Orbital Aggregation & Space Infrastructure Systems (OASIS) Background Develop robust and cost effective concepts in support of future space commercialization.

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Presentation transcript:

Orbital Aggregation & Space Infrastructure Systems (OASIS) Background Develop robust and cost effective concepts in support of future space commercialization and exploration missions assuming inexpensive launch of propellant and logistics payloads. Infrastructure costs would be shared by Industry, NASA and other users. Status Report A reusable in-space transportation architecture composed of modular fuel depots, chemical/solar electric stages and crew transportation elements has been developed (OASIS). OASIS can accommodate nearly all current spacecraft with respect to Geostationary Transfer Orbit (GTO) with reusable chemical propulsion and much larger payloads in support of Human exploration missions when both solar electric and chemical propulsion modules are used. OASIS Enabling OASIS technologies include: Large deployable thin film arrays, Zero Boil-Off (ZBO) system, Integrated primary multifunction structure, radiation & meteoroid and orbital debris shielding, Autonomous operations including rendezvous and docking, On-orbit cryogenic fluid transfer, Lightweight cryogenic propellant tanks, Graphitic foams and syntactic metal foams, High performance, high cycle life LH2/LOX main engine, Integrated GH2/GOX Reaction Control System (RCS), High Power Gridded ion engines.

Orbital Aggregation & Space Infrastructure Systems (OASIS) Liquid Hydrogen Liquid Oxygen Xenon Liquid Hydrogen Liquid Oxygen Xenon H ybrid P ropellant M odule H ybrid P ropellant M odule Infrastructure Elements: Lunar Gateway Space Station Crew Transfer Vehicle Solar Electric Propulsion Chemical Transfer Module Background Develop robust and cost effective concepts in support of future space commercialization and exploration missions assuming inexpensive launch of propellant and logistics payloads. Infrastructure costs would be shared by Industry, NASA and other users. Status Report A reusable in-space transportation architecture composed of modular fuel depots, chemical/solar electric stages and crew transportation elements has been developed (OASIS). OASIS can accommodate nearly all current spacecraft with respect to Geostationary Transfer Orbit (GTO) with reusable chemical propulsion and much larger payloads in support of Human exploration missions when both solar electric and chemical propulsion modules are used. Background Develop robust and cost effective concepts in support of future space commercialization and exploration missions assuming inexpensive launch of propellant and logistics payloads. Infrastructure costs would be shared by Industry, NASA and other users. Status Report A reusable in-space transportation architecture composed of modular fuel depots, chemical/solar electric stages and crew transportation elements has been developed (OASIS). OASIS can accommodate nearly all current spacecraft with respect to Geostationary Transfer Orbit (GTO) with reusable chemical propulsion and much larger payloads in support of Human exploration missions when both solar electric and chemical propulsion modules are used.