e l e c t r o n i c Assembly and Commissioning Instructions AC Drive FUS .../L5/3L5 Quality is our Drive.
EC Declaration of Conformity The manufacturer / company placing the product on the market (authorized representatives of the manufacturer / companies placing the product on the market that are established within the Community) Name / Address: PETER electronic GmbH & Co. KG Bruckäcker 9 92348 Berg Germany hereby declares that the following product (device, component, unit) in the version as supplied Product designation: Frequency Inverter Serien / type designation: FUS .../L5; FUS ...
1T000.10001 (V03) 09/16 FUS .../L5/3L5 Chapter 0 Chapter 1 Chapter 2 Chapter 3 Chapter 4 Table of Contents Preface 0.1 Preface Safety Precautions 1.1 Before Power UP 1.2 During Power UP 1.3 Before Operation 1.4 During Operation 1.5 Inverter Disposal Part Number Definition 2.1 Model part number 2.2 Standard Product Specification Environment & Installation 3.1 Environment 3.2 Installation 3.2.1 Installation methods 3.2.2 Installation space 3.2.3 De-rating curve 3.3 Wiring guidelines 3.3.
Chapter 5 Chapter 6 Appendix 1 Appendix 2 Appendix 3 Appendix 4 Appendix 5 4.1.4 Example of Keypad Operation 4.1.5 Operation Control 4.2 Programmable Parameter Groups 4.3 Parameter Function Description Troubleshooting and Maintenance 5.1 Error Display and Corrective Action 5.1.1 Manual Reset and Auto-Reset 5.1.2 Keypad Operation Error Instruction 5.1.3 Special conditions 5.2 General troubleshooting 5.3 Troubleshooting of the inverter 5.3.1 Quick troubleshooting of the inverter 5.3.
0.1 Preface Chapter 0 Preface To extend the performance of the product and ensure personnel safety, please read this manual thoroughly before using the inverter. Should there be any problem in using the product that cannot be solved with the information provided in the manual, contact our technical or sales representative who will be willing to help you. ※Precautions The inverter is an electrical product.
Chapter 1 Safety Precautions 1.1 Before Power Up Danger Make sure the main circuit connections are correct. Single phase L1(L),L3(N), and Three phase L1(L),L2,L3(N); 400V : L1,L2,L3 are power-input terminals and must not be mistaken for T1,T2 and T3. Otherwise, inverter damage can result. Caution The line voltage applied must comply with the inverter’s specified input voltage.(See the nameplate) To avoid the front cover from disengaging, or other damge do not carry the inverter by its covers.
1.2 During Power Up Danger When the momentary power loss is longer than 2 seconds, the inverter will not have sufficient stored power for its control circuit. Therefore, when the power is re-applied, the run operation of the inverter will be based on the setup of following parameters: Run parameters. 00-02 or 00-03. Direct run on power up. Parameter. 07-04 and the status of external run switch, Note-: the start operation will be regardless of the settings for parameters 07-00/07-01/07-02. Danger.
1.4 During Operation Danger Do not connect or disconnect the motor during operation. Otherwise, It may cause the inverter to trip or damage the unit. Danger To avoid electric shock, do not take the front cover off while power is on. The motor will restart automatically after stop when auto-restart function is enabled. In this case, care must be taken while working around the drive and associated equipment . The operation of the stop switch is different than that of the emergency stop switch.
Chapter 2 Part Number Definition 2.1 Model part number FUS...L5/3L5 Supply voltage 1:100V Class 2:200V Class 4:400V Class Internal Voltage Blank : +12V Series A : +24V Series Horsepower 100V Class P2: 0.25 HP P5: 0.5 HP 01: 0.75 HP 200V Class P2: P5: 01: 02: 03: 400V Class 01: 1HP 02: 2HP 03: 3HP 0.25 HP 0.
2.2 Standard Product Specification Model FUS 020/L5 FUS 037/L5 FUS 075/L5 FUS 150/L5 FUS 220/L5 FUS 075/3L5 FUS 150/3L5 FUS 220/3L5 Supply Voltage (VAC) 1-ph.,200~240V +10 %/-15 % 3-ph., 380~480V +10 %/-15 % Frequency (Hz) 50/60 Hz 50/60 Hz Filter Model (HP) (kW) 0,25 0,5 1 2 3 1 2 3 0,2 0,4 0,75 1,5 2,2 0,75 1,5 2,2 NPN PNP Built-in ◎ ◎ ◎ ◎ ◎ ◎ ◎ ◎ ◎ ◎ ◎ ◎ ◎ ◎ ◎ ◎ Suitable for use on a circuit capable of delivering not more than 5,000 rms symmetrical amperes, 120/240 volts maximum.
Chapter 3 Environment & Installation 3.
3.2 Installation 3.2.1 Installation methods Frame1. Mounting on a flat surface. Screw: M4 Din rail type installation: Din rail kit includes a plastic and a metal adaptor plates. Assembly Steps:1) Attach the metal adaptor plate to the inverter base with the screws provided. 2) Attach the plastic Din rail adaptor to the metal adaptor plate. 3) Push the plastic adaptor forward to lock into position. Disassembly Steps:1) Unlock by pushing the snap hooks 2) Retract and remove the plastic Din rail adaptor.
Frame 2. Mounting on a flat surface. Screw: M4 Din rail type installation: Din rail kit includes a plastic adaptor plate as an attachment for the inverter base. Refer to Diagram below:- Disassembly:- Assembly:- Plastic Adaptor plate Snap hook Middle Snap hook Din Rail Mounting & Dismounting as shown in the diagram below:-Use a 35mm Din Rail. Dismounting Mounting Note: 29000.2T011 (Din rail kit part number), including the following parts 1. Metal plate adaptor 2. Plastic adaptor 3.
3.2.2 Installation space Provide sufficient air circulation space for cooling as shown in examples below. Install the Inverter on surfaces that provide good heat dissipation. Single unit Installation Install the inverter verticality to obtain effective cooling. Frames1 & 2.
3.2.3 De-rating curve Curves below show the applicable output current de-rate due to setting of carrier frequency and the ambient operating temperatures of 40 and 50 degree C.
3.3 Wiring Guidelines 3.3.1 Power Cables. Supply power cable must be connected to TM1 terminal block, terminals L1(L) and L3(N) for single phase 200V supply, L1(L), L2, L3(N) for three phase 200V supply and L1, L2, L3 for three phase 400V supply. Motor cable must be connected to TM1 terminals. T1, T2, T3. Warning:- Connection of Supply line cable to terminals T1,T2& T3 will result in serious damage to the drive components. Example power connections:- Inverter with dedicated power line.
