Barnes Wallis


Sir Barnes Neville Wallis was an English engineer and inventor. He is best known for inventing the bouncing bomb used by the Royal Air Force in Operation Chastise to attack the dams of the Ruhr Valley during World War II.
The raid was the subject of the 1955 film The Dam Busters, in which Wallis was played by Michael Redgrave. Among his other inventions were his version of the geodetic airframe and the earthquake bomb, including designs such as the Tallboy and Grand Slam bombs.

Early life and education

Barnes Wallis was born in Ripley, Derbyshire, to general practitioner Charles George Wallis and his wife Edith Eyre, daughter of Rev. John Ashby. The Wallis family subsequently moved to New Cross, south London, living in "straitened, genteel circumstances" after Charles Wallis was crippled by polio in 1893. He was educated at Christ's Hospital in Horsham and Haberdashers' Aske's Hatcham Boys' Grammar School in southeast London, leaving school at seventeen to start work in January 1905 at Thames Engineering Works at Blackheath, southeast London. He subsequently changed his apprenticeship to J. Samuel White's, the shipbuilders based at Cowes on the Isle of Wight. He originally trained as a marine engineer and in 1922 he took a degree in engineering via the University of London External Programme.

Aircraft and geodetic construction

Wallis left J. Samuel White's in 1913 when an opportunity arose for him as an aircraft designer, at first working on airships and later aeroplanes. He joined Vickers – later part of Vickers-Armstrongs and then part of the British Aircraft Corporation – and worked for them until his retirement in 1971. There he worked on the Admiralty's first rigid airship HMA No. 9r under H. B. Pratt, helping to nurse it though its political stop-go career and protracted development. The first airship of his own design, the R80, incorporated many technical innovations and flew in 1920.
By the time he came to design the R100, the airship for which he is best known, in 1930 he had developed his revolutionary geodetic construction, which he applied to the gasbag framing. He also pioneered, along with John Edwin Temple, the use of light alloy and production engineering in the structural design of the R100. Nevil Shute Norway, later to become a writer under the name of Nevil Shute, was the chief calculator for the project, responsible for calculating the stresses on the frame.
Despite a better-than-expected performance and a successful return flight to Canada in 1930, the R100 was broken up following the crash near Beauvais in northern France of its "sister" ship, the R101. The later destruction of the Hindenburg led to the abandonment of airships as a mode of mass transport.
File:Vickers Wellington Mark X, HE239 'NA-Y', of No. 428 Squadron RCAF.png|thumb|RCAF Wellington bomber, having flown back to England despite a direct anti-aircraft hit, with exposed geodetic airframe construction
By the time of the R101 crash, Wallis had moved to the Vickers aircraft factory at the Brooklands motor circuit and aerodrome between Byfleet and Weybridge in Surrey. The pre-war aircraft designs of Rex Pierson, the Wellesley, the Wellington and the later Warwick and Windsor all employed Wallis's geodetic design in the fuselage and wing structures.
The Wellington had one of the most robust airframes ever developed, and pictures of its skeleton largely shot away, but still sound enough to bring its crew home, are still impressive. The geodetic construction offered a light and strong airframe, with clearly defined space within for fuel tanks, payload and so on. The technique was not easily transferred to other aircraft manufacturers, nor was Vickers able to build other designs in factories tooled for geodetic work.

