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February 1956
This article was originally published in
Transactions of the American Society of Mechanical Engineers
ISSN 0097-6822
In this Issue
Research Papers
Oil and Gas-Well Casing Suspension Assemblies
Trans. ASME. February 1956, 78(2): 225–232.
doi: https://doi.org/10.1115/1.4013622
Topics:
Natural gas wells
,
Design
,
Deflection
,
Engineers
,
Stress
Study of Pneumatic Processes in the Continuous Control of Motion With Compressed Air—I
Trans. ASME. February 1956, 78(2): 233–241.
doi: https://doi.org/10.1115/1.4013623
Topics:
Compressed air
,
Damping
,
Flow (Dynamics)
,
Fluids
,
Motion control
,
Pressure
,
Servomotors
,
Stress
,
Valves
Study of Pneumatic Processes in the Continuous Control of Motion With Compressed Air—II
Trans. ASME. February 1956, 78(2): 243–249.
doi: https://doi.org/10.1115/1.4013626
Topics:
Compressed air
,
Damping
,
Design
,
Flow (Dynamics)
,
Motion control
,
Servomotors
,
Stress
,
Unsteady flow
,
Valves
Dynamic Analysis of Chemical Processes
Trans. ASME. February 1956, 78(2): 251–257.
doi: https://doi.org/10.1115/1.4013627
Topics:
Chemical processes
,
Dynamic analysis
,
Equations of motion
,
Heat
,
Stability
,
Transfer functions
Determination of System Characteristics from Normal Operating Records
Trans. ASME. February 1956, 78(2): 259–268.
doi: https://doi.org/10.1115/1.4013632
Topics:
Delay lines
,
Linear systems
,
Noise (Sound)
The Chemical Deaeration of Boiler Water—The Use of Hydrazine Compounds
Trans. ASME. February 1956, 78(2): 273–279.
doi: https://doi.org/10.1115/1.4013638
Topics:
Boilers
,
Water
,
Chemical kinetics
,
Oxygen
,
Catalysts
,
High pressure (Physics)
Controlling Iron and Copper Pickup With Neutralizing Amines
Trans. ASME. February 1956, 78(2): 287–294.
doi: https://doi.org/10.1115/1.4013646
Topics:
Copper
,
Iron
,
Boilers
,
Cycles
,
Feedwater
,
High pressure (Physics)
,
Sampling methods
,
Steam
Hydrazine as an Oxygen Scavenger—A Progress Report on Tests at Springdale Station
Trans. ASME. February 1956, 78(2): 299–303.
doi: https://doi.org/10.1115/1.4013651
Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater
Trans. ASME. February 1956, 78(2): 305–310.
doi: https://doi.org/10.1115/1.4013654
Topics:
Flue gases
,
Solids
,
Temperature
,
High temperature
,
Air pollution
,
Low temperature
,
Pressure vessel systems
,
Smoke
,
Stress
Design Aspects of an Electrostatic Precipitator for the Collection of Small Solids Ahead of the Air Heater
Trans. ASME. February 1956, 78(2): 317–325.
doi: https://doi.org/10.1115/1.4013667
Investigations Into Blade-Root Fixings of High-Temperature Steels
Trans. ASME. February 1956, 78(2): 327–338.
doi: https://doi.org/10.1115/1.4013672
Topics:
Blades
,
High temperature
,
Steel
,
Aircraft
,
Stress
,
Structural design
,
Temperature
,
Automobiles
,
Creep
,
Disks
Factors Influencing the Notch Fatigue Strengthening of N-155 Alloy at Elevated Temperatures
Trans. ASME. February 1956, 78(2): 339–347.
doi: https://doi.org/10.1115/1.4013673
Topics:
Alloys
,
Fatigue
,
Temperature
,
Stress
,
Finishes
Factors Influencing the Notch-Rupture Strength of Heat-Resistant Alloys at Elevated Temperatures
Trans. ASME. February 1956, 78(2): 349–358.
doi: https://doi.org/10.1115/1.4013676
Topics:
Alloys
,
Heat
,
Rupture
,
Temperature
,
Stress
,
Deformation
,
Ductility
,
Fracture (Materials)
,
Fracture (Process)
,
Geometry
Orifice Coefficients for Reynolds Numbers from 4 to 50,000
Trans. ASME. February 1956, 78(2): 359–364.
