Radial play is a major consideration when selecting a bearing. Prior to fitting a bearing has an ‘initial’ amount of play and after being mounted it has a ‘residual’ radial play (sometimes referred to as operational radial play as it is what is remaining). When a shaft is supported between bearings then consideration needs to be given to the alignment of the bearings as misalignment reduces radial play, therefore it is important that selection accounts for this. There should always be some ‘residual’ radial play after fitting as this extends bearing life by avoiding skidding and reducing axial play.

There are a number of things that can change radial play during fitting. A tight shaft, larger than the inner ring, will expand the inner ring and this can reduce radial play up to 80% of the interference fit. The same thing happens if the outer ring is larger than the housing diameter, the ring is effectively compressed and reduces radial play in the same way. If there was a temperature difference seen between the shaft and the housing then thermal expansion either on the inner or outer ring, would lead to a reduction in radial play. This may be calculated as opposite:

Chrome Steel – 0.0000125 x (inner ring temp – outer ring temp °C) x outer ring raceway diameter in mm.

440 Stainless Steel – 0.0000103 x (inner ring temp – outer ring temp °C) x outer ring raceway diameter in mm.

The outer ring raceway diameter is roughly calculated as: 0.2 x (d + 4D) where d is the bore in mm and D is the outer diameter in mm.

Another factor to consider relating to thermal expansion is the material that is used for the shaft and housing. For example, a housing material with a higher coefficient of expansion than the bearing material could under certain conditions ‘squeeze’ the bearing outer ring and reduce radial play.