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Von Braun Station
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In the first 1946 summary of his work during World War II, Wernher von Braun prophesied the construction of space stations in orbit. The design, a toroidal station spun to provide artificial gravity, would be made very familiar to the American public over the next six years. The design was elaborated at the First Symposium on Space Flight on 12 October 1951 at the Hayden Planetarium in New York City. The design was popularized in the series in Colliers magazine, illustrated with gorgeous Chesley Bonestell painting, in 1952.
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Ehricke 4-man orbital station
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In 1954 Ehricke postulated a four-man design that might serve a number of different purposes, depending upon altitude and orbital inclination. Such a station might be used for a multitude of scientific research, for orbital reconnaissance, for an observation platform, and as a launch site for more distant space ventures. The station would be launched initially by a large multistaged booster and subsequently visited by crews and resupplied by means of smaller ferry rockets.
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Outpost
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In 1958, the year after Sputnik 1, Krafft Ehricke, then with General Dynamics' Convair Division, designed a four-man space station known as Outpost. Ehricke proposed that the Atlas ICBM being developed by Convair could be adapted as the station's basic structure. The Atlas, 3 m in diameter and 22.8 m long, was America's largest rocket at the time.
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Horizon Station
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In the Project Horizon report, Wernher von Braun, then with the Army Ballistic Missile Agency, advanced a theory that he had conceived years earlier for using a booster's spent stage as a space station's basic structure. This later evolved into the "wet stage" concept for the Skylab Program. Project Horizon envisioned moving quickly to an early improved station constructed from 22 upper stage shells. Prior to any expansion of lunar outpost operations, sufficient tankage would have been placed in orbit to permit construction of two or three such stations. The orbital station crew strength was approximately ten; however, the crew would be rotated every several months.
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Ideal Home Station
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Designed by Douglas, the Space Vehicle was represented by a full-scale model at the Ideal Home Show in London in 1962. It had a length of 19 m and was 5.2 m in diameter. It was clearly based on the use of a Saturn S-IV spent second stage. After take-off the first stage of the Saturn I would burn out at an altitude of 60 km; the second stage would enter orbit at 400 km. Once in orbit the Space Vehicle was pointed towards the sun. Its mission was to map stellar space, to make spectroscopic observations and to obtain other astronomical data, all of which are telemetered directly to earth stations.
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Mercury Mark I
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Proposed derivatives of the basic one-crew Mercury capsule for investigation of earth orbit rendezvous, lifting re-entry and land landing. Two-crew derivatives of Mercury, originally designated Mercury Mark II, are covered under 'Gemini'.
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LORL
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Large Orbiting Research Laboratory was a term applied to a number of NASA and USAF designs of the 1960's intended to succeed MORL. Typically these were rotating stations orbited in a single Saturn V launch. NASA finally decided it preferred a large zero-G station, which became the baseline for studies by 1968.
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MORL
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In June 1964 Boeing and Douglas received Phase I contracts for Manned Orbital Research Laboratory station designs. The recommended concept was a 13.5 metric ton "dry" space station, launched by Saturn IB, with Gemini or Apollo being used for crew rotation. The 6.5 meter diameter and 12.6 meter long station included a docking adapter, hangar section, airlock, and a dual-place centrifuge. Douglas was selected by NASA LaRC for further Phase 2 and 3 studies in 1963 to 1966. Although MORL was NASA's 'baseline station' during this period, it was dropped by the late 1960's in preference to the more capable station that would become Skylab.
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USAF Recommended Station
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During 1962 NASA Centers, the Air Force, and many of the major aerospace contractors were developing possible space station concepts and studying their potential uses. This was the Air Force recommended concept of the period.
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Apollo X
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Apollo X was the designation given at various times during the Apollo program for follow-on versions of the spacecraft for extended earth-orbit operations (for a time, all follow-on projects using Apollo hardware were termed 'Apollo X'.
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Lockheed 1963 Space Station
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Lockheed made an unsolicited proposal to NASA in 1963 for an ambitious space station project. The elements would be launched by Saturn I, as would the 'Astrocommuter' shuttle. Neither NASA or Lockheed management showed much interest in the concept.
