English

Vol. 8 3, 2018 p 352-359

Pages

Article name, authors, abstract and keyword

352-359

Method of vibroacoustic intensification in waste-water treatment

Sergey . Polovkov a, rina V. Nikolaeva a, Stanislav V. Meshcheryakov b, ikhail V. Ivanov c

a Pipeline Transport Institute, LLC (Transneft R&D, LLC), 47a Sevastopolsky prospect, Moscow, 117186, Russian Federation
b Gubkin Russian State University of Oil and Gas (National Research University), 65 Leninsky prospect, Moscow, 119991, Russian Federation
c Bauman Moscow State Technical University, 5/1 Baumanskaya 2nd Str. , Moscow, 105005, Russian Federation

DOI: 10.28999/2541-9595-2018-8-3-352-359

Abstract: Study results on vibroacoustic intensification of coagulation and flocculation for waste water treatment at the oil pump station of the Ryazan oil refinery. The intensification consisted in applying the resonance-frequency vibration effect with vibration acceleration of approx. 1 g to the coagulation and flocculation unit. Lime, synthetic flocculant and aluminum-containing coagulant were used as reagents. Waste-water contained kerosene and diesel oil, including a total content of petroleum products of approx. 1 mg/l. The experimental study results demonstrated a high efficiency of vibration application. Thus, the vibration effect reduces the required concentration of reagents in the treated waste-water by up to 8 time for lime, by up to 6 times for coagulant and by up to 2 times for synthetic flocculant; accordingly, the treatment time is reduced twofold with the same efficiency up to 98%.

Keywords: water treatment, coagulation, flocculation, vibration, oil products, reactant treatment.

For citing:
Polovkov S. A., Nikolaeva A. V., Meshcheryakov S. V., Ivanov M. V. Method of vibroacoustic intensification in waste-water treatment. Nauka i tehnologii truboprovodnogo transporta nefti i nefteproduktov = Science & Technologies: Oil and Oil Products Pipeline Transportation. 2018;8(3):352359. DOI: 10.28999/2541-9595-2018-8-3-352-359.

