A Review of Icephobic Coating Performances Over the Last Decade

Abstract

Current in-flight aircraft anti-icing and de-icing systems rely on active methods such equally oestrus for ice mitigation, which tends to reduce the operating efficiency of the shipping. Significant enquiry is currently ongoing to develop anti-icing coatings for passive ice removal from aircraft surfaces. Although significant blanket advances accept been accomplished in reducing ice adhesion and accretion, the majority of the developed prototypes cannot survive the harsh operating environments of an shipping. Therefore, the goal of this work was to develop a blanket with significant ice adhesion reduction and of sufficiently high durability to withstand typical aerospace operating weather (with the exception of atmospheric condition at the wing leading edge areas). Low ice adhesion topcoats and clear coats have been developed based on qualified exterior aerospace coatings, and ice adhesion tests showed a decrease of upwards to 95% in the ice adhesion force as compared to control coatings. These coatings are also as durable every bit current polyurethane aerospace topcoats. For example, the coatings did non sustain any harm for upwardly to 30 min in a rain erosion test conducted at typical rain impact speeds to approximate real flight conditions. In addition, ice adhesion tests performed on degraded coatings (i,700 h of QUV Accelerated Weathering Examination, UVB-313 nm lamp) showed that the ice release properties were retained.

Keywords

• Aerospace
• Coating
• Durability
• Durable
• Ice adhesion
• Ice release

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Acknowledgements

The authors acknowledge Ed Rakiewicz, Mike Mayo, Michael Zalich, Scott Moravek, and Emily Chunderlik of PPG Coatings Innovation Center, Allison Park, PA for their contributions to this work.

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Affiliations

1. PPG Aerospace Research and Technology Center, Burbank, CA, Usa

   Guangliang Tang, Yong Han Yeong & Mikhail Khudiakov

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Correspondence to Mikhail Khudiakov .

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Tang, G., Yeong, Y.H., Khudiakov, M. (2018). Ice Release Coatings of Loftier Immovability for Aerospace Applications. In: Wohl, C., Berry, D. (eds) Contamination Mitigating Polymeric Coatings for Extreme Environments. Advances in Polymer Science, vol 284. Springer, Cham. https://doi.org/10.1007/12_2017_39

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• DOI : https://doi.org/ten.1007/12_2017_39

• Published: 06 Jan 2018

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