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Lockheed 1963 Space Tug
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Lockheed proposed a space tug to service its 1963 space station.
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Self-Deploying Space Station
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The first space station designs using the Saturn V launch vehicle involved spinning stations, providing artificial G for the crew. This resulted in a number of interesting single-launch designs with unfolding station structures. By the mid-1960's these had been abandoned at NASA in favor of zero-G monolithic stations.
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Gemini Pecan
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In 1964 the MSC Advanced Spacecraft Technology Division formulated a mission flight plan for using a Gemini spacecraft to link up with an orbiting vehicle to achieve a long-duration space mission (dubbed the "Pecan" mission). The two crewmen were to transfer to the Pecan for the duration of the mission.
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Saturn II Stage Wet Workshop
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Wernher von Braun made a rough sketch of a space station based on fitting out of an expended Saturn II stage in orbit on 24 November 1964. Although this would have provided a larger station than Skylab while also using a single Saturn V launch, the idea was not pursued further.
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Apollo LM Lab
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Use of the Apollo LM as an earth-orbiting laboratory was proposed for Apollo Applications Program missions. The LM would have its engines and propellants removed, providing space for up to 10 metric tons of scientific equipment. A specific version of the LM lab was the Apollo Telescope Mount.
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Extended Mission Gemini
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A McDonnell concept for using Gemini for extended duration missions. The basic Gemini would dock with an Agena upper stage. Between the docking collar and the Agena was an orbital shelter where the crew would live and work for weeks at a time.
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Orbital Workshop
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The Orbital Workshop (OWS) was a 1960's NASA program to create an embryonic space station in orbit using the spent S-IVB rocket stage of a Saturn IB. Once in orbit, the station would be visited by a crew launched by a Saturn IB in an Apollo CSM. The crew would dock with the station, vent the residual propellants from the S-IVB stage, fill the hydrogen tank with a breathable oxygen atmosphere, and then enter the tank and outfit it as a station.
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Apollo ATM
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The Apollo Telescope Mount began as a solar telescope built into the spaceframe of an Apollo lunar module. Initially it was to be either free-flying (operated by a visiting crew in an Apollo CSM) or launched separately and docked to a Saturn S-IVB orbital workshop. Over many years it evolved into a piece of hardware unrelated to the Apollo LM and integrated into the Skylab space station.
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Apollo LMSS
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Under the Apollo Applications Program NASA began hardware and software procurement, development, and testing for a Lunar Mapping and Survey System. The system would be mounted in an Apollo CSM. The system was later cancelled due to the shrinking NASA post-Apollo budget.
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Gemini Observatory
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Proposed version of Gemini for low-earth orbit solar or stellar astronomy. This would be launched by a Saturn S-IB. It has an enlarged reentry module which seems to be an ancestor of the 'Big Gemini' of 1967.
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Apollo RM
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In 1967 it was planned that Saturn IB-launched Orbital Workshops would be supplied by Apollo CSM spacecraft and Resupply Modules (RM) with up to three metric tons of supplies and instruments.
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Apollo 120 in Telescope
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Concept for use of a Saturn V-launched Apollo CSM with an enormous 10 m diameter space laboratory equipped with a 3 m diameter astronomical telescope.
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Apollo LMAL
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This was one of 18 conceptual designs published 25 April 1968 for the Earth-orbital spacecraft lunar module adapter laboratory prepared by spacecraft design experts of the MSC Advanced Spacecraft Technology Division. The configuration was developed to illustrate the extent to which the building block philosophy could be carried. It would utilize both Gemini and Apollo spacecraft and would require 2 unmanned launches and 10 manned logistic launches. The report was published 25 April 1968.
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Space Station
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NASA's baseline Space Station of 1970, which was to be operational at early as 1977, was a large earth orbiting laboratory having a crew of 12 and a minimum operational lifetime of 10 years with resupply flights every 90 days. The station would be launched, unmanned, by an Saturn INT-21 (modified two-stage Saturn V). The station would be activated after completion of initial rendezvous and docking operations by the space shuttle.
