Fracture studies on cruciform bend specimens of pressure vessel steel subjected to thermo-mechanical loading.

The safety of a nuclear power plant during incidents, such as a Loss of Coolant Accident (LOCA), heavily relies on conducting a comprehensive structural integrity assessment of both the Reactor Pressure Vessel (RPV) and its components, specifically to withstand Pressurized Thermal Shock (PTS). PTS is characterized by a combination of steep temperature gradient, resulting from the injected emergency coolant during a LOCA, and internal pressure within the RPV. Majority of the reported fracture assessment studies on RPV steel, whether experimental or numerical investigations, have predominantly focused on standard uniaxial specimens at iso-thermal loading conditions. To better simulate the thermal shock scenario in RPVs, the present work aims to assess the impact of a biaxial stress field on both fracture parameters (crack mouth opening displacement and J -integral) and plastic collapse load. This assessment is conducted through experimental and numerical investigations, both with and without prior transient thermal load. Fracture experiments are performed on cruciform bend specimens, featuring two different biaxiality ratios (1:1 and 2:1). Moreover, numerical studies on cruciform specimens are conducted using finite element analysis to validate and corroborate the observations derived from the fracture experiments. • Impact of a biaxial stress on fracture parameters and plastic collapse load is studied under thermal shock scenario. • Fracture experiments conducted on cruciform bend specimens of two different biaxiality ratios under thermal transient • Finite element analysis carried out to validate experimental observations. • Results showed that thermal shock reduces load-carrying capacity. • Equi-biaxial cruciform specimens exhibit a higher level of constraint. [ABSTRACT FROM AUTHOR]