VTVL

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This article is about rockets. For aircraft capable of vertical takeoff and landing see VTOL.
Pixel is a Quad that took off and landed vertically
DC-XA landing in 1996

Vertical takeoff, vertical landing (VTVL) is a form of takeoff and landing for rockets. Multiple VTVL craft have flown. As of 2016, VTVL is under intense development as a technology for reusable rockets, with two companies, Blue Origin and SpaceX, both having demonstrated recovery of launch vehicles, with Blue Origin's New Shepard booster rocket making the first successful vertical landing following a test flight that reached outer space, and SpaceX's Falcon 9 Flight 20 marking the first landing of a commercial orbital booster.

VTVL rockets are not to be confused with aircraft which take off and land vertically which use the air for support and propulsion, such as helicopters and jump jets which are VTOL aircraft.

History

  • 1961 Bell Rocket Belt, personal VTVL rocket belt demonstrated.[1]
  • VTVL rocket concepts were studied by Philip Bono of Douglas Aircraft Co. in the 1960s.[2]
  • Apollo Lunar Module was a 1960s two-stage VTVL vehicle for landing and taking off from the moon.
  • The Soviet Union did some development work on, but never flew, a vertically-landing manned capsule called Zarya in the late 1980s.[3]
  • The McDonnell Douglas DC-X was an unmanned prototype VTVL launch vehicle that flew several successfully test flights in the 1990s. In June 1996, the vehicle set an altitude record of 3,140 metres (10,300 ft), before making a vertical landing.[4]
  • Between 1998 and 2003 the Japanese Space Agency (JAXA) developed and flew a number of VTVL rocket vehicles in the Reusable Vehicle Testing program
  • Rotary Rocket successfully tested a vertical landing system for their Roton design, based around a rocket tipped helicopter system in 1999, but were unable to raise funds to build a full vehicle.
  • During 2006-2009, Armadillo Aerospace's Scorpius / Super Mod, Masten Space Systems' Xombie and Unreasonable Rocket's Blue Ball flying VTVL rockets competed in the Northrop Grumman / NASA Lunar Lander Challenge. Follow-on VTVL designs including Masten's Xaero and Armadillo's Stig were aimed at higher-speed flight to higher suborbital altitudes.[5]
  • SpaceX announced plans in 2010 to eventually install deployable landing gear on the Dragon spacecraft and use the vehicle's thrusters to perform a land-based landing.[6]
  • In 2010, three VTVL craft were proffered to NASA in response to NASA's suborbital reusable launch vehicle (sRLV) solicitation under NASA's Flight Operations Program: the Blue Origin New Shepard, the Masten Xaero, and the Armadillo Super Mod.[7]
  • Morpheus is a 2010s NASA project developing a vertical test bed that demonstrates new green propellant propulsion systems and autonomous landing and hazard detection technology.[8]
  • Mighty Eagle is a 2010s Robotic Prototype Lander being developed by NASA[9]
  • SpaceX announced in September 2011 that they would attempt to develop powered descent and recovery of both Falcon 9 stages, with a VTVL Dragon capsule as well.[10][11]
The Falcon 9's first stage landing on 22 December 2015 after boosting commercial satellites to low earth orbit

Technology

The technology required to successfully achieve VTVL has several parts. First, thrust must be greater than weight, second the thrust is normally required to be vectored and requires some degree of throttling. Guidance must be capable of calculating the position and attitude of the vehicle, small deviations from the vertical can cause large deviations of the vehicles horizontal position. RCS systems are usually required to keep the vehicle at the correct angle. Landing legs and deployment mechanisms add to the weight of the vehicle compared to expendable vehicles, which can reduce performance. Aerodynamics and mass distribution is also crucial; vehicles generally have to be nose heavy during ascent, but need to be stable during landing- usually on their tail, and after touchdown, where they are susceptible to winds.

It can also be necessary to be able to ignite engines in a variety of conditions potentially including vacuum, hypersonic, supersonic, transonic, and subsonic.[19]

Elon Musk has discussed the potential for substantial reductions in space flight costs as a result of being able to reuse rockets after successful VTVL landings.[20]

Popular culture

Vertical landing rocket depicted in 1951 comic Rocket Ship X

Vertical landing of spaceships was the predominant mode of rocket landing envisioned in the pre-spaceflight era. Many science fiction authors as well as depictions in popular culture showed rockets landing vertically, typically resting after landing on the space vehicle's fins. This view was sufficiently ingrained in popular culture that in 1993, following a successful low-altitude test flight of a prototype rocket, a writer opined: "The DC-X launched vertically, hovered in mid-air ... The spacecraft stopped mid-air again and, as the engines throttled back, began its successful vertical landing. Just like Buck Rogers."[21] In the 2010s, SpaceX rockets have likewise seen the appellation to this popular culture notion of Buck Rogers in a "Quest to Create a 'Buck Rogers' Reusable Rocket."[22][23]

See also

References

  1. American Rocketman Rocket Belt History
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  4. Klerkx, Greg: Lost in Space: The Fall of NASA and the Dream of a New Space Age, page 104. Secker & Warburg, 2004
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  17. "Blue Origin make historic rocket landing." Blue Origin, November 24, 2015. Retrieved: November 24, 2015.
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  20. "Reusable rockets cheaper." ZME Science, August 20, 2015. Retrieved: November 24, 2015.
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External links

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