Space Shuttle orbiter
ManufacturerRockwell International
Country of originUnited States
OperatorNASA
ApplicationsCrew and cargo spaceplane
Specifications
Spacecraft typeCrewed, reusable
Launch mass110,000 kg (240,000 lb)
Dry mass78,000 kg (172,000 lb)
RegimeLow Earth orbit
Dimensions
Length37.237 m (122.17 ft)
Height17.86 m (58.6 ft)
Wingspan23.79 m (78.1 ft)
Capacity
Payload to Low Earth orbit
Mass24,310 kg (53,590 lb)
Production
StatusRetired
Built6
Launched5 orbiters
135 missions
Lost2 orbiters
Maiden launchSpace Shuttle Columbia
STS-1
(April 12, 1981)
Last launchSpace Shuttle Atlantis
STS-135
(July 8, 2011)
Last retirementSpace Shuttle Atlantis
STS-135
(July 21, 2011)

The Space Shuttle orbiter is the spaceplane component of the Space Shuttle, a partially reusable orbital spacecraft system that was part of the discontinued Space Shuttle program. Operated from 1977 to 2011 by NASA,[1] the U.S. space agency, this vehicle could carry astronauts and payloads into low Earth orbit, perform in-space operations, then re-enter the atmosphere and land as a glider, returning its crew and any on-board payload to the Earth.

Six orbiters were built for flight: Enterprise, Columbia, Challenger, Discovery, Atlantis, and Endeavour. All were built in Palmdale, California, by the Pittsburgh, Pennsylvania-based Rockwell International company. The first orbiter, Enterprise, made its maiden flight in 1977. An unpowered glider, it was carried by a modified Boeing 747 airliner called the Shuttle Carrier Aircraft and released for a series of atmospheric test flights and landings. Enterprise was partially disassembled and retired after completion of critical testing. The remaining orbiters were fully operational spacecraft, and were launched vertically as part of the Space Shuttle stack.

Columbia was the first space-worthy orbiter; it made its inaugural flight in 1981. Challenger, Discovery, and Atlantis followed in 1983, 1984, and 1985 respectively. In 1986, Challenger was destroyed in an accident shortly after its 10th launch, killing all seven crew members. Endeavour was built as Challenger's successor, and was first launched in 1992. In 2003, Columbia was destroyed during re-entry, leaving just three remaining orbiters. Discovery completed its final flight on March 9, 2011, and Endeavour completed its final flight on June 1, 2011. Atlantis completed the final Shuttle flight, STS-135, on July 21, 2011.

In addition to their crews and payloads, the reusable orbiter carried most of the Space Shuttle System's liquid-propellant rocket system, but both the liquid hydrogen fuel and the liquid oxygen oxidizer for its three main rocket engines were fed from an external cryogenic propellant tank. Additionally, two reusable solid rocket boosters (SRBs) provided additional thrust for approximately the first two minutes of launch. The orbiters themselves did carry hypergolic propellants for their Reaction Control System (RCS) thrusters and Orbital Maneuvering System (OMS) engines.

Description

About the size of a McDonnell Douglas DC-9,[2] the Space Shuttle orbiter resembled an airplane in its design, with a standard-looking fuselage and two double delta wings, both swept wings at an angle of 81 degrees at their inner leading edges and 45 degrees at their outer leading edges. The vertical stabilizer of the orbiter had a leading edge that was swept back at a 45-degree angle. There were four elevons mounted at the trailing edges of the delta wings, and the combination rudder and speed brake was attached at the trailing edge of the vertical stabilizer. These, along with a movable body flap located underneath the main engines, controlled the orbiter during later stages of reentry.

Attitude control system

Space Shuttle forward reaction control thrusters

The Reaction Control System (RCS) was composed of 44 small liquid-fueled rocket thrusters and their very sophisticated fly-by-wire flight control system, which utilized computationally intensive digital Kalman filtering. This control system carried out the usual attitude control along the pitch, roll, and yaw axes during all of the flight phases of launching, orbiting, and re-entry. This system also executed any needed orbital maneuvers, including all changes in the orbit's altitude, orbital plane, and eccentricity. These were all operations that required more thrust and impulse than mere attitude control.

