0 00 400 0 0 00 x F130 Skip Area B 25 0 5 x 0 Frequency to 1Rotate speed D F131 Display Contents 2 Linear velocity 0 v ai 3 Output voltage B 4 Output current F132 NunberofMotor Poks 2 100 4 x 5 F133 Dive Ban 0 100 200 0 1 00 x Driven System a F134 Range ok 10 60000 1800 x a Velocity FI3S Reserved Figg rer Odnvalid 1 Valid 0 x Memory Auto Start of Analog 0 Auto start F138 Signals Speed I Press Run to start 0 x Control AUD Start ane O Invalid restart F139 Power Resupplied 0 x 1 Valid restart or Reset Start by the Terminal O Invalid F140 Direction Signal 1 Valid q FI41 F159 Reserved O Not restoring F160 Restore Mfr s Value ME JAG 0 x 1 Restoring Mfr s Value zi 0 Keypad command 5 F200 Start Control 1 Terminal command 0 x 5 2 3 4 Reserved z5 sw 0 No additional start Fa functi Gs unction 8 F201 len 1 Keypad command 0 x st Control z 2 Terminal command 44 F1000 G 0 Keypad Command F202 Stop Control 1 Terminal Command 0 x 2 3 4 Reserved 0 No additional start N function F203 totale 1 Keypad command 0 x Control 2 Terminal command 3 4 Reserved 0 Keypad speed control 1 Multi speed control F204 Basic Modes of 2 Terminal speed control 0 x Speed
54. ration Control iese se ee Re ER EG Re GR ee Re Gee ee ee ee ee 20 6 1 Parameters Setting iese sae eke GR ee GR Re ER ee ER eek ee Re 20 6 2 Basic Modes of Speed Control ee ke se ee ee Re ee 193 VII Multi Speed Control ese eke sk ek ER ER ee GR ee Re ee ee Re ee ee 26 7 1 Parameters Setting iese es ese Dee EER EE ES ee Ee EE E 26 7 2 Multi Speed Control and Coordinate Speed Control 26 VIII Terminal DefinitHOn ee ese ee es ee ek eke GR ee Re GR ee Re ee ee eed 30 8 1 Definable Input Terminal 0 ee ee ge ee eg Re ene ek ee 30 8 2 Definable Output Terminal eise se se ese ee ee Re eee Re ene es 31 8 3 Special Output Terminal iese es ee sk ek ee cece Re ek ee Re ee 32 IX V F Control and ProtecHON ees esse se ee sk ee ek ese ek ee Re ee ea ee 34 VA VEE Control iS REEDE ie eee GE 34 92 Timing Control era 38 9 3 Programmable Protection FUuncCtON iese esse ek ee ee ee ke ee 38 X Analog Input and Frequency Output eise ese eek es sk eek eek ee ed 41 Appendix I Trouble Shooting cesessesseeeneennnenn 42 Appendix2 Zoom Table of Function Code c 00 43 Appendix3 Products and Structure iese ese ee ee ee GR GR ER ER ee 52 F1000 G EEE IT i lower range 0 A 400K W 3 kind of 51809001 certified This manual offers a brief introduction of the installation connection for F100 G serie
55. ration Time 60 08 for 37 400kw ih F341 Deed 0 07 3000 0 0 v Interval F342 F360 Reserved OP1 terminal input 0 Level touch off a F400 signal type 1 Pulse touch off 0 x e F401 OP2 terminal input 0 Level touch off 0 x 5 a 5 signal type 1 Pulse touch off os 5 F402 OP3 terminal input er he 0 S 5 s signal type Pulse touch o F403 OP4 terminal input 0 Level touch off 0 s signal type 1 Pulse touch off A7 F1000 G F404 OPS terminal input 0 Level touch off 0 signal type 1 Pulse touch off OP6 terminal input 0 Level touch off F405 0 signal type 1 Pulse touch off OP7 terminal input O Leveltouch off F406 0 signal type 1 Pulse touch off F407 OP8 terminal input 0 Level touch off 0 signal type 1 Pulse touch off F408 Function 11 Up frequency increase 3 Setting ia eminal OP2 Function 0 37 speed terminal I F409 12 DOWN frequency 0 Setting vardjati e 1 3 7 speed terminal2 dseresse teminal OP3 Function oe wels ase temina F410 Settin 2 3 T speed terminal3 13 corotationterminal 1 F411 OP4 Function 3Jogging terminal 14 reverseterminal 5 Setting 4 reset terminal 15 direction terminal F412 OPS Function S free stop terminal 16 acce deceleration time 5 Setting 6 run terminal switch terminal 5 F413 7 stop terminal 17 external interruption 13 mie etting n OP Func
56. riod of time setting value of F530 If output current is higher than Initial Overload Current all the time during waiting time mverter will start F1000 G Stalling Adjusting Time to Remove Fluctuation when Stalling Adjusting Quits F533 when output current is lower than Initial Overload Current during stalling adjusting Stalling Adjusting will not stop immediately but wait for a certain period of time setting value of F533 If output current is lower than Initial Overload Current all the time during waiting time inverter will quit Stalling Adjusting function Lower Frequency Limit of Stalling Adjusting F532 Output Frequency will drop automatically during Stalling Adjusting till it reaches the Lower Frequency Limit of stalling adjusting eliminated Inverter will maintain this frequency should the stalling fail to be Protection Time of Stalling Adjusting F535 When Output Frequency drops to the Lower Frequency Limit of Stalling Adjusting during Stalling Adjusting and if stalling still continues after waiting for a certain period of time setting value of F535 inverter will enter Overload OL protection state This period of time shall be the protection time of Stalling Adjusting Action Time and Quiting Time of Stalling Adjusting F531 F534 In case of stalling the time of frequency A drop will be the acting time of Hz E30 1533 31 Bi
