Investigation of Variable Spanwise Waviness Wavelength Effect on Wing Aerodynamic Performance

Abstract—: Tubercles on flippers of a humpback whale offer a hydrodynamic advantage. Previously, multiple attempts were made to employ them on airplane wings to get an aerodynamic advantage. The effects of the airfoil thickness, the wing planform, the Reynolds number Re, and the wavelength and ampli...

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Bibliographic Details
Published in:Fluid Dynamics
Main Authors: Tunio, I. A., Kumar, D., Hussain, T., Jatoi, M., Safiullah
Other Authors: Swinburne University of Technology
Format: Article in Journal/Newspaper
Language:unknown
Published: Pleiades Publishing Ltd 2020
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Online Access:http://hdl.handle.net/1959.3/457829
https://doi.org/10.1134/S0015462820040102
Description
Summary:Abstract—: Tubercles on flippers of a humpback whale offer a hydrodynamic advantage. Previously, multiple attempts were made to employ them on airplane wings to get an aerodynamic advantage. The effects of the airfoil thickness, the wing planform, the Reynolds number Re, and the wavelength and amplitude are actively investigated to understand their impact on the wavy wing aerodynamic performance and the flow mechanism. However, the effect of varying wavelength along the span of the finite wing and its flow physics is yet to be explored. This research work aims at investigating the effect of varying waviness wavelength along the finite wingspan and its underlying flow mechanism in the pre-stall and post-stall regimes. The wavy wing models are designed using the NACA0021 airfoil and the simulation results are compared with the smooth leading edge (named as baseline model) at Reynolds number Re = 1.2 × 105. The simulation results were validated against experimental results from the literature. Two different wavy wing models, i.e., with increasing wavelength from root to tip of the wing (λ0305h1) and decreasing wavelength from root to tip of the wing (λ0503h1) were simulated. From the aerodynamic force behavior it is estimated that in the pre-stall regime the maximum reduction in the lift-to-drag (L/D) ratio is 16.89% and 4.22% for λ0503h1 and λ0305h1, respectively. However, in the post-stall regime the maximum increase in the L/D ratio is estimated as 2.97% and 19.18% for λ0503h1 and λ0305h1, respectively, at 20o angle of attack. It is observed that the λ0503h1 model has a lower L/D ratio in the post-stall regime due to the vortices produced on the wing surface. These vortices create a flow recirculation zone over the wing which causes an increase in the pressure at the upper surface of the wing. On the basis of the obtained results, it is concluded that the spanwise waviness on aircraft wing is only beneficial in the post-stall regime. It is also concluded that an increase in the waviness wavelength from the root to the tip provides higher aerodynamic advantage than for the case with decreasing waviness wavelength toward the tip.