Vortex formation and saturation for low-aspect-ratio rotating flat-plate fins

We investigate experimentally the unsteady, three-dimensional vortex formation of low-aspect-ratio, trapezoidal flat-plate fins undergoing rotation from rest at a 90° angle of attack and Reynolds numbers of O(103). The objectives are to characterize the unsteady three-dimensional vortex structure, examine vortex saturation, and understand the effects of the root-to-tip flow for different velocity programs. The experiments are conducted in a water tank facility, and the diagnostic tools are dye flow visualization and digital particle image velocimetry. The dye visualizations show that the low-aspect-ratio plate produces symmetric ring-like vortices comprised mainly of tip-edge vorticity. They also indicate the presence of the root-to-tip velocity. For large rotational amplitudes, the primary ring-like vortex sheds and a secondary ring-like vortex is generated while the plate is still in motion, indicating saturation of the leading vortex. The time-varying vortex circulation in the flow symmetry plane provides quantitative evidence of vortex saturation. The phenomenon of saturation is observed for several plate velocity programs. The temporal development of the vortex circulation is often complex, which prevents an objective determination of an exact saturation time. This is the result of an interaction between the developing vortex and the root-to-tip flow, which breaks apart the vortex. However, it is possible to define a range of time during which the vortex reaches saturation. A formation-parameter definition is investigated and is found to reasonably predict the state corresponding to the pinch-off of the initial tip vortex across the velocity programs tested. This event is the lower bound on the saturation time range.

[1]  Holger Babinsky,et al.  Three-dimensional effects on sliding and waving wings , 2011 .

[2]  Kamran Mohseni,et al.  Numerical experiments on vortex ring formation , 2001, Journal of Fluid Mechanics.

[3]  Paul J Strykowski,et al.  Bias and precision errors of digital particle image velocimetry , 2000 .

[4]  Lauder,et al.  Locomotor forces on a swimming fish: three-dimensional vortex wake dynamics quantified using digital particle image velocimetry. , 1999, The Journal of experimental biology.

[5]  J. Wakeling Biomechanics of fast-start swimming in fish. , 2001, Comparative biochemistry and physiology. Part A, Molecular & integrative physiology.

[6]  Holger Babinsky,et al.  Leading Edge Vortex Development on a Waving Wing at Reynolds Numbers Between 10,000 and 60,000 , 2011 .

[7]  Franz S. Hover,et al.  Review of Hydrodynamic Scaling Laws in Aquatic Locomotion and Fishlike Swimming , 2005 .

[8]  D. Pierce,et al.  Photographic evidence of the formation and growth of vorticity behind plates accelerated from rest in still air , 1961, Journal of Fluid Mechanics.

[9]  Eric D. Tytell,et al.  Median fin function in bluegill sunfish Lepomis macrochirus: streamwise vortex structure during steady swimming , 2006, Journal of Experimental Biology.

[10]  W. Su,et al.  Investigation of flow mechanism of a robotic fish swimming by using flow visualization synchronized with hydrodynamic force measurement , 2007 .

[11]  Domenici,et al.  The kinematics and performance of fish fast-start swimming , 1997, The Journal of experimental biology.

[12]  M. Triantafyllou,et al.  Oscillating foils of high propulsive efficiency , 1998, Journal of Fluid Mechanics.

[13]  Jun Sakakibara,et al.  Stereo-PIV study of flow around a maneuvering fish , 2004 .

[14]  M. Dickinson,et al.  Force production and flow structure of the leading edge vortex on flapping wings at high and low Reynolds numbers , 2004, Journal of Experimental Biology.

[15]  Moshe Rosenfeld,et al.  Circulation and formation number of laminar vortex rings , 1998, Journal of Fluid Mechanics.

[16]  I. Borazjani,et al.  Numerical investigation of the hydrodynamics of carangiform swimming in the transitional and inertial flow regimes , 2008, Journal of Experimental Biology.

[17]  R. Blake Fish functional design and swimming performance , 2004 .

