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Mathematical modeling of modernized brushless direct current motor working at maximum speed

https://doi.org/10.35266/1999-7604-2025-4-9

Abstract

The paper presents an experimental study of a modernized brushless direct current motor and develops mathematical and parameter-oriented models for calculating maximum speed based on the characteristics of the motor. The experiments on the test bed show the dependency relations of the motor revolutions to the current at each of its phases. The specified dependencies reflect the main motor settings and allow obtaining the peak current and speed values.
The testing establishes the fact that the winding coil amount has a limit. A sudden increase in the maximum
current specifies it without changes in the number of motor revolutions. A parameter-oriented model is developed by linking the conveniently measurable electrical characteristics of a modernized brushless direct current motor and a battery with the maximum speed. Also, a mathematical model of such a motor is proposed, which makes it possible to calculate the peak current and corresponding revolutions based on its parameters. The study shows the necessity of considering the influence of the chief characteristics and counter-electromotive force while working on the development of similar models, as the impact of the latter is a major at maximum speed.

About the Authors

S. N. Tkachenko
Балтийский федеральный университет имени Иммануила Канта, Калининград
Russian Federation

Candidate of Sciences (Engineering), Docent



A. S. Krivoguzova
Балтийский федеральный университет имени Иммануила Канта, Калининград
Russian Federation

Postgraduate



A. A. Shpilevoi
Балтийский федеральный университет имени Иммануила Канта, Калининград
Russian Federation

Candidate of Sciences (Physics and Mathematics), Docent



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Review

For citations:


Tkachenko S.N., Krivoguzova A.S., Shpilevoi A.A. Mathematical modeling of modernized brushless direct current motor working at maximum speed. Proceedings in Cybernetics. 2025;24(4):80-92. (In Russ.) https://doi.org/10.35266/1999-7604-2025-4-9

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ISSN 1999-7604 (Online)