Numerical studies on liquid sodium flow boiling in a 7-pin hexagonal subassembly towards flow rundown scenario in SFR

Abstract

The present study is intended for the development of high resolution CFD based model for the prediction of two-phase flow and heat transfer characteristics of liquid sodium in a 7-pin bundle. The sodium flow boiling from its inception to nucleate boiling and the forced convective vaporization regimes are analyzed by developing an Eulerian-Eulerian model (two-fluid model) using flow regime dependent constitutive correlations and modified non-equilibrium wall boiling model. The Algebraic Interfacial Area Density (AIAD) model is implemented for providing required closure terms as flow regime dependent based on the local flow topology within the two-fluid model. The sodium flow boiling simulations are performed in a 7-pin subassembly using the model under constant wall heat flux for different inlet mass flow rates and predicted the quasi-steady boiling. The radial and axial void fraction progress in the flow sub-channels, variation of sodium temperature, and wall boiling components along the heated pin length are numerically predicted. Also analyzed the transient sodium boiling under flow rundown scenario in the 7-pin subassembly with a continuous reduction in the inlet mass flow rate under constant wall heat flux. The prediction of wall temperature variation during this flow scenario confirmed the incidence of local dry-out at the end of the transient which causes loss of heat transfer from the pin surface. Also, the mechanistic model based evaluations for wall heat transfer coefficient and possible flow regimes are obtained based on the flow and thermal conditions predicted.