The calculation approach to investigations of radial magnetic forces due to rotor eccentricity

Kruchinina, I. Yu.; Boguslavskiy, I. Z.; Khozikov, Y. Ph.; Liubimtcev, A. S.; Paltceva, V. V.

doi:10.4467/2353737XCT.16.244.6043

Artykuł - szczegóły

Tytuł artykułu

The calculation approach to investigations of radial magnetic forces due to rotor eccentricity

Autorzy

Kruchinina I. Yu. , Boguslavskiy I. Z. , Khozikov Y. Ph. , Liubimtcev A. S. , Paltceva V. V.

Wybrane pełne teksty z tego czasopisma

http://repozytorium.biblos.pk.edu.pl/resources/35437

Identyfikatory

DOI

10.4467/2353737XCT.16.244.6043

Warianty tytułu

Metodyka obliczeń w badaniach promieniowych sił magnetycznych powodowanych ekscentrycznością wirnika

Języki publikacji

Abstrakty

This paper presents the method of rotor magnetic pulling tensioning force calculation, caused by the static radial rotor eccentricity. The method is applied to calculate the total force acting on the rotor of high-speed permanent magnet (PM) synchronous machine (PMSM). The calculations are based on 2D simulation of magnetic field distribution in the active part of the machine, taking into account the saturation of the magnetic circuit and the spatial harmonics of the air gap magnetic flux in the no-load mode and in the rated mode.

W artykule przedstawiono metodę obliczania siły naciągu magnetycznego działającej na wirnik, spowodowanej przez radialną ekscentryczność statyczną wirnika. Metoda ta jest stosowana do obliczenia całkowitej siły działającej na wirnik szybkoobrotowej maszyny synchronicznej (PMSM) z magnesami trwałymi (PM). Obliczenia są oparte na symulacji 2D rozkładu pola magnetycznego w aktywnej części maszyny, z uwzględnieniem stopnia nasycenia obwodu magnetycznego oraz harmonicznych przestrzennych strumienia magnetycznego w szczelinie powietrznej w stanie jałowym pracy i dla pracy znamionowej.

Słowa kluczowe

rotor eccentricity high-speed synchronous machines radial magnetic pulling tensioning forces permanent magnets

ekscentryczność wirnika szybkoobrotowe maszyny synchroniczne promieniowesiły naciągu magnetycznego magnesy trwałe

Wydawca

Wydawnictwo Politechniki Krakowskiej im. Tadeusza Kościuszki

Czasopismo

Czasopismo Techniczne. Elektrotechnika

Rocznik

2016

Tom

Y. 113, iss. 2-E

Strony

17--28

Opis fizyczny

Bibliogr. 29 poz., wz., wykr.

Twórcy

autor

Kruchinina I. Yu.

Institute of Silicate Chemistry named after I.V. Grebenschikov Russian Academy of Sciences (IChS RAS), Federal Agency for Scientific Organizations

autor

Boguslavskiy I. Z.

Institute of Silicate Chemistry named after I.V. Grebenschikov Russian Academy of Sciences (IChS RAS), Federal Agency for Scientific Organizations

autor

Khozikov Y. Ph.

Institute of Silicate Chemistry named after I.V. Grebenschikov Russian Academy of Sciences (IChS RAS), Federal Agency for Scientific Organizations

autor

Liubimtcev A. S.

Institute of Silicate Chemistry named after I.V. Grebenschikov Russian Academy of Sciences (IChS RAS), Federal Agency for Scientific Organizations

autor

Paltceva V. V.

Institute of Silicate Chemistry named after I.V. Grebenschikov Russian Academy of Sciences (IChS RAS), Federal Agency for Scientific Organizations

Bibliografia

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[3] Rezig A., Mekideche M.R., Effect of rotor eccentricity faults on noise generation in permanent magnet synchronous motors, Progress in Electromagnetics Research C, vol. 15, 2010, 117–132.
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[5] Torregrossa D., Khoobroo A., Fahimi B., Prediction of Acoustic Noise and Torque Pulsation in PM Synchronous Machines with Static Eccentricity and Partial Demagnetization Using Field Reconstruction Method, IEEE Trans. Ind. Electronics, vol. 59, no. 2, Feb. 2012, 934–944.
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[7] Dutta R., Rahman M.F., Design and analysis of an interior permanent magnet (IPM) machine with very wide constant power operation range, IEEE Trans. Energy Conv., vol. 23, no. 1, Mar. 2008, 25–33.
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[14] Danilevich Y.B., Antipov V.N. , High–speed (3000–15000 rpm) permanent magnet generator (design and testing), Book of Abstracts 2006 ICEM XVII International Conference on Electrical Machines, 2–5.
[15] Danilevich J.B., Antipov V.N., Kruchinina I. Yu., Finite element analysis and comparison parameters of permanent magnet synchronous and two-ply solid rotor induction motors, Przegląd Elektrotechniczny, no. 5, 2010, 133–136.
[16] Danilevich J.B., Kruchinina I. Yu., Antipov V.N., Khozikov Y. Ph., Ivanova A.V., Some Problems of the High Speed Permanent Magnet Miniturbogenerators Development, Proc. 2008 of XVIII International Conference on Electrical Machines, Paper ID 942.
[17] Danilevich J.B., Kruchinina I. Yu., Antipov V.N., Khozikov Y. Ph., Ivanova A.V., Prospective Permanent Magnet Turbogenerator Design for Local Power Engineering, Proc. 2010 of XIX International Conference on Electrical Machines, Paper No. 003603.
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[23] Danilevich Ya.B., Kruchinina I. Yu., Shtainle L. Yu., Metod raschyota harmonik v zazore electricheskih mashin// Nauchno-tekhnicheskiye vedomosti SPbGPU. 2011. № 117. S. 221–226. – SPb.: Izd-vo Politekhn. un-ta. 2011 (in Russian).
[24] Kruchinina I. Yu., Shtainle L. Yu., Magnetomotive Force of Stator Multiphase Windings with Fractional Number of Slots Q per Pole and Phase. //Allerton Press, Inc. Distributed worldwide by Springer, Russian Electrical Engineering, Vol. 81, No. 8, 2010.
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[28] Boguslavskiy I.Z., Kruchinina I. Yu., Khozikov Yu. Ph., Lyubimtcev A.S., High-Speed Synchronous Machines: Magnetic Pulling Tensioning Forces Calculation Approach, Proc. of the XXI International Conference on Electrical Machines (ICEM’2014), Berlin, Sept. 2–5, 2014, P094 GD-004693.
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Uwagi

The authors would like to thank the Russian Foundation for Basic Research for support of the project under Grant 14-08-00817.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-4fcc1947-dd50-48fa-bbaa-bf27f8e46c1c