REVERSE ENGINEERING OF TILLAGE MACHINE PARTS FOR FINITE ELEMENT ANALYSIS

UDC 631.316

Kozharina Tatiana Vladimirovna – master’s degree student, the Department “Computer-integrated Systems in Mechanical Engineering”. Tambov State Technical University (106, Sovetskaya str., 392000, Tambov, Russian Federation). E-mail: tata.vladimiiirovna@gmail.com

Karpov Sergey Vladimirovich – PhD (Engineering), Assistant Professor, the Department “Computerintegrated Systems in Mechanical Engineering”. Tambov State Technical University (106, Sovetskaya str., 392000, Tambov, Russian Federation). E-mail: karpov.sv@mail.tstu.ru

Goronovsky Andrey Romanovich – PhD (Engineering), Assistant Professor, the Department of Logging Machinery, Forest Roads and Timber Production Technology. Belarusian State Technological University (13a, Sverdlova str., 220006, Minsk, Republic of Belarus). E-mail: arg@belstu.by

DOI: https://doi.org/ 10.52065/2519-402X-2024-276-20.

Key words: abrasive wear, wear of parts, erosion, 3D scanning, editing of grid geometry, solid geometry, finite element analysis, quality control, tillage, modeling of tillage.

For citation: Kozharina T. V., Karpov S. V., Goronovsky A. R. Reverse engineering of tillage machines parts for finite element analysis. Proceedings of BSTU, issue 1, Forestry, Nature Management. Processing of Renewable Resources, 2024, no. 1 (276), pp. 150–156 (In Russian). DOI: 10.52065/2519-402X-2024-276-20.

Abstract

This article presents a study that was conducted to explore the possibilities and problems associated with the use of 3D scanning in reverse engineering and product quality control. The study is based on the application of computational fluid dynamics methods for the complex analysis of zones of increased abrasion of tillage tools. The results obtained allow us to conclude that at present there are more and more methods that allow to rebuild a part using the principles of reverse engineering. One of such methods is computational fluid dynamics (CFD), which is used for modeling and numerical solution of equations describing the motion of liquids and gases. In this case, CFD is used to analyze the impact of soil on the working bodies of tillage machines. With the help of CFD methods, a detailed study of the soil flow around the working organs was carried out, and the impact of pressure and forces that arise during work was also evaluated. References to previous studies of the authors are given, including an analysis of the possibilities and problems of 3D scanning technology for reverse engineering of products in order to conduct finite element analyses of parts of soil-processing machines.

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References

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23.10.2023