57. rload protection when output current is accumulated to the set overload accumulation value Overload Lasting Time the time from the moment when output current is greater than Initial Overload Current to the moment when Overload Protection occurs Overload coefficient the ratio of the current when overload protection occurs over the rated current The values to be taken shall be subject to the actual load Overload Interuption Time a d Initial Overload Current refers to the current starting to calculate the overload time Overload Ampere Second Value refers to the product of the current exceeding Initial Overload Current values and time The accumulation integral of overload ampere second value is called accumulated overload value Overload protection value is actually understood as currentxtime If output current remains higher than the value of Initial Overload Current then the system will accumulate the overload Ampere Second Value if output current suddenly drops below Initial Overload Current then overload Ampere Second Value will stop its accumulation If the current is still lower than Initial Overload Current after a certain period of time setting value of F717 then the accumulated overload value made before will be eliminated If output current exceeds again Initial Overload Current value during this time then Overload Ampere Second Value will be continuousl
58. romotion curve V F can be set V FContrto q within ID 16 Stall Prevention Current output is restricted and threshold current can be adjusted Overload Capacity 150 rated current I minute Potentiometer or external analog signal F Setti 00 5V OG 10V OD 20mA keypad requency Settin q y 8 terminal A V keys external control Operation logic and PLC setting Function Start Stop Control Passive contact switch control or keypad control Fre yc Rate 0 1 3000S time required for certain frequency change Protection Input out phase input under voltage DC over voltage over current over load current stall Function over heat external disturbance F1000 G LED nixie tube showing present output frequency present rotate speed rpm present output current present output voltage present linear velocity types of faults and Denby parameters for the system and operation LED indicators showing the current working status of inverter Equipment Location Free of tangy caustic gases or dust Environment Temperature 10 50 pi O O sop Conditions Environment Humidity Below 90 no water bead coagulation Vibration Strength Below 0 5g acceleration Height above sea level 1000m or below Applicabl PP ADEN 0 4 400KW Motor 1 5 Designed Standards for Implementation GB T 12668 2 2002 Stipulation of rated value of AC low voltage electric drive system GB 12668 3 2003 Standard for EMC and the
59. s Proper grounding wih grounding resistance hot exceeding 40 ensure good ventilation separate een coro Lo and power ao 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 Nameplate Taking for instance the F1000 G series 15KW OHFinverter HUIFENG ELECTRONICS CO LTD inverter with three phase input its nameplate my i MODEL F1000 GO220T3C _ maar is illustrated as Fig 1 1 INPUT AC 3PH 380V__50 60HZ 3Ph three phase input 380V 50 60Hz input OUTPUT SPH 22 KW 44A 0 36 OV 0 50 400 0 HZ voltage range and rated frequency 3Ph 3 phase output 32A 15KW rated output m INT In nn current and power 0 50 400 0Hz output frequency range MADE IN CHINA Fig 1 1 Nameplate Illustration 1 2 Model Illustration Taking the same instance of 15KW inverter with three phase its model illustration is shown as Fig 1 2 G 0150 T3 C Structure mode code C metal hanging B plastic housing D metal cabinet Power input T3 3 phase 380VAC input S2 single phase 220VAC input Applicable motor power 15KW Series code Manufacturer s name and upgrade code Don Fig 1 2 Product Model Illustration 1 3 Appearance The external structure of F1000 G series inverter is classified into plastic and metal housings Only wall hanging type is available for plastic housing wh
