Volumes | Turbo Expo | American Society of Mechanical Engineers Digital Collection

Topics: Coal , Combined cycle power stations , Fuel gasification , High pressure (Physics) , Carbon dioxide , Energy generation , Methane , Slurries , Steady state , Steam

Utilization of Coal-Derived Fuel in Advanced Power Generation Systems: An Evaluation

R. D. Lessard, F. L. Robson, W. A. Blecher, A. W. Carlson

GT 1982; V003T05A003https://doi.org/10.1115/82-GT-168

Abstract

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Topics: Coal , Energy / power systems , Fuels , Gaseous fuels , Fuel gasification , Combined cycle gas turbines , Cycles , Electricity (Physics) , Magnetohydrodynamics , Molten carbonate fuel cells

A Fluidized Bed Combustion Heat Transfer Model Using Finite Elements

P. E. Jenkins, T. W. Richardson

GT 1982; V003T05A004https://doi.org/10.1115/82-GT-169

Abstract

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Topics: Finite element analysis , Fluidized bed combustion , Heat transfer , Combustion chambers , Finite element methods , Fluidized beds , Heat conduction , Poisson equation , Temperature

Measured Particle Rebound Characteristics Useful for Erosion Prediction

T. Wakeman, W. Tabakoff

GT 1982; V003T05A005https://doi.org/10.1115/82-GT-170

Abstract

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Topics: Erosion , Particulate matter , Flow (Dynamics) , High temperature , High temperature materials , Temperature , Testing , Turbomachinery

Erosion Resistance and Efficiency of Energy Exchangers

W. J. Thayer, III, R. T. Taussig

GT 1982; V003T05A006https://doi.org/10.1115/82-GT-191

Abstract

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Topics: Combustion chambers , Energy consumption , Erosion , Fluidized beds , Gas turbines , Machinery , Particulate matter , Power stations , Waves , Wear

An Assessment of Erosion in PFBC Power Plant Turbines

R. A. Wenglarz, S. J. Schneider

GT 1982; V003T05A007https://doi.org/10.1115/82-GT-194

Abstract

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Topics: Erosion , Power stations , Turbines , Blades , Particulate matter , Boilers , Cascades (Fluid dynamics) , Combustion , Combustion chambers , Damage

Dust Removal Concepts for Pressurized Fluidized Bed Systems

R. R. Boericke, W. E. Moore

GT 1982; V003T05A008https://doi.org/10.1115/82-GT-210

Abstract

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Topics: Dust removal , Fluidized beds , Filters , Acoustics , Ceramics , Combined cycles , Energy generation , High temperature

A General Performance Model for the Open-Loop Water-Cooled Gas Turbine

M. A. El-Masri, Y. Kobayashi, J. F. Louis

GT 1982; V003T05A009https://doi.org/10.1115/82-GT-212

Abstract

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Topics: Gas turbines , Water , Cycles , Turbines , Critical heat flux , Design , Heat transfer , Pressure , Steam , Temperature

High-Temperature Turbine Technology Readiness

M. W. Horner, A. Caruvana

GT 1982; V003T05A010https://doi.org/10.1115/82-GT-213

Abstract

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Topics: High temperature , Turbines , Gas turbines , Temperature , Coal , Combined cycle power stations , Combustion , Combustion chambers , Fuel systems , Gaseous fuels

Steam Injection in Medium-BTU Gas-Fueled, High Temperature Combined Cycle Power Plants

J. P. Lewis, C. Kinney

GT 1982; V003T05A011https://doi.org/10.1115/82-GT-274

Abstract

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Topics: Combined cycle power stations , High temperature , Steam , Fuels , Water , Combustion , Combustion chambers , Cooling towers , Gas turbines , Natural gas

Combustion and Fuels

Smoke Reduction in FJR-710 Turbofan Engines by an Airblast Combustor

K. Eguchi, A. Ishii, K. Kitahara, K. Suzuki, T. Tagashira

GT 1982; V003T06A001https://doi.org/10.1115/82-GT-24

Abstract

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Topics: Combustion chambers , Engines , Smoke , Turbofans , Emissions , Air flow , Aircraft engines , Durability , Flames , Fuels

