Stress Intensity Factor of Interface Crack in the Cermet Cladding Material Structure under Steady Mechanical-Thermal Coupled Loads

Jun Ru Yang; Yu Rong Chi; Ming Lan Wang; Ran Zhu

doi:10.4028/www.scientific.net/KEM.723.394

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 723Stress Intensity Factor of Interface Crack in the...

Stress Intensity Factor of Interface Crack in the Cermet Cladding Material Structure under Steady Mechanical-Thermal Coupled Loads

Abstract:

In the paper, the crack parallel to and lying on the interface in the hard cermet cladding material structure is taken as the study object. Theoretical models of the stress intensity factor (SIF) of the interface crack under steady mechanical-thermal coupled loads are built. Based on which the interface crack SIFs in the cermet cladding material of 5Cr2Ni08C/Q235 under the same loads are analyzed with the finite element method. The crack SIF change laws under the coupled loads are obtained. K_Iincreases with the increase of the temperature, the mechanical load and the crack length respectively. The absolute values of K_II have the same change laws. And K_I corresponding to the coupled loads is bigger than that to the single load. The research results are very important to develop the interface crack propagation theory. And they will also improve the optimization designs of the hard cladding material parts, and expand their applications.

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Proceedings of International Conference on Material Science and Engineering 2016

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Periodical:

Key Engineering Materials (Volume 723)

Pages:

394-399

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.723.394

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Online since:

December 2016

Authors:

Jun Ru Yang*, Yu Rong Chi, Ming Lan Wang, Ran Zhu

Keywords:

Cermet Cladding Material Structure, Interface Crack, Mechanical-Thermal Coupled Loads, Stress Intensity Factor

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