New water-stainless steel rod-plate heat pipe: model and experiments

IF 1.7 4区工程技术 Q3 MECHANICS

Heat and Mass Transfer Pub Date : 2024-04-15 DOI:10.1007/s00231-024-03471-2

Elvis Falcão de Araújo, Juan Pablo Flórez Mera, Luis H. R. Cisterna, Márcia Barbosa Henriques Mantelli

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Abstract

This work proposes a novel flat heat pipe technology, namely the rod-plate heat pipe, formed by the diffusion bonding of a set of parallel rods, of around 8 mm diameter, between flat plates of approximately 500 × 60 × 2 mm³. This design is inspired by the mini wire-plate heat pipe concept. This work is the first in the literature to apply this technology to large size heat pipes. A theoretical model is devised and used to predict the fluid distribution along the heat pipe, detect regions of flooding and dry-out and determine the best charging volume. Experiments are performed with a stainless-steel device operating in horizontal orientation with water as working fluid. Electrical cartridge resistances play the role of the evaporator heat source, while the condenser is cooled by either natural convection and radiation or heat exchangers linked to a thermal bath. For the experiments using a device with an exposed condenser, the minimum thermal resistance is 0.147 °C/W, for 88.50 W for heat input. The operation temperature increases with heat input up to 326.56 °C for a heat load of 191.40 W. The thermal resistances of the heat pipe cooled by heat exchangers have a minimum of 0.123 °C/W at 171.57 W heat transport rate, for a 40 °C thermal bath temperature. The theoretical results and data obtained so far corroborate the feasibility of this technology, with devices able to transfer up to 22.18 W per groove.

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新型水-不锈钢棒-板热管：模型与实验

摘要这项工作提出了一种新型扁平热管技术，即棒-板热管，由一组直径约为 8 毫米的平行棒扩散粘合在约 500 × 60 × 2 立方毫米的平板之间形成。这种设计灵感来自微型线板热管概念。这是文献中首次将该技术应用于大型热管。我们设计了一个理论模型，用于预测热管沿线的流体分布、检测淹没和干涸区域以及确定最佳充注量。实验中，不锈钢设备以水平方向运行，工作流体为水。电热筒电阻是蒸发器的热源，而冷凝器则通过自然对流和辐射或与热浴相连的热交换器进行冷却。在使用外露冷凝器的实验中，输入 88.50 W 热量时，最小热阻为 0.147 °C/W。通过热交换器冷却的热管的热阻最小为 0.123 °C/W，热浴温度为 40 °C，热传输率为 171.57 W。目前获得的理论结果和数据证实了这一技术的可行性，每槽设备的传输功率可达 22.18 瓦。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Heat and Mass Transfer 工程技术-力学

CiteScore

4.80

自引率

4.50%

发文量

148

审稿时长

8.0 months

期刊介绍： This journal serves the circulation of new developments in the field of basic research of heat and mass transfer phenomena, as well as related material properties and their measurements. Thereby applications to engineering problems are promoted. The journal is the traditional "Wärme- und Stoffübertragung" which was changed to "Heat and Mass Transfer" back in 1995.