Details
| Original language | English |
|---|---|
| Pages (from-to) | 24-37 |
| Number of pages | 14 |
| Journal | International Journal of Engineering Science |
| Volume | 68 |
| Publication status | Published - 11 Apr 2013 |
Abstract
In this study, a polycrystalline material model is introduced. It consists of an artificial grain structure, where the individual crystal geometries are generated by Voronoi cells. In the grains slip planes and sliding directions, corresponding to the slip systems of bcc crystals, are incorporated. The crystallographic behaviour is captured in a consistent continuum mechanics based crystal plasticity framework based on the elastoplastic multiplicative split of the deformation gradient and a viscoplastic regularisation due to a constitutive relation of slip rates and the critical shear stress in the slip systems. A suitable flow rule fulfils the requirement of plastic incompressibility. The specific material considered is the ferritic steel DC04 (material number 1.0338). Based on the results of experimental studies, the initial texture is transferred via Euler angles into the modelled polycrystalline structure. For the determination of initial data as well as the validation of the material behaviour EBSD investigations are carried out. The comparison of the results is done by measuring the strain evolution of grains, the texture and the Schmid factor under uniaxial tensile load. In addition to EBSD measurements of pre-deformed material, in situ EBSD tensile tests are carried out in the SEM. The results of the in situ studies coincide with the results of the pre-deformed material. It is shown that the simulation results agree very well with the experimentally obtained data. The plastic material behaviour is reproduced very well by the simulation, whereas the texture and Schmid factor development shows a good correlation between model and experiment.
Keywords
- Finite crystal plasticity DC04 Pre-textured models Texture Sheet-bulk metal forming In situ EBSD
ASJC Scopus subject areas
- Materials Science(all)
- Engineering(all)
- Engineering(all)
- Mechanics of Materials
- Engineering(all)
- Mechanical Engineering
Cite this
- Standard
- Harvard
- Apa
- Vancouver
- BibTeX
- RIS
In: International Journal of Engineering Science, Vol. 68, 11.04.2013, p. 24-37.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - Texture development and formability prediction for pre-textured cold rolled body-centred cubic steel
AU - Lehmann, Eva
AU - Faßmann, Dennis
AU - Loehnert, Stefan
AU - Schaper, Mirko
AU - Wriggers, Peter
N1 - Funding information: The authors thank especially Wilhelm Rust who took on a lot of work including programming and postprocessing of data. Gratefully acknowledged is also the financial support for this research that was provided by the Deutsche Forschungsgemeinschaft (DFG) under grant SFB TR 73. This contribution evolved from the collaboration of subprojects C2 and C4.
PY - 2013/4/11
Y1 - 2013/4/11
N2 - In this study, a polycrystalline material model is introduced. It consists of an artificial grain structure, where the individual crystal geometries are generated by Voronoi cells. In the grains slip planes and sliding directions, corresponding to the slip systems of bcc crystals, are incorporated. The crystallographic behaviour is captured in a consistent continuum mechanics based crystal plasticity framework based on the elastoplastic multiplicative split of the deformation gradient and a viscoplastic regularisation due to a constitutive relation of slip rates and the critical shear stress in the slip systems. A suitable flow rule fulfils the requirement of plastic incompressibility. The specific material considered is the ferritic steel DC04 (material number 1.0338). Based on the results of experimental studies, the initial texture is transferred via Euler angles into the modelled polycrystalline structure. For the determination of initial data as well as the validation of the material behaviour EBSD investigations are carried out. The comparison of the results is done by measuring the strain evolution of grains, the texture and the Schmid factor under uniaxial tensile load. In addition to EBSD measurements of pre-deformed material, in situ EBSD tensile tests are carried out in the SEM. The results of the in situ studies coincide with the results of the pre-deformed material. It is shown that the simulation results agree very well with the experimentally obtained data. The plastic material behaviour is reproduced very well by the simulation, whereas the texture and Schmid factor development shows a good correlation between model and experiment.
AB - In this study, a polycrystalline material model is introduced. It consists of an artificial grain structure, where the individual crystal geometries are generated by Voronoi cells. In the grains slip planes and sliding directions, corresponding to the slip systems of bcc crystals, are incorporated. The crystallographic behaviour is captured in a consistent continuum mechanics based crystal plasticity framework based on the elastoplastic multiplicative split of the deformation gradient and a viscoplastic regularisation due to a constitutive relation of slip rates and the critical shear stress in the slip systems. A suitable flow rule fulfils the requirement of plastic incompressibility. The specific material considered is the ferritic steel DC04 (material number 1.0338). Based on the results of experimental studies, the initial texture is transferred via Euler angles into the modelled polycrystalline structure. For the determination of initial data as well as the validation of the material behaviour EBSD investigations are carried out. The comparison of the results is done by measuring the strain evolution of grains, the texture and the Schmid factor under uniaxial tensile load. In addition to EBSD measurements of pre-deformed material, in situ EBSD tensile tests are carried out in the SEM. The results of the in situ studies coincide with the results of the pre-deformed material. It is shown that the simulation results agree very well with the experimentally obtained data. The plastic material behaviour is reproduced very well by the simulation, whereas the texture and Schmid factor development shows a good correlation between model and experiment.
KW - Finite crystal plasticity DC04 Pre-textured models Texture Sheet-bulk metal forming In situ EBSD
UR - http://www.scopus.com/inward/record.url?scp=84876221081&partnerID=8YFLogxK
U2 - 10.1016/j.ijengsci.2013.03.003
DO - 10.1016/j.ijengsci.2013.03.003
M3 - Article
AN - SCOPUS:84876221081
VL - 68
SP - 24
EP - 37
JO - International Journal of Engineering Science
JF - International Journal of Engineering Science
SN - 0020-7225
ER -