RESEARCH PROGRESS OF ELECTRO-DRIVEN SELECTIVE MEMBRANE SEPARATION TECHNOLOGY

WU You; GAO Shu-jia; WANG Tian-yu; SUN Jing-qiu; HU Cheng-zhi

doi:10.13205/j.hjgc.202107003

Volume 39 Issue 7

Jan. 2022

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WU You, GAO Shu-jia, WANG Tian-yu, SUN Jing-qiu, HU Cheng-zhi. RESEARCH PROGRESS OF ELECTRO-DRIVEN SELECTIVE MEMBRANE SEPARATION TECHNOLOGY[J]. ENVIRONMENTAL ENGINEERING , 2021, 39(7): 30-37,115. doi: 10.13205/j.hjgc.202107003

Citation:

WU You, GAO Shu-jia, WANG Tian-yu, SUN Jing-qiu, HU Cheng-zhi. RESEARCH PROGRESS OF ELECTRO-DRIVEN SELECTIVE MEMBRANE SEPARATION TECHNOLOGY[J]. ENVIRONMENTAL ENGINEERING , 2021, 39(7): 30-37,115. doi: 10.13205/j.hjgc.202107003

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RESEARCH PROGRESS OF ELECTRO-DRIVEN SELECTIVE MEMBRANE SEPARATION TECHNOLOGY

doi: 10.13205/j.hjgc.202107003

WU You^1,2,
GAO Shu-jia^1,3,
WANG Tian-yu¹,
SUN Jing-qiu^1,2,
HU Cheng-zhi^{1,2,3
,
,}

1. Key Laboratory of Drinking Water Science and Technology, Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing 100085, China;
2. University of Chinese Academy of Sciences, Beijing 100049, China;
3. Guangxi Key Laboratory of Environmental Pollution Control Theory and Technology, Guilin University of Technology, Guilin 541004, China

Received Date: 2021-02-20
Available Online: 2022-01-18

Abstract

Abstract

The recovery of resource and energy in sewage and wastewater is an important part of building a low-carbon society. Electro-driven membrane separation is an effective way to realize the resource utilization of sewage and wastewater, which combines electrochemistry with membrane separation technology, and enhances membrane separation effect by adjusting electric field or electrode potential. And it is expected to break through the technical bottlenecks of membrane fouling, weak selective separation and trade-off effect. The concept of electro-driven membrane separation was proposed for the first time, and the electro-driven membrane separation was divided into electrical control membrane separation, electrodialysis and membrane capacitance deionization. This paper focused on the recovery of valuable substances in wastewater via selective membrane separation, so as to realize the recycling of wastewater. Firstly, the basic research progress of electro-driven membrane separation technology was introduced. Then, the research progress of electro-controlled membrane separation, electrodialysis and membrane capacitor deionization was reviewed and summarized from the perspectives of membrane/electrode material innovation and process optimization. Finally, the future development direction of the technology was prospected from three aspects:basic research, material innovation and reactor development.
- electro-driven membrane separation,
- electrochemical water treatment,
- conductive membrane,
- membrane fouling,
- wastewater utilization

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References(65)

