Direct Numerical Simulation of the Airfoil Segment's Flutter and its Effect on the Aerodynamic Force

Universal Journal of Applied Mathematics Pub Date : 2017-04-01 DOI:10.13189/ujam.2017.050202

A. Zelenyy, A. Bunyakin

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Abstract

This article presents numerical simulation of planar potential flow around an airfoil with possibility of changing its shape. Two-dimensional unsteady flow model with scalar velocity potential, which allows us to calculate pressure distribution along an airfoil from Cauchy-Lagrange integral, is used. For this purpose, an airfoil contour is approximated by a complex cubic spline with possibility of displacement its vertices. This algorithm has been used in the context of fluid-structure interaction and has been applied successfully to determination of stability of an elastic airfoil segment interacting with a flow stream, so-called panel flutter problem. Calculation of external flow is carried out by vortex panel method with Kutta-Joukowski trailing edge condition, which makes mathematical solution unique. Using this method of approximation of an airfoil in combination with the method of discrete vortices provides a semi-analytical solution for complex potential for whole computational domain of air flow. This solution significantly accelerates process of numerical computation of time-averaged aerodynamic force as well as the dynamic stability problem for aeroelastic wing design and temporal evolution of its natural disturbances.

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翼型段颤振及其对气动力影响的直接数值模拟

本文对具有改变翼型形状可能性的翼型进行了平面势流的数值模拟。采用二维标量速度势非定常流模型，利用柯西-拉格朗日积分计算翼型压力分布。为此目的，翼型轮廓是近似的一个复杂的三次样条与位移其顶点的可能性。该算法已应用于流固耦合的背景下，并已成功地应用于确定弹性翼型段与气流相互作用的稳定性，即所谓的板颤振问题。采用Kutta-Joukowski后缘条件下的涡面板法计算外流，具有数学解的唯一性。将这种翼型近似方法与离散涡的方法相结合，为整个气流计算域的复势提供了一种半解析解。该方法大大加快了气动弹性翼时均气动力的数值计算过程和气动弹性翼设计的动力稳定性问题及其自然扰动的时间演化过程。

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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Universal Journal of Applied Mathematics

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