60. s After Auto circulation Setting Rang 0 Stop 1 Run at the ER Mfr s Value 0 Running Finished speed of last stage That the inverter runs at the preset stage speed one by one under the auto circulation speed control is called as one time If F212 0 inverter will run at infinite auto circulation which will be stopped by stop signal If F212 gt 0 inverter will have run at auto circulation conditionally When auto circulation of the preset times is finished continuously set by F212 inverter will finish auto circulation running conditionally If F213 0 then inverter will stop after auto circulation is finished If F213 1 then inverter will run at the speed of the last stage after auto circulation is finished as follows 0 inverter will run at infinite auto circulation F212 a F213 0 inverter will stop after auto circulation is finished F213 1 run at the speed of the last stage after auto circulation is finished F1000 G e g F211 3 then the inverter will run at auto circulation of 3 stage speed F212 100 then the inverter will run 100 times of auto circulation F213 1 the inverter will run at the Run at 3 stage speed speed of the last stage after the auto circulation running is finished Fig 6 1 Diagram of Auto circulation running The inverter can be stopped by pressing stop or sending stop signal through terminal during auto circulation running F
61. specific experimental methods GB 12668 5 security requirements relating to electric heat and other function 1 6 Precautions 1 6 1 Notice for Application Installation and application environment should be free of rain drips steam dust and oily dirt without corrosive or flammable gases or liquids metal particles or metal powder Environment temperature within the scope of 10 Q 50 C Inverter is installed in a control cabinet and smooth ventilation should be ensured Do not drop anything into the inverter Never touch the internal elements within 15 minutes after power off Wait till it is completely discharged Input terminals R S and T are connected to power supply of 380V while output terminals U V and W are connected to motor Proper grounding should be ensured with grounding resistance not exceeding 4Q separate grounding is required for motor and inverter No grounding with series connection is allowed No load switch is allowed 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 F1000 G 1 6 2 1 6 3 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
62. speed EE Switch control is input from external terminal When potentiometer of keypad is selected for the input voltage analog speed control coding switch must select 0 5V Keypad voltage analog signals and terminal voltage analog signals can not be entered at the same time 4 3 Main Functioins There are a total 14 kinds of speed control running modes with F1000 G series inverters covering jogging keypad terminal three stage speed seven stage speed auto circulating analog signal combination of keypad and terminals combination of three stage and seven stage speeds with terminal combination of three stage and seven stage with keypad combination of analog signals and three stage speed combination of analog signals and seven stage speed coding speed control and communication speed control All these must work with corresponding parameter setting as shown in Fig 4 3 F1000 G series inverters also have other efficient control functions like switchover of acceleration deceleration time acceleration deceleration forbidden state token output interruption control switchover of display contents etc Refer to Terminal Function Definition and Operation Panel 14 F1000 G Mode F408 F415 F400 F407 ermma Definition Direction Coding Speed Control Analog Speed Control gt Auto Circulating Speed Control Pe E204 2 i tro Se
63. speed can be obtained normally using it as the 1 stage speed e g F807 5Hz F409 0 OP2 is defined as 7 Stage Speed Terminal 1 F410 1 OP3 is defined as 7 Stage Speed Terminal 2 F411 2 OP4 is defined as 7 Stage Speed Terminal 3 then refer to Table 7 2 for selection of 8 Stage Speeds F1000 G Table 7 2 Methods on Effecting Eight Stage Speed Control Speed OP4 OP3 OP2 AocekrationTime DecekrationTime Hequercyofeachstage Direction Setting I stage 0 0 0 F114 F115 F807 Z stage 0 0 1 F301 F304 F302 sage 0 1 0 F307 F310 F308 4 stage 0 1 1 F313 F316 F314 a 5 stage 1 0 0 F319 F322 F320 6 stage 1 0 1 F325 F328 F326 T stage 1 1 0 F331 F334 F332 8 stage 1 1 1 F337 F340 F338 Note 1 indicates input signal terminal is connected with CM 0 shows input signal terminal is disconnected from CM 7 2 7 Auto Circulation Running F204 1 F210 2 Auto Circulating Running means auto circulating running at multi stage speed i e inverter will automacally change its stage speed and run at the acceleration deceleration time running time running frequency running direction of the speeds properly preset after giving Run command should Stop command fail to be given inverter will keep running in cycles as per the number of circulating times set by F212 Auto Circulation Running can be started by the Run ke
