Three-dimensional flow structures and vorticity control in fish-like swimming

Q. ZHU; M. J. WOLFGANG; D. K. P. YUE; M. S. TRIANTAFYLLOU

doi:10.1017/S002211200200143X

Abstract

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We employ a three-dimensional, nonlinear inviscid numerical method, in conjunction with experimental data from live fish and from a fish-like robotic mechanism, to establish the three-dimensional features of the flow around a fish-like body swimming in a straight line, and to identify the principal mechanisms of vorticity control employed in fish-like swimming. The computations contain no structural model for the fish and hence no recoil correction. First, we show the near-body flow structure produced by the travelling-wave undulations of the bodies of a tuna and a giant danio. As revealed in cross-sectional planes, for tuna the flow contains dominant features resembling the flow around a two-dimensional oscillating plate over most of the length of the fish body. For the giant danio, on the other hand, a mixed longitudinal–transverse structure appears along the hind part of the body. We also investigate the interaction of the body-generated vortices with the oscillating caudal fin and with tail-generated vorticity. Two distinct vorticity interaction modes are identified: the first mode results in high thrust and is generated by constructive pairing of body-generated vorticity with same-sign tail-generated vorticity, resulting in the formation of a strong thrust wake; the second corresponds to high propulsive efficiency and is generated by destructive pairing of body-generated vorticity with opposite-sign tail-generated vorticity, resulting in the formation of a weak thrust wake.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Tytell, Eric 2003. FISH CONTROL THEIR ROTATION. Journal of Experimental Biology, Vol. 206, Issue. 3, p. 429.

NIHEI, Yasuo FUKUNAGA, Kenichi and OZAWA, Yoshiharu 2004. NUMERICAL SIMULATION FOR A FLOW AROUND FISH WITH ACTUAL FISH BEHAVIOR. Doboku Gakkai Ronbunshu, Vol. 2004, Issue. 768, p. 55.

Guglielmini, Laura Blondeaux, Paolo and Vittori, Giovanna 2004. A simple model of propulsive oscillating foils. Ocean Engineering, Vol. 31, Issue. 7, p. 883.

Tytell, Eric D. and Lauder, George V. 2004. The hydrodynamics of eel swimming. Journal of Experimental Biology, Vol. 207, Issue. 11, p. 1825.

Guglielmini, Laura and Blondeaux, Paolo 2004. Propulsive efficiency of oscillating foils. European Journal of Mechanics - B/Fluids, Vol. 23, Issue. 2, p. 255.

Smith, Richard and Wright, Jeffrey 2004. Simulation of RoboTuna Fluid Dynamics Using a New Incompressible ALE Method.

Lauder, G.V. and Drucker, E.G. 2004. Morphology and Experimental Hydrodynamics of Fish Fin Control Surfaces. IEEE Journal of Oceanic Engineering, Vol. 29, Issue. 3, p. 556.

Gilmanov, Anvar and Sotiropoulos, Fotis 2005. A hybrid Cartesian/immersed boundary method for simulating flows with 3D, geometrically complex, moving bodies. Journal of Computational Physics, Vol. 207, Issue. 2, p. 457.

Lauder, George V. and Tytell, Eric D. 2005. Fish Biomechanics. Vol. 23, Issue. , p. 425.

Schouveiler, L. Hover, F.S. and Triantafyllou, M.S. 2005. Performance of flapping foil propulsion. Journal of Fluids and Structures, Vol. 20, Issue. 7, p. 949.

Webb, Paul W. 2005. Fish Biomechanics. Vol. 23, Issue. , p. 281.

Bartol, Ian K. Gharib, Morteza Webb, Paul W. Weihs, Daniel and Gordon, Malcolm S. 2005. Body-induced vortical flows: a common mechanism for self-corrective trimming control in boxfishes. Journal of Experimental Biology, Vol. 208, Issue. 2, p. 327.

Triantafyllou, M. S. Hover, F. S. Techet, A. H. and Yue, D. K. P. 2005. Review of Hydrodynamic Scaling Laws in Aquatic Locomotion and Fishlike Swimming. Applied Mechanics Reviews, Vol. 58, Issue. 4, p. 226.

Adkins, D. and Yan, Y. Y. 2006. CFD simulation of fish-like body moving in viscous liquid. Journal of Bionic Engineering, Vol. 3, Issue. 3, p. 147.

Zhu, Qiang Liu, Yuming and Yue, Dick K. P. 2006. Dynamics of a Three-Dimensional Oscillating Foil Near the Free Surface. AIAA Journal, Vol. 44, Issue. 12, p. 2997.

Kelly, Scott D. and Hukkeri, Ramadev B. 2006. Mechanics, Dynamics, and Control of a Single-Input Aquatic Vehicle With Variable Coefficient of Lift. IEEE Transactions on Robotics, Vol. 22, Issue. 6, p. 1254.

Smith, Richard and Wright, Jeffrey 2006. A Comparison of Euler and Navier-Stokes Simulations with Experiment for a Flapping Hydrofoil.

Platzer, Max and Jones, Kevin 2006. Flapping Wing Aerodynamics - Progress and Challenges.

Vainchtein, Dmitri and Meziç, Igor 2006. Control of Fluid Flow. Vol. 330, Issue. , p. 189.

Tytell, Eric D. 2006. Median fin function in bluegill sunfishLepomis macrochirus:streamwise vortex structure during steady swimming. Journal of Experimental Biology, Vol. 209, Issue. 8, p. 1516.

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Three-dimensional flow structures and vorticity control in fish-like swimming

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