Centaur (rocket stage)

Centaur (rocket stage)

Centaur is a rocket stage designed for use as the upper stage of space launch vehicles. Centaur boosts its satellite payload to its final orbit or, in the case of an interplanetary space probe, to escape velocity. Centaur was the world's first high-energy upper stage, burning liquid hydrogen (LH2) and liquid oxygen (LOX).

Centaur, named after the centaurs of Greek mythology, was the brain child of Karel J. "Charlie" Bossart (the man behind the Atlas ICBM) and Dr. Krafft A. Ehriche, both Convair employees. Their design was essentially a smaller version of the Atlas concept, using lightweight stainless steel "balloon tanks" whose structural strength was provided by the pressure of the fuel within.

Centaur uses an ingenious common double-bulkhead to separate the LOX and LH2 tanks. The two stainless steel skins are separated by a 0.25 inch (6.4 mm) layer of fiberglass. The extreme cold of the LH2 on one side creates a vacuum within the fiberglass layer, giving the bulkhead a low thermal conductivity, and thus preventing heat transfer from the relatively warm LOX to the super cold LH2. It is powered by one or two RL-10 rocket engines (SEC and DEC variants respectively).

Development history

Development started in 1956 at NASA's Lewis Research Center, now the Glenn Research Center, but proceeded slowly, with the first (unsuccessful) test flight in May 1962. In the late 1950s and early 1960s Centaur was proposed as a high energy upper stage for the Saturn I, Saturn IB and Saturn V rockets, under the designation S-V ("Saturn V") in accordance with the numbering of other stages of Saturn rockets. However, the first successful Centaur flight did not take place until 1965, by which point NASA had replaced the Centaur with much larger upper stages on their designs.

From 1966 to 1989, the Centaur-D was used as the upper stage for 63 Atlas rocket launches. 55 of these launches were successful. [cite web
last = Krebs
first = Gunter
title = Centaur
work = Gunter's Space Page
url = http://skyrocket.de/space/doc_stage/centaur.htm

From 1974 to 1977, the Centaur-D-1T was used as the third stage on 7 Titan III-E launches, 6 of which were successful. Spacecraft launched by these vehicles included Viking 1, Viking 2, Voyager 1, and Voyager 2. [cite web
last = Wade
first = Mark
title = Titan 3E
work = Encyclopedia Astronautica
url = http://www.astronautix.com/lvs/titan3e.htm

A major change to the Centaur occurred in the early 1980s with the removal of the hydrogen peroxide powered boost pumps and attitude control system from the vehicle. Instead the RL-10 engines were fed directly via tank pressure- resulting in significant reduction in system complexity. A hydrazine monopropellant attitude control system replaced the previous hydrogen peroxide system.

A new version, the Centaur-G, was developed for use with the Space Shuttle but was never used due to tougher safety rules imposed after the "Challenger" accident. This Shuttle/Centaur configuration changed the hydrogen tank diameter to 14 feet while retaining the 10 foot diameter oxygen tank. The geometry was optimized for installation into the Space Shuttle Orbiter payload bay. Its initial mission was to be the Galileo scientific probe to Jupiter. The Centaur systems were dwarfed in their complexity by the supporting fluids, avionic and structural systems which were integrated into the Centaur Integrated Support System or CISS. In addition to more mundane tasks these systems were required to rapidly dump propellants overboard in the event of a Return to Launch Site (RTLS) abort. This was required to permit the orbiter to land safely. These contingency, emergency and abort provisions effectively amplified system complexity to an extreme level and drove the majority of the systems design.

The decision to terminate the Shuttle/Centaur program spurred the US Air Force to create the Titan IV, which used a similar Centaur-T with a 14 foot hydrogen tank diameter as its final stage. This vehicle was capable of launching payloads which had originally been designed for the Shuttle-Centaur combination. In the Titan 401A configuration, a Centaur-T was launched 9 times between 1994 and 1998. In the Titan 401B configuration, a Centaur-T was launched 7 times, with one failure, between 1997 and 2003. The last Titan-Centaur launch was in 2003. [http://www.space.com/missionlaunches/titan4_launch_030909.html] The 14 ft diameter Centaur design has now been effectively retired.

