ЭКРАНИРОВАНИЕ ПОДЗЕМНОЙ КАБЕЛЬНОЙ ЛИНИИ СВЕРХВЫСОКОГО НАПРЯЖЕНИЯ С ПОМОЩЬЮ ПЛОСКОГО ФЕРРОМАГНИТНОГО ЭКРАНА

I.M.  Kucheriava

doi:10.15407/techned2019.06.013

No. 6 (2019), Theoretical Electrical Engineering and Electrophysics

No. 6 (2019)

Theoretical Electrical Engineering and Electrophysics

SHIELDING OF UNDERGROUND EXTRA-HIGH VOLTAGE CABLE LINE BY PLANE FERROMAGNETIC SHIELD

Published 2019-10-31

https://doi.org/10.15407/techned2019.06.013

I.M. Kucheriava ⁺⁻

I.M. Kucheriava

Institute of Electrodynamics National Academy of Sciences of Ukraine, Peremohy, 56, Kyiv, 03057, Ukraine

ARTICLE_2_PDF (Українська)

Keywords

underground three-phase cable line
ferromagnetic screen
magnetic field
computer simulation подземная трехфазная кабельная линия
ферромагнитный экран
магнитное поле
компьютерное моделирование

How to Cite

[1]

Кучерявая , И. 2019. SHIELDING OF UNDERGROUND EXTRA-HIGH VOLTAGE CABLE LINE BY PLANE FERROMAGNETIC SHIELD. Tekhnichna Elektrodynamika. 6 (Oct. 2019), 013. DOI:https://doi.org/10.15407/techned2019.06.013.

Abstract

The computer modeling by finite-element method is used to study the features of magnetic field distribution around the underground single-circuit three-phase 330 kV cable line with polyethylene insulation when using a flat ferromagnetic shield. In the developed model, the three-phase currents running in cable conductors along with the currents induced in cable metallic shields are taken into account. The open-shield configuration is considered. The shield is made of the ferromagnetic hot-rolled low-carbon material Magnetil with specified electrophysical properties. The computed distributions of the magnetic field established by the cable line are obtained and discussed. The magnetic field level depending on the depth of the shield in the ground, the dimensions of the shield (including its width and thickness), the magnetic permeability of shield material as a function of magnetic flux density are analyzed. References 10, figures 5.

https://doi.org/10.15407/techned2019.06.013

ARTICLE_2_PDF (Українська)

References

Doronin M.V., Greshniakov G.V., Korovkin N.V. Magnetic shields of special design. Nauchno-tekhni-cheskie vedomosti Sankt-Petersburgskogo politekhnicheskogo universiteta. 2017. Vol 23. No 1. Pp. 124–133. DOI: https://doi.org/10.18721/ JEST.230112 (Rus)

Machado V.M. Magnetic field mitigation shielding of underground power cables. IEEE Transactions on Magnetics. 2012. Vol. 48. No 2. Pp. 707–710.

Kucheriava I.M. Magnetic field of extra-high voltage two-circuit cable line with XLPE insulation. Pratsi In-stytutu Elektrodynamiki NAN Ukrainy. 2019. Is. 52. Pp. 13–17. (Rus). DOI: https://doi.org/10.15407/publishing2019.52.013

D’Amore M., Menghi E., Sarto M.S. Shielding techniques of the low-frequency magnetic field from cable power lines. IEEE Internat. Symposium on Electromagnetic Compatibility. 18–22 Aug., 2003. Istanbul. 2003. Vol. 1. Pp. 203–208.

De Wulf M., Wouters P., Sergeant P., Dupré L., Hoferlin E., Jacobs S., Harlet P. Electromagnetic shielding of high-voltage cables. Journal of Magnetism and Magnetic Materials. 2007. No 316. Pp. 908–911. DOI: https://doi.org/10.1016/j.jmmm.2007.03.137

Shcherba A.A., Podoltsev O.D., Kucheriava I.M. The magnetic field of underground 330 kV cable line and ways for its reduction. Tekhnichna Elektrodynamika. 2019. No 5. Pp. 3 – 9. (Rus) DOI: https://doi.org/10.15407/techned2019.05.003

Comsol multiphysics modeling and simulation software. http://www.comsol.com/

Podoltsev A.D., Kucheriava I.M. Multiscale modeling in electrical engineering. Kyiv: Instytut Elektrody-namiky NAN Ukrainy, 2011. 255 p. (Rus)

Lyach V.V., Molchanov V.M., Santatskii V.G., Kvitsinskii A.A. 330 kV cable line: some aspects of de-signing. Promelektro. 2009. No 6. Pp. 27–33. (Rus)

Electric installation code. Minpalyvenerho Ukrainy, 2010. 776 p. (Ukr)