The forward rockets of the Reaction Control System, located near the nose of the Space Shuttle orbiter, included 14 primary and two vernier RCS rockets. The aft RCS engines were located in the two Orbital Maneuvering System (OMS) pods at the rear of the orbiter, and these included 12 primary (PRCS) and two vernier (VRCS) engines in each pod. The PRCS system provided the pointing control of the Orbiter, and the VRCS was used for fine maneuvering during the rendezvous, docking, and undocking maneuvers with the International Space Station, or formerly with the Russian Mir space station. The RCS also controlled the attitude of the orbiter during most of its re-entry into the Earth's atmosphere – until the air became dense enough that the rudder, elevons and body flap became effective.[3]

The orbiter's OMS and RCS fuel is monomethyl hydrazine (CH3NHNH2), and the oxidizer is dinitrogen tetroxide (N2O4). This particular propellant combination is extremely reactive and spontaneously ignites on contact (hypergolic) with each other. This chemical reaction (4CH3NHNH2 + 5N2O4 → 9N2 + 4CO2 + 12H2O) occurs within the engine's combustion chamber. The reaction products are then expanded and accelerated in the engine bell to provide thrust. Due to their hypergolic characteristics these two chemicals are easily started and restarted without an ignition source, which makes them ideal for spacecraft maneuvering systems.

During the early design process of the orbiter, the forward RCS thrusters were to be hidden underneath retractable doors, which would open once the orbiter reached space. These were omitted in favor of flush-mounted thrusters for fear that the RCS doors would remain stuck open and endanger the crew and orbiter during re-entry.[4]

Pressurized cabin

Space Shuttle glass cockpit (simulated, composite image)
A window on Endeavour's aft flight deck

The orbiter's flight deck or cockpit originally had 2,214 controls and displays, about three times as many as the Apollo command module.[2] The crew cabin consisted of the flight deck, the mid-deck, and the utility area. The uppermost of these was the flight deck, in which sat the Space Shuttle's commander and pilot, with up to two mission specialists seated behind them. The mid-deck, which was below the flight deck, had three more seats for the rest of the crew members.

The galley, toilet, sleep locations, storage lockers, and the side hatch for entering and exiting the orbiter were also located on the mid-deck, as well as the airlock. The airlock had an additional hatch into the payload bay. This airlock allowed two or three astronauts, wearing their Extravehicular Mobility Unit (EMU) space suits, to depressurize before a walk in space (EVA), and also to repressurize and re-enter the orbiter at the conclusion of the EVA.

The utility area was located under the floor of the mid-deck and contained air and water tanks in addition to the carbon dioxide scrubbing system.

Propulsion

Atlantis's main engines during launch

Three Space Shuttle Main Engines (SSMEs) were mounted on the orbiter's aft fuselage in the pattern of an equilateral triangle. These three liquid-fueled engines could be swiveled 10.5 degrees vertically and 8.5 degrees horizontally during the rocket-powered ascent of the orbiter in order to change the direction of their thrust. Hence, they steered the entire Space Shuttle, as well as providing rocket thrust towards orbit. The aft fuselage also housed three auxiliary power units (APU). The APUs chemically converted hydrazine fuel from a liquid state to a gas state, powering a hydraulic pump which supplied pressure for all of the hydraulic system, including the hydraulic sub-system that pointed the three main liquid-fueled rocket engines, under computerized flight control. The hydraulic pressure generated was also used to control all of the orbiter's flight control surfaces (the elevons, rudder, speed brake, etc.), to deploy the landing gear of the orbiter, and to retract the umbilical hose connection doors located near the rear landing gear, which supplied the orbiter's SSMEs with liquid hydrogen and oxygen from the external tank.

Two Orbital Maneuvering System (OMS) thrusters were mounted in two separate removable pods on the orbiter's aft fuselage, located between the SSMEs and the vertical stabilizer. The OMS engines provided significant thrust for course orbital maneuvers, including insertion, circularization, transfer, rendezvous, deorbit, abort to orbit, and to abort once around.[5] At lift-off, two solid rocket boosters (SRBs) were used to take the vehicle to an altitude of roughly 140,000 feet.[6]

Electrical power

Electric power for the orbiter's subsystems was provided by a set of three hydrogen-oxygen fuel cells which produced 28 volt DC power and was also converted into 115 volt 400 Hz AC three-phase electric power (for systems that used AC power).[7] These provided power to the entire Shuttle stack (including the SRBs and ET) from T-minus 3m30s up through the end of the mission. The hydrogen and oxygen for the fuel cells was kept in pairs of cryogenic storage tanks in the mid-fuselage underneath the payload bay liner, and a variable number of such tank sets could be installed (up to five pairs) depending on the requirements of the mission. The three fuel cells were capable of generating 21 kilowatts of power continuously (or a 15-minute peak of 36 kilowatts) with the orbiter consuming an average of about 14 kilowatts of that power (leaving 7 kilowatts for the payload).

