电渗析过程传质模型的研究进展

doi:10.16085/j.issn.1000-6613.2019-1076

摘要/Abstract

摘要：

电渗析是一种利用离子交换膜和电势差从溶液及其他不带电组分中分离出离子的物质分离过程，该技术具有适应性强、预处理简单、能耗低、环境污染小等优点，被广泛应用于化工、生物等领域的分离纯化过程。本文主要介绍了用于电渗析分离过程的6种传质模型，总结了各模型的优势及存在的问题，指出限制电渗析技术进一步发展的主要原因是对包含物质传递、浓差极化、流体流动行为、电解质溶液-膜平衡等复杂现象的电渗析过程进行理论和实验研究难度大，而传质模型化为电渗析分离过程的物质传递研究提供了一条有效途径，有助于深入研究电渗析过程中物质的传递机理，准确预测分离性能并导向性优化电渗析结构设计和操作工艺。并且提出未来电渗析传质模型的研究方向是结合经验方程或传质系数进一步优化传质模型，并采用仿真工具模拟传质过程，提高模型的准确性和普适性。

关键词: 电渗析, 模型, 传质, 分离, 模拟

Abstract:

Electrodialysis is a mass separation process in which ion exchange membranes and electrical potential difference are used to separate ionic species from aqueous solution and other uncharged components. This separation technology possesses the advantages of strong adaptability, simple pretreatment of feed, low energy consumption and little environmental pollution, which make it widely applied in separation and purification processes of chemical and biological industries. This review covers six mass transfer models used in the description of mass transportation phenomena and summarizes the advantages and problems of these models. It is pointed out in this paper that the main limitation for further improvement of electrodialysis technology is that it is troublesome to theoretically or experimentally study the electrodialysis process that includes a number of complex phenomena such as mass transportation, concentration polarization, fluid flow behavior and electrolyte-membrane equilibrium. Mass transfer modeling of electrodialysis, which is favorable to deeply study mass transfer mechanism for accurate performance prediction and target-oriented process optimization, provides an effective strategy to study the separation process of electrodialysis. Moreover, the research direction is optimization of mass transfer models by combining empirical equations or transfer coefficients, and simulation of electrodialysis process with modeling tools, aiming to improve the accuracy and universality of mass transfer models.

Key words: electrodialysis, model, mass transfer, separation, simulation

中图分类号:

TQ028

祝海涛,杨波,高从堦. 电渗析过程传质模型的研究进展[J]. 化工进展, 2020, 39(3): 815-823.

Haitao ZHU,Bo YANG,Congjie GAO. Research progress on mass transfer models for electrodialysis process[J]. Chemical Industry and Engineering Progress, 2020, 39(3): 815-823.

