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In the last few years, RSM method has been used widely to analyze, optimize and evaluate the interaction of independent factors for chemical, biochemical, and environmental processes. This study examined and evaluated the applicability of this method to manage Oilfield Produced Water to prevent marine environment due to the presence of hard degradable compounds by ozonation process. In this study simulated oil-water sample and a homogenizer reactor was used. The main reactor used in this study was impeinger equipped with sintered glass filter through which the treated oil-water was entered to reactor in the form of discontinuous flow. After ozonation and at the end of the reaction time (60 min), the concentration of oil hydrocarbons was determined by a gas chromatography device equipped with a flame ionization detector. The performance of the central composite design (CCD) approach was evaluated by the F-Value, P-Value, R2, lack of fit test and Adequate Precision parameters to determine the influence of effective factors, including ozonation time, pH, ozone dose, and TPH concentration on the TPH removal efficiency. The mean TPH efficiency obtained from the design of the 30-step experiment resulting from surface-response method was 49.903%, with a standard deviation of 12.47. This study showed the high power of model adopted from the central composite design to predict the hydrocarbons removal from oilfield water using advanced oxidation process, and it was proved that this model can be used alone to determine the design space nature.
Czasopismo
Rocznik
Tom
Strony
22--30
Opis fizyczny
Bibliogr. 53 poz., rys., tab.
Twórcy
autor
- Iran University of Medical Sciences, Iran, Research Center for Environmental Health Technology
- Iran University of Medical Sciences, Iran, Department of Environmental Health Engineering, School of Public Health
autor
- North Khorasan University of Medical Sciences, Iran, Department of Environmental Health Engineering, School of Public Health
autor
- Gonabad University of Medical Sciences, Iran, Social Development & Health Promotion Research Center, Department of Environmental Health Engineering, School of Public Health
autor
- Iran University of Medical Sciences, Iran, Research Center for Environmental Health Technology
- Iran University of Medical Sciences, Iran, Department of Environmental Health Engineering, School of Public Health
autor
- Iran University of Medical Sciences, Iran, Department of Environmental Health Engineering, School of Public Health
Bibliografia
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- 4. Ahamadabadi, M., Saeidi, M., Rahdar, S., Narooie, M.R., Salimi, A., Alipour, V., Khaksefidi, R., Baneshi, M.M. & Biglari, H. (2016). Assessment of the chemical quality of groundwater resources in Chabahaar City using GIS software in 2016, Research Journal of Applied Sciences, 11(11), pp. 1399-1403.
- 5. Ahmed, O., Mahmoud, S. & Mousa, A. (2015). Aliphatic and poly-aromatic hydrocarbons pollution at the drainage basin of Suez Oil Refinery Company, Current Science International, 4(1), pp. 27-44.
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- 7. Biglari, H., Afsharnia, M., Alipour, V., Khosravi, R., Sharafi, K. & Mahvi, A.H. (2017). A review and investigation of the effect of nanophotocatalytic ozonation process for phenolic compound removal from real effluent of pulp and paper industry, Environmental Science and Pollution Research, 24(4), pp. 4105-4116. doi:10.1007/s11356-016-8079-x.
- 8. Biglari, H., Rahdar, S., Baneshi, M.M., Ahamadabadi, M., Saeidi, M., Narooie, M.R., Salimi, A. & Khaksefidi, R. (2017). Estimating the amount of methane gas generated from the solid waste using the land GEM software, sistan and baluchistan, Journal of Global Pharma Technology, 9(3), pp. 35-41.
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- 10. Cha, Z., Lin, C.-F., Cheng, C.-J. & Hong, P.A. (2010). Removal of oil and oil sheen from produced water by pressure-assisted ozonation and sand filtration, Chemosphere, 78(5), pp. 583-590.
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- 17. Ebrahimzadeh, G., Biglari, H., Mehrizi, E.A., Zarei, A., Narooie, M.R. & Baneshi, M.M. (2017). Determining appropriate strategy to improve performance of solid waste recycling system in zahedan by swot method, Pollution Research, 36(3), pp. 437-444.
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- 19. Fakhru’l-Razi, A., Pendashteh, A., Abdullah, L.C., Biak, D.R.A., Madaeni, S.S. & Abidin, Z.Z. (2009). Review of technologies for oil and gas produced water treatment, Journal of Hazardous Materials, 170(2), pp. 530-551.
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- 21. Jamali, H., Dindarloo, K. & Nikpey, A. (2015). Optimization of metal working fluids treatment using calcium chloride by response surface methodology, The Journal of Qazvin University of Medical Sciences, 19 (2), pp. 46-54,
- 22. Jamali, H.A. (2016). Application of response surface methodology to optimize the removal of nitrate from aqueous solutions using electrocoagulation, Journal of Shahrekord University of Medical Sciences, 18(4), pp. 135-146.
