Recrystallization Mechanisms in Hot Working Processes of a Nickel-Based Alloy for Ultra-Supercritical Power Plant Application

doi:10.11900/0412.1961.2017.00022

Acta Metall Sin

2017, Vol. 53

Issue (12): 1611-1619 DOI: 10.11900/0412.1961.2017.00022

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Recrystallization Mechanisms in Hot Working Processes of a Nickel-Based Alloy for Ultra-Supercritical Power Plant Application

Kang WEI, Maicang ZHANG(

), Xishan XIE

School of Materials Science and Engineering, University of Science and Technology Beijing, Beijing 100083, China

Cite this article:

Kang WEI, Maicang ZHANG, Xishan XIE. Recrystallization Mechanisms in Hot Working Processes of a Nickel-Based Alloy for Ultra-Supercritical Power Plant Application. Acta Metall Sin, 2017, 53(12): 1611-1619.

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Abstract

Nickel-based alloy is a good choice for materials used in ultra-supercritical power plant, which is subjected to high temperature about 700 ℃ and high pressure in service. In order to meet the requirements above, a nickel-based alloy was designed and the tubes were successfully manufactured. Based on the hot/cold working processes of tube components of the nickel-based alloy, microstructural evolution, especially the recrystallization mechanisms during hot working processes of the alloy were systematically investigated by using a series of hot compression tests, solution annealing tests, OM and TEM analyses. The results showed that dynamic recrystallization was dominated by discontinuous dynamic recrystallization mechanism involving grain boundary bulging, whereas the nucleation mechanism with strain inducing grain boundary migration was the driving force of static recrystallization. In addition, the essence of different forms of step grain boundary producing during dynamic recrystallization and static recrystallization was to make the surface deviate from low index surface, which could ensure more interface to be low energy close-packed surface, so that the energy of grain boundary interface would be reduced. The morphology of step grain boundary depended on the crystallographic relationship of crystal interface and the Burgers vector of grain boundary dislocation. Moreover, the presence of step grain boundary could also promote grain boundary migration and accelerate the recrystallization process. When the recrystallization process was completed, step grain boundaries still remained partially to minimize interfacial energy and continue to promote subsequent grain growth processes.

Key words: nickel-based alloy recrystallization step grain boundary

Received: 16 January 2017

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	Kang WEI
	Maicang ZHANG
	Xishan XIE

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https://www.ams.org.cn/EN/10.11900/0412.1961.2017.00022 OR https://www.ams.org.cn/EN/Y2017/V53/I12/1611

Fig.1 Schematic of hot simulation processes

Fig.2 Microstructure of longitudinal section from the as-forge bar

Fig.3 Microstructures of the alloy under different hot deformation parameters

(a) 1050 ℃, 0.01 s^-1 (b) 1050 ℃, 1 s^-1 (c) 1050 ℃, 10 s^-1

(d) 1150 ℃, 0.01 s^-1 (e) 1150 ℃, 1 s^-1 (f) 1150 ℃, 10 s^-1

Fig.4 TEM images of the alloy under different hot deformation conditions

(a) 1050 ℃, 0.01 s^-1 (b) 1150 ℃, 0.01 s^-1 (c) 1050 ℃, 20 s^-1 (d) 1150 ℃, 20 s^-1

Fig.5 Microstructure in longitudinal direction of the as-cold-rolled tube

Fig.6 Microstructures of the alloy after various heat-treated conditions

(a) 1100 ℃, 5 min (b) 1100 ℃, 10 min (c) 1100 ℃, 40 min(d) 1150 ℃, 5 min (e) 1150 ℃, 10 min (f) 1150 ℃, 40 min

(g) 1180 ℃, 5 min (h) 1180 ℃, 10 min (i) 1180 ℃, 40 min

Fig.7 Dislocation structures of the alloy under different solution annealing conditions

(a) cold-rolled state (b) 1100 ℃, 20 min (c) 1140 ℃, 20 min

(d) 1180 ℃, 20 min (e) 1140 ℃, 5 min (f) 1140 ℃, 60 min

Fig.8 Step grain boundaries of the alloy in different hot deformation processes

(a) 1050 ℃, 1 s^-1 (b) 1150 ℃, 20 s^-1

Fig.9 Step grain boundaries of the alloy after various heat-treated conditions

(a) 1140 ℃, 20 min (b) 1140 ℃, 60 min (c) 1100 ℃, 20 min (d) 1180 ℃, 20 min

Fig.10 Schematic of the platform-step-kink model on free surface

Fig.11 Schematic of the grain boundary dislocation in fcc materials (b—Burgers vector)

Fig.12 Step grain boundary of the alloy after solution treatment and ageing processes

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