Influence of the Seven-Phase Winding Phase Timing Sequence on Producing the Resulting Voltage Vector

Authors

  • Владимир [Vladimir] Михайлович [M.] Терешкин [Tereshkin]
  • Дмитрий [Dmitriy] Анатольевич [A.] Гришин [Grishin]
  • Сергей [Sergey] Павлович [P.] Баландин [Balandin]
  • Вячеслав [Vyacheslav] Владимирович [V.] Терешкин [Tereshkin]

DOI:

https://doi.org/10.24160/1993-6982-2021-5-83-91

Keywords:

seven-phase winding, converter control algorithm, changing the phase timing sequence, operating space-time vector of the third and fifth harmonic components

Abstract

The subject of the study is a seven-phase symmetric winding, namely, its properties due to the possibility to alter the phase timing sequence. The seven-phase ABCDEFG winding can be connected to a symmetrical seven-phase voltage with different phase timing sequences: ABCDEFG, ACEGBDF, or ADGCFBE.

In the study, the vector analysis methods, methods of expanding in a Fourier series, and grapho-analytical function analysis methods were used. The results of theoretical studies are confirmed by experimental data obtained on a prototype seven-phase engine sample.

It has been found that with the phase timing sequence ACEGBDF of the seven-phase winding ABCDEFG, the operating space-time vector is the vector of the fifth harmonic component, which rotates in the opposite direction in comparison with the space-time vector that is produced with the phase timing sequence ABCDEFG. With this phase timing sequence, it is only the fifth phase voltage time harmonic component that produces the space-time vector. With the time sequence ADGCFBE, it is only the third time harmonic component that produces the resulting space-time voltage vector. By changing, using the converter control algorithm, the phase sequence, it is possible to obtain three values of the field rotation frequency with the same converter frequency value. These properties broaden the seven-phase machine control capabilities, a circumstance that can be used in implementing modern electric traction drives.

Author Biographies

Владимир [Vladimir] Михайлович [M.] Терешкин [Tereshkin]

Ph.D. (Techn.), Assistant Professor of Electromechanics Dept., Ufa State Aviation Technical University, e-mail: tvm53@mail.ru

Дмитрий [Dmitriy] Анатольевич [A.] Гришин [Grishin]

Lead Engineer, LLC «Gaz-Project-Engineering», e-mail: lowrat@mail.ru

Сергей [Sergey] Павлович [P.] Баландин [Balandin]

Ph.D. (Phys.-Math.), Assistant Professor of Electromechanics Dept., Ufa State Aviation Technical University, e-mail: balandin.matem@yandex.ru

Вячеслав [Vyacheslav] Владимирович [V.] Терешкин [Tereshkin]

Student of Electromechanics Dept., Ufa State Aviation Technical University, e-mail: stierishkin@mail.ru

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Для цитирования: Терешкин В.М., Гришин Д.А., Баландин С.П., Терешкин В.В. Влияние временной последовательности чередования фаз семифазной обмотки на формирование результирующего вектора напряжения // Вестник МЭИ. 2021. № 5. С. 83—91. DOI: 10.24160/1993-6982-2021-5-83-91.

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For citation: Tereshkin V.M., Grishin D.A., Balandin S.P., Tereshkin V.V. Influence of the Seven-Phase Winding Phase Timing Sequence on Producing the Resulting Voltage Vector. Bulletin of MPEI. 2021;5:83—91. (in Russian). DOI: 10.24160/1993-6982-2021-5-83-91.

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Published

2020-11-26

Issue

No. 5 (2021): Вulletin № 5

Section

Electrical Complex and Systems (05.09.03)