Fouling of WO3 nanoparticle-incorporated PSf membranes in ultrafiltration of landfill leachate and dairy a combined wastewaters:An investigation using model

doi:10.1016/j.cjche.2016.12.001

Abstract

Abstract: As fouling has always been a major drawback of membrane technology, qualitative and quantitative understanding of membrane fouling mechanisms therefore becomes vital in order to help push membrane separation technologies forward. In this study, firstly, self-cleaning Polysulfone (PSf) membranes were synthesized by incorporation of WO₃ nanoparticles (0-2 wt%) and subsequent UV irradiation for efficient ultrafiltration (UF) of landfill leachate and dairy wastewater. The membrane surface properties were characterized by scanning electron microscopy (SEM) and contact angle analysis. It was found that UV-irradiated membranes exhibited higher percent COD removals due to the hydrophilicity and photocatalytic properties of nano-WO₃. Subsequently, in order to analyze the fouling behavior of the membranes, a set of experimental data from cross-flow ultrafiltration of municipal landfill leachate and industrial dairy wastewater at 25℃ was obtained. A new model of membrane fouling was proposed based on a resistance in series concept and was fitted well with all experimental data sets. Almost all relative errors of prediction provided by the proposed model were less than 2.5%. In addition, it was revealed that this newly-developed model exhibited smooth transition between the common successive twostep pore blockage-cake filtration phenomena and thus eliminates the need to use separate equations for different mechanisms.

Key words: Fouling model, Leachate wastewater, Ultrafiltration, Whey wastewater, Chemical oxygen demand

摘要： As fouling has always been a major drawback of membrane technology, qualitative and quantitative understanding of membrane fouling mechanisms therefore becomes vital in order to help push membrane separation technologies forward. In this study, firstly, self-cleaning Polysulfone (PSf) membranes were synthesized by incorporation of WO₃ nanoparticles (0-2 wt%) and subsequent UV irradiation for efficient ultrafiltration (UF) of landfill leachate and dairy wastewater. The membrane surface properties were characterized by scanning electron microscopy (SEM) and contact angle analysis. It was found that UV-irradiated membranes exhibited higher percent COD removals due to the hydrophilicity and photocatalytic properties of nano-WO₃. Subsequently, in order to analyze the fouling behavior of the membranes, a set of experimental data from cross-flow ultrafiltration of municipal landfill leachate and industrial dairy wastewater at 25℃ was obtained. A new model of membrane fouling was proposed based on a resistance in series concept and was fitted well with all experimental data sets. Almost all relative errors of prediction provided by the proposed model were less than 2.5%. In addition, it was revealed that this newly-developed model exhibited smooth transition between the common successive twostep pore blockage-cake filtration phenomena and thus eliminates the need to use separate equations for different mechanisms.

关键词: Fouling model, Leachate wastewater, Ultrafiltration, Whey wastewater, Chemical oxygen demand

Majid Peyravi, Mohsen Jahanshahi, Soodabeh Khalili. Fouling of WO₃ nanoparticle-incorporated PSf membranes in ultrafiltration of landfill leachate and dairy a combined wastewaters:An investigation using model[J]. , 2017, 25(6): 741-751.

