- Title
- Development of the scaled boundary finite element method for crack propagation modeling of elastic solids subjected to coupled thermo-mechanical loads
- Creator
- Iqbal, M. D.; Birk, C.; Ooi, Ean Tat; Gravenkamp, H.
- Date
- 2021
- Type
- Text; Journal article
- Identifier
- http://researchonline.federation.edu.au/vital/access/HandleResolver/1959.17/180075
- Identifier
- vital:15689
- Identifier
-
https://doi.org/10.1016/j.cma.2021.114106
- Identifier
- ISBN:0045-7825 (ISSN)
- Abstract
- This study presents the development of the scaled boundary finite element method to model discrete crack propagation induced by thermal loads. The SBFEM excels in modeling stress singularities at sharp crack tips with high accuracy. Polygon meshes are used so that a robust local re-meshing algorithm can be utilized to propagate the crack. The scaled boundary finite element formulation for steady-state thermal stress analysis is presented. Following a scaled boundary finite element analysis of a given thermal problem, the effect of initial strains due to temperature is taken into account semi-analytically in a subsequent stress analysis. Several numerical examples are presented to validate the technique and illustrate its salient features. © 2021
- Publisher
- Elsevier B.V.
- Relation
- Computer Methods in Applied Mechanics and Engineering Vol. 387, no. (2021), p.
- Rights
- All metadata describing materials held in, or linked to, the repository is freely available under a CC0 licence
- Rights
- Copyright @ 2021 Elsevier B.V.
- Subject
- 01 Mathematical Sciences; 09 Engineering; Crack propagation; SBFEM; Stress intensity factors; Thermoelasticity
- Reviewed
- Funder
- The research reported herein was partially performed within the scope of the Australia–Germany Joint Research Cooperation and DAAD-PPP (Australia) Schemes. The financial support of Universities Australia and the German Federal Ministry of Education and Research represented by the German Academic Exchange Service are gratefully acknowledged. The first author would also like to thank Mercator Research Centre Ruhr for providing travel support within the scope of project Pr-2017-0017.
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