Extraction of stress intensity factors of biharmonic equations with corner singularities corresponding to mixed boundary conditions of clamped, simply supported, and free (II)

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Tarih

2022

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Yayıncı

Pergamon-Elsevier Science Ltd

Erişim Hakkı

info:eu-repo/semantics/closedAccess

Özet

In [13], we derived stress intensity factors (SIF) extraction formulas of a biharmonic equation delta(2)u = f in a cracked domain whose crack faces have clamped boundary conditions. In this paper, we extend our investigation to the derivation of the SIF extraction formulas of the biharmonic equation in non-convex polygonal domains containing cracks or reentrant corners when various BC such as clamped (CC), simply supported (SS), free (FF), or mixed conditions (CS, FC, SF) are imposed on the boundary. We prove that the SIF is expressed as the integral of f Psi s(k)* - u delta(2)Psi s(k)* for a cut-off function psi and a dual singular function s(k)* on a small neighborhood of the singularity. The dual singular function is determined in this paper. For a numerical approximation of u, we proposed an iteration method as well as a direct finite element method. For a finite element solution of delta(2)u = f, we have to use C-1-continuous basis functions. For continuous differentiable basis functions, we use either C-1 continuous B-spline basis functions or the conventional Hermite basis function. Because of several advantages of B-spline functions in imposing complex boundary conditions, we choose B-spline basis functions for the finite element approximation of u. Moreover, in the direct numerical method, we propose to use implicitly enriched basis functions that resemble the singularities.

Açıklama

Anahtar Kelimeler

Stress Intensity Factor, Biharmonic Equations With Corner Singularities, C-1-Continuous Basis Function, Iterative Method, Enriched Galerkin Method

Kaynak

Computers & Mathematics With Applications

WoS Q Değeri

Q1

Scopus Q Değeri

Q1

Cilt

109

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Künye