基于样条的全封闭区域流固耦合问题的时空有限元方法

M. Make, T. Spenke, N. Hosters, M. Behr
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引用次数: 2

摘要

非均匀有理b样条(NURBS)曲面通常在计算机辅助设计(CAD)工具中用于表示几何对象。当使用等几何分析(IGA)时,可以直接使用NURBS几何进行数值分析。然而,分析流体流动需要复杂的三维几何图形来表示流域。使用NURBS定义这种体积域的参数化可能具有挑战性,并且仍然是IGA社区中正在进行的主题。随着最近发展的NURBS增强有限元法(NEFEM),在标准有限元方法中使用了NURBS的有利几何特性。这是通过使用NURBS几何本身来增强接触边界的元素来实现的。在目前的工作中,介绍了NEFEM的一种新的变体,它适用于三维时空有限元公式。提出的方法利用了一种新的映射,得到了适合流固相互作用(FSI)的非笛卡尔公式。这是通过将该方法与解决FSI问题的强耦合分区框架中的IGA公式相结合来证明的。该框架通过单个NURBS生成完全基于样条的流固界面表示。流固界面处的耦合条件通过Robin-Neumann型耦合方案来实现。当考虑完全dirichlet有界和弯曲问题中的不可压缩流体时,该格式特别有用,因为它满足耦合过程中每一步流体的不可压缩约束。引入的基于样条的时空有限元方法的精度和性能及其在提出的耦合FSI框架中的应用*通讯作者:make@cats.rwth-aachen.de (Michel Make), spenke@cats.rwth-aachen.de (Thomas Spenke), hosters@cats.rwth-aachen.de (Norbert Hosters), behr@cats.rwth-aachen.de (Marek Behr)预打印提交给计算机与数学应用。2022年3月31日:2023[c . c . E][16][15][2][2]用一系列二维和三维基准问题证明了工作。
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Spline-Based Space-Time Finite Element Approach for Fluid-Structure Interaction Problems With a Focus on Fully Enclosed Domains
Non-Uniform Rational B-Spline (NURBS) surfaces are commonly used within Computer-Aided Design (CAD) tools to represent geometric objects. When using isogeometric analysis (IGA), it is possible to use such NURBS geometries for numerical analysis directly. Analyzing fluid flows, however, requires complex three-dimensional geometries to represent flow domains. Defining a parametrization of such volumetric domains using NURBS can be challenging and is still an ongoing topic in the IGA community. With the recently developed NURBS-enhanced finite element method (NEFEM), the favorable geometric characteristics of NURBS are used within a standard finite element method. This is achieved by enhancing the elements touching the boundary by using the NURBS geometry itself. In the current work, a new variation of NEFEM is introduced, which is suitable for three-dimensional space-time finite element formulations. The proposed method makes use of a new mapping which results in a non-Cartesian formulation suitable for fluidstructure interaction (FSI). This is demonstrated by combining the method with an IGA formulation in a strongly-coupled partitioned framework for solving FSI problems. The framework yields a fully spline-based representation of the fluid-structure interface through a single NURBS. The coupling conditions at the fluid-structure interface are enforced through a Robin-Neumann type coupling scheme. This scheme is particularly useful when considering incompressible fluids in fully Dirichlet-bounded and curved problems, as it satisfies the incompressibility constraint on the fluid for each step within the coupling procedure. The accuracy and performance of the introduced spline-based space-time finite element approach and its use within the proposed coupled FSI frame∗Corresponing Author Email addresses: make@cats.rwth-aachen.de (Michel Make), spenke@cats.rwth-aachen.de (Thomas Spenke), hosters@cats.rwth-aachen.de (Norbert Hosters), behr@cats.rwth-aachen.de (Marek Behr) Preprint submitted to Computers and Mathematics with Applications. March 31, 2022 ar X iv :2 20 3. 16 15 2v 1 [ cs .C E ] 3 0 M ar 2 02 2 work are demonstrated using a series of twoand three-dimensional benchmark problems.
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