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Proceedings Papers

Proceedings Volume Cover
ASME 1996 International Gas Turbine and Aeroengine Congress and Exhibition
June 10–13, 1996
Birmingham, UK
Conference Sponsors:
  • International Gas Turbine Institute
ISBN:
978-0-7918-7875-0
In This Volume
Volume 4: Heat Transfer; Electric Power; Industrial and Cogeneration

Heat Transfer

Application of Thermochromic Liquid Crystal to Rotating Surfaces
C. Camci, G. Glezer, J. M. Owen, R. G. Pilbrow, B. J. Syson
GT 1996; V004T09A001doi:https://doi.org/10.1115/96-GT-138
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Topics: Liquid crystals , Temperature , Disks , Rotating bodies , Thermocouples , Errors , Rotating disks , Sensors
3-D Numerical Simulation of the Flow Through a Turbine Blade Cascade With Cooling Injection at the Leading Edge
Dieter Bohn, Karsten Kusterer, Harald Schönenborn
GT 1996; V004T09A002doi:https://doi.org/10.1115/96-GT-150
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Topics: Cascades (Fluid dynamics) , Computer simulation , Cooling , Flow (Dynamics) , Turbine blades , Temperature , Blades , Simulation , Pressure , Coolants
The Influence of Rotation on Impingement Cooling
Ch. Mattern, D. K. Hennecke
GT 1996; V004T09A003doi:https://doi.org/10.1115/96-GT-161
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Topics: Impingement cooling , Rotation , Cooling , Geometry , Heat transfer , Jets , Heat , Mass transfer , Reynolds number , Turbine blades
The Role of the Impingement Plate in Array Heat Transfer
Kenneth W. Van Treuren, Zoulan Wang, Peter Ireland, Terry V. Jones, S. T. Kohler
GT 1996; V004T09A004doi:https://doi.org/10.1115/96-GT-162
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Topics: Heat transfer , Temperature , Boundary-value problems , Heat transfer coefficients , Steady state , Engines , Heat flux , Jets , Transients (Dynamics) , Airfoils
Comparison and Prediction of Local and Average Heat Transfer Coefficients Under an Array of Inline and Staggered Impinging Jets
Kenneth W. Van Treuren, Zoulan Wang, Peter Ireland, Terry V. Jones, S. T. Kohler
GT 1996; V004T09A005doi:https://doi.org/10.1115/96-GT-163
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Topics: Heat transfer coefficients , Jets , Heat transfer , Reynolds number , Flow (Dynamics) , Transients (Dynamics) , Wall temperature
A Row of Streamwise-Inclined Jets in Crossflow: Measurements and Calculations
Matthew J. Findlay, Pingfan He, Martha Salcudean, Ian S. Gartshore
GT 1996; V004T09A006doi:https://doi.org/10.1115/96-GT-167
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Topics: Jets , Turbulence , Flow (Dynamics) , Kinetic energy , Computers , Density , Isotropy , Reynolds number , Stress , Temperature
Heat Transfer Measurements on a Turbine Airfoil at Various Reynolds Numbers and Turbulence Intensities Including Effects of Surface Roughness
A. Hoffs, U. Drost, A. Bölcs
GT 1996; V004T09A007doi:https://doi.org/10.1115/96-GT-169
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Topics: Airfoils , Heat transfer , Reynolds number , Surface roughness , Turbines , Turbulence , Liquid crystals , Boundary layers , Cascades (Fluid dynamics) , Mach number
Evaluation of the External Heat Transfer Coefficients in the High-Pressure Turbine of a Full-Scale Core Engine
A. R. Narcus, H. R. Przirembel, F. O. Soechting
GT 1996; V004T09A008doi:https://doi.org/10.1115/96-GT-172
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Topics: Engines , Heat transfer coefficients , High pressure (Physics) , Turbines , Turbine blades , Airfoils , Heat flux , Thermocouples , Accuracy and precision , Calibration
Effect of Aspect Ratio on the Buoyancy Driven Reverse Flow Near the Leading Wall of Rotating Cooling Passages
Prabhat Tekriwal
GT 1996; V004T09A009doi:https://doi.org/10.1115/96-GT-173
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Topics: Buoyancy , Cooling , Flow (Dynamics) , Ducts , Rotation , Temperature , Computation , Computational fluid dynamics , Cross section (Physics) , Design
Flowfield Measurements for Film-Cooling Holes With Expanded Exits
K. Thole, M. Gritsch, A. Schulz, S. Wittig
GT 1996; V004T09A010doi:https://doi.org/10.1115/96-GT-174
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Topics: Film cooling , Cooling , Turbulence , Geometry , Mach number , Blades , Coolants , Density , Gas turbines , Shear (Mechanics)
Influence of a Leaking Gap Downstream of the Injection Holes on Film Cooling Performance
Y. Yu, M. K. Chyu
GT 1996; V004T09A011doi:https://doi.org/10.1115/96-GT-175
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Topics: Film cooling , Leakage , Temperature , Flow (Dynamics) , Heat transfer coefficients , Coolants , Geometry , Heat transfer , Imaging , Liquid crystals
Leading Edge Film Cooling: Computations and Experiments Including Density Effects
Pingfan He, Dragos Licu, Martha Salcudean, Ian S. Gartshore
GT 1996; V004T09A012doi:https://doi.org/10.1115/96-GT-176
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Topics: Computation , Density , Film cooling , Coolants , Blades , Carbon dioxide , Computational fluid dynamics , Heat , Heat transfer , Image segmentation
Compressible, Turbulent, Viscous Flow Computations for Blade Aerodynamic and Heat Transfer
A. A. Boretti
GT 1996; V004T09A013doi:https://doi.org/10.1115/96-GT-178
