Abstract
The WIMS/PANTHER Embedded Supercell Method (ESM) provides a significant improvement in prediction accuracy for radial power distributions for PWR reactors compared to the standard “two-step” approach, without the need for a significant increase in computational resource. Recent papers at PHYSOR conferences have outlined the details of the method and demonstrated its operation, and the accuracy improvements possible, by means of benchmarking calculations.This paper applies the method to a 4-loop PWR in the U.K, and three PWRs (3-loop and 2-loop) in Belgium. Comparisons are made against measured data from the start-of-cycle physics testing performed for each cycle, and power-shape measurements collected during the cycle using a conventional “two-step” nodal reactor solution, and with the ESM. All results will be presented with the JEF2.2 nuclear data library, for ease of comparison between the methods and previously reported results, although the effects of more modern evaluations will be commented upon.The benchmark calculations referred to above studied a challenging MOX/UO2 benchmark core akin to an SMR. The four reactors studied here include conventional UO2 only core designs and cycles with UO2/MOX mixed cores. A variety of boron-and gadolinium-based burnable absorbers are also present. The data is used to show that the method both operates successfully for real reactor problems, and delivers improvements in the prediction accuracy of measured parameters.
Highlights
This paper presents a summary of results comparing core calculations employing the WIMS/PANTHER Embedded Supercell Method (ESM) against plant measurements, for a range of operating PWRs
The ESM is a recent development in the WIMS [1] and PANTHER [2] codes which is intended to provide a significant improvement in prediction accuracy in radial power distributions for PWR reactors compared to the standard “two-step” approach, without the need for a significant increase in computational resource
WIMS10-based models are seen to provide more consistent cycle-to-cycle behaviour than the original LWRWIMS models; the reactivity difference introduced by the ESM method is less than 10 ppm and broadly cycle-independent
Summary
This paper presents a summary of results comparing core calculations employing the WIMS/PANTHER Embedded Supercell Method (ESM) against plant measurements, for a range of operating PWRs. The ESM is a recent development in the WIMS [1] and PANTHER [2] codes which is intended to provide a significant improvement in prediction accuracy in radial power distributions for PWR reactors compared to the standard “two-step” approach, without the need for a significant increase in computational resource. The method described here will eventually replace the existing method currently in use for both UK and Belgian reactors, which was described in [3]. While originally designed to provide improved accuracy for UO2/MOX mixed cores, the method is capable of providing improved modelling throughout any core, including at the core edge/reflector interface and with inserted control rods
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