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ASME 1995 International Gas Turbine and Aeroengine Congress and Exposition

June 5–8, 1995

Houston, Texas, USA

Conference Sponsors:

ISBN:

978-0-7918-7881-1

In This Volume

Heat Transfer (49)
Electric Power (24)
Industrial and Cogeneration (18)

Volume 4: Heat Transfer; Electric Power; Industrial and Cogeneration

Heat Transfer

Distribution of Film-Cooling Effectiveness on a Turbine Endwall Measured Using the Ammonia and Diazo Technique

S. Friedrichs, H. P. Hodson, W. N. Dawes

GT 1995; V004T09A001https://doi.org/10.1115/95-GT-001

Abstract

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Topics: Film cooling , Turbines , Coolants , Flow (Dynamics) , Calibration , Cascades (Fluid dynamics) , Coating processes , Coatings , Cooling , Design

Effect of Velocity and Temperature Distribution at the Hole Exit on Film Cooling of Turbine Blades

Vijay K. Garg, Raymond E. Gaugler

GT 1995; V004T09A002https://doi.org/10.1115/95-GT-002

Abstract

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Topics: Film cooling , Temperature distribution , Turbine blades , Rotors , Blades , Coolants , Heat transfer coefficients , Pressure , Suction , Cooling

Heat Transfer and Film Cooling Effectiveness in a Linear Airfoil Cascade

N. Abuaf, R. Bunker, C. P. Lee

GT 1995; V004T09A003https://doi.org/10.1115/95-GT-003

Abstract

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Topics: Airfoils , Cascades (Fluid dynamics) , Film cooling , Heat transfer , Heat transfer coefficients , Transients (Dynamics) , Cylinders , Steady state , Boundary layers , Chords (Trusses)

The Effects of Adverse Pressure Gradients on Momentum and Thermal Structures in Transitional Boundary Layers: Part 1 — Mean Quantities

Scott P. Mislevy, Ting Wang

GT 1995; V004T09A004https://doi.org/10.1115/95-GT-004

Abstract

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Topics: Boundary layers , Momentum , Pressure gradient , Turbulence , Temperature profiles , Wire , Heat transfer , Pressure , Heat conduction , Probes

The Effects of Adverse Pressure Gradients on Momentum and Thermal Structures in Transitional Boundary Layers: Part 2 — Fluctuation Quantities

Scott P. Mislevy, Ting Wang

GT 1995; V004T09A005https://doi.org/10.1115/95-GT-005

Abstract

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Topics: Boundary layers , Momentum , Pressure gradient , Turbulence , Shear (Mechanics) , Shear stress , Boundary layer turbulence , Eddies (Fluid dynamics) , Fluctuations (Physics) , Flux (Metallurgy)

Transient Liquid Crystal Technique for Convective Heat Transfer on Rough Surfaces

Douglas N. Barlow, Yong W. Kim

GT 1995; V004T09A006https://doi.org/10.1115/95-GT-006

Abstract

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Topics: Convection , Liquid crystals , Surface roughness , Transients (Dynamics) , Stators , Heat transfer coefficients , Momentum , Turbines , Boundary layers , Composite materials

Flow Visualization in a Linear Turbine Cascade of High Performance Turbine Blades

Hai-Ping Wang, Steven J. Olson, Richard J. Goldstein, Ernst R. G. Eckert

GT 1995; V004T09A007https://doi.org/10.1115/95-GT-007

Abstract

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Topics: Cascades (Fluid dynamics) , Flow visualization , Turbine blades , Turbines , Vortices , Blades , Flow (Dynamics) , Suction , Wire , Smoke

Transient Heat Transfer Experiments in a Linear Cascade via an Insertion Mechanism Using the Liquid Crystal Technique

A. Hoffs, A. Bolcs, S. P. Harasgama

GT 1995; V004T09A008https://doi.org/10.1115/95-GT-008

Abstract

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Topics: Cascades (Fluid dynamics) , Liquid crystals , Transient heat transfer , Airfoils , Boundary layers , Compressors , Displacement , Gages , Heat transfer , Image processing

Multiple Jets in a Crossflow: Detailed Measurements and Numerical Simulations

Peter Ajersch, Jian-Ming Zhou, Steven Ketler, Martha Salcudean, Ian S. Gartshore

GT 1995; V004T09A009https://doi.org/10.1115/95-GT-009

Abstract

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Topics: Computer simulation , Jets , Flow (Dynamics) , Stress , Smoke , Turbulence , Algebra , Computational fluid dynamics , Film cooling , Flow visualization

