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Proceedings Papers

Proceedings Volume Cover
ASME 1967 Gas Turbine Conference and Products Show
March 5–9, 1967
Houston, Texas, USA
Conference Sponsors:
  • International Gas Turbine Institute
ISBN:
978-0-7918-7988-7
In This Volume
ASME 1967 Gas Turbine Conference and Products Show

General

Effects of Turbine Atmospheres on Sulfidation Corrosion
M. J. Donachie, Jr., E. F. Bradley, R. A. Sprague, F. P. Talboom
GT 1967; V001T01A002https://doi.org/10.1115/67-GT-2
View Articletitled, Effects of Turbine Atmospheres on Sulfidation Corrosion
PDF
Topics: Corrosion , Turbines , Alloys , Fuels , Gas turbines , Sulfur , Testing
A Comparison of Oil and Gas Lubrication Systems for Closed-Loop Gas-Turbine Machinery
P. W. Curwen, R. A. Harmon, G. B. Manning
GT 1967; V001T01A003https://doi.org/10.1115/67-GT-3
View Articletitled, A Comparison of Oil and Gas Lubrication Systems for Closed-Loop Gas-Turbine Machinery
PDF
Topics: Gas turbines , Industrial lubrication systems , Machinery , Cycles , Lubrication , Bearings , Design , Fluids , Leakage , Lubricants
The Influence of Tailpipe Length on Flame Stability
Louis G. Palermo, John R. O’Loughlin
GT 1967; V001T01A004https://doi.org/10.1115/67-GT-4
View Articletitled, The Influence of Tailpipe Length on Flame Stability
PDF
Topics: Flames , Stability , Pipes
The Effects of Microstructural Variations on Stress-Corrosion Cracking Susceptibility of Ti-8Al-1Mo-1V Alloy on Marinized Gas Turbines
W. P. Danesi, R. A. Sprague, M. J. Donachie, Jr.
GT 1967; V001T01A005https://doi.org/10.1115/67-GT-5
View Articletitled, The Effects of Microstructural Variations on Stress-Corrosion Cracking Susceptibility of Ti-8Al-1Mo-1V Alloy on Marinized Gas Turbines
PDF
Topics: Alloys , Cracking (Materials) , Fracture (Process) , Gas turbines , Stress corrosion cracking , Testing , Titanium alloys , Fracture (Materials) , High temperature , Stress
Working Fluid as a Design Variable for a Family of Small Rankine Power Systems
John W. Bjerklie
GT 1967; V001T01A006https://doi.org/10.1115/67-GT-6
View Articletitled, Working Fluid as a Design Variable for a Family of Small Rankine Power Systems
PDF
Topics: Design , Fluids , Power systems (Machinery) , Temperature , Bearings , Rankine cycle , Turbines , Turbomachinery
Design Aspects of Power Plants for V/STOL Aircraft
J. F. Coplin
GT 1967; V001T01A007https://doi.org/10.1115/67-GT-7
View Articletitled, Design Aspects of Power Plants for V/STOL Aircraft
PDF
Topics: Aircraft , Design , Power stations , Thrust , Engines , Fans , Jets , Flight , Weight (Mass) , Generators
Bristol Siddeley/SNECMA Olympus 593 Powerplant for Concorde
Derek J. John
GT 1967; V001T01A008https://doi.org/10.1115/67-GT-8
View Articletitled, Bristol Siddeley/SNECMA Olympus 593 Powerplant for Concorde
PDF
Topics: Power stations , Engines , Turbojets , Aircraft , Axial flow , Fuels , Oils , Petroleum
Metallurgical and Fluid Dynamic Results of a 2000-Hour Endurance Test on a Two-Stage, 200-Horsepower Turbine in Wet Potassium Vapor
W. F. Zimmerman, R. J. Rossbach
GT 1967; V001T01A009https://doi.org/10.1115/67-GT-9
View Articletitled, Metallurgical and Fluid Dynamic Results of a 2000-Hour Endurance Test on a Two-Stage, 200-Horsepower Turbine in Wet Potassium Vapor
PDF
Topics: Fluids , Horsepower , Potassium , Turbines , Vapors , Erosion , Stainless steel , Testing , Cavitation , Contamination
Industrial Closed-Cycle Gas Turbines for Conventional and Nuclear Fuel
C. Keller, D. Schmidt
GT 1967; V001T01A010https://doi.org/10.1115/67-GT-10
View Articletitled, Industrial Closed-Cycle Gas Turbines for Conventional and Nuclear Fuel
PDF
Topics: Closed-cycle gas turbines , Nuclear fuels , Fossil fuels , Gas turbines , Helium , High temperature , Nuclear power stations , Plant design
