ДИНАМІЧНА МОДЕЛЬ ЛІНІЙНОГО ГЕНЕРАТОРА З ПОСТІЙНИМИ МАГНІТАМИ ДЛЯ ПЕРЕТВОРЕННЯ ЕНЕРГІЇ ХВИЛЬ

I.P. Kondratenko; A.P. Rashchepkin; D.D. Vashchishin

No. 2 (2012), Electrotechnological Complexes and Systems

No. 2 (2012)

Electrotechnological Complexes and Systems

A DYNAMIC MODEL OF A LINEAR PERMANENT MAGNET GENERATOR FOR CONVERTING WAVE ENERGY

Published 2012-02-02

I.P. Kondratenko⁺⁻
A.P. Rashchepkin⁺⁻
D.D. Vashchishin⁺⁻

I.P. Kondratenko

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

A.P. Rashchepkin

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

D.D. Vashchishin

National university of life and environmental sciences of Ukraine, str. Heroyiv oborony, 12, Kyiv, 03041, Ukraina

ARTICLE_54_PDF (Українська)

Keywords

linear generator
permanent magnets
energy of waves лінійний генератор
постійні магніти
енергія хвилі

How to Cite

[1]

Kondratenko, I. et al. 2012. A DYNAMIC MODEL OF A LINEAR PERMANENT MAGNET GENERATOR FOR CONVERTING WAVE ENERGY. Tekhnichna Elektrodynamika. 2 (Feb. 2012), 113.

Abstract

The method of calculating the electrical characteristics of the linear generator was devised, which is part of a device for converting energy of sea waves, considering dynamic modes of inductor motion and reaction of electromagnetic system. The method is based on a compatible solution of the equations of dynamic equilibrium mechanical system (d'Alembert) and electric circuit of three-phase linear generator (equation of the second Kirchhoff law). The design of a linear generator with a inductor realized in the form of a periodic system of permanent magnets. The dependence the linear generator energy characterizes on the nature of the moving inductor at a given wave shape, and examined the impact strength of electromagnetic interaction on the power generated by the generator at the specified parameters of inductor-buoy. References 4.

ARTICLE_54_PDF (Українська)

References

Kondratenko I.P., Rashchepkin A.P., Vashchishin D.D. The calculation of the electromotive force of the linear generator for the convertion of the wave energy // Visnyk Kremenchutskogo Universytetu im. M.Ostrogradskogo. 2010. Vol.1. Pp. 72-75. (Ukr)

Kondratenko I.P., Rashchepkin A.P., Vashchishin D.D. The device mathematical model for transforming the sea waves energy // Problemy energoresursozberezhennia v elektrotekhnichnych systemakh. Nauka, osvita i praktyka. 2011. Vol.1. Pp. 224-225. (Ukr)

Vishtak P.A., Krutilin V.A. , Kondratenko I.P., Rashchepkin A.P. The magnetic field in the gap linear induction machines with concentric windings // Tekhnicheskaia elektrodinamika. 1984. No 1. Pp. 15-20. (Rus)

Rashchepkin A.P. Field in the gap with a variable linear load winding induction machine // Magnitnaia hidrodinamika. 1965. No 3. Pp. 96-102. (Rus)

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