References

[1]	USEPA.Wastewater Management Fact Sheet:Energy Conservation[S].EPA 832-F-06-024,2006.
[2]	XIE M,SHON H K,GRAY S R,et al.Membrane-based processes for wastewater nutrient recovery:technology,challenges,and future direction[J].Water Research,2016,89:210-221.
[3]	MCCARTY P L,BAE J,KIM J.Domestic wastewater treatment as a net energy producer-can this be achieved?[J].Environmental Science & Technology,2011,45(17):7100-7106.
[4]	隋冰.膜分离技术在环境工程中的应用现状及发展前景[J].中国战略新兴产业,2018(12):161.
[5]	胡承志,刘会娟,曲久辉.电化学水处理技术研究进展[J].环境工程学报,2018,12(3):677-696.
[6]	TANG W W,HE D,ZHANG C Y,et al.Optimization of sulfate removal from brackish water by membrane capacitive deionization (MCDI)[J].Water Research,2017,121:302-310.
[7]	WEIDLICH C,MANGOLD K M.Electrochemically switchable polypyrrole coated membranes[J].Electrochimica Acta,2011,56(10):3481-3484.
[8]	DUDCHENKO A V,ROLF J,RUSSELL K,et al.Organic fouling inhibition on electrically conducting carbon nanotube-polyvinyl alcohol composite ultrafiltration membranes[J].Journal of Membrane Science,2014,468:1-10.
[9]	AL-AMSHAWEE S,YUNUS M Y B M,AZODDEIN A A M,et al.Electrodialysis desalination for water and wastewater:a review[J].Chemical Engineering Journal,2020,380:122231.
[10]	FOLARANMI G,BECHELANY M,SISTAT P,et al.Towards electrochemical water desalination techniques:a review on capacitive deionization,membrane capacitive deionization and flow capacitive deionization[J].Membranes (Basel),2020,10(5):96.
[11]	SUN P Z,ZHENG F,WANG K L,et al.Electro-and magneto-modulated ion transport through graphene oxide membranes[J].Scientific Reports,2014,4:6798.
[12]	LI D,JING W H,LI S Q,et al.Electric field-controlled ion transport in TiO₂ nanochannel[J].Acs Applied Materials & Interfaces,2015,7(21):11294-11300.
[13]	OJHA K,ARULMOZHI N,ARANZALES D,et al.Double layer of Pt(111)-aqueous electrolyte interface:potential of Zero charge and anomalous gouy-chapman screening[J].Angewandte Chemie-International Edition,2020,59(2):711-715.
[14]	CHENG C,JIANG G P,SIMON G P,et al.Low-voltage electrostatic modulation of ion diffusion through layered graphene-based nanoporous membranes[J].Nature Nanotechnology,2018,13(8):685-690.
[15]	DONNAN F G.The Theory of Membrane Equilibria[J].Chemical Reviews,1924,1(1):73-90.
[16]	PETROPOULOS J H,TSIMBOUKIS D G,KOUZELI K.Non-equipotential volume membrane models-relation between the glueckauf and equipotential surface models[J].Journal of Membrane Science,1983,16:379-389.
[17]	KAMCEV J,PAUL D R,FREEMAN B D.Ion activity coefficients in ion exchange polymers:applicability of manning's counterion condensation theory[J].Macromolecules,2015,48(21):8011-8024.
[18]	KAMCEV J,GALIZIA M,BENEDETTI F M,et al.Partitioning of mobile ions between ion exchange polymers and aqueous salt solutions:importance of counter-ion condensation[J].Phys Chem Chem Phys,2016,18(8):6021-6031.
[19]	HU C Z,LI M Q,SUN J Q,et al.NOM fouling resistance in response to electric field during electro-ultrafiltration:significance of molecular polarity and weight[J].Journal of Colloid and Interface Science,2019,539:11-18.
[20]	SUN J Q,HU C Z,WU B C,et al.Improving ion rejection of graphene oxide conductive membranes by applying electric field[J].Journal of Membrane Science,2020,604:118077.
[21]	SUN J Q,HU C Z,TONG T Z,et al.Performance and mechanisms of ultrafiltration membrane fouling mitigation by coupling coagulation and applied electric field in a novel electrocoagulation membrane reactor[J].Environmental Science & Technology,2017,51(15):8544-8551.
[22]	SUN J Q,HU C Z,ZHAO K,et al.Enhanced membrane fouling mitigation by modulating cake layer porosity and hydrophilicity in an electro-coagulation/oxidation membrane reactor (ECOMR)[J].Journal of Membrane Science,2018,550:72-79.
[23]	FAN X F,ZHAO H M,QUAN X,et al.Nanocarbon-based membrane filtration integrated with electric field driving for effective membrane fouling mitigation[J].Water Research,2016,88:285-292.
[24]	SUN J Q,WANG G G,ZHANG H,et al.Facile fabrication of a conductive polypyrrole membrane for anti-fouling enhancement by electrical repulsion and in situ oxidation[J].Chemosphere,2020,270:129416.
