Energia (rocket)

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Energia
Энергия
Energia perspective free render with multiple angles and human (1.76 m) for scale.
FunctionHuman-rated multi-purpose super heavy-lift launch vehicle
ManufacturerNPO "Energia"
Country of originSoviet Union
Size
Height58.765 m (192.80 ft)[1]
Diameter17.65 m (57.9 ft)[1]
Mass2,400,000 kg (5,300,000 lb)
Stages2
Capacity
Payload to LEO
Mass100,000 kg (220,000 lb)[2]
Payload to GSO
Mass20,000 kg (44,000 lb)[2]
Payload to TLI
Mass32,000 kg (71,000 lb)[2]
Launch history
StatusRetired
Launch sitesBaikonur
Total launches2
Success(es)1
Failure(s)1
First flight15 May 1987
Last flight15 November 1988
Boosters – Zenit
No. boosters4
Height39.46 m (129.5 ft)[1]
Diameter3.92 m (12.9 ft)[1]
Powered by1 RD-170
Maximum thrust29,000 kN (6,500,000 lbf) sea level
32,000 kN (7,200,000 lbf) vacuum
Specific impulse309 s (3.03 km/s) at sea level
338 s (3.31 km/s) in vacuum
Burn time156 s
PropellantRP-1/LOX
Core stage
Height58.765 m (192.80 ft)[1]
Diameter7.75 m (25.4 ft)[1]
Powered by4 RD-0120
Maximum thrust5,800 kN (1,300,000 lbf) sea level
7,500 kN (1,700,000 lbf) vacuum
Specific impulse359 s (3.52 km/s) at sea level
454 s (4.45 km/s) in vacuum
Burn time480-500 s
PropellantLH2/LOX

Energia (Russian: Энергия, romanizedEnergiya, lit.'Energy'; GRAU 11K25) was a 1980s super-heavy lift launch vehicle. It was designed by NPO Energia of the Soviet Union as part of the Buran program for a variety of payloads including the Buran spacecraft. Control system main developer enterprise was the Khartron NPO "Electropribor".[3][4] The Energia used four strap-on boosters each powered by a four-chamber RD-170 engine burning kerosene/LOX, and a central core stage with four single-chamber RD-0120 (11D122) engines fueled by liquid hydrogen/LOX.[5]

The launch vehicle had two functionally different operational variants: Energia-Polyus, the initial test configuration, in which the Polyus system was used as a final stage intended to put the payload into orbit, and Energia-Buran,[6] in which the Buran orbiter was the payload and the source of the orbit insertion impulse.

The launch vehicle had the capacity to place about 100 tonnes in Low Earth orbit, up to 20 tonnes to geostationary orbit and up to 32 tonnes by translunar trajectory into lunar orbit.[2]

The launch vehicle made just two flights before being discontinued.[7][6] Since 2016, there have been attempts to revive the launch vehicle, reusing an updated version of its booster engine in the Soyuz-5 rocket.

Development history[edit]

Work on the Energia/Buran system began in 1976 after the decision was made to cancel the unsuccessful N1 rocket. The facilities and infrastructure built for the N1 were reused for Energia (notably the huge horizontal assembly building), just as NASA reused infrastructure designed for the Saturn V in the Space Shuttle program. Energia also replaced the "Vulkan" concept, which was a design based on the Proton and using the same hypergolic propellants, but much larger and more powerful. The "Vulkan" designation was later given to a variation of the Energia which has eight boosters and multiple stages.

The Energia was designed to launch the Soviet "Buran" reusable shuttle,[6] and for that reason was designed to carry its payload mounted on the side of the stack, rather than on the top, as is done with other launch vehicles. Design of the Energia-Buran system assumed that the booster could be used without the Buran orbiter, as a heavy-lift cargo launch vehicle; this configuration was originally given the name "Buran-T".[7] This configuration required the addition of an upper stage to perform the final orbital insertion.[7] The first launch of the Energia was in the configuration of a heavy launch vehicle, with the large Polyus military satellite as a payload, however Polyus failed to correctly perform the orbital insertion.

Due to the termination of the Buran program the Energia program was concluded after only two launches, and further the payload on the first launch did not perform the final boost properly. The legacy of Energia/Buran project manifests itself most visibly in form of the RD-170 family of rocket engines, and the Zenit launcher, with the first stage roughly the same as one of the Energia first-stage boosters.

