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http://dx.doi.org/10.4491/eer.2016.017

Membrane fouling control in low pressure membranes: A review on pretreatment techniques for fouling abatement  

Arhin, Samuel Gyebi (Department of Agricultural and Bio-Systems Engineering, Makerere University)
Banadda, Noble (Department of Agricultural and Bio-Systems Engineering, Makerere University)
Komakech, Allan John (Department of Agricultural and Bio-Systems Engineering, Makerere University)
Kabenge, Isa (Department of Agricultural and Bio-Systems Engineering, Makerere University)
Wanyama, Joshua (Department of Agricultural and Bio-Systems Engineering, Makerere University)
Publication Information
Environmental Engineering Research / v.21, no.2, 2016 , pp. 109-120 More about this Journal
Abstract
Conventional treatment techniques cannot meet the stringent modern water quality regulations emanating from the need to provide high quality drinking water. Therefore, a number of studies have suggested low pressure membrane filtration as a worthwhile alternative. However, a major constraint to the extensive use of this technology in low and middle income countries is the high operating and maintenance costs caused by the inherent predisposition to membrane fouling. Notwithstanding, pretreatment of feed water using techniques such as coagulation, adsorption, oxidation and bio-filtration is believed to control fouling. In this review paper, the existing scientific knowledge on membrane fouling and pretreatment techniques for controlling fouling in low pressure membranes is analyzed with the aim of providing new and valuable insights into such techniques, as well as unveiling crucial issues noteworthy for further studies. Among the techniques reviewed, coagulation was observed to be the most cost-effective and will remain the most dominant in the coming years. Although oxidants and magnetic ion exchange resins can also control fouling, the propensity of oxidants to form health treating precursors and the high economic implications of magnetic ion exchange resins will hinder their adoption in developing countries.
Keywords
Fouling control; Low pressure membranes; Membrane fouling; Pretreatment techniques; Water quality;
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1 Khan MMT, Takizawa S, Lewandowski Z, Jones WL, Camper AK, Katayama H, et al. Membrane fouling due to dynamic particle size changes in the aerated hybrid PAC-MF system. J. Memb. Sci. 2011;371:99-107.   DOI
2 Fan X, Tao Y, Wang L, Zhang X, Lei Y, Wang Z, et al. Performance of an integrated process combining ozonation with ceramic membrane ultra-filtration for advanced treatment of drinking water. Desalination 2014;335:47-54.   DOI
3 Zhang X, Guo J, Wang L, Hu J, Zhu J. In situ ozonation to control ceramic membrane fouling in drinking water treatment. Desalination 2013;328:1-7.   DOI
4 Kim J, Davies SHR, Baumann MJ, Tarabara V V, Masten SJ. Effect of ozone dosage and hydrodynamic conditions on the permeate flux in a hybrid ozonation-ceramic ultrafiltration system treating natural waters. J. Memb. Sci. 2008;311:165-172.   DOI
5 Van Geluwe S, Braeken L, Van der Bruggen B. Ozone oxidation for the alleviation of membrane fouling by natural organic matter: A review. Water Res. 2011;45:3551-3570.   DOI
6 Song Y, Dong B, Gao N, Xia S. Huangpu River water treatment by micro fi ltration with ozone pretreatment. Desalination 2010;250:71-75.   DOI
7 Wang X, Wang L, Liu Y, Duan W. Ozonation pretreatment for ultrafiltration of the secondary effluent. J. Memb. Sci. 2007;287:187-191.   DOI
8 Williams MD, Pirbazari M. Membrane bioreactor process for removing biodegradable organic matter from water. Water Res. 2007;41:3880-3893.   DOI
9 Choo KH, Lee H, Choi SJ. Iron and manganese removal and membrane fouling during UF in conjunction with prechlorination for drinking water treatment. J. Memb. Sci. 2005;267:18-26.   DOI
10 Lihua S, Ruiping L, Shengji X, Yanling Y, Guibai L. Enhanced As (III) removal with permanganate oxidation, ferric chloride precipitation and sand filtration as pretreatment of ultrafiltration. Desalination 2009;243:122-131.   DOI
11 Chaturvedi S, Dave PN. Removal of iron for safe drinking water. Desalination 2012;303:1-11.   DOI
12 Halle C, Huck PM, Peldszus S, Haberkamp J, Jekel M. Assessing the performance of biological filtration as pretreatment to low pressure membranes for drinking water. Environ. Sci. Technol. 2009;43:3878-3884.   DOI
13 Mosqueda-Jimenez DB, Huck PM, Basu OD. Fouling characteristics of an ultrafiltration membrane used in drinking water treatment. Desalination 2008;230:79-91.   DOI
14 Banadda EN, Kansiime F, Kigobe M, Kizza M, Nhapi I. Landuse-based nonpoint source pollution: A threat to water quality in Murchison Bay, Uganda. Water Policy 2009;11:94-105.   DOI
15 Beukes LS, Schmidt S. Microbiological Assessment of the Biofilter Matrix Within a Biofiltration system Treating Borehole water in KwaZulu-Natal (South Africa). Int. J. Environ. Res. 2015;9:263-272.