Description and Operating Experience of Three Regenerative-Cycle Gas Turbines Installed in an Argentine Portland Cement Plant
Rolando Thomas
GT 1967; V001T01A011https://doi.org/10.1115/67-GT-11
View Articletitled, Description and Operating Experience of Three Regenerative-Cycle Gas Turbines Installed in an Argentine Portland Cement Plant
PDF
Topics: Cement plants , Cycles , Gas turbines
A Quantitative Method of Screening Working Fluids for Rankine-Cycle Power Plants
Stephen Luchter
GT 1967; V001T01A012https://doi.org/10.1115/67-GT-12
View Articletitled, A Quantitative Method of Screening Working Fluids for Rankine-Cycle Power Plants
PDF
Topics: Fluids , Power stations , Rankine cycle , Turbines
Status of the Army Closed-Brayton-Cycle Gas Turbine Program
John A. Bailey, Franklin D. Jordan, Carey A. Kinney
GT 1967; V001T01A013https://doi.org/10.1115/67-GT-13
View Articletitled, Status of the Army Closed-Brayton-Cycle Gas Turbine Program
PDF
Topics: Army , Cycles , Gas turbines , Energy conversion , Fortification
A Rapid Approximate Method of Determining Axial-Flow Turbine Disk and Blade Temperatures
F. M. Simpson
GT 1967; V001T01A014https://doi.org/10.1115/67-GT-14
View Articletitled, A Rapid Approximate Method of Determining Axial-Flow Turbine Disk and Blade Temperatures
PDF
Topics: Axial flow , Blades , Disks , Temperature , Turbines , Geometry , Cooling , Computer programming , Journal bearings , Rotors
Pneumatic Starting Systems
Robert J. Von Flue
GT 1967; V001T01A015https://doi.org/10.1115/67-GT-15
View Articletitled, Pneumatic Starting Systems
PDF
Topics: Compressors , Energy resources , Gas turbines , Reliability , Turbines
The Thermodynamic Design of a Combined Steam and Gas Turbine Marine Propulsion System
R. M. Marwood, C. A. Bassilakis
GT 1967; V001T01A016https://doi.org/10.1115/67-GT-16
View Articletitled, The Thermodynamic Design of a Combined Steam and Gas Turbine Marine Propulsion System
PDF
Topics: Design , Gas turbines , Propulsion systems , Steam , High pressure (Physics) , Aircraft , Boilers , Cycles , Diesel , Heating
The Materials Challenge of High-Temperature Turbine Vanes and Blades
W. R. Martens, W. A. Raabe
GT 1967; V001T01A017https://doi.org/10.1115/67-GT-17
View Articletitled, The Materials Challenge of High-Temperature Turbine Vanes and Blades
PDF
Topics: Blades , High temperature , Turbines , Corrosion , Creep , Fatigue , Temperature , Coating processes , Coatings , Cooling
An Examination of the Propulsion System for the Compound Helicopter
Lester B. Veno
GT 1967; V001T01A018https://doi.org/10.1115/67-GT-18
View Articletitled, An Examination of the Propulsion System for the Compound Helicopter
PDF
Topics: Design , Disks , Drag (Fluid dynamics) , Engines , Fuels , Hybrid electric vehicles , Propellers , Propulsion systems , Weight (Mass) , Wings
Residual Oil Combustion in Gas Turbines: State of the Art
William G. Taylor
GT 1967; V001T01A019https://doi.org/10.1115/67-GT-19
View Articletitled, Residual Oil Combustion in Gas Turbines: State of the Art
PDF
Topics: Combustion , Gas turbines , Fuels , Maintenance , Stress , Turbines
Development of Cartridges for Aircraft Engine Cartridge Starters
Joseph T. Hamrick
GT 1967; V001T01A020https://doi.org/10.1115/67-GT-21
View Articletitled, Development of Cartridges for Aircraft Engine Cartridge Starters
PDF
Topics: Aircraft engines , Design , High pressure (Physics) , Propellants , Storage , Turbines
Heat Recovery for Gas Turbine an Advanced Design
P. E. Clay
GT 1967; V001T01A021https://doi.org/10.1115/67-GT-22
View Articletitled, Heat Recovery for Gas Turbine an Advanced Design
PDF
Topics: Design , Gas turbines , Heat recovery , Boilers , Heat transfer , Pressure
