Numerical study of the minimum uncut chip thickness in micro‑machining of Inconel 718 based on Johnson–Cook isothermal model

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Autor(es): dc.contributorUniversity of Brasília, Faculty of Technology, Department of Mechanical Engineering-
Autor(es): dc.contributorUniversity of Brasília, Faculty of Technology, Department of Mechanical Engineering-
Autor(es): dc.contributorUniversity of Brasília, Faculty of Technology, Department of Mechanical Engineering-
Autor(es): dc.creatorSilva, Gabriel de Paiva-
Autor(es): dc.creatorOliveira, Déborah de-
Autor(es): dc.creatorMalcher, Lucival-
Data de aceite: dc.date.accessioned2024-10-23T16:37:19Z-
Data de disponibilização: dc.date.available2024-10-23T16:37:19Z-
Data de envio: dc.date.issued2024-05-20-
Data de envio: dc.date.issued2024-05-20-
Data de envio: dc.date.issued2023-06-07-
Fonte completa do material: dc.identifierhttp://repositorio2.unb.br/jspui/handle/10482/48106-
Fonte completa do material: dc.identifierhttps://doi.org/10.1007/s00170-023-11573-0-
Fonte completa do material: dc.identifierhttps://orcid.org/0000-0002-3654-4953-
Fonte: dc.identifier.urihttp://educapes.capes.gov.br/handle/capes/913049-
Descrição: dc.descriptionTraditional machining in micro-scale still presents many challenges associated with bad chip formation, presence of high burrs, elevated tool wear and low surface quality. Most problems in micro-machining are a consequence of the size efect, which is the similarity in the scale sizes of the cutting-edge radius of the tool and the minimum uncut chip thickness (MUCT). Micro-machining tends to be even more challenging for low-machinability alloys, such as Inconel 718. Through the fnite ele ment method (FEM), it is possible to estimate the minimum uncut chip thickness of a material providing that the constitutive model that describes its elastoplastic behavior is known. Therefore, the objective of this contribution is to analyze the chip formation in orthogonal micro-cutting of Inconel 718 using numerical FEM simulations and the Johnson–Cook plasticity model in an explicit scheme. Two cutting tools were modelled with diferent edge radius in order to represent a sharp tool and a tool that sufered rounding of the tip because of wear. Simulations were carried out with diferent values of feed per tooth in order to determine which value is closest to MUCT. The Mises stress and accumulated plastic strain were monitored, as well as the cutting forces. The results show that the rounded tool, with an edge radius of 5 µm, leads to higher forces, worse chip formation and worse surface quality when compared to the sharp tool, with an edge radius of 1 µm.-
Descrição: dc.descriptionFaculdade de Tecnologia (FT)-
Descrição: dc.descriptionDepartamento de Engenharia Mecânica (FT ENM)-
Descrição: dc.descriptionPrograma de Pós-Graduação em Ciências Mecânicas-
Idioma: dc.languageen-
Publicador: dc.publisherSpringer-
Relação: dc.relationhttps://link.springer.com/article/10.1007/s00170-023-11573-0-
Direitos: dc.rightsAcesso Restrito-
Palavras-chave: dc.subjectMétodo dos elementos finitos-
Palavras-chave: dc.subjectPlasticidade-
Título: dc.titleNumerical study of the minimum uncut chip thickness in micro‑machining of Inconel 718 based on Johnson–Cook isothermal model-
Tipo de arquivo: dc.typelivro digital-
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