A naphthalene sublimation technique is used to investigate convective transport from a simulated turbine blade in a stationary linear cascade. In some of the tests undertaken, a trip wire is stretched along the span of the blade near the leading edge. The disturbance produced by tripping the boundary layers on the blade near the leading edge causes early boundary layer transition, creates high mass transfer rate on the pressure side and in the laminar flow region on the suction side, but lowers the transfer rate in the turbulent flow region on the suction side. Comparison is made with other heat and mass transfer studies in the two-dimensional region far from the endwall and good agreement is found. Near the endwall, flow visualization indicates a strong secondary flow pattern. The impact of vortices initiated near the endwall on the laminar–turbulent transition extends three-dimensional effects to about 0.8 chord lengths on the suction side and to about 0.2 chord lengths on the pressure side away from the endwall. The effect of the passage vortex and the new vortex induced by the passage vortex on mass transfer is clearly seen and can be traced along the suction surface of the blade. Close to the endwall the highest mass transfer rate on the suction surface is not found near the leading edge. It occurs at about 27 percent of the curvilinear distance from the stagnation line to the trailing edge where a strong main flow and the secondary passage flow from the pressure side of the adjacent blade interact. The influences of some small but very intense corner vortices and the passage vortex on mass transfer are also observed on both surfaces of the blade.

1.
Ambrose
D.
,
Lawrenson
I. J.
, and
Sprake
C. H. S.
,
1975
, “
The Vapour Pressure of Naphthalene
,”
Journal of Chemical Thermodynamics
, Vol.
22
, No.
5
, pp.
213
228
.
2.
Arts, T., and Graham, C. G., 1985, “External Heat Transfer Study on a HP Turbine Rotor Blade,” AGARD-CP-390, Heat Transfer and Cooling in Gas Turbines, pp. 5.1–5.6.
3.
Bayley
F. J.
, and
Priddy
W. J.
,
1981
, “
Effects of Free Stream Turbulence Intensity and Frequency on Heat Transfer to Turbine Blading
,”
ASME Journal of Engineering for Power
, Vol.
103
, pp.
60
64
.
4.
Chen, P. H., 1988, “Measurement of Local Mass Transfer From a Gas Turbine Blade,” Ph.D. Thesis, University of Minnesota, Minneapolis, MN.
5.
Chen
P. H.
, and
Goldstein
R. J.
,
1992
, “
Convective Transport Phenomena on the Suction Surface of a Turbine Blade Including the Influence of Secondary Flows Near the Endwall
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
114
, pp.
776
787
.
6.
Cho, H. H., 1992, “Heat/Mass Transfer Flow Through an Array of Holes and Slits,” Ph.D. Thesis, University of Minnesota, Minneapolis, MN.
7.
Eckert, E. R. G., 1976, “Analogies to Heat Transfer Processes,” Measurement in Heat Transfer, E. R. G. Eckert and R. J. Goldstein, eds., Hemisphere Publishing, New York.
8.
Eckert, E. R. G., and Drake, R. M., 1972, Analysis of Heat and Mass Transfer, McGraw-Hill, New York, pp. 293–295, 326–327.
9.
Goldstein
R. J.
, and
Chen
P. H.
,
1987
, “
Film Cooling on a Turbine Blade With Injection Through Two Rows of Holes in the Near-End-Wall Region
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
109
, pp.
588
593
.
10.
Goldstein
R. J.
, and
Spores
R. A.
,
1988
, “
Turbulent Transport on the Endwall in the Region Between Adjacent Turbine Blades
,”
ASME Journal of Heat Transfer
, Vol.
110
, pp.
862
869
.
11.
Graham, R. W., 1990, “Recent Progress in Research Pertaining to Estimates of Gas-Side Heat Transfer in an Aircraft Gas Turbine,” ASME Paper No. 90-GT-100.
12.
Gregory-Smith
D. G.
, and
Cleak
J. G. E.
,
1992
, “
Secondary Flow Measurements in a Turbine Cascade With High Inlet Turbulence
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
114
, pp.
173
183
.
13.
Hain, R., Wang, H. P., Chen, P. H., and Goldstein, R. J., 1991, “A Microcomputer-Controlled Data Acquisition System for Naphthalene Sublimation Measurement,” Proceedings, 11th ABCM Mechanical Engineering Conference, Sao Paulo, Brazil, Dec.
14.
Hazarika, B. K., Raj, R., and Boldman, D. R., 1986, “Three-Dimensional Fluid Flow Phenomena in the Blade End Wall Corner Region,” ASME Paper No. 86-GT-179.
15.
Jabbari
M. J.
,
Goldstein
R. J.
,
Marston
K. C.
, and
Eckert
E. R. G.
,
1992
, “
Three Dimensional Flow at the Junction Between a Turbine Blade and Endwall
,”
Warme- und Stoffubertragung
, Vol.
27
, pp.
51
59
.
16.
Jilek, J., 1986, “An Experimental Investigation of the Three-Dimensional Flow Within Large Scale Turbine Cascade,” ASME Paper No. 86-GT-170.
17.
Joslyn
D.
, and
Dring
R.
,
1992
, “
Three-Dimensional Flow in an Axial Turbine: Part 1—Aerodynamic Mechanisms
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
114
, pp.
61
70
.
18.
Krishnamoorthy, V., 1982, “Effects of Turbulence on the Heat Transfer in a Laminar and Turbulent Boundary Layer Over a Gas Turbine Blade,” ASME Paper No. 82-GT-146.
19.
Langston, L. S., 1990, “Research on Cascade Secondary and Tip-Leakage Flows-Periodicity and Surface Flow Visualization,” AGARD-CP-469, Secondary Flows in Turbomachines.
20.
Marchal, P., and Sieverding, C. H., 1976, “Secondary Flows Within Turbomachinery Bladings,” AGARD-CP-214, Secondary Flows in Turbomachines.
21.
Ota
T.
,
Aiba
S.
,
Tsuruta
T.
, and
Kaga
M.
,
1983
, “
Forced Convection Heat Transfer From an Elliptic Cylinder of Axis Ratio 1:2
,”
Bulletin of the JSME
, Vol.
26
, No.
212
, pp.
262
267
.
22.
Schulz
H. D.
,
Gallus
H. E.
, and
Ladshminarayana
B.
,
1990
, “
Three-Dimensional Separated Flow Field in the Endwall Region of an Annular Compressor Cascade in the Presence of Rotor-Stator Interaction: Part 1—Quasi-Steady Flow and Comparison With Steady-State Data
,”
ASME JOURNAL OF TURBOMACHINERY
, Vol.
112
, pp.
669
678
.
23.
Sieverding
C. H.
,
1985
, “
Recent Progress in the Understanding of Basic Aspects of Secondary Flows in Turbine Blade Passages
,”
ASME Journal of Engineering for Gas Turbine and Power
, Vol.
107
, pp.
248
257
.
24.
Sonoda, T., 1985, “Experimental Investigation on Spatial Development of Streamwise Vortices in a Turbine Inlet Guide Vane Cascade,” ASME Paper No. 85-GT-20.
25.
Sparrow
E. M.
,
Quack
H.
, and
Boerner
C. J.
,
1970
, “
Local Nonsimilarity Boundary-Layer Solutions
,”
AIAA Journal
, Vol.
8
, No.
11
, pp.
1936
1942
.
26.
Wittig, S., Schulz, A., Bauer, H. J., and Sill, K. H., 1985, “Effects of Wakes on the Heat Transfer in Gas Turbine Cascades,” AGARD-CP-390, Heat Transfer and Cooling in Gas Turbines, pp. 6.1–6.13.
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