employee from 01.01.2019 to 01.01.2023
Ivanovo, Ivanovo, Russian Federation
Yaroslavl, Yaroslavl, Russian Federation
Shchedrino, Yaroslavl, Russian Federation
The paper considers the influence of different input parameters on the ultrafiltration process of oily wastewater from reinforced concrete structures manufacturing plants, which are water-oil systems. Also we defined quantitative and qualitative indicators of the wastewater composition as the concentration of pollutants, particle sizes of pollutants, density, hydrogen index, specific electrical conductivity (SEC), etc. Based on this analysis, we determined the choice of material and physical characteristics of the membranes, the development of technological processes for the treatment of oily wastewater for specific production conditions. The study contains data on quantitative and chemical analysis of oily wastewater; an experimental installation for separation into components of water-oil systems; the effect of operating pressure, medium temperature, and flow velocity on the ultrafiltration process kinetics; experimental studies on separation of oily wastewater.
oily waste water, ultrafiltration, ceramic membranes
1. The Water Code of the Russian Federation: Federal Law No. 74 – FZ of 03.06.2006 (2006), Collection of Legislation of the Russian Federation, (23), St. 2381 (in Russian).
2. Enaldiev, A.F. & Golik, V.I. (2004) Pollution of the hydrosphere by the industrial complex, Gornyy informatsionno-analiticheskiy byulleten, (3), pp. 187-188 (in Russian).
3. Masloboev, V.A. (2009) Long-term experience of monitoring industrial pollution // Vestnik Kol'skogo nauchnogo centra RAN, (1), pp. 24-33 (in Russian).
4. Voronov, Yu.V. & Yakovlev, S.V. (2006) Drainage and wastewater treatment. Textbook for universities. M.: Izd-vo ASV (in Russian).
5. Zakharov, S.L. (2002) Sewage treatment of oil depots, Ekologiya i promyshlennost' Rossii, May, pp. 35-37 (in Russian).
6. Karelin, Ya.A., Popova, I.A., Evseeva, L.A. et al. (2002) Wastewater treatment of oil refineries. M: Stroyizdat. (in Russian).
7. Krylov, I.O., Anufrieva, S.I. & Isaev, V.I. (2002) Installation of post-treatment of wastewater and stormwater from petroleum products, Ekologiya i promyshlennost' Rossii, June, pp. 17-19 (in Russian).
8. Minakov, V.V., Krivenko, SM. & Nikitina, T.O. (2002) New technologies of purification from oil pollution, Ekologiya i promyshlennost' Rossii, May, pp. 7-9 (in Russian).
9. Asfandiyarova, L.R., Asfandiyarov, R N., Fatkullin, R.N., Rashidova, A.R. & Gvozdeva, K.A. (2011) Purification of oily wastewater, Bashkirskiy khim. zhurn., (2), pp. 52-55 (in Russian).
10. Semenova, E.I., Bubliyenko, N.A. & Shilofost, T.A. (2014) Purification of oily wastewater, Vestnik VGTU, (27), pp. 161-167 (in Russian).
11. Gimazutdinova, R.R., Ibragimova, A.R. & Ibragimov, R.R. (2013) Technology of oil-containing wastewater treatment, Tekhnicheskie nauki – ot teorii k praktike, (19), pp. 151-155 (in Russian).
12. Petrova, A.V. (2013) Improvement of oil-containing wastewater treatment, Arctic Environmental Research, (1), pp. 14-19 (in Russian).
13. Pervov, A.G. (2009) Modern highly efficient technologies of purification of drinking and industrial water using membranes: reverse osmosis, nanofiltration, ultrafiltration. M.: Izdatel'stvo Associacii stroitel'nyh vuzov (in Russian).
14. Povorov, A.A. (2002) The use of ultrafiltration for the purification of oily wastewater, Vodosnabzhenie i santekhnika, (3), pp. 35-39 (in Russian).
15. Fedosov, S.V. (2018) Theoretical analysis of the process of ultrafiltration of liquid media in tubular type apparatuses, Vestnik Povolzhskogo gosudarstvennogo tekhnologicheskogo universiteta. Seriya: Materialy. Konstrukcii. Tekhnologii, (1), pp. 32-41(in Russian).
16. Fedosov, S.V. (2020) Pressure loss along the channel of a tubular membrane during the ultrafiltration of liquid media, Theoretical Foundations of Chemical Engineering, 54(2), pp. 380-387.
17. Fedosov, S.V. (2020) Modeling of the ultrafiltration process taking into account the formation of sediment on the membrane surface, Membrany i membrannye tekhnologii, 10(3), pp. 177-189 (in Russian).
18. Technical specifications: TU 0258-038-58042865-2009 "Grease for molds and formwork "POLYPLAST FORMS", sanitary conclusion 71.TC.04.000.T.000378.08.09 [online]. Available at: e-ecolog.ru (in Russian).
19. HDPE F 14.1:2.115-97 Method of performing measurements of the mass concentration of nonionic surfactants in samples of natural and treated wastewater by photometric method with phosphoric-tungstic acid (2014). M.: FGU FCAM (in Russian).
20. Maksachuk, A.I. & Leonov, G.V. (2009) Optical-acoustic method of remote control of the size of dispersed particles, Tekhnicheskaya akustika, (9), pp. 1-14 (in Russian).
21. Vedenyapin, G.V. (1973) General methodology of experimental research and processing of experimental data. M.: Kolos (in Russian).