Heat Transfer Coefficients Over a Flat Surface With Air and CO₂ Injection Through Compound Angle Holes Using a Transient Liquid Crystal Image Method

Srinath V. Ekkad, Dyrk Zapata, Je-Chin Han

GT 1995; V004T09A010https://doi.org/10.1115/95-GT-010

Abstract

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Topics: Heat transfer coefficients , Liquid crystals , Tertiary petroleum recovery , Transients (Dynamics) , Coolants , Density , Carbon dioxide , Coating processes , Coatings , Film cooling

Film Effectiveness Over a Flat Surface With Air and CO₂ Injection Through Compound Angle Holes Using a Transient Liquid Crystal Image Method

Srinath V. Ekkad, Dyrk Zapata, Je-Chin Han

GT 1995; V004T09A011https://doi.org/10.1115/95-GT-011

Abstract

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Topics: Liquid crystals , Tertiary petroleum recovery , Transients (Dynamics) , Coolants , Density , Carbon dioxide , Film cooling , Gas turbines , Heat transfer coefficients , Turbulence

Total-Coverage Discrete Hole Wall Cooling

Hyung Hee Cho, Richard J. Goldstein

GT 1995; V004T09A012https://doi.org/10.1115/95-GT-012

Abstract

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Topics: Cooling , Flow (Dynamics) , Heat , Mass transfer , Plates (structures) , Combustion chambers , Film cooling , Flow separation , Jets , Reynolds number

Turbulent Flow Heat Transfer and Friction in a Rectangular Channel With Varying Number of Ribbed Walls

Pankaj R. Chandra, Michael E. Niland, Je-Chin Han

GT 1995; V004T09A013https://doi.org/10.1115/95-GT-013

Abstract

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Topics: Friction , Heat transfer , Turbulence , Surface roughness , Air flow , Heat transfer coefficients , Reynolds number

Effect of Surface Roughness on Local Heat Transfer and Film Cooling Effectiveness

Douglas N. Barlow, Yong W. Kim

GT 1995; V004T09A014https://doi.org/10.1115/95-GT-014

Abstract

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Topics: Film cooling , Heat transfer , Surface roughness , Heat transfer coefficients , Boundary layers , Cooling , Density , Flow (Dynamics) , Liquid crystals , Momentum

The Discharge Coefficient of Flared Film Cooling Holes

N. Hay, D. Lampard

GT 1995; V004T09A015https://doi.org/10.1115/95-GT-015

Abstract

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Topics: Discharge coefficient , Film cooling , Cross-flow , Electrical discharge machining , Flow (Dynamics) , Geometry , Pressure

An Experimental Study to Compare the Naphthalene Sublimation With the Liquid Crystal Technique in Compressible Flow

M. Häring, A. Hoffs, A. Bolcs, B. Weigand

GT 1995; V004T09A016https://doi.org/10.1115/95-GT-016

Abstract

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Topics: Compressible flow , Liquid crystals , Mach number , Turbines , Airfoils , Heat transfer coefficients , Boundary layers , Cylinders , Flat plates , Reynolds number

A New Analogy Function for the Naphthalene Sublimation Technique to Measure Heat Transfer Coefficients on Turbine Airfoils

M. Häring, B. Weigand

GT 1995; V004T09A017https://doi.org/10.1115/95-GT-017

Abstract

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Topics: Airfoils , Heat transfer coefficients , Turbines , Flow (Dynamics) , Heat transfer , Mach number , Mass transfer , Pressure gradient , Approximation , Ducts

Pressure Gradient Effects on Film Cooling

Donald L. Schmidt, David G. Bogard

GT 1995; V004T09A018https://doi.org/10.1115/95-GT-018

Abstract

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Topics: Film cooling , Pressure gradient , Jets , Cooling , Density , Blades , Flat plates , Gas turbines , Momentum , Pressure

Design and Evaluation of a Single Passage Test Model to Obtain Turbine Airfoil Film Cooling Effectiveness Data

Frederick A. Buck, Chander Prakash

GT 1995; V004T09A019https://doi.org/10.1115/95-GT-019

Abstract

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Topics: Airfoils , Design , Film cooling , Turbines , Boundary layers , Coolants , Pressure , Suction , Aerodynamics , Cascades (Fluid dynamics)