3.3.2 Control Cable selection and Wiring. Control cables should be connected to terminal block TM2. Choose power & Control cables according to the following criteria: Use copper wires with correct diameter and temperature rating of 60/75°C. Minimum cable voltage rating for 200V type inverters should be 300VAC. Route all cables away from other high voltage or high current power lines to reduce interference effects.
3.3.3 Wiring and EMC guidelines. For effective interference suppression, do not route power and control cables in the same conduit or trucking. To prevent radiated noise, motor cable should be put in a metal conduit. Alternatively an armored or shielded type motor cable should be used. For effective suppression of noise emissions the cable armor or shield must be grounded at both ends to the motor and the inverter ground. These connections should be as short as possible.
3.3.4 Failure liability Teco bears no responsibility for any failures or damaged caused to the inverter if the recommendations in this instruction manual have not been followed specifically points listed below, If a correctly rated Fuse or Circuit breaker has not been installed between the power source and the inverter. If a magnetic contactor, a phase capacitor, burst absorber and LC or RC circuits have been connected between the inverter and the motor.
3.3.5 Considerations for peripheral equipment Power Circuit Breaker & RCD Magnetic contactor Ensure that the supply voltage is correct. A molded-case circuit breaker or fused disconnect must be installed between the AC source and the inverter Use a molded-case circuit breaker that conforms to the rated voltage and current of the inverter. Do not use the circuit breaker as the run/stop switch for the inverter.
3.3.6 Ground connection Inverter Ground terminal must be connected to installation ground correctly and according to the required local wiring regulations. Ground cable size must be according to the required local wiring regulations. Ground connection should be as short as possible. Do not share the ground of the inverter with other high current loads (Welding machine, high power motors). Ground each unit separately.
3.4 Specifications 3.4.1 Product Specifications 200V Class : Single phase. Model : FUS .../L5 Horse power (HP) Suitable motor capacity (KW) Rated output current (A) Rated capacity (KVA) Input voltage range(V) Allowable voltage fluctuation Output voltage range(V) Input current (A) Allowable momentary power loss time (S) Enclosure 400V Class : Three phase. Model : FUS ...
3.4.2 General Specifications Item Control Mode Range Setting resolution Frequency Setting Frequency limit Run Operation set V / F curve setting Carrier frequency Main Controls Acceleration and deceleration control Multifunction input Multifunction output Multifunction analog output Main features FUS .../L5/3L5 V/F Control + Auto-torque compensation function 0.01~650.00Hz Digital input : 0.01Hz Analog input : 0.
Display LED LED Status Indicator Overload Protection Over voltage Under voltage Momentary Power Loss Restart Protective Functions Stall Prevention Short-circuit output terminal Grounding Fault Additional protective functions International Certification Communication Environment Operating temperature Storage temperature Humidity Shock EMC Compliance LVD Compliance Electrical Safety Protection level Display: parameter/parameter value/frequency/line speed/DC voltage/output voltage/output current/PID
3.5 Standard wiring 3.5.
3.5.
3.5.
3.5.
3.6 Terminal Description 3.6.1 Description of main circuit terminals Terminal symbols L1(L) L2 L3(N) P* BR* T1 T2 T3 TM1 Function Description Main power input, L1(L)/L2/L3(N) externally connected braking resistor Inverter output, connect to U, V, W terminals of motor Ground terminal *P,BR for 400V series Single phase L1(L) L2 L3(N) T1 T2 T3 Note: the screw on L2 terminal is removed for the single phase input supply models.
3.6.2 Control circuit terminal description Terminal symbols RA RB COM +12V / +24V S1 S2 S3 S4 S5 10V AVI ACI AO AGND TM1 Function Description Relay output terminal, Specification: 250VAC/1A(30VDC/1A) S1~S5 (COMMON) 【NPN】 S1~S5 (COMMON) 【PNP】(+24V) Multi-function input terminals(refer to group3) Built in Power for an external speed potentiometer Analog voltage input, Specification : 0~10VDC/ 2-10V Analog current input, Specification : 0/4~20mA Multi function analog output terminal.
3.
Frame2 Unit : mm(inch) Model FUS 150/L5 FUS 220/L5 FUS 075/3L5 FUS 150/3L5 FUS 220/3L5 W W1 W2 H H1 H2 D D1 Weight 118 (4,65) 108 (4,25) 108 (4,25) 144 (5,67) 131 (5,16) 121 (4,76) 150 (5,92) 144 (5,68) 1,6 kg 3-22
3.8 EMC Filter Disconnection EMC filter may be disconnected: Inverter drives with built-in EMC filter are not suitable for connection to certain type of supply systems, such as listed below; in these cases the RFI filter can be disabled. In all such cases consult your local electrical standards requirements. IT type supply systems (ungrounded) & certain supply systems for medical equipment.
Chapter4 Software Index 4.1 Keypad Description 4.1.1 Operator Panel Functions Type Item Main digital displays Digital display & LEDs Variable Resistor LED Status FREQ SET Used to set the frequency RUN RUN: Run at the set frequency. STOP/RESET (Dual function keys) STOP: Decelerate or Coast to Stop. RESET: Use to Reset alarms or resettable faults. Increment parameter number and preset values. Decrement parameter number and preset values.
4.1.2 Digital display Description Alpha numerical display format LED LED Letter Digit 0 Letter A n LED Symbol ° 1 b o 2 C P _ 3 d q .
LED display examples Display Description In stop mode shows the set frequency In run mode shows the actual output frequency Selected Parameter Parameter Value Output Voltage Output Current in Amps DC Bus voltage Temperature PID feedback value Error display Analogue Current / Voltage ACID / AVI .
4.1.3 Digital display set up On power up digital display screens will be as shown below.
Example 2. Set parameter 2: 12- 00=【12345】 to obtain the display format shown below. MODE Temperature <4> PIDfeedback <5> MODE MODE MODE MODE 2sec later Output Current <1> Display: Power supply DC voltage <3> Output Voltage <2> Parameter MODE MODE Set Frequency Increment/ Decrement key functions: 1.“▲”/ “▼” : T1 Short time press Long time press T2 Quick pressing of these keys will Increment or Decrement the selected digit by one.
4.1.
Example2: Modifying the frequency from keypad in run and stop modes.
4.1.
4.2 Programmable Parameter Groups Parameter Group No. Description Group 00 Basic parameters Group 01 V/F Pattern selections & setup Group 02 Motor parameters Group 03 Multi function digital Inputs/Outputs Group 04 Analog signal inputs/ Analog output Group 05 Preset Frequency Selections.
