Boost-glide
Boost-glide trajectories are a class of spacecraft guidance and reentry trajectories that extend the range of suborbital spaceplanes and reentry vehicles by employing aerodynamic lift in the high upper atmosphere. In most examples, boost-glide roughly doubles the range over the purely ballistic trajectory. In others, a series of skips allows range to be further extended, and leads to the alternate term skip-glide.
The concept was first seriously studied as a way to extend the range of ballistic missiles, but has not been used operationally in this form. The underlying aerodynamic concepts have been used to produce maneuverable reentry vehicles, or MARV, to increase the accuracy of some missiles. More recently the traditional form with an extended gliding phase has been considered as a way to reach targets while flying below their radar coverage.
Early concepts
The conceptual basis for the boost-glide concept was first noticed by German artillery officers, who found that their Peenemünder Pfeilgeschosse arrow shells travelled much further when fired from higher altitudes. This was not entirely unexpected due to geometry and thinner air, but when these factors were accounted for they still could not explain the much greater ranges being seen. Investigations at Peenemünde led them to discover that the longer trajectories resulted in the shell having an angle of attack that produced aerodynamic lift. At the time this was considered highly undesirable because it made the trajectory very difficult to calculate, but its possible application for extending range was not lost on the observers.[1]
In June 1939, Kurt Patt of Klaus Riedel's design office at Peenemünde proposed wings for converting rocket speed and altitude into aerodynamic lift and range.[2] He calculated that this would roughly double range of the A-4 rockets from 275 kilometres (171 mi) to about 550 kilometres (340 mi). Early development was considered under the A-9 name, although little work other than wind tunnel studies at the Zeppelin-Staaken company would be carried out during the next few years. Low-level research continued until 1942 when it was cancelled.[3]
The earliest known use of the boost-glide concept for truly long-range use dates to the 1941 Silbervogel proposal by Eugen Sänger for a rocket powered bomber able to attack New York City from bases in Germany and then fly on for landing somewhere in the Pacific Ocean held by the Empire of Japan. The idea would be to use the vehicle's wings to generate lift and pull up into a new ballistic trajectory, exiting the atmosphere again and giving the vehicle time to cool off between the skips.[4] It was later demonstrated that the heating load during the skips was much higher than initially calculated, and would have melted the spacecraft.[5]
In 1943 the A-9 work was dusted off again, this time under the name A-4b. It has been suggested this was either because it was now based on an otherwise unmodified A-4,[3] or because the A-4 program had "national priority" by this time, and placing the development under the A-4 name guaranteed funding.[6] A-4b used swept wings in order to extend the range of the V2 enough to allow attacks on UK cities in The Midlands or to reach London from areas deeper within Germany.[1] The A-9 was originally similar, but later featured long ogive delta shaped wings instead of the more conventional swept ones. This design was adapted as a manned upper stage for the A-9/A-10 intercontinental missile, which would glide from a point over the Atlantic with just enough range to bomb New York before the pilot bailed out.[6][lower-alpha 1]
Post-war development
In the immediate post-war era, Soviet rocket engineer Alexey Isayev found a copy of an updated August 1944 report on the Silbervogel concept. He had the paper translated to Russian, and it eventually came to the attention of Joseph Stalin who was intensely interested in the concept of an antipodal bomber. In 1946, he sent his son Vasily Stalin and scientist Grigori Tokaty, who had also worked on winged rockets before the war, to visit Sänger and Irene Bredt in Paris and attempt to convince them to join a new effort in the Soviet Union. Sänger and Bredt turned down the invitation.[8]
In November 1946 the Soviets formed the NII-1 design bureau under Mstislav Keldysh to develop their own version without Sänger and Bredt.[9] Their early work convinced them to convert from a rocket powered hypersonic skip-glide concept to a ramjet powered supersonic cruise missile, not unlike the Navaho being developed in the United States during the same period. Development continued for a time as the Keldysh bomber, but improvements in conventional ballistic missiles ultimately rendered the project unnecessary.[8][lower-alpha 2]
In the United States the skip-glide concept was advocated by many of the German scientists who moved there, primarily Walter Dornberger and Krafft Ehricke at Bell Aircraft. In 1952 Bell proposed a bomber concept that was essentially a vertical launch version of Silbervogel known as Bomi. This led to a number of follow-on concepts during the 1950s, including Robo, Hywards, Brass Bell, and ultimately the Boeing X-20 Dyna-Soar.[10] Earlier designs were generally bombers, while later models were aimed at reconnaissance or other roles. Dornberger and Ehricke also collaborated on a 1955 Popular Science article pitching the idea for airliner use.[11][12]
The introduction of successful intercontinental ballistic missiles (ICBMs) in the offensive role ended any interest in the skip-glide bomber concepts, as did the reconnaissance satellite for the spyplane roles. The X-20 space fighter saw continued interest through the 1960s, but was ultimately the victim of budget cuts.