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MOL
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MOL (Manned Orbiting Laboratory) was the US Air Force's manned space project after Dynasoar was cancelled, until it in turn was cancelled in 1969. The earth orbit station used a helium-oxygen atmosphere. The crew rode the station to orbit and returned to earth aboard a Gemini-B capsule that was part of the station - no rendezvous or docking was required. Experiments planned ranged the gamut from military reconnaissance using large optical cameras and side-looking radar, through interception and inspection of satellites, to exploring the usefulness of man in space and test of Manned Maneuvering Units.
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S-IVB Advanced Station
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Follow-on to Skylab proposed by Douglas. The station would still use the S-IVB stage as the basis, but would be much more extensively outfitted for larger crews.
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Skylab
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First US space station. The project began life as the Orbital Workshop (see separate entry) - outfitting of an S-IVB stage with a docking adapter with equipment launched by several subsequent S-1B launches. Curtailment of the Apollo moon landings meant that surplus Saturn V's were available, so the pre-equipped, five times heavier, and much more capable Skylab resulted.
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Space Base
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Growth of Space Station into a 50 man Space Base was a required capability in the Phase B NASA Space Station studies of 1969-1970. The original core Station Module was to be used in the Base build-up several years later or was to be used as a prototype of one of the Space Base modules. Space Base would serve as a major international facility for research, applications and for the support of other space operations such as servicing unmanned satellites. The crew would be large enough to include specialists of many kinds and to minimize even more the need for astronaut-type training. The Space Base would provide nearly equal zero and artificial gravity volumes and would be configured with permanent dedicated laboratories and observatories in addition to general purpose facilities.
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Planetary Mission Module
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NASA had the long range goal of sending men to explore the planet Mars. To assure that the developments undertaken as part of the Space Station program contributed to this long term goal without undue increase in program cost or complexity, an assessment was made to determine where common or near common requirements existed. Two manned Mars missions, a 1981 opposition class mission and a 1986 conjunction class mission, were selected as representative types about which to develop total vehicle and operational concepts. These concepts involved the use of two Nuclear Shuttles for Earth departure and a third Shuttle to accompany the planetary spacecraft for use in braking into Mars orbit, in Mars orbit departure and in braking into a highly elliptic Earth orbit.
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Modularised Space Station
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Space station design of 1972 using modules sized for transport in the Space Shuttle payload bay. could be carried inside the Shuttle orbiter payload bay. NASA hoped to launch such a space station in 1978, but the budget crunch forced the project to be delayed until it emerged again as the bloated International Space Station in the 1990's.
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Manned Orbiting Facility
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NASA carried out a number of space station studies while the Shuttle was being developed in the mid-1970s. The first was McDonnell-Douglas' Manned Orbiting Facility (MOF) , a small 4-man space station that would have been configured differently for various missions, much like the Soviet Salyut stations.
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AMSS - Austere Modular Space Station
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Another 1970s design was North American Rockwell's 'Austere Modular Space Station'. The most important application in those days was constructing large space structures, e.g. extremely large communications satellites , giant 20 kilometer-wide solar power satellites or even giant orbiting space colonies for millions of people. Contemporary space station studies such as Rockwell's and Boeing's were closely tied to this objective. NASA's Outlook for Space report from 1975 recommended a number of possible goals, including development of a 12-man space station in low Earth orbit by 1988 and a similar station in lunar orbit by 1994.
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Apollo ASTP Docking Module
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The ASTP docking module was basically an airlock with docking facilities on each end to allow crew transfer between the Apollo and Soyuz spacecraft. The docking module was 3.15 m long, 1.4 m maximum diameter, and weighed 2,012 kg. Apollo's cabin atmosphere was 100 percent oxygen at 0.34 atmosphere pressure, while that of Soyuz was nitrogen/oxygen at 1.0 atmosphere. Transfer between these two atmospheres would require pre-breathing of pure oxygen to purge the blood of suspended nitrogen. This was avoided by lowering the Soyuz pressure to 0.68 atmospheres pressure. The docking module served mainly as an airlock to raise or lower the pressure between 0.34 and 0.68 atmospheres when moving from one spacecraft to the other. This was done through the use of pressure equalization valves with both hatches closed.
