Disassembly damage and bearing capacity of shaft with surface micro-texture

Yin, Chaochao; Huang, Haihong; Zhou, Dan; Liu, Zhifeng

doi:10.1080/02670844.2022.2113775

Surface Engineering

2022

DOI: 10.1080/02670844.2022.2113775

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Disassembly damage and bearing capacity of shaft with surface micro-texture

Chaochao Yin

Haihong Huang

Dan Zhou

et al.

Abstract: The re-assembly performance of the mating surfaces in interference fit was affected by the disassembly in the previous step due to the serious friction damage. The experimental platform was built to investigate the disassembly damage and bearing capacity of a shaft in an interference fit. The effects of the surface micro-textures with different shapes and densities on disassembly damage and bearing capacity of the shaft in an interference fit were analysed from the micromorphology, microstructure, and material… Show more

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2024

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Machine Learning-Driven Optimization of Micro-Textured Surfaces for Enhanced Tribological Performance: A Comparative Analysis of Predictive Models

Ge,

Hu,

Wang

et al. 2024

Coatings

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Micro-textured surfaces show promise in improving tribological properties, but predicting their performance remains challenging due to complex relationships between surface features and frictional behavior. This study evaluates five algorithms—linear regression, decision tree, gradient boosting, support vector machine, and neural network—for their ability to predict load-carrying capacity and friction force based on texture parameters including depth, side length, surface ratio, and shape. The neural network model demonstrated superior performance, achieving the lowest MAE (24.01) and highest R-squared value (0.99) for friction force prediction. The results highlight the potential of machine learning techniques to enhance the understanding and prediction of friction-reducing micro-textures, contributing to the development of more efficient and durable tribological systems in industrial applications.

show abstract

Machine Learning-Driven Optimization of Micro-Textured Surfaces for Enhanced Tribological Performance: A Comparative Analysis of Predictive Models

Ge,

Hu,

Wang

et al. 2024

Coatings

View full text Add to dashboard Cite

show abstract

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Disassembly damage and bearing capacity of shaft with surface micro-texture

Cited by 1 publication

References 14 publications

Machine Learning-Driven Optimization of Micro-Textured Surfaces for Enhanced Tribological Performance: A Comparative Analysis of Predictive Models

Machine Learning-Driven Optimization of Micro-Textured Surfaces for Enhanced Tribological Performance: A Comparative Analysis of Predictive Models

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