Computations of Film Cooling for the Leading Edge Region of a Turbine Blade Model

Pingfan He, Martha Salcudean, Ian S. Gartshore

GT 1995; V004T09A020https://doi.org/10.1115/95-GT-020

Abstract

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Topics: Computation , Film cooling , Turbine blades , Orifices , Blades , Coolants , Density , Flow (Dynamics) , Geometry , Mesh generation

The Influence of Large Scale High Intensity Turbulence on Vane Heat Transfer

Forrest E. Ames

GT 1995; V004T09A021https://doi.org/10.1115/95-GT-021

Abstract

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Topics: Heat transfer , Turbulence , Pressure , Reynolds number , Cascades (Fluid dynamics) , Combustion chambers , Chords (Trusses) , Energy dissipation , Mach number

Cooling Flow Prediction for Fully Impingement Cooled Gas Turbine Blades

Stefano Consonni

GT 1995; V004T09A022https://doi.org/10.1115/95-GT-022

Abstract

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Topics: Blades , Cooling , Flow (Dynamics) , Gas turbines , Convection , Coolants , Pressure , Chords (Trusses) , Engines , Film cooling

Computation of Spatially Periodic Turbulent Fluid Flow and Heat Transfer in a Channel With Various Rib Shapes

Tong-Miin Liou, Shih-Hui Chen

GT 1995; V004T09A023https://doi.org/10.1115/95-GT-023

Abstract

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Topics: Computation , Fluid dynamics , Heat transfer , Shapes , Turbulence , Cross section (Physics) , Flow (Dynamics) , Holographic interferometry , Kinetic energy , Lasers

Simulation of Film-Cooling Aerodynamics With a 2D Navier-Stokes Solver Using Unstructured Meshes

Stefan Irmisch

GT 1995; V004T09A024https://doi.org/10.1115/95-GT-024

Abstract

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Topics: Aerodynamics , Film cooling , Simulation , Flow (Dynamics) , Coolants , Algorithms , Computer simulation , Finite volume methods , Navier-Stokes equations , Steady state

Prediction of Vane Surface Film Cooling Effectiveness Using Compressible Navier-Stokes Procedure and k-ε Turbulence Model With Wall Function

Yoshitaka Fukuyama, Fumio Otomo, Minoru Sato, Yuichi Kobayashi, Hiroyuki Matsuzaki

GT 1995; V004T09A025https://doi.org/10.1115/95-GT-025

Abstract

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Topics: Cooling , Thin films , Turbulence , Film cooling , Geometry , Pressure , Turbines , Convection , Reynolds number , Winding (process)

Experimental and Numerical Investigations of the Aerodynamical Effects of Coolant Injection Through the Trailing Edge of a Guide Vane

Dieter E. Bohn, Volker J. Becker, Klaus D. Behnke, Bernhard F. Bonhoff

GT 1995; V004T09A026https://doi.org/10.1115/95-GT-026

Abstract

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Topics: Coolants , Guide vanes , Flow (Dynamics) , Turbulence , Anisotropy , Cooling , Finite volume methods , Gas turbines , Pressure gradient , Symmetry (Physics)

Flow Characteristics and Aerodynamic Losses of Film-Cooling Jets With Compound Angle Orientations

Sang Woo Lee, Yong Beom Kim, Joon Sik Lee

GT 1995; V004T09A027https://doi.org/10.1115/95-GT-038

Abstract

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Topics: Film cooling , Flow (Dynamics) , Jets , Flow visualization , Flow measurement , Probes , Vortices

Film Cooling From Spanwise Oriented Holes in Two Staggered Rows

Phillip M. Ligrani, Anthony E. Ramsey

GT 1995; V004T09A028https://doi.org/10.1115/95-GT-039

Abstract

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Topics: Film cooling , Density , Heat transfer coefficients , Momentum

Measurements of Heat Transfer Coefficients and Friction Factors in Rib-Roughened Channels Simulating Leading-Edge Cavities of a Modern Turbine Blade

M. E. Taslim, T. Li, S. D. Spring

GT 1995; V004T09A029https://doi.org/10.1115/95-GT-040

Abstract

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Topics: Cavities , Friction , Heat transfer coefficients , Turbine blades , Blades , Flow (Dynamics) , Cooling , Shapes , Airfoils , Design

