University of Hertfordshire

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Temperature oscillation of a dual compensation chamber loop heat pipe under acceleration conditions

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Original languageEnglish
Article number117450
Number of pages12
JournalApplied Thermal Engineering
Volume198
Early online date23 Aug 2021
DOIs
Publication statusE-pub ahead of print - 23 Aug 2021

Abstract

Loop heat pipe has a wide application in the fields of airborne electronics cooling and thermal management. However, the pertinent temperature oscillation of the loop heat pipe could lead to adverse effects on the electronics. In the current study, an ammonia-stainless steel dual compensation chamber loop heat pipe was developed to experimentally investigate the temperature oscillation under different acceleration conditions. The impact of several control parameters such as different heat loads, loading modes, acceleration directions and magnitudes on the operational performance of the loop heat pipe was analyzed in a systematic manner. The heat load applied on the evaporator ranged from 25 W to 300 W. The acceleration magnitude varied from 1g to 9g and four different acceleration direction, i.e. configurations A, B, C and D, were taken into account. Two different loading modes were applied with different heat load and acceleration force. Experimental results show that (i) the loop temperature will change and oscillate as the acceleration force was applied under all test conditions. It can be easily found that the temperature oscillation occurred at both heat loads of 250 W and 300 W. (ii) for the case of the first loading mode, periodic temperature oscillation is observed on the liquid line, whereas for the second loading mode, periodic temperature oscillation can be easily appeared on the entire loop. (iii) the loop temperature under both configurations A and B with acceleration of 7g does not oscillate at heat load of 150 W, 200 W and 250 W when the first loading mode is applied. Especially under configuration B, the acceleration could contribute to repress the temperature oscillation. Under the current heat loads for almost all cases, the temperature oscillation can be observed for configurations A, C and D with acceleration of 5g. (iv) the amplitude of evaporator at heat load of 300 W under configuration C are 0.6 oC, 0.3 oC, 0.2 oC and 0.3 oC with acceleration of 3g, 5g, 7g and 9g. The corresponding period is 66 s, 36 s, 34 s and 36 s, respectively.

Notes

© 2021 Elsevier Ltd. All rights reserved. This is the accepted manuscript version of an article which has been published in final form athttps://doi.org/10.1016/j.applthermaleng.2021.117450

ID: 25748654