A method for calculating a tubular electrobaromembrane apparatus with a nonuniform filtration area has been developed. Due to the addition of concentric cathode and anode membranes with protrusions of increased diameter, the tabular electrobaromembrane apparatus has an increased separation area per unit volume of the apparatus. The developed technique enables one to calculate the volume and weight of the apparatus and its environmental and economic efficiency in the separation of biologically active solutions.
Similar content being viewed by others
References
S. L. Zakharov, A. S. Zakharov, A. V. Efremov, and A. Kh. Volodin, “Structural modernization of engineering and graphic projects of devices with different membranes,” Remont. Vosstanov. Modernizats., No. 2, 38–42 (2014).
D. V. Spitsov and A. P. Andrianov, “Improving the design of membrane devices in order to reduce operating costs in the operation of membrane units,” Uspekhi Sovr. Nauki, 4(2), 41–44 (2017).
L. E. Kopylova, N. V. Golovaneva, and N. Z. Khabibova, “Energy-saving technology of membrane extraction of tryptophan from aqueous solutions,” Uspekhi Khim. Khimich. Tekhnol., 31, No. 15(196), 73–75 (2017).
U. M. Kalybek, I. Abdurasulov, and K. K. Beishekeev, “The use of homogeneous charge-selective membranes in electrodialysis apparatus for the removal of singly charged cations,” Innovats. Nauka, No. 4-3, 110–115 (2016).
S. I. Lazarev, I. V. Khorokhorina, K. V. Shestakov, and D. S. Lazarev, “Recovery of zinc, copper, nickel and cobalt from electroplating wastewater by electro-nanofiltration,” Russ. J. Appl. Chem., 94, N. 8, 1105–1110 (2021).
B. A. Lobasenko, D. M. Borodulin, R. V. Kotlyarov, et al., “The use of new membrane equipment in the creation of low-waste and waste-free technologies,” Ekol. Promyshl. Rossii, 23, No. 10, 4–9 (2019).
S. I. Lazarev, S. V. Kovalev, I. V. Khorokhorina, and M. I. Mikhailin, “Design and technological calculation of a combined electric baromembrane apparatus for separating solutions in chemical production processes,” Chem. Pet. Eng., 56, 475–482 (2020).
S. I. Lazarev, V. L. Golovashin, D. O. Abonosimov, et al., Pat. 2540363 RF, IPC B 01 D 61/42, Electrobaromembrane Apparatus of Tubular Type (2013).
V. M. Gutsalyuk, V. I. Rudenko, V. R. Kulinchenko, et al., A.s. USSR No. 799779, class. B 01 D 13/00. Membrane Apparatus with Tubular Filter Elements (1979).
S. I. Lazarev, V. B. Korobov, V. I. Konovalov, et al., A.s. USSR No. 1681926, class. B 01 D 61/42. Membrane Apparatus (1991).
V. Yu. Bogomolov, S. I. Lazarev, V. I. Kochetov, et al., “Improving the efficiency of membrane concentration of cheese whey,” Vest. Tamb. Univ. Ser. Yestestv. Tekhnich. Nauki, 19, No. 3, 944–947 (2014).
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Khimicheskoe i Neftegazovoe Mashinostroenie, Vol. 58, No. 9, pp. 28–30, September, 2022.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Lazarev, S.I., Khorokhorina, I.V., Abonosimov, O.A. et al. An Analysis of the Design of a Tubular Electrobaromembrane Apparatus with Filter Elements in Various Areas and a Method for its Calculation. Chem Petrol Eng 58, 766–771 (2023). https://doi.org/10.1007/s10556-023-01159-8
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10556-023-01159-8