Experimental investigations of frost release by hydrophilic surfaces

Frost formation occurs when water vapor in the surrounding air comes into contact with cold surfaces through heat and mass transfer. It is usually an undesirable phenomenon in most refrigeration and cryogenic systems. A few studies have shown that changing the surface energy, such as increasing the...

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Bibliographic Details
Published in:Frontiers in Energy 2010-12, Vol.4 (4), p.475-487
Main Authors: LIU, Zhongliang, HUANG, Lingyan, GOU, Yujun, LIU, Yaomin
Format: Article
Language:English
Subjects:
Air temperature
Coating
Cold
Cold surfaces
Data acquisition systems
Deposition
Education
Energy
Energy consumption
Energy Systems
Frost
frost formation
heat and mass transfer
Heat exchangers
Heat transfer
High temperature
Humidity
Hydrophilic surfaces
hydrophilicity
Ice
Laboratories
Mass transfer
Mathematical analysis
Mathematical models
Paints
Polymers
Protective coatings
Refrigeration
Research Article
Studies
Temperature
Water vapor
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Summary:Frost formation occurs when water vapor in the surrounding air comes into contact with cold surfaces through heat and mass transfer. It is usually an undesirable phenomenon in most refrigeration and cryogenic systems. A few studies have shown that changing the surface energy, such as increasing the surface hydrophilicity or hydrophobicity, has significant effects on frost growth. In this paper, a kind of hydrophilic polymer paint is formulated to counteract frost deposition on cold surfaces. The coated surface can retard frost formation up to three hours under low plate temperatures (-15.3°C) and high air humidity (72%). To test the antifrosting performance of the hydrophilic paint under more practical conditions, it is applied to a fin-and-tube heat exchanger and a domestic refrigerator at a coating thickness of 30 μm. Comparisons of frost deposition, pressure drops, and outlet temperatures are made between uncoated and coated heat exchangers. Under conditions of high air temperature (2.2°C) and relative high air humidity (90%), the paint prolongs the defrosting interval from 80 to 137 min. Experimental observations also show that the coated hydrophilic fins are free of frost deposition during the entire course of the test and that the coating has no significant additional thermal resistance.
ISSN:2095-1701
1673-7393
2095-1698
1673-7504
DOI:10.1007/s11708-010-0114-x