Extraordinary boiling enhancement through micro-chimney effects in gradient porous micromeshes for high-power applications

Extraordinary boiling enhancement through micro-chimney effects in gradient porous micromeshes for high-power applications

•Cost-effective gradient micromeshes are developed for holistic boiling enhancement.•Both high critical heat flux and heat transfer coefficient are demonstrated.•Extra gain compared with model prediction reveals new boiling enhancement mechanism.•Unique micro-chimney effect enables ever-faster bubbl...

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Bibliographic Details
Published in:Energy conversion and management Vol. 209; p. 112665
Main Authors: Zhang, Shiwei, Jiang, Xingchi, Li, Yuanjie, Chen, Gong, Sun, Yalong, Tang, Yong, Pan, Chin
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-04-2020
Elsevier Science Ltd
Subjects:
Boiling
Boiling heat transfer
Boiling water reactors
Concentrated photovoltaics
Concentration gradient
Critical heat flux
Gradient micromesh
Heat flux
Heat transfer
Heat transfer coefficients
Micro-chimney effect
Microchannels
Nuclear energy
Nucleate boiling
Performance enhancement
Photovoltaic cells
Photovoltaics
Porosity
Surface structure
System effectiveness
Thermal management
Gradient micromesh
Thermal management
Concentrated photovoltaics
Boiling heat transfer
Critical heat flux
Micro-chimney effect
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Summary:•Cost-effective gradient micromeshes are developed for holistic boiling enhancement.•Both high critical heat flux and heat transfer coefficient are demonstrated.•Extra gain compared with model prediction reveals new boiling enhancement mechanism.•Unique micro-chimney effect enables ever-faster bubble departure at small diameters.•Gradient micromesh boiling greatly improves concentrated photovoltaics performance. Boiling enhancement from engineering surfaces is of fundamental importance for efficiency enhancement of energy systems and effective thermal management of high-power electronics. The present study develops highly cost-effective and ultrascalable copper porous micromeshes with gradient porosity to further maximize the boiling performance holistically. A unique micro-chimney effect in the gradient meshes, enabling ever-faster bubble departure at small diameters, is revealed to prevail throughout the entire nucleate boiling. This robust surface structure presents an outstanding critical heat flux up to 2719 kW/m2 simultaneously with ultrahigh heat transfer coefficient of 261 kW/m2K, which is superior to the maxima achieved in most relevant literatures. The analysis of facilitated bubble dynamics and comparison with an analytical model demonstrate that the micro-chimney effect due to simple porosity modulation is another significant mechanism to further enhance boiling capacity. Finally, as an example of potential areas, the nucleate boiling of gradient micromeshes exhibits great advantage of cell performance enhancement in concentrated ratio and electrical efficiency of concentrated photovoltaics. This study promises a high-performance surface modification for more efficient phase-change devices, such as flow boiling microchannels, boiling water reactors, and other high-power thermal systems.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2020.112665