Consistent streamline residual-based artificial viscosity stabilization for numerical simulation of incompressible turbulent flow by isogeometric analysis

Pub Date : 2022-06-06 DOI:10.21136/AM.2022.0131-21
Bohumír Bastl, Marek Brandner, Kristýna Slabá, Eva Turnerová
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Abstract

In this paper, we propose a new stabilization technique for numerical simulation of incompressible turbulent flow by solving Reynolds-averaged Navier-Stokes equations closed by the SST k-ω turbulence model. The stabilization scheme is constructed such that it is consistent in the sense used in the finite element method, artificial diffusion is added only in the direction of convection and it is based on a purely nonlinear approach. We present numerical results obtained by our in-house incompressible fluid flow solver based on isogeometric analysis (IgA) for the benchmark problem of a wall bounded turbulent fluid flow simulation over a backward-facing step. Pressure coefficient and reattachment length are compared to experimental data acquired by Driver and Seegmiller, to the computational results obtained by open source software OpenFOAM and to the NASA numerical results.

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基于等几何分析的连续流线残余人工粘滞稳定不可压缩湍流数值模拟
本文通过求解由SST k-ω湍流模型封闭的reynolds -average Navier-Stokes方程,提出了一种新的不可压缩湍流数值模拟稳定化技术。该稳定方案的构造与有限元方法的意义一致,仅在对流方向上加入人工扩散,并且基于纯非线性方法。本文给出了基于等几何分析(IgA)的不可压缩流体流动求解器对后台阶壁面有界湍流流动模拟基准问题的数值结果。将压力系数和再附着长度与Driver和Seegmiller获得的实验数据、开源软件OpenFOAM获得的计算结果以及NASA的数值结果进行了比较。
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