مدل‌سازی فرآیندی و بررسی سینتیکی تصفیه پساب پالایشگاه نفت در یک راکتور فتوکاتالیستی با استفاده از نانو ذرات

نوع مقاله : مقاله پژوهشی

نویسندگان

1 جهاد دانشگاهی، واحد استان کرمانشاه

2 شرکت پالایش نفت، استان کرمانشاه

3 دانشکده بهداشت، مرکز تحقیقات اپیدومیولوژی، کرمانشاه

چکیده

در این پژوهش اکسیداسیون فتوکاتالیستی و معدنی‌سازی پساب پالایشگاه نفت در یک سوسپانسیون آبی از دی اکسید تیتانیوم (20% روتایل، 80 % آناتاز) در یک راکتور ناپیوسته مورد مطالعه قرار گرفت. آزمایشات بر اساس طراحی ترکیبی مرکزی (CCD) طراحی گردید و با استفاده از متدولوژی پاسخ سطح، آنالیز و بررسی شد. به منظور بررسی فرآیند چهار متغیر فرآیندی که نقش اساسی در فرآیند فتوکاتالیستی دارند، انتخاب شدند این چهار متغیر عبارتند از: pH محیط (2-10)، غلظت کاتالیست (mg/l 200-0)، دما (22/5-C° 57/5) و زمان واکنش (30-150min) و حذف اکسیژن مورد نیاز شیمیایی کل (TCOD) به عنوان پاسخ فرآیندی انتخاب گردید. بر اساس نتایج ANOV، اثرات درجه اول کلیه متغیرها (pH، دما، غلظت کاتالیست و زمان) و اثرات درجه دوم pH، غلظت کاتالیست و دما بیشترین تأثیر را بر روی فرآیند حذف COD کل داشتند. بیشترین مقدار حذف COD با راندمان حذف 83% در شرایط 6=pH، غلظت کاتالیست mg/l 100، دما C° 45 و زمان واکنش 120 دقیقه به‌دست آمد. همچنین نتایج سینتیکی به‌دست آمده نشان داد که انرژی فعال‌سازی برای تبدیل TCOD مقدار kg/mol 34-19 می‌باشد.
 

کلیدواژه‌ها

عنوان مقاله [English]

Process Modeling and Kinetic Evaluation of Petroleum Refinery Wastewater Treatment in a Photocatalytic Reactor Using TiO2 Nanoparticles

نویسندگان [English]

  • Fatemeh Shahrezaei 1
  • Azita Shafei 2
  • Amirmohammad Mansouri 3
1 Academic Center for Education, Culture & Research (ACECR), Kermanshah
2 Oil Refinery Co., Kermanshah
3 Department of Analytical Chemistry, Faculty of Chemistry, Razi University, Kermanshah
چکیده [English]

The photocatalytic oxidation and mineralization of petroleum refinery wastewater in aqueous catalyst suspensions of titanium dioxide (TiO2), Degussa P25 (80% anatase, 20% rutile) was carried out in a batch circulating photocatalytic reactor. The experiments were conducted based on a central composite design (CCD) and analyzed using response surface methodology (RSM). In order to analyze the process, four significant variables viz. pH (2-10), catalyst concentration (0-200 mg/l), temperature (22.5-52.5 °C), and reaction time (30-150 min) and TCOD removal as the process response were studied. From the data derived from the factorial design, the ANOVA analysis revealed that the first order effects of reaction time, pH, temperature, and catalyst concentration and second order effect of pH, catalyst concentration, and temperature produced the main effect on TCOD removal efficiency. A maximum reduction in TCOD of more than 83% was achieved at the optimum conditions (pH of 4, catalyst concentration of 100 mg/l, temperature of 45 °C, and reaction time of 120 min). The reaction kinetics showed that reactive activation energy for TCOD conversion was calculated to be 19.34 kJ/mol.
 

کلیدواژه‌ها [English]

  • Petroleum Refinery Wastewater
  • Photocatalytic Degradation
  • TiO2 Nanoparticles
  • Kinetics
  • RSM