References:
[1] Polovkov S. A. Maintenance of industrial safety, ecology and labour protection in the organizations of the Transneft system. Nauka i tehnologii truboprovodnogo transporta nefti i nefteproduktov = Science & Technologies: Oil and Oil Products Pipeline Transportation. 2016;(2):2831. (In Russ.)
[2] Savostyanova M. Y., Vlasova L. S., Polovkov S. A. Organization of an ecological monitoring system for soil and natural water in the operation area of production sites of Transneft Baltic, LLC branch Ust-Luga oil depot. Nauka i tehnologii truboprovodnogo transporta nefti i nefteproduktov = Science & Technologies: Oil and Oil Products Pipeline Transportation. 2016;(4):98101. (In Russ.)
[3] Frog B. N., Levchenko . P. Water treatment: study guide for higher schools. Moscow: Moscow State University Press; 1996. 680 p. (In Russ.)
[4] Zapolsky . ., Baran . . Coagulums and flocculants in water treatment processes: Properties. Reception. Application. Leningrad: Khimiya (Chemistry) Publ.; 1987. 204 p. (In Russ.)
[5] Babenkov . D. Water treatment by coagulums. Moscow: Nauka Publ.; 1977. 358 p. (In Russ.)
[6] Rodriguez-Narvaez O. M., Peralta-Hernandez J. M., Goonetilleke A., Bandala E. R. Treatment technologies for emerging contaminants in water: a review. Chemical Engineering Journal. 2017;323:361380. DOI: 10.1016/j.cej.2017.04.106.
[7] Chezganova G. V., Moskovchenko N. G. Operation of treatment facilities at sites of KRUMN. Nauka i tehnologii truboprovodnogo transporta nefti i nefteproduktov = Science & Technologies: Oil and Oil Products Pipeline Transportation. 2011;(1):7074. (In Russ.)
[8] Davletyarov R. R., Bobykin D. V. Reliability improvement of waste water treatment system. Nauka i tehnologii truboprovodnogo transporta nefti i nefteproduktov = Science & Technologies: Oil and Oil Products Pipeline Transportation. 2013;(2):7983. (In Russ.)
[9] Jafarinejad S. Treatment of oily wastewater. Petroleum Waste Treatment and Pollution Control. Butterworth-Heinemann, 2017.P. 185267. DOI: 10.1016/B978-0-12-809243-9.00006-7.
[10] Fakhrul-Razi ., Pendashteh A., Abdullah L. C., Biak D. R. A., Madaeni S. S., Abidin Z. Z. Review of technologies for oil and gas produced water treatment. Journal of Hazardous Materials. 2009;170(23):530551. DOI: 10.1016/j.jhazmat.2009.05.044.
[11] Epoyan S. ., Blagodarnaya G. I., Dushkin S. S., Stashuk V. . Operational efficiency improvement of facilities in drinking water treatment: monograph. Kharkov: KhNAGKh; 2013, 190 p. (In Russ.)
[12] Feofanov Y. ., Khirshieva I. V. Coagulation process intensification of colored waters of low turbidity by weighting agents adding. Water and Ecology: problems and solutions. 2004;(2):2430. (In Russ.)
[13] Munoz M., Garcia-Munoz P., Pliego G., De Pedro Z. M., Zazo J. A., Casas J. A., Rodriguez J. J. Application of intensified Fenton oxidation to the treatment of hospital wastewater: Kinetics, ecotoxicity and disinfection. Journal of Environmental Chemical Engineering. 2016;4(4), Part A: 4107-4112. DOI: 10.1016/j.jece.2016.09.019.
[14] Baran W., Adamek E., Jajko M., Sobczak A. Removal of veterinary antibiotics from wastewater by electrocoagulation. Chemosphere. 2018;194:381389. DOI: 10.1016/j.chemosphere.2017.11.165.
[15] Mullakaev . S. Ultrasonic intensification of technical processes for oil mining and refining, oily water and soil treatment [dissertation]. Moscow, 2011. 419 p.
[16] Abramov O. V., Abramov V. O., Veksler G. B., Kulov N. N., Zabotina E. V., Kashirskaya O. A., Shkolnikov A. V., Mullakaev M. S. Ultrasonic activation of reagent purification of surface wastewaters from oil products. Chemical technology. 2008;9(5):226232. (In Russ.)
[17] Keremetin P. P., Parilov P. S., Kruchinina N. E., Mullakaev M. S., Abramov V. O., Veksler G. B. Determination of the technological parameters for the sonochemical purification of oily water. Chemical technology. 2010;11(1):5662. (In Russ.)
[18] senofontov B. S., Ivanov M. V. Investigation of the effect of the vibrations on flotation treatment of waste water. Science and Education of Bauman MSTU. 2011;(10). (In Russ.)
[19] Devisilov V. A., Sharay E. J. Research of behavior of particles in the hydrodynamic filter on the basis of numeral calculations. Izvestiya of the Samara Science Center of the Russian Academy of Sciences. 2010;10(19):22162222. (In Russ.)
[20] Ivanov M., Ksenofontov B. Intensification of chemical agents mixing by vibroacoustical agitation. Ecology and Industry of Russia. 2017;21(9):49. DOI: 10.18412/1816-0395-2017-9-4-9. (In Russ.)
[21] Genkin G., Waite T. D., Fane A. G., Chang S. The effect of vibration and coagulant addition on the filtration performance of submerged hollow fibre membranes. Journal of Membrane Science. 2006;281(12):726734. DOI: 10.1016/j.memsci.2006.04.048. (In Russ.)
[22] Guo X., Du Z., Li G., Shu Z. High Frequency Vibration Recovery Enhancement Technology in the Heavy Oil Fields of China. Proceedings of Society of Petroleum Engineers International Thermal Operations and Heavy Oil Symposium and Western Regional Meeting. March 1618, 2004, Bakersfield, California, USA. DOI: 10.2118/86956-MS.
[23] Ponomarev V. G., Ioakimis E. G. Formation and treatment of waste water of oil refineries. oscow: Soyuz Design Publ.; 2009. 256 p. (In Russ.)
[24] Guo X., Lu H., Yang J., Peng T. Resonant water motions within a recessing type moonpool in a drilling vessel. Ocean Engineering. 2017;129:228239.
[25] Osorio J. G., Sowrirajan K., Muzzio F. J. Effect of resonant acoustic mixing on pharmaceutical powder blends and tablets. Advanced Powder Technology. 2016;27(4):11411148. DOI:10.1016/j.apt.2016.03.025.
[26] Nikolaeva . V., Troshin . ., Meshcheryakov S. V., Ostakh S. V., Ostakh . S. Identification and forecasting of effectiveness of the best available techniques for oily wastes decontamination. Environmental bulletin of Russia. 2017;(2):1822. (In Russ.)