期刊
NUCLEAR ENGINEERING AND DESIGN
卷 378, 期 -, 页码 -出版社
ELSEVIER SCIENCE SA
DOI: 10.1016/j.nucengdes.2021.111182
关键词
Heat pipe cooled reactor; Potassium heat pipe; Experimental investigation; Heat transfer performance; Heat transfer limit
资金
- National Key Research and Development Program of China [2019YFB1901100]
- China National Postdoctoral Program for Innovative Talents [BX201600124]
- China Postdoctoral Science Foundation [2019M3737]
- Science and Technology on Reactor System Design Technology Laboratory
Heat pipe cooled reactor (HPR) is considered a promising candidate for space power systems. This study experimentally investigated the heat transfer performance of potassium heat pipes under various conditions. The results show that heating power affects heat transfer within the capillary limit, while inclination angle has a strong impact on thermal efficiency. The study provides valuable insights for the design and application of high-temperature heat pipes in HPR systems.
Heat pipe cooled reactor (HPR) is considered as an excellent candidate for space power systems. As a core cooling method, the operational characteristics of high-temperature heat pipes need to be researched. In this paper, the heat transfer performance of potassium heat pipes (phi 30mm x 800 mm) is studied experimentally. The thermal behavior of heat pipe is tested under various conditions, including heating power (0.2-4 kW), air/water cooling method, inclination angle (0-90 degrees), and filling ratio (20% and 100% of void in wick). And the characteristics of heat transfer limits are analyzed, consisting of dryout, entrainment, and sonic limit. The results show heating power is beneficial to heat transfer within the capillary limit. However, overheating occurs when heating power exceeds the capillary limit. The inclination angle has a strong effect on the thermal efficiency of heat pipe for the competition between gravity and entrainment, and the angle of 30 degrees corresponds to the best thermal performance. Sonic limit and entrainment limit are estimated with a relative error of 38.7% and 17.9%. Dryout is divided into local dryout ( 200 degrees C/m) and integral dryout ( 200 degrees C/m). It is concluded that the high filling ratio (100%) and the small inclination angle (30 degrees) are helpful to realize the optimal thermal performance. This work makes it possible to validate the operation of a high-temperature heat pipe and provides a reference for the design and application of HPR.
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