Weng Wen, B. Ghidersa, W. Hering, J. Starflinger, R. Stieglitz
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引用次数: 0
摘要
由于热管能够通过内部工作流体的蒸发和冷凝将热量从热源输送到散热器,并且能够大大扩大冷却回路的传热面积,因此考虑了在DEMO容器内等离子体面组件(pfc)中使用热管(HP)。最近在EUROfusion工作包Divertor框架内进行的工程研究(Wen et al ., 2021)表明,可以使用复合毛细管结构(其中轴向槽覆盖绝热区和冷凝器,烧结多孔材料覆盖蒸发器)设计毛细管极限超过6 kW的热管。这一功率水平对应于20兆瓦/平方米的应用热流,使得这种设计在导流器目标概念方面很有趣。为了验证最初的工程分析结果,已经进行了几个实验来评估所提出的热管概念的实际性能。本文介绍了两种不同蒸发器设计的工作极限的实验结果:一种是平面多孔结构,另一种是肋和通道结构。
The use of heat pipes (HP) for the DEMO in-vessel plasma-facing components (PFCs) has been considered because of their high capacity to transport the heat from a heat source to a heat sink by means of the vaporization and condensation of the working fluid inside and their ability to enlarge the heat transfer area of the cooling circuit substantially. Recent engineering studies conducted in the framework of the EUROfusion work package Divertor (Wen et al, 2021) indicate that it is possible to design a heat pipe with a capillary limit above 6 kW using a composite capillary structure (wherein axial grooves cover the adiabatic zone and the condenser, and sintered porous material covers the evaporator). This power level would correspond to an applied heat flux of 20 MW/m2, rendering such a design interesting with respect to a divertor target concept. To validate the results of the initial engineering analysis, several experiments have been conducted to evaluate the actual performance of the proposed heat pipe concept. The present contribution presents the experiment’s results regarding the examination of the operating limits of two different designs for an evaporator: one featuring a plain porous structure, and one featuring ribs and channels.
期刊介绍:
The Journal of Nuclear Engineering and Radiation Science is ASME’s latest title within the energy sector. The publication is for specialists in the nuclear/power engineering areas of industry, academia, and government.