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17.08.2022 | Original Article

A multiscale approach to modeling the frictional behavior of the materials produced by additive manufacturing technologies

verfasst von: Alexey Smolin, Evgeny Shilko, Aleksandr Grigoriev, Evgeny Moskvichev, Andrey Fillipov, Nikolay Shamarin, Andrey Dmitriev, Anton Nikonov, Evgeny Kolubaev

Erschienen in: Continuum Mechanics and Thermodynamics | Ausgabe 4/2023

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Abstract

Additive manufacturing allows fabricating materials with complex structures and specific properties. For Cu-Al alloys that are widely used in the sliding friction units of many machines in different industries, the 3D printing technique using electron beam-induced deposition seems to be very promising due to its great possibility in fabricating materials with varied compositions and gradient structure. The material structure and its surface properties play the most important role in frictional behavior. Friction is a very complex phenomenon, which includes a wide range of mechanical, physical, and chemical processes occurring at various scales simultaneously. Despite the great importance of friction, just a few restricted theories have been proposed till now. The same is valid for computer-aided simulation approaches. This paper presents a multiscale approach for modeling the mechanical behavior of the metallic materials in friction zone under sliding. This approach uses coupled discrete-continuum computational scheme in which a narrow contact zone of interacting bodies is described by the discrete element method and the rest of the material, which experiences elastic deformation, by the conventional finite element method of solid mechanics. Thus, at the mesoscale of friction that corresponds to contacting layers and third body we use computational particle mechanics. Here, special attention is given to describing the mechanical behavior of shape memory alloys that looks very promising for tribological applications of Cu-Al alloys. It is also shown that for obtaining some parameters of the mesomodel it is possible to use molecular dynamics simulation at the atomic scale. Finally, the results of friction simulation are considered and discussed for different values of the model parameters corresponding to the shape memory effect.

Vorheriger Artikel Setting of forced oscillations of viscoelastic coating

Nächster Artikel The discrete contact problem for a two-level system of indenters

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Titel: A multiscale approach to modeling the frictional behavior of the materials produced by additive manufacturing technologies
verfasst von: Alexey Smolin
Evgeny Shilko
Aleksandr Grigoriev
Evgeny Moskvichev
Andrey Fillipov
Nikolay Shamarin
Andrey Dmitriev
Anton Nikonov
Evgeny Kolubaev
Publikationsdatum: 17.08.2022
Verlag: Springer Berlin Heidelberg
Erschienen in: Continuum Mechanics and Thermodynamics / Ausgabe 4/2023
Print ISSN: 0935-1175
Elektronische ISSN: 1432-0959
DOI: https://doi.org/10.1007/s00161-022-01135-2

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