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Temperature-dependent axial mechanical properties of Zircaloy-4 with various hydrogen amounts and hydride orientations

Shinhyo Bang, Ho-a Kim, Jae-Soo Noh, Donguk Kim, Kyunghwan Keum, Youho Lee

2021Nuclear Engineering and Technology18 citationsDOIOpen Access PDF

Abstract

The effects of hydride amount (20–850 wppm), orientation (circumferential and radial), and temperature (room temperature, 100 °C, 200 °C) on the axial mechanical properties of Zircaloy-4 cladding were comprehensively examined. The fraction of radial hydride fraction in the cladding was quantified using PROPHET, an in-house radial hydride fraction analysis code. Uniaxial tensile tests (UTTs) were conducted at various temperatures to obtain the axial mechanical properties. Hydride orientation has a limited effect on the axial mechanical behavior of hydrided Zircaloy-4 cladding. Ultimate tensile stress (UTS) and associated uniform elongation demonstrated limited sensitivity to hydride content under UTT. Statistical uncertainty of UTS was found small, supporting the deterministic approach for the load-failure analysis of hydrided Zircaloy-4 cladding. These properties notably decrease with increasing temperature in the tested range. The dependence of yield strength on hydrogen content differed from temperature to temperature. The ductility-related parameters, such as total elongation, strain energy density (SED), and offset strain decrease with increasing hydride contents. The abrupt loss of ductility in UTT was found at ∼700 wppm. Demonstrating a strong correlation between total elongation and offset strain, SED can be used as a comprehensive measure of ductility of hydrided zirconium alloy.

Topics & Concepts

Materials scienceCladding (metalworking)HydrideZirconium alloyUltimate tensile strengthElongationHydrogenComposite materialDuctility (Earth science)ZirconiumMetallurgyAlloyChemistryCreepMetalOrganic chemistryNuclear Materials and PropertiesFusion materials and technologiesPowder Metallurgy Techniques and Materials