ON THE MOTION OF SMALL SPHERICAL BUBBLES IN 2-DIMENSIONAL VORTICAL FLOWS

The motion of small, spherical noninteracting bubbles in two-dimension al vortical flows by means of numerical simulations is investigated. A fter a discussion concerning the various bubble equations, bubble traj ectories are calculated in a solid-body vortex, where it is found that the bubble motion can be described in terms of the location where the bubbles accumulate, or equilibrium points, and the rate of entrapment into these equilibrium points. Of importance here is that the rate of entrapment into the vortex has an optimum value for some value of the inertia parameter, or inverse Stokes number. The bubble motion in a t emporally evolving shear layer is investigated, where it is found that the solid-body vortex model predicts the trends in the growth in conc entration about the vortex center for the case without gravity. For th e case with gravity, not all bubbles are captured by the vortex, and t he percentage of bubbles captured increases with decreasing inertia pa rameter. Also discussed is how these factors affect the generation of the interface between regions seeded and not seeded with bubbles.