Abstract
Wetting and temperature polarization (TP) are two critical issues that are closely associated with the lifespan and production efficiency in membrane distillation (MD). An ideal MD membrane should be wetting resistant with low TP. Although great achievements were made to date in MD design, maintaining wetting resistance and low TP is still challenging. This study developed a facile and effective strategy to construct a high-performance hierarchical MD membrane by spraying carbon nanotubes (CNTs) on both sides of a pristine PTFE membrane (PTFE-dCNTs membrane, d stands for double layers). Spray coating the pristine PTFE membrane by less than 800 nm thick CNTs double-layers enhanced the water flux by 1.6 fold (52.3 LMH) and increased the wetting resistance time by 2.2-fold (51.1 h) with a temperature difference of 40 °C (feed of 60 °C and permeate of 20 °C). With optimized CNTs coating density, the PTFE-dCNT (2) membrane displays a water flux as high as 126 L m−2 h−1 with a salt rejection rate of 99.9% under the temperature difference of 60 °C in direct contact MD, surpassing most of the reported MD membranes. Experimental and simulation results demonstrate that a unique sandwich structure of MD membrane having thermal conductive and wetting resistant layers on both sides of membranes is beneficial to enhance the water flux and operation stability by suppressing temperature polarization and membrane wetting on both sides in direct contact MD. The strategy proposed here can be extended to a wide range of materials, holding a great potential to fabricate high-efficiency MD membranes.
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