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Topics: Blades , Computation , Heat transfer , Turbulence , Viscous flow , Reynolds number , Computer simulation , Partial differential equations , Approximation , Boundary layers
Endwall Heat Transfer Measurements in a Transonic Turbine Cascade
P. W. Giel, D. R. Thurman, G. J. Van Fossen, S. A. Hippensteele, R. J. Boyle
GT 1996; V004T09A014doi:https://doi.org/10.1115/96-GT-180
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Topics: Cascades (Fluid dynamics) , Heat transfer , Turbines , Flow (Dynamics) , Mach number , Turbine blades , Boundary layers , Chords (Trusses) , Computational fluid dynamics , Liquid crystals
A Novel Technique for the Internal Blade Cooling
B. Glezer, H. K. Moon, T. O’Connell
GT 1996; V004T09A015doi:https://doi.org/10.1115/96-GT-181
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Topics: Blades , Cooling , Heat transfer , Film cooling , Airfoils , Design , Flow (Dynamics) , Manufacturing , Screws , Swirling flow
Effects of Geometry on Slot–Jet Film Cooling Performance
Daniel G. Hyams, Kevin T. McGovern, James H. Leylek
GT 1996; V004T09A016doi:https://doi.org/10.1115/96-GT-187
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Topics: Film cooling , Geometry , Engineering simulation , Simulation , Density , Flow (Dynamics) , Gas turbines , Heat transfer coefficients , Jets , Physics
Internal Passage Heat Transfer Prediction Using Multiblock Grids and a k-ω Turbulence Model
David L. Rigby, A. A. Ameri, E. Steinthorsson
GT 1996; V004T09A017doi:https://doi.org/10.1115/96-GT-188
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Topics: Heat transfer , Turbulence , Computer simulation , Ducts , Flow (Dynamics) , Reynolds number
Analysis of Gas Turbine Rotor Blade Tip and Shroud Heat Transfer
A. A. Ameri, E. Steinthorsson
GT 1996; V004T09A018doi:https://doi.org/10.1115/96-GT-189
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Topics: Blades , Gas turbines , Heat transfer , Rotors , Boundary layers , Computers , Engineering simulation , Navier-Stokes equations , Rotation , Simulation
Full Surface Local Heat Transfer Coefficient Measurements in a Model of an Integrally Cast Impingement Cooling Geometry
David R. H. Gillespie, Zuolan Wang, Peter T. Ireland, S. Toby Kohler
GT 1996; V004T09A019doi:https://doi.org/10.1115/96-GT-200
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Topics: Geometry , Heat transfer coefficients , Impingement cooling , Cooling , Temperature , Engines , Transients (Dynamics) , Boundary-value problems , Coolants , Flow (Dynamics)
Convective Heat Transfer of Cubic Fin Arrays in a Narrow Channel
M. K. Chyu, Y. C. Hsing, V. Natarajan
GT 1996; V004T09A020doi:https://doi.org/10.1115/96-GT-201
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Topics: Blades , Convection , Cooling , Diamonds , Fins , Heat transfer , Pressure , Shapes
Effect of Periodic Wake Passing on Film Effectiveness of Inclined Discrete Cooling Holes Around the Leading Edge of a Blunt Body
Ken-ichi Funazaki, Eitaro Koyabu, Shigemichi Yamawaki
GT 1996; V004T09A021doi:https://doi.org/10.1115/96-GT-207
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Topics: Cooling , Wakes , Turbulence , Thermocouples , Turbine blades , Density , Flow (Dynamics) , Generators , Liquid crystals , Temperature
Aerodynamic Aspects of Endwall Film-Cooling
S. Friedrichs, H. P. Hodson, W. N. Dawes
GT 1996; V004T09A022doi:https://doi.org/10.1115/96-GT-208
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Topics: Film cooling , Flow (Dynamics) , Coolants , Pressure , Blades , Cascades (Fluid dynamics) , Design , Entropy , Separation (Technology) , Turbines
Fluctuating Thermal Field in the Near Hole Region for Film Cooling Flows
Atul Kohli, David G. Bogard
GT 1996; V004T09A023doi:https://doi.org/10.1115/96-GT-209
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Topics: Film cooling , Flow (Dynamics) , Coolants , Density , Jets , Probability , Temperature , Frequency response , Momentum , Temperature measurement
High-Accuracy Turbine Performance Measurements in Short-Duration Facilities
Charles W. Haldeman, Jr., Michael G. Dunn
GT 1996; V004T09A024doi:https://doi.org/10.1115/96-GT-210
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Topics: Flow (Dynamics) , Inertia (Mechanics) , Pressure , Pressure transducers , Shock (Mechanics) , Temperature , Tunnels , Turbines
Adiabatic Effectiveness and Heat Transfer Coefficient on a Film-Cooled Rotating Blade
Vijay K. Garg
GT 1996; V004T09A025doi:https://doi.org/10.1115/96-GT-221
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Topics: Heat transfer coefficients , Rotating blades , Blades , Pressure , Coolants , Engines , Film cooling , Rotors , Suction , Temperature
Transonic Film-Cooling Investigations: Effects of Hole Shapes and Orientations
S. Wittig, A. Schulz, M. Gritsch, K. A. Thole
GT 1996; V004T09A026doi:https://doi.org/10.1115/96-GT-222
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Topics: Film cooling , Shapes , Coolants , Design , Discharge coefficient , Fluids , Heat transfer coefficients , Mach number , Momentum , Rotation
Comparison of Predicted and Experimental Nusselt Number for a Film-Cooled Rotating Blade
Vijay K. Garg, Reza S. Abhari
GT 1996; V004T09A027doi:https://doi.org/10.1115/96-GT-223
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Topics: Rotating blades , Blades , Film cooling , Computation , Heat transfer , Pressure , Rotors , Turbine blades , Boundary-value problems , Clearances (Engineering)
