Expendable launch system

A Delta II ELV launching the Dawn spacecraft from CCAFS SLC-17 (left) and a Proton-K rocket launching the Zvezda Service Module for the International Space Station in 2000

An expendable launch system is a launch system that uses an expendable launch vehicle (ELV) to carry a payload into space. The vehicles used in expendable launch systems are designed to be used only once (i.e. they are "expended" during a single flight), and their components are not recovered for re-use after launch. The vehicle typically consists of several rocket stages, discarded one by one as the vehicle gains altitude and speed.

Design rationale

The ELV design differs from that of reusable launch systems, where the vehicle is launched and recovered more than once. Reuse might seem to make systems like the Space Shuttle more cost effective than ELVs, but in practice launches using ELVs have been less expensive than Shuttle launches. (See Space Shuttle Program and Criticism of the Space Shuttle program for discussion of Space Shuttle economics.) Most satellites are currently launched using expendable launchers; they are perceived as having a low risk of mission failure, a short time to launch and a relatively low cost.

History

Many orbital expendable launchers are derivatives of 1950s-era ballistic missiles. As such, the cost was not a major consideration in their design. The largest of these is the Titan IV, the second costliest per flight launch vehicle in history (following the Space Shuttle).

On the other hand, a reusable launcher requires stronger parts and additional parts, thus decreasing payload capacity. The Space Shuttle was a major national asset, used with great and expensive caution. Only five orbiters were built, and the loss of two (Challenger and Columbia) caused great concern and an extended hiatus in Shuttle flights. Expendable launch failures usually caused a much shorter pause, each of which impacted only that model of launcher.

For these reasons the Space Shuttle did not reduce the costs of constructing and launching payloads into orbit and did not replace expendable satellite launchers.

Development

European sponsorship

On March 26, 1980, the European Space Agency and the Centre National d'Etudes Spatiales (CNES) created Arianespace, the world's first commercial space transportation company. Arianespace produces, operates and markets the Ariane launcher family. During 1995 Arianespace lofted its 100th satellite and on 23 September 1997 the Ariane rocket had its 100th launch.^[1] Arianespace's 23 shareholders represent scientific, technical, financial and political entities from 10 different European countries. The major shareholder is the CNES, with 34.68% of capital.^[2]^[3]

American deregulation

From the beginning of the Shuttle program until the Challenger disaster in 1986, it was the policy of the United States that NASA be the public-sector provider of U.S. launch capacity to the world market.^[4] At the start, NASA subsidized satellite launches, intending to eventually price Shuttle service for the commercial market at long-run marginal cost.^[5] On October 30, 1984, United States President Ronald Reagan signed into law the Commercial Space Launch Act.^[6] This enabled an American industry of private operators of expendable launch systems.

On November 5, 1990, United States President George H. W. Bush signed into law the Launch Services Purchase Act] ^[7] The Act, in a complete reversal of the earlier Space Shuttle monopoly, requires NASA to purchase launch services for its primary payloads from commercial providers whenever such services are required in the course of its activities.

Russian privatization

The Russian government sold part of its stake in RSC Energia to private investors in 1994. Energia together with Khrunichev constituted most of the Russian manned space program. In 1997, the Russian government sold off enough of its share to lose the majority position.

American subsidization

In 1996 the United States government selected Lockheed Martin and Boeing to each develop Evolved Expendable Launch Vehicles (EELV) to compete for launch contracts and provide assured access to space. The government's acquisition strategy relied on the strong commercial viability of both vehicles to lower unit costs. This anticipated market demand did not materialize, but both the Delta IV and Atlas V EELVs remain in active service.

Russian renationalization

Beginning in 2013, the Russian government began a renationalization of the Russian space sector. Among the actions taken was the formation of the United Rocket and Space Corporation (Russian: Объединенная ракетно-космическая корпорация) to consolidate a large number of disparate companies and bureaus.^[8]^[9] The efforts have continued into 2014.^[10] On 19 May 2015 State Duma passed a bill on a creation of Roscosmos State Corporation, further consolidating the industry.^[11]

Launch alliances

Since 1995 Khrunichev's Proton rocket is marketed through International Launch Services while the Soyuz rocket is marketed via Starsem. Energia builds the Soyuz rocket and owns part of the Sea Launch project which flies the Ukrainian Zenit rocket.

