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Solution of General Stress Concentrators in Anisotropic Media by Combination of FEM and the Complex Potential Theory
Ševeček, Oldřich ; Kotoul, Michal (vedoucí práce)
The thesis focuses to the solution of the problems of general stress concentrators in anisotropic media. Particularly, it is a problem of cracks terminating on the interface of two dissimilar materials or problems of general multi-material wedge. The main aim of the work is to work up a complex toolbox for the assessment of general stress concentrators, i.e. a tool for the description of the stress field in its vicinity, the inclusion of the crack bridging effect into the resulting stress field, and the definition of the fracture criteria for the crack impinging at the interface in dissimilar anisotropic media. For the description of the stress field the so-called Lechnitskii-Stroh formalism and continuously distributed dislocation technique, exploiting the complex potential theory is used. The work also widely employs the two-state "psi"-integral (for the calculation of various factors of the asymptotic stress expansions) based on the Betti´s reciprocal theorem in combination with FEM. For the fracture criterion definition the theory of Finite Fracture Mechanics and matched asymptotic expansions is used. Especially the competition between the crack deflection along the interface and the crack penetration into the base material is studied. All the needed calculations are performed in the mathematical softwares MAPLE 10.0, MATLAB 7.1 and in the finite element system ANSYS 10.0.
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Solution of General Stress Concentrators in Anisotropic Media by Combination of FEM and the Complex Potential Theory
Ševeček, Oldřich ; Kotoul, Michal (vedoucí práce)
The thesis focuses to the solution of the problems of general stress concentrators in anisotropic media. Particularly, it is a problem of cracks terminating on the interface of two dissimilar materials or problems of general multi-material wedge. The main aim of the work is to work up a complex toolbox for the assessment of general stress concentrators, i.e. a tool for the description of the stress field in its vicinity, the inclusion of the crack bridging effect into the resulting stress field, and the definition of the fracture criteria for the crack impinging at the interface in dissimilar anisotropic media. For the description of the stress field the so-called Lechnitskii-Stroh formalism and continuously distributed dislocation technique, exploiting the complex potential theory is used. The work also widely employs the two-state "psi"-integral (for the calculation of various factors of the asymptotic stress expansions) based on the Betti´s reciprocal theorem in combination with FEM. For the fracture criterion definition the theory of Finite Fracture Mechanics and matched asymptotic expansions is used. Especially the competition between the crack deflection along the interface and the crack penetration into the base material is studied. All the needed calculations are performed in the mathematical softwares MAPLE 10.0, MATLAB 7.1 and in the finite element system ANSYS 10.0.
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Solution of General Stress Concentrators in Anisotropic Media by Combination of FEM and the Complex Potential Theory
Ševeček, Oldřich ; Knésl, Zdeněk (oponent) ; Náhlík, Luboš (oponent) ; Kotoul, Michal (vedoucí práce)
The thesis focuses to the solution of the problems of general stress concentrators in anisotropic media. Particularly, it is a problem of cracks terminating on the interface of two dissimilar materials or problems of general multi-material wedge. The main aim of the work is to work up a complex toolbox for the assessment of general stress concentrators, i.e. a tool for the description of the stress field in its vicinity, the inclusion of the crack bridging effect into the resulting stress field, and the definition of the fracture criteria for the crack impinging at the interface in dissimilar anisotropic media. For the description of the stress field the so-called Lechnitskii-Stroh formalism and continuously distributed dislocation technique, exploiting the complex potential theory is used. The work also widely employs the two-state "psi"-integral (for the calculation of various factors of the asymptotic stress expansions) based on the Betti´s reciprocal theorem in combination with FEM. For the fracture criterion definition the theory of Finite Fracture Mechanics and matched asymptotic expansions is used. Especially the competition between the crack deflection along the interface and the crack penetration into the base material is studied. All the needed calculations are performed in the mathematical softwares MAPLE 10.0, MATLAB 7.1 and in the finite element system ANSYS 10.0.
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