Fabrication of Anti-Icing Surface Structures on Aluminum Alloy for Aerospace Applications

Abhijit Cholkar; Ronan McCann; David Kinahan; Dermot Brabazon

doi:10.4028/p-19ai96

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 926Fabrication of Anti-Icing Surface Structures on...

Fabrication of Anti-Icing Surface Structures on Aluminum Alloy for Aerospace Applications

Abstract:

Icing, the phenomenon of the formation and accumulation of ice or frost on a surface due to the solidification of water droplets at low temperature can be undesirable in many applications. Surface icing can lead to increased energy consumption in aerospace and automotive applications due to increased aerodynamic drag. Ice formation can also present a mechanical and electrical safety hazard, and as such significant work has been done to produce surfaces with anti-icing properties through surface modification to decrease ice formation and adhesion to surfaces. One route toward the generation of anti-icing surfaces is through laser surface processing. Laser micro/nanostructuring of surfaces has advanced greatly in recent years due to advancements in laser source technology and reduction in capital costs for ultrafast femtosecond pulsed machining lasers. Laser material processing offers a rapid, scalable, and non-contact method for fabricating large area anti-icing surfaces. In this work, the production of anti-icing surfaces using femtosecond laser micro-and nanostructuring on aluminum alloy 7075 surfaces was examined. With an aim to optimize the anti-icing properties of the substrates, laser parameters such as pulse energy, repetition rate and beam scanning speed were varied to produce highly defined microstructures on the aluminum surface.Various functional properties such as hydrophobicity and surface roughness are examined.

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Periodical:

Key Engineering Materials (Volume 926)

Pages:

1643-1649

DOI:

https://doi.org/10.4028/p-19ai96

Citation:

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Online since:

July 2022

Authors:

Abhijit Cholkar*, Ronan McCann, David Kinahan, Dermot Brabazon

Keywords:

Aluminum, Anti-Icing, Laser Processing, Surface Structuring, Ultrafast Laser Processing

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Creative Commons CC BY 4.0

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* - Corresponding Author

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