In 2003 Arianespace joined with Boeing Launch Services and Mitsubishi Heavy Industries to create the Launch Services Alliance. In 2005, continued weak commercial demand for EELV launches drove Lockheed Martin and Boeing to propose a joint venture called the United Launch Alliance to lower costs for the United States government.^[12]

Rocket Height Calculator

          $h=\left({\frac {Mi}{Mr}}\right)^{2}\left({\frac {\mathrm {P} i}{\rho g}}\right)$  
Where      h = height
           Mi = Intial Mass Of Air
           Mr = Mass With Air
           Pi = Pressure Inside Tube

References

↑ Arianespace: milestones Accessed 26 April 2017
↑ Arianespace: shareholders Archived 2014-10-08 at the Wayback Machine.
↑ company-profile (appears to give different shareholdings from those in main text); arianespace.com Accessed 26 April 2017
↑ Setting Space Transportation Policy for the 1990s, Congressional Budget Office, October 1, 1986 Accessed 26 April 2017
↑ Seedhouse, Erik (2012-02-22). Astronauts For Hire: The Emergence of a Commercial Astronaut Corps. Springer Science & Business Media. ISBN 9781461405207.
↑ Statement on signing the Commercial Space Launch Act, October 30, 1984, at reagan.utexas.edu/archives/speeches/1984 Accessed 26 April 2017
↑ Space Frontier Foundation — Advancing Newspace, championing ideas for opening the space frontier to human settlement as rapidly as possible
↑ Messier, Doug (2013-08-30). "Rogozin: Russia to Consolidate Space Sector into Open Joint Stock Company". Parabolic Arc. Retrieved 2014-09-11.
↑ Messier, Doug (2013-10-09). "Rogozin Outlines Plans for Consolidating Russia’s Space Industry". Parabolic Arc. Retrieved 2014-09-11.
↑ Messier, Doug (2014-01-05). "Big Changes Ahead for the Russia Space Program in 2014". Parabolic Arc. Retrieved 2014-09-11.
↑ "Draft Law on setting up public corporation "Roscosmos" unanimously supported by the RF DUMA" (Press release). S.P. Korolev Rocket and Space Corporation Energia. 20 May 2015. Retrieved 19 June 2015.
↑ Boeing, Lockheed Martin to Form Launch Services Joint Venture | SpaceRef - Your Space Reference

External links

Lockheed Martin website
The Boeing Company
Arianespace website
ESA website
Mitsubishi Heavy Industries website (in Japanese)
Mitsubishi Heavy Industries website (in English)

Orbital launch systems
See also: Comparison of orbital launch systems
Current	Angara A5 Antares 230 Ariane 5 Atlas V Delta II IV Electron Epsilon Falcon 9 v1.2 "Full Thrust" GSLV Mk II Mk III H-IIA H-IIB Kuaizhou Long March 2C 2D 2F 3A 3B 3C 4B 4C 5 6 7 11 Minotaur I IV V C Pegasus Proton-M PSLV Rokot Safir Shavit Simorgh Soyuz-FG Soyuz-2 2.1a / STA 2.1b / STB 2-1v SPARK SS-520 Strela Unha Vega Zenit 3SL 3SLB 3F
In development	Angara 1.2 A5P Antares 300 Ariane 6 Cyclone-4M Eris Falcon 9 Block 5 Falcon Heavy H3 ITS KZ-11 KZ-21 Long March 8 9 LauncherOne Mayak Naga-L Naro-2 New Glenn Oril Proton Light Medium RPS SLS Soyuz-5 Sunkar Tronador II ULV Vector-R VLM VLS Alfa VLS Beta Vulcan
Retired	Antares 110/120/130 Ariane 1 2 3 4 ASLV Athena I II Atlas B D E/F G H I II III LV-3B SLV-3 Able Agena Centaur Black Arrow Conestoga Delta A B C D E G J L M N 0100 1000 2000 3000 4000 5000 III Diamant Dnepr Energia Europa Falcon 1 Falcon 9 v1.0 v1.1 Feng Bao 1 GSLV Mk I H-I H-II Juno I Juno II Kaituozhe-1 Kosmos 1 2I 3 3M Lambda 4S Long March 1 2A 2E 3 4A Mu 4S 3C 3H 3S 3SII V N1 N-I N-II Naro-1 Paektusan Pilot Proton UR-500 K R-7 Luna Molniya M L Polyot Soyuz original L M U U2 Soyuz/Vostok Sputnik Voskhod Vostok L K 2 2M R-29 Shtil' Volna Saturn I IB V INT-21 Scout SLV Space Shuttle Sparta Start-1 Thor Able Ablestar Agena Burner Delta DSV-2U Thorad-Agena Titan II GLV IIIA IIIB IIIC IIID IIIE 34D 23G CT-3 IV Tsyklon 2 3 4 Vanguard VLS-1 Zenit 2 2M

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