Numerical investigation of a plunging flat-plate airfoil using a diffuse interface immersed boundary method

International Journal for Computational Methods in Engineering Science and Mechanics Pub Date : 2022-03-09 DOI:10.1080/15502287.2022.2049399

Fazlolah Mohaghegh, M. Janechek, James H. J. Buchholz, H. Udaykumar

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Abstract

Abstract This study investigates the capabilities of a diffuse interface immersed boundary method in the simulation of fluid flow over an oscillating flat-plate airfoil at moderately high Reynolds numbers where interacting unsteady vortical flows control the flow behavior. The recently developed and modified Smoothed Profile Method (SPM) is adopted as a diffuse interface immersed boundary solver to model the fluid-structure interaction (FSI) problem. While in general diffuse interface methods are simpler to implement relative to sharp-interface methods (SIMs), they have been thought to lose accuracy in the simulation of moderate Reynolds number flows. The simulation results show that the lift coefficient and vorticity contours from SPM match well with experiments. Moreover, our detailed analysis of the vorticity fluxes at the airfoil leading edge and the comparison with experiments also show that SPM can be used for moderate Reynolds number external aerodynamics problems applicable to micro-air vehicles.

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俯冲平板翼型的扩散界面浸入边界法数值研究

摘要本文研究了扩散界面浸没边界法在中高雷诺数下振荡平板翼型上流体流动的模拟能力，其中相互作用的非定常旋涡控制了流动行为。采用新近发展和改进的光滑剖面法(SPM)作为扩散界面浸入边界求解器来模拟流固耦合问题。虽然一般来说，扩散界面方法相对于锐界面方法(SIMs)更容易实现，但它们被认为在模拟中等雷诺数流动时失去了准确性。仿真结果表明，SPM计算得到的升力系数和涡度曲线与实验结果吻合较好。此外，本文还对翼型前缘涡量通量进行了详细的分析，并与实验结果进行了比较，结果表明SPM可用于求解微飞行器的中等雷诺数外空气动力学问题。

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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International Journal for Computational Methods in Engineering Science and Mechanics

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