Dual leading-edge vortices on flapping wings

SUMMARY An experimental investigation was performed with two aims: (1) to clarify the existence of the dual leading-edge vortices (i.e. two vortices with the same sense of rotation located close to the leading edge above the leeward wing surface) observed on flapping wings in previous studies; (2) to study systematically the influences of kinematic and geometric parameters on such a vortical structure. Based on a scaled-up electromechanical model flapping in a water tank, the leading-edge vortex (LEV) cores were visualized via dye flow visualization, and the detailed sub-structures of LEV were revealed through digital particle image velocimetry (DPIV) with high spatial resolution. Five wing aspect ratios (AR) (1.3, 3.5, 5.8, 7.5 and 10), eight mid-stroke angles of attack (αm) (10-80°), and six Reynolds numbers (Re) (160-3200) were examined. In addition, the well-studied case of the fruit fly Drosophila was re-examined. The results confirm for the first time the existence of dual LEVs on flapping wings. The sectional flow structure resembles the dual-vortex observed on non-slender delta wings. Insensitive to AR, a dual LEV system such as this could be created when αm and Re reached certain high levels. The primary vortex was attached to the wing, while at the outer wing the minor vortex shed, generating a same-sense vortex behind.

[1]  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.

[2]  M. Raffel,et al.  A Stereo PIV Investigation of a Vortex Breakdown Above a Delta Wing by Analysis of the Vorticity Field. , 2005 .

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

[4]  Mao Sun,et al.  Unsteady aerodynamic force generation by a model fruit fly wing in flapping motion. , 2002, The Journal of experimental biology.

[5]  Mao Sun,et al.  Lift and power requirements of hovering flight in Drosophila virilis. , 2002, The Journal of experimental biology.

[6]  R. Norberg Hovering Flight of the Dragonfly Aeschna Juncea L., Kinematics and Aerodynamics , 1975 .

[7]  Robert Dudley,et al.  Biomechanics of Flight in Neotropical Butterflies: Morphometrics and Kinematics , 1990 .

[8]  F. Lehmann,et al.  The fluid dynamics of flight control by kinematic phase lag variation between two robotic insect wings , 2004, Journal of Experimental Biology.

[9]  R. Dudley Biomechanics of Flight in Neotropical Butterflies: Aerodynamics and Mechanical Power Requirements , 1991 .

[10]  M. S. Chong,et al.  INTERPRETATION OF FLOW VISUALIZATION , 2000 .

[11]  M. Dickinson,et al.  The influence of wing–wake interactions on the production of aerodynamic forces in flapping flight , 2003, Journal of Experimental Biology.

[12]  S. Leibovich Vortex stability and breakdown - Survey and extension , 1984 .

[13]  Mao Sun,et al.  Unsteady aerodynamic forces of a flapping wing , 2004, Journal of Experimental Biology.

[14]  C. Ellington The Aerodynamics of Hovering Insect Flight. III. Kinematics , 1984 .

[15]  Ellington,et al.  A computational fluid dynamic study of hawkmoth hovering , 1998, The Journal of experimental biology.

[16]  Ismet Gursul,et al.  Buffeting Flows over a Low-Sweep Delta Wing , 2004 .

[17]  R. B. Srygley,et al.  Unconventional lift-generating mechanisms in free-flying butterflies , 2002, Nature.

[18]  C. Ellington The Aerodynamics of Hovering Insect Flight. II. Morphological Parameters , 1984 .

[19]  U. Dallmann,et al.  Flow Field Diagnostics: Topological Flow Changes and Spatio-Temporal Flow Structure , 1995 .

[20]  C. Brennen,et al.  Swimming and Flying in Nature , 1975, Springer US.