非封闭式保温斗篷热防护性能研究

None Miao Yu-Zhao, None Tang Gui-Hua
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摘要

高超声速飞行器鼻锥气动热可达MWm<sup>-2</sup>在飞行过程中,以传导和辐射的形式传递到高超声速飞行器内部。高效的保温材料对保证内部电子元件的安全工作具有重要意义。热超材料可以调节宏观热流路径,在热防护领域发展迅速,具有广阔的应用前景。本文设计了一种非封闭的理论热斗篷,利用变换多热学原理对高超声速飞行器鼻锥周围的热流进行引导,同时控制热传导和热辐射。由于参数的各向异性,设计了一种简化近似的多层结构。基于COMSOL软件,对斗篷和多层结构的热防护特性和传热机理进行了数值研究。结果表明:在理论热斗篷和多层结构中,热量都能以传导和辐射的形式在物体周围流动,从而减少了传递到内部区域的热量。与隔热材料相比,保护区升温速度减慢,高超声速飞行器鼻锥前端温度明显降低。然而,斗篷和多层结构的热防护性能的提高,要求材料的固体导热系数和辐射导热系数低于原有的保温材料。为了解决这一问题,进一步提出了一种非封闭的理论外推热斗篷。外推式热斗篷的固体导热系数和辐射导热系数均非奇异,可能高于原保温材料。数值模拟结果表明,外推式热斗篷能够引导物体周围的热流,显著提高了热防护能力。与隔热材料相比,高超声速飞行器鼻锥前部温度降低了100 K,高超声速飞行器鼻锥内部中心区域温度降低了10 K。非封闭外推式热斗篷为热防护提供了新的途径,适用于复杂靶区,在热防护方面显示出巨大的应用潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Study on thermal protection characteristics of non-enclosed thermal cloak
The aerodynamic heat of hypersonic vehicle nose cone can reach MWm-2 magnitude during flight, which could be transferred to the interior of hypersonic vehicle in the form of conduction and radiation. High efficient thermal insulation material is significant to keep internal electronic components working safely. Thermal metamaterials can regulate the macroscopic heat flow path, which have been developing rapidly and have a wide application prospect in the field of thermal protection. In this paper, a non-enclosed theoretical thermal cloak is designed to guide heat flow around hypersonic vehicle nose cone by using the transformation multithermotics, which can control thermal conduction and radiation simultaneously. A multi-layer structure is designed as cloak's simplified approximation due to the anisotropic parameters. Based on the software COMSOL, the thermal protection characteristics and heat transfer mechanism of the cloak and multi-layer structure are studied numerically. The results show that heat can flow around the object in the form of conduction and radiation in both theoretical thermal cloak and multi-layer structure, so the heat transferred to the inner area is decreased. Compared with the thermal insulation material, the heating rate of the protected area slows down, and the temperature at the front of the hypersonic vehicle nose cone is significantly reduced. However, the improvement of the thermal protection performance of cloak and multi-layer structures requires that the solid and radiative thermal conductivities of the material be lower than those of the original thermal insulation materials. To solve this problem, a non-enclosed theoretical extrapolation thermal cloak is further proposed. The solid and radiative thermal conductivities of extrapolation thermal cloak are non-singular, which could be higher than those of the original thermal insulation materials. Numerical simulation results show that the extrapolation thermal cloak can guide heat flow around object, so the thermal protection capability is improved significantly. Compared with the thermal insulation materials, the temperature of the front of the hypersonic vehicle nose cone is reduced by 100 K, and the temperature of the inner central zone of the hypersonic vehicle nose cone is reduced by 10 K. The non-enclosed extrapolation thermal cloak provides a new approach for thermal protection and is suitable for complex target areas, showing great application potential in thermal protection.
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