Alexander Lippisch
Alexander Lippisch, with Günther Grönhoff in the cockpit of the Storch V.
Born(1894-11-02)November 2, 1894
DiedFebruary 11, 1976(1976-02-11) (aged 81)
NationalityGerman
OccupationEngineer
Engineering career
ProjectsMesserschmitt Me 163
Significant advancefirst rocket plane
first delta wing to fly
first mass-produced rocket fighter

Alexander Martin Lippisch (November 2, 1894 – February 11, 1976) was a German aeronautical engineer, a pioneer of aerodynamics who made important contributions to the understanding of tailless aircraft, delta wings and the ground effect, and also worked in the U.S. Within the Opel-RAK program, he was the designer of the world's first rocket-powered glider.

He developed and conceptualized delta wing designs which functioned practically in supersonic delta wing fighter aircraft as well as in hang gliders. People he worked with continued the development of the delta wing and supersonic flight concepts over the 20th century. His most famous designs are the Messerschmitt Me 163 rocket-powered interceptor[1]:174 and the Dornier Aerodyne.

Early life

Lippisch was born in Munich, Kingdom of Bavaria. He later recalled that his interest in aviation began with a demonstration conducted by Orville Wright over Tempelhof Field in Berlin in September 1909.[2] Nonetheless, he planned to follow his father's footsteps into art school, until the outbreak of World War I intervened. During his service with the German Army, between 1915 and 1918, Lippisch had the chance to fly being an aerial photographer and mapper.

Early aircraft designs

Following the war, Lippisch worked with the Zeppelin Company, and it was at this time that he first became interested in tailless aircraft. In 1921, his first design to be built, by his friend Gottlob Espenlaub, was the Espenlaub E-2 glider. This was the beginning of a research programme that would result in some fifty designs throughout the 1920s and 1930s. Lippisch's growing reputation saw him appointed in 1925 to director of the Rhön-Rossitten Gesellschaft (RRG), a glider organisation including research groups and construction facilities.

Lippisch also designed conventional gliders at this time, including the Wien of 1927 and its successor the Fafnir of 1930. In 1928, partaking in the Opel-RAK program by Fritz von Opel and Max Valier, Lippisch's tail-first Ente (Duck) was equipped with powder rockets by Friedrich Wilhelm Sander's company and became the first aircraft to fly under rocket power.[3] From 1927, he resumed his tailless work, leading to a series of designs named Storch IStorch IX (Stork I-IX), mostly gliders. These designs attracted little interest from the government and private industry.

Delta wing designs

Experience with the Storch series led Lippisch to concentrate increasingly on delta-winged designs. The Delta I was the world's first[4] tailless delta wing aircraft to fly (in 1931[5][6]). This interest resulted in five aircraft, numbered Delta I – Delta V, which were built between 1931 and 1939.[6] In 1933, RGG had been reorganised into the Deutsche Forschungsanstalt für Segelflug (German Institute for Sailplane Flight, DFS) and the Delta IV and Delta V were designated as the DFS 39 and DFS 40 respectively.

World War II projects

In early 1939, the Reichsluftfahrtsministerium (RLM, Reich Aviation Ministry) transferred Lippisch and his team to work at the Messerschmitt factory in Augsburg, in order to design a high-speed fighter aircraft around the rocket engines[5] then under development by Hellmuth Walter. The team quickly adapted their most recent design, the DFS 194, to rocket power, the first example successfully flying in early 1940. This successfully demonstrated the technology for what would become the Messerschmitt Me 163 Komet.[7]

Although technically novel, the Komet did not prove to be a successful weapon and friction between Lippisch and Messerschmitt was frequent. In 1943, Lippisch transferred to Vienna's Aeronautical Research Institute (Luftfahrtforschungsanstalt Wien, LFW) in Wiener Neustadt, in an own design bureau to concentrate on the problems of high-speed flight.[5] That same year, he was awarded a doctoral degree in engineering by the University of Heidelberg. With him came the mathematician Hermann Behrbohm on half time (and continued half time for Messerschmitt in Oberammergau to where the development activities were moved into the underground facility after the air raids on Augsburg the 25 February 1944).