Additionally, the fuel cells provided potable water for the crew during the mission.

Computer systems

The orbiter's computer system consisted of five identical IBM AP-101 avionics computers, which redundantly controlled the vehicle's on-board systems. The specialized HAL/S programming language was used for orbiter systems.[8][9]

Thermal protection

Discovery's ventral thermal protection system

The orbiters were protected by Thermal Protection System (TPS) materials (developed by Rockwell Space Systems) inside and out, from the orbiter's outer surface to the payload bay.[10][11] The TPS protected it from the cold soak of −121 °C (−186 °F) in space to the 1,649 °C (3,000 °F) heat of re-entry. The tile materials comprising much of the orbiter's outermost layer were mostly air held within near-pure silica fibers, which made it efficient at refractory insulation that absorbed and redirected heat back out into the air, and covered in silicon borides and borosilicate glass, with blacker tiles covering the lower surface, and whiter tiles covering the tail, parts of the upper wing and crew cabin surfaces, and the outsides of the payload bay doors. The nose cap, nose landing gear doors, and leading edges were made of reinforced carbon–carbon, which is rayon impregnated with graphite-filled resins and coated in silicon carbide.[12] The upper, white materials that were not in tiles were mostly made of either Nomex felt coated in silicon-rich elastomer or beta cloth, woven silica fibers covered in Teflon. This was especially true in the interior of the payload bay.[13][14][15][11]

Structure

The orbiter's structure was made primarily from aluminium alloy, although the engine thrust structure was made from titanium alloy. The later orbiters (Discovery, Atlantis and Endeavour) substituted graphite epoxy for aluminum in some structural elements in order to reduce weight. The windows were made of aluminum silicate glass and fused silica glass, and comprised an internal pressure pane, a 1.3-inch-thick (33 mm) optical pane, and an external thermal pane.[16] The windows were tinted with the same ink used to make American banknotes.[17]

Landing gear

Atlantis's landing gear are deployed following STS-122.

The Space Shuttle orbiter had three sets of landing gear which emerged downwards through doors in the heat shield. As a weight-saving measure, the gear could not be retracted once deployed. Since any premature extension of the landing gear would very likely have been catastrophic (as it opened through the heat shield layers), the landing gear could only be lowered by manual controls, and not by any automatic system.

Similarly, since the Shuttle landed at high speed and could not abort its landing attempt, the gear had to deploy reliably on the first try every time. The gear were unlocked and deployed by triple redundant hydraulics, with the gear doors actuated by mechanical linkages to the gear strut. If all three hydraulic systems failed to release the landing gear uplocks within one second of the release command, pyrotechnic charges automatically cut the lock hooks and a set of springs deployed the gear.

During landing, the Shuttle nose wheel could be steered with the rudder pedals in the cockpit. During the construction of Space Shuttle Endeavour, an improved nose wheel steering system was developed which allowed easier and more effective nose wheel steering. After Endeavour's roll-out, the system was installed on the other shuttles during their overhauls in the early 1990s.

Lack of navigational lights

The Space Shuttle orbiter did not carry anti-collision lights, navigational lights, or landing lights, because the orbiter always landed in areas that had been specially cleared by both the Federal Aviation Administration (FAA) and the U.S. Air Force. The orbiter always landed at either Edwards Air Force Base, California or at the Kennedy Space Center Shuttle Landing Facility, Florida, except STS-3 at the White Sands Space Harbor in New Mexico. Similar special clearances (no-fly zones) were also in effect at potential emergency landing sites, such as in Spain and in West Africa during all launches.

When an orbiter landing was carried out at night, the runway was always strongly illuminated with light from floodlights and spotlights on the ground, making landing lights on the orbiter unnecessary and also an unneeded spaceflight weight load. A total of 26 landings took place at night, the first being STS-8 in September 1983.[18]

Markings and insignia

The Space Shuttle orbiter ranks second among the world's first spaceplanes, preceded only by the North American X-15 and followed by the Buran, SpaceShipOne, and the Boeing X-37.
Enterprise displaying the orbiter markings.

