Equations of motion of vibration machines with a translational motion of platforms and a vibration exciter in the form of a passive auto-balancer

Authors

DOI:

https://doi.org/10.15587/1729-4061.2017.111216

Keywords:

inertial vibration exciter, two-frequency vibrations, resonant vibration machine, auto-balancer, single-mass vibration machine, multi-mass vibration machine

Abstract

Generalized models have been built of one-, two-, and three-mass vibration machines with a rectilinear translational motion of platforms and a vibration exciter in the form of a ball, a roller, or a pendulum auto-balancer.

In the generalized model of a single-mass vibration machine, the platform relies on an elastic-viscous support with the guides enabling the platform’s rectilinear translational motion. A passive auto-balancer is installed on the platform.

In the generalized models of two- and three-mass vibration machines, each platform relies on a fixed external elastic-viscous support with the platforms coupled in pairs by elastic-viscous inner supports. The guides allow the platforms to move rectilinearly translationally. A passive auto-balancer is installed on one of the platforms.

We have derived differential equations of the motion of vibration machines. The equations are reduced to the form that is independent of the type of an auto-balancer.

The models of particular one-, two- and three-mass vibration machines can be obtained from the generalized models by selecting a specific type of the auto-balancer.

The models of particular two-mass vibration machines can also be obtained from the corresponding generalized model by rejecting one of the external elastic-viscous supports.

The models of particular three-mass vibration machines can also be derived from the corresponding generalized model by rejecting:

– one or two external elastic-viscous supports;

– one of the three inner elastic-viscous supports;

– one or two external elastic-viscous supports and one of the three inner elastic-viscous supports.

The constructed models are applicable both for analytical studies into dynamics of the relevant vibration machines and for performing computational experiments.

When employed in analytical studies, the models are designed to search for the established modes of a vibration machine motion, to determine conditions for their existence and stability

Author Biographies

Volodymyr Yatsun, Central Ukrainian National Technical University Universytetskyi ave., 8, Kropivnitskiy, Ukraine, 25006

PhD, Associate Professor

Department of Road Cars and Building

Gennadiy Filimonikhin, Central Ukrainian National Technical University Universytetskyi ave., 8, Kropivnitskiy, Ukraine, 25006

Doctor of Technical Sciences, Professor, Head of Department

Department of Machine Parts and Applied Mechanics

 

Kostyantyn Dumenko, Central Ukrainian National Technical University Universytetskyi ave., 8, Kropivnitskiy, Ukraine, 25006

Doctor of Technical Sciences, Associate Professor

Department of Operation and Repair of Machines

Andrey Nevdakha, Central Ukrainian National Technical University Universytetskyi ave., 8, Kropivnitskiy, Ukraine, 25006

PhD

Department of Machine Parts and Applied Mechanics

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Published

2017-10-24

How to Cite

Yatsun, V., Filimonikhin, G., Dumenko, K., & Nevdakha, A. (2017). Equations of motion of vibration machines with a translational motion of platforms and a vibration exciter in the form of a passive auto-balancer. Eastern-European Journal of Enterprise Technologies, 5(1 (89), 19–25. https://doi.org/10.15587/1729-4061.2017.111216

Issue

Vol. 5 No. 1 (89) (2017): Engineering technological systems

Section

Engineering technological systems

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Copyright (c) 2017 Volodymyr Yatsun, Gennadiy Filimonikhin, Kostyantyn Dumenko, Andrey Nevdakha

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