Abstract :
Energy sources for aerospace systems include electrochemicals, mechanical rotation, solar illumination, radioisotopes, and nuclear reactors. Energy is converted to power with engines, turbines, photovoltaics, thermoelectric and thermionic devices, and electrochemical processes. Although some early spacecraft flew with battery power, for longer flights the choice has been either solar or nuclear. Manned spacecraft must have power for the total mission duration including boost into orbit, on-orbit, and subsequent re-entry. Batteries are too heavy for extended manned space missions; tradeoff study alternatives range from radioisotope heated thermionic converters to hyperbolic-fueled engines. Arrays of solar cells are the obvious choice for powering space stations and for other extended-duration missions. This article emphasizes developments for space and airplane power systems. Enabling technologies are described along with significant spin-offs and future systems.
Keywords :
aerospace engines; fuel cells; missiles; radioisotope thermoelectric generators; solar cell arrays; space vehicle power plants; thermionic conversion; electrochemical processes; electrochemicals; energy sources; engines; hyperbolic-fueled engines; manned spacecraft; mechanical rotation; missiles; nuclear reactors; photovoltaics; radioisotope heated thermionic converters; radioisotopes; solar cell arrays; solar illumination; space systems; thermionic devices; thermoelectric devices; turbines; Batteries; Engines; Fission reactors; Lighting; Photovoltaic cells; Radioactive materials; Space technology; Space vehicles; Thermoelectricity; Turbines;
