Experimental investigation of the heat transfer of supercritical R134a in a horizontal micro-fin tube

Abstract The heat transfer of supercritical R134a was investigated experimentally in a horizontal micro-fin tube for conditions related to the supercritical heater in trans-critical ORC systems, including the effects of heat flux, pressure, and mass flux. The results showed that Nutop was smaller than Nubottom due to the buoyancy. The effects of pressure and heat flux on Nu were found to differ in different bulk enthalpy regions and tube positions. Large mass fluxes increase Nu while buoyancy has a stronger effect at low mass fluxes. Previous correlations were evaluated with new correlations developed for Nu in a micro-fin tube. The Bishop correlation gave reasonable predictions of Nutop, but none of the correlations could accurately predict Nubottom. A pair of more accurate correlations were developed for the top and bottom Nusselt numbers using the dimensionless number π c to account for the effects of the drastic property variations. The new correlations have a mean deviation of 10.3% for Nutop, and 17.8% for Nubottom, with 96.1% of the experimental data for Nutop and 83.8% of the data for Nubottom well predicted with deviations smaller than 30%.

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