Engineering:Atlas III

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Short description: American medium expendable launch vehicle
Atlas III
Atlas III Centaur.jpg
The maiden flight of the Atlas III
FunctionMedium expendable launch vehicle
ManufacturerLockheed Martin
Country of originUnited States
Size
Height52.8 m (173 ft)
Diameter3.05 m (10.0 ft)
Mass214,338 kg (472,534 lb)
Stages2
Capacity
Payload to 185 km 28.5° Low Earth orbitIIIA: 8,686 kg (19,149 lb)
IIIB: 10,759 kg (23,720 lb)[1]
Payload to Geostationary transfer orbitIIIA: 4,060 kg (8,950 lb)
IIIB: 4,500 kg (9,900 lb)[1]
Payload to 185 km 90° Polar orbitIIIA: 7,162 kg (15,790 lb)
IIIB: 9,212 kg (20,309 lb)[1]
Associated rockets
FamilyAtlas
Launch history
StatusRetired
Launch sites
  • SLC-36B, Cape Canaveral
  • SLC-3E, VSFB (never used)
Total launches6
(IIIA: 2, IIIB: 4)
Successes6
(IIIA: 2, IIIB: 4) [2]
First flightIIIA: 24 May 2000
IIIB: 21 February 2002
Last flightIIIA: 13 March 2004
IIIB: 3 February 2005
First stage
Engines1 RD-180
Thrust4,148.7 kN (932,700 lbf)
Specific impulse311 s (3.05 km/s)
Burn time132 seconds
FuelRP-1 / LOX
Second stage (Atlas IIIA/IIIB) – Centaur (SEC)
Engines1 RL-10A
Thrust99.2 kN (22,300 lbf)
Specific impulse451 s (4.42 km/s)
Burn time738 seconds
FuelLH2 / LOX
Second stage (Atlas IIIB) – Centaur (DEC)
Engines2 RL-10A
Thrust147 kN (33,000 lbf)
Specific impulse449 s (4.40 km/s)
Burn time392 seconds
FuelLH2 / LOX

The Atlas III (known as the Atlas II-AR (R for Russian) early in development [3]) was an American orbital launch vehicle, used in the years between 2000 and 2005.[4] It was developed from the highly successful Atlas II rocket and shared many components.[1] It was the first member of the Atlas family since the Atlas A to feature a "normal" staging method, compared to the previous Atlas family members, which were equipped with two jettisonable outboard engines on the first (booster) stage (with a single center engine serving as the sustainer). The Atlas III was developed further to create the Atlas V.

Description

The Atlas III was developed from the highly successful Atlas II rocket and consisted of two stages. The first stage was heavily modified from Atlas II and the upper stage remained the Centaur. The Atlas III was produced in two versions. The baseline was the Atlas IIIA, but the Atlas IIIB, featuring a stretched twin-engine version of the Centaur upper stage, was also produced.[2]

First stage

An RD-180 engine undergoes a test firing at NASA's Marshall Space Flight Center in November 1998.

The first stage of Atlas III was derived from that of Atlas II. Its propellant tanks were 3 m (9.8 ft) longer than those on Atlas II, making more propellant available to the engine and increasing the vehicle's performance. Over 183 tons of RP-1 and liquid oxygen propellants were stored inside the tanks. The storied "stage-and-a-half" system used on all Atlas rockets from Atlas B to Atlas II, where three engines are lit on the ground and two of them are dropped away during flight, was replaced by a single Russian RD-180 engine, boasting higher thrust and efficiency than previous engines. Unlike Atlas II and the later Atlas V, there was no option for solid rocket motors to be added to the first stage. 12 retrorockets were mounted on the stage to aid in separating it from Centaur during flight.[1]

The first stage continued to make use of the balloon tank technology of previous Atlas rockets, where the stainless steel tank walls were thin and had to remain pressurized in order to not collapse. The tanks were pressurized with helium gas, which was stored in 13 bottles throughout the stage.[1]

The first stage was unchanged between the Atlas IIIA and IIIB variants.

The Atlas Roll Control Module, which contained several hydrazine thrusters and helped maintain roll stability on Atlas II, was removed on the Atlas III. The dual-chamber RD-180 was therefore responsible for gimballing to control the rocket's pitch, yaw, and roll during first-stage flight.[1]

Centaur second stage

Main page: Engineering:Centaur (rocket stage)

The second stage of Atlas III was the Centaur. It was powered by one or two Pratt & Whitney (later Aerojet Rocketdyne) RL-10 engines, fueled by liquid hydrogen and liquid oxygen. Compared to the Atlas II, the added thrust and efficiency of the first stage of Atlas III allowed for one RL-10 engine to be removed from Centaur, and Atlas III was the first Atlas to offer a single-engine Centaur. The engines of a dual-engine Centaur were mounted directly on the aft propellant tank bulkhead, whereas the engine on a single-engine Centaur was mounted on a specially-made beam connected to those existing dual-engine mounts. The single-engine Centaur featured an RL-10A-4-1 engine with a 51 cm (20 in) extendible nozzle, which increased the engine's thrust by 1.4 kN and specific impulse by 6.5 seconds.[1]