doi: https://doi.org/10.1115/1.4013677
Topics:
Reynolds number
,
Pipes
,
Calibration
,
Engineering standards
,
Manufacturing
,
Mechanical engineers
,
Orifices
,
Shapes
Discharge Measurements at Low Reynolds Numbers—Special Devices
Trans. ASME. February 1956, 78(2): 365–368.
doi: https://doi.org/10.1115/1.4013678
Topics:
Reynolds number
,
Discharge coefficient
,
Diffusers
,
Flowmeters
,
Friction
,
Nozzles
Effect of a Globe Valve in Approach Piping on Orifice-Meter Accuracy
Trans. ASME. February 1956, 78(2): 369–371.
doi: https://doi.org/10.1115/1.4013680
Flow of Saturated Boiler Water Through Knife-Edge Orifices in Series
Trans. ASME. February 1956, 78(2): 373–376.
doi: https://doi.org/10.1115/1.4013681
Topics:
Boilers
,
Flow (Dynamics)
,
Orifices
,
Water
,
Pressure
Notes on Some Recently Published Experiments on Orifice Meters
Trans. ASME. February 1956, 78(2): 379–387.
doi: https://doi.org/10.1115/1.4013684
Topics:
Mechanical finishes (Metals)
,
Reynolds number
The Mechanism of Separation in the Louver-Type Dust Separator
Trans. ASME. February 1956, 78(2): 389–399.
doi: https://doi.org/10.1115/1.4013685
Topics:
Air flow
,
Blades
,
Dust
,
Particle collisions
,
Particulate matter
,
Separation (Technology)
,
Shapes
Plastic Working of Metals
Trans. ASME. February 1956, 78(2): 401–405.
doi: https://doi.org/10.1115/1.4013686
Topics:
Metals
,
Deformation
,
Temperature
,
Work hardening
Plasticity Equations and Their Application to Working of Metals in the Work-Hardening Range
Trans. ASME. February 1956, 78(2): 407–412.
doi: https://doi.org/10.1115/1.4013687
Topics:
Metals
,
Plasticity
,
Work hardening
,
Extruding
,
Stress
,
Compression
,
Deformation
,
Flow (Dynamics)
,
Aluminum
,
Friction
Plastic Metalworking
Trans. ASME. February 1956, 78(2): 413–415.
doi: https://doi.org/10.1115/1.4013688
Topics:
Atoms
,
Automobiles
,
Deformation
,
Flight
,
Flow (Dynamics)
,
Heat
,
Mathematics
,
Metal cutting
,
Metals
,
Metalworking
Performance Characteristics of Francis Type Pump-Turbines
Trans. ASME. February 1956, 78(2): 417–423.
doi: https://doi.org/10.1115/1.4013689
Topics:
Performance characterization
,
Pump turbines
,
Cavitation
,
Consulting engineers
,
Design
Zirconium-Fabrication Techniques and Alloy Development
Trans. ASME. February 1956, 78(2): 427–433.
doi: https://doi.org/10.1115/1.4013696
Topics:
Alloys
,
Manufacturing
,
Zirconium
,
Absorption
,
Corrosion resistance
,
Mechanical properties
,
Neutrons
,
Zirconium alloys
Laminar Free Convection from a Vertical Plate With Uniform Surface Heat Flux
Trans. ASME. February 1956, 78(2): 435–440.
doi: https://doi.org/10.1115/1.4013697
Topics:
Heat flux
,
Natural convection
,
Vertical plates
,
Heat transfer
,
Temperature
,
Boundary layers
,
Prandtl number
Heat Transfer to Laminar Flow in a Round Tube or Flat Conduit—The Graetz Problem Extended
Trans. ASME. February 1956, 78(2): 441–447.
doi: https://doi.org/10.1115/1.4013701
Topics:
Eigenfunctions
,
Eigenvalues
,
Heat flux
,
Heat transfer
,
Laminar flow
,
Wall temperature
Discussions and Closures
Discussion: “Study of Pneumatic Processes in the Continuous Control of Motion With Compressed Air—I” (Shearer, J. L., 1956, Trans. ASME, 78, pp. 233–241)
Trans. ASME. February 1956, 78(2): 241–242.
