Dislocation density-based constitutive model for cyclic deformation and softening of Ni-based superalloys

Abstract

A physically-based constitutive modeling framework is proposed for the cyclic deformation and softening of Ni-based superalloys. The constitutive model accounts for underlying mechanisms of grain size strengthening, dislocation strengthening, solid solution strengthening, and precipitate strengthening, commonly observed in these alloys. A constitutive model is proposed for the shearing of precipitates on their interaction with glide dislocations during cyclic deformation. This is the primary contributor to the experimentally observed cyclic softening behavior in Ni-based superalloys. Model predictions of the cyclic stress-strain response and the cyclic softening (quantified in terms of the peak stress) are compared with the experimental counterparts for a range of strain amplitudes under fully-reversed cyclic loading of Inconel 718 (IN 718). Further, model predictions of precipitate size are also compared with the experimentally measured transmission electron micrographs of precipitate sizes at the end of deformation. Concurrence in the cyclic stress-strain response, peak stress, and precipitate size provides validation for our constitutive modeling framework. Development of a physically-based constitutive modeling framework for cyclic deformation. Microstructure-based strengthening mechanisms are considered in the model. Model incorporated the physical mechanisms of cyclic softening due to precipitate shearing.