A Plate Infinite Element Method (PIEM) formulation based on Reissner-Mindlin theory is proposed for the stress analysis of cracked plates under bending and tension. The validity of the proposed formulation is demonstrated by comparing the results obtained for the normalized Stress Intensity Factor (SIF) under various loading conditions with the solutions presented in the literature. Importantly, the proposed formulation enables the effects of different crack lengths to be analyzed without the need to re-mesh the computational domain for each simulation/analysis. Overall, the PIEM formulation provides an accurate and computationally-efficient means of analyzing a wide variety of plate bending problems.
Structural analysis problems are traditionally solved using the Finite Element Method (FEM). However, when the structure of interest contains discontinuities such as cracks or re-entrant corners, a large number of elements are required to accurately reproduce the stress characteristics in the region of the discontinuities. As a result, the FEM method requires a large storage space and has a slow convergence speed. It has been shown that the Infinite Element Method (IEM) overcomes these limitations and provides a feasible means of solving various types of elasticity and singularity problems. Previous studies have generally focused on the use of IEM formulations based on low-order elements (2×2). By contrast, this study develops a high-order (3×3) IEM formulation. The solutions obtained using the proposed IEM method for various 2D elasto-static problems are compared with the results obtained using the traditional low-order IEM method and the analytical solutions presented in the literature. It is shown that the results obtained using the proposed method are more accurate than those obtained using the low-order IEM method and are in excellent agreement with the analytical solutions. 1132heterogeneous properties, those with inhomogeneous behaviors pose a far greater challenge. Various researchers have suggested that the limitations of the FEM and BEM methods can be overcome by the Infinite Element Method (IEM) (3) . The basic principle of IEM involves discretizing the problem domain in to a large numbers of elements using a suitable partitioning technique and nodal sequence such that each element layer is similar to the other layers. Ying (4) , Han and Ying (5) , and Ying and Pan (6) developed the mathematical foundations of the IEM formulation for the Laplace equation, exterior Stokes problem, corner problem, and planar elasticity problem in fracture mechanics. Ying (7) proved the existence of a transformation matrix relating the nodal displacement vectors of the inner and outer layers, respectively, and showed that the stiffness matrices associated with each layer could therefore be combined to form an overall stiffness matrix defined in terms of the boundary nodes and tractions only. In addition, it was shown that the combined stiffness matrix converges to a certain constant quantity as the number of element layers approaches infinity. Guo (8) proved that the concept of similar elements could be extended to arbitrary isoparametric elements and also presented a transformation procedure for constructing the overall stiffness matrix of the body of interest by combining the local stiffness matrices of each layer. Liu and Chiou (9)-(12) recently developed both 2D (2×2) and 3D (2×2×2) IEM formulations to solve a variety of elasticity and singularity problems. In addition, the authors proposed a convergence criterion for the IEM formulation which extended the imaginary "infinity layer" concept to practical applications and ensured the convergence of the overall IE stiffness matrix.Previous researchers have generally focu...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.