Creation of mathematical model of platform-vibrator with shock, designed for concrete products compaction and molding

Authors

DOI:

https://doi.org/10.32347/2410-2547.2020.104.103-116

Keywords:

platform-vibrator, shock, vibro-impact, mold with concrete, upper and lower accelerations

Abstract

Platform-vibrators are the main molding equipment in the production of precast concrete elements. Shock-vibration technology for the precast concrete production on low-frequency resonant platform-vibrators significantly improves the quality of the products front surfaces and the degree of their factory readiness. This technology is used to produce large elements.

We describe the creation of a mathematical model for platform-vibrator that uses shock to produce asymmetric oscillations. The values of the upper and lower accelerations of the mold with concrete have different values with shock-vibration technology.

The created mathematical model corresponds to the two-body 2-DOF vibro-impact system. It is strongly nonlinear non-smooth discontinuous system. It has some peculiar properties, namely: the upper body with very large mass breaks away from the lower body during vibrational motion; both bodies move separately; the upper body falls down onto the soft constraint; the impact that occurs is soft one due to the softness and flexibility of the constraint. The soft impact simulation requires special discussion. In this paper, we simulate a soft impact by a nonlinear contact force in accordance with the Hertz quasistatic contact law.

The numerical parameters for this system were chosen in such a way that: firstly they provide the fulfillment of requirements for real machine, and secondly they allow analyzing its dynamic behavior by nonlinear dynamics tools. The created model is well enough to fulfill a number of requirements, namely: T-periodic steady-state movement after passing the transient process; the appropriate value of mold oscillations amplitude; the satisfactory value of the asymmetry coefficient that is the ratio of lower acceleration to the upper acceleration. We believe that the created model meets all the necessary requirements.

Author Biographies

Viktor Bazhenov, Kyiv National University of Construction and Architecture

Doctor of Technical Sciences, Professor, Academician of the National Academy of Pedagogical Sciences of Ukraine, Head of the Department of Structural Mechanics, Director of the Research Institute of Structural Mechanics

Olga Pogorelova, Kyiv National University of Construction and Architecture

Candidate of Physical and Mathematical Sciences, Senior Researcher, Leading Researcher of the Research Institute of Structural Mechanics

Tetiana Postnikova, Kyiv National University of Construction and Architecture

Candidate of technical sciences, senior researcher, senior researcher of the Research Institute of Structural Mechanics

References

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Bazhenov V.A., Pogorelova O. S., Postnikova T. G. (2019). Intermittent and Quasiperiodic Routes to Chaos in Vibroimpact System. Numerical simulation. LAP LAMBERT Academic Publishing, Beau Bassin, Mauritius, 2019.

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Published

2020-09-10

Issue

No. 104 (2020)

Section

Статті

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Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.