Pressure Oscillations in a Combustor With Dual-Orifice Fuel Injection
Rodney H. Hudson
GT 1967; V001T01A022https://doi.org/10.1115/67-GT-23
View Articletitled, Pressure Oscillations in a Combustor With Dual-Orifice Fuel Injection
PDF
Topics: Combustion chambers , Fuels , Oscillations , Pressure , Flow (Dynamics) , Nozzles , Combustion , Engines , Gas turbines , Sprays
Gas Turbine Propulsion for High-Speed Railcars
P. B. Garner, W. L. Hull
GT 1967; V001T01A023https://doi.org/10.1115/67-GT-24
View Articletitled, Gas Turbine Propulsion for High-Speed Railcars
PDF
Topics: Gas turbines , Propulsion , Turbines , Mechanical drives , Power stations , Propulsion systems , Railroads
Development of the Combustion System for the AiResearch TPE331 Turboprop Engine
J. M. Haasis
GT 1967; V001T01A024https://doi.org/10.1115/67-GT-25
View Articletitled, Development of the Combustion System for the AiResearch TPE331 Turboprop Engine
PDF
Topics: Combustion systems , Engines , Design , Gas turbines , Thermoplastic rubber
Mechanisms of Gas Turbine Regenerator Fouling
James A. Miller
GT 1967; V001T01A025https://doi.org/10.1115/67-GT-26
View Articletitled, Mechanisms of Gas Turbine Regenerator Fouling
PDF
Topics: Gas turbines , Adhesives , Coating processes , Coatings , Condensation , Heat transfer , Particulate matter , Pressure drop
The Use of Gases Other Than Air in the Acoustical Testing of Model Compressors
R. J. Wells, J. M. McGrew
GT 1967; V001T01A026https://doi.org/10.1115/67-GT-27
View Articletitled, The Use of Gases Other Than Air in the Acoustical Testing of Model Compressors
PDF
Topics: Acoustics , Compressors , Gases , Testing , Air compressors , Axial flow , Closed loop systems , Engineering prototypes , Scaling laws (Mathematical physics)
Control Design and Experience on CODAG-Powered 210-ft Reliance-Class Cutters
Reed D. Hamilton
GT 1967; V001T01A027https://doi.org/10.1115/67-GT-28
View Articletitled, Control Design and Experience on CODAG-Powered 210-ft Reliance-Class Cutters
PDF
Topics: Design , Control systems , Stress , Vessels , Diesel engines , Gas turbines , Machinery , Propulsion
Experimental Results of a Transpiration-Cooled Turbine Operated in an Engine for 150 Hours at 2500 F Turbine Inlet Temperature
S. Lombardo, S. L. Moskowitz, S. A. Schnure
GT 1967; V001T01A028https://doi.org/10.1115/67-GT-29
View Articletitled, Experimental Results of a Transpiration-Cooled Turbine Operated in an Engine for 150 Hours at 2500 F Turbine Inlet Temperature
PDF
Topics: Engines , Temperature , Transpiration , Turbines , Alloys , Blades , Cooling , Melting , Metals , Oxidation
Operating Experience With Gas Turbines Under Arctic and Tropical Conditions
F. Arvidsson
GT 1967; V001T01A029https://doi.org/10.1115/67-GT-30
View Articletitled, Operating Experience With Gas Turbines Under Arctic and Tropical Conditions
PDF
Topics: Arctic region , Gas turbines , Climate
Gas Turbine Propulsion Machinery for the MSTS Roll-On/Roll-Off Ship
Donald L. Caldera, Gerald C. Swensson, Charles E. Hoch
GT 1967; V001T01A030https://doi.org/10.1115/67-GT-31
View Articletitled, Gas Turbine Propulsion Machinery for the MSTS Roll-On/Roll-Off Ship
PDF
Topics: Gas turbines , Machinery , Propulsion , Ships , Ocean liners , Design
Operating Gas Turbines in a Gas Processing Plant
Eugene B. Byrnes, Donald H. McCrary, Quinton L. Darnell
GT 1967; V001T01A031https://doi.org/10.1115/67-GT-32
View Articletitled, Operating Gas Turbines in a Gas Processing Plant
PDF
Topics: Gas turbines , Natural gas processing , Exhaust systems , Maintenance , Shorelines
Mobile Compressor Stations for Natural Gas Transmission Service
Trevor Albone
GT 1967; V001T01A032https://doi.org/10.1115/67-GT-33
