Category: Electrical Equipment Manuals

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Lingshida Inverter LSD-B7000 Series User Manual Usage Guide

I. Introduction

The Lingshida LSD-B7000 series inverter is a high-performance, multi-functional full-vector variable frequency drive widely used in various industrial control fields. To help users better understand and utilize this inverter, this article will provide a detailed explanation of its panel functions, parameter settings, external wiring, fault code handling, and more.

Lingshida frequency converter LSD-B7000 operation panel function diagram

II. Panel Function Introduction

The Lingshida LSD-B7000 series inverter features a clean and intuitive panel design with reasonably laid out function keys for easy operation. The main function keys include:

  • RUN Button: Starts the inverter.
  • STOP Button: Stops the inverter.
  • PROG Button: Enters or exits programming mode for modifying and viewing parameters.
  • ▲▼ Buttons: Used to increase or decrease parameter values in programming mode.
  • DATA Button: Confirms parameter settings and saves them.

Additionally, the panel is equipped with LED indicators to display the inverter’s operational status and fault information.

III. Parameter Settings

  1. Selecting the Appropriate V/F Curve

The V/F curve represents the relationship between the output voltage and frequency of the inverter. Selecting the right V/F curve is crucial for ensuring stable motor operation. The LSD-B7000 series inverter offers multiple preset V/F curves. Users can choose based on the motor type and load characteristics by adjusting the Pr015 parameter in programming mode.

  1. Setting Maximum Frequency, Maximum Voltage, Minimum Frequency, Minimum Voltage, Intermediate Voltage, and Intermediate Frequency
  • Maximum Frequency: Sets the highest output frequency of the inverter, adjustable through the Pr016 parameter.
  • Maximum Voltage: Sets the highest output voltage, adjustable through the Pr017 parameter.
  • Minimum Frequency: Prevents motor overheating at low speeds by setting the lowest output frequency, adjustable through the Pr022 parameter.
  • Minimum Voltage: Ensures stable motor operation at low speeds by setting the lowest output voltage, adjustable through the Pr023 parameter.
  1. Setting Intermediate Voltage and Intermediate Frequency

Adjusting the intermediate voltage and frequency can optimize the inverter’s performance. Users can set two intermediate frequency points and their corresponding voltage values by modifying the Pr018 to Pr021 parameters.

  1. Setting UP/DOWN Frequency Given Function

The UP/DOWN function allows users to manually adjust the output frequency of the inverter using the ▲▼ buttons on the panel. Enable and adjust this function by modifying the Pr060 and Pr061 parameters in programming mode.

  1. Jogging Speed Adjustment

Jogging is a temporary method for adjusting the output frequency. Set the jogging frequency by modifying the Pr058 parameter and press the JOG button on the panel to achieve jogging speed adjustment.

IV. External Wiring and Parameter Settings

  1. External Terminal Forward/Reverse Control

To achieve forward/reverse control via external terminals, connect the forward (FR) and reverse (RR) terminals. In programming mode, select the external terminal control mode by adjusting the Pr005 parameter and set the Pr141 and Pr142 parameters for forward and reverse functions.

  1. External Potentiometer Speed Control

External potentiometer speed control is a commonly used speed adjustment method. Connect the output end of the potentiometer to the frequency given terminal (e.g., FV terminal) of the inverter. Users can adjust the output frequency of the inverter by rotating the potentiometer. In programming mode, select the external analog voltage given mode by adjusting the Pr004 parameter and set the corresponding FV terminal parameters (e.g., Pr152 and Pr153) to adjust the gain and offset.

Lingshida inverter LSD-B7000 standard wiring diagram

V. Fault Code Meaning Analysis and Solutions

The Lingshida LSD-B7000 series inverter features comprehensive fault protection. When a fault occurs, the inverter displays the corresponding fault code. Below are some common fault codes, their meanings, and solutions:

  • OC: Overcurrent Protection. May be caused by motor overload or output short circuit. Solutions include checking motor load, output circuit, and parameter settings.
  • OV: Overvoltage Protection. May be due to excessive input voltage or damaged brake resistor. Solutions include checking input voltage and brake resistor.
  • LU: Undervoltage Protection. May be due to low input voltage. Solutions include checking input power supply and voltage stabilizer.
  • EF: External Fault. May be caused by abnormal external input signals. Solutions include checking external input terminals and signal sources.

When encountering a fault code, users should first make a preliminary judgment based on the code’s meaning, then follow the solutions to inspect and repair. If the problem persists, contact Lingshida’s after-sales service center for further technical support.

VI. Conclusion

The Lingshida LSD-B7000 series inverter is a powerful and easy-to-use full-vector variable frequency drive. Through this guide, users can better understand and utilize this inverter, mastering its panel functions, parameter settings, external wiring, and fault code handling. In practical applications, users should set parameters and wire connections based on actual needs, regularly perform maintenance and inspections to ensure the long-term stable operation of the inverter.

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Difuss Inverter DS9 Series Operation Manual User Guide

I. Introduction to Operation Panel Functions and Parameter Settings

Operation Panel Functions

The Difuss Inverter DS9 series features an intuitive and user-friendly operation panel, which primarily comprises a data display area, function indicators, a numeric display area, and multiple function keys. The data display area shows the current operating status, set values, and monitoring data. Function indicators such as IRUN (Running Indicator) and ILOCAL/REMOTE (Operation Mode Indicator) help users quickly understand the inverter’s working status. The numeric display area, with a 5-digit LED display, supports the display of set frequency, output frequency, various monitoring data, and alarm codes. Function keys include PRG (Program Key), ENTER (Confirm Key), FUN (Multi-function Key), Shift Key, RUN (Run Key), and STOP/RES (Stop/Reset Key), facilitating parameter setting and operational control.

Function diagram of DS9 frequency converter operation panel

Parameter Settings

1. Setting Rated Frequency, Current, and Power

The DS9 inverter allows users to set the motor’s rated frequency, current, and power based on actual needs. These parameters are typically set in the P1 group of motor parameters. For instance, the motor’s rated power is set via P1-01, and its rated current is set via P1-03. Proper setting of these parameters is crucial for the normal operation of the inverter, ensuring that the motor operates stably within its rated working range.

2. Setting Upper and Lower Limit Frequencies

The upper and lower limit frequencies are set through parameters P0-12 and P0-14, respectively. The upper limit frequency defines the maximum frequency output by the inverter, while the lower limit frequency defines the minimum output frequency. Setting these parameters helps protect the motor from overload or damage during low-speed operation, ensuring stable operation within the set frequency range.