- 23. Ji, G., Sun, T., Ni, J. & Tong, J. (2009). Anaerobic baffled reactor (ABR) for treating heavy oil produced water with high concentrations of salt and poor nutrient, Bioresource Technology, 100(3), pp. 1108-1114.
- 24. Khatib, Z. & Verbeek, P. (2003). Water to value-produced water management for sustainable field development of mature and green fields, Journal of Petroleum Technology, 55(01), pp. 26-28.
- 25. Leili, M., Moussavi, G. & Naddafi, K. (2012). Removal of furfural from wastewater using combined catalytic ozonation process (COP) and cyclic biological reactor (CBR)[dissertation], Tehran: Tarbiat Modares University.
- 26. Lu, M. & Wei, X. (2011). Treatment of oilfield wastewater containing polymer by the batch activated sludge reactor combined with a zerovalent iron/EDTA/air system, Bioresource Technology, 102(3), pp. 2555-2562.
- 27. Ma, H. & Wang, B. (2006). Electrochemical pilot-scale plant for oil field produced wastewater by M/C/Fe electrodes for injection, Journal of Hazardous Materials, 132(2), pp. 237-243.
- 28. Majlesi, M. & Hashempour, Y. (2016). Removal of 4-chlorophenol from aqueous solution by granular activated carbon/nanoscale zero valent iron based on Response Surface Modeling, Archives of Environmental Protection, 43(4), pp. 13-25.
- 29. Mazloomi, S., Nabizadeh, N.R. & Noori, S.M. (2013). Efficiency of response surface methodology for optimizing catalytic ozonation process with activated carbon in removal of petroleum compound from groundwater resources, Journal of Health and Hygiene, 4, 3, pp. 198-206.
- 30. Mohammadi, M.J., Salari, J., Takdastan, A., Farhadi, M., Javanmardi, P., Yari, A.R., Dobaradaran, S., Almasi, H. & Rahimi, S. (2017). Removal of turbidity and organic matter from car wash wastewater by electrocoagulation process, Desalination and Water Treatment, 68, pp. 122-128.
- 31. Mohammadi, M.J., Takdastan, A., Jorfi, S., Neisi, A., Farhadi, M., Yari, A.R., Dobaradaran, S. & Khaniabadi, Y.O. (2017). Electrocoagulation process to chemical and biological oxygen demand treatment from carwash grey water in Ahvaz megacity, Iran, Data in Brief, 11, pp. 634-639.
- 32. Mohammadi, M.J., Yari, A.R., Saghazadeh, M., Sobhanardakani, S., Geravandi, S., Afkar, A., Salehi, S.Z., Valipour, A., Biglari, H., Hosseini, S.A., Rastegarimehr, B., Vosoughi, M. & Omidi Khaniabadi, Y. (2017). A health risk assessment of heavy metals in people consuming Sohan in Qom, Iran, Toxin Reviews, pp. 1-9. doi:10.1080/15569543.2017.1362655.
- 33. Mohebi, S., Sharifirad, G.H., Shahsiah, M., Botlani, S., Matlabi, M. & Rezaeian, M. (2012). The effect of assertiveness training on student’s academic anxiety, JPMA. The Journal of the Pakistan Medical Association, 62(3 Suppl 2), pp. 37-41.
- 34. Mojadam, M., Matlabi, M., Haji, A., Cheraghi, M., Bitaraf, S. & Abdullatif Khafaie, M. (2018). Khuzestan dust phenomenon: a content analysis of most widely circulated newspapers, Environmental Science and Pollution Research, 16, pp. 15918-15924. doi:10.1007/s11356-018-1833-5.
- 35. Moradi, M., Fazlzadehdavil, M., Pirsaheb, M., Mansouri, Y., Khosravi, T. & Sharafi, K. (2016). Response surface methodology (RSM) and its application for optimization of ammonium ions removal from aqueous solutions by pumice as a natural and low cost adsorbent, Archives of Environmental Protection, 42(2), pp. 33-43.
- 36. Moradi, M., Safari, Y., Biglari, H., Ghayebzadeh, M., Darvishmotevalli, M., Fallah, M., Nesari, S. & Sharafi, H. (2016). Multi-year assessment of drought changes in the Kermanshah city by standardized precipitation index, International Journal of Pharmacy and Technology, 8(3), pp. 17975-17987.
- 37. Moussavi, G. & Alizadeh, R. (2010). The integration of ozonation catalyzed with MgO nanocrystals and the biodegradation for the removal of phenol from saline wastewater, Applied Catalysis B: Environmental, 97(1), pp. 160-167.
