Numerical simulation of aspherical collapses of vapor bubbles containing non-condensable gas

We investigate numerically the effect of non-condensable gas inside a vapor bubble on the bubble dynamics, the collapse pressure and the maximum pressure at the wall for aspherical collapses close to the wall. Free gas in the vapor bubble has a cushioning effect that can weaken the pressure wave and enhance the bubble rebound. In order to assess this effect numerically, simulations of collapsing vapor bubbles with different stand-off distances to the wall are performed. The bubbles contain either only vapor or vapor and a certain amount of non-condensable gas. For the cavitating liquid and the non-condensable gas we employ a homogeneous mixture model with a coupled equation of state for all components. The cavitation model is a barotropic thermodynamic equilibrium model. Compressibility of all phases is considered, in order to capture the shockwave of the bubble collapse.     «

We investigate numerically the effect of non-condensable gas inside a vapor bubble on the bubble dynamics, the collapse pressure and the maximum pressure at the wall for aspherical collapses close to the wall. Free gas in the vapor bubble has a cushioning effect that can weaken the pressure wave and enhance the bubble rebound. In order to assess this effect numerically, simulations of collapsing vapor bubbles with different stand-off distances to the wall are performed. The bubbles contain e...     »