Abstract
A realistic internal cooling system of a turbine blade includes both ribs and pin-fins inside the passages to enhance the heat transfer. However, the majority studies in the open literature assessing the heat transfer characteristics on a simplified cooling model by examining ribbed-roughen passages and pin-finned passage separately. This work presents the high-resolution heat transfer coefficients of a scaled realistic turbine blade internal cooling design. The cooling system, using a 3D-printed plastic material, consists of an S-shaped inlet, four serpentine passages (three U-bends) of variable aspect ratio, and the trailing edge ejection. Angled ribs are implemented inside the passages and the elongated fins and pins are used near the trailing edge. Two dust holes are realized on the blade tip, the injections are individually controlled to reflect the realistic coolant flowrate variation inside the entire internal cooling system. The tests are conducted at two Reynolds number, 45,000 and 60,000 based on the hydraulic diameter of the inlet passage. Transient heat transfer technique using thermochromic liquid crystal is applied to obtain the detailed heat transfer characteristic inside the cooling channel. The local and averaged Nusselt numbers are also compared with the correlations in the open literature. This paper provides gas turbine designers the difference of local heat transfer distributions between the realistic and simplified internal cooling designs.
Issue Section:
Research Papers
References
1.
Han
, J. C.
, Dutta
, S.
, and Ekkad
, S. V.
, 2012
, Gas Turbine Heat Transfer and Cooling Technology
, 2nd ed., CRC Press
, Boca Raton, FL
.2.
Han
, J. C.
, 2018
, “Advanced Cooling in Gas Turbines 2016 Max Jakob Memorial Award Paper
,” ASME J. Heat Trans.
, 140
(11
), p. 113001
. 10.1115/1.40396443.
Han
, J. C.
, 1988
, “Heat Transfer and Friction Characteristics in Rectangular Channels With Rib Turbulators
,” ASME J. Heat Trans.
, 110
(2
), pp. 321
–328
. 10.1115/1.32504874.
Han
, J. C.
, Park
, J. S.
, and Ibrahim
, M. Y.
, 1986
, “Measurement of Heat Transfer and Pressure Drop in Rectangular Channels With Turbulence Promoters
,” NASA Contractor Report 4015; AVSCOM Technical Report 86-C-25, pp. 1
–197
.5.
Han
, J. C.
, and Park
, J. S.
, 1988
, “Developing Heat Transfer in Rectangular Channels With Rib Turbulators
,” Int. J. Heat Mass Trans.
, 31
(1
), pp. 183
–195
. 10.1016/0017-9310(88)90235-96.
Park
, J. S.
, Han
, J. C.
, Huang
, Y.
, Ou
, S.
, and Boyle
, R. J.
, 1992
, “Heat Transfer Performance Comparisons of Five Different Rectangular Channels With Parallel Angled Ribs
,” Int. J. Heat Mass Trans.
, 35
(11
), pp. 2891
–2903
. 10.1016/0017-9310(92)90309-G7.
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 Trans.
, 131
(7
), p. 071703
. 10.1115/1.30908188.
Rallabandi
, A. P.
, Alkhamis
, N.
, and Han
, J. C.
, 2011
, “Heat Transfer and Pressure Drop Measurements for a Square Channel With 45 Deg Round-Edged Ribs at High Reynolds Numbers
,” ASME J. Turbomach.
, 133
(3
), p. 031019
. 10.1115/1.40012439.
Fan
, C. S.
, and Metzger
, D. E.
, 1987
, “Effects of Channel Aspect Ratio on Heat Transfer in Rectangular Passage Sharp 180-Deg Turns
,” ASME
Paper No. 87-GT-113.10.
Han
, J. C.
, Chandra
, P. R.
, and Lau
, S. C.
, 1988
, “Local Heat/Mass Transfer Distributions Around Sharp 180 Deg Turns in Two-Pass Smooth and Rib-Roughened Channels
,” ASME J. Heat Trans.
, 110
(1
), pp. 91
–98
. 10.1115/1.325047811.
Schabacker
, J.
, Bölcs
, A.
, and Johnson
, B. V.
