A High-Order Flux Reconstruction Method for 2-D Vorticity Transport

Volume 1: Aerospace Engineering Division Joint Track; Computational Fluid Dynamics Pub Date : 2021-08-10 DOI:10.1115/fedsm2021-63196

A. Gharakhani

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引用次数: 1

Abstract

A compact high-order finite difference method on unstructured meshes is developed for discretization of the unsteady vorticity transport equations (VTE) for 2-D incompressible flow. The algorithm is based on the Flux Reconstruction Method of Huynh [1, 2], extended to evaluate a Poisson equation for the streamfunction to enforce the kinematic relationship between the velocity and vorticity fields while satisfying the continuity equation. Unlike other finite difference methods for the VTE, where the wall vorticity is approximated by finite differencing the second wall-normal derivative of the streamfunction, the new method applies a Neumann boundary condition for the diffusion of vorticity such that it cancels the slip velocity resulting from the solution of the Poisson equation for the streamfunction. This yields a wall vorticity with order of accuracy consistent with that of the overall solution. In this paper, the high-order VTE solver is formulated and results presented to demonstrate the accuracy and convergence rate of the Poisson solution, as well as the VTE solver using benchmark problems of 2-D flow in lid-driven cavity and backward facing step channel at various Reynolds numbers.

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二维涡量输运的高阶通量重建方法

针对二维不可压缩流动的非定常涡量输运方程，提出了一种紧凑的非结构化网格高阶有限差分法。该算法基于Huynh[1,2]的通量重建方法，将其扩展为求解流函数的泊松方程，在满足连续性方程的同时强化速度场和涡度场之间的运动学关系。与VTE的其他有限差分方法不同，在这些方法中，壁涡度是通过流函数的第二次壁法向导数的有限差分来近似的，新方法对涡度的扩散应用了诺伊曼边界条件，这样它就抵消了由流函数泊松方程的解引起的滑移速度。由此得到的壁面涡度精度与整体解的精度一致。本文建立了高阶VTE求解器，并给出了结果，以证明泊松解的准确性和收敛速度，以及使用不同雷诺数下的盖驱动腔和后向阶跃通道二维流动基准问题的VTE求解器。

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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Volume 1: Aerospace Engineering Division Joint Track; Computational Fluid Dynamics

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