Penetration and Break-Up Studies of Discrete Liquid Jets in Cross Flowing Airstreams

G. A. Hussein, A. K. Jasuja, R. S. Fletcher

GT 1982; V003T06A002https://doi.org/10.1115/82-GT-25

Abstract

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Topics: Atmospheric pressure , Design , Jets , Lasers , Light scattering , Photography , Temperature

Evaluation of Shale Oil as a Utility Gas Turbine Fuel

R. A. Sederquist, J. Frese, J. McVey, C. L. Knauf, H. Schreiber

GT 1982; V003T06A003https://doi.org/10.1115/82-GT-26

Abstract

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Topics: Fuels , Gas turbines , Shales , Engines , Nitrogen oxides , Combustion chambers , Electricity (Physics) , Emissions , Hot water , Nitrogen

Thermal Decomposition of Aviation Fuel

A. E. Peat

GT 1982; V003T06A004https://doi.org/10.1115/82-GT-27

Abstract

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Topics: Aviation , Fuels , Engines , Metals , Temperature , Carbon , Flow (Dynamics) , Fuel injectors , Fuel systems , Gas turbines

Alternative Fuels: Burner Concepts and Emission Characteristics of a Silo Combustor

W. Krockow, H. Schabbehard

GT 1982; V003T06A005https://doi.org/10.1115/82-GT-29

Abstract

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Topics: Combustion chambers , Emissions , Fuels , Coal , Combustion , Nitrogen oxides , Design , Gases , Heat , Methane

A Model for Computation of Net Local Soot Generation

S. S. Koussa

GT 1982; V003T06A006https://doi.org/10.1115/82-GT-30

Abstract

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Topics: Computation , Soot , Combustion chambers , Turbulence

Combustor Liner Temperature in the Gas Turbine Using Heavy Fuels

Y. S. H. Najjar

GT 1982; V003T06A007https://doi.org/10.1115/82-GT-31

Abstract

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Topics: Combustion chambers , Fuels , Gas turbines , Temperature , Aviation , Fuel oils , Radiation (Physics) , Smoke , Temperature measurement

Plain-Jet Airblast Atomization of Alternative Liquid Petroleum Fuels Under High Ambient Air Pressure Conditions

A. K. Jasuja

GT 1982; V003T06A008https://doi.org/10.1115/82-GT-32

Abstract

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Topics: Fuels , Petroleum , Pressure , Fuel oils , Gas turbines , Lasers , Light scattering , Sprays , Viscosity

Fuel Microemulsions for Jet Engine Smoke Reduction

D. W. Naegeli, C. A. Moses

GT 1982; V003T06A009https://doi.org/10.1115/82-GT-33

Abstract

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Topics: Fuels , Jet engines , Microemulsions , Smoke , Ethanol , Emissions , Radiation (Physics) , Surfactants , Water , Combustion

Acoustic Control of Dilution-Air Mixing in a Gas Turbine Combustor

P. J. Vermeulen, J. Odgers, V. Ramesh

GT 1982; V003T06A010https://doi.org/10.1115/82-GT-35

Abstract

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Topics: Acoustics , Combustion chambers , Gas turbines , Design , Flow (Dynamics) , Stress , Temperature distribution , Temperature profiles

The Low Temperature Properties of Aviation Fuels

G. Brunton, R. R. Willock, M. A. Voisey

GT 1982; V003T06A012https://doi.org/10.1115/82-GT-48

Abstract

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Topics: Aviation , Fuels , Low temperature , Aircraft , Flight , Flow (Dynamics) , Phase transition temperature , Safety , Turbines

Deposit Formation in Hydrocarbon Fuels

R. Roback, E. J. Szetela, L. J. Spadaccini

GT 1982; V003T06A013https://doi.org/10.1115/82-GT-49

Abstract

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Topics: Fuels , Carbon , Wall temperature , Copper , High pressure (Physics) , Nickel , Nickel plating , Plating , Thermal stability

Experience With Large Gas Turbine Combustion Chambers

A. Lienert, O. Schmoch

GT 1982; V003T06A014https://doi.org/10.1115/82-GT-57

Abstract

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Topics: Combustion chambers , Gas turbines , Maintenance , Turbines , Combustion , Failure , Inspection , Manholes , Peak load , Stress

