TY - GEN
T1 - COMPARISONS OF MEASURED BLADE TEMPERATURES WITH PREDICTIONS USING AVAILABLE CORRELATIONS
AU - Bonn, Ethan F.
AU - Gailey, Nicholas L.
AU - Berdanier, Reid A.
AU - Thole, Karen Ann
AU - Arisi, Allan N.
AU - Sung, Andrew
N1 - Publisher Copyright:
Copyright © 2025 by Raytheon Technologies Corporation, Pratt & Whitney division.
PY - 2025
Y1 - 2025
N2 - As turbine inlet temperatures have steadily increased over several decades, turbine blade designs have transformed to accommodate higher gas path temperatures through the addition of internal convective cooling, external film cooling, and protective thermal barrier coatings. First order cooling effectiveness benefits of these different features can be predicted analytically through correlations presented throughout the literature and then validated experimentally. The challenge of recreating engine operating conditions in a laboratory environment means that experiments are typically conducted at scaled conditions which necessitates the use of non-dimensional parameters to relate the experimental results to the engine conditions. For this reason, experiments and corresponding correlations are often developed using scaling approaches with appropriate nondimensional parameters. This study compiles a first-order analysis using experimentally-based correlations to predict cooling effectiveness for true-scale engine blades operated at scaled conditions in a one-stage turbine rig. To validate the correlations, turbine blade temperatures were measured using infrared imaging under rotating blade conditions for increasing levels of blade cooling flow and multiple cooling designs: internal convective only; blades with different thermal barrier coating thicknesses; and blades with internal convection and film-cooling. For purposes of this study, a subset of shaped, compound-angle film holes was evaluated for overall cooling effectiveness and subsequently compared to results achieved from a one-dimensional analysis. Ultimately, this analysis showed the ability of available correlations to accurately predict cooling effectiveness changes within 3% of the experimentally measured values. Additionally, the validated heat transfer correlations were used to, first, infer the cooling benefit by further changing the designs and operating conditions, then, investigate additional heat transfer effects of film cooling. TBC and film cooling were observed to reduce heat flux substantially but improved overall cooling effectiveness with distinct trends from each other when evaluating the heat load parameter.
AB - As turbine inlet temperatures have steadily increased over several decades, turbine blade designs have transformed to accommodate higher gas path temperatures through the addition of internal convective cooling, external film cooling, and protective thermal barrier coatings. First order cooling effectiveness benefits of these different features can be predicted analytically through correlations presented throughout the literature and then validated experimentally. The challenge of recreating engine operating conditions in a laboratory environment means that experiments are typically conducted at scaled conditions which necessitates the use of non-dimensional parameters to relate the experimental results to the engine conditions. For this reason, experiments and corresponding correlations are often developed using scaling approaches with appropriate nondimensional parameters. This study compiles a first-order analysis using experimentally-based correlations to predict cooling effectiveness for true-scale engine blades operated at scaled conditions in a one-stage turbine rig. To validate the correlations, turbine blade temperatures were measured using infrared imaging under rotating blade conditions for increasing levels of blade cooling flow and multiple cooling designs: internal convective only; blades with different thermal barrier coating thicknesses; and blades with internal convection and film-cooling. For purposes of this study, a subset of shaped, compound-angle film holes was evaluated for overall cooling effectiveness and subsequently compared to results achieved from a one-dimensional analysis. Ultimately, this analysis showed the ability of available correlations to accurately predict cooling effectiveness changes within 3% of the experimentally measured values. Additionally, the validated heat transfer correlations were used to, first, infer the cooling benefit by further changing the designs and operating conditions, then, investigate additional heat transfer effects of film cooling. TBC and film cooling were observed to reduce heat flux substantially but improved overall cooling effectiveness with distinct trends from each other when evaluating the heat load parameter.
UR - https://www.scopus.com/pages/publications/105014757165
UR - https://www.scopus.com/pages/publications/105014757165#tab=citedBy
U2 - 10.1115/GT2025-154153
DO - 10.1115/GT2025-154153
M3 - Conference contribution
AN - SCOPUS:105014757165
T3 - Proceedings of the ASME Turbo Expo
BT - Energy Storage; Fans and Blowers; Heat Transfer
PB - American Society of Mechanical Engineers (ASME)
T2 - 70th ASME Turbo Expo 2025: Turbomachinery Technical Conference and Exposition, GT 2025
Y2 - 16 June 2025 through 20 June 2025
ER -