Visual Study on Flow and Operational Characteristics of Flat Plate Closed Loop Pulsating Heat Pipes

This paper presents an experimental study including visualization on a flat plate closed loop pulsating heat pipes.It consists of a total of 40 channels with square cross section(2 mm×2 mm,165 mm long) machined directly on an aluminum plate(180 mm×120 mm×3 mm) covered by a transparent plate.The working fluid employed is ethanol.As a result,various flow patterns and their transitions are observed and found to be related to the fluid fill ratio,input heat load and the device orientation.Also the operational characteristics and working mechanism are discussed.

Parametric Influence on Thermal Performance of Flat Plate Closed Loop Pulsating Heat Pipes

This paper presents an experimental study on a flat plate closed loop pulsating heat pipes. It consisted of total 40 channels with square cross section （2 × 2 mm^2, 165 mm long） machined directly on an aluminum plate（180×120×3 nm^2）, which was covered by a transparent plate. The working fluid employed was ethanol. As the results, the influence parameters of thermal performance were investigated, such as filling ratio, heat load and operational orientations etc. Filling ratio was found to be a critical parameter, and its effect was rather complicated. According to its values the PHP plate could have four distinct working zones with different operational characteristics and heat transfer performance. The effect of heat load on thermal performance was found to be positive, and in general, iucrcasing the heat load would improve heat transfer performance. In order to analyze the effect of gravity on thermal performance, three different heat modes and total seven tilt angles were tested and compared. Successful operation at all orientations with respect to gravity was also achieved.

倾角对平板型LHP 运行性能的影响

通过改变内部毛细芯结构达到改善环路热管性能、减小环路热管体积的目的,取消储液腔,将传统的长矩形蒸汽槽道更改为特斯拉阀形状,并且将蒸发器进出口设置在蒸发器两侧。研究该热管在不同倾角下的启动性能、运行特性。结果显示:相对于0°倾角运行,倾角的存在能够减少环路热管的启动时间,降低蒸发器温度,存在倾角的条件下启动特性差别不大。随着功率的增加,不同倾角的环路热管热阻减小,仅在倾角(10°以下)较低时有较大的热阻。随着倾角的增加,环路热管热阻随功率的变化无较大改变。

平板型环路热管研究现状及发展趋势

平板型环路热管是一种具有平板蒸发器的环路结构热管器件,其利用气液相变原理进行高效热传递。由于平板型环路热管更符合先进电子技术的发展趋势,并具有优异的远距离热传输性能,在航天飞行器、电子设备冷却、余热回收利用等领域具备广阔的应用前景。因此,文章综述了近年来研究者在平板型环路热管的吸液芯、工质、工作特性、理论模型以及异型结构等方面所做出的努力,总结了平板型环路热管上述方向的发展现状,提出平板型环路热管的未来发展趋势,助力先进两相散热技术发展。

Influence of Filling Ratio and Working Fluid Thermal Properties on Starting up and Heat Transferring Performance of Closed Loop Plate Oscillating Heat Pipe with Parallel Channels

Using ethanol or acetone as the working fluid, the performance of starting up and heat transfer of closed-loop plate oscillating heat pipe with parallel channels(POHP-PC) were experimentally investigated by varying filling ratio, inclination, working fluids and heating power. The performance of the tested pulsating heat pipe was mainly evaluated by thermal resistance and wall temperature. Heating copper block and cold water bath were adopted in the experimental investigations. It was found that oscillating heat pipe with filling ratio of 50% started up earlier than that with 70% when heating input was 159.4 W, however, it has similar starting up performance with filling ratio of 50% as compared to 70% on the condition of heat input of 205.4 W. And heat pipe with filling ratio of 10% could not start up but directly transit to dry burning. A reasonable filling ratio range of 35%-70% was needed in order to achieve better performance, and there are different optimal filling ratios with different heating inputs- the more heating input, the higher optimal filling ratio, and vice versa. However, the dry burning appeared easily with low filling ratio, especially at very low filling ratio, such as 10%. And higher filling ratio, such as 70%, resulted in higher heat transfer( dry burning) limit. With filling ratio of 70% and inclination of 75°, oscillating heat pipe with acetone started up with heating input of just 24 W, but for ethanol, it needed to be achieved 68 W, Furthermore, the start time with acetone was similar as compared to that with ethanol. For steady operating state, the heating input with acetone was about 80 W, but it transited to dry burning state when heating input was greater than 160 W. However, for ethanol, the heating input was in vicinity of 160 W. Furthermore, thermal resistance with acetone was lower than that with ethanol at the same heating input of 120 W.