Group 00- The basic parameters group No.
Group 01- V/F Pattern selection & Setup No. Description Range 01-00 Volts/Hz Patterns 01-01 V/F Max voltage 01-02 01-03 01-04 01-05 01-06 01-07 01-08 01-09 Max Frequency Max Frequency Voltage Ratio Mid Frequency 2 Mid Frequency Voltage Ratio 2 Mid Frequency 1 Mid Frequency Voltage Ratio 1 Min Frequency Min Frequency Voltage Ratio Volts/Hz Curve Modification (Torque Boost) V/F start Frequency 01-10 01-11 1~7 200V:198.0~256.0 400V:323.0~528.0 0.20 ~ 650.00 0.0 ~ 100.0 0.10 ~ 650.00 0.0 ~ 100.0 0.
Group 03- Multi function Digital Inputs/Outputs No. Description Range 03-00 Multifunction Input Term. S1 03-01 Multifunction Input Term. S2 03-02 03-03 Multifunction Input Term. S3 Multifunction Input Term. S4 03-04 Multifunction Input Term.
14:Brake Control Reserved 03-12 03-13 03-14 03-15 03-16 03-17 03-18 Output frequency detection level (Hz) Frequency Detection band Output Current Detection Level Output Current Detection Period External Brake Release level External Brake Engage Level 0.00~650.00 0.00 Hz *1 0.00~30.00 2.00 Hz *1 0.1~15.0 0.1 A 0.1~10.0 0.1 s 0.00~20.00 0.00 Hz 0.00~20.00 0.00 Hz 0 - 0:A (Normally open) 1:B (Normally close) ※ “NO” indicates normally open, “NC” indicates normally closed.
Group 05- Preset Frequency Selections. No.
Group 06- Auto Run(Auto Sequencer) function No. 06-00 06-01 06-02 06-03 06-04 06-05 06-06 06-07 06-08 ~ 06-15 06-16 06-17 06-18 06-19 06-20 06-21 06-22 06-23 06-24 ~ 06-31 06-32 06-33 Description Range Factory Setting Unit Auto Run (sequencer) mode selection 0: Disabled. 1: Single cycle. (Continues to run from the Unfinished step if restarted). 2: Periodic cycle. (Continues to run from the unfinished step if restarted). 3: Single cycle, then holds the speed Of final step to run.
Group 06- Auto Run(Auto Sequencer) function No. 06-34 06-35 06-36 06-37 06-38 06-39 Description Range Auto_ Run Mode running direction 2 Auto_ Run Mode running direction 3 Auto_ Run Mode running direction 4 Auto_ Run Mode running direction 5 Auto_ Run Mode running direction 6 Auto_ Run Mode running direction 7 Group 07- Start/Stop command setup No.
Group 08No.
Group 09- Communication function setup No. 09-00 09-01 Assigned Communication Station Number RTU code /ASCII code select 09-02 Baud Rate Setting (bps) 09-03 Stop Bit Selection 09-04 Parity Selection 09-05 09-06 09-07 09-08 09-09 Factory Setting Unit Note 1 - *2*3 0 - *2*3 2 bps *2*3 0 - *2*3 0 - *2*3 0 - *2*3 0.
Group10- PID function Setup Range Factory Setting Unit Note PID target value selection (when 00-05\00-06=6, this function is enabled) 0:Potentiometer on Keypad 1: Analog Signal Input. (AVI) 2: Analog Signal Input. (ACI) 3: Frequency set by communication 4: KeyPad Frequency parameter 10-02 1 - *1 10-01 PID feedback value selection 0:Potentiometer on Keypad 1: Analog Signal Input. (AVI) 2: Analog Signal Input. (ACI) 3: Frequency set by communication 2 - *1 10-02 PID Target (keypad input) 50.
Group11- Performance Control functions No. Description 11-00 Reverse operation control 11-01 Carrier Frequency (kHz) 11-02 Carrier mode Selection 11-03 11-04 11-05 11-06 11-07 11-08 11-09 11-10 11-11 Carrier Frequency Reduction by temperature rise S-Curve Acc 1 S-Curve Acc 2 S-Curve Dec 3 S-Curve Dec 4 Skip Frequency 1 Skip Frequency 2 Skip Frequency 3 Skip Frequency Bandwidth (±) Factory Setting unit 0 - 5 KHz 0 - 0 - 0.0 ~ 4.0 0.0 ~ 4.0 0.0 ~ 4.0 0.0 ~ 4.0 0.00 ~ 650.00 0.00 ~ 650.
Group12 Digital Display & Monitor functions No. Factory Setting Unit Note ----- - *4 Factory Setting unit Note ---- - - *3 ---- - - *3*4 ---- - - *3*4 0~23 - hour *3 ---- day *3 0 - *3 0 - 00000 - 00000 - Description Range S1 12-05 S2 S3 S4 S5 Inputs and output Logic status display ( S1 to S5) & RY1 RY1 Group 13 Inspection & Maintenance functions No.
4.3 Parameter Function Description 00- Basic parameter group 00- 01 Motor Direction Control 【0】: Forward Range 【1】: Reverse 00 - 01 Is valid in key pad mode only. ※Note: When Reverse function is disabled by parameter 11- 00=1 setting 00-01 to 1 .” LOC” will be displayed 00- 02 Main Run Command Source selection 00- 03 Alternative Run Command Source selection 【0】: Keypad Range 【1】: External Run/Stop Control 【2】: Communication Parameter 00 - 02/00- 03 sets the inverter operation command source.
00- 08 Communication Frequency Command Range 【0.00~650.00】Hz This parameter can be used to set frequency command This parameter can be used to read the set frequency in communication mode This parameter is only effective in the communication mode. 00- 09 Range 00-09= 00-09= 00-10 Range 00-11 Range Frequency Command save on power down (Communication mode) 【0】:disable 【1】:enable 【0】 Keypad frequency is saved. 【1】 Frequency set by communication is saved.
00-14 Acceleration time 1 Range 00-15 【0.1~3600.0】 s Deceleration time 1 Range 00-16 【0.1~3600.0】s Acceleration time 2 Range 00-17 【0.1~3600.0】s Deceleration time 2 Range 【0.1~3600.0】s Preset Acceleration and Deceleration times by above parameters are the time taken for the output frequency to ramp up or ramp down between the Upper and the lower frequency limits.
