Flow characterizations and drag reduction on the hydrophobic surface with a full covering gas film

P. Du; D. Song; F. Ren; Q. Xue; H. Hu

doi:10.18869/acadpub.jafm.73.239.26462

Flow characterizations and drag reduction on the hydrophobic surface with a full covering gas film

P. Du, D. Song, F. Ren, Q. Xue, H. Hu

School of Marine Science and Technology

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

5 Scopus citations

Abstract

Characteristics of the flow on hydrophobic surfaces with a full covering gas film are investigated using the single-component multi-phase (SCMP) Lattice Boltzmann (LB) simulation. By adopting the Shan-Doolen force model and incorporating equations of state (EOS) of real fluids, large density ratios are achieved. The height of the air film maintained is observed to increase with the improvement of the surface hydrophobicity. In the laminar flow, the state of the gas-liquid interface is not influenced by the Reynolds number (Re). On the gas layer, the slip effect and wall shear stress reduction are sustained continuously regardless of their positions (on the space or on the micro-structure). Even so, decreasing the solid area fraction is also significant to enhance the slip effect and decrease the wall shear stress on hydrophobic surfaces.

Original language	English
Pages (from-to)	491-498
Number of pages	8
Journal	Journal of Applied Fluid Mechanics
Volume	10
Issue number	2
DOIs	https://doi.org/10.18869/acadpub.jafm.73.239.26462
State	Published - 2017

Keywords

Drag reduction
Gas film
Hydrophobic surface
Lattice Boltzmann method
Slip

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10.18869/acadpub.jafm.73.239.26462

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title = "Flow characterizations and drag reduction on the hydrophobic surface with a full covering gas film",

abstract = "Characteristics of the flow on hydrophobic surfaces with a full covering gas film are investigated using the single-component multi-phase (SCMP) Lattice Boltzmann (LB) simulation. By adopting the Shan-Doolen force model and incorporating equations of state (EOS) of real fluids, large density ratios are achieved. The height of the air film maintained is observed to increase with the improvement of the surface hydrophobicity. In the laminar flow, the state of the gas-liquid interface is not influenced by the Reynolds number (Re). On the gas layer, the slip effect and wall shear stress reduction are sustained continuously regardless of their positions (on the space or on the micro-structure). Even so, decreasing the solid area fraction is also significant to enhance the slip effect and decrease the wall shear stress on hydrophobic surfaces.",

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T1 - Flow characterizations and drag reduction on the hydrophobic surface with a full covering gas film

AU - Du, P.

AU - Song, D.

AU - Ren, F.

AU - Xue, Q.

AU - Hu, H.

PY - 2017

Y1 - 2017

N2 - Characteristics of the flow on hydrophobic surfaces with a full covering gas film are investigated using the single-component multi-phase (SCMP) Lattice Boltzmann (LB) simulation. By adopting the Shan-Doolen force model and incorporating equations of state (EOS) of real fluids, large density ratios are achieved. The height of the air film maintained is observed to increase with the improvement of the surface hydrophobicity. In the laminar flow, the state of the gas-liquid interface is not influenced by the Reynolds number (Re). On the gas layer, the slip effect and wall shear stress reduction are sustained continuously regardless of their positions (on the space or on the micro-structure). Even so, decreasing the solid area fraction is also significant to enhance the slip effect and decrease the wall shear stress on hydrophobic surfaces.

AB - Characteristics of the flow on hydrophobic surfaces with a full covering gas film are investigated using the single-component multi-phase (SCMP) Lattice Boltzmann (LB) simulation. By adopting the Shan-Doolen force model and incorporating equations of state (EOS) of real fluids, large density ratios are achieved. The height of the air film maintained is observed to increase with the improvement of the surface hydrophobicity. In the laminar flow, the state of the gas-liquid interface is not influenced by the Reynolds number (Re). On the gas layer, the slip effect and wall shear stress reduction are sustained continuously regardless of their positions (on the space or on the micro-structure). Even so, decreasing the solid area fraction is also significant to enhance the slip effect and decrease the wall shear stress on hydrophobic surfaces.

KW - Drag reduction

KW - Gas film

KW - Hydrophobic surface

KW - Lattice Boltzmann method

KW - Slip

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DO - 10.18869/acadpub.jafm.73.239.26462

M3 - 文章

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SN - 1735-3572

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JO - Journal of Applied Fluid Mechanics

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IS - 2

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Flow characterizations and drag reduction on the hydrophobic surface with a full covering gas film

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Keywords

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