Tambov State University after G. R. Derzhavin
Tambov State University after G. R. Derzhavin (Department of Mathematical Modeling and Information Technology, Professor)
employee from 01.01.2005 to 01.01.2025
Tambov, Tambov, Russian Federation
graduate student from 01.01.2022 to 01.01.2025
Tambov State University after G. R. Derzhavin
Tambov, Tambov, Russian Federation
graduate student
Tambov State University after G. R. Derzhavin (Department of Mathematical Modeling and Information Technology, graduate student)
graduate student from 01.01.2023 to 01.01.2025
Tambov, Tambov, Russian Federation
VAK Russia 4.1.1
VAK Russia 4.1.2
VAK Russia 4.1.3
VAK Russia 4.1.4
VAK Russia 4.1.5
VAK Russia 4.2.1
VAK Russia 4.2.2
VAK Russia 4.2.3
VAK Russia 4.2.4
VAK Russia 4.2.5
VAK Russia 4.3.5
UDC 66.081.6
CSCSTI 65.13
The objective of the study is to develop an integrated approach to the design and calculation of electric baromembrane units for the separation of process solutions in food production. The object of the study is an integrated approach to the design and calculation of electric baromembrane units for the separation of process solutions in food production. The research method is an analytical description and evaluation of the design parameters of the system under study: total surface (area) of membranes, volume of structural material, weight. The economic parameter of the studied integrated approach is the cost of the constituent elements of the device design. For the effective implementation of the processes of electric baromembrane separation of liquid process solutions in food production, it is necessary to develop universal designs of devices, which is based on the following main stages: design of the multi-chamber device; description of its operating principle with confirmation of the technical results; study of the conditions of industrial applicability with evaluation of the design and economic parameters (membrane surface area, volume of structural material, weight (mass of materials), cost; evaluation of the design and economic parameters during software implementation on a computer (in the Delphi/Object Pascal programming language) to automate the process of calculating the design elements. Analytical expressions for calculating the membrane surface area, the volume of structural material, and the weight (mass) of materials are obtained using the example of calculating flat-chamber electrobaromembrane and electrobaromembrane devices. Based on the proposed integrated approach and the calculation of the effective surface area, volume, and mass of the device elements, it is proven that the BMAPT made of 12Kh18N10T steel has the highest manufacturing cost (RUB 13,479), followed by the EBMAPT made of PA-6 (caprolon) (RUB 3,925). Based on the cost analysis of device designs for this type, two types of devices are promising options, as they can handle a variety of food media.
processes and devices, food production, separation and concentration of solutions, integrated approach, electrobaromembrane separation
1. Stabnikov VN, Lysyanskij VM, Popov VD. Processy i apparaty pischevyh proizvodstv. 4th ed., revised and additional. Moscow: Agropromizdat; 1985. 503 p. (In Russ).
2. Kaveckij GD, Vasil'ev BV. Processy i apparaty pischevoj tehnologii. 2nd ed., revised and additional. Moscow: Kolos; 2000. 551 p. (In Russ).
3. Kovaleva OA, Kovalev SV. Separation of molasses distillery slop on UFM-50®, UPM-50M®, OPMN-P®, and OFAM-K® porous membranes. Membranes and membrane technologies. 2017;57(6):542-551. (In Russ.). DOI:https://doi.org/10.1134/S0965544117060044.
4. Sviridenko YuYa, Myagkonosov DS, Abramov DV, et al. Development of manufacturing processes of whey protein hydrolyzates using membrane technology. Part 2. Optimizing process conditions for producing whey protein hydrolysates in an enzymatic membrane reactor. Food industry. 2017;(8):40-43. (In Russ.).
5. Khramtsov AG. Technological breakthrough of the agrarian-and-food innovations in dairy case for example of universal agricultural raw materials. Diafiltration. Agricultural and food innovations. 2022;(2):9-25. (In Russ). DOI:https://doi.org/10.31208/2618-7353-2022-18-9-25.
6. Khramtsov AG, Borisenko AA, Evdokimov IA, et al. Evolution of whey processing: past, present, future (part 1). Modern science and innovation. 2021;(2):129-139. (In Russ.). DOI:https://doi.org/10.37493/2307-910X.2021.2.12.
7. Gavrish AV, Anisimov GS, Kravtsov VA, et al. Reverse osmotic purification of permeates obtained by nanofiltration of dairy raw materials. Modern science and innovation. 2023;(5):16-18. (In Russ.). DOI:https://doi.org/10.21603/1019-8946-2023-5-2.
8. Yakovleva MR, Nikulina OK, Koloskova OV, et al. Comparative assessment of electrodialysis and electrodeionization processes. Food industry: science and technology. 2023;16(4):61-68. (In Russ.).
