Numerical studies of nuclear traveling waves in a supercritical water cooled fast reactor

Abstract An axial fuel shuffling strategy is proposed based on the mechanism of the nuclear fission traveling wave and implemented numerically in the calculation for a supercritical water cooled fast reactor (SCWFR). The ERANOS code is adopted to perform the neutronics and burn-up calculations, and the calculation scheme for axial fuel shuffling and coolant density coupling are set up. The parametric studies of a typical PWR with Th–U and U–Pu ( 235 U instead of 239 Pu) conversions by burn-up and k eff calculations indicate that the breeding effects only exist in configurations with very low water content and the conversion or breeding becomes worse as the initial enrichment is increasing. The shuffling calculations for the 1-D SCWFR model described in this paper brought about some interesting results for a certain range of water content. The results indicate that the non-enriched fresh fuel is not possible for both Th–U and U–Pu conversions. As could be expected due to the η-values of the main fissile isotopes 233 U and ( 235 U, 239 Pu), respectively, the Th–U conversion needs a lower enrichment, and results in a slightly higher burn-up than the U–Pu conversion. The asymptotic power density distribution of the Th–U conversion is broader and lower than that of the U–Pu conversion. By reducing the water volume fraction, an increased burn-up can be achieved with correspondingly reduced fuel shuffling speed and reduced initial enrichment. Furthermore, the steady state calculations for the asymptotic state show that the Th–U conversion is superior to the U–Pu one concerning SCWFR safety aspects, where the absolute value of the Doppler constant is larger and the coolant feedback is negative for the Th–U conversion, while the coolant feedback is positive for the U–Pu one.