Combustor Turbine Interface Studies—Part 1: Endwall Effectiveness Measurements-Reference-Cited by-同舟云学术

Combustor Turbine Interface Studies—Part 1: Endwall Effectiveness Measurements

Published:2003-04-01 Issue:2 Volume:125 Page:193-202
ISSN:0889-504X
Container-title:Journal of Turbomachinery
language:en
Short-container-title:

Author:

Colban W. F.¹,Thole K. A.¹,Zess G.²

Affiliation:

1. Mechanical Engineering Department, Virginia Polytechnic Institute and State University, Blacksburg, VA 24061

2. Pratt and Whitney, East Hartford, CT 06108

Abstract

Improved durability of gas turbine engines is an objective for both military and commercial aeroengines as well as for power generation engines. One region susceptible to degradation in an engine is the junction between the combustor and first vane given that the main gas path temperatures at this location are the highest. The platform at this junction is quite complex in that secondary flow effects, such as the leading edge vortex, are dominant. Past computational studies have shown that the total pressure profile exiting the combustor dictates the development of the secondary flows that are formed. This study examines the effect of varying the combustor liner film-cooling and junction slot flows on the adiabatic wall temperatures measured on the platform of the first vane. The experiments were performed using large-scale models of a combustor and nozzle guide vane in a wind tunnel facility. The results show that varying the coolant injection from the upstream combustor liner leads to differing total pressure profiles entering the turbine vane passage. Endwall adiabatic effectiveness measurements indicate that the coolant does not exit the upstream combustor slot uniformly, but instead accumulates along the suction side of the vane and endwall. Increasing the liner cooling continued to reduce endwall temperatures, which was not found to be true with increasing the film-cooling from the liner.

Publisher

ASME International

Subject

Mechanical Engineering

Link

http://asmedigitalcollection.asme.org/turbomachinery/article-pdf/125/2/193/5757931/193_1.pdf

Reference15 articles.

1. Langston, L. S. , 1980, “Crossflows in a Turbine Cascade Passage,” ASME J. Eng. Power, 102, pp. 866–874.

2. Blair, M. F. , 1974, “An Experimental Study of Heat Transfer and Film Cooling on Large-Scale Turbine Endwalls,” ASME J. Heat Transfer, Nov., pp. 524–529.

3. Granser, D., and Schulenberg, T., 1990, “Prediction and Measurement of Film Cooling Effectiveness for a First-Stage Turbine Vane Shroud,” 90-GT-95.

4. Burd, S. W., and Simon, T. W., “Effects of Slot Bleed Injection over a Contoured Endwall on Nozzle Guide Vane Cooling Performance: Part I: Flow Field Measurements,” ASME Paper No. 2000-GT-199.

5. Burd, S. W., Satterness, C. J., and Simon, T. W., “Effects of Slot Bleed Injection over a Contoured Endwall on Nozzle Guide Vane Cooling Performance: Part II: Thermal Measurements,” 2000-GT-200.

Cited by 41 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. The effect of changing the combustion chamber head structure on turbine blades under thermal shock test;International Journal of Thermal Sciences;2024-11

2. Effect of Misalignment at the Flat and Profiled Endwall of Nozzle Guide Vane on Heat Transfer;International Journal of Heat and Mass Transfer;2024-09

3. The Effect of Changing the Combustion Chamber Head Structure on Turbine Blades Under Thermal Shock Test;2024

4. Turbine Vane Passage Cooling Experiments With a Close-Coupled Combustor–Turbine Interface Geometry Part II: Describing the Coolant Coverage;Journal of Turbomachinery;2023-08-02

5. Turbine Vane Passage Experiments Documenting Evolution of Secondary Flows With Changes in Combustor Coolant Injection Flowrates;Journal of Turbomachinery;2023-01-09