Preface Thank you for choosing DELTA’s multifunction VFD-EL Series. The VFD-EL Series is manufactured with high-quality components and materials and incorporate the latest microprocessor technology available. This manual is to be used for the installation, parameter setting, troubleshooting, and daily maintenance of the AC motor drive. To guarantee safe operation of the equipment, read the following safety guidelines before connecting power to the AC motor drive.
WARNING! 1. DO NOT use Hi-pot test for internal components. The semi-conductor used in AC motor drive easily damage by high-voltage. 2. There are highly sensitive MOS components on the printed circuit boards. These components are especially sensitive to static electricity. To prevent damage to these components, do not touch these components or the circuit boards with metal objects or your bare hands. 3. Only qualified persons are allowed to install, wire and maintain AC motor drives. CAUTION! 1.
Table of Contents Preface ............................................................................................................. i Table of Contents .......................................................................................... iii Chapter 1 Introduction ................................................................................ 1-1 1.1 Receiving and Inspection....................................................................1-2 1.1.1 Nameplate Information.........................
Chapter 3 Keypad and Start Up ..................................................................3-1 3.1 Description of the Digital Keypad ....................................................... 3-1 3.2 How to Operate the Digital Keypad .................................................... 3-3 3.3 Reference Table for the 7-segment LED Display of the Digital Keypad 34 3.4 Operation Method .............................................................................. 3-4 3.5 Trial Run ..........................
5.14 Environmental Condition...................................................................5-9 5.15 Affecting Other Machines ...............................................................5-10 Chapter 6 Fault Code Information and Maintenance................................ 6-1 6.1 Fault Code Information .......................................................................6-1 6.1.1 Common Problems and Solutions............................................... 6-1 6.1.2 Reset .............................
B.8.1 DeviceNet Communication Module (CME-DN01) .....................B-16 B.8.1.1 Panel Appearance and Dimensions ..................................B-16 B.8.1.2 Wiring and Settings ...........................................................B-16 B.8.1.3 Power Supply ....................................................................B-17 B.8.1.4 LEDs Display.....................................................................B-17 B.8.2 LonWorks Communication Module (CME-LW01) .....................B-17 B.8.2.
Appendix C How to Select the Right AC Motor Drive.............................. C-1 C.1 Capacity Formulas ............................................................................ C-2 C.2 General Precaution ........................................................................... C-4 C.3 How to Choose a Suitable Motor.......................................................
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Chapter 1 Introduction The AC motor drive should be kept in the shipping carton or crate before installation. In order to retain the warranty coverage, the AC motor drive should be stored properly when it is not to be used for an extended period of time. Storage conditions are: CAUTION! 1. Store in a clean and dry location free from direct sunlight or corrosive fumes. 2. Store within an ambient temperature range of -20 °C to +60 °C. 3.
Chapter 1 Introduction| 1.1 Receiving and Inspection This VFD-EL AC motor drive has gone through rigorous quality control tests at the factory before shipment. After receiving the AC motor drive, please check for the following: Check to make sure that the package includes an AC motor drive, the User Manual/Quick Inspect the unit to assure it was not damaged during shipment. Make sure that the part number indicated on the nameplate corresponds with the part Start and CD. number of your order.
Chapter 1 Introduction| 1.1.3 Series Number Explanation 007EL23A 0T 7 01 230V 3-phase 1HP(0.75kW) Production number Production week Production year 2007 Production factory T: Taoyuan, W: Wujiang Model If the nameplate information does not correspond to your purchase order or if there are any problems, please contact your distributor. 1.1.4 Drive Frames and Appearances 0.25-2HP/0.2-1.5kW (Frame A) 1-5HP/0.75-3.
Chapter 1 Introduction| Internal Structure Digital keypad NPN/PNP ACI/AVI RS485 port (RJ-45) RFI Jumper Location at the right side NOTE RFI jumper is near the input terminals as shown in the above figure and can be removed by taking off screws. Frame Power range Models VFD002EL11A/21A/23A, A 0.25-2hp (0.2-1.5kW) VFD004EL11A/21A/23A/43A, VFD007EL21A/23A/43A, VFD015EL23A/43A B 1-4 1-5hp (0.75-3.7kW) VFD007EL11A, VFD015EL21A, VFD022EL21A/23A/43A, VFD037EL23A/43A Revision August 2008, 2ELE, V1.
Chapter 1 Introduction| RFI Jumper RFI Jumper: The AC motor drive may emit the electrical noise. The RFI jumper is used to suppress the interference (Radio Frequency Interference) on the power line. Main power isolated from earth: If the AC motor drive is supplied from an isolated power (IT power), the RFI jumper must be cut off. Then the RFI capacities (filter capacitors) will be disconnected from ground to prevent circuit damage (according to IEC 61800-3) and reduce earth leakage current. CAUTION! 1.
Chapter 1 Introduction| 1.2.1 Ambient Conditions Install the AC motor drive in an environment with the following conditions: -10 ~ +50°C (14 ~ 122°F) for UL & cUL Air Temperature: -10 ~ +40°C (14 ~ 104°F) for side-by-side mounting Relative Humidity: Operation <90%, no condensation allowed Atmosphere pressure: Installation Site Altitude: 86 ~ 106 kPa <1000m Vibration: <20Hz: 9.80 m/s2 (1G) max 20 ~ 50Hz: 5.88 m/s2 (0.
Chapter 1 Introduction| Frame B Mounting Clearances Option 1 (-10 to +50°C) Option 2 (-10 to +40°C) 150mm 150mm 50mm Air Flow 50mm 50mm 50mm Air flow 150mm 150mm CAUTION! 1. Operating, storing or transporting the AC motor drive outside these conditions may cause damage to the AC motor drive. 2. 3. Failure to observe these precautions may void the warranty! Mount the AC motor drive vertically on a flat vertical surface object by screws. Other directions are not allowed. 4.
Chapter 1 Introduction| Installation with Metal Separation 120mm 150mm Installation without Metal Separation 120mm 150mm B A 120mm 120mm 120mm Frame A 150mm Air flow 150mm A B 120mm 150mm 150mm Frame B Frame A Frame B 1.2.2 DC-bus Sharing: Connecting the DC-bus of the AC Motor Drives in Parallel 1. 2. This function is not for 115V models. The AC motor drives can absorb mutual voltage that generated to DC bus when deceleration. 1-8 3.
Chapter 1 Introduction| power should be applied at the same time (only the same power system can be connected in parallel) Power 208/220/230/380/440/480 (depend on models) U V W U V W U V W U V W IM IM IM IM Braking modules For frame A and B, terminal + (-) is connected to the terminal + (-) of the braking module. 1.3 Dimensions (Dimensions are in millimeter and [inch]) W W1 D H H1 D Frame W W1 H H1 D Ø ØD A 72.0[2.83] 59.0[2.32] 174.0[6.86] 151.6[5.97] 136.0[5.36] 5.4[0.21] 2.7[0.
Chapter 1 Introduction| NOTE Frame A: VFD002EL11A/21A/23A, VFD004EL11A/21A/23A/43A, VFD007EL21A/23A/43A, VFD015EL23A/43A Frame B: VFD007EL11A, VFD015EL21A, VFD022EL21A/23A/43A, VFD037EL23A/43A 1-10 Revision August 2008, 2ELE, V1.
Chapter 2 Installation and Wiring After removing the front cover, check if the power and control terminals are clear. Be sure to observe the following precautions when wiring. General Wiring Information Applicable Codes All VFD-EL series are Underwriters Laboratories, Inc. (UL) and Canadian Underwriters Laboratories (cUL) listed, and therefore comply with the requirements of the National Electrical Code (NEC) and the Canadian Electrical Code (CEC).
Chapter 2 Installation and Wiring| DANGER! 1. A charge may still remain in the DC bus capacitors with hazardous voltages even if the power has been turned off. To prevent personal injury, please ensure that the power is turned off and wait ten minutes for the capacitors to discharge to safe voltage levels before opening the AC motor drive. 2. Only qualified personnel familiar with AC motor drives is allowed to perform installation, wiring and commissioning. 3.
Chapter 2 Installation and Wiring| Figure 1 for models of VFD-EL Series VFD002EL11A/21A, VFD004EL11A/21A, VFD007EL11A/21A, VFD015EL21A, VFD022EL21A BR BUE brake resi stor (opti onal) brake unit ( optional) F us e/NF B(N o F use B reaker) + R(L1) S(L2) R(L1) S(L2) Recommended Circui t when power s uppl y is turned O FF by a fault output If the fault occ ur s, the contact will be O N to turn off the power and protect the power sys tem.
Chapter 2 Installation and Wiring| Figure 2 for models of VFD-EL Series VFD002EL23A, VFD004EL23A/43A, VFD007EL23A/43A, VFD015EL23A/43A, VFD022EL23A/43A, VFD037EL23A/43A BR brake resi stor (opti onal) BUE F us e/NF B(No F use B reaker) R(L1) S(L2) T( L3) Recommended Circui t when power suppl y SA is turned O FF by a MC fault output. If the fault occ ur s, the ON OF F contact will be O N to MC turn off the power and protect the power sys tem.
Chapter 2 Installation and Wiring| Figure 3 Wiring for NPN mode and PNP mode A. NPN mode without external power NPN PNP Factory setting B. NPN mode with external power NPN PNP 24 Vdc + - Factory setting C. PNP mode without external power NPN Sw1 PNP Factory setting Revision August 2008, 2ELE, V1.
Chapter 2 Installation and Wiring| D. PNP mode with external power NPN Sw1 PNP Factory setting + 24 Vdc - CAUTION! 1. 2. The wiring of main circuit and control circuit should be separated to prevent erroneous actions. Please use shield wire for the control wiring and not to expose the peeled-off net in front of the terminal. 3. Please use the shield wire or tube for the power wiring and ground the two ends of the shield wire or tube. 4.
Chapter 2 Installation and Wiring| Excellent Good Not allowed Revision August 2008, 2ELE, V1.
Chapter 2 Installation and Wiring| 2.2 External Wiring Items Power Supply Power supply FUSE/NFB Fuse/NFB (Optional) There may be an inrush current during power up. Please check the chart of Appendix B and select the correct fuse with rated current. Use of an NFB is optional. Magnetic contactor Magnetic contactor (Optional) Please do not use a Magnetic contactor as the I/O switch of the AC motor drive, as it will reduce the operating life cycle of the AC drive.
Chapter 2 Installation and Wiring| 2.3 Main Circuit 2.3.
Chapter 2 Installation and Wiring| Please use voltage and current within the regulation shown in Appendix A. When using a GFCI (Ground Fault Circuit Interrupter), select a current sensor with sensitivity of 200mA, and not less than 0.1-second detection time to avoid nuisance tripping. For specific GFCI of the AC motor drive, please select a current sensor with sensitivity of 30mA or above. Do NOT run/stop AC motor drives by turning the power ON/OFF.
Chapter 2 Installation and Wiring| 2.3.2 Main Circuit Terminals Frame A Frame Power Terminals R/L1, S/L2, T/L3 A U/T1, V/T2, W/T3, Frame B Torque Wire Wire type 14.2-16.3kgf-cm 12-18 AWG. (3.3-0.8mm2) Copper only, 75oC (12-14in-lbf) R/L1, S/L2, T/L3 U/T1, V/T2, W/T3 B 16.3-19.3kgf-cm 8-18 AWG. (8.40.
