Please use this identifier to cite or link to this item:
https://sci.ldubgd.edu.ua/jspui/handle/123456789/13996
Title: | Mathematical Model of the Dynamics of Spherical Elements |
Authors: | PASTERNAK, Viktoriya RUBAN, Artem HOLII, Oleksandr VAVRENIUK, Sergii |
Keywords: | boundary conditions spheres modelling three-dimensional mode interconnections |
Issue Date: | 2024 |
Publisher: | Trans Tech Publications Ltd |
Series/Report no.: | Advances in Science and Technology;Vol. 156 |
Abstract: | This paper presents a study in the field of modelling the dynamics of spherical elements. The results obtained indicate the successful use of the discrete element method (DEM) as a numerical tool for analysing the behaviour of the system studied with the help of spheres. The results are based on the importance of correct consideration of the boundary conditions for the spheres, which determine the key aspects of modelling with the developed three-dimensional model. The developed model solves a number of important tasks, expanding the field of scientific research. Firstly, it allows studying the main parameters of the formation of a heterogeneous medium by analysing the compaction of spherical elements in different media. Next, the three dimensional model is used to study the process of changing the structure of a heterogeneous medium from a static to an oscillatory state, which allows for a deeper understanding of this process. By modelling the mathematical behaviour of spherical elements under the influence of external and additional factors, a detailed understanding of their dynamics and contact interaction can be obtained. The application of the developed model to analyse the contact interaction of spherical elements in heterogeneous media allows predicting the main parameters of spheres and their heterogeneous environment with a reliable accuracy of up to ±1 %. It should be noted that the results obtained on the basis of the three-dimensional model are effective and indicate a number of practical applications in various fields. |
Description: | In modern scientific research, spherical elements have become the subject of in-depth analysis using mathematical models [1, 2, 3]. Understanding the dynamics of these elements is a key aspect in various fields of science and technology, from astrophysics to molecular biology [4, 5, 6]. It should be noted that the abstract concepts of mathematical models and their practical application in specific situations are a modern and urgent task of today. Therefore, it is important and necessary to carefully analyse various properties of spherical elements, in particular their motion characteristics based on their dynamics, interaction in various conditions, and the interaction of contacts with each other [7, 8, 9]. Mathematical models based on the discrete element method (DEM) are defined as an important tool for considering the real dynamics of these objects [10, 11, 12]. The DEM is becoming the main approach to modelling spheres and studying their motion and interaction in a general dynamic environment [13, 14, 15]. It should also be noted that the practical aspects of using such mathematical models in modern research, including their role in predicting and optimising various processes where spherical elements are key participants, are not well established [16, 17, 18]. There is also little research on how these models can influence the development of new technologies and innovations in various scientific fields [19, 20, 21]. |
URI: | https://sci.ldubgd.edu.ua/jspui/handle/123456789/13996 |
ISSN: | 1662-0356 |
Appears in Collections: | 2024 |
Files in This Item:
File | Description | Size | Format | |
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SCOPUS 18.pdf | 894.95 kB | Adobe PDF | View/Open |
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