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UM E-Theses Collection (澳門大學電子學位論文庫)

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Title

Dual boundary element analysis of fatigue crack growth in two-dimensional linear elastic fracture problem

English Abstract

The objective of this study was the analysis of fatigue crack growth in two-dimensional case and presents an analysis of mixed-mode fracture problems arising in isotropic material. Basic concepts of fracture mechanics are discussed to analyze their applicability in modeling fatigue crack propagation. Special attention was given to the calculation of stress intensity factors of crack tips under mixed Mode I and Mode II in linear elastic fracture problems. Boundary element method and the J integral used in this thesis were accurate techniques widely used to the computation of stress intensity factors KI and KII. The recent developed dual boundary element method was introduced to analysis the fatigue crack growth. The basic equations of this method were the displacement and the traction boundary integral equations (BIEs). Applying the first BIE on one of the crack surfaces and the second one on the other, one can solve the general crack iv problems in a single-region analysis. Finite element based Franc2D is also used in the fracture analysis to verify the results of the boundary element method. Examples of geometries with an embedded eccentric crack and two inclined cracks were analyzed using dual BEM and FEM. The accuracy of stress intensity factors obtained from BEM was verified by those obtained from FEM and the analytical ones in relative reference. It was found in this work that the dual boundary element method was an effective method in the analysis of fatigue crack extension. For the fatigue analysis, numerical examples of problems under pure mode I and mixed mode deformations were given. Another example was given to present the whole process of fatigue analysis for a specify crack problem.

Issue date

2012.

Author

Li, Jian Tao

Faculty
Faculty of Science and Technology
Department
Department of Civil and Environmental Engineering
Degree

M.Sc.

Subject

Fracture mechanics

Materials -- Fatigue

Supervisor

Kou, Kun Pang

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TOC & Abstract

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Location
1/F Zone C
Library URL
991001459189706306