Open AccessPreliminary Study on Small Long-Life PWR Reactor Design Fueled Thorium with Protactinium as Burnable Poiso
Author(s) -
Jubaidah Jubaidah
Publication year - 2017
Publication title -
einstein : jurnal hasil penelitian dan rekayasa ilmu fisika/einsten: : jurnal hasil penelitian dan rekayasa ilmu fisika
Language(s) - English
Resource type - Journals
eISSN - 2407-747X
pISSN - 2338-1981
DOI - 10.24114/einstein.v4i3.6212
Subject(s) - fissile material , burnup , nuclear engineering , criticality , thermal hydraulics , enriched uranium , thorium fuel cycle , neutron transport , coolant , protactinium , thorium , materials science , environmental science , uranium , nuclear physics , neutron , physics , mechanics , engineering , heat transfer , metallurgy
Thorium as fissile material has overweigh advantages compared to Uranium in order to have a long-life PWR reactor without replacement fuel. Additional of Protactinium as a burnable poison is effective to reduce excess reactivity in the beginning of the reactor operation. This study aims to analyze the neutronic, burnup fuel, thermal-hydraulic and kinetic calculations in regard to reactor safety. The calculation is performed with SRAC program using JENDL-32 as data library. The results show that the value of keff for 33 years are still in the range 1.0154 <keff<1.0171 and the burn-up level has increased, due to the additional fissile material as conversion results of Th232 and Pa231. Axial linear power distribution indicates normal distribution pattern. The coolant temperature distribution in the axial direction is quite flat. Key words: PWR, Th-232, U-233, Pa-231, neutronic, thermal-hydraulic, burn-up level, reactor kinetics