Bombs

After the outbreak of the Second World War in Europe in 1939, Wallis saw a need for strategic bombing to destroy the enemy's ability to wage war and he wrote a paper titled "A Note on a Method of Attacking the Axis Powers". Referring to the enemy's power supplies, he wrote : "If their destruction or paralysis can be accomplished they offer a means of rendering the enemy utterly incapable of continuing to prosecute the war". As a means to do this, he proposed huge bombs that could concentrate their force and destroy targets which were otherwise unlikely to be affected. Wallis's first super-large bomb design came out at some ten tons, far more than any current bomber could carry. Rather than drop the idea, this led him to suggest a plane that could carry it – the "Victory Bomber".
File:Mohne Dam Breached.jpg|thumb|left|The Möhne Dam, breached by bouncing bombs
Early in 1942, Wallis began experimenting with skipping marbles over water tanks in his garden, leading to his April 1942 paper "Spherical Bomb – Surface Torpedo". The idea was that a bomb could skip over the water surface, avoiding torpedo nets, and sink directly next to a battleship or dam wall as a depth charge, with the surrounding water concentrating the force of the explosion on the target.
A crucial innovation was to spin the bomb. The spin direction determined the number of bounces/range of the bomb. A change to backspin, was put forward by another Vickers designer, George Edwards, based on his knowledge as a cricketer. Spin caused the bomb to trail behind the dropping aircraft, increased the range of the bomb, and also prevented it from moving away from the target wall as it sank. After some initial scepticism, the Air Force accepted Wallis's bouncing bomb for attacks on the Möhne, Eder and Sorpe dams in the Ruhr area.
The raid on these dams in May 1943 was immortalised in Paul Brickhill's 1951 book The Dam Busters and the 1955 film of the same name. The Möhne and Eder dams were breached, causing damage to German factories and disrupting hydro-electric power.
After the success of the bouncing bomb, Wallis was able to return to his huge bombs, producing first the Tallboy and then the Grand Slam deep-penetration earthquake bombs. These were not the same as the "blockbuster" bomb, which was a conventional blast bomb. Although there was still no aircraft capable of lifting these two bombs to their optimal release altitude, they could be dropped from a lower height, entering the earth at supersonic speed and penetrating to a depth of before exploding. They were used on strategic German targets such as V-2 rocket launch sites, the V-3 supergun bunker, submarine pens and other reinforced structures, large civil constructions such as viaducts and bridges, as well as the battleship. They were forerunners of bunker-busting bombs.

Post-war research

Aircraft design

Having been dispersed with the Design Office from Brooklands to the nearby Burhill Golf Club in Hersham, after the Vickers factory was badly bombed in September 1940, Wallis returned to Brooklands in November 1945 as head of the Vickers-Armstrongs Research & Development Department which was based in the former motor circuit's 1907 clubhouse. Here he and his staff worked on many futuristic aerospace projects including supersonic flight and "swing-wing" technology. Following the high death toll of the aircrews involved in the Dambusters raid, he made a conscious effort never again to endanger the lives of his test pilots. His designs were extensively tested in model form, and consequently he became a pioneer in the remote control of aircraft.
A massive Stratosphere Chamber was designed and built beside the clubhouse by 1948. It became the focus for much R&D work under Wallis's direction in the 1950s and 1960s, including research into supersonic aerodynamics that contributed to the design of Concorde, before finally closing by 1980. This unique structure was restored at Brooklands Museum thanks to a grant from the AIM-Biffa fund in 2013 and was officially reopened by Mary Stopes-Roe, Barnes Wallis's daughter, on 13 March 2014.
Although he did not invent the concept, Wallis did much pioneering engineering work to make the swing-wing functional. He developed the wing-controlled aerodyne, a concept for a tailless aeroplane controlled entirely by wing movement with no separate control surfaces. His Wild Goose, designed in the late 1940s, was intended to use laminar flow, and alongside it he also worked on the Green Lizard cruise missile and the Heston JC.9 manned experimental aeroplane. The Swallow was a supersonic development of Wild Goose, designed in the mid-1950s, which could have been developed for either military or civil applications. Both Wild Goose and Swallow were flight tested as large flying scale models, based at Predannack in Cornwall. Despite promising wind tunnel and model work, his designs were not adopted. Government funding for Swallow was cancelled in the round of cuts following the Sandys Defence White Paper in 1957, although Vickers continued model trials with some support from the RAE.
An attempt to gain American funding led Wallis to initiate a joint NASA-Vickers study. NASA found aerodynamic problems with the Swallow and, informed also by their work on the Bell X-5, settled for a conventional tail which would eventually lead in turn to the TFX programme and the General Dynamics F-111. In the UK, Vickers submitted a wing-controlled aerodyne for specification OR.346 for a reconnaissance/strike-fighter-bomber, the TSR-2 specification with added fighter capability. When Maurice Brennan left Vickers for Folland he worked on the FO.147, a variable-sweep development of the Gnat lightweight fighter-trainer, offering both tailed and tailless options. Wallis's ideas were ultimately passed over in the UK in favour of the fixed-wing BAC TSR-2 and Concorde. He was critical of both, believing that swing-wing designs would have been more appropriate. In the mid-1960s, TSR-2 was ignominiously scrapped in favour of the American F-111, which had swing-wings influenced by Wallis's work at NASA, although this order was also subsequently cancelled.