Design factors for reducing ice adhesion

The purpose of this study was to investigate the relationships between a type of engineering material and the ice adhesion strength while in direct application in icing conditions. Ice adhesion tests were conducted on various materials with different surface conditions. There is an identified need f...

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Bibliographic Details
Published in:Journal of adhesion science and technology Vol. 31; no. 21; pp. 2271 - 2284
Main Authors: Fillion, Ryan M., Riahi, A. R., Edrisy, A.
Format: Journal Article
Language:English
Published: Utrecht Taylor & Francis 02-11-2017
Taylor & Francis Ltd
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Summary:The purpose of this study was to investigate the relationships between a type of engineering material and the ice adhesion strength while in direct application in icing conditions. Ice adhesion tests were conducted on various materials with different surface conditions. There is an identified need for systematic studies on the effects of varying surface conditions with well-characterized roughness and accurate adhesion measurement. This information is key in understanding the adhering behaviour of ice which is a necessary prerequisite for modelling the behaviour of ice adhesion to other surfaces and for icing prevention. Results show that the type of material will determine, in large, the strength of the ice adhesion between surfaces with similar roughness characteristics and the receding contact angle of water can be used as a predictor of relative ice adhesion. The adhesive strength of ice can be increased or decreased dramatically by means of adjusting the surface roughness with a uniform process. Each material tested exhibits a similar linear relationship. There was a stark contrast in the ice adhesion between the varying materials despite very similar polished surface conditions and static water contact angles. Ice bonded to the glass surface with an adhesion of 1562 ± 113 kPa, and to aluminum at 1039 ± 117 kPa, and stainless steel at 1022 ± 115 kPa, and finally Teflon at only 33 ± 52 kPa and during 80% of trials the ice/substrate interface was broken with no measured adhesion. The information gathered can be used to improve designs for a number of devices needed in cold weather climates.
ISSN:0169-4243
1568-5616
DOI:10.1080/01694243.2017.1297588