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Aerospace Systems Design Laboratory (ASDL)
Aerospace Systems Design Laboratory (ASDL)
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ItemSizing of an Entry, Descent, and Landing System for Human Mars Exploration(Georgia Institute of Technology, 2006-09) Christian, John A., III ; Wells, Grant William ; Lafleur, Jarret M. ; Manyapu, Kavya ; Verges, Amanda ; Lewis, Charity ; Braun, Robert D.The human exploration of Mars presents many challenges, not least of which is the task of entry, descent, and landing (EDL). Because human-class missions are expected to have landed masses on the order of 40 to 80 metric tons, significant challenges arise that have not been seen to date in robotic missions. This study provides insight into the challenges encountered as well as potential solutions through parametric trade studies on vehicle size and mass. Aerocapture and entry-from-orbit analyses of 10 and 15 m diameter aeroshells with a lift-to-drag ratio of 0.3 or 0.5 were investigated. Results indicate that in the limit, a crew capsule used only for descent could have an initial mass as low as 20 t. For larger landed payloads, such as a 20 t surface power system, a vehicle with an initial mass on the order of 80 t may be required. In addition, no feasible EDL systems were obtained with the capability to deliver more than approximately 25 t of landed payload to the Mars surface for initial masses less than 100 t. This suggests that an aeroshell diameter of 15 m may not be sufficient for human Mars exploration.
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ItemDesign of a Long Endurance Titan VTOL Vehicle(Georgia Institute of Technology, 2006-03) Prakash, Ravi ; Braun, Robert D. ; Colby, Luke S. ; Francis, Scott R. ; Gündüz, Mustafa E. ; Flaherty, Kevin W. ; Lafleur, Jarret M. ; Wright, Henry S.Saturn's moon Titan promises insight into many key scientific questions, many of which can be investigated only by in situ exploration of the surface and atmosphere of the moon. This research presents a vertical takeoff and landing (VTOL) vehicle designed to conduct a scientific investigation of Titan's atmosphere, clouds, haze, surface, and any possible oceans. In this investigation, multiple options for vertical takeoff and horizontal mobility were considered. A helicopter was baselined because of its many advantages over other types of vehicles, namely access to hazardous terrain and the ability to perform low speed aerial surveys. Using a nuclear power source and the atmosphere of Titan, a turbo expander cycle produces the 1.9 kW required by the vehicle for flight and operations, allowing it to sustain a long range, long duration mission that could traverse the majority of Titan. Such a power source could increase the lifespan and quality of science for planetary aerial flight to an extent that the limiting factor for the mission life is not available power but the life of the mechanical parts. Therefore, the mission could potentially last for years. This design is the first to investigate the implications of this potentially revolutionary technology on a Titan aerial vehicle.
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ItemEntry Descent and Landing Challenges of Human Mars Exploration(Georgia Institute of Technology, 2006-02) Wells, Grant William ; Lafleur, Jarret M. ; Verges, Amanda ; Manyapu, Kavya ; Christian, John A., III ; Lewis, Charity ; Braun, Robert D.Near-term capabilities for robotic spacecraft include a target of landing 1 - 2 metric ton payloads with a precision of about 10 kilometers, at moderate altitude landing sites (as high as +2 km MOLA). While challenging, these capabilities are modest in comparison to the requirements for landing human crews on Mars. Human Mars exploration studies imply the capability to safely land 40 - 80 metric ton payloads with a precision of tens of meters, possibly at even higher altitudes. New entry, descent and landing challenges imposed by the large mass requirements of human Mars exploration include: (1) the potential need for aerocapture prior to entry, descent and landing and associated thermal protection strategies, (2) large aeroshell diameter requirements, (3) severe mass fraction restrictions, (4) rapid transition from the hypersonic entry mode to a descent and landing configuration, (5) the need for supersonic propulsion initiation, and (6) increased system reliability. This investigation explores the potential of extending robotic entry, descent and landing architectures to human missions and highlights the challenges of landing large payloads on the surface of Mars.
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ItemDaedalon: A Revolutionary Morphing Spacecraft Design for Planetary Exploration(Georgia Institute of Technology, 2005-01) Lafleur, Jarret M. ; Olds, John R. ; Braun, Robert D.The product of a study sponsored by the NASA Institute for Advanced Concepts (NIAC), Daedalon is a spacecraft design baselined for Mars which utilizes morphing wing technology to achieve the design objective of a standard, flexible architecture for unmanned planetary exploration. This design encompasses a detailed vehicle mass and power sizing study for the Daedalon lander as well as its cruise stage and entry backshell. A cost estimation and comparison study is also performed, and qualitative functionality comparisons are made between Daedalon and other Mars lander and airplane designs. Quantitative comparisons of gross mass and range are also made, including the results of scaling an existing Mars aerial vehicle design to match Daedalon functionality. Altogether, the Daedalon launch mass is found to be 896 kg for a 12 kg payload capacity. If five such vehicles are produced, it is found that the per-mission cost can be as low as $224 million. Given the necessary morphing wing technology development, it is concluded that the Daedalon design may be a feasible and cost-effective approach to planetary exploration 20-40 years in the future.