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Micromechanical predictions of TRIP steel behavior as a function of microstructural parameters

Micromechanical predictions of TRIP steel behavior as a function of microstructural parameters
Micromechanical predictions of TRIP steel behavior as a function of microstructural parameters

Micromechanically-based models are used to mimic the martensitic phase transformations in retained austenite and the elasto-plastic behavior of the adjacent ferritic phase. The numerical simulations concern TRIP steel samples with a finite number of grains of retained austenite embedded in a polycrystalline ferrite-based matrix. Parametric analyses are performed in order to investigate the effect of the variation of microstructural properties on the stability of retained austenite, and thus on the overall mechanical response. The microstructural parameters considered are (i) the initial volume fraction of the retained austenite, (ii) the elasto-plastic properties of the surrounding ferritic matrix, (iii) the crystallographic orientations of the ferritic and austenitic grains, and (iv) the carbon concentration in the retained austenite. The results show that the effective strength of TRIP steels increases with the carbon concentration in the retained austenite, but it depends non-monotonically on the initial volume fraction of retained austenite. It is shown that the overall strength and the martensitic transformation rate depend strongly on the crystallographic orientations of the grains and the properties of the surrounding matrix. This information is useful for the optimization of the mechanical characteristics of TRIP steels and the improvement of their processing parameters. The numerical predictions are in good qualitative agreement with experimental observations.

Micromechanical modeling, Microstructural parameters, Retained austenite stability, TRIP steels
0927-0256
107-116
Tjahjanto, D. D.
5245c9ae-bf27-49db-86a3-bb34bd16b6fb
Suiker, A. S.J.
a3678c57-c858-484d-b558-32a0419be9cf
Turteltaub, S.
b56fac3e-42f6-4dda-a7f5-4aa2104fa510
Rivera Diaz del Castillo, P. E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
van der Zwaag, S.
ad11f134-8a43-4635-9feb-7c3d01158f4b
Tjahjanto, D. D.
5245c9ae-bf27-49db-86a3-bb34bd16b6fb
Suiker, A. S.J.
a3678c57-c858-484d-b558-32a0419be9cf
Turteltaub, S.
b56fac3e-42f6-4dda-a7f5-4aa2104fa510
Rivera Diaz del Castillo, P. E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
van der Zwaag, S.
ad11f134-8a43-4635-9feb-7c3d01158f4b

Tjahjanto, D. D., Suiker, A. S.J., Turteltaub, S., Rivera Diaz del Castillo, P. E.J. and van der Zwaag, S. (2007) Micromechanical predictions of TRIP steel behavior as a function of microstructural parameters. Computational Materials Science, 41 (1), 107-116. (doi:10.1016/j.commatsci.2007.03.005).

Record type: Article

Abstract

Micromechanically-based models are used to mimic the martensitic phase transformations in retained austenite and the elasto-plastic behavior of the adjacent ferritic phase. The numerical simulations concern TRIP steel samples with a finite number of grains of retained austenite embedded in a polycrystalline ferrite-based matrix. Parametric analyses are performed in order to investigate the effect of the variation of microstructural properties on the stability of retained austenite, and thus on the overall mechanical response. The microstructural parameters considered are (i) the initial volume fraction of the retained austenite, (ii) the elasto-plastic properties of the surrounding ferritic matrix, (iii) the crystallographic orientations of the ferritic and austenitic grains, and (iv) the carbon concentration in the retained austenite. The results show that the effective strength of TRIP steels increases with the carbon concentration in the retained austenite, but it depends non-monotonically on the initial volume fraction of retained austenite. It is shown that the overall strength and the martensitic transformation rate depend strongly on the crystallographic orientations of the grains and the properties of the surrounding matrix. This information is useful for the optimization of the mechanical characteristics of TRIP steels and the improvement of their processing parameters. The numerical predictions are in good qualitative agreement with experimental observations.

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More information

Accepted/In Press date: 15 March 2007
Published date: November 2007
Keywords: Micromechanical modeling, Microstructural parameters, Retained austenite stability, TRIP steels

Identifiers

Local EPrints ID: 492560
URI: http://eprints.soton.ac.uk/id/eprint/492560
DOI: doi:10.1016/j.commatsci.2007.03.005
ISSN: 0927-0256
PURE UUID: 28d43cbb-cd7a-4b4f-9cc8-f6b0ab16f1eb
ORCID for P. E.J. Rivera Diaz del Castillo: ORCID iD orcid.org/0000-0002-0419-8347

Catalogue record

Date deposited: 05 Aug 2024 16:42
Last modified: 06 Aug 2024 02:04

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Contributors

Author: D. D. Tjahjanto
Author: A. S.J. Suiker
Author: S. Turteltaub
Author: P. E.J. Rivera Diaz del Castillo ORCID iD
Author: S. van der Zwaag

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