Conductive Fe3O4/PANI@PTFE membrane for high thermal efficiency in interfacial induction heating membrane distillation

膜蒸馏 材料科学 聚苯胺 聚四氟乙烯 化学工程 涂层 复合材料 导电体 聚合物 海水淡化 聚合 遗传学 生物 工程类
作者
Weihua Qing,Zhifeng Hu,Qingquan Ma,Wen Zhang
出处
期刊:Nano Energy [Elsevier BV]
卷期号:89: 106339-106339 被引量:49
标识
DOI:10.1016/j.nanoen.2021.106339
摘要

Conventional membrane distillation (MD) undergoes interfacial temperature polarization and thus may suffer from a reduced thermal efficiency when using the hot saline water as the primary thermal driver. To address this issue, this study employed a conductive Fe3O4/polyaniline (PANI) coated polytetrafluoroethylene (Fe3O4/[email protected]) membrane to achieve local interfacial heating under electromagnetic induction and promote the thermal efficiency of direct-contact MD (DCMD). Induction-responsive Fe3O4 nanoparticles were dispersed in a conductive PANI polymer matrix that binds to the hydrophobic porous PTFE membrane by spray coating. Dispersing Fe3O4 nanoparticles in a conductive PANI polymer matrix doubled the heating efficiency (2.0 °C s−1) than directly dispersing Fe3O4 nanoparticles onto PTFE without PANI (1.1 °C s−1). This enhanced heating efficiency is ascribed to the formation of multiple conductive pathways or eddy current channels via the conductive polymer networks. A parametric study of the DCMD performance revealed that the permeate flux increased from 0.7 to 3.4 L m−2 h−1 with the increase of the coolant flow velocity (1.4–22.9 cm min−1) and induction power (0.9–3.6 kW). However, increasing the feed (3.5 wt% NaCl solution) flow velocity (1.4–8.6 cm min−1) significantly reduced the permeate flux from 5.0 to 1.6 L m−2 h−1 due to the insufficient time of water/membrane contact for mass transfer. Moreover, thermal and mass transport processes at the induction-heated membrane interface were analyzed by finite element analysis (FEA), which matched well the experimental results and determined the thermal efficiency up to 88% as opposed to the reported levels (20–58%) for the conventional DCMD. Our study laid additional foundation for induction-heating DCMD by devising new composite membrane materials and new interfacial thermal and mass transfer mechanisms.
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