01-V/F command group Volts/Hz Patterns (V/F) 【1~7】 Range Set 01-00 to one of the following preset V/f selections 【1~6】according to the required application. Parameters 01-02~01-09 are not applicable. Six fixed V/f patterns are shown below.【1~3】for 50 Hz systems and 【4~6】for 60 Hz. 01- 00 Function TYPE 50Hz 01-00 60Hz V/F pattern 01-00 (V)% (V)% 100 General Use 100 =【1】 =【4】 B C B C 2.5 50 650 Hz 1 (V)% (V)% 100 100 =【5】 B C 3.0 50 650 Hz B C 1 2.
01- 01 Range 01- 02 v/f Maximum voltage 200:【198.0~256.0】V 400:【323.0~528.0】V Maximum Frequency Range 01- 03 【0.20 ~ 650.00】Hz Maximum Frequency Voltage Ratio Range 01- 04 【0.0 ~ 100.0】% Medium Frequency 2 Range 01- 05 【0.10 ~ 650.00】Hz Medium Frequency Voltage Ratio 2 Range 01- 06 【0.0 ~ 100.0】% Medium Frequency 1 Range 01- 07 【0.10 ~ 650.00】Hz Medium Frequency Voltage Ratio 1 Range 01- 08 【0.0 ~ 100.0】% Minimum Frequency Range 01- 09 【0.10 ~ 650.
01-11 V/F start Frequency Range 【0.00 ~10.00】Hz VF Start Frequency is for occasion where Start Frequency higher than zero Hz is needed. 02- Motor parameter group 02- 00 Motor no load current Range 02- 01 ---Motor Rated Current Range 02- 02 ---Motor rated Slip Compensation Range 02- 03 【0.0 ~ 100.
【1】:Reverse/Stop Command---------------------(Parameters 00-02/00-03=1 & 00-04) 【2】:Preset Speed 1 (5- 02)--------------------- (Parameter Group5) 【3】:Preset Speed 2 (5- 03)----------------------(Parameter Group5) 【4】:Preset Speed 4 (5- 05) ---------------------(Parameter Group5) 【6】:JOG Forward Command-------------------(Parameters 00-18~00-20) 【7】:JOG Reverse Command------------------ (Parameters 00-18~00-20) 【8】:Up Command------------------------------- (Parameters 00- 05/00- 06=4& 03-06/03-07) 【9】:Down
2-wire method. Mode 2. Example: RUN/STOP and REV/FWD from two inputs ( S1&S2) Set 00- 04=【1】; S1: 03- 00=【0】(RUN/STOP); S2:03- 01=【1】(REV/FWD); S1( RUN /STOP) S2( REV/FWD) COM Hz FWD T REV S1 ON S2 OFF OFF ON 3-wire method. Example:- Two separate push buttons for RUN & STOP and a two position switch for FWD/ REV Set 00- 04 =2.( 3 wire control mode), then terminals S1, S2 and S3 are dedicated to this function and Preset selections for parameters 03-00, 03-01 and 03-02.are not relevant.
2) Parameters 03- 00~03- 04=【4, 3, 2】Preset speed selections. Combination of any three terminals from S1~ S5 can be used to select preset speeds 0 to 7 according to the table below. Preset speed 0-7 and the related acceleration/decelerating times should be set in parameter group 5. For example timing diagram refer to Group 5 description.
Hz T RUN Command S1 STOP RUN OFF ON ON OFF 7) 03- 00~03- 04=【12】Main/ Alternative run source select. When an input terminal is set to function【12】and is turned on, the run command source is according to parameter 00-03(Alternative Run source).If the Input is off it will be according to 00-02 ( Main run source).
Hz Actual output frequency △Hz △Hz T S1 ON ON ON ON S2 ON ON Mode 2:If UP or DOWN input terminals are turned on for more than 2Seconds, the original UP/DOWN mode is restored Output frequency Ramps up or down as long as the input is kept ON. As shown in the diagram below.
03- 08 Multifunction terminals S1~S5 scan time Range 【1~200】 1m s Multifunction input terminal On/Off periods will be scanned for the number of cycles according to the set value in parameter 03-08. If the signal status for On or off period is less than the set period it will be treated as noise. Scan period unit is 1ms. Use this parameter if unstable input signal is expected, however setting long scan time periods results in slower response times.
Example:Setting Freq. =30, and Frequency Detection Width (03-14) =5, Relay will be ON when output frequency reached 25Hz to 30Hz and Run Command is on (Allowable tolerance ±0.01). 4) 03-11=【3】RY1 will be ON when Setting Freq. and Output Frequency reached (03-13 +/- 03-14). Example: Frequency Detection Level (03-13) =30, and Frequency Detection Width (03-14) =5 cause Frequency Detection Range upper limit = 35, and Frequency Detection Range lower limit = 25. So RY1 will be on when Setting Freq.
5) 03-11=【4】. RY1 will be on while Output Freq. > Frequency Detection Level (03-13). 6) 03-11=【5】. RY1 will be on while Output Freq. < Frequency Detection Level (03-13). Output Current Detection Level Range 【0.1~15.0】 A 03-16 Output Current Detection Period Range 【0.1~10.0】Sec 03-11=【13】.RY1 will be on as soon as the output current value > Output current detection level (03-15). 03-15: Setting range (0.1~15.0 Amps) as required according to the rated motor current. 03-16: Setting range (0.1~10.
100% I load 03-15 Fixed T Value 100msec 03-16 03-11 ON 03-17 Brake Release Level 【0.00~20.00】 Hz Range 03-18 Brake Engage Level 【0.00~20.00】 Hz Range If 03-11 =【14】 In accelerating mode. RY1 will be ON as soon as the actual output frequency reaches the external Brake release level set in parameter 03-17. In decelerating mode, RY1 will be OFF as soon as the actual output frequency reaches the external Brake engage level set in parameter 03-18.
Timing diagram for 03-17 > 03-18 is shown below: 03- 19 Range Relay Output Status type 【0】:A (Normally open) 【1】:B (Normally close) 04- External analog signal input / output functions 04- 00 Range Analog Voltage & Current input selections AVI ACI 【0】:0~10V 0~20mA 【1】:0~10V 4~20mA 【2】:2~10V 0~20mA 【3】:2~10V 4~20mA Analog Input Scaling formulas:- AVI (0~10V), ACI (0~20mA) AV I(0~10V ) : F( H z ) = V ( v) (00 12) 10( v) ; ACI(0~20mA) : F( Hz ) = I(mA ) (00 12) 20(mA ) AVI (2~10V), A
04- 01 AVI signal verification Scan Time Range 04- 02 【1~200】1m s AVI Gain Range 04- 03 【0 ~ 1000】% AVI Bias Range 04- 04 【0~ 100】% AVI Bias Selection Range 04- 05 【0】: Positive 【1】: Negative AVI Slope Range 04- 06 【0】: Positive 【1】: Negative ACI signal verification Scan Time Range 04- 07 【1~200】1m sec ACIGain Range 04- 08 【0 ~ 1000】% ACI Bias Range 04- 09 【0 ~ 100】% ACI Bias Selection Range 04-10 【0】: Positive ACI Slope 【1】: Negative Range 【0】: Positive 【1】: Negative Set 04- 01 an
(2) Negative Bias type and effects of modifying Bias amount by parameter 04-03 and Slope type with parameter 04-05 are shown in Fig 3&4.