16 Maeng M, Choi E, Dockko S. International Biodeterioration & Biodegradation Reduction of organic matter in drinking water using a hybrid system combined with a rock biofilter and membrane in developing countries. Int. Biodeterior Biodegradation 2015;102:223-230.   DOI
17 Zhang R, Vigneswaran S, Ngo HH, Nguyen H. Magnetic ion exchange ($MIEX^{(R)}$) resin as a pre-treatment to a submerged membrane system in the treatment of biologically treated wastewater. Desalination 2006;192:296-302.   DOI
18 Croue J, Humbert H. Combination of coagulation and ion exchange for the reduction of UF fouling properties of a high DOC content surface water. Water Res. 2007;41:3803-3811.   DOI
19 Kitis M, Ilker Harman B, Yigit NO, Beyhan M, Nguyen H, Adams B. The removal of natural organic matter from selected Turkish source waters using magnetic ion exchange resin ($MIEX^{(R)}$). React Funct. Polym. 2007;67:1495-1504.   DOI
20 Ding L, Deng H, Wu C, Han X. Affecting factors, equilibrium, kinetics and thermodynamics of bromide removal from aqueous solutions by MIEX resin. Chem. Eng. J. 2012;181-182:360-370.   DOI
21 Croue J, Humbert H. Performance of selected anion exchange resins for the treatment of a high DOC content surface water. Water Res. 2005;39:1699-1708.   DOI
22 Filloux E, Gallard H, Croue JP. Identification of effluent organic matter fractions responsible for low-pressure membrane fouling. Water Res. 2012;46:5531-5540.   DOI
23 Mergen MRD, Jefferson B, Parsons SA, A PJ. Magnetic ion-exchange resin treatment: Impact of water type and resin use. Water Res. 2008;42:1977-1988.   DOI
24 Mozia S, Tomaszewska M, Morawski AW. Application of an ozonation-adsorption-ultrafiltration system for surface water treatment. Desalination 2006;190:308-314.   DOI
25 Watson K, Farre MJ, Knight N. Enhanced coagulation with powdered activated carbon or $MIEX^{(R)}$ secondary treatment: A comparison of disinfection by-product formation and precursor removal. Water Res. 2015;68:454-466.   DOI
26 Kim HC. High-rate MIEX filtration for simultaneous removal of phosphorus and membrane foulants from secondary effluent. Water Res. 2015;69:40-50.   DOI
27 Bhavnani D, Goldstick JE, Cevallos W, Trueba G, Eisenberg JNS. Impact of rainfall on diarrheal disease risk associated with unimproved water and sanitation. Am. J. Trop. Med. Hyg. 2014;90:705-11.   DOI
28 Pruss-Ustun A, Bartram J, Clasen T, Colford JM, Cumming O, Curtis V, et al. Burden of disease from inadequate water, sanitation and hygiene in low- and middle-income settings: A retrospective analysis of data from 145 countries. Trop. Med. Int. Heal. 2014;19:894-905.   DOI
29 WHO/UNICEF Joint Monitoring Programme for Water Supply and Sanitation. Progress on Sanitation and Drinking-Water: 2015 Update and MDG Assessment. Geneva, Switzerland: WHO Press; 2015. p. 90.
