A typical Rover mission, its requirements, the environment it imposes on the radionuclide thermoelectric generator (RTG), and a design approach for making the RTG operable in such an environment are described. Specific RTG designs for various thermoelectric element alternatives are presented. The result of studies show that current multifoil-insulated GPHS (general-purpose heat source) RTG and Mod-RTG designs can be modified to operate in an environment with an external atmosphere (e.g., Mars). This can be done while the helium generated by the fuel's alpha decay is vented to the external atmosphere. The use of novel selective vents and high-capacity getters is not required. The Rover RTGs can be built from standard, proven GPHS modules and standard SiGe unicouples or SiGe/GaP multicouples, using demonstrated thermoelectric material performance parameters. Rover's 500 W power requirement can be satisfied with two 250 W or four 125 W RTGs, whose sizes are compatible with currently envisaged Rover designs. An auxiliary cooling loop (e.g., water and antifreeze) will be required to cool the FTG while it is within the Rover's aeroshell during launch and transit to Mars.
Requirements and designs for Mars Rover RTGs
Anforderungen und Entwürfe für Mars Rover RTGs (thermoelektrische Radionuklidbatterien)
1989
11 Seiten, 15 Quellen
Aufsatz (Konferenz)
Englisch
Thermal and electrical analysis of Mars Rover RTGs
Tema Archiv | 1989
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