МАГНІТОЕЛЕКТРИЧНИЙ ПЕРЕТВОРЮВАЧ ЕНЕРГІЇ МОРСЬКИХ ХВИЛЬ

wave energy conversion
cylindrical magnetoelectric generator
energy indicators
use of gear перетворення енергії хвиль
редуктор
циліндричний магнітоелектричний генератор
енергетичні показники

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Ращепкін, А., Кондратенко, І., Карлов, О. and Крищук, Р. 2021. MAGNETO-ELECTRIC ENERGY CONVERTER OF SEA WAVES. Tekhnichna Elektrodynamika. 4 (Jun. 2021), 025. DOI:https://doi.org/10.15407/techned2021.04.025.

Abstract

To convert the energy of sea waves, the use of cylindrical (with a radial magnetic flux) three-phase magnetoelectric generators with a permanent magnet rotor using a mechanical gearbox to increase the rotor speed is considered. Given the real rotor motion, a mathematical model has been developed to calculate the distribution of magnetic fields in the gap of the generator, and functional dependences of the flux linkage of the winding and the electromagnetic moment of the generator on its design and the parameters of permanent magnets have been obtained. For the adopted design, the electromagnetic moment, the distribution of phase currents in the windings, the power and voltage of the generator are determined. A comparison is made of the energy performance of generators with a traditional float drive and using a ratchet to ensure one-sided rotation of the rotor. The expediency of using a ratchet generator to convert the energy of sea waves is considered. References 6, figures 7.

https://doi.org/10.15407/techned2021.04.025

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References

Savchenko G.Yu. Assessment of energy parameters of a wave float power station. Prykladna hidromekhanika. 2016. Vol. 18. No 2. Pp. 58 - 63. (Rus)

Kondratenko I.P., Rashchepkin A.P., Vashchishin D.D. A dynamic model of a linear permanent magnet generator for converting wave energy. Tekhnichna electrodynamika. 2012. No 2. P. 113-114 (Ukr).

Omar Farrok, Koushik Ahmed, Abdirazak Dahir Tahlil, Mohamud Mohamed Farah, Mahbubur Rahman Kiran, Md. Rabiul Islam. Electrical Power Generation from the Oceanic Wave for Sustainable Advancement in Renewable Energy. Technologies Sustainability. 2020 Vol. 12(6). Рр. 1-23. DOI: https://doi.org/10.3390/su12062178

Tamm I.E. Theory of electricity. Мoskow: Nauka, 1976. 616 p. (Rus)

Gakhov F.D., Chersky Yu.I. Convolution type equations. Moskva: Nauka, 1978. 292 p. (Rus)

White D., Woodson G. Electromechanical energy conversion. Moskva-Leningrad: Energiia, 1964. 528 p. (Rus)

Kostenko M.P., Piotrovskii L.N. Electric machines. Part 2: AC machines. Leningrad: Energiia, 1973. 648 p. (Rus)

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

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MAGNETO-ELECTRIC ENERGY CONVERTER OF SEA WAVES

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