Numerical investigation of the thermal conductivity of UO2 - Mo microplate fuel pellets to realize enhanced heat transfer in the fuel radial direction

The thermal performance of composite UO2 fuel pellets, as a potential candidate for accident-tolerant fuels, is being attempted to be actively enhanced by employing high conductivity materials as additives. Herein, we numerically investigated the thermal performance of UO2 - 3 vol% Mo microplate fuel pellets with microsized Mo plates to enhance the corresponding thermal conductivity in the fuel radial direction. UO2 - 3 vol% Mo microplate fuel pellets were successfully fabricated through the conventional sintering process, and the characteristics of the thermal conductivities were investigated in terms of the shape factor of the Mo microplate, amount of Mo content, and arrangement (such as the spacing and angle) of the Mo microplates in the UO2 fuel pellets. The results demonstrated that the arrangement of the Mo microplates parallel to the main heat transfer flow direction could further enhance the thermal conductivity. The numerical results pertaining to the calculation based on the microplate arrangement exhibited a reasonable agreement with the measured values, and the thermal conductivity was noted to be enhanced by 47% at 1000 degrees C compared to that of UO2. Moreover, the UO2 - 3 vol% Mo microplate fuel pellets with enhanced thermal conductivities could reduce the maximum pellet temperature by 149 degrees C compared to that of the UO2 pellet under a linear heat generation rate of 200 W/cm. (C) 2021 Published by Elsevier B.V.

Automated summary

The thermal performance of composite UO2 fuel pellets can be significantly improved by adding microsized Mo plates to enhance thermal conductivity, especially when Mo plates are arranged parallel to the main heat transfer flow direction. The enhanced thermal conductivity of UO2 - 3 vol% Mo microplate fuel pellets can reduce the maximum pellet temperature by 149 degrees C compared to conventional UO2 pellets under a linear heat generation rate of 200 W/cm.