Chapter 2 Installation and Wiring| 2.4 Control Terminals Circuit diagram for digital inputs (NPN current 16mA.
Chapter 2 Installation and Wiring| Terminal Symbol Factory Settings (NPN mode) Terminal Function MI5 Multi-function Input 5 MI6 Multi-function Input 6 ON: Connect to DCM ON: the activation current is 5.5mA. OFF: leakage current tolerance is 10μA. +24V DC Voltage Source +24VDC, 50mA used for PNP mode. DCM Digital Signal Common Common for digital inputs and used for NPN mode. RA Multi-function Relay output (N.O.) a RB Multi-function Relay output (N.C.) b Resistive Load: 5A(N.O.)/3A(N.C.
Chapter 2 Installation and Wiring| Analog inputs (AVI, ACM) Analog input signals are easily affected by external noise. Use shielded wiring and keep it as short as possible (<20m) with proper grounding. If the noise is inductive, connecting the shield to terminal ACM can bring improvement. If the analog input signals are affected by noise from the AC motor drive, please connect a capacitor (0.
Chapter 2 Installation and Wiring| The specification for the control terminals The position of the control terminals 24V MI1 MI3 MI5 10V AVI RS-485 RA RB RC MI2 MI4 MI6 DCM AFM ACM Frame Torque Wire A, B 5.1-8.1kgf-cm (4.4-7in-lbf) 16-24 AWG. (1.3-0.2mm2) NOTE Frame A: VFD002EL11A/21A/23A, VFD004EL11A/21A/23A/43A, VFD007EL21A/23A/43A, VFD015EL23A/43A Frame B: VFD007EL11A, VFD015EL21A, VFD022EL21A/23A/43A, VFD037EL23A/43A Revision August 2008, 2ELE, V1.
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Chapter 3 Keypad and Start Up 3.1 Description of the Digital Keypad 1 3 2 4 5 6 7 1 Status Display Display the driver's current status. 2 LED Display Indicates frequency, voltage, current, user defined units and etc. 3 4 Potentiometer For master Frequency setting. 5 UP and DOWN Key Set the parameter number and changes the numerical data, such as Master Frequency. 6 MODE Change between different display mode. 7 STOP/RESET Stops AC drive operation and reset the drive after fault occurred.
Chapter 3 Keypad and Start Up| Display Message Descriptions Displays the AC drive Master Frequency. Displays the actual output frequency at terminals U/T1, V/T2, and W/T3. User defined unit (where U = F x Pr.00.05) Displays the output current at terminals U/T1, V/T2, and W/T3. Displays the AC motor drive forward run status. Displays the AC motor drive reverse run status. The counter value (C). Displays the selected parameter. Displays the actual stored value of the selected parameter. External Fault.
Chapter 3 Keypad and Start Up| 3.2 How to Operate the Digital Keypad Setting Mode S TART MO DE MO DE MO DE MO DE MO DE GO START NOTE: In the selection mode, press MO DE to set the parameters. Setting parameters or ENTER ENTER ENTER Success to set parameter. NOTE:In the parameter setting mode, you can press MO DE Input data error to return the selecting mode. To shift data Setting direction (When operation source is digital keypad) MO DE MO DE Revision August 2008, 2ELE, V1.
Chapter 3 Keypad and Start Up| 3.3 Reference Table for the 7-segment LED Display of the Digital Keypad Digit 0 1 2 3 4 5 6 7 8 9 A b Cc d E F G Hh Ii Jj K L n Oo P q r S Tt U v Y Z LED Display English alphabet LED Display English alphabet LED Display English alphabet LED Display 3.4 Operation Method The operation method can be set via communication, control terminals and digital keypad. 3-4 Revision August 2008, 2ELE, V1.
Chapter 3 Keypad and Start Up| Operation Method Frequency Source Operation Command Source Operate from When setting communication by the PC, it needs to use VFD-USB01 or IFD8500 converter to connect to the PC. the communication Refer to the communication address 2000H and 2101H setting for details.
Chapter 3 Keypad and Start Up| 1. After applying the power, verify that LED display shows F 60.0Hz. key to set frequency to around 2. Press 5Hz. 3. Press key for forward running. And if you want to change to reverse running, you should press . And if you want to RUN decelerate to stop, please press key. 4. Check following items: Check if the motor direction of rotation Check if the motor runs steadily Check if acceleration and deceleration is correct.
Chapter 4 Parameters The VFD-EL parameters are divided into 11 groups by property for easy setting. In most applications, the user can finish all parameter settings before start-up without the need for re-adjustment during operation.
Chapter 4 Parameters| 4.1 Summary of Parameter Settings : The parameter can be set during operation. Group 0 User Parameters Factory Customer Setting Parameter Explanation Settings 00.00 Identity Code of the AC motor drive Read-only ## 00.01 Rated Current Display of the AC motor drive Read-only #.# 0: Parameter can be read/written 1: All parameters are read only 8: Keypad lock 00.02 Parameter Reset 9: All parameters are reset to factory settings (50Hz, 230V/400V or 220V/380V depends on Pr.00.
Chapter 4 Parameters| Parameter Explanation Settings Factory Customer Setting 7: Display output power (P) 8: Display PID setting and feedback signal 9: Display AVI (I) (V) 10: Display ACI (i) (mA) 11: Display the temperature of IGBT (h) (°C) User-Defined Coefficient K 0. 1 to 160.0 1.0 00.06 Software Version Read-only #.## 00.07 Reserved 00.08 Password Input 0 to 9999 0 00.09 Password Set 0 to 9999 0 00.10 Reserved 00.11 Reserved 00.12 50Hz Base Voltage Selection 00.
Chapter 4 Parameters| Parameter Explanation Factory Customer Setting Settings 115V/230V series: 0.1V to 255.0V 10.0 460V series: 0.1V to 510.0V 20.0 0.10 to 600.0 Hz 1.50 Minimum Output Voltage (Vmin) 115V/230V series: 0.1V to 255.0V 10.0 460V series: 0.1V to 510.0V 20.0 01.07 Output Frequency Upper Limit 0.1 to 120.0% 01.08 Output Frequency Lower Limit 0.0 to100.0 % 01.09 Accel Time 1 0.1 to 600.0 / 0.01 to 600.0 sec 10.0 01.10 Decel Time 1 0.1 to 600.0 / 0.01 to 600.0 sec 10.
Chapter 4 Parameters| Group 2 Operation Method Parameters Parameter 02.00 Explanation Source of First Master Frequency Command Settings Factory Customer Setting 0: Digital keypad UP/DOWN keys or Multifunction Inputs UP/DOWN. Last used frequency saved. 1: 0 to +10V from AVI 1 2: 4 to 20mA from ACI 3: RS-485 (RJ-45) communication 4: Digital keypad potentiometer 0: Digital keypad 1: External terminals. Keypad STOP/RESET enabled. 02.01 Source of First Operation Command 2: External terminals.
Chapter 4 Parameters| Parameter Explanation Factory Customer Setting Settings 3: Enable. Operation status will change if operation command source Pr.02.01 is changed. 0: Decelerate to 0 Hz 02.06 Loss of ACI Signal (4-20mA) 1: Coast to stop and display “AErr” 1 2: Continue operation by last frequency command 0: by UP/DOWN Key 02.07 Up/Down Mode 02.08 Accel/Decel Rate of Change of UP/DOWN Operation with Constant Speed 1: Based on accel/decel time 0 2: Constant speed (Pr.02.
Chapter 4 Parameters| Parameter 02.14 Explanation Initial Frequency Selection (for keypad & RS485) 02.15 Initial Frequency Setpoint (for keypad & RS485) 02.16 Display the Master Freq Command Source Settings Factory Customer Setting 0: by Current Freq Command 1: by Zero Freq Command 0 2: by Frequency Display at Stop 0.00 ~ 600.0Hz 60.00 Read Only Bit0=1: by First Freq Source (Pr.02.00) Bit1=1: by Second Freq Source (Pr.02.09) ## Bit2=1: by Multi-input function Read Only 02.
Chapter 4 Parameters| Parameter Explanation Factory Customer Setting Settings 11: Preliminary count value attained 12: Over Voltage Stall supervision 13: Over Current Stall supervision 14: Heat sink overheat warning 15: Over Voltage supervision 16: PID supervision 17: Forward command 18: Reverse command 19: Zero speed output signal 20: Warning(FbE,Cexx, AoL2, AUE, SAvE) 21: Brake control (Desired frequency attained) 22: AC motor drive ready 03.01 Reserved 03.02 Desired Frequency Attained 0.
Chapter 4 Parameters| Parameter Explanation Settings Factory Customer Setting 03.10 Reserved 03.11 Brake Release Frequency 0.00 to 20.00Hz 0.00 03.12 Brake Engage Frequency 0.00 to 20.00Hz 0.00 03.13 Display the Status of Read only Relay ## Group 4 Input Function Parameters Parameter Explanation 04.00 Keypad Potentiometer Bias 04.01 Keypad Potentiometer Bias Polarity 04.02 Keypad Potentiometer Gain 04.03 04.
Chapter 4 Parameters| Parameter Explanation 04.08 Multi-function Input Terminal (MI6) Factory Customer Setting Settings 9: External base block 4 10: Up: Increment master frequency 11: Down: Decrement master frequency 12: Counter Trigger Signal 13: Counter reset 14: E.F.
Chapter 4 Parameters| Parameter Explanation Settings Factory Customer Setting Min ACI Current 0.0 to 20.0mA 04.16 Min ACI Frequency 0.0 to 100.0% 04.17 Max ACI Current 0.0 to 20.0mA 20.0 04.18 Max ACI Frequency 0.0 to 100.0% 100.0 04.15 4.0 0.0 04.19 | Reserved 04.25 Read only. Bit0: MI1 Status 04.26 Display the Status of Multi-function Input Terminal Bit1: MI2 Status ## Bit2: MI3 Status Bit3: MI4 Status Bit4: MI5 Status Bit5: MI6 Status 04.27 04.
Chapter 4 Parameters| Parameter Explanation Factory Customer Setting Settings 05.05 6th Step Speed Frequency 0.00 to 600.0 Hz 0.00 05.06 7th Step Speed Frequency 0.00 to 600.0 Hz 0.00 05.07 8th Step Speed Frequency 0.00 to 600.0 Hz 0.00 05.08 9th Step Speed Frequency 0.00 to 600.0 Hz 0.00 05.09 10th Step Speed Frequency 0.00 to 600.0 Hz 0.00 05.10 11th Step Speed Frequency 0.00 to 600.0 Hz 0.00 05.11 12th Step Speed Frequency 0.00 to 600.0 Hz 0.00 05.
Chapter 4 Parameters| Parameter Explanation Settings Factory Customer Setting 2: Enabled during constant speed operation. After the over-torque is detected, stop running. 3: Enabled during accel. After the over-torque is detected, keep running until OL1 or OL occurs. 4: Enabled during accel. After the over-torque is detected, stop running. 06.04 06.05 06.06 Over-Torque Detection Level 10 to 200% 150 Over-Torque Detection Time 0.1 to 60.0 sec 0.
