1. ELARTU — Інституційний репозитарій ТНТУ імені Івана Пулюя
  2. Матеріали конференцій, семінарів, читань
  3. 2021
  4. International conference „Advanced Applied Energy and Information Technologies 2021“, (ICAAEIT 2021)
Link lub cytat. http://elartu.tntu.edu.ua/handle/lib/36947

Tytuł: Electromagnetic interferences in transistor converters and methods of interferences mitigation
Authors: Gurin, Viktor K.
Pavlovskyi, Volodymyr O.
Yurchenko, Oleg M.
Senko, Vitaliy I.
Akcesoria: Institute of Electrodynamics of National Academy of Science of Ukraine, Prosp. Peremogy, 56, Kyiv, 03057, Ukraine.
Technical University of Ukraine “Igor Sikorsky Kyiv Polytechnic Institute” , Prosp. Peremohy, 37 Kyiv, 03056
Cytat: Electromagnetic interferences in transistor converters and methods of interferences mitigation / Viktor K. Gurin, Volodymyr O. Pavlovskyi, Oleg M. Yurchenko, Vitaliy I. Senko // ICAAEIT 2021, 15-17 December 2021. — Tern. : TNTU, Zhytomyr «Publishing house „Book-Druk“» LLC, 2021. — P. 7–13. — (Electrical engineering and power electronics).
Bibliographic description: Gurin V. K., Pavlovskyi V. O., Yurchenko O. M., Senko V. I. (2021) Electromagnetic interferences in transistor converters and methods of interferences mitigation. ICAAEIT 2021 (Tern., 15-17 December 2021), pp. 7-13.
Część publikacji: Proceedings of the International Conference „Advanced applied energy and information technologies 2021”, 2021
Data wydania: 15-gru-2021
Date of entry: 28-gru-2021
Wydawca: TNTU, Zhytomyr «Publishing house „Book-Druk“» LLC
Place edycja: Ternopil
Zakresu czasowego: 15-17 December 2021
Słowa kluczowe: galvanic decoupling
conductive electromagnetic interference
rechargeable battery
Strony: 7
Zakres stron: 7-13
Główna strona: 7
Strona końcowa: 13
Abstract: This paper describes the main types of conductive electromagnetic interference that occur in modern high-frequency transistor converters and shows methods for these interferences’ mitigation. A network interference-suppression device which makes it impossible penetration of conductive electromagnetic interference (EMI) from a consumer to a mains and back is introduced. The device also provides the complete galvanic decoupling between the power mains and the consumer. This is achieved through the introduction of an intermediate link between the consumer and the network, the link being powered by a rechargeable battery, and time separation of electrical energy between consumption and transmission cycles due to the special algorithm of charging and discharging the batteries of the consumer. It provides mutual protection of the consumer and the network from all types of conductive EMI, as well as protection of the consumer from possible electric shock.
URI: http://elartu.tntu.edu.ua/handle/lib/36947
ISBN: 978-617-8079-60-4
Właściciel praw autorskich: © Ternopil Ivan Puluj National Technical University, Ukraine, 2021
Związane URL literatura: http://ied.org.ua/disertac/disert_Gurin.pdf
https://etd.ohiolink.edu/apexprod/rws_etd/send_file/send?accession=osu1385983252&disposition=inline
http://power-e.ru/pdf/2006_04_58.pdf
http://powel.ru/files/library/VicorAC_DC.pdf
http://dspace.nbuv.gov.ua/bitstream/handle/123456789/62135/57-Gurvin.pdf?sequence=1
http://previous.techned.org.ua/index.php?option=com_content&view=article&id=907&Itemid=77
https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=8304668
References: 1. Ott, H. W. (2009). Electromagnetic Compatibility Engineering. New Jersey: John Wiley & Sons, Inc.
2. Gurin, V.K. (2019). Improving the effectiveness of noise reduction means in power supply systems with high-frequency transistor converters. (Candidate’s thesis). Institute of Electrodynamics of National Academy of Sciences of Ukraine. Kyiv: 150 p. (in Ukrainian) Available from: http://ied.org.ua/disertac/disert_Gurin.pdf
3. Xu, L., Wang, J., Illindala, M.S. (2013). EMI Modeling and Characterization for Ultra-Fast Switching Power Circuit Based on SiC and GaN Devices. (PhD thesis). Ohio State University. Available from: https://etd.ohiolink.edu/apexprod/rws_etd/send_file/send?accession=osu1385983252&disposition=inline
4. Lantsov, B., Eranosyan, C. (2006). Electromagnetic compatibility of switching power supplies: problems and solutions. Part I. Power electronics, 4-2006, 58-64. (in Russian). Available from: http://power-e.ru/pdf/2006_04_58.pdf
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6. Beloturov, V. (2005). Filtration and overvoltage protection modules from Vicor. Power Electronics. 2-2005, 104-107. (in Russian). Available from: http://powel.ru/files/library/VicorAC_DC.pdf
7. EN 55022:2014. Information technology equipment - Radio disturbance characteristics - Limits and methods of measurement.
8. IEC 61000-2-4-2002. Electromagnetic compatibility (EMC) - Part 2-4: Environment - Compatibility levels in industrial plants for low-frequency conducted disturbances.
9. Lundmark, M. (2006) High-Frequency Noise in Power Grids, Neutral and Protective Earth. Luleå University of Technology.
10. DSTU GOST 12.1.038:2008 “Occupational safety standards system. Electrical safety. Maximum permissible values of pickup voltages and currents”.
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12. Napp, A., Joosten, S., Stunder, D., Knackstedt, C., Zink, M., Bellmann, B., … Silny J. (2014) Electromagnetic interference with implantable cardioverter-defibrillators at power frequency. Circulation, 129, 441-450. doi: 10.1161/CIRCULATIONAHA.113.003081
13. Wang, S., Chen, R., Van Wyk, J.D. (2005). Developing Parasitic Cancellation Technologies to Improve EMI Filter Performance for Switching Mode Power Supplies. IEEE Transactions on Electromagnetic Compatibility, 47(4), 921-929.
14. Gurin V.K.; Pavlovskyi V.O.; Yurchenko O.M. (2012). Self-parasitic and mutual parasitic parameters in power line filters for switching mode power supplies. Tekhnichna Elektrodynamika. 2012(2), 119-120. (in Ukrainian) Available from: http://dspace.nbuv.gov.ua/bitstream/handle/123456789/62135/57-Gurvin.pdf?sequence=1
15. Pavlovskyi V.A. (1990) Power line filter as a source of noise. Tekhnichna Elektrodynamika, 1990(5), 65-70. (in Russian) Available from: http://previous.techned.org.ua/index.php?option=com_content&view=article&id=907&Itemid=77
16. Li, C., Liang, J., Wang, S. (2018). Interlink Hybrid DC Circuit Breaker. IEEE Transactions on industrial electronics, 65(11), 8677-8686. Available from: https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=8304668
17. Basin, E.N. (1988). Network rectifier for secondary power supplies with increased conversion frequency. Radiotehnika, 1988(4). 29-31. (in Russian)
Typ zawartości: Conference Abstract
Występuje w kolekcjach:International conference „Advanced Applied Energy and Information Technologies 2021“, (ICAAEIT 2021)

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