References

[1] A. Salahi, M. Abbasi, T. Mohammadi, Permeate flux decline during UF of oily wastewater:Experimental and modeling, Desalination 251(1) (2010) 153-160.
[2] J. Hermia, Constant pressure blocking filtration law application to powder-law nonNewtonian fluid, Trans. Inst. Chem. Eng. 60(1982) 183-187.
[3] K.-J. Hwang, T.-T. Lin, Effect of morphology of polymeric membrane on the performance of cross-flow microfiltration, J. Membr. Sci. 199(1) (2002) 41-52.
[4] M.C.V. Vela, S.Á. Blanco, J.L. García, E.B. Rodríguez, Analysis of membrane pore blocking models applied to the ultrafiltration of PEG, Sep. Purif. Technol. 62(3) (2008) 489-498.
[5] A. Salahi, A. Gheshlaghi, T. Mohammadi, S.S. Madaeni, Experimental performance evaluation of polymeric membranes for treatment of an industrial oily wastewater, Desalination 262(1) (2010) 235-242.
[6] T. Mohammadi, M. Kazemimoghadam, M. Saadabadi, Modeling of membrane fouling and flux decline in reverse osmosis during separation of oil in water emulsions, Desalination 157(1) (2003) 369-375.
[7] Y. Pan, W. Wang, T. Wang, P. Yao, Fabrication of carbon membrane and microfiltration of oil-in-water emulsion:An investigation on fouling mechanisms, Sep. Purif. Technol. 57(2) (2007) 388-393.
[8] T. Arnot, R. Field, A. Koltuniewicz, Cross-flow and dead-end microfiltration of oilywater emulsions:Part Ⅱ. Mechanisms and modelling of flux decline, J. Membr. Sci. 169(1) (2000) 1-15.
[9] M.C.V. Vela, S.Á. Blanco, J.L. García, E.B. Rodríguez, Analysis of membrane pore blocking models adapted to crossflow ultrafiltration in the ultrafiltration of PEG, Chem. Eng. J. 149(1) (2009) 232-241.
[10] E.-E. Chang, S.-Y. Yang, C.-P. Huang, C.-H. Liang, P.-C. Chiang, Assessing the fouling mechanisms of high-pressure nanofiltration membrane using the modified Hermia model and the resistance-in-series model, Sep. Purif. Technol. 79(3) (2011) 329-336.
[11] E.-E. Chang, Y.-C. Chang, C.-H. Liang, C.-P. Huang, P.-C. Chiang, Identifying the rejection mechanism for nanofiltration membranes fouled by humic acid and calcium ions exemplified by acetaminophen, sulfamethoxazole, and triclosan, J. Hazard. Mater. 221(2012) 19-27.
[12] I.N.H.M. Amin, A.W. Mohammad, M. Markom, L.C. Peng, N. Hilal, Analysis of deposition mechanism during ultrafiltration of glycerin-rich solutions, Desalination 261(3) (2010) 313-320.
[13] N. Shafaei, M. Peyravi, M. Jahanshahi, G. Najafpour, Self-cleaning behavior of nanocomposite membrane induced by photocatalytic WO₃ nanoparticles for landfill leachate treatment, Korean J. Chem. Eng. 33(10) (2016) 2968-2981.
[14] G. Romanos, C. Athanasekou, V. Likodimos, P. Aloupogiannis, P. Falaras, Hybrid ultrafiltration/photocatalytic membranes for efficient water treatment, Ind. Eng. Chem. Res. 52(39) (2013) 13938-13947.
[15] A. Rahimpour, S. Madaeni, A. Taheri, Y. Mansourpanah, Coupling TiO₂ nanoparticles with UV irradiation for modification of polyethersulfone ultrafiltration membranes, J. Membr. Sci. 313(1) (2008) 158-169.
[16] O. Carp, C.L. Huisman, A. Reller, Photoinduced reactivity of titanium dioxide, Prog. Solid State Chem. 32(1) (2004) 33-177.
[17] P. Ragesh, V.A. Ganesh, S.V. Nair, A.S. Nair, A review on ‘self-cleaning and multifunctional materials’, J. Mater. Chem. A 2(36) (2014) 14773-14797.
[18] S. Chakrabarti, B.K. Dutta, Photocatalytic degradation of model textile dyes in wastewater using ZnO as semiconductor catalyst, J. Hazard. Mater. 112(3) (2004) 269-278.
[19] I.P. Parkin, R.G. Palgrave, Self-cleaning coatings, J. Mater. Chem. 15(17) (2005) 1689-1695.
[20] C. Duclos-Orsello, W. Li, C.-C. Ho, A three mechanism model to describe fouling of microfiltration membranes, J. Membr. Sci. 280(1) (2006) 856-866.
[21] G. Bolton, D. LaCasse, R. Kuriyel, Combined models of membrane fouling:Development and application to microfiltration and ultrafiltration of biological fluids, J. Membr. Sci. 277(1) (2006) 75-84.
[22] C.-C. Ho, A.L. Zydney, A combined pore blockage and cake filtration model for protein fouling during microfiltration, J. Colloid Interface Sci. 232(2) (2000) 389-399.
[23] A. Asatekin, S. Kang, M. Elimelech, A.M. Mayes, Anti-fouling ultrafiltration membranes containing polyacrylonitrile-graft-poly (ethylene oxide) comb copolymer additives, J. Membr. Sci. 298(1) (2007) 136-146.
