Secondary Precipitation Behavior of Nitride in the Electro-slag Remelted Structure of Alloy 690

doi:10.1007/s40195-017-0541-3

Abstract

Abstract:

The precipitation and evolution of secondary nitrides (S-nitrides) in the Alloy 690 electro-slag remelted (ESR) structure were investigated. Experimental results indicate that S-nitrides precipitated in the interdendritic region of the ESR structure at temperatures higher than 1100 °C. S-nitrides could spread throughout the entire interdendritic area after sufficient exposure, and they were more numerous and much finer than primary nitrides. Furthermore, after studying the evolution of S-nitride particles at 1100, 1200 and 1300 °C, it was determined that the precipitation of S-nitrides was controlled by the diffusion of nitrogen. In addition, by investigating the elemental segregation of ESR structure and calculating critical Ti concentrations, S-nitride precipitation was found to be thermodynamically inevitable in the Alloy 690 ESR structure.

Key words: Alloy, 690, ESR, Nitride, Precipitation

Min Wang, Bo Chen, Xian-Chao Hao, Ying-Che Ma, Kui Liu. Secondary Precipitation Behavior of Nitride in the Electro-slag Remelted Structure of Alloy 690[J]. Acta Metallurgica Sinica (English Letters), 2017, 30(8): 771-780.

Figures/Tables 13

Fig. 1 ESR macrostructure of the Plate III, which was the No. 3 slice cut from the ingot’s longitudinal central section and was sampled at the center, the mid-radius and the edge

Fig. 2 SEM observations on S-nitrides (a) at the ingot’s mid-radius before exposure, and (b) at the center, (c) the mid-radius, (d) the edge after being exposed at 1200 °C for 60 min, respectively

Fig. 3 Dark-field OM observations on S-nitrides in the specimens thermally exposed at 1100 °C for (a, b) 30 min, and (c) 240 min. b is an enlarged image of the area framed in a

Fig. 4 TEM characterizations of S-nitrides: a the morphology, b selected area diffraction pattern and c EDS

Fig. 5 SEM observations on S-nitrides in the mid-radius specimens thermally exposed at a-d 1100 °C, e-h 1200 °C, i-l 1300 °C for 30, 60, 120 and 240 min, respectively

Fig. 6 Statistical analysis on the a average particle radius, b average particle quantity of S-nitrides

Fig. 7 SEM observations on S-nitrides in the specimens thermally exposed for 60 min at a 1200 °C, b 1350 °C, respectively

Fig. 8 Qualitative elemental mapping images of Ti, N, Cr and Ni at the center, the mid-radius and the edge of the ingot

Fig. 9 Concentration profiles of a Cr, b Ti, c Ni obtained across dendritic arms at the center, the mid-radius and the edge of the ingot

Table 1 Interdendritic concentrations (\(C^{i}_{{\text{inter}}}\), wt%), intradendritic concentrations (\(C^{i}_{{\text{intra}}}\), wt%) and the segregation indexes (\(\xi_{i} = C^{i}_{{\text{intra}}} /C^{i}_{{\text{inter}}}\)) of Cr, Ti and Ni at the center, the mid-radius and the edge of the ingot

Element	Cr			Ti			Ni
Position	Cent.	M-R	Edge	Cent.	M-R	Edge	Cent.	M-R	Edge
C-inter	31.99	31.21	30.77	0.36	0.24	0.17	57.86	58.75	59.12
C-intra	30.10	29.69	30.25	0.14	0.13	0.10	59.40	59.81	59.31
\(\xi_{i}\)	0.94	0.95	0.98	0.40	0.56	0.56	1.03	1.02	1.00

Fig. 10 Quantitative analysis on the growth of S-nitrides including the a linear relationships between \(\bar{r}^{3}\) and t at various exposing temperatures, b the temperature dependence of ln k

Fig. 11 Schematic illustration of the growing mechanism of S-nitride particles. a S-nitride particles have formed between dendritic arms; b nitrogen diffuses to the interdendritic region for sustaining the growth of S-nitride particles. The brightness of red color and intensity of greenish color represent the concentration of titanium and nitrogen, respectively

Table 2 Critical Ti concentrations for S-nitride precipitation in the ESR ingot

\(\left[ {\text{Ti}} \right]\)(wt%)	\(\left[ {\text{N}} \right]\)(wt%)	A	B	T (K)	References
0.0122	0.005	4.940	14,400	1573	Wada et al. [24]
0.0044		5.190	15,490		Kunze et al. [27]
0.0015		4.350	14,890		Inoue et al. [25]
0.0004		3.820	15,020		Irvine et al. [26]

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