DOI: https://doi.org/10.15407/techned2018.06.042
SIMULATION OF INDUCTION MACHINES WITH COMMON SOLID ROTOR
Journal |
Tekhnichna elektrodynamika |
Publisher |
Institute of Electrodynamics National Academy of Science of Ukraine |
ISSN |
1607-7970 (print), 2218-1903 (online) |
Issue |
No 6, 2018 (November/December) |
Pages |
42 – 45 |
Authors М. Zablodskiy1*, V. Pliuhin2**, R. Chuenko1*** 1 – National University of Life and Environmental Sciences of Ukraine, 15, Heroiv Oborony Str., Kyiv, 03041, Ukraine, e-mail:
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2 – O.M. Beketov National University of Urban Economy in Kharkiv, 17, Marshal Bazhanov Str., Kharkiv, 61002, Ukraine, e-mail:
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* ORCID ID : http://orcid.org/0000-0001-8889-8158 ** ORCID ID : http://orcid.org/0000-0003-4056-9771 *** ORCID ID : http://orcid.org/0000-0002-9339-9764
Abstract
A simulation model is developed and transient modes of a double-module induction machine with a common external solid rotor are researched. It is established, that with the counter rotation of magnetic fields, a gearless mode of the steady operation of a double-module induction machine is provided at low rotational speeds of the solid hollow rotor, combined with a screw actuator. References 14, figure 1, table 1.
Key words: simulation model, induction machine, solid rotor, transient mode.
Received: 05.03.2018 Accepted: 24.04.2018 Published: 23.10.2018
References
1. Kim K.K., Ivanov S.N. On the problem of determining speed-torque characteristics of thermal electromechanical converters. Russian Electrical Engineering. 2009. No. 80. Pp. 459–465. (Rus) 2. Zablodskiy N., Plyugin V., Gritsyuk V. Polyfunctional electromechanical energy transformers for technological purposes. Russian Electrical Engineering. 2016. No 87(3). Pp. 140–144. (Rus) 3. Szczygiel M., Kluszczynski K. Rotary-linear induction motor based on the standard 3-phase squirrel cage induction motor-constructional and technological features. Czasopismo Techniczne. Elektrotechnika. 2016. No 112. Pp. 395–406. 4. Amiri E., Jagiela M., Dobzhanski O., Mendrela E. Modeling dynamic end effects in rotary armature of rotary-linear induction motor. Proceedings of IEEE Electric Machines & Drives Conference (IEMDC). 2013. Pp. 1088-1091. 5. Alwash J.H., Qaseer L.J. Three-dimension finite element analysis of a helical motion induction motor. ACES. 2010. Vol. 25. No 8. Pp. 703-712. 6. Zhao J., Xinhui L., Xin Z., Han Y. Research on the energy-saving technology of concrete mixer trucks. Proceedings of IV IEEE Conference on Industrial Electronics and Applications. 2009. Pp. 3551 – 3554. 7. Popovych O.M., Golovan І.V. Determination of equivalent circuit parameters of the induction motor and non-linear functions for field analysis results. Pratsi Instytutu Elektrodynamiky Natsionalnoi Akademii Nauk Ukrainy. 2012. No 31. Pp. 38–48. (Rus) 8. Deshpande M.V. Electrical machines. New Delhi: PHI, 2011. 430 p. (Rus) 9. Kucevalov V.M. Questions of the theory and calculation of asynchronous machines with solid rotors. М.-L.: Energy, 1966. 302 p. (Rus) 10. Zablodskii N., Pliugin V.,Lettl J., Fligl S. Dynamic Simulation of the Double-Stator Induction Electromechanical Converter with Ferromagnetic Rotor. Power Engineering. 2013. Pp. 1448 – 1453. (Rus) 11. Kopylov I.P. Mathematical modeling of electric machines. Мoskva: Vysshaia Shkola, 2001. 327 p. (Rus) 12. Chornii O.P., Lugovoi А.V., Rodkin D.Y., Sysiuk G.Yu., Sadovoi О.V. Modelling of electromechanical systems. Kremenchuk, 2001. 410 p. (Rus) 13. Zablodskii N.N., Pliugin V.E., Skryl V.V. Problems of simulation and design of double-module EMPE with solid rotor. Visnyk NTU KhPI. 2013. No 51. Pp. 20 – 27. (Rus) 14. Sen S.K. Principles Of Electrical Machine Design With Computer Programs. Oxford: IBH Publishing Company Pvt. Limited, 2006. 415 p.
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