Single-stage tubular and multistage planar systems of passive permeate-side-heated solar membrane distillation

Scarcity of drinking water is a global problem and especially serious in rural areas of developing countries. Passive permeate-side-heated interfacial-heating solar membrane distillation has been shown recently as a promising system for off-grid distributed water and wastewater treatment. In this study, single-stage tubular systems were developed by giving the poly(vinylidene fluoride) (PVDF) membrane (pore size: 0.45 mu m) a tubular structure with the outer surface (i.e., the permeate side) coated with carbon black NPs which absorbed solar thermal energy and evaporated the feedwater inside the membrane tube. Under natural sunlight, the vertical tubular system had a production rate of distilled water per footprint of 0.67-2.06 kg m(-2) day(-1) throughout the year, 71% higher than the single-stage planar system on average. The three-stage planar systems were developed by overlapping three single-stage modules. Two adjacent modules shared a common copper sheet that serves as both the top of the condensation chamber of the preceding stage and the bottom of the feedwater chamber of the following stage. The copper sheet can partially transfer the condensation heat of the preceding stage to the feedwater of the following stage, thus enhancing the system energy efficiency (eta(sys) )in producing distilled water. The eta(sys) and distillate flux of the three-stage systems were 62% and 5.01 kg m(-2) day(-1), respectively, at the average daytime irradiance of 422 W m(-2), 34% higher than the single-stage planar systems.

Automated summary

Scarcity of drinking water, especially in rural areas of developing countries, is a global problem. Recently, a system called passive permeate-side-heated interfacial-heating solar membrane distillation has shown promise for off-grid distributed water and wastewater treatment. This study developed single-stage tubular systems and three-stage planar systems, which utilized solar thermal energy to evaporate the feedwater and produced distilled water, resulting in higher energy efficiency and water production compared to traditional systems.