2021
DOI: 10.3390/jmmp5030083
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An Efficient Methodology towards Mechanical Characterization and Modelling of 18Ni300 AMed Steel in Extreme Loading and Temperature Conditions for Metal Cutting Applications

Abstract: A thorough control of the machining operations is essential to ensure the successful post-processing of additively manufactured components, which can be assessed through machinability tests endowed with numerical simulation of the metal cutting process. However, to accurately depict the complex metal cutting mechanism, it is not only necessary to develop robust numerical models but also to properly characterize the material behavior, which can be a long-winded process, especially for state-of-stress sensitive … Show more

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Cited by 6 publications
(2 citation statements)
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“…when metallic materials are subjected to extreme deformation loads characterized by high deformation speed and large strain, they usually undergo macroscopic localization of the deformation, form a concentrated shear zone, and result in plastic instability [1][2][3]. in earlier research on metal material microstructures, the bright white high-hardness bands in the concentrated deformation zone assumed to be martensitic products formed via phase transformation [4][5][6]. Later on, transmission electron microscopy, field emission scanning electron microscopy, and electron back-scattered diffraction (eBSD) were applied to investigate the microstructure, and the results proved that equiaxed non-distortion crystal grains of sub-micron size were formed in the concentrated deformation zone [7,8].…”
Section: Introductionmentioning
confidence: 99%
“…when metallic materials are subjected to extreme deformation loads characterized by high deformation speed and large strain, they usually undergo macroscopic localization of the deformation, form a concentrated shear zone, and result in plastic instability [1][2][3]. in earlier research on metal material microstructures, the bright white high-hardness bands in the concentrated deformation zone assumed to be martensitic products formed via phase transformation [4][5][6]. Later on, transmission electron microscopy, field emission scanning electron microscopy, and electron back-scattered diffraction (eBSD) were applied to investigate the microstructure, and the results proved that equiaxed non-distortion crystal grains of sub-micron size were formed in the concentrated deformation zone [7,8].…”
Section: Introductionmentioning
confidence: 99%
“…Therefore, technology-adapted material characterization and modelling is highly relevant in impulse-based manufacturing. Silva et al suggest a me-thodology for the mechanical characterization and modelling of materials under extreme load conditions considering strain, strain rate, temperature, and state of stress [12]. Al-though the validation in this paper is based on metal cutting, these load conditions show comprehensive similarities with the situation in impulse-based manufacturing, so the approach is relevant and could benefit these technologies, too.…”
mentioning
confidence: 98%