- 38. Moussavi, G., Khosravi, R. & Farzadkia, M. (2011). Removal of petroleum hydrocarbons from contaminated groundwater using an electrocoagulation process: Batch and continuous experiments, Desalination, 278(1), pp. 288-294.
- 39. Niri, M.V., Mahvi, A.H., Alimohammadi, M., Shirmardi, M., Golastanifar, H., Mohammadi, M.J., Naeimabadi, A. & Khishdost, M. (2015). Removal of natural organic matter (NOM) from an aqueous solution by NaCl and surfactant-modified clinoptilolite, Journal of Water and Health, 13(2), pp. 394-405.
- 40. Oller, I., Malato, S. & Sánchez-Pérez, J. (2011). Combination of advanced oxidation processes and biological treatments for wastewater decontamination - a review, Science of the Total Environment, 409(20), pp. 4141-4166.
- 41. Rahimi, Z., Mohebi, S., Yousefi, Z., Kheirollahi, F., Saraf, P. & Matlabi, M. (2016). Analysis of training needs of mothers on exclusive breastfeeding; a study in health care centers, International Journal of Pediatrics, 4(12), pp. 40894098. doi:10.22038/ijp.2016.7664.
- 42. Rezaei, H., Narooie, M.R., Khosravi, R., Mohammadi, M.J., Sharafi, H. & Biglari, H. (2018). Humic acid removal by electrocoagulation process from natural aqueous environments, International Journal of Electrochemical Science, 13(3), pp. 2379-2389. doi:10.20964/2018.03.10.
- 43. Ríos, F., Olak-Kucharczyk, M., Gmurek, M. & Ledakowicz, S. (2017). Removal efficiency of anionic surfactants from water during UVC photolysis and advanced oxidation process in H2O2/UVC system, Archives of Environmental Protection, 43(1), pp. 20-26.
- 44. Rocha, J.H.B., Gomes, M.M.S., Fernandes, N.S., da Silva, D.R. & Martínez-Huitle, C.A. (2012). Application of electrochemical oxidation as alternative treatment of produced water generated by Brazilian petrochemical industry, Fuel Processing Technology, 96, pp. 80-87.
- 45. Sajjadi, S.A., Asgari, G., Biglari, H. & Chavoshani, A. (2016). Pentachlorophenol removal by persulfate and microwave processescoupled from aqueous environments, Journal of Engineering and Applied Sciences, 11(5), pp. 1058-1064. doi:10.3923/jeasci.2016.1058.1064.
- 46. Sohrabi, Y., Nafez, A.H., Charganeh, S.S., Abdollahzadeh, D. & Biglari, H. (2017). Analyzing chemical parameters of drinking water of urban water system - Kermanshah-Iran, Bulgarian Chemical Communications, 49 (Special Issue J), pp. 256-262.
- 47. Szyczewski, P., Frankowski, M., Zioła-Frankowska, A., Siepak, J., Szyczewski, T. & Piotrowski, P. (2016). A comparative study of the content of heavy metals in oils: linseed oil, rapeseed oil and soybean oil in technological production processes, Archives of Environmental Protection, 42(3), pp. 37-40.
- 48. Thomas, M., Białecka, B. & Zdebik, D. (2016). Removal of organic compounds from wastewater originating from the production of printed circuit boards by UV-Fenton method, Archives of Environmental Protection, 43(4), pp. 39-49.
- 49. Utvik, T.I.R. (1999). Chemical characterisation of produced water from four offshore oil production platforms in the North Sea, Chemosphere, 39(15), pp. 2593-2606.
- 50. Uzun, Y. & §ahan, T. (2017). Optimization with Response Surface Methodology of biosorption conditions of Hg (II) ions from aqueous media by Polyporus Squamosus fungi as a new biosorbent, Archives of Environmental Protection, 43(2), pp. 37-43.
- 51. Valdés, H. & Zaror, C.A. (2006). Heterogeneous and homogeneous catalytic ozonation of benzothiazole promoted by activated carbon: kinetic approach, Chemosphere, 65(7), pp. 1131-1136.
- 52. Wu, J., Zhang, H., Oturan, N., Wang, Y., Chen, L. & Oturan, M.A. (2012). Application of response surface methodology to the removal of the antibiotic tetracycline by electrochemical process using carbon-felt cathode and DSA (Ti/RuO 2-IrO 2) anode, Chemosphere, 87(6), pp. 614-620.
- 53. Zhang, Y., Gao, B., Lu, L., Yue, Q., Wang, Q. & Jia, Y. (2010). Treatment of produced water from polymer flooding in oil production by the combined method of hydrolysis acidification- -dynamic membrane bioreactor-coagulation process, Journal of Petroleum Science and Engineering, 74(1), pp. 14-19.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-1eb84259-1394-42da-9937-b546999d53e4