Large Lightweight Deployable Structures for Planetary Defence: Solar Sail Propulsion, Solar Concentrator Payloads, Large-scale Photovoltaic Power (1) DLR.

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Large Lightweight Deployable Structures for Planetary Defence: Solar Sail Propulsion, Solar Concentrator Payloads, Large-scale Photovoltaic Power (1) DLR Institute of Space Systems, Robert-Hooke-Strasse 7, Bremen – (2) +49-(0) , – (3) +49-(0) , – (4) +49-(0) , – (5) +49-(0) , – (6) +49-(0) , – (7) Faculty of Aerospace Engineering, FH Aachen University of Applied Sciences, Hohenstaufenallee 6, Aachen, Germany, / , – (8) DLR Institute of Composite Structures and Adaptive Systems – Composite Design, Lilienthalplatz 7, Braunschweig, Germany – (9) +49-(0) , – (10) +49-(0) , – (11) Technical University of Braunschweig, Institute of Adaptronics and Function Integration, Langer Kamp 6, Braunschweig, Germany, +49-(0) , Patric Seefeldt (1,2), Waldemar Bauer (1,3), Bernd Dachwald (7), Jan Thimo Grundmann (1,4), Marco Straubel (8,9), Maciej Sznajder (1,5), Norbert Tóth (1,6), Martin E. Zander (8,10,11) IAA-PDC15-P-20 Gossamer-1 Deployment Technology Ultra light weight deployable membrane structures –Launch mass saving –Mission propellant saving –Basis for re-thinking existing and new mission concepts –Scalable technology –Controlled Deployment Realisation, the 3-Step Gossamer Roadmap –Gossamer-1 5x5 m 2 Deployment demonstrator (LEO) –Gossamer-2 20x20 m 2 Validation of attitude control for solar sails –Gossamer-3 50x50 m 2 Fully functional solar sail Gossamer 1 hardware development and an artist’s impression of the spacecraft Sails –Aluminum coated polyimide foil –Additional protective oxide coatings –Load introduction analysis and interface design –Embedded thin film photovoltaics Booms –Two 8m booms to provide stiffness for the deployed sail –Coilable carbon composite booms –Lightweight: Mass contribution of only 530 gram (~35g/m) Deployment Mechanisms –Four independent deployment units wireless connected to the bus system –Deploying simultaneously booms and sails –Jettison of Mechanism for solar sailing mode DLR’s Gossamer Structures Know How Use Cases –Solar sailing, highly specific new mission targets –Ultra-lightweight solar power generation for mass critical systems –Possible deorbit technology from LEO Configuration –4 sail segment, crossed booms (see main picture), 4 independent deployment units –On board wireless communication between independent units Electronics –Each deployment unit is equipment with an own board computer, power subsystem, motor, … –The central unit command the deployment units –On-Board Wireless System (OWCS) realized with Bluetooth PICONET Qualification Testing -Boom characterization test rig -Vibration Testing -Centrifuge Testing -Fast Decompression, -Thermal Vacuum -Laboratory Deployment