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Heat transfer of impinging sweeping jets: Influence of nozzle-to-target spacing and feedback channel minimum passage width

C. D'angelo, Gerardo Paolillo, Carlo Salvatore Greco, Gennaro Cardone, Tommaso Astarita

2025International Journal of Heat and Mass Transfer16 citationsDOIOpen Access PDF

Abstract

Infrared Thermography and the heated thin foil heat flux sensor are employed to experimentally investigate the heat transfer characteristics of sweeping jets impinging on a flat surface. Multiple nozzle-to-target spacings H ( H / w = 0 . 5 , 1 , 1 . 5 , 2 , 4 , 6 , 8 and 10, where w represents the width of the square exit nozzle throat) and feedback channel minimum passage widths g ( g / w = 1 , 0 . 83 , 0 . 67 , 0 . 50 , 0 . 33 , 0 . 17 and 0) are analyzed to evaluate the effects of these two parameters on the convective heat transfer of the investigated jets. The Reynolds number is set to 1 . 47 × 1 0 4 for all the experiments performed. To assess the heat transfer behavior of the studied sweeping jet device, both time-averaged and phase-averaged analyses are conducted. This study demonstrates that the convective heat transfer of the impinging sweeping jet affects a broader area of the foil as the nozzle-to-target spacing increases, whereas the opposite effect is observed when reducing the minimum passage width of the feedback channels. Furthermore, the time-averaged analyses reveal that for 0 . 5 ≤ H / w ≤ 1 . 5 , compared to the corresponding steady jet, sweeping jets enhance the convective heat transfer close to the impingement center of the target surface; instead, for H / w > 2 the steady jet exhibits superior heat transfer performance near the stagnation region, while the sweeping jets generate a more uniformly distributed region of maximum convective heat transfer. Additionally, the analysis of the phase-averaged Nusselt number distributions across the target surface reveals that the maximum convective heat transfer region is situated on its uphill side, close to the stagnation point, resembling the behavior of inclined impinging jets. • The triple decomposition technique is used to perform phase-averaged measurements. • For 0.5 ≤ H/w ≤ 1.5 the sweeping jet outperforms the steady jet. • The region of greater N u Φ is located on the uphill side of the target surface. • For H/w>2 the sweeping jet generates lower heat transfer near the impingement center. • By reducing g/w, the oscillation amplitude decreases while the frequency increases.

Topics & Concepts

NozzleMechanicsChannel (broadcasting)Heat transferMaterials scienceJet (fluid)Transfer (computing)PhysicsThermodynamicsComputer scienceTelecommunicationsParallel computingHeat Transfer MechanismsFluid Dynamics and Turbulent FlowsAerodynamics and Acoustics in Jet Flows
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