Heat Transfer Augmentation in a Rectangular Channel With Slit Rib-Turbulators on Two Opposite Walls

Jenn-Jiang Hwang, Tong-Miin Liou

GT 1995; V004T09A030https://doi.org/10.1115/95-GT-041

Abstract

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Topics: Heat transfer , Friction , Cooling , Design , Flow (Dynamics) , Heat transfer coefficients , Holographic interferometry , Lasers , Reynolds number , Turbine blades

The Effect of Twisted Tape Width on Heat Transfer and Pressure Drop for Fully Developed Laminar Flow

Walid M. Chakroun, Sami F. Al-Fahed

GT 1995; V004T09A031https://doi.org/10.1115/95-GT-042

Abstract

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Topics: Heat transfer , Laminar flow , Pressure drop , Friction , Reynolds number , Flow (Dynamics) , Geometry , Boundary-value problems , Design , Heat exchangers

Effects of Free Stream Turbulence on the Instantaneous Heat Transfer in a Wall Jet Flow

Savash Yavuzkurt

GT 1995; V004T09A032https://doi.org/10.1115/95-GT-043

Abstract

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Topics: Heat transfer , Jets , Turbulence , Probes , Flow (Dynamics) , Stress , Wire

Bulk Flow Pulsations and Film Cooling: Flow Structure Just Downstream of the Holes

Phillip M. Ligrani, J. Michael Cuthrell, Ruoming Gong

GT 1995; V004T09A033https://doi.org/10.1115/95-GT-044

Abstract

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Topics: Film cooling , Flow (Dynamics) , Blades , Pressure , Boundary layers , Engines , Shear (Mechanics) , Shear stress , Shock waves , Stress tensors

Study and Application of Hemispheric Cavities for Surface Heat Transfer Augmentation

A. V. Schukin, A. P. Kozlov, R. S. Agachev

GT 1995; V004T09A034https://doi.org/10.1115/95-GT-059

Abstract

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Topics: Cavities , Heat transfer , Flow (Dynamics) , Airfoils , Convection , Cooling , Gas turbines , Manufacturing , Pressure , Turbulence

Experimental Study on Convective Heat Transfer of Radial Air Flow in Rotating Multi-Channels

G. J. Hwang, C. R. Kuo, C. Y. Chang

GT 1995; V004T09A035https://doi.org/10.1115/95-GT-060

Abstract

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Topics: Air flow , Convection , Flow (Dynamics) , Heat transfer , Aluminum alloys , Buoyancy , Ducts , Heat conduction , Reynolds number , Rotation

Heat Transfer Predictions for Two Turbine Nozzle Geometries at High Reynolds and Mach Numbers

R. J. Boyle, R. Jackson

GT 1995; V004T09A036https://doi.org/10.1115/95-GT-104

Abstract

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Topics: Heat transfer , Mach number , Nozzles , Turbines , Computational fluid dynamics , Pressure , Turbulence , Algebra , Design , Eddies (Fluid dynamics)

Prediction of Unshrouded Rotor Blade Tip Heat Transfer

A. A. Ameri, E. Steinthorsson

GT 1995; V004T09A037https://doi.org/10.1115/95-GT-142

Abstract

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Topics: Blades , Heat transfer , Rotors , Turbines , Channel flow , Computation , Computers , Engines , Fuels , High pressure (Physics)

A Combined Experimental/Computational Study of Flow in Turbine Blade Cooling Passage: Part II — Numerical Simulations

Diane M. McGrath, David G. N. Tse

GT 1995; V004T09A038https://doi.org/10.1115/95-GT-149

Abstract

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Topics: Computer simulation , Cooling , Flow (Dynamics) , Turbine blades , Buoyancy , Compressible flow , Coriolis force , Engineering simulation , Fluid density , Gas turbines

Prediction of Film Cooling Effectiveness and Heat Transfer due to Streamwise and Compound Angle Injection on Flat Surfaces

S. Neelakantan, M. E. Crawford

GT 1995; V004T09A039https://doi.org/10.1115/95-GT-151

Abstract

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Topics: Film cooling , Heat transfer , Momentum , Density , Heat transfer coefficients

Turbulent Transport Measurements in a Heated Boundary Layer: Combined Effects of Free-Stream Turbulence and Removal of Concave Curvature

