Passive propulsion in vortex wakes

Beal, David; Hover, Franz S.; Triantafyllou, Michael S.; Liao, James C.; Lauder, George V.

doi:10.1017/s0022112005007925

Cited by 333 publications

(246 citation statements)

References 25 publications

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“…Yet, experimental evidence seems to suggest the existence of some mechanisms for passive stabilization in fish motion. For example, [3] reported upstream motion of anesthetized fish (undeniably passive) in vortical flows and mentioned that the elastic properties of the fish body are essential to achieve this motion. Indeed, the motion of elongated rigid bodies in unsteady flows is known to be passively unstable, see, for example, [15,8,20].…”

Section: Introductionmentioning

confidence: 99%

Effects of body elasticity on stability of underwater locomotion

Jing

Kanso

2011

J. Fluid Mech.

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We examine the stability of the "coast" motion of fish, that is to say, the motion of a neutrally buoyant fish at constant speed in a straight line. The forces and moments acting on the fish body are thus perfectly balanced. The fish motion is said to be unstable if a perturbation in the conditions surrounding the fish results in forces and moments that tend to increase the perturbation and it is stable if these emerging forces tend to reduce the perturbation and return the fish to its original state. Stability may be achieved actively or passively. Active stabilization requires neurological control that activates musculo-skeletal components to compensate for the external perturbations acting against stability. Passive stabilization on the other hand requires no energy input by the fish and is dependent upon the fish morphology, i.e. geometry and elastic properties. In this paper, we use a deformable body consisting of an articulated body equipped with torsional springs at its hinge joints and submerged in an unbounded perfect fluid as a simple model to study passive stability as a function of the body geometry and spring stiffness. We show that for given body dimensions, the spring elasticity, when properly chosen, leads to passive stabilization of the (otherwise unstable) coast motion.

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Section: Introductionmentioning

confidence: 99%

Effects of body elasticity on stability of underwater locomotion

Jing

Kanso

2011

J. Fluid Mech.

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“…Beal et al (2006) showed that dead trout can recover sufficient energy from the surrounding flow to allow it to passively swim upstream. Inspired by this observation, we propose a simple model to emulate the motion of a body in an externally generated vortex street.…”

Section: Equations Of Motionmentioning

confidence: 99%

“…The second example examines the effect of the ambient vorticity, modeled using point vortices, on the net locomotion of a rigid body, [5]. This example is inspired by [1] where dead trout was reported to recover sufficient energy from the surrounding flow to allow it to passively swim upstream. Indeed, we identify configurations where even a rigid body (no elasticity) can swim passively in the direction opposite to the motion of vortices at no energy cost.…”

Section: Introductionmentioning

confidence: 99%

Swimming in an inviscid fluid

Kanso¹

2009

Iutam Bookseries

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We present a set of equations governing the motion of a body due to prescribed shape changes in an inviscid, planar fluid with nonzero vorticity. The derived equations, when neglecting vorticity, reduce to the model developed in [4] for swimming in potential flow, and are also consistent with the models developed in [2,5,15] for a rigid body interacting dynamically with point vortices. The effects of cyclic shape changes and the presence of vorticity on the locomotion of a submerged body are discussed through examples.

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“…More importantly, the columnar vortices do not remain straight, and under the influence of the vortex ring become significantly distorted. For vorticity control, where oncoming coherent vortices may be manipulated to either enhance forces or recover energy by downstream bodies (Gopalkrishnan et al 1994;Beal et al 2006), this poses difficulties since the orientation of shed columnar vortices does not remain predictable. Hence, finding ways to reduce three-dimensionality are desirable.…”

Section: Introductionmentioning

confidence: 99%

“…Also, in fish swimming, it is shown that the caudal fin operates in the wake of upstream fins, gaining propulsive efficiency through interaction with the oncoming vortices (Zhu et al 2002). The ability of bodies to extract energy from oncoming coherent vortices has been demonstrated in Beal et al (2006), who showed that a dead trout can extract energy from the coherent vortices of an oncoming Karman street wake generated by a D-shaped cylinder, causing it to surge upstream. The same results were demonstrated with a passive foil in the wake behind a D-shaped cylinder.…”

Section: Introductionmentioning

confidence: 99%

Shape of retracting foils that model morphing bodies controls shed energy and wake structure

et al. 2016

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The flow mechanisms of shape-changing moving bodies are investigated through the simple model of a foil that is rapidly retracted over a spanwise 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.

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Passive propulsion in vortex wakes

Cited by 333 publications

References 25 publications

Effects of body elasticity on stability of underwater locomotion

Effects of body elasticity on stability of underwater locomotion

Swimming in an inviscid fluid

Shape of retracting foils that model morphing bodies controls shed energy and wake structure

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