Flow-induced oscillations of pitching swept wings: Stability boundary, vortex dynamics and force partitioning

Abstract

We experimentally study the aeroelastic instability boundaries and three-dimensional vortex dynamics of pitching swept wings, with the sweep angle ranging from 0 to 25 degrees. The structural dynamics of the wings are simulated using a cyber-physical control system. With a constant flow speed, a prescribed high inertia and a small structural damping, we show that the system undergoes a subcritical Hopf bifurcation to large-amplitude limit-cycle oscillations (LCOs) for all the sweep angles. The onset of LCOs depends largely on the static characteristics of the wing. The saddle-node point is found to change non-monotonically with the sweep angle, which we attribute to the non-monotonic power transfer between the ambient fluid and the elastic mount. An optimal sweep angle is observed to enhance the power extraction performance and thus promote LCOs and destabilize the aeroelastic system. The frequency response of the system reveals a structural-hydrodynamic oscillation mode for wings with relatively high sweep angles. Force, moment, and three-dimensional flow structures measured using multi-layer stereoscopic particle image velocimetry are analyzed to explain the differences in power extraction for different swept wings. Finally, we employ a physics-based Force and Moment Partitioning Method (FMPM) to quantitatively correlate the three-dimensional vortex dynamics with the resultant unsteady aerodynamic moment.