Michael D. Kestoras, Terrence W. Simon

GT 1995; V004T09A040https://doi.org/10.1115/95-GT-152

Abstract

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Topics: Boundary layers , Turbulence , Momentum , Flow (Dynamics) , Heat , Test facilities

Indirect Turbulence Measurement in Gas Turbine Stages Using Heat Flux Probe

Luzeng J. Zhang, Boris Glezer

GT 1995; V004T09A041https://doi.org/10.1115/95-GT-153

Abstract

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Topics: Gas turbines , Heat flux , Probes , Turbulence , Combustion chambers , Blades , Wakes , Airfoils , Cascades (Fluid dynamics) , Engine design

The Effect of Periodic Wake Passing on Film Effectiveness of Discrete Cooling Holes Around the Leading Edge of a Blunt Body

K. Funazaki, M. Yokota, S. Yamawaki

GT 1995; V004T09A042https://doi.org/10.1115/95-GT-183

Abstract

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Topics: Cooling , Wakes , Turbulence , Density , Temperature , Aircraft engines , Flow (Dynamics) , Generators , Liquid crystals , Thermocouples

Gas Turbine Model Scaling

Mark R. D. Davies, John D. Wallace

GT 1995; V004T09A043https://doi.org/10.1115/95-GT-205

Abstract

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Topics: Gas turbines , Boundary layers , Heat transfer , Engines , Entropy , Test facilities , Viscosity , Boundary-value problems , Dimensional analysis , Flow (Dynamics)

Adiabatic Effectiveness, Thermal Fields, and Velocity Fields for Film Cooling With Large Angle Injection

Atul Kohli, David G. Bogard

GT 1995; V004T09A044https://doi.org/10.1115/95-GT-219

Abstract

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Topics: Film cooling , Momentum , Turbulence , Cooling , Density

Full Coverage Effusion Film Cooling With Inclined Holes

G. E. Andrews, I. M. Khalifa, A. A. Asere, F. Bazdidi-Tehrani

GT 1995; V004T09A045https://doi.org/10.1115/95-GT-274

Abstract

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Topics: Film cooling , Cooling , Flow (Dynamics) , Combustion chambers , Density , Adiabatic cooling , Air flow , Gas turbines , Lasers

Leading Edge Film Cooling Effects on Turbine Blade Heat Transfer

Vijay K. Garg, Raymond E. Gaugler

GT 1995; V004T09A046https://doi.org/10.1115/95-GT-275

Abstract

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Topics: Film cooling , Heat transfer , Turbine blades , Coolants , Flow (Dynamics) , Heat transfer coefficients , Pressure , Blades , Engines , Suction

A Combined Experimental/Computational Study of Flow in Turbine Blade Cooling Passage: Part I — Experimental Study

D. G. N. Tse, D. B. McGrath

GT 1995; V004T09A047https://doi.org/10.1115/95-GT-355

Abstract

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Topics: Cooling , Flow (Dynamics) , Turbine blades , Coriolis force , Fluctuations (Physics) , Heat transfer , High pressure (Physics) , Lasers , Pressure , Reynolds number

Endwall Heat Transfer and Aerodynamic Measurements in an Annular Cascade of Nozzle Guide Vanes

M. C. Spencer, G. D. Lock, T. V. Jones, N. W. Harvey

GT 1995; V004T09A048https://doi.org/10.1115/95-GT-356

Abstract

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Topics: Cascades (Fluid dynamics) , Heat transfer , Nozzle guide vanes , Mach number , Engines , Flow (Dynamics) , Flow visualization , Heat transfer coefficients , High pressure (Physics) , Liquid crystals

The Application of Thin Film Gauges on Flexible Plastic Substrates to the Gas Turbine Situation

S. M. Guo, M. C. Spencer, G. D. Lock, T. V. Jones, N. W. Harvey

GT 1995; V004T09A049https://doi.org/10.1115/95-GT-357

Abstract

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Topics: Gages , Gas turbines , Thin films , Heat transfer , Aluminum , Metals , Nozzle guide vanes , Temperature , Boundary-value problems , Calibration

Electric Power

Off-Design Performance of Multipressure Heat Recovery Boilers

Nicola Bettagli, Bruno Facchini

GT 1995; V004T10A001https://doi.org/10.1115/95-GT-154

Abstract

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Topics: Boilers , Design , Heat recovery , Heat recovery steam generators , Combined cycle power stations , Flow (Dynamics) , Heat transfer , Pressure , Simulation , Temperature