View Articletitled, Mobile Compressor Stations for Natural Gas Transmission Service
PDF
Topics: Compressors , Natural gas , Aircraft , Compression , Design , Generators , Pipelines , Stress , Turbines , Weight (Mass)
Performance Testing of the Compact APCSE Closed Brayton-Cycle System
J. M. Janis, G. S. Braun, R. D. Ryan
GT 1967; V001T01A033https://doi.org/10.1115/67-GT-34
View Articletitled, Performance Testing of the Compact APCSE Closed Brayton-Cycle System
PDF
Topics: Brayton cycle , Testing performance , Cycles , Energy conversion , Power conversion systems
Creole’s 50 Industrial Gas Turbines in Repressuring Service
L. B. Sanborn
GT 1967; V001T01A034https://doi.org/10.1115/67-GT-35
View Articletitled, Creole’s 50 Industrial Gas Turbines in Repressuring Service
PDF
Topics: Industrial gases , Secondary petroleum recovery , Turbines , Gas turbines , Crude oil , Design , Flow (Dynamics) , Pressure , Reservoirs , Wells
Gas Turbines Supply Power for Electrolytic Cells
R. J. Swofford
GT 1967; V001T01A035https://doi.org/10.1115/67-GT-36
View Articletitled, Gas Turbines Supply Power for Electrolytic Cells
PDF
Topics: Gas turbines , Boilers , Cycles , Ducts , Electricity (Physics) , Exhaust systems , Generators , Heat , Power stations , Shells
AiResearch Energy Systems Applications of the 831 Series Gas Turbines
Russell V. Hoffman
GT 1967; V001T01A036https://doi.org/10.1115/67-GT-37
View Articletitled, AiResearch Energy Systems Applications of the 831 Series Gas Turbines
PDF
Topics: Energy / power systems , Gas turbines , Absorption , Compressors , Energy conversion , Exhaust systems , Heat exchangers , Turbines , Turbochargers
The Design and Application of the Gas Turbine Heat Recovery Boiler
J. C. Stewart, H. J. Stretch
GT 1967; V001T01A037https://doi.org/10.1115/67-GT-38
View Articletitled, The Design and Application of the Gas Turbine Heat Recovery Boiler
PDF
Topics: Boilers , Design , Gas turbines , Heat recovery , Heat , Computer software , Exhaust systems , Heat transfer , Steam , Trains
Mechanical Drive Combined-Cycle Gas and Steam Turbines for Northern Gas Products
B. F. Wobker, C. E. Knight
GT 1967; V001T01A038https://doi.org/10.1115/67-GT-39
View Articletitled, Mechanical Drive Combined-Cycle Gas and Steam Turbines for Northern Gas Products
PDF
Topics: Combined cycles , Mechanical drives , Steam turbines , Compressors , Gas turbines , Natural gas , Reliability , Stress , Combined cycle power stations , Helium
The Design and Economics of On-Site Generation With Aircraft-Type Gas Turbines for a Chemical Complex
A. B. Crouchley, C. E. Carroll’
GT 1967; V001T01A039https://doi.org/10.1115/67-GT-40
View Articletitled, The Design and Economics of On-Site Generation With Aircraft-Type Gas Turbines for a Chemical Complex
PDF
Topics: Aircraft , Design , Economics , Gas turbines , Energy generation , Steam , Waste heat
Thermal Efficiency Versus Engine Price: Optimizing for Industrial Vehicles
Glenn W. Kahle, Edward S. Wright
GT 1967; V001T01A040https://doi.org/10.1115/67-GT-41
View Articletitled, Thermal Efficiency Versus Engine Price: Optimizing for Industrial Vehicles
PDF
Topics: Engines , Thermal efficiency , Vehicles , Cycles , Gas turbines , Computers , Diesel , Fuel consumption , Pressure , Profitability
Gas Turbine Electrical Power and Steam Generation at Allison Division of General Motors
G. W. Bixler, H. J. Clifford
GT 1967; V001T01A041https://doi.org/10.1115/67-GT-42
View Articletitled, Gas Turbine Electrical Power and Steam Generation at Allison Division of General Motors
PDF
Topics: Electricity (Physics) , Gas turbines , Motors , Steam , Aircraft engines , Boilers , Diesel , Engineering prototypes , Engines , Exhaust systems
Control System for and Sea Operation Experience With CODOG-Powered Frigates
