MEMBRANES SEPARATION PROCESS FOR OILY WASTEWATER TREATMENT
محتوى المقالة الرئيسي
الملخص
Pilot-scale dead end microfiltration membranes were carried out to determine the feasibility of the
process for treating the oily wastewater which discharge from some Iraqi factories such as power station of south of Baghdad and the general company of petrochemical industries. Polypropylene membranes
(cylindrical shape) with different pore diameters (1 and 5 micron) were used to conduct the study on
micromembrane process. The variables studied are oil concentration (100 – 1000 ppm), feed flow rate (20 –
40 l/h), operating temperature (31 – 50°C) and time (0 – 3 h). It was found that the flux increases with
increasing feed flow rate, temperature and pore size of membrane, and decreases with increasing oil
concentration and operating time. It was found also that the effect of feed oil concentration has the greatest effect on the fouling of membrane among other variables. The percent rejection of oil improved significantly with decreasing oil concentration but decreased with increasing feed temperature, pore size of membrane and operating time. Feed flow rate has slightly effect on oil rejection. The type of oil used in this work is 20W-50 gasoline and diesel engine oil. A general model of dead end filtration mode has been successfully evaluated to explain fundamental mechanisms involved in flux decline during dead end microfiltration of oily water emulsions. Analysis of the fall in flux with time for the polypropylene membrane (5 μm) indicates that intermediate and standard pore models give the best prediction for experimental behavior. Empirical correlations for the prediction of the flux and percent reject of oil were determined in this study. These equations have the correlation coefficient 98.87% and 91.49% respectively.
تفاصيل المقالة
القسم
كيفية الاقتباس
المراجع
• Mohammadi, T., Kazemimoghadam, M. and Saadabadi, M., 2003, "Modeling of Membrane Fouling and
Flux Decline in Reverse Osmosis During Separation of Oil in Water Emulsions", Desalination (157), 369 – 375.
• Percy, J.A., 1982, "Benthic and Intertidal Organisms Oil and Dispersant inCanadian Seas", Environment Canada
Report EPS3 – EC-82-2, Ottawa, Canada.
• Jassim, M.K., 2008, "Using of Local Bentonite for Removal of Oil Contaminants from Industrial Wastewater", M.Sc. Thesis, University of Baghdad.
• Iraqi limits for rivers maintenance system from pollution and specialized with discharge water discarded to water
sources (rivers) No. 25, 1967.
• Shams Ashaghi, K., Ebrahimi, M. and Czermak, P., 2007, "Ceramic Ultra- and Nanofiltration Membranes for Oilfield
Produced Water Treatment: A Mini Review", The Open Environmental Journal, (1), 1-8.
• Mike, P. and Ivan, A.C., 2008, "Ultrafiltration for Oily Industrial Water", NC AWWA-WEA conference November17.
• Syed, R.Q. Edward, M.M. and Guang Z., 2000, "Water Works Engineering: Planning, Design, and Operation",
Prentice – Hall, Inc., USA.
• Cheryana, M. and Rajagopalanb, N., 1998, "Membrane Processing of Oily Streams. Wastewater Treatment and
Waste Reduction", Journal of Membrane Science (151), 13 – 28.
• Cheryan, M., 1998, "Ultrafiltration and Microfiltration Handbook", Technomic, Lancaster, PA.
• Rune, G., 1985, "Microfiltration – State of the Art", Desalination (53), 363 – 372.
• John, A.B., 2003, "Feasibility of Cross- Flow Microfiltration for Combined Sewer Overflows", M.Sc. Thesis, Pittsburgh
University.
• Mohammed, B., 2008, "Membrane Separation Process for Treatment and Reuse of Water from Effluents of Cooling
Towers", M.Sc. Thesis, University of Baghdad.
• Zaidi, A., Simms, K., Kok, S. and Nelson, R., 1992, "Recent Advances in the Application of Membrane Technology for
the Removal of Oil and Suspended Solids from Produced Water", in J.P. Ray and ER. Engelhart (Eds.) Produced Water,
Plenum Press, New York, 1992.
• Jeffrey, M., Yanwei, C. and Robert H.D., 1997, "Crossflow microfiltration of oily water", Journal of Membrane Science
(129), 221– 235.
• John, C.C., Rhodes, R.T., David, W.H., Kerry, J.H., and George, T., 2005, "Water Treatment: Principles and Design", John
Wiley & Sons, Inc., 2nd Ed.
• Lim, A.L., and Renbi, B., 2003, "Membrane Fouling and Cleaning in Microfiltration of Activated Sludge
Wastewater", Journal of Membrane Science (216), 279– 290.
• Hermia, J., 1982, "Constant pressure blocking filtration laws-application to power-law non-Newtonian fluids", Chem.
Eng. Res. Des., (60), 183–187.
• Ohyaa, H., Kimb, J.J., Chinena, A., Aiharaa, M., Semenovaa, S.I., Negishia, Y., Moric, O., and Yasudac, M., 1998,
"Effects of pore size on separation mechanisms of microfiltration of oily water, using porous glass tubular
membrane", Journal of Membrane Science (145), 1– 14.
• Nandi, B.K., Moparthi, A., Uppaluri, R. and Purkait, M.K., 2010, "Treatment of oily wastewater using low cost ceramic
membrane: Comparative assessment of pore blocking and artificial neural network models", chemical engineering
research and design, journal homepage: www.elsevier.com/locate/cherd.
• Peng, H. and Tremblay, A.Y., 2008, "Membrane regeneration and filtration modeling in treating oily wastewaters",
Journal of Membrane Science (324), 59 – 66.
• Ahmed, F.H., 2000, "Study of The Factors Affecting the Efficiency of Reverse Osmosis Process", M.Sc. thesis,
Baghdad University.