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30-11-2018 | Composites

Mechanical characterization by multiscale instrumented indentation of highly heterogeneous materials for braking applications

Authors: Stephania Kossman, Alain Iost, Didier Chicot, David Mercier, Itziar Serrano-Muñoz, Francine Roudet, Philippe Dufrénoy, Vincent Magnier, Anne-Lise Cristol

Published in: Journal of Materials Science | Issue 6/2019

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Abstract

This work is focused on the mechanical characterization by multiscale indentation (nano and macro) of a brake pad material, with multiple phases and complex microstructure for applications in the railway industry. Grid nanoindentation tests allowed to identify the mechanical properties of the components in the formulation. The significant difference between constituent’s properties gives a quickly composite response. In parallel, multicyclic macroindentation tests were performed to obtain a composite mechanical response. The properties change according to test locations and configurations of staking phases, due to the high heterogeneity of the brake pad material. The results demonstrated that multiscale indentation tests give a consistent response, which approximates the mechanical properties at different scales. Considering such a very heterogeneous material (broad distribution of properties and particle sizes), the used methodology is appropriate for other heterogeneous complex materials. A multiscale characterization of the mechanical properties is necessary to deal with the problematic of vibrations induced by friction, particularly for brake squeal prediction.

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Title: Mechanical characterization by multiscale instrumented indentation of highly heterogeneous materials for braking applications
Authors: Stephania Kossman
Alain Iost
Didier Chicot
David Mercier
Itziar Serrano-Muñoz
Francine Roudet
Philippe Dufrénoy
Vincent Magnier
Anne-Lise Cristol
Publication date: 30-11-2018
Publisher: Springer US
Published in: Journal of Materials Science / Issue 6/2019
Print ISSN: 0022-2461
Electronic ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-018-3158-7

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