Stig Olof Svensson
GT 1967; V001T01A042https://doi.org/10.1115/67-GT-43
View Articletitled, Control System for and Sea Operation Experience With CODOG-Powered Frigates
PDF
Topics: Control systems , Seas , Navy , Propellers , Diesel engines , Engines , Gas turbines , Gears , Governors , Instrumentation
Recent Sea-Salt-in-Air Implications as Highlighted by Marine Gas Turbine Requirements
R. E. Kaufman, R. J. Pollini
GT 1967; V001T01A043https://doi.org/10.1115/67-GT-44
View Articletitled, Recent Sea-Salt-in-Air Implications as Highlighted by Marine Gas Turbine Requirements
PDF
Topics: Marine gas turbines , Seas , Damage , Electromagnetic induction , Vessels , Wind
Process Air Extraction From a Gas Turbine
P. C. Husen
GT 1967; V001T01A044https://doi.org/10.1115/67-GT-45
View Articletitled, Process Air Extraction From a Gas Turbine
PDF
Topics: Gas turbines , Compressors , Exhaust systems , Petrochemicals , Stress , Waste heat
Gas Turbine Versatility as a Generator Driver
O. F. Kay
GT 1967; V001T01A045https://doi.org/10.1115/67-GT-46
View Articletitled, Gas Turbine Versatility as a Generator Driver
PDF
Topics: Gas turbines , Generators
Design of Compressor Blades Suitable for Transonic Axial-Flow Compressors
M. P. Boyce
GT 1967; V001T01A046https://doi.org/10.1115/67-GT-47
View Articletitled, Design of Compressor Blades Suitable for Transonic Axial-Flow Compressors
PDF
Topics: Axial flow , Blades , Compressors , Design , Computer programming , Computers , Design methodology , Flow charts , Mach number
V/STOL Aircraft Gas Turbine Requirements
O. G. Robbins
GT 1967; V001T01A047https://doi.org/10.1115/67-GT-48
View Articletitled, V/STOL Aircraft Gas Turbine Requirements
PDF
Topics: Aircraft , Gas turbines , Engines , Propulsion systems , Fans , Generators , Turbofans , Turbojets
Jet Engine Starters, Cartridge-Pneumatic
J. A. Anderson, C. R. Galasinski
GT 1967; V001T01A048https://doi.org/10.1115/67-GT-49
View Articletitled, Jet Engine Starters, Cartridge-Pneumatic
PDF
Topics: Jet engines , Design , Energy conversion , Engine start-up , High pressure (Physics) , High temperature
Fuels for Marine Gas Turbines
A. V. Cabal, J. H. Warren
GT 1967; V001T01A049https://doi.org/10.1115/67-GT-50
View Articletitled, Fuels for Marine Gas Turbines
PDF
Topics: Fuels , Marine gas turbines , Contamination , Engines
The Marine Gas Turbine Regenerator Material and Fabrication Considerations
H. A. Weber, E. C. Thorsrud
GT 1967; V001T01A050https://doi.org/10.1115/67-GT-51
View Articletitled, The Marine Gas Turbine Regenerator Material and Fabrication Considerations
PDF
Topics: Manufacturing , Marine gas turbines , Heat exchangers , Gas turbines , Navy , Power stations , Ships , Thermal efficiency
Fuel Problems With Marine Gas Turbine Engines
J. P. Attiani
GT 1967; V001T01A051https://doi.org/10.1115/67-GT-52
View Articletitled, Fuel Problems With Marine Gas Turbine Engines
PDF
Topics: Copper , Filters , Fuel oils , Fuels , Gas turbines , Marine gas turbines , Navy , Nozzles , Thermal stability
Supplementary Firing of Gas Turbine Exhaust Systems
Ed Gjerde
GT 1967; V001T01A052https://doi.org/10.1115/67-GT-53
View Articletitled, Supplementary Firing of Gas Turbine Exhaust Systems
PDF
Topics: Exhaust systems , Firing , Gas turbines , Waste heat , Design , Flames , Temperature profiles , Ducts , Laminar flow , Radiation effects
A 3-Shaft Gas Turbine to Meet Automotive Requirements
P. J. Collet
GT 1967; V001T01A053https://doi.org/10.1115/67-GT-54
View Articletitled, A 3-Shaft Gas Turbine to Meet Automotive Requirements
PDF
Topics: Gas turbines , Engines , Braking , Nozzles , Pressure , Stress , Torque , Turbines , Automotive industry , Cycles
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