04-03 bias Hz 100% 60Hz b 37.5Hz 50% 30Hz 0% 0Hz Upper Frequency 5V 10V Hz 100% 60Hz 50% 30Hz 0% 0Hz V Figure 9 d 0V 5V 10V 04- 04 04- 05 V Figure 10 04- 02 04- 03 e 50% 20% 1 0 f 200% 20% 1 0 04- 04 04- 05 04- 02 04- 03 g 50% 50% 1 1 h 200% 0% 0 1 Hz Hz Upper Frequency 60Hz 60Hz g f 04-03 bias Upper Frequency c 37.5Hz a 0V 04-03 bias 18.26Hz -0% 0Hz 04-03 bias -0% e 1V 4V 10V V -50% -50% -100% -100% 1.
04-12 AO Gain Range 04-13 【0 ~ 1000】% AO Bias Range 04-14 【0 ~ 100】% AO Bias Selection Range 04-15 【0】: Positive AO Slope 【1】: Negative Range 【0】: Positive 【1】: Negative Select the Analog output type for the multifunction analog output on terminal (TM2) as required by parameter 04-11. Output format is 0-10V dc. The output voltage level can be scaled and modified by parameters 04-12 to 04-15 If necessary.
Range 【0.1 ~ 3600.0】s When 05- 00 =【0】Accel /Decl 1 or 2 set by parameters 00-14/00-15 or 00-16/00-17 apply to all speeds. When 05- 00 =【1】Individual Accel/Decel apply to each preset speed 0-7. Parameters 05-17 to 05-32.
Hz 05-03 05-02 FWD Preset speed2 05-01 Preset speed1 Preset speed0 a RUN command b RUN c d RUN STOP e STOP T f RUN STOP S2 OFF S3 ON OFF S4 OFF ON When the run command is On/Off, acceleration and deceleration times for each cycle can be calculated as below:- time unit is in seconds’. a= (0517)(05 01) (0518)(05 01) (0519)(05 02) (05 20)(05 02) ,b= ,c= ,d = …… 01 02 01 02 0102 01 02 Mode2 Example. Continuous run command.
06- Auto Run(Auto Sequencer) function 06- 00 Range Auto Run( sequencer) mode selection 【0】:Disabled 【1】:Single cycle (Continues to run from the unfinished step if restarted). 【2】:Periodic cycle. (Continues to run from the unfinished step if restarted). 【3】:Single cycle, then holds the speed of final step to run. (Continues to run from the unfinished step if restarted). 【4】:Single cycle. (Starts a new cycle if restarted). 【5】:Periodic cycle. (Starts a new cycle if restarted).
06- 37 06- 38 06- 39 Range Auto_ Run Mode Running Direction5 Auto_ Run Mode Running Direction6 Auto_ Run Mode Running Direction7 【0】: STOP 【1】: Forward 【2】: Reverse Auto Run sequencer mode has to be enabled by using one of the multifunctional inputs S1 to S5 and setting the relevant parameter 03-00 to 03-04 to selection【18】. Various Auto Run (sequencer) modes can be selected by parameter (06-00) as listed above.
Example 2. Periodic cycle Run. Mode: 06- 00=【2】or【5】 The inverter will repeat the same cycle periodically. All other Parameters are set same as Example 1. shown above. Hz 06-02 06-02 06-01 06-01 05-01 05-01 T 06-16 06-17 06-18 06-03 06-16 06-17 06-18 06-03 06-19 06-19 RUN Command RUN S1 to S5 auto Run enable ON Example 3. Auto_Run Mode for Single Cycle 06-00=【3 or 6】 The speed of final step will be held to run. Auto Run Mode.
Example 4&5 . Auto Run Mode 06-00=【1~3】. After a restart continues to run from the unfinished step. Auto Run Mode 06-00=【4~6】. After a restart, it will begin a new cycle. Output Frequency 06- 00 1~3 Run Command run stop 4~6 Run Command run stop run Output Frequency Output Frequency run begin a new cycle Continue running from unfinished step time time ACC/DEC time in Auto run mode will be according to the setting of 00-14/00-15 or 00-16/00-17. For Auto sequence 0.
07- 03 Reset Mode Setting 【0】:Enable Reset Only when Run Command is Off Range 【1】:Enable Reset when Run Command is On or Off 07-03=0 Once the inverter is detected a fault, please turn Run switch Off and then On again to perform reset, otherwise restarting will not be possible. 07- 04 Direct Running on Power Up 【0】:Enable Direct running after power up Range 【1】:Disable Direct running after power up 07- 05 Delay-ON Timer (Seconds) Range 【1.0~300.
08- 00 Range 08- 01 08- Protection function group Trip Prevention Selection 【xxxx0】:Enable Trip Prevention During Acceleration 【xxxx1】:Disable Trip Prevention During Acceleration 【xxx0x】:Enable Trip Prevention During Deceleration 【xxx1x】:Disable Trip Prevention During Deceleration 【xx0xx】:Enable Trip Prevention in Run Mode 【xx1xx】:Disable Trip Prevention in Run Mode 【x0xxx】:Enable over voltage Prevention in Run Mode 【x1xxx】:Disable over voltage Prevention in Run Mode Trip Prevention Level During Acceler
Minute 5.0 1.0 103 150 Current Precent (%) 08- 07 OH over heat Protection 【0】:Auto (Depends on heat sink temp.) 【1】:Operate while in RUN mode Range 【2】:Always Run 【3】:Disabled 08- 07=【0】: Cooling fan runs as the inverter detects temperature rise. 08- 07=【1】: Cooling fan runs while the inverter is running. 08- 07=【2】: Cooling fan runs continuously. 08- 07=【3】: Cooling fan is Disabled.
09- Communication function group 09- 00 Assigned Communication Station Number Range 【1 ~ 32】 09-00 sets the communication station number when there are more that one unit on the communication network. Up to 32 Slave units can be controlled from one master controller such as a PLC.
