MTV measurements of the vortical field in the wake of an airfoil oscillating at high reduced frequency

We present an experimental investigation of the flow structure and vorticity field in the wake of a NACA-0012 airfoil pitching sinusoidally at small amplitude and high reduced frequencies. Molecular tagging velocimetry is used to quantify the characteristics of the vortex array (circulation, peak vorticity, core size, spatial arrangement) and its downstream evolution over the first chord length as a function of reduced frequency. The measured mean and fluctuating velocity fields are used to estimate the mean force on the airfoil and explore the connection between flow structure and thrust generation. Results show that strong concentrated vortices form very rapidly within the first wavelength of oscillation and exhibit interesting dynamics that depend on oscillation frequency. With increasing reduced frequency the transverse alignment of the vortex array changes from an orientation corresponding to velocity deficit (wake profile) to one with velocity excess (reverse Kármán street with jet profile). It is found, however, that the switch in the vortex array orientation does not coincide with the condition for crossover from drag to thrust. The mean force is estimated from a more complete control volume analysis, which takes into account the streamwise velocity fluctuations and the pressure term. Results clearly show that neglecting these terms can lead to a large overestimation of the mean force in strongly fluctuating velocity fields that are characteristic of airfoils executing highly unsteady motions. Our measurements show a decrease in the peak vorticity, as the vortices convect downstream, by an amount that is more than can be attributed to viscous diffusion. It is found that the presence of small levels of axial velocity gradients within the vortex cores, levels that can be difficult to measure experimentally, can lead to a measurable decrease in the peak vorticity even at the centre of the flow facility in a flow that is expected to be primarily two-dimensional.

[1]  M. Koochesfahani,et al.  Effect of boundary conditions on axial flow in a concentrated vortex core , 1993 .

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

[3]  T. Kármán,et al.  Airfoil Theory for Non-Uniform Motion , 1938 .

[4]  Max Platzer,et al.  Aerodynamic analysis of flapping wing propulsion , 1993 .

[5]  M. Koochesfahani,et al.  The accuracy of remapping irregularly spaced velocity data onto a regular grid and the computation of vorticity , 2000 .

[6]  Manoochehr Koochesfahani,et al.  Molecular tagging velocimetry and other novel applications of a new phosphorescent supramolecule , 1997 .

[7]  Morteza Gharib,et al.  Flow patterns generated by oblate medusan jellyfish: field measurements and laboratory analyses , 2005, Journal of Experimental Biology.

[8]  P. Freymuth Propulsive vortical signature of plunging and pitching airfoils , 1988 .

[9]  Anders Hedenström,et al.  Quantitative studies of the wakes of freely flying birds in a low-turbulence wind tunnel , 2003 .

[10]  D. Mathioulakis,et al.  THE FORMATION AND INTERNAL STRUCTURE OF COHERENT VORTICES IN THE WAKE OF A PITCHING AIRFOIL , 1996 .

[11]  J. Guilkey,et al.  The use of photoactivatable fluorophores in the study of turbulent pipe mixing: effects of inlet geometry , 2000 .

[12]  D. Bohl,et al.  Molecular tagging velocimetry measurements of axial flow in a concentrated vortex core , 2004 .

[13]  M. Visbal,et al.  Study of the vortical wake patterns of an oscillating airfoil , 1989 .

[14]  T. Y. Wu,et al.  Hydromechanics of Swimming of Fishes and Cetaceans , 1971 .

[15]  이은도,et al.  아세톤 광분해를 이용한 Molecular Tagging Velocimetry , 2008 .

[16]  J. D. Delaurier,et al.  Experimental study of oscillating-wing propulsion , 1982 .

[17]  Joseph Katz,et al.  Behavior of Vortex Wakes from Oscillating Airfoils , 1978 .

[18]  R. Ramamurti,et al.  Simulation of Flow About Flapping Airfoils Using Finite Element Incompressible Flow Solver , 2001 .

[19]  A Hedenström,et al.  The relationship between wingbeat kinematics and vortex wake of a thrush nightingale , 2004, Journal of Experimental Biology.

[20]  D. Bohl,et al.  MTV Measurements of Axial Flow in Concentrated Vortex Cores , 2003 .

[21]  Richard K. Cohn,et al.  Simultaneous whole-field measurements of velocity and concentration fields using a combination of MTV and LIF , 2000 .

[22]  M. Koochesfahani Vortical patterns in the wake of an oscillating airfoil , 1987 .

[23]  D. Bohl,et al.  WHOLE-FIELD MEASUREMENTS OF UNSTEADY SEPARATION IN A VORTEX RING/WALL INTERACTION , 1997 .

[24]  K. Streitlien,et al.  On Thrust Estimates for Flapping Foils , 1998 .

[25]  Max F. Platzer,et al.  Numerical Computation of Flapping-Wing Propulsion and Power Extraction , 1997 .

[26]  Keiji Kawachi,et al.  Regular Article: A Numerical Study of Undulatory Swimming , 1999 .

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

[28]  Manoochehr Koochesfahani,et al.  A spatial correlation technique for estimating velocity fields using molecular tagging velocimetry (MTV) , 1996 .

[29]  T. Theodorsen General Theory of Aerodynamic Instability and the Mechanism of Flutter , 1934 .

[30]  T. Kármán General aerodynamic theory. Perfect fluids , 1963 .