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Volume 113, Issue 3
July 1991
Issue Cover
ISSN 0889-504X
EISSN 1528-8900
In this Issue

Research Papers

Heat Transfer in Rotating Serpentine Passages With Smooth Walls
J. H. Wagner, B. V. Johnson, F. C. Kopper
J. Turbomach. July 1991, 113(3): 321–330. doi: https://doi.org/10.1115/1.2927879
View articletitled, Heat Transfer in Rotating Serpentine Passages With Smooth Walls
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Topics: Heat transfer , Flow (Dynamics) , Buoyancy , Coolants , Heat transfer coefficients , Rotation , Turbine blades , Cooling , Coriolis force , Gas turbines
Parametric and Numerical Study of Fully Developed Flow and Heat Transfer in Rotating Rectangular Ducts
H. Iacovides, B. E. Launder
J. Turbomach. July 1991, 113(3): 331–338. doi: https://doi.org/10.1115/1.2927880
View articletitled, Parametric and Numerical Study of Fully Developed Flow and Heat Transfer in Rotating Rectangular Ducts
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Topics: Ducts , Flow (Dynamics) , Heat transfer , Reynolds number , Pressure , Turbulence , Vortices , Suction , Computation , Cross section (Physics)
Heat Transfer Measurements in Rectangular Channels With Orthogonal Mode Rotation
W. D. Morris, G. Ghavami-Nasr
J. Turbomach. July 1991, 113(3): 339–345. doi: https://doi.org/10.1115/1.2927881
View articletitled, Heat Transfer Measurements in Rectangular Channels With Orthogonal Mode Rotation
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Topics: Heat transfer , Rotation , Ducts , Flow (Dynamics) , Coolants , Blades , Buoyancy , Cooling , Forced convection , Gas turbines
An Experimental Investigation of Heat Transfer in an Orthogonally Rotating Channel Roughened With 45 deg Criss-Cross Ribs on Two Opposite Walls
M. E. Taslim, L. A. Bondi, D. M. Kercher
J. Turbomach. July 1991, 113(3): 346–353. doi: https://doi.org/10.1115/1.2927882
View articletitled, An Experimental Investigation of Heat Transfer in an Orthogonally Rotating Channel Roughened With 45 deg Criss-Cross Ribs on Two Opposite Walls
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Topics: Heat transfer , Cooling , Rotation , Heat transfer coefficients , Blades , Circuits , Surface roughness , Turbine blades , Aircraft engines , Creep
An Investigation of Convective Heat Transfer in a Rotating Coolant Channel
J. O. Medwell, W. D. Morris, J. Y. Xia, C. Taylor
J. Turbomach. July 1991, 113(3): 354–359. doi: https://doi.org/10.1115/1.2927883
View articletitled, An Investigation of Convective Heat Transfer in a Rotating Coolant Channel
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Topics: Convection , Coolants , Cooling , Ducts , Equations of motion , Finite element methods , Heat conduction , Heat transfer , Numerical analysis , Turbine blades
Turbulent Heat Transfer and Friction in a Square Channel With Discrete Rib Turbulators
S. C. Lau, R. D. McMillin, J. C. Han
J. Turbomach. July 1991, 113(3): 360–366. doi: https://doi.org/10.1115/1.2927884
View articletitled, Turbulent Heat Transfer and Friction in a Square Channel With Discrete Rib Turbulators
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Topics: Friction , Turbulent heat transfer , Flow (Dynamics) , Heat transfer , Reynolds number , Turning
Heat Transfer Characteristics of Turbulent Flow in a Square Channel With Angled Discrete Ribs
S. C. Lau, R. D. McMillin, J. C. Han
J. Turbomach. July 1991, 113(3): 367–374. doi: https://doi.org/10.1115/1.2927885
View articletitled, Heat Transfer Characteristics of Turbulent Flow in a Square Channel With Angled Discrete Ribs
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Topics: Heat transfer , Turbulence , Pressure drop , Airfoils , Cooling , Flow (Dynamics) , Friction , Gas turbines , Reynolds number , Turbulent heat transfer
Cooling-Air Injection Into Secondary Flow and Loss Fields Within a Linear Turbine Cascade
A. Yamamoto, Y. Kondo, R. Murao
J. Turbomach. July 1991, 113(3): 375–383. doi: https://doi.org/10.1115/1.2927886
View articletitled, Cooling-Air Injection Into Secondary Flow and Loss Fields Within a Linear Turbine Cascade