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Space Operations Center
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The Space Operations Center was proposed by NASA's Johnson Spaceflight Center in 1979. Like most other space station studies from the mid/late 1970s its primary mission was the assembly and servicing of large spacecraft in Earth orbit -- not science. NASA/JSC signed a contract with Boeing in 1980 to further develop the design. Like most NASA space station plans, SOC would be assembled in orbit from modules launched on the Space Shuttle. The crew's tour of duty would have been 90 days. NASA originally estimated the total cost to be $2.7 billion, but the estimated cost had increased to $4.7 billion by 1981. SOC would have been operational by 1990.
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Science and Applications Manned Space Platform
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While NASA/Johnson was studying the Space Operations Center concept, the Marshall Space Flight Center was lobbying for its own station -- the Science and Applications Manned Space Platform (SAMSP). MSFC envisioned a series of cheap 'platforms' costing only $500 million that could be outfitted for different missions. One mission would be to service spacecraft such as the Hubble Space Telescope. The platform would provide power, communications, thermal control and other services for standard Shuttle payload experiments -- it essentially served as a surrogate Shuttle payload bay. SAMSP could gradually evolve into a manned space station by adding pressurized crew modules derived from Spacelab. Initially, SAMSP would have a crew of three to four astronauts.
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STS External Tank Station
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NASA studied several concepts in the 1980's using the 'wet workshop' approach to the capacious External Tank carried into orbit with every shuttle flight. Despite the incredible logic of this, NASA management never pursued it seriously - seeing it as an irresistible low-cost alternative to their own large modular space station plans.
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Industrial Space Facility
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In 1982 Space Industries Inc. planned to develop an 'Industrial Space Facility' (ISF), a 'mini space station' that would fly unmanned most of the time but be serviced regularly by the Space Shuttle. ISF would have housed up to 11,000 kg (71 m3) of commercial microgravity and industrial manufacturing experiments in 31 payload racks; twin 140 m2 solar panels would have produced 20 kW of power. But endless political wrangling and NASA policy changes after the Challenger disaster delayed to the next millennium any industrial exploitation of space.
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Space Station Designs - 1982
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NASA regarded a permanently manned space station as the next 'logical step' in manned spaceflight after the Space Shuttle entered service in April 1981. The agency formed a Space Station Task Force in May 1982 to study possible user requirements. In August 1992, NASA awarded eight $1-million study contracts to Boeing, McDonnell-Douglas, TRW, Rockwell, Grumman, General Dynamics/Convair and Martin Marietta. The contractors reported back in March 1983.....
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Spacelab
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The Spacelab was designed by the European Space Agency to fit in the US space shuttle payload bay and allow extended experiments to be conducted by astronauts in orbit. Spacelab and the Canadian remote manipulator arm were the remnants of NASA's efforts to internationalize the shuttle program at its inception. In the absence of an American space station, Spacelab provided the only opportunity for America to carry out extensive man-tended experiments in space from the first Spacelab flight in 1983 until the Shuttle-Mir program in 1995.
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OMV
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The Orbital Maneuvering Vehicle (OMV) was an important component in NASA's future Space Station plans in the 1980s. As a separately funded part of the 1984 Space Station plan, the OMV was intended as a short range robotic 'space tug' that could move payloads about in the vicinity of the Shuttle and Space Station.
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Polar Platform
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In order to increase the Space Station's and Space Shuttle's appeal, NASA tried to involve as many users as possible. Hence the 1984 Space Station program would also include a large unmanned platform for Earth observation. NASA claimed this Polar Platform would utilize many of the same systems as the Station and be serviced by the Space Shuttle, although it would reside in a different (polar-) orbit than the main Station complex. The Polar Platform was finally transferred to the 'Mission to Planet Earth' remote sensing program in late 1990 when the Space Station's budget again was reduced.