Prediction of Effectiveness and Heat Transfer Using a New 2-D Injection and Dispersion Model of the Film Cooling Process
S. Neelakantan, M. E. Crawford
GT 1996; V004T09A028doi:https://doi.org/10.1115/96-GT-224
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Topics: Film cooling , Heat transfer , Cross-flow , Databases , Flow (Dynamics)
Applications of Advanced Liquid Crystal Video Thermography to Turbine Cooling Passage Heat Transfer Measurement
Robert P. Campbell, Michael J. Molezzi
GT 1996; V004T09A029doi:https://doi.org/10.1115/96-GT-225
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Topics: Cooling , Heat transfer , Liquid crystals , Thermography , Turbines , Gas turbines , Heat transfer coefficients , Temperature , Thermocouples , Algorithms
Application of Advanced Experimental Techniques in the Development of a Cooled Turbine Nozzle
H. K. Moon, B. Glezer
GT 1996; V004T09A030doi:https://doi.org/10.1115/96-GT-233
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Topics: Nozzles , Turbines , Cooling , Design , Heat transfer , Temperature , Cascades (Fluid dynamics) , Coolants , Heat flux , Heat transfer coefficients
Prediction of Turbulent Flow and Heat Transfer in Rotating Square and Rectangular Smooth Channels
Sandip Dutta, Malcolm J. Andrews, Je-Chin Han
GT 1996; V004T09A031doi:https://doi.org/10.1115/96-GT-234
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Topics: Heat transfer , Turbulence , Coolants , Flow (Dynamics) , Rotation , Vortices , Buoyancy , Pressure , Temperature , Turbine blades
Optimization of Transient Heat Transfer Measurements Using Thermochromic Liquid Crystals Based on an Error Estimation
Rainer Höcker
GT 1996; V004T09A032doi:https://doi.org/10.1115/96-GT-235
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Topics: Errors , Liquid crystals , Optimization , Transient heat transfer , Heat transfer , Boundary-value problems , Transients (Dynamics)
PIV Measurements of Periodically Forced Flat Plate Film Cooling Flows With High Free Stream Turbulence
Sivaram P. Gogineni, Darryl D. Trump, Richard B. Rivir, David J. Pestian
GT 1996; V004T09A033doi:https://doi.org/10.1115/96-GT-236
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Topics: Film cooling , Flat plates , Flow (Dynamics) , Turbulence , Particulate matter , Rotors , Turbines , Wakes
Experimental Measurement and CFD Prediction of Heat Transfer to a Nozzle Guide Vane
Trevor J. Kirsten, Andreas M. Lippert, Glen C. Snedden, Graham D. J. Smith
GT 1996; V004T09A034doi:https://doi.org/10.1115/96-GT-237
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Topics: Computational fluid dynamics , Heat transfer , Nozzle guide vanes , Boundary layers , Blades , Cascades (Fluid dynamics) , Flow (Dynamics) , Temperature , Transients (Dynamics) , Turbulence
Effects of Surface Roughness on Film Cooling
Donald L. Schmidt, Basav Sen, David G. Bogard
GT 1996; V004T09A035doi:https://doi.org/10.1115/96-GT-299
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Topics: Film cooling , Surface roughness , Heat transfer coefficients , Momentum , Heat transfer , Cooling , Density , Flat plates , Geometry , Jets
Predicted Turbine Heat Transfer for a Range of Test Conditions
R. J. Boyle, B. L. Lucci
GT 1996; V004T09A036doi:https://doi.org/10.1115/96-GT-304
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Topics: Heat transfer , Turbines , Blades , Turbulence , Mach number , Rotors
CFD Based Sensitivity Study of Flow Parameters for Engine Like Film Cooling Conditions
Stefan Baldauf, Michael Scheurlen
GT 1996; V004T09A037doi:https://doi.org/10.1115/96-GT-310
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Topics: Computational fluid dynamics , Engines , Film cooling , Flow (Dynamics) , Gas turbines , Cooling , Density , Flat plates , Geometry
Inverse Heat Transfer Engineering Design for Internally Cooled Gas Turbine Airfoils
Francisco J. T. Cunha, David A. DeAngelis
GT 1996; V004T09A038doi:https://doi.org/10.1115/96-GT-312
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Topics: Airfoils , Engineering design , Gas turbines , Heat transfer , Design , Temperature , Coolants , Metals , Optimization , Boundary element methods
Secondary Flow and its Contribution to Heat Transfer Enhancement in a Blade Cooling Passage With Discrete Ribs
Zhengjun Hu, Jiarui Shen
GT 1996; V004T09A039doi:https://doi.org/10.1115/96-GT-313
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Topics: Blades , Cooling , Flow (Dynamics) , Heat transfer , Boundary layers , Design methodology , Engines , Flow visualization , Heat transfer coefficients , Roads
A Systematic Computational Methodology Applied to a Three–Dimensional Film–Cooling Flowfield
Dibbon K. Walters, James H. Leylek
GT 1996; V004T09A040doi:https://doi.org/10.1115/96-GT-351
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Topics: Film cooling , Turbulence , Density , Errors , Flat plates , Gas turbines , Jets , Mesh generation , Modeling , Simulation
Measurements of Heat Transfer Coefficients and Friction Factors in Passages Rib-Roughened on All Walls
M. E. Taslim, T. Li, S. D. Spring
GT 1996; V004T09A041doi:https://doi.org/10.1115/96-GT-355
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Topics: Friction , Heat transfer coefficients , Cavities , Cooling , Blades , Flow (Dynamics) , Gas turbines , Heat transfer , Liquid crystals , Pressure
