基于减少局部熵产生的同向旋转平台非稳态现象数值分析

Xingyu Jia, Xi Zhang, Qiushuang Yan, Zicheng Zhao
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摘要

本研究的主要目的是减少反向旋转阶段的局部熵产生。因此,需要明确非稳态流动现象以及径向载荷分布对这些现象和局部熵产生的影响。本研究采用 SBES 湍流模型捕捉流动分离区的涡流,并采用 γ-Reθ 过渡模型预测边界层内的过渡现象。分别构建适合不同湍流模型的熵产率模型,计算局部熵产。根据 Lambda_ci 准则实现涡旋可视化,并利用相对涡度变化率分析尖端间隙涡旋的成分。从欧拉和拉格朗日描述的角度分析了过渡现象。主要结论可归纳如下:后转子的过渡开始得更早,进展得更快。涡流以双倍频率传播,边界层内的熵产生率与相同频率的壁面剪应力同步变化。此外,对尖端间隙漩涡的研究得出结论,尖端间隙漩涡的主要结构与高熵产生率区域的流动模式相吻合,与高发散区域相关的流动结构对于考虑后续优化以降低熵产生率至关重要。
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Numerical Analysis of Unsteady Phenomena in a Contra-Rotating Stage Based On the Reduction of Local Entropy Production
The primary purpose of this study is the reduction of local entropy production in a contra-rotating stage. As such, the unsteady flow phenomena and the impact of radial load distribution on these phenomena and local entropy production need to be clarified. In this study, the SBES turbulence model is utilized to capture the vortices in the flow separation zone, and the γ-Reθ transition model is employed to predict the transition phenomenon within the boundary layer. Entropy production rate models suitable for different turbulence models are constructed separately to calculate local entropy production. Vortex visualization is achieved according to the Lambda_ci criterion, and the relative vorticity change rate is used to analyze the components of the tip clearance vortices. The transition phenomenon is analyzed from the perspectives of both the Euler and the Lagrange descriptions. The primary findings can be summarized as follows: The transition begins earlier and progresses more rapidly in the rear rotor. Wake propagation, occurring at double the frequency, entropy production rate within the boundary layer changes in synchrony with the wall shear stress at the same frequency. Additionally, an investigation of the tip clearance vortices concludes that the main structure of the tip clearance vortices coincides with the flow pattern of the high entropy production rate region, and the flow structure related to the high divergence area is essential for considering subsequent optimization with the aim of reducing the entropy production rate.
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