The typeface used on the Space Shuttle orbiter was Helvetica.[19]

The prototype orbiter Enterprise originally had a flag of the United States on the upper surface of the left wing and the letters "USA" in black on the right wing. The name "Enterprise" in black was painted on the payload bay doors just above the forwardmost hinge and behind the crew module; on the aft end of the payload bay doors was the NASA "worm" logotype in gray. Underneath the rear of the payload bay doors on the side of the fuselage just above the wing was the text "United States" in black with a flag of the United States ahead of it.

The first operational orbiter, Columbia, originally had the same markings as Enterprise, although the letters "USA" on the right wing were slightly larger and spaced farther apart. Columbia also had black tiles which Enterprise lacked on its forward RCS module, around the cockpit windows, and on its vertical stabilizer. Columbia also had distinctive black chines on the forward part of its upper wing surfaces, which none of the other orbiters had.

Gray NASA "worm" logotype used on the orbiters from 1982 to 1998.

Challenger established a modified marking scheme for the shuttle fleet that would be matched by Discovery, Atlantis and Endeavour. The letters "USA" in black above an American flag were displayed on the left wing, with the NASA "worm" logotype in gray centered above the name of the orbiter in black on the right wing. Also, the name of the orbiter was inscribed not on the payload bay doors, but on the forward fuselage just below and behind the cockpit windows. This would make the name visible when the orbiter was photographed in orbit with the doors open. Challenger also had black tiles on the tip of its vertical stabilizer much like Columbia, which the other orbiters lacked.

In 1983, Enterprise had its wing markings changed to match Challenger, and the NASA "worm" logotype on the aft end of the payload bay doors was changed from gray to black. Some black markings were added to the nose, cockpit windows and vertical tail to more closely resemble the flight vehicles, but the name "Enterprise" remained on the payload bay doors as there was never any need to open them. Columbia had its name moved to the forward fuselage to match the other flight vehicles after STS-61-C, during the 1986–1988 hiatus when the shuttle fleet was grounded following the loss of Challenger, but retained its original wing markings until its last overhaul (after STS-93), and its unique black chines for the remainder of its operational life.

NASA "meatball" insignia used on the operational Space Shuttle orbiters after 1998.

Beginning in 1998, the flight vehicles' markings were modified to incorporate the NASA "meatball" insignia. The "worm" logotype, which the agency had phased out, was removed from the payload bay doors and the "meatball" insignia was added aft of the "United States" text on the lower aft fuselage. The "meatball" insignia was also displayed on the left wing, with the American flag above the orbiter's name, left-justified rather than centered, on the right wing. The three surviving flight vehicles, Discovery, Atlantis and Endeavour, still bear these markings as museum displays. Enterprise became the property of the Smithsonian Institution in 1985 and was no longer under NASA's control when these changes were made, hence the prototype orbiter still has its 1983 markings and still has its name on the payload bay doors.

Retirement

With the end of the Shuttle program, plans were made to place the three remaining Space Shuttle orbiters on permanent display. NASA Administrator Charles F. Bolden Jr. announced the disposition location of the orbiters on April 12, 2011, the 50th anniversary of the first human space flight and the 30th anniversary of the first flight of Columbia. Discovery went to the Smithsonian's Steven F. Udvar-Hazy Center, replacing Enterprise which was moved to the Intrepid Sea, Air & Space Museum in New York City. Endeavour went to the California Science Center in Los Angeles arriving on October 14, 2012. Atlantis went to the Kennedy Space Center Visitor Complex on November 2, 2012. Hundreds of other shuttle artifacts will be put on display at various other museums and educational institutions around the U.S.[20]

One of the Crew Compartment Trainer Flight and mid-deck training hardware is on display at the National Museum of the U.S. Air Force,[21] while the other is on display at the JSC.[22] The Full Fuselage Trainer, which includes the payload bay and aft section but no wings, is on display at the Museum of Flight in Seattle, Washington.[23] The Mission Simulation and Training Facility's Shuttle Mission Simulator Fixed Base Simulator originally went to the Adler Planetarium in Chicago, Illinois[24] but was later transferred to the Stafford Air & Space Museum in Weatherford, Oklahoma.[25] The Motion Base Simulator was transferred to the Texas A&M Aerospace Engineering Department in College Station, Texas,[26] and the Guidance and Navigation Simulator went to the Wings of Dreams Aviation Museum in Starke, Florida.[27] NASA also made approximately 7,000 TPS tiles available to schools and universities.[28]