Chapter 4 Parameters| Parameter Explanation Factory Customer Setting Settings 14: Phase-Loss (PHL) 15: Reserved 16: Auto Acel/Decel failure (CFA) 06.10 Third Most Recent Fault Record 17: SW/Password protection (codE) 18: Power Board CPU WRITE failure (cF1.0) 19: Power Board CPU READ failure (cF2.0) 20: CC, OC Hardware protection failure (HPF1) 06.
Chapter 4 Parameters| Parameter Explanation Settings Factory Customer Setting 07.02 Torque Compensation 0.0 to 10.0 0.0 07.03 Slip Compensation 0.00 to 10.00 0.00 07.04 | Reserved 07.09 07.10 Accumulative Motor Operation Time (Min.) 0 to 1439 Min. 0 07.11 Accumulative Motor Operation Time (Day) 0 to 65535 Day 0 07.12 Motor PTC Overheat Protection 07.13 Input Debouncing Time of the PTC Protection 0~9999(*2ms) 100 07.14 Motor PTC Overheat Protection Level 0.1~10.0V 2.4 07.
Chapter 4 Parameters| Parameter Explanation Factory Customer Setting Settings 08.02 DC Brake Time during Stopping 0.0 to 60.0 sec 0.0 08.03 Start-Point for DC Brake 0.00 to 600.0Hz 0.00 0: Operation stops after momentary power loss 08.04 Momentary Power Loss Operation Selection 1: Operation continues after momentary power loss, speed search starts with the Master Frequency reference value 0 2: Operation continues after momentary power loss, speed search starts with the minimum frequency 08.
Chapter 4 Parameters| Parameter Explanation 08.17 Auto Energy Saving Settings 0: Disable Factory Customer Setting 0 1: Enable 0: AVR function enable 08.18 AVR Function 1: AVR function disable 2: AVR function disable for decel. 0 3: AVR function disable for stop 08.19 08.20 Reserved 0.0~5.0 Compensation Coefficient for Motor Instability 0.0 Group 9 Communication Parameters Parameter 09.
Chapter 4 Parameters| Parameter Explanation Factory Customer Setting Settings 4: 8,E,1 (Modbus, RTU) 5: 8,O,1 (Modbus, RTU) 6: 8,N,1 (Modbus, RTU) 7: 8,E,2 (Modbus, RTU) 8: 8,O,2 (Modbus, RTU) 9: 7,N,1 (Modbus, ASCII) 10: 7,E,2 (Modbus, ASCII) 11: 7,O,2 (Modbus, ASCII) 09.05 Reserved 09.06 Reserved 09.07 Response Delay Time 0 ~ 200 (unit: 2ms) 1 Group 10 PID Control Parameters Parameter Explanation Factory Customer Setting Settings 0: Disable PID operation 1: Keypad (based on Pr.02.00) 10.
Chapter 4 Parameters| Parameter 10.04 Explanation Derivative Control (D) Settings 0.00 to 1.00 sec Factory Customer Setting 0.00 10.05 Upper Bound for Integral Control 0 to 100% 100 10.06 Primary Delay Filter Time 0.0 to 2.5 sec 0.0 10.07 PID Output Freq Limit 0 to 110% 100 10.08 PID Feedback Signal Detection Time 0.0 to 3600 sec (0.0 disable) 60.0 10.09 Treatment of the Erroneous PID Feedback Signals 10.10 Gain Over the PID Detection Value 10.
Chapter 4 Parameters| Parameter Explanation Factory Customer Setting Settings 0: Keep operating 10.20 Treatment of the Erroneous PID Feedback Level 1: Coast to stop 0 2: Ramp to stop 3: Ramp to stop and restart after time set in Pr.10.21 Restart Delay Time after Erroneous PID Deviation Level 1 to 9999 sec 60 Set Point Deviation Level 0 to 100% 0 Detection Time of Set Point Deviation Level 0 to 9999 sec 10 10.24 Offset Level of Liquid Leakage 0 to 50% 0 10.
Chapter 4 Parameters| 4.2 Parameter Settings for Applications Speed Search Applications Windmill, winding machine, fan and all inertia loads Purpose Restart freerunning motor Functions Before the free-running motor is completely stopped, it can be restarted without detection of motor speed. The AC motor drive will auto search motor speed and will accelerate when its speed is the same as the motor speed. Related Parameters 08.04~08.08 DC Brake before Running Applications Purpose Keep the freeWhen e.g.
Chapter 4 Parameters| Overheat Warning Applications Air conditioner Purpose Safety measure Related Parameters Functions When AC motor drive overheats, it uses a thermal sensor to have overheat warning. 03.00 04.05~04.
Chapter 4 Parameters| Auto Restart after Fault Applications Air conditioners, remote pumps Purpose Functions For continuous and The AC motor drive can be reliable operation restarted/reset automatically up to 10 without operator times after a fault occurs. intervention Related Parameters 08.15~08.
Chapter 4 Parameters| Carrier Frequency Setting Applications General application Purpose Low noise Related Parameters Functions The carrier frequency can be increased when required to reduce motor noise. 02.03 Keep Running when Frequency Command is Lost Applications Air conditioners Purpose For continuous operation Related Parameters Functions When the frequency command is lost by system malfunction, the AC motor drive can still run. Suitable for intelligent air conditioners. 02.
Chapter 4 Parameters| Output Signal for Base Block Applications General application Purpose Functions When executing Base Block, a signal Provide a signal for is given for external system or control running status wiring. Related Parameters 03.00 Overheat Warning for Heat Sink Applications General application Purpose For safety Functions When heat sink is overheated, it will send a signal for external system or control wiring. Related Parameters 03.
Chapter 4 Parameters| 4.3 Description of Parameter Settings Group 0: User Parameters 00.00 Identity Code of the AC Motor Drive Settings 00.01 This parameter can be set during operation. Read Only Factory setting: ## Rated Current Display of the AC Motor Drive Settings Read Only Factory setting: #.# Pr. 00.00 displays the identity code of the AC motor drive. The capacity, rated current, rated voltage and the max. carrier frequency relate to the identity code.
Chapter 4 Parameters| This parameter allows the user to reset all parameters to the factory settings except the fault records (Pr.06.08 ~ Pr.06.12). 50Hz: Pr.01.00 and Pr.01.01 are set to 50Hz and Pr.01.02 will be set by Pr.00.12. 60Hz: Pr.01.00 and Pr.01.01 are set to 60Hz and Pr.01.02 is set to 115V, 230V or 460V. When Pr.00.02=1, all parameters are read-only. To write all parameters, set Pr.00.02=0. 00.
Chapter 4 Parameters| 00.04 Content of Multi-function Display 9 Display the signal of AVI analog input terminal (V). 10 Display the signal of ACI analog input terminal (mA). 11 Display the temperature of IGBT (h) in °C When Pr00.03 is set to 03, the display is according to the setting of Pr00.04. 00.05 User Defined Coefficient K Settings Unit: 0. 1 0. 1 to d 160.0 Factory Setting: 1.0 The coefficient K determines the multiplying factor for the user-defined unit.
Chapter 4 Parameters| 00.09 Password Set Unit: 1 Settings 0 to 9999 Display 0 No password set or successful input in Pr. 00.08 Factory Setting: 0 1 Password has been set To set a password to protect your parameter settings. If the display shows 0, no password is set or password has been correctly entered in Pr.00.08. All parameters can then be changed, including Pr.00.09. The first time you can set a password directly. After successful setting of password the display will show 1.
Chapter 4 Parameters| 00.10 Reserved 00.11 Reserved 00.12 50Hz Base Voltage Selection Factory Setting: 0 Settings 0 230V/400V 1 220V/380V This parameter determines the base voltage for 50Hz. 00.13 User-defined Value 1 (correspond to max. frequency) Settings 0 to 9999 Unit: 1 Factory Setting: 0 This parameter corresponds to max. frequency. When Pr.00-13 is not set to 0, “F” will disappear in frequency mode and the right-most digit will blink. Many ranges will be changed to Pr.00.
Chapter 4 Parameters| Group 1: Basic Parameters 01.00 Maximum Output Frequency (Fmax) Settings 50.00 to 600.0 Hz Unit: 0.01 Factory Setting: 60.00 This parameter determines the AC motor drive’s Maximum Output Frequency. All the AC motor drive frequency command sources (analog inputs 0 to +10V and 4 to 20mA) are scaled to correspond to the output frequency range. 01.01 Maximum Voltage Frequency (Fbase) Settings 0.10 to 600.0Hz Unit: 0.01 Factory Setting: 60.
Chapter 4 Parameters| This parameter sets the Mid-Point Voltage of any V/f curve. With this setting, the V/f ratio between Minimum Frequency and Mid-Point Frequency can be determined. This parameter must be equal to or greater than Minimum Output Voltage (Pr.01.06) and equal to or less than Maximum Output Voltage (Pr.01.02). 01.05 Minimum Output Frequency (Fmin) Settings Unit: 0.01 0.10 to 600.0Hz Factory Setting: 1.50 This parameter sets the Minimum Output Frequency of the AC motor drive.
Chapter 4 Parameters| 01.08 Unit: 0.1 Output Frequency Lower Limit Settings 0.0 to 100.0% Factory Setting: 0.0 The Upper/Lower Limits are to prevent operation errors and machine damage. If the Output Frequency Upper Limit is 50Hz and the Maximum Output Frequency is 60Hz, the Output Frequency will be limited to 50Hz. If the Output Frequency Lower Limit is 10Hz, and the Minimum Output Frequency (Pr.01.05) is set to 1.0Hz, then any Command Frequency between 1.
Chapter 4 Parameters| In the diagram shown below, the Acceleration/Deceleration Time of the AC motor drive is the time between 0 Hz to Maximum Output Frequency (Pr.01.00). Suppose the Maximum Output Frequency is 60 Hz, Minimum Output Frequency (Pr.01.05) is 1.0 Hz, and Acceleration/Deceleration Time is 10 seconds. The actual time for the AC motor drive to accelerate from start-up to 60 Hz and to decelerate from 60Hz to 1.0Hz is in this case 9.83 seconds. ((60-1) * 10/60=9.83secs). Frequency 01.00 Max.
Chapter 4 Parameters| Before using the JOG command, the drive must be stopped first. And during Jog operation, other operation commands are not accepted, except FORWARD/REVERSE commands. Frequency 01.15 JOG Frequency 01.05 Min. output frequency 0 Hz JOG Accel. Time 01.13 JOG Decel. Time Time 01.14 01.12 The definition of JOG Accel./Decel. Time01.21 01.16 Auto-Acceleration / Deceleration Factory Setting: 0 Settings 0 Linear acceleration / deceleration 1 Auto acceleration, linear Deceleration.
Chapter 4 Parameters| 01.17 Acceleration S-Curve 01.18 Deceleration S-Curve Unit: 0.1/0.01 Unit: 0.1/0.01 Factory Setting: 0 Settings 0.0 S-curve disabled 0.1 to 10.0/0.01 to 10.00 S-curve enabled (10.0/10.00 is the smoothest) This parameter is used to ensure smooth acceleration and deceleration via S-curve. The S-curve is disabled when set to 0.0 and enabled when set to 0.1 to 10.0/0.01 to 10.00. Setting 0.1/0.01 gives the quickest and setting 10.0/10.00 the longest and smoothest S-curve.