[24] S. Brownlow, J.H.M. Cabral, R. Cooper, D.R. Flower, S.J. Yewdall, I. Polikarpov, A.C.T. North, L. Sawyer, Bovine β-lactoglobulin at 1.8Å resolution-Still an enigmatic lipocalin, Structure 5(4) (1997) 481-495.
[25] M. Peyravi, A. Rahimpour, M. Jahanshahi, Thin film composite membranes with modified polysulfone supports for organic solvent nanofiltration, J. Membr. Sci. 423-424(2012) 225-237.
[26] H. Yu, X. Zhang, Y. Zhang, J. Liu, H. Zhang, Development of a hydrophilic PES ultrafiltration membrane containing SiO₂@N-Halamine nanoparticles with both organic antifouling and antibacterial properties, Desalination 326(2013) 69-76.
[27] S. Madaeni, N. Ghaemi, Characterization of self-cleaning RO membranes coated with TiO₂ particles under UV irradiation, J. Membr. Sci. 303(1) (2007) 221-233.
[28] H. Irie, K. Hashimoto, Photocatalytic active surfaces and photo-induced high hydrophilicity/high hydrophobicity, Environmental Photochemistry Part Ⅱ, Springer 2005, pp. 425-450.
[29] S. You, C. Wu, Fouling removal of UF membrane with coated TiO₂ nanoparticles under UV irradiation for effluent recovery during TFT-LCD manufacturing, Int. J. Photoenergy 2013(2013).
[30] C. Liu, S. Caothien, J. Hayes, T. Caothuy, T. Otoyo, T. Ogawa, Membrane Chemical Cleaning:From Art to Science, Pall Corporation, Port Washington, NY 11050, 2001.
[31] K. Guan, Relationship between photocatalytic activity, hydrophilicity and selfcleaning effect of TiO₂/SiO₂ films, Surf. Coat. Technol. 191(2) (2005) 155-160.
[32] M. Peyravi, A. Rahimpour, M. Jahanshahi, Developing nanocomposite PI membranes:Morphology and performance to glycerol removal at the downstream processing of biodiesel production, J. Membr. Sci. 473(2015) 72-84.
[33] Y. Yang, H. Zhang, P. Wang, Q. Zheng, J. Li, The influence of nano-sized TiO₂ fillers on the morphologies and properties of PSF UF membrane, J. Membr. Sci. 288(1) (2007) 231-238.
[34] N. Hilal, M. Khayet, C.J. Wright, Membrane Modification:Technology and Applications, Taylor & Francis, New York, 2012.
[35] Y.S. Al-Degs, A.H. El-Sheikh, M.A. Al-Ghouti, B. Hemmateenejad, G.M. Walker, Solidphase extraction and simultaneous determination of trace amounts of sulphonated and azo sulphonated dyes using microemulsion-modified-zeolite and multivariate calibration, Talanta 75(4) (2008) 904-915.
[36] T. Jiang, M.D. Kennedy, W.G. van der Meer, P.A. Vanrolleghem, J.C. Schippers, The role of blocking and cake filtration in MBR fouling, Desalination 157(1) (2003) 335-343.
[37] Z. Wang, J. Ma, C.Y. Tang, K. Kimura, Q. Wang, X. Han, Membrane cleaning in membrane bioreactors:A review, J. Membr. Sci. 468(2014) 276-307.
[38] M. Peyravi, A. Rahimpour, M. Jahanshahi, A. Javadi, A. Shockravi, Tailoring the surface properties of PES ultrafiltration membranes to reduce the fouling resistance using synthesized hydrophilic copolymer, Microporous Mesoporous Mater. 160(2012) 114-125.
[39] I. Axelsson, Characterization of proteins and other macromolecules by agarose gel chromatography, J. Chromatogr. A 152(1) (1978) 21-32.
[40] S.A. Patil, V.V. Ahire, M.H. Hussain, Dairy wastewater-A case study, Int. J. Res. Eng. Technol. 03(09) (2014) 30-34.
[41] T.V. Adulkar, V.K. Rathod, Ultrasound assisted enzymatic pre-treatment of high fat content dairy wastewater, Ultrason. Sonochem. 21(3) (2014) 1083-1089.
[42] B. Demirel, O. Yenigun, T.T. Onay, Anaerobic treatment of dairy wastewaters:A review, Process Biochem. 40(8) (2005) 2583-2595.
[43] S.T. Kelly, A.L. Zydney, Mechanisms for BSA fouling during microfiltration, J. Membr. Sci. 107(1) (1995) 115-127.
[44] S.T. Kelly, W.S. Opong, A.L. Zydney, The influence of protein aggregates on the fouling of microfiltration membranes during stirred cell filtration, J. Membr. Sci. 80(1) (1993) 175-187.

Fouling of WO₃ nanoparticle-incorporated PSf membranes in ultrafiltration of landfill leachate and dairy a combined wastewaters:An investigation using model

Fouling of WO₃ nanoparticle-incorporated PSf membranes in ultrafiltration of landfill leachate and dairy a combined wastewaters:An investigation using model

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