Journal
INTERNATIONAL JOURNAL OF THERMAL SCIENCES
Volume 195, Issue -, Pages -Publisher
ELSEVIER FRANCE-EDITIONS SCIENTIFIQUES MEDICALES ELSEVIER
DOI: 10.1016/j.ijthermalsci.2023.108644
Keywords
Heat transfer; Turbulent flow; SDP; NPR
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This study numerically investigated the influence of spherical dimple-protrusion (SDP) structures with negative Poisson ratio characteristics on turbulent flow and heat transfer in a rectangular channel. The results showed that increasing the dimple depth-to-diameter ratio and density improved the heat transfer performance, and increasing the Reynolds number first enhanced the heat transfer coefficient before stabilizing.
This study numerically investigated the turbulent flow and heat transfer in a rectangular channel with spherical dimples (SDs) and protrusions (SPs) having negative Poisson ratio (NPR) characteristics. The influences of dimple depth-to-diameter ratio (Delta = 0.1-0.4), dimple density (phi = 0.45-0.75), and Reynolds number (Re = 18,700-60,000) on the flow field structure, local and average heat transfer coefficient (HTC), and thermalhydraulic performance (THP) of the spherical dimple-protrusion (SDP) structure were studied. The results showed that as the Delta increases, the vortex structure inside SD changed from symmetric to asymmetric and gradually increased in size. Further, under the same Delta, the increase in phi reduced the dimensions of the separation zone downstream of the SP. Therefore, both increases in Delta and phi were beneficial to the increase in performance of the SDP for heat transfer. With the increase in Re, the HTC and friction factor of the SDP first increase and then become stable at a large dimple density (phi >= 0.65). The globally averaged HTC and the friction factor of the SDP were respectively 1.2-2.1 times and 1.1-5.4 times of those for the smooth channel. The maximum THP of the SDP was obtained at Delta = 0.2, which was 33% greater than that of the smooth channel. At a similar phi, the SDP structure, as the SD structure, virtually preserves the comparatively high thermal performance factor in the range of 1.34-1.49 and offers the advantage of NPR characteristics.
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