Rib Heat Transfer Coefficient Measurements in a Rib-Roughened Square Passage
G. J. Korotky, M. E. Taslim
GT 1996; V004T09A042doi:https://doi.org/10.1115/96-GT-356
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Topics: Heat transfer coefficients , Corners (Structural elements) , Boundary-value problems , Friction , Geometry
An Experimental Study of Turbine Vane Heat Transfer With Water-Air Cooling
Nirm V. Nirmalan, John A. Weaver, Larry D. Hylton
GT 1996; V004T09A043doi:https://doi.org/10.1115/96-GT-381
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Topics: Cooling , Heat transfer , Turbines , Water , Airfoils , Coolants , Engines , Flow (Dynamics) , Geometry , Mach number
Characterization and Laboratory Simulation of Turbine Airfoil Surface Roughness and Associated Heat Transfer
David G. Bogard, Donald L. Schmidt, Martin Tabbita
GT 1996; V004T09A044doi:https://doi.org/10.1115/96-GT-386
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Topics: Airfoils , Heat transfer , Simulation , Surface roughness , Turbines , Plates (structures) , Turbulence , Flow (Dynamics) , High pressure (Physics) , Shapes
Rotation Effect on Jet Impingement Heat Transfer in Smooth Rectangular Channels With Four Heated Walls and Radially Outward Cross Flow
J. A. Parsons, J. C. Han, C. P. Lee
GT 1996; V004T09A045doi:https://doi.org/10.1115/96-GT-387
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Topics: Cross-flow , Heat transfer , Rotation , Jets , Coolants , Heat transfer coefficients , Temperature , Flow (Dynamics) , Impingement cooling , Orifices
Computational Prediction of Heat Transfer to Gas Turbine Nozzle Guide Vanes With Roughened Surfaces
S. M. Guo, T. V. Jones, G. D. Lock, S. N. Dancer
GT 1996; V004T09A046doi:https://doi.org/10.1115/96-GT-388
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Topics: Gas turbines , Heat transfer , Nozzle guide vanes , Surface roughness , Heat transfer coefficients , Airfoils , Computation , Damping , Engines , Flow visualization
A Comparison of Full Surface Local Heat Transfer Coefficient and Flow Field Studies Beneath Sharp-Edged and Radiused Entry Impinging Jets
D. R. H. Gillespie, S. M. Guo, Z. Wang, P. T. Ireland, S. T. Kohler
GT 1996; V004T09A047doi:https://doi.org/10.1115/96-GT-428
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Topics: Flow (Dynamics) , Heat transfer coefficients , Jets , Heat transfer , Blades , Casting , Engines , Gages , Gas turbines , Laser cutting
The Ammonia and Diazo Technique With CO2-Calibration for Highly Resolving and Accurate Measurement of Adiabatic Film Cooling Effectiveness With Application to a Row of Holes
W. Haslinger, D. K. Hennecke
GT 1996; V004T09A048doi:https://doi.org/10.1115/96-GT-438
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Topics: Calibration , Carbon dioxide , Film cooling , Electromagnetic scattering , Heat , Mass transfer , Radiation scattering , Scattering (Physics) , Wind
Effects of Free-Stream Turbulence and Surface Roughness on Film Cooling
Donald L. Schmidt, David G. Bogard
GT 1996; V004T09A049doi:https://doi.org/10.1115/96-GT-462
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Topics: Film cooling , Surface roughness , Turbulence , Heat transfer coefficients , Momentum , Turbines , Cooling , Density , Flat plates , Geometry
An Investigation of Heat Transfer by Leading Edge Film Cooling Applying the Naphthalene Sublimation Technique
J. Richter, K. Jung, D. K. Hennecke
GT 1996; V004T09A050doi:https://doi.org/10.1115/96-GT-463
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Topics: Film cooling , Heat transfer , Mass transfer , Cooling , Bubbles , Flow (Dynamics) , Pressure , Separation (Technology) , Smoke , Blades
Heat Transfer in a Two-Pass Internally Ribbed Turbine Blade Coolant Channel With Cylindrical Vortex Generators
Richard G. Hibbs, Sumanta Acharya, Yi Chen, Dimitris E. Nikitopoulos, Tod A. Myrum
GT 1996; V004T09A051doi:https://doi.org/10.1115/96-GT-474
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Topics: Coolants , Generators , Heat transfer , Turbine blades , Vortices , Mass transfer , Reynolds number , Wakes , Geometry , Heat
LDA Study of the Flow Development Through an Orthogonally Rotating U-Bend of Strong Curvature and Rib Roughened Walls
H. Iacovides, D. C. Jackson, H. Ji, G. Kelemenis, B. E. Launder, K. Nikas
GT 1996; V004T09A052doi:https://doi.org/10.1115/96-GT-476
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Topics: Flow (Dynamics) , Rotation , Turbulence , Bubbles , Pressure , Separation (Technology) , Ducts , Suction , Blades , Coolants
An Unsteady Velocity Formulation for the Edge of the Near-Wall Region
Dennis E. Wilson, Anthony J. Hanford
GT 1996; V004T09A053doi:https://doi.org/10.1115/96-GT-478
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Topics: Computation , Cylinders , Flow (Dynamics) , Oscillations , Reynolds number , Spectra (Spectroscopy) , Turbulence
Effect of Rib Height and Pitch on the Thermal Performance of a Passage Disturbed by Detached Solid Ribs
Tong-Miin Liou, Woei-Jiunn Shuy, Yu-Houe Tsao
GT 1996; V004T09A054doi:https://doi.org/10.1115/96-GT-490
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Topics: Clearances (Engineering) , Ducts , Flow visualization , Friction , Heat transfer , Holographic interferometry , Lasers , Pressure measurement , Reynolds number , Turbulent heat transfer
