Physicochemical model for simulating the chemical processes during the crystallization of minerals from spent ion exchange regenerant

IF 4.5 3区 工程技术 Q1 WATER RESOURCES
Marc Arpad Boncz , Niels van Linden , Amir Haidari , Yundan Wang , Henri Spanjers
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引用次数: 2

Abstract

Traditionally, industrial processes produce wastes that, even though often containing useful materials, are discarded, contributing to environmental pollution and depletion of natural resources. An example of such wastes are brines, flows of concentrated salts, produced in water treatment processes, which are now routinely discharged into receiving water bodies. Brines however can also be considered as flows of reusable materials which should be recovered, and the Zero Brine cooperation project aims to develop processes for that purpose. For a demineralized water production plant in the port of Rotterdam (the Netherlands), a closed water processing cycle was proposed to treat the large volume of spent Ion Exchange (IEX) regenerant brine which, apart from recovering demineralized water, is also intended to produce magnesium (Mg2+) and calcium (Ca2+) salts, with the highest purity possible, from the otherwise discharged brine. The process scheme includes nanofiltration (NF) for separating mono- and multivalent ions, followed by sequential chemical precipitation of Mg2+ and Ca2+ ions from the NF concentrate, and production of demineralized water by evaporation of the NF permeate. The concentrate of monovalent ions produced in the evaporator, essentially a concentrated sodium chloride solution, in its turn might be reused for IEX regeneration. Part of the supernatant of the sequential precipitation may be fed to the evaporator as well, but bleeding the other part of this supernatant is essential in order to maintain process stability, avoid accumulation of minor pollutants, and reduce scaling. In this study, various scenarios to operate the process were modeled, using PHREEQC and Excel. According to the simulation results, recovery of ≈97% of Mg2+ and Ca2+ is possible, the latter with a higher purity than the former. The main factors affecting the results are the concentration of carbonate present in the spent IEX regenerant, as well as characteristics of the NF membrane and the dosing of sodium hydroxide in the sequential precipitation steps. The results of the simulations were used for the design and operation of a pilot plant, comprising all mentioned process steps.

模拟废离子交换再生剂矿物结晶过程的物理化学模型
传统上,工业过程产生的废物,即使经常含有有用的材料,也被丢弃,造成环境污染和自然资源枯竭。这种废物的一个例子是盐水,即水处理过程中产生的浓缩盐流,现在通常排放到接收水体中。然而,卤水也可以被视为应被回收的可重复使用材料的流动,零卤水合作项目旨在为此目的开发工艺。对于鹿特丹港(荷兰)的一家脱盐水生产厂,提出了一个封闭的水处理循环来处理大量的离子交换(IEX)再生盐水,除了回收脱盐水外,还打算从排放的盐水中生产纯度最高的镁(Mg2+)和钙(Ca2+)盐。该工艺方案包括纳滤(NF)分离单价和多价离子,然后从纳滤浓缩物中依次化学沉淀Mg2+和Ca2+离子,然后通过纳滤渗透物蒸发生产脱盐水。蒸发器中产生的一价离子浓缩液,基本上是浓缩的氯化钠溶液,又可用于IEX再生。顺序沉淀的部分上清液也可能被送入蒸发器,但为了保持工艺稳定性、避免小污染物的积累和减少结垢,必须排出该上清液的另一部分。在本研究中,使用PHREEQC和Excel对操作过程的各种场景进行了建模。模拟结果表明,Mg2+和Ca2+的回收率可达约97%,且Ca2+的纯度高于Mg2+。影响结果的主要因素是废IEX再生剂中碳酸盐的浓度、纳滤膜的特性和顺序沉淀步骤中氢氧化钠的投加量。模拟的结果用于中试装置的设计和运行,包括上述所有工艺步骤。
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来源期刊
Water Resources and Industry
Water Resources and Industry Social Sciences-Geography, Planning and Development
CiteScore
8.10
自引率
5.90%
发文量
23
审稿时长
75 days
期刊介绍: Water Resources and Industry moves research to innovation by focusing on the role industry plays in the exploitation, management and treatment of water resources. Different industries use radically different water resources in their production processes, while they produce, treat and dispose a wide variety of wastewater qualities. Depending on the geographical location of the facilities, the impact on the local resources will vary, pre-empting the applicability of one single approach. The aims and scope of the journal include: -Industrial water footprint assessment - an evaluation of tools and methodologies -What constitutes good corporate governance and policy and how to evaluate water-related risk -What constitutes good stakeholder collaboration and engagement -New technologies enabling companies to better manage water resources -Integration of water and energy and of water treatment and production processes in industry
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