Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

15.11.2011

Herausgeber

K. Timmerhaus

Verlag

Springer Us

Seitenzahl

748

Maße (L/B/H)

24,4/17/4,1 cm

Gewicht

1299 g

Auflage

Softcover reprint of the original 1st ed. 1978

Sprache

Englisch

ISBN

978-1-4613-4041-6

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

15.11.2011

Herausgeber

K. Timmerhaus

Verlag

Springer Us

Seitenzahl

748

Maße (L/B/H)

24,4/17/4,1 cm

Gewicht

1299 g

Auflage

Softcover reprint of the original 1st ed. 1978

Sprache

Englisch

ISBN

978-1-4613-4041-6

Herstelleradresse

Springer-Verlag KG
Sachsenplatz 4-6
1201 Wien
AT

Email: GPSR Kontakt

Noch keine Bewertungen vorhanden

Verfassen Sie die erste Bewertung zu diesem Artikel

Helfen Sie anderen Kundinnen und Kunden durch Ihre Meinung.

Kundinnen und Kunden meinen

Bewertungen (0)

  • Produktbild: Advances in Cryogenic Engineering
  • Produktbild: Advances in Cryogenic Engineering
  • Superconductivity Applications—MHD Magnets.- A—1 Commercial Realization of MHD—A Challenge for Superconducting Magnets.- A—2 Cryogenic Aspects of the U. S. SCMS Superconducting Dipole Magnet for MHD Research.- A—3 Fabrication Experiences and Operating Characteristics of the U. S. SCMS Superconducting Dipole Magnet for MHD Research.- A—4 Design Study of Superconducting Magnets for a Combustion Magnetohydrodynamic (MHD) Generator.- A—5 Design of Superconducting Magnets for Full-Scale MHD Generators.- Superconductivity Applications—Energy Storage.- B—1 0.54-MJ Superconducting Magnetic Energy Transfer and Storage.- B—2 A Superconducting 0.54-MJ Pulsed Energy Storage Coil.- B—3 Design and Development of a Large Superconducting Solenoid with Aluminum-Stabilized Superconductors.- B—4 Conductor for LASL 10-MWhr Superconducting Energy Storage Coil.- B—5 Constant-Tension and Constant-Field Solenoids.- B—6 Results from a Model System of Superconducting Solenoids and Phase-Shifting Bridge for Pulsed Power Studies for Proposed Tokamak EF Coils.- B—7 Pulsed DC Losses in Superconducting Solenoids.- B—8 Dielectric Strength of Helium Vapor and Liquid at Temperatures between 1.4 and 4.2 K.- Superconductivity Applications—Rotating Machinery.- C—1 Experimental Simulation of Cryogenic System for a Large Superconducting Rotor.- C—2 Development of a Helium Transfer Coupling for a Superconducting Generator Rotor.- C—3 High-Speed Helium Transfer System—Evaluation and Testing.- C—4 A Bonded-Strain-Gage Pressure Transducer for High-Speed Liquid Helium Temperature Rotors.- C—5 A Method for Calculating Temperatures in Superconducting Rotors Cooled with Two-Phase Helium.- C—6 Temperature Distribution in Rotating Thermosiphons Containing Two-Phase Helium in Nonisentropic Equilibrium.- Superconductivity Applications—Magnet Technology.- D—1 Basic Study of Superconducting Electromagnetic Thrust Device for Propulsion in Seawater.- D—2 Design and Prototype Fabrication of a 30-Tesla Cryogenic Magnet.- D—3 Production Test of Energy Doubler Magnets.- D—4 Cryogenic Aspects of a Demountable Toroidal Field Magnet System for Tokamak-Type Fusion Reactors.- D—5 Recovery Velocities for Composite Superconductors.- D—6 Effect of Conductor Self-Shielding on Eddy Current Losses.- D—7 Effects of Electrical Shorts on Cryostatic Stable Superconducting Magnets.- D—8 High-Current Power Leads for Tokamak Fusion Reactor Superconducting Magnets.- Cooling Superconducting Systems.- E—1 Vapor Locking as a Limitation to the Stability of Composite Conductors Cooled by Boiling Helium.- E—2 Cryogenic Recovery Analysis of Forced-Flow Supercritical-Helium-Cooled Superconductors.- E—3 Nonstationary Heat Transfer and Temperature State of Cryogenic Cable at Short-Circuit Conditions.- E—4 Temperature Profiles in a Long Gaseous-Helium-Cooled Tube.- E—5 Design and Development of Cryostable Superconducting Ohmic Heating Coils for a Tokamak.- Heat Transfer.- F—1 Two-Phase Choked Flow in Tubes with Very Large L/D.- F—2 Cryogenic Fluid Flow Heat Transfer in a Porous Heat Exchanger.- F—3 Boiling Incipience and Convective Boiling of Neon and Nitrogen.- F—4 Effect of Ice Contamination on Liquid Nitrogen Drops in Film Boiling.- F—5 Estimating Surface Temperature in Forced Convection Nucleate Boiling—A Simplified Method.- F—6 Film Boiling of Liquid Nitrogen on a Sphere in an Enclosure.- F—7 Effects of Natural Convection on Heat Transfer in Porous Cryogenic Insulations.