, 1998
, “PIV Investigation of the Flow Characteristics in an Internal Coolant Passage With Two Ducts Connected by a Sharp 180° Bend
,” ASME
Paper No. 98-GT-544.12.
Cheah
, S. C.
, Iacovides
, H.
, Jackson
, D. C.
, Ji
, H.
, and Launder
, B. E.
, 1996
, “LDA Investigation of the Flow Development Through Rotating U-Ducts
,” ASME J. Turbomach.
, 118
(3
), pp. 590
–596
. 10.1115/1.283670613.
Liou
, T. M.
, and Chen
, C. C.
, 1999
, “Heat Transfer in a Rotating Two-Pass Smooth Passage With a 180° Rectangular Turn
,” Int. J. Heat Mass Trans.
, 42
(2
), pp. 231
–247
. 10.1016/S0017-9310(98)00148-314.
Metzger
, D. E.
, Berry
, R. A.
, and Bronson
, J. P.
, 1982
, “Developing Heat Transfer in Rectangular Ducts With Staggered Arrays of Short Pin Fins
,” ASME J. Heat Trans.
, 104
(4
), pp. 700
–706
. 10.1115/1.324518815.
Metzger
, D. E.
, Fan
, C.
, and Haley
, S.
, 1984
, “Effects of Pin Shape and Array Orientation on Heat Transfer and Pressure Loss in Pin Fin Arrays
,” ASME J. Eng. Gas Turbines Power
, 106
(1
), pp. 252
–257
. 10.1115/1.323954516.
Brigham
, B. A.
, and VanFossen
, G. J.
, 1984
, “Length to Diameter Ratio and Row Number Effects in Short Pin Fin Heat Transfer
,” ASME J. Eng. Gas Turbines Power
, 106
(1
), pp. 241
–245
. 10.1115/1.323954117.
Chyu
, M.
, Hsing
, Y.
, and Natarajan
, V.
, 1998
, “Convective Heat Transfer of Cubic Fin Arrays in a Narrow Channel
,” ASME J. Turbomach.
, 120
(2
), pp. 362
–367
. 10.1115/1.284141418.
Chyu
, M. K.
, Hsing
, Y. C.
, Shih
, T. I.-P.
, and Natarajan
, V.
, 1999
, “Heat Transfer Contributions of Pins and Endwall in Pin-Fin Arrays: Effects of Thermal Boundary Condition Modeling
,” ASME J. Turbomach.
, 121
(2
), pp. 257
–263
. 10.1115/1.284130919.
Uzol
, O.
, and Camci
, C.
, 2005
, “Heat Transfer, Pressure Loss and Flow Field Measurements Downstream of Staggered Two-Row Circular and Elliptical Pin Fin Arrays
,” ASME J. Heat Trans.
, 127
(5
), pp. 458
–471
. 10.1115/1.186056320.
Jenkins
, S. C.
, Shevchuk
, I. V.
, Wolfersdorf
, J.
, and Weigand
, B.
, 2007
, “Transient Thermal Field Measurements in a High Aspect Ratio Channel Related to Transient Thermochromic Liquid Crystal Experiments
,” ASME
Paper No. GT2007-27812.21.
Lamont
, J. A.
, Ekkad
, S. V.
, and Alvin
, M. A.
, 2012
, “Detailed Heat Transfer Measurements Inside Rotating Ribbed Channels Using the Transient Liquid Crystal Technique
,” ASME J. Thermal Sci. Eng. Appl.
, 4
(1
), p. 011002
. 10.1115/1.400560422.
Lamont
, J. A.
, Ekkad
, S. V.
, and Alvin
, M. A.
, 2014
, “Effect of Rotation on Detailed Heat Transfer Distribution for Various Rib Geometries in Developing Channel Flow
,” ASME J. Heat Trans.
, 136
(1
), p. 011901
. 10.1115/1.402521123.
Yang
, L.
, Tyagi
, K.
, Ekkad
, S. V.
, and Ren
, J.
, 2015
, “Influence of Rotation on Heat Transfer in a Two-Pass Channel With Impingement Under High Reynolds Number
,” ASME
Paper No. GT2015-42871.24.