30 Arnal JM, Garcia-Fayos B, Verdu G, Lora J. Ultrafiltration as an alternative membrane technology to obtain safe drinking water from surface water: 10 years of experience on the scope of the AQUAPOT project. Desalination 2009;248:34-41.   DOI
31 UNICEF/WHO. Diarrhoea: Why children are still dying and what can be done? Geneva, Switzerland: WHO Press; 2009. p. 68.
32 Li M, Wu G, Guan Y, Zhang X. Treatment of river water by a hybrid coagulation and ceramic membrane process. Desalination 2011;280:114-119.   DOI
33 Choi YH, Nason JA, Kweon JH. Effects of aluminum hydrolysis products and natural organic matter on nanofiltration fouling with PACl coagulation pretreatment. Sep. Purif. Technol. 2013;120:78-85.   DOI
34 Zularisam AW, Ismail AF, Salim R. Behaviours of natural organic matter in membrane filtration for surface water treatment - a review. Desalination 2006;194:211-231.   DOI
35 Xiangli Q, Zhenjia Z, Nongcun W, Wee V, Low M, Loh CS, et al. Coagulation pretreatment for a large-scale ultrafiltration process treating water from the Taihu River. Desalination 2008;230:305-313.   DOI
36 Zularisam AW, Ismail AF, Salim MR, Sakinah M, Matsuura T. Application of coagulation - ultrafiltration hybrid process for drinking water treatment : Optimization of operating conditions using experimental design. Sep. Purif. Technol. 2009;65:193-210.   DOI
37 Hill VR, Kahler AM, Jothikumar N, Johnson TB, Hahn D, Cromeans TL. Multistate evaluation of an ultrafiltration-based procedure for simultaneous recovery of enteric microbes in 100-liter tap water samples. Appl. Environ. Microbiol. 2007;73:4218-4225.   DOI
38 Jeong CH, Postigo C, Richardson SD, Simmons JE, Kimura SY, Marin BJ, et al. Occurrence and Comparative Toxicity of Haloacetaldehyde Disinfection Byproducts in Drinking Water. Environ. Sci. Technol. 2015;49:13749-13759.   DOI
39 Chon K, Kim SJ, Moon J, Cho J. Combined coagulation-disk filtration process as a pretreatment of ultrafiltration and reverse osmosis membrane for wastewater reclamation: An autopsy study of a pilot plant. Water Res. 2012;46:1803-1816.   DOI
40 Gamage NP, Chellam S. Aluminum electrocoagulation pretreatment reduces fouling during surface water microfiltration. J. Memb. Sci. 2011;379:97-105.   DOI
41 Kearns EA, Magana S, Lim D V. Automated concentration and recovery of micro-organisms from drinking water using dead-end ultrafiltration. J. Appl. Microbiol. 2008;105:432-442.   DOI
42 Lai C, Chou Y, Yeh H. Assessing the interaction effects of coagulation pretreatment and membrane material on UF fouling control using HPSEC combined with peak-fitting. J. Memb. Sci. 2015;474:207-214.   DOI
43 Gao W, Liang H, Ma J, Han M, Chen Z, Han Z, et al. Membrane fouling control in ultrafiltration technology for drinking water production: A review. Desalination 2011;272:1-8.   DOI
44 Hill VR, Polaczyk AL, Hahn D, Narayanan J, Cromeans TL, Roberts JM, et al. Development of a rapid method for simultaneous recovery of diverse microbes in drinking water by ultrafiltration with sodium polyphosphate and surfactants. Appl. Environ. Microbiol. 2005;71:6878-6884.   DOI
45 Peiris RH, Halle C, Budman H, Moresoli C, Peldszus S, Huck PM, et al. Identifying fouling events in a membrane-based drinking water treatment process using principal component analysis of fluorescence excitation-emission matrices. Water Res. 2010; 44:185-194.   DOI
46 Xu H, Chen W, Xiao H, Hu X. Stability of an ultrafiltration system for drinking water treatment, using chlorine for fouling control. Desalination 2014;336:187-195.   DOI
47 Her N, Amy G, Plottu-Pecheux A, Yoon Y. Identification of nanofiltration membrane foulants. Water Res. 2007;41:3936-3947.   DOI
48 Rosas I, Collado S, Gutierrez A, Diaz M. Fouling mechanisms of Pseudomonas putida on PES microfiltration membranes. J. Memb. Sci. 2014;465:27-33.   DOI
49 Pezeshk N, Narbaitz RM. More fouling resistant modified PVDF ultrafiltration membranes for water treatment. Desalination 2012;287:247-254.   DOI
50 Huang H, Schwab K. Critical Review Pretreatment for Low Pressure Membranes in Water Treatment : A Review. Environ. Sci. Technol. 2009;43:3011-3019.   DOI
51 Li NN, Fane AG, Ho WSW, Matsuura T. Advanced Membrane Technology and Applications. John Wiley & Sons, Hoboken, New Jersey; 2008. p. 989.
