Criticality and burn up evolutions of the Fixed Bed Nuclear Reactor with alternative fuels

Time evolution of criticality and burn-up grades of the Fixed Bed Nuclear Reactor (FBNR) are investigated for alternative fuels. These are: (1) low enriched uranium, (2) weapon grade plutonium, (3) reactor grade plutonium, and (4) minor actinides in the spent fuel of light water reactors (LWRs). The criticality calculations are conducted with SCALE 5.1 using S8-P3 approximation in 238 neutron energy groups with 90 groups in thermal energy region. in results of the study can be summarized as follows: riched uranium (UO2): FBNR with an enrichment grade of 9% and 19% will start with keff = 1.2744 and keff = 1.36 and can operate ∼8 and >15 years with the same fuel charge, where criticality drops to keff = 1.06 and a burn-up grade of 54 000 and >110 000 MW.D/t can be attained. grade plutonium: Such a high quality nuclear fuel suggests to be mixed with thorium. Second series of criticality calculations are conducted with fuel compositions made of thoria (ThO2) and weapon grade PuO2, where PuO2 component has been varied from 1% to 100%. Criticality with keff > 1.0 is achieved by ∼2.5% PuO2. At 4% PuO2, the reactor criticality will become satisfactory (keff = 1.1121), rapidly increasing with more PuO2. A reasonable mixture will by around 20% PuO2 and 80% ThO2 with a keff = 1.2864. This mixed fuel would allow full power reactor operation for >20 years and burn-up grade can reach 136 000 MW.D/t. r grade plutonium: Third series of criticality calculations are conducted with fuel compositions made of thoria and reactor grade PuO2, where PuO2 is varied from 1% to 100%. Reactor becomes critical by ∼8% PuO2 content. One can achieve keff = 1.2670 by 35% PuO2 and would allow full power reactor operation also for >20 years and burn-up grade can reach 123 000 MW.D/t. actinides in the spent fuel of LWRs: Fourth series of criticality calculations are conducted with fuel compositions made of thoria and MAO2, where MAO2 is varied from 1% to 100%. Reactor becomes critical by ∼17% MAO2 content. Reasonably high reactor criticality (keff = 1.2673) is achieved by 50% MAO2 for a reactor operation time of 15 years with a burn up of 86 000 MW.D/t without fuel change. On that way, the hazardous nuclear waste product can be transmuted as well as utilized as fuel.