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Power Tower Space Station - 1984
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The NASA Concept Definition Team eventually selected the Boeing/Grumman 'Power Tower' design as its baseline. It would provide maximized user viewing opportunities, a clear area for Shuttle dockings and versatility in Station growth. The design was also less sensitive to changes in mass caused by the addition of modules to the Station. The 'Power Tower' station's main structure was to be 122 meters tall with 75 kW solar panels sticking 41 meters to either side of the centerline.
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Space Station 1984
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President Reagan finally approved a space station project for NASA in January 1984. In the face of Pentagon opposition, NASA promised Reagan that the first two years of the project would be low-cost definition studies and agreed to develop a facility that would cost no more than $8 billion at 1984 rates. The foot was in the door, and by 2005 Reagan's space station had metastized into the International Space Station, still not complete at a cost of over.
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Dual Keel Space Station - 1985
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NASA radically changed its Space Station baseline design in October 1985 following frequent complaints from users and astronauts. The new 'Dual Keel' Station was largely based on Lockheed and McDonnell-Douglas designs and its structure was much stiffer and hence easier to stabilize. It would offer additional space for external instruments plus a better microgravity environment than the previous gravity gradient-stabilized 'Power Tower.' The number of crew members was increased to 8 astronauts because scientists were concerned that a crew of six would be too busy with assembly and maintenance tasks and have no time for research. NASA's target date for the launch of the first element was now January 1993 while the initial operational capability had slipped to January 1994 mainly because the Fiscal 1986 budget was reduced from $280 million to just $200 million.
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ISS Space Station Remote Manipulator System
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When the Space Station plan was changed in 1987, its satellite servicing element was postponed indefinitely. The Canadian robotic arm was now necessary for assembling the Station itself, since the Shuttle's existing 'Canadarm' manipulator only could handle 29.5t loads. The redesigned 'Canadian Mobile Servicing Center' would be used to dock the Shuttle and, possibly, payloads launched on expendable launchers to the Station.
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ESA Polar Platform
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Britain initially expressed strong interest in developing an unmanned Polar Platform for Earth observation as part of the European Columbus package. In 1986 the platform was scheduled for a 1995 launch. By 1987 the launch date had slipped by two years as the British were expressing doubts about the Space Station project. Britain finally pulled out in February 1988 and the design was scaled back to a smaller satellite based on the French SPOT-4 spacecraft bus. The design was retained when the British decided to rejoin a year later, but British Aerospace was appointed main contractor of the project. The $972-million POEM-1 project was moved out of the Columbus space station package in November 1991 and was subsequently descoped into Envisat-1.
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NASDA Japanese Experiment Module
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The Japanese Experiment Module (JEM) has been a rare island of stability in the often tumultuous Space Station program. Conceived in 1985, JEM consists of a pressurized laboratory mainly dedicated to advanced technology experiments, a logistics module, an unpressurized pallet for vacuum experiments in space plus a small robotic arm. The Japanese National Space Development Agency (NASDA) formally submitted the JEM proposal to NASA in March 1986. The Japanese Space Activities Commission recommended formal participation in the Space Station project five months later and the JEM design changed little since the mid-1980s.
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Spacedock
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After the 1986 Space Shuttle Challenger accident, a number of space policy reports ('Pioneering the Space Frontier', 'Leadership and America's Future in Space') advocated an aggressive manned lunar/Mars program to restore America's lead in space. NASA now embarked on a number of studies to see how the downscaled Space Station Freedom could assist this goal. This would involve use of a large spacedock facility for assembly and checkout of manned lunar or planetary spacecraft.
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Flight Telerobotic Servicer
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NASA decided to develop a $288-million Flight Telerobotic Servicer in 1987 after Congress voiced concern about American competitiveness in the field of robotics. The FTS would also help astronauts assemble the Space Station, which was growing bigger and more complex with each redesign.
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HTV
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Japanese space tug designed for launch by the H-2A for International Space Station resupply. The HTV would carry International Standard Payload Racks but it had no docking capability. Instead, the HTV would rendezvous with the Canadian robotic arm which then would grapple it and move it to one of the Space Station's docking hatches.
