Formation mechanism of large grains inside annealed microstructure of GH4169 superalloy by cellular automation method

doi:10.1016/j.jmst.2018.11.026

Abstract

Abstract:

In authors’ previous work [Mater. Charact. 141 (2018) 212-222], it was found that the heterogeneous deformed microstructures can be replaced by the relatively homogeneous recrystallized grains through an annealing treatment. However, there are still some relatively large recrystallized grains. To find the reasons for the formation of large grains, some new annealing treatment tests were done, and the cellular automation (CA) simulations were carried out in the present work. The experimental results showed that the microstructural evolution during annealing treatment is significantly affected by the content of δ phase. So, the effects of δ phase on the nucleation and growth of grains are carefully considered in the CA model to accurately simulate the microstructural evolution behavior. By the CA simulation, it is found that the dislocation density rapidly decreases due to the nucleation of static recrystallization (SRX) and the growth of dynamc recrystallization (DRX) nuclei at the early stage of annealing. The high initial dislocation density can provide the high velocity for the growth of DRX nuclei, which is responsible for the formation of coarse grains. However, the growth rate of SRX nuclei is relatively small due to the low dislocation density and pinning effects of δ phase.

Key words: GH4169 superalloy, Cellular automation model, Coarse grains, Annealing treatment, Recrystallization behavior

Ming-Song Chen, Zong-Huai Zou, Y.C. Lin, Hong-Bin Li, Guan-Qiang Wang. Formation mechanism of large grains inside annealed microstructure of GH4169 superalloy by cellular automation method[J]. J. Mater. Sci. Technol., 2019, 35(7): 1403-1411.

Figures/Tables 11

Fig. 1. Experimental procedure for the test.

Fig. 2. The microstructures of the studied superalloy: (a) deformed one; (b, c, d) annealed one.

Fig. 3. Grain size distribution for annealed microstructure shown in Fig. 2(d).

Table 1 The values of α and n at different temperatures.

Temperature (°C)	n	α
950	0.24	0.32
980	-0.69	1.5
1010	-1.02	1.33

Table 2 The mobility of high-angle boundaries of GH4169 superalloy.

Temperature (K)	M₀ (m⁴ J^-1 s^-1)
1253	4.05 × 10^-13
1283	8.00 × 10^-13
1313	1.42 × 10^-12

Fig. 4. Comparisons between the experimental and simulated average grain sizes.

Fig. 5. Experimental and simulated microstructures at different condition; (a-c, g-i) simulated results; (d-f, j-l) experimental results, Aging conditions: (h, k) aged for 0 h; (i, l) aged for 12 h, the others aged for 24 h; Annealing condition: (a, d) T = 950 °C, t = 10 min; (b, e, h, i, l, l) T = 980 °C, t = 10 min; (c, f) T = 980 °C, t = 30 min; (g, j) T = 1010 °C, t = 10 min.

Fig. 6. Evolution of average dislocation in annealing process at the annealing temperature of 980 °C.

Fig. 7. Simulated microstructures annealed at 980 °C for 385 s.

Fig. 8. CA simulation microstructures annealed at 980 °C with different time: (a) t = 50 s; (b) t = 200 s; (c) t = 300 s; (d) t = 600 s; (e) t = 900 s; (f) t = 1800 s.

Fig. 9. Dislocation density distribution at different annealing times: (a) t = 50 s; (b) t = 200 s; (c) t = 300 s; (d) t = 600 s; (e) t = 900 s; (f) t = 1800 s.

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