52 Munla L, Peldszus S, Huck PM. Reversible and irreversible fouling of ultrafiltration ceramic membranes by model solutions. J. Am. Water Works Assoc. 2012;104.
53 Ahmadiannamini P, Bruening ML, Tarabara V V. Sacrificial polyelectrolyte multilayer coatings as an approach to membrane fouling control: Disassembly and regeneration mechanisms. J. Memb. Sci. 2015;491:149-158.   DOI
54 Wang L, Wang X, Fukushi K. Effects of operational conditions on ultrafiltration membrane fouling. Desalination. 2008;229:181-191.   DOI
55 Gray SR, Ritchie CB, Tran T, Bolto BA. Effect of NOM characteristics and membrane type on microfiltration performance. Water Res. 2007;41:3833-3841.   DOI
56 Zularisam AW, Ismail AF, Salim MR, Sakinah M, Ozaki H. The effects of natural organic matter (NOM) fractions on fouling characteristics and flux recovery of ultrafiltration membranes. Desalination 2007;212:191-208.   DOI
57 Lee EK, Chen V, Fane a. G. Natural organic matter (NOM) fouling in low pressure membrane filtration - effect of membranes and operation modes. Desalination 2008;218:257-70.   DOI
58 Cui X, Choo K. Natural Organic Matter Removal and Fouling Control in Low-Pressure Membrane Filtration for Water Treatment. Environ. Eng. Res. 2014;19:1-8.   DOI
59 Campinas M, Rosa MJ. Assessing PAC contribution to the NOM fouling control in PAC/UF systems. Water Res. 2010;44:1636-1644.   DOI
60 Zhao Y, Song L, Ong SL. Fouling behavior and foulant characteristics of reverse osmosis membranes for treated secondary effluent reclamation. J. Memb. Sci. 2010;349:65-74.   DOI
61 Stoquart C, Servais P, Berube PR, Barbeau B. Hybrid Membrane Processes using activated carbon treatment for drinking water: A review. J. Memb. Sci. 2012;411-412:1-12.   DOI
62 Koo CH, Mohammad AW, Suja' F, Meor Talib MZ. Review of the effect of selected physicochemical factors on membrane fouling propensity based on fouling indices. Desalination 2012;287:167-177.   DOI
63 Chen F, Peldszus S, Peiris RH, Ruhl AS, Mehrez R, Jekel M, et al. Pilot-scale investigation of drinking water ultrafiltration membrane fouling rates using advanced data analysis techniques. Water Res. 2014;48:508-518.   DOI
64 Crittenden JC, Trussell RR, Hand DW, Howe KJ, Tchobanoglous G. MWH's Water Treatment Principles and Design. Third Edit. New Jersey: John Wiley & Sons, Inc; 2012.