[18]  R. Adrian,et al.  On the relationships between local vortex identification schemes , 2005, Journal of Fluid Mechanics.

[19]  Triantafyllou,et al.  Near-body flow dynamics in swimming fish , 1999, The Journal of experimental biology.

[20]  John O. Dabiri,et al.  Starting flow through nozzles with temporally variable exit diameter , 2005, Journal of Fluid Mechanics.

[21]  M. Triantafyllou,et al.  Optimal Thrust Development in Oscillating Foils with Application to Fish Propulsion , 1993 .

[22]  P.R. Bandyopadhyay,et al.  Trends in biorobotic autonomous undersea vehicles , 2005, IEEE Journal of Oceanic Engineering.

[23]  Daegyoum Kim,et al.  Characteristics of vortex formation and thrust performance in drag-based paddling propulsion , 2011, Journal of Experimental Biology.

[24]  D. Weihs Hydromechanics of Fish Schooling , 1973, Nature.

[25]  Peter Freymuth Visualizing the Connectivity of Vortex Systems for Pitching Wings , 1989 .

[26]  Julio Soria,et al.  Morphology of the forced oscillatory flow past a finite-span wing at low Reynolds number , 2007, Journal of Fluid Mechanics.

[27]  Christoph Brücker,et al.  Vortex dynamics in the wake of a mechanical fish , 2007 .

[28]  R. Åke Norberg,et al.  Delta-wing function of webbed feet gives hydrodynamic lift for swimming propulsion in birds , 2003, Nature.

[29]  Adrian L. R. Thomas,et al.  Leading-edge vortices in insect flight , 1996, Nature.

[30]  Kevin K. Chen,et al.  The leading-edge vortex and quasisteady vortex shedding on an accelerating plate , 2009 .

[31]  George V Lauder,et al.  Quantification of the wake of rainbow trout (Oncorhynchus mykiss) using three-dimensional stereoscopic digital particle image velocimetry. , 2002, The Journal of experimental biology.

[32]  T. Colonius,et al.  Three-dimensional flows around low-aspect-ratio flat-plate wings at low Reynolds numbers , 2009, Journal of Fluid Mechanics.

[33]  M. S. Chong,et al.  A general classification of three-dimensional flow fields , 1990 .

[34]  Morteza Gharib,et al.  Experimental study of three-dimensional vortex structures in translating and rotating plates , 2010 .

[35]  E. G. Drucker,et al.  A hydrodynamic analysis of fish swimming speed: wake structure and locomotor force in slow and fast labriform swimmers. , 2000, The Journal of experimental biology.

[36]  Tyson L. Hedrick,et al.  Large Eddy Simulation of Flows with Complex Moving Boundaries: Application to Flying and Swimming in Animals , 2009 .

[37]  J. Sumich,et al.  An introduction to the biology of marine life , 1976 .

[38]  D. I. Pullin,et al.  Some flow visualization experiments on the starting vortex , 1980, Journal of Fluid Mechanics.

[39]  Matthew Nicholas Watts,et al.  Emulating the fast-start swimming performance of the Chain Pickerel (Esox niger) using a mechanical fish design , 2006 .

[40]  John O. Dabiri,et al.  The formation number of vortex rings formed in uniform background co-flow , 2006, Journal of Fluid Mechanics.

[41]  J. Soria,et al.  Flow structures behind a heaving and pitching finite-span wing , 2003, Journal of Fluid Mechanics.

[42]  Markus Raffel,et al.  Particle Image Velocimetry: A Practical Guide , 2002 .

[43]  Brenden P. Epps,et al.  Swimming performance of a biomimetic compliant fish-like robot , 2009 .

[44]  Michael Sfakiotakis,et al.  Review of fish swimming modes for aquatic locomotion , 1999 .

[45]  P. Koumoutsakos,et al.  Simulations of the viscous flow normal to an impulsively started and uniformly accelerated flat plate , 1996, Journal of Fluid Mechanics.

[46]  Jonathan M. Rausch,et al.  Vortex Formation of Plunging Flat Plates , 2009 .

