Optimization of Reynolds stress model coefficients at multiple discrete flow regions for three-dimensional realizations of fractal-generated turbulence

IF 2.5 3区 工程技术 Q2 MECHANICS European Journal of Mechanics B-fluids Pub Date : 2024-03-12 DOI:10.1016/j.euromechflu.2024.03.002
Michael Chee Hoe Mok, Chin Vern Yeoh, Ming Kwang Tan, Ji Jinn Foo
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Abstract

The quantification of global turbulence statistical moments generated by grid turbulators is crucial for the enhancement of conjugate heat transfer in industrial thermo-fluid systems. As such, there is a need for precise, low-cost alternatives to numerically model three-dimensional flow dynamics of fractal-generated turbulence (FGT) behind multilength-scale square fractal grids (SFGs), in contrast to previously-reported direct numerical simulations. In this study, a numerical framework consisting of multiple applications of the Reynolds stress model (RSM), each employing its own distinct set of optimized coefficient values, is developed by segregating an FGT flow domain into its production and decay regions with Nelder-Mead optimization on key coefficients then performed independently for each region. The flow fields predicted by such RSM framework achieved overall disparities below 3% and 13% w.r.t. reported experimental measurements of mean velocity and turbulence intensity, respectively, considering the evolution in the flow domain along the streamwise, vertical, and spanwise directions. This is therefore the first documentation of any RANS-turbulence model being validated for mean velocity and turbulence intensity predictions of FGT in all three-dimensions. Thereafter, this proposed RSM framework is generalized to predict industry-relevant turbulence statistical moments of four additional FGT flows. The predicted centerline-statistics are verified against reported experiments, and the findings potentially enable realizations of FGT induced by arbitrary SFGs without relying on a posteriori validation while eliminating further reliance on the Nelder-Mead optimization algorithm on a case-by-case basis. The findings indicate a potential to apply the model coefficients as continuous functions of space to simulate the entire FGT domain. Overall, the accurate and numerically sustainable realizations of FGT in 3D provide valuable insights to engineer potent fluid-solid heat transfer via passive turbulence management within HVAC systems.

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针对分形生成湍流的三维现实,优化多个离散流动区域的雷诺应力模型系数
网格湍流器产生的全局湍流统计矩的量化对于增强工业热流体系统中的共轭传热至关重要。因此,与之前报道的直接数值模拟相比,需要精确、低成本的替代方法来对多长尺度方形分形网格(SFGs)后分形产生的湍流(FGT)的三维流动动力学进行数值建模。在本研究中,通过将 FGT 流域划分为产生区和衰减区,并对每个区域的关键系数进行独立的奈尔德-梅德优化,建立了一个由多个雷诺应力模型(RSM)应用组成的数值框架,每个应用都采用了各自不同的优化系数值。考虑到流域沿流向、垂直和跨向的演变,这种 RSM 框架预测的流场与报告的平均速度和湍流强度实验测量值的总体差异分别低于 3% 和 13%。因此,这是首次对任何 RANS 湍流模型进行三维验证,以预测 FGT 的平均速度和湍流强度。随后,我们对所提出的 RSM 框架进行了推广,以预测另外四种 FGT 气流的行业相关湍流统计矩。预测的中心线统计量与报告的实验结果进行了验证,这些发现有可能实现由任意 SFG 诱导的 FGT,而无需依赖后验证,同时消除了对 Nelder-Mead 优化算法的进一步依赖。研究结果表明,可以将模型系数作为空间的连续函数来模拟整个 FGT 领域。总之,三维 FGT 的精确性和数值可持续实现为通过暖通空调系统内的被动湍流管理进行有效的流固传热工程提供了宝贵的见解。
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来源期刊
CiteScore
5.90
自引率
3.80%
发文量
127
审稿时长
58 days
期刊介绍: The European Journal of Mechanics - B/Fluids publishes papers in all fields of fluid mechanics. Although investigations in well-established areas are within the scope of the journal, recent developments and innovative ideas are particularly welcome. Theoretical, computational and experimental papers are equally welcome. Mathematical methods, be they deterministic or stochastic, analytical or numerical, will be accepted provided they serve to clarify some identifiable problems in fluid mechanics, and provided the significance of results is explained. Similarly, experimental papers must add physical insight in to the understanding of fluid mechanics.
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