Shuttle Orbiter Specifications (OV-105)

Data from [29]

General characteristics

  • Crew: Eight: Commander, pilot, three mission and three payload specialists
  • Capacity: 2-8 passengers or 25,060 kg (55,250 lb)
  • Length: 122 ft 2.0 in (37.237 m)
  • Wingspan: 78 ft 1 in (23.79 m)
  • Height: 58 ft 7 in (17.86 m)
  • Wing area: 2,690 sq ft (249.9 m2) [30]
  • Empty weight: 171,961 lb (78,000 kg)
  • Max takeoff weight: 242,508 lb (110,000 kg)
  • Payload to LEO: 24,310 kg (53,590 lb)

Performance

  • Maximum speed: 17,320 mph (27,870 km/h, 15,050 kn)
  • Range: 120–600 mi (190–960 km, 100–520 nmi)
  • Service ceiling: 607,000–2,110,000 ft (185,000–643,000 m)
  • Maximum glide ratio: Variable with speed, 1:1 at hypersonic speed - 2:1 at supersonic speed - 4.5:1 at subsonic speed[31]

The cargo bay is 60 ft (18 m) by 15 ft (4.6 m),[32] and could transport 24,400 kg (53,800 lb) to 204 km (127 mi), or 12,500 kg (27,600 lb) to the ISS at 407 km (253 mi).[33] The most massive payload launched by the Space Shuttle was the Chandra X-ray Observatory in 1999 at 50,162 lb (22,753 kg), including its Inertial Upper Stage (IUS) and support equipment.[34] The Shuttle was capable of returning approximately 16,000 kg (35,000 lb) of cargo to Earth.[35]

The orbiter's maximum glide ratio / lift-to-drag ratio varied considerably with speed, ranging from 1:1 at hypersonic speeds, 2:1 at supersonic speeds, and reaching 4.5:1 at subsonic speeds during approach and landing.[31]

Fleet

Shuttle launch profiles. From left to right: Columbia, Challenger, Discovery, Atlantis, and Endeavour.

Individual Space Shuttle orbiters were named in honor of antique sailing ships of the navies of the world (though the test orbiter Enterprise, originally to be named "Constitution", had its name changed after the Star Trek starship, itself named after a series of US Navy ships), and they were also numbered using the NASA Orbiter Vehicle designation system. Three of the names had also been given to Apollo spacecraft between 1969 and 1972: Apollo 11 Command Module Columbia, Apollo 15 Command Module Endeavour, and Apollo 17 Lunar Module Challenger.

While all of the orbiters were externally practically identical, they had minor differences in their interiors. New equipment for the Orbiters was installed in the same order that they underwent maintenance work, and the newer orbiters were constructed by Rockwell International, under NASA supervision, with some more advanced, lighter in weight, structural elements. Thus, the newer orbiters (Discovery, Atlantis and Endeavour) had slightly more cargo capacity than Columbia or Challenger.

The Space Shuttle orbiters were assembled at Rockwell's assembly facility in Palmdale, California,[36] at the federally owned Plant 42 complex.

Orbiter Vehicle Designation

Each NASA Space Shuttle designation was composed of a prefix and suffix separated by a dash. The prefix for operational shuttles is OV, for Orbiter Vehicle. The suffix is composed of two parts: the series and the vehicle number; "0" was used for non-flight ready orbiters, and "1" was used for flight-ready orbiters. The vehicle number is sequentially assigned within the series, beginning with 1. Therefore, there can never be an OV-100 as it would read "Orbiter Vehicle Series 1 Vehicle 0". Many proposals to build a second generation of orbiters, externally compatible with the current system but internally new, refer to them as "OV-200" or "OV-2xx" in order to differentiate them from the "first generation", the OV-100s. This terminology is informal, and it is unlikely that any Shuttle-derived vehicle built will be given such designation. Challenger was originally intended to be used as a Structural Test Article (STA), rather than a flight-capable orbiter; as such, the numbering was changed when it was rebuilt. Enterprise, on the other hand, was intended to be rebuilt into a flight-capable orbiter; it was found to be cheaper to rebuild STA-099 than OV-101, so it remained unflown. The designations were not altered, despite these changes in plans. An "OV-106" designation was given to the set of structural components manufactured to replace those used in the construction of Endeavour; however, the contract for these was canceled shortly afterwards, and they were never completed.[37] The "096" and "097" designators were given to structural test articles that were canceled, but while they exist in some NASA records, the NASA History Office has no official record of STA-096 and STA-097.[38]

