近似反卷积大涡模拟的动态闭合建模框架:Burgers方程

Cogent Physics Pub Date : 2018-01-01 DOI:10.1080/23311940.2018.1464368

R. Maulik, O. San

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引用次数: 3

摘要

基于近似反卷积(AD)方法，从解析的流量中自适应计算Smagorinsky常数，提出了Burgers方程大涡模拟的动态闭包建模框架。在我们提出的框架中，用AD过程代替了标准动态模型的测试过滤过程。考虑到Burgers方程的保守和偏对称形式，该模型的鲁棒性得到了检验。我们对解决单模正弦波和衰减Burgers湍流问题的数值评估表明，目前的框架有效地抑制了网格到网格的振荡，并为中心数值方案提供了改进的冲击捕获特性，作为潜在的离散化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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A dynamic closure modeling framework for large eddy simulation using approximate deconvolution: Burgers equation

Abstract We put forth a dynamic closure modeling framework for the large eddy simulations of the Burgers equation based upon the use of the approximate deconvolution (AD) procedure to compute the Smagorinsky constant self-adaptively from the resolved flow quantities. In our proposed framework, the test filtering process of the standard dynamic model is replaced by the AD procedure. The robustness of the model has been tested considering the Burgers equation in its conservative and skew-symmetric forms. Our numerical assessments for solving the single-mode sine wave and the decaying Burgers turbulence problems show that the present framework effectively damps grid-to-grid oscillations and yields an improved shock capturing property for central numerical schemes as underlying discretizations.

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Cogent Physics PHYSICS, MULTIDISCIPLINARY-

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