Variable Switching System for Heat Protection and Dissipation of Ultra-LEO Satellites Based on LHP Coupled with TEC

Aerospace Pub Date : 2024-07-01 DOI:10.3390/aerospace11070539

Jin Huang, Liang Chang, Baiyang Dong, Jianping Wang, Hulin Huang

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Abstract

Ultra-low Earth orbit (LEO) satellites are widely used in the military, remote sensing, scientific research, and other fields. The ultra-LEO satellite faces the harsh aerothermal environment, and the complex variable attitude task requires the radiator of the satellite to not only meet the heat dissipation requirements of the load but also to resist aerothermal flux. In this study, the aerothermal flux of 160–110 km was calculated, and the loop heat pipe (LHP) coupled with a thermo-electric cooler (TEC) and multi-layer insulation (MLI) were applied to ultra-LEO satellites to determine the variable switching and fast response of heat dissipation and heat protection. An aerothermal flux simulation test platform was built. After the assessment of the ultra-LEO aerothermal flux test, even when the head temperature was as high as 350 °C and the side radiator temperature was as high as 160 °C, the temperature of the internal heat source could be controlled within 22.5 °C through the efficient work of the thermal variable switch system. The study confirms the accuracy and feasibility of the system, which provides an important reference for the subsequent actual on-orbit mission.

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基于 LHP 和 TEC 的超 LEO 卫星热保护和散热可变开关系统

超低地球轨道（LEO）卫星广泛应用于军事、遥感、科研等领域。超低地轨道卫星面临着恶劣的气热环境，复杂的变姿态任务要求卫星的散热器不仅要满足负载的散热要求，还要能抵抗气热通量。本研究计算了 160-110 km 的气热通量，并将环形热管（LHP）与热电冷却器（TEC）和多层隔热材料（MLI）耦合应用于超 LEO 卫星，以确定散热和热保护的可变切换和快速响应。建立了一个空气热通量模拟试验平台。经过对超 LEO 空气热通量试验的评估，即使头部温度高达 350 ℃，侧面散热器温度高达 160 ℃，通过热可变开关系统的高效工作，内部热源的温度也能控制在 22.5 ℃以内。研究证实了该系统的准确性和可行性，为后续的实际在轨任务提供了重要参考。

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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Aerospace

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