Low cycle fatigue and stress relaxation behaviours of powder metallurgy Ni-based superalloy FGH4098

In this study, the effects of microstructure, temperature and dwell time in a loading cycle on low cycle fatigue (LCF) and stress relaxation behaviours of a powder metallurgy Ni-based superalloy (i.e. FGH4098) for aeroengine turbine disc application were studied along with detailed microscopic characterisation of fracture features and deformation substructures. The results indicate that the LCF failure mode of FGH4098 transits from transgranular to intergranular with the increase of temperature and dwell time, and the propensity of intergranular fatigue cracking is higher in fine-grained FGH4098. FGH4098 predominantly shows cyclic hardening behaviour which is mainly related to dislocation interactions. With the increase of temperature and/or dwell time, the cyclic hardening behaviour diminishes to some extent due to the increasing shearing of secondary gamma' precipitates by stacking fault and partial dislocation pairs. Similarly, stress relaxation in FGH4098 is also associated with the shearing of gamma' precipitates and becomes more prominent at high temperature with long dwell period. Microtwinning may also contribute to stress relaxation at 750 degrees C.

Automated summary

The study reveals that the low cycle fatigue failure mode and stress relaxation behavior of FGH4098 change with increasing temperature and dwell time, mainly influenced by microstructure.