湍流阻尼在OpenFOAM多相流求解器interFoam中的实现

IF 0.8 Q4 THERMODYNAMICS

Archives of Thermodynamics Pub Date : 2023-07-20 DOI:10.24425/ather.2022.140923

J. Polansky, S. Schmelter

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引用次数: 2

摘要

在所提出的工作中，Egorov的方法（在k-ω模型中的ω-方程中添加一个源项，该方法模拟了固体壁附近湍流的阻尼）在剪切应力传输模型的子类中实现。因此，湍流阻尼适用于所有剪切应力传输类型的模型，包括基于ω-方程的混合模型。研究表明，湍流阻尼不仅改善了雷诺平均Navier-Stokes模拟的轴向速度文件预测，还改善了分离涡模拟和延迟分离涡模拟模型的轴向速度预测。此外，它导致对压降的更现实的估计，并因此导致对液位的更正确的预测。本文给出了四种不同湍流模型的模拟结果，并通过与实验数据的比较进行了验证。此外，还研究了阻尼因子大小对不同气液流量比下通道压降的影响。这些研究表明，更高的气液流量比需要更高的阻尼系数来正确预测压降。最后，就如何确定特定测试用例的适当阻尼系数提出了建议。

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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Implementation of turbulence damping in the OpenFOAM multiphase flow solver interFoam

In the presented work Egorov’s approach (adding a source term to the ω -equation in the k - ω model, which mimics the damping of turbulence close to a solid wall) was implemented in on the subclass of shear stress transport models. Hence, turbulence damping is available for all shear stress transport type models, including hybrid models that are based on the ω -equation. It is shown that turbulence damping improves the prediction of the axial velocity proﬁle not only for Reynolds-averaged Navier–Stokes simulation but also for detached eddy simulation and delayed detached eddy simulation models. Furthermore, it leads to a more realistic estimation of the pressure drop and, hence, to a more correct prediction of the liquid level. In this paper, simulation results for four diﬀerent turbulence models are presented and validated by comparison with experimental data. Furthermore, the inﬂuence of the magnitude of the damping factor on the pressure drop in the channel is investigated for a variety of diﬀerent gas-to-liquid ﬂow rate ratios. These investigations show that higher gas-to-liquid ﬂow rate ratios require higher damping factors to correctly predict the pressure drop. In the end, advice is formulated on how an appropriate damping factor can be determined for a speciﬁc test case.

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来源期刊

Archives of Thermodynamics THERMODYNAMICS-

CiteScore

1.80

自引率

22.20%

发文量

期刊介绍： The aim of the Archives of Thermodynamics is to disseminate knowledge between scientists and engineers interested in thermodynamics and heat transfer and to provide a forum for original research conducted in Central and Eastern Europe, as well as all over the world. The journal encompass all aspect of the field, ranging from classical thermodynamics, through conduction heat transfer to thermodynamic aspects of multiphase flow. Both theoretical and applied contributions are welcome. Only original papers written in English are consider for publication.