- Heat Transfer in Helium.- G—1 Heat Transfer to Helium in the Near-Critical Region.- G—2 Heat Transfer to Subcooled Liquid Helium.- G—3 Kapitza Conductance of Aluminum and Heat Transport from a Flat Surface through a Large-Diameter Tube to Saturated Helium II.- G—4 Oscillations and Hysteresis of Helium during Lambda Transition above the Thermodynamic Critical Pressure in the Presence of Heat Flow.- G—5 Helium II in Low-Temperature and Superconductive Magnet Engineering.- G—6 Measurements of Axial Heat Transport in Helium II with Forced Convection.- Mass Transfer.- H—1 Frost Density Measurements on Vertical Cylinders by Gamma- Ray Attenuation.- H—2 Computational Simulation of Rectifier for an Air Separation Plant Using the Newton-Raphson Technique.- H—3 A New Pump for Liquefied Inert Gases.- H—4 Determination of the Flow Velocity of a Cryogenic Fluid by Use of a Correlation Technique.- Refrigeration and Liquefaction.- J—1 Reliability and Repair Policy Assessment for Long-Duration Operation of Helium Refrigeration Systems.- J—2 The Stirling Cycle Cooler: Approaching One Year of Maintenance-Free Life.- J—3 Helium Refrigeration System for Fermilab Energy Doubler.- J—4 Thermodynamic Optimization of the Helium Multiengine Claude Refrigeration Cycle.- J—5 Cryogenic Refrigeration Concepts Utilizing Adsorption Pumping in Zeolites.- J—6 A Regenerator with an Iron Whisker Matrix.- J—7 Thermodynamic and Mechanical Design of the FNAL Central Helium Liquefier.- J—8 A Conceptual Design of a Helium Liquefaction System for a 300-MVA Superconducting Generator.- Cryogenic Techniques.- K—1 A New Laser Aerosol Detector and Monitor for Use on High-Pressure Gas Streams.- K—2 Helium Storage at High Density and Discharge at High Flow Rates.- K—3 Fast-Response Cryogenic Calorimeter Containing a 52-Kilogram Radiation Absorber.- K—4 Alternate Sets of Fixed Points for Simplified Realizations of IPTS-68.- K—5 Ultra-Low Dynamic Current Measurements with an RF SQUID.- LNG Design.- L—1 Reversible LNG.- L—2 Economic Removal of Nitrogen from LNG.- L—3 Internally Insulated Cryogenic Pipelines.- L—4 Solubility Enhancement of Solid Hydrocarbons in Liquid Methane Due to the Presence of Ethane.- L—5 Predicted Solubilities of Methanol in Compressed Natural Gas at Low Temperatures and High Pressures.- LNG Properties.- M—1 Thermodynamic Properties of Natural Gas, Petroleum Gas, and Related Mixtures: Enthalpy Predictions.- M—2 Prediction of the Transport Properties of Natural Gas and Similar Mixtures.- M—3 A Calculational Method for Obtaining the Density of a Liquefied Natural Gas.- M—4 Density of Liquefied Natural Gas Components.- M—5 VLE Calculations Using Temperature-Dependent k12 Values for Methane-Containing Binary Systems.- M—6 Liquid Mixture Excess Volumes and Total Vapor Pressures Using a Magnetic Suspension Densimeter with Compositions Determined by Chromatographic Analysis: Methane Plus Ethane.- M—7 Vapor Pressures and Heats of Vaporization for Propane and Propene from 50 K to the Normal Boiling Point.- M—8 On the Nonanalytic Equation of State for Propane.- Cryogenic Applications—Space Technology.- N—1 Thermal Analysis of a Helium II-Cooled Infrared Telescope for Spacelab.- N—2 Liquid Helium-Cooled Infrared Telescope for Astronomical and Atmospherical Measurements from Spacelab.- N—3 Operating Performance of He3-Cooled Bolometers.- N—4 Test Flight Results of a Balloon-Borne He3 Cryostat.- N—5 Development of a Burst Disk with a Temperature-Insensitive Vacuum Seal for Space Shuttle Propellant Lines.- Cryogenic Applications—Cryopumping.- O—1 Large-Scale Cryopumping for Controlled Fusion.- O—2 Performance of a Cryopump Cooled by a Small Closed-Cycle 10-K Refrigerator.- Cryogenic Applications—Laser Fusion.- Q—1 A New Method for Producing Cryogenic Laser Fusion Targets.- Q—2 Development of Cryogenic Targets for Laser Fusion.- Q—3 Cryogenic Pellets for Laser-Fusion Research—Theoretical and Practical Considerations.- Q—4 Point-Contact Conduction-Cooling Technique and Apparatus for Cryogenic Laser Fusion Pellets.- Q—5 Cryogenic Handling of Polymeric Laser-Fusion Pellets.- Q—6 Equilibrium Constants for the Hydrogen Isotopic Self-Exchange Reactions in the 4.2- to 50-K Temperature Range.- Cryogenic Applications—Health and Safety.- R—1 Cryogenic Freezing of Foods.- R—2 Safety with Cryogenic Systems.- Indexes.- Author Index.