Results of second law analysis of experimentally-measured aerodynamic losses are presented for a cambered vane with and without film cooling, including comparisons with similar results from a symmetric airfoil. Included are distributions of local entropy creation, as well as mass-averaged magnitudes of global exergy destruction. The axial chord length of the cambered vane is 4.85 cm, the true chord length is 7.27 cm, and the effective pitch is 6.35 cm. Data are presented for three airfoil Mex distributions (including one wherein the flow is transonic), magnitudes of inlet turbulence intensity from 1.1% to 8.2%, and ks/cx surface roughness values of 0, 0.00108, and 0.00258. The associated second law aerodynamics losses are presented for two different measurement locations downstream of the vane trailing edge (one axial chord length and 0.25 axial chord length). The surface roughness, when present, simulates characteristics of the actual roughness which develops on operating turbine airfoils from a utility power engine, over long operating times, due to particulate deposition and to spallation of thermal barrier coatings. Quantitative surface roughness characteristics which are matched include equivalent sandgrain roughness size, as well as the irregularity, nonuniformity, and the three-dimensional irregular arrangement of the roughness. Relative to a smooth, symmetric airfoil with no film cooling at low Mach number and low freestream turbulence intensity, overall, the largest increases in exergy destruction occur with increasing Mach number, and increasing surface roughness. Important variations are also observed as airfoil camber changes. Progressively smaller mass-averaged exergy destruction increases are then observed with changes of freestream turbulence intensity, and different film cooling conditions. In addition, the dependences of overall exergy destruction magnitudes on mainstream turbulence intensity and freestream Mach number are vastly different as level of vane surface roughness changes. When film cooling is present, overall mass-averaged exergy destruction magnitudes are significantly less than values associated with increased airfoil surface roughness for both the cambered vane and the symmetric airfoil. Dimensional exergy destruction values (associated with wake aerodynamic losses) for the symmetric airfoil with film cooling are then significantly higher than data from the cambered vane with film cooling, when compared at a particular blowing ratio.
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July 2013
Research-Article
Second Law Analysis of Aerodynamic Losses: Results for a Cambered Vane With and Without Film Cooling
Phil Ligrani,
Phil Ligrani
1
Oliver L. Parks Endowed Chair,
Professor of Aerospace and Mechanical Engineering,
Director of Graduate Programs
e-mail: pligrani@slu.edu
Professor of Aerospace and Mechanical Engineering,
Director of Graduate Programs
e-mail: pligrani@slu.edu
1Corresponding author.
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Jae Sik Jin
Jae Sik Jin
Post-Doctoral Research Fellow
Department of Aerospace and Mechanical Engineering,
Parks College of Engineering, Aviation, and Technology,
Department of Aerospace and Mechanical Engineering,
Parks College of Engineering, Aviation, and Technology,
Saint Louis University
,3450 Lindell Boulevard
,McDonnell Douglas Hall, Room 1033A
,St. Louis, MO 63103
Search for other works by this author on:
Phil Ligrani
Oliver L. Parks Endowed Chair,
Professor of Aerospace and Mechanical Engineering,
Director of Graduate Programs
e-mail: pligrani@slu.edu
Professor of Aerospace and Mechanical Engineering,
Director of Graduate Programs
e-mail: pligrani@slu.edu
Jae Sik Jin
Post-Doctoral Research Fellow
Department of Aerospace and Mechanical Engineering,
Parks College of Engineering, Aviation, and Technology,
Department of Aerospace and Mechanical Engineering,
Parks College of Engineering, Aviation, and Technology,
Saint Louis University
,3450 Lindell Boulevard
,McDonnell Douglas Hall, Room 1033A
,St. Louis, MO 63103
1Corresponding author.
Contributed by the International Gas Turbine Institute (IGTI) Division of ASME for publication in the JOURNAL OF TURBOMACHINERY. Manuscript received July 9, 2012; final manuscript received July 17, 2012; published online June 5, 2013. Assoc. Editor: David Wisler.
J. Turbomach. Jul 2013, 135(4): 041013 (14 pages)
Published Online: June 5, 2013
Article history
Received:
July 9, 2012
Revision Received:
July 17, 2012
Citation
Ligrani, P., and Sik Jin, J. (June 5, 2013). "Second Law Analysis of Aerodynamic Losses: Results for a Cambered Vane With and Without Film Cooling." ASME. J. Turbomach. July 2013; 135(4): 041013. https://doi.org/10.1115/1.4007588
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