What are the main parts of a simple motor?

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No matter the type of motor, there are three basic parts: a stator, a commutator, and a rotor. Together they use electromagnetism to cause the motor to spin. As long as the motor receives steady current, the motor works.

What are the six parts of a simple motor?

These six components include:

• 1) The Rotor. The rotor is the moving part of your electric motor. …
• 3) The Bearings. The rotor in your electric motor is supported by bearings, which allow it to turn on its axis. …
• 4) The Windings. …
• 5) The Air Gap. …
• 6) The Commutator. …
• What Do All of These Components Have in Common?

What are the three main parts of a simple motor?

Electric motor designs can vary quite a lot, though in general they have three main parts: a rotor, a stator and a commutator. These three parts use the attractive and repulsive forces of electromagnetism, causing the motor to spin continually as long as it receives a steady flow of electric current.

What are the 5 parts of an electric motor?

Here’s a look at five main parts of an electric motor.

• Rotor. This is the electric motor’s main moving part. …
• Stator. The stator plays a crucial role in creating the magnetic field needed to drive the rotating armature. …
• Air Gap. …
• Windings. …
• Commutator.

What are two main components of an electric motor?

The two main components of this kind of motor are the stator (stationary element) and the rotor (rotating element). The stator is a fixed part of the stationary motor.

What is the difference between an electric motor and a generator?

Difference Between Motor and Generator in Detail

An electric motor converts electrical energy into mechanical or kinetic energy, whereas the electric generator transforms the electric energy into mechanical/kinetic energy. … Getting electricity supply during power off is possible because of generators.

How does a simple motor works?

This simple electric motor works by the magnetic force F = IL x B. … The magnetic field at both of these spots points in the same direction. Thus, the magnetic force on the wire at opposite ends of the loop points in opposite directions, causing it to spin.