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Mesh objective continuum damage models for ductile fracture

Ragnar Larsson (Institutionen för tillämpad mekanik, Material- och beräkningsmekanik) ; Senad Razanica (Institutionen för tillämpad mekanik, Material- och beräkningsmekanik) ; Lennart Josefson (Institutionen för sjöfart och marin teknik)
International Journal for Numerical Methods in Engineering (0029-5981). Vol. 106 (2016), 10, p. 840-860.
[Artikel, refereegranskad vetenskaplig]

During machining processes the work piece material is subjected to high deformation rates, increased temperature, large plastic deformations, damage evolution and fracture. In this context the Johnson-Cook models are often used even though it exhibits a pathological mesh size dependence. In order to remove the mesh size sensitivity, a set of mesh objective damage models are proposed based on a local continuum damage formulation combined with the concept of a scalar damage phase field. The first model represents a mesh objective augmentation of the well-established element removal model, whereas the second one degrades the continuum stress in a smooth fashion. Plane strain plate and hat specimens are used in the FE- simulations, with the restriction to the temperature and rate independent cases. To investigate the influence of mesh distortion a structured and an unstructured mesh were used for the respective geometry. For structured meshes, the results clearly show that the pathological mesh size sensitivity is removed for both models. When considering unstructured meshes the mesh size sensitivity is more complex as revealed by the considered hat--specimen shear test. Nevertheless, the present work indicates that the proposed models can predict realistic ductile failure behaviors in a mesh objective fashion.

Nyckelord: continuum damage; ductile fracture; Johnson-Cook model; mesh objective models; element removal

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Denna post skapades 2015-12-13. Senast ändrad 2016-05-27.
CPL Pubid: 228088


Institutioner (Chalmers)

Institutionen för tillämpad mekanik, Material- och beräkningsmekanik (2005-2017)
Institutionen för sjöfart och marin teknik (2005-2017)


Hållbar utveckling

Chalmers infrastruktur

C3SE/SNIC (Chalmers Centre for Computational Science and Engineering)

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Denna publikation ingår i:

Computational modelling of machining - Mesh objective ductile damage modelling