Array Jet Impingement Onto High Porosity Thin Metal Foams at Zero Jet-to-Foam Spacing

Volume 8B: Heat Transfer and Thermal Engineering Pub Date : 2018-11-09 DOI:10.1115/IMECE2018-87915

Prashant Singh, Mingyang Zhang, J. Pandit, R. Mahajan

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引用次数: 7

Abstract

Metal foams enhance heat transfer rates by providing significant increase in wetted surface area and by thermal dispersion caused by flow mixing induced by the tortuous flow paths. Further, jet impingement is also an effective method of enhancing local convective heat transfer rates. In the present study, we have carried out an experimental investigation to study the combined effect of the two thermal performance-enhancement mechanisms. To this end, we conducted a set of experiments to determine convective heat transfer rates by impinging an array of jets onto thin metal foams attached on a uniformly heated smooth aluminum plate simulating a high heat-dissipating chip. The metal foams used were high porosity aluminum foams (ε∼0.94–0.96) with pore densities of 5 ppi, 10 ppi and 20 ppi (ppi: pores per inch) with thicknesses of 19 mm, 12.7 mm and 6.35 mm, respectively. With the jet-to-foam distance (z/d) set to zero, we conducted experiments with values of jet-to-jet spacing (x/d = y/d) of 2, 3 and 5. The jet plate featured an array of 5 × 5 cylindrical jet-issuing nozzles. The normalized jet-to-jet distance was varied by changing the jet diameter and keeping the jet center-to-center distance constant. Steady state heat transfer and pressure drop experiments were carried out for Reynolds number (based on jet diameter) ranging from 2500 to 10000. We have found that array impingement on thin foams leads to a significant enhancement in heat transfer compared to normal impingement over smooth surfaces. The gain in heat transfer was greatest for the 20 ppi foam (∼2.3 to 2.8 times that for the plain surface smooth target). However, this enhancement came at a significant increase of about 2.85 times in the plenum static pressure. With the pressure drop penalty taken into consideration, the x/d = 3 jet plate for the 20 ppi foam and x/d = 2 jet plate for the 10 ppi foam were found to be the most efficient cooling designs amongst the 18 cooling designs investigated in the present study.

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零喷泡间隔下阵列射流对高孔隙度薄金属泡沫的冲击

金属泡沫通过提供显着增加的湿表面积和由弯曲流道引起的流动混合引起的热分散来提高传热率。此外，射流撞击也是提高局部对流换热率的有效方法。在本研究中，我们进行了实验研究，以研究两种热性能增强机制的联合效应。为此，我们进行了一系列实验，通过将一系列射流撞击到附着在均匀加热的光滑铝板上的薄金属泡沫上来模拟高散热芯片，以确定对流换热率。金属泡沫材料为高孔隙率泡沫铝(ε ~ 0.94-0.96)，孔密度分别为5 ppi、10 ppi和20 ppi (ppi:孔/英寸)，厚度分别为19 mm、12.7 mm和6.35 mm。将射流到泡沫的距离(z/d)设为零，将射流到泡沫的间距(x/d = y/d)设为2,3和5。喷射板的特点是一组5 × 5的圆柱形喷射喷嘴。通过改变射流直径和保持射流中心距离不变来改变归一化射流与射流之间的距离。在2500 ~ 10000雷诺数(基于射流直径)范围内进行稳态传热和压降实验。我们发现，与光滑表面上的正常撞击相比，阵列撞击薄泡沫导致传热显著增强。20 ppi泡沫的传热增益最大(是普通表面光滑目标的2.3至2.8倍)。然而，这种增强是在静压增加约2.85倍的情况下发生的。考虑到压降损失，在本研究调查的18种冷却设计中，20 ppi泡沫的x/d = 3射流板和10 ppi泡沫的x/d = 2射流板被认为是最有效的冷却设计。

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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Volume 8B: Heat Transfer and Thermal Engineering

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