Abstract
The production process significantly influences the surface properties of rolling element bearings raceways. Deep rolling can induce a depth dependent residual stress state. Previous numerical and experimental studies have shown that rolling bearings fatigue life can be positively influenced by high compressive residual stress to a depth of around 300 µm from the surface. By extending the components life, the resource efficiency of machine components can be increased. In order to determine the influence of the residual stress state in bearing fatigue life, a calculation method was developed for predicting the bearing fatigue life. This method was validated for hard-turning and subsequent deep rolling by experiments on a test rig in four-bearing configuration under radial load. An increase of the L10 bearing life by a factor of 2.5 has been achieved by inducing residual stresses on the bearing’s inner ring. Due to similar process control, the manufacturing steps turning and deep rolling were combined. Bearings were manufactured combining the processes hard-turning and deep rolling (called turn-rolling). The heat from the hard machining has an effect on the residual stresses in the bearing subsurface, thus further altering the magnitude and maximum depth of the residual stress influencing the microstructure. With these bearings, the additional fatigue life was determined experimentally and compared to the results of the bearings produced by hard-turning and subsequent deep rolling. It could be shown, that the process of hard turning and subsequent deep rolling has highest potential to achieve improved bearing fatigue life. These findings were transferred to a “Tailored Forming” shaft with integrated raceway in a second step. In this case, a shaft made of mild steel is combined with a cladding layer of high strength bearing steel to be used as a bearing raceway.
Highlights
A high reliability of machine elements under relative motion is of main importance
The aim of this study is to provide guidelines for optimized manufacturing processes for so called “Tailored Forming” machine elements such as multi-material shafts with integrated raceways for cylindrical roller bearings (CRB), as used in Coors et al (2018)
A bearing steel with a high resistance to wear and fatigue like 100Cr6 or better, is applied by plasma powder deposition welding on low-cost steel shafts, c.f. (Golovin et al, 2019). This allows for the local deposition of high strength steel, which serves as the raceway for a rolling element bearing and covers the fatigue life-determining material volume regarding rolling contact fatigue, c.f. (Behrens et al, 2019)
Summary
A high reliability of machine elements under relative motion is of main importance. The dimensions of machine elements are calculated for reliability. Bearings properties as typical highly loaded machine elements are based on proven conventional production techniques. During operation bearings have to resist very high cyclic stresses. The fatigue life of rolling bearings is influenced in particular by the raceway properties. Böhmer provides an overview of the load conditions and material behavior of rolling contacts in Böhmer (1998).
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