On the evaluation of the Bauschinger effect in an austenitic stainless steel—the role of multi-scale residual stresses
On the evaluation of the Bauschinger effect in an austenitic stainless steel—the role of multi-scale residual stresses
In this work, a physically based self-consistent model is developed and employed to examine the microscopic lattice response of pre-strained Type 316H polycrystalline austenitic stainless steel subjected to uniaxial tensile and compressive loading. The model is also used to explain the Bauschinger effect observed at the macroscopic length-scale. Formulated in a crystal based plasticity framework, the model incorporates detailed strengthening effects associated with different microstructural elements such as forest dislocation junctions, solute atoms and precipitates on individual crystallographic slip planes of each individual grain within the polycrystal. The elastoplastic response of the bulk polycrystal is obtained by homogenizing the response of all the constituent grains using a self-consistent approach. Micro-plasticity mechanisms and how these influence the Bauschinger effect are illustrated in terms of the role of residual stresses at different length-scales. Overall, predictions are in good agreement with experimental data of the Bauschinger effect and the corresponding meso-scale lattice response of the material, with the latter measured by neutron diffraction. The results demonstrate that transient softening of the material is related to residual stresses at different length scales. In addition, the (Type III) residual stress at the micro-scale slip system level extends the strain range over which the tensile and compressive reloading curves of the pre-strained material merge.
203-223
Hu, Jianan
6419969e-0c94-46f8-86ed-635e593846fb
Chen, Bo
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Smith, David J.
4a133363-d55a-41b9-9132-2484d37915e4
Flewitt, Peter E.J.
f4ac343e-c50c-45e0-8290-e43978274645
Cocks, Alan C.F.
58b0c2c2-5987-488d-80bb-8cea9dbbb7e9
21 July 2016
Hu, Jianan
6419969e-0c94-46f8-86ed-635e593846fb
Chen, Bo
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Smith, David J.
4a133363-d55a-41b9-9132-2484d37915e4
Flewitt, Peter E.J.
f4ac343e-c50c-45e0-8290-e43978274645
Cocks, Alan C.F.
58b0c2c2-5987-488d-80bb-8cea9dbbb7e9
Hu, Jianan, Chen, Bo and Smith, David J.
,
et al.
(2016)
On the evaluation of the Bauschinger effect in an austenitic stainless steel—the role of multi-scale residual stresses.
International Journal of Plasticity, 84, .
(doi:10.1016/j.ijplas.2016.05.009).
Abstract
In this work, a physically based self-consistent model is developed and employed to examine the microscopic lattice response of pre-strained Type 316H polycrystalline austenitic stainless steel subjected to uniaxial tensile and compressive loading. The model is also used to explain the Bauschinger effect observed at the macroscopic length-scale. Formulated in a crystal based plasticity framework, the model incorporates detailed strengthening effects associated with different microstructural elements such as forest dislocation junctions, solute atoms and precipitates on individual crystallographic slip planes of each individual grain within the polycrystal. The elastoplastic response of the bulk polycrystal is obtained by homogenizing the response of all the constituent grains using a self-consistent approach. Micro-plasticity mechanisms and how these influence the Bauschinger effect are illustrated in terms of the role of residual stresses at different length-scales. Overall, predictions are in good agreement with experimental data of the Bauschinger effect and the corresponding meso-scale lattice response of the material, with the latter measured by neutron diffraction. The results demonstrate that transient softening of the material is related to residual stresses at different length scales. In addition, the (Type III) residual stress at the micro-scale slip system level extends the strain range over which the tensile and compressive reloading curves of the pre-strained material merge.
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e-pub ahead of print date: 24 May 2016
Published date: 21 July 2016
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Local EPrints ID: 489947
URI: http://eprints.soton.ac.uk/id/eprint/489947
ISSN: 0749-6419
PURE UUID: 5f456594-d7c6-4576-af99-6877f76fcf4c
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Date deposited: 08 May 2024 16:30
Last modified: 09 May 2024 04:01
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Author:
Jianan Hu
Author:
Bo Chen
Author:
David J. Smith
Author:
Peter E.J. Flewitt
Author:
Alan C.F. Cocks
Corporate Author: et al.
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