DC Brush Motors – The Classic


The DC brush motor is one of the simplest motors in use today. You can find these motors just about anywhere. They are in household appliances, toys, and automobiles. Being simple to construct and control, these motors are the go-to solution for professionals and hobbyists alike.

The Anatomy of a Brush Motor


To better understand how one works, let’s start by tearing down a simple hobby motor. As you can see, they are simple in construction, comprising of a few key components.


Disected Motor!

Brushes – Delivers power from the contacts to the armature through the commutator
Contacts – Brings power from the controller to the brushes
Commutator – Delivers power to the appropriate set of windings as the armature rotates
Windings – Converts electricity to a magnetic field that drives the axle
Axle – Transfers the mechanical power of the motor to the user application
Magnets – Provide a magnetic field for the windings to attract and repel
Bushing – Minimizes friction for the axle
Can – Provides a mechanical casing for the motor

Theory of Operation DC Brush Motors



As the windings are energized, they attract to the magnets located around the motor. This rotates the motor until the brushes make contact with a new set of commutator contacts. This new contact energizes a new set of windings and starts the process again. To reverse the direction of the motor, simply reverse the polarity on the motor contacts. Sparks inside a brush motor are produced by the brush jumping to the next contact. Each wire of a coil is connected to the two closest commutator contacts.

DC Brush Motors Coils Shown

An odd number of windings is always used to prevent the motor from getting locked into a steady state. Larger motors also use more sets of windings to help eliminate “cogging,” thus providing smooth control at low revolutions per minute (RPMs). Cogging can be demonstrated by rotating the motor axle by hand. You will feel “bumps” in the motion where the magnets are closest to the exposed stator. Cogging can be eliminated with a few tricks in design, but the most prevalent is removing the stator all together. These types of motors are referred to as ironless or coreless motors.


Simple to control
Excellent torque at low RPM
Inexpensive and mass produced

Brushes can wear out over time
Brush arcing can generate electromagnetic noise
Usually limited in speed due to brush heating


Three Basic Types of Stepper Motors

Three basic types of stepper motors include the permanent magnet motor, the variable re-luctance motor, and the hybrid motor, which is a combination of the previous two. 1, Permanent Magnet 2, Variable Reluctance 3, Hybrid Permanent Magnet Figure […]

Stepper Motors – Simply Precise

Stepper Motors – Simply Precise Stepper motors are great motors for position control. They can be found in desktop printers, plotters, 3d printers, CNC milling machines, and anything else requiring precise position control. Steppers are […]

Electromagnetic Chuck for Grinding

Electromagnetic Chuck for Grinding, Electromagnetic Chuck for Surface Grinding, Electromagnetic system Electromagnetic Chuck for Grinding – The coil system in the ElectroMagnetic chuck is designed to spread the heat optimally on the whole surface of the chuck. […]