Application Macro Settings

CNC Machine Tool 100Hz Macro

By setting P0-29=11, you can select the CNC Machine Tool 100Hz macro. Tailored for CNC machine tool applications, this macro ensures stable inverter operation at 100Hz, meeting the high precision and stability requirements of CNC machine tools.

Spindle 400Hz Macro

By setting P0-29=21, 22, or 23, you can select different spindle 400Hz macros. Designed for high-speed spindle motors, these macros support output frequencies of up to 400Hz, catering to the needs of precision machining and high-speed cutting. Users can choose the appropriate macro based on specific application scenarios and fine-tune it through parameters like P0-03 and P0-08 to achieve optimal performance.

Basic wiring diagram of DS9 frequency converter

II. Terminal Control and External Speed Regulation Settings

Forward and Reverse Control

Achieving forward and reverse control of the inverter through terminals is straightforward. First, configure terminal X1 for forward operation (FWD) and terminal X2 for reverse operation (REV). The specific settings are as follows:

  • Enter the P4 group of input terminal settings and set P4-00 to 1 (X1 terminal for forward operation).
  • Set P4-01 to 2 (X2 terminal for reverse operation).

After these settings, controlling the on/off states of terminals X1 and X2 via external switches or PLCs enables forward and reverse control of the inverter.

External Potentiometer Speed Regulation

External potentiometer speed regulation is a commonly used speed control method that adjusts the inverter’s output frequency by changing the potentiometer’s resistance. The specific settings are as follows:

  • Configure AI1 terminal as an analog input to receive voltage signals from an external potentiometer. Select the AI1 curve via parameter P4-33 and set parameters such as P4-13 to P4-16 to define the correspondence between input voltage and output frequency.
  • During wiring, connect the sliding end of the external potentiometer to the AI1 terminal and its fixed ends to the +10V and GND terminals, respectively.

After completing the settings and wiring, rotating the potentiometer changes the inverter’s output frequency, enabling speed regulation.

III. Fault Code Analysis and Solutions

The DS9 inverter boasts a comprehensive fault protection mechanism that stops the inverter promptly and displays the corresponding fault code in case of a fault. Here are some common fault codes and their solutions:

  • Err01 (Inverter Unit Protection): May be caused by output circuit short circuit, excessive length of motor and inverter wiring, or module overheating. Solutions include troubleshooting peripheral issues, installing reactors or output filters, and checking for blocked air ducts.
  • Err02 (Acceleration Overcurrent): May result from too short an acceleration time, low voltage, or excessive load. Solutions include increasing the acceleration time, adjusting the voltage to the normal range, or reducing the load.
  • Err03 (Deceleration Overcurrent): Similar to acceleration overcurrent, it may be caused by too short a deceleration time, low voltage, or excessive load. The solutions are also similar.
  • Err14 (Module Overheating): May be due to high ambient temperature, blocked air ducts, or damaged fans. Solutions include lowering the ambient temperature, cleaning the air ducts, or replacing the fans.

When encountering a fault, users should first look up possible fault causes based on the displayed fault code and follow the corresponding solutions. If the problem persists, users should promptly contact the inverter manufacturer or agent for technical support.

IV. Conclusion

The Difuss Inverter DS9 Series Operation Manual provides users with a comprehensive user guide, covering operation panel function introduction, parameter setting methods, terminal control and external speed regulation settings, fault code analysis, and troubleshooting. By carefully reading and following the instructions in the manual, users can easily master the operation and maintenance skills of the inverter, ensuring stable and efficient equipment use.

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User Manual Guide for JTE330 Series Inverter by Jintian

The JTE330 series inverter from Jintian is a high-performance vector inverter widely used in industrial automation control systems. To assist you in utilizing this inverter more effectively, this article will provide a detailed introduction to its operation panel functions, parameter settings, and specific operation procedures.

Jintian frequency converter JTE330 basic wiring diagram

1. Introduction to Operation Panel Functions

The JTE330 series inverter features an intuitive operation panel that allows users to monitor and control the inverter’s operation status. The panel typically includes buttons for frequency adjustment, mode selection, start/stop, and parameter settings.

  • Frequency Adjustment Buttons: These allow users to manually adjust the output frequency of the inverter.
  • Mode Selection Button: This button toggles between different operational modes, such as frequency setting, parameter adjustment, and fault diagnosis.
  • Start/Stop Button: Used to start or stop the inverter’s output.
  • Parameter Setting Buttons: These buttons are used to navigate through the inverter’s parameter settings for detailed configuration.

2. Controlling Inverter Operation Using “Preset Frequency F0-08” and Panel Start Mode

To control the inverter using the preset frequency F0-08 and panel start mode, you need to set the following specific parameters:

  1. Enter Parameter Setting Mode:
    • Press the “Mode” button to enter the parameter setting mode.
    • Use the navigation buttons to select the parameter you wish to adjust.
  2. Set Preset Frequency F0-08:
    • Locate parameter F0-08, which represents the preset frequency.
    • Adjust the value of F0-08 to the desired output frequency using the frequency adjustment buttons.
  3. Enable Panel Start Mode:
    • Navigate to the relevant parameter that controls the start mode (usually labeled as a start source selection parameter).
    • Set this parameter to “Panel” or the equivalent option to enable panel start mode.
  4. Save Settings and Exit:
    • After setting the desired parameters, press the “Save” or equivalent button to store the settings.
    • Exit the parameter setting mode by pressing the “Mode” button again.

Now, when you press the start button on the operation panel, the inverter will output the frequency set in F0-08.

3. Restoring Factory Default Settings

To restore the inverter to its factory default settings, follow these steps:

  1. Enter Parameter Setting Mode:
    • As described above, enter the parameter setting mode using the “Mode” button.
  2. Navigate to Reset Parameter:
    • Use the navigation buttons to locate the parameter responsible for resetting the inverter to factory defaults. This parameter is usually labeled as “Reset to Factory Defaults” or something similar.
  3. Perform Reset:
    • Set the reset parameter to “Yes” or the equivalent value to initiate the reset process.
    • The inverter may require confirmation; follow any on-screen prompts to complete the reset.
  4. Save Settings and Exit:
    • After the reset is complete, press the “Save” button to store the factory default settings.
    • Exit the parameter setting mode.