An Experimental Investigation of the Velocity and Temperature Fields of Cold Jets Injected Into a Hot Crossflow
Hans A. Rydholm
GT 1996; V004T09A055doi:https://doi.org/10.1115/96-GT-491
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Topics: Jets , Temperature , Combustion chambers , Cooling , Density , Design , Dimensional analysis , Flow (Dynamics) , Scaling laws (Mathematical physics) , Stress
Discharge Coefficient of Turbine Cooling Holes: A Review
N. Hay, D. Lampard
GT 1996; V004T09A056doi:https://doi.org/10.1115/96-GT-492
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Topics: Cooling , Discharge coefficient , Turbines , Flow (Dynamics) , Evaluation methods , Film cooling , Geometry
Hydrodynamics and Heat Exchange With Wall Jet Cooling of Gas Turbine Blade Internal Spaces
A. V. Soudarev, B. V. Soudarev, N. N. Medvedev, V. V. Medvedev, V. B. Soudarev
GT 1996; V004T09A057doi:https://doi.org/10.1115/96-GT-526
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Topics: Blades , Cooling , Gas turbines , Heat , Hydrodynamics , Space , Flow (Dynamics) , Jets , Convection , Internal flow
Wall-Jet Turbulent Boundary Layer Heat Flux, Velocity, and Temperature Spectra and Time Scales
David G. Holmberg, David J. Pestian
GT 1996; V004T09A058doi:https://doi.org/10.1115/96-GT-529
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Topics: Boundary layer turbulence , Heat flux , Spectra (Spectroscopy) , Temperature , Boundary layers , Fluctuations (Physics) , Flat plates , Flow (Dynamics) , Probes , Turbulence
Gas Temperature Measurement in Internal Cooling Passages
Z. Wang, P. T. Ireland, S. T. Kohler
GT 1996; V004T09A059doi:https://doi.org/10.1115/96-GT-534
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Topics: Cooling , Temperature measurement , Liquid crystals , Crystals , Temperature distribution , Gas turbines , Heat transfer , Nylon fabrics , Temperature
Comparison of k-ε Models in Predicting Heat Transfer and Skin Friction Under High Free Stream Turbulence
Ganesh R. Iyer, Savash Yavuzkurt
GT 1996; V004T09A060doi:https://doi.org/10.1115/96-GT-537
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Topics: Heat transfer , Skin friction (Fluid dynamics) , Turbulence , Boundary layer turbulence , Boundary layers , Energy dissipation , Flat plates , Flow (Dynamics) , Kinetic energy , Partial differential equations
The Effect of Periodic Ribs on the Local Aerodynamic and Heat Transfer Performance of a Straight Cooling Channel
G. Rau, M. Çakan, D. Moeller, T. Arts
GT 1996; V004T09A061doi:https://doi.org/10.1115/96-GT-541
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Topics: Cooling , Heat transfer , Flow (Dynamics) , Ducts , Friction , Pressure , Reynolds number
Heat Transfer Measurements to a Gas Turbine Cooling Passage With Inclined Ribs
Z. Wang, P. T. Ireland, S. T. Kohler, J. W. Chew
GT 1996; V004T09A062doi:https://doi.org/10.1115/96-GT-542
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Topics: Cooling , Gas turbines , Heat transfer , Heat transfer coefficients , Flow (Dynamics) , Computational fluid dynamics , Friction , Transients (Dynamics) , Vortices

Electric Power

2MW Class High Efficiency Gas Turbine IM270 for Co-Generation Plants
Hideo Kobayashi, Shogo Tsugumi, Yoshio Yonezawa, Riuzou Imamura
GT 1996; V004T10A001doi:https://doi.org/10.1115/96-GT-001
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Topics: Cogeneration plants , Gas turbines , Engines , Nitrogen oxides , Air pollution control , Combustion systems , Conceptual design , Cycles , Design engineering , Emergencies
Technology Development Programs for the Advanced Turbine Systems Engine
Ihor S. Diakunchak, Ronald L. Bannister, David J. Huber, D. Frank Roan
GT 1996; V004T10A002doi:https://doi.org/10.1115/96-GT-005
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Topics: Engines , Technology development , Turbines , Advanced materials , Coatings , Combustion , Cooling , Design , Fuels , Nitrogen oxides
Government/Industry Partnership: A Revolutionary Approach in Global Leadership of Advanced Gas Turbines
Sy A. Ali, Charles M. Zeh
GT 1996; V004T10A003doi:https://doi.org/10.1115/96-GT-006
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Topics: Gas turbines , Governments , Leadership , Turbines , Combined heat and power , Design , Electricity (Physics) , Steam
Operation of Combustion Turbines on Alternate Fuel Oils
K. W. Johnson
GT 1996; V004T10A004doi:https://doi.org/10.1115/96-GT-007
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Topics: Combustion , Fuel oils , Turbines , Fuels , Maintenance
Gas Turbine Firing Medium BTU Gas From Gasification Plant
Piero Zanello, Andrea Tasselli
GT 1996; V004T10A005doi:https://doi.org/10.1115/96-GT-008
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Topics: Firing , Fuel gasification , Gas turbines , Engines , Integrated gasification combined cycle power stations , Air flow , Combustion , Control systems , Design , Emissions
A Test Rig for the Realization of Water Recovery in a Steam-Injected Gas Turbine
Xueyou Wen, Jiguo Zou, Zheng Fu, Shikang Yu, Lingbo Li
GT 1996; V004T10A006doi:https://doi.org/10.1115/96-GT-009
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Topics: Gas turbines , Steam , Water reuse , Condensers (steam plant) , Cooling , Design , Filters , Industrial gases , Turbines , Water
The Reduction of Low Frequency Gas Turbine Exhaust Noise: A Case Study
William C. Lucas, George F. Hessler, Jr.
