To Next PageTo Next PageWhat does encoder initial communication error 2 mean on Mitsubishi MR-J4-200A?
Encoder initial communication error 2 on your Mitsubishi Amplifier can indicate an encoder malfunction or a load-side encoder malfunction.
What causes encoder initial communication error 1 on Mitsubishi MR-J4-200A?
Encoder initial communication error 1 on your Mitsubishi Amplifier can be caused by: * Encoder initial communication - Receive data error 1. * Encoder initial communication - Receive data error 2. * Encoder initial communication - Receive data error 3. * Encoder initial communication - Transmission data error 1. * Encoder initial communication - Transmission data error 2. * Encoder initial communication - Transmission data error 3. * Encoder initial communication - Process error 1. * Encoder initial communication - Process error 2. * Encoder initial communication - Process error 3. * Encoder initial communication - Process error 4. * Encoder initial communication - Process error 5. * Encoder initial communication - Process error 6.
Why does my Mitsubishi MR-J4-200A Amplifier show an overvoltage error?
An overvoltage error in your Mitsubishi Amplifier is due to a main circuit voltage error.
What does memory error 2 mean on Mitsubishi MR-J4-200A?
Memory error 2 (EEP-ROM) on your Mitsubishi Amplifier can occur due to: * EEP-ROM error at power on. * EEP-ROM error during operation.
What causes encoder normal communication error 1 on Mitsubishi MR-J4-200A Amplifier?
Encoder normal communication error 1 on your Mitsubishi Amplifier can be caused by: * Encoder normal communication - Receive data error 1. * Encoder normal communication - Receive data error 2. * Encoder normal communication - Receive data error 3. * Encoder normal communication - Transmission data error 1. * Encoder normal communication - Transmission data error 2. * Encoder normal communication - Transmission data error 3. * Encoder normal communication - Receive data error 4. * Encoder normal communication - Receive data error 5.
What does encoder normal communication error 2 mean on Mitsubishi MR-J4-200A?
Encoder normal communication error 2 on your Mitsubishi Amplifier can be caused by: * Encoder data error 1. * Encoder data update error. * Encoder data waveform error. * Encoder non-signal error. * Encoder hardware error 1. * Encoder hardware error 2. * Encoder data error 2.
What causes a servo control error on my Mitsubishi MR-J4-200A Amplifier?
A servo control error on your Mitsubishi Amplifier (specifically for linear servo motors and direct drive motors) can be caused by: * Servo control error by position deviation. * Servo control error by speed deviation. * Servo control error by torque/thrust deviation. * Fully closed loop control error by position deviation. * Fully closed loop control error by speed deviation. * Fully closed loop control error by position deviation during command stop.
What does a board error on my Mitsubishi MR-J4-200A Amplifier mean?
A board error on your Mitsubishi Amplifier indicates: * Board error 1. * Board error 2. * Board error 3.
What causes a regenerative error in my Mitsubishi MR-J4-200A Amplifier?
A regenerative error in your Mitsubishi Amplifier can stem from: * Regeneration heat error. * Regeneration signal error. * Regeneration feedback signal error.
What does parameter error mean on my Mitsubishi MR-J4-200A Amplifier?
A parameter error on your Mitsubishi Amplifier indicates either a parameter setting range error or a parameter combination error.
General| Type | AC Servo Amplifier |
|---|---|
| Series | MR-J4 |
| Model | MR-J4-200A |
| Rated Output | 2.0 kW |
| Voltage Class | 200 V |
| Position Control | Yes |
| Speed Control | Yes |
| Torque Control | Yes |
| Full-closed control | Yes |
| STO | Yes |
| Communication | SSCNET III/H |
| Protection functions | Overcurrent, Overvoltage, Overheating |
| Ambient Temperature | 0 to 55 °C |
| Ambient Humidity | 90% RH or less (non-condensing) |
| Vibration Resistance | 5.9 m/s² (0.6 G) at 10-55 Hz |
| Cooling Method | Natural Cooling |
Crucial safety instructions to prevent electric shock during wiring, operation, and inspection.
Safety precautions to prevent fire hazards related to installation and component usage.
Details regarding the input power supply circuit requirements and connection for various voltage classes.
Provides examples of connecting I/O signals for different control modes like position, speed, and torque.
Explains the forced stop deceleration function (SS1) and its connection requirements.
Illustrates timing charts for alarm occurrences, showing the sequence of events.
Provides essential guidelines for proper grounding of the servo amplifier and motor to prevent electrical shock.
Detailed technical specifications for the MR-J4 servo amplifier series, including voltage, current, and performance.
Outlines the procedure for initial power-on startup.
Details the critical checks required for power supply and motor wiring before initial power-on.
Provides detailed explanations for various parameter groups, including basic, gain/filter, extension, and I/O settings.
Discusses various methods for adjusting servo gains, including auto tuning and manual modes.
Explains how to perform automatic gain adjustment using one-touch tuning via software or push buttons.
Covers auto tuning modes 1 and 2, including their operating principles and parameter adjustments.
Describes functions that allow continued operation even under alarm conditions, including vibration and power failure tough drive.
Illustrates overload protection characteristics for various servo motors and their combinations with servo amplifiers.
Explains dynamic brake operation, including coasting distance calculation and time constants.
Outlines the specifications and system requirements for using MR Configurator2 software.
Explains the selection and connection of external dynamic brakes for specific servo amplifier models.
Outlines the step-by-step procedure for starting up the absolute position detection system.
Details the protocol for transferring absolute position data between the servo amplifier and controller.
Lists and explains potential errors during absolute position data transfer.
Outlines residual risks associated with the STO function and manufacturer responsibilities.
Lists the specifications related to functional safety, performance, and CE marking of the STO function.
Details the STO I/O signal connector (CN8) and its pin configurations for signal layouts.
Illustrates connection examples for the STO function using safety logic units and relays.
Details crucial precautions for using communication functions to prevent electrical shock and equipment malfunction.
Provides detailed explanations of command processing, including data conversion and examples.
Covers essential safety precautions, wiring guidelines, and signal explanations for linear servo motors.
Covers safety precautions, wiring guidelines, and signal explanations for direct drive motors.
Explains the requirements and procedures for absolute position detection with direct drive motors.
Shows representative electrical installation and configuration examples for 200V and 400V class servo amplifiers.
Lists technical data for MR-J4 servo amplifiers, including electrical specifications and safety compliance.
