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Gap-modulated dynamics of flexible plates

The effect of single perforations and their location on the drag and reconfiguration of flexible plates was explored through laboratory experiments and direct numerical simulations. The plates were subjected to uniform flows with negligible turbulence, and the perforations had a square cross-section...

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Published in:	Journal of fluid mechanics 2023-10, Vol.974, Article A12
Main Authors:	Cheng, Shyuan, Olivieri, Stefano, Rosti, Marco E., Chamorro, Leonardo P.
Format:	Article
Language:	English
Subjects:	Aerodynamic forces Deformation Direct numerical simulation Drag Effective porosity Effective velocity Flexible structures Flow velocity Fluid flow Investigations JFM Papers Laboratory experimentation Mathematical models Perforated plates Porosity Reconfiguration Reynolds number Turbulence Uniform flow Velocity Velocity distribution Velocity profiles
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container_title	Journal of fluid mechanics
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creator	Cheng, Shyuan Olivieri, Stefano Rosti, Marco E. Chamorro, Leonardo P.
description	The effect of single perforations and their location on the drag and reconfiguration of flexible plates was explored through laboratory experiments and direct numerical simulations. The plates were subjected to uniform flows with negligible turbulence, and the perforations had a square cross-section resulting in a low porosity ratio of $\gamma \approx 0.028$. Rigid plates with and without perforations and flexible plates without perforations served as the baseline cases. The perforated plates exhibited distinct jets through the openings in the wake, significantly impacting the aerodynamic force and plate deformation. The velocity and position of the centre jet velocity in relation to downwind distance were influenced by both the incoming flow and the location of the perforations. The centre jet velocity profiles were normalized using an effective velocity and corrected perforation half-width, revealing their dependence on these factors. A simple first-order formulation was developed to predict the change in drag for various perforated plates under a wide range of incoming velocities. This formulation was supported by numerical simulations across a wider range of Cauchy number to confirm the proposed model and separate the effect of the Cauchy and Reynolds numbers. The results of this study may inform the design of flexible structures, define effective porosity and serve as an initial step towards modelling the complex interaction between flow and structures with low porosity.
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The plates were subjected to uniform flows with negligible turbulence, and the perforations had a square cross-section resulting in a low porosity ratio of $\gamma \approx 0.028$. Rigid plates with and without perforations and flexible plates without perforations served as the baseline cases. The perforated plates exhibited distinct jets through the openings in the wake, significantly impacting the aerodynamic force and plate deformation. The velocity and position of the centre jet velocity in relation to downwind distance were influenced by both the incoming flow and the location of the perforations. The centre jet velocity profiles were normalized using an effective velocity and corrected perforation half-width, revealing their dependence on these factors. A simple first-order formulation was developed to predict the change in drag for various perforated plates under a wide range of incoming velocities. This formulation was supported by numerical simulations across a wider range of Cauchy number to confirm the proposed model and separate the effect of the Cauchy and Reynolds numbers. The results of this study may inform the design of flexible structures, define effective porosity and serve as an initial step towards modelling the complex interaction between flow and structures with low porosity.</description><identifier>ISSN: 0022-1120</identifier><identifier>EISSN: 1469-7645</identifier><identifier>DOI: 10.1017/jfm.2023.806</identifier><language>eng</language><publisher>Cambridge, UK: Cambridge University Press</publisher><subject>Aerodynamic forces ; Deformation ; Direct numerical simulation ; Drag ; Effective porosity ; Effective velocity ; Flexible structures ; Flow velocity ; Fluid flow ; Investigations ; JFM Papers ; Laboratory experimentation ; Mathematical models ; Perforated plates ; Porosity ; Reconfiguration ; Reynolds number ; Turbulence ; Uniform flow ; Velocity ; Velocity distribution ; Velocity profiles</subject><ispartof>Journal of fluid mechanics, 2023-10, Vol.974, Article A12</ispartof><rights>The Author(s), 2023. 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Fluid Mech</addtitle><date>2023-10-25</date><risdate>2023</risdate><volume>974</volume><artnum>A12</artnum><issn>0022-1120</issn><eissn>1469-7645</eissn><abstract>The effect of single perforations and their location on the drag and reconfiguration of flexible plates was explored through laboratory experiments and direct numerical simulations. The plates were subjected to uniform flows with negligible turbulence, and the perforations had a square cross-section resulting in a low porosity ratio of $\gamma \approx 0.028$. Rigid plates with and without perforations and flexible plates without perforations served as the baseline cases. The perforated plates exhibited distinct jets through the openings in the wake, significantly impacting the aerodynamic force and plate deformation. The velocity and position of the centre jet velocity in relation to downwind distance were influenced by both the incoming flow and the location of the perforations. The centre jet velocity profiles were normalized using an effective velocity and corrected perforation half-width, revealing their dependence on these factors. A simple first-order formulation was developed to predict the change in drag for various perforated plates under a wide range of incoming velocities. This formulation was supported by numerical simulations across a wider range of Cauchy number to confirm the proposed model and separate the effect of the Cauchy and Reynolds numbers. 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source	Cambridge Journals Online
subjects	Aerodynamic forces Deformation Direct numerical simulation Drag Effective porosity Effective velocity Flexible structures Flow velocity Fluid flow Investigations JFM Papers Laboratory experimentation Mathematical models Perforated plates Porosity Reconfiguration Reynolds number Turbulence Uniform flow Velocity Velocity distribution Velocity profiles
title	Gap-modulated dynamics of flexible plates
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