What does user-defined fault 2 mean for Inovance MD380T3.7GB DC Drives?
If your Inovance DC Drive reports a 'User-defined fault 2', it means the user-defined fault 2 signal is being input via DI or virtual I/O. To resolve this, reset the operation.
Why does Inovance MD380T3.7GB have overcurrent during acceleration?
When an Inovance DC drive experiences overcurrent during acceleration, it may be due to a grounded or short-circuited output circuit, failure to perform motor auto-tuning, an excessively short acceleration time, an inappropriate manual torque boost or V/F curve, low voltage, starting a rotating motor, a sudden load during acceleration, or an undersized AC drive. To address this, eliminate external faults, perform motor auto-tuning, increase the acceleration time, adjust the manual torque boost or V/F curve, correct the voltage, use rotational speed tracking restart or wait for the motor to stop before starting, remove the added load, or select an AC drive with a higher power class.
What to do if Inovance DC Drives show overcurrent at constant speed?
If you observe overcurrent at constant speed in Inovance DC Drives, it could be caused by a grounded or short-circuited output circuit, failure to perform motor auto-tuning, low voltage, a sudden load during operation, or an AC drive model with insufficient power. To fix this, eliminate any external faults, perform motor auto-tuning, ensure the voltage is within the normal range, remove any added loads, or choose an AC drive with a higher power class.
Why does Inovance MD380T3.7GB have overvoltage during deceleration?
If overvoltage occurs during deceleration in Inovance DC Drives, it could be due to high input voltage, an external force driving the motor, a deceleration time that is too short, or the absence of a braking unit and resistor. To solve this, adjust the voltage to the normal range, eliminate the external force or install a braking resistor, increase the deceleration time, or install the braking unit and braking resistor.
What does accumulative power-on time reached mean for Inovance MD380T3.7GB DC Drives?
If your Inovance DC Drive indicates that the 'Accumulative power-on time reached', it signifies that the preset power-on time has been reached. Clear the record by using the parameter initialization function.
What causes initial position fault in Inovance DC Drives?
If your Inovance DC Drive shows an initial position fault, it means the motor parameters are not set based on the actual situation. Check that the motor parameters are set correctly and verify that the setting of rated current is not too small.
What does AC drive hardware fault mean in Inovance DC Drives?
If your Inovance DC Drive displays an 'AC drive hardware fault', it indicates either an overvoltage or overcurrent condition. Address the issue based on the specific overvoltage or overcurrent troubleshooting steps.
What causes pulse-by-pulse current limit fault in Inovance DC Drives?
If your Inovance DC Drive is experiencing a pulse-by-pulse current limit fault, it could be due to an excessively heavy load, a locked rotor on the motor, or an AC drive model with insufficient power. To fix this, reduce the load and check the motor and mechanical condition, or select an AC drive of higher power class.
What causes EEPROM read- write fault in Inovance MD380T3.7GB DC Drives?
If your Inovance DC Drive displays an EEPROM read-write fault, it indicates that the EEPROM chip is damaged. Replace the main control board to resolve this.
What causes power input phase loss in Inovance MD380T3.7GB?
If your Inovance DC Drives show power input phase loss, it could be due to an abnormal three-phase power input, a faulty drive board, a faulty lightening board, or a faulty main control board. To address this, eliminate external faults or contact Inovance or their agent.
Covers various voltage classes supported by the MD380 series AC drive.
Details the supported control modes like SVC, CLVC, and V/F control.
Explains the enhanced SVC algorithm for improved stability and torque.
Essential guidelines for safe installation, operation, and maintenance of the AC drive.
Specific safety precautions graded by danger level for installation and wiring.
General safety advice covering RCD, motor insulation, thermal protection, and vibration.
Explains the model designation rules and the information on the product nameplate.
Lists the key technical specifications of the MD380 series AC drive.
Guidelines for physically installing the AC drive, including environment and clearance.
Instructions for electrical wiring, including main and control circuit terminals.
Overview of the operation panel, including indicators, display, and keys.
Explains how to navigate and change function codes and parameters.
Guides on setting motor parameters and performing auto-tuning for optimal performance.
Comprehensive table listing all function codes, parameter names, and ranges.
Details of standard function parameters, including setting ranges and defaults.
Detailed explanations of each function code group and parameter.
Explanations of fundamental parameters related to motor control and frequency sources.
Parameters for configuring motor overload, voltage, current, and other protection mechanisms.
Overview of EMC standards and compliance requirements for the MD380 drive.
Guidance on selecting necessary peripheral devices like input filters and reactors for EMC compliance.
Addresses issues related to current leakage and provides solutions for circuit breaker tripping.
Comprehensive guide to selecting the correct MD380 model and understanding its physical dimensions.
Provides physical dimensions and mounting hole details for different MD380 housing types.
Recommendations for cable selection and installation dimensions for power terminals.
Comprehensive guide for maintaining the MD380 drive and resolving common issues.
Procedures for routine maintenance and periodic inspection to ensure optimal performance.
A detailed guide to common faults, their possible causes, and recommended solutions for troubleshooting.
General| Power | 3.7 kW |
|---|---|
| Voltage | 380V |
| Frequency Range | 0-400 Hz |
| Storage Temperature | -20°C to +60°C |
| Control Mode | V/F control, vector control |
| Protection Features | Overcurrent, Overvoltage, Undervoltage, Overload, Short circuit, Overheating |
| Cooling Method | Forced air cooling |
| Humidity | 5% to 95% (non-condensing) |
| Altitude | Below 1000 m |
To Next Page