Stress intensity factors for a crack in two intersecting uniformly stressed sheets

Stress intensity factors are presented for cracks at the edges of the central holes in a panel containing a uniformly spaced array of circular holes. The finite element method is employed to obtain numerical values of the J-integral and the near-tip displacements from which the stress intensity fact

Abstrac-Two and three parallel cracks in a finite sheet subjected to remote tensile loading have been studied. This paper presents empirical stress intensity factor formulae for these crack configurations. The stress intensity factors used to develop these formulae were obtained from finite element

In this paper an analytical solution is developed for two three-dimensional coplanar rectanguiar-shaped cracks embedded in an infinite elastic medium and subiected to normal loading. Employing two-dimensional integral transforms, the solution of the problem is reduced to triple integral equations. A

Ab&aet-This paper presents a method of numerical analysis for the problem of two collinear cracks in a finite, linearly elastic, isotropic plate and subjected to in plane forces. The problem is treated imagining the plate with the two cracks draws in an unbounded region. Using the analytical soluti

Green's functions for stresses, stress intensities, and displacements were derived for an infinite cracked isotropic sheet under point symmetric loading. First, complex stress functions were derive6 for four point symmetric concentrated loads acting on a cracked sheet. Then, the functions and their

Stress intensity factors for a long cylindrical crack in a long cylinder have been calculated using the energy release rate approach. The investigated loading cases include centrifugal forces (Mode I), radial surface forces (Mode I), forces parallel to the axis (Mode II), and twisting moments (Mode