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NASA Recycling in Space Challenge

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Posted October 13, 2018

The aim of this Challenge is to identify receptacle and feeder mechanisms suitable for a microgravity environment that can deliver mission waste to a high temperature reactor that can recycle astronaut waste into valuable substances (water, gases & solids).

On Earth, recycling technologies can utilize gravity to move waste when converting it to new materials or constituent molecules. In a microgravity environment, however, technology is the only way to transfer the waste for processing.

Given the volume and variety of waste products generated while residing in space, it is crucial that NASA identify mechanisms to facilitate mission recycling.

NASA astronaut Don Pettit, Expedition 30 flight engineer, is pictured among stowage bags in the Harmony node of the International Space Station. The bags, containing trash and excessed equipment, will be transferred to the docked Progress 45 spacecraft for disposal. The unpiloted ISS Progress 45 supply vehicle is scheduled to undock from the space station on Jan. 24, 2011. Photo credit: NASA

Background

Long-duration human space exploration missions to the Moon and Mars need solutions for managing trash and other waste generated by the crew. NASA’s Advanced Exploration Systems logistics reduction project is developing technologies to mitigate issues with waste. Four astronauts can generate 2,500 kilograms of waste during a yearlong mission. Trash takes up space and presents a safety risk to the crew from biological and physical hazards. Current waste disposal methods on the International Space Station rely on astronauts manually processing trash by placing it into bags then loading it onto a designated vehicle for short term storage, which depending on the craft, returns the trash to Earth or burns up in the atmosphere. This disposal method will not be available for missions beyond low-Earth orbit.

Recycling trash is one method for mitigating these issues, as well as potentially transforming waste into a source of supplies for the mission. Astronauts can process small pieces of trash in a high-temperature reactor, which breaks the waste down into water, oxygen, and other gases which the crew can use or vent as needed. Besides the gases, the remainder of the waste is greatly reduced in size, and no longer biologically active.

“Along with a commitment to explore and pioneer, comes a commitment to use the resources at our disposal fully, efficiently and responsibly,” said Anne Meier, lead research engineer at NASA’s Kennedy Space Center. “Recycling in space and repurposing all or as much of the mass that we launch up to space is key for sustainable long-duration space travel. Waste conversion and volume reduction will free up volume for more science, more exploration, and is the heart of closing the loop on human spaceflight, and logistics reduction and reutilization.”

To harness the recycling potential of the reactor, this challenge is seeking proposals for a unit that can function in microgravity with a receptacle component for depositing various types of waste into the unit and a feeder component capable of transferring the waste into the reactor through a small opening. Without these components, the crew would have to spend time processing trash and manually inserting it into the reactor instead of working on other higher priority tasks. By employing crowdsourcing, which has proven effective in previous challenges, it increases the likelihood of finding an innovative solution. Crowdsourcing allows NASA to harness a surge of creativity from external sources and augment ideas generated by the agency’s workforce.

The Recycling in Space challenge compliments a similar initiative at the agency to increase innovation headed by the NASA’s Center of Excellence for Collaborative Innovation and its [email protected] team. By using a new platform that enables employees across NASA to collaborate and share ideas on challenges posted to [email protected], participants have already started proposing solutions for the inaugural challenge of developing an astronaut-friendly waste receptacle design.

NASA also is pursuing other methods of handling trash during deep space missions including reaching out to industry through the Next Space Technologies for Exploration Partnerships solicitation for prototype Trash Compaction and Processing System. Awards for the first phase of the public private partnership went to Sierra Nevada Corporation (SNC) and UTC Aerospace Systems (UTAS) to develop systems that can reduce trash volume. They will have 18 months to develop and test their designs, before NASA conducts a preliminary design review (PDR). There will be a second phase focused on procurement after the PDR.

Since 2011, the NTL has used a variety of open innovation platforms to engage crowdsourcing communities in challenges to create the most innovative, efficient and optimal solutions for specific, real-world challenges faced by NASA and the federal government.

NineSigma North America Inc. helps organizations in the public, private and nonprofit sectors find new solutions, knowledge and partners to accelerate innovation, addressing problems of a global magnitude through its Grand Challenge innovation programs.

For more information about the challenge, and details on how to apply, visit https://9sig.co/NASA_RISC.

For more information about the NASA Tournament Lab, visit www.nasa.gov/coeci/ntl.

Prizes

There is a total prize pool of US$15,000 available in the form of one US$10,000 first prize and two US$2,500 second prizes. Successful entrants may also have the opportunity for future collaboration with NASA.

Deadline for submissions is January 16, 2019 by 5PM EST.

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