Centaur hosted the vehicle's avionics and flight computers and controlled the entire flight. The RL-10 engine on the single-engine Centaur featured electromechanical gimballing, as opposed to the hydraulic gimballing on other variants.[1]

The tanks of Centaur were balloon tanks like the first stage, made from stainless steel. PVC foam insulation was installed on the outside of the tank walls to help limit propellant boiloff inside the tanks.[1]

Two variants of Centaur flew on Atlas III:

  • Centaur II, which flew on Atlas IIIA, was only offered with one RL-10 engine. This stage is nearly identical to the Centaur II of Atlas II, with the only major difference being only one engine attached.[5]
  • Centaur III, aka Common Centaur, which flew on Atlas IIIB, was available with one or two RL-10 engines. Its tanks were 1.68 m (5 ft 6 in) longer than those of the Centaur II, offering a substantial increase in propellant capacity and increasing the stage's performance.[1] This stage would later fly on the Atlas V.[5]

Flying a mission on an Atlas IIIB with a dual-engine Centaur provided a nearly 400 kg boost in payload capability to geostationary transfer orbit compared to using a single-engine Centaur.[1]

An Extended Mission Kit (EMK) was available for Centaur. This kit included additional helium bottles, radiation shielding on the LOX tank and electronics, and thermal paint to maintain stable temperatures for electronics.[1]

Payload fairing

Two aluminum fairing models (which previously flew on the Atlas II) were available for the Atlas III, both with a 4.2 m (14 ft) diameter:[1][5]

  • Large, with a height of 12.2 m (40 ft) and a mass of 2,087 kg (4,601 lb)
  • Extended, with a height of 13.1 m (43 ft) and a mass of 2,255 kg (4,971 lb)

Fairing selection had a small but noticeable impact on the performance of Atlas III. For example, when going to a 185 km (115 mi) low Earth orbit, flying with the Extended payload fairing would reduce the payload capacity by around 45 kg (99 lb) compared to flying with the Large payload fairing.[1]

Both fairing options were still flown on the Atlas V rocket until 2022.[6] For the Atlas V, these fairings were part of the 400-series of that rocket, and a further extended option ("Extra Extended") was available.[1][7]

Launches

The first flight of the Atlas III occurred on 24 May 2000, launching the Eutelsat W4 communications satellite into a geosynchronous orbit.[8] All Atlas III launches were made from Space Launch Complex 36B at Cape Canaveral Space Force Station (CCSFS), which at that time was called Cape Canaveral Air Force Station (CCAFS). The Atlas III made its sixth and final flight on 3 February 2005, with a classified payload for the United States National Reconnaissance Office.[9][10] Although its career was short, Atlas III performed 6 successful missions with no failures.

Proposed derivatives

The GX rocket, formerly under development by Galaxy Express Corporation, was originally intended to use the boost stage of the Atlas III, provided by Lockheed-Martin, and a newly designed upper stage. It would have launched from the Tanegashima Space Center, south of Kyūshū, Japan. In December 2009, the Japanese government decided to cancel the GX project.[11]

The Atlas III first stage was considered as a Removable Propulsion Module (RPM) for the Starbooster concept. [12]

See also

References

  1. 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 1.13 1.14 1.15 "Atlas Launch System Payload Planner's Guide". Lockheed Martin. http://www-eng.lbl.gov/~lafever/SNAP/OldFiles/MiscFiles/atlas.pdf. 
  2. 2.0 2.1 Space Launch Report: Atlas III Data Sheet accessed September 24, 2014
  3. "Lockheed Martin Selects RD-180 to Power Atlas IIAR". International Launch Services. January 17, 1996. http://www.ilslaunch.com/newsroom/news-releases/lockheed-martin-selects-rd-180-power-atlas-iiar. 
  4. "Atlas IIIA". Encyclopedia Astronautica. http://www.astronautix.com/lvs/atlsiiia.htm. 
  5. 5.0 5.1 5.2 United Launch Alliance. "The Centaur Upper Stage Vehicle". https://www.ulalaunch.com/docs/default-source/upper-stages/the-centaur-upper-stage-vehicle.pdf. 
  6. "last-4m". 10 November 2022. https://www.nasaspaceflight.com/2022/11/jpss-2-launch/. 
  7. United Launch Alliance. "Atlas V". https://www.ulalaunch.com/rockets/atlas-v. 
  8. Gunter D. Krebs. "Atlas-3A (Atlas-IIIA)". Gunter's Space Page. https://space.skyrocket.de/doc_lau_det/atlas-3a.htm. 
  9. Ray, Justin (3 February 2015). "Last Atlas 3 rocket launches a pair of spy satellites". Spaceflight Now. https://spaceflightnow.com/atlas/ac206/. 
  10. Plain, Charlie. "NASA – Out With a Bang!". https://www.nasa.gov/missions/solarsystem/slc_36.html.  This article incorporates text from this source, which is in the public domain.
  11. "Japan scraps GX rocket development project". iStockAnalyst. December 16, 2009. http://www.istockanalyst.com/article/viewiStockNews/articleid/3716870. 
  12. "Starcraft Boosters, Inc. - The StarBooster System - A Cargo Aircraft for Space". October 1999. https://ntrs.nasa.gov/api/citations/19990113117/downloads/19990113117.pdf.