Thermal protection system development,testing, and qualification for atmospheric probes and sample return missions: Examples for Saturn,Titan and Stardust-type sample return |
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Authors: | E. Venkatapathy B. Laub G.J. Hartman J.O. Arnold M.J. Wright G.A. Allen Jr. |
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Affiliation: | 1. NASA Ames Research Center, MS229-1, Moffett Field, CA 94035, USA;2. NASA Ames Research Center, MS234-1, Moffett Field, CA 94035, USA;3. NASA Ames Research Center (Retired), MS229-1, Moffett Field, CA 94035, USA;4. University of California, Santa Cruz/NASA ARC, MS229-1, Moffett Field, CA 94035, USA;5. NASA Ames Research Center, MS230-1, Moffett Field, CA 94035, USA;6. ELORET Corporation, 465 S. Mathilda Ave., Suite 103, Sunnyale, CA 94086, USA |
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Abstract: | The science community has continued to be interested in planetary entry probes, aerocapture, and sample return missions to improve our understanding of the Solar System. As in the case of the Galileo entry probe, such missions are critical to the understanding not only of the individual planets, but also to further knowledge regarding the formation of the Solar System. It is believed that Saturn probes to depths corresponding to 10 bars will be sufficient to provide the desired data on its atmospheric composition. An aerocapture mission would enable delivery of a satellite to provide insight into how gravitational forces cause dynamic changes in Saturn’s ring structure that are akin to the evolution of protoplanetary accretion disks. Heating rates for the “shallow” Saturn probes, Saturn aerocapture, and sample Earth return missions with higher re-entry speeds (13–15 km/s) from Mars, Venus, comets, and asteroids are in the range of 1–6 KW/cm2. New, mid-density thermal protection system (TPS) materials for such probes can be mission enabling for mass efficiency and also for use on smaller vehicles enabled by advancements in scientific instrumentation. Past consideration of new Jovian multiprobe missions has been considered problematic without the Giant Planet arcjet facility that was used to qualify carbon phenolic for the Galileo probe. This paper describes emerging TPS technologies and the proposed use of an affordable, small 5 MW arcjet that can be used for TPS development, in test gases appropriate for future planetary probe and aerocapture applications. Emerging TPS technologies of interest include new versions of the Apollo Avcoat material and a densified variant of Phenolic Impregnated Carbon Ablator (PICA). Application of these and other TPS materials and the use of other facilities for development and qualification of TPS for Saturn, Titan, and Sample Return missions of the Stardust class with entry speeds from 6.0 to 28.6 km/s are discussed. |
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Keywords: | Thermal protection system |
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