Long-term service induced mechanical properties change of hot-end welding metals in a retired CrMoV bainitic gas turbine rotor

This research focused on evaluating the mechanical properties change of Welding Metals (WMs) at the turbine-end (hot-end, working beyond 500 °C) of a retired CrMoV bainitic gas turbine rotor serving over 14 years, by comparison to those WMs at the compressor-end (cold-end, working below 300 °C). Aft...

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Published inMaterials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 833; p. 142323
Main Authors Rui, Shao-Shi, Han, Qi-Nan, Wang, Xue, Zhao, Jia-Min, Cai, Zhipeng, Du, Dong, Shi, Hui-Ji
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 26.01.2022
Elsevier BV
Subjects
Anelastic relaxation
Crack propagation
Creep strength
Dislocation density
Elastic modulus
Fatigue failure
Gas turbines
High temperature
Mechanical properties
Modulus of elasticity
Retired rotor
Room temperature
Rotors
Welding
Welding metal
Retired rotor
Mechanical properties
Elastic modulus
Welding metal
Anelastic relaxation
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Summary:This research focused on evaluating the mechanical properties change of Welding Metals (WMs) at the turbine-end (hot-end, working beyond 500 °C) of a retired CrMoV bainitic gas turbine rotor serving over 14 years, by comparison to those WMs at the compressor-end (cold-end, working below 300 °C). After long-term service, the room-temperature elastic modulus and the bainitic microstructure of hot-end WMs stayed almost the same as those of cold-end WMs, but the high-temperature elastic modulus and the dislocations density of the former became higher than those of the latter. The above change, especially the change of high-temperature elastic modulus produced significant influences on the tensile, fatigue and creep behaviors of hot-end WMs, which further led to a higher tensile and creep strength but a lower ductility, as well as a better fatigue crack propagation resistance under high-temperature condition. A correlation between the high-temperature elastic modulus change and the tensile/fatigue/creep behaviors change was established for hot-end WMs based on mechanics modelling, which provided a feasible way to monitor the rotor properties change. •Long-term service raised the activation energy for anelastic relaxation of hot-end welding metals.•High-temperature elastic modulus of hot-end welding metals with less anelasticity became higher.•Higher elastic modulus improves tensile/creep strength but reduces ductility at high-temperature.•Higher elastic modulus increases the resistance to fatigue crack propagation at high-temperature.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2021.142323