Quantitative Characterization of Heat Treatment Response in a Single Crystal Nickel-Based Superalloy

Zhen Wei Wei; Chang Kui Liu; Yao Li; Bing Qing Chen

doi:10.4028/www.scientific.net/KEM.871.32

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 871Quantitative Characterization of Heat Treatment...

Quantitative Characterization of Heat Treatment Response in a Single Crystal Nickel-Based Superalloy

Abstract:

To study quantitatively the effect of heat treatment on the microstructure, composition and mechanical property in a new single crystal nickel-based superalloy for industrial gas turbine (IGT) applications, the eutectic fraction, carbide fraction, and the fraction, size, shape and distribution of the γ ́ phase was characterized by quantitative metallographic method, the evolution of chemical composition and hardness between core and inter dendrite was tested through EMPA and nanoindentation. The experimental results indicate that: The eutectic fraction decreases from (0.52±0.08) % to (0.03±0.01) %. The carbides fraction decreases from (0.23±0.04) % to (0.12±0.03) %, and Feret ratio decreases from 3.21±2.54 to 2.14±0.98. The γ ́ fraction increases from (55.66±4.18) % to (73.78±3.24) % in core dendritic region, from (64.82±1.44) % to (70.11±3.10) % in inter dendritic region. The γ ́-size is 406±111(nm) in core dendritic region and 918±384(nm) in inter dendritic region before heat treatment, 359±69(nm) in core dendritic region and 361±57(nm) in inter dendritic region after heat treatment. The γ ́-cuboidal degree is 1.08±0.20 in core dendritic region and 1.14±0.23 in inter dendritic region before heat treatment, 1.08±0.19 in core dendritic region and 1.02±0.14 in inter dendritic region after heat treatment. The solidification segregation coefficient of main segregation elements, such as Re, W, Hf, Ta, Al, and Mo, is closer to 1, with an average decrease of 27% after heat treatment. The hardness and modulus increase in core and inter dendritic, and their inhomogeneity is reduced between cores and inter dendritic. The improvement of properties result from the improvement of size uniformity and cuboidal degree of γ ́, and the reduction of carbides and eutectic through element homogeneity during heat treatment. The solidification segregation coefficient of main segregation elements, such as Re, W, Hf, Ta, Al, and Mo, is closer to 1, with an average decrease of 27% after heat treatment. With the addition of refractory elements, some elements partition to the dendrite core, while other elements tend to accumulate in the interdendritic liquid and then solidify as the interdendritic and eutectic regions during solidification. The hardness and modulus increase in core and inter dendritic, and their inhomogeneity is reduced between cores and inter dendritic. The improvement of properties result from the improvement of size uniformity and cuboidal degree of γ ́, and the reduction of carbides and eutectic through element homogeneity during heat treatment.

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Periodical:

Key Engineering Materials (Volume 871)

Pages:

32-39

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.871.32

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Online since:

January 2021

Authors:

Zhen Wei Wei*, Chang Kui Liu, Yao Li, Bing Qing Chen

Keywords:

Heat Treatment, Microstructure, Nanoindentation, Quantitative Characterization, Single Crystal Nickel-Base Superalloy

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References

[1] M. Zietara, S. Neumeier, M. Göken, et al. Characterization of γ and γ' Phases in 2nd and 4th Generation Single Crystal Nickel-Base Superalloys, Met. Mater. Int.23 (2017) 126-131.