Development of a novel two-phase flow solver for nuclear reactor analysis: Validation against sodium boiling experiments

“…The resulting tool, called GeN-Foam, is a multiphysics solver for steady-state and transient nuclear reactor analysis [11]. It couples together a multiscale fine/coarse mesh subsolver for thermal hydraulics (one and two phases) [16,17], a subsolver for neutronics (point kinetics [18], diffusion [19], SP3 [20], and SN [21,22]), and a displacement-based subsolver for thermal-mechanics to allow deforming the neutronics mesh for an explicit modeling of the expansion reactivity feedback. The developed solver can easily be maintained and modified thanks to object-oriented programming.…”

Investigation and Validation of Unstructured Mesh Methodologies for Modeling Experimental Reactors

“…The resulting tool, called GeN-Foam, is a multiphysics solver for steady-state and transient nuclear reactor analysis [11]. It couples together a multiscale fine/coarse mesh subsolver for thermal hydraulics (one and two phases) [16,17], a subsolver for neutronics (point kinetics [18], diffusion [19], SP3 [20], and SN [21,22]), and a displacement-based subsolver for thermal-mechanics to allow deforming the neutronics mesh for an explicit modeling of the expansion reactivity feedback. The developed solver can easily be maintained and modified thanks to object-oriented programming.…”

Investigation and Validation of Unstructured Mesh Methodologies for Modeling Experimental Reactors

Multiphysics modeling of groundwater flow on the example of a coupled thermo-hydro-mechanical model of infiltration of water warmer or cooler than the surroundings

Molten salt reactor physics: characterization, neutronic performance, multiphysics coupling, and reduced-order modeling