Comparative Performance of Gas/Steam Combined Cycle Power Plants

R. Yadav, Lakshman Singh

GT 1995; V004T10A002https://doi.org/10.1115/95-GT-155

Abstract

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Topics: Combined cycle power stations , Steam , Design

Characteristics Charts for Preliminary Design and Selection of a Gas Turbine Cogeneration Plant

K. Sarabchi, G. T. Polley

GT 1995; V004T10A003https://doi.org/10.1115/95-GT-156

Abstract

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Topics: Cogeneration plants , Design , Gas turbines , Boilers , Integrated systems

Gas Turbine Performance: New Application and Test Correction Curves

Scott T. Cloyd, Arthur J. Harris, Jr.

GT 1995; V004T10A004https://doi.org/10.1115/95-GT-167

Abstract

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Topics: Gas turbines , Engines , Fuels , Exhaust systems , Generators , Heating , Methane , Natural gas , Pressure

Thermodynamic Study of Coupled Steam-Gas Turbine Plant With Steam Extraction and Injection

Zheng Qun, Li Shunglong, Yang Yaogen

GT 1995; V004T10A005https://doi.org/10.1115/95-GT-170

Abstract

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Topics: Steam , Turbines , Gas turbines , Feedwater , Heat , Steam turbines , Water , Boilers , Cycles , Exhaust systems

New 200 MW Class 501G Combustion Turbine

L. Southall, G. McQuiggan

GT 1995; V004T10A006https://doi.org/10.1115/95-GT-215

Abstract

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Topics: Combustion , Turbines , Combined cycles

Qualifying Combustion Turbines for Inlet Air Cooling Capacity Enhancement

Brian J. Kitchen, Jerry A. Ebeling

GT 1995; V004T10A007https://doi.org/10.1115/95-GT-266

Abstract

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Topics: Combustion , Cooling , Turbines , Exhaust systems , Flow (Dynamics) , Heat , Pressure , Temperature

The 501D5A Combustion Turbine

Douglas E. Hintz

GT 1995; V004T10A008https://doi.org/10.1115/95-GT-267

Abstract

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Topics: Combustion , Turbines , Engines , Combustion systems , Compressors , Cycles , Emissions , Flow (Dynamics) , Heat , Rotors

Design, Part Load and Transient Operation of Combined Cycle Plants With Water Flashing

P. J. Dechamps

GT 1995; V004T10A009https://doi.org/10.1115/95-GT-268

Abstract

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Topics: Combined cycle power stations , Design , Flashing , Stress , Transients (Dynamics) , Water , Combined cycles , Pressure , Heat recovery steam generators , Flash tanks

A Numerical Method for Power Plant Simulations

Carlo Carcasci, Bruno Facchini

GT 1995; V004T10A010https://doi.org/10.1115/95-GT-269

Abstract

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Topics: Engineering simulation , Numerical analysis , Power stations , Simulation , Cycles , Algebra , Combustion chambers , Compressors , Energy generation , Gas turbines

Development of Advanced Thermal Barrier Coatings for Severe Environments

Warren A. Nelson, Robert M. Orenstein, Paul S. DiMascio, Curtis A. Johnson

GT 1995; V004T10A011https://doi.org/10.1115/95-GT-270

Abstract

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Topics: Thermal barrier coatings , Gas turbines , Coating processes , Coatings , Design , Engineers , Superalloys , Combustion chambers , Delamination , Energy generation

Gas Turbine Power Generation Evolutionary Advances for the Future

James C. Corman

GT 1995; V004T10A012https://doi.org/10.1115/95-GT-271

Abstract

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Topics: Energy generation , Gas turbines , Energy / power systems , Emissions , Fuels , Biomass , Coal , Combined cycles , Combustion systems , Fuel gasification

Energy Industry Changes: The Role of Advanced Combustion Turbine Technology

George Touchton, Arthur Cohn

GT 1995; V004T10A013https://doi.org/10.1115/95-GT-280

Abstract

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Topics: Combustion , Energy industry , Turbines , Compressed air , Distributed power generation , Durability , Electricity (Physics) , Power stations , Reliability , Storage

Ensuring Adequate Coolant Purity for Advanced Gas Turbines

D. E. Woodmansee, A. K. Tolpadi, T. H. Hwang, A. D. Maddaus

GT 1995; V004T10A014https://doi.org/10.1115/95-GT-281

Abstract

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Topics: Coolants , Gas turbines , Particulate matter , Computational fluid dynamics , Flow (Dynamics) , Inspection , Sedimentation , Turbulence

