Evaluation of air layer behavior on patterned PTFE surfaces under underwater environment conditions

Evaluation of air layer behavior on patterned PTFE surfaces under underwater environment conditions

The ability to reduce the friction resistance between water and solid surface is one of the key functions of superhydrophobic surfaces. Reducing the frictional resistance between a solid surface and water is called drag reduction. This function is induced by the air layer formed at interface between...

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Bibliographic Details
Published in:Journal of mechanical science and technology Vol. 35; no. 2; pp. 679 - 687
Main Authors: Yoo, Kwang Jae, Moon, In Yong, Lee, Ho Won, Oh, Young-Seok, Kim, Se-Jong, Moon, Young Hoon, Kang, Seong-Hoon
Format: Journal Article
Language:English
Published: Seoul Korean Society of Mechanical Engineers 01-02-2021
Springer Nature B.V
대한기계학회
Subjects:
Control
Drag reduction
Dynamical Systems
Engineering
Friction reduction
Friction resistance
Grooves
Hydrophobic surfaces
Hydrophobicity
Hydrostatic pressure
Industrial and Production Engineering
Mechanical Engineering
Micrometers
Original Article
Pneumatics
Polytetrafluoroethylene
Solid surfaces
Sustainability
Underwater
Vibration
Water circulation
기계공학
Superhydrophobic
Hierarchical patterns
Drag reduction
Air layer
Friction resistance
Hot imprinting
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Summary:The ability to reduce the friction resistance between water and solid surface is one of the key functions of superhydrophobic surfaces. Reducing the frictional resistance between a solid surface and water is called drag reduction. This function is induced by the air layer formed at interface between the water and a superhydrophobic surface. The sustainability of the air layer is a key factor to induce stable drag reduction effect. Despite the importance of the air layers, only a few studies on the air layer sustainability have been reported. Therefore, in this study, various experiments on the air layer sustainability and drag reduction were carried out under the simulated underwater environment. Superhydrophobic PTFE surfaces with groove patterns having several hundred micrometers were applied in the experiments. As a result, it was possible to optimize groove pattern shape that can effectively maintain the air layer under hydrostatic pressure of 100 kPa. Furthermore, the effect of the groove patterns on the drag reduction was analyzed using water circulation system developed in this work.
ISSN:1738-494X
1976-3824
DOI:10.1007/s12206-021-0128-9