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The Institute of Electrodynamics

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DOI: https://doi.org/10.15407/publishing2019.54.063

ELECTROMECHANICAL ENERGY CONVERTERS FOR ELECTROGENERATION AND ELECTRIC DRIVE SYSTEMS

L.I. Mazurenko*, V.V. Grebenikov**, O.V. Dzhura***, O.B. Bibik****, R.V. Gamaliia, M.O. Shykhnenko*****
Institute of Electrodynamics of the National Academy of Sciences of Ukraine,
Peremohy, 56, Kyiv-57, 03680, Ukraine,
e-mail: This e-mail address is being protected from spambots. You need JavaScript enabled to view it
* ORCID ID : http://orcid.org/0000-0002-7059-249X
** ORCID ID : http://orcid.org/0000-0002-1114-1218
*** ORCID ID : http://orcid.org/0000-0002-0224-3351
**** ORCID ID : http://orcid.org/0000-0002-6236-6732
***** ORCID ID : http://orcid.org/0000-0003-4012-1731

The main scientific and practical results that are obtained when performing research and development robots are presented. A comparative analysis of the modification of the magnetic system of an electric generator with permanent magnets is carried out. According to the results of mathematical modeling a mechanical characteristic of the switched reluctance motor of the traction drive has been formed with the maximum value of the efficiency. The possibility of stabilization of the rotational speed of the experimental model SRM is substantiated. Recommendations for choosing the moment of inertia of the еlectric drive of single cylinder compressors on its basis with the provision of a regulated level of pulsations of the rotational speed of the rotor for the regulation range of 1: 4 have been developed. The models and algorithms for controlling the distributed generation system with wind power plants on the basis of asynchronous generators during parallel operation with the network were developed, the influence of distributed generation units on losses in the deadlock of the network was investigated. A technical solution was proposed, calculations were made, working design documentation was created, a prototype of a multifunctional autonomous electro-aggregate of single-phase current of high quality of electric power was manufactured. Reference 16, figures 10, table 1.
Key words: permanent magnet generator, switched reluctance motor, simulation model, induction motor, electro-aggregate, startup charger, distributed generation, wind power plants.



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5. Mazurenko L.I., Bibik O.A., Shykhnenko M.O. Simulation mode and speed control of switched reluctance motor using a converter with the C-dump and the oscillation return of energy at changing switching angles. Visnyk Natsionalnoho tekhnichnoho universytetu «KHPI». Seriya: Elektrychni mashyny ta elektromekhanichne peretvorennya enerhiyi.2016. No 11 (1183). Pp. 64–69. (Ukr)
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7. Mazurenko L.I, Bibik O.V., Shykhnenko M.O. Estimation of the possibility of using a switched reluctance motor as part of a machine-swinging device. Visnyk Natsionalnoho tekhnichnoho universytetu «KHPI». Seriya: Elektrychni mashyny ta elektromekhanichne peretvorennya enerhiyi. 2017. No 1 (1223). Pp. 97–100. (Ukr)
8. Bibik O.V., Grebenikov V.V. Analysis of the influence of magnetic systems on the characteristics of switched reluctance and synchronous reluctance motors. Hidroenerhetyka Ukrayiny.2016. No 3. Pp. 47–50. (Ukr)
9. Mazurenko L.I., Bibik O.V., Bilyk O.A., Shykhnenko M.O., Klymenko V.G. Method of stabilization of the speed of switched reluctance motor. Pat. to utility model No. 107247 Ukraine, H02P 6/08, H02P 8/12, H02K 19/06. (Ukr)
10. Mazurenko L.I., Dzhura O.V. A mathematical model of an autonomous electrogenerating system with induction generators and a single semiconductor excitation converter. Pratsi Instytutu Elektrodynamiky Natsionalnoi Akademii Nauk Ukrainy. 2016. No 44. Pp. 69–78. (Ukr)
11. Mazurenko L.I., Vasyliv K.M. Patterns of Electromagnetic Processes of the Contactless Excitation System of the Autonomous Asynchronous Generator on the Basis of the Cascade Three-Phase-Three-phase Voltage Modulator. Tekhnichna Electrodynamika. 2018. No 6. Pp. 46–49. (Ukr) DOI: https://doi.org/10.15407/techned2018.06.046
12. Mazurenko L.I., Dzhura O.V. Mathematical model and control algorithm for autonomous unregulated wind turbine with inverter excited induction generator. Elektromekhanichni i enerhozberihayuchi systemy. Kremenchuk, Ukraine. 2018. No 3(43). Pp. 24–30. (Ukr)  DOI: https://doi.org/10.30929/2072-2052.2018.3.43.24-30
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14. Mazurenko L.I., Dzhura O.V. Mathematical modeling of three-phase transformers based on the equivalent circuit for replacing a single-phase transformer. XVIII International Scientific and Practical Conference Renewable Energy and Energy Efficiency in the 21st Century. Kyiv, Ukraine, 27-29 September 2017. Pp. 156–160.
15. Popovych O.M., Golovan I.V. Study of changed main flux reactance of squirrel-cage induction motors using field analysis of their starting characteristics. Tekhnichna Electrodynamika. 2018. No 5.  Pp. 69–72. DOI: https://doi.org/10.15407/techned2018.05.069
16. Mazurenko L.I., Dzhura O.V., Shevchuk S.P. Transients in a transistor-switched capacitor regulator of a stand-alone induction generator supplying a single-phase load. International Conference on Modern Electrical and Energy Systems (MEES). Kremenchuk, Ukraine. 2017. Pp. 244–247.  DOI: https://doi.org/10.1109/MEES.2017.8248901

Received 12.06.2019  

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