期刊
FATIGUE & FRACTURE OF ENGINEERING MATERIALS & STRUCTURES
卷 44, 期 9, 页码 2337-2355出版社
WILEY
DOI: 10.1111/ffe.13493
关键词
crack tip displacement; crystal plasticity; grain size; microplasticity; microstructure
资金
- Sandia National Laboratories [193072]
The study introduces a microstructure-sensitive finite element approach to investigate the effects of grain size and crystallographic orientation on crack tip microplasticity and blunting, showing that microstructure can act as a buffer between local and far fields. Grain size and texture affect local ductility and induce significant multiaxial plastic deformation.
Traditional fracture theories infer damage at cracks (local field) by surveying loading conditions away from cracks (far field). This approach has been successful in predicting ductile fracture, but it normally assumes isotropic and homogeneous materials. However, myriads of manufacturing procedures induce heterogeneous microstructural gradients that can affect the accuracy of traditional fracture models. This work presents a microstructure-sensitive finite element approach to explore the shielding effects of grain size and crystallographic orientation gradients on crack tip microplasticity and blunting. A dislocation density-based crystal plasticity model conveys texture evolution, grain size effects, and directional hardening by computing the constraint from dislocation structures. The results demonstrate that the microstructure can act as a buffer between the local and far fields that affects the crack tip microplasticity variability. For nominal opening loading, grain size and texture affect the local ductility and induce a non-negligible multiaxial plastic deformation. Furthermore, driving forces based on measuring displacements away from the crack tip are less affected by the microstructure, which suggests that traditional experimental methods smear out important crack tip variability.
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