<i>In situ</i> monitor of superhydrophobic surface degradation to predict its drag reduction in turbulent flow

Zhang, Linsheng; Crick, Colin R.; Poole, Robert J.

doi:10.1063/5.0160007

Applied Physics Letters

2023

DOI: 10.1063/5.0160007

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In situ monitor of superhydrophobic surface degradation to predict its drag reduction in turbulent flow

Linsheng Zhang,

Colin R. Crick,

Robert J. Poole

Abstract: In situ monitoring is the most insightful technique to examine superhydrophobic surface degradation as it provides real-time information on the liquid–solid interface in a continuous, noninvasive manner. Using reflecting-pixel intensity, we introduced a simple method to characterize in situ the air-plastron over a superhydrophobic surface in a turbulent channel flow. Prior to the turbulent experiments, a no-flow hydrostatic test was carried out to determine a critical absolute pressure under which the surfaces… Show more

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Cited by 3 publications

References 34 publications

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Polymer-dominant drag reduction in turbulent channel flow over a superhydrophobic surface

Zhang,

Garcia-Gonzalez,

Crick

et al. 2023

Physics of Fluids

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In this study, we focused on the integration of a flexible polymer (polyacrylamide) and a (randomly patterned) superhydrophobic surface in a large-scale turbulent channel flow rig to investigate their combined drag reduction effectiveness. Experimental results indicate that, prior to degradation, polyacrylamide (at a 100-ppm concentration) and superhydrophobic surfaces individually manifest drag reductions of 35% and 7%, respectively. However, when combined, the influence of polymer additives remained consistent, with the introduction of superhydrophobic surfaces yielding negligible differences. A clear predominance was evidenced in our facility looking at realistic pressure for applications, with polymer additives overshadowing the impact of superhydrophobic surfaces.

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Polymer-dominant drag reduction in turbulent channel flow over a superhydrophobic surface

Zhang,

Garcia-Gonzalez,

Crick

et al. 2023

Physics of Fluids

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Impact of sandpaper grit size on drag reduction and plastron stability of super-hydrophobic surface in turbulent flows

Mohammadshahi,

O'Coin,

Ling

2024

Physics of Fluids

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In this work, we experimentally investigated the impact of surface roughness on drag reduction as well as the plastron stability of superhydrophobic surfaces (SHSs) in turbulent flows. A series of SHSs were fabricated by spraying hydrophobic nanoparticles on sandpapers. By changing the grit size of sandpapers from 240 to 1500, the root mean square roughness height (krms) of the SHSs varied from 4 to 14 μm. The experiments were performed in a turbulent channel flow facility, where the mean flow speed (Um) varied from 0.5 to 4.4 m/s, and the Reynolds number (Rem) based on Um and channel height changed from 3400 to 26 400. The drag reduction by SHSs was measured based on pressure drops in the fully developed flow region. The plastron status and gas fraction (φg) were simultaneously monitored by reflected-light microscopy. Our results showed a strong correlation between drag reduction and krms+ = krms/δv, where δv is the viscous length scale. For krms+ < 1, drag reduction was independent of krms+. A maximum 47% drag reduction was observed. For 1 < krms+ < 2, less drag reduction was observed due to the roughness effect. And for krms+ > 2, the SHSs caused an increase in drag. Furthermore, we found that surface roughness influenced the trend of plastron depletion in turbulent flows. As increasing Rem, φg reduced gradually for SHSs with large krms, but reduced rapidly and maintained as a constant for SHSs with small krms. Finally, we found that as increasing Rem, the slip length of SHS reduced, although φg was nearly a constant.

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Superhydrophobic surfaces: Fundamentals, manufacture, and applications

Wu,

Chu,

Orejon

et al. 2024

Applied Physics Letters

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In situ monitor of superhydrophobic surface degradation to predict its drag reduction in turbulent flow

Cited by 3 publications

References 34 publications

Polymer-dominant drag reduction in turbulent channel flow over a superhydrophobic surface

Polymer-dominant drag reduction in turbulent channel flow over a superhydrophobic surface

Impact of sandpaper grit size on drag reduction and plastron stability of super-hydrophobic surface in turbulent flows

Superhydrophobic surfaces: Fundamentals, manufacture, and applications

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