Shape of retracting foils that model morphing bodies controls shed energy and wake structure
Shape of retracting foils that model morphing bodies controls shed energy and wake structure
The flow mechanisms of shape-changing moving bodies are investigated through the simple model of a foil that is rapidly retracted over a span wise distance as it is towed at constant angle of attack. It is shown experimentally and through simulation that by altering the shape of the tip of the retracting foil, different shape-changing conditions may be reproduced, corresponding to: (a) a vanishing body, (b) a deflating body, and (c) a melting body. A sharp-edge, ‘vanishing-like’ foil manifests strong energy release to the fluid; however it is accompanied by an additional release of energy, resulting in the formation of a strong ring vortex at the sharp tip edges of the foil during the retracting motion. This additional energy release introduces complex and quickly-evolving vortex structures. By contrast, a streamlined, ‘shrinking-like’ foil avoids generating the ring vortex, leaving a structurally simpler wake. The ‘shrinking’ foil also recovers a large part of the initial energy from the fluid, resulting in much weaker wake structures. Finally, a sharp-edged but hollow, ‘melting-like’ foil provides an energetic wake while avoiding the generation of a vortex ring. As a result, a melting-like body forms a simple and highly energetic and stable wake, that entrains all of the original added mass fluid energy. The three conditions studied correspond to different modes of flow control employed by aquatic animals and birds, and encountered in disappearing bodies, such as rising bubbles undergoing phase change to fluid.
355-383
Steele, Stephanie
51d603c8-7872-4172-ab3b-1423bc069f0e
Dahl, Jason
280fbf08-ef3a-4bbb-a659-aebe02f0bef1
Weymouth, Gabriel
b0c85fda-dfed-44da-8cc4-9e0cc88e2ca0
Triantafyllou, Michael
952d3f70-df17-4a8d-98d4-c2680ed83711
25 October 2016
Steele, Stephanie
51d603c8-7872-4172-ab3b-1423bc069f0e
Dahl, Jason
280fbf08-ef3a-4bbb-a659-aebe02f0bef1
Weymouth, Gabriel
b0c85fda-dfed-44da-8cc4-9e0cc88e2ca0
Triantafyllou, Michael
952d3f70-df17-4a8d-98d4-c2680ed83711
Steele, Stephanie, Dahl, Jason, Weymouth, Gabriel and Triantafyllou, Michael
(2016)
Shape of retracting foils that model morphing bodies controls shed energy and wake structure.
Journal of Fluid Mechanics, 805, .
(doi:10.1017/jfm.2016.553).
Abstract
The flow mechanisms of shape-changing moving bodies are investigated through the simple model of a foil that is rapidly retracted over a span wise distance as it is towed at constant angle of attack. It is shown experimentally and through simulation that by altering the shape of the tip of the retracting foil, different shape-changing conditions may be reproduced, corresponding to: (a) a vanishing body, (b) a deflating body, and (c) a melting body. A sharp-edge, ‘vanishing-like’ foil manifests strong energy release to the fluid; however it is accompanied by an additional release of energy, resulting in the formation of a strong ring vortex at the sharp tip edges of the foil during the retracting motion. This additional energy release introduces complex and quickly-evolving vortex structures. By contrast, a streamlined, ‘shrinking-like’ foil avoids generating the ring vortex, leaving a structurally simpler wake. The ‘shrinking’ foil also recovers a large part of the initial energy from the fluid, resulting in much weaker wake structures. Finally, a sharp-edged but hollow, ‘melting-like’ foil provides an energetic wake while avoiding the generation of a vortex ring. As a result, a melting-like body forms a simple and highly energetic and stable wake, that entrains all of the original added mass fluid energy. The three conditions studied correspond to different modes of flow control employed by aquatic animals and birds, and encountered in disappearing bodies, such as rising bubbles undergoing phase change to fluid.
Text
Steele JFM 2016 accepted preprint manuscript.pdf
- Accepted Manuscript
More information
Accepted/In Press date: 4 August 2016
e-pub ahead of print date: 20 September 2016
Published date: 25 October 2016
Organisations:
Fluid Structure Interactions Group
Identifiers
Local EPrints ID: 399173
URI: http://eprints.soton.ac.uk/id/eprint/399173
ISSN: 0022-1120
PURE UUID: 8cd4b9ef-caf9-4763-948a-926d8b84ba3f
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Date deposited: 10 Aug 2016 14:27
Last modified: 15 Mar 2024 05:47
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Author:
Stephanie Steele
Author:
Jason Dahl
Author:
Michael Triantafyllou
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