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Electric Motor Presentation


Electric motor bearings
The purpose of a bearing in an electric motor is to support and locate the rotor, to keep the air gap small and consistent and transfer the loads from the shaft to the motor. The bearings should be able to operate at low and high speeds whilst minimizing frictional loses. At the same time the bearing must be economic and require absolutely minimal maintenance (if any).

The following points are considered for selecting bearings during motor design


Weights and forces involved
Power transmitted
Magnetic pull as a result of unsymmetrical air gaps
Dynamic forces due to inaccurate adjustment
Out-of-balance situations
Pitch errors in gears
Potential thrust loads

Heavy loads are usually left to roller bearings and lighter loads are carried by ball bearings. Directions of all these loads will have direct relevance on your choice of bearing.

For example, cylindrical rollers can carry high radial loads but virtually no axial loads. Other bearings such as angular contact ball bearings can carry radial and axial loads.


The prescribed shaft speed will have a direct effect on the choice of lubricant, bearing size, cage design, internal clearance and shield/seal types. Induction motors and pulse modulation motors can produce electrical pitting or ribbing on bearing raceways, hence insulated bearing options are to be considered.

Coupling with gears or belts

The type of motor connection will produce load on the motors bearings. A coupling drive can produce forces in various directions; hence alignment is of key importance here.
In many cases a roller bearing with a degree of shaft float is used at the drive end and at the other a ball bearing, hence fixing the float direction and magnitude. A belt or gear take off can place higher loads than a coupling.

Vertical mounting arrangements

Motors, which are to be operated vertically, should have special consideration. Bearing arrangement is vital in vertical mounting, as are lubricant requirements.

Operating Environment

High humidity or damp conditions will require the bearing to have seals or shields. Solid contamination such as dust, mud, wood chips, metal flakes and other solid material will also require the bearing to have shields or seals. It should be born in mind that where solid contamination is high then secondary forms of sealing are desirable.


Ambient temperatures
Operating temperatures
Bearings generate their own heat but most heat will come from the rotor. Either air, oil or water can be used to cool the bearing however when there is the possibility of a high temperature gradient from the inner ring to the outer ring then special attention should be paid to the internal clearance. If no care is taken preloading could occur which will quickly lead to bearing failure.


In high vibration conditions cylindrical roller bearings provide the most resistance although special care should be taken over cage selection.

Low noise

Some applications require low noise bearings in which case deep groove bearings coupled with low noise grease provide the best solution. Bearing clearance can also have an effect here.

Bearing life

The life of a bearing is defined as the number of revolutions (or the number of operating hours at a given constant speed) the bearing can endure before the first sign of fatigue. The service life of a bearing depends to a large extent on the operating conditions while procedures used to mount and maintain it are equally important.


Grease lubrication should always be used where possible in motor applications. It simplifies maintenance and prolongs bearing life. Where speeds and temperatures are high then oil lubrication should be considered.


Motor maintenance normally consists of:
Servicing of the stator windings
Lubrication of the bearings
Monitoring of the motor performance
Permanently lubricated bearings that have shields or seals fitted do not require any relubrication, thus these are maintenance free.


The accuracy of the equipment will determine the accuracy of the precision grade of the bearings. For high precision bearings (normally associated with high speeds) the seating areas on the shaft need to be machined to corresponding levels of surface finish and roundness + concentricity.


Bearing type Load direction (magnitude) Speed
Tapered roller bearing Uniaxial (high), radial (high) Moderate
Ball bearing Axial (low), radial (moderate) High
Cylindrical roller bearing Radial (high) Moderate
Angular-contact ball bearing Axial (moderate), radial (moderate) High
Spherical-roller thrust bearing Uniaxial (moderate to heavy) High
Toroidal roller bearing Radial (high) Moderate