Materials for bearing rings and rolling elements

Bearing steels for through-hardening
The most common steel for through-hardening is a carbon chromium steel (100Cr6), containing approximately 1% carbon and 1,5% chromium, in accordance with ISO 683-17:1999. Today, carbon-chromium steel is one of the oldest and most intensively investigated steels due to the continuously increasing demands for extended bearing service life. The composition of this bearing steel provides an optimum balance between manufacturing and application performance. This steel normally undergoes a martensitic or bainitic heat treatment to obtain a hardness between 58 and 65 HRC.
Within the last few years, process developments have enabled more stringent cleanliness specifications to be realized, which has had a significant impact on the consistency and quality of SKF’s bearing steel. The reduction of oxygen and harmful non-metallic inclusions has led to significantly improved properties of rolling bearing steels – the steels from which SKF Explorer bearings are made.
Bearing steels for induction-hardening
Surface induction-hardening offers the possibility to selectively harden a component’s raceway, while leaving the remainder of the component unaffected by the hardening process. The steel grade and the manufacturing processes used prior to surface induction-hardening dictate the properties in the unaffected areas, which means that a combination of properties can be achieved in one component.
An example of this is the flanged wheel hub bearing unit (HBU), where the properties of the unhardened flange must resist structural fatigue, while the raceways are hardened to resist rolling contact fatigue.
Bearing steels for case-hardening
Chromium-nickel and manganese-chromium alloyed steels in accordance with ISO 683-17:1999 with a carbon content of approximately 0,15% are the steels most commonly used for case-hardened SKF rolling bearing components.
In applications where there are high tensile interference fits and heavy shock loads, SKF recommends bearings with case-hardened rings and/or rolling elements.
Stainless steels
The most common stainless steels used for SKF bearing rings and rolling elements are high chromium content steels like X65Cr13 in accordance with ISO 683-17:1999 and X105CrMo17 in accordance with EN 10088-1.
It should be noted that for some applications, corrosion resistant coatings might be an excellent alternative to stainless steel. For additional information about alternative coatings, contact the SKF application engineering service.
High-temperature bearing steels
Depending on the bearing type, standard bearings made of steels for through-hardening and surface-hardening have a recommended maximum operating temperature, which ranges between 120 and 200 °C (250 to 390 °F). The maximum operating temperature is directly related to the heat treat process.
For operating temperatures up to 250 °C (480 °F), a special heat treat (stabilization) process can be applied. In this case, however, the process reduces the load carrying capacity of the bearing, which must be taken into consideration.
For bearings operating at elevated temperatures above 250 °C (480 °F) for extended periods, highly alloyed steels like 80MoCrV42-16, manufactured in accordance with ISO 683-17:1999, should be used. This steel, which retains its hardness, enables the bearing to maintain its performance characteristics even under extreme temperature conditions. For additional information about high-temperature bearing steels, contact the SKF application engineering service.
The common ceramic used for SKF bearing rings and rolling elements is a bearing grade silicon nitride in accordance with ISO 26602:2009. It consists of fine elongated grains of beta-silicon nitride in a glassy phase matrix. It provides a combination of favourable properties for rolling bearings:
  • high hardness
  • high modulus of elasticity
  • low density
  • low coefficient of thermal expansion
  • high electric resistivity
  • low dielectric constant
  • no response to magnetic fields
For information about material properties, refer to table 1.
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