Parallelized plastic coupling of non-ordinary state-based peridynamics and finite element method

IF 4 2区工程技术 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Advances in Engineering Software Pub Date : 2024-07-10 DOI:10.1016/j.advengsoft.2024.103718

Suyeong Jin , Sunwoo Kim , Jung-Wuk Hong

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Abstract

Parallel computing is essential for enhancing computational efficiency and advancing computational mechanics. To reduce the computational cost, peridynamics, a nonlocal numerical method, has been coupled with the finite element method (FEM). However, the accurate modeling of plastic deformation within the coupling framework of the FEM and non-ordinary state-based peridynamics (NOSB-PD) requires further investigation and might add to the computational expense. In this study, the open multi-processing application interface (OpenMP) is implemented for the plastic coupling of the FEM and stabilized NOSB-PD. The framework for the plastic coupling model using OpenMP is described in detail. The implemented code is used to investigate the coupling boundary effect on plastic deformation depending on the size of the coupling zone. After verifying the plastic coupling, the parallelization performance of the coupling model is examined. The efficient coupling model is applied to simulate plastic deformation on a plate with a circular hole, and the displacement results show good agreement with the reference solution. The proposed coupling model can be applied to efficiently solve the plastic deformation and fracture in future studies.

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基于非平凡状态的周动力学与有限元法的并行塑性耦合

并行计算对于提高计算效率和推动计算力学的发展至关重要。为了降低计算成本，周动力学这种非局部数值方法已经与有限元方法（FEM）相结合。然而，在有限元法和基于非平凡状态的周动力学（NOSB-PD）耦合框架内对塑性变形进行精确建模还需要进一步研究，而且可能会增加计算费用。在本研究中，针对有限元和稳定 NOSB-PD 的塑性耦合实现了开放式多处理应用接口（OpenMP）。本文详细介绍了使用 OpenMP 的塑性耦合模型框架。实施的代码用于研究耦合边界对塑性变形的影响，这种影响取决于耦合区的大小。在验证了塑性耦合之后，研究了耦合模型的并行化性能。将高效耦合模型用于模拟带圆孔的板的塑性变形，位移结果与参考解显示出良好的一致性。所提出的耦合模型可用于未来研究中塑性变形和断裂的高效求解。

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来源期刊

Advances in Engineering Software 工程技术-计算机：跨学科应用

CiteScore

7.70

自引率

4.20%

发文量

169

审稿时长

37 days

期刊介绍： The objective of this journal is to communicate recent and projected advances in computer-based engineering techniques. The fields covered include mechanical, aerospace, civil and environmental engineering, with an emphasis on research and development leading to practical problem-solving. The scope of the journal includes: • Innovative computational strategies and numerical algorithms for large-scale engineering problems • Analysis and simulation techniques and systems • Model and mesh generation • Control of the accuracy, stability and efficiency of computational process • Exploitation of new computing environments (eg distributed hetergeneous and collaborative computing) • Advanced visualization techniques, virtual environments and prototyping • Applications of AI, knowledge-based systems, computational intelligence, including fuzzy logic, neural networks and evolutionary computations • Application of object-oriented technology to engineering problems • Intelligent human computer interfaces • Design automation, multidisciplinary design and optimization • CAD, CAE and integrated process and product development systems • Quality and reliability.