A motor encoder is a rotary encoder mounted on a motor and is an electromechanical device that provides a closed-loop feedback signal by tracking the speed and/or position of the motor shaft, which is used by the control system to monitor specific parameters of the application, And make adjustments as necessary to keep the machine running as required. The parameters monitored by the motor encoder are determined by the type of application, including speed, distance, RPM, position, etc. Applications that utilize encoders or other sensors to control specific parameters are known as closed-loop feedback or closed-loop control systems.

A motor encoder is a rotary encoder mounted on a motor and is an electromechanical device that provides a closed-loop feedback signal by tracking the speed and/or position of the motor shaft, which is used by the control system to monitor specific parameters of the application, And make adjustments as necessary to keep the machine running as required. The parameters monitored by the motor encoder are determined by the type of application, including speed, distance, RPM, position, etc. Applications that utilize encoders or other sensors to control specific parameters are known as closed-loop feedback or closed-loop control systems.

The environment in which the motor encoder is used will determine the motor encoder technology that needs to be used. Two broad motor encoder technologies are: the output of an incremental motor encoder is used to control the speed of the motor shaft, and the output of an absolute motor encoder indicates the speed of the motor shaft. Absolute motor encoders are most commonly used on servo motors in applications requiring positional accuracy.

Motor encoders are available in a wide variety of configurations such as incremental or absolute, optical or magnetic, with shaft or hub/hollow shaft, etc.
The type of motor encoder used depends on many factors, notably the type of motor, the application requiring closed-loop feedback, and the desired mounting configuration. When selecting components for a closed-loop control system, determine the motor encoder based on the type of motor selected for the application. The most common types are:

1.AC motor encoder

AC induction motors are economical and robust, making them a popular choice for general automated machine control systems. In applications using AC motors, motor encoders are used for more precise speed control and are often required to have stronger IP, shock and vibration parameters. Incremental encoders are often used to help stop a AC motor at a desired position, thereby changing the angle and position of a motor-driven device.

2.Servo motor encoder

Servo motor encoders (permanent magnet motor encoders) provide closed-loop feedback control systems for applications that require greater precision and precision and are not as powerful as AC induction motors. Motor encoders used on servo motors can be modular, with a choice of incremental or absolute, depending on the level of resolution and accuracy required.

3.stepper motor encoder

Stepper motors are cost-effective, accurate, and are typically used in open-loop systems. In systems using stepper motors that require speed control, an incremental motor encoder is often mounted on the motor. This will allow the stepper motor system to obtain a closed-loop feedback. Stepper motor encoders are also used in some applications to improve control of stepper motors by providing precise feedback of the motor shaft position relative to the step angle.

4.DC motor encoder

DC motor encoders are used for speed control feedback in DC motors in which an armature or rotor with wound wires rotates within a magnetic field generated by a stator. A DC motor encoder provides a mechanism to measure rotor speed and provide closed-loop feedback to the drive for precise speed control.

Considerations for Installing a Motor Encoder

The next factor that affects motor encoder selection is the mounting options, the most common options are: Shaft motor encoders use a coupling method to connect the motor encoder shaft to the motor shaft. Couplings provide mechanical and electrical isolation from the motor shaft, but add cost through the coupling and the longer shaft length required to mount the motor encoder, hub/hollow shaft encoders are mounted directly via a spring-loaded cord on the motor shaft. This method is easy to install and does not require shaft alignment, but proper measures must be taken to provide electrical isolation. Bearingless motor encoders are also known as ring mounts, this mounting option consists of a sensor assembly mounted in a ring form on the face of the motor and a magnetic wheel mounted on the motor shaft.