65 Yamamura H, Kimura K, Watanabe Y. Mechanism involved in the evolution of physically irreversible fouling in microfiltration and ultrafiltration membranes used for drinking water treatment. Environ Sci. Technol. 2007;41:6789-6794.   DOI
66 Tian JY, Ernst M, Cui F, Jekel M. Correlations of relevant membrane foulants with UF membrane fouling in different waters. Water Res. 2013;47:1218-1228.   DOI
67 Kimura K, Tanaka K, Watanabe Y. Microfiltration of different surface waters with/without coagulation: Clear correlations between membrane fouling and hydrophilic biopolymers. Water Res. 2014;49:434-443.   DOI
68 Kaya Y, Barlas H, Arayici S. Evaluation of fouling mechanisms in the nanofiltration of solutions with high anionic and nonionic surfactant contents using a resistance-in-series model. J. Memb. Sci. 2011;367:45-54.   DOI
69 Meng F, Zhang H, Yang F, Li Y, Xiao J, Zhang X. Effect of filamentous bacteria on membrane fouling in submerged membrane bioreactor. J. Memb. Sci. 2006;272:161-168.   DOI
70 Bergamasco R, Konradt-Moraes LC, Vieira MF, Fagundes-Klen MR, Vieira AMS. Performance of a coagulation-ultrafiltration hybrid process for water supply treatment. Chem. Eng. J. 2011;166:483-489.   DOI
71 Rai P, Rai C, Majumdar GC, Dasgupta S, De S. Resistance in series model for ultrafiltration of mosambi (Citrus sinensis (L.) Osbeck) juice in a stirred continuous mode. J. Memb. Sci. 2006;283:116-122.   DOI
72 Duclos-Orsello C, Li W, Ho CC. A three mechanism model to describe fouling of microfiltration membranes. J. Memb. Sci. 2006;280:856-866.   DOI
73 Howe KJ, Clark MM. Effect of coagulation pretreatment on membrane filtration performance. J. Am. Water Work Assoc. 2006;98:133-146.
74 Fabris R, Lee EK, Chow CWK, Chen V, Drikas M. Pre-treatments to reduce fouling of low pressure micro-filtration (MF) membranes. J. Memb. Sci. 2007;289:231-240.   DOI
75 Kabsch-Korbutowicz M. Ultrafiltration as a method of separation of natural organic matter from water. Mater. Sci. 2008;26.
76 Fiksdal L, Leiknes T. The effect of coagulation with MF/UF membrane filtration for the removal of virus in drinking water. J. Memb. Sci. 2006;279:364-371.   DOI
77 Jung J, Kim Y, Park Y, Lee S, Kim D. Optimization of coagulation conditions for pretreatment of microfiltration process using response surface methodology. Environ. Eng. Res. 2015;20:223-229.   DOI
78 Kabsch-Korbutowicz M. Removal of natural organic matter from water by in-line coagulation/ultrafiltration process. Desalination. 2006;200:421-423.   DOI
79 Lee BB, Choo KH, Chang D, Choi SJ. Optimizing the coagulant dose to control membrane fouling in combined coagulation/ ultrafiltration systems for textile wastewater reclamation. Chem. Eng. J. 2009;155:101-107.   DOI
80 Hatt JW, Germain E, Judd SJ. Precoagulation-microfiltration for wastewater reuse. Water Res. 2011;45:6471-6478.   DOI
81 Matsushita T, Shirasaki N, Tatsuki Y, Matsui Y. Investigating norovirus removal by microfiltration, ultrafiltration, and precoagulation- microfiltration processes using recombinant norovirus virus-like particles and real-time immuno-PCR. Water Res. 2013;47:5819-5827.   DOI
82 Kim H-C, Hong JH, Lee S. Fouling of microfiltration membranes by natural organic matter after coagulation treatment: A comparison of different initial mixing conditions. J. Memb. Sci. 2006;283:266-272.   DOI
83 Kim H-C. Microfiltration of humic-rich water coagulated with cationic polymer: The effects of particle characteristics on the membrane performance. J. Memb. Sci. 2015;475:349-356.   DOI
84 Wan M-W, Yang H-L, Chang C-H, Reguyal F, Kan C-C. Fouling Elimination of PTFE Membrane under Precoagulation Process Combined with Ultrasound Irradiation. J. Environ. Eng. 2012;138:337-343.   DOI
85 Dong BZ, Chen Y, Gao NY, Fan JC. Effect of coagulation pretreatment on the fouling of ultrafiltration membrane. J. Environ. Sci. 2007;19:278-283.   DOI
86 Kim H-C, Lee S-J, Byun S., Y M. Application of improvedrapid mixing for enhanced removal of dissolved organic matter and DBPFP(disinfection by-product formation potential) control. Water Sci. Technol. Water Supply 2006;6:49-57.