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ISS Space Telescope
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The Space Station's free-flying unmanned platforms were all deleted in 1987-90 to compensate for the budget cuts. However, some of them may yet be reintroduced in the 21st century. One possibility was a space telescope capable of detecting planets orbiting around nearby stars. It would be serviced by International Space Station astronauts. The early 1984 Space Station plan briefly featured a similar 'Astro' platform.
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Space Station Freedom
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NASA's first detailed cost assessment for the US space station caused a political uproar in Congress, where many politicians had started to express doubt about the project. However, NASA and Reagan Administration officials reached a compromise in March 1987 which allowed the agency to proceed with a cheaper $12.2-billion Phase One Station. This design initially omitted the $3.4-billion 'Dual Keel' structure and half of the power generators. The new Space Station configuration was named 'Freedom' by Reagan in June 1988.
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ESA ACRV
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As Hermes gradually faded into oblivion, the European Space Agency started to take a closer a look at cheaper and less complicated manned space capsules. An 'Ariane-X' crew rescue capsule was part of the preliminary European space station studies in the late 1980s, and the French and Italian aerospace industry also investigated unmanned concepts such as the 'Carina' version in 1990. 'Carina' was to have a diameter of 4 meters and would be launched on the Ariane-4 rocket. Its main mission was commercial microgravity experiments. The European Space Agency started a six-month Phase 1 'Assured Crew Return Vehicle' study in October 1992. Aerospatiale, Alenia Spazio and Deutsche Aerospace were prime contractors. In June 1993, the European Space Agency announced that a simpler manned space capsule would replace the Hermes manned spaceplane project.
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Robotic Satellite Servicer
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After the Orbital Maneuvering Vehicle encountered developmental problems in 1989-90, NASA tried to integrate the OMV and Flight Telerobotic Servicer into a 'Robotic Satellite Servicer.' This in turn was cancelled when the station's free-flying space platforms were deleted.
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Space Station Fred
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Following the collapse of the Space Station Freedom project, NASA unveiled its new Space Station design in March 1991. The resulting configuration was mockingly referred to as 'Fred' by the programs critics, underscoring the truncated nature of the design. The Space Station assembly sequence was greatly simplified by switching to shorter, prefabricated truss segments that required no assembly in space. Only 250-300 hours of annual EVA 'spacewalks' were now required for maintaining the Station's external areas. One set of solar arrays were deleted, reducing the power from 75 kW to 56 kW although 30 kW still would be available for users.
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ISS Mini PLM
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As NASA's Space Station budget received further cutbacks, the agency was forced to consider more and more hardware paid for by foreign space agencies although Congress and private industry were opposed to it. In 1992, Italy's Alenia Spazio announced they would build a small Mini-Pressurized Logistics Module (MPLM) for the Space Shuttle, enabling it to carry 4500 kg of cargo to the Space Station. The MPLM might also be transformed into a small life sciences laboratory. Boeing had previously wanted to build the MPLM, but NASA could not afford to pay for it. Instead, the Italian space agency, ASI, would now finance the $400-million project in return for crew time and experiments on the Space Station.
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ISS Columbus Orbiting Facility
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In October 1993, ESA decided to further slash its overall budget by a combined $4.8 billion in 1994-2000. The Columbus space station module survived, but in a reduced form. It would now cost $900 million less than the proposed $3.1 billion through 2000. The new Columbus Orbiting Facility (COF) was shorter and lighter. It was based on the same Alenia-developed pressurized module as the Multi-Purpose Logistics Module.
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ISS MPLM
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When the International Space Station (ISS) was redesigned again in 1993, it was decided to expand the original Mini-Pressurized Logistics Module design. The new Multi-Purpose Logistics Module was twice as long and could carry 9000 kg of cargo to ISS. The European Space Agency also became a partner, since Alenia Spazio would use the same pressurized module and some thermal subsystems in the Columbus Orbiting Facility as well. In return, ESA provided three environmental control and life-support system units for use in the Multipurpose Logistics Module. The module carried sixteen International Standard Payload Racks.
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Space Station Options 1993
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Following the collapse of Space Station Fred, NASA quickly formed a Space Station redesign team which identified three major redesign options in April 1993....