Launch history[edit]

First launch (Energia–Polyus)[edit]

Polyus satellite on Energia launch vehicle

The Energia was first test-launched on 15 May 1987, with the Polyus spacecraft as the payload. An FGB ("functional cargo block") engine section originally built as a cancelled Mir module was incorporated into the upper stage used to insert the payload into orbit, similarly to Buran and the US Space Shuttle performing the final orbital insertion, since the planned "Buran-T" upper stage had not yet progressed beyond the planning stage.[7] The intended orbit had 280 km (170 mi) altitude and 64.6° inclination.[8]

The Soviets had originally announced that the launch was a successful sub-orbital test of the new Energia booster with a dummy payload, but some time later it was revealed that in fact the flight had been intended to bring the Polyus into orbit. The two stages of the Energia launcher functioned as designed, but due to a software error in its attitude control system, Polyus's orbital insertion motor failed to inject the payload into orbit. Instead, the Polyus reentered the atmosphere over the Pacific Ocean.[9]

Second launch (Energia–Buran)[edit]

Buran shuttle on Energia launch vehicle

The second flight, and the first one where payload successfully reached orbit, was launched on 15 November 1988. This mission launched the uncrewed Soviet Shuttle vehicle Buran. At apogee, the Buran spacecraft made a 66.7 m/s burn to reach a final orbit of 251 km × 263 km.[6][10]

Energia Flights
Flight number
(COSPAR ID)
Date (UTC) Launch site Serial no. Payload Orbit at payload separation Remarks
1 15 May 1987
17:30:00
Baikonur Cosmodrome Site 250 6SL[11] Polyus −15 × 155 km × 64.61°[12] Spacecraft software error led to orbit insertion burn performed in incorrect attitude and payload re-entered atmosphere without entering orbit.[13]
2
(1988‑100A)
15 November 1988
03:00:01
Baikonur Cosmodrome Site 110/37 1L[11] Buran −11.2 × 154.2 km × 51.64°[14]
After burn: 251 x 263 km[10]
First and only flight of Buran. The spacecraft orbited Earth twice before de-orbiting and landed at Baikonur at 06:24 UTC.

Discontinuation and potential revival[edit]

Production of Energia rockets ended with the end of the Buran shuttle project in the late 1980s, and more certainly, with the fall of the Soviet Union in 1991. Since that time, there have been persistent[citation needed] rumors of the renewal of production, but given the political realities, that is highly unlikely. While the Energia is no longer in production, the Zenit boosters were in use until 2017. The four strap-on liquid-fuel boosters, which burned kerosene and liquid oxygen, were the basis of the Zenit rocket which used the same engines. The engine is the four combustion chamber RD-170. Its derivative, the RD-171, was used on the Zenit rocket. A half-sized derivative of the engine, the two-chamber RD-180, powers Lockheed Martin's Atlas V rocket, while the single-chamber derivative, the RD-191, has been used to launch the Korean Naro-1 (as a reduced-thrust variant named the RD-151) and the Russian Angara rocket. The RD-181, based on the RD-191, is used on the Antares rocket.[15]

In August 2016, Roscosmos announced conceptual plans to develop a super heavy-lift launch vehicle from existing Energia components[clarification needed] instead of pushing the less-powerful Angara A5V project.[16] This would allow Russia to launch missions towards establishing a permanent Moon base with simpler logistics, launching just one or two 80–160-ton super-heavy rockets instead of four 40-ton Angara A5Vs implying quick-sequence launches and multiple in-orbit rendezvous.[17] Tests of RD-171MV engine, an updated version of the engine used in Energia, were completed in September 2021 and may potentially be used in the successor Soyuz-5 rocket.[18]

Proposed variants[edit]

Three major design variants were conceptualized after the original configuration, each with vastly different payloads.

Energia-M[edit]

The Energia-M was an early-1990s design configuration and the smallest of the three. The number of boosters was reduced from four to two, the core stage was shortened and fitted with just one RD-0120 engine. It was designed to replace the Proton rocket, but lost a 1993 competition to the Angara rocket.[19][20]

A non-functional prototype ("structural test vehicle") of the Energia M still exists in the Dynamic Test Stand facility at Baikonur Cosmodrome.[21]

Energia-2 (GK-175)[edit]

Energia-2 was an evolution of the Energia studied in the 1980s. Unlike the Energia-Buran, which was planned to be semi-reusable (like the U.S. Space Shuttle), the GK-175 concept was to have allowed the recovery and reuse of all elements of the vehicle, similarly to the original, fully reusable Orbiter/Booster concept of the U.S. Shuttle.[22][23] The Energia-2 core as proposed would be capable of re-entering and gliding to a landing.[22]

