Microstructure degradation and residual low cycle fatigue life of a serviced turbine blade

Author:

Tan L.1,Yang X. G.1ORCID,Sun Y. T.2,Shi D. Q.1,Hao W. Q.1,Zhang C.1,Fu Z. Z.2,Ji P. F.2,Fan Y. S.1

Affiliation:

1. School of Energy and Power Engineering Beihang University Beijing China

2. Beijing Aeronautical Engineering Technical Research Center Beijing China

Abstract

AbstractThis paper was attempted to investigate the microstructure degradation and low cycle fatigue (LCF) performance of a serviced K465 Ni‐based superalloy turbine blade. LCF tests were carried out with small‐scale plate specimens sampled from the blades. Relationship between residual LCF life and microstructure state was estimated. The results indicate that the coarsening of γ/γ′ phases was the most significant microstructure degradation mode for the serviced blades. Both the γ matrix width and the γ′ precipitate diameter increased with the increase of service duration, while the γ′ precipitate volume fraction slightly decreased. The most severe microstructure degradation occurred at the leading edge along the chord direction, particularly at 50–70 % airfoil spans. The residual LCF life exhibited an accelerated decrease characteristic as increases of microstructure degradation degree. The coarsened microstructure diminished shear resistance of the superalloy, which resulted in additional accumulated inelastic deformation and a corresponding reduction in LCF life.

Funder

Academic Excellence Foundation of BUAA for PHD Students

National Major Science and Technology Projects of China

National Natural Science Foundation of China

Publisher

Wiley

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