A method is developed for calculating the values of concentration polarization during the separation of an aqueous solution containing anionic surfactants for ultrafiltration membranes with ideal and non-ideal rejection coefficients in a wide range of changes in the values of the diffusion Peclet number.
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A. V. Panasenko, E. V. Kondratyuk, and L. F. Komarova, “Alternative solutions to the problems of industrial and storm wastewater treatment to remove oil products and surfactants” [in Russian], Polzunkovskiy Vestnik, No. 3, 287–289 (2010).
V. V. Burenin, “New designs of filters for wastewater treatment of chemical and petrochemical enterprises” [in Russian], Khim. Tekhn., No. 7 (2012).
A. G. Balandina, R. I. Khangildin, I. G. Ibragimov, et al., “Development of membrane technologies and the possibility of their application for waste water treatment at chemical and petrochemical enterprises” [in Russian], Neftegazovoye Delo, No. 5, 336–375 (2015).
S. A. Vertyagin, Petrash Zbinek, Novak Lubosh, et al., “Environmental and economic aspects of the development of membrane technologies in petrochemistry, food industry and wastewater treatment” [in Russian], NefteGazoKhimiya, No. 3, 52–56 (2015).
M. T. Bryk and E. A. Tsapyuk, Ultrafiltration [in Russian], Naukova Dumka, Kyiv (1989).
V. M. Starov, N. V. Churaev, V. M. Dorokhov, et al., “Influence of the association of ions in the zone of concentration polarization and precipitation of crystals on the selectivity of reverse osmosis membranes” [in Russian], Khim. Tekhnol. Vody, 8, No. 2, 67–72 (1986).
S. V. Fedosov, Yu. P. Osadchiy, and A. V. Markelov, “Modeling the ultrafiltration process taking into account the formation of sediment on the membrane surface” [in Russian], Membrany i Membrannye Tekhnologii, 10, No. 3, 177–189 (2020).
S. I. Lazarev, O. A. Abonosimov, A. A. Levin, et al., “Mathematical description of mass transfer and method of calculating local mass transfer coefficients in the intermembrane channel of baromembrane roll elements” [in Russian], Khim. Neftegaz. Mashinostr., No. 9, 16–18 (2018).
O. A. Abonosimov, S. I. Lazarev, V. I. Kochetov, et al., “On the methodology for studying the structure of flow in a roll-type reverse osmosis apparatus” [in Russian], Virtual Modeling, Prototyping and Industrial Design: Mater. IV Int. Sci.-Pract. Conf., Publishing house of the Federal State Budgetary Educational Institution of Higher Education “TSTU”, Tambov (2017), p. 134–140.
S. I. Lazarev, I. V. Horokhorina, K. S. Lazarev, et al., “Mathematical description of heat transfer and a method for determining the temperature characteristics of the electro-ultrafiltration process of purifying industrial solutions” [in Russian], Khim. Neftegaz. Mashinostr., No. 11, 6–9 (2017).
S. R. Derkach, G. I. Berestova, and T. A. Motyleva, “The use of surfactants for the intensification of oil production during the primary and secondary opening of layers” [in Russian], Vestnik MSTU (Bulletin of the Murmansk State Technical University), 13, No. 4-1, 784–792 (2010).
G. M. Ostrovsky and R. Sh. Abiev, New Reference of a Chemist and Technologist: Processes and Devices of Chemical Technology [in Russian], in 2 parts, Part 2, Professional, St. Petersburg (2006).
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Translated from Khimicheskoe i Neftegazovoe Mashinostroenie, Vol. 57, No. 4, pp. 18–20, April, 2021.
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Lazarev, S.I., Khorokhorina, I.V., Shestakov, K.V. et al. Method for Calculation of Concentration Polarization in Membrane Separation of Petrochemical Industrial Solutions. Chem Petrol Eng 57, 299–303 (2021). https://doi.org/10.1007/s10556-021-00933-w
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DOI: https://doi.org/10.1007/s10556-021-00933-w