针对运动边界问题,采用锐界面直接强迫浸入边界法的结构化自适应网格细化策略

Mehdi Badri Ghomizad, Hosnieh Kor, K. Fukagata
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引用次数: 3

摘要

我们利用移动最小二乘尖锐直接强迫浸入边界法(IBM)开发了一种用于不可压缩流固耦合(FSI)模拟的通用和精确的结构自适应网格细化(S-AMR)策略。计算网格由不同细化级别的若干嵌套块组成。当网格最粗的块覆盖整个计算域时,计算域通过在每个坐标方向上对选定的块进行等分,在实体边界(移动或固定)的位置进行局部细化。网格拓扑和数据结构由Afivo工具包的扩展版本管理(Teunissen和Ebert, 2018),其中引入了一种新技术,用于粗块和细块之间的保守数据传输,特别是在速度变换中,质量守恒起着至关重要的作用。在本研究中,不可压缩流动的连续性方程和Navier-Stokes方程用二阶中心有限差分法采用并置排列进行空间离散,用半隐式二阶分数阶方法进行时间积分,尽管所提出的S-AMR策略可以用于不同的离散化方案。使用移动最小二乘方法的IBM用于施加边界条件。为了处理FSI问题,所有流体和结构的动力学控制方程都通过预测校正策略在时间上同时推进。为了验证所提方法的鲁棒性和准确性,以及仿真驱动的网格自适应能力,本文还解决了几个日益复杂的测试用例。
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A structured adaptive mesh refinement strategy with a sharp interface direct-forcing immersed boundary method for moving boundary problems
We develop a versatile and accurate structured adaptive mesh refinement (S-AMR) strategy with a moving least square sharp-direct forcing immersed boundary method (IBM) for incompressible fluid-structure interaction (FSI) simulations. The computational grid consists of several nested blocks in different refinement levels. While blocks with the coarsest grid cover the entire computational domain, the computational domain is locally refined at the location of solid boundary (moving or fixed) by bisecting selected blocks in every coordinate direction. The grid topology and data structure is managed by an extended version of Afivo toolkit (Teunissen and Ebert, 2018), where a novel technique is introduced for conservative data transfer between the coarser and the finer blocks, particularly in velocity transformation for which the mass conservation plays a crucial role. In the present study, the continuity and Navier-Stokes equations for incompressible flows are spatially discretized with a second order central finite difference method using a collocated arrangement and are time-integrated using a semi-implicit second order fractional step method, although the proposed S-AMR strategy can be used with different discretization schemes. An IBM using a moving least square approach is utilized to impose boundary conditions. To handle FSI problems, all the governing equations for the dynamics of fluid and structure are simultaneously advanced in time by a predictorcorrector strategy. Several test cases of increasing complexity are solved in order to demonstrate the robustness and accuracy of the proposed method as well as its capability in simulation-driven mesh adaptivity.
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来源期刊
CiteScore
1.00
自引率
12.50%
发文量
2
期刊介绍: Journal of Fluid Science and Technology (JFST) is an international journal published by the Fluids Engineering Division in the Japan Society of Mechanical Engineers (JSME). JSME had been publishing Bulletin of the JSME (1958-1986) and JSME International Journal (1987-2006) by the continuous volume numbers. Considering the recent circumstances of the academic journals in the field of mechanical engineering, JSME reorganized the journal editorial system. Namely, JSME discontinued former International Journals and projected new publications from the divisions belonging to JSME. The Fluids Engineering Division acted quickly among all divisions and launched the premiere issue of JFST in January 2006. JFST aims at contributing to the development of fluid engineering by publishing superior papers of the scientific and technological studies in this field. The editorial committee will make all efforts for promoting strictly fair and speedy review for submitted articles. All JFST papers will be available for free at the website of J-STAGE (http://www.i-product.biz/jsme/eng/), which is hosted by Japan Science and Technology Agency (JST). Thus papers can be accessed worldwide by lead scientists and engineers. In addition, authors can express their results variedly by high-quality color drawings and pictures. JFST invites the submission of original papers on wide variety of fields related to fluid mechanics and fluid engineering. The topics to be treated should be corresponding to the following keywords of the Fluids Engineering Division of the JSME. Basic keywords include: turbulent flow; multiphase flow; non-Newtonian fluids; functional fluids; quantum and molecular dynamics; wave; acoustics; vibration; free surface flows; cavitation; fluid machinery; computational fluid dynamics (CFD); experimental fluid dynamics (EFD); Bio-fluid.
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