Vulkan[edit]

The final never-built design concept was also the largest. With eight Zenit booster rockets and an Energia-M core as the upper stage, the Vulkan (which shared the name with another Soviet heavy lift rocket that was cancelled years earlier) configuration was initially projected to launch up to 200 metric tonnes into 200 km orbit with inclination 50.7°.[24]

The development of the Vulkan and the refurbishment of Universal Test Stand and Launch Pad at site 250 for its launches was in progress between 1990–1993 and abandoned soon after due to a lack of funds and the collapse of the Soviet Union.[25]

See also[edit]

References[edit]

  1. ^ a b c d e f Energia Characteristics
  2. ^ a b c d Launch vehicle "Energia" Official Site
  3. ^ Krivonosov, Khartron: Computers for rocket guidance systems
  4. ^ Control systems for intercontinental ballistic missiles and launch vehicles Archived 2010-02-05 at the Wayback Machine
  5. ^ Russian Space Web, Energia page. Accessed 21 September 2010
  6. ^ a b c d Bart Hendrickx; Bert Vis (2007). Energiya-Buran: The Soviet Space Shuttle. Springer Science & Business Media. ISBN 978-0-387-73984-7.
  7. ^ a b c d B. Hendrickx, "The Origins and Evolution of the Energiya Rocket Family," J. British Interplanetary Soc., Vol. 55, pp. 242-278 (2002).
  8. ^ Vassili Petrovitch, Polyus (accessed 21 September 2010).
  9. ^ "Polyus". Astronautix. Archived from the original on August 20, 2016. Retrieved September 25, 2017.
  10. ^ a b Mark Wade, Encyclopedia Astronautics, Buran. (accessed 21 September 2010).
  11. ^ a b Lukashevich, Vadim. "Manufacturing History of the Energia Launch Vehicle". buran.ru (in Russian). Retrieved 25 January 2018.
  12. ^ Lukashevich, Vadim. "The Polyus Spacecraft". buran.ru (in Russian). Retrieved 25 January 2018.
  13. ^ Day, Dwayne A.; Kennedy, Robert G. III (January 2010). "Soviet Star Wars: The launch that saved the world from orbiting laser battle stations". Air & Space/Smithsonian. Retrieved 25 January 2018.
  14. ^ Lukashevich, Vadim. "Timeline of the flight of Buran on 15 November 1988". buran.ru (in Russian). Retrieved 25 January 2018.
  15. ^ "First Angara rocket launched on suborbital test flight". Spaceflight Now. July 9, 2014. Retrieved July 9, 2014.
  16. ^ "Роскосмос" создаст новую сверхтяжелую ракету. Izvestia (in Russian). August 22, 2016.
  17. ^ Zak, Anatoly (24 July 2018). "Russia's New Rocket Project Might Resurrect a Soviet-Era Colossus". Popular Mechanics. Hearst Digital Media. Retrieved 24 October 2019.
  18. ^ Berger, Eric (9 October 2021). "Rocket Report: Next Falcon Heavy launch date set, Soyuz 5 engines clear tests". Ars Technica.
  19. ^ "This Immense Russian Rocket Was Abandoned For Decades". Popular Mechanics. 2015-07-06. Retrieved 2017-05-28.
  20. ^ "Origin of the Angara project". www.russianspaceweb.com. Retrieved 2021-07-15.
  21. ^ Wenz, John (2015-07-06). "This Immense Russian Rocket Was Abandoned For Decades". Popular Mechanics. Retrieved 2021-03-24.
  22. ^ a b "Б.И.Губанов. Триумф и трагедия «Энергии» глава 41".
  23. ^ "The Space Shuttle - NASA Technical Reports Server (NTRS)" (PDF). nasa.gov. 2011. Archived from the original (PDF) on 5 April 2015.
  24. ^ Gubanov, Boris (1998). "38. Перспективный ряд ракет-носителей" [38. Perspective launch vehicles]. Триум и трагедия "Энергии" [Energia Triumph and Tragedy] (in Russian). Nizhny Novgorod: NIER.
  25. ^ Godwin, Robert (2006). Russian Spacecraft. Space Pocket Reference Guides. Apogee Books. p. 59. ISBN 1-894959-39-6.

External links[edit]