Effective cooling of the airfoil leading edge is imperative in gas turbine designs. Among several methods of cooling the leading edge, impingement cooling has been utilized in many modern designs. In this method, the cooling air enters the leading edge cavity from the adjacent cavity through a series of crossover holes on the partition wall between the two cavities. The crossover jets impinge on a smooth leading-edge wall and exit through the film holes, and, in some cases, form a cross flow in the leading-edge cavity and move toward the end of the cavity. It was the main objective of this investigation to measure the heat transfer coefficient on a smooth as well as rib-roughened leading-edge wall. Experimental data for impingement on a leading-edge surface roughened with different conical bumps and radial ribs have been reported by the same authors previously. This investigation, however, deals with impingement on different horseshoe ribs and makes a comparison between the experimental and numerical results. Three geometries representing the leading-edge cooling cavity of a modern gas turbine airfoil with crossover jets impinging on (1) a smooth wall, (2) a wall roughened with horseshoe ribs, and (3) a wall roughened with notched-horseshoe ribs were investigated. The tests were run for a range of flow arrangements and jet Reynolds numbers. The major conclusions of this study were: (a) Impingement on the smooth target surface produced the highest overall heat transfer coefficients followed by the notched-horseshoe and horseshoe geometries. (b) There is, however, a heat transfer enhancement benefit in roughening the target surface. Among the three target surface geometries, the notched-horseshoe ribs produced the highest heat removal from the target surface, which was attributed entirely to the area increase of the target surface. (c) CFD could be considered as a viable tool for the prediction of impingement heat transfer coefficients on an airfoil leading-edge wall.

1.
Burggraf, F., 1970, “Experimental Heat Transfer and Pressure Drop With Two Dimensional Turbulence Promoters Applied to Two Opposite Walls of a Square Tube,” Augmentation of Convective Heat and Mass Transfer, edited by A. E. Bergles and R. L. Webb, ASME, New York, pp. 70–79.
2.
Chandra
,
P. R.
, and
Han
,
J. C.
,
1989
, “
Pressure Drop and Mass Transfer in Two-Pass Ribbed Channels
,”
J. Thermophys. Heat Transfer
,
3
, pp.
315
319
.
3.
El-Husayni
,
H. A.
,
Taslim
,
M. E.
, and
Kercher
,
D. M.
,
1994
, “
An Experimental Investigation of Heat Transfer Coefficients in a Spanwise Rotating Channel With Two Opposite Rib-Roughened Walls
,”
ASME J. Turbomach.
,
113
, pp.
75
82
.
4.
Han
,
J. C.
,
1984
, “
Heat Transfer and Friction in Channels With Two Opposite Rib-Roughened Walls
,”
ASME J. Heat Transfer
,
106
, pp.
774
781
.
5.
Han
,
J. C.
,
Glicksman
,
L. R.
, and
Rohsenow
,
W. M.
,
1978
, “
An Investigation of Heat Transfer and Friction for Rib Roughened Surfaces
,”
Int. J. Heat Mass Transfer
,
21
,
1143
1156
.
6.
Han
,
J. C.
,
Park
,
J. S.
, and
Lei
,
C. K.
,
1985
, “
Heat Transfer Enhancement in Channels With Turbulence Promoters
,”
ASME J. Eng. Gas Turbines Power
,
107
, pp.
628
635
.
7.
Han
,
J. C.
,
Zhang
,
Y. M.
, and
Lee
,
C. P.
,
1992
, “
Influence of Surface Heat Flux Ratio on Heat Transfer Augmentation in Square Channels With Parallel, Crossed, and V-Shaped Angled Ribs
,”
ASME J. Turbomach.
,
114
, pp.
872
880
.
8.
Metzger, D. E., Vedula, R. P., and Breen, D. D., 1987, “The Effect of Rib Angle and Length on Convection Heat Transfer in Rib-Roughened Triangular Ducts,” Proceedings of the ASME-JSME Thermal Engineering Joint Conference, Vol. 3, pp. 327–333.
9.