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Topics: Cascades (Fluid dynamics) , Cooling , Flow (Dynamics) , Turbines , Blades , Internal flow , Kinetic energy , Turbine blades , Vortices
Heat Transfer and Aerodynamics of a High Rim Speed Turbine Nozzle Guide Vane Tested in the RAE Isentropic Light Piston Cascade (ILPC)
S. P. Harasgama, E. T. Wedlake
J. Turbomach. July 1991, 113(3): 384–391. doi: https://doi.org/10.1115/1.2927887
View articletitled, Heat Transfer and Aerodynamics of a High Rim Speed Turbine Nozzle Guide Vane Tested in the RAE Isentropic Light Piston Cascade (ILPC)
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Topics: Aerodynamics , Cascades (Fluid dynamics) , Heat transfer , Nozzle guide vanes , Pistons , Turbines , Mach number , Reynolds number , Chords (Trusses) , Engines
Navier–Stokes Analysis of Turbine Blade Heat Transfer
R. J. Boyle
J. Turbomach. July 1991, 113(3): 392–403. doi: https://doi.org/10.1115/1.2927888
View articletitled, Navier–Stokes Analysis of Turbine Blade Heat Transfer
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Topics: Heat transfer , Turbine blades , Turbulence , Blades , Eddies (Fluid dynamics) , Flow (Dynamics) , Prandtl number , Pressure gradient , Reynolds number , Turbines
Heat Transfer Measurements and Calculations in Transitionally Rough Flow
M. H. Hosni, H. W. Coleman, R. P. Taylor
J. Turbomach. July 1991, 113(3): 404–411. doi: https://doi.org/10.1115/1.2927889
View articletitled, Heat Transfer Measurements and Calculations in Transitionally Rough Flow
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Topics: Flow (Dynamics) , Heat transfer , Surface roughness , Turbulence , Air flow , Boundary layer turbulence , Boundary layers , Computation , Pressure gradient , Skin friction (Fluid dynamics)
The Effect of Incident Wake Conditions on the Mean Heat Transfer of an Airfoil
K. Dullenkopf, A. Schulz, S. Wittig
J. Turbomach. July 1991, 113(3): 412–418. doi: https://doi.org/10.1115/1.2927890
View articletitled, The Effect of Incident Wake Conditions on the Mean Heat Transfer of an Airfoil
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Topics: Airfoils , Heat transfer , Wakes , Cascades (Fluid dynamics) , Blades , Flow (Dynamics) , Boundary layers , Cylinders , Generators , Heat
Laminar Boundary Layer Interaction With an Unsteady Passing Wake
D. E. Paxson, R. E. Mayle
J. Turbomach. July 1991, 113(3): 419–427. doi: https://doi.org/10.1115/1.2927891
View articletitled, Laminar Boundary Layer Interaction With an Unsteady Passing Wake
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Topics: Boundary layers , Wakes , Flow (Dynamics) , Oscillations
More on the Turbulent-Strip Theory for Wake-Induced Transition
R. E. Mayle, K. Dullenkopf
J. Turbomach. July 1991, 113(3): 428–432. doi: https://doi.org/10.1115/1.2927892
View articletitled, More on the Turbulent-Strip Theory for Wake-Induced Transition
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Topics: Strips , Turbulence , Wakes , Flow (Dynamics) , Boundary layers , Dimensional analysis , Wake turbulence
Effects of Vortices With Different Circulations on Heat Transfer and Injectant Downstream of a Single Film-Cooling Hole in a Turbulent Boundary Layer
P. M. Ligrani, C. S. Subramanian, D. W. Craig, P. Kaisuwan
J. Turbomach. July 1991, 113(3): 433–441. doi: https://doi.org/10.1115/1.2927893
View articletitled, Effects of Vortices With Different Circulations on Heat Transfer and Injectant Downstream of a Single Film-Cooling Hole in a Turbulent Boundary Layer
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Topics: Boundary layer turbulence , Film cooling , Heat transfer , Vortices , Flow (Dynamics) , Temperature , Boundary layers , Heat flux
Film-Cooling Effectiveness Downstream of a Single Row of Holes With Variable Density Ratio
A. K. Sinha, D. G. Bogard, M. E. Crawford
J. Turbomach. July 1991, 113(3): 442–449. doi: https://doi.org/10.1115/1.2927894
View articletitled, Film-Cooling Effectiveness Downstream of a Single Row of Holes With Variable Density Ratio
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Topics: Density , Film cooling , Momentum , Jets , Temperature , Coolants , Errors , Heat conduction , Thermocouples
