A design of an electrochemical apparatus for separating solutions of chemical and machine-building industries has been developed and the area of membranes in flat channels of flanges has been calculated. It was determined that the increment in the flange membranes area of the apparatus of the developed design in comparison with the prototypes is 16%.
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V. V. Goncharuk, T. Y. Dul’neva, and D. D. Kucheruk, “Water purification of hydroxocomlexes of heavy metals by electromicrofiltration using inorganic membranes,” J. Water Chem. Technol., 32, No. 2, 95–100 (2010).
V. G. Myronchuk, Yu. G. Zmievskii, Y. Dzyazko, L. M. Rozhdestvenska, and V. Zakharov, “Whey desalination using polymer and inorganic membranes: operation conditions,” Acta Periodica Technol., 49, 103–115 (2018).
N. A. Bykovskiy, L. N. Puchkova, and N. N. Fanakova, “Processing of the ethylenediamine dihydrochloride in a non-flowing electrodialyzer with monopolar and bipolar membranes,” Fundam. Issled., No. 1, 7–11 (2018).
E. M. Akberova, A. M. Yatsev, E. A. Goleva, and V. I. Vasil’eva, “Mineral fouling on the MA-40 anion exchange membrane during electrodialysis of strongly mineralized natural waters,” Kondens. Sredy Mezhfaz. Gran., 19, No. 3, 452–463 (2017).
S. I. Lazarev, Y. M. Golovin, S. V. Kovalev, and A. A. Levin, “Characteristics of thermal action on porous cellulose acetate composite material,” J. Eng. Phys. Thermophys., 92, No. 4, 1050–1054 (2019).
O. A. Abonosimov, S. I. Lazarev, and S. V. Kovalev, “A study of the longitudinal agitation coefficient in roll elements of baromembrane apparatus,” Russ. J. Appl. Chem., 80, No. 10, 1676–1679 (2007).
D. D. Temershin, S. V. Gavrilov, Yu. D. Sidorov, and A. V. Kanarskiy, “Application of electrolyzers and electrodialyzers in the food industry,” Vestn. Kazan. Tekhnol. Univ., 18, No. 3, 110–115 (2015).
A. M. Yatsev, E. M. Akberova, E. A. Goleva, et al., “Diagnostics of surface and bulk microstructure changes of the MK-40 sulfocation exchange membrane at electrodialysis of highly mineralized natural waters,” Sorbts. Khromatograf. Prots., 17, No. 2, 313–322 (2017).
S. T. Antipov and A. I. Klyuchnikov, “Mathematical modeling of microfiltration in a rectangular channel,” Theor. Found. Chem. Eng., 53, No. 1, 83–96 (2019).
S. V. Kovalev, “Increase in efficiency of electrobaromembrane device with flat channels,” Chem. Petrol. Eng., 50, No. 1-2, 18–23 (2014).
S. I. Lazarev, S. V. Kovalev, O. A. Kovaleva, and D. N. Konovalov, “Design and calculation of effective separation area of flatchamber electrobaromembrane equipment,” Chem. Petrol. Eng., 55, No. 5, 5–6 (2019).
S. V. Kovalev, S. I. Lazarev, D. N. Konovalov, and P. Lua, “Efficient design of a flat-chamber-type electrobaromembrane apparatus and a method for calculating structural and technological characteristics in the separation of chemical and engineering industrial solutions,” Chem. Petrol. Eng., 56, No. 1-2, 109–115 (2020).
This study was supported by the Derzhavin grant for young scientists.
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Translated from Khimicheskoe i Neftegazovoe Mashinostroenie, Vol. 57, No. 5, pp. 14−16, May, 2021.
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Kovaleva, O.A. Promising Design of an Electrochemical Apparatus for Separating Industrial Solutions with Increased Area of Membranes in Flat Channels of Flanges. Chem Petrol Eng 57, 383–386 (2021). https://doi.org/10.1007/s10556-021-00947-4
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DOI: https://doi.org/10.1007/s10556-021-00947-4