High-temperature Tensile Behavior in Coarse-grained and Fine-grained Nb-containing 25Cr-20Ni Austenitic Stainless Steel

doi:10.1007/s40195-020-01076-2

Abstract

Abstract:

In this study, tensile behavior of Nb-containing 25Cr-20Ni austenitic stainless steels composed of coarse or fine grains has been investigated at temperatures ranging from room temperature to 900 °C. Results show that the tensile strength of fine-grained specimens decreases faster than that of coarse-grained specimens, as the test temperature increases from 600 °C to 800 °C. The rapidly decreasing tensile strength is attributed to the enhanced dynamic recovery and recrystallization, because additional slip systems are activated, and cross-slipping is accelerated during deformation in fine-grained specimens. After tensile testing at 700-900 °C, sigma phases are formed concurrently with dynamic recrystallization in fine-grained specimens. The precipitation of sigma phases is induced by simultaneous recrystallization as the diffusion of alloying elements is accelerated during the recrystallization process. Additionally, the minimum ductility is observed in coarse-grained specimens at 800 °C, which is caused by the formation of M₂₃C₆ precipitates at the grain boundaries.

Key words: Austenitic stainless steels, High-temperature tensile properties, Grain size, Precipitates

Guodong Hu, Pei Wang, Dianzhong Li, Yiyi Li. High-temperature Tensile Behavior in Coarse-grained and Fine-grained Nb-containing 25Cr-20Ni Austenitic Stainless Steel[J]. Acta Metallurgica Sinica (English Letters), 2020, 33(11): 1455-1465.

Figures/Tables 12

Table 1 Chemical compositions of the experimental steel (wt.%)

C	Si	Mn	Cr	Ni	Nb	N	Fe
0.060	0.83	1.64	23.95	19.54	0.32	0.078	Bal.

Fig. 1 Initial microstructure of fine-grained specimen in a OM, b SEM, c TEM micrograph; coarse-grained specimen in d OM, e SEM, f TEM micrograph. The inset in c shows the EDS mapping of Nb-rich precipitates

Fig. 2 Temperature dependence of the engineering stress-strain curves for the tested specimens

Fig. 3 a UTS and YS, b elongation and Z reduction of the investigated specimens at different test temperatures

Fig. 4 Microstructure of the FG-specimens after tensile test at a RT, b 400 °C, c 600 °C, d 700 °C, e 800 °C, f 900 °C; TA indicates tensile axis. The insets in d, e show the microstructure at higher magnification

Fig. 5 Microstructure of the CG-specimens after tensile test at a RT, b 400 °C, c 600 °C, d 700 °C, e 800 °C, f 900 °C; TA indicates tensile axis

Fig. 6 TEM micrographs of FG-specimens after tensile test at a RT, b 400 °C, c 600 °C, d 700 °C, e 900 °C

Fig. 7 TEM micrographs of CG-specimens after tensile test at a RT, b 400 °C, c 600 °C, d 700 °C, e 900 °C

Fig. 8 SEM microstructures of FG-specimens after tensile test at a 700 °C, b 800 °C, c 900 °C; microstructures of CG-specimens after tensile test at d 700 °C, e 800 °C, f 900 °C. The insets in d, e, f show the precipitates at higher magnification

Fig. 9 a SEM-EDS concentration profile across the sigma precipitate in FG-specimen after test at 800 °C, b EDS results of the precipitates in FG-specimen after test at 900 °C, c STEM-HAADF image and corresponding map results of precipitates in CG-specimen after test at 900 °C

Table 2 Chemical composition of austenite matrix calculated by Thermo-Calc (wt.%)

	C	Si	Mn	Cr	Ni	Nb	N	Fe	Cr_eq/Ni_eq
FG	0.044	0.83	1.64	24.0	19.6	0.034	0.042	Bal.	1.09
CG	0.048	0.83	1.64	24.0	19.6	0.14	0.065	Bal.	1.05

Fig. 10 Fracture morphology of FG-specimens after tensile test at a 600 °C, b 700 °C, c 800 °C, d 900 °C; CG-specimens after tensile test at e 600 °C, f 700 °C, g 800 °C, h 900 °C. The insets in g, h show the corresponding figures of cracks in longitudinal section

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