Vortex interactions with flapping wings and fins can be unpredictable.

Lentink, David; Van Heijst, Gertjan F; Muijres, Florian; Van Leeuwen, Johan L

Vortex interactions with flapping wings and fins can be unpredictable.

Mark

Lentink, David ; Van Heijst, Gertjan F ; Muijres, Florian ^LU and Van Leeuwen, Johan L (2010) In Biology letters 6(3). p.394-397

Abstract: As they fly or swim, many animals generate a wake of vortices with their flapping fins and wings that reveals the dynamics of their locomotion. Previous studies have shown that the dynamic interaction of vortices in the wake with fins and wings can increase propulsive force. Here, we explore whether the dynamics of the vortex interactions could affect the predictability of propulsive forces. We studied the dynamics of the interactions between a symmetrically and periodically pitching and heaving foil and the vortices in its wake, in a soap-film tunnel. The phase-locked movie sequences reveal that abundant chaotic vortex-wake interactions occur at high Strouhal numbers. These high numbers are representative for the fins and wings of... (More); As they fly or swim, many animals generate a wake of vortices with their flapping fins and wings that reveals the dynamics of their locomotion. Previous studies have shown that the dynamic interaction of vortices in the wake with fins and wings can increase propulsive force. Here, we explore whether the dynamics of the vortex interactions could affect the predictability of propulsive forces. We studied the dynamics of the interactions between a symmetrically and periodically pitching and heaving foil and the vortices in its wake, in a soap-film tunnel. The phase-locked movie sequences reveal that abundant chaotic vortex-wake interactions occur at high Strouhal numbers. These high numbers are representative for the fins and wings of near-hovering animals. The chaotic wake limits the forecast horizon of the corresponding force and moment integrals. By contrast, we find periodic vortex wakes with an unlimited forecast horizon for the lower Strouhal numbers (0.2-0.4) at which many animals cruise. These findings suggest that swimming and flying animals could control the predictability of vortex-wake interactions, and the corresponding propulsive forces with their fins and wings. (Less)

Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/1886273

author

Lentink, David ; Van Heijst, Gertjan F ; Muijres, Florian ^LU and Van Leeuwen, Johan L

organization

Evolutionary ecology

publishing date

2010

type

Contribution to journal

publication status

published

subject

Biological Sciences

keywords

Animal: physiology, Flight, Animal, Extremities: physiology, Extremities, Animals, Biomechanics, Models, Anatomic, Biological, Swimming, Swimming: physiology, Wing, Wing: physiology

in

Biology letters

volume

6

issue

3

pages

394 - 397

publisher

Royal Society Publishing

external identifiers

scopus:77953043763
pmid:20129947

ISSN

1744-9561

DOI

10.1098/rsbl.2009.0806

language

English

LU publication?

yes

id

f970ce15-3d76-4ed9-a8a0-ee704fd61f30 (old id 1886273)

date added to LUP

2016-04-01 10:09:23

date last changed

2022-04-12 02:28:22

@article{f970ce15-3d76-4ed9-a8a0-ee704fd61f30,
  abstract     = {{As they fly or swim, many animals generate a wake of vortices with their flapping fins and wings that reveals the dynamics of their locomotion. Previous studies have shown that the dynamic interaction of vortices in the wake with fins and wings can increase propulsive force. Here, we explore whether the dynamics of the vortex interactions could affect the predictability of propulsive forces. We studied the dynamics of the interactions between a symmetrically and periodically pitching and heaving foil and the vortices in its wake, in a soap-film tunnel. The phase-locked movie sequences reveal that abundant chaotic vortex-wake interactions occur at high Strouhal numbers. These high numbers are representative for the fins and wings of near-hovering animals. The chaotic wake limits the forecast horizon of the corresponding force and moment integrals. By contrast, we find periodic vortex wakes with an unlimited forecast horizon for the lower Strouhal numbers (0.2-0.4) at which many animals cruise. These findings suggest that swimming and flying animals could control the predictability of vortex-wake interactions, and the corresponding propulsive forces with their fins and wings.}},
  author       = {{Lentink, David and Van Heijst, Gertjan F and Muijres, Florian and Van Leeuwen, Johan L}},
  issn         = {{1744-9561}},
  keywords     = {{Animal: physiology; Flight; Animal; Extremities: physiology; Extremities; Animals; Biomechanics; Models; Anatomic; Biological; Swimming; Swimming: physiology; Wing; Wing: physiology}},
  language     = {{eng}},
  number       = {{3}},
  pages        = {{394--397}},
  publisher    = {{Royal Society Publishing}},
  series       = {{Biology letters}},
  title        = {{Vortex interactions with flapping wings and fins can be unpredictable.}},
  url          = {{http://dx.doi.org/10.1098/rsbl.2009.0806}},
  doi          = {{10.1098/rsbl.2009.0806}},
  volume       = {{6}},
  year         = {{2010}},
}

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Vortex interactions with flapping wings and fins can be unpredictable.