Nanofiltration membranes to reduce phenol concentration in wastewater

Desalination

Volumn 245, Issue 1-3, 2009, Pages 680-686

  Bodalo A ^a   Gomez E ^a   Hidalgo, A M ^a   Gomez M ^a   Murcia, M D ^a   Lopez I ^a  

^a Grupo de Analisis y Simulacion de Procesos Quimicos   (Spain)

Author keywords

Membrane processes; Nanofiltration; Phenol; Wastewater

Indexed keywords

ADSORPTION PROCESS; AQUEOUS SOLUTIONS; BIOLOGICAL METHODS; ENVIRONMENTAL PROBLEMS; EXPERIMENTAL CONDITIONS; HYBRID PROCESS; MEMBRANE PROCESSES; OPERATING PRESSURE; PHENOL CONCENTRATION; PHENOL REMOVAL; PHENOLIC COMPOUNDS; PRESSURE DRIVEN MEMBRANES; RESEARCH GROUPS; WATER PERMEABILITY;

ADSORPTION; CHEMICAL COMPOUNDS; CHEMICALS REMOVAL (WATER TREATMENT); NANOFILTRATION; NANOFILTRATION MEMBRANES; PHENOLS; REVERSE OSMOSIS; WASTEWATER; WATER FILTRATION;

OSMOSIS MEMBRANES;

AQUEOUS SOLUTION; FILTRATION; MEMBRANE; PERMEABILITY; PHENOL; WASTEWATER; WATER TREATMENT;

EID: 67650756974     PISSN: 00119164     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.desal.2009.02.037     Document Type: Article

References (27)

1. Gellman I. Environmental effects of paper industry wastewater - an overview. Water Sci. Technol. 20 2 (1998) 59-65
2. Lista europea de sustancias contaminantes, available in Internet: http://eper.eea.europa.eu/eper/
3. Agency for Toxic Substances and Disease Registry (ATSDR), Toxicological profile for Phenol, Atlante, GA: US, Department of Health and Human Services, Public Health Service, 2006.
4. Milstein O. Removal of chlorophenols and chlorolignins from bleaching effluent by combined chemical and biological treatment. Water Sci. Technol. 20 1 (1988) 161-170
5. Wang R.C., Kuo C.C., and Shyu C.C. Adsorption of phenols onto granular activated carbon in a liquid-solid fluidized bed. J. Chem. Technol. Biotech. 68 2 (1997) 187-194
6. Wilson G.J., Khodadoust A.P., Suidan M.T., Brenner R.C., and Acheson C.M. Anaerobic/aerobic biodegradation of pentachlorophenol using GAC fluidized bed reactors: optimization of the empty bed contact time. Water Sci. Technol. 38 7 (1998) 9-17
7. Kataoka T., Nishiki T., and Kimura S. Phenol permeation through liquid surfactant membrane-permeation model and effective diffusivity. J. Membr. Sci. 41 (1989) 197-209
8. Kujawski W., Warszawski A., Ratajczak W., Porebski T., Capala W., and Ostrowska I. Removal of phenol by different separation techniques. Desalination 163 1-3 (2004) 287-296
9. Wan Y.H., Wang X., and Zhang X.J. Treatment of high concentration phenolic wastewater by liquid membrane with N503 as mobile carrier. J. Membr. Sci. 135 (1997) 263-270
10. Reis M.T.A., Freitas O.M.F., Ismael M.R.C., and Carvalho J.M.R. Recovery of phenol from aqueous solutions using liquid membranes with Cyanex 923. J. of Membr. Sci. 305 (2007) 313-324
11. Correia P.F.M.M., and Carvalho J.M.R. Recovery of phenol from phenolic resin plant effluents by emulsion liquid membranes. J. Membr. Sci. 225 (2003) 41-49
12. Kojima T., Nishijima N., and Matsukata M. Removal and recovery of phenol from FCC efluent. J. Membr. Sci. 102 (1995) 43-47
13. Arsuaga J.M., López M.J., Sotto A., and Rosario G. Retention of phenols and carboxylic acids by nonofiltration/reverse osmosis membranes: sieving and membrane-solute interaction effects. Desalination 200 (2006) 731-733
14. Schutte C.F. The rejection of specific organic compounds by reverse osmosis membranes. Desalination 158 1-3 (2003) 285-294
15. Ben-Daid A., Bason S., Jopp J., Oren Y., and Freger V. Partitioning of organic solutes between water and polyamide layer of RO and NF membranes: correlation to rejection. J. Membr. Sci. 281 1-2 (2006) 480-490
16. Gupta T., Pradhan N.C., and Adhikari B. Separation of phenol from aqueous solution by pervaporation using HTPB-based polyurethaneurea membrane. J. Membr. Sci. 217 (2003) 43-53
17. Pereira C.C., Habert A.C., Nobrega R., and Borges C.P. New insights in the removal of diluted volatile compounds from dilute aqueous solution by pervaportion process. J. Membr. Sci. 138 (1998) 227-235
18. Wu P., Field R.W., England R., and Brisdon B.J. A fundamental study of organofunctionalised PDMS membranes for the pervorative recovery of phenolic compounds from aqueous streams. J. Membr. Sci. 190 (2001) 147-157
19. Ipek U. Phenol removal capacity of RO with and without pre-treatment. Filt. Sep. 41 7 (2004) 39-40
20. Sagehashi M., Nomura T., Shishido H., and Sakoda A. Separation of phenols and furfural by pervaporation and reverse osmosis membranes from biomass-superheated steam pirolisis-derived aqueous solution. Bioresour. Technol. 98 (2007) 2018-2026
21. Marrot B., Barrios A., Moulin P., and Roche N. Biodegradation of high phenol concentration by activated sludge in an immersed membrane bioreactor. Biochem. Eng. J. 30 (2006) 174-183
22. Juang R., and Tsai S. Role of membrane-attached biofilm in the biodegradation of phenol and sodium salicylate in microporous membrane bioreactors. J. Membr. Sci. 283 (2006) 484-492
23. Barrios A., Barbot E., Marrot B., Moulin P., and Roche N. Degradation of synthetic phenolcontaining wastewaters by MBR. J. Membr. Sci. 281 (2006) 288-296
24. Bódalo A., Gómez J.L., Gómez M., León G., Hidalgo A.M., and Ruíz M.A. Phenol removal from water by hybrid processes: study of the membrane process step. Desalination 223 (2008) 323-329
25. Standard Methods for the Examination of Water and Wastewater, 19th Ed., Method 5530, Section 5, 1995, pp. 36-39.
26. Ahmad A.L., and Tan K.Y. Reverse osmosis of binary organic solutes mixtures in the presence of strong solute-membrane affinity. Desalination 165 (2004) 193-199
27. Lin S.H., Hsiao R.C., and Juang R.S. Removal of soluble organics from water by a hybrid process of clay adsorption and membrane filtration. J. Hazard. Mater. 135 1-3 (2006) 134-140