Comprehensive experimental and theoretical investigations on the effect of microbubble two-phase flow on the performance of direct-contact membrane distillation

This study provides a comprehensive and systematic overview of the application of gas-liquid two-phase flow with microbubbles in the feed stream to improve heat and mass transfer in direct-contact membrane distillation (DCMD) processes for seawater desalination. A swirl-flow-type microbubble generator (MBG) was installed at the feed-side inlet of the DCMD module to investigate its effect on transmembrane flux. The maximum improvement in the MBG-assisted DCMD permeation flux was found to be approximately 18% at a lower feed temperature (40 degrees C) and optimal air flow rate (50 cc/min), and an optimal MBG geometry comprising a swirler, a nozzle tip of diameter 2 mm, and a diffuser at an angle of 30 degrees. The results were observed to be related to the number density of microbubbles less than 100 mu m in size, which plays an important role in improving heat and mass transfer in two-phase flow. In addition, the simulation results based on conventional heat transfer correlations of bubbly flow underestimated the experimental results. Therefore, this study also aims to propose and verify a new two-phase flow heat transfer correlation. The proposed correlation considers the effects of bubble size distribution to accurately predict the performance of MBG-assisted DCMD processes.

Automated summary

This study provides a comprehensive overview of using gas-liquid two-phase flow with microbubbles to enhance heat and mass transfer in seawater desalination using direct-contact membrane distillation (DCMD). A swirl-flow-type microbubble generator was installed at the feed-side inlet of the DCMD module, and the results showed an 18% increase in permeation flux at a lower feed temperature and optimal air flow rate. The study also proposes a new heat transfer correlation that considers bubble size distribution to accurately predict the performance of MBG-assisted DCMD processes.