10-PID function Setup PID block diagram 1? 2 Target 10-00 Positive P(10-05) Negative I(10-06) + - + + I Limiter 3? 4 1? 3 10-03 2? 4 Feedback 10-01 D(10-07) I Reset + Offset (10-08 10-09) 10-03=0 or external terminal prohibit or stop Delay device (10-10) PID Limit Sleep /Wake Function PID Communication Read 2? 4 10-03 D 10-21 12-00, PID Feedback Display 1? 3 10-03 10-22 10- 00 PID target value selection 【0】:Potentiometer on Keypad 【1】:External AVI Analog Signal Input 【2】:External ACI
10- 03 Range PID operation selection 【0】: PID Function disabled 【1】: FWD Characteristic. 【2】: FWD Characteristic. 【3】: REV Characteristic. 【4】: REV Characteristic. Deviation is D-controlled Feedback is D-controlled Deviation is D-controlled Feedback is D-controlled 10- 03 =【1】. Deviation (target - detected value) is derivative controlled in unit time set in parameter 10-07. 10- 03 =【2】 Feedback (detected value) is derivative controlled in unit time set in parameter 10- 07.
Feedback Loss Detection Level 【0 ~ 100】 Range 10-12 is the level for signal loss. Error = (Set point – Feedback value). When the error is larger than the loss level setting, the feedback signal is considered lost. 10-13 Feedback Loss Detection Delay Time 【0.0 ~25.5】s Range 10-13:The minimum time delay before feedback signal loss is determined. 10-14 Integration Limit Value 【0 ~ 109】% Range 10-14: the Limiter to prevent the PID from saturating.
10-21 Max PID Feedback Level. 【0 ~ 999】 Range 10-22 Min PID Feedback Level. 【0 ~ 999】 Range Example: If 10-21=100 and 10-22=50 and the unit for the range from 0 to 999 will be defined with the parameters setting of 12-02 , actual feedback value variation range, will be scaled to 50 and 100 only for display, as Shown below.
11 Performance control functions 11- 00 Prevention of Reverse operation 【0】:Reverse command is enabled Range 【1】:Reverse command is disabled 11-00=1, the reverse command is disabled. 11- 01 Carrier Frequency Range 【1~16】KHz 11- 02 Carrier mode selection 【0】:Carrier mode0 3-phase PW M modulation Range 【1】:Carrier mode1 2-phase PW M modulation 【2】:Carrier mode2 2-phase randomized PW M modulation Mode 0: 3-phase PWM Modulation Three Output transistors on at the same time (Full Duty).
11- 04 11- 05 11- 06 11- 07 S-Curve Acc 1 S-Curve Acc 2 S-Curve Dec 3 S-Curve Dec 4 Range 【0.0 ~ 4.0】s Use S Curve parameters where a smooth acceleration or deceleration action is required, this will prevent possible damage to driven machines by sudden acceleration/deceleration. Actual output frequency S2 S3 S1 S4 T RUN command RUN Note: Regardless of the stall prevention period, actual acceleration and deceleration time =preset acceleration / deceleration time + S curve time.
12 Monitor function group 12- 00 Display Mode 0 0 0 0 0 MSD LSD 00000~77777 Each digit can be set from 0 to 7 as listed below. 【0】:Disable display 【1】:output Current Range 【2】:output Voltage 【3】:DC voltage 【4】:Temperature 【5】:PID feedback 【6】:AVI 【7】:ACI MSD= Most significant digit. LSD= Least significant digit. Note: MSD of parameter 12-00 sets the power on display, other digits set user selected displays.
Example 1: The following figure shows 12 - 05 display status, when S1, S3, S5 Inputs are ON and S2, S4 and RY1 are OFF. S1 S2 S3 S4 S5 Example 2: The following figure shows 12 - 05 display status when S2, S3, S4 inputs are ON and S1, S5 are OFF but RY1 is ON.
Range 13- 05 【0~65535】Days Accumulated Inverter Operation Time Mode 【0】:Power on time Range 【1】:Operation time When the operation time recorded in accumulator 1(Parameter 13-03) reaches 24 hours The recorded value in accumulator 2 parameter 13-04 changes to 1 day and the value in accumulator 1 is reset to 0000.
Password failed to lift
Chapter 5 Troubleshooting and maintenance 5.1 Error display and corrective action 5.1.1 Manual Reset and Auto-Reset Display -OV- Faults which can not be recovered manually content OH-C CtEr EPr COt Display OC-A Detection circuit malfunction Consult with the supplier Voltage too low when stopped 1. Power voltage too low 2. Pre-charge resistor or fuse burnt out. 3. Detection circuit malfunction 1.Check if the power voltage is correct 2. failed resistor or fuse 3.
OC-S Over current at start OV-C 1.Short circuit between the motor coil and the case 2.Short circuit between motor coil and ground 3.IGBT module damaged Excessive Voltage during operation/ deceleration 1.Deceleration time setting too short or excessive load inertia 2.Power voltage varies widely (fluctuates) Input phase Loss Abnormal fluctuations in the main circuit voltage PF 1.Inspect the motor 2.Inspect the wiring 3.Consult with the supplier 1.Set a longer deceleration time 2.
Display Err2 content Parameter setting error Err5 Modification of parameter is not available in communication Err6 Communication failed Err7 Parameter conflict 5.1.3 Special conditions Display StP0 StP1 StP2 E.S. b.b. PdEr Cause 1.00-13 is within the range of (11-08 ±11-11) or (11-09 ±11-11) or (11-10 ±11-11) 2.00- 12≦00-13 3.set 00-05 and 00-06 to be same value 4.when 01-00≠7 , modify parameter 01-01~01-09 Corrective action 1.Control command sent during communication. 2.
5.2 General troubleshooting Status Checking point Is the wiring for the output Motor runs in terminals correct? wrong Is the wiring for forward and direction reverse signals correct? Is the wiring for the analog The motor frequency inputs correct? speed can Is the setting of operation mode not be correct? regulated.
5.3 Troubleshooting of the Inverter 5.3.1 Quick troubleshooting of the Inverter INV Fault Is fault known? NO YES Symptoms other than burn out, damage, or fuse meltdown in the inverter? NO Any Symptoms of burn out and damage? Check burnt and damaged parts NO Consult with the supplier NO Replace fuse NO YES Fault signal? YES Is the main circuit DM intact? YES NO YES Is the fuse intact? Check according to displayed fault messages YES Is the main circuit I.G.B.
