Macromolecular Research, Vol.23, No.2, 183-188, February, 2015
Preparation of a new charged nanofiltration membrane based on polyelectrolyte complex by forced fouling induction for a household water purifier
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A new technique is introduced for the preparation of composite membranes based on the salting-out effect. The concept of this new technique consists of three parts: (i) polymer precipitation by the salting-out effect, (ii) blocking the pore structure by pressurizing the precipitated polymer particles (polyelectrolyte), and (iii) deposition of opposite charged polyelectrolyte through ionic cross-linking (polyelectrolyte complex). The pore blocked polyelectrolyte has the role of a membrane, and we called this membrane preparation technique by forced fouling induction “precipitated solute pressurization” (PSP). In this study, water-soluble polymers that are all polyelectrolytes were used as coating materials, namely polyethylenimine (PEI), poly(styrene sulfonic acid-co-maleic acid) (PSSA_MA), and poly(vinyl sulfonic acid) (PVSA). The polymer particles formed by the addition of Mg(NO3)2·6H2O were pressurized and flown to the surface of microporous polyvinyledene fluoride (PVDF) to prepare composite membranes under varying conditions of polyelectrolyte concentration, ionic strength of salt, pressure, annealing temperature, etc. The resulting membranes were characterized in terms of the flux and rejection for 100 ppm NaCl at 4 atm to determine their suitability for application in a household water purifier. A combination of PVSA and PEI polyelectrolyte complex produced by the PSP method showed the best performance of flux of 43 LMH and salt rejection rate of 83%, and this performance was maintained without loss of flux or rejection rate in a durability test carried out for 10 days.
Keywords:charged nanofiltration membrane;salting-out;polyelectrolyte complex;forced fouling induction;hollow fiber composite membrane
- Lu XF, Bian XK, Shi LQ, J. Membr. Sci., 210(1), 3 (2002)
- Schafer AI, Fane AG, Waite TD, Water Res., 36, 1509 (2001)
- Gorenflo A, Velazquez-Padron D, Frimmel FH, Desalination, 151, 253 (2002)
- Petersen RJ, Membr J, Sci., 83, 81 (1993)
- Petersen RJ, Cadotte JE, Thin Film Composite Reverse Osmosis Membranes, in Handbook of Industrial Membrane Technology, Porter MC, Ed., Noyes Publications, Park Ridge (1990)
- Tang CY, Fu QS, Robertson AP, Criddle CS, Leckie JO, Environ. Sci. Technol, 40, 7343 (2006)
- Tang CYY, Kwon YN, Leckie JO, J. Membr. Sci., 287(1), 146 (2007)
- Tang CYY, Kwon YN, Leckie JO, Desalination, 242(1-3), 149 (2009)
- Kim IC, Yoon HG, Lee KH, J. Appl. Polym. Sci., 84(6), 1300 (2002)
- Musale DA, Kumar A, Sep. Purif. Technol., 21(1-2), 27 (2000)
- Decher G, Science, 277(5330), 1232 (1997)
- Stanton BW, Harris JJ, Miller MD, Bruening ML, Langmuir, 19(17), 7038 (2003)
- Hong SU, Bruening ML, J. Membr. Sci., 280(1-2), 1 (2006)
- Li XF, Feyter SD, Chen DJ, Aldea S, Vandezande P, Prez FD, Vankelecom IFJ, Chem. Mater, 20, 3876 (2008)
- Miao J, Chen GH, Gao CJ, Desalination, 181(1-3), 173 (2005)
- Huang RH, Chen GH, Sun MK, Hu YM, Gao CJ, J. Membr. Sci., 286(1-2), 237 (2006)
- Dong TT, Chen GH, Gao CJ, J. Membr. Sci., 304(1-2), 33 (2007)
- Huang RH, Chen GH, Sun MK, Gao CJ, Desalination, 239(1-3), 38 (2009)
- Xu TW, Yang WH, J. Membr. Sci., 215(1-2), 25 (2003)
- Jin HT, An QF, Zhao Q, Qian JW, Zhu MH, J. Membr. Sci., 347(1-2), 183 (2010)
- Guo YM, Geng W, Sun JQ, Langmuir, 25(2), 1004 (2009)
- Ji YL, An QF, Zhao Q, Chen HL, Qian JW, Gao CJ, J. Membr. Sci., 357(1-2), 80 (2010)
- Rhim JW, Lee B, Park HH, Seo CH, Macromol. Res., 22(4), 361 (2014)
- Cheong SI, Kim B, Lee H, Rhim JW, Macromol. Res., 20, 629 (2013)
- Park CJ, Kim SP, Cheong SI, Rhim JW, Polym.(Korea), 36(6), 810 (2012)
- Kim B, Lee H, Lee B, Kim S, Cheong SI, Rhim JW, Polym.(Korea), 35(5), 438 (2011)
- Ries PD, McDonald CJ, WO 95/03878 (1997)