Fuel-steel mixing and radial mesh effects in power excursion simulations

•Fuel-steel mixing and radial mesh effects are significant on power excursion.•The earliest power peak is reduced and retarded by these two effects.•Unprotected loss of coolant transients in ESFR core are calculated. This paper deals with SIMMER-III once-through simulations of the earliest power exc...

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Bibliographic Details
Published in:Annals of nuclear energy 2016-04, Vol.90, p.26-31
Main Authors: Chen, X.-N., Rineiski, A., Gabrielli, F., Andriolo, L., Vezzoni, B., Li, R., Maschek, W., Kiefhaber, E.
Format: Article
Language:English
Subjects:
Boiling
Computer simulation
Finite element method
Fuel-steel mixing effect
Fuels
Homogenizing
Melting
Mesh size effect
Nuclear power generation
Power excursion simulation
SIMMER-III code
Sodium
Sodium cooled fast reactor
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Summary:•Fuel-steel mixing and radial mesh effects are significant on power excursion.•The earliest power peak is reduced and retarded by these two effects.•Unprotected loss of coolant transients in ESFR core are calculated. This paper deals with SIMMER-III once-through simulations of the earliest power excursion initiated by an unprotected loss of flow (ULOF) in the Working Horse design of the European Sodium Cooled Fast Reactor (ESFR). Since the sodium void effect is strictly positive in this core and dominant in the transient, a power excursion is initiated by sodium boiling in the ULOF case. Two major effects, namely (1) reactivity effects due to fuel-steel mixing after melting and (2) the radial mesh size, which were not considered originally in SIMMER simulations for ESFR, are studied. The first effect concerns the reactivity difference between the heterogeneous fuel/clad/wrapper configuration and the homogeneous mixture of steel and fuel. The full core homogenization (due to melting) effect is −2$, though a smaller effect takes place in case of partial core melting. The second effect is due to the SIMMER sub-assembly (SA) coarse mesh treatment, where a simultaneous sodium boiling onset in all SAs belonging to one ring leads to an overestimated reactivity ramp. For investigating the influence of fuel/steel mixing effects, a lumped “homogenization” reactivity feedback has been introduced, being proportional to the molten steel mass. For improving the coarse mesh treatment, we employ finer radial meshes to take the subchannel effects into account, where the side and interior channels have different coolant velocities and temperatures. The simulation results show that these two effects have significant impacts on the earliest power excursion after the sodium boiling.
ISSN:0306-4549
1873-2100
DOI:10.1016/j.anucene.2015.11.041