直接缺氧纳滤除铁除锰技术用于间接饮用水回用

IF 0.8 4区工程技术 Q4 ENGINEERING, CHEMICAL

Membrane Water Treatment Pub Date : 2019-07-01 DOI:10.12989/MWT.2019.10.4.299

Yongxun Jin, Yeseul Choi, K. Song, Soyoun Kim, Chanhyuk Park

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引用次数: 3

摘要

作为传统水资源的替代方案，有管理的含水层补给系统越来越受到人们的关注。然而，当在MAR系统中回收水时，溶解的铁和锰物种可能很容易氧化，它们会导致井筛堵塞或需要废弃提取井。在本研究中，分析了好氧和缺氧条件，以验证膜过滤性能在各种溶液化学条件下的可行性。利用合成废水研究了缺氧条件下金属离子的污染机理。然后通过SEM和XPS对被污染的膜进行进一步分析，以验证无机污染的主要原因。最新提出的缺氧工艺精炼现有膜工艺有望提供更多关于纳滤（NF）膜污染的宝贵信息，特别是为了证明无化学物质饮用水生产用于间接饮用水再利用的潜在优势。

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Iron and manganese removal in direct anoxic nanofiltration for indirect potable reuse

Managed aquifer recharge (MAR) systems are gaining interest as an alternative to conventional water resources. However, when the water recovered in MAR systems, dissolved iron and manganese species may easily oxidize and they cause well screen clogging or require abandonment of extraction wells. In this study, both oxic and anoxic conditions were analyzed to verify the feasibility of the membrane filtration performance under various solution chemistries. The fouling mechanisms of the metal ions under anoxic conditions were also investigated by employing synthetic wastewater. The fouled membranes were then further analyzed to verify the major causes of inorganic fouling through SEM and XPS. The newly suggested anoxic process refining existing membrane process is expected to provide more precious information about nanofiltration (NF) membrane fouling, especially for demonstrating the potential advantages to chemical-free drinking water production for indirect potable reuse.

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来源期刊

Membrane Water Treatment ENGINEERING, CHEMICAL-WATER RESOURCES

CiteScore

1.90

自引率

30.00%

发文量

审稿时长

>12 weeks

期刊介绍： The Membrane and Water Treatment(MWT), An International Journal, aims at opening an access to the valuable source of technical information and providing an excellent publication channel for the global community of researchers in Membrane and Water Treatment related area. Specific emphasis of the journal may include but not limited to; the engineering and scientific aspects of understanding the basic mechanisms and applying membranes for water and waste water treatment, such as transport phenomena, surface characteristics, fouling, scaling, desalination, membrane bioreactors, water reuse, and system optimization.