Numerical simulation of superhydrophobic surface's flow field characteristic and drag reduction rule

Qiao Gao Huang; Guang Pan; Bao Wei Song; Zhan Yi Liu; Hai Bao Hu

doi:10.3969/j.issn.1007-7294.2014.h1.001

Numerical simulation of superhydrophobic surface's flow field characteristic and drag reduction rule

Qiao Gao Huang, Guang Pan, Bao Wei Song, Zhan Yi Liu, Hai Bao Hu

School of Marine Science and Technology

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Based on the numerical simulation model of superhydrophobic surfaces flow field, the flow field characteristics and the drag reduction law are studied with superhydrophobic surfaces with the microcosmic topography in turbulence. The results show that the prominent slip flows on the gas-liquid interface and the conjugated streamwise vortex near the microcosmic topography of superhydrophobic surfaces appear. These factors inhibit the turbulent fluctuation, reduce Reynolds stress and energy loss together, so that the superhydrophobic surfaces generate drag reduction effect; the drag reduction of superhydrophobic surfaces increases with the increase of the free shear area ratios and increases with the increase of the topography periods. There is a qualitative relationship between the drag reduction and the slip, namely the greater slip, the better drag reduction effect.

Original language	English
Pages (from-to)	1-11
Number of pages	11
Journal	Chuan Bo Li Xue/Journal of Ship Mechanics
Volume	18
Issue number	1-2
DOIs	https://doi.org/10.3969/j.issn.1007-7294.2014.h1.001
State	Published - Feb 2014

Keywords

Drag reduction law
Flow field structure
Microcosmic topography
Slip
Super-hydrophobic
Superhydrophobic surfaces

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10.3969/j.issn.1007-7294.2014.h1.001

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title = "Numerical simulation of superhydrophobic surface's flow field characteristic and drag reduction rule",

abstract = "Based on the numerical simulation model of superhydrophobic surfaces flow field, the flow field characteristics and the drag reduction law are studied with superhydrophobic surfaces with the microcosmic topography in turbulence. The results show that the prominent slip flows on the gas-liquid interface and the conjugated streamwise vortex near the microcosmic topography of superhydrophobic surfaces appear. These factors inhibit the turbulent fluctuation, reduce Reynolds stress and energy loss together, so that the superhydrophobic surfaces generate drag reduction effect; the drag reduction of superhydrophobic surfaces increases with the increase of the free shear area ratios and increases with the increase of the topography periods. There is a qualitative relationship between the drag reduction and the slip, namely the greater slip, the better drag reduction effect.",

keywords = "Drag reduction law, Flow field structure, Microcosmic topography, Slip, Super-hydrophobic, Superhydrophobic surfaces",

author = "Huang, {Qiao Gao} and Guang Pan and Song, {Bao Wei} and Liu, {Zhan Yi} and Hu, {Hai Bao}",

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AU - Huang, Qiao Gao

AU - Pan, Guang

AU - Song, Bao Wei

AU - Liu, Zhan Yi

AU - Hu, Hai Bao

PY - 2014/2

Y1 - 2014/2

N2 - Based on the numerical simulation model of superhydrophobic surfaces flow field, the flow field characteristics and the drag reduction law are studied with superhydrophobic surfaces with the microcosmic topography in turbulence. The results show that the prominent slip flows on the gas-liquid interface and the conjugated streamwise vortex near the microcosmic topography of superhydrophobic surfaces appear. These factors inhibit the turbulent fluctuation, reduce Reynolds stress and energy loss together, so that the superhydrophobic surfaces generate drag reduction effect; the drag reduction of superhydrophobic surfaces increases with the increase of the free shear area ratios and increases with the increase of the topography periods. There is a qualitative relationship between the drag reduction and the slip, namely the greater slip, the better drag reduction effect.

AB - Based on the numerical simulation model of superhydrophobic surfaces flow field, the flow field characteristics and the drag reduction law are studied with superhydrophobic surfaces with the microcosmic topography in turbulence. The results show that the prominent slip flows on the gas-liquid interface and the conjugated streamwise vortex near the microcosmic topography of superhydrophobic surfaces appear. These factors inhibit the turbulent fluctuation, reduce Reynolds stress and energy loss together, so that the superhydrophobic surfaces generate drag reduction effect; the drag reduction of superhydrophobic surfaces increases with the increase of the free shear area ratios and increases with the increase of the topography periods. There is a qualitative relationship between the drag reduction and the slip, namely the greater slip, the better drag reduction effect.

KW - Drag reduction law

KW - Flow field structure

KW - Microcosmic topography

KW - Slip

KW - Super-hydrophobic

KW - Superhydrophobic surfaces

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Numerical simulation of superhydrophobic surface's flow field characteristic and drag reduction rule

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Keywords

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