4. Setting Up Speed Tracking Function

The speed tracking function allows the inverter to automatically adjust its output frequency to match the speed of an external motor or rotating equipment. To set up this function:

  1. Enter Parameter Setting Mode:
    • Enter the parameter setting mode as described earlier.
  2. Locate Speed Tracking Parameters:
    • Navigate to the parameters related to the speed tracking function. These parameters may include settings for enabling speed tracking, selecting the speed tracking source, and adjusting speed tracking gain.
  3. Enable Speed Tracking:
    • Set the parameter that enables speed tracking to “On” or the equivalent value.
  4. Configure Speed Tracking Source:
    • Select the appropriate speed tracking source, which could be an encoder, another motor, or another external signal.
  5. Adjust Speed Tracking Gain:
    • Use the related parameter to adjust the gain of the speed tracking system. This setting determines how sensitive the inverter’s output frequency is to changes in the tracked speed.
  6. Save Settings and Exit:
    • After configuring all necessary parameters, press the “Save” button to store the settings.
    • Exit the parameter setting mode.

By following these guidelines, you can effectively utilize the JTE330 series inverter’s operation panel to control its operation, restore factory default settings, and set up advanced functions like speed tracking.

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Shanghai RMSPD INVERTER SPD990M Mini User Guide

I. Introduction to Inverter Panel Functions and Basic Operations

1. Panel Function Introduction
Function diagram of RMSPD INVERTER SPD990M operation panel

The RMSPD INVERTER SPD990M Mini is equipped with an LED operation panel that primarily includes the following function keys:

  • Shift Key: Used to select digits for modification when editing data.
  • Multi-function Key: Function set by parameter F8.04, defaulting to Jog.
  • Analog Potentiometer: Used for frequency setting.
  • Programming Key: Enters or exits the programming mode.
  • Increment/Decrement Keys: Adjusts data or function codes.
  • Confirm Key: Enters the next menu level or confirms data.
  • Run Key: Starts the inverter.
  • Stop/Reset Key: Stops the inverter or resets faults.
2. Resetting to Factory Defaults

To reset the inverter to its factory settings, follow these steps:

  1. Enter the programming mode (press the programming key).
  2. Use the shift and increment/decrement keys to select function code F8.03.
  3. Press the confirm key to enter F8.03 settings and select “1” for factory reset.
  4. Press the confirm key again to save and exit.
3. Starting, Stopping, and Adjusting Frequency via Panel
  • Starting: Press the run key to start the inverter.
  • Stopping: Press the stop key to stop the inverter.
  • Frequency Adjustment: Use the analog potentiometer or increment/decrement keys to adjust the output frequency.
4. Terminal Forward/Reverse Control and External Potentiometer Frequency Setting
  • Forward/Reverse Control: Control via terminals X1 (forward) and X2 (reverse), requiring F2.13 and F2.14 to be set to corresponding functions.
  • External Potentiometer Frequency Setting: Connect to the AVI terminal and set F0.03 to 3 (AVI analog input).

II. PID Function Control for a Single Water Pump Motor

1. PID Function Wiring and Parameter Settings
  • Wiring: Connect the PID feedback signal to the AVI or ACI terminal.
  • Parameter Settings:
    • F3.00: Enable PID regulation, selecting appropriate input and feedback channels.
    • F3.01: Set the PID setpoint.
    • F3.02: Adjust the feedback channel gain.
    • F3.03 and F3.04: Set the proportional gain (P) and integral time (Ti).
2. Sleep Function Settings and Wake-up
  • Sleep Settings:
    • F3.10 and F3.11: Set sleep and wake-up threshold coefficients.
    • F3.12 and F3.13: Set sleep and wake-up delay times.
  • Wake-up: When the feedback value is less than the wake-up threshold, the inverter will automatically wake up.

III. Controlling the Inverter via a Weinview Touchscreen using Modbus Protocol

1. Inverter Settings
  • Communication Parameters:
    • F6.00: Set the device address.
    • F6.01: Configure Modbus communication parameters (baud rate, data format, etc.).
  • Control Commands:
    • Use function code 06 to write control commands to address 2002H for inverter forward/reverse and stop control.
    • Read and write frequencies to address 2001H.
2. Reading Alarm Values
  • Use function code 03 to read alarm codes starting from address 2100H.
RMSPD INVERTER SPD990M Wiring Diagram

IV. Fault Code Meanings and Solutions

Fault CodeNamePossible CausesSolutions
E0C1Overcurrent During AccelerationToo short acceleration time, undersized inverterExtend acceleration time, choose a larger inverter
E0C2Overcurrent During DecelerationToo short deceleration time, undersized inverterExtend deceleration time, choose a larger inverter
EHU1Overvoltage During AccelerationAbnormal input voltageCheck the input power supply
ESC1Power Module FaultOutput short circuit, control board malfunctionCheck motor wiring, contact the manufacturer for service
EOL1Inverter OverloadImproper V/F curve settings, heavy loadAdjust V/F curve, choose a larger inverter

V. Conclusion

The Shanghai RMSPD INVERTER SPD990M Mini is a powerful and easy-to-use variable frequency drive. Basic start, stop, and frequency adjustment can be achieved through the panel. Terminal control enables forward/reverse operation and analog frequency adjustment. PID functionality allows for closed-loop control of water pump motors. Communication with an upper computer can be facilitated via the Modbus protocol. In the event of a fault, referring to the fault code table can quickly identify the issue and take appropriate measures. We hope this guide assists users in better utilizing and maintaining the SPD990M Inverter.

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YQ3000-F11 User Guide and PID Function Application for Constant Pressure Water Supply of Yuqiang Inverter

The YQ3000-F11 inverter from Yuqiang, with its high performance and reliable stability, is widely used in various industrial automation applications. This article will provide a detailed introduction to the panel startup and speed adjustment methods, how to restore factory default settings, specific wiring and parameter settings for terminal forward/reverse rotation and external potentiometer speed adjustment, as well as the steps to implement PID function for single-loop closed-loop pressure control on a single-pump constant pressure water supply system. Additionally, fault code meanings and solutions will be provided.

