Void coalescence mechanism for combined tension and large amplitude cyclic shearing

•Void coalescence for combined tension and large amplitude cyclic shearing is shown.•Voids develop protrusions in the shearing place and these evolve for each cycle.•The far-field loading, the void shape, and the void growth are monitored.•Calculations are pushed to complete loss of load carrying ca...

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Bibliographic Details
Published inEngineering fracture mechanics Vol. 189; pp. 164 - 174
Main Authors Nielsen, K.L., Andersen, R.G., Tvergaard, V.
Format Journal Article
LanguageEnglish
Published New York Elsevier Ltd 15.02.2018
Elsevier BV
Subjects
Amplitudes
Bearing strength
Coalescing
Constant mean stress
Cracks
Cyclic loads
Damage
Deformation
Deformation mechanisms
Ductile failure
Elongation
Fatigue failure
Load
Load carrying capacity
Low cycle fatigue
Shear deformation
Shearing
Strain hardening
Tensile stress
Voids
Ductile failure
Constant mean stress
Damage
Low cycle fatigue
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Summary:•Void coalescence for combined tension and large amplitude cyclic shearing is shown.•Voids develop protrusions in the shearing place and these evolve for each cycle.•The far-field loading, the void shape, and the void growth are monitored.•Calculations are pushed to complete loss of load carrying capacity. Void coalescence at severe shear deformation has been studied intensively under monotonic loading conditions, and the sequence of micro-mechanisms that governs failure has been demonstrated to involve collapse, rotation, and elongation of existing voids. Under intense shearing, the voids are flattened, such that the void volume diminishes, whereafter the flattened crack-like voids rotate and elongate until interaction with neighboring micro-voids dominates the material response and coalescence sets in. Eventually, this leads to a complete loss of load carrying capacity. The severe shear loading, imposed at the far boundary, is in an early state of the deformation associated with significant stretching of parts of the void surface, while other parts remain practically un-deformed. A largely uneven distribution of the strain hardening, therefore, evolves along the void circumference and, thus, one cannot expect the void to return to its original shape in the case where the far-field loading is reversed. The present numerical work aims to investigate the evolution of micro-voids subject to constant tension and large amplitude cyclic shearing. The far-field loading, the void shape, and the void growth are monitored, and the calculations are pushed to coalescence and complete loss of load carrying capacity. The initially circular cylindrical voids are predicted to develop protrusions in the shearing plane with normal in the direction of the applied tensile load. These protrusions evolve during repeated cyclic shearing and spread towards neighboring voids - eventually being responsible for void coalescence.
ISSN:0013-7944
1873-7315
DOI:10.1016/j.engfracmech.2017.10.035