Effect of Central Multiphase Microstructure of Thick Plates on Work Hardening and Crack Propagation

doi:10.1007/s40195-023-01632-6

Abstract

Abstract:

The effect of multiphase microstructure in the center segregation zones (CSZ) of high-strength steel thick plates on work hardening characteristics and crack initiation/propagation were studied. Microstructure was correlated with deformation damage behavior by using Taylor factor (TF) gradients, kernel average misorientation (KAM), and geometric necessary dislocation (GND) density. The results show that the segregation leads to a mixed structure of ferrite (soft phase) and martensite/bainite (hard phase) in the center of the thick plate. Compared to the 1/4 thickness (1/4 T) region, grain refinement occurred in the CSZ, with KAM values increasing from 0.24 to 0.49 and a decrease in the proportion of high-angle grain boundaries (> 15°) from 77.4 to 51.8%. In the process of deformation, due to the influence of grain refinement and adjacent martensite/bainite, ferrite grains were divided into structural units with different TF values. The higher KAM value and GND density at the interface between soft/hard phases resulted in severe work hardening. In addition, the presence of micron-sized inclusions in the CSZ caused local strain concentration and non-continuous deformation of the matrix, which induced crack initiation. The fracture surface showed a mixed mode of brittle cleavage fracture and ductile fracture.

Key words: Thick plate, Center segregation zone, Multiphase microstructure, Taylor factor, Crack propagation

Lei Hu, Liqin Zhang, Feng Hu, Kuan Zheng, Guohong Zhang. Effect of Central Multiphase Microstructure of Thick Plates on Work Hardening and Crack Propagation[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(2): 325-338.

Figures/Tables 18

Table 1 Chemical composition of test steel (wt%)

C	Mn	Si	S	P	Nb	Ti + V	Fe
0.161	1.5	0.37	0.005	0.009	0.05	< 0.05	Bal.

Fig. 1 Schematic diagram of thick plate position division and sampling

Table 2 Mechanical properties of the test steel

Position	R_0.2 (MPa)	R_m (MPa)	R_0.2/R_m	Total elongation (%)	Uniform elongation (%)
1/4 T	421 ± 14	560 ± 11	0.75 ± 0.01	33.1 ± 0.2	12.9 ± 0.2
Center	425 ± 12	586 ± 10	0.72 ± 0.01	25.3 ± 0.1	8.6 ± 0.1

Fig. 2 OM and SEM micrographs of the near fracture surfaces of the 1/4 T and center tensile samples of the test steel: a, c 1/4 T; b, d CSZ; e energy spectrum map of inclusion in d

Fig. 3 EBSD micrographs of 1/4 T and center samples of test steel. a, d IPF maps; b, e misorientation distribution maps; c, f KAM distribution maps; g statistical figure of large and small-angle grain boundary distribution; h KAM value distribution statistical maps. a, b, c 1/4 T; d, e, f CSZ

Table 3 Statistics of test steel EBSD characterization results

Position	Misorientation 2°-15° (%)	Misorientation > 15° (%)	Grain size (µm)	KAM value (°)
1/4 T	22.6	77.4	10.73	0.24
Center	48.2	51.8	9.22	0.49

Fig. 4 EBSD band slope analysis results of CSZ in test steel: a band slope map; b bcc phase map that conforms to band slope data; c multiphase structure distribution map

Fig. 5 Element distribution maps in the CSZ

Fig. 6 a, b TEM micrographs of the precipitated particles, c HRTEM images of the white circle in b, and SAED pattern

Fig. 7 SEM micrographs of the tensile fracture of the test steel; a, c 1/4 T; b, d center; e energy spectrum map of inclusions in d

Fig. 8 EBSD maps of the fracture longitudinal section voids of the center sample: a IPF map; b misorientation distribution map; c KAM distribution map

Fig. 9 a-e SEM micrographs of cracks in the CSZ; f energy spectrum map of inclusions

Fig. 10 EBSD maps of fracture section crack in CSZ: a IPF map; b phase map; c KAM map

Fig. 11 a Hollomon model, b modified C-J analysis

Table 4 Slopes and transition strain points for each stage in the model position

Position	Hollomon analysis		Modified C-J analysis
	Slope (n)		Slope (1-n_s)			Transition strain (ε_t)
		I	II	I	II	III	I-II	II-III
1/4 T	0.32	0.14	−3.69	−7.89		0.098
Center	0.33	0.12	−3.05	−6.81	−13.54	0.080	0.102

Fig. 12 a Taylor factor map, b GND distribution map

Fig. 13 a Distribution map of sub-grain boundaries; b Taylor factor map; c changes in misorientation along line 1 in b; d changes in misorientation along line 2 in b

Fig.14 Crack propagation path and microstructure distribution in CSZ

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