64. t of OJ 20mA and a measuring range of A and inverter has T for its output rated current then F423 can be set as A I and ammeter will have a correct indication of inverter s output current ie the motor current Note Manufacturer can only guarantee the correct output of IM when motor current is less than twice of inverter s rated current Single phase inverter has no this function F424 is used to compensate the output error of IM and compensation value shall be fixed based on the actual measuring se un un z a mete IX Control amp FE rie om EE oe ousi protection er er 9 1 V F Control 9 1 1 V F Compensation and Carrier Wave Frequency F500 Compensation of Setting Ri 00 8 Mfr s Value 0 Speed Difference NR a The load is higher The speed difference is larger Adjusting the parameter value will make motor s actual rotate speed close to the rated rotate speed F501 Torque Compensation Setting Range 0 Beeline type compersation 1 Reserved 2Resered Mfr s Value 0 2 Mfr s Value 0 4 3 7KW 5 F502 Beeline type Torque z bi i Setting Range 1 16 5 5 30KW 4 Compensation Curve 370 400KW 3 F503 Reserved There are altogether 16 beeline torque compensation curves which are used to increase the output torque at low frequency Compensation will be increased with bigger values as indicated in Fig 9 1 Over settin
65. ti 8 acce decel forbidden terminal D F414 MOGRON n 18 input terminal of 14 ze Setting terminal es OPET codingsped control F415 Function 9 10 190 22 Reserved 4 Setting 3 F416 Token Output of Relay 0 s F417 Token Output of 3 a Terminal OUT I OO 12 See Table 8 2 5 9 F418 Token Output of 3 la l Terminal OUT2 D Duty Ratio of Brake 5 F419 uty Ratio of Brake og 100 80 ae Signal a Lowest Frequency at g F420 Ee F112 400 0 50 00 Max FM IM FM Output Rai F421 Bee gt ee 0 00 5V 1 00 10V l0 Selection FM Out F422 kit og 12094 0 Compensation FM IM Output F423 ER 0 00 10 0 2 0 Parameter Selection F424 IM Output og 120 0 Compensation IM Output Range 0 00 20mA F425 0 Selection 1 4 20mA F426 FM Function 0 Output Frequency Display 0 Selection 1 Output Current Display F427 IM ad 0 Output Frequency Display 1 Selection 1 Output Current Display F428 F460 Reserved AS F1000 G Compensation of p309 Speed Difference as 8 0 Beeline type F501 compensation 0 x P 1 Reserved 2 Reserved Beeline type Torque 0 41 3 7K W 5 F502 Compensation Ig 16 5 5 30K WA x Curve 370 110KW 3 F503 F511 Reserved Setting 0 41 3 7KW 1000 10000 0 4 3 7KW 1000 F512 Carrier Wave 5 5 30K W 1000 9000 5 5 30KW 1000 x Frequency 37 10KW 1000 6000 370 400K W 1000 F513 Reserved 0 DC braking function forbidding F514 DC Braking 1 Braking before start 0
66. tion protection current c When sum of shaded area is more than overload protection value overload protection occurs F1000 G X Analog ipp I Lower and upper limits may change output Relation between analog change and i gun input compensation frequency may bring inut ae opa hagan am Eerie 1o genen Mwa j In analog speed control mode moderate adjustment is sometimes required for an ideal effect on the lower and upper limits of input analog the relation between analog changes and output frequency and the corresponding output frequency as min analog is input If F204 3 then select Analog Speed Control F800 Lower Limit of Analog Input Setting Range 0 1023 Mfr s Value 20 F801 Upper Limit of Analog Input Setting Range 0 1023 Mfr s Value 1000 F806 Analog Input Compensation Setting Range 0 100 Mfr s Value 0 F807 Corresponding Frequency of Lower Limit Setting Range O F111 Mfr s Value 0 of Analog Signal Hz F808 Relation Between Analog Setting Range 0 Direct proportion A Changesand Output Frequency 1 Inverse proportion Mfr s Value 0 Setting the Lower and Upper Limits of Analog a If analog reaches the max input but running frequency still fails to reach the upper limiting frequency then reduce the F801 value gradually until requirement is met b Incase of min input with analog while inverter cannot have its output drop to OHz then increase the valu