Metzger, D. E., Chyu, M. K., and Bunker, R. S., 1988, “The Contribution of On-Rib Heat Transfer Coefficients to Total Heat Transfer From Rib-Roughened Surfaces,” Transport Phenomena in Rotating Machinery, edited by J. H. Kim, Hemisphere Publishing Co., Washington, DC.
10.
Metzger, D. E., Fan, C. S., and Yu, Y., 1990, “Effects of Rib Angle and Orientation on Local Heat Transfer in Square Channels With Angled Roughness Ribs,” Compact Heat Exchangers: A Festschrift for A.L. London, Hemisphere Publishing Co., Washington, DC, pp. 151–167.
11.
Taslim, M. E., and Spring, S. D., 1988, “An Experimental Investigation of Heat Transfer Coefficients and Friction Factors in Passages of Different Aspect Ratios Roughened With 45° Turbulators,” Proc. National Heat Conference, Houston, TX.
12.
Taslim, M. E., and Spring, S. D., 1988, “Experimental Heat Transfer and Friction Factors in Turbulated Cooling Passages of Different Aspect Ratios, Where Turbulators are Staggered,” Paper AIAA-88-3014.
13.
Taslim
,
M. E.
,
Bondi
,
L. A.
, and
Kercher
,
D. M.
,
1991
, “
An Experimental Investigation of Heat Transfer in an Orthogonally Rotating Channel Roughened 45 Degree Criss-Cross Ribs on Two Opposite Walls
,”
ASME J. Turbomach.
,
113
, pp.
346
353
.
14.
Taslim, M. E., and Spring, S. D., 1991, “An Experimental Investigation Into the Effects Turbulator Profile and Spacing Have on Heat Transfer Coefficients and Friction Factors in Small Cooled Turbine Airfoils,” Paper AIAA-91-2033.
15.
Taslim
,
M. E.
,
Rahman
,
A.
, and
Spring
,
S. D.
,
1991
, “
An Experimental Investigation of Heat Transfer Coefficients in a Spanwise Rotating Channel With Two Opposite Rib-Roughened Walls
,”
ASME J. Turbomach.
,
113
, pp.
75
82
.
16.
Webb
,
R. L.
,
Eckert
,
E. R. G.
, and
Goldstein
,
R. J.
,
1971
, “
Heat Transfer and Friction in Tubes With Repeated-Rib-Roughness
,”
Int. J. Heat Mass Transfer
,
14
, pp.
601
617
.
17.
Zhang
,
Y. M.
,
Gu
,
W. Z.
, and
Han
,
J. C.
,
1994
, “
Heat Transfer and Friction in Rectangular Channels With Ribbed or Ribbed-Grooved Walls
,”
ASME J. Heat Transfer
,
116
, pp.
58
65
.
18.
Chupp
,
R. E.
,
Helms
,
H. E.
,
McFadden
,
P. W.
, and
Brown
,
T. R.
,
1969
, “
Evaluation of Internal Heat Transfer Coefficients for Impingement Cooled Turbine Blades
,”
J. Aircr.
,
6
, pp.
203
208
.
19.
Metzger
,
D. E.
,
Yamashita
,
T.
, and
Jenkins
,
C. W.
,
1969
, “
Impingement Cooling of Concave Surfaces With Lines of Circular Air Jets
,”
J. Eng. Power
,
93
, pp.
149
155
.
20.
Kercher
,
D. M.
, and
Tabakoff
,
W.
,
1970
, “
Heat Transfer by a Square Array of Round Air Jets Impinging Perpendicular to a Flat Surface Including the Effect of Spent Air
,”
J. Eng. Power
,
92
, pp.
73
82
.
21.
Florschetz
,
L. W.
,
Berry
,
R. A.
, and
Metzger
,
D. E.
,
1980
, “
Periodic Streamwise Variation of Heat Transfer Coefficients for Inline and Staggered of Circular Jets With Crossflow of Spent Air
,”
ASME J. Heat Transfer
,
102
, pp.
132
137
.
22.
