Author_Institution :
Dept. of Chem. & Nucl. Eng., New Mexico Univ., Albuquerque, NM, USA
Abstract :
This paper examined candidate energy conversion technologies for advanced radioisotope and space nuclear reactor power systems, including three static, SiGe, segmented and cascaded thermoelectric, and alkali-metal thermal-to-electric conversion, and two dynamic, free piston Stirling and closed Brayton engines; each is at a different technology readiness level (TRL). The eventual selection of the appropriate technology for a class of missions would be based not only on the TRL, but also on considerations of safety, systems´ specific power, mission lifetime, specific radiator area (m2/kWe), and the overall system´s mass and size. Other important considerations are modularity, reliability, scalability, load following, power management and distribution requirements, radiation hardness integration into the spacecraft, and absence of single point failures.
Keywords :
Stirling engines; nuclear power; radioisotope thermoelectric generators; space vehicle power plants; SiGe; alkali-metal thermal-to-electric conversion; cascaded thermoelectric conversion; closed Brayton engines; distribution requirements; energy conversion technologies; free piston Stirling engines; future planetary exploration; load following; mission lifetime; modularity; nuclear reactor power systems; power management; radiation hardness integration; radioisotope power systems; reliability; safety; scalability; segmented thermoelectric conversion; single point failures absence; space nuclear reactor power systems; spacecraft; specific power; specific radiator area; Energy conversion; Fission reactors; Germanium silicon alloys; Pistons; Power system dynamics; Power systems; Radioactive materials; Silicon germanium; Space technology; Thermoelectricity;