Chapter 4 Parameters| Group 2: Operation Method Parameters 02.00 Source of First Master Frequency Command 02.09 Source of Second Master Frequency Command Factory Setting: 1 Factory Setting: 0 Settings 0 Digital keypad UP/DOWN keys or Multi-function Inputs UP/DOWN. Last used frequency saved.
Chapter 4 Parameters| Combination of the First and Second Master Frequency Command 02.10 Factory Setting: 0 Settings 02.02 0 First Master Frequency Command Only 1 First Master Frequency + Second Master Frequency 2 First Master Frequency - Second Master Frequency 0 STOP: ramp to stop Stop Method Factory Setting: 0 Settings E.F.: coast to stop 1 STOP: coast to stop E.F.: coast to stop 2 STOP: ramp to stop E.F.: ramp to stop 3 STOP: coast to stop E.F.
Chapter 4 Parameters| Frequency output frequency Frequency output frequency motor speed motor speed Time operation command stops according to decel eration time STOP RUN Time free run to stop operation command RUN STOP ramp to stop and free run to stop Frequency Frequency frequency output motor speed frequency output motor speed stops according to decel eration time operation command free run to stop operation command EF EF When Pr.02.02 is set to 0 or 1 When Pr.02.
Chapter 4 Parameters| Carrier Frequency Acoustic Noise 2kHz Significant Electromagnetic Noise or leakage current Minimal Heat Dissipation Current Wave Minimal Minimal Significant Significant 8kHz 12kHz Minimal Significant From the table, we see that the PWM carrier frequency has a significant influence on the electromagnetic noise, AC motor drive heat dissipation, and motor acoustic noise.
Chapter 4 Parameters| 25℃ with mounting method B 90% 50℃ with mounting method A 40℃ with mounting method B 80% 70% 60% 50% Rated Current (%) Rated Current (%) 100% 35℃ with mounting method A 25℃ with mounting method B 90% 50℃ with mounting method A 40℃ with mounting method B 80% 70% 60% 50% 40% 40% 2kHz 02.
Chapter 4 Parameters| When the operation command source is from external terminal and operation command is ON (MI1/MI2-DCM=closed), the AC motor drive will operate according to Pr.02.05 after power is applied. 1. When Pr.02.05 is set to 0 or 2, AC motor drive will run immediately. 2. When Pr.02.05 is set to 1 or 3, AC motor drive will remain stopped until operation command is received after previous operation command is cancelled. MI1-DCM (close) Pr.02.
Chapter 4 Parameters| MI1-DCM (close) ON OFF power is applied output frequency Pr.02.05=0 or 1 OFF ON ON it will run output frequency Pr.02.05=2 or 3 it won't run when power is applied It needs to received a run command after previous command is cancelled The Line Start Lockout feature does not guarantee that the motor will never start under this condition. It is possible the motor may be set in motion by a malfunctioning switch. 02.
Chapter 4 Parameters| These parameters determine the increase/decrease of the master frequency when operated via the Multi-function Inputs when Pr.04.05~Pr.04.08 are set to 10 (Up command) or 11 (Down command). When Pr.02.07 is set to 0: increase/decrease the frequency by using UP/DOWN key. It is valid only when the AC motor drive is running. When Pr.02.07 is set to 1: increase/decrease the frequency by acceleration/deceleration settings. It is valid only when the AC motor drive is running. When Pr.02.
Chapter 4 Parameters| These parameters are used to determinate the frequency at stop: When setting Pr.02.14 to 0: the initial frequency will be current frequency. When setting Pr.02.14 to 1: the initial frequency will be 0. When setting Pr.02.14 to 2: the initial frequency will be Pr.02.15. 02.16 Display the Master Freq Command Source Settings Read Only Factory setting: ## You can read the master frequency command source by this parameter.
Chapter 4 Parameters| Use this parameter to change frequency when (1) Pr.00.13 is not set to 0 and frequency source is from communication or (2) Pr.02.10 is not set to 0. 02.19 User-defined Value 2 Settings Unit: 1 Read-only Factory Setting: 0 For example: suppose that the frequency source is the first master frequency + second master frequency command (first master frequency is from keypad and second master frequency is from AVI), user-defined value 1 is set to 180.0(Pr.00.13 is set to 1800, Pr.00.
Chapter 4 Parameters| Group 3: Output Function Parameters 03.00 Multi-function Output Relay (RA1, RB1, RC1) Factory Setting: 8 Settings Function Description 0 No Function 1 AC Drive Operational Active when the drive is ready or RUN command is “ON”. Master Frequency Active when the AC motor drive reaches the output Attained frequency setting. 2 3 Zero Speed 4 Over-Torque Detection 5 6 7 8 9 10 11 12 13 Baseblock (B.B.
Chapter 4 Parameters| Settings 14 Function Description Heat Sink Overheat When heatsink overheats, it will signal to prevent OH turn off Warning the drive. When it is higher than 85oC (185oF), it will be ON.
Chapter 4 Parameters| Frequency master frequency detection 4Hz range 2Hz detection range detection -2Hz range desired frequency waiting time for 03.02 frequency run/stop OFF desired freq. attained OFF setting 03 zero speed indication Time OFF ON master freq.
Chapter 4 Parameters| For Example: When using the meter with full scale of 5 volts, adjust Pr.03.04 to 50%. If Pr.03.03 is set to 0, then 5VDC will correspond to Maximum Output Frequency. 03.05 Terminal Count Value Settings Unit: 1 0 to 9999 Factory Setting: 0 This parameter sets the count value of the internal counter. To increase the internal counter, one of Pr.04.05 to 04.08 should be set to 12. Upon completion of counting, the specified output terminal will be activated. (Pr.03.00 set to 10).
Chapter 4 Parameters| 03.08 Fan Control Factory Setting: 0 Settings 0 Fan always ON 1 1 minute after AC motor drive stops, fan will be OFF 2 Fan ON when AC motor drive runs, fan OFF when AC motor drive stops 3 Fan ON when preliminary heatsink temperature attained This parameter determines the operation mode of the cooling fan. 03.09 Reserved 03.10 Reserved 03.11 Brake Release Frequency Settings 03.12 0.00 to 600.0Hz Unit: 0.01 Factory Setting: 0.00 Brake Engage Frequency Settings 0.
Chapter 4 Parameters| 03.13 Display the Status of Relay Settings Read Only Factory setting: ## For standard AC motor drive, the multi-function output terminals are falling-edge triggered. 0: Relay is ON; 1: Relay is OFF. 4-52 Revision August 2008, 2ELE, V1.
Chapter 4 Parameters| Group 4: Input Function Parameters 04.00 Keypad Potentiometer Bias Settings 04.01 Unit: 0. 1 0.0 to 100.0% Factory Setting: 0.0 Keypad Potentiometer Bias Polarity Factory Setting: 0 Settings 04.02 Positive Bias 1 Negative Bias Keypad Potentiometer Gain Settings 04.03 0 Unit: 0.1 0.1 to 200.0% Factory Setting: 100.
Chapter 4 Parameters| Pr.01.00=60Hz--Max. output Freq. Potentiometer Pr.04.00 =16.7%--Bias adjustment Pr.04.01 =0--Positive bias Pr.04.02 =100%--Input gain Pr.04.03 =0--No negative bias command 60Hz 40Hz 10Hz Bias Adjustment 0Hz 0V Gain:100% 5V 10V Bias adjustment:((10Hz/60Hz)/(Gain/100%))*100%=16.7% Example 3: Use of bias and gain for use of full range This example also shows a popular method. The whole scale of the potentiometer can be used as desired.
Chapter 4 Parameters| Example 5: Use of negative bias in noisy environment In this example, a 1V negative bias is used. In noisy environments it is advantageous to use negative bias to provide a noise margin (1V in this example). Pr.01.00=60Hz--Max. output Freq. Potentiometer Pr.04.00 =10.0%--Bias adjustment Pr.04.01 =1--Negative bias Pr.04.02 =100%--Input gain Pr.04.03 =0--No negative bias command 60Hz 54Hz Gain:100% 0Hz Negative 0V 1V bias 6Hz 10V Bias adjustment:((6Hz/60Hz)/(Gain/100%))*100%=10.
Chapter 4 Parameters| Example 8: Use negative slope In this example, the use of negative slope is shown. Negative slopes are used in applications for control of pressure, temperature or flow. The sensor that is connected to the input generates a large signal (10V) at high pressure or flow. With negative slope settings, the AC motor drive will slow stop the motor. With these settings the AC motor drive will always run in only one direction (reverse).
Chapter 4 Parameters| 01.00 04.14 04.18 04.12 04.16 04.11 04.15 04.17 analog input 01.00=60.00 Hz 04.14=70 AVI 04.18=50 ACI 04.12=30 analog input 04.16=0 04.11=0V 04.15=4mA 04.13=10V 04.17=20mA 04.19 Reserved 04.20 Reserved 04.21 Reserved 04.22 Reserved 04.23 Reserved 04.24 Reserved 04.25 Reserved 04.
Chapter 4 Parameters| There are three different types of control modes: 04.04 0 External Terminal 2-wire FWD/STOP MI1:("OPEN":STOP) ("CLOSE":FWD) FWD /STOP REV/STOP MI2:("OPEN": STOP) ("CLOSE": REV) DCM VFD-EL 2-wire RUN/STOP MI1:("OPEN":STOP) ("CLOSE":RUN) FWD/ REV FWD/REV MI2:("OPEN": FWD) ("CLOSE": REV) DCM VFD-EL REV / STOP 1 RUN / STOP STOP RUN MI1 : ("CLOSE":RUN) MI3:("OPEN":STOP) 2 3-wire REV/FWD 04.05 Multi-function Input Terminal (MI3) 04.
Chapter 4 Parameters| Settings 1 2 3 4 Function Description Multi-Step Speed Command 1 Multi-Step Speed These four inputs select the multi-speed defined by Pr.05.00 to Pr.05.14 as shown in the diagram at the end of this table. Command 2 Multi-Step Speed Command 3 Multi-Step Speed NOTE: Pr.05.00 to Pr.05.14 can also be used to control output speed. There are 17 step speed frequencies (including Master Frequency and Jog Frequency) to select for application.
Chapter 4 Parameters| Settings 10 Function Description UP: Increase Increase/decrease the Master Frequency each time an input is Master Frequency received or continuously when the input stays active. When both inputs are active at the same time, the Master Frequency 11 DOWN: Decrease increase/decrease is halted. Please refer to Pr.02.07, 02.08. This Master Frequency function is also called “motor potentiometer”.
Chapter 4 Parameters| Settings Function Description Operation ON: Operation command via Communication Command Selection (Pr 02.01 20 21 setting/ Pr.02.01 is disabled if this parameter value 20 is set. See the Communication) explanation below this table. Forward/Reverse Source of second 22 frequency command enabled 04.09 OFF: Operation command via Pr.02.01 setting This function has top priority to set the direction for running (If “Pr.02.
Chapter 4 Parameters| 0=N.O 1=N.C Weights 1 Bit 1 0 1 0 0 MI1 MI2 MI3 MI4 MI5 MI6 The setting value 5 4 2 = bit5x2 +bit4x2 +bit2x2 5 4 2 = 1x2 +1x2 +1x2 =32+16+4 =52 Setting 04.09 04.
