Sound generation by the interaction of a vortex ring with a rigid sphere

Abstract: High-Reynolds-number interactions between a vortex ring and a stationary rigid sphere are computed using two Lagrangian particle models. The first is a 3D slender vortex filament scheme which tracks the motion of the filament centerline. The centerline velocity is expressed as the sum of a self-induced velocity and potential velocity added to satisfy potential boundary conditions on the surface of the sphere. The self-induced velocity is computed numerically from the line Biot-Savart integral, which is careful… Show more

“…(19) and (20)) of the core vorticity. The results indicate that as the vortex ring passes over the sphere, its radius stretches while its cross-section becomes thinner [26]. Due to their larger self-induced velocity, thin rings complete the passage in a shorter time period than thicker rings.…”

“…Meanwhile, the acoustic pressure signal computed in the particle simulation reveals a high-frequency component that is not observed in the filament calculations (Refs. [20,26]). In fact, the acoustic signal in the particle simulation appears to be composed of a low-frequency component, whose evolution is in agreement with the signal from a slender vortex model, on which high-frequency oscillations are superimposed [22].…”

Vortex particle methods in aeroacoustic calculations

“…(19) and (20)) of the core vorticity. The results indicate that as the vortex ring passes over the sphere, its radius stretches while its cross-section becomes thinner [26]. Due to their larger self-induced velocity, thin rings complete the passage in a shorter time period than thicker rings.…”

“…Meanwhile, the acoustic pressure signal computed in the particle simulation reveals a high-frequency component that is not observed in the filament calculations (Refs. [20,26]). In fact, the acoustic signal in the particle simulation appears to be composed of a low-frequency component, whose evolution is in agreement with the signal from a slender vortex model, on which high-frequency oscillations are superimposed [22].…”

Vortex particle methods in aeroacoustic calculations

Dynamically Coupled Rigid Body+Vortex Rings in $$\mathbb {R}^3$$