Frost spreading on microscale wettability/morphology patterned surfaces

[Display omitted] •Effects of wettability and morphology patterns on frost spreading.•Frost spreading at varying substrate temperature.•Demonstration of morphology patterned surface with anti-frosting performance.•A simple analytical model for describing frost spreading. Frost on a solid surface spr...

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Bibliographic Details
Published in:Applied thermal engineering 2017-07, Vol.121, p.136-145
Main Authors: Zhao, Yugang, Yang, Chun
Format: Article
Language:English
Subjects:
Frost resistance
Frost spreading
Hard surfacing
Ice
Ice bridging
Morphological patterns
Morphology
Photography
Resists
Spreading
Substrate temperature
Substrates
Velocity
Wettability
Wettability patterns
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Summary:[Display omitted] •Effects of wettability and morphology patterns on frost spreading.•Frost spreading at varying substrate temperature.•Demonstration of morphology patterned surface with anti-frosting performance.•A simple analytical model for describing frost spreading. Frost on a solid surface spreads essentially via building up ice bridges between condensed droplets. Modulation of condensate droplet distributions is thus an effective approach to control frost spreading. Here, we investigate the effects of both surface wettability and morphological patterns on the frost spreading velocity for various substrate surface temperatures. Our experimental results showed that the morphological patterned surfaces drastically retard frost spreading while the effect of the wettability patterned surfaces is not significant. The frost spreading velocity increases with decreasing substrate temperature on the smooth surfaces and the wettability patterned surfaces. The morphology patterned surface effectively resists frost spreading over a wide range of subcooled temperatures. A simple model is proposed to elaborate the effects of wettability, morphology, and temperature on the frost spreading velocity and the model is found to be in reasonable agreement with our experiments. Additionally, microphotography reveals ice bridging regimes in different cases. Our findings facilitate understanding of the frost spreading dynamics which can lead to the novel designs of frost-free surfaces.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2017.04.063