图/表 2

参考文献 77

1	HAN L,GALIER S,R-D BALMANN H.A phenomenological model to evaluate the performances of electrodialysis for the desalination of saline water containing organic solutes[J].Desalination,2017,422:17-24.
2	包申旭,张一敏,刘涛,等.电渗析处理石煤提钒废水[J].中国有色金属学报,2010,20(7):1440-1445.
	BAO S X,ZHANG Y M,LIU T,et al.Electrodialytic treatment of wastewater produced in vanadium extraction from stone coal[J].The Chinese Journal of Nonferrous Metals,2010,20(7):1440-1445.
3	XU T,HUANG C.Electrodialysis-based separation technologies: a critical review[J].AIChE Journal,2008,54(12):3147-3159.
4	CERVA M L,LIBERTO M D,GURRERI L,et al.Coupling CFD with a one-dimensional model to predict the performance of reverse electrodialysis stacks[J].Journal of Membrane Science,2017,541:595-610.
5	DEMEKHIN E A,NIKITIN N V,SHELISTOV V S.Direct numerical simulation of electrokinetic instability and transition to chaotic motion[J].Physics of Fluids,2013,25(12):122001.
6	FIDALEO M,MORESI M.Optimal strategy to model the electrodialytic recovery of a strong electrolyte[J].Journal of Membrane Science,2005,260(1/2):90-111.
7	MAREEV S A,BUTYLSKII D Y,PISMENSKAYA N D,et al.Chronopotentiometry of ion-exchange membranes in the overlimiting current range. Transition time for a finite-length diffusion layer: modeling and experiment[J].Journal of Membrane Science,2016,500:171-179.
8	NAKAYAMA A,SANO Y,BAI X,et al.A boundary layer analysis for determination of the limiting current density in an electrodialysis desalination[J].Desalination,2017,404:41-49.
9	ZALTZMAN B,RUBINSTEIN I.Electro-osmotic slip and electroconvective instability[J].Journal of Fluid Mechanics,2007,579:173-226.
10	H-I JEONG,KIM H J,KIM D-K.Numerical analysis of transport phenomena in reverse electrodialysis for system design and optimization[J].Energy,2014,68:229-237.
11	PHAM V S,LI Z,LIM K M,et al.Direct numerical simulation of electroconvective instability and hysteretic current-voltage response of a permselective membrane[J].Physical Review E,2012,86(4):046310.
12	VOLGIN V M,DAVYDOV A D.Ionic transport through ion-exchange and bipolar membranes[J].Journal of Membrane Science, 2005,259 (1/2):110-121.
13	ZOURMAND Z,FARIDIRAD F,KASIRI N,et al.Mass transfer modeling of desalination through an electrodialysis cell[J].Desalination,2015,359:41-51.
14	BAWORNRUTTANABOONYA K,DEVAHASTIN S,YOOVIDHYA T,et al.Mathematical modeling of transport phenomena and quality changes of fish sauce undergoing electrodialysis desalination[J].Journal of Food Engineering,2015,159:76-85.
15	FIDALEO M,MORESI M,CAMMAROTO A,et al.Modelling of soy sauce desalting by electrodialysis[J].Food and Bioprocess Technology,2012,6(7):1681-1695.
16	NEZUNGAI C D,MAJOZI T.Optimum synthesis of an electrodialysis framework with a background process—Ⅰ: A novel electrodialysis model[J].Chemical Engineering Science,2016,147:180-188.
17	ROHMAN F S,OTHMAN M R,AZIZ N.Modeling of batch electrodialysis for hydrochloric acid recovery[J].Chemical Engineering Journal,2010,162(2):466-479.
18	HAN L,GALIER S,R-D BALMANN H.Transfer of neutral organic solutes during desalination by electrodialysis: influence of the salt composition[J].Journal of Membrane Science,2016,511:207-218.
19	WANG Y,WANG A,ZHANG X,et al.The concentration, resistance, and potential distribution across a cation exchange membrane in 1∶2 (Na₂SO₄) type aqueous solution[J].Desalination,2012,284:106-115.
20	ZABOLOTSKII V I,SHARAFAN M V,SHEL’DESHOV N V.The dissociation rate of water molecules in systems with cation- and anion-exchange membranes[J].Russian Journal of Electrochemistry,2012,48(5):550-555.
21	MAIGROT E,SABATES J.Apparat zur Läuterung von Zuckersäften mittels Elektrizität:Germ.Pat. Nr. 50443[P].1890.
22	GREBENYUK V D,GREBENYUK O V.Electrodialysis: from an idea to realization[J].Russian Journal of Electrochemistry,2002,38(8):806-809.
23	刘骆峰,张雨山,黄西平,等.淡化后浓海水化学资源综合利用技术研究进展[J].化工进展,2013,32(2):446-452.
	LIU L F,ZHANG Y S,HUANG X P,et al.Research progress of multipurpose utilization technologies of brine from seawater desalination plant[J].Chemical Industry and Engineering Progress,2013,32(2):446-452.
24	王秋霜,应铁进,赵超艺,等.电渗析技术在大豆低聚糖溶液脱盐上的应用[J].农业工程学报,2008,24(10):243-247.
	WANG Q S,YING T J,ZHAO C Y,et al.Application of electrodialysis technology on desalination of soybean oligosaccharides solution[J].Transactions of the CSAE,2008,24(10):243-247.
25	NAGARALE R K,GOHIL G S,SHAHI V K.Recent developments on ion-exchange membranes and electro-membrane processes[J].Advances in Colloid and Interface Science,2006,119(2/3):97-130.
26	RAN J,WU L,HE Y,et al.Ion exchange membranes: new developments and applications[J].Journal of Membrane Science,2017,522:267-291.