Gas Turbine Film Cooling: Flowfield Due to a Second Row of Holes
A. K. Sinha, D. G. Bogard, M. E. Crawford
J. Turbomach. July 1991, 113(3): 450–456. doi: https://doi.org/10.1115/1.2927895
View articletitled, Gas Turbine Film Cooling: Flowfield Due to a Second Row of Holes
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Topics: Film cooling , Gas turbines , Boundary layers , Density , Jets , Shear stress , Turbulence
Velocity and Temperature Profiles for Stagnation Film Cooling
R. E. Mayle, A. Anderson
J. Turbomach. July 1991, 113(3): 457–463. doi: https://doi.org/10.1115/1.2927896
View articletitled, Velocity and Temperature Profiles for Stagnation Film Cooling
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Topics: Film cooling , Temperature profiles , Flow (Dynamics) , Fluids , Temperature measurement
Effect of Acceleration on the Heat Transfer Coefficient on a Film-Cooled Surface
H. D. Ammari, N. Hay, D. Lampard
J. Turbomach. July 1991, 113(3): 464–471. doi: https://doi.org/10.1115/1.2927897
View articletitled, Effect of Acceleration on the Heat Transfer Coefficient on a Film-Cooled Surface
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Topics: Heat transfer coefficients , Density , Carbon dioxide , Coolants , Flat plates , Mass transfer
The Influence of Curvature on Film Cooling Performance
S. G. Schwarz, R. J. Goldstein, E. R. G. Eckert
J. Turbomach. July 1991, 113(3): 472–478. doi: https://doi.org/10.1115/1.2927898
View articletitled, The Influence of Curvature on Film Cooling Performance
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Topics: Film cooling , Momentum , Density , Flow (Dynamics) , Flow instability , Mass transfer , Pressure gradient
Film Cooling Effectiveness in High-Turbulence Flow
G. W. Jumper, W. C. Elrod, R. B. Rivir
J. Turbomach. July 1991, 113(3): 479–483. doi: https://doi.org/10.1115/1.2927899
View articletitled, Film Cooling Effectiveness in High-Turbulence Flow
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Topics: Film cooling , Flow (Dynamics) , Turbulence , Reynolds number , Cooling , Ejectors , Flat plates
Film Cooling in the Presence of Mainstream Pressure Gradients
A. J. H. Teekaram, C. J. P. Forth, T. V. Jones
J. Turbomach. July 1991, 113(3): 484–492. doi: https://doi.org/10.1115/1.2927900
View articletitled, Film Cooling in the Presence of Mainstream Pressure Gradients
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Topics: Film cooling , Pressure gradient , Boundary layer turbulence , Energy dissipation , Engines , Flat plates , Flow (Dynamics) , Gas turbines , Heat transfer coefficients , Mach number
Effect of Incidence on Wall Heating Rates and Aerodynamics on a Film-Cooled Transonic Turbine Blade
C. Camci, T. Arts
J. Turbomach. July 1991, 113(3): 493–501. doi: https://doi.org/10.1115/1.2927901
View articletitled, Effect of Incidence on Wall Heating Rates and Aerodynamics on a Film-Cooled Transonic Turbine Blade
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Topics: Aerodynamics , Heating , Turbine blades , Cooling , Blades , Convection , Flow (Dynamics) , Heat transfer , Pressure , Suction
Turbine Tip and Shroud Heat Transfer
D. E. Metzger, M. G. Dunn, C. Hah
J. Turbomach. July 1991, 113(3): 502–507. doi: https://doi.org/10.1115/1.2927902
View articletitled, Turbine Tip and Shroud Heat Transfer
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Topics: Heat transfer , Turbines , Blades , Leakage flows , Clearances (Engineering) , Pressure , Flow (Dynamics) , Airfoils , Computation , Cooling
All Issues
Design Guidelines for Inertial Particle Separators
J. Turbomach
Impact of Trailing Edge Damage on Nozzle Guide Vane Aerodynamic Performance
J. Turbomach (October 2025)
An unsteady deposition model for evaluating CMAS nonuniform deposition behavior and aerodynamic performance degradation under hot streak clocking effect
J. Turbomach
HIGH SPEED ROTATING HPT BLADE THERMAL IMAGING OF A FULL SCALE COOLED 1+1/2 STAGE TURBINE IN A SHORT DURATION TRANSIENT TEST FACILITY
J. Turbomach
2024 Associate Editors
J. Turbomach
  • Online ISSN 1528-8900
  • Print ISSN 0889-504X

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