Effects of Hot Deformation on the Evolution of Microstructure in Pearlitic Steel Wire Rod

doi:10.1007/s40195-023-01617-5

Abstract

Abstract:

The influences of hot deformation parameters on pearlite grain nucleation and growth during austenite-pearlite phase transformation in a steel wire rod have been investigated through quantitative analysis of microstructure parameters such as austenite grain size, ferrite grain size, pearlite colony size, and lamellar spacing. During hot deformation, the austenite grain size decreases due to recrystallization, providing extra nucleation sites for pearlite phase transformation, which decreases the ferrite grain size and pearlite colony size. Moreover, the stored strain energy in undercooled austenite accelerates carbon diffusion during pearlite phase transformation, which facilitates ferrite grain growth and increases pearlite colony size. Consequently, the competing influence of recrystallization and strain energy provides flexibility in adjusting ferrite grain size and colony size by hot deformation. This study highlights the critical role of hot deformation in determining the microstructure of pearlitic steel.

Key words: Pearlite, Pearlitic phase transformation, Hot deformation, Microstructure, Stored strain energy

Zhendan Yang, Xiao Zhang, Chenhao Sang, Pei Wang, Dianzhong Li. Effects of Hot Deformation on the Evolution of Microstructure in Pearlitic Steel Wire Rod[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(12): 2058-2068.

Figures/Tables 14

Fig. 1 Schematics showing the hot deformation experiments with different parameters

Fig. 2 Stress-strain curves of samples deformed at different temperatures with different strain rates

Fig. 3 EBSD images of prior austenite grain boundary of samples at: a T = 800 ℃, without deformation, c T = 800 ℃, $\dot{\varepsilon }$ = 0.01 s−1, e T = 800 ℃, $\dot{\varepsilon }$ = 1 s−1; b T = 1000 ℃, without deformation, d T = 1000 ℃, $\dot{\varepsilon }$ = 0.01 s−1, f T = 1000 ℃, $\dot{\varepsilon }$ = 1 s−1

Fig. 4 Prior austenite grain size of samples with different hot deformation in the first series of experiments

Fig. 5 Prior austenite grain size in the hot deformed samples in the second series of experiments

Fig. 6 Grain boundary observed by EBSD and SEM morphology corresponding to grain boundary image of samples at 800 ℃ with different strain rates a, b without deformation, c, d 0.01 s−1, e, f 1 s−1, a, c, e EBSD images, b, d, f SEM images

Fig. 7 Grain boundary observed by EBSD and SEM morphology corresponding to grain boundary image of samples at 1000 ℃ with different strain rates a, b without deformation, c, d 0.01 s−1, e, f 1 s−1, a, c, e EBSD images, b, d, f SEM images

Fig. 8 Statistical data of ferrite grain size a and pearlite colony size b in the samples in first series of experiments

Fig. 9 Statistical data of ferrite grain size a and pearlite colony size b in the samples in second series of experiments

Fig. 10 Lamellar spacing of pearlite in the samples in first series of experiments

Fig. 11 Microhardness of the samples in first series of experiments

Fig. 12 Lamellar spacing of pearlite in the samples in second series of experiments

Fig. 13 Ratio of ferrite grain size to pearlite colony size in different samples

Fig. 14 Relationship between ferrite grains and pearlite colonies of a, d P1, b, e P2, c, f P3 samples

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