27	ALI A,TUFA R A,MACEDONIO F,et al.Membrane technology in renewable-energy-driven desalination[J].Renewable and Sustainable Energy Reviews,2018,81:1-21.
28	VERMAAS D A,VEERMAN J,YIP N Y,et al.High efficiency in energy generation from salinity gradients with reverse electrodialysis[J].ACS Sustainalbe Chemistry & Engineering,2013,1(10):1295-1302.
29	TEDESCO M,HAMELERS H V M,BIESHEUVEL P M.Nernst-Planck transport theory for (reverse) electrodialysis:Ⅰ. Effect ofco-ion transport through the membranes[J].Journal of Membrane Science,2016,510:370-381.
30	TEDESCO M,HAMELERS H V M,BIESHEUVEL P M.Nernst-Planck transport theory for (reverse) electrodialysis:Ⅱ. Effect of water transport through ion-exchange membranes[J].Journal of Membrane Science,2017,531:172-182.
31	GHORBANI A,GHASSEMI A,ANDERSEN P K,et al.A prediction model of mass transfer through an electrodialysis cell[J].Desalination and Water Treatment,2016,57(47):22290-22303.
32	NIKONENKO V,ZABOLOTSKY V,LARCHET C,et al.Mathematical description of ion transport in membrane systems[J].Desalination,2002,147(1/2/3):369-374.
33	GNUSIN N P.Modeling of mass electrotransfer in an electrodialysis cell[J].Theoretical Foundations of Chemical Engineering,2004,38(3):296-300.
34	GNUSIN N P,DEMINA O A,BEREZINA N P,et al.Modeling of mass electrotransfer in terms of the transport and structural properties of ion-exchange membranes[J].Theoretical Foundations of Chemical Engineering,2004,38(4):394-398.
35	TANAKA Y.Concentration polarization in ion-exchange membrane electrodialysis—The events arising in a flowing solution in a desalting cell[J].Journal of Membrane Science,2003,216(1/2):149-164.
36	FIDALEO M,MORESI M.Application of the Nernst-Planck approach to model the electrodialytic recovery of disodium itaconate[J].Journal of Membrane Science,2010,349(1/2):393-404.
37	MA L,GUTIERREZ L,VANOPPEN M,et al.Transport of uncharged organics in ion-exchange membranes: experimental validation of the solution-diffusion model[J].Journal of Membrane Science,2018,564:773-781.
38	ROHMAN F S,AZIZ N.Mathematical model of ion transport in electrodialysis process[J].Bulletin of Chemical Reaction Engineering & Catalysis,2008,3(1/2/3):3-8.
39	MIER M,IBANEZ R,ORTIZ I.Influence of ion concentration on the kinetics of electrodialysis with bipolar membranes[J].Separation and Purification Technology,2008,59(2):197-205.
40	PISMENSKIY A,NIKONENKO V,URTENOV M,et al.Mathematical modelling of gravitational convection in electrodialysis processes[J].Desalination,2006,192(1/2/3):374-379.
41	TANAKA Y.Mass transport and energy consumption in ion-exchange membrane electrodialysis of seawater[J].Journal of Membrane Science,2003,215(1/2):265-279.
42	KRAAIJEVELD G,SUMBEROVA V,KUINDERSMA S,et al.Modelling electrodialysis using the Maxwell-Stefan description[J].The Chemical Engineering Journal,1995,57:163-176.
43	PINTAURO P N,BENNION D N.Mass transport of electrolytes in membranes. 2. Determination of sodium chloride equilibrium and transport parameters for Nafion[J].Industrial & Engineering Chemistry Fundamentals,1984,23:234-243.
44	WESSELINGH J A,VONK P,KRAAIJEVELD G.Exploring the Maxwell-Stefan description of ion exchange[J].The Chemical Engineering Journal,1995,57:75-89.
45	ENCISO R,DELGADILLO J A,NGUEZ O DOM,et al.Analysis and validation of the hydrodynamics of an electrodialysis cell using computational fluid dynamics[J].Desalination,2017,408:127-132.
46	JIANG C,WANG Q,LI Y,et al.Water electro-transport with hydrated cations in electrodialysis[J].Desalination,2015,365:204-212.
47	CASAS S,BONET N,ALADJEM C,et al.Modelling sodium chloride concentration from seawater reverse osmosis brine by electrodialysis: preliminary results[J].Solvent Extraction and Ion Exchange,2011,29(3):488-508.
48	KRISHNA R.Diffusion in multicomponent electrolyte systems[J].The Chemical Engineering Journal,1987,35:19-24.
49	LEE E G,S-H MOON,CHANG Y K,et al.Lactic acid recovery using two-stage electrodialysis and its modelling[J].Journal of Membrane Science,1998,145(1):53-66.
50	AUCLAIR B,NIKONENKO V,LARCHET C,et al.Correlation between transport parameters of ion-exchange membranes[J].Journal of Membrane Science,2002,195(1):89-102.
51	NIKONENKO V V,LEBEDEV K A,SULEIMANOV S S.Influence of the convective term in the Nernst-Planck equation on properties of ion transport through a layer of solution or membrane[J].Russian Journal of Electrochemistry,2009,45(2):160-169.
52	LARCHET C,AUCLAIR B,NIKONENKO V.Approximate evaluation of water transport number in ion-exchange membranes[J].Electrochimica Acta,2004,49(11):1711-1717.
