Lubrication conditions - the viscosity ratio κ
The effectiveness of the lubricant is primarily determined by the degree of surface separation between the rolling contact surfaces. If an adequate lubricant film is to be formed, the lubricant must have a given minimum viscosity when the application has reached its normal operating temperature. The condition of the lubricant is described by the viscosity ratio κ as the ratio of the actual viscosity ν to the rated viscosity ν1 for adequate lubrication, both values being considered when the lubricant is at normal operating temperature (→ Selecting lubricating oils).
It follows from using
|ν||=||actual operating viscosity of the lubricant [mm2/s]|
|ν1||=||rated viscosity depending on the bearing mean diameter and rotational speed [mm2/s]|
The rated viscosity ν1, required for adequate lubrication, can be determined from diagram 1, using the bearing mean diameter dm = 0,5 (d + D), [mm], and the rotational speed of the bearing n [r/min]. This diagram has been revised taking the latest findings of tribology in rolling bearings into account.
When the operating temperature is known from experience or can otherwise be determined, the corresponding viscosity at the internationally standardized reference temperature of 40 °C (150 °F) can be obtained from diagram 2, or can be calculated in the Viscosity calculator. The diagram is compiled for a viscosity index of 95. Table 1 lists the viscosity grades according to ISO 3448:1992 showing the range of viscosity for each class at 40 °C (150 °F) Certain bearing types, e.g. spherical roller bearings, tapered roller bearings, and spherical roller thrust bearings, normally have a higher operating temperature than other bearing types, e.g. deep groove ball bearings and cylindrical roller bearings, under comparable operating conditions.