Chapter 4 Parameters| For Example: If Pr.04.26 displays 52, it means MI1, MI2 and MI4 are active. The display value 52= 32+16+4 =1 X 25+ 1X 24 + 1X 22 = bit 6 X 25+ bit 5 X 24 + bit 3 X 22 Weights Bit 1 1 0 1 0 0 0=Active 1=Off MI1 MI2 MI3 MI4 MI5 MI6 04.27 Unit: 1 Internal/External Multi-function Input Terminals Selection Settings Factory Setting: 0 0 to 4095 This parameter is used to select the terminals to be internal terminal or external terminal.
Chapter 4 Parameters| 0=external terminal 1=internal terminal Weights 1 Bit 1 0 1 0 0 MI1 MI2 MI3 MI4 MI5 MI6 04.28 Unit: 1 Internal Terminal Status Settings Factory Setting: 0 0 to 4095 This parameter is used to set the internal terminal action via keypad or communication. For standard AC motor drive, the multi-function input terminals are MI1 to MI6 as shown in the following.
Chapter 4 Parameters| Group 5: Multi-step speeds parameters 05.00 1st Step Speed Frequency Unit: 0.01 05.01 2nd Step Speed Frequency Unit: 0.01 05.02 3rd Step Speed Frequency Unit: 0.01 05.03 4th Step Speed Frequency Unit: 0.01 05.04 5th Step Speed Frequency Unit: 0.01 05.05 6th Step Speed Frequency Unit: 0.01 05.06 7th Step Speed Frequency Unit: 0.01 05.07 8th Step Speed Frequency Unit: 0.01 05.08 9th Step Speed Frequency Unit: 0.01 05.09 10th Step Speed Frequency Unit: 0.
Chapter 4 Parameters| 05.07 Frequency 05.06 05.08 05.05 05.09 05.04 05.10 05.03 05.11 05.02 05.12 05.01 JOG Freq. 01.15 05.13 05.00 05.14 Master Speed 04.05~04.08 Multi-function terminals Run/Stop PU/external terminals /communication 1st speed ( MI3 to MI6 1) 2nd speed ( MI3 to MI6 2) 3rd speed ( MI3 to MI6 3) 4th speed ( MI3 to MI6 4) Jog Freq.
Chapter 4 Parameters| Group 6: Protection Parameters 06.00 Over-Voltage Stall Prevention Unit: 0.1 Settings 115V/230V series 330.0 to 410.0V Factory Setting: 390.0 460V series 660.0 to 820.0V 0 Disable Over-voltage Stall Prevention (with brake unit or brake resistor) Factory Setting: 780.0 During deceleration, the DC bus voltage may exceed its Maximum Allowable Value due to motor regeneration.
Chapter 4 Parameters| 06.01 Over-Current Stall Prevention during Acceleration Settings Unit: 1 20 to 250% Factory Setting: 170 0: disable A setting of 100% is equal to the Rated Output Current of the drive. During acceleration, the AC drive output current may increase abruptly and exceed the value specified by Pr.06.01 due to rapid acceleration or excessive load on the motor.
Over-Current Detection Level 06.02 Over-Current Stall Prevention during Operation, output frequency decrease Chapter 4 Parameters| Output Current Output Frequency over-current stall prevention during operation 06.03 Over-Torque Detection Mode (OL2) Factory Setting: 0 Settings 0 Over-Torque detection disabled. 1 Over-Torque detection enabled during constant speed operation. After over-torque is detected, keep running until OL1 or OL occurs.
Chapter 4 Parameters| This parameter sets the time for how long over-torque must be detected before “OL2” is displayed. 06.
Chapter 4 Parameters| 06.08 Present Fault Record 06.09 Second Most Recent Fault Record 06.10 Third Most Recent Fault Record 06.11 Fourth Most Recent Fault Record 06.12 Fifth Most Recent Fault Record Factory Setting: 0 Readings 0 No fault 1 Over-current (oc) 2 Over-voltage (ov) 3 IGBT Overheat (oH1) 4 Reserved 5 Overload(oL) 6 Overload (oL1) 7 Motor Overload (oL2) 8 External Fault (EF) 9 Hardware protection failure (HPF) 10 Current exceeds 2 times rated current during accel.
Chapter 4 Parameters| 29-31 Reserved 32 ACI signal error (AErr) 33 Reserved 34 Motor PTC overheat protection (PtC1) 35-40 Reserved In Pr.06.08 to Pr.06.12 the five most recent faults that occurred, are stored. After removing the cause of the fault, use the reset command to reset the drive. 4-72 Revision August 2008, 2ELE, V1.
Chapter 4 Parameters| Group 7: Motor Parameters 07.00 Motor Rated Current Settings 30% FLA to 120% FLA Unit: 1 Factory Setting: FLA Use the following formula to calculate the percentage value entered in this parameter: (Motor Current / AC Drive Current) x 100% with Motor Current=Motor rated current in A on type shield AC Drive Current=Rated current of AC drive in A (see Pr.00.01) 07.01 Motor No-load Current Settings 0% FLA to 90% FLA Unit: 1 Factory Setting: 0.
Chapter 4 Parameters| 07.09 Reserved 07.10 Accumulative Motor Operation Time (Min.) Settings 07.11 Unit: 1 0~1439 Factory Setting: 0 Accumulative Motor Operation Time (Day) Settings Unit: 1 0 ~65535 Factory Setting: 0 Pr.07.10 and Pr.07.11 are used to record the motor operation time. They can be cleared by setting to 0 and time is less than 1 minute is not recorded. 07.12 Motor PTC Overheat Protection Unit: 1 Factory Setting: 0 Settings 07.
Chapter 4 Parameters| VFD-EL +10V resistor-divider R1 AVI 47kΩ PTC ACM internal circuit Refer to following calculation for protection level and warning level. 1. Protection level Pr.07.14= V+10 * (RPTC1//47K) / [R1+( RPTC1//47K)] 2. Warning level Pr.07.16= V+10 * (RPTC2//47K) / [R1+( RPTC2//47K)] 3. Definition: V+10: voltage between +10V-ACM, Range 10.4~11.2VDC RPTC1: motor PTC overheat protection level. Corresponding voltage level set in Pr.07.14, RPTC2: motor PTC overheat warning level.
Chapter 4 Parameters| resistor value ( Ω) 1330 550 Tr Tr-5℃ 07.15 Motor PTC Overheat Warning Level Settings 07.16 Unit: 0.1 0.1~10.0V Factory Setting: 1.2 Motor PTC Overheat Reset Delta Level Settings 07.17 temperature (℃) Tr+5℃ Unit: 0.1 0.1~5.0V Factory Setting: 0.6 Treatment of the motor PTC Overheat Factory Setting: 0 Settings 0 Warn and RAMP to stop 1 Warn and COAST to stop 2 Warn and keep running If temperature exceeds the motor PTC overheat warning level (Pr.07.
Chapter 4 Parameters| Group 8: Special Parameters 08.00 DC Brake Current Level Settings Unit: 1 0 to 100% Factory Setting: 0 This parameter sets the level of DC Brake Current output to the motor during start-up and stopping. When setting DC Brake Current, the Rated Current (Pr.00.01) is regarded as 100%. It is recommended to start with a low DC Brake Current Level and then increase until proper holding torque has been achieved. 08.01 DC Brake Time during Start-up Settings Unit: 0.1 0.0 to 60.
Chapter 4 Parameters| DC Brake during Start-up is used for loads that may move before the AC drive starts, such as fans and pumps. Under such circumstances, DC Brake can be used to hold the load in position before setting it in motion. DC Brake during stopping is used to shorten the stopping time and also to hold a stopped load in position. For high inertia loads, a brake resistor for dynamic brake may also be needed for fast decelerations. 08.
Chapter 4 Parameters| Output frequency (H) Input B.B. signal Output voltage(V) Disable B.B. signal Stop output voltage Waiting time 08.07 A 08.08 Current Limit for Speed SearchSpeed Speed Search Synchronization speed detection Time FWD Run B.B. Fig 1:B.B. Speed Search with Last Output Frequency Downward Timing Chart (Speed Search Current Attains Speed Search Level) Output frequency (H) Input B.B. signal Stop output voltage Disable B.B. signal Waiting time 08.07 08.
Chapter 4 Parameters| When momentary power loss is detected, the AC motor drive will block its output and then wait for a specified period of time (determined by Pr.08.07, called Base-Block Time) before resuming operation. This parameter should be set at a value to ensure that any residual regeneration voltage from the motor on the output has disappeared before the drive is activated again.
Chapter 4 Parameters| These parameters set the Skip Frequencies. It will cause the AC motor drive never to remain within these frequency ranges with continuous frequency output. These six parameters should be set as follows Pr.08.09 ≥ Pr.08.10 ≥ Pr.08.11 ≥ Pr.08.12 ≥ Pr.08.13 ≥ Pr.08.14. internal frequency command The frequency ranges may be overlapping. 08.15 08.09 08.10 08.11 08.12 08.13 08.
Chapter 4 Parameters| 08.17 Automatic Energy-saving Factory Setting: 0 Settings 0 Energy-saving operation disabled 1 Energy-saving operation enabled Output Voltage 100% 70% During auto-energy saving operation is the output voltage lowered as much as possible to keep the load. The output voltage is maximally lowered to 70% of the normal output voltage Output Frequency 08.
Chapter 4 Parameters| 08.19 08.20 Reserved Compensation Coefficient for Motor Instability Settings 0.0~5.0 Unit: 0.1 Factory Setting: 0.0 The drift current will occur in a specific zone of the motor and it will make motor instable. By using this parameter, it will improve this situation greatly. The drift current zone of the high-power motors is usually in the low frequency area. It is recommended to set to more than 2.0. Revision August 2008, 2ELE, V1.
Chapter 4 Parameters| Group 9: Communication Parameters There is a built-in RS-485 serial interface, marked RJ-45 near to the control terminals. The pins are defined below: 8 1 RS-485 Serial interface 3: GND 1: Reserved 2: EV 4: SG5: SG+ 6: Reserved 7: Reserved 8: Reserved Each VFD-EL AC motor drive has a pre-assigned communication address specified by Pr.09.00. The RS485 master then controls each AC motor drive according to its communication address. 09.
Chapter 4 Parameters| 09.03 Time-out Detection Settings Unit: 0.1 0.0 to 120.0 sec 0.0 Factory Setting: 0.0 Disable If Pr.09.03 is not equal to 0.0, Pr.09.02=0~2, and there is no communication on the bus during the Time Out detection period (set by Pr.09.03), “cE10” will be shown on the keypad. 09.
Chapter 4 Parameters| Character ASCII code ‘8’ 38H ‘9’ 39H ‘A’ 41H ‘B’ 42H ‘C’ 43H ‘D’ 44H ‘E’ 45H ‘F’ 46H RTU mode: Each 8-bit data is the combination of two 4-bit hexadecimal characters. For example, 64 Hex. 2. Data Format For ASCII: ( 7.N.2) Start bit 0 1 2 3 5 4 6 Stop bit Stop bit 7-bit character 10-bit character frame ( 7.E.1) Start bit 0 1 3 2 4 5 6 Even Stop parity bit 7-bit character 10-bit character frame ( 7.O.
