Extraordinary boiling enhancement by hybrid dividing zones of micro-nano structures

Extraordinary boiling enhancement by hybrid dividing zones of micro-nano structures

Boiling two-phase transition is considered to be the ultimate effective cooling strategy for the next generation of high-power devices in the near future in various application scenarios, such as power electronics, radar systems, and computer data centers. The liquid-solid interface plays a crucial...

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Bibliographic Details
Published in:International communications in heat and mass transfer Vol. 153; p. 107345
Main Authors: Jiang, Xingchi, Shah, Syed Waqar Ali, Chen, Gong, Xie, Shangzhen
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-04-2024
Subjects:
Critical heat flux
Heat transfer enhancement
Hybrid strategy
Micro-nano structures
Pool boiling
Heat transfer enhancement
Micro-nano structures
Critical heat flux
Pool boiling
Hybrid strategy
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Summary:Boiling two-phase transition is considered to be the ultimate effective cooling strategy for the next generation of high-power devices in the near future in various application scenarios, such as power electronics, radar systems, and computer data centers. The liquid-solid interface plays a crucial role in the boiling phase change and the bubble evolvement. This study proposes a novel architecture of micro-nano structures using a unique hybrid dividing zone array, which can not only enhance the onset of nucleate boiling (ONB) and dramatically elevate the heat transfer coefficient (HTC), but also accelerate liquid replenishment, pushing the critical heat flux (CHF) to a much higher level. This is achieved through a superhydrophilic liquid storage zone that provides timely and continuous liquid supplementation for boiling phase change during the drying out period of the most copper surface. Compared to the plain surface copper sample, the proposed hybrid structured sample achieves about 5–7 °C earlier of ONB, up to 293% enhancement of the maximum HTC, and up to 242% improvement of CHF. Overall, this study demonstrates an effective surface enhancement approach that significantly and comprehensively improve boiling heat transfer performance, making it highly promising for cooling high-power applications. •Hybrid micro-nanostructures were constructed using a unique hybrid dividing zone array.•5–7 °C earlier of onset of nucleate boiling was achieved.•Up to 293% enhancement of the maximum heat transfer coefficient was accomplished.•Up to 242% improvement of critical heat flux was realized.•Stable and continuous boiling was sustained when large bubble fully covering heating surface.
ISSN:0735-1933
1879-0178
DOI:10.1016/j.icheatmasstransfer.2024.107345