GT 1996; V004T10A007doi:https://doi.org/10.1115/96-GT-010
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Topics: Exhaust systems , Gas turbines , Noise (Sound) , Construction , Cycles , Design , Structures , Teams , Testing , Turbines
H Gas Turbine Combined Cycle Technology and Development Status
James C. Corman
GT 1996; V004T10A008doi:https://doi.org/10.1115/96-GT-011
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Topics: Combined cycles , Gas turbines , Cycles , Energy / power systems , Cooling systems , Design , Design methodology , Exhaust systems , Nitrogen oxides , Operating temperature
GE MS7001 Gas Turbine Advanced Technology Uprate
Michael A. Cocca, Arthur Stappenbeck, James Van Wormer
GT 1996; V004T10A009doi:https://doi.org/10.1115/96-GT-013
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Topics: Gas turbines , Maintenance , Combined cycle power stations , Industrial research , Steam
Designing for High Reliability and Availability in New Combustion Turbines
G. McQuiggan
GT 1996; V004T10A010doi:https://doi.org/10.1115/96-GT-014
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Topics: Combustion , Design , Reliability , Turbines , Process design , Risk analysis
The Advanced Cooling Technology for the 1500 °C Class Gas Turbines: The Steam Cooled Vanes and the Air Cooled Blades
H. Nomoto, A. Koga, S. Ito, Y. Fukuyama, F. Otomo, S. Shibuya, M. Sato, Y. Kobayashi, H. Matsuzaki
GT 1996; V004T10A011doi:https://doi.org/10.1115/96-GT-016
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Topics: Blades , Cooling , Gas turbines , Steam , Wind tunnels , Combined cycle power stations , Combined cycles , Design , Electricity (Physics) , Film cooling
Repowering Fossil Steam Power Plants With Combustion Turbine-Based Technologies
Stanley Pace, Arden Walters
GT 1996; V004T10A012doi:https://doi.org/10.1115/96-GT-020
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Topics: Boilers , Combined cycles , Combustion , Cycles , Economics , Energy generation , Exhaust systems , Feedwater , Gas turbines , Heating
Dutch Experience With Hot Windbox Repowering
P. J. Ploumen, J. J. Veenema
GT 1996; V004T10A013doi:https://doi.org/10.1115/96-GT-250
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Topics: Boilers , Cycles , Emissions , Gas turbines , Heat , Nitrogen oxides , Power stations , Steam , Turbines , Wind
Application of Aeroengine Aerodynamic Design Codes to Industrial Gas Turbine Design
David A. Little, Keith Cobley
GT 1996; V004T10A014doi:https://doi.org/10.1115/96-GT-280
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Topics: Design , Industrial gases , Turbines , Airfoils , Boundary layers , Combined cycles , Diffusion (Physics) , Separation (Technology) , Suction , Engines
User-Oriented Gas Turbine Research at KEMA
R. A. Rooth
GT 1996; V004T10A015doi:https://doi.org/10.1115/96-GT-291
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Topics: Gas turbines , Power stations , Rotors , Blades , Combined cycles , Combustion chambers , Compressors , Creep , Electric power generation , Emissions
Collaborative Advanced Gas Turbine (CAGT) Program Status: An International Initiative to Catalyze an Intercooled Aeroderivative (ICAD) Gas Turbine Launch Order
Barry Davidson, Dan Whitney, Niels Laursen, Art Cohn, George A. Hay, III
GT 1996; V004T10A016doi:https://doi.org/10.1115/96-GT-292
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Topics: Gas turbines , Cycles , Combined cycles , Distributed power generation , Aircraft , Combined heat and power , Engines , Heating , Renewable energy , Stress
Design of the Tempest Industrial Gas Turbine
Kevin R. Scott, Ian G. Amos, Paul D. P. Garbett, Roger G. Wells
GT 1996; V004T10A017doi:https://doi.org/10.1115/96-GT-293
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Topics: Design , Industrial gases , Turbines , Gas turbines , Combined heat and power , Energy generation , Engineering design processes , Engines , Fuels , Machinery
Development of Advanced Gas Turbine
H. Matsuzaki, Y. Suto, Y. Kanazawa, M. Sato, I. Kobayashi, Y. Kobayashi
GT 1996; V004T10A018doi:https://doi.org/10.1115/96-GT-294
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Topics: Gas turbines , Blades , Electricity (Physics) , Combustion chambers , Cooling , Cycles , Firing , Heat resistant materials , High temperature , Liquefied natural gas
Results of Small Gas Turbine for Distributed Generation Strategies Workshop
George A. Hay, III, Art Cohn, Paul Baustista, George Touchton, William Parks, Joseph Darguzas
GT 1996; V004T10A019doi:https://doi.org/10.1115/96-GT-297
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Topics: Distributed power generation , Gas turbines , Workshops (Work spaces) , Public utilities , Architects , Economic analysis , Economics , Electricity (Physics) , Engineers , Feedback
Inlet Conditioning Enhances Performance of Modern Combined Cycle Plants for Cost-Effective Power Generation
Septimus Van Der Linden, David E. Searles
