A Multi-phase Field Model for Static Recrystallization of Hot Deformed Austenite in a C-Mn Steel

doi:10.1007/s40195-017-0595-2

Abstract

Abstract:

A multi-phase-field model has been developed to simulate the microstructure evolution and kinetics of the austenite static recrystallization (SRX) in a C-Mn steel. In this model, the bulk free energy that coupling the deformation stored energy with a special interpolation function is incorporated. Both the deformed grain topology and the deformation stored energy have been included in order to investigate the influence of pre-deformation on the subsequent austenite SRX at different hot deformation levels. Diverse scenarios of microstructure evolution show different deformation-dependent recrystallized grain sizes. The transformation kinetics is then discussed by analyzing the overall SRX fraction and the average interface velocity on the recrystallization front.

Key words: Phase-field, Static recrystallization, Microstructure evolution, Hot deformation, Mesoscopic modeling

Jun Zhang, Cheng-Wu Zheng, Dian-Zhong Li. A Multi-phase Field Model for Static Recrystallization of Hot Deformed Austenite in a C-Mn Steel[J]. Acta Metallurgica Sinica (English Letters), 2018, 31(2): 208-215.

Figures/Tables 13

Fig. 1 Profiles of η and the free energy (f s , f s + f e ) across the unrecrystallized (UnRex, η 1) and recrystallized (Rex, η 2) grains

Table 1 Values of the fitting parameters for σ prediction

n ₁	n ₂	A	B	Q _def (kJ mol^-1)
0.45	0.1	48	30	22

Fig. 2 Flow stresses as functions of strain during hot rolling at T = 900 °C and \(\dot{\varepsilon }\) = 1.0 s-1 for C-Mn steels. The model prediction compares with experimental measurements

Table 2 Key parameters used in simulations [16]

G (GPa)	b (m)	Q _m (kJ mol^-1)	σ _gb (J m^-2)	D ₀ (m² s^-1)	Q _a (kJ mol^-1)
80	2.48 × 10^-10	140	0.56	1.1 × 10^-13	170

Fig. 3 Initial undeformed microstructure

Fig. 4 Increase in grain boundary area with increasing strain ?. S 0 is the original grain boundary area and S d is the grain boundary area after deformation

Fig. 5 Simulated microstructural evolution during the austenite SRX after hot deformation under different pre-strains of a ε = 0.2, b ε = 0.3, c ε = 0.4, d ε = 0.5

Fig. 6 Variations of the SRX grains number with time under different pre-strains

Fig. 7 Average SRX grain size d aver as a function of time under different pre-strains

Fig. 8 Average grain size ln(d rex) with the respect to ln ?

Fig. 9 Simulated SRX kinetics under different pre-strains and a comparison with the predictions by the JMAK model

Fig. 10 Relation between ln t 0.5 and ln ?

Fig. 11 Average interface velocity 〈v〉 as a function of time

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