Three-dimensional flow around and through a porous screen

We investigate the three-dimensional flow around and through a porous screen for various porosities at high Reynolds number Re = O(10000). Historically, the study of this problem was focused on two-dimensional cases and for a screen spanning completely or partially a channel. Since many recent probl...

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Bibliographic Details
Published inarXiv.org
Main Authors Marchand, Olivier C, Ramananarivo, Sophie, Duprat, Camille, Josserand, Christophe
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 08.11.2023
Subjects
Aerodynamic drag
Aerodynamic forces
Air flow
Angle of attack
Diameters
Drag
Drag coefficients
Flat plates
Fluid flow
Free flow
Harvesters
High Reynolds number
Laminar flow
Physics - Fluid Dynamics
Pressure distribution
Reynolds number
Screens
Shape effects
Three dimensional flow
Three dimensional models
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Summary:We investigate the three-dimensional flow around and through a porous screen for various porosities at high Reynolds number Re = O(10000). Historically, the study of this problem was focused on two-dimensional cases and for a screen spanning completely or partially a channel. Since many recent problems have involved a porous object in a three-dimensional free flow, we present a three-dimensional model for porous screens, initially based on Koo & James (1973) and Steiros & Hultmark (2018), accounting for viscous effects at the vicinity of the screen, from which we can derive velocities, pressure distribution as well as aerodynamic forces. We then characterize experimentally the aerodynamic drag coefficient for a porous square screen, composed of fibers, immersed in a laminar air flow with different angles of attack. We test various fiber diameters to explore the effect of the space between the pores on the drag force. The drag prediction from the model is in good agreement with our experimental results. Our theoretical and experimental results suggest that for high solidity, a homogeneous porous screens composed of fibers can have a higher drag coefficient than a flat plate with the same dimensions. We also show that local viscous effects are important: at the same solidity and with the same air flow, the drag coefficient strongly depends on the Reynolds number based on the fiber diameter. The model, taking into account three-dimensional effects and the shape of the porous screen, may have many applications including the prediction of water collection efficiency for fog harvesters.
ISSN:2331-8422
DOI:10.48550/arxiv.2303.00711