Assessment of Predictive Capability of Hybrid RANS/LES Turbulence Models for Thermofluid Applications

Volume 1: Aerospace Engineering Division Joint Track; Computational Fluid Dynamics Pub Date : 2021-08-10 DOI:10.1115/fedsm2021-65808

A. Zope, A. Schemmel, Xiao Wang, S. Bhushan, Prashant Singh, E. Luke

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引用次数: 1

Abstract

In this study, we have assessed performance of URANS model, various hybrid RANS/LES turbulence models such as detached eddy simulation, Nichols-Nelson HRLES model, dynamic HRLES (DHRL) model, as well as LES for two classes of problems: (a) heat transfer due to subsonic swirling flow subjected to a sudden expansion leading to cylindrical chamber, and (b) flow separation due to oblique shock wave-turbulent boundary layer interaction (STBLI). The results are assessed using the heat transfer characteristics, separation and reattachment characteristics, and capability to predict flow unsteadiness. The study indicates that URANS can predict large scale flow features reasonably well. However, it fails to resolve turbulence. PANS improves TKE prediction, hence, improves heat transfer prediction. Among the hybrid RANS/LES models, DHRL coupled with ILES is capable of providing accurate prediction of flow separation/reattachment characteristics for boundary layer flows. For free-shear dominated flows, implicit LES performs better compared to the explicit LES models.

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混合RANS/LES湍流模型在热流体应用中的预测能力评估

在这项研究中，我们评估了URANS模型、各种混合RANS/LES湍流模型(如分离涡模拟、Nichols-Nelson HRLES模型、动态HRLES (DHRL)模型以及LES在两类问题上的性能:(a)由于亚音速旋涡流动受到突然膨胀导致圆柱形室的传热，以及(b)由于斜激波-湍流边界层相互作用(STBLI)导致的流动分离。使用传热特性、分离和再附着特性以及预测流动不稳定性的能力来评估结果。研究表明，URANS可以较好地预测大尺度流场特征。然而，它无法解决湍流问题。PANS改进了TKE预测，从而改进了传热预测。在RANS/LES混合模型中，DHRL与ILES相结合能够准确预测边界层流动的分离/再附着特性。对于自由剪切占主导地位的流动，隐式LES模型比显式LES模型表现更好。

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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Volume 1: Aerospace Engineering Division Joint Track; Computational Fluid Dynamics

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