高超音速
气动加热
冷却液
喷射(流体)
机械
材料科学
蒸腾作用
热的
空气动力学
航空航天工程
主动冷却
高超音速飞行
湍流
环境科学
质量流量
热保护
流量(数学)
核工程
水冷
航天飞机热防护系统
质量流
热力学
计算流体力学
机械工程
传热
前沿
自由流
热效率
作者
Haifeng Hu,Jinglai Zheng,Andi Lin,Haiming Huang,Xiaoyan Liang
摘要
Transpiration cooling has demonstrated exceptional potential in reducing aerodynamic heating for the leading edges of hypersonic vehicles. However, its effectiveness is fundamentally constrained by the inherent conflict between pressure-driven coolant transport and localized thermal load demands: regions experiencing higher surface pressures (typically associated with elevated heat fluxes) exhibit reduced transpiration in leading edges. To resolve this critical mismatch, this study proposes a hybrid thermal protection system integrating stagnation-region opposing jets with shoulder-region stepped transpiration cooling. The Navier–Stokes equations, along with the standard [Formula: see text] turbulence model, are solved by using a stepwise computational method. The results indicate that the synergistic interaction between the opposing jet and pressure-adaptive transpiration achieves cooling efficiency exceeding 0.94 at the stagnation zone, while maintaining cooling efficiency above 0.90 across the shoulder region. Additionally, it is observed that both increasing the coolant mass flow rate and the opposing jet flow ratio contribute to improved cooling performance. This hybrid cooling architecture establishes a paradigm for intelligent thermal management through dynamic pressure-thermal load matching, offering transformative potential for next-generation hypersonic vehicle thermal protection systems.
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