Another major reconfiguration was done for the Atlas III vehicle with a change from dual RL-10 engines as standard to a single RL-10. This change was accomplished while retaining the ability to revert to dual engines should mission requirements dictate. For most missions however a single RL-10 is optimal or adequate and hence a substantial reliability and cost benefit was realized.

A "Common Centaur" was unveiled by LM on November 30 1999. The stretched stage was 38.5 feet (11.68 m) in length, 5.5 feet (1.7 m) longer than the Centaur used on Atlas IIA and IIAS rockets at that time. [cite web | url = http://www.lockheedmartin.com/news/press_releases/1999/LOCKHEEDMARTINBUILDSFIRSTSTRETCHEDC_1.html | title = LOCKHEED MARTIN BUILDS FIRST "STRETCHED" CENTAUR FOR NEXT-GENERATION ATLAS | publisher = LM]

Current status

As of 2006, derivatives of the 10 foot diameter Centaur-3, with either one or two RL-10A4-2 engines, continue to be used as the upper stage of the Atlas V EELV rocket, the successor of the Titan-Centaur configuration.

Although Centaur has a long and successful history in planetary exploration, on June 15, 2007 the engine in the Centaur upper stage of an Atlas V shut down early, leaving its payload -- a pair of National Reconnaissance Office ocean surveillance satellites -- in a lower than intended orbit. [cite web | url = http://www.aviationweek.com/aw/generic/story_channel.jsp?channel=defense&id=news/NRO062207.xml | title = NRO Shortfall May Delay Upcoming ULA Missions | publisher = Aviation Week] The failure was called "A major disappointment", though later statements claim the spacecraft will still be able to complete their missioncite web | author = Craig Covault | title = AF Holds To EELV Schedule | publisher = Aerospace Daily & Defense Report | date = 2007-07-03 | url = http://www.aviationweek.com/aw/generic/story_channel.jsp?channel=space&id=news/eelv070307.xml] . The cause was traced to a stuck-open valve that depleted some of the hydrogen fuel, resulting in the second burn terminating 4 seconds early. The problem was fixed [cite web |url=http://www.space.com/missionlaunches/sfn-071009-atlas5-prelaunch.html |title=Atlas Rocket Team Ready for Wednesday Satellite Launch | author = Justin Ray | publisher=Spaceflight Now] and the next flight was nominal [cite web |url=http://www.space.com/missionlaunches/sfn-071010atlas5-countdown.html |title=Atlas 5 Rocket Orbits Military Communciations Satellite | author = Justin Ray | publisher=Spaceflight Now] .

Future uses

There is a possible use of the Centaur as an upper stage on the new Delta IV Heavy rocket, which started test flights in 2004, and may even be used as a high-energy "kick motor" for planetary probes launched onboard the 125-ton Ares V, which will see its first flight after 2015.fact|date=November 2007.

The Centaur has a planned evolutionary upgrade which changes the tank diameter to 5.4m and increases propellant load from 1.5 to 6.0 times that of the present Atlas V configuration. This diameter matches the existing Contraves-built 5.4m payload fairing, thus eliminating many structural elements and permitting the vehicle to fly from existing launch complexes with minimal modifications. This design reverses the internal common bulkhead and streamlines many systems while permitting many existing systems and components to fly unchanged. Modular design enables multiple engine configurations from one to six RL-10s or up to three advanced next-generation high performance engines. This evolved Centaur can be flown either on existing Atlas boosters ( designated a Phase 1 configuration) or on next generation 5.4m diameter boosters (designated Phase 2).

Performance levels for the Evolved Centaur based Phase 1 vehicles envelope all Atlas V capabilities. In certain circumstances a single Atlas booster vehicle with five solids and with an evolved Centaur upper-stage can replace a three-booster core Atlas HLV. This has obvious reliability and cost benefits. Phase 2 vehicles open the door to a vastly higher performance capability. Up to 80 metric tons can be lifted to low earth orbit on a Phase 2 HLV vehicle — a substantial fraction of a Saturn V or Ares V vehicle. This performance level, mandated only by NASA crewed exploration missions, can be achieved using hardware identical to that used for traditional commercial and USG missions thus allowing development and support costs to be diluted by rate.

