New insights into the role of porous microstructure on dynamic shear localization

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Show simple item record Ambikadevi Rajasekharan Nair, Vishnu Nieto Fuentes, Juan Carlos Marvi Mashhadi, Mohammad Rodriguez Martinez, Jose Antonio 2022-02-23T19:25:42Z 2022-02-23T19:25:42Z 2022-01-01
dc.identifier.bibliographicCitation Vishnu, A. R., Marvi-Mashhadi, M., Nieto-Fuentes, J. C., & Rodríguez-Martínez, J. A. (2022). New insights into the role of porous microstructure on dynamic shear localization. En International Journal of Plasticity,148, p. 103150
dc.identifier.issn 0749-6419
dc.description.abstract This paper provides new insights into the role of porous microstructure on dynamic shear localization. For that purpose, we have performed 3D finite element calculations of electromagnetically collapsing thick-walled cylinders. The geometry and dimensions of the cylindrical specimens are taken from the experiments of Lovinger et al. (2015), and the loading and boundary conditions from the 2D simulations performed by Lovinger et al. (2018). The mechanical behavior of the material is modeled as elastic-plastic, with yielding described by the von Mises criterion, an associated flow rule and isotropic hardening/softening, being the flow stress dependent on strain, strain rate and temperature. Moreover, plastic deformation is considered to be the only source of heat, and the analysis accounts for the thermal conductivity of the material. The distinctive feature of this work is that we have followed the methodology developed by Marvi-Mashhadi et al. (2021) to incorporate into the finite element calculations the actual porous microstructure of 4 different additively manufactured materials –aluminium alloy AlSi10Mg, stainless steel 316L, titanium alloy Ti6Al4V and Inconel 718– for which the initial void volume fraction varies between 0.001% and 2%, and the pores size ranges from ≈ 6 μm to ≈ 110 μm. The numerical simulations have been performed using the Coupled Eulerian-Lagrangian approach available in ABAQUS/Explicit (2016), which allows to capture the shape evolution, coalescence and collapse of the voids at large strains. To the authors’ knowledge, this paper contains the first finite element simulations with explicit representation of the material porosity which demonstrate that voids promote dynamic shear localization, acting as preferential sites for the nucleation of the shear bands, speeding up their development, and tailoring their direction of propagation. In addition, the numerical calculations bring out that for a given void volume fraction more shear bands are nucleated as the number of voids increases, while the shear bands are incepted earlier and develop faster as the size of the pores increases.
dc.description.sponsorship The research leading to these results has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme. Project PURPOSE, grant agreement 758056.
dc.language.iso eng
dc.publisher Elsevier
dc.rights © 2021 The Authors.
dc.rights Atribución-NoComercial-SinDerivadas 3.0 España
dc.subject.other Adiabatic shear bands
dc.subject.other Porous microstructure
dc.subject.other Thermal softening
dc.subject.other Microstructural softening
dc.subject.other Printed metals
dc.title New insights into the role of porous microstructure on dynamic shear localization
dc.type article
dc.subject.eciencia Ingeniería Mecánica
dc.rights.accessRights openAccess
dc.relation.projectID info:eu-repo/grantAgreement/EC/H2020/758056/PURPOSE
dc.type.version publishedVersion
dc.identifier.publicationfirstpage 1
dc.identifier.publicationlastpage 29
dc.identifier.publicationtitle INTERNATIONAL JOURNAL OF PLASTICITY
dc.identifier.publicationvolume 148
dc.identifier.uxxi AR/0000029758
dc.contributor.funder European Commission
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