On solving the cracked‐beam problem by block method

Abstract: SUMMARYAn extremely accurate solution is obtained for the cracked-beam problem by one-block version of the block method (BM). The obtained numerical results demonstrate the exponential convergence of the BM with respect to the number of quadrature nodes. A simple and high accurate formula to compute the stress intensity factor is given. The comparisons with other high accurate results in the literature have been carried out.

“…Moreover, the classic Jacobi or Gauss-Seidel iterations converge as geometrical progression with the ratio independent of n (see [12,13]). Let u ε m be an approximate value of the solution u m of system (21), with an accuracy of ε = 5 × 10 −16 in double, and ε = 5 × 10 −34 in quadruple precisions.…”

“…Finally, we mention the papers [11][12][13], in which by using the one block version of the block method (BM) given in [25,26] the highly accurate results are obtained for the solution of the Motz problem, cracked-beam problem and problems in L shaped domains respectively.…”

“…These coefficients have great importance in many applications, especially in fracture mechanics. The methods for the approximation of the coefficients a j can be divided into two groups: (i) the post-processing approach in the finite element or finite difference methods (see [5][6][7][8][9][10]), in the block method (see [11][12][13]) and in the block-grid method [14][15][16] (ii) directly calculated methods, without finding approximate solution of the boundary value problem (see [4,1,[17][18][19][20] and the references therein).…”

One-block method for computing the generalized stress intensity factors for Laplace’s equation on a square with a slit and on an L-shaped domain

“…Moreover, the classic Jacobi or Gauss-Seidel iterations converge as geometrical progression with the ratio independent of n (see [12,13]). Let u ε m be an approximate value of the solution u m of system (21), with an accuracy of ε = 5 × 10 −16 in double, and ε = 5 × 10 −34 in quadruple precisions.…”

“…Finally, we mention the papers [11][12][13], in which by using the one block version of the block method (BM) given in [25,26] the highly accurate results are obtained for the solution of the Motz problem, cracked-beam problem and problems in L shaped domains respectively.…”

“…These coefficients have great importance in many applications, especially in fracture mechanics. The methods for the approximation of the coefficients a j can be divided into two groups: (i) the post-processing approach in the finite element or finite difference methods (see [5][6][7][8][9][10]), in the block method (see [11][12][13]) and in the block-grid method [14][15][16] (ii) directly calculated methods, without finding approximate solution of the boundary value problem (see [4,1,[17][18][19][20] and the references therein).…”

One-block method for computing the generalized stress intensity factors for Laplace’s equation on a square with a slit and on an L-shaped domain

“…In engineering problems a very important constant is the so-called stress intensity factor . This constant gives a measure of "the amount of torsion the beam can endure before fracture occurs" [10,13]. On the basis in the "singular" part for ℎ −1 = 64, = 140. of (31) we give a simple and highly accurate formula for the stress intensity factor denoting by for = 2, 6:…”

Analysis of the Block-Grid Method for the Solution of Laplace's Equation on Polygons with a Slit

The Singular Function Boundary Integral Method for singular Laplacian problems over circular sections