Numerical analysis of the ROCOM boron dilution benchmark experiment using the CUPID code

Abstract

Abstract The Rossendorf Coolant Mixing Model (ROCOM) boron dilution benchmark experiment was assessed using the CUPID code in the framework of a Coordinated Research Project by the International Atomic Energy Agency, namely, “Application of Computational Fluid Dynamics Codes for Nuclear Power Plant Design.” Two-equation Reynolds-Averaged Navier–Stokes (RANS) turbulence models, such as the standard k-e model, Re-Normalization Group (RNG) k-e model, and Shear Stress Transport (SST) k-ω model, were tested, and predictions of boron concentration were compared to measurements at the downcomer and core inlet in the reactor pressure vessel. The analysis result showed that the de-borated water slug injected from one cold leg was diffused by the turbulence mixing effect as it flowed downward in the downcomer and passes through a perforated drum in the lower plenum. The applied turbulence model affected the mixing patterns of the de-borated water, which resulted in a local distribution of boron concentration at the core inlet. This was the main concern of the boron dilution phenomena from the viewpoint of safety analysis. The result showed combining the CUPID code with the RANS turbulence models could reasonably predict the boron dilution phenomena in the reactor vessel when the proper y-plus wall treatment was assured, considering the characteristics of the turbulence models.