doi: https://doi.org/10.1115/1.4013624
Topics:
Compressed air
,
Motion control
Closure to “Discussion of ‘Study of Pneumatic Processes in the Continuous Control of Motion With Compressed Air—I’” (1956, Trans. ASME, 78, pp. 241–242)
Trans. ASME. February 1956, 78(2): 242.
doi: https://doi.org/10.1115/1.4013625
Topics:
Compressed air
,
Motion control
Discussion: “Dynamic Analysis of Chemical Processes” (Holzmann, E. G., 1956, Trans. ASME, 78, pp. 251–257)
Trans. ASME. February 1956, 78(2): 257.
doi: https://doi.org/10.1115/1.4013628
Topics:
Chemical processes
,
Dynamic analysis
Discussion: “Dynamic Analysis of Chemical Processes” (Holzmann, E. G., 1956, Trans. ASME, 78, pp. 251–257)
Trans. ASME. February 1956, 78(2): 257–258.
doi: https://doi.org/10.1115/1.4013629
Topics:
Chemical processes
,
Dynamic analysis
Discussion: “Dynamic Analysis of Chemical Processes” (Holzmann, E. G., 1956, Trans. ASME, 78, pp. 251–257)
Trans. ASME. February 1956, 78(2): 258.
doi: https://doi.org/10.1115/1.4013630
Topics:
Chemical processes
,
Dynamic analysis
Closure to “Discussions of ‘Dynamic Analysis of Chemical Processes’” (1956, Trans. ASME, 78, pp. 257–258)
Trans. ASME. February 1956, 78(2): 258.
doi: https://doi.org/10.1115/1.4013631
Topics:
Dynamic analysis
Discussion: “Determination of System Characteristics from Normal Operating Records” (Goodman, T. P., and Reswick, J. B., 1956, Trans. ASME, 78, pp. 259–268)
Trans. ASME. February 1956, 78(2): 268–269.
doi: https://doi.org/10.1115/1.4013633
Discussion: “Determination of System Characteristics from Normal Operating Records” (Goodman, T. P., and Reswick, J. B., 1956, Trans. ASME, 78, pp. 259–268)
Trans. ASME. February 1956, 78(2): 269–270.
doi: https://doi.org/10.1115/1.4013634
Closure to “Discussions of ‘Determination of System Characteristics from Normal Operating Records’” (1956, Trans. ASME, 78, pp. 268–270)
Trans. ASME. February 1956, 78(2): 270–271.
doi: https://doi.org/10.1115/1.4013637
Discussion: “The Chemical Deaeration of Boiler Water—The Use of Hydrazine Compounds” (Leicester, J., 1956, Trans. ASME, 78, pp. 273–279)
Trans. ASME. February 1956, 78(2): 279–280.
doi: https://doi.org/10.1115/1.4013639
Discussion: “The Chemical Deaeration of Boiler Water—The Use of Hydrazine Compounds” (Leicester, J., 1956, Trans. ASME, 78, pp. 273–279)
Trans. ASME. February 1956, 78(2): 280.
doi: https://doi.org/10.1115/1.4013640
Discussion: “The Chemical Deaeration of Boiler Water—The Use of Hydrazine Compounds” (Leicester, J., 1956, Trans. ASME, 78, pp. 273–279)
Trans. ASME. February 1956, 78(2): 280–281.
doi: https://doi.org/10.1115/1.4013641
Discussion: “The Chemical Deaeration of Boiler Water—The Use of Hydrazine Compounds” (Leicester, J., 1956, Trans. ASME, 78, pp. 273–279)
Trans. ASME. February 1956, 78(2): 281.
doi: https://doi.org/10.1115/1.4013642
Discussion: “The Chemical Deaeration of Boiler Water—The Use of Hydrazine Compounds” (Leicester, J., 1956, Trans. ASME, 78, pp. 273–279)
Trans. ASME. February 1956, 78(2): 281–282.
doi: https://doi.org/10.1115/1.4013643
Discussion: “The Chemical Deaeration of Boiler Water—The Use of Hydrazine Compounds” (Leicester, J., 1956, Trans. ASME, 78, pp. 273–279)
Trans. ASME. February 1956, 78(2): 282.