Catalytic Burners for Stationary Combustion Turbines: A Preliminary Design Analysis

L. C. Angello, P. W. Pillsbury, J. L. Toof

GT 1982; V003T06A015https://doi.org/10.1115/82-GT-58

Abstract

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Topics: Combustion , Design , Turbines , Combustion chambers , Gas turbines , Combustion technologies , Emissions , Fuels , Nitrogen , Nitrogen oxides

Experimental Study of External Fuel Vaporization

E. J. Szetela, J. A. TeVelde

GT 1982; V003T06A016https://doi.org/10.1115/82-GT-59

Abstract

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Topics: Fuels , Heat exchangers , Temperature , Aircraft , Diesel , Engines , Flow (Dynamics) , Gas chromatography , Gas turbines , Heat transfer coefficients

An Examination of the Mechanism of Flame Stabilization by the Interaction of a Rich Two-Phase Combustible Mixture Jet With a Counter Air Stream

I. Wierzba

GT 1982; V003T06A017https://doi.org/10.1115/82-GT-60

Abstract

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Topics: Flames , Flow (Dynamics) , Fuels , Vapors

Atomization Quality of Twin Fluid Atomizers for Gas Turbines

M. M. Elkotb, M. A. Elsayed Mahdy, M. E. Montaser

GT 1982; V003T06A018https://doi.org/10.1115/82-GT-61

Abstract

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Topics: Fluids , Gas turbines , Fuels , Pressure , Flow (Dynamics) , Drops , Nozzles , Geometry , Heat , Needles

Carbon Formation by the Pyrolysis of Gas Turbine Fuels in Preflame Regions of Gas Turbine Combustors

C. D. Hurley

GT 1982; V003T06A019https://doi.org/10.1115/82-GT-84

Abstract

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Topics: Carbon , Combustion chambers , Fuels , Gas turbines , Pyrolysis , Diesel , Temperature , Aviation

Fluid Pulsed Thermocouple Rake System for Automated High Gas Temperature Measurements

F. K. Gabriel, E. A. DeZubay, R. W. Mitchell

GT 1982; V003T06A020https://doi.org/10.1115/82-GT-107

Abstract

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Topics: Fluids , Temperature measurement , Thermocouples , Temperature , Combustion , Data acquisition , Design , Errors , Microelectronic devices , Reliability

Scale Combustor Tests With Simulated Lower Heating Value Gas

A. McWhirter, A. E. Dezubay

GT 1982; V003T06A021https://doi.org/10.1115/82-GT-108

Abstract

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Topics: Combustion chambers , Heating , Carbon dioxide , Design , Fuels , Gaseous fuels , Nitrogen oxides , Regression analysis , Stoichiometry

Chemical and Physical Properties of Soot as a Function of Fuel Molecular Structure in a Swirl-Stabilized Combustor

R. M. Himes, R. L. Hack, G. S. Samuelsen

GT 1982; V003T06A022https://doi.org/10.1115/82-GT-109

Abstract

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Topics: Combustion chambers , Fuels , Soot , Smoke , ASTM International , Chemical properties , Combustion systems , Density , Molecular weight , Particulate matter

The Potential Impact of Future Fuels on Small Gas Turbine Engines

J. A. Saintsbury, P. Sampath

GT 1982; V003T06A023https://doi.org/10.1115/82-GT-133

Abstract

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Topics: Fuels , Gas turbines , Aviation , Engines , Aircraft , Combustion

Particulate and Sulfur Oxides Emissions From a 60-MW Heavy Duty Gas Turbine Burning No. 2 Distillate Fuel: Methods Development and Test Results

G. L. Touchton, III, M. B. Hilt

GT 1982; V003T06A024https://doi.org/10.1115/82-GT-136

Abstract

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Topics: Combustion , Emissions , Fuels , Gas turbines , Particulate matter , Sulfur

An Empirically-Based Simulation Model for Heavy-Duty Gas Turbine Engines Using Treated Residual Fuel