[25]	SUBTIL E L,GONÇALVES J,LEMOS H G,et al.Preparation and characterization of a new composite conductive polyethersulfone membrane using polyaniline (PANI) and reduced graphene oxide (rGO)[J].Chemical Engineering Journal,2020,390:124612.
[26]	WANG X Y,WANG Z W,CHEN H Q,et al.Removal of Cu(Ⅱ) ions from contaminated waters using a conducting microfiltration membrane[J].Jounral of Hazardous Materials,2017,339:182-190.
[27]	TAN X,HU C Z,ZHU Z Q,et al.Electrically pore-size-tunable polypyrrole membrane for antifouling and selective separation[J].Advanced Functional Materials,2019,29(35):1903081.
[28]	YI G,CHEN S,QUAN X,et al.Enhanced separation performance of carbon nanotube-polyvinyl alcohol composite membranes for emulsified oily wastewater treatment under electrical assistance[J].Separation and Purification Technology,2018,197:107-115.
[29]	SUN J Q,HU C Z,LIU Z T,et al.Surface charge and hydrophilicity improvement of graphene membranes via modification of pore surface oxygen-containing groups to enhance permeability and selectivity[J].Carbon,2019,145:140-148.
[30]	ZHANG H G,QUAN X,FAN X F,et al.Improving ion rejection of conductive nanofiltration membrane through electrically enhanced surface charge density[J].Environmental Science & Technology,2019,53(2):868-877.
[31]	HU C Z,LIU Z T,LU X L,et al.Enhancement of the Donnan effect through capacitive ion increase using an electroconductive rGO-CNT nanofiltration membrane[J].Journal of Materials Chemistry A,2018,6(11):4737-4745.
[32]	GUO L,JING Y,CHAPLIN B P.Development and characterization of ultrafiltration TiO₂ magneli phase reactive electrochemical membranes[J].Environmental Science & Technology,2016,50(3):1428-1436.
[33]	张桐,仝胜录,王晓雷,等.电渗析技术对煤气化灰水的处理[J].环境工程,2016,34(增刊1):278-281,290.
[34]	LEMAY N,MIKHAYLIN S,MAREEV S,et al.How demineralization duration by electrodialysis under high frequency pulsed electric field can be the same as in continuous current condition and that for better performances?[J].Journal of Membrane Science,2020,603:117878.
[35]	SOSA-FERNANDEZ P A,POST J W,RAMDLAN M S,et al.Improving the performance of polymer-flooding produced water electrodialysis through the application of pulsed electric field[J].Desalination,2020,484:114424.
[36]	DUFTON G,MIKHAYLIN S,GAALOUL S,et al.Systematic study of the impact of pulsed electric field parameters (pulse/pause duration and frequency) on ED performances during acid whey treatment[J].Membranes,2020,10(1):14.
[37]	WU D S,CHEN G Q,HU B S,et al.Feasibility and energy consumption analysis of phenol removal from salty wastewater by electro-electrodialysis[J].Separation and Purification Technology,2019,215:44-50.
[38]	ZHANG Z Y,LIBA D,ALVARADO L,et al.Separation and recovery of Cr(Ⅲ) and Cr(Ⅵ) using electrodeionization as an efficient approach[J].Separation and Purification Technology,2014,137:86-93.
[39]	ZHOU Y,HU C Z,LIU H J,et al.Potassium-Ion recovery with a polypyrrole membrane electrode in novel redox transistor electrodialysis[J].Environmental Science & Technology,2020,54(7):4592-4600.
[40]	REIG M,VECINO X,VALDERRAMA C,et al.Application of selectrodialysis for the removal of As from metallurgical process waters:recovery of Cu and Zn[J].Separation and Purification Technology,2018,195:404-412.
[41]	BUNANI S,YOSHIZUKA K,NISHIHAMA S,et al.Application of bipolar membrane electrodialysis (BMED) for simultaneous separation and recovery of boron and lithium from aqueous solutions[J].Desalination,2017,424:37-44.
[42]	DURAND R,PELLERIN G,THIBODEAU J,et al.Screening for metabolic syndrome application of a herring by-product hydrolysate after its separation by electrodialysis with ultrafiltration membrane and identification of novel anti-inflammatory peptides[J].Separation and Purification Technology,2020,235:116205.
[43]	DURAND R,FRABOULET E,MARETTE A,et al.Simultaneous double cationic and anionic molecule separation from herring milt hydrolysate and impact on resulting fraction bioactivities[J].Separation and Purification Technology,2019,210:431-441.
[44]	BAZINET L AND MOALIC M.Coupling of porous filtration and ion-exchange membranes in an electrodialysis stack and impact on cation selectivity:a novel approach for sea water demineralization and the production of physiological water[J].Desalination,2011,277(1/3):356-363.
