Improved thin-film-composite forward-osmosis membrane for coal mine water purification

During the emergency rescue, such as coal mining disasters, potable water was the primary factor to ensure the safety of people trapped underground, and it was easy to be obtained by the filtration of coal mine water. As a membrane separation technology, forward osmosis (FO) membranes were expected...

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Published in:Materials chemistry and physics 2022-05, Vol.283, p.126011, Article 126011
Main Authors: Liu, Eryong, Jing, Weiqi, Zhang, Xing, Du, Shuangming, Zeng, Zhixiang, Zhu, Lijing, Du, Huiling
Format: Article
Language:English
Subjects:
Coal mine water
Coal mines
Coal mining
Compound modification
Contact angle
Disaster management
Drinking water
Emergencies
Emergency filtration
Filtration
Forward osmosis membrane
Hydrophilicity
Interfacial bonding
Membrane separation
Membranes
Mine waters
Osmosis
Polyamide resins
Polysulfone resins
Polyvinyl alcohol
Purification performance
Rejection
Rescue operations
Thin films
Titanium dioxide
Water purification
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container_start_page 126011
container_title Materials chemistry and physics
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creator Liu, Eryong
Jing, Weiqi
Zhang, Xing
Du, Shuangming
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Zhu, Lijing
Du, Huiling
description During the emergency rescue, such as coal mining disasters, potable water was the primary factor to ensure the safety of people trapped underground, and it was easy to be obtained by the filtration of coal mine water. As a membrane separation technology, forward osmosis (FO) membranes were expected to be used in the emergency filtration of coal mine water with higher contents of SO42− and F−. In this paper, a thin film composite (TFC) FO membrane was prepared by phase conversion and interfacial bonding methods, and the influence of compound modification by TiO2, polyvinyl alcohol (PVA) and polydopamine (PDA) on the morphology and permeability of the TFC FO membrane was studied. The results show that the large size TiO2 (50 nm) was only physically deposited on the polysulfone (PSF) membrane, and PVA increased the binding strength of the PDA membrane to the polyamide (PA) membrane. As a result, 2 wt% TiO2 and 2 wt% PVA and PDA co-doping led to a low water contact angle of 27° and a high FO water flux performance of 12.9 LM−2H−1 using a 2 M NaCl draw solution. Furthermore, the composite membrane showed better hydrophilicity, and the rejection of SO42− and F− were 92.1% and 89.3%, respectively, indicating that TiO2 improved the internal channels of the TFC FO membrane and PVA and PDA increased the hydrophilicity of the PA layer. Therefore, the novel TFC FO membrane exhibited good rejection and reproducibility, and this study demonstrated that TFC FO membrane was a good candidate for the emergency filtration of coal mine water. [Display omitted] •FO membranes were expected to be used in the emergency filtration of coal mine water with SO42− and F−.•FO membranes with compound modification by TiO2, PVA and PDA exhibited good rejection and reproducibility.•The composite membranes showed better hydrophilicity in coal mine water and rejection with SO42− and F−.
doi_str_mv 10.1016/j.matchemphys.2022.126011
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subjects Coal mine water
Coal mines
Coal mining
Compound modification
Contact angle
Disaster management
Drinking water
Emergencies
Emergency filtration
Filtration
Forward osmosis membrane
Hydrophilicity
Interfacial bonding
Membrane separation
Membranes
Mine waters
Osmosis
Polyamide resins
Polysulfone resins
Polyvinyl alcohol
Purification performance
Rejection
Rescue operations
Thin films
Titanium dioxide
Water purification
title Improved thin-film-composite forward-osmosis membrane for coal mine water purification
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