Summary
In automotive traction drives, power is transmitted by friction forces. The friction forces result from the shear stresses developed in lubricated and highly loaded contacts between rolling bodies. Due to the kinematics of a traction drive, shear velocities occur in both the rolling direction and perpendicular to it. Due to these shear velocities and by normal pressure, the lubricant is forced to build up shear stresses. The increase of the shear stresses may be modelled by a nonlinear viscous element. The describing differential equations are coupled by the equivalent shear stress, which defines the nonlinear behaviour of the element. A fast method is described to evaluate the coupled differential equations. By using a known analytical approximation for the equivalent shear stress, the differential equations are decoupled and can be solved analytically. In an iterative procedure the equivalent shear stress is updated, and the complete solution is found. The iterative method is extended to account for thermal effects in the contact.
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Received 17 June 1999; accepted for publication 26 October 1999
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Bork, H., Pfeiffer, F. Fast evaluation of friction forces in traction-drive contacts including thermal effects. Archive of Applied Mechanics 70, 479–488 (2000). https://doi.org/10.1007/s004190000083
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DOI: https://doi.org/10.1007/s004190000083