Waterwheel-inspired rotating evaporator for efficient and stable solar desalination even in saturated brine

[Display omitted] Solar desalination is one of the most promising technologies to address global freshwater shortages. However, traditional evaporators encounter the bottleneck of reduced evaporation rate or even failure due to salt accumulation in high-salinity water. Inspired by ancient waterwheel...

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Veröffentlicht in:	Science bulletin 2023-08, Vol.68 (15), p.1640-1650
Hauptverfasser:	Jiang, Hanjin, Liu, Xinghang, Wang, Haitao, Wang, Dewen, Guo, Yanan, Wang, Dong, Gao, Gang, Wang, Xiaoyi, Hu, Chaoquan
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Sprache:	eng
Schlagworte:	Adaptively rotating evaporator Self-removal of salt Stable solar desalination Waterwheel-inspired
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container_title	Science bulletin
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creator	Jiang, Hanjin Liu, Xinghang Wang, Haitao Wang, Dewen Guo, Yanan Wang, Dong Gao, Gang Wang, Xiaoyi Hu, Chaoquan
description	[Display omitted] Solar desalination is one of the most promising technologies to address global freshwater shortages. However, traditional evaporators encounter the bottleneck of reduced evaporation rate or even failure due to salt accumulation in high-salinity water. Inspired by ancient waterwheels, we have developed an adaptively rotating evaporator that enables long-term and efficient solar desalination in brines of any concentration. The evaporator is a sulphide-loaded drum-type biochar. Our experiments and numerical simulations show that this evaporator, thanks to its low density and unique hydrophilic property, rotates periodically under the center-of-gravity shift generated by salt accumulation, achieving self-removal of salt. This allows it to maintain a high evaporation rate of 2.80 kg m−2 h−1 within 24 h even in saturated brine (26.47%), which was not achieved previously. This proof-of-concept work therefore demonstrates a concentration- and time-independent, self-rotation-induced solar evaporator.
doi_str_mv	10.1016/j.scib.2023.07.011
format	Article
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However, traditional evaporators encounter the bottleneck of reduced evaporation rate or even failure due to salt accumulation in high-salinity water. Inspired by ancient waterwheels, we have developed an adaptively rotating evaporator that enables long-term and efficient solar desalination in brines of any concentration. The evaporator is a sulphide-loaded drum-type biochar. Our experiments and numerical simulations show that this evaporator, thanks to its low density and unique hydrophilic property, rotates periodically under the center-of-gravity shift generated by salt accumulation, achieving self-removal of salt. This allows it to maintain a high evaporation rate of 2.80 kg m−2 h−1 within 24 h even in saturated brine (26.47%), which was not achieved previously. 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subjects	Adaptively rotating evaporator Self-removal of salt Stable solar desalination Waterwheel-inspired
title	Waterwheel-inspired rotating evaporator for efficient and stable solar desalination even in saturated brine
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