SBIR-STTR Award

The space environment around the earth is now littered with both functioning and non-functioning satellites. This is over and above the man-made debris generated as a result of launching these space objects and their density is increasing exponentially with time. If nothing is done about this, the earth will eventually have its own Saturn ring if not a spherical shell of orbiting objects and debris. There is definitely a pressing need for an inexpensive and reliable method of de-orbiting satellites after their mission life has ended. We propose to carryout a for a passively deployable, lightweight, low-compaction ratio bolt-on de-orbit device for satellites. The de-orbiter is packaged into a small bolt-on canister that gets attached to the spacecraft. It stays in the packaged configuration until the end of the satellite mission at which time it is activated deploying the de-orbit element out of its canister, increasing the spacecraft drag area against the atmosphere. For high low-earth orbit starting altitudes where the atmospheric density is extremely low, the de-orbiter drag sail is made to work like a solar sail capitalizing on the solar radiation pressure but in this case to decrease the satellites energy thereby lowering its altitude over time. It is pointed out that using this solar-sailing approach has practically unlimited delta v capability. The innovation in the proposed de-orbiter design is the use of a proprietary shape memory composite material for the structural elements of the de-orbiter. It is foldable and packageable into a small stowed volume and deployment is passively achieved by simply releasing the stored strain energy in the packaged configuration. Tests and measurements performed in the laboratory show that the material formulation we use achieves deployment to the memorized configuration even after the material has been in the folded state for years. When the solar sail mode is used, it can be used to extend the satellite lifetime. Potential NASA Applications (Limit 1500 characters, approximately 150 words) NASA can use the drag sail as de-orbiter devices for satellites in low earth orbit. And for higher starting altitudes where the atmosphere is extremely thin, the de-orbiter is made to work like a solar sail capitalizing on the solar radiation pressure but in this case to decrease the satellite energy to lower the satellite altitude over time. This approach has practically unlimited delta v capability. In fact, the drag solar-sail configuration can be made to work in GEO orbit to place non functioning satellites in higher parking orbits. Potential Non-NASA Applications (Limit 1500 characters, approximately 150 words) The military and commercial sectors will find the de-orbiter design as an inexpensive addition to their payloads to enable de-orbiting their spacecrafts after mission life has ended. When the solar-sail mode of the de-orbiter is turned on, the de-orbiter can be used to increase the satellite lifetime on orbit.

Two simple bolt-on de-orbit device configurations developed during Phase I will be carried to the CDR level for Phase II culminating in a ready-to-fly de-orbiter at the end of the project. The first is a passive de-orbiter suitable for use at altitudes up to 1200 km where no vane sail articulation is needed. For altitudes above 1200 km our analysis showed that in order to decay within the 25-year "requirement" an articulating vane sail type de-orbiter is needed for rough-pointing against solar pressure. Even if the vane sail of the de-orbiter is mis-pointed by 45 degrees, it will still see about 70 percent solar pressure drag. For these higher altitudes a passively articulating bolt-on de-orbit device based on two-way shape memory alloy is used. The two-way shape memory alloy unfurls to a large area against solar pressure during the sun-side of the orbit when it is warmed, and when its "back is turned against the sun" on its way to the eclipse side of the orbit, it cools down and folds back to a low area device decreasing the solar pressure on it as it exits the sun side. The de-orbiter area can be tailored such that after it crosses the 1200 km limit on its way down, the active area against the atmosphere is still sufficient for de-orbiting within 25 years. The SMA based de-orbiter has no need for motors or sources of power and the mass and stowed volume gained can be used for an increase in the amount of material to package making it suitable for both altitude regimes. Potential NASA Applications (Limit 1500 characters, approximately 150 words) The potential NASA applications include the use of the Bolt-On De-orbiter to assure that its LEO satellites de-orbit within the 25-year "requirement". The 2-way shape memory based de-orbiter unfurls when warmed and folds when cooled. This means that another potential application of the passively articulating 2-way shape memory de-orbiter is for use as substrates of solar panels that automatically unfurls during the sun-side of orbit to catch sun and folds during eclipse to reduce drag area thereby increasing the satellite lifetime. Potential Non-NASA Applications (Limit 1500 characters, approximately 150 words) The 2-way shape memory based de-orbiter unfurls when warmed and folds compactly when cooled. This means that another potential application of the passively articulating 2-way shape memory de-orbiter is for use as substrates of solar panels that automatically unfurls during the sun-side of orbit to catch sun and folds during eclipse to reduce drag area thereby increasing the satellite lifetime.