THERMOHYDRAULIC PERFORMANCE ANALYSIS OF ABSORBER TUBE WITH COILED WIRE TURBULATORS IN SMALL APERTURE PARABOLIC TROUGH COLLECTOR

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Three-dimensional (3D) simulation using computational fluid dynamics (CFD) has been performed to investigate the impact of a coiled wire turbulator (CWT) on heat transfer and fluid flow in the absorber tube of a small aperture parabolic trough collector (PTC) under a turbulent flow regime. The PTC was modeled with a projected aperture area of 0.64 m<sup>2</sup> and an optimized value of rim angle 90 degrees using the ray tracing tool SolTrace based on an optimum value of average heat flux (8.58 kW/m<sup>2</sup>), and this optimum average heat flux was used as one of the boundary conditions in CFD simulation. The CFD-simulated findings for the smooth absorber tube of the PTC model are compared with the Dittus-Boelter equation for heat transfer and the Filonenko equation for friction factor. The simulated result showed an average deviation of 2.54% and 14.68% in the Nusselt number and friction factor, respectively. The effect of a wall-detached type of CWT (D<sub>m</sub> = 10 mm) on thermohydraulic performance with coil pitch ratios (P/d<sub>h</sub>) of 1, 1.5, and 2 and height ratios (e/d<sub>h</sub>) of 0.053, 0.063, and 0.074 is considered for the analysis in the Reynolds number (Re) range of 4000-12000. The optimal value of thermohydraulic performance (η<sub>thp</sub>) is obtained 1.56 for P/d<sub>h</sub> = 2, e/d<sub>h</sub> = 0.053, and Re = 4000, corresponding to which enhancement ratio of Nusselt number (Nu<sub>r</sub>/Nu<sub>s</sub>) and friction factor (f<sub>r</sub>/f<sub>s</sub>) are 2.28 and 3.14, respectively.