高温热管技术在空间核能热能转换系统中的应用及展望

李欣; 袁达忠; 陈民; 杜宝瑞

doi:10.16511/j.cnki.qhdxxb.2024.22.040

清华大学学报（自然科学版） >

2024 , Vol. 64 >Issue 10: 1818 - 1838

DOI: https://doi.org/10.16511/j.cnki.qhdxxb.2024.22.040

核能与新能源技术

高温热管技术在空间核能热能转换系统中的应用及展望

李欣 ,
袁达忠 ,
陈民 ,
杜宝瑞

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1. 中国科学院工程热物理研究所, 北京 100190;
2. 中国科学院大学, 北京 100049;
3. 清华大学航天航空学院, 北京 100084

收稿日期: 2024-05-20

网络出版日期: 2024-09-20

基金资助

国家重点研发计划(2022YFB4002802)

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Application and research progress of high-temperature heat pipe technology in space nuclear power systems for thermal energy conversion

LI Xin ,
YUAN Dazhong ,
CHEN Min ,
DU Baorui

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1. Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing 100190, China;
2. University of Chinese Academy of Sciences, Beijing 100049, China;
3. School of Aerospace Engineering, Tsinghua University, Beijing 100084, China

Received date: 2024-05-20

Online published: 2024-09-20

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摘要

随着未来空间多元化任务的需求提升, 空间核电源中核能热能转换系统的空间受限、长距离无动力循环、无重力环境等极限传热难题凸显。高温热管具有传热热流密度大、工作温度高、传热温差小、自适应能力强等优点, 可作为空间核电源核能热能转换系统的关键核心器件, 应用前景广阔。该文分析了当前空间核电源核能热能转换系统存在的极限传热难题, 讨论了高温热管技术应用于空间核能热能转换系统的优势和挑战, 从高温热管内工质流动传热机理、高温热管的冷态启动、稳态传热、传热极限和寿命失效以及异形高温热管设计和研制等方面进行了综述, 总结了高温热管技术在空间核能热能转换系统中的研究现状和最新应用进展, 并给出合理建议。适应极限传热的高温热管工质流动和传热机制、异形高温热管的研制和热力结构耦合传热实验验证、空间核能热能转换与用能之间的匹配和优化是后续研究的重点方向。

关键词： 高温热管; 空间核电源; 核能热能中间转换系统; 极限传热

本文引用格式

李欣 , 袁达忠 , 陈民 , 杜宝瑞 . 高温热管技术在空间核能热能转换系统中的应用及展望[J]. 清华大学学报（自然科学版）, 2024 , 64(10) : 1818 -1838 . DOI: 10.16511/j.cnki.qhdxxb.2024.22.040

Abstract

[Significance] The increasing demand for diversified space missions necessitates addressing the extreme heat transfer challenges in space nuclear power systems, such as spatial constraints, long-distance unpowered cycles, and zero-gravity environments. Thus, the stable transfer of the substantial heat generated by the reactor core to the energy conversion device is crucial. High-temperature heat pipes, characterized by high heat flux, high operating temperatures, minimal temperature differences in heat transfer, and strong adaptability, are ideal for the key components of nuclear thermal energy conversion in space power systems. Traditional nuclear reactor power systems using coolants are less competitive in space because of their complexity, leakage risk, and stringent material strength requirements. Conversely, space heat-pipe-cooled reactors do not require auxiliary equipment such as high-temperature pumps. The phase change of the working fluid and the diffusive transport of vapor in a high-temperature heat pipe form a natural cycle that transfers heat from the core to the thermoelectric converter, thereby reducing system complexity, enhancing safety and reliability, and thus providing an effective solution for efficient heat transfer and energy conversion in space nuclear power systems. [Progress] The research and development of high-temperature heat pipe technology are pivotal for improving energy conversion efficiency and heat transfer performance in space nuclear power applications. Research on high-temperature heat pipes encompasses working fluid flow and heat transfer mechanisms, model establishment, experimental verification of frozen startup and heat transfer limits, steady-state heat transfer experimental analysis, and failure mechanisms, yielding promising results. As this technology advances, its applications and research in space nuclear thermal energy conversion systems have become more extensive and in-depth. Studies have focused on the startup and safety performance of space nuclear power systems, the coupling performance of high-temperature heat pipes in nuclear thermal energy conversion systems, and the research and design of high-temperature heat pipes in the radiators of space reactors. However, high-temperature heat pipes face challenges in achieving efficient thermal energy transfer and management, structural design of heat pipes and wicks, and adaptability to extreme space environments when applied to space nuclear power systems for thermal energy conversion. In response to these challenges, new research and attempts have been conducted. Studies on heat pipe performance under microgravity conditions have demonstrated their feasibility. In addition, research on shaped high-temperature heat pipes designs more flexible and efficient structures to meet complex heat transfer requirements. Furthermore, studies on additive manufacturing, aerogel insulation, and advanced testing techniques provide theoretical support and a technical foundation for the space application of high-temperature heat pipes. The current research on the space applications of high-temperature heat pipes still has some limitations. Ground-based tests of high-temperature heat pipes have advanced but cannot match the demands of real space scenarios. This mismatch prevents us from knowing their true performance in space reactors. Moreover, studies on the performance of high-temperature heat pipes coupled with nuclear reactors and thermoelectric converters are scarce. Thus, the overall coupling performance is largely unknown. [Conclusions and Prospects] High-temperature heat pipe technology shows promise, but still faces challenges in space applications. Currently, most space heat-pipe-cooled reactors are in the design and feasibility exploration stages. Future research will focus on optimizing high-temperature heat pipe models and their applicability, exploring the heat and mass transfer mechanisms of working fluids in space environments, conducting theoretical research and complex wick design and manufacturing studies for shaped heat pipes, and ensuring reliable coupling of high-temperature heat pipes with other components in space nuclear power systems.

Key words： high-temperature heat pipe; space nuclear power; nuclear thermal energy intermediate conversion system; extreme heat transfer

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