Wind tunnel research in 1939 had suggested that the delta wing was a good choice for supersonic flight, and Lippisch set to work designing a supersonic, ramjet-powered fighter, the Lippisch P.13a. By the time the war ended, however, the project had only advanced as far as a development glider, the DM-1.

Importance for the delta wing and supersonic flight concepts

Even though the Lippisch P.13a never flew, it and Lippisch's research and development had a significant importance for the development of the delta wing and supersonic flight concepts and supersonic-delta wing-fighter aircraft.

All this later development being funded by governments in the 1950s (like the Swedish Defence Act of 1958) to meet the need to be able to swiftly attack strategic nuclear weapons-bombers such as the Tupolev Tu-16 before they reached their targets. Lippisch's delta wing concept proved to be very steady and efficient in very high speed supersonic flight.

The research of the Messerschmitt and Lippisch offices were continued by:

Postwar work in the United States

Like many German scientists, Lippisch was taken to the United States after the war under Operation Paperclip. He worked at the White Sands Missile Range.

Ground effect aircraft

From 1950 to 1964, Lippisch worked for the Collins Radio Company in Cedar Rapids, Iowa, which had an aeronautical division.[5] It was during this time that his interest shifted toward ground effect craft. The result was an aerofoil boat research seaplane X-112, flown in 1963. However, Lippisch contracted cancer, and resigned from Collins.

When he recovered in 1966, he formed his own research company, Lippisch Research Corporation, and attracted the interest of the West German government. Prototypes for both the aerodyne and the ground-effect craft RFB X-113 (1970) then RFB X-114 (1977) were built, but no further development was undertaken. The Kiekhaefer Mercury company was also interested in his ground-effect craft and successfully tested one of his designs as the Aeroskimmer, but also eventually lost interest.

Aerodyne

Lippisch conceived of a VTOL craft which he called an "aerodyne". Its fuselage comprised a large ducted rotor, and the thrust could be varied between downwards for vertical takeoff and landing, and backwards for forward flight. He worked principally with two companies in its development.

The Collins Aerodyne, developed while he was there, had a horizontal-axis rotor with the efflux directed via large flaps located immediately behind it. The craft was stabilised by a long, high tail running back from above the flaps.

The Dornier Aerodyne was a smaller drone which sat vertically for takeoff and landing, and the whole craft rotated horizontally for forward flight.

Neither type got beyond the prototype stage.

Death and legacy

Lippisch died in Cedar Rapids on February 11, 1976.[5] In 1985, he was inducted into the International Air & Space Hall of Fame at the San Diego Air & Space Museum.[8]

Some Lippisch designs

See also

References

  1. Reitsch, H., 1955, The Sky My Kingdom, London: Biddles Limited, Guildford and King's Lynn, ISBN 1853672629
  2. Wright Flyer over Templehoff Archived 2005-11-26 at the Wayback Machine
  3. Walter J. Boyne The Rocket Men in Air Force Magazine, September 1, 2004, accessed 12 October 2023
  4. Ford, Roger (2000). Germany's secret weapons in World War II (1. publ. ed.). Osceola, WI: MBI Publ. p. 36. ISBN 0-7603-0847-0. Lippisch.
  5. 1 2 3 4 5 F. Marc de Piolenc & George E. Wright Jr. Ducted Fan Design. Vol. 1 (Revised ed.). pp. 129–130. Retrieved 13 February 2011.
  6. 1 2 "New Triangle Plane Is Tailless", December 1931, Popular Science article and photo of Delta I at bottom of page 65
  7. Lippisch, A.; The Delta Wing: History and Development, Iowa State University 1981, page 45: "Let me stress, however that the DFS 194 should in no way be regarded as a predecessor of the Me 163. The Me 163-Delta IVd was derived directly from the Delta-IVc-DFS 39."
  8. Sprekelmeyer, Linda, editor. These We Honor: The International Aerospace Hall of Fame. Donning Co. Publishers, 2006. ISBN 978-1-57864-397-4.
  9. Masters, David (1982). German Jet Genesis (1. publ. ed.). London, UK: Jane's Publishing Company Limited. p. 142. ISBN 0-86720-622-5.
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