Effects of sub-solvus ageing on the tensile and creep properties of a new cast nickel-based superalloy

doi:10.1016/j.jmst.2024.06.014

Abstract

Abstract: For nickel-based superalloys with medium volume-fraction γʹ phase (20 %-40 %), dual or multi-stage aging treatments are usually conducted to generate a microstructure containing the multimodal distribution of γʹ for a balance of strength and plasticity. In the present study, the microstructure and high-temperature properties of a novel cast nickel-based superalloy K4800 were investigated after being subjected to three heat treatments (HT) procedures, namely HT1: 1180 ℃/4 h+1090 ℃/2 h+800 ℃/16 h, HT2: 1180 ℃/4 h+1060 ℃/2 h+800 ℃/16 h and HT3: 1180 ℃/4 h+800 ℃/16 h. It was found that the sub-solvus aging treatments at 1090 and 1060 ℃ precipitated sub-micron-sized (～300 nm) primary γʹ phase which enhanced the ductility during 800 ℃ tensile (the total elongation of T1, T2, and T3 samples were 6.75 %, 7.3 %, and 3.25 %, respectively) without evidently impairing the strength. After careful microstructure observation and deformation mechanism analysis, the enhancement of elongation was rationalized that the precipitation of the sub-micron-sized primary γʹ phase decreased the volume-fraction and size of the nanometer-sized γʹ phase which was precipitated at 800 ℃, and simultaneously, promoted the dislocation movement by suppressing the non-planar slip. However, an excessive amount of the sub-micron-sized primary γʹphase led to a faster ripening process of the nanometer-sized γʹ during creep, which decreased the creep life at 800 ℃/430 MPa (T1: 125 h, T2: 199 h, and T3: 198 h). Based on this, we monitored the number density of nanometer-sized γʹ phase coexisting with different amounts of large γʹduring creep. An area fraction less than 7 % of the sub-micron-sized γʹ phase was considered to have little detrimental effect on the creep life of K4800 alloy, which corresponded to a sub-solvus temperature range about 1080-1090 ℃.

Key words: Nickel-base superalloy, Heat treatment, Mechanical property, Precipitation strengthening, Deformation mechanism

Peng-Fei Zhao, Kun-Lei Hou, Min Wang, Mei-Qiong Ou, Ya-qian Yang, Ying-Che Ma. Effects of sub-solvus ageing on the tensile and creep properties of a new cast nickel-based superalloy[J]. J. Mater. Sci. Technol., 2025, 212: 289-302.

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