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采用单价选择性阴离子交换膜的电渗析法对含活性染料和无机盐的水性混合物进行分离的适用性

Suitability of Electrodialysis with Monovalent Selective Anion-Exchange Membranes for Fractionation of Aqueous Mixture Containing Reactive Dye and Mineral Salt.

作者信息

Majewska-Nowak Katarzyna, Ahmed Arif Eftekhar, Grzegorzek Martyna, Baraniec Karolina

机构信息

Faculty of Environmental Engineering, Wrocław University of Science and Technology, Wybrzeże Wyspiańskiego 27, 50-370 Wrocław, Poland.

NIRAS, Strzegomska 138, 54-429 Wrocław, Poland.

出版信息

Membranes (Basel). 2025 Mar 7;15(3):85. doi: 10.3390/membranes15030085.

DOI:10.3390/membranes15030085
PMID:40137037
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11943749/
Abstract

To fulfil the goals of the circular economy, the treatment of textile wastewater should be focused on the recovery of valuable components. Monovalent anion-selective electrodialysis (MASED) was applied for the separation of reactive dyes from mineral salts. Standard cation-exchange membranes (CM membranes) and monovalent selective anion-exchange membranes (MVA membranes) were used in the electrodialysis (ED) stack. The separation efficiency was evaluated for model solutions of various reactive dyes (varying in molecular weight and chemical reactivity) containing NaCl. In the course of MASED, the mineral salt was successfully removed from the dye solutions with an efficacy of 97.4-99.4%, irrespectively of the composition of the treated solution. The transport of dye molecules through the ion-exchange membranes (IEMs) from diluate to concentrate compartments was irrelevant. Nonetheless, a significant adsorption of dye particles on the membranes was observed. Around 11-40% of the initial dye mass was deposited in the ED stack. Dye adsorption intensity was significantly affected by dye reactivity. This study showed the potential of the MASED process for the separation of the reactive dye from the mineral salt on condition that antifouling membrane properties are improved. The obtained streams (the concentrate rich in mineral salt and the diluate containing the reactive dye) can be reused in the dye-house textile operations; however, some loss of dye mass should be included.

摘要

为实现循环经济目标,纺织废水处理应聚焦于有价值成分的回收。采用单价阴离子选择性电渗析(MASED)从矿物盐中分离活性染料。电渗析(ED)堆栈中使用了标准阳离子交换膜(CM膜)和单价选择性阴离子交换膜(MVA膜)。对含有NaCl的各种活性染料(分子量和化学反应性不同)的模型溶液评估了分离效率。在MASED过程中,无论处理溶液的组成如何,矿物盐均能成功从染料溶液中去除,去除率为97.4 - 99.4%。染料分子从稀释室通过离子交换膜(IEMs)向浓缩室的传输无关紧要。尽管如此,观察到染料颗粒在膜上有显著吸附。约11 - 40%的初始染料质量沉积在ED堆栈中。染料吸附强度受染料反应性的显著影响。本研究表明,在改善防污膜性能的条件下,MASED工艺具有从矿物盐中分离活性染料的潜力。所得物流(富含矿物盐的浓缩物和含有活性染料的稀释物)可在染厂纺织作业中再利用;然而,应考虑到染料质量的一些损失。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/55b5/11943749/63c90c2b3f43/membranes-15-00085-g012.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/55b5/11943749/183261759a91/membranes-15-00085-g013.jpg
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本文引用的文献

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Evaluation of Electrodialysis Desalination Performance of Novel Bioinspired and Conventional Ion Exchange Membranes with Sodium Chloride Feed Solutions.
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Membranes (Basel). 2021 Mar 19;11(3):217. doi: 10.3390/membranes11030217.
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