Space station

For radio broadcasts sent from space, see space radio station.

The modular International Space Station

A space station, also known as an orbital station or an orbital space station, is a spacecraft capable of supporting a crew, which is designed to remain in space (most commonly as an artificial satellite in low Earth orbit) for an extended period of time and for other spacecraft to dock. A space station is distinguished from other spacecraft used for human spaceflight by lack of major propulsion or landing systems. Instead, other vehicles transport people and cargo to and from the station. As of April 2016 two space stations are in orbit: the International Space Station, which is permanently manned, and China's Tiangong-1 (which successfully launched on September 29, 2011), which is unmanned most of the time.^[1][2] Previous stations include the Almaz and Salyut series, Skylab, and most recently Mir.

Today's space stations are research platforms, used to study the effects of long-term space flight on the human body as well as to provide platforms for greater number and length of scientific studies than available on other space vehicles. Each crew member staying aboard the station for weeks or months, but rarely more than a year. Most of the time crew remain at station but its not necessary that crew should have to be stay at station. Since the ill-fated flight of Soyuz 11 to Salyut 1, all manned spaceflight duration records have been set aboard space stations. The duration record for a single spaceflight is 437.7 days, set by Valeriy Polyakov aboard Mir from 1994 to 1995. As of 2013, three astronauts have completed single missions of over a year, all aboard Mir.

Space stations have also been used for both military and civilian purposes. The last military-use space station was Salyut 5, which was used by the Almaz program of the Soviet Union in 1976 and 1977.^[3]

History

Early concepts

File:The Brick Moon.gif

The Brick Moon, first known depiction of a space station.

See also: History of spaceflight

Space stations have been envisaged since at least as early as 1869 when Edward Everett Hale wrote "The Brick Moon".^[4] The first to give serious consideration to space stations were Konstantin Tsiolkovsky in the early 20th century and Hermann Oberth about two decades later.^[4] In 1929 Herman Potočnik's The Problem of Space Travel was published, the first to envision a "rotating wheel" space station to create artificial gravity.

During the Second World War, German scientists researched the theoretical concept of an orbital weapon based on a space station. Pursuing Oberth's idea of a space-based weapon, the so-called "sun gun" was a concept of a space station orbiting Earth at a height of 8,200 kilometres ( mi), with a weapon that was to utilize the sun's energy.^[5]

In 1951, in Collier's weekly, Wernher von Braun published his design for a rotating wheel space station, which referenced Potočnik's idea – however these concepts would never leave the concept stage during the 20th century.^[4]

During the same time as von Braun pursued Potočnik's ideas, the Soviet design bureaus – chiefly Vladimir Chelomey's OKB-52 – were pursuing Tsiolkovsky's ideas for space stations. The work by OKB-52 would lead to the Almaz programme and (together with OKB-1) to the first space station: Salyut 1. The developed hardware laid the ground for the Salyut and Mir space stations, and is even today a considerable part of the ISS space station.

Salyut, Almaz, and Skylab (1971–1986)

Main article: Salyut program

Owen Garriott on EVA in 1973

The first space station was Salyut 1, which was launched by the Soviet Union on April 19, 1971. Like all the early space stations, it was "monolithic", intended to be constructed and launched in one piece, and then manned by a crew later. As such, monolithic stations generally contained all their supplies and experimental equipment when launched, and were considered "expended", and then abandoned, when these were used up.

The earlier Soviet stations were all designated "Salyut", but among these there were two distinct types: civilian and military. The military stations, Salyut 2, Salyut 3, and Salyut 5, were also known as Almaz stations.

The civilian stations Salyut 6 and Salyut 7 were built with two docking ports, which allowed a second crew to visit, bringing a new spacecraft with them; the Soyuz ferry could spend 90 days in space, after which point it needed to be replaced by a fresh Soyuz spacecraft.^[6] This allowed for a crew to man the station continually. Skylab was also equipped with two docking ports, like second-generation stations, but the extra port was never utilized. The presence of a second port on the new stations allowed Progress supply vehicles to be docked to the station, meaning that fresh supplies could be brought to aid long-duration missions. This concept was expanded on Salyut 7, which "hard docked" with a TKS tug shortly before it was abandoned; this served as a proof-of-concept for the use of modular space stations. The later Salyuts may reasonably be seen as a transition between the two groups.

Mir (1986–2001)

Main article: Mir

Earth and the Mir station

Unlike previous stations, the Soviet space station Mir had a modular design; a core unit was launched, and additional modules, generally with a specific role, were later added to that. This method allows for greater flexibility in operation, as well as removing the need for a single immensely powerful launch vehicle. Modular stations are also designed from the outset to have their supplies provided by logistical support, which allows for a longer lifetime at the cost of requiring regular support launches.

