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http://dx.doi.org/10.12989/mwt.2015.6.1.077

Ultrafiltration membranes for drinking-water production from low-quality surface water: A case study in Spain  

Rojas-Serrano, Fatima (Technologies for Water Management and Treatment Research Group, University of Granada, Department of Civil Engineering)
Alvarez-Arroyo, Rocio (Technologies for Water Management and Treatment Research Group, University of Granada, Department of Civil Engineering)
Perez, Jorge I. (Technologies for Water Management and Treatment Research Group, University of Granada, Department of Civil Engineering)
Plaza, Fidel (Department of Research and Development, CADAGUA S.A.)
Garralon, Gloria (Department of Research and Development, CADAGUA S.A.)
Gomez, Miguel A. (Technologies for Water Management and Treatment Research Group, University of Granada, Department of Civil Engineering)
Publication Information
Membrane and Water Treatment / v.6, no.1, 2015 , pp. 77-94 More about this Journal
Abstract
Ultrafiltration membranes have several advantages over conventional drinking-water treatment. However, this technology presents major limitations, such as irreversible fouling and low removal of natural organic matter. Fouling depends heavily on the raw-water quality as well as on the operating conditions of the process, including flux, permeate recovery, pre-treatment, chemical cleaning, and backwashing. Starting with the premise that the optimisation of operating variables can improve membrane performance, different experiments were conducted in a pilot plant located in Granada (Spain). Several combinations of permeate and backwashing flow rates, backwashing frequencies, and aeration flow rates were tested for low-quality water coming from Genil River with the following results: the effluent quality did not depend on the combination of operating conditions chosen; and the membrane was effective for the removal of microorganisms, turbidity and suspended solids but the yields for the removal of dissolved organic carbon were extremely low. In addition, the threshold transmembrane pressure (-0.7 bar) was reached within a few hours and it was difficult to recover due to the low efficiency of the chemical cleanings. Moreover, greater transmembrane pressure due to fouling also increased the energy consumption, and it was not possible to lower it without compromising the permeate recovery. Finally, the intensification of aeration contributed positively to lengthening the operation times but again raised energy consumption. In light of these findings, the feasibility of ultrafiltration as a single treatment is questioned for low-quality influents.
Keywords
economical feasibility; fouling; natural organic matter; transmembrane pressure; ultrafiltration;
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  • Reference
1 Amy, G. (2008), "Fundamental understanding of organic matter fouling of membranes", Desalination, 231(1-3), 44-51.   DOI
2 Aoustin, E., Schafer, A.I., Fane, A.G. and Waite, T.D. (2001), "Ultrafiltration of natural organic matter", Sep. Purif. Tech., 22-23, 63-78.   DOI
3 Arnal, J.M., Sancho, M., Garcia Fayos, B., Lora, J. and Verdu, G. (2007), "Aquapot: UF real applications for water potabilization in developing countries. Problems, location and solutions adopted", Desalination, 204(1-3), 316-321.   DOI
4 Baker, R.W. (2004), Membrane Technology and Applications, John Wiley and Sons, Chichester, WS, UK.
5 Bellara, S.R., Cui, Z.F. and Pepper, D.S. (1996), "Gas sparging to enhance permeate flux in ultrafiltration using hollow fibre membranes", J. Memb. Sci., 121(2), 175-184.   DOI
6 Betancourt, W.Q. and Rose, J.B. (2004), "Drinking water treatment processes for removal of Cryptosporidium and Giardia", Vet. Parasitol., 126(1-2), 219-234.   DOI
7 Braak, E., Alliet, M., Schetrite, S. and Albasi, C. (2011), "Aeration and hydrodynamics in submerged membrane bioreactors", J. Memb. Sci., 379(1-2), 1-18.   DOI
8 Cabassud, C., Laborie, S. and Laine, J.M. (1997), "How slug flow can improve ultrafiltration flux in organic hollow fibres", J. Memb. Sci., 128(1), 93-101.   DOI
9 Cheng, T.W. and Lee, Z.W. (2008), "Effects of aeration and inclination on flux performance of submerged membrane filtration", Desalination, 234 (1-3), 74-80.   DOI
10 Cornelissen, E.R., Vrouwenvelder, J.S., Heijman, S.G.J., Viallefont, X.D., Van Der Kooij, D. and Wessels, L.P. (2007), "Periodic air/water cleaning for control of biofouling in spiral wound membrane elements", J. Memb. Sci., 287(1), 94-101.   DOI
11 Cornelissen, E.R., Rebour, L., van der Kooij, D. and Wessels, L.P. (2009), "Optimization of air/water cleaning (AWC) in spiral wound elements", Desalination, 236(1-3), 266-272.   DOI