板式脉动热管内气液两相流流型演化及传热分析

基于VOF方法建立了板式脉动热管内气液两相流动和相变传热的三维非稳态数学模型,并进行了数值求解.研究了该型热管内气液两相流流型演化和相变传热特性,比较了不同加热功率条件下热管内的流型和温度分布.研究结果表明:该板式脉动热管在运行过程中出现的主要流型有泡状流、柱塞流、环状流;当加热功率为100和120 W时,启动工况下热管内总气相含气率会出现飞升;稳定循环运行工况下热管各点温度随时间做有规律的周期性脉动,加热段脉动幅度最大,绝热段次之,冷却段最小,温度脉动频率随着功率的增大而升高.

微型热管的研究进展

微型热管是伴随微电子技术的发展而发展起来的一门新兴技术,是有效冷却高热流密度电子器件的主要途径之一。阐述常用的微型热管即脉动热管、微槽平板热管、环路热管的研究现状和进展,总结微型热管研究所面临的困难和挑战,指出微型热管的发展趋势,认为必将广泛应用于电子器件冷却、航空航天及计算机等领域。

平板式小型环路热管的实验研究

设计一套蒸发器尺寸为74 mm(D)×14 mm(H)的平板式小型环路热管(mLHP),工质为甲醇,冷凝方式采用冰水混合物冷却,研究其换热性能。实验表明,该环路热管能够实现重力和无重力辅助启动。倾角为18°、充灌率为60%时,热负荷从20 W增加到140 W,整个环路热管热阻从2.58℃/W减小到0.44℃/W。无重力辅助启动时,mLHP能够散去130 W的热量而壁面温度低于80℃。当热负荷一定,无重力辅助启动时的蒸发器壁面温度高于重力辅助启动时的壁面温度。在保证系统启动的工质裕量前提下,减少工质充灌量有利于降低蒸发器壁面温度。mLHP运行存在低热负荷区和高热负荷区,在低热负荷区,蒸发器和补偿腔温度随着热负荷的增加降低;在高热负荷区,蒸发器和补偿腔温度随着热负荷的增加升高。

倾角及冷却工况对多通路并联回路板式脉动热管传热性能的影响

针对多通路并联回路板式脉动热管建立实验台,采用铜质模块加热和水浴冷却方式作为热工条件,着重考察脉动热管在不同倾角(90°,75°,60°)及冷却工况(4.5 g·s-1和9.0 g·s-1)下的传热性能,通过壁面温度的振荡和传热热阻来评价其传热效果。实验结果表明,重力对多通路并联回路板式脉动热管传热性能的影响较大,随着倾角的减少,工质的回流变弱,传热热阻变大,传热极限变低;脉动热管的加热功率与冷却能力是相互匹配的,匹配度越高,脉动热管越不易干烧,传热极限越高,在有倾角的工况下提高传热极限表现得更为明显;脉动热管运行时存在一个最佳水流量,在最佳冷却工况下,脉动热管的运行热阻最低。

多通路并联回路板式脉动热管可视化及启动性能试验研究

针对多通路并联回路板式脉动热管搭建试验台，选用无水乙醇作为工质，在不同的充液率、倾斜角度和加热功率情况下，观测工质的流型以及流动方式的变化，分析脉动热管的启动特性。结果表明，工质的流型为泡状流，汽液塞间隔分布的塞状流，塞状流与环状流并存的混合流，整个通道中不存在完全是环状流的流型；充液率为10％时，工质主要分布在脉动热管的中间部位，充液率为35％-85％，工质分布的均匀性增强；运行过程中工质以塞状流（靠近冷凝端）和环状流（靠近加热端）并存的混合流形式存在，随着加热功率的增加，环状流的平衡位置逐渐向冷凝端移动；启动方式为温度渐进式，启动时间随着加热功率的升高而缩短，倾角的减少而增加，在竖直状态下，脉动热管能够较快启动，正常启动范围为60°-90°，倾角为45°和30°时不能稳定启动。