Production use
The boost-glide concept relies on the lift generated during the hypersonic flight of reentry. Through the 1960s this concept saw interest not as a way to extend range, which was not longer a concern with modern missiles, but as the basis for maneuverable reentry vehicles for ICBMs. The first known example was the Alpha Draco tests of 1959, followed by the Boost Glide Reentry Vehicle (BGRV) test series, ASSET[13] and PRIME.[14]
This research was eventually put to use in the Pershing II's MARV reentry vehicle. In this case there is no extended gliding phase; the warhead uses lift only for short periods to adjust its trajectory. This is used late in the reentry process, combining data from a Singer Kearfott inertial navigation system with a Goodyear Aerospace active radar.[15] Similar concepts have been developed for most nuclear armed nation's theatre ballistic missiles.
In contrast to these maneuvering warhead concepts, there has been growing interest in the traditional boost-glide concept not to extend range per se, but to allow it to reach a given range while flying at a much lower altitude. The goal in this case is to keep the reentry vehicle below radar coverage until it enters the terminal phase. Such a system is assumed to be used on the Chinese DF-21D anti-ship ballistic missile, which is also believed to maneuver during the terminal phase to make interception more difficult. The later DF-26, a development of the DP-21, may be armed with the WU-14, a hypersonic glide vehcile that has been successfully test six times by the Chinese.[16]
In the early 21st century, boost-glide became the topic of some interest as a possible solution to the Prompt Global Strike (PGS), which seeks a weapon that can hit a target anywhere on the Earth within one hour of launch from the United States. PGS does not define the mode of operation, and current studies include Advanced Hypersonic Weapon boost-glide warhead, Falcon HTV-2 hypersonic aircraft, and submarine launched missiles.[17] According to reports from The Pentagon, the Chinese have started development of a similar weapon known as WU-14 that has undergone test flights, and Russia having earlier run the Kholod and Igla hypersonic test projects, but now carring the test flights of the maneuvering Yu-71 hypersonic warhead.[18]
Notes
- ↑ Yengst's chronology of the A-series weapons differs considerably from most accounts. For instance, he suggests the A-9 and A-10 were two completely separate developments, as opposed to the upper and lower stages of a single ICBM design. He also states that the A-4b was the SLBM development, as opposed to the winged A-4.[7]
- ↑ Navaho met the same fate in 1958, when it was cancelled in favor of the Atlas missile.
References
Citations
- 1 2 Yengst 2010, p. 29.
- ↑ Neufeld 1995, p. 92.
- 1 2 Neufeld 1995, p. 93.
- ↑ Duffy, James (2004). Target: America — Hitler's Plan to Attack the United States. Praeger. p. 124. ISBN 0-275-96684-4.
- ↑ Reuter, Claus (2000). The V2 and the German, Russian and American Rocket Program. German - Canadian Museum of Applied History. p. 99. ISBN 9781894643054.
- 1 2 Yengst 2010, pp. 30-31.
- ↑ Yengst 2010, p. 31.
- 1 2 Westman, Juhani (2006). "Global Bounce". PP.HTV.fi. Retrieved 2008-01-17.
- ↑ Wade, Mark. "Keldysh". Encyclopedia Astronautica.
- ↑ Godwin, Robert (2003). Dyna-Soar: Hypersonic Strategic Weapons System. Apogee Books. p. 42. ISBN 1-896522-95-5.
- ↑ "Rocket Liner Would Skirt Space to Speed Air Travel". Popular Science: 160–161. February 1955.
- ↑ Dornberger, Walter (1956). The Rocket-Propelled Commercial Airliner (Technical report). University of Minnesota Institute of Technology.
- ↑ Wade, Mark. "ASSET". Encyclopedia Astronautica.
- ↑ Jenkins, Dennis; Landis, Tony; Miller, Jay (June 2003). AMERICAN X-VEHICLES An Inventory—X-1 to X-50 (PDF). NASA. p. 30.
- ↑ Wade, Mark. "Pershing". Encyclopedia Astronautica.
- ↑ "Chinese Develop "Kill Weapon" to Destroy US Aircraft Carriers". US Naval Institute. 21 March 2009.
- ↑ Woolf, Amy (6 February 2015). Conventional Prompt Global Strike and Long-Range Ballistic Missiles: Background and Issues (PDF) (Technical report). Congressional Research Service.
- ↑ Gertz, Bill (13 January 2014). "Hypersonic arms race: China tests high-speed missile to beat U.S. defenses". The Washington Free Beacon.
Bibliography
- Neufeld, Michael (1995). The Rocket and the Reich: Peenemünde and the Coming of the Ballistic Missile Era. Simon and Schuster. ISBN 9780029228951.
- Yengst, William (April 2010). Lightning Bolts: First Maneuvering Reentry Vehicles. Tate Publishing. ISBN 9781615665471.