论文信息 - Full-scope simulation of a dry storage cask using computational fluid dynamics

Full-scope simulation of a dry storage cask using computational fluid dynamics

A computational fluid dynamics (CFD) analysis of a TN24P cask was performed through a full-scope simulation using FLUENT. In order to establish the analysis methodology while minimizing the computational burden, the sensitivities of various parameters were investigated by constructing a small-scale model. The full-scale CFD predictions of the TN24P cask were compared with the experimental data and COBRA-SFS results. There was good agreement between the FLUENT predictions and the experimental data. FLUENT showed similar temperature predictions to COBRA-SFS, while there were deviations between FLUENT and COBRA-SFS in the velocity predictions. By conducting sensitivity studies for the application uncertainties using a full-scale simulation, it was found that the basket gap size was the most sensitive parameter in the analysis.

[1] D. R. Rector,et al. COBRA-SFS predictions of single assembly spent fuel heat transfer data , 1986 .

[2] Ephraim M Sparrow,et al. Longitudinal Laminar Flow Between Cylinders Arranged in Regular Array , 1959 .

[3] Isamu Maekawa,et al. Natural Convection Heat Transfer in the Horizontal Dry Storage System for the LWR Spent Fuel Assemblies , 1996 .

[4] A Zigh,et al. Computational Fluid Dynamics Best Practice Guidelines in the Analysis of Storage Dry Cask , 2008 .

[5] Toshiari Saegusa,et al. Thermal hydraulic analysis compared with tests of full-scale concrete casks , 2008 .

[6] Florian R. Menter,et al. CFD Best Practice Guidelines for CFD Code Validation for Reactor- Safety Applications , 2002 .

[7] Soeren Kliem,et al. Fluid mixing and flow distribution in a primary circuit of a nuclear pressurized water reactor—Validation of CFD codes , 2007 .

[8] Zhou Zhi-wei,et al. A numerical investigation of natural convection heat transfer in horizontal spent-fuel storage cask , 2002 .

[9] Frank P. Incropera,et al. Fundamentals of Heat and Mass Transfer , 1981 .