Novel Compressed Air Energy Storage (CAES) Systems Applying Air Expanders

Isaac Shnaid, Dan Weiner, Shimshon Brokman

GT 1995; V004T10A015https://doi.org/10.1115/95-GT-282

Abstract

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Topics: Compressed air , Energy storage , Gas turbines , Heat , Reservoirs , Temperature , Air compressors , Economic analysis , Electricity (Physics) , Exhaust systems

The KEMA Gas Turbines Target Project: Overview and Status

R. A. Rooth

GT 1995; V004T10A016https://doi.org/10.1115/95-GT-283

Abstract

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Topics: Gas turbines , Power stations , Rotors , Blades , Combustion chambers , Compressors , Creep , Emissions , Fatigue , Filtration

Gas Turbine Inlet Air Cooling and the Effect on a Westinghouse 501D5 CT

Chuck Kohlenberger

GT 1995; V004T10A017https://doi.org/10.1115/95-GT-284

Abstract

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Topics: Cooling , Gas turbines , Temperature , Heat , Exhaust systems , Flow (Dynamics) , Heat recovery steam generators , Engineering standards , Systems engineers

Trial Operation Results of the Fully-Fired Combined Cycle Generating Plants in Chita

T. Mita, N. Ando, A. Kawauchi, K. Morikawa

GT 1995; V004T10A018https://doi.org/10.1115/95-GT-333

Abstract

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Topics: Air conditioning , Boilers , Combined cycle power stations , Combined cycles , Combustion , Construction , Electricity (Physics) , Exhaust systems , Gas turbines , Gases

Comparative Evaluation of the Effect of Turbine Configuration on the Performance of Heavy-Duty Gas Turbines

Tong Seop Kim, Sung Tack Ro

GT 1995; V004T10A019https://doi.org/10.1115/95-GT-334

Abstract

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Topics: Gas turbines , Turbines , Degrees of freedom , Engines , Gas flow , High temperature , Systems analysis

Final Report of the Key Technology Development Program for a Next Generation High Temperature Gas Turbine

M. Sato, Y. Kobayashi, H. Matsuzaki, S. Aoki, Y. Tsukuda, E. Akita

GT 1995; V004T10A020https://doi.org/10.1115/95-GT-407

Abstract

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Topics: Gas turbines , High temperature , Technology development , Blades , Combined cycle power stations , Combustion systems , Cooling , Electricity (Physics) , Heat resistant materials , Nitrogen oxides

The Basic Performance of Combined Cycles and Their Optimum Gas Turbine Pressure Ratios

Ruixian Cai

GT 1995; V004T10A021https://doi.org/10.1115/95-GT-416

Abstract

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Topics: Combined cycles , Gas turbines , Pressure , Cycles , Fluidized beds , Heat recovery , Steam turbines

Rotational Effects on Heat Transfer at Advanced Engine Conditions

F. W. Staub, A. D. Maddaus, P. K. Tekriwal

GT 1995; V004T10A022https://doi.org/10.1115/95-GT-417

Abstract

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Topics: Engines , Heat transfer , Computational fluid dynamics , Coolants , Databases , Rotation , Accounting , Cooling , Design , Fluids

Performance Analysis With Different Means of Cooling in a Combined Cycle

Onkar Singh, R. Yadav

GT 1995; V004T10A023https://doi.org/10.1115/95-GT-451

Abstract

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Topics: Combined cycles , Cooling , Temperature , Cycles , Gas turbines , Pressure , Steam , Turbines , Blades , Compressors

The “3A-Series” Gas Turbines With HBR^® Combustors

B. Becker, T. Schulenberg, H. Termuehlen

GT 1995; V004T10A024https://doi.org/10.1115/95-GT-458

Abstract

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Topics: Combustion chambers , Gas turbines , Machinery , Design , Stress

Industrial and Cogeneration

Split Stream Boilers for High Temperature/High Pressure Topping Steam Turbine Combined Cycles

Ivan G. Rice

GT 1995; V004T11A001https://doi.org/10.1115/95-GT-029

Abstract

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Topics: Boilers , Combined cycles , High pressure (Physics) , High temperature , Steam turbines , Exhaust systems , Gas turbines , Firing , Flow (Dynamics) , Gaseous fuels