مراجع

[1]. Wbg (World Bank Group), “Pollution prevention and abatement handbook: toward cleaner production washington,” D.C., USA, , 1999.##
[2]. Kavitha V., and Palanivelu K., “The role of ferrous ion in Fenton and photo-Fenton processes for the degradation of phenol,” Chemosphere 55, pp. 1235–1243, 2004.##
[3]. Abdelwahab O., Amin N. K., and El-Ashtoukhy E. S. Z., “Electrochemical removal of phenol from oil refinery wastewater,” Journal of Hazardous Materials 163, pp. 711–716, 2009.##
[4]. Lathasree S., Rao N., Sivashankar B., Sadasivam V., Rengaraj K., “Heterogeneous photo catalytic mineralization of phenols in aqueous solutions,” Journal of Molecular Catalysis A: Chemical 223, pp. 101-105, 2004.##
[5]. Pardeshi S. K. and Patil A. B., “A simple route for photocatalytic degradation of phenol inaqueous zinc oxide suspension using solar energy,” Solar Energy 82, pp. 700–705, 2008.##
[6]. Yang Sol–gel X., “Synthesized nanomaterials for environmental applications,” PhD Thesis, Kansas State University, 2008.##
[7]. El-Naas M. H., Al-Zuhair S., Al-Lobaney A., and Makhlouf S., “Assessment of electrocoagulation for the treatment of petroleum refinery wastewater,” Journal of Environmental Management 91, pp.180-185, 2009.##
[8]. Tensel B. and Regula J., “Coagulation enhanced centrifugation for treatment of petroleum hydrocarbon contaminated waters,” Journal of Environmental Science and Health 35, pp. 1557-1575, 2000.##
[9]. El-Naas M. H., Al-Zuhair S., and Alhaija M. A., “Reduction of COD in refinery wastewater through adsorption on Date-Pit activated carbon,” Journal of Hazardous Materials 173, pp. 750-757, 2009.##
[10]. Elmaleh S., Ghaffor N., “Upgrading oil refinery effluents by cross flow ultra filtration,” Water Science and Technology 34, pp. 231-238, 1996.##
[11]. Leiknes T., Semmens M. J., “Membrane filtration for preferential removal of mulsified oil from water,” Water Science and Technology 41, pp. 101-108, 2000.##
[12]. Li Y., Yan L., Xiang C., and Hong L. J., “Treatment of oily wastewater by organic inorganic composite tubular ultrafiltration (UF) membranes,” Desalination 196, pp. 76-83, 2006.##
[13]. Laoufi N. A., Tassalit D., and Bentahar F., “The degradation of phenol in water solution by TiO2 photocatalyst in a chemical reactor,” Global NEST Journal 10, pp. 404–418, 2008.##
[14]. Kuyukina M. S., Ivshina I. R., Serebrennikova M. K., Krivorutchko A. B., Podorozhko E. A., Ivanov R. V., and Lozinsky V. I., “Petroleum-contaminated water treatment in a fluidized-bed bioreactor with immobilized Rhodococcus cells,” International Biodeterioration & Biodegradation 63, pp.427-432, 2009.##
[15]. Box G. E. P. and Draper N. R., “Empirical ModelBuilding and Response Surfaces,” Wiley,New York, 1987.##
[16]. Bas D. I. and Boyaci H., “Modeling and optimization I: usability of response surface methodology,” Journal of Food Engineering 78 (3), pp. 836-845, 2007.##
[17]. Akhbari A., Zinatizadeh A. A. L., Mohammadi P., Irandoust M., and Mansouri Y., “Process modeling and analysis of biological nutrients removal in an integrated RBC-AS system using response surface methodology,” Chemical Engineering Journal 168, pp. 269-279, 2011.##
[18]. Ghorbania F., Younesi H., Ghasempouri S. M., Zinatizadeh A. A., Amini M., and Daneshi A., “Application of response surface methodology for optimization of cadmium biosorption in an aqueous solution by Saccharomyces cerevisiae,” Chemical Engineering Journal 145, pp. 267–275, 2008.##
[19]. Bahadir K. K. and Rauf M. A., “Response surface methodology (RSM) analysis of photoinduced decoloration of toludine blue,” Chemical Engineering Journal 136, pp. 25–30, 2008.##
[20]. Aghamohammadi N., Hamidi Bin A. A., Hasnain I. M., and Zinatizadeh A. A., “Powdered activated carbon augmented activated sludge process for treatment of semi-aerobic landfill leachate using response surface methodology,” Bioresource Technology 98, pp. 3570–3578, 2007.##
[21]. APHA, “Standard Methods for the Examination of Water and Wastewater,” 19th ed. American Public Health Association, Washington, Dce., 1999.##
[22]. Chen Y., Sun Z., Yang Y., and Ke Q., “Heterogeneous photocatalytic oxidation of polyvinyl alcohol in water,” Journal of Photochemistry and Photobiology A 142, pp. 85–89, 2001.##
[23]. Saien J. and Nejati H., “Enhanced photocatalytic degradation of pollutants in petroleum refinery wastewater under mild conditions,” Journal of Hazardous Materials 148, pp. 491–495, 2007.##
[24]. Ahmed S., Rasul M. G., Martens W. N., Brown R., and Hashib M. A., “Heterogeneous photocatalytic degradation of phenols in wastewater: a review on current status and developments,” Desalination 261, pp. 3-18, 2010.##
[25]. Adesina A. A., “Industrial exploitation of photocatalysis: progress, perspectives and prospects,” Catalysis Surveys from Asia 8 (4), pp. 265–273, 2004##
[26]. Saien J. and Nejati H., “Enhanced photocatalytic degradation of pollutants in petroleum refinery wastewater under mild conditions,” Journal of Hazardous Materials 148, pp. 491–495, 2007.##

فایل ها

هم رسانی

ارجاع به این مقاله

آمار