Advanced high temperature sodium cooled receiver design

In this paper, receiver designs for 3D printing are analyzed by CFD calculations that are based on Reynolds-averaged Navier-Stokes (RANS) steady state simulations. The results show the surface and channel temperatures as well as dimensionless values to analyze the characteristics of the sodium flow....

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Hauptverfasser: Fuchs, Joachim, Arbeiter, Frederik, Böttcher, Michael, Hering, Wolfgang, Neuberger, Heiko, Stieglitz, Robert
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Arbeiter, Frederik
Böttcher, Michael
Hering, Wolfgang
Neuberger, Heiko
Stieglitz, Robert
description In this paper, receiver designs for 3D printing are analyzed by CFD calculations that are based on Reynolds-averaged Navier-Stokes (RANS) steady state simulations. The results show the surface and channel temperatures as well as dimensionless values to analyze the characteristics of the sodium flow. Helical installations induce a rotational flow inside the channels and enhance the heat transfer. For larger scale receivers, “Cold spray” is described as an additive manufacturing process.
doi_str_mv 10.1063/5.0149630
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subjects Dimensionless analysis
Fluid flow
Helical flow
High temperature
Reynolds averaged Navier-Stokes method
Sodium
Three dimensional printing
Vortices
title Advanced high temperature sodium cooled receiver design
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