Integrated Valorization of Desalination Brine through NaOH Recovery: Opportunities and Challenges

Kumar, Amit; Phillips, Katherine R.; Cai, Janny; Schröder, Uwe; Lienhard, John H.

doi:10.1002/ange.201810469

Cited by 9 publications

(3 citation statements)

References 71 publications

(178 reference statements)

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“…Despite the economic and environmental benefits of the BMED process, the industrial implementation of BMED technology is currently far behind the other pressure-driven membrane processes or the conventional electrodialysis. 12,37,38 To our knowledge, the sluggish development of the BMED is attributed to the large consumption of the expensive bipolar membranes and the unmatching behavior between water splitting and ion migration. 39 On one hand, the BMED is usually assembled in a plate-and-frame membrane module that the effective area of each piece of bipolar membrane is identical to that of the monopolar membrane.…”

Section: Introductionmentioning

confidence: 99%

Asymmetric bipolar membrane electrodialysis for acid and base production

Wang

Yan

et al. 2022

AIChE Journal

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Bipolar membrane electrodialysis (BMED) is a promising technique for upgrading traditional manufacturing procedures and achieving a circular economy. However, the industrial applications of BMED technology have been restricted by the large consumption of expensive bipolar membranes and the unmatching behavior between water splitting and ion migration. Herein, we proposed a novel asymmetric bipolar membrane electrodialysis (ABMED) to regulate the water splitting in the bipolar membrane and orientational ion migration in the electrodialysis (ED). It was found that the ABMED exhibited comparable performances to BMED for acid/base production when the area of the bipolar membrane was reduced to 50% of the monopolar membrane.

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Section: Introductionmentioning

confidence: 99%

Asymmetric bipolar membrane electrodialysis for acid and base production

Wang

Yan

et al. 2022

AIChE Journal

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“…It stems from these studies ,− that BMED is a potentially eco-friendly, cost-effective method for SWRO brine management, yet techno-economical barriers and the lack of sufficient knowledge still limit the application of BMED on an industrial scale . Indeed, very few studies ,,, have included an economic evaluation related to the production of an acid and base from SWRO brine by BMED. Thiel et al emphasized that using real SW concentrated streams (pretreated by NF or other methods) is critical for determining the techno-economic feasibility of BMED.…”

Section: Introductionmentioning

confidence: 99%

Decreasing Seawater Desalination Footprint by Integrating Bipolar-Membrane Electrodialysis in a Single-Pass Reverse Osmosis Scheme

Chaudhury

Harlev

Haim

et al. 2021

ACS Sustainable Chem. Eng.

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Reverse osmosis (RO) is currently the most costefficient method for seawater (SW) desalination; however, producing high-quality water with a low boron concentration typically requires a two-pass process, which increases the required area and chemical consumption. We propose a sustainable and economic pathway for boron removal in a single RO step, thus reducing the area footprint. At the same time, chemicals are produced onsite from the RO brine using bipolar membrane electrodialysis (BMED), thus reducing the chemical footprint. We conducted BMED using natural and synthetic feed solutions and studied the acid and base production kinetics and electricity consumption to assess the feasibility. In terms of energy efficiency, the divalent cationic impurities in the feed are more detrimental than the anionic ones. We found that monoselective cation-exchange membranes are not efficacious in eliminating these, and hence, precipitation/nanofiltration before BMED is essential. As a BMED feed, the nanofiltered SWRO brine was the best option over SW or nanofiltered SW. Economical analysis shows that as compared to purchasing chemicals, BMED integration can reduce the process cost by 45%. In addition, the results point to the flexibility of the proposed design that increases its robustness toward fluctuation in chemicals and electricity prices.

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“…BMED is an advanced electro-membrane process that combines the water splitting in the bipolar membrane and directional migration of ionic components in the conventional electrodialysis process [11,12]. The saline wastewater inputted to the BMED system can be effectively converted to acids and bases, achieving a closed loop industrial production.…”

Section: Introductionmentioning

confidence: 99%

In-Situ Combination of Bipolar Membrane Electrodialysis with Monovalent Selective Anion-Exchange Membrane for the Valorization of Mixed Salts into Relatively High-Purity Monoprotic and Diprotic Acids

Yan

Li²,

Zhou

et al. 2020

Membranes

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The crystalized mixed salts from the zero liquid discharge process are a hazardous threat to the environment. In this study, we developed a novel electrodialysis (SBMED) method by assembling the monovalent selective anion-exchange membrane (MSAEM) into the bipolar membrane electrodialysis (BMED) stack. By taking the advantages of water splitting in the bipolar membrane and high perm-selectivity of MSAEM for the Cl− ions against the SO42− ions, this combination allows the concurrent separation of Cl−/SO42− and conversion of mixed salts into relatively high-purity monoprotic and diprotic acids. The current density has a significant impact on the acid purity. Both the monoprotic and diprotic acid purities were higher than 80% at a low current density of 10 mA/cm2. The purities of the monoprotic acids decreased with an increase in the current density, indicating that the perm-selectivity of MSAEM decreases with increasing current density. An increase in the ratio of monovalent to divalent anions in the feed was beneficial to increase the purity of monoprotic acids. High-purity monoprotic acids in the range of 93.9–96.1% were obtained using this novel SBMED stack for treating simulated seawater. Therefore, it is feasible for SBMED to valorize the mixed salts into relatively high-purity monoprotic and diprotic acids in one step.

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Integrated Valorization of Desalination Brine through NaOH Recovery: Opportunities and Challenges

Cited by 9 publications

References 71 publications

Asymmetric bipolar membrane electrodialysis for acid and base production

Asymmetric bipolar membrane electrodialysis for acid and base production

Decreasing Seawater Desalination Footprint by Integrating Bipolar-Membrane Electrodialysis in a Single-Pass Reverse Osmosis Scheme

In-Situ Combination of Bipolar Membrane Electrodialysis with Monovalent Selective Anion-Exchange Membrane for the Valorization of Mixed Salts into Relatively High-Purity Monoprotic and Diprotic Acids

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