Abstract
Currently there is no integral experimental data for code validation regarding the decay heat of MOX fuels, excepted fission burst experiments (for fission products contributions at short cooling times) or post-irradiated experiments on nuclide inventories (restricted number of nuclide of interest for decay heat). The uncertainty quantification mainly relies on uncertainty propagation of nuclear data covariances. In the recent years, the transposition method, based on the data assimilation theory, was used in order to transpose the experiment-to-calculation discrepancies at a given set of parameters (cooling time, fuel burnup) to another set of parameters. As an example, this method was used on the CLAB experiments and the experiment-to-calculation discrepancies at 13 years were transposed to an UOX fuel between 5 and 27 years and for burnups from 10 to 50 GWd/t. The purpose of this paper is to study to what extent the transposition method could be used for MOX fuels. In particular, the Dickens fission burst experiment of 239Pu was considered for MOX fuels at short cooling times (< 1h30) and low burnup (< 10 GWd/t). The impact of fission yields (FY) correlations was also discussed. As a conclusion, the efficiency of the transposition process is limited by the experimental uncertainties larger than nuclear data uncertainties, and by the fact that fission burst experiments would only be representative to the FY contribution of the decay heat uncertainty of an irradiated reactor fuel. Nevertheless, this method strengthens the decay heat uncertainties at very short cooling times, previously based only on nuclear data covariance propagation through computation.
Highlights
The decay heat (DH) is a crucial issue for safety design and operation in both normal and accidental scenarios, from reactor shutdown until geological times
This library is completed with cross-sections from JEFF-3.1.1 for the missing isotopes in the APOLLO2 filiation chains, and completed with decay data and fission yields (FY) data coming from the JEFF-3.1.1 library as well
This paper focuses on a MOX fuel with a 5.4% plutonium content (1.2% 238Pu, 59.7% 239Pu, 24.1% 240Pu, 8.4% 241Pu, 4.7% 242Pu and 1.9% 241Am)
Summary
The decay heat (DH) is a crucial issue for safety design and operation in both normal and accidental scenarios, from reactor shutdown until geological times. The transposition of the calculation/experiment (C/E) discrepancies of the CLAB assemblies can be done for PWR UOX fuels at cooling times from 5 to 27 years and for burnups from 10 to 50 GWd/t at least. The PEPIN2 depletion code uses the input data file provided by APOLLO2 in order to produce a collapsed library with burnup dependent cross-sections. This library is completed with cross-sections from JEFF-3.1.1 for the missing isotopes in the APOLLO2 filiation chains, and completed with decay data and fission yields (FY) data coming from the JEFF-3.1.1 library as well. A very precise depletion history can be given to the PEPIN2 code, with intra-cycles for instance, power variations and cooling periods
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