I. Panel Startup and Speed Adjustment Methods

The YQ3000-F11 inverter from Yuqiang features an intuitive control panel, allowing users to set and adjust inverter parameters via buttons or knobs on the panel. Specific operation steps are as follows:

  1. Pre-startup Preparation: Close the air switch, observe whether there are abnormal displays on the inverter keyboard display, listen for any unusual sounds or vibrations within the inverter, and check for any unusual odors.
  2. Parameter Setting: According to the rated power and operating conditions of the motor, set the inverter’s maximum output frequency, start frequency, acceleration time, deceleration time, and other parameters via the control panel to ensure smooth and reliable inverter operation.
  3. Startup and Speed Adjustment: Set the inverter’s startup mode to manual or automatic. In automatic mode, the inverter will automatically start the motor based on preset parameters. After the motor starts, the speed can be adjusted via speed adjustment buttons or knobs on the control panel. The speed adjustment method may vary depending on the inverter model and display interface.
On site pressure gauge indication

II. Method to Restore Factory Default Settings

When the inverter settings are incorrect or a reset is needed, the parameters can be restored to factory defaults through the following two methods:

  1. Method 1: While the inverter is powered off, press and hold three combination keys simultaneously. Then, turn on the inverter power switch. Release the keys shortly after, and the inverter will restore its factory parameters.
  2. Method 2: Follow specific operating steps via the panel control to select the mode, switch parameters, and then press and hold the SET key to restore factory defaults.
Pressure feedback signal wiring

III. Specific Wiring and Parameter Settings for Terminal Forward/Reverse Rotation and External Potentiometer Speed Adjustment

The YQ3000-F11 inverter from Yuqiang supports motor forward/reverse rotation and external potentiometer speed adjustment via terminals. Specific wiring and parameter settings are as follows:

  1. Forward/Reverse Wiring:
    • Connect the positive and negative terminals of the motor to the corresponding terminals on the inverter according to the terminal wiring diagram.
    • Set the forward/reverse parameters (e.g., P001) as needed, enabling the inverter to achieve motor forward/reverse rotation based on control signals.
  2. External Potentiometer Speed Adjustment Wiring:
    • Connect the output terminal of the external potentiometer to the AI1 (or other adjustable input terminal) of the inverter.
    • Set AI1 as the speed reference input channel in the inverter parameters and adjust related parameters (e.g., P006) to achieve potentiometer speed adjustment.

IV. PID Function Application Method for Constant Pressure Water Supply

On a single-pump constant pressure water supply system, the YQ3000-F11 inverter from Yuqiang can achieve single-loop closed-loop pressure control via the PID function. Specific steps are as follows:

  1. Wiring:
    • Connect the output terminals of the pressure sensor (+10V, GND, and VF) to the corresponding control terminals of the inverter (e.g., AI1).
  2. Parameter Setting:
    • Set P006=7 to select AI1 as the PID feedback input channel.
    • Set P0902=0 to enable the PID function.
    • Set PID parameters (e.g., proportional gain P, integral time I, derivative time D) as needed to achieve stable pressure control.
    • Set the PID setpoint, which is the target pressure value. This is typically done by entering a specific numerical value in the inverter’s parameter settings.
  3. Debugging:
    • During initial debugging, the proportional gain P can be preset to an intermediate to large value or temporarily left at the factory default.
    • If the controlled physical quantity (i.e., pressure) oscillates near the target value, increase the integral time I. If oscillation persists, appropriately decrease the proportional gain P.
    • If the controlled physical quantity is difficult to recover after changing, increase the proportional gain P. If recovery is still slow, appropriately decrease the integral time I or increase the derivative time D.

V. Fault Code Meanings and Solutions

When using the YQ3000-F11 inverter from Yuqiang, various fault codes may be encountered. These codes are usually displayed on the inverter’s display screen to help users quickly locate issues. Below are some common fault codes and their solutions:

  1. OC (Overcurrent):
    • Cause: Excessive motor load, improper inverter parameter settings, etc.
    • Solution: Check motor load, adjust inverter parameters, optimize motor matching, etc.
  2. OV (Overvoltage):
    • Cause: Excessively high input voltage, internal inverter faults, etc.
    • Solution: Check input voltage stability, replace the inverter, etc.
  3. OL (Overload):
    • Cause: Motor overload, poor heat dissipation, etc.
    • Solution: Check motor load, improve heat dissipation conditions, etc.
  4. OH (Overheat):
    • Cause: Poor inverter heat dissipation, excessively high ambient temperature, etc.
    • Solution: Improve heat dissipation conditions, reduce ambient temperature, etc.

In conclusion, the YQ3000-F11 inverter from Yuqiang boasts powerful functions and a wide range of applications. Through reasonable parameter settings and wiring methods, precise motor speed adjustment and stable control of constant pressure water supply systems can be achieved. At the same time, familiarity with fault code meanings and solutions also aids users in better maintaining and using the inverter.

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KCINT Inverter KC280/KC300 Series User Guide and Realization Method of Constant Pressure Water Supply Control

I. KCINT Inverter KC280/KC300 Series User Guide

1. Terminal Panel Start and Speed Regulation Method

The KCINT Inverter KC280/KC300 series can be started and speed-regulated through the terminal panel. Specific operations are as follows:

KCINT IVERTER connects motor terminals
  • Wiring Instructions:
    • Connect the three-phase power supply to the R, S, T terminals of the inverter.
    • Connect the U, V, W terminals of the motor to the U, V, W output terminals of the inverter.
    • Connect the ground wire to the PE terminal of the inverter.
  • Parameter Settings:
    • Set P0.01 to 0 to select the keyboard command channel.
    • Set P0.03 to 0 to select the keyboard setting mode.
    • Set P0.07 to the desired operating frequency.
  • Operation Method:
    • Press the RUN button to start the inverter.
    • Hold the ▲ button to increase the output frequency of the inverter; hold the ▼ button to decrease the output frequency.
    • Press the STOP button to stop the inverter.
KCINT IVERTER connects the pressure sensor signal wire terminal

2. Terminal Forward/Reverse and External Potentiometer Speed Regulation Method

  • Wiring Instructions:
    • Connect the three-phase power supply to the R, S, T terminals of the inverter.
    • Connect the U, V, W terminals of the motor to the U, V, W output terminals of the inverter.
    • Connect the ground wire to the PE terminal of the inverter.
    • Connect the output terminal of the external potentiometer to the VI terminal of the inverter, and the common terminal to the GND terminal.
    • Connect the forward control terminal FWD-COM to the forward control signal, and the reverse control terminal REV-COM to the reverse control signal.
  • Parameter Settings:
    • Set P0.00 to 1 to select the input terminal control mode.
    • Set P0.01 to 1 to select the terminal command channel.
    • Set P0.03 to 1 to select the analog VI setting mode.
    • Set P5.07 to 0 to select the two-wire control mode.
  • Operation Method:
    • When only FWD-COM is closed, the motor rotates forward; when only REV-COM is closed, the motor rotates reverse; when both are closed or open, the motor decelerates and stops.
    • Adjust the external potentiometer to change the output frequency of the inverter, thereby achieving speed regulation.
KCINT IVERTER physical item