Orbiter vehicles Test articles
Designation Vehicle Designation Vehicle
OV-099 [lower-alpha 1] Challenger OV-095 Shuttle Avionics Integration Laboratory (SAIL) mockup
OV-101 Enterprise STA-096 ECLSS Structural Test Article
OV-102 Columbia STA-097 Vibro Acoustic Structural Test Article
OV-103 Discovery OV-098 [lower-alpha 2] Pathfinder
OV-104 Atlantis MPTA-098 Main Propulsion Test Article
OV-105 Endeavour
  1. Formerly known as STA-099.
  2. Retroactive honorary designation

Test article

Test Articles
Picture OVD Name Notes
OV-095 - Shuttle Avionics Integration Laboratory, simulator for actual flight hardware and software system testing and training
OV-098 [lower-alpha 1] Pathfinder Orbiter simulator for moving and handling tests. Currently on display at the U.S. Space & Rocket Center.
MPTA-098 Testbed for propulsion and fuel delivery systems
STA-099 Structural test article used for stress and thermal testing, later became Challenger
OV-101 Enterprise First atmospheric free flight August 12, 1977. Used for approach and landing tests, not suitable for spaceflight. Formerly located at the Steven F. Udvar-Hazy Center, the orbiter is currently located on the flight deck of the USS Intrepid (CV-11) at the Intrepid Sea, Air & Space Museum in New York City.[20]

Operational orbiters

Operational Orbiters
Name Picture OVD First flight Number of flights Last flight Status [39] Ref.
Atlantis
OV-104 STS-51-J
October 3–7, 1985
33 STS-135
July 8–21, 2011
Retired.
Displayed at Kennedy Space Center Visitor Complex in Florida.
[40]
Challenger
OV-099 STS-6
April 4–9, 1983
10 STS-51-L
January 28, 1986
Destroyed.
Disintegrated due to faulty solid rocket booster on January 28, 1986. Debris buried at Cape Canaveral LC-31.
[41]
Columbia
OV-102 STS-1
April 12–14, 1981
28 STS-107
January 16 – February 1, 2003
Destroyed.
Broke up on reentry due to wing damage during launch on February 1, 2003. Remains of orbiter stored at Vehicle Assembly Building.
Discovery
OV-103 STS-41-D
August 30, 1984
39 STS-133
February 24, 2011
Retired.
Displayed at the Steven F. Udvar-Hazy Center in Chantilly, Virginia.
[42]
Endeavour
OV-105 STS-49
May 7, 1992
25 STS-134
May 16, 2011
Retired.
Displayed at California Science Center in Los Angeles, California.
[43]
Enterprise
OV-101 ALT Free Flight#1
August 12, 1977
5 (suborbital) ALT Free Flight #5
October 26, 1977
Retired.
Displayed at Intrepid Sea, Air & Space Museum in New York City.
[44]
  • Challenger was first launched on April 4, 1983. On January 28, 1986, it disintegrated 73 seconds after launch on its 10th mission.
  • Atlantis was first launched on October 3, 1985. It flew 33 spaceflights including the final Space Shuttle mission, STS-135, in July 2011.
  • Endeavour was first launched on May 7, 1992. It flew 25 spaceflights, the final being STS-134, launched May 16, 2011.

Mockups

In addition to the test articles and orbiters produced for use in the Shuttle program, there are also various mockup replicas on display throughout the United States:

Mockups
Name Picture Replicates Location Status
Adventure
Forward Fuselage Space Center Houston Removed
America
Full Six Flags Great America Removed
Inspiration (California)
Most Except Left-Wing, Vertical Stabilizer, and Payload Bay Doors Columbia Memorial Space Center Removed
Independence
Full Space Center Houston On Display
Inspiration (Florida)
Full Shuttle Landing Facility On Display
  • Adventure, a full-scale replica of an orbiter mid-deck and flight deck, also at Space Center Houston.
  • Resolution!, a full-scale replica of an orbiter crew-compartment, originally built to house an amateur flight simulator but later intended for use by Kennedy Space Center firefighters to practice rescue techniques.[47] Now abandoned and nearly destroyed by nature and neglect.[48]

