Abstract
There is a growing need in ecologically clean preparations for fighting against harmful microorganisms. Anolytes produced by diaphragm electrolysis in a non-flowing electrolyzer are the most suitable for this purpose. In order to increase the activity of the anolyte it is proposed to perform its ozone bubbling. Results of modeling the main physical and chemical processes occurring in the electrolyzer in Comsol Multiphysics are given. The principal scheme of automation of operation of non-flowing electrolyzer on the basis of microcontroller with display of entered and measured parameters is developed. Content of separate ions in each electrolyzer chamber was determined experimentally, temperature and hydrogen index values were measured. The analysis of coincidence of the received data with the modeling results showed sufficient adequacy (the relative error was between 2 and 6%). On the basis of the studies it was recommended to activate the water for 12–14 min, followed by 5-min ozone bubbling.
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References
Bakhir, V.M., Vtorenko, V.I., Leonov, B.I., et al.: Efficiency and safety of chemicals for disinfection, presterilization cleaning and sterilization. Disinfect. Case 1, 29–36 (2003)
Prilutsky, V.I., Dolgopolov, V.I., Barabash, T.B.: Anolytes at the market of disinfectants: make no mistake! Medical alphabet. Epidemiol. Hygiene 3, 52–61 (2013)
Oskin, S.V.: Electrotechnological directions of increase of ecological safety of agricultural production. Emerg. Situ. Ind. Ecol. Safety 1–2, 107–115 (2010)
Oskin, S.V., Ovsyannikov, D.A.: The necessity of application of ecologically clean ways of treating bees families from existing diseases. Emergency Situ. Ind. Ecol. Safety 2(18), 134–144 (2014)
Oskin, S.V.: Innovative ways to improve environmental safety of agricultural products. Land Manage. Cadastre Land Monitor. 8(104), 75–80 (2013)
Oskin, S.V., Tsokur, D.S.: The use of electroactive water in the technological process of ecologically safe cultivation of vegetable crops in closed ground conditions. Emerg. Situ. Ind. Env. Safety 2(18), 148–154 (2014)
Oskin, S.V., Ovsyannikov, D.A.: Modeling the basic physical processes in a beehive. Biophysics 1, 153–161 (2019). 10.1134/S0006350919010159
Hricova, D., Stephan, R., Zweifel, C.: Electrolyzed water and its application in the food industry. J. Food Prot. 71, 1934–1947 (2008)
Koseki, M., Tanaka, Y., Noguchi, H., et al.: Effect of pH on the taste of alkaline electrolyzed water. J. Food Sci. 72, 298–302 (2007)
Oskin, S., Tsokur, D., Voloshin, S.: Modeling the process of water bubbling with ozone to obtain the disinfectant solutions in beekeeping. Eng. Rural Dev. 1210–1214 (2019).https://doi.org/10.22616/ERDev2019.18.N412
Oskin, S.V., Tsokur, D.S.: Preparation of disinfectant solution for use in agricultural production and processing industry. J. Phys. Conf. Ser. 1353 (2019). https://doi.org/10.1088/1742-6596/1353/1/012035
Kurchenko, N.Y.: Application of electro-activated water in Russian agriculture. In: Materials of the International Scientific Conference Scientific Discoveries, pp. 17–26 (2016)
Oskin, S.V., Kurchenko, N.Y.: Engineering method for determination of the electrolyzer parameters. Multidisc. Netw. Electron. Sci. J. Kuban State Agrarian Univ. 3, 1–5 (2015)
Pasko, O.A.: Activated water and its application in agriculture, pp. 216–220. TPU, Tomsk (2000)
Hsu, S.Y.: Effects of flow rate, temperature and salt concentration on chemical and physical properties of electrolyzed oxidizing water. J. Food Eng. 66, 171–176 (2005)
Bakhir, V.M., Leonov, B.I., Panicheva, S.A., et al.: Efficiency and safety of chemical means for disinfection, pre-sterilized purification and sterilization. Disinfection 1, 29–36 (2003)
Hricova, D., Stephan, R., Zweifel, C.: J. Food Protection 71, 1934–1947 (2008)
Stopforth, J.D., Mai, T., Kottapalli, B., et al.: J. Food Protection 71, 625–628 (2008)
Udompijitkul, P., Daeschel, M.A., Zhao, Y.: J. Food Sci. 72, 397–406 (2007)
Oskin, S.V.: Electrotechnological trends of ecological safety increase of agricultural crops. Emerg. Ind. Ecol. Safety 1–2, 107–115 (2010)
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Oskin, S.V., Tsokur, D.S. (2021). Improving the Efficiency of a Non-flowing Diaphragm Electrolyzer. In: Radionov, A.A., Gasiyarov, V.R. (eds) Advances in Automation II. RusAutoCon 2020. Lecture Notes in Electrical Engineering, vol 729. Springer, Cham. https://doi.org/10.1007/978-3-030-71119-1_15
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