Biological Ion Exchange for Natural Organic Matter Removal from Drinking Water

IF 11.4 1区环境科学与生态学 Q1 ENGINEERING, ENVIRONMENTAL

Water Research Pub Date : 2025-04-25 DOI:10.1016/j.watres.2025.123722

Karl Zimmermann, Klaas Schoutteten, Zhen Liu, William Chen, Pierre Bérubé, Madjid Mohseni, Benoit Barbeau

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引用次数: 0

Abstract

The state of knowledge for ion exchange (IEX) drinking water filters is updated in this review with new understandings that allow for dramatically extending filter run length from days to months or years between regenerations. By simply allowing IEX filters to operate past chloride exhaustion, water practitioners can take advantage of continuing natural organic matter removal through a combination of sulphate-based secondary IEX and bio-removal mechanisms. Herein, we review literature and add new findings to describe all three mechanisms and their relative contributions, and provide insights to design and operate biological IEX, or ‘BIEX’, drinking water filters. Generalizing with new and literature data on 34 case studies from three continents, the chloride-based primary IEX lasted 3,100 bed volumes (BV) with 69% DOC removal, while sulphate-based secondary IEX provided an additional 24,400 BV with 51% DOC removal. Bio-removal provides 5-10% DOC removal irrespective of the IEX mechanism, although bio-removal mechanisms are less understood. Treatment performance depended on operating conditions and influent water quality, specifically the ratio of [Total Anions]-to-[DOC] concentrations in influent water, for which a linear relationship was described as

[% D O C r e m o v a l] = 0.57 - 0.0123 \times [T o t a l A n i o n s : D O C r a t i o]

$[% D O C r e m o v a l] = 0.57 - 0.0123 \times [T o t a l A n i o n s : D O C r a t i o]$ . Two models are shared to estimate filter run length either from empirical data or by minimizing the operating expenses (OPEX). While OPEX was influenced by either brine disposal or resin replacement costs depending on the system’s scale, the total costs were dominated by capital expenses. Meanwhile, resin lifetime was influenced by filter run length and regeneration, and so cleaning approaches are discussed including caustic or citric acid. Understanding the mechanisms for DOC removal and informed with empirical models to predict treatment performance and run length, our renewed knowledge of ion exchange drinking water filters enables water practitioners to capitalize on their low-maintenance and long-term treatment abilities as a tool for safe drinking water in small and large water systems worldwide.

查看原文本刊更多论文

生物离子交换法去除饮用水中的有机物质

本综述更新了有关饮用水离子交换（IEX）过滤器的知识，并提出了新的认识，使过滤器的运行时间从数天延长到数月或数年。只需让 IEX 过滤器在氯离子耗尽后继续运行，水务从业人员就可以通过结合硫酸盐二级 IEX 和生物去除机制，利用持续的天然有机物去除。在此，我们回顾了相关文献，并增加了新的研究成果，以描述这三种机制及其相对贡献，并为设计和运行生物 IEX（或称 "BIEX"）饮用水过滤器提供启示。通过对来自三大洲的 34 个案例研究的新数据和文献数据进行归纳，基于氯化物的一级 IEX 持续了 3100 个床层体积 (BV)，DOC 去除率为 69%，而基于硫酸盐的二级 IEX 则额外提供了 24400 个床层体积，DOC 去除率为 51%。尽管对生物去除机制的了解较少，但无论 IEX 机制如何，生物去除都能去除 5-10% 的 DOC。处理性能取决于运行条件和进水水质，特别是进水中[总阴离子]与[DOC]浓度之比，其线性关系为[DOC去除率%]=0.57-0.0123×[总阴离子：DOC比率][DOC去除率%]=0.57-0.0123×[总阴离子：DOC比率]。根据经验数据或通过最小化运行费用（OPEX）来估算过滤器运行长度的模型有两种。根据系统规模的不同，运行费用受盐水处理或树脂更换费用的影响，而总费用则以资本费用为主。同时，树脂寿命受过滤器运行时间和再生的影响，因此讨论了包括苛性碱或柠檬酸在内的清洁方法。了解了 DOC 的去除机制，并利用经验模型预测处理性能和运行时间，我们对离子交换饮用水过滤器有了新的认识，这使水务从业人员能够利用其低维护和长期处理能力，作为全球小型和大型供水系统的安全饮用水工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Water Research 环境科学-工程：环境

CiteScore

20.80

自引率

9.40%

发文量

1307

审稿时长

38 days

期刊介绍： Water Research, along with its open access companion journal Water Research X, serves as a platform for publishing original research papers covering various aspects of the science and technology related to the anthropogenic water cycle, water quality, and its management worldwide. The audience targeted by the journal comprises biologists, chemical engineers, chemists, civil engineers, environmental engineers, limnologists, and microbiologists. The scope of the journal include: •Treatment processes for water and wastewaters (municipal, agricultural, industrial, and on-site treatment), including resource recovery and residuals management; •Urban hydrology including sewer systems, stormwater management, and green infrastructure; •Drinking water treatment and distribution; •Potable and non-potable water reuse; •Sanitation, public health, and risk assessment; •Anaerobic digestion, solid and hazardous waste management, including source characterization and the effects and control of leachates and gaseous emissions; •Contaminants (chemical, microbial, anthropogenic particles such as nanoparticles or microplastics) and related water quality sensing, monitoring, fate, and assessment; •Anthropogenic impacts on inland, tidal, coastal and urban waters, focusing on surface and ground waters, and point and non-point sources of pollution; •Environmental restoration, linked to surface water, groundwater and groundwater remediation; •Analysis of the interfaces between sediments and water, and between water and atmosphere, focusing specifically on anthropogenic impacts; •Mathematical modelling, systems analysis, machine learning, and beneficial use of big data related to the anthropogenic water cycle; •Socio-economic, policy, and regulations studies.