非均匀热流条件下相变发汗冷却实验研究

doi:10.7527/S1000-6893.2026.33058

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非均匀热流条件下相变发汗冷却实验研究

吕鑫琪¹,邱云龙²,曾繁宇¹,佟川¹,江中正¹,陈伟芳¹

1. 浙江大学
2. 浣江实验室

收稿日期:2025-11-07 修回日期:2026-01-20 出版日期:2026-01-21 发布日期:2026-01-21
通讯作者: 邱云龙
基金资助:
国家自然科学基金;国家自然科学基金;国家自然科学基金;浣江实验室专项资助项目

Experimental Investigation on Phase Change Transpiration Cooling under Non-Uniform Heat Flux Conditions

Received:2025-11-07 Revised:2026-01-20 Online:2026-01-21 Published:2026-01-21
Contact: Yunlong QIU
Supported by:
National Natural Science Foundation of China;National Natural Science Foundation of China;National Natural Science Foundation of China;Specialized Research Projects of Huanjiang Laboratory

摘要/Abstract

摘要： 本文通过辐照加热实验系统性地研究了非均匀热流密度情形下3D打印金属多孔介质结构的相变发汗冷却过程及其传热恶化产生机制。实验过程中低热流区域热流维持在71kW·m-2，高热流区域热流范围为84kW·m-2~108kW·m-2。实验研究结果表明，在非均匀热流作用下，高热流区域受蒸汽堵塞影响，当地流动阻力较大，冷却剂供应困难，逐渐形成表面干涸区，并且结构温度和干涸区域会随时间不断增长；低热流区域的充分浸润区由于流动阻力较小，冷却剂会优先流入，形成优势通道，使充分浸润区的温度进一步降低。实验中观测到，产生传热恶化时的温升曲线存在明显的温度拐点，壁面温度会在超过温度拐点后急剧攀升。由于优势通道的存在，当壁面温度超过温度拐点时，即使增加冷却剂供应流量，也难以遏制表面干涸区进一步扩展和持续升温。

关键词: 相变发汗冷却, 非均匀热流, 主动热防护, 多孔介质, 传热恶化

Abstract: This study systematically investigates the phase change transpiration cooling process and heat transfer deterioration mechanisms of 3D printed metal porous media structures under non-uniform heat flux conditions using an irradiation heating experimental system. During the experiment, the low heat flux region maintained a heat flux of 71kW·m-2, while the high heat flux region exhibited a heat flux range of 84kW·m-2 to 108kW·m-2. The experimental results indicate that, under the influence of non-uniform heat flux, the high heat flux region is significantly affected by vapor blockage, leading to higher local flow resistance and difficulty in coolant supply. This results in the gradual formation of a dry-out zone, with both the structure temperature and the dry-out zone continuously increasing over time. In contrast, in the fully wetted zone of the low heat flux area, the coolant preferentially flows into this zone due to lower flow resistance, forming a dominant flow channel, which further reduces the temperature of the fully wetted zone. During the experiment, a noticeable inflection point in the temperature rise curve was observed when heat transfer deterioration occurred, where the wall temperature sharply increased after surpassing the inflection point. Due to the presence of the dominant flow channel, even when the coolant supply flow rate is increased after the wall temperature exceeds the inflection point, it becomes difficult to prevent further expansion of the dry-out zone and the continuous rise in temperature.

Key words: phase change transpiration cooling, non-uniform heat flux, active thermal protection, porous media, heat transfer deterioration

中图分类号:

吕鑫琪邱云龙曾繁宇佟川江中正陈伟芳. 非均匀热流条件下相变发汗冷却实验研究[J]. 航空学报, doi: 10.7527/S1000-6893.2026.33058.

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E-mail：hkxb@buaa.edu.cn

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主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

非均匀热流条件下相变发汗冷却实验研究

Experimental Investigation on Phase Change Transpiration Cooling under Non-Uniform Heat Flux Conditions

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