Air-propelled, herringbone-textured platelets

Hélène De Maleprade; Dan Soto; David Quéré; E. John Hinch; Tobias Baier; Maximilian T. Schür; Steffen Hardt

doi:10.1103/PhysRevFluids.3.104101

Air-propelled, herringbone-textured platelets

Hélène De Maleprade
, Dan Soto
, David Quéré
, E. John Hinch
, Tobias Baier
, Maximilian T. Schür
, Steffen Hardt

École Polytechnique

CNRS
Laboratoire d'Hydrodynamique de l'Ecole Polytechnique
University of Cambridge
Technische Universität Darmstadt

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Solids can be levitated by actively nourishing an air cushion beneath them, using air blown through a porous substrate. It has recently been demonstrated that introducing asymmetry in the airflow close to a hovercraft can lead to its propulsion by viscous entrainment. In this work, we focus on the major consequence of a simple modification in the set-up: instead of engraving the texture on the substrate as in previous works, we directly carve it into the hovercraft. Provided that air-flux is strong enough, propulsion at any Reynolds number is observed. However, motion happens in the direction opposite to the viscous scenario. To understand experimental observations, an analytical model is proposed to account for the force of propulsion and the pressure needed for levitation, emphasizing asymptotic situations at low and high Reynolds numbers, further confirmed by numerical simulations.

langue originale	Anglais
Numéro d'article	104101
journal	Physical Review Fluids
Volume	3
Numéro de publication	10
Les DOIs	https://doi.org/10.1103/PhysRevFluids.3.104101
état	Publié - 1 oct. 2018

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10.1103/PhysRevFluids.3.104101

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title = "Air-propelled, herringbone-textured platelets",

abstract = "Solids can be levitated by actively nourishing an air cushion beneath them, using air blown through a porous substrate. It has recently been demonstrated that introducing asymmetry in the airflow close to a hovercraft can lead to its propulsion by viscous entrainment. In this work, we focus on the major consequence of a simple modification in the set-up: instead of engraving the texture on the substrate as in previous works, we directly carve it into the hovercraft. Provided that air-flux is strong enough, propulsion at any Reynolds number is observed. However, motion happens in the direction opposite to the viscous scenario. To understand experimental observations, an analytical model is proposed to account for the force of propulsion and the pressure needed for levitation, emphasizing asymptotic situations at low and high Reynolds numbers, further confirmed by numerical simulations.",

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doi = "10.1103/PhysRevFluids.3.104101",

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AU - De Maleprade, Hélène

AU - Soto, Dan

AU - Quéré, David

AU - Hinch, E. John

AU - Baier, Tobias

AU - Schür, Maximilian T.

AU - Hardt, Steffen

PY - 2018/10/1

Y1 - 2018/10/1

N2 - Solids can be levitated by actively nourishing an air cushion beneath them, using air blown through a porous substrate. It has recently been demonstrated that introducing asymmetry in the airflow close to a hovercraft can lead to its propulsion by viscous entrainment. In this work, we focus on the major consequence of a simple modification in the set-up: instead of engraving the texture on the substrate as in previous works, we directly carve it into the hovercraft. Provided that air-flux is strong enough, propulsion at any Reynolds number is observed. However, motion happens in the direction opposite to the viscous scenario. To understand experimental observations, an analytical model is proposed to account for the force of propulsion and the pressure needed for levitation, emphasizing asymptotic situations at low and high Reynolds numbers, further confirmed by numerical simulations.

AB - Solids can be levitated by actively nourishing an air cushion beneath them, using air blown through a porous substrate. It has recently been demonstrated that introducing asymmetry in the airflow close to a hovercraft can lead to its propulsion by viscous entrainment. In this work, we focus on the major consequence of a simple modification in the set-up: instead of engraving the texture on the substrate as in previous works, we directly carve it into the hovercraft. Provided that air-flux is strong enough, propulsion at any Reynolds number is observed. However, motion happens in the direction opposite to the viscous scenario. To understand experimental observations, an analytical model is proposed to account for the force of propulsion and the pressure needed for levitation, emphasizing asymptotic situations at low and high Reynolds numbers, further confirmed by numerical simulations.

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DO - 10.1103/PhysRevFluids.3.104101

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JO - Physical Review Fluids

JF - Physical Review Fluids

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ER -

Air-propelled, herringbone-textured platelets

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