II. Closed-Loop PID Control Application in Constant Pressure Water Supply

1. Parameter Settings

  • Set P0.03 to 5 to select the PID control setting mode.
  • Set P0.13 to 3 to select the constant pressure water supply macro function.
  • Set P9.00 to 0 to select the keyboard preset PID setting.
  • Set P9.01 to the desired PID setpoint (relative value, 0~100%).
  • Set P9.02 to 0 to select the analog channel VI feedback.
  • Adjust PID parameters such as P9.04 (proportional gain), P9.05 (integral time), and P9.06 (derivative time) as needed to achieve the desired control effect.

2. Wiring Instructions

  • Connect the output terminal of the remote pressure gauge or 4-20mA pressure transmitter to the VI terminal of the inverter, and the common terminal to the GND terminal.
  • Correctly connect the power wire and signal wire according to the wiring requirements of the pressure gauge or transmitter.

3. Operation Method

  • After starting the inverter, adjust the PID setpoint (A value) through the panel’s up and down keys.
  • The system will automatically adjust the output frequency of the inverter based on the set PID parameters and feedback signals to maintain a constant water supply pressure.
KCINT IVERTER working pictures

III. Fault Code Analysis and Solutions

The KCINT Inverter KC280/KC300 series may display various fault codes during operation. The following are some common fault codes, their analyses, and solutions:

  • FL (Inverter Unit Fault):
    • Possible Causes: Too fast acceleration, internal IGBT damage, interference causing malfunctions, poor grounding, etc.
    • Solutions: Increase acceleration time, check and eliminate interference sources, check grounding, etc.
  • OC (Overcurrent Fault):
    • Possible Causes: Too fast acceleration or deceleration, large load inertia torque, low grid voltage, insufficient inverter power, etc.
    • Solutions: Increase acceleration or deceleration time, select a larger inverter, check grid voltage, etc.
  • OU (Overvoltage Fault):
    • Possible Causes: Abnormal input voltage, too fast deceleration, large load inertia, etc.
    • Solutions: Check the input power supply, increase the deceleration time, add suitable energy consumption braking components, etc.
  • LU (Bus Undervoltage Fault):
    • Possible Cause: Low grid voltage.
    • Solution: Check the grid input power supply.
  • OL (Overload Fault):
    • Possible Causes: Low grid voltage, incorrect motor rated current setting, motor stall or excessive load mutation, etc.
    • Solutions: Check the grid voltage, reset the motor rated current, check the load, etc.

When using the KCINT Inverter KC280/KC300 series, wiring and parameter settings should be strictly carried out according to the manual, and regular maintenance and servicing of the inverter should be performed to ensure its normal operation and extend its service life. At the same time, for fault codes that appear, the cause should be promptly analyzed and corresponding solutions taken to ensure the smooth progress of the production process.

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M-DRIVER INVERTER M900 Series User Manual Guide

1. Introduction to Inverter Panel Functions and Parameter Settings

1.1 Panel Function Introduction

The M-DRIVER INVERTER M900 series features an intuitive and user-friendly panel design, with key functions including:

  • Running Indicators: Display the inverter’s operating status, such as Forward (FWD), Reverse (REV), and Stop (STOP).
  • Fault Indicator (ALM): Lights up when the inverter encounters a fault, prompting the user to check.
  • Program Key (PRGM): Used to enter or exit the parameter setting interface.
  • Enter Key (ENTER): Confirms parameter modifications or accesses the next menu level.
  • Increment Key (▲) and Decrement Key (▼): Adjust parameter values or select menu items.
  • Shift Key (<<): Toggles between digit positions during parameter modification.
  • Run Key (RUN) and Stop Key (STOP/RESET): Start and stop the inverter, respectively.

1.2 Restoring Factory Default Parameters

Restoring factory default parameters resets the inverter to its initial state. The steps are as follows:

  1. Press the Program Key (PRGM) to enter the parameter setting interface.
  2. Use the Increment Key (▲) or Decrement Key (▼) to select parameter F0-24.
  3. Press the Enter Key (ENTER) to enter the parameter modification interface.
  4. Set the value of F0-24 to 1.
  5. Press the Enter Key (ENTER) again to save the setting and exit.

1.3 Setting and Removing Passwords

To protect the inverter parameters from unauthorized modification, a user password can be set:

  1. Enter the parameter setting interface and select parameter F6-03.
  2. Press the Enter Key (ENTER) to enter the password modification interface.
  3. Use the Increment Key (▲) or Decrement Key (▼) to set the password.
  4. Press the Enter Key (ENTER) again to save the password.

To remove the password, simply set the value of F6-03 to 0.

1.4 Setting Parameters for Synchronous Motor Control

When using the M900 series inverter to control a synchronous motor, the following parameters need to be set:

  • F8-06: Motor Control Mode, set to “2” (Synchronous Motor Vector Control without Speed Sensor).
  • F8-07: Motor Parameter Self-Tuning, select “Static Parameter Tuning” or “Dynamic Parameter Tuning” based on the motor state.
  • F8-16 to F8-18: Enter the synchronous motor’s stator resistance, d-axis inductance, and q-axis inductance parameters (if available on the nameplate, input directly; otherwise, perform parameter tuning).

2. Terminal Forward/Reverse and External Potentiometer Speed Control

2.1 Wiring Instructions

  • Forward/Reverse Control: Connect external switches to the inverter’s DI1 and DI2 terminals, with GND as the common terminal.
  • External Potentiometer Speed Control: Connect the potentiometer’s three terminals to the inverter’s AI1, GND, and +10V terminals, respectively.

2.2 Parameter Settings

  1. Enter the parameter setting interface and select F0-00, setting its value to “1” (Terminal Control).
  2. Select F1-00 and F1-01, setting the functions of DI1 and DI2 to Forward (FWD) and Reverse (REV), respectively.
  3. Select F0-01 and set its value to “2” (AI1 as the frequency source).
  4. Adjust the gain (F1-24) and offset (F1-25) of AI1 as needed to ensure the appropriate speed control range.

