Passive elastic mechanism to mimic fish-muscle action in anguilliform swimming

Sophie Ramananarivo; Ramiro Godoy-Diana; Benjamin Thiria

doi:10.1098/rsif.2013.0667

Passive elastic mechanism to mimic fish-muscle action in anguilliform swimming

Sophie Ramananarivo
, Ramiro Godoy-Diana
, Benjamin Thiria

UMR 7636 CNRS-ESPCI ParisTech-Université Pierre et Marie Curie

Research output: Contribution to journal › Article › peer-review

Abstract

Swimmers in nature use body undulations to generate propulsive and manoeuvring forces. The anguilliform kinematics is driven by muscular actions all along the body, involving a complex temporal and spatial coordination of all the local actuations. Such swimming kinematics can be reproduced artificially, in a simpler way, by using the elasticity of the body passively. Here, we present experiments on self-propelled elastic swimmers at a free surface in the inertial regime. Byaddressing the fluid-structure interaction problem of anguilliform swimming, we show that our artificial swimmers are well described by coupling a beam theory with the potential flow model of Lighthill. In particular, we show that the propagative nature of the elastic wave producing the propulsive force is strongly dependent on the dissipation of energy along the body of the swimmer.

Original language	English
Journal	Journal of the Royal Society Interface
Volume	10
Issue number	88
DOIs	https://doi.org/10.1098/rsif.2013.0667
Publication status	Published - 6 Nov 2013
Externally published	Yes

Keywords

Anguilliform swimming
Fluid - Structure interaction
Slender body

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10.1098/rsif.2013.0667

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title = "Passive elastic mechanism to mimic fish-muscle action in anguilliform swimming",

abstract = "Swimmers in nature use body undulations to generate propulsive and manoeuvring forces. The anguilliform kinematics is driven by muscular actions all along the body, involving a complex temporal and spatial coordination of all the local actuations. Such swimming kinematics can be reproduced artificially, in a simpler way, by using the elasticity of the body passively. Here, we present experiments on self-propelled elastic swimmers at a free surface in the inertial regime. Byaddressing the fluid-structure interaction problem of anguilliform swimming, we show that our artificial swimmers are well described by coupling a beam theory with the potential flow model of Lighthill. In particular, we show that the propagative nature of the elastic wave producing the propulsive force is strongly dependent on the dissipation of energy along the body of the swimmer.",

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AB - Swimmers in nature use body undulations to generate propulsive and manoeuvring forces. The anguilliform kinematics is driven by muscular actions all along the body, involving a complex temporal and spatial coordination of all the local actuations. Such swimming kinematics can be reproduced artificially, in a simpler way, by using the elasticity of the body passively. Here, we present experiments on self-propelled elastic swimmers at a free surface in the inertial regime. Byaddressing the fluid-structure interaction problem of anguilliform swimming, we show that our artificial swimmers are well described by coupling a beam theory with the potential flow model of Lighthill. In particular, we show that the propagative nature of the elastic wave producing the propulsive force is strongly dependent on the dissipation of energy along the body of the swimmer.

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KW - Slender body

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Passive elastic mechanism to mimic fish-muscle action in anguilliform swimming

Abstract

Keywords

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