Evolution of γ′ Particles in Ni-Based Superalloy Weld Joint and Its Effect on Impact Toughness During Long-Term Thermal Exposure

doi:10.1007/s40195-019-00959-3

Abstract

Abstract:

Effects of long-term thermal exposure on γ′ particles evolution and impact toughness in the weld joint of Nimonic 263 (N263) superalloy were deeply studied at 750 °C. Results showed that the precipitates in the weld metal were mainly composed of fine γ′ particles, bulky MC carbides, and small M₂₃C₆ carbides. With the thermal exposure time increasing from 0 to 3000 h, γ′ particles in the weld metal grew up from 19.7 nm to 90.1 nm at an extremely slow rate. After being exposed for 1000 h, γ′ particles coarsened and some of them transformed into acicular η phase. At the same time, MC carbides decomposed to form η phase and γ′ particles. This dynamic transition ensured the slight reduction in impact toughness of the weld metal after the thermal exposure, which indicated the stable serving performance of N263 weld joint.

Key words: Ni-based superalloy, Weld joint, Long-term thermal exposure, γ′, Phase evolution;, Impact toughness

Xian-Kai Fan, Fu-Quan Li, Lei Liu, Hai-Chao Cui, Feng-Gui Lu, Xin-Hua Tang. Evolution of γ′ Particles in Ni-Based Superalloy Weld Joint and Its Effect on Impact Toughness During Long-Term Thermal Exposure[J]. Acta Metallurgica Sinica (English Letters), 2020, 33(4): 561-572.

Figures/Tables 15

Table 1 Main chemical compositions of N263 base metal and filler material for welding (wt%)

Table 2 TIG welding parameters

Fig. 1 Cross-sectional OM micrographs of N263 TIG weld joint: macro appearance of weld joint a; microstructure of b base metal, c HAZ, d weld metal

Fig. 2 Microstructure characterizations of N263 base metal: a SEM image; b TEM image and SAD pattern of M23C6 carbides at the grain boundary; cγ′ particles in γ matrix; d EDS results of M23C6 carbide in b

Fig. 3 EDS analysis results of MC carbides in the base metal. MC can be expressed as (Ti, Mo)C

Fig. 4 Microstructure characterizations of the weld metal: a dendritic columnar grains; b SEM image of precipitated particles; c MC and M23C6 carbides; d EDS results of MC carbide in c; e TEM image of precipitated particles; f coherent γ′ particles showing strain contrast and lines of no contrast

Fig. 5 Morphologies of γ′ particles in the weld metal during thermal exposure at 750 °C for a 0 h, b 1000 h, c 2000 h, d 3000 h

Fig. 6 Curves of γ′ particle size d3, d2, and d versus thermal exposure time t under different models: a LSW model; b TIDC model; c non-integer temporal exponent model

Fig. 7 Microstructure evolution after 1000 h thermal exposure at 750 °C: a SEM graphs of interdendritic precipitates in the weld metal; bη laths and lined γ′ particles are found around the decomposed MC carbide; c no η laths appear away from MC carbide

Fig. 8 MC carbides decompose after being exposed for 3000 h and transform to γ′ particles and η laths. a SE and b BSE images showing the small γ′ particles on the MC carbide. c-f EDS elemental maps of C, Ti, Mo, and Cr

Fig. 9 Schematic illustration of MC carbides decomposition: MC + γ → M23C6 + γ′ + η

Fig. 10 Equilibrium phase diagrams of N263 through thermodynamic calculation. γ′ phase is metastable and η phase may precipitate during long-term thermal exposure

Fig. 11 Characterizations of η phase in the weld metal after being exposed for 3000 h: a chemical etching grooves of η phase at the grain boundary and emerged γ′ free zones; bη phase around a decomposed MC carbide; c TEM image and SAD pattern of η phase

Fig. 12 Impact toughness results of base metal and weld metal after thermal exposure at 750 °C: a impact toughness values; b, c weld metal fracture without thermal exposure, d, e weld metal fracture after thermal exposure for 3000 h

Fig. 13 Microstructures of fractured impact specimen in the weld metal after thermal exposure for 3000 h: a the whole fracture; b intergranular rupture; c precipitates at the grain boundary hinder and deflect the crack propagation

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