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Formation of Vibration Fields for a Mechatronic Platform Driven by Dual Asynchronous Motors. / Фрадков, Александр Львович; Андриевский, Борис Ростиславич; Томчина, Ольга Петровна; Зайцева, Юлия Сергеевна.

In: Electronics (Switzerland), Vol. 13, No. 16, 3165, 10.08.2024.

Research output: Contribution to journalArticlepeer-review

Harvard

Фрадков, АЛ, Андриевский, БР, Томчина, ОП & Зайцева, ЮС 2024, 'Formation of Vibration Fields for a Mechatronic Platform Driven by Dual Asynchronous Motors', Electronics (Switzerland), vol. 13, no. 16, 3165. https://doi.org/10.3390/electronics13163165

APA

Фрадков, А. Л., Андриевский, Б. Р., Томчина, О. П., & Зайцева, Ю. С. (2024). Formation of Vibration Fields for a Mechatronic Platform Driven by Dual Asynchronous Motors. Electronics (Switzerland), 13(16), [3165]. https://doi.org/10.3390/electronics13163165

Vancouver

Фрадков АЛ, Андриевский БР, Томчина ОП, Зайцева ЮС. Formation of Vibration Fields for a Mechatronic Platform Driven by Dual Asynchronous Motors. Electronics (Switzerland). 2024 Aug 10;13(16). 3165. https://doi.org/10.3390/electronics13163165

Author

Фрадков, Александр Львович ; Андриевский, Борис Ростиславич ; Томчина, Ольга Петровна ; Зайцева, Юлия Сергеевна. / Formation of Vibration Fields for a Mechatronic Platform Driven by Dual Asynchronous Motors. In: Electronics (Switzerland). 2024 ; Vol. 13, No. 16.

BibTeX

@article{406c77f01c2243529b5f701999f09081,
title = "Formation of Vibration Fields for a Mechatronic Platform Driven by Dual Asynchronous Motors",
abstract = "This paper investigates the formation of vibration fields in a mechatronic setup driven by dual induction motors, relying on the controlled synchronization of unbalanced rotors. The proposed algorithm enables precise control over rotor speeds and phase shifts. Experimental results from a multi-resonance vibration laboratory setup demonstrate this approach{\textquoteright}s ability to form the vibration fields. The ability to control these fields is crucial for applications such as vibratory transportation and the mixing of bulk materials. The results obtained can ensure a diverse picture of the complex trajectories of motion for various points of the platform, primarily in the screens, making various useful effects for vibration technologies. Additionally, the practical value of this research is that in the case of double synchronous mode the ordinate of the lower point of the trajectory is lower than in the case of single synchronous mode, which improves the efficiency of unloading and prevents congestion formation. The experimental data highlight the practical advantages and potential improvements in efficiency and reliability offered by this method.",
keywords = "phase shift, synchronization, vibration field, vibration machines",
author = "Фрадков, {Александр Львович} and Андриевский, {Борис Ростиславич} and Томчина, {Ольга Петровна} and Зайцева, {Юлия Сергеевна}",
year = "2024",
month = aug,
day = "10",
doi = "10.3390/electronics13163165",
language = "English",
volume = "13",
journal = "Electronics (Switzerland)",
issn = "2079-9292",
publisher = "MDPI AG",
number = "16",

}

RIS

TY - JOUR

T1 - Formation of Vibration Fields for a Mechatronic Platform Driven by Dual Asynchronous Motors

AU - Фрадков, Александр Львович

AU - Андриевский, Борис Ростиславич

AU - Томчина, Ольга Петровна

AU - Зайцева, Юлия Сергеевна

PY - 2024/8/10

Y1 - 2024/8/10

N2 - This paper investigates the formation of vibration fields in a mechatronic setup driven by dual induction motors, relying on the controlled synchronization of unbalanced rotors. The proposed algorithm enables precise control over rotor speeds and phase shifts. Experimental results from a multi-resonance vibration laboratory setup demonstrate this approach’s ability to form the vibration fields. The ability to control these fields is crucial for applications such as vibratory transportation and the mixing of bulk materials. The results obtained can ensure a diverse picture of the complex trajectories of motion for various points of the platform, primarily in the screens, making various useful effects for vibration technologies. Additionally, the practical value of this research is that in the case of double synchronous mode the ordinate of the lower point of the trajectory is lower than in the case of single synchronous mode, which improves the efficiency of unloading and prevents congestion formation. The experimental data highlight the practical advantages and potential improvements in efficiency and reliability offered by this method.

AB - This paper investigates the formation of vibration fields in a mechatronic setup driven by dual induction motors, relying on the controlled synchronization of unbalanced rotors. The proposed algorithm enables precise control over rotor speeds and phase shifts. Experimental results from a multi-resonance vibration laboratory setup demonstrate this approach’s ability to form the vibration fields. The ability to control these fields is crucial for applications such as vibratory transportation and the mixing of bulk materials. The results obtained can ensure a diverse picture of the complex trajectories of motion for various points of the platform, primarily in the screens, making various useful effects for vibration technologies. Additionally, the practical value of this research is that in the case of double synchronous mode the ordinate of the lower point of the trajectory is lower than in the case of single synchronous mode, which improves the efficiency of unloading and prevents congestion formation. The experimental data highlight the practical advantages and potential improvements in efficiency and reliability offered by this method.

KW - phase shift

KW - synchronization

KW - vibration field

KW - vibration machines

UR - https://www.mendeley.com/catalogue/4e6caefa-fb03-3e03-b30e-5441ed098781/

U2 - 10.3390/electronics13163165

DO - 10.3390/electronics13163165

M3 - Article

VL - 13

JO - Electronics (Switzerland)

JF - Electronics (Switzerland)

SN - 2079-9292

IS - 16

M1 - 3165

ER -

ID: 125627609