Phase change technology is a science that is continually finding new applications, from passive refrigeration cycles to semiconductor cooling. The primary heat transfer techniques associated with phase change heat transfer are pool boiling, flow boiling, and spray cooling. Of these techniques, spray cooling is the least studied and the most recent to receive attention in the scientific community. Spray cooling is capable of removing large amounts of heat between the cooled surface and the liquid, with reported heat flux capabilities of up to 1000 W/cm2 for water. Many previous studies have emphasized heat flux as a function of spray parameters and test conditions. Enhanced spray cooling investigations to date have been limited to surface roughness studies. These studies concluded that surface tolerance (i.e. variations in machined surface finish) had an impact upon heat flux when using pressure atomized sprays. Analogous pool boiling studies with enhanced surfaces have shown heat flux enhancement. A spray cooling study using enhanced surfaces beyond the surface roughness range may display heat flux enhancement as well. In the present study, a group of extended and embedded surfaces (straight fins, cubic pin fins, pyramids, dimples and porous tunnels) have been investigated to determine the effects of enhanced surface structure on heat flux. The surface enhancements were machined on the top surface of copper heater blocks with a cross-sectional area of 2.0 cm2. Measurements were also obtained on a flat surface for baseline comparison purposes. Thermal performance data was obtained under saturated (pure fluid at 101 kPa), nominally degassed (chamber pressure of 41.4 kPa) and gassy conditions (chamber with N2 gas at 101 kPa). The study shows that both extended and embedded structures (beyond the surface roughness range) promote heat flux enhancement for both degassed and gassy spray cooling conditions. The study also shows that straight fins provide the best utilization of surface area added for heat transfer. An Energy conservation based CHF correlation for flat surface spray cooling was also developed. CHF predictions were compared against published and non-published studies by several researchers. Results for the correlations performance show an average mean error of ±17.6% with an accuracy of ±30% for 88% of the data set compared against.
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机译:相变技术是一门不断发现新应用的科学,从被动制冷循环到半导体冷却。与相变传热相关的主要传热技术是池沸腾,流沸腾和喷雾冷却。在这些技术中,喷雾冷却技术是研究最少的技术,也是最近引起科学界关注的最新技术。喷雾冷却能够去除冷却表面和液体之间的大量热量,据报道,水的热通量高达1000 W / cm2。以前的许多研究都强调热通量是喷雾参数和测试条件的函数。迄今为止,增强的喷雾冷却研究仅限于表面粗糙度研究。这些研究得出的结论是,使用压力雾化喷雾时,表面公差(即机加工表面光洁度的变化)会对热通量产生影响。具有增强表面的类似池沸腾研究表明,热通量得到了增强。使用超出表面粗糙度范围的增强表面的喷雾冷却研究也可能显示出热通量的增强。在本研究中,已经研究了一组扩展表面和嵌入表面(直翅片,立方钉状翅片,金字塔形,凹痕和多孔隧道),以确定增强的表面结构对热通量的影响。表面增强材料在横截面积为2.0 cm2的铜加热块的顶面上进行机加工。还出于基准比较的目的,在平坦表面上获得了测量值。热性能数据是在饱和(纯流体在101 kPa下),标称脱气(腔室压力为41.4 kPa)和气体条件下(带有N2气体的腔室在101 kPa)下获得的。研究表明,在脱气和气体喷雾冷却条件下,扩展和嵌入结构(超出表面粗糙度范围)均可促进热通量的提高。研究还表明,直翅片可最大程度地利用增加的表面积进行传热。还开发了用于平面喷雾冷却的基于节能的CHF相关性。一些研究人员将CHF预测与已发表和未发表的研究进行了比较。相关性能的结果显示,相对于88%的数据集,平均平均误差为±17.6%,准确度为±30%。
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