Scientists Develop Real-Life “Stillsuit” From Dune
The new spacesuit urine filtration system by Cornell researchers recycles astronauts’ urine into drinkable water, aiming to improve comfort and efficiency on future Moon and Mars missions.
Currently, astronauts must relieve themselves inside their spacesuits during spacewalks. This is not only uncomfortable and unhygienic, but also wasteful. Unlike the wastewater management system on the International Space Station (ISS), the water from urine during spacewalks is not recycled.
Researchers at Cornell are addressing this issue with a novel urine collection and filtration system inspired by the ‘stillsuits’ from the sci-fi franchise Dune. Like these ‘stillsuits’, their prototype absorbs and purifies urine, and recycles it into drinking water.
Sofia Etlin, a research staff member at Weill Cornell Medicine and Cornell University and the first author of the study, explained, “The design includes a vacuum-based external catheter that leads to a combined forward-reverse osmosis unit, providing a continuous supply of potable water with multiple safety mechanisms to ensure astronaut wellbeing.”
This new design was recently published in Frontiers in Space Technologies.
Future Missions and Current Challenges
In 2025 and 2026, NASA is planning for the Artemis II and III missions, where a crew will orbit the Moon and land on its south pole, respectively. These missions are expected to be followed by crewed missions to Mars by the early 2030s. However, astronauts have long complained about a lack of comfort and hygiene of the existing maximum absorbency garment (MAG) – the waste management system of traditional NASA spacesuits –in use since the late 1970s – which functions like a multi-layered adult diaper made of superabsorbent polymer.
New Solutions for Old Problems
“The MAG has reportedly leaked and caused health issues such as urinary tract infections and gastrointestinal distress. Additionally, astronauts currently have only one liter of water available in their in-suit drink bags. This is insufficient for the planned, longer-lasting lunar spacewalks, which can last ten hours, and even up to 24 hours in an emergency,” said Etlin.
Astronauts have also requested that the time needed to fill and de-gas the in-suit drink bags be reduced in future spacesuits and that a separate supply of non-caffeinated high-energy drinks be added.
Innovative Design for Urine Collection
With all these objectives in mind, Etlin and colleagues have now designed a urine collection device, including an undergarment made of multiple layers of flexible fabric. This connects to a collection cup (with a different shape and size for women and men) of molded silicone, to fit around the genitalia.
The inner face of the collection cup is lined with polyester microfiber or a nylon-spandex blend, to draw urine away from the body and towards the inner cup’s inner face, from where it is sucked by a vacuum pump. An RFID tag, linked to an absorbent hydrogel, reacts to moisture by activating the pump.
Once collected, the urine is diverted to the urine filtration system, where it gets recycled with an efficiency of 87% through a two-step, integrated forward and reverse osmosis filtration system. This uses a concentration gradient to remove water from urine, plus a pump to separate water from salt. The purified water is then enriched in electrolytes and pumped into the in-suit drink bag, again available for consumption. Collecting and purifying 500ml of urine takes only five minutes.
Testing and Implementation of the New System
The system, which integrates control pumps, sensors, and a liquid-crystal display screen, is powered by a 20.5V battery with a capacity of 40 amp-hours. Its total size is 38 by 23 by 23 cm, with a weight of approximately eight kilograms: sufficiently compact and light to be carried on the back of a spacesuit.
Now that the prototype is available, the new design can be tested under simulated conditions, and subsequently during real spacewalks.
“Our system can be tested in simulated microgravity conditions, as microgravity is the primary space factor we must account for. These tests will ensure the system’s functionality and safety before it is deployed in actual space missions,” concluded Dr Christopher E Mason, a professor at the same institute as Etlin and the study’s lead author.
Reference: “Enhanced astronaut hygiene and mission efficiency: a novel approach to in-suit waste management and water recovery in spacewalks” by Sofia Etlin, Luca Bielski, Julianna Rose, Karen Morales, Avery Belman, Emma Alexander, Emma Li, Richard Lin, Krishna Patel, Stephanie Rakhmonova, Claire Walter and Christopher E. Mason, 15 May 2024, Frontiers in Space Technologies.
DOI: 10.3389/frspt.2024.1391200