负压式平板型环路热管试验

为解决高热流密度电子器件的散热问题,设计了一套负压式铜-甲醇环路热管,其蒸发器设计成平板型。研究表明,该平板型环路热管具有较高的散热能力,能够在无重力姿态和重力姿态下顺利启动。当重力倾角分别为0°、18°和30°,热负荷为160W时,蒸发器壁面温度分别达到85.8℃、66.3℃和64.6℃。按照环路热管启动状态,其启动过程可分为3个阶段:加热阶段、预启动阶段和后启动阶段。在低热负荷区域,环路热管会出现温度波动现象。增大重力倾角,有利于降低蒸发器壁面温度和热阻。当重力倾角为30°,热负荷从10W递增到160W时,环路热管的热阻从4.97℃/W降低到0.39℃/W。

板式脉动热管的实验与应用研究进展

板式脉动热管具有结构简单、成本低、适应性好、传热性能极佳、易于微小型化等优点,因此作为微小设备冷却系统更具竞争力,也吸引了众多研究者的关注,但目前仍缺乏有效的设计准则指导工程应用。本文在介绍了脉动热管的工作原理及特点基础上,综述了近年来针对板式结构所开展的研究,以水力直径变化为主线总结了传热性能的研究,包括管内流型和振荡特征、主要参数的影响以及进一步提高传热性能的途径;回顾了有关启动特性的研究,涉及启动条件、启动过程时间与温度的关系及相关理论分析;介绍了目前传热极限发生机理的分析,同时简述了板式脉动热管应用方面的研究进展;最后指出了目前未能解决的关键问题,特别是为充分发挥板式结构微小型化的优势,对影响启动条件的参数研究至关重要。

常用微型热管的特性比较

常用的微型热管主要有脉动热管、微槽平板热管和环路热管。当前对脉动热管的研究主要通过实验观察,实验数据不足,尚不能完全明确脉动热管的运行和传热的机理。对微槽平板热管的传热传质机理仍缺少深入而准确的了解,也未建立起工作极限参数,缺少可靠的计算与设计方法。环路热管是一种采用两相流技术的新型传热装置,经过近30年的发展,技术已趋成熟。

多弯头数平板状闭式回路脉动热管流动及试验运行机理的可视化试验研究

对多弯头数平板状闭式回路脉动热管进行了可视化试验研究。在180×120×3mm^3的铝板上加工出40个首尾相接的正方形槽道（每个槽道横截面尺寸2×2mm^2，长165mm），构成闭式回路。采用酒精为工作介质，充液率在10％-90％范围内变化，安装角度可任意调节。通过试验，系统观察平板内部的流型及流态转换规律，探讨其运行机理。

板式脉动热管强化传热方法研究

为了研究板式脉动热管的传热性能强化的方法,对原型和改进型两种不同板式脉动热管传热特性进行数值分析比较。基于VOF方法建立板式脉动热管汽液两相流动及相变传热三维非稳态数学模型,仿真得到不同加热功率条件下热管内流型演化和温度分布。仿真结果表明,改进型脉动热管在高功率阶段,整体等效热阻小于原型。

用于高热通量电子散热的平板环路重力热管

为解决高热通量电子设备散热问题,设计一套蒸发器上下表面由多个方柱相连的平板型环路重力热管(LGHP)。通过实验研究其换热性能,包括在不同加热功率下平板热管的传热特性及均温特性,以及蒸发器摆放方式和不同种工质对平板热管传热性能的影响。实验结果表明,环路热管工质采用R134a的工作性能比R600a好,平板竖直放置比水平放置好。采用R134a且竖直放置时,其临界热通量(CHF)可达212.3 kW/m^2,对应传热系数为16.2kW/(m^2·K)。该平板换热器可以保证电子设备工作温度不超过60℃,且运行过程中平板蒸发器与热源接触的壁面各测点间除出口处外温度差值小于5℃,均温性能优异。