Enhancement of Strength-Ductility Balance of the Laser Melting Deposited 12CrNi2 Alloy Steel Via Multi-step Quenching Treatment

doi:10.1007/s40195-021-01209-1

Abstract

Abstract:

A ferrite-austenite 12CrNi2 alloy steel additively manufactured by laser melting deposition (LMD) was heat treated by direct quenching (DQ) and tempering inter-critical quenching (TIQ) at 800 °C for enhancing its strength-ductility balance. Both heat-treated alloy steels have the martensite-ferrite dual-phase (DP) microstructures. The volume fractions of martensite in the two treated alloy steels are nearly similar (~ 85 vol%), while the sizes of the prior austenitic grain for martensite are different. The martensite-dominated DP microstructure resulted in an obvious improvement in strength-ductility balance of the alloy steel. Compared with the DQ treatment, the multi-step TIQ treatment caused the strength-ductility balance of the alloy steel to be enhanced due to its higher total elongation. The better ductility of the TIQ-treated alloy steel can be attributed to the optimization of the microstructure. The preferred orientation of ferritic grain in the as-deposited alloy steel which was adverse to plastic deformation through dislocation slip was eliminated via the multi-step TIQ treatment. Moreover, the TIQ treatment promoted the formation of finer-grained martensite with larger areas of grain boundaries and twinning boundaries which resulted in the enhancement of the coordinated deformability of the martensite with the ferrite.

Key words: Laser melting deposition, Alloy steel, Dual-phase microstructure, Mechanical property, Work-hardening rate

Wei Zhang, Zhi-Hong Dong, Hong-Wei Kang, Chen Yang, Yu-Jiang Xie, Mohamad Ebrahimnia, Xiao Peng. Enhancement of Strength-Ductility Balance of the Laser Melting Deposited 12CrNi2 Alloy Steel Via Multi-step Quenching Treatment[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(9): 1234-1244.

Figures/Tables 13

Table 1 Chemical compositions of commercial 12CiNi2 alloy steel powder (mass%)

C	Ni	Cr	O	Si	Mn	Fe
0.12	1.83	0.85	0.035	0.24	0.46	Bal

Fig. 1 Schematic diagram of the laser melting deposited process

Fig. 2 Detailed schematic diagram of the quenching treatments including DQ and TIQ. *WQ means water quenching, AC means air cooling

Fig. 3 Typical optical micrographs with the insert of scanning electron micrographs showing microstructural evolution of a as-deposited, b DQ-treated and c TIQ-treated specimens

Fig. 4 Combined band contrast and grain boundary outline maps of a DQ-treated and b TIQ-treated specimens

Fig. 5 TEM results of the precipitates inside laths of martensite in the heat-treated specimens: a bright field image of the DQ-treated specimen; b selected area electron diffraction (SAED) pattern corresponding to the circled region in a; c bright field image of the TIQ-treated specimen; d SAED pattern corresponding to the circled region in c

Fig. 6 TEM results of the twins inside laths of martensite in the heat-treated specimens: a bright field image of the DQ-treated specimen; b SAED pattern corresponding to the circle region shown in a; c bright field image of the TIQ-treated specimen; d SAED pattern corresponding to the circle region as shown in c

Table 2 Mechanical properties of the as-deposited and heat-treated specimens

Specimens	Yield strength (MPa)	Ultimate tensile strength (MPa)	Total elongation (%)	Strength-ductility balance (GPa∙%)
As-deposited	631.4	683.6	22.7	15.52
DQ-treated	939	1180.5	16.43	18.21
TIQ-treated	772	1109.6	20.14	22.35

Fig. 7 Engineering stress-strain curves of the as-deposited, DQ- and TIQ-treated specimens

Fig. 8 Inverse pole figures at the cross-sectional un-deformed areas of a as-deposited, b DQ- and c TIQ-treated tensile specimens, and corresponding Schmid factor maps of the d DQ- and e TIQ-treated tensile specimens

Fig. 9 Kernel average misorientation maps at the cross-sectional uniform-deformed area of a DQ- and b TIQ-treated tensile specimens, and c corresponding histogram of the kernel average misorientation of the DQ- and TIQ-treated specimens

Fig. 10 Microstructures at the cross-sectional necking areas just beneath the fracture surface of a DQ- and b TIQ-treated tensile specimens. (①: micro-voids at the martensite/ferrite interfaces; ②: micro-voids inside martensite)

Fig. 11 Work-hardening curves of the heat-treated specimens

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