3. Modbus Communication and Siemens PLC SMART Control

3.1 Communication Parameter Settings

  1. Enter the parameter setting interface and select F7-00 to set the inverter’s device address.
  2. Select F7-01 to set the baud rate (e.g., 9600BPS).
  3. Select F7-02 to set the data format (e.g., no parity, even parity, etc.).
  4. Select F7-03 to set the communication timeout period.

3.2 PLC Control Settings

In the PLC programming software, send control commands to the inverter via the Modbus protocol. For example, to achieve forward/reverse control, the following commands can be sent:

  • Forward: Write the number “1” to the inverter’s 2nd register.
  • Reverse: Write the number “2” to the inverter’s 2nd register.

Ensure that F0-00 is set to “2” (Communication Control) and F0-01 is set to “8” (Communication Setting) to allow the inverter to receive control commands from the PLC.

4. Fault Code Meaning Analysis and Resolution Methods

4.1 Example Fault Codes

  • Err01: Inverter Unit Protection. Possible causes include output circuit short-circuit, excessive length of motor and inverter wiring, etc. Solutions include troubleshooting peripheral faults, installing reactors or output filters, etc.
  • Err02: Acceleration Overcurrent. Possible causes include output circuit grounding or short-circuit, too short acceleration time, etc. Solutions include increasing the acceleration time, adjusting the manual torque boost or V/F curve, etc.
  • Err10: Inverter Overload. Possible causes include excessive load or motor lock. Solutions include reducing the load and checking the motor and machinery, or selecting an inverter with a higher power rating.

4.2 Fault Handling Process

  1. Check Fault Code: When a fault code appears on the inverter panel, first record it and consult the fault code table in the manual.
  2. Analyze Possible Causes: Based on the fault code table, analyze the possible causes of the fault.
  3. Take Corrective Measures: Follow the suggestions in the manual or combine them with actual conditions to take appropriate corrective measures.
  4. Verify Repair Effectiveness: After resolving the fault, restart the inverter and verify that it has returned to normal operation.

5. Conclusion

The M-DRIVER INVERTER M900 Series User Manual provides detailed usage guides and parameter setting instructions. Through this guide, users can learn about panel functions, parameter restoration, password setting, synchronous motor control, terminal wiring and settings, Modbus communication, and fault handling. In practical applications, users should strictly follow the instructions in the manual to ensure the normal operation and long-term stability of the inverter.

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Guangzhou Numerical Control Servo Unit DA98A User Manual Usage Guide

I. Basic Operations and Parameter Settings of the Servo Unit

1. Factory Reset and Parameter Backup
  • Factory Reset: To restore the servo unit to its default parameter settings, first enter the special password for modifying motor parameters, PA0=385. Then, find the corresponding code for your motor model (refer to Appendix A) and input it into parameter PA1. Finally, execute the parameter restoration operation.
  • Parameter Backup: To prevent erroneous parameter modifications, you can back up the current parameters to the EEPROM backup area. Select the “Parameter Backup” option in the parameter management menu via the operation panel to complete the backup operation. To restore, select “Restore Backup”.
2. Setting the Motor Model Selection Parameter
  • Motor Model Selection: Choose the compatible motor model by setting parameter PA1. After inputting the correct motor model code, the servo unit will automatically load the corresponding default parameters.
3. Jog Start and Stop
  • Jog Operation: In the menu, select the jog operation mode (PA4=3), set the jog speed (PA21), and ensure PA98=1 to force internal enabling. Subsequently, control the motor’s start and stop for forward and reverse rotation using the “+” and “-” keys on the operation panel.
4. Parameter Optimization
  • Speed Loop and Current Loop Optimization: The adjustments to the speed loop proportional gain (PA5) and integral coefficient (PA6) affect the servo system’s response speed and stability. The adjustments to the current loop filter coefficient (PA7) and speed feedback filter coefficient (PA8) influence the current smoothness and speed feedback response speed. These parameters need to be fine-tuned based on specific motor models and load conditions to achieve optimal performance.
DA98A servo unit position mode wiring diagram

II. Wiring and Parameter Settings Under Position Mode Control

1. Wiring Instructions
  • Position Mode Wiring: The main connections include power input (R, S, T), motor output (U, V, W), control power (r, t), encoder feedback (CN2 interface), and control signals (CN1 interface). Refer to the wiring diagrams in the manual for specific terminal connections.
2. Forward and Reverse Control
  • Forward and Reverse Implementation: Realize motor forward and reverse control by inputting pulse and direction signals through the PULS+, PULS-, and SIGN+, SIGN- terminals of the control signal CN1, or by using CCW and CW pulses. Set parameter PA14 to choose the pulse input mode (pulse + direction or CCW/CW pulses).
3. Key Parameter Settings
  • Position Command Electronic Gear Ratio: Adjust the electronic gear ratio to match different pulse sources and control resolutions by setting parameters PA12 (pulse command multiplication coefficient) and PA13 (pulse command division coefficient).
  • Position Command Pulse Input Mode: Set parameter PA14 to 0 for pulse + direction mode or to 1 for CCW/CW pulse mode.
  • Position Arrival Signal: Set the position arrival range pulse number by adjusting parameter PA16. When the remaining pulse number in the position deviation counter is less than or equal to this value, the COIN signal outputs ON.
DA98A servo unit main circuit wiring diagram

III. Fault Codes and Solutions

1. List of Fault Codes and Their Meanings
  • Err-1: Overspeed, indicating that the servo motor speed exceeds the set value.
  • Err-2: Overvoltage in the main circuit, indicating that the main circuit power supply voltage is too high.
  • Err-3: Undervoltage in the main circuit, indicating that the main circuit power supply voltage is too low.
  • Err-4: Position error, indicating that the value in the position deviation counter exceeds the set value.
  • Err-9: Encoder fault, indicating that the encoder signal is erroneous.
  • Err-11: IPM module fault, indicating that the IPM intelligent module is faulty.
  • Err-12: Overcurrent, indicating that the motor current is too high.
  • Err-13: Overload, indicating that the servo unit and motor are overloaded.
2. Solutions
  • Err-1: Check the control circuit board, motor encoder, input pulse frequency, and electronic gear ratio settings, or adjust the load moment of inertia ratio.
  • Err-2: Check the power supply, braking resistor wiring, internal braking resistor or circuit, or reduce the start-stop frequency and load inertia.
  • Err-3: Confirm the main circuit power wiring, power supply voltage, power capacity, and heat sink status.
  • Err-4: Check the pulse command frequency, electronic gear ratio settings, load inertia, motor encoder and its connections, or adjust the speed loop and position loop gains.
  • Err-9: Inspect the encoder connector and signal wire soldering, shorten the encoder cable length, or replace the motor encoder.
  • Err-11: Replace the servo unit, check the braking resistor wiring, adjust the current loop parameters, or reduce the load inertia.
  • Err-12: Reduce the load, check the grounding, or replace the motor.
  • Err-13: Adjust the speed loop gain, increase the acceleration/deceleration time, reduce the load inertia, or replace the high-power servo unit and motor.

