MOOG D136-001-008 Servo valve controller

MOOG D136-001-008 Servo valve controller

Product Overview

The MOOG D136-001-008 Servo Valve Controller is typically used in industrial and mechanical applications to control hydraulic or pneumatic servo valves for precise flow, pressure or position control. The controllers are suitable for a variety of applications including, but not limited to, industrial automation, aerospace, medical devices, energy, and more.

Key Features

Flow Control: The MOOG D136-001-008 servo valve controller is capable of accurately controlling the flow of a fluid (liquid or gas) to meet specific flow control needs.

Pressure control: The controller can control the pressure of the fluid to ensure that the system operates within a safe and stable operating range.

Position control: For hydraulic servo valves, the MOOG D136-001-008 enables precise position control of the actuator or valve to control the motion of the work unit.

Feedback System: Servo valve controllers are often used in conjunction with feedback sensors to monitor actuator position, flow, or pressure for closed-loop control. the MOOG D136-001-008 also has this feature, which improves the accuracy and stability of control.

Programmability: The MOOG D136-001-008 servo valve controller may be programmable, allowing the user to adjust and configure the parameters according to the needs of different applications. This makes the controller more flexible and adaptable.

Communication Interface: The controller may have a communication interface that allows data exchange and communication with other control systems or devices. This helps with system integration and remote monitoring.

High performance: The MOOG D136-001-008 servo valve controller usually has high performance computing power to handle high speed and high precision motion requirements. It also provides real-time control functions to ensure rapid response of the mechanical system to input signals.

Multi-axis motion control: In addition to the control of individual servo valves, the MOOG D136-001-008 also supports multi-axis motion control functions, which can control multiple axes of motion (e.g., servo motors or stepper motors) to realise complex mechanical movements.

Technical Specifications and Benefits

The current loop bandwidth is up to 2500Hz, providing fast response and precise control.

Adopts self-developed CANopen communication protocol, which defines a variety of standard communication interfaces to achieve communication, network management and emergency handling functions.

Servo full closed-loop control, for equipment with high positioning accuracy or dynamic response, solves the precision error brought by intermediate link transmission, and finally realises high precision and responsive positioning.

Configuration of high-precision absolute value code disc improves the control precision and overall performance of the servo system.

Application Areas

MOOG D136-001-008 servo valve controller has a wide range of applications in many fields, including but not limited to:

Industrial automation: used to control hydraulic or pneumatic servo valves in various automation equipment to achieve precise motion control.

Aerospace: In the aerospace field, the controller can be used to control the hydraulic and pneumatic systems of aircraft to ensure flight safety and stability.

Medical Equipment: In medical equipment, the MOOG D136-001-008 can be used to control a variety of precision hydraulic or pneumatic actuators, such as surgical robots and rehabilitation equipment.

Energy: In the energy field, the controller can be used to control a variety of hydraulic or pneumatic-driven energy equipment, such as oil drilling rigs, wind power generation equipment, and so on.

Technical Specifications

Voltage & Current: Specific voltage and current specifications may vary depending on application scenarios and customisation needs, but usually feature multiple voltage and frequency adaptations to suit different regional power standards.

Durability and Safety: High-quality power interface boards are typically made of durable materials and equipped with safety devices such as fuses and circuit breakers to ensure long term reliability and stability while protecting the equipment and users.

Communication features: Some power interface boards may have communication interfaces that allow the device to communicate with a computer or other control system for remote monitoring and control.

Indicator lights and displays: Some power interface boards may be equipped with indicator lights for displaying information such as power status, connection status, etc., which are convenient for users to carry out troubleshooting and status monitoring.

Application Areas

Power generation plants: monitoring and controlling generators, steam turbines, governors and other equipment to ensure the stable operation of the power generation system.

Power transformer and distribution: used in substations and distribution stations to monitor and control transformers, circuit breakers, voltage regulators and other equipment.

Grid control: applied in monitoring, scheduling and control of power systems to ensure the stability and reliability of power networks.

Industrial process control: in manufacturing and chemical plants for automating and monitoring production processes.

Energy Management System: supports the monitoring, analysis and optimisation of energy systems to improve energy efficiency.

Power Generation Scheduling: Coordinates and optimises the operation of power generation plants to meet electricity demand.

Smart Grid: in smart grids to support the digitisation and intelligence of power grids.