A reduced smoothed integration scheme of the cell-based smoothed finite element method for solving fluid–structure interaction on severely distorted meshes

IF 1.7 4区工程技术 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS International Journal for Numerical Methods in Fluids Pub Date : 2024-04-02 DOI:10.1002/fld.5289

Tao He, Fang-Xing Lu, Xi Ma

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Abstract

This article describes an inexpensive partitioned coupling strategy for computational fluid–structure interaction (FSI) admitting negative-Jacobian elements. The emphasis is very much on a reduced smoothed integration (RSI) scheme of the cell-based smoothed finite element method (CSFEM) using four-node quadrilateral (Q4) elements for a cost-effective solution to the Navier–Stokes (NS) equations. In the discrete fluid field, each Q4 element is considered as one single smoothing cell so as to diminish the smoothed integration loops substantially. However, the RSI scheme does not respect the stability condition of smoothed Galerkin weak-form integral in the CSFEM. To tackle this issue, a simple hourglass control is introduced to the under-integrated formulation of the NS solver. Importantly, the stabilized RSI scheme has an inbuilt advantage of its enormous tolerance towards negative-Jacobian elements. The developed technique is easy-to-implement and has been tested in various FSI examples adopting both fine and distorted meshes.

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基于单元的简化平滑有限元法的简化平滑积分方案，用于解决严重扭曲网格上的流固耦合问题

本文介绍了一种用于计算流固耦合（FSI）的廉价分区耦合策略，该策略采用负雅各布元素。重点是基于单元的平滑有限元法（CSFEM）的简化平滑积分（RSI）方案，该方案使用四节点四边形（Q4）单元，可经济高效地求解纳维-斯托克斯（NS）方程。在离散流体场中，每个 Q4 元素都被视为一个平滑单元，从而大大减少了平滑积分回路。然而，RSI 方案并不尊重 CSFEM 中平滑 Galerkin 弱形式积分的稳定性条件。为了解决这个问题，在 NS 求解器的欠积分公式中引入了一个简单的沙漏控制。重要的是，稳定的 RSI 方案具有对负雅各布元素具有极大容错性的内在优势。所开发的技术易于实施，并已在采用精细和扭曲网格的各种 FSI 示例中进行了测试。

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来源期刊

International Journal for Numerical Methods in Fluids 物理-计算机：跨学科应用

CiteScore

3.70

自引率

5.60%

发文量

111

审稿时长

8 months

期刊介绍： The International Journal for Numerical Methods in Fluids publishes refereed papers describing significant developments in computational methods that are applicable to scientific and engineering problems in fluid mechanics, fluid dynamics, micro and bio fluidics, and fluid-structure interaction. Numerical methods for solving ancillary equations, such as transport and advection and diffusion, are also relevant. The Editors encourage contributions in the areas of multi-physics, multi-disciplinary and multi-scale problems involving fluid subsystems, verification and validation, uncertainty quantification, and model reduction. Numerical examples that illustrate the described methods or their accuracy are in general expected. Discussions of papers already in print are also considered. However, papers dealing strictly with applications of existing methods or dealing with areas of research that are not deemed to be cutting edge by the Editors will not be considered for review. The journal publishes full-length papers, which should normally be less than 25 journal pages in length. Two-part papers are discouraged unless considered necessary by the Editors.