[47]  C. Willert,et al.  Digital particle image velocimetry , 1991 .

[48]  M. Triantafyllou,et al.  Numerical experiments on flapping foils mimicking fish-like locomotion , 2005 .

[49]  J. Videler,et al.  Hydrodynamics of unsteady fish swimming and the effects of body size: comparing the flow fields of fish larvae and adults. , 2000, The Journal of experimental biology.

[50]  S. Ting,et al.  Extracting energetically dominant flow features in a complicated fish wake using singular-value decomposition , 2009 .

[51]  T. Maxworthy,et al.  The formation and maintenance of a leading-edge vortex during the forward motion of an animal wing , 2007, Journal of Fluid Mechanics.

[52]  E. G. Drucker,et al.  Wake dynamics and fluid forces of turning maneuvers in sunfish. , 2001, The Journal of experimental biology.

[53]  Michele Milano,et al.  Fluid Dynamics as an Evolutionary Constraint for Flapping Appendages , 2006 .

[54]  George V. Lauder,et al.  Low-dimensional models and performance scaling of a highly deformable fish pectoral fin , 2009, Journal of Fluid Mechanics.

[55]  Jürgen Kompenhans,et al.  Particle Image Velocimetry - A Practical Guide (2nd Edition) , 2007 .

[56]  Michele Milano,et al.  Uncovering the physics of flapping flat plates with artificial evolution , 2005, Journal of Fluid Mechanics.

[57]  Julio Soria,et al.  Using stereo multigrid DPIV (SMDPIV) measurements to investigate the vortical skeleton behind a finite-span flapping wing , 2005 .

[58]  M. Dickinson,et al.  Time-resolved reconstruction of the full velocity field around a dynamically-scaled flapping wing , 2006 .

[59]  Aaron Altman,et al.  Experiments in Vortex Formation of Flapping Flat Plates , 2009 .

[60]  Chapman,et al.  Experimental simulation of the thrust phases of fast-start swimming of fish , 1997, The Journal of experimental biology.

[61]  Q. X. Lian,et al.  Starting flow and structures of the starting vortex behind bluff bodies with sharp edges , 1989 .

[62]  M. Gharib,et al.  A universal time scale for vortex ring formation , 1998, Journal of Fluid Mechanics.

[63]  J. Dabiri Optimal Vortex Formation as a Unifying Principle in Biological Propulsion , 2009 .

[64]  Renato Tognaccini,et al.  The start-up vortex issuing from a semi-infinite flat plate , 2002, Journal of Fluid Mechanics.

[65]  Cameron Tropea,et al.  The influence of airfoil kinematics on the formation of leading-edge vortices in bio-inspired flight , 2009 .

[66]  David E Tobias,et al.  Kinematic and vortical wake patterns of rapidly maneuvering fish and flapping foils , 2006 .

[67]  A. Smits,et al.  On the evolution of the wake structure produced by a low-aspect-ratio pitching panel , 2005, Journal of Fluid Mechanics.

[68]  Brenden P. Epps,et al.  Impulse generated during unsteady maneuvering of swimming fish , 2007 .

[69]  J. Westerweel,et al.  The effect of a discrete window offset on the accuracy of cross-correlation analysis of digital PIV recordings , 1997 .

[70]  P.W. Webb,et al.  Maneuverability - general issues , 2004, IEEE Journal of Oceanic Engineering.

[71]  Paul S. Krueger,et al.  The significance of vortex ring formation to the impulse and thrust of a starting jet , 2003 .

[72]  M. Gharib,et al.  Role of the tip vortex in the force generation of low-aspect-ratio normal flat plates , 2007, Journal of Fluid Mechanics.

[73]  Shinnosuke Obi,et al.  Stereo PIV measurement of a finite, flapping rigid plate in hovering condition , 2010 .

[74]  Alexander J Smits,et al.  The wake structure and thrust performance of a rigid low-aspect-ratio pitching panel , 2008, Journal of Fluid Mechanics.