添加工作流体的中心芯热管的流体流动和传热特性：可视化实验研究

Q3 Engineering

Multiphase Science and Technology Pub Date : 2023-01-01 DOI:10.1615/multscientechn.2023048029

Yasushi Koito, C. Chen, R. Kakizoe, A. Fukushima

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引用次数: 1

摘要

本文介绍了附加工质的中心芯热管的实验研究。采用半透明热管，在水平、垂直、侧向三种方向下进行换热实验。灯芯结构为烧结铜粉，工作流体为水。热管芯结构与容器壁之间有小间隙。在每种取向方式中，热管的冷凝器部分使用冷却套进行水冷，蒸发器部分使用加热器进行加热。利用摄像机捕捉了热管中的流体流动和相变现象，并利用热电偶获得了热管温度的时间变化。由于额外的工作流体，在蒸汽流动通道中发现了液体段塞。液体段塞可以分为两种类型:动态液体段塞和静态液体段塞。实验结果表明，动静液塞在水平方向下分布更有效。因此，相比于其他两种取向模式，水平取向模式下热管的热阻更小，热管的最大热输入也更大。实验结果也证实了小间隙在水平取向模式下是有效的。额外的工作流体被储存在间隙中，这增加了热管的热性能。

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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Fluid Flow and Heat Transfer Characteristics of a Centered-wick Heat Pipe with Additional Working Fluid: Experimental Study with Visualization

This article describes the experimental study of the centered-wick heat pipe with additional working fluid. A semi-transparent heat pipe is employed, and the heat transfer experiments are conducted in three orientation modes: horizontal, vertical, and sideways. The wick structure is a sintered copper powder, and the working fluid is water. The heat pipe has a small gap between the wick structure and the container wall. In each orientation mode, a condenser section of the heat pipe is water-cooled with a cooling jacket, and an evaporator section is heated with a heater. Fluid-flow and phase-change phenomena in the heat pipe are captured by using a video camera, and the temporal changes in the temperatures of the heat pipe are obtained by using thermocouples. Due to the additional working fluid, liquid slugs are found in vapor flow channels. The liquid slugs can be categorized into two types: a dynamic liquid slug and a static liquid slug. The experimental results demonstrate that the dynamic and static liquid slugs are distributed more effectively in the horizontal orientation mode. Thus, the thermal resistance of the heat pipe tends to be smaller and the maximum heat input to the heat pipe is larger in the horizontal orientation mode than in the other two orientation modes. The experimental results also confirm that the small gap is effective in the horizontal orientation mode. The additional working fluid is stored in the gap, which increases the thermal performance of the heat pipe.

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来源期刊

Multiphase Science and Technology Engineering-Engineering (all)

CiteScore

0.80

自引率

0.00%

发文量

期刊介绍： Two-phase flows commonly occur in nature and in a multitude of other settings. They are not only of academic interest but are found in a wide range of engineering applications, continuing to pose a challenge to many research scientists and industrial practitioners alike. Although many important advances have been made in the past, the efforts to understand fundamental behavior and mechanisms of two-phase flow are necessarily a continuing process. Volume 8 of Multiphase Science and Technology contains the text of the invited lectures given at the Third International Workshop on Two-Phase Flow Fundamentals sponsored by the Electric Power Research Institute (EPRI) and the U. S. Department of Energy (DOE).