Flight statistics

Key
 Test vehicle
 Lost
Shuttle Designation Flights Flight time Orbits Longest flight First flight Last flight Mir
dockings
ISS dockings Sources
Flight Date Flight Date
Enterprise OV-101 5 00d 00h 19m 0 00d 00h 05m ALT-12 12 August 1977 ALT-16 26 October 1977 [49][50][51][52]
Columbia OV-102 28 300d 17h 47m 15s 4,808 17d 15h 53m 18s STS-1 12 April 1981 STS-107 16 January 2003 0 0 [49][50][53][54][55]
Challenger OV-099 10 62d 07h 56m 15s 995 08d 05h 23m 33s STS-6 4 April 1983 STS-51-L 28 January 1986 0 0 [49][50][56][57]
Discovery OV-103 39 364d 22h 39m 29s 5,830 15d 02h 48m 08s STS-41-D 30 August 1984 STS-133 24 February 2011 1 13 [49][50][58][59]
Atlantis OV-104 33 306d 14h 12m 43s 4,848 13d 20h 12m 44s STS-51-J 3 October 1985 STS-135 8 July 2011 7 12 [49][50][60][61]
Endeavour OV-105 25 296d 03h 34m 02s 4,677 16d 15h 08m 48s STS-49 7 May 1992 STS-134 16 May 2011 1 12 [49][50][62][63]
Total 135 1330d 18h 9m 44s 21,158 9 37

Flight history timeline

See also

Notes

  1. Unofficial honorary designation

References

  1. "Facts About the Space Shuttles". NASA.
  2. 1 2 Stevens, William K.; Times, Special To the New York (April 6, 1981). "New Generation of Astronauts Poised for Shuttle Era". The New York Times. p. A1. ISSN 0362-4331. Retrieved July 14, 2020.
  3. "HSF – The Shuttle". NASA. Archived from the original on February 10, 2001. Retrieved July 17, 2009. Public Domain This article incorporates text from this source, which is in the public domain.
  4. Young, John W.; Hansen, James R. (2012). "Part IV. The Shuttle Era". Forever Young: A Life of Adventure in Air and Space (Kindle eBook). University Press of Florida. ISBN 978-0-8130-4281-7. OCLC 1039310141. In the design plans, we saw that the RCS would have big doors that opened outward. The problem was, if those doors failed to close, the orbiter would be lost as it was coming back through the atmosphere. I wrote a 'review item disposition' (RID) asking NASA to eliminate the outward-opening doors.
  5. "Orbital Maneuvering System". NASA. Retrieved July 17, 2009.
  6. Kulkarni, Nilesh; Krishnakumar, Kalmaje (2005). Spacecraft Guidance, Navigation, and Control Requirements for an Intelligent Plug-n-Play Avionics (PAPA) Architecture. AIAA Infotech@Aerospace. September 26–29, 2005. Arlington, Virginia. doi:10.2514/6.2005-7123. hdl:2060/20060019188. AIAA 2005-7123.
  7. "Electrical Power System". Shuttle Reference Manual. NASA Human Spaceflight. Archived from the original on May 4, 2001. Retrieved February 1, 2013.
  8. "General-Purpose Computers". NASA. Archived from the original on June 8, 2001. Retrieved January 18, 2014.
  9. Lohr, Steve (February 7, 2003). "Loss of the Shuttle: Technology; Computers Driving Shuttle Are to Be Included in Inquiry". The New York Times. Retrieved January 18, 2014.
  10. "Automotive Design & Manufacturing". NASA Tech Briefs. 40 Years of Innovations. 22 (9): 26. September 1998. hdl:2060/20110003618.
  11. 1 2 Oakes, Ryan (June 2, 2003). "Space Shuttle Tiles". UW Departments Web Server. Retrieved March 24, 2023.
  12. Lyle, Karen H.; Fasanella, Edwin L. (2009). "Permanent set of the Space Shuttle Thermal Protection System Reinforced Carbon–Carbon material". Composites Part A: Applied Science and Manufacturing. Elsevier BV. 40 (6–7): 702–708. doi:10.1016/j.compositesa.2009.02.016. ISSN 1359-835X.
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