Abstract
The purification of loose agricultural products containing metal particles is a pressing problem nowadays. It must be solved because it may result in significant material and economic losses. Magnetic and electromagnetic purification methods are based on the differences in the magnetic properties of the separated products, mainly their magnetizability. The operating area of the separator contains an attraction zone for magnetic particles, whose height is determined by the minimum distance between the working body and the surface of the fixed pole and, and the transport zone that takes the magnetic product to the discharge point. The magnetic field in the separator’s operating area is generated by the systems of permanent magnets or electromagnetic systems with the solenoid coil. Parametric design is the basis for the design and engineering works in the development of the electromagnetic separator. It helps determine the ultimate goal of the unit at the early stages of project implementation. This work suggests using a nomogram-parameter design for the electromagnetic separator and its operating parameters. Nomogram parameterization stipulates the construction of a nomogram for the calculation of the operating parameters of the electromagnetic separator with permanent magnets.
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References
Gortinsky, V.V., Demsky, A.B., Boriskin, A.M.: Separation Processes at Grain Gills, p. 304. Kolos, Moscow (1980)
Evdokimov, A.A., Kopytin, I.I., Charykov, V.I.: Innovative solutions in designing electromagnetic separators, p. 182. Kurgan State University, Kurgan (2015)
YuI, B., Vasilyev A.S., Nikanorov, A.N., et al.: Modern energy-saving technology, p. 564. ETU LETI, St. Petersburg (2000)
Zuev, V.S., Charykov, V.I.: Electromagnetic separators: theory and design, p. 178. Zauralye, Kurgan (2002)
Melnik, N.M.: Pedagogy of creation: parametric construction of actual knowledge. In: Education. Culture. Society. Collection of Selected Articles Based on the Materials of the International Scientific Conference, St. Petersburg, pp. 22–24 (2020)
Charykov, V.I., Kopytin, I.I.: The competitive ability of USS electromagnetic separators. In: The Monograph on the Problems of Economy and Management in Today’s World, Kurgan, pp. 219–231 (2017)
Kopytin, I.I.: Improving the efficiency of loose product purification through the upgrading of the electromagnetic separator. In: Proceedings of LII International Science and Technology Conference on the Scientific Advances for Agricultural Production. South Ural State Agrarian University, Chelyabinsk V, pp. 169–171 (2013)
Iannicelli, J., Pechin, J.: Magnetic separation of kaolin clay using an advanced 9 T separator. IEEE Trans. Appl. Supercond. 10(1), 917–922 (2000)
Konev, N.N., Komarov, S.G.: Analyzing the current situation with magnets and magnetic separators for the food industry. OILS&FATS 4, 36 (2005)
Koshchuk, G.A.: Method of optimization calculation of structures of suspended electromagnetic separators. Omsk Sci. Bull. 3(171), 47–50 (2020)
Konyaev, A., Bagin, D.N.: Modeling an electromagnetic separator based on the linear inductor. Russ. Electr. Eng. 3, 34–40 (2018)
Obvintseva, T.Yu., Konyaev, A.Yu.: Linear induction machines for electrodynamic separation for non – ferrotis metals. In: Proceedings of the 2017 IEEE Russia Section Young Researchers in Electrical and Electronic Engineering Conference, EIConRus 2017, St. Petersburg, Russia, pp. 1657–1670 (2017)
Ugarov, G.G., Vyrykhanov, D.A., Moshkin, V.I.: The structural analysis of the electromechanical energy conversion. J. Electrotech. 4(25), 57–64 (2019)
Mityunin, A.A.: Designing an electromagnetic separator with permanent magnets for the purification of oil crop seeds with metal particles (the sunflower case study): a thesis for the candidate degree in engineering, Troitsk, p. 169 (2019)
Krivoshapko, S.N.: Analytical ruled surfaces and their complete classification. Struct. Mech. Eng. Struct. Struct. 16(2), 131–138 (2020)
Konyaev, A.Yu., Konyaev. I.A., Nazarov, S.L., Markin, N.E.: Electrodynamic separators with a running magnetic field: the bases of theory and calculations, p. 104. Ural Federal University, Yekaterinburg (2012)
Sumtsov, V.F.: Electromagnetic iron separators, p. 212. Mashinostroyeniye, Moscow (1981)
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Charykov, V.I., Evdokimov, A.A., Kopytin, I.I. (2023). Nomogram-Parametric Design for the Electromagnetic Separator with Permanent Magnets. In: Radionov, A.A., Gasiyarov, V.R. (eds) Proceedings of the 8th International Conference on Industrial Engineering. ICIE 2022. Lecture Notes in Mechanical Engineering. Springer, Cham. https://doi.org/10.1007/978-3-031-14125-6_2
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