Aerothermoelastic-Acoustics Simulation of Flight Vehicles.

K. Gupta, S. Choi, S. Lung, A. Ibrahim
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引用次数: 4

Abstract

This paper describes a novel computational-fluid-dynamics-based numerical solution procedure for effective simulation of aerothermoacoustics problems with application to aerospace vehicles. A finite element idealization is employed for both fluid and structure domains, which fully accounts for thermal effects. The accuracies of both the fluid and structure capabilities are verified with flight- and ground-test data. A time integration of the structural equations of motion, with the governing flow equations, is conducted for the computation of the unsteady aerodynamic forces, which uses a transpiration boundary condition at the surface nodal points in lieu of the updating of the fluid mesh. Two example problems are presented herein to that effect. The first one relates to a cantilever wing with a NACA 0012 airfoil. The solution results demonstrate the effect of temperature loading that causes a significant increase in acoustic response. A second example, the hypersonic X-43 vehicle, is also analyzed; and relevant results are presented. The common finite element-based aerothermoelastic-acoustics simulation process, its applicability to the efficient and routine solution of complex practical problems, the employment of the effective transpiration boundary condition in the computational fluid dynamics solution, and the development and public domain distribution of an associated code are unique features of this paper.
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飞行器气动热弹性声学模拟。
本文提出了一种新的基于计算流体力学的数值求解方法,可有效地模拟航空航天飞行器中的气动热声学问题。流体和结构领域均采用有限元理想化,充分考虑了热效应。通过飞行和地面试验数据验证了流体和结构能力的准确性。将结构运动方程与控制流方程进行时间积分,计算非定常气动力,采用表面节点处的蒸腾边界条件代替流体网格的更新。为此,本文提出了两个实例问题。第一个涉及一个悬臂翼与NACA 0012翼型。求解结果表明,温度载荷的影响会导致声响应的显著增加。第二个例子,高超声速X-43飞行器,也进行了分析;并给出了相关结果。常见的基于有限元的气动热弹声学模拟过程,适用于复杂实际问题的高效和常规求解,在计算流体动力学解中采用有效蒸腾边界条件,以及开发和公共领域发布相关程序是本文的独特之处。
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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