A Wall-Modeled/Wall-Resolved LES Method For Turbulent Wall Flows

14th WCCM-ECCOMAS Congress Pub Date : 2021-03-11 DOI:10.23967/WCCM-ECCOMAS.2020.045

F. D. Vanna, Michele Cogo, M. Bernardini, F. Picano, E. Benini

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引用次数: 5

Abstract

. This present paper reports a novel methodology to simulate wall-bounded ﬂows in the Large-Eddy Simulation framework using an automatic transition between a wall-modelled and a wall-resolved approach. The proposed technique aims at prescribing the right (modelled or resolved) wall shear stress and wall heat ﬂux, preserving at the same time the no-slip/no-penetration conditions for the velocity and the isothermal/adiabatic conditions for the temperature ﬁelds. The approach is successfully implemented in a high-order ﬁnite-difference framework, and it is found able to adapt smoothly to the available near-wall grid spacing. Thus, the method falls into the wall-resolved case, when the near-wall dynamic is directly computed, whereas it employs the wall stress model when a full resolution of the near-wall region is not achievable. The method is tested on a nearly-incompressible turbulent channel ﬂow and a supersonic spatially-devolving boundary layer ﬂow. The obtained results highlight an excellent accuracy in representing the wall turbulence dynamics in terms of mean velocity proﬁles and ﬂuctuations, almost independently of the near-wall spatial resolution. Thus, the proposed method results in a promising technique for analysis of high-Reynolds wall-bounded ﬂows.

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湍流壁面流动的壁面建模/壁面解析LES方法

．本文报告了一种新的方法来模拟大涡模拟框架中的壁面有界流动，使用壁面建模和壁面解析方法之间的自动转换。所提出的技术旨在规定正确的(模拟或解析的)壁面剪切应力和壁面热流，同时保持速度的无滑移/无穿透条件和温度场的等温/绝热条件。该方法成功地在高阶有限差分框架中实现，并且能够平滑地适应可用的近壁网格间距。因此，当直接计算近壁动力时，该方法属于壁面解析情况，而当无法实现近壁区域的完全解析时，该方法采用壁面应力模型。对几乎不可压缩的湍流通道流动和超音速空间退化边界层流动进行了试验。所获得的结果强调了用平均速度分布和波动来表示壁面湍流动力学的极好精度，几乎独立于近壁面空间分辨率。因此，所提出的方法是一种很有前途的分析高雷诺数壁面流动的技术。

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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14th WCCM-ECCOMAS Congress

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