From previous page Check Inverter parameters Perform parameter initializations Specify operation control mode Does the FWD or REV LED light flash? Replace the control board NO YES Set up frequency command Is the frequency value displayed on the display? NO Replace the control board NO Replace the control board YES Are there voltage outputs at terminals U, V and W YES Connect the motor to run Does the control Board function after replacement YES NO Is there any fault display? YES NO NO Are
5.3.2 Troubleshooting for OC, OL error displays The inverter displays OC, OL errors Is the main circuit I.G.B.T working NO Replace I.G.B.
5.3.
5.3.4 The motor can not run The motor can not run Is MCCB On? NO YES Can MCCB be turned On? NO Short circuited wiring NO 1.The power is abnormal 2.Incorrect wiring YES Are voltages between power terminals correct? YES Is LED lit? NO INVfault NO The operation switch is set to “RUN” position YES Is the operation switch in UN?? YES Are there outputs between the U,V, and W terminals of the motor? NO INVfault NO INVfault YES Are outputs between U,V,W the same? YES 1. Motor 2.
5.3.
5.3.6 Motor runs unbalanced Motor runs unevenly Does it happen during eceleration? YES Is the acceleration time correct? NO YES Are the output voltages between U-V,V-W,W-U balanced? NO NO Increase the Acc/ Dec time Reduce the load.Increase capacities of INV and the motor. INV faults YES Is the load fluctuating? YES Reduce the load fluctuation or add a flywheel.
5.4 Routine and periodic inspection To ensure stable and safe operations, check and maintain the inverter at regular intervals. Use the checklist below to carry out inspection. Disconnect power after approximately 5 minutes to make sure no voltage is present on the output terminals before any inspection or maintenance.
5.5 Maintenance To ensure long-term reliability, follow the instructions below to perform regular inspection. Turn the power off and wait for a minimum of 5 minutes before inspection to avoid potential shock hazard from the charge stored in high-capacity capacitors. 1. Maintenance Check List. Ensure that temperature and humidity around the inverters is as required in the instruction manual, installed away from any sources of heat and the correct ventilation is provided..
Chapter 6 Peripherals Components 6.1 Reactor Specifications Model: FUS ... 020/L5 037/L5 075/L5 150/L5 220/L5 075/3L5 150/3L5 220/3L5 Specification Inductance (mH) 7,0 4,2 2,1 1,1 0,71 15,22 9,21 6,73 Current (A) 3,0 5,2 9,4 19,0 25,0 2,3 3,8 5,2 6.2 Electromagnetic Contactor and No fuse circuit breaker Model: FUS ... 020/037/L5 075/150/L5 220/L5 075...220/3L5 Molded-case circuit breaker made by TECO TO-50E 15A TO-50E 20A TO-50E 30A TO-50E 15A Magnetic contactor made by TECO (MC) CN-11 6.
6.5 Braking Resistor. 400V range Our braking resistors have been especially developed for use in applications involving high moments of inertia that need to be brought to a standstill rapidly and in a controlled way. A dynamic braking resistor supports the inverter by converting excess energy from the motor into heat. For the braking resistor appropriate for your inverter, please contact us. ※Note: Braking resistor : W= ( Vpnb * Vpnb ) * ED% / Rmin 1. W: The power consumption of braking action 2.
Appendix I L5 parameters setting list Customer Inverter Model Using Site Contact Phone Address Parameter Code 00-00 Setting Content Parameter Code 03-04 Setting Content 00-01 03-05 Parameter Code 05-17 05-18 00-02 03-06 05-19 07-03 00-03 03-07 05-20 07-04 00-04 03-08 05-21 07-05 00-05 03-09 05-22 07-06 00-06 05-23 07-07 00-07 03-10 03-11 05-24 07-08 00-08 03-12 05-25 08-00 00-09 03-13 05-26 08-01 00-10 03-14 05-27 08-02 00-11 03-15 05-28 08-03 00-12 03-16
Parameter Code 10-13 Setting Content Parameter Code 11-02 Setting Content Parameter Code 12-03 10-14 11-03 12-04 10-15 11-04 12-05 10-16 11-05 13-00 10-17 11-06 13-01 10-18 11-07 13-02 10-19 11-08 13-03 10-20 11-09 13-04 10-21 10-22 11-00 11-01 11-11 12-00 12-01 12-02 13-05 13-06 13-07 13-08 App1-2 Setting Content Parameter Code Setting Content
Appendix-2 Instructions for UL Appendix-2 Instructions for UL ◆ Safety Precautions DANGER Electrical Shock Hazard Do not connect or disconnect wiring while the power is on. Failure to comply will result in death or serious injury. WARNING Electrical Shock Hazard Do not operate equipment with covers removed. Failure to comply could result in death or serious injury. The diagrams in this section may show drives without covers or safety shields to show details.
Appendix-2 Instructions for UL NOTICE Do not modify the drive circuitry. Failure to comply could result in damage to the drive and will void warranty. Teco is not responsible for any modification of the product made by the user. This product must not be modified. Check all the wiring to ensure that all connections are correct after installing the drive and connecting any other devices. Failure to comply could result in damage to the drive.
Appendix-2 Instructions for UL Recommended Input Fuse Selection Fuse Type Drive Model FUS ... Manufacturer: Bussmann Model Fuse Ampere Rating (A) 200 V Class Single-Phase Drives 020/L5 Bussmann 10CT 690 V, 10 A 037/L5 Bussmann 10CT/16CT 690 V, 10 A / 690 V, 16 A 075/L5 Bussmann 16CT/20CT 690 V, 16 A / 690 V, 20 A 150/L5 Bussmann 30FE 690 V, 30 A 220/L5 Bussmann 50FE 690 V, 50 A Fuse Type Drive Model FUS ...
Appendix-2 Instructions for UL ◆ Drive Motor Overload Protection Set parameter 02-01 (motor rated current) to the appropriate value to enable motor overload protection. The internal motor overload protection is UL listed and in accordance with the NEC and CEC.
Appendix 3: protocol FUS L5 MODBUS Communication 1. Communication Data Frame L5 series inverter can be controlled by a PC or other controller with the Communication protocol, Modbus ASCII Mode & Mode RTU, RS485 or RS232. Frame length maximum 80 bytes. 1.
MASTER(PLC etc.) send request to SLAVE, whereas response to SLAVE MASTER. Address The signal receiving is illustrated here. The data length is varied with the command(Function). Function Code DATA CRC CHECK Signal Interval ** The interval should be maintained at 10ms between command signal and request. 1.3 SLAVE(Address) 00H : Broadcast to all the drivers 01H : to the No.01 Drivers 0FH : to the No.15 Drivers 10H : to the No.16 Drivers and so on....,Max to 32(20H) 1.
