Control of pressurized microbubble generation by multi-channel membranes: Experiments and modeling

Microbubbles have been attracting a lot of attention in the fields of chemical and petrochemical engineering, environmental protection, medicine, and aquaculture etc. Herein, a controlled pressurized microbubble gener-ation system is developed. Numerous microbubbles are generated under certain of pressure by multi-channel ceramic membranes in a surfactant-free system consisting of dispersed gaseous and continuous aqueous pha-ses. The average diameter and size distribution of the microbubbles are significantly affected by the membrane pore size, membrane area, liquid viscosity, pressure and gas-liquid flow ratio. A mathematical model about the average diameter of microbubbles is established for the first time by directly introducing the membrane pa-rameters including the membrane area and membrane pore size, and the error of the as-established model is less than 10%. More importantly, the model can be used to predict the optimal membrane pore size and membrane area under different operating conditions under the premise of achieving the expected bubble size. The work will aid the understanding and development of microbubble generation with high performance.

Automated summary

A controlled pressurized microbubble generation system has been developed, which can produce numerous microbubbles under certain pressure using multi-channel ceramic membranes in a surfactant-free system. The average diameter and size distribution of the microbubbles are significantly influenced by various factors. A mathematical model is established to predict the optimal membrane parameters and bubble size under different operating conditions. This work contributes to the understanding and development of high-performance microbubble generation.