J. C. Blanton, W. F. O’Brien, Jr.

GT 1982; V003T06A025https://doi.org/10.1115/82-GT-139

Abstract

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Topics: Fuels , Gas turbines , Simulation models , Engines , Bearings , Turbines , Water , Combustion , Cooling , Engineering simulation

HC and CO Emission Abatement via Selective Fuel Injection

D. W. Bahr

GT 1982; V003T06A026https://doi.org/10.1115/82-GT-178

Abstract

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Topics: Emissions , Fuels , Engines , Combustion chambers , Nozzles , Annulus , Aircraft , Carbon , Turbofans

Application of Heavy Fuel Test Results to Gas Turbine Operation

R. S. Rose, A. Caruvana, A. Cohn, H. Von Doering

GT 1982; V003T06A027https://doi.org/10.1115/82-GT-193

Abstract

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Topics: Fuels , Gas turbines , Water , Nozzles , Temperature , Coke , Cooling , Drops , Economics , Electricity (Physics)

Fuel Tolerance of Staged Combustors

T. J. Rosfjord, R. A. Sederquist, L. C. Angello

GT 1982; V003T06A028https://doi.org/10.1115/82-GT-195

Abstract

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Topics: Combustion chambers , Fuels , Synthetic fuels , Emissions , Combustion systems , Durability , Electricity (Physics) , Gas turbines , Heating , Hydrogen

Combustion of Medium Heating Value Coal Gas at Turbine Operating Conditions

J. A. Schwab, D. C. Cicero, R. S. Basel

GT 1982; V003T06A029https://doi.org/10.1115/82-GT-197

Abstract

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Topics: Coal , Combustion , Heating , Turbines , Fuels , Combustion chambers , Emissions , Fluidized beds , Fuel gasification , Gaseous fuels

Combustor Flame Radiation and Wall Temperatures for #2 Distillate and a Coal Derived Liquid Fuel

R. J. Kuznar, E. W. Tobery, A. Cohn

GT 1982; V003T06A030https://doi.org/10.1115/82-GT-208

Abstract

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Topics: Coal , Combustion chambers , Flames , Fuels , Radiation (Physics) , Wall temperature , Temperature , Combustion , Heat flux , Film cooling

Effect of Using Emulsions of High Nitrogen Containing Fuels and Water in a Gas Turbine Combustor on NO_x and Other Emissions

P. P. Singh, P. R. Mulik, A. Cohn

GT 1982; V003T06A031https://doi.org/10.1115/82-GT-224

Abstract

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Topics: Combustion chambers , Emissions , Emulsions , Fuels , Gas turbines , Nitrogen , Nitrogen oxides , Water , Underground injection , Carbon

A Procedure for Evaluating Fuel Composition Effects on Combustor Life

H. L. Foltz, M. J. Kenworthy

GT 1982; V003T06A032https://doi.org/10.1115/82-GT-296

Abstract

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Topics: Combustion chambers , Fuels , Temperature , Coolants , Fracture (Materials) , Materials properties , Metals , Service life (Equipment) , Stress , Stress concentration

Oil and Gas Applications

Kawasaki Gas Turbine Engines for Generator Sets

Y. Otsuki, Y. Nishihara, E. Ito, A. Hoshino, I. Inobe

GT 1982; V003T07A001https://doi.org/10.1115/82-GT-6

Abstract

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Topics: Gas turbines , Generators , Industrial gases , Design , Engines , Turbines

Development of 20,000 to 50,000 HP Aircraft-Derivative Gas Turbines

K. Takeo, Y. Shimura

GT 1982; V003T07A002https://doi.org/10.1115/82-GT-23

Abstract

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Topics: Aircraft , Gas turbines , Stress , Blades , Engines , Turbines , Reliability , Resonance , Rotor assembly , Strain gages

The Use of Performance-Monitoring to Prevent Compressor and Turbine Blade Failures

R. E. Dundas

GT 1982; V003T07A003https://doi.org/10.1115/82-GT-66

Abstract

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Topics: Compressors , Failure , Turbine blades , Fatigue , Flutter (Aerodynamics) , Resonance , Vibration , Axial flow , Blades , Gas turbines

Factory Testing Gas Turbines and Driven Equipment for Prudhoe Bay, Alaska (EOA)

