Neutral Buoyancy Laboratory
An astronaut training in the NBL | |
Established | April 1995[1] |
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Location | Houston, Texas, United States |
Operating agency | NASA |
Website |
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The Neutral Buoyancy Laboratory (NBL) is an astronaut training facility and neutral buoyancy pool operated by NASA and located at the Sonny Carter Training Facility, near the Johnson Space Center in Houston, Texas.[2] The NBL's main feature is a large indoor pool of water,[3] in which astronauts may perform simulated EVA tasks in preparation for upcoming missions. Trainees wear suits designed to provide neutral buoyancy to simulate the microgravity that astronauts would experience during spaceflight.
Pool features
The diving tank is 202 feet (62 m) in length, 102 feet (31 m) wide, and 40 feet 6 inches (12.34 m) deep, and contains 6.2 million gallons (23.5 million litres) of water.[4][5] The NBL contains full-scale mock-ups of International Space Station (ISS) modules and payloads, as well as visiting vehicles such as the Japan Aerospace Exploration Agency (JAXA) HTV, the European Space Agency ATV, the SpaceX Dragon, and the Orbital Sciences Corporation Cygnus.[4] Previously there was also a mockup of the Space Shuttle payload bay, but since Space Shuttle retirement it has been removed.
History
In the late 1980s NASA began to consider replacing its previous neutral-buoyancy training facility, the Weightless Environment Training Facility (WETF). The WETF, located within Johnson Space Center, had been successfully used to train astronauts for numerous missions, but its pool was too small to hold useful mock-ups of space station components of the sorts intended for the mooted Space Station Freedom, or its successor, the International Space Station. NASA purchased the structure that now holds the NBL from McDonnell Douglas in the early 1990s and began refitting it as a neutral-buoyancy training center in 1995.[6]
Neutral-buoyancy training
During training exercises, neutral-buoyancy diving is used to simulate the weightlessness of space travel. To achieve this effect, suited astronauts or pieces of equipment are lowered into the pool using an overhead crane and then weighted in the water by support divers so that they experience minimal buoyant force and minimal rotational moment about their center of mass.[2] The suits worn by trainees in the NBL are down-rated from fully flight-rated EMU suits like those in use on the Space Shuttle and International Space Station. Divers breathe nitrox while working in the tank.[7][8]
Training challenges
One disadvantage of neutral-buoyancy diving as a simulation of microgravity is the significant amount of drag created by the water.[9] This makes it difficult to set an object in motion, and difficult to keep it in motion. It also makes it easier to keep the object stationary. This effect is the opposite of what is experienced in space, where it is easy to set an object in motion, but very difficult to keep it still. Generally, drag effects are minimized by doing tasks slowly in the water.
Another downside of neutral buoyancy simulation is that astronauts are not weightless within their suits, meaning that as divers tilt their suits they are pressed against whatever inside surface is facing down. This can be uncomfortable in certain orientations, such as heads-down. Thus, precise suit sizing is critical.
See also
References
- ↑ "NBL Timeline". Neutral Buoyancy Laboratory. Retrieved 20 March 2015.
- 1 2 Strauss S (July 2008). "Space medicine at the NASA-JSC, neutral buoyancy laboratory". Aviat Space Environ Med 79 (7): 732–3. PMID 18619137.
- ↑ "Behind the scenes training". NASA. May 30, 2003. Retrieved March 22, 2011.
- 1 2 Strauss S, Krog RL, Feiveson AH (May 2005). "Extravehicular mobility unit training and astronaut injuries". Aviat Space Environ Med 76 (5): 469–74. PMID 15892545. Retrieved 2008-08-27.
- ↑ "NBL Characteristics". About the NBL. NASA. June 23, 2005.
- ↑ Hutchinson, Lee (4 March 2013). "Swimming with spacemen: training for spacewalks at NASA’s giant pool". Ars Technica. Retrieved 24 March 2015.
- ↑ Fitzpatrick DT, Conkin J (2003). "Improved pulmonary function in working divers breathing nitrox at shallow depths". Undersea Hyperb Med abstract 30 (Supplement). Retrieved 2008-08-27.
- ↑ Fitzpatrick DT, Conkin J (July 2003). "Improved pulmonary function in working divers breathing nitrox at shallow depths". Aviat Space Environ Med 74 (7): 763–7. PMID 12862332. Retrieved 2008-08-27.
- ↑ Pendergast D, Mollendorf J, Zamparo P, Termin A, Bushnell D, Paschke D (2005). "The influence of drag on human locomotion in water". Undersea Hyperb Med 32 (1): 45–57. PMID 15796314. Retrieved 2008-08-27.
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Coordinates: 29°36′26″N 95°08′38″W / 29.6071°N 95.1439°W