Mathematical model of the damping process in a one system with a ball vibration absorber

Автор: Zhengbing Hu, Viktor Legeza, Ivan Dychka, Dmytro Legeza

Журнал: International Journal of Intelligent Systems and Applications @ijisa

Статья в выпуске: 1 vol.10, 2018 года.

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The forced oscillations of the damping mechanical system of solids "Ball Vibration Absorber (BVA) with linearly viscous resistance – a movable carrier body" under the influence of external harmonic excitation are considered. Based on Appell's formalism, the dynamic equations for the joint motion of a heavy ball without sliding into a spherical cavity of a carrier body are formulated and numerically studied. The amplitude-frequency characteristic of the damping mechanical system and the curves of the dependences of the maximum amplitude of the oscillations of the carrier body on the values of the radius of the spherical cavity and the coefficient of viscous resistance of the BVA are obtained. The conditions and restrictions on the rolling of a heavy ball in the spherical recess of the absorber without sliding are determined.

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Damping Mechanical System, Carrier Body, Working Body, External Harmonic Excitation, Ball Vibration Absorber (BVA), Kinematic Ties, Nonholonomic Ties, Appell's Formalism, Amplitude-Frequency Characteristic (AFC), Parameters Settings of Absorber, Determining the Optimum Parameters, Rolling of a Heavy Ball Without Sliding

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Короткий адрес: https://sciup.org/15016451

IDR: 15016451   |   DOI: 10.5815/ijisa.2018.01.04

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