使用涡流粘度闭合模型对表面安装立方体流动的高分辨率RANS模拟

IF 0.5 Q4 ENGINEERING, MECHANICAL Journal of Verification, Validation and Uncertainty Quantification Pub Date : 2019-03-01 DOI:10.1115/1.4044695
M. Goldbach, M. Uddin
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引用次数: 0

摘要

虽然雷诺平均模拟在许多典型剪切流和中等分离流的评估中取得了成功,但将其应用于高度分离流却显示出明显的不足。本研究旨在探讨在分离流动条件下常用的四种湍流模型的涡流-黏度公式中存在的这些缺陷,以帮助改进这类模型的公式。基于立方体高度h和自由流速度U0,对40,000雷诺数下壁挂式立方体(WMC)周围的流场进行了分析。虽然在工业应用中很常见,但这种类型的流动构成了一个复杂的结构,表现出大的分离尾迹区域,高各向异性和多个涡结构。此外,由立方体不同面形成的漩涡之间的相互作用显著地改变了整体流动特性,这对常用的工业湍流模型提出了重大挑战。平均流动特性的比较表明,实验值与能够预测过渡流的湍流模型具有显著的一致性。对湍流参数的评估表明,过渡模型普遍低估了雷诺应力,而完全湍流模型则高估了雷诺应力,导致两类模型(过渡模型和完全湍流模型)之间的平均流动结构完全不同。
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High-Resolution RANS Simulations of Flow Past a Surface-Mounted Cube Using Eddy-Viscosity Closure Models
While Reynolds-averaged simulations have found success in the evaluation of many canonical shear flows and moderately separated flows, their application to highly separated flows have shown notable deficiencies. This study aimed to investigate these deficiencies in the eddy-viscosity formulation of four commonly used turbulence models under separated flow in an attempt to aid in the improved formulation of such models. Analyses are performed on the flow field around a wall-mounted cube (WMC) at a Reynolds number of 40,000 based on the cube height, h, and freestream velocity, U0. While a common occurrence in industrial applications, this type of flow constitutes a complex structure exhibiting a large separated wake region, high anisotropy, and multiple vortex structures. As well, interactions between vortices developed off of different faces of the cube significantly alter the overall flow characteristics, posing a significant challenge for the commonly used industrial turbulence models. Comparison of mean flow characteristics show remarkable agreement between experimental values and turbulence models which are capable of predicting transitional flow. Evaluation of turbulence parameters show the general underestimation of Reynolds stress for transitional models, while fully turbulent models show this value to be overestimated, resulting in completely disparate representations of mean flow structures between the two classes of models (transitional and fully turbulent).
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CiteScore
1.60
自引率
16.70%
发文量
12
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