Drag reduction properties of superhydrophobic mesh pipes

Nicasio Geraldi; Linzi Dodd; Ben Xu; Gary Wells; David Wood; Michael Newton; Glen McHale

doi:10.1088/2051-672X/aa793b

Drag reduction properties of superhydrophobic mesh pipes

Nicasio Geraldi, Linzi Dodd, Ben Xu, Gary Wells, David Wood, Michael Newton, Glen McHale

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Abstract

Even with the recent extensive study into superhydrophobic surfaces, the fabrication of such surfaces on the inside walls of a pipe remains challenging. In this work we report a convenient bi-layered pipe design using a thin superhydrophobic metallic mesh formed into a tube, supported inside another pipe. A flow system was constructed to test the fabricated bi-layer pipeline, which allowed for different constant flow rates of water to be passed through the pipe, whilst the differential pressure was measured, from which the drag coefficient (ƒ) and Reynolds numbers (Re) were calculated. Expected values of ƒ were found for smooth glass pipes for the Reynolds number (Re) range 750–10 000, in both the laminar and part of the turbulent regimes. Flow through plain meshes without the superhydrophobic coating were also measured over a similar range (750

Original language	English
Pages (from-to)	34001
Journal	Surface Topography: Metrology and Properties
Volume	5
DOIs	https://doi.org/10.1088/2051-672X/aa793b
Publication status	Published - 4 Jul 2017

Keywords

drag reduction
flow
superhydrophobicity
mesh
pipes
internal flow

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10.1088/2051-672X/aa793bLicence: CC BY

Geraldi et al - Drag reduction properties of superhydrophobic mesh pipesFinal published version, 983 KBLicence: CC BY

https://doi.org/10.1088/2051-672X/aa793bLicence: CC BY

Cite this

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title = "Drag reduction properties of superhydrophobic mesh pipes",

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AU - Geraldi, Nicasio

AU - Dodd, Linzi

AU - Xu, Ben

AU - Wells, Gary

AU - Wood, David

AU - Newton, Michael

AU - McHale, Glen

PY - 2017/7/4

Y1 - 2017/7/4

N2 - Even with the recent extensive study into superhydrophobic surfaces, the fabrication of such surfaces on the inside walls of a pipe remains challenging. In this work we report a convenient bi-layered pipe design using a thin superhydrophobic metallic mesh formed into a tube, supported inside another pipe. A flow system was constructed to test the fabricated bi-layer pipeline, which allowed for different constant flow rates of water to be passed through the pipe, whilst the differential pressure was measured, from which the drag coefficient (ƒ) and Reynolds numbers (Re) were calculated. Expected values of ƒ were found for smooth glass pipes for the Reynolds number (Re) range 750–10 000, in both the laminar and part of the turbulent regimes. Flow through plain meshes without the superhydrophobic coating were also measured over a similar range (750

AB - Even with the recent extensive study into superhydrophobic surfaces, the fabrication of such surfaces on the inside walls of a pipe remains challenging. In this work we report a convenient bi-layered pipe design using a thin superhydrophobic metallic mesh formed into a tube, supported inside another pipe. A flow system was constructed to test the fabricated bi-layer pipeline, which allowed for different constant flow rates of water to be passed through the pipe, whilst the differential pressure was measured, from which the drag coefficient (ƒ) and Reynolds numbers (Re) were calculated. Expected values of ƒ were found for smooth glass pipes for the Reynolds number (Re) range 750–10 000, in both the laminar and part of the turbulent regimes. Flow through plain meshes without the superhydrophobic coating were also measured over a similar range (750

KW - drag reduction

KW - flow

KW - superhydrophobicity

KW - mesh

KW - pipes

KW - internal flow

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DO - 10.1088/2051-672X/aa793b

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Drag reduction properties of superhydrophobic mesh pipes

Abstract

Keywords

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