Pressure-Velocity Coupling in Transpiration Cooling

arXiv - PHYS - Fluid Dynamics Pub Date : 2024-08-09 DOI:arxiv-2408.05166

Sophie Hillcoat, Jean-Pierre Hickey

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Abstract

Transpiration cooling is an active thermal protection system of increasing interest in aerospace applications wherein a coolant is effused through a porous wall into a hot external flow. The present work focuses on the interaction between the high-temperature turbulent boundary layer and the pressure-driven coolant flow through the porous wall. Coupling functions were obtained from pore-network simulations to characterize the flow through the porous medium. These were then coupled to direct numerical simulations of a turbulent boundary layer over a massively-cooled flat plate. Two different types of coupling function were used: linear expressions, which do not account for flow interactions between neighbouring pores, and shallow convolutional neural networks (CNN) which incorporate spatial correlations. All coupled cases demonstrated a significant variation in blowing due to the streamwise variation in mean pressure associated with the onset of coolant injection. This trend was reflected in the cooling effectiveness, and was mitigated in the CNN-coupled cases due to the incorporation of lateral flow between neighbouring pores. The distribution of turbulent kinetic energy (TKE) in the coupled cases was also modified by the coupling due to the competing effects of near-wall turbulence attenuation and increased shear due to increasing blowing ratio. Finally, the coupling was shown to impact the power spectral density of the pressure fluctuations at the wall within the transpiration region, attenuating the largest scales of the turbulence whilst leaving the smaller scales relatively unaffected.

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蒸腾冷却中的压力-速度耦合

蒸腾冷却是一种主动式热保护系统，在航空航天领域的应用日益受到关注，冷却剂通过多孔壁喷射到高温的外部气流中。本研究的重点是高温湍流边界层与压力驱动的冷却剂流经多孔壁之间的相互作用。通过孔隙网络模拟获得耦合函数，以描述流经多孔介质的流动特征。然后将这些耦合函数与大规模冷却平板上湍流边界层的直接数值模拟相耦合。使用了两种不同类型的耦合函数：线性表达式（不考虑相邻孔隙之间的流动相互作用）和浅层卷积神经网络（CNN）（包含空间相关性）。所有耦合案例都表明，由于与冷却剂喷射开始相关的平均压力流向变化，吹气发生了显著变化。这一趋势反映在冷却效果上，而在 CNN 耦合案例中，由于加入了相邻孔隙之间的横向流动，这一趋势得到了缓解。在耦合情况下，由于近壁湍流衰减和增加吹气比导致的剪切力增加的竞争效应，湍流动能（TKE）的分布也因耦合而改变。最后，研究表明耦合影响了蒸腾区内壁面压力波动的功率谱密度，衰减了最大尺度的湍流，而较小尺度的湍流则相对不受影响。

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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arXiv - PHYS - Fluid Dynamics

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