L. L. Broadbent

GT 1982; V003T07A004https://doi.org/10.1115/82-GT-119

Abstract

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Topics: Gas turbines , Testing , Delays , Maintenance , Trains

Accuracy Expectations for Gas Turbine and Centrifugal Compressor Performance Testing

T. C. Heard, E. J. Hipp

GT 1982; V003T07A005https://doi.org/10.1115/82-GT-128

Abstract

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Topics: Compressors , Gas turbines , Testing performance , Errors , Engineers , Uncertainty , Accuracy and precision , Equipment performance , Fuel consumption , Instrumentation

Performance Testing of Gas Turbine Compressor Sets

A. Cleveland

GT 1982; V003T07A006https://doi.org/10.1115/82-GT-199

Abstract

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Topics: Compressors , Gas turbines , Testing performance , Testing

Low Heating Value Fuel Burning Capabilities of General Electric Industrial Gas Turbines

R. A. Battista, R. P. Pandalai, M. B. Hilt

GT 1982; V003T07A007https://doi.org/10.1115/82-GT-255

Abstract

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Topics: Combustion , Fuels , Heating , Industrial gases , Turbines , Gas turbines , Aircraft , Combustion systems , Energy generation , Temperature effects

The Status and Prospects of the Industrial and Marine Gas Turbine With Particular Reference to the RB.211

B. H. Slatter

GT 1982; V003T07A008https://doi.org/10.1115/82-GT-279

Abstract

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Topics: Marine gas turbines , Cycles , Diesel engines , Engines

Operating Experience With Five Sulzer Gas Turbine-Compressor Modules in an Off-Shore Gas Lift Application

A. C. Brunner, A. Maurer

GT 1982; V003T07A009https://doi.org/10.1115/82-GT-282

Abstract

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Topics: Compressors , Ocean engineering , Turbines , Inspection , Maintenance , Reliability

Oil Field Experience With Gas Turbine-Driven Compressor Stations

H. Saadawi

GT 1982; V003T07A010https://doi.org/10.1115/82-GT-300

Abstract

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Topics: Compressors , Oil fields , Turbines , Compression , Design , Engineering disciplines , Errors , Teams

Sliding Pressure Operation in Combined Cycles

M. P. Polsky

GT 1982; V003T07A011https://doi.org/10.1115/82-GT-308

Abstract

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Topics: Combined cycles , Pressure , Stress , Gas turbines , Boilers , Power stations , Pressure control , Steam turbines

Centrifugal Compressor Testing Experience and Practice

R. H. Meier, C. S. Rhea

GT 1982; V003T07A012https://doi.org/10.1115/82-GT-320

Abstract

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Topics: Compressors , Testing , Testing performance , Instrumentation , Natural gas

Cycle Innovations

A Study of a High Temperature Nuclear Power Plant Incorporating a Non-Integrated Indirect Cycle Gas Turbine

G. Sarlos, W. Helbling, E. Zollinger, N. Gregory, H. Luchsinger

GT 1982; V003T08A001https://doi.org/10.1115/82-GT-39

Abstract

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Topics: Cycles , Gas turbines , High temperature , Nuclear power stations , Design , Plant design

Cryogenic Turbine Testing

R. J. Iannuzzelli, R. E. Filippi

GT 1982; V003T08A002https://doi.org/10.1115/82-GT-113

Abstract

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Topics: Data acquisition , Engineers , Instrumentation , Machine testing , Testing , Turbines , Turbomachinery

Status Report: Advanced Heat Exchanger Technology for a CCGT Power Generation System

D. E. Wright, L. L. Tignac

GT 1982; V003T08A003https://doi.org/10.1115/82-GT-164

Abstract

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Topics: Energy / power systems , Heat exchangers , Coal , Fluidized beds , Ceramics , Combined heat and power , Combustion systems , Design , Energy generation , High temperature

Design of a 6- by 6-Foot Coal-Fired Heater for a CCGT Air Heater

L. H. Russell, J. Campbell, Jr.

GT 1982; V003T08A004https://doi.org/10.1115/82-GT-171

Abstract

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Topics: Coal , Design , Fluidized beds , Atmospheric pressure , Closed-cycle gas turbines , Combined heat and power , Combustion , Dimensions , Fluids , Heat

