Earlier this month, astronauts disposed of some 172 pounds of trash from the International Space Station (ISS) using a completely new method: sending it out of the commercial Bishop Airlock designed, owned, and operated by Houston-based Nanoracks. Once the specially designed trash bag was ejected from the airlock, voilà—the ISS crew had less waste to worry about.
Cooper Read, Bishop Airlock program manager at Nanoracks, noted, “The first full end-to-end cycle was a great opportunity to demonstrate the commercial . . . interaction and how that can continue to be a positive thing for everyone.”
- Trash is typically disposed of via Cygnus cargo vessels. This new airlock method could provide a more sustainable, efficient disposal mechanism.
- Astronauts can fill the special waste container mounted within Bishop Airlock with up to 600 pounds of trash.
- In the first test, astronauts disposed of items ranging from packing materials to dirty clothes.
- For any readers out there concerned with environmental, social, and governance (ESG) criteria, Nanoracks’s orbital trash bags burn up when they reenter the atmosphere. We earthlings need not worry about astro trash raining down on our heads.
Bishop Airlock’s backstory
Operation Take Out the Trash (that’s an unofficial working title) represented the first full open-close cycle of Bishop. According to Nanoracks, Bishop offers five times the current volume of what can be moved in and out of the ISS. It can support up to 144 units of payloads simultaneously (1 unit equals 10 by 10 by 10 centimeters).
Key Bishop Airlock design elements
- Bishop can support space walks, satellite deployments, and payload hosting.
- It has external hosting capabilities and a “pretty universal mounting capability,” Read said, with six external sites. The same standardized approach extends to Bishop’s racks, lockers, and electrical interfaces.
- With soft-stowed configurations and pressurized hosting opportunities, the module is also poised to make “payload developers’ lives easier,” according to Read.
- Bishop Airlock can support experiments in partial-pressure environments. Nanoracks can “pump it down to a pressure so it’s not in a vacuum,” Read explained, potentially allowing users to simulate a lunar or Martian environment for experiments.
- The airlock opens up commercial use cases and scientific experiments not previously feasible because they might have been a crew hazard.
Start small, then ramp up
Nanoracks and parent Voyager Space Holdings are “in talks with multiple other companies, public and private” to use Bishop Airlock, Read said. And next year, NASA will begin the Space Entanglement and Annealing QUantum Experiment (or SEAQUE), a quantum computing demo hosted on Bishop.
Nanoracks has gained loads of flight heritage by iterating over time. It “started small, then ramped up,” Read said, graduating from CubeSat deployers to locker-size platforms inside the ISS to a “small external platform on the Japanese-exposed facility” to Bishop.
Bishop will eventually detach from the ISS and join Starlab, a free-flying low Earth orbit (LEO) outpost owned and operated by Voyager and Lockheed Martin. “There are lots of things we’ve learned along the way that will help us with Starlab and building up that station,” Read said.
This story originally appeared in the Payload newsletter and is republished here with permission.
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