This paper experimentally and numerically investigates the effects of large scale high freestream turbulence intensity and exit Reynolds number on the surface heat transfer distribution of a turbine vane in a 2D linear cascade at realistic engine Mach numbers. A passive turbulence grid was used to generate a freestream turbulence level of 16% and integral length scale normalized by the vane pitch of 0.23 at the cascade inlet. The base line turbulence level and integral length scale normalized by the vane pitch at the cascade inlet were measured to be 2% and 0.05, respectively. Surface heat transfer measurements were made at the midspan of the vane using thin film gauges. Experiments were performed at exit Mach numbers of 0.55, 0.75, and 1.01, which represent flow conditions below, near, and above nominal conditions. The exit Mach numbers tested correspond to exit Reynolds numbers of 9×105, 1.05×106, and 1.5×106 based on a vane chord. The experimental results showed that the large scale high freestream turbulence augmented the heat transfer on both the pressure and suction sides of the vane as compared to the low freestream turbulence case and promoted a slightly earlier boundary layer transition on the suction surface for exit Mach 0.55 and 0.75. At nominal conditions, exit Mach 0.75, average heat transfer augmentations of 52% and 25% were observed on the pressure and suction sides of the vane, respectively. An increased Reynolds number was found to induce an earlier boundary layer transition on the vane suction surface and to increase heat transfer levels on the suction and pressure surfaces. On the suction side, the boundary layer transition length was also found to be affected by increase changes in Reynolds number. The experimental results also compared well with analytical correlations and computational fluid dynamics predictions.

1.
Zimmermann
,
D. R.
, 1979, “
Laser Anemometer Measurements at the Exit of a T63-C20 Combustor
,” NASA Report No. CR-159623.
2.
Van Fossen
,
G. J.
, and
Bunker
,
R. S.
, 2001, “
Augmentation of Stagnation Heat Transfer Due to Turbulence From a DLN Can Combustor
,”
ASME J. Turbomach.
0889-504X,
123
, pp.
140
146
.
3.
Ames
,
F. E.
,
Wang
,
C.
, and
Barbot
,
P. A.
, 2003, “
Measurement and Prediction of the Influence of Catalytic and Dry Low NOx Combustor Turbulence on Vane Surface Heat Transfer
,”
ASME J. Turbomach.
0889-504X,
125
, pp.
221
231
.
4.
Ames
,
F. E.
, 1997, “
The Influence of Large-Scale High Intensity Turbulence on Vane Heat Transfer
,”
ASME J. Turbomach.
0889-504X,
119
, pp.
23
30
.
5.
Ames
,
F. E.
,
Argenziano
,
M.
, and
Wang
,
C.
, 2004, “
Measurement and Prediction of Heat Transfer Distributions on an Aft Loaded Vane Subjected to the Influence of Catalytic and Dry Low NOx Combustor Turbulence
,”
ASME J. Turbomach.
0889-504X,
126
, pp.
139
149
.
6.
Radomsky
,
R.
, and
Thole
,
K. A.
, 2002, “
Detailed Boundary Layer Measurements on a Turbine Stator Vane at Elevated Freestream Turbulence Levels
,”
ASME J. Turbomach.
0889-504X,
124
, pp.
107
118
.
7.
Nealy
,
D. A.
,
Mihelc
,
M. S.
,
Hylton
,
L. D.
, and
Gladden
,
H. J.
, 1990, “
Measurements of Heat Transfer Distribution Over the Surfaces of Highly Loaded Turbine Nozzle Guide Vanes
,”
ASME J. Eng. Gas Turbines Power
0742-4795,
106
, pp.
149
158
.
8.
Arts
,
T.
, and
Lambert de Rouvroit
,
M.
, 1992, “
Aero-Thermal Performance of a Two-Dimensional Highly Loaded Transonic Turbine Nozzle Guide Vane: A Test Case for Inviscid and Viscous Flow Computations
,”
ASME J. Turbomach.
0889-504X,
114
, pp.
147
154
.
9.
Hoffs
,
A.
,
Drost
,
U.
, and
Bolcs
,
A.
, 1996, “
Heat Transfer Measurements on a Turbine Airfoil at Various Reynolds Numbers and Turbulence Intensities Including Effects of Surface Roughness
,” ASME Paper No. GT-1996-169.
10.
Bunker
,
R. S.
, 1997, “
Separate and Combined Effects of Surface Roughness and Turbulence Intensity on Vane Heat Transfer
,” ASME Paper No. GT-1997-135.
11.
Carullo
,
J. S.
,
Nasir
,
S.
,
Cress
,
R. D.
,
Ng
,
W. F.
,
Thole
,
K. A.
,
Zhang
,
L. J.
, and
Moon
,
H. K.
, 2007, “
The Effects of Freestream Turbulence, Turbulence Length Scale, and Exit Reynolds Number on Turbine Blade Heat Transfer in a Transonic Cascade
,” ASME Paper No. GT-2007-27859.
12.
Nix
,
A. C.
,
Diller
,
T. E.
, and
Ng
,
W. F.
, 2007, “
Experimental Measurements and Modeling of the Effects of Large-Scale Freestream Turbulence on Heat Transfer
,”
ASME J. Turbomach.
0889-504X,
129
, pp.
542
550
.
13.
Holmberg
,
D. G.
, and
Diller
,
T. E.
, 2005, “
Simultaneous Heat Flux and Velocity Measurements in a Transonic Turbine Cascade
,”
ASME J. Turbomach.
0889-504X,
127
, pp.
502
506
.
14.
Smith
,
D. E.
,
Bubb
,
J. V.
,
Popp
,
O.