doi: https://doi.org/10.1115/1.4013644
Closure to “Discussions of ‘The Chemical Deaeration of Boiler Water—The Use of Hydrazine Compounds’” (1956, Trans. ASME, 78, pp. 279–282)
Trans. ASME. February 1956, 78(2): 282–285.
doi: https://doi.org/10.1115/1.4013645
Discussion: “Controlling Iron and Copper Pickup With Neutralizing Amines” (Ristroph, J. D., and Yorkgitis, E. A., 1956, Trans. ASME, 78, pp. 287–294)
Trans. ASME. February 1956, 78(2): 294–295.
doi: https://doi.org/10.1115/1.4013647
Discussion: “Controlling Iron and Copper Pickup With Neutralizing Amines” (Ristroph, J. D., and Yorkgitis, E. A., 1956, Trans. ASME, 78, pp. 287–294)
Trans. ASME. February 1956, 78(2): 295.
doi: https://doi.org/10.1115/1.4013648
Discussion: “Controlling Iron and Copper Pickup With Neutralizing Amines” (Ristroph, J. D., and Yorkgitis, E. A., 1956, Trans. ASME, 78, pp. 287–294)
Trans. ASME. February 1956, 78(2): 295–296.
doi: https://doi.org/10.1115/1.4013649
Closure to “Discussions of ‘Controlling Iron and Copper Pickup With Neutralizing Amines’” (1956, Trans. ASME, 78, pp. 294–296)
Trans. ASME. February 1956, 78(2): 296–297.
doi: https://doi.org/10.1115/1.4013650
Discussion: “Hydrazine as an Oxygen Scavenger—A Progress Report on Tests at Springdale Station” (Baker, M. D., and Marcy, V. M., 1956, Trans. ASME, 78, pp. 299–303)
Trans. ASME. February 1956, 78(2): 303–304.
doi: https://doi.org/10.1115/1.4013652
Topics:
Oxygen
Closure to “Discussion of ‘Hydrazine as an Oxygen Scavenger—A Progress Report on Tests at Springdale Station’” (1956, Trans. ASME, 78, pp. 303–304)
Trans. ASME. February 1956, 78(2): 304.
doi: https://doi.org/10.1115/1.4013653
Topics:
Oxygen
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 310.
doi: https://doi.org/10.1115/1.4013655
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 310–311.
doi: https://doi.org/10.1115/1.4013656
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 311.
doi: https://doi.org/10.1115/1.4013657
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 311.
doi: https://doi.org/10.1115/1.4013658
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 311–312.
doi: https://doi.org/10.1115/1.4013659
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 312.
doi: https://doi.org/10.1115/1.4013660
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 312.
doi: https://doi.org/10.1115/1.4013661
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 312–313.
doi: https://doi.org/10.1115/1.4013662
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 313.
doi: https://doi.org/10.1115/1.4013663
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 313–314.
doi: https://doi.org/10.1115/1.4013664
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater” (Tigges, A. J., and Karlsson, Hilmer, 1956, Trans. ASME, 78, pp. 305–310)
Trans. ASME. February 1956, 78(2): 314.
doi: https://doi.org/10.1115/1.4013665
Topics:
Flue gases
,
Solids
,
Temperature
Closure to “Discussions of ‘Lower Flue-Gas Exit Temperatures Through Removal of the Solids Ahead of the Air Preheater’” (1956, Trans. ASME, 78, pp. 310–314)
Trans. ASME. February 1956, 78(2): 314–315.
doi: https://doi.org/10.1115/1.4013666
Topics:
Flue gases
,
Solids
,
Temperature
Discussion: “Factors Influencing the Notch Fatigue Strengthening of N-155 Alloy at Elevated Temperatures” (Hyler, W. S., and Simmons, W. F., 1956, Trans. ASME, 78, pp. 339–347)
Trans. ASME. February 1956, 78(2): 347–348.
doi: https://doi.org/10.1115/1.4013674
Topics:
Alloys
,
Fatigue
,
Temperature
Discussion: “Discharge Measurements at Low Reynolds Numbers—Special Devices” (Jorissen, A. L., 1956, Trans. ASME, 78, pp. 365–368)
Trans. ASME. February 1956, 78(2): 368.
