Dynamic Analysis of Flow Field at the End of Combustor Simulator
DOI:
https://doi.org/10.11113/jt.v58.1540Keywords:
Flow fields, gas turbines, dilution holes, film–cooling, cooling holesAbstract
This study was carried out in order to extend database knowledge about the flow field characteristics and define the various flow field contours inside a combustor simulator. The modern gas turbine industries try to get higher engine efficiencies. Brayton cycle is a key to achieve this purpose. According to this cycle industries should increase the turbine inlet temperature to get more engine efficiency and power. However the turbine inlet temperature increasing creates an extremely harsh environment for the downstream critical components such as turbine vanes. In this research a three-dimensional representation of a true Pratt and Whitney aero-engine which studied before in Virginia University was simulated and analyzed to collect essential data. This combustor simulator combined the interaction of two rows of dilution jets, which were staggered in the stream wise direction and aligned in the span wise direction, with that of filmcooling along the combustor liner walls. The overall findings of the study indicate that three-component velocity measurements showed the dilution jet-mainstream interaction produced shear forces and as a result a counter-rotating vortex pair was created. The highest turbulent kinetic energy was found at the top of recirculating region due to the interaction of the second row of dilution jets and mainstream flow. Furthermore, the centers of the counter-rotating vortex pair were spread relatively far apart due to the opposing dilution jets. Along the dilution jet centerline, negative stream wise velocities were measured indicating the recirculation region just downstream of the jet. Into the combustor exit, the acceleration of the flow increased and thereby the uniformity of the velocity profile enhancement was found as well.References
Harrington, M. K., & McWaters, M. A., & Bogard, D. G., & Lemmon,
C. A., & Thole K. A. 2001. Full-Coverage Film Cooling With Short
Normal Injection Holes. Journal of Turbomachinery. 123: 798–805.
Barringer, M. D., & Richard, O. T., & Walter, J. P., & Stitzel, S. M., &
Thole, K. A. 2002. Flow Field Simulations of a Gas Turbine
Combustor. Journal of Turbomachinery. 124: 508–516.
Li, L. & Liu, T. & Peng, X. F. 2005. Flow Characteristics in an
Annular Burner with Fully Film Cooling. Journal of Applied Thermal
Engineering. 25: 3013–3024.
Scrittore, J. J. 2008. Experimental Study of the Effect of Dilution Jets
on Film Cooling Flow in a Gas Turbine Combustor. PhD theses.
Virginia Polytechnic Institute and State University, Virginia. 160.
Peterson, S. D., & Plesniak, M. W. 2002. Short-hole Jet-in-cross Flow
Velocity Field and Its Relationship to Film-cooling Performance.
Experiments in Fluids. 33: 889–898.
Plesniak, M. W. 2006. Noncanonical Short Hole Jets-in-Crossflow for
Turbine Film Cooling. Journal of Applied Mechanics. 73: 474–482.
Ou, S., & Je-Chin, H., & Mehendale, A. B., & Lee, C. P. 1994.
Unsteady Wake Over a Linear Turbine Blade Cascade with Air and
CO2 Film Injection: Part I—Effect on Heat Transfer Coefficients.
Journal of Turbomachinery. 116: 721–729.
Mehendale, A. B., & Je-Chin. H., & Ou, S., & Lee, C. P. 1994.
Unsteady Wake Over a Linear Turbine Blade Cascade with Air and
CO2 Film Injection: Part II—Effect on Film Effectiveness and Heat
Transfer Distributions. Journal of Turbomachinery. 116: 730–737.
Tarchi, L., & Facchini, B., & Maiuolo, F., & Coutandin, D. 2012.
Experimental Investigation on the Effects of a Large Recirculating
Area on the Performance of an Effusion Cooled Combustor Liner.
Journal of Engineering for Gas Turbines and Power. 134:. 041505-1-
-9.
Tarchi, L., & Facchini, B., & Maiuolo, F., & Coutandin, D. 2012.
Experimental Investigation on the Effects of a Large Recirculating
Area on the Performance of an Effusion Cooled Combustor Liner.
Journal of Engineering for Gas Turbines and Power. 134: 041505-1-
-9.
Milanes, D. W., & Kirk, D. R., & Fidkowski, K. J., & Waitz, I. A.
Gas Turbine Engine Durability Impacts of High Fuel-Air Ratio
Combustors: Near Wall Reaction Effects on Film-Cooled BackwardFacing Step Heat Transfer. Journal of Engineering for Gas Turbines
and Power. 128: 318–325.
Baldauf, S., & Schulz, A., & Wittig, S. 2001. High-Resolution
Measurements of Local Heat Transfer Coefficients from Discrete Hole
Film Cooling. Journal of Turbomachinery. 123: 749–757.
Scrittore, J. J., & Thole, K. A., & Burd, S. W. 2007. Investigation of
Velocity Profiles for Effusion Cooling of a Combustor Liner. Journal
of Turbomachinery. 129: 518–526.
Moffat, J. R. 1988. Describing the Uncertainties in Experimental
Results. Exp. Therm. Fluid Sci. 1: 3–17.
Bernsdorf, S., & Rose, M., & Abhari, R. S. 2006. Modeling of Film
Cooling—Part I: Experimental Study of Flow Structure. Journal of
Turbomachinery. 128: 141–149.
Wright, L. M., & McClain, S. T., & Clemenson, M. D. 2011. Effect of
Freestream Turbulence Intensity on Film Cooling Jet Structure and
Surface Effectiveness Using PIV and PSP. Journal of Turbomachinery.
: 041023-1- 041023-12.
Bazdidi Tehrani, F., & Mahmoodi A. A. Finite Element Analysis of
Flow Field in the Single Hole Film Cooling Technique. Annals New
York Academy of Science. 393–400.
Stitzel, S., & Thole, K. A. 2004. Flow Field Computations of
Combustor-Turbine Interactions Relevant to a Gas Turbine Engine.
Journal of Turbomachinery. 126: 122–129.
Scrittore, J. J. 2008. Experimental Study of the Effect of Dilution Jets
on Film Cooling Flow in a Gas Turbine Combustor. PhD theses.
Virginia Polytechnic Institute and State University, Virginia. 160.
Vakil, S. S., & Thole, K. A. 2005. Flow and Thermal Field
Measurements in a Combustor Simulator Relevant to a Gas Turbine
Aero engine. Journal of Engineering for Gas Turbines and Power.
: 257–267.
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