IV. Scientific Usage Process of the Servo System

  1. System Installation and Wiring: Install the servo unit and motor correctly according to the installation instructions and wiring diagrams in the manual, ensuring all connections are accurate and error-free.
  2. Parameter Setting and Debugging: Set the corresponding parameters based on the motor model in use and conduct necessary debugging, including the optimization of key parameters such as the speed loop and current loop.
  3. Functional Testing: Conduct manual, jog, speed mode, and position mode operation tests under no-load conditions to ensure the servo system functions normally.
  4. Load Operation: After confirming the normal operation of the servo system under no-load conditions, connect the load for loaded operation testing and monitor the motor’s operating status and performance indicators.
  5. Fault Handling and Maintenance: In case of alarms or faults during use, troubleshoot and resolve them according to the fault codes and handling methods in the manual. Meanwhile, regularly maintain and service the servo unit and motor to ensure their long-term stable operation.

By following the above steps, you can ensure the scientific use and maintenance of the Guangzhou Numerical Control (GSK CNC) Servo Unit DA98A, improving production efficiency and equipment reliability.

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Kingda Inverter V380 Series User Manual Operation Guide

Kingda Inverter V380 Series User Manual Operation Guide

I. Introduction to Inverter Operation Panel Functions and Factory Reset

The Kingda Inverter V380 series features a versatile operation panel with the following main keys:

  • Run/Stop Key: Used to start or stop the inverter.
  • Forward/Reverse Key: Used to control the motor’s forward and reverse rotation, respectively.
  • Stop/Fault Reset Key: Used to reset or stop the inverter in case of a fault.
  • Return Key: Used to switch between monitoring modes or return to the previous state.
  • Confirm Key: Confirms the current status or parameter and enters the next level of the function menu.
  • Data Modify Key: Used to modify function codes or parameters.
  • Shift Key: Used to move the cursor position when setting parameters.
Kingda Inverter V380 Operation Panel

Factory Reset:

  • To restore factory settings, enter the parameter settings interface, find the P0.03 parameter (Parameter Initialization), set it to 1, and then press the confirm key to execute the initialization. This operation will clear all user-defined parameters, and the inverter will revert to its factory default settings.

Carrier Frequency and Carrier Characteristic Parameters:

  • Carrier Frequency: Refers to the frequency of the PWM (Pulse Width Modulation) signal within the inverter, affecting the harmonic content of the output current and motor noise levels. A higher carrier frequency reduces harmonic content but increases switching losses, potentially leading to increased inverter heat generation.
  • Carrier Characteristic Parameter (P0.12): Controls whether the carrier frequency changes with the output frequency. When set to 0, the carrier frequency does not change with the output frequency; when set to 1, the carrier frequency increases with the output frequency, helping to reduce noise and vibration at lower frequencies.
  • Setting Carrier Frequency: Enter the parameter settings interface, find the P0.11 parameter (Carrier Frequency), and adjust its value according to actual needs, typically ranging from 0.8 to 15.0 KHz.

II. Terminal Start/Stop and External Potentiometer Speed Regulation Settings

Terminal Start/Stop:

  • Wiring: Connect external control signals to the inverter’s DI (Digital Input) terminals. Typically, the forward start signal is connected to DI1, the reverse start signal to DI2, and the stop signal to DI3 (or a combination of states shared by DI1 and DI2).
  • Parameter Settings: Enter the parameter settings interface and set P1.05 (Run Command Channel) to 1 (Terminal Control Start/Stop).
Kingda Inverter V380

External Potentiometer Speed Regulation:

  • Wiring: Connect the output of the external potentiometer to the inverter’s AI1 (Analog Input 1) terminal. The sliding end of the potentiometer is used to adjust the output voltage, thereby controlling the inverter’s output frequency.
  • Parameter Settings: Enter the parameter settings interface, set P1.00 (Main Frequency Channel A Selection) to 3 (Panel Potentiometer), and set P2.00 and P2.01 to the lower and upper voltage limits of AI1 input, respectively.

III. Modbus Protocol Settings and PID Control via Siemens PLC (S7-200)

To achieve PID control (e.g., single-pump constant pressure water supply) of the inverter via a Siemens PLC (S7-200) using the Modbus protocol, the following settings are required:

  • Modbus Parameter Settings:
    • Enter the parameter settings interface, set the units place of P9.00 (Communication Settings) to the corresponding baud rate (e.g., 4 for 9600 bps), and the tens place to the data format (e.g., 0 for no parity).
    • Set P9.01 (Device Address) to the Modbus address of the inverter.
    • Ensure P9.04 (Communication Timeout Fault Detection Time) is set reasonably to avoid communication interruptions.
  • PID Control Parameter Settings:
    • Enter the parameter settings interface and enable the built-in PID control (P8.00 set to a non-zero value).
    • Set the PID setpoint and feedback channels (P8.01), typically selecting the external voltage signal AI1 as the feedback channel.
    • Adjust PID proportional constant (P8.07), integral constant (P8.08), and other parameters according to control requirements.
  • PLC Programming:
    • Write a Modbus communication program in the Siemens PLC (S7-200) to read the current status of the inverter and send PID setpoints.
    • Write a PID control algorithm program to adjust the setpoint based on the feedback signal, achieving control objectives such as constant pressure water supply.

