Abstract
H-adaptivity is an effective tool to introduce local mesh refinement in the FEM-based numerical simulation of crack propagation. The implementation of h-adaptivity could benefit the numerical simulation of fatigue or accidental load scenarios involving large structures, such as ship hulls. Meanwhile, in engineering applications, the element deletion method is frequently used to represent cracks. However, the element deletion method has some drawbacks, such as strong mesh dependency and loss of mass or energy. In order to mitigate this problem, the element splitting method could be applied. In this study, a numerical method called ‘h-adaptive element splitting’ (h-AES) is introduced. The h-AES method is applied in FEM programs by combining h-adaptivity with the element splitting method. Two examples using the h-AES method to simulate cracks in large structures under linear-elastic fracture mechanics scenario are presented. The numerical results are verified against analytical solutions. Based on the examples, the h-AES method is proven to be able to introduce mesh refinement in large-scale numerical models that mostly consist of structured coarse meshes, which is also beneficial to the reduction of computational resources. By employing the h-AES method, very small cracks are well represented in large structures without any deletions of elements.
Highlights
The finite element method (FEM) is an effective tool for the simulation of static or cyclic crack propagation
An adaptive mesh refinement method called the ‘h-adaptive element splitting’ (h-AES) method was introduced for the numerical simulation of cracks using shell elements in FEM
The numerical results were verified against analytical solutions and showed good correspondence
Summary
The finite element method (FEM) is an effective tool for the simulation of static or cyclic crack propagation. In FEM-based simulations of crack propagation in large structures using shell elements, such as ship hulls, coarse meshes are often employed in consideration of computational cost [1,2]. If a higher accuracy or more local details are needed in the numerical model, it is desirable to introduce local mesh refinement, which requires less computational cost than applying a fine mesh to the entire model [3,4]. In order to introduce local mesh refinement, the h-adaptivity could be applied. The h-adaptivity has been proven to be an effective tool to enhance local accuracy while keeping computational costs low, as can be seen in several research works on the simulation of cracks [5,6,7,8]
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