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Spacehab
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Founded by Bob Citron in 1982, Spacehab Inc. was the only entrepreneurial company to successfully develop a commercial manned spaceflight module. Spacehab was initially formed to develop a 5000 kg pressurized module derived from ESA's Spacelab. The 3 meter long Spacehab module was carried inside the Shuttle cargo bay and provides 28.3 cubic meters of expanded habitable space for experiments and logistics transport to space stations.
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ISS Russian Science and Power Platform
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The RSPP was originally going to be launched on six Russian Proton rockets fairly early during the ISS assembly phase. The Science and Power Platform would only power the Russian laboratory modules, so it was not crucial to the success of the whole ISS project. Further Russian cutbacks led to the RSPP being cancelled and replaced with one of the four American solar arrays.
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International Space Station
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In 1987-1993 the Russians successfully assembled and operated the 124-metric ton Mir station. The station's modules were evolved from those of the secret military Almaz station of the 1970s. Mir and its crews whirled round and round the world, through the collapse of the Soviet Union and Russian economic meltdown. By 1993, Russia had acquired unmatched experience in long-duration human flight, but it was apparent that there was no money for the follow-on Mir-2.
At the same time, NASA had scaled down its space station in the seventh redesign in nine years. This more modest station Alpha deleted most of the original science experiments, but would still cost more than Clinton was willing to spend. In October 1993, with the gunfire of the coup attempt outside their windows, NASA negotiators in Moscow agreed to the 'International Space Station' (ISS), a merger of stations Alpha and Mir-2.
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ISS Unity
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Unity was the first U.S.-built component of the International Space Station. It consisted of a six-sided connecting module and passageway, and was the primary cargo of Space Shuttle mission STS-88, the first mission dedicated to assembly of the station.
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ISS Zarya
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The Russian Zarya FGB space tug was the cornerstone of the new International Space Station since it acted as an adapter between the US and Russian-built ISS segments and also provided some propulsion and propellant storage capabilities. It was closely based on the older Russian TKS spacecraft design that was intended as a ferry for the Almaz military station. The United States paid $220 million for the FGB (vs. $450 million for Lockheed's rejected 'Bus-1' option) and Khrunichev successfully completed the project on schedule and within budget. However, the launch had to be delayed by 17 months to November 1998 because the Russians were unable to complete their own ISS Zvezda service module on time.
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Transhab Module
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Cost overruns soon forced NASA to consider other options for the International Space Station's habitation module. The space agency originally intended to use the same 8.2-meter long habitation module as the final 1991 Space Station Freedom design. In late 1998, NASA's Johnson Space Center proposed a much larger and lighter inflatable 8-meter diameter 'Transhab' module that also could be converted into crew quarters for future manned missions to the Moon and Mars. It was also possible that the module could be built and paid for by private industry and leased to NASA, although the exact configuration wasn't clear. Transhab and the 8.2-meter module appeared to be equally expensive ($100 million in 1998) and NASA had not made a final decision.
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ISS Commercial Enterprise Module
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The Russian economic crisis provided some intriguing opportunities for private industry. Spacehab Inc. and NPO Energia announced a small commercially financed laboratory that would be launched on a Zenit rocket in 2003. The 'Enterprise' module would contain a windowed 'studio bay' giving crew members views of the Station, arriving vehicles and Earth. Loosely based on the Progress cargo spacecraft, the 'Enterprise' interior was to be divided into two sections - a 64 position equipment bay able to accommodate standardized Station Express racks, Shuttle mid-deck lockers and Spacehab module lockers - and the studio bay.
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ISS Zvezda
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The Zvezda service module of the International Space Station had its origins a quarter century before it was launched. The Mir-2 space station was originally authorized in the February 1976 resolution setting forth plans for development of third generation Soviet space systems. It would undergo many changes over the years, with only one thing remaining constant: the starting point was always the DOS-8 base block space station core module, built as a back-up to the DOS-7 base block used in the Mir station. When the International Space Station was agreed to, the $3-billion DOS-8 became the first Russian segment of the station, originally known as the Service Module.
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