53	GHASSEMI S A,DANESH S.A hybrid fuzzy multi-criteria decision making approach for desalination process selection[J].Desalination,2013,313:44-50.
54	KILIMANN K,HARTMANN C,DELGADO A,et al.A fuzzy logic-based model for the multistage high-pressure inactivation ofLactococcus lactis ssp. cremoris MG 1363[J].International Journal of Food Microbiology,2005,98(1):89-105.
55	SHAHSAVAND A,CHENAR M P.Neural networks modeling of hollow fiber membrane processes[J].Journal of Membrane Science,2007,297(1/2):59-73.
56	JING G L,DU W T,CHEN X,et al.Prediction model in electrodialysis process based on ANFIS[J].Advanced Materials Research,2011, 268/269/270:332-335.
57	JING G,DU W.Fuzzy logic-based model for prediction of separation percent of NaCl solution using electrodialysis[J].Asian Journal of Chemistry,2012,24(5):2216-2220.
58	SADRZADEH M,GHADIMI A,MOHAMMADI T.Coupling a mathematical and a fuzzy logic-based model for prediction of zinc ions separation from wastewater using electrodialysis[J].Chemical Engineering Journal,2009,151(1/2/3):262-274.
59	MJALLI F S,AL-ASHEH S,ALFADALA H E.Use of artificial neural network black-box modeling for the prediction of wastewater treatment plants performance[J].J. Environ. Manage.,2007,83(3):329-338.
60	SHA W,EDWARDS K L.The use of artificial neural networks in materials science based research[J].Materials & Design,2007,28(6):1747-1752.
61	CHELLAM S.Artificial neural network model for transient crossflow microfiltration of polydispersed suspensions[J].Journal of Membrane Science,2005,258(1/2):35-42.
62	CURCIO S,CALABR V,IORIO G.Reduction and control of flux decline in cross-flow membrane processes modeled by artificial neural networks[J].Journal of Membrane Science,2006,286(1/2):125-132.
63	AL-ZOUBI H,HILAL N,DARWISH N A,et al.Rejection and modelling of sulphate and potassium salts by nanofiltration membranes: neural network and Spiegler-Kedem model[J].Desalination,2007,206(1/2/3):42-60.
64	ABBAS A,AL-BASTAKI N.Modeling of an RO water desalination unit using neural networks[J].Chemical Engineering Journal,2005,114(1/2/3):139-143.
65	CINAR O,HASAR H,KINACI C.Modeling of submerged membrane bioreactor treating cheese whey wastewater by artificial neural network[J].Journal of biotechnology,2006,123(2):204-209.
66	SADRZADEH M,MOHAMMADI T,IVAKPOUR J,et al.Neural network modeling of Pb²⁺ removal from wastewater using electrodialysis[J].Chemical Engineering and Processing: Process Intensification,2009,48(8):1371-1381.
67	CHINDAPAN N,SABLANI S S,CHIEWCHAN N,et al.Modeling and optimization of electrodialytic desalination of fish sauce using artificial neural networks and genetic algorithm[J].Food and Bioprocess Technology,2012,6(10):2695-2707.
68	SADRZADEH M,MOHAMMADI T,IVAKPOUR J,et al.Separation of lead ions from wastewater using electrodialysis: comparing mathematical and neural network modeling[J].Chemical Engineering Journal,2008,144(3):431-441.
69	TANAKA Y,REIG M,CASAS S,et al.Computer simulation of ion-exchange membrane electrodialysis for salt concentration and reduction of RO discharged brine for salt production and marine environment conservation[J].Desalination,2015,367:76-89.
70	CAMPIONE A,GURRERI L,CIOFALO M,et al.Electrodialysis for water desalination: a critical assessment of recent developments on process fundamentals, models and applications[J].Desalination,2018,434:121-160.
71	DŁUGOŁĘCKI P,ANET B,METZ S J,et al.Transport limitations in ion exchange membranes at low salt concentrations[J].Journal of Membrane Science,2010,346(1):163-171.
72	GLER E,ELIZEN R,SAAKES M,et al.Micro-structured membranes for electricity generation by reverse electrodialysis[J].Journal of Membrane Science,2014,458:136-148.
73	PAWLOWSKI S,GERALDES V,CRESPO J G,et al.Computational fluid dynamics (CFD) assisted analysis of profiled membranes performance in reverse electrodialysis[J].Journal of Membrane Science,2016,502:179-190.
74	WEINER A M,MCGOVERN R K,LIENHARD V J H.Increasing the power density and reducing the levelized cost of electricity of a reverse electrodialysis stack through blending[J].Desalination,2015,369:140-148.
75	MCGOVERN R K,ZUBAIR S M,LIENHARD V J H.The cost effectiveness of electrodialysis for diverse salinity applications[J].Desalination,2014,348:57-65.
76	BRAUNS E,DE WILDE W,BOSCH B VAN DEN,et al.On the experimental verification of an electrodialysis simulation model for optimal stack configuration design through solver software[J].Desalination,2009,249(3):1030-1038.
77	KOTER S,WARSZAWSKI A.A new model for characterization of bipolar membrane electrodialysis of brine[J].Desalination,2006,198(1/2/3):111-123.

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