IV. Fault Code Analysis and Solutions

The Kingda Inverter V380 series features comprehensive fault protection. When a fault occurs, the inverter displays the corresponding fault code. Below are some common fault codes, their analysis, and solutions:

  • EC.01: Overcurrent during acceleration. Possible causes include too short an acceleration time, an inappropriate V/F curve, etc. Solutions include extending the acceleration time, adjusting the V/F curve, etc.
  • EC.02: Overcurrent during deceleration of the inverter. A possible cause is too short a deceleration time. The solution is to increase the deceleration time.
  • EC.03: Overcurrent during inverter operation or stoppage. Possible causes include sudden load changes, low grid voltage, etc. Solutions include reducing load fluctuations and checking the power supply voltage.
  • EC.04 to EC.07: Related to overvoltage faults, possible causes include abnormal power supply voltage, improper deceleration time settings, etc. Solutions include checking the power supply voltage and adjusting the deceleration time.
  • EC.12 and EC.13: Indicate inverter and motor overload, respectively. Possible causes include excessive load, too short an acceleration time, etc. Solutions include reducing the load and extending the acceleration time.

For other fault codes, refer to the Fault Diagnosis and Countermeasures section of the user manual for detailed analysis and solutions. When troubleshooting, ensure that the inverter is powered off and take necessary safety measures.

V. Conclusion

This document provides a detailed introduction to the operation guide of the Kingda Inverter V380 series, including the operation panel function introduction, factory reset method, carrier frequency and carrier characteristic parameter settings, terminal start/stop and external potentiometer speed regulation settings, Modbus protocol and PLC PID control settings, as well as fault code analysis and solutions. With this guide, users can better understand and utilize this inverter to achieve efficient and stable motor control.

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User Manual Guide for GTAKE Inverter GK600 Series

I. Introduction to the Operating Panel Functions and Password Settings

The operating panel of the GTAKE Inverter GK600 series serves as its core human-machine interface, providing parameter setting, operational status display, and more. The primary indicators and button functions on the operating panel are as follows:

  • Indicators: Include frequency indication, current indication, voltage indication, speed indication, etc., used to display the current operating status of the inverter.
  • Buttons: Include RUN, STOP/RESET, MF (multi-function button), etc., used to control the start, stop, and parameter settings of the inverter.
GTAKE INVERTER GK600 series operation panel diagram

Setting and Removing Passwords

To protect the inverter parameters from unauthorized changes, users can set passwords to restrict access. The specific operations are as follows:

  1. Setting a Password:
    • Enter function code A0-00, input a four-digit non-zero password, and press ENT to confirm.
    • Re-enter the same password within 10 seconds to confirm, and “P-Set” will be displayed upon successful setting.
    • If there are no button operations within 5 minutes or after a complete power-off and power-on cycle, the password will automatically take effect.
  2. Removing a Password:
    • Enter function code A0-00 and input the original four-digit password.
    • Input 0000 twice and press ENT to confirm, and the password will be cleared successfully with “P-Set” displayed.

Initializing Parameters

Users can restore the inverter parameters to their factory settings through the initialization function. The specific operations are as follows:

  • Enter function code A0-03 and set it to 2 (restore all function code group parameters to factory settings, excluding motor parameters) or 3 (restore all function code group parameters to factory settings, including motor parameters), then press ENT to confirm and the parameters will be initialized.

II. Terminal Forward/Reverse Start/Stop and Potentiometer External Speed Regulation

Terminal Forward/Reverse Start/Stop

The GK600 series inverter supports forward/reverse start/stop functions through terminals. The specific settings and wiring are as follows:

  1. Parameter Settings:
    • Enter the C0 group function codes and set the functions of terminals X1, X2, X3, and X4 to forward jog, reverse jog, forward run, reverse run, etc.
    • Set C0-00 to 0 (edge trigger + level valid) or 1 (level valid) based on actual needs.
  2. Wiring:
    • Connect the external control signals to the corresponding forward/reverse start/stop terminals.

Potentiometer External Speed Regulation

Speed regulation can be achieved through an external potentiometer. The specific settings and wiring are as follows:

  1. Parameter Settings:
    • Enter the b0 group function codes and set the frequency main given method b0-01 to 2 (analog input AI1).
    • Ensure that the AI1 terminal is correctly connected to the potentiometer, and select voltage or current input via the jumper.
  2. Wiring:
    • Connect the three pins of the potentiometer to the positive, negative, and ground terminals of the AI1 terminal.
GTAKE INVERTER GK600 Series Standard Wiring Diagram

III. Swing Frequency Function and Length Control

Swing Frequency Function

The swing frequency function allows the inverter to operate with fluctuating frequencies within a set range, suitable for applications requiring periodic frequency changes. The specific parameter settings are as follows:

  • Enter the F3 group function codes and set F3-00 to 1 (select swing frequency function).
  • Set parameters such as F3-01 swing frequency operation mode, F3-02 swing frequency preset, F3-03 swing frequency preset hold time, and F3-04 swing frequency amplitude.

Length Control

Length control automatically stops the inverter based on a set length. The specific wiring and parameter settings are as follows:

  1. Wiring:
    • Connect the length counting pulse signal to the X6/DI terminal.
    • Ensure that the external length sensor or pulse generator is correctly connected.
  2. Parameter Settings:
    • Enter the F3 group function codes and set parameters such as F3-08 set length unit and F3-09 set length.
    • Ensure that C0-06 has set the X6/DI terminal function to length counting.

IV. Fault Code Analysis

The GK600 series inverter features comprehensive fault protection functions, displaying corresponding fault codes when anomalies are detected. Users can quickly locate the cause of the issue based on the fault code and take corresponding measures. Common fault codes and their meanings are as follows:

  • oC1/oC2/oC3: Indicate acceleration overcurrent, constant speed overcurrent, and deceleration overcurrent faults, respectively.
  • ov1/ov2/ov3: Indicate acceleration overvoltage, constant speed overvoltage, and deceleration overvoltage faults, respectively.
  • FAL: Indicates IGBT module protection fault.
  • oL1/oL2: Indicate inverter overload and motor overload faults, respectively.
  • ISF: Indicates input power supply abnormality fault.

Users can analyze the fault cause in detail according to the fault code table in the manual and perform corresponding repairs.

V. Conclusion

The user manual for the GTAKE Inverter GK600 series provides detailed information on the operating panel functions, parameter settings, terminal wiring, and fault code analysis of the inverter. Through this guide, users can quickly master the basic operations of the inverter, realize forward/reverse start/stop and external speed regulation functions, configure swing frequency and length control parameters, and quickly locate and resolve fault issues based on fault codes. It is hoped that this article will provide strong assistance to users when using the GK600 series inverter.