Enhanced pool-boiling heat transfer and critical heat flux using femtosecond laser surface processing

C. Kruse, T. Anderson, Chris Wilson, C. Zuhlke, D. Alexander, G. Gogos, S. Ndao
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引用次数: 3

Abstract

In this paper, we present the experimental investigation of pool boiling heat transfer on multiscale (micro/nano) functionalized metallic surfaces. The multiscale structures were fabricated via a femtosecond laser surface process (FLSP) technique which forms mound-like microstructures covered by layers of nanoparticles. Using a pool boiling experimental setup with deionized water as the working fluid, both the heat transfer coefficient and critical heat flux were investigated. The polished reference sample was found to have a critical heat flux of 91 W/cm2 at 40 °C of superheat and a maximum heat transfer coefficient of 23,000 W/m2-K. The processed sample was found to have a critical heat flux of 122 W/cm2 at 18 °C superheat and a maximum heat transfer coefficient of 67,400 W/m2-K. Flow visualization revealed nucleate boiling to be the main two-phase heat transfer mechanism. The overall heat transfer performance of the metallic multiscale structured surface has been attributed to both augmented heat transfer surface area and enhanced nucleate boiling regime. On the other hand, increase in the critical heat flux can be attributed to the superhydrophilic nature of the laser processed surface and the presence of nanoparticle layers.
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利用飞秒激光表面处理增强池沸腾传热和临界热流密度
本文对多尺度(微纳)功能化金属表面的池沸腾传热进行了实验研究。采用飞秒激光表面加工(FLSP)技术制备了多尺度结构,形成了由纳米颗粒层覆盖的丘状微结构。采用去离子水为工质的池沸腾实验装置,对传热系数和临界热流密度进行了研究。抛光后的参考样品在40°C过热时的临界热流密度为91 W/cm2,最大传热系数为23,000 W/m2-K。在18℃过热条件下,样品的临界热流密度为122 W/cm2,最大传热系数为67,400 W/m2-K。流动显示显示,核沸腾是主要的两相传热机制。金属多尺度结构表面的整体传热性能归因于传热表面积的增加和核沸腾状态的增强。另一方面,临界热通量的增加可归因于激光加工表面的超亲水性和纳米颗粒层的存在。
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