High-pressure stage gas turbine blades feature serpentine passages where rib turbulators are installed to enhance heat transfer between the relatively colder air bled off from the compressor and the hot internal walls. Most of the prior studies have been restricted to Reynolds number of 90,000 and several studies have been carried out to determine geometrically optimized parameters for achieving high levels of heat transfer in this range of Reynolds number. However, for land-based power generation gas turbines, the Reynolds numbers are significantly high and vary between 105 and 106. The present study is targeted toward these high Reynolds numbers where traditional rib turbulator shapes and prescribed optimum geometrical parameters have been investigated experimentally. A steady-state liquid crystal thermography technique is employed for measurement of detailed heat transfer coefficient. Five different rib configurations, viz., 45 deg, V-shaped, inverse V-shaped, W-shaped, and M-shaped have been investigated for Reynolds numbers ranging from 150,000 to 400,000. The ribs were installed on two opposite walls of a straight duct with an aspect ratio of unity. For very high Reynolds numbers, the heat transfer enhancement levels for different rib shapes varied between 1.4 and 1.7 and the thermal hydraulic performance was found to be less than unity.
Issue Section:
Research Papers
References
1.
Han
, J. C.
, Dutta
, S.
, and Ekkad
, S.
, 2012
, Gas Turbine Heat Transfer and Cooling Technology
, CRC Press
, Boca Raton, FL
.2.
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 Transf.
, 21
(8
), pp. 1143
–1156
. 3.
Kiml
, R.
, Mochizuki
, S.
, and Murata
, A.
, 2001
, “Effects of Rib Arrangements on Heat Transfer and Flow Behavior in a Rectangular Rib-Roughened Passage: Application to Cooling of Gas Turbine Blade Trailing Edge
,” ASME J. Heat Transfer
, 123
(4
), pp. 675
–681
. 4.
Casarsa
, L.
, Cakan
, M.
, and Arts
, T.
, 2002
, “Characterization of the Velocity and Heat Transfer Fields in an Internal Cooling Channel With High Blockage Ratio
,” ASME
Paper No. GT-2002-30207. 5.
Rau
, G.
, Çakan
, M.
, Moeller
, D.
, and Arts
, T.
, 1998
, “The Effect of Periodic Ribs on Local Aerodynamic and Heat Transfer Performance of a Straight Cooling Channel
,” ASME J. Turbomach.
, 120
(2
), pp. 368
–375
. 6.
Han
, J. C.
, 1984
, “Heat Transfer and Friction in Channels With Two Opposite Rib-Roughened Walls
,” ASME J. Heat Transfer
, 106
(4
), pp. 774
–781
. 7.
Han
, J. C.
, Huang
, J. J.
, and Lee
, C. P.
, 1993
, “Augmented Heat Transfer in Square Channels With Wedge-Shaped and Delta-Shaped Turbulence Promoters
,” J. Enhanced Heat Transfer
, 1
(1
), pp. 37
–52
. 8.
Lau
, S. C.
, Kukreja
, R. T.
, and McMillin
, R. D.
, 1991
, “Effects of V-Shaped Rib Arrays on Turbulent Heat Transfer and Friction of Fully Developed Flow in a Square Channel
,” Int. J. Heat Mass Transfer
, 34
(7
), pp. 1605
–1616
. 9.
Jia
, R. G.
, Saidi
, A.
, and Aundwn
, B.
, 2002
, “Heat Transfer Enhancement in Square Ducts With V-Shaped Ribs of Various Angles
,” ASME Turbo.
, 3
, pp. 469
–476
. 10.
Singh
, P.
, Ji
, Y.
, Zhang
, M.
and Ekkad
, S. V.
, 2017
, “Heat Transfer Enhancement by Criss-Cross Pattern Formed by 45° Angled Rib Turbulators in a Straight Square Duct
,” ASME 2017 Heat Transfer Summer Conference
, ASME
Paper No. V001T06A003. 11.
Singh
, P.
, Pandit
, J.
, and Ekkad
, S. V.
, 2017
, “Characterization of Heat Transfer Enhancement and Frictional Losses in a Two-Pass Square Duct Featuring Unique Combinations of Rib Turbulators and Cylindrical Dimples
,” Int. J. Heat Mass Transfer
, 106
, pp. 629
–647
. 12.
Singh
, P.
, Ravi
, B. V.
, and Ekkad
, S.
, 2016
, “Experimental and Numerical Study of Heat Transfer due to Developing Flow in a Two Pass Rib Roughened Square Duct
,” Int. J. Heat Mass Transfer
, 102
, pp. 1245
–1256
. 13.
Singh
, P.
, and Ekkad
, S.