Chapter 4 Parameters| For RTU: ( 8.N.2 ) Start bit 0 1 2 3 4 5 6 7 Stop Stop bit bit 6 7 Even Stop parity bit 6 7 8-bit character 11-bit character frame ( 8.E.1 ) Start bit 0 1 2 3 5 4 8-bit character 11-bit character frame ( 8.O.1 ) Start bit 0 1 2 3 5 4 Odd Stop parity bit 8-bit character 11-bit character frame ( 8.N.
Chapter 4 Parameters| LRC CHK Hi LRC check sum: LRC CHK Lo 8-bit check sum consists of 2 ASCII codes END Hi End characters: END Lo END1= CR (0DH), END0= LF(0AH) START A silent interval of more than 10 ms RTU mode: Address Communication address: 8-bit address Function Command code: 8-bit command DATA (n-1) to DATA 0 Contents of data: n×8-bit data, n<=40 (20 x 16-bit data) CRC CHK Low CRC check sum: CRC CHK High 16-bit check sum consists of 2 8-bit characters END A silent interval of mo
Chapter 4 Parameters| (1) 03H: multi read, read data from registers. Example: reading continuous 2 data from register address 2102H, AMD address is 01H.
Chapter 4 Parameters| CRC CHK Low 6FH CRC CHK High F7H Content of address 2103H 00H 00H CRC CHK Low FEH CRC CHK High 5CH (2) 06H: single write, write single data to register. Example: writing data 6000(1770H) to register 0100H. AMD address is 01H.
Chapter 4 Parameters| 17H Data content Data content 70H 17H 70H CRC CHK Low 86H CRC CHK Low 86H CRC CHK High 22H CRC CHK High 22H 3.4 Check sum ASCII mode: LRC (Longitudinal Redundancy Check) is calculated by summing up, module 256, the values of the bytes from ADR1 to last data character then calculating the hexadecimal representation of the 2’s-complement negation of the sum. For example, reading 1 word from address 0401H of the AC drive with address 01H.
Chapter 4 Parameters| RTU mode: Address 01H Function 03H Starting data address 21H 02H Number of data 00H (count by word) 02H CRC CHK Low 6FH CRC CHK High F7H CRC (Cyclical Redundancy Check) is calculated by the following steps: Step 1: Load a 16-bit register (called CRC register) with FFFFH. Step 2: Exclusive OR the first 8-bit byte of the command message with the low order byte of the 16-bit CRC register, putting the result in the CRC register. Step 3: Examine the LSB of CRC register.
Chapter 4 Parameters| for(j=0;j<8;j++){ if(reg_crc & 0x01){ /* LSB(b0)=1 */ reg_crc=(reg_crc>>1) ^ 0xA001; }else{ reg_crc=reg_crc >>1; } } } return reg_crc; } 3.5 Address list The contents of available addresses are shown as below: Content AC drive Parameters Address GGnnH Function GG means parameter group, nn means parameter number, for example, the address of Pr 04.01 is 0401H. Refer to chapter 5 for the function of each parameter.
Chapter 4 Parameters| Content Address Status monitor 2100H Function Error code: Read only 0: No error occurred 1: Over-current (oc) 2: Over-voltage (ov) 3: IGBT Overheat (oH1) 4: Reserved 5: Overload (oL) 6: Overload1 (oL1) 7: Overload2 (oL2) 8: External fault (EF) 9: Current exceeds 2 times rated current during accel (ocA) 10: Current exceeds 2 times rated current during decel (ocd) 11: Current exceeds 2 times rated current during steady state operation (ocn) 12: Ground Fault (GFF) Status monitor
Chapter 4 Parameters| Content Address Function 28: IGBT Overheat (cF3.
Chapter 4 Parameters| Content Address Function 2104H Output current (AXX.X) 2105H Reserved 2106H Display analog signal of PID feedback input terminal 2107H Reserved 2108H DC-BUS Voltage (UXXX.X) 2109H Output voltage (EXXX.X) 210AH Display temperature of IGBT (°C) 2116H User defined (Low word) 2117H User defined (High word) Note: 2116H is number display of Pr.00.04. High byte of 2117H is number of decimal places of 2116H. Low byte of 2117H is ASCII code of alphabet display of Pr.00.04.
Chapter 4 Parameters| Exception code ‘0’ ‘2’ LRC CHK Low ‘7’ LRC CHK High ‘7’ END 1 CR END 0 LF The explanation of exception codes: Exception Explanation code Illegal function code: 01 The function code received in the command message is not available for the AC motor drive. Illegal data address: 02 The data address received in the command message is not available for the AC motor drive.
Chapter 4 Parameters| #define BRDL 0x0000 #define IER 0x0001 #define BRDH 0x0001 #define LCR 0x0003 #define MCR 0x0004 #define LSR 0x0005 #define MSR 0x0006 unsigned char rdat[60]; /* read 2 data from address 2102H of AC drive with address 1 */ unsigned char tdat[60]={':','0','1','0','3','2','1','0',’2', '0','0','0','2','D','7','\r','\n'}; void main(){ int i; outportb(PORT+MCR,0x08); outportb(PORT+IER,0x01); /* interrupt enable */ /* interrupt as data in */ outportb(PORT+LCR,(inportb(PORT+LCR) | 0x80));
Chapter 4 Parameters| RS485 BUS Response Message of AC Drive PC command Handling time of AC drive Max.: 6msec Revision August 2008, 2ELE, V1.02 Response Delay Time Pr.09.
Chapter 4 Parameters| Group 10: PID Control 10.00 PID Set Point Selection Factory Setting: 0 Settings 10.01 0 Disable 1 Digital keypad UP/DOWN keys 2 AVI 0 ~ +10VDC 3 ACI 4 ~ 20mA 4 PID set point (Pr.10.
Chapter 4 Parameters| When P is greater than 1, it will decrease the deviation and get the faster response speed. But if setting too large value in Pr.10.02, it may cause the increased deviation during the stable area. NOTE The parameter can be set during operation for easy tuning. 10.03 Integral Time ( I ) Settings Unit: 0.01 0.00 to 100.0 sec 0.00 Factory Setting: 1.00 Disable This parameter specifies integral control (continual sum of the deviation) and associated gain (I).
Chapter 4 Parameters| This parameter defines an upper bound or limit for the integral gain (I) and therefore limits the Master Frequency. The formula is: Integral upper bound = Maximum Output Frequency (Pr.01.00) x (Pr.10.05). This parameter can limit the Maximum Output Frequency. 10.06 Unit: 0.1 Primary Delay Filter Time Settings 0.0 to 2.5 sec Factory Setting: 0.0 To avoid amplification of measurement noise in the controller output, a derivative digital filter is inserted.
Chapter 4 Parameters| 10.09 Treatment of the Erroneous Feedback Signals (for PID feedback error) Factory Setting: 0 Settings 0 Warning and RAMP to stop 1 Warning and COAST to stop 2 Warning and keep operating This function in only for ACI signal. AC motor drive action when the feedback signals (analog PID feedback) are abnormal according to Pr.10.16. 10.10 Gain Over the PID Detection Value Settings 0.0 to 10.0 Unit: 0.1 Factory Setting: 1.
Chapter 4 Parameters| When the actual frequency command > Pr.10.16 and the time exceeds the setting of Pr.10.14, the AC motor drive will restart. When the AC motor drive is in sleep mode, frequency command is still calculated by PID. When frequency reaches wake up frequency, AC motor drive will accelerate from Pr.01.05 minimum frequency following the V/f curve. The wake up frequency must be higher than sleep frequency. Frequency frequency calculated by PID 10.16 The limit of decel.
Chapter 4 Parameters| 10.17 Minimum PID Output Frequency Selection Factory Setting: 0 Settings 0 By PID control 1 By Minimum output frequency (Pr.01.05) This is the source selection of minimum output frequency when control is by PID. 10.18 PID Control Detection Signal Reference Settings Unit: 0.1 1.0 to 99.9 Factory Setting: 99.9 When Pr.00.04 is set to 8, it will display 00:00 as follows. This parameter is used only for display and has no relation with Pr.00.13, Pr.00.14, Pr.02.18 and Pr.02.
Chapter 4 Parameters| P 10.02 I + Setpoint 10.03 - In teg ra l g ain l imi t + 10.05 + + O utp ut Fr eq . L imi t 10.07 Di gi tal fi lte r 10.06 Fr eq . Co mman d D 10.04 In pu t Fre q. G ai n P ID fe ed ba ck 10.01 10.10 10.20 Treatment of the Erroneous PID Feedback Level Factory Setting: 0 Settings 0 Keep operating 1 Coast to stop 2 Ramp to stop 3 Ramp to stop and restart after time set in Pr.10.21 In PID control mode, it will act according to Pr.10.
Chapter 4 Parameters| Example: suppose that the set point of constant pressure control of a pump is 4kg, Pr.10.22 is set to 5%, Pr.10.23 is set to 15 seconds. It means that deviation is 0.2kg (4kgX5%=0.2kg), i.e. when feedback value is higher than 3.8kg for a time exceeding 15 seconds, the AC motor drive will decelerate to stop (this deceleration time will act according to Pr.01.12). When the feedback value is less than 3.8kg, the AC motor drive will start to run. 10.
Chapter 4 Parameters| Example: suppose that the set point of constant pressure control of a pump is 4kg, Pr.10.22 is set to 5%, Pr.10.23 is set to 15 seconds, Pr.10.24 is set to 25%, Pr.10.25 is set to 3% and Pr.10.26 is set to 0.5 seconds. It means that offset is 0.2kg (4kgX5%=0.2kg), i.e. when feedback value is higher than 3.8kg for a time exceeding 15 seconds, the AC motor drive will decelerate to stop (this deceleration time will act according to Pr.01.12). When the feedback value is less than 3.
Chapter 5 Troubleshooting 5.
Chapter 5 Troubleshooting| 5.2 Ground Fault Is output circuit(cable or motor) of AC motor drive grounded? GFF Ground fault Maybe AC motor drive has malfunction or misoperation due to noise. Please contact DELTA. No Yes Remove ground fault 5.3 Over Voltage (OV) Over voltage No Reduce voltage to be within spec. Is voltage within specification Yes Has over-voltage occurred without load Maybe AC motor drive has malfunction or misoperation due to noise. Please contact with DELTA.
Chapter 5 Troubleshooting| 5.
Chapter 5 Troubleshooting| 5.5 Over Heat (OH1) AC motor drive ov erheats Heat sink overheats No Chec k if temperature of heat sink is greater than 90 O C Temperature detection malfunctions. Please c ontact D ELTA. Yes Yes Is load too large Reduce load No If cooling fan functions normally No Change cooling f an Yes Chec k if cooling f an is jammed Yes Remove obstruct ion No Maybe AC motor drive has malfunction or misoperation due to noise. Please contact DELTA.
Chapter 5 Troubleshooting| 5.7 Keypad Display is Abnormal Abnormal display or no display Yes Cycle power to AC motor drive Fix connector and eliminate noise No No Display normal? Check if all connectors are connect correctly and no noise is present Yes Yes AC motor drive works normally AC motor drive has malfunction. Please contact DELTA. 5.
