Modeling of the microstructural behavior of hydrided zirconium alloys

A multiphase microstructural system of two types of hydrides; f.c.c. delta and b.c.c.. epsilon hydride precipitates within a parent h.c.p. zircaloy-4 parent matrix were modelled by a crystalline dislocation-density and a finite-element (FE) method that is specialized for large inelastic strains and nonlinear behavior. The different crystalline structure of the hydrides, the parent matrix, and the orientation relationships between the different crystalline phases have been accounted for and modeled with a validated FE approach. The effects of radial hydride factors, hydride volume fraction, hydride morphology, and hydride orientation and distribution on overall behavior were investigated. The predictions provide an understanding of why a distribution of circumferential hydrides have higher strength and ductility than a distribution of radial hydrides. Furthermore, zircaloy delta (f.c.c.) hydride systems have less ductility and strength than the zircaloy epsilon (b.c.c.) systems.

Automated summary

A multiphase microstructural system consisting of two types of hydrides was modeled, with the effects of different factors such as hydride volume fraction, morphology, orientation, and distribution on overall behavior investigated. Predictions show that a distribution of circumferential hydrides has higher strength and ductility, and zircaloy epsilon (bcc) hydride systems exhibit more ductility and strength compared to zircaloy delta (fcc) systems.