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HomeNano Hybrids and CompositesNano Hybrids and Composites Vol. 32Frictional Heat Simulation of Brake Composites in...

Frictional Heat Simulation of Brake Composites in a Pin-on-Disc Tribotesting

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Abstract:

This paper presents the comparative investigation of temperature distributions in the pin-on-disc tribo-contact with dry friction conditions. Heat generation and distribution mechanism in contact of a pin made by phenolic resin–based brake friction composite and 35HNL steel disc counter-face material were studied. Both experimental and simulation methods were used to study the temperature changes. In order to analyse the thermal effects, the change in the coefficient of friction with time were also characterized. Experimental friction tests performed on universal “pin-on-disc"-type friction and wear test machine model MMW-1. Interface temperature measurements of the disc was conducted non-contact type infra-red laser thermometer. Heat simulations were modelled via finite element method using COMSOL Multiphysics 5.5, Heat Transfer in Solid Module. The simulations helped to determine in the increase of temperature over selected time period. Obtained experimental results compared with results of numerical analysis.

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Nano Hybrids and Composites Vol. 32

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Periodical:

Nano Hybrids and Composites (Volume 32)

Pages:

63-71

DOI:

https://doi.org/10.4028/www.scientific.net/NHC.32.63

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Online since:

April 2021

Authors:

Fikrat Fakhraddin Yusubov*

Keywords:

Brake Pad, Comsol Multiphysics, FEM Model, Frictional Heat, Pin-on-Disc, Simulation

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* - Corresponding Author

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