Aerodynamics of Owl-like Wing Model at Low Reynolds Numbers

Abstract

Aerodynamics of an owl-like wing model at low Reynolds numbers (Re = O(10^4–5)) are investigated using large-eddy simulations with high-resolution computational schemes. The airfoil shape of the owl-like wing model is constructed based on a cross-sectional geometry of the owl wing at 40% wingspan from the root. The chord-based Re ranges from 1.0 × 10⁴ to 5.0 × 10⁴ and the angle of attack (α) varies from 0 to 14 deg. The time-averaged lift (C_l) and drag coefficients computed are in reasonable agreement with the results of force measurement. The results computed clarify a nonlinear change in the C_l curve slope, which is due to an increase in the suction peaks in conjunction with the change in type of separation, the formation of a laminar separation bubble (LSB), and pressure recovery on the pressure side. The generation of the LSB on the suction and/or pressure sides at the Re of 2.3 × 10⁴ and 4.6 × 10⁴ are seen, while reattachments are observed only on the pressure side at the Re of 1.0 × 10⁴ due to the camber of the wing. Furthermore, the owl-like wing model demonstrates favorable aerodynamic performance in terms of a maximum lift-to-drag ratio in comparison with several airfoils at the Re range considered. This is due to the strong suction peaks and distribution of surface pressure on the pressure side. It is emphasized that the concave lower surface enhances the time-averaged aerodynamic performance at all of the α even though the LSB is generated and fluctuation in lift history is induced at low α.