Octopus-inspired drag cancellation by added mass pumping
Octopus-inspired drag cancellation by added mass pumping
Recent work has shown that when an immersed body suddenly changes its size, such as a deflating octopus during rapid escape jetting, the body experiences large forces due to the variation of added-mass energy. We extend this line of research by investigating a spring-mass oscillator submerged in quiescent fluid subject to periodic changes in its volume. This system isolates the ability of the added-mass thrust to cancel the bluff body resistance (having no jet flow to confuse the analysis) and moves closer to studying how these effects would work in a sustained propulsion case by studying periodic shape-change instead of a "one-shot" escape maneuver. With a combination of analytical, numerical, and experimental results, we show that the recovery of added-mass kinetic energy can be used to completely cancel the drag of the fluid, driving the onset of sustained oscillations with amplitudes as large as four times the average body radius. Moreover, these results are fairly independent of the details of the shape-change kinematics as long as the Stokes number and shape-change number are large. In addition, the effective pumping frequency range based on parametric oscillator analysis is shown to predict large amplitude response region observed in the numerics and experiments.
Weymouth, Gabriel
b0c85fda-dfed-44da-8cc4-9e0cc88e2ca0
Giorgio-Serchi, Francesco
8571dc14-19c1-4ed1-8080-d380736a6ffa
November 2016
Weymouth, Gabriel
b0c85fda-dfed-44da-8cc4-9e0cc88e2ca0
Giorgio-Serchi, Francesco
8571dc14-19c1-4ed1-8080-d380736a6ffa
Weymouth, Gabriel and Giorgio-Serchi, Francesco
(2016)
Octopus-inspired drag cancellation by added mass pumping.
69th American Physical Society (APS) Fluid Dynamics Division meeting (APS-DFD 2016), Portland, United States.
20 - 22 Nov 2016.
Record type:
Conference or Workshop Item
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Abstract
Recent work has shown that when an immersed body suddenly changes its size, such as a deflating octopus during rapid escape jetting, the body experiences large forces due to the variation of added-mass energy. We extend this line of research by investigating a spring-mass oscillator submerged in quiescent fluid subject to periodic changes in its volume. This system isolates the ability of the added-mass thrust to cancel the bluff body resistance (having no jet flow to confuse the analysis) and moves closer to studying how these effects would work in a sustained propulsion case by studying periodic shape-change instead of a "one-shot" escape maneuver. With a combination of analytical, numerical, and experimental results, we show that the recovery of added-mass kinetic energy can be used to completely cancel the drag of the fluid, driving the onset of sustained oscillations with amplitudes as large as four times the average body radius. Moreover, these results are fairly independent of the details of the shape-change kinematics as long as the Stokes number and shape-change number are large. In addition, the effective pumping frequency range based on parametric oscillator analysis is shown to predict large amplitude response region observed in the numerics and experiments.
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Published date: November 2016
Venue - Dates:
69th American Physical Society (APS) Fluid Dynamics Division meeting (APS-DFD 2016), Portland, United States, 2016-11-20 - 2016-11-22
Organisations:
Fluid Structure Interactions Group
Identifiers
Local EPrints ID: 404934
URI: http://eprints.soton.ac.uk/id/eprint/404934
PURE UUID: dd9ee7f9-2611-47d6-a2da-5bbe492731bd
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Date deposited: 25 Jan 2017 10:01
Last modified: 12 Dec 2021 03:59
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Author:
Francesco Giorgio-Serchi
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