Particle Virtual Element Method (PVEM): an agglomeration technique for mesh optimization in explicit Lagrangian free-surface fluid modelling

IF 6.9 1区 工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY Computer Methods in Applied Mechanics and Engineering Pub Date : 2024-10-24 DOI:10.1016/j.cma.2024.117461
Cheng Fu , Massimiliano Cremonesi , Umberto Perego , Blaž Hudobivnik , Peter Wriggers
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Abstract

Explicit solvers are commonly used for simulating fast dynamic and highly nonlinear engineering problems. However, these solvers are only conditionally stable, requiring very small time-step increments determined by the characteristic length of the smallest, and often most distorted, element in the mesh. In the Lagrangian description of fluid motion, the computational mesh quickly deteriorates. To circumvent this problem, the Particle Finite Element Method (PFEM) creates a new mesh (e.g., through a Delaunay tessellation, based on node positions) when the current one becomes overly distorted. A fast and efficient remeshing technique is therefore of pivotal importance for an effective PFEM implementation in explicit dynamics. Unfortunately, the 3D Delaunay tessellation does not guarantee well-shaped elements, often generating zero- or near-zero-volume elements (slivers), which drastically reduce the stable time-step size. Available mesh optimization techniques have limited applicability due to their high computational cost when runtime remeshing is required. An innovative possibility to overcome this problem is the use of the Virtual Element Method (VEM), a variant of the finite element method that can make use of polyhedral elements of arbitrary shapes and number of nodes. This paper presents the formulation of a 3D first-order Particle Virtual Element Method (PVEM) for weakly compressible flows. Starting from a tetrahedral mesh, poorly shaped elements, such as slivers, are agglomerated to form polyhedral Virtual Elements (VEs) with a controlled characteristic length. This approach ensures full control over the minimum time-step size in explicit dynamics simulations, maintaining stability throughout the entire analysis.
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粒子虚拟元素法(PVEM):用于显式拉格朗日自由表面流体建模中网格优化的集聚技术
显式求解器通常用于模拟快速动态和高度非线性工程问题。然而,这些求解器仅具有条件稳定性,需要非常小的时间步长增量,该增量由网格中最小元素(通常是扭曲最严重的元素)的特征长度决定。在流体运动的拉格朗日描述中,计算网格会迅速恶化。为了避免这一问题,粒子有限元法(PFEM)会在当前网格过度扭曲时创建一个新网格(例如,通过基于节点位置的 Delaunay 细分)。因此,快速高效的重网格技术对于在显式动力学中有效实施 PFEM 至关重要。遗憾的是,三维 Delaunay 细分并不能保证元素形状良好,经常会产生零或接近零体积元素(切片),从而大大减少了稳定的时间步长。由于需要在运行时重新网格化,现有网格优化技术的计算成本较高,因此适用性有限。克服这一问题的一种创新方法是使用虚拟元素法(VEM),它是有限元法的一种变体,可以使用任意形状和节点数的多面体元素。本文介绍了针对弱可压缩流的三维一阶粒子虚拟元素法(PVEM)。从四面体网格开始,将形状不佳的元素(如切片)聚集在一起,形成具有受控特征长度的多面体虚拟元素(VE)。这种方法可确保在显式动力学模拟中完全控制最小时间步长,并在整个分析过程中保持稳定。
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来源期刊
CiteScore
12.70
自引率
15.30%
发文量
719
审稿时长
44 days
期刊介绍: Computer Methods in Applied Mechanics and Engineering stands as a cornerstone in the realm of computational science and engineering. With a history spanning over five decades, the journal has been a key platform for disseminating papers on advanced mathematical modeling and numerical solutions. Interdisciplinary in nature, these contributions encompass mechanics, mathematics, computer science, and various scientific disciplines. The journal welcomes a broad range of computational methods addressing the simulation, analysis, and design of complex physical problems, making it a vital resource for researchers in the field.
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