Determining the deformations and the contact stress of the rollers in the roller bearing structure is difficult to achieve experimentally. Usually the research focuses on calculations of the contact stress at the roller-ring contact and considers the general model of the Hertz-type contact with various particularities. The aim of the paper is to develop a measuring methodology for the elastic deformations of the rollers in the structure of general-purpose roller bearing. Experimental work was performed on determining the elastic roller deformations for the most loaded roller using a non-contact and material-independent method based on the principle of digital image correlation (DIC) - without expensive and time-consuming preparations. The experimental data was used further to perform more accurate Finite Element Analysis.

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Alshorman, O., Irfan, M., Saad, N., Zhen, D., Haider, N., Glowacz, A., A. AlShorman, A., A Review of Artificial Intelligence Methods for Condition Monitoring and Fault Diagnosis of Rolling Element Bearings for Induction Motor, Shock and Vibration, Article ID 8843759, 2020.

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Yu Hou, Xi Wang, Measurement of load distribution in a cylindrical roller bearing with an instrumented housing: Finite element validation and experimental study, Tribology International, 155, 2021.

Wenbin Wu, Dong Zhao, Jian Zhao, Removable camera based 2D digital image correlation for planar slender area quasi-static deformation measurement, Optik, Volume 226, Part 1, 2021.

Vieira, F.G.; Scari, A.S.; Magalhães Júnior, P.A.A.; Martins, J.S.R.; Magalhães, C.A. Analysis of Stresses in a Tapered Rolle r Bearing Using Three-Dimensional Photoelasticity and Stereolithography. Materials, 12, 3427, 2019.