Energy conversion becomes a critical element in the availability of electrical energy for power applications
Energy conversion becomes a critical element in the availability of electrical energy for power applications.

Space structures, power, and power conditioning : part of the 1988 Innovative Science and Technology Symposium, James A. Ionson, symposium chair, 11-13 January 1988, Los Angeles, California

Space structures, power, and power conditioning: 11-13 January 1988, Los Angeles, California: part of the 1988 Innovative Science and Technology Symposium ...

Proceedings of SPIE-The International Society for Optical Engineering Volume 871·Space Structures,Power,and Power Conditioning

Space Structures, Power, And Power Conditioning (proceedings Of Spie--the International Society For Optical Engineering)

Askew, Raymond F; Society of Photo-optical Instrumentation Engineers; Innovative Science and Technology Symposium (1988: Los Angeles, Calif.)

Raymond F Askew; Society of Photo-optical Instrumentation Engineers (U.S.); Innovative Science and Technology Symposium

James A Ionson; Innovative Science and Technology Symposium

SPIE - The International Society for Optical Engineering

Bellingham, Wash., USA: The Society

Society Of Photo Optical

Proceedings of SPIE - The International Society for Optical Engineering, Bellingham, 1988

United States, United States of America

Volume 871, 1988

Cut-off text on some pages due to tight binding
Cut-off text on front & back cover tight
printed as skewed front & back cover
printed as skewed text on some pages inherent from the source.

Includes bibliographies and index.

contributor: 浙江大学

format: Image/Djvu(.djvu)

unit_name: 浙江大学

Type: 英文图书

Bookmarks:
1. (p1) Session 1 Space Reactors
1.1. (p2) Two-phase flow in a nuclear magnetohydrodynamic(MHD)generator
1.2. (p10) Gigawatt,closed cycle,vapor core- magnetohydrodynamic(MHD)space power system conceptual design study
1.3. (p15) Disk MHD generator for a burst power gas core reactor
1.4. (p25) Heterogeneous gas core reactor for space nuclear power
1.5. (p31) Neutronics of a coupled multiple chamber gaseous core reactor power system
1.6. (p42) Pulsed gas core reactor for burst power
1.7. (p48) Fundamental considerations of gas core reactor systems
1.8. (p53) Phenomenological parametric analysis of advanced nuclear power systems
2. (p63) Session 2 Energy Conversion
2.1. (p64) Recent advances in alkali metal thermoelectric converter(AMTEC)electrode performance and modeling
2.2. (p70) Oscillating thermionic conversion for high-density space power
2.3. (p81) Thermoelectromagnetic pumps for space nuclear power systems
2.4. (p89) High temperature,electrically conductive graphite composites for space nuclear power
2.5. (p96) Light-weight electrochemical converter for space power applications
2.6. (p103) Ballistic acceleration by superheated hydrogen
3. (p121) Session 3 Power Switches
3.1. (p122) Laser-induced current switching in gaseous discharge
3.2. (p127) Photoconductive switch designs utilizing field confinement and displacement for faster opening in pulse power systems
3.3. (p133) Electron-beam controlled semiconductor switches
3.4. (p140) Laser controlled semiconductor closing and opening switch
3.5. (p148) Semiconductor-metal eutectic composites for high-power switching
3.6. (p153) Superionic conductors as fast,repetitive opening switches
3.7. (p157) Optical probes for the characterization of surface breakdown
3.8. (p165) Characteristics of a pulsed,liquid-metal field emission source for use in fast high-current switches
3.9. (p173) A 40 kV/20 kA pseudospark switch for laser applications
4. (p181) Session 4 Advanced Space Technologies I:Space Structures
4.1. (p182) Insulation directions for high power space systems
4.2. (p190) State space simulation of spacecraft power systems
4.3. (p197) Novel scheme for space power generation and energy storage
4.4. (p205) Structural vibration of space power station systems
4.5. (p225) Fast risetime impulse voltage generation facility at the University of Buffalo
4.6. (p230) Minimum-time control of large space structures
4.7. (p242) Experimental investigations in active vibration control for application to large space systems
4.8. (p254) Novel fusion reactor for space power and propulsion
5. (p261) Session 5 Advanced Space Technologies Ii
5.1. (p262) A high density anodized aluminum microstrip structure for high-speed interconnections
5.2. (p268) Repetition rate system evaluations at SUNY at Buffalo
5.3. (p273) Performance of in-situ copper alloys as electrodes in high current
5.4. (p280) The effect of repetition rate on electrode material performance in high current switches
5.5. (p282) Dynamics and control of large space platforms and small experimental payloads
5.6. (p297) Cryogenic silicon photoconductive switches for high power lasers
6. (p307) Session 6 Advanced Space Technologies Iii
6.1. (p308) Multilevel DLC(diamondlike carbon)capacitor structure
6.2. (p313) Production of ground state atomic oxygen in a multifactor stress environment
6.3. (p317) SPEAR:rocket flights to investigate the innovative design of high power space systems
6.4. (p326) Surface breakdown of prestressed insulators
6.5. (p333) C-Mo and C-Zr alloys for space power systems
6.6. (p341) Magnetic insulation for the space environment
6.7. (p348) Investigation of open cycle H2-02 Ljungstrom turbine configurations for space power conversion

viii, 360 p. : 28 cm
Includes bibliographies and index

2024-07-01