Sayfidinova, M., Sayfidinov, O., & Aslonova, M.
Investigating the thermal impact on lathe machine tool inserts. |
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Full Article: PDF
Scientific Object Identifier: http://s-o-i.org/1.1/TAS-10-126-17
DOI: https://dx.doi.org/10.15863/TAS.2023.10.126.17
Language: English
Citation: Sayfidinova, M., Sayfidinov, O., & Aslonova, M. (2023). Investigating the thermal impact on lathe machine tool inserts. ISJ Theoretical & Applied Science, 10 (126), 250-261. Soi: http://s-o-i.org/1.1/TAS-10-126-17 Doi: https://dx.doi.org/10.15863/TAS.2023.10.126.17 |
Pages: 250-261
Published: 30.10.2023
Abstract: This study employs Finite Element Method (FEM) simulations to analyze the lathe machine tool insert, employing a division into small 3D tetrahedra with multiple nodes, optimizing tetrahedron sizes for enhanced interaction time. A nominal ambient temperature of 20°C is specified at the center of the insert due to its connection to the holder, affecting its temperature. The FEM simulations scrutinize the insert, revealing the influence of various parameters on material temperatures. Materials with lower heat transfer properties and lower density exhibit lower temperatures. The study indicates that assembling the lathe machine tool for simulation yields more precise results. The temperature effect, though minimal for the insert, reveals advantages when using carbon and titanium. The accuracy of results for simulating the lathe machine tool assembly relies on detecting heat sources accurately, optimizing mesh sizing, and characterizing the material properties of the machine tool components.
Key words: Finite Element Method, FEM, Simulation, Lathe Machine Tool, Temperature Effect, Material Properties, Mesh Sizing, Heat Transfer.
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