Effect of flexure on aerodynamic propulsive efficiency of flapping flexible airfoil

Abstract The aim of present study is to investigate the effect of chord-wise flexure amplitude on unsteady aerodynamic characteristics for a flapping airfoil with various combinations of Reynolds number and reduced frequency. Unsteady, viscous flows over a single flexible airfoil in plunge motion are computed using conformal hybrid meshes. The dynamic mesh technique is applied to illustrate the deformation modes of the flexible flapping airfoil. In order to investigate the influence of the flexure amplitude on the aerodynamic performance of the flapping airfoil, the present study considers eight different flexure amplitudes ( a 0 ) ranging from 0 to 0.7 in intervals of 0.1 under conditions of Re=10 4 , reduced frequency k =2, and dimensionless plunge amplitude h 0 =0.4. The computed unsteady flow fields clearly reveal the formation and evolution of a pair of leading edge vortices along the body of the flexible airfoil as it undergoes plunge motion. Thrust-indicative wake structures are generated when the flexure amplitude of the airfoil is less than 0.5 of the chord length. An enhancement in the propulsive efficiency is observed for a flapping airfoil with flexure amplitude of 0.3 of the chord length. This study also calculates the propulsive efficiency and thrust under various Reynolds numbers and reduced frequency conditions. The results indicate that the propulsive efficiency has a strong correlation with the reduced frequency. It is found that the flow conditions which yield the highest propulsive efficiency correspond to Strouhal number St of 0.255.

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

[2]  Max F. Platzer,et al.  Thrust Generation due to Airfoil Flapping , 1996 .

[3]  T. Maxworthy The Fluid Dynamics of Insect Flight , 1981 .

[4]  Kirill V. Rozhdestvensky,et al.  Aerohydrodynamics of flapping-wing propulsors , 2003 .

[5]  Sam Heathcote,et al.  Flexible flapping airfoil propulsion at low Reynolds numbers , 2005 .

[6]  Sam Heathcote,et al.  Flexible Flapping Airfoil Propulsion at Zero Freestream Velocity , 2003 .

[7]  Laurens E. Howle,et al.  Spring stiffness influence on an oscillating propulsor , 2003 .

[8]  Franz S. Hover,et al.  Effect of angle of attack profiles in flapping foil propulsion , 2004 .

[9]  M. F. Platzer,et al.  A Numerical and Experimental Investigation of Flapping-Wing Propulsion in Ground Effect , 2002 .

[10]  C. M. Dohring,et al.  Experimental and Computational Investigation of the Knoller-Betz Effect , 1998 .

[11]  Max F. Platzer,et al.  Improved Performance and Control of Flapping-Wing Propelled Micro Air Vehicles , 2004 .

[12]  R. McNeill Alexander,et al.  Locomotion of animals , 1982 .

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

[14]  Ronald S. Fearing,et al.  Development of PZT and PZN-PT based unimorph actuators for micromechanical flapping mechanisms , 2001, Proceedings 2001 ICRA. IEEE International Conference on Robotics and Automation (Cat. No.01CH37164).

[15]  Michael S. Triantafyllou,et al.  Forces on oscillating foils for propulsion and maneuvering , 2003 .

[16]  Max F. Platzer,et al.  A Fast Method for the Prediction of Dynamic Stall Onset on Turbomachinery Blades , 1997 .

[17]  Ismail H. Tuncer,et al.  Thrust Generation Caused by Flapping Airfoils in a Biplane Configuration , 2003 .

[18]  Tim Lee,et al.  Measurement of unsteady boundary layer developed on an oscillating airfoil using multiple hot-film sensors , 1998 .

[19]  Max F. Platzer,et al.  Characteristics of a Plunging Airfoil at Zero Freestream Velocity , 2001 .

[20]  K. Isogai,et al.  Effects of Dynamic Stall on Propulsive Efficiency and Thrust of Flapping Airfoil , 1999 .