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Swimming freely near the ground leads to flow-mediated equilibrium altitudes

Swimming freely near the ground leads to flow-mediated equilibrium altitudes
Swimming freely near the ground leads to flow-mediated equilibrium altitudes
Experiments and computations are presented for a foil pitching about its leading edge near a planar, solid boundary. The foil is examined when it is constrained in space and when it is unconstrained or freely swimming in the cross-stream direction. It was found that the foil has stable equilibrium altitudes: the time-averaged lift is zero at certain altitudes and acts to return the foil to these equilibria. These stable equilibrium altitudes exist for both constrained and freely swimming foils and are independent of the initial conditions of the foil. In all cases, the equilibrium altitudes move farther from the ground when the Strouhal number is increased or the reduced frequency is decreased. Potential flow simulations predict the equilibrium altitudes to within 3 %–11 %, indicating that the equilibrium altitudes are primarily due to inviscid mechanisms. In fact, it is determined that stable equilibrium altitudes arise from an interplay among three time-averaged forces: a negative jet deflection circulatory force, a positive quasistatic circulatory force and a negative added mass force. At equilibrium, the foil exhibits a deflected wake and experiences a thrust enhancement of 4 %–17 % with no penalty in efficiency as compared to a pitching foil far from the ground. These newfound lateral stability characteristics suggest that unsteady ground effect may play a role in the control strategies of near-boundary fish and fish-inspired robots.
0022-1120
R1
Kurt, Melike
15dea522-b5e5-4360-8b03-7a68e543c873
Cochran-Carney, Jackson
c8c3350b-cbe1-468a-811a-dc0bd13377b2
Zhong, Qiang
79e26067-9375-462c-855e-99d529a51888
Mivehchi, Amin
e3cd21f8-2efd-4b02-9c02-c0fe320e3d24
Quinn, Daniel B.
d4277789-68c7-4620-8c6f-4072575f0120
Moored, Keith W.
9c89d06c-a49a-4ff0-bd32-37d9d143d39a
Kurt, Melike
15dea522-b5e5-4360-8b03-7a68e543c873
Cochran-Carney, Jackson
c8c3350b-cbe1-468a-811a-dc0bd13377b2
Zhong, Qiang
79e26067-9375-462c-855e-99d529a51888
Mivehchi, Amin
e3cd21f8-2efd-4b02-9c02-c0fe320e3d24
Quinn, Daniel B.
d4277789-68c7-4620-8c6f-4072575f0120
Moored, Keith W.
9c89d06c-a49a-4ff0-bd32-37d9d143d39a

Kurt, Melike, Cochran-Carney, Jackson, Zhong, Qiang, Mivehchi, Amin, Quinn, Daniel B. and Moored, Keith W. (2019) Swimming freely near the ground leads to flow-mediated equilibrium altitudes. Journal of Fluid Mechanics, 875, R1. (doi:10.1017/jfm.2019.540).

Record type: Article

Abstract

Experiments and computations are presented for a foil pitching about its leading edge near a planar, solid boundary. The foil is examined when it is constrained in space and when it is unconstrained or freely swimming in the cross-stream direction. It was found that the foil has stable equilibrium altitudes: the time-averaged lift is zero at certain altitudes and acts to return the foil to these equilibria. These stable equilibrium altitudes exist for both constrained and freely swimming foils and are independent of the initial conditions of the foil. In all cases, the equilibrium altitudes move farther from the ground when the Strouhal number is increased or the reduced frequency is decreased. Potential flow simulations predict the equilibrium altitudes to within 3 %–11 %, indicating that the equilibrium altitudes are primarily due to inviscid mechanisms. In fact, it is determined that stable equilibrium altitudes arise from an interplay among three time-averaged forces: a negative jet deflection circulatory force, a positive quasistatic circulatory force and a negative added mass force. At equilibrium, the foil exhibits a deflected wake and experiences a thrust enhancement of 4 %–17 % with no penalty in efficiency as compared to a pitching foil far from the ground. These newfound lateral stability characteristics suggest that unsteady ground effect may play a role in the control strategies of near-boundary fish and fish-inspired robots.

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More information

Published date: 25 September 2019

Identifiers

Local EPrints ID: 474780
URI: http://eprints.soton.ac.uk/id/eprint/474780
DOI: doi:10.1017/jfm.2019.540
ISSN: 0022-1120
PURE UUID: fedd29b9-d1a8-4cb6-b539-b74a729d4b64
ORCID for Melike Kurt: ORCID iD orcid.org/0000-0001-6711-7025

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Date deposited: 02 Mar 2023 17:47
Last modified: 17 Mar 2024 04:05

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Contributors

Author: Melike Kurt ORCID iD
Author: Jackson Cochran-Carney
Author: Qiang Zhong
Author: Amin Mivehchi
Author: Daniel B. Quinn
Author: Keith W. Moored

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