ISS (1998–present)

Main article: International Space Station

The core module of the International Space Station was launched in 1998.

The ISS is divided into two main sections, the Russian orbital segment (ROS), and the United States operational segment (USOS).

USOS modules were brought to the station by the Space Shuttle and manually attached to the ISS by crews during EVAs. Connections are made manually for electrical, data, propulsion and cooling fluids. This results in a single piece which is not designed for disassembly.^[7]

ISS under construction

The Russian orbital segment's modules are able to launch, fly and dock themselves without human intervention using Proton rockets.^[8] Connections are automatically made for power, data and propulsion fluids and gases. The Russian approach allows assembly of space stations orbiting other worlds in preparation for manned missions. The Nauka module of the ISS will be used in the 12th Russian/Soviet space station, OPSEK, whose main goal is supporting manned deep space exploration.

Russian Modular or 'next generation' space stations differ from 'Monolithic' single piece stations by allowing reconfiguration of the station to suit changing needs. According to a 2009 report, RKK Energia is considering methods to remove from the station some modules of the Russian Orbital Segment when the end of mission is reached for the ISS and use them as a basis for a new station, known as the Orbital Piloted Assembly and Experiment Complex. None of these modules would have reached the end of their useful lives in 2016 or 2020. The report presents a statement from an unnamed Russian engineer who believes that, based on the experience from Mir, a thirty-year life should be possible, except for micrometeorite damage, because the Russian modules have been built with on-orbit refurbishment in mind.^[9]

Tiangong (2011–present)

Main article: Tiangong

China's first space station, Tiangong-1 was launched in September 2011. The unmanned Shenzhou 8 then successfully performed an automatic rendezvous and docking in November 2011. The manned Shenzhou 9 then docked with Tiangong-1 in June 2012, the manned Shenzhou 10 in 2013. Two more space stations, Tiangong 2 and Tiangong 3 are expected to be launched in subsequent years, paving the way for the construction of a larger space station around 2030.

Habitability

Main article: Effect of spaceflight on the human body

These stations have various issues that limit their long-term habitability, such as very low recycling rates, relatively high radiation levels and a lack of weight. Some of these problems cause discomfort and long-term health effects. In the case of solar flares, all current habitats are protected by the Earth's magnetic field, and are below the Van Allen belts.

Future space habitats may attempt to address these issues, and could be intended for long-term occupation. Some designs might even accommodate large numbers of people, essentially "cities in space" where people would make their homes. No such design has yet been constructed, since even for a small station, the current (2016) launch costs are not economically or politically viable.

Possible ways to deal with these costs would be to build a large number of rockets (economies of scale), employ reusable rockets, In Situ Resource Utilisation, or non-rocket spacelaunch methods such as space elevators. For example, in 1975, proposing to seek long-term habitability through artificial gravity and enough mass in space to allow high radiation shielding, the most ambitious historical NASA study, a conceptual 10000-person spacestation, envisioned a future mass driver base launching 600 times its own mass in lunar material cumulatively over years.^[10]

Architecture

Solar arrays of space station modules backlit by the Sun

A space station is a complex system with many interrelated subsystems:

1. Structure
2. Electrical power
3. Thermal control
4. Attitude determination and control
5. Orbital navigation and propulsion
6. Automation and robotics
7. Computing and communications
8. Environmental and life support
9. Crew facilities
10. Crew and cargo transportation

Environmental Microbiology

Molds that develop aboard space stations can produce acids that degrade metal, glass and rubber ^[11]

List of space stations

Main article: List of space stations

The Soviet space stations came in two types, the civilian Durable Orbital Station (DOS), and the military Almaz stations. (dates refer to periods when stations were inhabited by crews)

• Salyut space stations (USSR, 1971–1986)
  • Salyut 1 (1971, 1 crew and 1 failed docking)
  • DOS-2 (1972, launch failure)
  • Salyut 2/Almaz (1973, failed shortly after launch)
  • Cosmos 557 (1973, re-entered eleven days after launch)
  • Salyut 3/Almaz (1974, 1 crew and 1 failed docking)
  • Salyut 4 (1975, 2 crews and 1 planned crew, failed to achieve orbit)
  • Salyut 5/Almaz (1976–1977, 2 crews and 1 failed docking)
  • Salyut 6 (1977–1981, 16 crews (5 long duration, 11 short duration and 1 failed docking)
  • Salyut 7 (1982–1986, 10 crews (6 long duration, 4 short duration and 1 failed docking)
• Skylab (USA, 1973–1979, 3 crews)
• Mir / (USSR/Russia, 1986–2000, 28 long duration crews)
• International Space Station (ISS) Russia, United States, European Space Agency, Japan and Canada 2000–ongoing, 47 long duration crews ( as of March 2016 )
• Tiangong (China, 2011–ongoing)
  • Tiangong 1 (2011–ongoing, 2 crews as of September 2015)

