飞机大涡模拟的可承受成本:计算流体动力学的一个里程碑

IF 2.8 Q2 MECHANICS
K. Goc, O. Lehmkuhl, G. Park, S. Bose, P. Moin
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引用次数: 45

摘要

图形摘要摘要尽管大涡模拟(LES)在复杂流动中有许多应用,但迄今为止,它们在实际工程配置中的应用,如全飞机模型,还很有限。然而,最近,在快速、高质量网格生成、低耗散数值方案以及基于物理的亚网格尺度和壁模型方面取得的进展,首次在不到一天的周转时间内,以适度的资源需求,准确模拟了着陆形态下的真实飞机(日本宇宙航空研究开发机构标准模型)。在本文中,对LES在一系列攻角(包括最大升力和失速后状态)下的预测能力、预测对网格分辨率的稳健性以及风洞效应的结合进行了系统研究。感兴趣的综合工程量,如升力、阻力和俯仰力矩,将与实验数据进行比较,而截面压力将用于证实综合工程量的准确性。在升力曲线上获得了与实验$C_L$数据的良好一致性,最大升力时的升力系数$C_{L,max}$始终被预测为在实验值的五个升力计数内。与最近的估计相比,实现这一精度水平的网格点要求降低了(即使是墙壁建模的LES),解决方案显示出网格细化的系统改进,但最低迎角的解决方案除外,这将在下文中讨论。包括风洞壁和机身安装系统在内的模拟能够复制实验中提到的流场的重要特征,这些特征在相同几何形状的自由空气计算中是不存在的,即失速后状态下内侧流分离的开始。一天中的周转时间之所以成为可能,部分原因是为了利用图形处理单元而进行的算法进步。本文给出的结果表明,这种组合方法(网格划分、数值算法、建模、高效的计算机实现)已接近航空设计工业应用的门槛。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Large eddy simulation of aircraft at affordable cost: a milestone in computational fluid dynamics
Graphical Abstract Abstract While there have been numerous applications of large eddy simulations (LES) to complex flows, their application to practical engineering configurations, such as full aircraft models, have been limited to date. Recently, however, advances in rapid, high quality mesh generation, low-dissipation numerical schemes and physics-based subgrid-scale and wall models have led to, for the first time, accurate simulations of a realistic aircraft in landing configuration (the Japanese Aerospace Exploration Agency Standard Model) in less than a day of turnaround time with modest resource requirements. In this paper, a systematic study of the predictive capability of LES across a range of angles of attack (including maximum lift and post-stall regimes), the robustness of the predictions to grid resolution and the incorporation of wind tunnel effects is carried out. Integrated engineering quantities of interest, such as lift, drag and pitching moment will be compared with experimental data, while sectional pressure forces will be used to corroborate the accuracy of the integrated quantities. Good agreement with experimental $C_L$ data is obtained across the lift curve with the coefficient of lift at maximum lift, $C_{L,max}$, consistently being predicted to within five lift counts of the experimental value. The grid point requirements to achieve this level of accuracy are reduced compared with recent estimates (even for wall modelled LES), with the solutions showing systematic improvement upon grid refinement, with the exception of the solution at the lowest angles of attack, which will be discussed later in the text. Simulations that include the wind tunnel walls and aircraft body mounting system are able to replicate important features of the flow field noted in the experiment that are absent from free air calculations of the same geometry, namely, the onset of inboard flow separation in the post-stall regime. Turnaround times of the order of a day are made possible in part by algorithmic advances made to leverage graphical processing units. The results presented herein suggest that this combined approach (meshing, numerical algorithms, modelling, efficient computer implementation) is on the threshold of readiness for industrial use in aeronautical design.
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CiteScore
2.40
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