9. Nikulina OK, Koloskova OV, Yakovleva MR, et al. Increasing the degree of purification of diffusion juice by electrochemical demineralization. Food industry: science and technology. 2022;15(3):69-78. (In Russ.). DOI:https://doi.org/10.47612/2073-4794-2022-15-3(57)-69-78.
10. Elmidaoui A, Chay L, Tahaikt M, et al. Demineralisation for beet sugar solutions using an electrodialysis pilot plant to reduce melassigenic ions. Desalination. 2006;189(1–3):209-214. DOI:https://doi.org/10.1016/j.desal.2005.06.026.
11. Luo J, Hang X, Zhai W, et al. Refining sugarcane juice by an integrated membrane process: filtration behavior of polymeric membrane at high temperature. Journal of Membrane Science. 2016;509:105-115. DOI:https://doi.org/10.1016/j.memsci.2016.02.053.
12. Qabli H, Rafik M, Tahri M, et al. Optimization of melassigenic ions removal operation from beet sugar syrups and mother liquor by electrodialysis. Chemica. 2016;8:95-103.
13. Volodin DN, Topalov VK, Ivanchenko EJ, et al. Osobennosti ispol'zovanija polimernyh membran v processe membrannogo frakcionirovanija molochnogo syr'ja. Pererabotka moloka. 2024;(2):292:6-8. (In Russ.).
14. Volodin DN, Topalov VK, Kulikova IK, et al. Membrane fractionation of skim milk: effect of casein on functional properties of protein concentrates. Molochnaja promyshlennost'. 2024;(6):48-53. (In Russ.).
15. Butylskii DYu, Troitskiy VA, Chuprynina DA, et al. Selective recovery of lithium ion from its mixed solution with potassium and sodium by electrobaromembrane method. Separation and Purification Technology. 2024;343:126675. DOI:https://doi.org/10.1016/j.seppur.2024.126675.
16. Butylskii DYu, Troitskiy VA, Smirnova NV, et al. Selective extraction of lithium cations from mixture of alkali metal chlorides using electrobaromembrane process. Membrany i membrannye technology. 2024;14(3):190–199. (In Russ.). DOI:https://doi.org/10.31857/S2218117224030022.
17. Butylskii DYu, Mareev SA, Ryzhkov II, et al. Evaluation of the effect of electroosmosis on the efficiency of electrobaromembrane separation using track-etched membranes. Membrany i membrannye technology. 2023;13(5):423-432. (In Russ.). DOI:https://doi.org/10.31857/S2218117223050024.
18. Butylskii DYu, Troitskiy VA, Chuprynina DA, et al. Selective separation of singly charged chloride and dihydrogen phosphate anions by electrobaromembrane method with nanoporous membranes. Membranes. 2023;13(5):455. DOI:https://doi.org/10.3390/membranes13050455.
19. Butylskii DYu, Troitskiy VA, Chuprynina DA, et al. Application of hybrid electrobaromembrane process for selective recovery of lithium from cobalt- and nickel-containing leaching solutions. Membranes. 2023;13(5):509. DOI:https://doi.org/10.3390/membranes13050509.
20. Golovashin VL, Lazarev SI, Lavrenchenko AA. Investigation of the kinetic coefficients of electroultrafiltration separation of industrial solutions for biochemical production. Transactions of the Tambov State Technical University. 2014;20(1):86-94. (In Russ.).
21. Lazarev SI, Rodionov DA, Bogomolov VYu, et al. Partial demineralization of subsurface serum by ultrafiltration with pulsed current supply. Cheese and butter making. 2019;(4):47-49. (In Russ.).
22. Kovalev SV, Kovaleva OA, Sedoplatov IS. Electrobaromembrane device of the flat-chamber type. Patent RUS № 2820720. 2024. Byul. № 25. (In Russ). Available at: https://fips.ru/registers-doc-view/fips_servlet?DB=RUPAT&DocNumber=2820720&TypeFile=html. Accessed: 08.04.2025.
23. Kaprolon, properties and characteristics: the website of the company QING Rubber products. Available at: https://cin.ru/opisanie/kaprolon-svoystva-i-kharakteristiki/. Accessed 08.04.2025.
24. Steel grade 12X18N10T: the website of the central metal portal. Available at: https://metallicheckiy-portal.ru/marki_metallov/stk/12X18H10T. Accessed: 08.04.2025.
25. Fedotov NA, Kovalev SV, Sedoplatov IS, et al. Certificate of state registration of the computer program No. 2024688015 Russian Federation. Program for calculating the parameters of a flat-chamber electrobaromembrane device: No. 2024687830: published: 25.11.2024.
