低温冷却器
材料科学
磁铁
核工程
霓虹灯
表征(材料科学)
低温学
超导磁体
热力学
机械工程
物理
原子物理学
氩
纳米技术
工程类
作者
Q. Gorit,John M. Maris,C Zoller
出处
期刊:Cryogenics
[Elsevier BV]
日期:2025-06-16
卷期号:150: 104138-104138
标识
DOI:10.1016/j.cryogenics.2025.104138
摘要
Pulsating heat pipes (PHPs), i.e. passive devices employing two-phase flow, are increasingly studied in cryogenic conditions to improve heat transfer between cryocoolers and high temperature superconducting (HTS) magnets. This paper presents the experimental characterization of PHPs tested in vertical orientation using neon as working fluid. The main objective is to carry out a parametric study to assess the optimum parameters for a potential application to the cooling of HTS magnets. A summary of the literature on PHPs experiments under cryogenic conditions justifies the choice of neon as the working fluid for this specific application. It also leads to the selection of high-performance PHP designs for the parametric study. The PHP designs, the experimental setup, procedures, and campaigns are described. The results of the individual characterization of two PHPs, having 5 and 10 turns respectively, are analyzed and their performances are compared. In addition, a specific configuration operating simultaneously two 5-turn PHPs in parallel is investigated. The experiments are performed for two condenser temperatures (27 and [Figure presented]), a wide range of filling ratios (15 to 90%) and of heat loads (2 to [Figure presented]). The effect of the number of turns and the series or parallel configuration on the thermal performance is quantified and discussed, along with the effect of condenser temperature, filling ratio and heat load. The optimum parameters are found to be the two 5-turn PHPs in parallel, the filling ratio of 35% and the condenser temperature of [Figure presented]. These conditions lead to the lowest evaporator temperatures with thermal resistances ranging from 0.15 to [Figure presented], while keeping a reliable working stability and no dry-out phenomena occurrence in the heat load range tested.
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