Indirect Pulverized-Coal Fired Air Heaters for Gas Turbine Service

D. Anson, H. R. Hazard, L. J. Flanigan

GT 1982; V003T08A005https://doi.org/10.1115/82-GT-172

Abstract

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Topics: Coal , Gas turbines , Design , Flames , Flow (Dynamics) , Flue gases , Furnaces , Temperature , Metals , Radiation (Physics)

Feasibility of Modifying Large Gas Turbines for Integration With External Heat Sources

S. C. Kuo, T. L. O. Horton, E. R. Fisher, J. E. Bigger

GT 1982; V003T08A006https://doi.org/10.1115/82-GT-179

Abstract

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Topics: Gas turbines , Heat , Cycles , Solar thermal power , Turbomachinery , Combustion chambers , Conceptual design , Electric power generation , Energy resources , Solar energy

Comparative Performance Study of Closed Cycle Gas Turbine Utilizing Cryogenic Cold

W. H. Lee

GT 1982; V003T08A007https://doi.org/10.1115/82-GT-180

Abstract

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Topics: Closed-cycle gas turbines , Cycles , Temperature , Liquefied natural gas , Low temperature , Evaporation , Heat exchangers , Heat sinks , Thermal efficiency , Thermodynamic power cycles

Split-Flow Nuclear Gas Turbine Cycle Using Dissociating N₂O₄

K. Kesavan, J. F. Osterle

GT 1982; V003T08A008https://doi.org/10.1115/82-GT-181

Abstract

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Topics: Cycles , Flow (Dynamics) , Gas turbines , Condensation , Gas compressors , Nitrogen , Pressure , Pumps , Temperature , Turbines

Fired Heater Versus CCGT/Cogeneration Cycle Parameters

J. Campbell, Jr., J. C. Lee

GT 1982; V003T08A009https://doi.org/10.1115/82-GT-187

Abstract

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Topics: Combined heat and power , Cycles , Coal , Heat , Closed-cycle gas turbines , Combustion , Fluid pressure , Fluids , Gas turbines , Heat engines

Performance Characteristics of Indirect-Fired Gas Turbine/Cogeneration Cycles

J. C. Lee

GT 1982; V003T08A010https://doi.org/10.1115/82-GT-196

Abstract

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Topics: Combined heat and power , Cycles , Gas turbines , Performance characterization , Design , Closed-cycle gas turbines , Cogeneration systems , Heat , Pressure , Steam turbines

The Gas Turbine Heat Exchanger in the Fluidized Bed Combustor

C. F. Holt, A. A. Boiarski, H. E. Carlton

GT 1982; V003T08A011https://doi.org/10.1115/82-GT-225

Abstract

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Topics: Combustion chambers , Fluidized beds , Gas turbines , Heat exchangers , Coal , Oxygen , Pressure , Design , Closed-cycle gas turbines , Combined heat and power

Materials Selection for Metallic Heat Exchangers in Advanced Coal-Fired Heaters

I. G. Wright, A. J. Minchener

GT 1982; V003T08A012https://doi.org/10.1115/82-GT-226

Abstract

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Topics: Coal , Heat exchangers , Alloys , Combustion chambers , Corrosion , Fluidized beds , Fluids , Nickel , Cladding systems (Building) , Closed-cycle gas turbines

The Nuclear Gas Turbine: A Perspective on a Long-Term Advanced Technology HTGR Plant Option

C. F. McDonald, C. O. Peinado

GT 1982; V003T08A013https://doi.org/10.1115/82-GT-289

Abstract

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Topics: Gas turbines , Very high temperature reactors , Cycles , Design , Steam , Brayton cycle , Combined cycles , Combined heat and power , Economics , Innovation

Optimum Cycle Parameters of Coal Fired Closed Cycle Gas Turbine in Regenerative and Combined Cycle Configurations

J. S. Rao

GT 1982; V003T08A014https://doi.org/10.1115/82-GT-290

Abstract

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Topics: Closed-cycle gas turbines , Coal , Combined cycles , Cycles , Compressors , Gases , Helium , Pressure , Carbon dioxide , Performance evaluation

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