doi: https://doi.org/10.1115/1.4013679
Topics:
Reynolds number
Discussion: “Flow of Saturated Boiler Water Through Knife-Edge Orifices in Series” (Monroe, Jr., E. S., 1956, Trans. ASME, 78, pp. 373–376)
Trans. ASME. February 1956, 78(2): 376–377.
doi: https://doi.org/10.1115/1.4013682
Topics:
Boilers
,
Flow (Dynamics)
,
Orifices
,
Water
Closure to “Discussion of ‘Flow of Saturated Boiler Water Through Knife-Edge Orifices in Series’” (1956, Trans. ASME, 78, pp. 376–377)
Trans. ASME. February 1956, 78(2): 377.
doi: https://doi.org/10.1115/1.4013683
Topics:
Boilers
,
Flow (Dynamics)
,
Orifices
,
Water
Discussion: “Performance Characteristics of Francis Type Pump-Turbines” (McCormack, W. J., 1956, Trans. ASME, 78, pp. 417–423)
Trans. ASME. February 1956, 78(2): 423–424.
doi: https://doi.org/10.1115/1.4013690
Topics:
Performance characterization
,
Pump turbines
Discussion: “Performance Characteristics of Francis Type Pump-Turbines” (McCormack, W. J., 1956, Trans. ASME, 78, pp. 417–423)
Trans. ASME. February 1956, 78(2): 424.
doi: https://doi.org/10.1115/1.4013691
Topics:
Performance characterization
,
Pump turbines
Discussion: “Performance Characteristics of Francis Type Pump-Turbines” (McCormack, W. J., 1956, Trans. ASME, 78, pp. 417–423)
Trans. ASME. February 1956, 78(2): 424.
doi: https://doi.org/10.1115/1.4013692
Topics:
Performance characterization
,
Pump turbines
Discussion: “Performance Characteristics of Francis Type Pump-Turbines” (McCormack, W. J., 1956, Trans. ASME, 78, pp. 417–423)
Trans. ASME. February 1956, 78(2): 424–425.
doi: https://doi.org/10.1115/1.4013693
Topics:
Performance characterization
,
Pump turbines
Discussion: “Performance Characteristics of Francis Type Pump-Turbines” (McCormack, W. J., 1956, Trans. ASME, 78, pp. 417–423)
Trans. ASME. February 1956, 78(2): 425–426.
doi: https://doi.org/10.1115/1.4013694
Topics:
Performance characterization
,
Pump turbines
Closure to “Discussions of ‘Performance Characteristics of Francis Type Pump-Turbines’” (1956, Trans. ASME, 78, pp. 423–426)
Trans. ASME. February 1956, 78(2): 426.
doi: https://doi.org/10.1115/1.4013695
Topics:
Performance characterization
,
Pumps
Discussion: “Laminar Free Convection from a Vertical Plate With Uniform Surface Heat Flux” (Sparrow, E. M., and Gregg, J. L., 1956, Trans. ASME, 78, pp. 435–440)
Trans. ASME. February 1956, 78(2): 440.
doi: https://doi.org/10.1115/1.4013698
Topics:
Heat flux
,
Natural convection
,
Vertical plates
Discussion: “Laminar Free Convection from a Vertical Plate With Uniform Surface Heat Flux” (Sparrow, E. M., and Gregg, J. L., 1956, Trans. ASME, 78, pp. 435–440)
Trans. ASME. February 1956, 78(2): 440.
doi: https://doi.org/10.1115/1.4013699
Topics:
Heat flux
,
Natural convection
,
Vertical plates
Closure to “Discussions of ‘Laminar Free Convection from a Vertical Plate With Uniform Surface Heat Flux’” (1956, Trans. ASME, 78, p. 440)
Trans. ASME. February 1956, 78(2): 440.
doi: https://doi.org/10.1115/1.4013700
Topics:
Heat
,
Natural convection
,
Vertical plates
Discussion: “Heat Transfer to Laminar Flow in a Round Tube or Flat Conduit—The Graetz Problem Extended” (Sellars, J. R., Tribus, Myron, and Klein, J. S., 1956, Trans. ASME, 78, pp. 441–447)
Trans. ASME. February 1956, 78(2): 447–448.
doi: https://doi.org/10.1115/1.4013702
Topics:
Heat transfer
,
Laminar flow
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