A generalized non-hourglass updated Lagrangian formulation for SPH solid dynamics

arXiv - CS - Computational Engineering, Finance, and Science Pub Date : 2024-09-17 DOI:arxiv-2409.11474

Shuaihao Zhang, Dong Wu, Sérgio D. N. Lourenço, Xiangyu Hu

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Abstract

Hourglass modes, characterized by zigzag particle and stress distributions, are a common numerical instability encountered when simulating solid materials with updated Lagrangian smoother particle hydrodynamics (ULSPH). While recent solutions have effectively addressed this issue in elastic materials using an essentially non-hourglass formulation, extending these solutions to plastic materials with more complex constitutive equations has proven challenging due to the need to express shear forces in the form of a velocity Laplacian. To address this, a generalized non-hourglass formulation is proposed within the ULSPH framework, suitable for both elastic and plastic materials. Specifically, a penalty force is introduced into the momentum equation to resolve the disparity between the linearly predicted and actual velocities of neighboring particle pairs, thereby mitigating the hourglass issue. The stability, convergence, and accuracy of the proposed method are validated through a series of classical elastic and plastic cases, with a dual-criterion time-stepping scheme to improve computational efficiency. The results show that the present method not only matches or even surpasses the performance of the recent essentially non-hourglass formulation in elastic cases but also performs well in plastic scenarios.

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SPH 固体动力学的广义非沙漏更新拉格朗日公式

沙漏模式以之字形粒子和应力分布为特征，是使用更新拉格朗日平滑粒子流体力学（ULSPH）模拟固体材料时经常遇到的数值不稳定性。虽然最近的解决方案使用本质上的非沙漏公式有效地解决了弹性材料中的这一问题，但由于需要以速度拉普拉斯的形式表达剪切力，因此将这些解决方案扩展到具有更复杂构成方程的塑性材料具有挑战性。为了解决这个问题，我们在ULSPH 框架内提出了一种适用于弹性和塑性材料的广义非沙漏公式。具体来说，在动量方程中引入了惩罚力，以解决相邻粒子对的线性预测速度和实际速度之间的差异，从而缓解沙漏问题。通过一系列经典的弹性和塑性案例验证了所提方法的稳定性、收敛性和准确性，并采用双准则时间步法来提高计算效率。结果表明，本方法不仅在弹性情况下达到甚至超过了最近提出的非沙漏公式的性能，而且在塑性情况下也表现出色。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - CS - Computational Engineering, Finance, and Science

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