A Comprehensive Method of Ion Exchange Resins Regeneration and Its Optimization for Water Treatment

Wastewater Treatment [Working Title] Pub Date : 2020-08-12 DOI:10.5772/intechopen.93429

S. Al-Asheh, A. Aidan

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引用次数: 8

Abstract

Ion exchange membranes, specifically resin technology, lie at the heart of electrolytically conductive systems used in the treatment of wastewater. This chapter deals with ion exchange deionization and the effect of resin amount as well as the concentration of acid and base on the product conductivity. The strong acidic cation polymeric exchanger resin is commercially called MERCK 104765 cation exchanger IV with capacity greater than 3.2 mmol/ml, while the strong basic anion polymeric exchanger resin is commercially called MERCK 104767 anion exchanger III with capacities greater than 1.0 mmol/ml. Water conductivity, as an indicator of regeneration efficiency, was monitored over time at the different conditions and scenario. In general, it was observed that the conductivity decreases with time until one point is reached and then starts to increase as a result of resin saturation. It was also noticed that the lowest conductivity is achieved when using 1-vol% NaOH and 5-vol% HCl in the cathodic and anodic resin tubes, respectively, and that water conductivity increases with the increase in the amount of water being used. The amount of resin significantly impacts the deionization efficiency; more ions are removed as the amount of resin increases.

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离子交换树脂再生的综合方法及其水处理优化

离子交换膜，特别是树脂技术，是用于废水处理的电解导电系统的核心。本章讨论了离子交换去离子以及树脂用量、酸碱浓度对产物电导率的影响。强酸性阳离子聚合物交换树脂商业上称为MERCK 104765阳离子交换树脂IV型，容量大于3.2 mmol/ml;强碱性阴离子聚合物交换树脂商业上称为MERCK 104767阴离子交换树脂III型，容量大于1.0 mmol/ml。水电导率作为再生效率的指标，在不同条件和场景下随时间进行监测。一般来说，我们观察到电导率随着时间的推移而下降，直到达到一个点，然后由于树脂饱和而开始增加。还注意到，当在阴极和阳极树脂管中分别使用1 vol% NaOH和5 vol% HCl时，电导率最低，并且水的电导率随着水用量的增加而增加。树脂用量对去离子效率有显著影响;随着树脂用量的增加，更多的离子被去除。

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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Wastewater Treatment [Working Title]

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