Simulation-based microstructural analysis of thermal–mechanical fatigue behavior in SiCp/A356 composites for brake disc applications

This article presents a study on the fatigue damage behavior of SiCp/A356 composites in severe service conditions of brake discs. A representative volume element (RVE) was constructed using finite element modeling technology to simulate the microstructure characteristics of the composites which take...

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Bibliographic Details
Published in:Journal of materials science 2024, Vol.59 (2), p.650-668
Main Authors: Zang, Jiajun, Yang, Zhiyong, Sun, Mengcheng, Li, Zhiqiang, Wang, Yubo, Ye, Shanshan
Format: Article
Language:English
Subjects:
Brake disks
Characterization and Evaluation of Materials
Chemistry and Materials Science
Classical Mechanics
Composite materials
Compressive properties
Control engineering
Crystallography and Scattering Methods
Damage assessment
Failure modes
Fatigue
Fatigue failure
Fatigue testing machines
finite element analysis
Finite element method
friction
High temperature
Light rail transit
Materials
Materials Science
mechanical stress
Metals & Corrosion
Microcracks
Microstructural analysis
Microstructure
Polymer Sciences
Residual stress
Silicon carbide
Simulation
Solid Mechanics
temperature
Tensile stress
Urban rail
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Summary:This article presents a study on the fatigue damage behavior of SiCp/A356 composites in severe service conditions of brake discs. A representative volume element (RVE) was constructed using finite element modeling technology to simulate the microstructure characteristics of the composites which takes into account the fatigue characteristics of the matrix. The RVE was loaded with local strain components and temperature histories obtained through the simulation of the braking condition of an urban rail train. The study found that the alternating effect of compressive stress and residual tensile stress at the matrix near the interface, especially at the sharp corners of SiC particles, causes fatigue damage on the matrix. Brake temperature was identified as the main factor for thermal–mechanical fatigue damage of the brake disc, and the matrix near the high-temperature position of the friction surface was found to have the highest degree of damage and the fastest failure process. The fatigue microcrack morphology and micro-failure modes inside the RVE were in good agreement with those of SiCp/A356 brake disc, and the RVE was able to characterize the micro-fatigue failure behavior of the SiCp/A356 composites under service thermal–mechanical load. This article provides a novel approach for investigating the thermo-mechanical fatigue behavior of SiCp/A356 composites from macroscopic to microscopic.
ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-023-09195-8