The paper presents the effect of a

The paper presents the effect of a free-spacing snail entry together with conical-nozzle turbulators on turbulent heat transfer and friction characteristics in a uniform heat-flux tube. The insertions of the conical or converging nozzle (C-nozzle) with different pitch ratios (PR) in common with the free-space snail entry are examined in a Reynolds number range from 8000 to 18000. A substantial augmentation of heat transfer for using the C-nozzles and snail entrance is expected by a strong influence from nozzleinduced reverse/re-circulation motion and snail-produced vortex/swirl motion for high Reynolds number. The experimental result shows a considerable increase in friction factor and heat transfer over the plain tube under the same operation conditions. Over the range investigated, the Nusselt numbers for employing both the enhancement devices with PR=2.0, 4.0 and 7.0 are found to be higher than that for the plain tube around 315%, 300% and 285% respectively. The results obtained are correlated in the form of Nusselt number as a function of Reynolds number, Prandtl number and pitch ratio. For performance comparison at equal pumping power, both the enhancement devices with the smallest pitch ratio perform the best, especially at low Reynolds number. The present results are also compared with correlations obtained from similar enhancement devices but without free-spacing entry.
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Experimental investigations have been conducted to examine the effect of a combination of C-nozzle turbulators and a snail with free-spacing entry on heat transfer rate and flow friction characteristics in a uniform heat flux tube using air as the test fluid. The application of the C-nozzles and free-spacing snail entry results in a considerable increase in heat transfer rate and friction loss, especially at smaller pitch ratio. This study indicates that instead of the snail with no entry length, the free-spacing snail entry should be introduced to lower friction loss associated but still favorable the heat transfer rate. Depending on the flow conditions and pitch ratio, the maximum improvements of heat transfer rate over the corresponding plain tube are found to be about 315%, 300% and 285%, for PR=2.0, 4.0, and 7.0, respectively. The variations of the enhancement efficiency for Reynolds number ranging from 5000 to 18000 are between 0.76 and 0.93; 0.7 and 0.85; and 0.67 and 0.8 for PR=2.0, 4.0 and 7.0, respectively. This means that the C-nozzle turbulators and snail with free-space entry are not feasible in terms of energy saving. Though, the devices of C-nozzle turbulators and a snail with free-spacing entry can be employed effectively at low Reynolds number or in places where pumping power is not important but compact sizes and ease of manufacture are needed.