GT 1996; V004T10A020doi:https://doi.org/10.1115/96-GT-298
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Topics: Combined cycle power stations , Energy generation , Gas turbines , Air conditioning , Blades , Coating processes , Coatings , Condensers (steam plant) , Cooling , Cooling towers
Development of the Next Generation 1500°C Class Advanced Gas Turbine for 50Hz Utilities
S. Aoki, Y. Tsukuda, E. Akita, Y. Iwasaki, R. Tomat, M. Rosso, C. Schips
GT 1996; V004T10A021doi:https://doi.org/10.1115/96-GT-314
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Topics: Gas turbines , Public utilities , Design , Combustion , Electricity (Physics) , Turbines , Combined cycles , Power stations
Development of the Sequential Combustion System for the ABB GT24/GT26 Gas Turbine Family
Franz Joos, Philipp Brunner, Burkhard Schulte-Werning, Khawar Syed, Adnan Eroglu
GT 1996; V004T10A022doi:https://doi.org/10.1115/96-GT-315
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Topics: Combustion systems , Gas turbines , Combustion chambers , Cooling , Engines , Boundary-value problems , Combustion , Computational fluid dynamics , Construction , Hardware
Optimum Power Boosting of Gas Turbine Cycles With Refrigerated Inlet Air and Compressor Intercooling
Mohand A. Ait-Ali
GT 1996; V004T10A023doi:https://doi.org/10.1115/96-GT-393
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Topics: Compressors , Cycles , Gas turbines , Temperature , Blades , Cooling , Turbines , Air flow , Compression , High pressure (Physics)
On Calculation and Optimization of Energy Systems
Peter Ortmann, George Gyarmathy
GT 1996; V004T10A024doi:https://doi.org/10.1115/96-GT-394
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Topics: Energy / power systems , Optimization , Gas turbines , Temperature , Compressors , Computers , Cycles , Flue gases , Fuels , Guide vanes
Modular Approach to Off-Design Gas Turbines Simulation: New Prospect for Reheat Applications
Carlo Carcasci, Bruno Facchini, Riccardo Marra
GT 1996; V004T10A025doi:https://doi.org/10.1115/96-GT-395
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Topics: Design , Gas turbines , Simulation , Power stations , Compressors , Stress , Surges
Identification of Best Integrated Combined Cycle Cogeneration Plant
K. Sarabchi, G. T. Polley
GT 1996; V004T10A026doi:https://doi.org/10.1115/96-GT-413
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Topics: Cogeneration plants , Combined cycles , Cogeneration systems , Heat , Steam , Stress
RAM - Performance of Modern Gas Turbines
Axel W. von Rappard, Heinz G. Neuhoff, Salvatore A. Della Villa
GT 1996; V004T10A027doi:https://doi.org/10.1115/96-GT-416
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Topics: Gas turbines , Reliability , Data collection , Emissions , Energy generation , Exhaust systems , Heat , Maintainability , Noise (Sound) , Power stations
The Gas Turbine GT26 in Combined Cycle Application: Conversion of a Coal Power Plant Into a Modern Combined Cycle Firing Natural Gas and Oil No. 2
Viktor Scherer, Dieter Scherer
GT 1996; V004T10A028doi:https://doi.org/10.1115/96-GT-424
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Topics: Coal power , Combined cycles , Firing , Gas turbines , Natural gas , Heat recovery steam generators , Power stations , Steam turbines , Boilers , Coal
Development and Shop Test Results of a New 25–35MW Class Gas Turbine MF-221
K. Takeishi, H. Mori, K. Tsukagoshi, M. Takahama
GT 1996; V004T10A029doi:https://doi.org/10.1115/96-GT-425
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Topics: Gas turbines , Turbines , Compressors , Reliability , Stress , Aerodynamics , Coating processes , Coatings , Cogeneration plants , Combined cycles
The Optimization of Combined Cycle HRSGs as a Function of the Plant Load Duty
P. J. Dechamps
GT 1996; V004T10A030doi:https://doi.org/10.1115/96-GT-497
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Topics: Combined cycles , Heat recovery steam generators , Optimization , Stress , Combined cycle power stations , Energy generation , Gas turbines , Natural gas , Pinch effect , Power stations
Economics of Gas Turbine Inlet Air Cooling System for Power Enhancement
Motoaki Utamura, Yoshio Nishimura, Akira Ishikawa, Nobuo Ando
GT 1996; V004T10A031doi:https://doi.org/10.1115/96-GT-516
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Topics: Cooling systems , Economics , Gas turbines , Cooling , Thermal energy , Combustion , Cycles , Design , Energy / power systems , Energy conversion
Newly Developed Filter Products for Gas Turbine Intake Air Filtration
Thomas Schroth, Antje Rudolph, Carl Freudenberg
GT 1996; V004T10A032doi:https://doi.org/10.1115/96-GT-517
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Topics: Filters , Filtration , Gas turbines , Pressure drop , Air pollution , Combustion , Dust , Embossing , Flow (Dynamics) , Pulsejets
Repowering a Steam Turbine-Generator Power Plant Through Heat Recovery Type Combined Cycle: Selection of the Cycle — A Case Study
