Paper Titles
Phase-Field Modeling of Recrystallization - Effects of Second-Phase Particles on the Recrystallization Kinetics
p.1189
Phase-Field Modeling and Simulation of Nucleation and Growth of Recrystallized Grains
p.1195
Modeling Recrystallization for 3D Multi-Pass Forming Processes
p.1201
Stored Energy and Recrystallisation in Cold Rolled Steel
p.1207
Coupled Simulation of the Static Recrystallization in Hot Deformed Austenite on Mesoscale
p.1213
Monte Carlo Potts Model Simulation and Statistical Theory of 3D Grain Growth
p.1219
Diffusion Controlled Abnormal Grain Growth in Ceramics
p.1227
Effect of the Intercalation of the Carbon Layer on the Kinetics of Grain Growth of FePt Magnetic Thin Film during Ordering Reaction - A Monte Carlo Simulation Study
p.1237
Characteristic Microstructure Evolution of Polycrystalline Ag Films Prepared from Ink-Jetted Ag Nanoparticle Suspension
p.1243

Coupled Simulation of the Static Recrystallization in Hot Deformed Austenite on Mesoscale

Article Preview

Abstract:

The kinetics and microstructure evolution during static recrystallization (SRX) of hot-deformed austenite in a low carbon steel are simulated by coupling a cellular automaton (CA) model with a crystal plasticity finite element model (CPFEM). The initial deformed characteristics, which include the stored energy of deformation and the crystallographic orientation induced by a plane strain hot compression are simulated using a crystal plasticity finite element model. These data are mapped onto the CA regular lattices as the initial parameters for SRX simulation. The coupled simulation results reveal that the heterogeneous distribution of the stored energy of deformation results in non-uniform nucleation and a slower kinetics. The influence of non-uniform distribution in stored energy on the SRX kinetics and microstructure evolution is discussed based on a microstructural path (MP) analysis.

You might also be interested in these eBooks
Recrystallization and Grain Growth III View Preview

Info:

Periodical:

Materials Science Forum (Volumes 558-559)

Pages:

1213-1218

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.558-559.1213

Citation:

Cite this paper

Online since:

October 2007

Authors:

Cheng Wu Zheng, Na Min Xiao, Dian Zhong Li, Yi Yi Li

Keywords:

Cellular Automaton (CA), Crystal Plasticity Finite Element Method, Microstructural Path Methodology, Static Recrystallization

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2007 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

References

[1] D. Raabe: Computational Material Science (Wiley-VCH, Weinheim, 1998).

Google Scholar

[2] H.W. Hesselbarth and I. R. Göbel: Acta Metall Mater, Vol. 39 (1991), p.2135.

Google Scholar

[3] R. Dewri and N. Chakraborti: Model Simul Mater Sci Eng, Vol. 13 (2005), p.173.

Google Scholar

[4] P.R. Riso, J.J. SCarvalho, T.C. Salazar, F.V.L. Paula, and J.A. Castro: Mater Sci Forum, Vols. 467-470 (2004), p.659.

Google Scholar

[5] V. Marx, F.R. Reher and G. Gottstein: Acta Mater, Vol. 147 (1999), p.1219.

Google Scholar

[6] R.L. Goetz and V. Seetharaman: Metall Mater Trans A, Vol. 29A(1997), p.2307.

Google Scholar

[7] F.J. Humphreys and M. Hatherly. Recrystallization and Related Annealing Phenomena (Pergamon Press, Oxford, 1995).

Google Scholar

[8] G.B. Sarma, B. Radhakrishnan and T. Zacharia: Comput Mater Sci, Vol. 46 (1998), p.4415.

Google Scholar

[9] N.M. Xiao, Z.F. Yue, Y.J. Lan, M.M. Tong and D.Z. Li: Acta Metall Sin, Vol. 41 (2005), p.496.

Google Scholar

[10] A. Yoshie, T. Fujita, M. Fujioka, K. Okamoto and H. Mroikawa: ISIJ Int, Vol. 36 (1996), p.467.

Google Scholar

[11] C.W. Zheng, Y.J. Lan, N.M. Xiao, D.Z. Li and Y.Y. Li: Acta Metall Sin, Vol. 42 (2006), p.474.

Google Scholar

[12] R.A. Vandermeer: Acta Mater, Vol. 53 (2005), p.1449.

Google Scholar

[13] P. R. Rios et al: Mater Res, Vol. 9 (2003), p.165.

Google Scholar