1. Leading-edge vortex dynamics on plunging airfoils and wings
- Author
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Zhijin Wang, Spencer Sherwin, Chris Cantwell, Ismet Gursul, Onur Son, An-Kang Gao, and Engineering & Physical Science Research Council (EPSRC)
- Subjects
Technology ,LIFT ,Science & Technology ,Physics ,FLOW ,Fluids & Plasmas ,Mechanical Engineering ,SOLVERS ,Mechanics ,vortex dynamics ,Condensed Matter Physics ,09 Engineering ,Physics::Fluid Dynamics ,STALL ,Physics, Fluids & Plasmas ,Mechanics of Materials ,Condensed Matter::Superconductivity ,Physical Sciences ,01 Mathematical Sciences - Abstract
The vortex dynamics of leading-edge vortices on plunging high-aspect-ratio (AR = 10) wings and airfoils were investigated by means of volumetric velocity measurements, numerical simulations and stability analysis to understand the deformation of the leading-edge vortex filament and spanwise instabilities. The vortex filaments on both the wing and airfoil exhibit spanwise waves, but with different origins. The presence of a wing-tip causes the leg of the vortex to remain attached to the wing upper surface, while the initial deformation of the filament near the wing tip resembles a helical vortex. The essential features can be modelled as the deformation of an initially L-shaped semi-infinite vortex column. In contrast, the instability of the vortices is well captured by the instability of counter-rotating vortex pairs, which are formed either by the trailing-edge vortices or the secondary vortices rolled-up from the wing surface. The wavelengths observed in the experiments and simulations are in agreement with the stability analysis of counter-rotating vortex pairs of unequal strength.
- Published
- 2022