H. A. Bazzini
GT 1996; V004T10A033doi:https://doi.org/10.1115/96-GT-530
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Topics: Combined cycles , Cycles , Heat recovery , Power stations , Steam , Turbogenerators , Heat recovery steam generators , Steam turbines , Heat , Pressure
The Travelling Cascade, Constant Volume Heat Exchanger in a Gas Turbine Lead Combined Cycle
Demos P. Georgiou
GT 1996; V004T10A034doi:https://doi.org/10.1115/96-GT-536
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Topics: Cascades (Fluid dynamics) , Combined cycles , Gas turbines , Heat exchangers , Cycles , Cavities , Pressure , Gases , Heat , Temperature
Efficient District Heat Production by Heat Extraction From Combined Cycle Plants
H. Haselbacher, H. U. Frutschi
GT 1996; V004T10A035doi:https://doi.org/10.1115/96-GT-538
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Topics: Central heating , Combined cycle power stations , Heat , Heating , Combined heat and power , Steam

Industrial and Cogeneration

Allison Model 501-KH Industrial Gas Turbine Engine
Ronald P. Porter
GT 1996; V004T11A001doi:https://doi.org/10.1115/96-GT-217
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Topics: Gas turbines , Industrial gases , Engines , Energy generation , Risk , Testing performance
A Unique Approach to HRSG Bypass Dampers
David T. Ryan, Judith A. Veatch, Akber Pasha
GT 1996; V004T11A002doi:https://doi.org/10.1115/96-GT-230
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Topics: Dampers , Heat recovery steam generators , Design , Flow (Dynamics) , Safety , Gas turbines , Exhaust systems , Flow control , Gases , Linkages
Power Plant Simulation Software for Optimizing Thermodynamic and Financial Plant Operation
Patrick R. Griffin, Maher Elmasri, Gwo-Tung Chen, Stephen Kamppila, Frank Basile
GT 1996; V004T11A003doi:https://doi.org/10.1115/96-GT-277
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Topics: Computer software , Power stations , Simulation , Databases , Combined cycle power stations , Control systems , Equipment performance , Instrumentation , Modeling
Evaluation of New Process Options for Co-Generation in the Sugar Industry
M. A. Gabra, B. O. Kjellström
GT 1996; V004T11A004doi:https://doi.org/10.1115/96-GT-301
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Topics: Combined heat and power , Gas turbines , Combined cycles , Electric power generation , Fuels , Municipal solid wastes , Solid wastes , Steam , Steam turbines , Bagasse
A Simultaneous Solution Method Based on a Modular Approach for Power Plant Analyses and Optimized Designs and Operations
Giovanni Cerri
GT 1996; V004T11A005doi:https://doi.org/10.1115/96-GT-302
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Topics: Power stations , Cycles , Design , Machinery , Modular construction , Optimization
Partial Regenerative Steam Injected Gas Turbine
Shigekazu Uji
GT 1996; V004T11A006doi:https://doi.org/10.1115/96-GT-331
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Topics: Gas turbines , Steam , Cycles , Compressors , Cooling , Engines
Dynamic Modeling of Single-Shaft Industrial Gas Turbine
R. Bettocchi, P. R. Spina, F. Fabbri
GT 1996; V004T11A007doi:https://doi.org/10.1115/96-GT-332
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Topics: Dynamic modeling , Industrial gases , Turbines , Gas turbines , Simulation , Transients (Dynamics) , Machinery , Sensors , Steady state
A Methodology for Establishing Optimal Part-Load Operation of Industrial Gas Turbines
Fabio Bozza, Raffaele Tuccillo
GT 1996; V004T11A008doi:https://doi.org/10.1115/96-GT-333
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Topics: Industrial gases , Stress , Turbines , Gas turbines , Emissions , Combined heat and power , Combustion chambers , Compressors , Cycles , Design
Optimal Planning of a Super Waste Incineration Cogeneration Plant
Koichi Ito, Ryohei Yokoyama, Makoto Shimoda
GT 1996; V004T11A009doi:https://doi.org/10.1115/96-GT-384
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Topics: Cogeneration plants , Cycles , Gas turbines , Steam turbines
Thermodynamic Design Point Study of a Semi-Closed Recuperated Intercooled Gas Turbine Combined With a Rankine Bottoming Cycle
Todd S. Nemec, William E. Lear
GT 1996; V004T11A010doi:https://doi.org/10.1115/96-GT-434
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Topics: Cycles , Design , Gas turbines , Thermal efficiency , Air flow , Combined cycles , Combustion chambers , Design engineering , Emissions , Feedwater
CTV: A New Method for Mapping a Full Scale Prototype of an Axial Compressor
Vasco Mezzedimi, Pierluigi Nava, Dave Hamilla
GT 1996; V004T11A011doi:https://doi.org/10.1115/96-GT-535
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Topics: Compressors , Engineering prototypes , Gas turbines , Turbines , Valves , Engine start-up , Inlet guide vanes , Machinery , Nozzles , Pressure
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