Mayo
, I.
, Lahalle
, A.
, Gori
, G. L.
, and Arts
, T.
, 2016
, “Aerothermal Characterization of a Rotating Ribbed Channel at Engine Representative Conditions-Part II: Detailed Liquid Crystal Thermography Measurements
,” ASME J. Turbomach.
, 138
(10
), p. 101009
. 10.1115/1.403292725.
Huang
, S. C.
, Wang
, C. C.
, and Liu
, Y. H.
, 2017
, “Heat Transfer Measurement in a Rotating Cooling Channel With Staggered and Inline Pin-Fin Arrays Using Liquid Crystal and Stroboscopy
,” Int. J. Heat Mass Trans.
, 115
(Part A
), pp. 364
–376
. 10.1016/j.ijheatmasstransfer.2017.07.04026.
Singh
, P.
, and Ekkad
, S. V.
, 2017
, “Experimental Investigation of Rotating Rib Roughened Two-Pass Square Duct With Two Different Channel Orientations
,” ASME
Paper. No. GT2017-64225.27.
Singh
, P.
, Ji
, Y.
, and Ekkad
, S. V.
, 2018
, “Multi-Pass Serpentine Cooling Designs for Negating Coriolis Force Effect on Heat Transfer: 45-Degree Angled Rib Turbulated Channels
,” ASME
Paper. No. GT2018-76689.28.
Hung
, S. C.
, Huang
, S. C.
, and Liu
, Y. H.
, 2018
, “Influences of the Non-Uniform Pin-Fin Array on Heat Transfer Distribution in A Rotating Rectangular Channel
,” ASME
Paper No. GT2018-76372.29.
Funazaki
, K.
, Ishizawa
, K.
, and Yamawaki
, S.
, 1998
, “Surface Heat Transfer Measurements of a Scaled Rib Roughened Serpentine Cooling Passage by Use of a Transient Liquid Crystal Technique
,” ASME
Paper No. 98-GT-515.30.
Poser
, R.
, Von Wolfersdorf
, J.
, Lutum
, E.
, and Semmler
, K.
, 2008
, “Performing Heat Transfer Experiments in Blade Cooling Circuits Using a Transient Technique With Thermochromic Liquid Crystals
,” ASME Paper No. GT2008-50364.31.
LeBlanc
, C.
, Ekkad
, S. V.
, Lambert
, T.
, and Rajendran
, V.
, 2011
, “Detailed Heat Transfer Distributions in Engine Similar Cooling Channels for a Turbine Rotor Blade With Different Rib Orientation
,” ASME
Paper No. GT2011-45254.32.
Siw
, S. C.
, Chyu
, M. K.
, Um
, J. Y.
, and Lee
, C. P.
, 2016
, “Detailed Experimental Characterization of Heat Transfer Coefficient Over the Internal Cooling Passages of an Additive Manufactured Turbine Airfoil
,” ASME
Paper No. GT2016-57787.33.
Funazaki
, K.
, Odagiri
, H.
, Horiuchi
, T.
, and Kazari
, M.
, 2018
, “Detailed Studies on The Flow Field and Heat Transfer Characteristics Inside a Realistic Serpentine Cooling Channel With a S-Shaped Inlet
,” ASME
Paper No. GT2018-76225.34.
Song
, I.
, Son
, C.
, Yang
, J.
, Lee
, C.
, and Lee
, K.
, 2018
, “Thermal Performance of the Realistic Leading Edge Cooling Passage of a Turbine Blade
,” ASME
Paper No. GT2018-77217.35.
Park
, N.
, Son
, C.
, Yang
, J.
, Lee
, C.
, and Lee
, K.
, 2018
, “Full Surface Heat Transfer Measurement of a Turbine Internal Cooling System Using a Large Scaled Model
,” ASME
Paper No. GT2018-77218.36.
Kline
, S. J.
, and McClintock
, F. A.
, 1953
, “Describing Uncertainties in a Single Sample Experiment
,” Mech. Eng. (Am. Soc. Mech. Eng.)
, 75
, pp. 3
–8
.Copyright © 2019 by ASME
You do not currently have access to this content.