2.2 CRC CHECK:CRC Check Code is calculated from SLAVE Address to end of the data. The calculation method is illustrated as follow: (1). Load a 16-bit register with FFFF hex (all’s1).Call this the CRC register. (2). Exclusive OR the first 8-bit byte of the message with the low-order byte of the 16-bit CRC register, putting the result in the CRC register. (3). Shift the CRC register one bit to the right (toward the LSB), Zero-filling the MSB, Extract and examines the LSB. (4).
3. Error code ASCII Mode STX RTU Mode SLAVE Address ‘:’ ‘0’ Address Function Exception code ‘1’ Function Exception code LRC Check 02H ‘8’ CRC-16 ‘6’ 83H 52H High C0H Low CDH ‘5’ ‘1’ ‘2’ ‘8’ ‘CR’ END ‘LF’ Under communication linking, the driver responses the Exception Code and send Function Code AND 80H to main system if there is error happened.
4. Inverter Control 4.1 Command Data (Readable and Writable) Register No.
4.2 Monitor Data (Only for reading) Register No.
Register No.
Register No.
4.3 Read the data in the holding register [03H] Master unit reads the contents of the holding register with the continuous number for the specified quantity. Note:1. Limit number of read data,RTU: 37,ASCII:17. 2. Can only Continuous read the address of the same Group 3. Read data Quantity≥1. (Example) Read the SLAVE station No:01 ,L510 drive’s frequency command.
4.4 LOOP BACK testing [08H] The function code checks communication between MASTER and SLAVE, the Instruction message is returned as a response message without being changed, Any values can be used for test codes or data.
4.5 Write holding register [06H] Specified data are written into the several specified holding registers from the Specified respectively. (Example)Set SLAVE station No:01, write L510 drive frequency reference 60.0HZ.
4.6 Write in several holding registers [10H] Specified data are written into the several specified holding registers from the Specified number respectively. Note:1. Limit number of read data,RTU: 35,ASCII:15. 2. Can only Continuous read the address of the same Group. 3. Read data Quantity≥1. (Example)Set SLAVE station No:01, L5 drive as forward run at frequency reference 60.0HZ.
Instruction Message RTU Mode Response Message (Normal) Response(Fault) SLAVE Address 01H SLAVE Address 01H SLAVE Address 01H Function Code 10H Function Code 10H Function Code 90H Error Code 52H Start Address High A0H High A0H 01H Start Address Low Low 01H Quantity High 00H Quantity High 00H Low 02H Low 02H DATA Number * First High DATA Low 04H High 32H Low 08H Next DATA CRC-16 00H CRC-16 01H High 17H Low High 70H 95H Low B0H * DATA Numbers are the actual nu
5. Comparison list between parameter and register Note: Parameter register No.: GGnnH, “GG”means Group number, “nn” means Parameter number for example: the address of Pr 08-03 is 0803H. the address of Pr 10-11 is 0A0BH Register Function Register Function Register No. Function No. No.
Register Function No. Group03 0300H 03-00 0301H 03-01 0302H 03-02 0303H 03-03 0304H 03-04 0305H 03-05 0306H 03-06 0307H 03-07 0308H 03-08 0309H 03-09 030AH 03-10 030BH 03-11 030CH 03-12 030DH 03-13 Register Function No. Group04 0400H 04-00 0401H 04-01 0402H 04-02 0403H 04-03 0404H 04-04 0405H 04-05 0406H 04-06 0407H 04-07 0408H 04-08 0409H 04-09 040AH 04-10 040BH 04-11 040CH 04-12 040DH 04-13 Register No.
Register Function No. Group06 0600H 06-00 0601H 06-01 0602H 06-02 0603H 06-03 0604H 06-04 0605H 06-05 0606H 06-06 0607H 06-07 Register Function No. Group07 0700H 07-00 0701H 07-01 0702H 07-02 0703H 07-03 0704H 07-04 0705H 07-05 0706H 07-06 0707H 07-07 Register No.
Register Function No. Group06 06-36 0624H 0625H 06-37 0626H 06-38 0627H 06-39 Function Register No. Group09 0900H 09-00 0901H 09-01 0902H 09-02 0903H 09-03 0904H 09-04 0905H 09-05 0906H 09-06 0907H 09-07 0908H 09-08 0909H 09-09 Register Function No. Group07 Register No. Register Function No. Group10 0A00H 10-00 0A01H 10-01 0A02H 10-02 0A03H 10-03 0A04H 10-04 0A05H 10-05 0A06H 10-06 0A07H 10-07 0A08H 10-08 Register No.
Register Function No. Group12 0C00H 12-00 0C01H 12-01 0C02H 12-02 0C03H 12-03 0C04H 12-04 0C05H 12-05 Register Function No. Group13 0D00H 13-00 0D01H 13-01 0D02H 13-02 0D03H 13-03 0D04H 13-04 0D05H 13-05 0D06H 13-06 0D07H 13-07 0D08H 13-08 App 3-18 Register No.
Appendix 4: RJ45-USB instruction manual 1. Model number and specification 1.1 Model number and function instruction RJ45-USB is a RS232 USB type to RS485 converter. It is used for communication between PC and inverter. 1.2 Dimensions 1.3 Connection between inverter and computer.
2. USB Interface Cable Pin Definition 2.1 RS232/USB at PC side RS485/RJ45 connector at inverter side 2.2 RS485/RJ45 Pin Definition Pin No. Pin 1 Pin 2 Pin 3 Pin 4 Pin 5 Pin 6 Pin 7 Pin 8 Define A B NC NC NC NC VCC GND Note: 1. A/B phase signal (Pin1&Pin2) is differential mode data signal of RS485. 2. VCC&GND is the +5Vdc power supply provided by inverter internal power source. 3. Notice 3-1. Please turn off the power before you connect the cable. 3-2.
Appendix 5: FUS L5 series accessories Option modules: Order nr. Profibus DP Gateway TCPIP Gateway DeviceNet Gateway CANopen Gateway 29000.2T001 29000.2T002 29000.2T003 29000.2T004 PC Communication: Order nr. RJ45 - USB cable 29000.2T005 Common accessories: Order nr. remote control/ copying module keypad extension cable 1m keypad extension cable 2m keypad extension cable 3m keypad extension cable 5m mounting plate for DIN rail 29000.2T006 29000.2T007 29000.2T008 29000.2T009 29000.2T010 29000.
Phone: +49(0)9189/4147-0 Fax: +49(0)9189/4147-47 eMail: mail@peter-electronic.com PETER electronic GmbH & Co. KG Bruckäcker 9 D-92348 Berg www.peter-electronic.
