Effect of burn-up on the thermal conductivity of light water reactor fuel: Results of investigations employing the laser flash technique

Analysing data drawn from three of EPRI’s NFIR Programmes and the High Burn-up Rim Project (HBRP) managed by CRIEPI of Japan, expressions for the degradation of thermal conductivity with burn-up up to 120 MWd/kgHM are presented. These indicate that at high burn-up, above 70 MWd/kgHM, the thermal conductivity of the matrix of the high burn-up structure (HBS) increases by 25 - 30% concomitant with recrystallization of the fuel grains. This increase is partially or completely off-set, however, by a decrease in conductivity associated with the porosity of the HBS which contains the fission gas gathered from the fuel matrix during transformation of the microstructure. Below 70 MWd/kgHM, in the absence of the HBS, the conductivity is about 15% lower than that currently accepted. It is also found that the conductivity of UO2 fuel falls sharply immediately irradiation begins. This is attributed to radiation damage rather than the incorporation of fission products in the fuel lattice. The data further reveals that at burn-ups below 70 MWd/kgHM the conductivity of UO2 containing 10 wt% Gd2O3 is markedly lower than that of UO2, but once the HBS has formed its conductivity is indistinguishable from that of conventional UO2, UO2 additive fuel or MOX. It is concluded that for accurate determination of the radial temperature profile in a high burn-up fuel pellet, knowledge of the volume fraction of the HBS in the pellet and the radial distribution of the porosity in the affected region is required.

TURNBULL J.A.;  WALKER Clive Thomas;  STAICU Dragos;  PAPAIOANNOU Dimitrios;  YAGNIK Suresh; 

2023-11-27

ELSEVIER

JRC130415

0022-3115 (online),   

https://www.sciencedirect.com/science/article/pii/S0022311523001666?via%3Dihub,    https://publications.jrc.ec.europa.eu/repository/handle/JRC130415,   

10.1016/j.jnucmat.2023.154398 (online),