12 Crozes, G.F., Jacangelo, J.G., Anselme, C. and Laine, J.M. (1997) "Impact of ultrafiltration operating conditions on membrane irreversible fouling", J. Memb. Sci., 124(1), 63-76.   DOI
13 Cui, Z.F. and Taha, T. (2003), "Enhancement of ultrafiltration using gas sparging: A comparison of different membrane modules", J. Chem. Tech. Biotech., 78(2-3), 249-253.   DOI
14 Cui, Z.F., Chang, S. and Fane, A.G. (2003), "The use of gas bubbling to enhance membrane processes", J. Memb. Sci., 221(1-2), 1-35.   DOI   ScienceOn
15 Fernandez, G., Plaza F., Garralon, G., Garralon, A., Perez, J.I. and Gomez, M.A. (2012), "A comparative study of ultrafiltration and physicochemical process as pretreatment of seawater reverse osmosis", Desal. Wat. Treat., 42(1-3), 73-79.   DOI
16 Gao, W., Liang, H., Ma, J., Han, M., Chen, Z., Han, Z. and Li, G. (2011), "Membrane fouling control in ultrafiltration technology for drinking water production: A review", Desalination, 272(1-3), 1-8.   DOI
17 Jacangelo, J.G., Trussell, R.R. and Watson, M. (1997), "Role of membrane technology in drinking water treatment in the United States", Desalination, 113(2-3), 119-127.   DOI
18 Ghosh, R. (2006), "Enhancement of membrane permeability by gas-sparging in submerged hollow fibre ultrafiltration of macromolecular solutions: Role of module design", J. Memb. Sci., 274(1-2), 73-82.   DOI   ScienceOn
19 Guo, X., Zhang, Z., Fang, L. and Su, L. (2009), "Study on ultrafiltration for surface water by a polyvinylchloride hollow fiber membrane", Desalination, 238(1-3), 183-191.   DOI
20 Huang, H., Schwab, K. and Jacangelo, J.G. (2009), "Pretreatment for low pressure membranes in water treatment: A review", Environ. Sci. Tech., 43(9), 3011-3019.   DOI
21 Ji, L. and Zhou, J. (2006), "Influence of aeration on microbial polymers and membrane fouling in submerged membrane bioreactors", J. Memb. Sci., 276(1-2), 168-177.   DOI
22 Judd, S. (2011), The MBR book: Principles and Applications of Membrane Bioreactors for Water and Wastewater Treatment, Elsevier, Oxford, OX, UK.
23 Kimura, K., Hane, Y., Watanabe, Y., Amy, G. and Ohkuma, N. (2004), "Irreversible membrane fouling during ultrafiltration of surface water", Wat. Res., 38(14-15), 3431-3441.   DOI
24 Laborie, S., Cabassud, C., Durand-Bourlier, L. and Laine, J.M. (1998), "Fouling control by air sparging inside hollow fibre membranes - effects on energy consumption", Desalination, 118(1-3), 189-196.   DOI
25 Laine, J., Vial, D. and Moulart, P. (2000), "Status after 10 years of operation - Overview of UF technology today", Desalination, 131(1-3), 17-25.   DOI
26 Li, N. (2008), Advanced Membrane Technology and Applications, John Wiley and Sons, Hoboken, NJ, USA.
27 Mosqueda-Jimenez, D.B., Huck, P.M. and Basu, O.D. (2008), "Fouling characteristics of an ultrafiltration membrane used in drinking water treatment", Desalination, 230(1-3), 79-91.   DOI
28 Liu, J., Liu, B., Liu, T., Bai, Y. and Yu, S. (2014), "Coagulation-bubbling-ultrafiltration: effect of floc properties on the performance of the hybrid process", Desalination, 333(1), 126-133.   DOI
29 Masse, A., Nguyen Thi, H., Legentilhomme, P. and Jaouen, P (2011), "Dead-end and tangential ultrafiltration of natural salted water: Influence of operating parameters on specific energy consumption", J. Memb. Sci., 380(1-2) 192-198.   DOI
30 Mijatovic, I., Matosic, M., Cerneha, B.H. and Bratulic, D. (2004), "Removal of natural organic matter by ultrafiltration and nanofiltration for drinking water production", Desalination, 169(3), 223-230.   DOI
31 Peter-Varbanets, M., Zurbrugg, C., Swartz, C. and Pronk, W. (2009), "Decentralized systems for potable water and the potential of membrane technology", Wat. Res., 43(2), 245-265.   DOI
32 Porcelli, N. and Judd, S. (2010), "Chemical cleaning of potable water membranes: A review", Sep. Purif. Tech., 71(2), 137-143.   DOI   ScienceOn
33 Rojas, J.C., Moreno, B., Garralon, G., Plaza, F., Perez, J. and Gomez, M.A. (2008), "Potabilization of low NOM reservoir water by ultrafiltration spiral wound membranes", J. Hazard. Mat., 158(2-3), 593-598.   DOI
34 Rojas, J.C., Garralon, G., Plaza, F., Perez, J., Moreno, B. and Gomez, M.A. (2010), "Humic acids removal by aerated spiral-wound ultrafiltration membrane combined with coagulation-hydraulic flocculation", Desalination, 266(1-3), 128-133.   DOI
35 Shi, X., Tal, G., Hankins, N.P. and Gitis, V. (2014), "Fouling and cleaning of ultrafiltration membranes: A review". J. Water Process Engin., 1(121-138).   DOI
36 Xia, S., Li, X., Liu, R. and Li, G. (2005), "Pilot study of drinking water production with ultrafiltration of water from the Songhuajiang River (China)", Desalination, 179(1-3), 369-374.   DOI