Abstract

In this contribution, numerical methods are discussed to predict the heat transfer to liquid metal flowing in rectangular flow channels. A correct representation of the thermo-hydraulic behaviour is necessary, because these numerical methods are used to perform design and safety studies of components with rectangular channels. Hence, it must be proven that simulation results are an adequate representation of the real conditions. Up to now, the majority of simulations are related to forced convection of liquid metals flowing in circular pipes or rod bundle, because these geometries represent most of the components in process engineering (e.g. piping, heat exchanger). Open questions related to liquid metal heat transfer, among others, is the behaviour during the transition of the heat transfer regimes. Therefore, this contribution aims to provide useful information related to the transition from forced to mixed and free convection, with the focus on a rectangular flow channel. The assessment of the thermo-hydraulic behaviour under transitional heat transfer regimes is pursued by means of system code simulations, RANS CFD simulations, LES and DNS, and experimental investigations. Thereby, each of the results will compared to the others. The comparison of external experimental data, DNS data, RANS data and system code simulation results shows that the global heat transfer can be consistently represented for forced convection in rectangular flow channels by these means. Furthermore, LES data is in agreement with RANS CFD results for different Richardson numbers with respect to temperature and velocity distribution. The agreement of the simulation results among each other and the hopefully successful validation by means of experimental data will fosters the confidence in the predicting capabilities of numerical methods, which can be applied to engineering application.

Highlights

  • The assessment of the thermo-hydraulic behaviour under transitional heat transfer regimes is pursued by means of system code simulations, Reynolds-averaged Navier-Stokes equations (RANS) CFD simulations, LES and DNS, and experimental investigations

  • Liquid metal flows are characterized by low molecular Prandtl numbers, which strongly influence the transport of heat from solid surfaces

  • Within the scope of the latter numerical methods, the RANS approach still seems to be the best compromise between required numerical effort and accuracy among the given methods, because the realization of DNS or even LES is still limited to rather simple geometries and specialized numerical codes

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Summary

Introduction

Liquid metal flows are characterized by low molecular Prandtl numbers, which strongly influence the transport of heat from solid surfaces. The comparison of external experimental data, DNS data, RANS data and system code simulation results shows that the global heat transfer can be consistently represented for forced convection in rectangular flow channels by these means.

Results
Conclusion

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