Effect of Grain Size on the Precipitation Behaviour in Super-Ferritic Stainless Steels During a Long-Term Ageing

doi:10.1007/s40195-021-01227-z

Abstract

Abstract:

A 27.6Cr-3.6Mo-2Ni alloy was solution treated and then aged for a long time to study the effect of grain size on precipitation behaviour by using X-ray diffraction, scanning electron microscopy and transmission electron microscopy. The experimental results demonstrated that the average grain size increased from 46.3 ± 6.2 to 101.8 ± 13.5 μm and the grain boundary length per unit area decreased from 3.3 × 10⁴ to 1.7 × 10⁴ m/m² with an increasing annealing temperature from 1100 to 1200 °C. After ageing at 800 °C, the σ-phase, χ-phase and Laves phase were observed. As the ageing time increased, the σ-phase notably increased, while the χ-phase and Laves phase gradually decreased before finally vanishing after ageing for 400 h. The σ-phase precipitation kinetics curves consisted of two parts, and the grain size had a significant effect on the first stage of the precipitation curves due to the abundance of nucleation sites in the specimens with finer grains. The Laves phase was transformed from Nb(C,N) particles by Nb diffusion. As the ageing time increased, the ferrite phase decreased due to the transformation of the ferrite phase to the σ-phase, and then C was expelled into the untransformed ferrite grains. Moreover, new Nb(C,N) particles were formed by Nb diffusion from the Laves phase, resulting in the absence of the Laves phase.

Key words: Ferritic stainless steel, Grain size, Ageing treatment, σ-phase precipitation kinetics, Laves phase transformation

Hui-Hu Lu, Xing-Quan Shen, Wei Liang. Effect of Grain Size on the Precipitation Behaviour in Super-Ferritic Stainless Steels During a Long-Term Ageing[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(9): 1285-1295.

Figures/Tables 9

Fig. 1 a-c IPF (inverse pole figure) and d-f grain size distribution images showing the microstructure evolution during the solution treating for 15 min at a, d 1100 °C, b, e 1150 °C, c, f 1200 °C

Fig. 2 a-c BSE images and d-f EDS spectra showing the representative second phase particles in specimens after annealing for 15 min at a 1100 °C, b 1150 °C, (c) 1200 °C: d EDS spectrum of matrix, e EDS spectrum of TiN, f EDS spectrum of Nb (CN)

Fig. 3 a XRD, b EBSD, and c, d TEM results identifying the representative precipitation phases in the aged specimens: a detected on the specimens after solution treating at 1100 °C and ageing for 32 h at 800 °C, b observed on the specimens after solution treating at 1200 °C and ageing for 16 h at 800 °C, c, d observed on the specimens after solution treating at 1100 °C and ageing for 0.5 h at 800 °C

Fig. 4 a BSE image and b-d EDS spectra showing the representative precipitation phases in specimens after annealing for 15 min at 1150 °C and ageing for 16 h at 800 °C: b EDS spectrum of χ-phase, c EDS spectrum of Laves phase, d EDS spectrum of σ-phase

Fig. 5 BSE images showing the typical precipitation after solution treating at 1200 °C and ageing at 800 °C for: a 0.5 h, b 1 h, c 4 h, d, 8 h, e 300 h, f 400 h

Fig. 6 Schematic diagram illustrating the precipitation evolution during ageing at 800 °C

Fig. 7 Volume fraction of σ-phase in the ST specimens after 800 °C ageing treating

Fig. 8 a, c and e Linearized σ-phase volume fraction as a function of time assuming JMA kinetic model for σ-phase formation in tested steel and b, d and f the JMA curves at different solution treating temperatures: a and b for 1100 °C solution treating, c and d for 1150 °C solution treating, e and f for 1120 °C solution treating condition

Fig. 9 Laves phase morphology in the specimens after solution treating at 1100 °C and ageing for 1 h at 800 °C

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