67. uctuation Removing Time when 5 7 Stalling Setting Quits S Setting Range 0 0 50 0 Mfr s Value 1 0 Mfr s Value F534 Quiting Time of Stalling 0 4 3 7KW 5 0S Adjusting 8 Setting Range 0 1 150 0 5 5 30KW 30 08 37 400K W 60 0S F535 Protection Time of Stalling Adjusting S Setting Range 0 1 100 0 Mfr s Value 4 0 When Stalling Adjusting function is valid inverter will adjust output frequency automatically restricting the output current within a certain range The frequency will therefore fluctuate within a smaller range Conditions for Stalling Adjusting when output current is higher than Initial Overload Current Stalling Adjusting starts to work Refer to Overload Protection for Initial Overload Current Fluctuation Removing the fluctuation of output current for a short time during stalling adjusting is considered fluctuation and is ignored which can increase the stability of output frequency The effect of fluctuation removing is subject to the time of removing fluctuation The longer it is the more stable with output However the effect of Stalling Adjusting wil be influenced Mfr s Value is normally adopted Time to Remove Fluctuation when Stalling Adjusting Starts F530 Stalling Adjusting will not happen immediately when inverter s output current exceeds the Initial Overload Current but will wait for a certain pe
68. ven stage Speed Control Mode o Speed Control By Multi Speed Control Three stage Speed Control Stop Signal go SE Aa Keypad Speed Contro Modes of Operation 4 3 Fi Running characteristics are set forth by compensation Running at parameters set by manufacturer is jeune A onn time jogging A e F100 User s Password Setting Range 0 9999 Mfr s Value 8 Correct user s password must be entered when power is supplied again or parameter modification is intended after fault resetting Otherwise parameter setting would not be possible with indicating Err1 User may modify User s Password in the same way as modifying other parameters F103 Inverter s Power kw Setting Range 0 40 400 0 Mfr s Value this inverter s power value This inverter is marked with power for recording product information F106 Inverter s Input Voltage Type Setting Range 0 single phase 1 three phase Mfr s Value Debugging Value F107 Output Voltage Proportion Setting Range 1 100 Mfr s Value 100 F111 Max Frequency limit Hz Setting Range F 113 400 0 Mfr s Value 50 00Hz Indicating inverter s max running frequency this inveter s max designed frequency 400 0Hz F112 Min Frequency Limit Hz Setting Range 0 50 F113 Mfr s Value 0 50Hz Showing inverter s min running frequenc
69. will automatically accelerating to the target frequency inverter After that it will stably run During its stable running the dynamic speed control can be realized by press A W keys Keypad speed control is the manufacturer s default mode of speed control 6 2 2 Terminal Speed Control F204 2 Terminal speed control is effected by Terminals UP and DOWN for dynamic speed F1000 G control the rest of which is the same as those of keypad speed control Terminals UP and DOWN are defined by F408 F415 Terminal UP works like A key on the keypad and Terminal DOWN like W key If F409 11 OP2 is defined as Terminal UP If connected with CM the frequency will increase If F410 12 OP3 is defined as Terminal DOWN If connected with CM the frequency will drop 6 2 3 Joint Speed Control with Keypad and Terminal F204 0 F205 3 Speed control is made with A W keys or UP DOWN terminals F409 11 OP2 is defined as UP terminal F410 12 OP3 is defined as DOWN terminal 6 2 4 Analog Signal Speed Control F204 3 Inverter s output frequency is regulated by voltage or current analog signal The voltage analog signal may be given by the potentiometer of the keypad controller or by the external potentiometer or by the analog signal output from other devices The current analog signal can be given by the corresponding sensors or the out
70. with the 3 stage Speed control in the meanwhile Priority level of 3 stage Speed control is higher than analog signal speed control 3 stage speed control can be implemented first if it has a valid signal of 3 stage speed in the mode of analog signal speed control 7 2 4 Coordinate Speed Control with Aanalog signal and 3 stage Speed F204 3 F205 2 F210 1 Analog signal speed control can be operated with the 7 stage Speed control in the meanwhile Priority level of 7 stage Speed control is higher than analog signal speed control 7 stage speed control can be implemented first if a valid signal of 7 stage speed is input in the mode of analog signal speed control 7 2 5 Coordinate Speed Control with 3 Stage or 7 Stage Speeds and Keypad or Terminal F204 1 F205 I or 3 F210 0 or 1 Adjustment will be made to the 3 Stage or 7 Stage Speeds by using the A W keys on the keypad or UP DOWN terminals 7 2 6 8 Stage Speed Control F204 3 F205 2 F210 1 F807 the running frequency for l stage speed of the 8 Stage Speed 8 Stage Speeds are realized by coordinate speed control of 7 Stage Speed control and analog signal speed control through special setting If the three stage speed terminals are all disconnected from CM the analog signal input is the lower limit value and corresponding frequency of lower limit of analog signal F807 is set as the required speed value then additional stage
