Reverse Electrodialysis: Potential Reduction in Energy and Emissions of Desalination

Tristán, Carolina; Fallanza, Marcos; Ibáñez, Raquel; Ortiz, Inmaculada

doi:10.3390/app10207317

Cited by 9 publications

(4 citation statements)

References 49 publications

(54 reference statements)

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“…As its name suggests, RED is the opposite process of electrodialysis (ED). So, in RED (Figure 1b), when a low salinity solution, such as river water or wastewater, and a high salinity solution, such as brine, are faced, the difference in concentrations generates ion flux between the different compartments, which generates an electric current between the anode and the cathode [25]. The magnitude of the electric current obtained is dependent on the difference of the concentrations of the input streams and the number of cell pairs (repetitive units) in the stack, among other parameters.…”

Section: Electro-membrane Technologies: Current Status and Challengesmentioning

confidence: 99%

“…Tristan et al [71] estimated the maximum SGE available in terms of net power density and the net specific energy delivered by a RED system in six SWRO desalination plants distributed worldwide, obtaining net specific energy maximum values in the range of 0.08-0.15 kWh•m −3 of desalted water and net power densities up to 3.7 W•m −2 . Moreover, recent studies [25] concluded that if all the salinity gradient energy is harnessed,~40% of the energy demand of an SWRO facility could be supplied; however, a reduction to the 10% of the supply is estimated due to the energy conversion irreversibility and untapped salinity gradient energy.…”

Section: Alternative A2-salinity Gradient Energy Harvestingmentioning

confidence: 99%

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Chemical and Energy Recovery Alternatives in SWRO Desalination through Electro-Membrane Technologies

Herrero-Gonzalez

Ibáñez

2021

Applied Sciences

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Electro-membrane technologies are versatile processes that could contribute towards more sustainable seawater reverse osmosis (SWRO) desalination in both freshwater production and brine management, facilitating the recovery of materials and energy and driving the introduction of the circular economy paradigm in the desalination industry. Besides the potential possibilities, the implementation of electro-membrane technologies remains a challenge. The aim of this work is to present and evaluate different alternatives for harvesting renewable energy and the recovery of chemicals on an SWRO facility by means of electro-membrane technology. Acid and base self-supply by means of electrodialysis with bipolar membranes is considered, together with salinity gradient energy harvesting by means of reverse electrodialysis and pH gradient energy by means of reverse electrodialysis with bipolar membranes. The potential benefits of the proposed alternatives rely on environmental impact reduction is three-fold: (a) water bodies protection, as direct brine discharge is avoided, (b) improvements in the climate change indicator, as the recovery of renewable energy reduces the indirect emissions related to energy production, and (c) reduction of raw material consumption, as the main chemicals used in the facility are produced in-situ. Moreover, further development towards an increase in their technology readiness level (TRL) and cost reduction are the main challenges to face.

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Section: Electro-membrane Technologies: Current Status and Challengesmentioning

confidence: 99%

Section: Alternative A2-salinity Gradient Energy Harvestingmentioning

confidence: 99%

Chemical and Energy Recovery Alternatives in SWRO Desalination through Electro-Membrane Technologies

Herrero-Gonzalez

Ibáñez

2021

Applied Sciences

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“…Different integration of these pressure driven membrane processes have been applied in a variety of wastewater treatment settings: particularly MF and UF as pretreatment to other unit processes [ 2 ]. Compared to the alternatives of electrodialysis and reverse electrodialysis—which are promising desalination technologies that can transform salinity gradient energy into electricity [ 2 , 3 , 4 ]—electrodialysis shows a relatively higher total organic carbon rejection than nanofiltration [ 3 ] but it is still prone to organic and inorganic fouling. Meanwhile, pretreatment with coagulation can enhance organic removal efficacy by the UF process [ 2 ].…”

Section: Introductionmentioning

confidence: 99%

Effects of Chemical Cleaning on the Ageing of Polyvinylidene Fluoride Microfiltration and Ultrafiltration Membranes Fouled with Organic and Inorganic Matter

et al. 2022

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Herein, the effects of cleaning with sodium hydroxide and citric acid solutions as cleaning reagents on the changes in the properties of two hollow-fiber PVDF microfiltration (MF) and ultrafiltration (UF) membranes fouled with organic and inorganic matter were investigated. Accelerated membrane ageing was induced by use of high concentrations of tannic acid and iron oxide (Fe2O3) particles in the feed water; these conditions were kept with different membrane soaking times to observe temporal effects. It was found that tannic acid molecules adsorb onto the membrane surface that results in changes in surface characteristics, particularly surface functional groups that are responsible for enhancing membrane’s hydrophilicity. Experimental results demonstrate that NaOH had a stronger effect on the tensile strength and surface chemistry of the fouled MF and UF membranes than citric acid. Prediction of lifetime by an exponential (decay) model confirmed that the UF membrane cleaned with NaOH would be aged within about 1.8 years and the MF membrane after about 5 years, at cleaning every 15 days, downtime 2 h per cleaning, when a 10% tensile strength decrease against the original membrane is allowed.

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“…The authors published in 2020 a review evaluating advantages and disadvantages of well-known membrane separation materials based on particle size, usually exposed to a large amount of water, versus dense hydrophobic membranes with targeted transport of contaminants through a selective barrier [ 19 , 20 , 21 ]. Electrodialysis (ED) with porous membrane has shown interesting membrane separation applications [ 22 , 23 ] in terms of valuable compound recovery from wastewater [ 17 , 24 , 25 , 26 ]. However, there are many challenges to overcome for a real full-scale application such as adsorbed pollutants on an ionic membrane, weak separation of macromolecules due to excursive membranes [ 24 ], low productivity and energy demanding, polarisation and fouling phenomena [ 25 ], and complex experimental setup (electrode, cationic and anionic membranes, and elution solution).…”

Section: Introductionmentioning

confidence: 99%

Removal of Ibuprofen from Water by Different Types Membranes

et al. 2021

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Ibuprofen separation from water by adsorption and pertraction processes has been studied, comparing 16 different membranes. Tailor-made membranes based on Matrimid, Ultem, and diaminobenzene/diaminobenzoic acid with various contents of zeolite and graphene oxide, have been compared to the commercial polystyrene, polypropylene, and polydimethylsiloxane polymeric membranes. Experimental results revealed lower ibuprofen adsorption onto commercial membranes than onto tailor-made membranes (10–15% compared to 50–70%). However, the mechanical stability of commercial membranes allowed the pertraction process application, which displayed a superior quantity of ibuprofen eliminated. Additionally, the saturation of the best-performing commercial membrane, polydimethylsiloxane, was notably prevented by atomic layer deposition of (3-aminopropyl)triethoxysilane.

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Reverse Electrodialysis: Potential Reduction in Energy and Emissions of Desalination

Cited by 9 publications

References 49 publications

Chemical and Energy Recovery Alternatives in SWRO Desalination through Electro-Membrane Technologies

Chemical and Energy Recovery Alternatives in SWRO Desalination through Electro-Membrane Technologies

Effects of Chemical Cleaning on the Ageing of Polyvinylidene Fluoride Microfiltration and Ultrafiltration Membranes Fouled with Organic and Inorganic Matter

Removal of Ibuprofen from Water by Different Types Membranes

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