Parametric Study and Correlation of Racetrack Shaped Jets for Leading Edge Impingement

Kulkarni, Ritwik V.; Wright, Lesley M.

doi:10.1115/1.4054900

Journal of Heat Transfer

2022

DOI: 10.1115/1.4054900

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Parametric Study and Correlation of Racetrack Shaped Jets for Leading Edge Impingement

Ritwik V. Kulkarni

Lesley M. Wright

Abstract: This paper provides a detailed experimental investigation of heat transfer and pressure loss for leading edge jet impingement using square-edged, racetrack jets. Experiments were carried out over various parameters: jet-to-jet spacings (s/d) of 2, 4, 8; jet-to-target surface spacings (z/d) of 2 and 4; jet plate thicknesses (l/d) of 1.33, 2.6, and 4; and Reynolds numbers from 10,000 to 100,000. The results show that pressure loss and heat transfer decrease with increasing s/d and z/d. There is an interesting ob… Show more

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2023

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Cited by 2 publications

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Effect of Microchannel on the Composite Cooling Performance of a Simulated Turbine Blade Leading Edge

Chen

Jun

2023

ASME Journal of Heat and Mass Transfer

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As the turbine blade leading edge becomes one of the hottest regions in the engine, a microchannel structure was applied to further improve the cooling performance. Adiabatic and conjugate heat transfer analyses were conducted to compare the heat transfer and cooling performance of the leading edge with or without microchannels, while the influence of mass flow rate of coolant was also included. Based on the investigations on the effect of geometrical designs, the flow and composite cooling performance of the microchannels were further optimized. The results indicate that the internal heat transfer intensity was greatly enhanced with the arrangement of microchannels, while the adiabatic film coolant coverage was slightly deteriorated. On this basis, the composite cooling performance of the leading edge was effectively improved by at least 7.54%. However, the flow resistance of film cooling holes was obviously increased due to the obstruction of microchannels, and a larger thickness of microchannels would alleviate this feature. In addition, the composite cooling performance of the leading edge was further optimized by increasing the radius of microchannels, and the same effect was achieved by reducing the spanwise distance between the film cooling holes and the micro-jet holes. Compared with the leading edge model without microchannels, the former design increased the area-averaged overall cooling effectiveness of the leading edge by at least 11.17% under all the mass flow rates of coolant studied in this paper, while the latter design improved the composite cooling performance by at least 12.76%.

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Effect of Microchannel on the Composite Cooling Performance of a Simulated Turbine Blade Leading Edge

Chen

Jun

2023

ASME Journal of Heat and Mass Transfer

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Heat Transfer and Pressure Loss Correlations for Leading Edge, Jet Impingement Using Racetrack-Shaped Jets With Filleted Edges

Kulkarni

Wright

2023

ASME Journal of Heat and Mass Transfer

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This paper presents an experimental investigation of heat transfer and pressure loss for leading edge jet impingement using racetrack shaped jets. The majority of literature for gas turbine cooling applications considers jet impingement using square, or sharp-edged orifices. However, the edge of the jet orifices generally has some degree of filleting (or rounding) along the edges, due to casting the airfoils or material wear due to long-term operation. Engineers need data under realistic engine configurations to improve the utilization of coolant while adequately protecting the airfoil. The current experimental study is a parametric investigation of heat transfer and pressure loss for leading edge jet impingement, where the effects of jet Reynolds number (Re = 10,000 - 100,000), jet - to - jet spacing (s/d = 2 - 8), jet - to - target surface spacing (z/d = 2 - 4), surface curvature (D/d = 2.67 - 5.33), and jet fillet - to - jet plate thickness (r/l = 0.16 - 0.5) are each considered. The edge rounding at both the inlet and outlet of the jet plate yields reduced heat transfer compared to the square edged jets. However, the fillets significantly improve the discharge coefficients associated with the racetrack shaped orifices. With the extensive testing completed in this study, design correlations have been developed to predict the surface Nusselt number and discharge coefficients, with 10% and 19% deviation from experimental results, respectively. Engine designers can predict the level of heat transfer and pressure loss for leading edge jet impingement using these correlations.

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Parametric Study and Correlation of Racetrack Shaped Jets for Leading Edge Impingement

Cited by 2 publications

References 21 publications

Effect of Microchannel on the Composite Cooling Performance of a Simulated Turbine Blade Leading Edge

Effect of Microchannel on the Composite Cooling Performance of a Simulated Turbine Blade Leading Edge

Heat Transfer and Pressure Loss Correlations for Leading Edge, Jet Impingement Using Racetrack-Shaped Jets With Filleted Edges

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