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Completely Superconducting Electric Machine with High Specific Power

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Abstract

The main tendency in transport development is a move toward electric or hybrid propulsion, which is due to the increased requirements relating to the ecological effects and efficiency of transport systems. A key parameter that determines the prospects of electric transport is the specific power of electric machines (generators and motors). Thus, e.g., electric machines with a specific power higher than 20 kW/kg are necessary to produce electrical aircraft. Studies have shown that, during long operation, such magnitudes of specific power can be achieved with the use of cryogenic cooling and modern high-temperature superconductors (HTSCs) in electric motors and generators. In addition, the critical properties of superconductors should be taken into account, which leads to scientific and engineering problems. In particular, the HTSC stator winding should be made of coils in the form of racetracks. This can be done in a machine with a number of grooves per pole and a phase less than unity. In this work, the circuit of such completely superconducting electric machine with high specific power has been considered. The analytical technique of calculations of the main parameters has been suggested. The obtained expressions allow one to analyze the influence of number of pole pairs, superconductor properties, and main dimensions of a machine on the specific power. The results of the finite-element modeling of a completely superconducting electric machine have been considered.

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References

  1. Shcherbakov, V., High-temperature superconducting 2G wires: from pilot technology to industrial scale, Sverkhprovodn. Elektroenerg., 2007, vol. 4, no.1.

    Google Scholar 

  2. Li, G., Liu, H., Wang, Y., and Zhang, H., Frequencydependence and anisotropy of AC losses of Bi2223/Ag and YBCO-coated conductors, IEEE Trans. Appl. Supercond., 2016, vol. 26, no.4.

    Google Scholar 

  3. But, D.A., Beskontaktnye elektricheskie mashiny (Contactless Electrical Machines), Moscow: Vysshaya Shkola, 1990, 2nd ed.

    Google Scholar 

  4. Shakhtarin, V.N., Kazovskii, E.Ya., and Kartsev, V.P., Sverkhprovodyashchie magnitnye sistemy (Superconducting Magnetic Systems), Leningrad: Nauka, 1967.

    Google Scholar 

  5. Bertinov, A.I., Alievskii, B.L., and Ilyushin, K.V., Sverkhprovodnikovye elektricheskie mashiny i magnitnye sistemy (Superconducting Electrical Machines and Magnetic Systems), Moscow: Mosk. Aviats. Inst., 1967.

    Google Scholar 

  6. Ivanov, N.S., Kobzeva, I.N., Kovalev, K.L., and Semenikhin, V.S., Analytical calculations of complete superconducting electric machine for aircrafts, in Innovatsionnye tekhnologii v energetike (Advanced Technologies in Energetics), Moscow: Nauka, 2016.

    Google Scholar 

  7. Kozub, L., Bogdanov, S., Dezhin, I., Kashtanov, D., Kovalev, E., Shuvalov, K., Smirnov, V., Sytnik, V., Shcherbakov, V., and Tkachenko, P., HTS racetrack coils for electrical machines, Proc. 13th IIR Int. Conf. “Cryogenics 2014,” Prague, Czech Republic, April 7–11, 2014, Paris: Int. Inst. Refrig., 2014.

    Google Scholar 

  8. Kovalev, L.K., Kovalev, K.L., Koneev, S.M.-A., Penkin, V.T., Poltavets, V.N., Il’yasov, R.I., and Dezhin, D.S., Elektricheskie mashiny i ustroistva na osnove massivnykh vysokotemperaturnykh sverkhprovodnikov (Electrical Machines and Devices Based on Massive High-Temperature Superconductors), Moscow: Fizmatlit, 2010.

    Google Scholar 

  9. But, D.A., Osnovy elektromekhaniki (Fundamentals of Electrical Engineering), Moscow: Mosk. Aviats. Inst., 1996.

    Google Scholar 

  10. Maxwell 3D, User’s guide. https://ru.scribd.com/doc/87741382/Maxwell3D-User-Manual.

  11. Ivanov, N.S., Kovalev, K.L., and Dezhin, D.S. Possible ways to increase specific power of electrical machines for electric airplanes, Vestn. Rybinsk. Gos. Aviats. Tekhnol. Akad. im. P.A. Solov’eva, 2015, no. 4.

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Authors and Affiliations

  1. National Research University MAI, Moscow, Russia

    D. S. Dezhin, N. S. Ivanov, I. N. Kobzeva & K. L. Kovalev

Authors
  1. D. S. Dezhin
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  2. N. S. Ivanov
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  3. I. N. Kobzeva
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  4. K. L. Kovalev
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Correspondence to D. S. Dezhin.

Additional information

Original Russian Text © D.S. Dezhin, N.S. Ivanov, I.N. Kobzeva, K.L. Kovalev, 2018, published in Elektrotekhnika, 2018, No. 2, pp. 2–7.

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Dezhin, D.S., Ivanov, N.S., Kobzeva, I.N. et al. Completely Superconducting Electric Machine with High Specific Power. Russ. Electr. Engin. 89, 75–79 (2018). https://doi.org/10.3103/S1068371218020049

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  • DOI: https://doi.org/10.3103/S1068371218020049

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