Chapter 5 Troubleshooting| 5.
Chapter 5 Troubleshooting| 5.10 Motor Speed cannot be Changed Motor can run but cannot change speed Yes Modify the setting No Check if the setting of the max. frequency is too low No If the setting of frequency Yes is out of range(upper/lower) bound No Press UP/DOWN key Yes to see if speed has any change No Yes If there is any change of the signal that sets Yes frequency (0-10V and 4-20mA) If the setting of Pr.05-00 to Pr.
Chapter 5 Troubleshooting| 5.
Chapter 5 Troubleshooting| 5.13 Electromagnetic/Induction Noise Many sources of noise surround AC motor drives and penetrate it by radiation or conduction. It may cause malfunctioning of the control circuits and even damage the AC motor drive. Of course, there are solutions to increase the noise tolerance of an AC motor drive. But this has its limits. Therefore, solving it from the outside as follows will be the best. 1. 2. Add surge suppressor on the relays and contacts to suppress switching surges.
Chapter 5 Troubleshooting| 4. Store within a relative humidity range of 0% to 90% and non-condensing environment. Use an air conditioner and/or exsiccator. 5.15 Affecting Other Machines An AC motor drive may affect the operation of other machines due to many reasons. Some solutions are: High Harmonics at Power Side High harmonics at power side during running can be improved by: 1. Separate the power system: use a transformer for AC motor drive. 2.
Chapter 6 Fault Code Information and Maintenance 6.1 Fault Code Information The AC motor drive has a comprehensive fault diagnostic system that includes several different alarms and fault messages. Once a fault is detected, the corresponding protective functions will be activated. The following faults are displayed as shown on the AC motor drive digital keypad display. The five most recent faults can be read from the digital keypad or communication.
Chapter 6 Fault Code Information and Maintenance| Fault Name Fault Descriptions Corrective Actions 1. 2. Overheating Heat sink temperature too high 3. 4. 5. Low voltage The AC motor drive detects that the DC bus voltage has fallen below its minimum value. Overload The AC motor drive detects excessive drive output current. NOTE: The AC motor drive can withstand up to 150% of the rated current for a maximum of 60 seconds. Overload 1 Internal electronic overload trip Overload 2 Motor overload. 1. 2. 3.
Chapter 6 Fault Code Information and Maintenance| Fault Name Fault Descriptions Corrective Actions 1. 2. Over-current during acceleration 3. 4. 1. Over-current during deceleration 2. 3. 1. Over-current during constant speed operation 2. 3. 1. External Fault 2. Short-circuit at motor output: Check for possible poor insulation at the output lines. Torque boost too high: Decrease the torque compensation setting in Pr.07.02. Acceleration Time too short: Increase the Acceleration Time.
Chapter 6 Fault Code Information and Maintenance| Fault Name Fault Descriptions Ground fault Auto accel/decel failure Communication Error Corrective Actions When (one of) the output terminal(s) is grounded, short circuit current is more than 50% of AC motor drive rated current, the AC motor drive power module may be damaged. NOTE: The short circuit protection is provided for AC motor drive protection, not for protection of the user. 1. Check whether the IGBT power module is damaged. 2.
Chapter 6 Fault Code Information and Maintenance| 6.1.2 Reset There are three methods to reset the AC motor drive after solving the fault: 1. 2. Press key on keypad. Set external terminal to “RESET” (set one of Pr.04.05~Pr.04.08 to 05) and then set to be ON. 3. Send “RESET” command by communication. NOTE Make sure that RUN command or signal is OFF before executing RESET to prevent damage or personal injury due to immediate operation. 6.
Chapter 6 Fault Code Information and Maintenance| DANGER! 1. 2. Disconnect AC power before processing! Only qualified personnel can install, wire and maintain AC motor drives. Please take off any metal objects, such as watches and rings, before operation. And only insulated tools are allowed. 3. Never reassemble internal components or wiring. 4. Prevent static electricity.
Chapter 6 Fault Code Information and Maintenance| Keypad Check Items Methods and Criterion Maintenance Period Daily Is the display clear for reading? Visual inspection { Any missing characters? Visual inspection { Half One Year Year Mechanical parts Check Items Methods and Criterion Maintenance Period Daily Half One Year Year If there is any abnormal sound or vibration Visual and aural inspection { If there are any loose screws Tighten the screws { If any part is deformed or damaged
Chapter 6 Fault Code Information and Maintenance| Terminals and wiring of main circuit Check Items Methods and Criterion Maintenance Period Daily Half One Year Year If the wiring shows change of color change or deformation due to overheat Visual inspection { If the insulation of wiring is damaged or the color has changed Visual inspection { If there is any damage Visual inspection { DC capacity of main circuit Check Items Methods and Criterion Maintenance Period Daily If there is any leak
Chapter 6 Fault Code Information and Maintenance| Transformer and reactor of main circuit Maintenance Period Check Items Methods and Criterion Daily If there is any abnormal vibration or peculiar smell Visual, aural inspection and smell Half One Year Year { Magnetic contactor and relay of main circuit Maintenance Period Check Items Methods and Criterion Daily If there are any loose screws Visual and aural inspection. Tighten screw if necessary.
Chapter 6 Fault Code Information and Maintenance| Cooling fan of cooling system Maintenance Period Check Items Methods and Criterion Daily Half One Year Year If there is any abnormal sound or vibration Visual, aural inspection and turn the fan with hand (turn off the power before operation) to see if it rotates smoothly { If there is any loose screw Tighten the screw { If there is any change of color due to overheating Change fan { Ventilation channel of cooling system Maintenance Period Check
Appendix A Specifications There are 115V, 230V and 460V models in the VFD-EL series. For 115V models, it is 1-phase models. For 0.25 to 3HP of the 230V models, there are 1-phase/3-phase models. Refer to following specifications for details. Voltage Class 115V Class 002 004 007 Max. Applicable Motor Output (kW) 0.2 0.4 0.75 Max. Applicable Motor Output (hp) 0.25 0.5 1.0 0.6 1.6 1.0 2.5 1.6 4.
Appendix A Specifications| Voltage Class 460V Class 004 007 015 022 Max. Applicable Motor Output (kW) 0.4 0.75 1.5 2.2 3.7 Max. Applicable Motor Output (hp) 0.5 1.0 2.0 3.0 5.0 Input Rating Output Rating Model Number VFD-XXXEL 037 Rated Output Capacity (kVA) 1.2 2.0 3.3 4.4 6.8 Rated Output Current (A) 1.5 2.5 4.2 5.5 8.2 Maximum Output Voltage (V) Output Frequency (Hz) Carrier Frequency (kHz) Rated Input Current (A) 3-Phase Proportional to Input Voltage 1.8 3.
Appendix A Specifications| General Specifications Operation Functions AVR, accel/decel S-Curve, over-voltage/over-current stall prevention, 5 fault records, reverse inhibition, momentary power loss restart, DC brake, auto torque/slip compensation, auto tuning, adjustable carrier frequency, output frequency limits, parameter lock/reset, PID control, external counter, MODBUS communication, abnormal reset, abnormal re-start, power-saving, fan control, sleep/wake frequency, 1st/2nd frequency source selections
Appendix A Specifications| This page intentionally left blank A-4 Revision August 2008, 2ELE, V1.
Appendix B Accessories B.1 All Brake Resistors & Brake Units Used in AC Motor Drives Note: Please only use DELTA resistors and recommended values. Other resistors and values will void Delta’s warranty. Please contact your nearest Delta representative for use of special resistors. The brake unit should be at least 10 cm away from AC motor drive to avoid possible interference. Refer to the “Brake unit Module User Manual” for further details.
Appendix B Accessories| 460V Series Voltage Applicable Motor Full Load Models Torque Min. Equivalent Equivalent Brake Unit Brake Brake Resistor Resistor Resistors Model BUE Torque Value for Value Model and No. each AC No. of Units 10%ED (suggestion) of Units Used Motor Used Drive hp kW 0.5 0.4 VFD004EL43A 0.216 300W 400Ω BUE40015 1 BR300W400 1 400 400Ω 1 0.75 VFD007EL43A 0.427 300W 400Ω BUE40015 1 BR300W400 1 200 200Ω 2 1.5 VFD015EL43A 0.
Appendix B Accessories| 100% Braking Time T1 ED% = T1/T0x100(%) Cycle Time 9. T0 For safety reasons, install a thermal overload relay between brake unit and brake resistor. Together with the magnetic contactor (MC) in the mains supply circuit to the drive it offers protection in case of any malfunctioning.
Appendix B Accessories| B.1.1 Dimensions and Weights for Brake Resistors (Dimensions are in millimeter) Order P/N: BR080W200, BR080W750, BR300W100, BR300W250, BR300W400, BR400W150, BR400W040 Model no. L1 L2 H D W Max. Weight (g) 140 125 20 5.3 60 160 BR200W150 165 150 40 5.3 BR200W250 165 150 40 5.3 215 200 30 5.3 60 750 265 250 30 5.3 60 930 BR080W200 BR080W750 BR300W100 BR300W250 BR300W400 BR400W150 BR400W040 B-4 Revision August 2008, 2ELE, V1.
Appendix B Accessories| Order P/N: BR500W030, BR500W100, BR1KW020, BR1KW075 Model no. L1 L2 H D W Max. Weight (g) 335 320 30 5.3 60 1100 400 385 50 5.3 100 2800 BR500W030 BR500W100 BR1KW020 BR1KW075 Revision August 2008, 2ELE, V1.
Appendix B Accessories| Order P/N: BR1K0W050 Order P/N: BR1K0W050, BR1K2W008, BR1K2W6P8, BR1K5W005, BR1K5W040 B-6 Revision August 2008, 2ELE, V1.
Appendix B Accessories| B.2 No Fuse Circuit Breaker Chart For 1-phase/3-phase drives, the current rating of the breaker shall be within 2-4 times rated input current.
Appendix B Accessories| B.3 Fuse Specification Chart Smaller fuses than those shown in the table are permitted. B-8 Line Fuse I (A) I (A) Input Output I (A) Bussmann P/N VFD002EL11A 6.4 1.6 15 JJN-15 VFD002EL21A 4.9 1.6 10 JJN-10 VFD002EL23A 1.9 1.6 5 JJN-6 Model VFD004EL11A 9 2.5 20 JJN-20 VFD004EL21A 6.5 2.5 15 JJN-15 VFD004EL23A 2.7 2.5 5 JJN-6 VFD004EL43A 1.8 1.5 5 JJS-6 VFD007EL11A 18 4.2 30 JJN-30 VFD007EL21A 9.3 4.2 20 JJN-20 VFD007EL23A 4.
Appendix B Accessories| B.4 AC Reactor B.4.1 AC Input Reactor Recommended Value 230V, 50/60Hz, 1-Phase kW HP Fundamental Amps 0.2 1/4 0.4 1/2 0.75 Inductance (mH) Max. continuous Amps 3~5% impedance 4 6 6.5 5 7.5 3 1 8 12 1.5 1.5 2 12 18 1.25 2.2 3 18 27 0.8 460V, 50/60Hz, 3-Phase kW HP Fundamental Amps Max. continuous Amps 3% impedance 5% impedance 0.4 1/2 2 3 20 32 0.75 1 4 6 9 12 1.5 2 4 6 6.5 9 2.2 3 8 12 5 7.5 3.
