NASA Tests New Robotic Refueling Technologies

A robot servicer could use autonomous rendezvous and fluid transfer technologies to extend the life of orbiting satellites (depicted, artist's concept). Image Credit: NASA

Concurrently on the ground, NASA is incorporating results from this test and the Robotic Refueling Mission on the International Space Station to prepare for an upcoming ground-based test of a full-sized robotic servicer system that will perform tasks on a mock satellite client. 

Collectively, these efforts are part of an ongoing and aggressive technology development campaign to equip robots and humans with the tools and capabilities needed for spacecraft maintenance and repair, the assembly of large space telescopes, and extended human exploration.

The Satellite Servicing Capabilities Office (SSCO) at NASA's Goddard Space Flight Center in Greenbelt, Md., checked another critical milestone off their list with the completion of their Remote Robotic Oxidizer Transfer Test (RROxiTT) in February 2014.

“This is the first time that anyone has tested this type of technology, and we've proven that it works. It's ready for the next step to flight,” says Frank Cepollina, veteran leader of the five servicing missions to the Hubble Space Telescope and the associate director of SSCO. 

“RROxiTT gives NASA, and the satellite community at large, confidence that advanced satellite refueling and maintenance technologies aren't a wild dream of the future,” says Cepollina. “They're being built and tested today – and the capabilities that they can unlock can become a reality.”

Since 2009, SSCO has been investigating human and robotic satellite servicing while developing the technologies necessary to bring on-orbit spacecraft inspection, repair, refueling, component replacement and assembly capabilities to space. 

Taking lessons learned from the successful Robotic Refueling Mission, the SSCO team devised the ground-based RROxiTT to test how robots can transfer hazardous oxidizer, at flight-like pressures and flow rates, through the propellant valve and into the mock tank of a satellite.

While this capability could be applied to spacecraft in multiple orbits, SSCO focused RROxiTT specifically on technologies that could help satellites traveling the busy space highway of geosynchronous Earth orbit, or GEO.

Located about 22,000 miles above Earth, this orbital path is home to more than 400 satellites, many of which beam communications, television and weather data to customers worldwide.

By developing robotic capabilities to repair and refuel GEO satellites, NASA hopes to add precious years of functional life to satellites and expand options for operators who face unexpected emergencies, tougher economic demands and aging fleets. NASA also hopes that these new technologies will help boost the commercial satellite-servicing industry that is rapidly gaining momentum.

Besides aiding the GEO satellite community, a capability to fix and relocate “ailing” satellites also could help mitigate the growing orbital debris problem that threatens continued space operations, ultimately making space greener and more sustainable.

Goddard and Kennedy Collaborate on New Technologies

RROxiTT tested a suite of new robotic technologies and procedures developed by the SSCO team at two collaborating centers, Goddard and Kennedy Space Center, Fla.

Technologies included a flexible propellant hose, a new Oxidizer Nozzle Tool, and a unique propellant transfer system (PTS) all developed by the multi-Center SSCO team. The PTS, consisting of oxidizer tanks, seal-less pumps, flow-metering devices, and a maze of tubing, contains the components a servicer satellite would need to replenish the propellant of orbiting spacecraft for many years of extended life.

During operations, a robot operator at NASA Goddard in Maryland commanded an industrial robot at Kennedy in Florida — more than 800 miles away — to mate to a satellite valve and transfer propellant into a mock tank. At the conclusion of nine days of RROxiTT operations, the SSCO team declared victory.

“It's one thing to build a set of technologies and discover that they work,” says Benjamin Reed, deputy project manager of SSCO at Goddard. “It's another thing to consider the capabilities that they could unlock. The paradigm of one-and-done should be relegated to the 20th century – the future of space will be re-use, re-purpose and replenish.”

Applications to Help People Stay Safer on Earth 

While RROxiTT technologies are being designed for use in space, they may one day be applied to robotically replenish satellites before they launch.

Oxidizer – namely nitrogen tetroxide – is a chemical that, when mixed with satellite fuel, causes instant combustion that provides thrust (motion) for a satellite. The liquid is contained within a satellite tank at intense pressures, up to 300 pounds per square inch (about 20 times atmospheric pressure). Toxic, extremely corrosive and compressed, it requires special handling.

Using these new RROxiTT technologies to robotically fill up satellites on the ground would keep humans at a safe distance during these extremely hazardous operations. 

Future Satellite Servicing Demonstrations

Since wrapping up RROxiTT, SSCO is broadening its portfolio to include xenon transfer technologies — propellant used by satellites with electric propulsion systems. 

The team is also gearing up for the next phase of the Robotic Refueling Mission on the International Space Station. The next Automated Transfer Vehicle, currently scheduled to launch to the space station in June of this year, will deliver new RRM hardware for a fresh set of activities.

Upcoming demonstrations include spacecraft inspection, the replenishment of cryogens in satellites not originally designed for in-flight service, and advanced solar cell technology. A separate space station demonstration currently in development will focus on real-time relative navigation.

On the ground, SSCO will be conducting a separate test at Goddard in later this year. Drawing from lessons learned from RRM, RROxiTT, and their efforts in robot algorithms and development, the team will command a full-sized robot servicer system to perform a series of servicing tasks on a suspended satellite mockup. Results will help the team evaluate how the numerous servicer subsystems and technologies work together as an integrated system to accomplish servicing objectives.  The event will test both proven and newly developed technologies.

“Sustainable space development is not only good stewardship of the shared resource of outer space,” says Reed, “but it also makes sense as we develop the skill set to embark humans deeper into our solar system.” 

Dewayne Washington and Adrienne Alessandro
NASA's Goddard Space Flight Center, Greenbelt, Md.

Media Contact

Dewayne Washington and Adrienne Alessandro EurekAlert!

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