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具有扁平蒸发器的环路热管的最新进展

Recent Advances in Loop Heat Pipes with Flat Evaporator.

作者信息

Szymanski Pawel, Law Richard, MᶜGlen Ryan J., Reay David A.

机构信息

Faculty of Mechanical Engineering and Ship Technology, Gdansk University of Technology, 80-233 Gdańsk, Poland.

School of Engineering, Newcastle University, Newcastle Upon Tyne NE1 7RU, UK.

出版信息

Entropy (Basel). 2021 Oct 20;23(11):1374. doi: 10.3390/e23111374.

DOI:10.3390/e23111374
PMID:34828073
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8621127/
Abstract

The focus of this review is to present the current advances in Loop Heat Pipes (LHP) with flat evaporators, which address the current challenges to the wide implementation of the technology. A recent advance in LHP is the design of flat-shaped evaporators, which is better suited to the geometry of discretely mounted electronics components (microprocessors) and therefore negate the need for an additional transfer surface (saddle) between component and evaporator. However, various challenges exist in the implementation of flat-evaporator, including (1) deformation of the evaporator due to high internal pressure and uneven stress distribution in the non-circular casing; (2) heat leak from evaporator heating zone and sidewall into the compensation chamber; (3) poor performance at start-up; (4) reverse flow through the wick; or (5) difficulties in sealing, and hence frequent leakage. This paper presents and reviews state-of-the-art LHP technologies; this includes an (a) review of novel manufacturing methods; (b) LHP evaporator designs; (c) working fluids; and (d) construction materials. The work presents solutions that are used to develop or improve the LHP construction, overall thermal performance, heat transfer distance, start-up time (especially at low heat loads), manufacturing cost, weight, possibilities of miniaturization and how they affect the solution on the above-presented problems and challenges in flat shape LHP development to take advantage in the passive cooling systems for electronic devices in multiple applications.

摘要

本综述的重点是介绍具有扁平蒸发器的环路热管(LHP)的当前进展,这些进展解决了该技术广泛应用面临的当前挑战。LHP的一项最新进展是扁平形蒸发器的设计,它更适合离散安装的电子元件(微处理器)的几何形状,因此无需在元件和蒸发器之间设置额外的传热表面(鞍座)。然而,扁平蒸发器的实施存在各种挑战,包括:(1)由于非圆形外壳内的高内部压力和应力分布不均导致蒸发器变形;(2)蒸发器加热区和侧壁向补偿腔的热泄漏;(3)启动时性能不佳;(4)通过毛细芯的逆流;或(5)密封困难,因此频繁泄漏。本文介绍并综述了最先进的LHP技术;这包括(a)新型制造方法的综述;(b)LHP蒸发器设计;(c)工作流体;以及(d)建筑材料。这项工作提出了用于开发或改进LHP结构、整体热性能、传热距离、启动时间(特别是在低热负荷下)、制造成本、重量、小型化可能性的解决方案,以及它们如何影响解决扁平形LHP开发中上述问题和挑战的方案,以便在多种应用的电子设备被动冷却系统中发挥优势。

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