Experimental heat transfer to supercritical carbon dioxide flowing upward vertical tube with highly conducting surroundings

This paper presents heat transfer characteristics of supercritical carbon dioxide flow inside vertical circular pipe surrounded by highly conducting material, and develops an adequate tool to test the performance of available heat transfer correlations with. The possible situations are illustrated for the nuclear power plant to which the above-mentioned geometric configuration might be applicable. An experimental loop with vertical circular geometry is designed and constructed to test the upward flow in supercritical state when the axial heat transfer is enhanced by the surrounding metals, resulting in a wall boundary condition between the constant heat flux and temperature. The set of correlations and important findings are critically reviewed from extensive literature survey. Incorporating nondimensional groups resorting to past insights from the available literature, a convective heat transfer correlation is proposed. The optimization procedure is described which utilizes a random walk method along with the in-house finite element heat transfer code to determine the coefficients of the proposed heat transfer correlation. The proposed methodology can be applied to evaluation of heat transfer when the heat transfer coefficient data cannot directly be determined from the experiment.

► Performed experiment for the upward SCO2 flow surrounded by highly conducting metal.
► Selected dimensionless groups representing the property variations and buoyancy.
► Developed the heat transfer correlation for the mixed thermal boundary condition.
► Wrote a finite element heat transfer code to find the appropriate correlation.
► Coupled the 1D convection and 2D heat conduction via heat transfer coefficient.