[45]	GE L,WU B,LI Q H,et al.Electrodialysis with nanofiltration membrane (EDNF) for high-efficiency cations fractionation[J].Journal of Membrane Science,2016,498:192-200.
[46]	SUSS M E,PORADA S,SUN X,et al.Water desalination via capacitive deionization:what is it and what can we expect from it?[J].Energy & Environmental Science,2015,8(8):2296-2319.
[47]	BIAN Y H,YANG X F,LIANG P,et al.Enhanced desalination performance of membrane capacitive deionization cells by packing the flow chamber with granular activated carbon[J].Water Research,2015,85:371-376.
[48]	PAN J F,ZHENG Y,DING J C,et al.Fluoride removal from water by membrane capacitive deionization with a monovalent anion selective membrane[J].Industrial & Engineering Chemistry Research,2018,57(20):7048-7053.
[49]	KIM Y J,KIM J H,CHOI J H.Selective removal of nitrate ions by controlling the applied current in membrane capacitive deionization (MCDI)[J].Journal of Membrane Science,2013,429:52-57.
[50]	SAKAR H,CELIK I,BALCIK CANBOLAT C,et al.Electro-sorption of ammonium by a modified membrane capacitive deionization unit[J].Separation Science and Technology,2017,52(16):2591-2599.
[51]	GAO F,WANG L,WANG J,et al.Nutrient recovery from treated wastewater by a hybrid electrochemical sequence integrating bipolar membrane electrodialysis and membrane capacitive deionization[J].Environmental Science:Water Research & Technology,2020,6(2):383-391.
[52]	WANG Z J,GONG H,ZHANG Y,et al.Nitrogen recovery from low-strength wastewater by combined membrane capacitive deionization (MCDI) and ion exchange (IE) process[J].Chemical Engineering Journal,2017,316:1-6.
[53]	KIM D I,GWAK G,DORJI P,et al.Palladium recovery through membrane capacitive deionization from metal plating wastewater[J].ACS Sustainable Chemistry & Engineering,2017,6(2):1692-1701.
[54]	JEON S I,PARK H R,YEO J G,et al.Desalination via a new membrane capacitive deionization process utilizing flow-electrodes[J].Energy & Environmental Science,2013,6(5):1471-1475.
[55]	LIANG P,SUN X L,BIAN Y H,et al.Optimized desalination performance of high voltage flow-electrode capacitive deionization by adding carbon black in flow-electrode[J].Desalination,2017,420:63-69.
[56]	ZHANG X D,YANG F,MA J J,et al.Effective removal and selective capture of copper from salty solution in flow electrode capacitive deionization[J].Environmental Science:Water Research & Technology,2020,6(2):341-350.
[57]	FANG K,GONG H,HE W Y,et al.Recovering ammonia from municipal wastewater by flow-electrode capacitive deionization[J].Chemical Engineering Journal,2018,348:301-309.
[58]	ZHANG J,TANG L,TANG W W,et al.Removal and recovery of phosphorus from low-strength wastewaters by flow-electrode capacitive deionization[J].Separation and Purification Technology,2020,237:116322.
[59]	LIN L,HU J,LIU J,et al.Selective ammonium removal from synthetic wastewater by flow-electrode capacitive deionization using a novel K₂Ti₂O₅-activated carbon mixture electrode[J].Environmental Science & Technology,2020,54(19):12723-12731.
[60]	ZHANG C J,MA J X,WAITE T D.Ammonia-rich solution production from wastewaters using chemical-free flow-electrode capacitive deionization[J].ACS Sustainable Chemistry & Engineering,2019,7(7):6480-6485.
[61]	XU L Q,YU C,TIAN S Y,et al.Selective recovery of phosphorus from synthetic urine using flow-electrode capacitive deionization (FCDI)-based technology[J].ACS ES&T Water,2020,1(1):175-184.
[62]	EPSHTEIN A,NIR O,MONAT L,et al.Treatment of acidic wastewater via fluoride ions removal by SiO₂ particles followed by phosphate ions recovery using flow-electrode capacitive deionization[J].Chemical Engineering Journal,2020,400:125892.
[63]	ZHANG C Y,WANG M,XIAO W,et al.Phosphate selective recovery by magnetic iron oxide impregnated carbon flow-electrode capacitive deionization (FCDI)[J].Water Research,2020,189:116653.
[64]	BIAN Y H,CHEN X,LU L,et al.Concurrent nitrogen and phosphorus recovery using flow-electrode capacitive deionization[J].ACS Sustainable Chemistry & Engineering,2019,7(8):7844-7850.
[65]	黄宽,唐浩,刘丹阳,等.电容去离子技术综述(一):理论基础[J].环境工程,2016,34(增刊1):82-88.