Canceled projects

• United States Air Force Manned Orbiting Laboratory (MOL) project, which was to employ elements of existing Gemini craft. It was canceled in 1969 about a year before the first planned test flight; this was unusual in being an explicitly military project, as opposed to the Soviet Almaz program, which was heavily intertwined with, and concealed by, the contemporaneous Salyut program.

1967 conceptual drawing of Gemini B reentry module separating from the Manned Orbital Laboratory (MOL) (USAF)

• A second Skylab unit (Skylab B) was manufactured, as a backup article; due to the high costs of providing launch vehicles, and a desire by NASA to cease Saturn and Apollo operations in time to prepare for the Space Shuttle coming into service, it was never flown. The hull can now be seen in the National Air and Space Museum, in Washington DC.
• A number of additional Salyuts were produced, as backups or as flight articles that were later canceled.
• The U.S. Space Station Freedom program, which, despite being under development for ten years, was never launched, instead evolving into the International Space Station
• The Soviet/Russian Mir-2 station, which was never constructed, had some of its elements incorporated into the International Space Station.
• The Industrial Space Facility was a station proposed in the 1980s that was to be privately funded. The project was canceled when the company created to build it, Space Industries Incorporated, was unable to secure funding from the United States government.^[12]

• The European Columbus project planned to create a small space station serviced by the Hermes shuttle. It evolved into the ISS Columbus module.

Future developments

Interior view of an O'Neill cylinder

• China is expected to launch two more space labs called Tiangong 2 and Tiangong 3 before 2016. It will then launch a three module 60-ton space station by 2020. Project 921-2 is the working name given by the People's Republic of China for plans to create a manned space station. The public is being asked to submit suggestions for names and symbols to adorn the planned Chinese space station.^[13]
• U.S. company Bigelow Aerospace is developing the Bigelow Commercial Space Station, a private orbital complex. Bigelow proposes to construct the space station using both Sundancer and BA 330 expandable spacecraft modules as well as a central docking node, propulsion, solar arrays, and attached crew capsules. Initial launch of space station components is planned for 2014, with portions of the station available for leased use as early as 2015.^[14] Bigelow began to publicly refer to the initial configuration—two Sundancer modules and one BA-330 module—of the first Bigelow station as Space Complex Alpha in October 2010.^[15] A second orbital station—Space Complex Bravo—is scheduled to begin launches in 2016.^[16] As of February 2011, the launches for Space Complex Alpha have been contracted to launch on Atlas V and Falcon 9 launch vehicles, from Cape Canaveral, starting in 2014.^[17][18][19]

• In April 2008, the Russian space agency proposed the construction of an orbital construction yard (OPSEK) for spacecraft too heavy to launch from Earth directly. It would not begin construction or be finished until after the decommissioning of the International Space Station.^[20] This plan was described to ISS partners by Anatoly Perminov June 17, 2009.^[21]

• The Orbital Technologies Commercial Space Station is a project of a Russian corporation (Orbital Technologies). The CSS is intended to accommodate diverse functions such as:^{[citation needed]}
  • Enabling space-based microgravity research.
  • Providing a destination for commercial human spaceflight, space tourism, and state sponsored human spaceflight programs.
  • Acting as a backup and emergency safe haven for the International Space Station and its crew.
  • Enabling product development.
  • Facilitating satellite servicing and maintenance.
  • Providing a staging outpost for human space flight missions beyond low Еarth orbit.
  • Supplying a uniquely capable remote sensing platform.

Proposed Exploration Gateway Platform at EML-1

The business arrangement for developing and marketing the station was recently clarified by Russian firm Orbital Technologies, who is collaborating to develop the station with the Rocket and Space Technology Corporation Energia (RSC Energia). ^[22]

• Excalibur Almaz, an international company based in the Isle of Man in the British Isles and headed by Arthur Dula, is developing a system integrated by a reusable space vehicle and a space station based on the technology of the Soviet military stations "Almaz".^[23] In this efforts, Excalibur-Almaz is co-working with a Russian corporation with a large tradition in aerospace technology, the military-industrial association "Mashinostroyenia".^[24]
• In December 2011 Boeing proposed using Node 4 as the core of an Exploration Gateway Platform to be constructed at the ISS and relocated via space tug to an Earth-Moon Lagrange point (EML-1 or 2). The purpose of the platform would be to support lunar landing missions with a reusable lunar lander after the first two SLS flights. It would also bypass the need for a L1 propellant depot for lunar missions. Other hardware would include an airlock, an 'international module', and a MPLM based habitat module.^[25]
• In February 2012 Playboy proposed an orbital "space club", in conjunction with Virgin Galactic. Their plans include a restaurant and a zero gravity dance club.^[26]
• India plans to upgrade its ISRO Orbital Vehicle to perform rendezvous and docking after the planned Indian human spaceflight programme.

