A dislocation density-based model for the work hardening and softening behaviors upon stress reversal

The mechanical behaviours of microalloyed and low-carbon steels under strain reversal were modelled based on the average dislocation density taking into account its allocation between the cell walls and cell interiors. The proposed model reflects the effects of the dislocations displacement, generat...

Full description

Saved in:
Bibliographic Details
Published in:Archives of Civil and Mechanical Engineering 2021-05, Vol.21 (2), p.84, Article 84
Main Authors: Lisiecka-Graca, Paulina, Bzowski, Krzysztof, Majta, Janusz, Muszka, Krzysztof
Format: Article
Language:English
Subjects:
Carbon
Civil Engineering
Deformation
Dislocation density
Electron back scatter
Engineering
Grain boundaries
Low carbon steels
Mechanical Engineering
Mechanical properties
Metal forming
Microstructural analysis
Microstructure
Original Article
Shear strain
Steel
Strain
Strain hardening
Structural Materials
Temperature
Tensors
Torsion tests
Work hardening
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The mechanical behaviours of microalloyed and low-carbon steels under strain reversal were modelled based on the average dislocation density taking into account its allocation between the cell walls and cell interiors. The proposed model reflects the effects of the dislocations displacement, generation of new dislocations and their annihilation during the metal-forming processes. The back stress is assumed as one of the internal variables. The value of the initial dislocation density was calculated using two different computational methods, i.e. the first one based on the dislocation density tensor and the second one based on the strain gradient model. The proposed methods of calculating the dislocation density were subjected to a comparative analysis. For the microstructural analysis, the high-resolution electron backscatter diffraction (EBSD) microscopy was utilized. The calculation results were compared with the results of forward/reverse torsion tests. As a result, good effectiveness of the applied computational methodology was demonstrated. Finally, the analysis of dislocation distributions as an effect of the strain path change was performed.
ISSN:1644-9665
2083-3318
1644-9665
DOI:10.1007/s43452-021-00239-x