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Bibliographic Details
Main Authors: Caprais, Mathis, Bergeron, André
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.03788
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author Caprais, Mathis
Bergeron, André
author_facet Caprais, Mathis
Bergeron, André
contents In this study, the Method of Characteristics (MOC) for Delayed Neutron Precursors (DNPs) is used to solve the precursors balance equation with turbulent diffusion. The diffusivity of DNPs, significantly higher than molecular diffusivity, emerges in turbulent flows from the time-averaging of the DNPs mass balance equation. To integrate this effect within the MOC framework, the advection-reaction component of the DNPs balance equation is solved using the MOC, while the diffusive source is computed from the concentration of the previous iteration. The method is validated on a 2D recirculating pipe reactor with high Reynolds number flow, comparing the MOC with diffusion to a standard finite volume (FV) discretization of the fission products balance equation. Additionally, the impact of the diffusivity term on DNP distributions and reactor reactivity is quantified as a function of the turbulent Schmidt number.
format Preprint
id arxiv_https___arxiv_org_abs_2411_03788
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle An iterative scheme to include turbulent diffusion in advective-dominated transport of delayed neutron precursors
Caprais, Mathis
Bergeron, André
Computational Physics
Fluid Dynamics
In this study, the Method of Characteristics (MOC) for Delayed Neutron Precursors (DNPs) is used to solve the precursors balance equation with turbulent diffusion. The diffusivity of DNPs, significantly higher than molecular diffusivity, emerges in turbulent flows from the time-averaging of the DNPs mass balance equation. To integrate this effect within the MOC framework, the advection-reaction component of the DNPs balance equation is solved using the MOC, while the diffusive source is computed from the concentration of the previous iteration. The method is validated on a 2D recirculating pipe reactor with high Reynolds number flow, comparing the MOC with diffusion to a standard finite volume (FV) discretization of the fission products balance equation. Additionally, the impact of the diffusivity term on DNP distributions and reactor reactivity is quantified as a function of the turbulent Schmidt number.
title An iterative scheme to include turbulent diffusion in advective-dominated transport of delayed neutron precursors
topic Computational Physics
Fluid Dynamics
url https://arxiv.org/abs/2411.03788