Vortex ring formation from the interaction of a cavitation bubble with a confined air bubble: experiments and a timing criterion

Abstract

We study vortex ring formation arising from the interaction between a cavitation bubble and a confined air bubble in a cylindrical blind hole, using high-speed shadowgraphy imaging. As the cavitation bubble grows above the hole, it drives a downward flow that compresses the air bubble at the base. The air bubble subsequently expands, expelling the overlying liquid column upward as a coherent slug; impact of this slug on the far boundary of the collapsing cavitation bubble produces a vortex ring. Parametric experiments across the dimensionless stand-off distance H = h/R and the air bubble fill fraction B = (dhole - dtop)/dhole identify three regimes: (i) liquid column impact during collapse, producing a vortex ring (H 0.5, B 0.5); (ii) late impact near the end of collapse (large H); and (iii) direct air bubble impact after bypassing the liquid column (large B), with neither (ii) nor (iii) producing a ring. Two one-dimensional models, based on the Rayleigh-Plesset equation and isentropic air bubble expansion, predict the liquid column impact location and its speed Ulc, respectively. A dimensionless timing parameter = (h + R) / (Ulc · tcav/2), comparing the liquid column travel time to the cavitation collapse half-period, distinguishes the three regimes: ring formation occurs for 1 1.5. The ring propagates from the hole at an initial speed of 5 m/s, decelerating quadratically, and breaks apart via azimuthal instabilities at Re ≈ 4500.