1-Dimensional simulation of thermal annealing in a commercial nuclear power plant reactor pressure vessel wall section

摘要

The objective of this work was to provide experimental heat transfer boundary condition and reactor pressure vessel (RPV) section thermal response data that can be used to benchmark computer codes that simulate thermal annealing of RPVS. This specific protect was designed to provide the Electric Power Research Institute (EPRI) with experimental data that could be used to support the development of a thermal annealing model. A secondary benefit is to provide additional experimental data (e.g., thermal response of concrete reactor cavity wall) that could be of use in an annealing demonstration project. The setup comprised a heater assembly, a 1.2 in (times) 1.2 m (times) 17.1 cm thick (4 ft (times) 4 ft (times) 6.75 in) section of an RPV (A533B ferritic steel with stainless steel cladding), a mockup of the (open quotes)mirror(close quotes) insulation between the RPV and the concrete reactor cavity wall, and a 25.4 cm (10 in) thick concrete wall, 2.1 in (times) 2.1 in (10 ft (times) 10 ft) square. Experiments were performed at temperature heat-up/cooldown rates of 7, 14, and 28(degrees)C/hr (12.5, 25, and 50(degrees)F/hr) as measured on the heated face. A peak temperature of 454(degrees)C (850(degrees)F) was maintained on the heated face until the concrete wall temperature reached equilibrium. Results are most representative of those RPV locations where the heat transfer would be 1-dimensional. Temperature was measured at multiple locations on the heated and unheated faces of the RPV section and the concrete wall. Incident heat flux was measured on the heated face, and absorbed heat flux estimates were generated from temperature measurements and an inverse heat conduction code. Through-wall temperature differences, concrete wall temperature response, heat flux absorbed into the RPV surface and incident on the surface are presented. All of these data are useful to modelers developing codes to simulate RPV annealing.