,
Grabowski
,
H. C.
,
Diller
,
T. E.
,
Schetz
,
J. A.
, and
Ng
,
W. F.
, 2000, “
An Investigation of Heat Transfer in a Film Cooled Transonic Turbine Cascade—Part I: Steady Heat Transfer
,” ASME Paper No. 2000-GT-202.
15.
Popp
,
O.
,
Smith
,
D. E.
,
Bubb
,
J. V.
,
Grabowski
,
H. C.
,
Diller
,
T. E.
,
Schetz
,
J. A.
, and
Ng
,
W. F.
, 2000, “
An Investigation of Heat Transfer in a Film Cooled Transonic Turbine Cascade—Part II: Unsteady Heat Transfer
,” ASME Paper No. 2000-GT-203.
16.
Schultz
,
D. L.
, and
Jones
,
T. V.
, 1973, “
Heat Transfer Measurements in Short Duration Hypersonic Facilities
,” AGARD Paper No. AG-165.
17.
Doorly
,
J. E.
, and
Oldfield
,
M. L. G.
, 1987, “
The Theory of Advanced Multi-Layer Thin Film Heat Transfer Gages
,”
Int. J. Heat Mass Transfer
0017-9310,
30
, pp.
1159
1168
.
18.
Dunn
,
M. G.
, 1995, “
The Thin-Film Gage
,”
Von Karman Institute for Fluid Dynamics Lecture Series 1995
.
19.
Joe
,
C. R.
, 1997, “
Unsteady Heat Transfer on the Turbine Research Facility at Wright Laboratory
,” Ph.D. thesis, Syracuse University.
20.
Cress
,
R. D.
, 2006, “
Turbine Blade Heat Transfer Measurements in a Transonic Flow Using Thin Film Gages
,” MS thesis, Virginia Polytechnic Institute and State University.
21.
Moffat
,
R. J.
, 1988, “
Describing Uncertainties in Experimental Results
,”
Exp. Therm. Fluid Sci.
0894-1777,
1
, pp.
3
17
.
22.
Baines
,
W. D.
, and
Peterson
,
E. G.
, 1951, “
An Investigation of Flow Through Screens
,”
Trans. ASME
0097-6822,
73
, pp.
467
480
.
23.
Nix
,
A. C.
,
Smith
,
A. C.
,
Diller
,
T. E.
,
Ng
,
W. F.
, and
Thole
,
K. A.
, 2002, “
High Intensity, Large Length-Scale Freestream Turbulence Generation in a Transonic Turbine Cascade
,” ASME Paper No. GT-2002-30523.
24.
Jones
,
W. P.
, and
Launder
,
B. E.
, 1972, “
The Prediction of Laminarization With a Two-Equation Model of Turbulence
,”
Int. J. Heat Mass Transfer
0017-9310,
15
, pp.
301
314
.
25.
Mayle
,
R. E.
, 1991, “
The Role of Laminar-Turbulent Transition in Gas Turbine Engines
,”
ASME J. Turbomach.
0889-504X,
113
, pp.
509
537
.
26.
Zhang
,
J.
, and
Han
,
J.-C.
, 1994, “
Influence of Mainstream Turbulence on Heat Transfer Coefficient From a Gas Turbine Blade
,”
ASME J. Heat Transfer
0022-1481,
116
, pp.
896
903
.
27.
Ames
,
F. E.
, and
Moffat
,
R. J.
, 1990, “
Heat Transfer With High Intensity, Large Scale Turbulence: The Flat Plate Turbulent Boundary Layer and the Cylindrical Stagnation Point
,” Thermosciences Division of Mechanical Engineering, Stanford University, Report No. HMT-44.
28.
Thole
,
K. A.
, and
Bogard
,
D. G.
, 1995, “
Enhanced Heat Transfer and Skin Friction Due to High Freestream Turbulence
,”
ASME J. Turbomach.
0889-504X,
117
, pp.
418
424
.
29.
Incropera
,
F. P.
, and
DeWitt
,
D. P.
, 2002,
Fundamentals of Heat and Mass Transfer
, 5th ed.,
Wiley
,
New York
.
30.
Dullenkopf
,
K.
, and
Mayle
,
R. E.
, 1995, “
An Account of Free-Stream-Turbulence Length Scale on Laminar Heat Transfer
,”
ASME J. Turbomach.
0889-504X,
117
, pp.
401
406
.
31.
Van Dresar
,
N. T.
, and
Mayle
,
R. E.
, 1989, “
A Quasi-Steady Approach to Leading Edge Heat Transfer Rates
,”
ASME J. Turbomach.
0889-504X,
111
, pp.
483
490
.
32.
Durbin
,
P.
, 1991, “
Near-Wall Turbulence Closure Modeling Without ‘Damping Functions’
,”
Theor. Comput. Fluid Dyn.
0935-4964,
3
, pp.
1
13
.
33.
Pecnik
,
R.
,
Pieringer
,
P.
, and
Sanz
,
W.
, 2005, “
Numerical Investigation of the Secondary Flow of a Transonic Turbine Stage Using Various Turbulence Closures
,” ASME Paper No. GT-2005-68754.
34.
Luo
,
J.
, and
Razinsky
,
E. H.
, 2007, “
Conjugate Heat Transfer Analysis of a Cooled Turbine Vane Using the v2-f Turbulence Model
,”
ASME J. Turbomach.
0889-504X,
129
, pp.
773
781
.
35.
Crawford
,
M. E.
, 1986, “
Simulation Codes for Calculation of Heat Transfer to Convectively-Cooled Turbine Blades
,”
A Set of Four Lectures in Convective Heat Transfer and Film Cooling in Turbomachinery VKI Lecture Series
1986.
You do not currently have access to this content.