71. y The value of min frequency limit must be set below F113 F113 Target Frequency Hz Setting Range F112 F111 Mfr s Value 10 00Hz Indicating the preset frequency Inverter will run automatically after startup to this frequency in keypad or terminal control mode F114 F116 1 and 2 Accekration Time S Setting Range ME SVOR OM A 7K W 5 0S PNG 5 50 30KW 30 0S F115 F117 1 and 2 Decekeration Time S 0 1 3000 370 400KW 60 08 Acceleration Deceleration Time The time required for acceleration deceleration from 0 50Hz to 50Hz 0 Nee F118 Turnover Frequency Hd Setting Range 15 00 400 0 Mfr s Value 50 00Hz Constant torque output when runn when exceeding this value Turnover Frequency normally adopts 50 ing frequency is below this value and constant power output Hz F119 Latent Frequency Hz Setting Range F112 F111 Mfr s Value 5 00Hz When output frequency exceeds this value the status of the output terminal may be defined as reverse the status of terminal will have its state restored when below this frequency When the definable output terminal is defined as the function of Over Latent Frequency this parameter sett ing Is valid FI20 Dead Time of Switch Between Corotation and Reverse S If Stop Reverse Setting Range 0 0 3000 Mfr s Value 0 0S signal is given within the Dead Time of Switch betwe
72. y accumulated on basis of the previous accumulation value Therefore the setting time of F717 is called Overload Interruption Time Current Compensation Coefficient a There may be some errors between the current value that inverter has obtained through galvanoscopy and the value actually measured Compensation can be made by setting F719 0 1 0 9 are negative compensation The current display will have a smaller F1000 G value with a smaller coefficient c 1 10 2 0 are positive compensation The current will display a bigger value with a bigger coefficient d F719 1 0 no compensation Relative Overload Value a This parameter indicates the difference value between overload protection current and Initial Overload Current adopting positive integer Relative Overload Value overload protection current initial overload current rated current 10 b E g overload coefficient 1 5 relative overload value 2 rated current 30A then the initial overload current value 1 5 0 2 x30 1 3x30 39A ie overload time is calculated from the moment when output current is 39A Diagram of Overload Protection Refer to Fig 9 4 for overload protection a Iy initial overload current lor overload protection current F717 in the frame shows overload interruption time b Sum of shaded area equals to the accumulated overload value overload protection value F715xoverload Fig 9 4 Overload Protec
73. y or the defined Run terminal and canceled by the Stop key on the keypad or the defined Stop terminal Auto Circulation Running may effect automatic circulating running at 2 stage 7 stage speeds set by F211 Inverter will automatically stop or maintain a steady running at the frequency of the last speed set by F213 after reaching the number of circulating times e g F211 7 select 7 stage speed auto circulating running F212 1000 auto circulating running for 1 000 times F213 0 automatically stop after circulating running is completed F300 F341 set the corresponding parametes of the 7 stage speeds F1000 G EE EE EF GEE H i i same lon cannot med for more none eee output terminals inal Two output terminak can be defined 8 1 Definable Input Terminal F400 F407 Terminal Input Signal Setting Range 0 Level triggering 1 Pulse triggering Mfr s Value 0 Define the input signal of Terminals OP1 OP8 respectively Electrical level triggering shall be valid when this terminal is connected with CM to input stable electrical level signal pulse triggering shall be valid when this terminal is instantly connected with CM to input pulse signal On the state of pulse triggering when pulse signal is input once port function is valid when pulse signal is input again port function is invalid F408 F415 Ter
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