Appendix B Accessories| 460V, 50/60Hz, 3-Phase kW HP Fundamental Amps Max. continuous Amps 3% impedance 5% impedance Inductance (mH) 0.4 1/2 2 3 20 32 0.75 1 4 6 9 12 1.5 2 4 6 6.5 9 2.2 3 8 12 5 7.5 3.7 5 12 18 2.5 4.2 B.4.
Appendix B Accessories| Application 2 Silicon rectifier and AC motor drive are connected to the same power. Question Switching spikes will be generated when the silicon rectifier switches on/off. These spikes may damage the mains circuit. Correct wiring Silicon Controlled Rectifier power reactor DC AC motor drive reactor motor Application 3 Question Used to improve the input power factor, to reduce harmonics and provide protection from AC line disturbances.
Appendix B Accessories| B.5 Zero Phase Reactor (RF220X00A) Dimensions are in millimeter and (inch) Cable type (Note) Singlecore Threecore Recommended Wire Size AWG mm2 ≦10 ≦5.3 Nominal (mm2) ≦5.5 Qty. Wiring Method 1 Diagram A ≦2 ≦33.6 ≦38 4 Diagram B ≦12 ≦3.3 ≦3.5 1 Diagram A ≦1 ≦42.4 ≦50 4 Diagram B Note: 600V Insulated unshielded Cable. Diagram A Please wind each wire 4 times around the core. The reactor must be put at inverter output as close as possible.
Appendix B Accessories| B.6 Remote Controller RC-01 Dimensions are in millimeter 8 6 5 4 16 15 14 13 11 RC-01Terminal block (Wiring connections) AFM ACM AVI +10V DCM MI5 MI1 MI2 MI6 VFD-EL I/O block VFD-EL Programming: Pr.02.00 set to 2 Pr.02.01 set to 1 (external controls) Pr.04.04 set to 1 (setting Run/Stop and Fwd/Rev controls) Pr.04.07 (MI5) set to 5 (External reset) Pr.04.08 (MI6) set to 8 (JOG operation) Revision August 2008, 2ELE, V1.
Appendix B Accessories| B.7 PU06 B.7.1 Description of the Digital Keypad VFD-PU06 LED Display Indicates frequency, voltage, current, user defined units, read, and save, etc. Frequency Command Status indicator Output Frequency Status indicator F H U Model Number VFD-PU06 User Defined Units Status indicator EXT PU JOG By pressing JOG key, Jog frequency operation. UP and DOWN Key Set the parameter number and changes the numerical data, such as Master Frequency.
Appendix B Accessories| Display Message Descriptions The specified parameter setting. The actual value stored in the specified parameter. External Fault “End” displays for approximately 1 second if the entered input data have been accepted. After a parameter value has been set, the new value is automatically stored in memory. To modify an entry, use the or keys. “Err” displays if the input is invalid. Communication Error.
Appendix B Accessories| B.8 Fieldbus Modules B.8.1 DeviceNet Communication Module (CME-DN01) B.8.1.1 Panel Appearance and Dimensions 1. For RS-485 connection to VFD-EL 2. Communication port for connecting DeviceNet network 3. Address selector 4. Baud rate selector 5. Three LED status indicators for monitor. (Refer to the figure below) 3 4 125K 5 250K ADD1 ADD2 BAUD NETMOD SP CME-DN01 2 72.2 [2.84] 57.3 [2.26] 14.3 [0.57] 59.7 [2.35] 500K 1 35.8 [1.41] 3.5 [0.14] UNIT: mm(inch) B.8.1.
Appendix B Accessories| B.8.1.3 Power Supply No external power is needed. Power is supplied via RS-485 port that is connected to VFD-EL. An 8 pins RJ-45 cable, which is packed together with this communication module, is used to connect the RS-485 port between VFD-EL and this communication module for power. This communication module will perform the function once it is connected. Refer to the following paragraph for LED indications. B.8.1.4 LEDs Display 1.
Appendix B Accessories| B.8.2.3 Specifications Power supply: 16-30VDC, 750mW Communication: Modbus in ASCII format, protocol: 9600, 7, N, 2 LonTalk: free topology with FTT-10A 78 Kbps. LonTalk terminal: 4-pin terminals, wire gauge: 28-12 AWG, wire strip length: 7-8mm RS-485 port: 8 pins with RJ-45 B.8.2.
Appendix B Accessories| B.8.3 Profibus Communication Module (CME-PD01) B.8.3.1 Panel Appearance Address Switches NET LED SP LED ADDH AD DL N ET SP CME-P B01 RS-485 (RJ45) 1: Reserved 2: EV 3: GND 4: SG5: SG+ 6: Reserved 7: Reserved 8: Reserved Profibus-DP Interface (DB9) 1. SP LED: Indicating the connection status between VFD-EL and CME-PD01. 2. NET LED: Indicating the connection status between CME-PD01 and PROFIBUS-DP. 3.
Appendix B Accessories| B.8.3.2 Dimensions ADDH A DDL NET SP CME-P B01 57.3 [2.26] 59.7 [2.35] 3.6 [0.14] 72.2 [2.84] 34.8 [1.37] UNIT: mm(inch) B.8.3.3 Parameters Settings in VFD-EL VFD-EL Baud Rate 9600 Pr.09.01=1 RTU 8, N, 2 Pr.09.03=3 Freq. Source Pr.02.00=4 Command Source Pr.02.01=3 B.8.3.4 Power Supply The power of CME-PD01 is supplied from VFD-EL. Please connect VFD-EL to CME-PD01 by using 8 pins RJ-45 cable, which is packed together with CME-PD01.
Appendix B Accessories| Address Meaning 1..0x7D Valid PROFIBUS address 0 or 0x7E..0xFE Invalid PROFIBUS address B.8.4 CME-COP01 (CANopen) CME-COP01 CANopen communication module is specifically for connecting to CANopen communication module of Delta VFD-EL AC motor drive. B.8.4.1 Product Profile 7 6 3 4 5 2 c COM port d CANopen connection port e RUN indicator f ERROR indicator g SP (Scan Port) indicator h Baud rate switch i Address switch 1 Unit: mm B.8.4.
Appendix B Accessories| Communication Process Data Objects (PDO) Service Data Object (SDO) Baud Message type Synchronization rate (SYNC) Emergency (EMCY) Network Management (NMT) Product code Delta VFD-EL AC motor drive 22 Device type 402 Vendor ID 477 10 Kbps 20 Kbps 50 Kbps 125 Kbps 250 Kbps 500 Kbps 800 Kbps 1 Mbps Environmental Specifications ESD(IEC 61131-2, IEC 61000-4-2): 8KV Air Discharge EFT(IEC 61131-2, IEC 61000-4-4): Power Line: 2KV, Digital I/O: 1KV, Noise Immunity Analog & Communication I/O
Appendix B Accessories| Example: If you need to set up the communication speed of CME-COP01 as 500K, simply switch BR to “5”. BR Value Baud rate BR Value Baud rate 0 10K 4 250K 1 20K 5 500K 2 50K 6 800K 3 125K 7 1M MAC ID Setting 789 BCD 345 6 BCD 345 789 A 6 A 012 EF 012 EF Rotary switches (ID_L and ID_H) set up the Node-ID on CANopen network in hex.
Appendix B Accessories| ERROR LED LED Status OFF Single Flash (Red) Double Flash (Red) Red ON State Indication No error CME-COP01 is working condition Warning limit reached At least one of error counter of the CANopen controller has reached or exceeded the warning level (too many error frames) Error control event A guard event or heartbeat event has occurred Bus-off The CANopen controller is bus-off SP LED LED Status State Indication OFF No Power No power on CME-COP01 card LED Blinking (Re
Appendix B Accessories| B.9 MKE-EP & DIN Rail B.9.1 MKE-EP EMC earthing plate for Shielding Cable C CLAMP Revision August 2008, 2ELE, V1.
Appendix B Accessories| B.9.2 DIN Rail: MKEL-DRA (Only for frame A) Dimensions This DIN rail (MKEL-DRA) is only for frame A. For frame B, it is shipped with DIN rail (MKEL-DRB). Refer to chapter 1.3 for VFD-EL dimension. NOTE Frame A: VFD002EL11A/21A/23A, VFD004EL11A/21A/23A/43A, VFD007EL21A/23A/43A, VFD015EL23A/43A Frame B: VFD007EL11A, VFD015EL21A, VFD022EL21A/23A/43A, VFD037EL23A/43A B-26 Revision August 2008, 2ELE, V1.
Appendix C How to Select the Right AC Motor Drive The choice of the right AC motor drive for the application is very important and has great influence on its lifetime. If the capacity of AC motor drive is too large, it cannot offer complete protection to the motor and motor maybe damaged. If the capacity of AC motor drive is too small, it cannot offer the required performance and the AC motor drive maybe damaged due to overloading.
Appendix C How to Select the Right AC Motor Drive| C.1 Capacity Formulas 1. When one AC motor drive operates one motor The starting capacity should be less than 1.5x rated capacity of AC motor drive The starting capacity= ⎛ k×N GD 2 N ⎞ ⎜ TL + × ⎟ ≤ 1.5 × the _ capacity _ of _ AC _ motor _ drive ( kVA) 973 × η × cos ϕ ⎜⎝ 375 t A ⎟⎠ 2. When one AC motor drive operates more than one motor 2.
Appendix C How to Select the Right AC Motor Drive| 2.
Appendix C How to Select the Right AC Motor Drive| C.2 General Precaution Selection Note 1. When the AC Motor Drive is connected directly to a large-capacity power transformer (600kVA or above) or when a phase lead capacitor is switched, excess peak currents may occur in the power input circuit and the converter section may be damaged. To avoid this, use an AC input reactor (optional) before AC Motor Drive mains input to reduce the current and improve the input power efficiency. 2.
Appendix C How to Select the Right AC Motor Drive| required time, either use an external brake resistor and/or brake unit, depending on the model, (to shorten deceleration time only) or increase the capacity for both the motor and the AC Motor Drive. C.3 How to Choose a Suitable Motor Standard motor When using the AC Motor Drive to operate a standard 3-phase induction motor, take the following precautions: 1. 2. The energy loss is greater than for an inverter duty motor.
Appendix C How to Select the Right AC Motor Drive| 7. Motor torque characteristics vary when an AC Motor Drive instead of commercial power supply drives the motor. Check the load torque characteristics of the machine to be connected. 8. Because of the high carrier frequency PWM control of the VFD series, pay attention to the following motor vibration problems: Resonant mechanical vibration: anti-vibration (damping) rubbers should be used to mount equipment that runs at varying speed.
Appendix C How to Select the Right AC Motor Drive| motor drive operates more than one motor, please pay attention to starting and changing the motor. Power Transmission Mechanism Pay attention to reduced lubrication when operating gear reduction motors, gearboxes, belts and chains, etc. over longer periods at low speeds. At high speeds of 50/60Hz and above, lifetime reducing noises and vibrations may occur.
Appendix C How to Select the Right AC Motor Drive| This page intentionally left blank. C-8 Revision August 2008, 2ELE, V1.