Abstract
Due to expansion of the micro- and nanocomposites application for manufacturing machine components and friction units, the problem of calculation methods for determination of deformability, strength and wear resistance parameters of gear drives made of essentially inhomogeneous disperse-reinforced materials is addressed. The potentialities of analytical and numerical methods are analyzed. The original three-level (micro, meso- and macro) method for tribomechanical parameters optimization of the gears by controlling material reinforcing is presented. Through specific examples, the potentialities of polymer reinforcement for obtaining functional materials for gears which allow for an increase in damping capability, shape stability and life time of the gear driven by the criterion of wear and bending strength have been studied.
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Shil’ko, S., Starzhinsky, V., Petrokovets, E. (2016). Methods and Results of Composite Gears Design. In: Goldfarb, V., Barmina, N. (eds) Theory and Practice of Gearing and Transmissions. Mechanisms and Machine Science, vol 34. Springer, Cham. https://doi.org/10.1007/978-3-319-19740-1_16
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DOI: https://doi.org/10.1007/978-3-319-19740-1_16
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