See also

• List of space stations
• Kerim Kerimov, lead architect behind earliest space stations
• Lunar outpost
• Lunar space elevator
• Martian outpost
• Propellant depot, future space station complexes may permit spacecraft to refuel
• Rotating wheel space station
• Timeline of Solar System exploration
• List of films featuring space stations

References

2. Barbosa, Rui. "China launches TianGong-1 to mark next human space flight milestone". NASASpaceflight.com. http://www.nasaspaceflight.com/2011/09/china-major-human-space-flight-milestone-tiangong-1s-launch/. 
3. Russian Space Stations (wikisource)
4. The First Space Station, Boy's Life, September 1989.
6. D.S.F. Portree (1995). "Mir Hardware Heritage". NASA. http://ston.jsc.nasa.gov/collections/TRS/_techrep/RP1357.pdf. Retrieved 30 November 2010. 
8. "Mechanical and Aerospace Engineering - mae.usu.edu". Usu.edu. http://www.usu.edu/mae/aerospace/publications/JDSC_RoadToAutonomy.pdf. Retrieved 2012-08-13. 
10. NASA, 1975: Space Settlements: A Design Study. Retrieved 2011-05-09.
11. Trudy E. Bell (2007). "Preventing "Sick" Spaceships". http://science.nasa.gov/science-news/science-at-nasa/2007/11may_locad3/. 
13. pacedaily.com/reports/Countdown_begins_for_Chineses_space_station_program_999.html Countdown begins for Chineses space station program]
14. Bigelow Aerospace — Next-Generation Commercial Space Stations: Orbital Complex Construction, Bigelow Aerospace, accessed 2011-01-10.
15. Bigelow still thinks big, The Space Review, 2010-11-01, accessed 2011-01-10.
16. Balloons in Space: A History, Space.com, 2010-11-12, accessed 2011-01-10.
18. "SpaceX Launch Manifest". http://www.spacex.com/launch_manifest.php. Retrieved 8 May 2011. 
19. Choi, Charles (2010-11-12). "In Race for Private Space Stations, It's U.S. Versus Russia". Space.com. http://www.space.com/9518-race-private-space-stations-russia.html. Retrieved 8 May 2011. "Their station could launch by 2015 or so, Gold said, using United Launch Alliance's Atlas 5 rocket or SpaceX's Falcon 9 rocket." 
20. Прогресс: Россия построит на орбите завод по сборке межпланетных кораблей, Lenta.Ru, April 12, 2008. Accessed on April 13, 2008.
21. Doug Messier. "Roskosmos Administrator Perminov Speaks About Past, Present and Future ISS Cooperation". http://www.parabolicarc.com/2009/06/29/roskosmos-administrator-perminov-speaks-present-future-iss-cooperation/. 
22. Cooperation Agreement with Roscosmos and RSC "Energia"
23. Excalibur-Almaz showcases space vehicles and space stations
24. ExcaliburAlmaz
25. "Exploration Gateway Platform hosting Reusable Lunar Lander proposed". NASASpaceFlight.com. 2011-12-02. http://www.nasaspaceflight.com/2011/12/exploration-gateway-platform-hosting-reusable-lunar-lander-proposed/. Retrieved 2012-08-13. 
26. "Playboy and Virgin Galactic Dream Up Cosmic Men's Space Club | Space Sex & Sex in Space | Virgin Galactic, Space Tourism & Private Space Travel". Space.com. 2012-02-23. http://www.space.com/14666-playboy-space-club-images-private-stations.html. Retrieved 2012-08-13. 

Bibliography

• Haeuplik-Meusburger: Architecture for Astronauts - An Activity based Approach. Springer Praxis Books, 2011, ISBN 978-3-7091-0666-2

External links

• Read Congressional Research Service (CRS) Reports regarding Space Stations
• [news:sci.space.station Space Station Newsgroup - sci.space.station]
• "Giant Doughnut Purposed As Space Station" early 1950s article on the subject of space exploration and a space station orbiting earth
• - Space Stations

This page uses Creative Commons Licensed content from Wikipedia (view authors).