Heat transfer in inertial confinement fusion reactor systems
Copyright policy )Heat transfer in inertial confinement fusion reactor systems
The transfer of energy produced by the interaction of the intense pulses of short-ranged fusion microexplosion products with materials is one of the most difficult problems in inertially-confined fusion (ICF) reactor design. The short time and deposition distance for the energy results in local peak power densities on the order of 10/sup 18/ watts/m/sup 3/. High local power densities may cause change of state or spall in the reactor materials. This will limit the structure lifetimes for ICF reactors of economic physical sizes, increasing operating costs including structure replacement and radioactive waste management. Four basic first wall protection methods have evolved: a dry-wall, a wet-wall, a magnetically shielded wall, and a fluid wall. These approaches are distinguished by the way the reactor wall interfaces with fusion debris as well as the way the ambient cavity conditions modify the fusion energy forms and spectra at the first wall. Each of these approaches requires different heat transfer considerations.
- University of California, Davis United States
- University of North Texas United States
- Lawrence Berkeley National Laboratory United States
- University of North Texas United States
- Lawrence Berkeley National Laboratory United States
Nucleon Reactions, Design, Pellets, Cost, Neutron Reactions, Tritons, Fusion Yield, Inertial Confinement, Hadron Reactions, Thermonuclear Reactors 700208* -- Fusion Power Plant Technology-- Inertial Confinement Technology, Size, Thermonuclear Reactor Walls, Charged Particles, Radiations, Laser Fusion Reactors, Nuclear Reactions, Plasma Confinement, X Radiation, Deuterons, Energy Spectra, Nuclear Reaction Yield, Electromagnetic Radiation, Thermonuclear Reactors, Cooling Systems, Spectra, Alpha Particles, Heat Transfer, First Wall, Energy Transfer, Fuel Pellets, Baryon Reactions, 70 Plasma Physics And Fusion Technology, Yields 700208* -- Fusion Power Plant Technology-- Inertial Confinement Technology, Ionizing Radiations, Confinement
Nucleon Reactions, Design, Pellets, Cost, Neutron Reactions, Tritons, Fusion Yield, Inertial Confinement, Hadron Reactions, Thermonuclear Reactors 700208* -- Fusion Power Plant Technology-- Inertial Confinement Technology, Size, Thermonuclear Reactor Walls, Charged Particles, Radiations, Laser Fusion Reactors, Nuclear Reactions, Plasma Confinement, X Radiation, Deuterons, Energy Spectra, Nuclear Reaction Yield, Electromagnetic Radiation, Thermonuclear Reactors, Cooling Systems, Spectra, Alpha Particles, Heat Transfer, First Wall, Energy Transfer, Fuel Pellets, Baryon Reactions, 70 Plasma Physics And Fusion Technology, Yields 700208* -- Fusion Power Plant Technology-- Inertial Confinement Technology, Ionizing Radiations, Confinement
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