, 2016
, “Effects of Rotation on Heat Transfer due to Jet Impingement on Cylindrical Dimpled Target Surface
,” ASME Turbo Expo 2016: Turbomachinery Technical Conference and Exposition
, ASME
Paper No. V05BT16A010. 14.
Singh
, P.
, and Ekkad
, S. V.
, 2017
, “Effects of Spent Air Removal Scheme on Internal-Side Heat Transfer in an Impingement-Effusion System at Low Jet-to-Target Plate Spacing
,” Int. J. Heat Mass Transfer
, 108
(Part A
), pp. 998
–1010
. 15.
Singh
, P.
, and Ekkad
, S.
, 2017
, “Experimental Study of Heat Transfer Augmentation in a Two-Pass Channel Featuring V-Shaped Ribs and Cylindrical Dimples
,” Appl. Therm. Eng.
, 116C
, pp. 205
–216
. 16.
Leiss
, C.
, 1975
, “Experimental Investigation of Film Cooling With Injection From a Row of Holes for the Application to Gas Turbine Blades
,” ASME J. Eng. Power
, 97
(1
), pp. 21
–27
. 17.
Han
, J. C.
, Zhang
, L.
, and Ou
, S.
, 1993
, “Influence of Unsteady Wake on the Heat Transfer Coefficients From a Gas Turbine Blade
,” ASME J. Heat Transfer
, 115
(4
), pp. 904
–911
. 18.
Han
, J. C.
, 1988
, “Heat Transfer and Friction Characteristics in Rectangular Channels With Rib Tabulators
,” ASME J. Heat Transfer
, 110
(2
), pp. 321
–328
. 19.
Fan
, C. S.
, and Metzger
, D. E.
, 1987
, “Effect of Channel Aspect Ratio on Heat Transfer in Rectangular Passage Sharp 180-deg Turns
,” ASME
Paper No. 87-GT-113.20.
Wagner
, J. H.
, Johnson
, B. V.
, and Hajek
, T. J.
, 1991
, “Heat Transfer in Rotating Passaged With Smooth Walls and Radial Outwards Flow
,” ASME J. Turbomach.
, 113
(1
), pp. 42
–51
. 21.
Han
, J. C.
, Zhang
, P.
, 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
(4
), pp. 872
–880
. 22.
Ekkad
, S. V.
, and Han
, J. C.
, 1997
, “Detailed Heat Transfer Distributions in Two-Pass Square Channels With Rib Turbulators
,” Int. J. Heat Mass Transfer
, 40
(11
), pp. 2525
–2537
. 23.
Jenkins
, S. C.
, Zehnder
, F.
, Shevchuk
, I. V.
, von Wolfersdorf
, J.
, Weigand
, B.
, and Schnieder
, M.
, 2013
, “The Effects of Ribs and Tip Wall Distance on Heat Transfer for a Varying Aspect Ratio Two-Pass Ribbed Internal Cooling Channel
,” ASME J. Turbomach.
, 135
(2
), p. 021001
. 24.
Tanda
, G.
, and Abram
, R.
, 2009
, “Forced Convection Heat Transfer in Channels With Rib Turbulators Inclined at 45 deg
,” ASME J. Turbomach.
, 131
(2
), p. 021012
. 25.
Tanda
, G.
, 2011
, “Effect of Rib Spacing on Heat Transfer and Friction in a Rectangular Channel With 45 Angled Rib Turbulators on One/Two Walls
,” Int. J. Heat Mass Transfer
, 54
(5
), pp. 1081
–1090
. 26.
Rallabandi
, A. P.
, Yang
, H.
, and Han
, J. C.
, 2009
, “Heat Transfer and Pressure Drop Correlations for Square Channels With 45 deg Ribs at High Reynolds Numbers
,” ASME J. Heat Transfer
, 131
(7
), p. 071703
. 27.
Ireland
, P. T.
, and Jones
, T. V.
, 2000
, “Liquid Crystal Measurements of Heat Transfer and Surface Shear Stress
,” Meas. Sci. Technol.
, 11
(7
), p. 969
. 28.
Moffat
, R. J.
, 1985
, “Using Uncertainty Analysis in the Planning of an Experiment
,” ASME Trans. J. Fluids Eng.
, 107
(2
), pp. 173
–178
. 29.
Swamee
, P. K.
, and Jain
, A. K.
, 1976
, “Explicit Equations for Pipe Flow Problems
,” J. Hydraulics Div.
, 102
(5
), pp. 657
–664
.30.
Han
, J. C.
, and Park
, J. S.
, 1988
, “Developing Heat Transfer in Rectangular Channels With Rib Turbulators
,” Int. J. Heat Mass Transfer
, 31
(1
), pp. 183
–195
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