Calculation method for the static carrying curve of double-row different-diameter ball slewing bearings

• Published in: Science progress (1916) Vol. 106; no. 2; p. 368504231180026
• Main Authors: Li, Yunfeng, Wang, Rundong, Mao, Feiran
• Format: Journal Article
• Language: English
• Published: London, England SAGE Publications 01.04.2023; Sage Publications Ltd
• Subjects: Axial loads; Carrying capacity; Contact angle; Coordinates; Design parameters; Diameters; Equilibrium conditions; Finite element method; Grooves; Load distribution; Load distribution (forces); Mathematical analysis; Original Manuscript; Slewing; mechanical model; design parameter; Slewing bearing; finite element analysis; carrying capacity
• ISSN: 0036-8504; 2047-7163
• DOI: 10.1177/00368504231180026

A method for calculating the static carrying curve of a double-row different-diameter ball slewing bearing was proposed. The relationship between the internal maximum rolling element load of each row and the combined external axial load and tilting moment load of the slewing bearing was established using the deformation compatibility and force equilibrium conditions. The rolling element load distribution range parameters of the main and auxiliary raceways of the double-row different-diameter ball slewing bearing were used as input invariables, and the corresponding external load combinations of the axial and tilting moment loads of the slewing bearing were obtained. These external load combinations were plotted in the coordinate system to obtain the static carrying curve of the slewing bearing. The obtained static carrying curve was compared with that calculated using the finite element method for verification. Finally, the influences of detailed design parameters such as the raceway groove radius coefficient, raceway contact angle, and rolling element diameter on the carrying capacity of the double-row different-diameter ball slewing bearing were analyzed based on the carrying curves. As the groove radius coefficient increases from 0.515 to 0.530, or the contact angle increases from 50° to 65°, the carrying capacity of the slewing bearing decreases. As the rolling element diameter increases from 0.90 times the initial diameter to 1.05 times the initial diameter, the carrying capacity of the slewing bearing increases.