Studies have been conducted showing the extensibility of the basic Centaur and Evolved Centaur designs to long duration space flight for exploration purposes and even for use as a Lunar Lander. Complementing these basic performance capabilities is the ability to rate the vehicle for crewed operation. Extensive work has been conducted showing that achieving this "man-rating" is straightforward and does not mandate wholesale design changes to the Centaur vehicle.

Test bed for cryogenic fluid management experiments

Lockheed Martin Space Systems has described the ability to use existing Centaur hardware, with little modification, as a test bed for in-space cryogenic fluid management techniques. [cite web |url=http://gltrs.grc.nasa.gov/cgi-bin/GLTRS/browse.pl?all/CR-2006-214410.html |title=Centaur Test Bed (CTB) for Cryogenic Fluid Management |last=Sakla |first=Steven |coauthors=Kutter, Bernard; Wall, John |date=2006 |publisher=NASA] Most Centaurs launched on Atlas have excess propellants, ranging from hundreds to thousands of pounds, which could be used for “rideshare” experiments flown as secondary payloads conducted after separation of the primary spacecraft.


External links

*Gunter's Space Page - information on [http://skyrocket.de/space/doc_stage/centaur.htm Centaur versions and launch list]
* [http://www.lockheedmartin.com/data/assets/12461.pdf Atlas & Centaur Evolution]
* [http://www.lockheedmartin.com/data/assets/12533.pdf Human Rated Flight]
* [http://www.lockheedmartin.com/data/assets/13350.pdf Lunar Lander Studies]

Wikimedia Foundation. 2010.

Look at other dictionaries:

  • Rocket propellant — is mass that is stored, usually in some form of propellant tank, prior to being used as the propulsive mass that is ejected from a rocket engine in the form of a fluid jet to produce thrust.Chemical rocket propellants are most commonly used,… …   Wikipedia

  • Centaur (étage de fusée) — Centaur (fusée) Pour les articles homonymes, voir Centaur. Etage Centaur est transporté pressurisé pour éviter qu il ne s effondre sur lui même (ici un étage utilisé pour le lancement d …   Wikipédia en Français

  • Centaur (disambiguation) — Centaur may refer to:* Centaur, a mythological creature * Centaur, a 20th century serif typeface based on Renaissance models * Centaur Technology, a CPU design company * Centaur (minor planet), a minor planet orbiting between Jupiter and Neptune… …   Wikipedia

  • Centaur (fusée) — Pour les articles homonymes, voir Centaur. Etage Centaur est transporté pressurisé pour éviter qu il ne s effondre sur lui même (ici un étage utilisé pour le lancement d une sonde Surveyor …   Wikipédia en Français

  • Rocket Engine Test Facility — Infobox nrhp name =Rocket Engine Test Facility nrhp type = nhl caption = 1982 photograph location= Lewis Research Center, Cleveland, Ohio locmapin = Ohio area = built =1957 architect= National Advisory Committee for Aeronautics (NACA)… …   Wikipedia

  • Bipropellant rocket — A bipropellant rocket engine is a rocket engine that uses two propellants (very often liquid propellants) which are kept separately prior to reacting to form a hot gas to be used for propulsion.In contrast, most solid rockets have single solid… …   Wikipedia

  • Saturn (rocket family) — The Saturn family of rockets were developed by a team of mostly German rocket scientists led by Wernher von Braun to launch heavy payloads to Earth orbit and beyond. Originally proposed as a military satellite launcher, they were adopted as the… …   Wikipedia

  • Inertial Upper Stage — The Inertial Upper Stage or IUS is a two stage solid fueled booster rocket developed by NASA and the U.S. Air Force for the launching of large payloads from either a Titan III (later Titan IV) rocket or from the payload bay of the Space… …   Wikipedia

  • Delta (rocket family) — Delta Family The Delta rocket family. Role Expendable launch system with various applications …   Wikipedia

  • Titan (rocket family) — Infobox Aircraft name=Titan family caption=The Titan rocket family. type=Expendable launch system with various applications manufacturer=Glenn L. Martin Company designer= first flight=1958 12 20 [cite web url=http://www.geocities.com/titan 1… …   Wikipedia

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”