87 Park P, Lee C, Choib S, Choo K, Kimd S, Yoone C. Effect of the removal of DOMs on the performance of a coagulation-UF membrane system for drinking water production. Desalination 2002;145:237-245.   DOI
88 Miller DJ, Kasemset S, Wang L, Paul DR, Freeman BD. Constant flux cross flow filtration evaluation of surface-modi fi ed fouling-resistant membranes. J. Memb. Sci. 2014;452:171-183.   DOI
89 Guigui C, Roucha JC, Bonnelyeb V, Aptel P. Impact of coagulation conditions on the in-line coagulationKJF process for drinking water production. Desalination 2002;147:95-100.   DOI
90 Liu P, Hill VR, Hahn D, Johnson TB, Pan Y, Jothikumar N, et al. Hollow- fiber ultrafiltration for simultaneous recovery of viruses, bacteria and parasites from reclaimed water. J. Microbiol Methods 2012;88:155-161.   DOI
91 Smith CM, Hill VR. Dead-end hollow-fiber ultrafiltration for recovery of diverse microbes from water. Appl. Environ. Microbiol. 2009;75:5284-5289.   DOI
92 Liang H, Gong W, Chen J, Li G. Cleaning of fouled ultrafiltration (UF) membrane by algae during reservoir water treatment. Desalination 2008;220:267-272.   DOI
93 Liu Y, Li X, Yang Y, Liang S. Fouling control of PAC/UF process for treating algal-rich water. Desalination 2015;355:75-82.   DOI
94 Li K, Qu F, Liang H, Shao S, Han ZS, Chang H, et al. Performance of mesoporous adsorbent resin and powdered activated carbon in mitigating ultrafiltration membrane fouling caused by algal extracellular organic matter. Desalination 2014;336:129-137.   DOI
95 Gai X-J, Kim H-S. The role of powdered activated carbon in enhancing the performance of membrane systems for water treatment. Desalination 2008;225:288-300.   DOI
96 Kim H-S, Takizawa S, Ohgaki S. Application of microfiltration systems coupled with powdered activated carbon to river water treatment. Desalination 2007;202:271-277.   DOI
97 Kim J, Cai Z, Benjamin MM. Effects of adsorbents on membrane fouling by natural organic matter. J. Memb. Sci. 2008;310:356-364.   DOI
98 Lee JW, Chun JI, Jung HJ, Kwak DH. Comparative Studies on Coagulation and Adsorption as a Pretreatment Method for the Performance Improvement of Submerged MF Membrane for Secondary Domestic Wastewater Treatment. Sep. Sci. Technol. 2005;40:2613-2632.   DOI
99 Haberkamp J, Ruhl AS, Ernst M, Jekel M. Impact of coagulation and adsorption on DOC fractions of secondary effluent and resulting fouling behaviour in ultrafiltration. Water Res. 2007;41:3794-3802.   DOI
100 Lee J, Walker HW. Effect of process variables and natural organic matter on removal of microcystin-LR by PAC-UF. Environ. Sci. Technol. 2006;40:7336-7342.   DOI
101 Ying Z, Ping G. Effect of powdered activated carbon dosage on retarding membrane fouling in MBR. Sep. Purif. Technol. 2006;52:154-160.   DOI
102 Torretta V, Urbini G, Raboni M, Copelli S, Viotti P, Luciano A, et al. Effect of powdered activated carbon to reduce fouling in membrane bioreactors: A sustainable solution. Case study. Sustain. 2013;5:1501-1509.   DOI
103 Saravia F, Naab P, Frimmel FH. Influence of particle size and particle size distribution on membrane-adsorption hybrid systems. Desalination 2006;200:446-8.   DOI
104 Jia Y, Wang R, Fane AG. Hybrid PAC-submerged membrane system for trace organics removal II: System simulation and application study. Chem. Eng. J. 2009;149:42-49.   DOI
105 Vigneswaran S, Guo WS, Smith P, Ngo HH. Submerged membrane adsorption hybrid system (SMAHS): process control and optimization of operating parameters. Desalination 2007;202:392-399.   DOI
106 Oh H, Yu M, Takizawa S, Ohgaki S. Evaluation of PAC behavior and fouling formation in an integrated PAC - UF membrane for surface water treatment. Desalination 2006;192:54-62.   DOI
107 M YM, Yuasa A, Ariga K. Removal of a synthetic organic chemical by PAC-UF Systems-I: Theory and modeling. Water Res. 2001;35:455-463.   DOI