System of closing relations of a two-fluid model for the HYDRA-IBRAE/LM/V1 code for calculation of sodium boiling in channels of power equipment

• Published in: Thermal engineering Vol. 64; no. 7; pp. 504 - 510
• Main Authors: Usov, E. V., Butov, A. A., Dugarov, G. A., Kudasov, I. G., Lezhnin, S. I., Mosunova, N. A., Pribaturin, N. A.
• Format: Journal Article
• Language: English
• Published: Moscow Pleiades Publishing 01.07.2017; Springer Nature B.V
• Subjects: Accidents; Channels; Conservation equations; Documents; Energy conservation; Engineering; Engineering Thermodynamics; Friction; Heat and Mass Transfer; Heat transfer; Liquid sodium; Mass transfer; Mathematical models; Nuclear electric power generation; Nuclear energy; Nuclear Power Stations; Nuclear reactors; Sodium; Sodium cooled reactors; HYDRA-IBRAE/LM code; sodium; closing relations; two-phase flow
• ISSN: 0040-6015; 1555-6301
• DOI: 10.1134/S0040601517070102

The system of equations from a two-fluid model is widely used in modeling thermohydraulic processes during accidents in nuclear reactors. The model includes conservation equations governing the balance of mass, momentum, and energy in each phase of the coolant. The features of heat and mass transfer, as well as of mechanical interaction between phases or with the channel wall, are described by a system of closing relations. Properly verified foreign and Russian codes with a comprehensive system of closing relations are available to predict processes in water coolant. As to the sodium coolant, only a few open publications on this subject are known. A complete system of closing relations used in the HYDRA-IBRAE/LM/V1 thermohydraulic code for calculation of sodium boiling in channels of power equipment is presented. The selection of these relations is corroborated on the basis of results of analysis of available publications with an account taken of the processes occurring in liquid sodium. A comparison with approaches outlined in foreign publications is presented. Particular attention has been given to the calculation of the sodium two-phase flow boiling. The flow regime map and a procedure for the calculation of interfacial friction and heat transfer in a sodium flow with account taken of high conductivity of sodium are described in sufficient detail. Correlations are presented for calculation of heat transfer for a single-phase sodium flow, sodium flow boiling, and sodium flow boiling crisis. A method is proposed for prediction of flow boiling crisis initiation.