API Standard 616: Scopes for Different Interpretations

G. K. Roy

GT 1995; V004T11A002https://doi.org/10.1115/95-GT-057

Abstract

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Topics: American Petroleum Institute , Gas turbines , Turbines , Bearings , Bridges (Structures) , Firing , Inspection , Machinery , Rotors , Temperature

Reheat and Regenerative Gas Turbines for Feed Water Repowering of Steam Power Plant

G. Negri di Montenegro, M. Gambini, A. Peretto

GT 1995; V004T11A003https://doi.org/10.1115/95-GT-058

Abstract

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Topics: Feedwater , Gas turbines , Thermal power stations , Cycles , Brayton cycle , Flow (Dynamics) , Steam , Steam turbines , Computer simulation , Condensers (steam plant)

Synchronous Condensing Using the Generator of Peak Load Plant

Morgan L. Hendry, John C. McGough

GT 1995; V004T11A004https://doi.org/10.1115/95-GT-273

Abstract

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Topics: Generators , Peak load , Turbines , Condensers (steam plant) , Electronic systems , Gas turbines , Turbogenerators

Benefits of Compressor Inlet Air Cooling for Gas Turbine Cogeneration Plants

Maurizio De Lucia, Carlo Lanfranchi, Vanni Boggio

GT 1995; V004T11A005https://doi.org/10.1115/95-GT-311

Abstract

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Topics: Cogeneration plants , Compressors , Cooling , Gas turbines , Absorption , Evaporative cooling , Stress , Climate , Cooling systems , Modeling

A Code for Thermal Analysis of STIG Turbines

Carlo M. Bartolini, Danilo Salvi, Marcello Pennacchioli

GT 1995; V004T11A006https://doi.org/10.1115/95-GT-316

Abstract

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Topics: Thermal analysis , Turbines , Compressors , Design , Temperature , Blades , Computers , Convection , Cooling , Film cooling

The Effect of a Constant Volume Recuperator on Brayton Cycle Efficiency and Equipment Cost

Solomon S. Fineblum

GT 1995; V004T11A007https://doi.org/10.1115/95-GT-317

Abstract

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Topics: Brayton cycle , Turbines , Pressure , Combustion chambers , Density , Combustion , Design , Evaporation , Flow (Dynamics) , Fuels

Technical/Economic Analysis of an Integrated System for Sludge Dehydration and Electric Power Generation Applying Gas Turbine Cycles

Umberto Ghezzi, Silvano Pasini

GT 1995; V004T11A008https://doi.org/10.1115/95-GT-318

Abstract

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Topics: Cycles , Diffusion (Physics) , Economic analysis , Electric power generation , Gas turbines , Integrated systems , Water treatment

Feasibility of Utilizing a Bio-Mass Derived Fuel for Industrial Gas Turbine Applications

R. G. Andrews, P. C. Patnaik, J. W. Michniewicz, L. J. Jankowski, V. I. Romanov, V. V. Lupandin, A. V. Ravich

GT 1995; V004T11A009https://doi.org/10.1115/95-GT-319

Abstract

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Topics: Biomass , Fuels , Industrial gases , Turbines , Engines , Gas turbines , Biofuel , Combustion , Combustion systems , Density

Design Development and Implementation of a Compact 5000 SHP Gas Turbine Package for an Electromagnetic Gun System

Feroze J. Meher-Homji, Gustavo Herrera, Ben Rech

GT 1995; V004T11A010https://doi.org/10.1115/95-GT-320

Abstract

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Topics: Design , Gas turbines , Turbines , Aluminum , Control systems , Cooling , Dimensions , Displacement , Fans , Fire

A High Efficiency Recuperated Cycle, Optimized for Reliable, Low Cost, Industrial Gas Turbine Engines

Thomas L. Ragland

GT 1995; V004T11A011https://doi.org/10.1115/95-GT-321

Abstract

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Topics: Cycles , Gas turbines , Industrial gases , Engines , Firing , Temperature , Pressure , Design , Durability , High pressure (Physics)

LM-2500 First Stage Filtration Upgrades

Steven R. Johnson, David A. Thomas

GT 1995; V004T11A012https://doi.org/10.1115/95-GT-322

Abstract

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Topics: Filtration , Engines , Air treatment systems , Combined heat and power , Gas turbines , Gypsum , Combined cycles , Evaporative cooling , Failure , Filters