Florschetz
,
L. W.
,
Truman
,
C. R.
, and
Metzger
,
D. E.
,
1981
, “
Streamwise Flow and Heat Transfer Distribution for Jet Impingement With Crossflow
,”
ASME J. Heat Transfer
,
103
, pp.
337
342
.
23.
Florschetz
,
L. W.
,
Metzger
,
D. E.
,
Su
,
C. C.
,
Isoda
,
Y.
, and
Tseng
,
H. H.
,
1984
, “
Heat Transfer Characteristics for Jet Arrays Impingement With Initial Crossflow
,”
ASME J. Heat Transfer
,
106
, pp.
34
41
.
24.
Metzger
,
D. E.
, and
Bunker
,
R. S.
,
1990
, “
Local Heat Transfer in Internally Cooled Turbine Airfoil Leading Edge Regions: Part I—Impingement Cooling Without Film Coolant Extraction
,”
ASME J. Turbomach.
,
112
, pp.
451
458
.
25.
Bunker
,
R. S.
, and
Metzger
,
D. E.
,
1990
, “
Local Heat Transfer in Internally Cooled Turbine Airfoil Leading Edge Regions: Part II—Impingement Cooling With Film Coolant Extraction
,”
ASME J. Turbomach.
,
112
, pp.
459
466
.
26.
Van Treuren
,
K. W.
,
Wang
,
Z.
,
Ireland
,
P. T.
, and
Jones
,
T. V.
,
1994
, “
Detailed Measurements of Local Heat Transfer Coefficient and Adiabatic Wall Temperature Beneath an Array of Impinging Jets
,”
ASME J. Turbomach.
,
116
, pp.
269
374
.
27.
Chang, H., Zhang, D., and Huang, T., 1997, “Impingement Heat Transfer From Rib Roughened Surface Within Arrays of Circular Jet: The Effect of the Relative Position of the Jet Hole to the Ribs,” Paper 97-GT-331.
28.
Huang
,
Y.
,
Ekkad
,
S. V.
, and
Han
,
J. C.
,
1998
, “
Detailed Heat Transfer Distributions Under an Array of Orthogonal Impinging Jets
,”
J. Thermophys. Heat Transfer
,
12
, pp.
73
79
.
29.
Akella
,
K. V.
, and
Han
,
J. C.
,
1999
, “
Impingement Cooling in Rotating Two-Pass Rectangular Channels With Ribbed Walls
,”
J. Thermophys. Heat Transfer
,
13
, pp.
364
371
.
30.
Ekkad
,
S. V.
,
Huang
,
Y.
, and
Han
,
J. C.
,
1999
, “
Impingement Heat Transfer on a Target Plate With Film Holes
,”
J. Thermophys. Heat Transfer
,
13
, pp.
522
528
.
31.
Taslim
,
M. E.
,
Setayeshgar
,
L.
, and
Spring
,
S. D.
,
2001
, “
An Experimental Evaluation of Advanced Leading Edge Impingement Cooling Concepts
,”
ASME J. Turbomach.
,
123
, pp.
147
153
.
32.
Taslim, M. E., and Setayeshgar, L., 2001, “Experimental Leading-Edge Impingement Cooling Through Racetrack Crossover Holes,” Paper 2001-GT-0153.
33.
Taslim
,
M. E.
,
Pan
,
Y.
, and
Spring
,
S. D.
,
2001
, “
An Experimental Study of Impingement on Roughened Airfoil Leading-Walls With Film Holes
,”
ASME J. Turbomach.
,
123
, pp.
766
773
.
34.
Taslim, M. E., Pan, Y., and Bakhtari, K., 2002, “Experimental Racetrack Shaped Jet Impingement on a Roughened Leading-Edge Wall With Film Holes,” Paper GT-2002-30477.
35.
Kline, S. J., and McClintock, F. A., 1953, “Describing Uncertainty in Single-Sample Experiments,” Mech. Eng. (Am. Soc. Mech. Eng.) 75, Jan., pp. 3–8.
You do not currently have access to this content.