Alan Arnold Griffith
(13 June 1893 – 13 October 1963), son of Victorian science fiction writer
George Griffith, was an English engineer. Among many other contributions he is best known for his work on
stress and fracture in metals that is now known as
metal fatigue, as well as being one of the first to develop a strong theoretical basis for the
jet engine
A jet engine is a type of reaction engine discharging a fast-moving jet of heated gas (usually air) that generates thrust by jet propulsion. While this broad definition can include rocket, Pump-jet, water jet, and hybrid propulsion, the term ...
. Griffith's advanced
axial-flow turbojet engine designs, were integral in the creation of Britain's first operational
axial-flow turbojet engine, the
Metropolitan-Vickers F.2 which first ran successfully in 1941. Griffith however had little direct involvement in actually producing the engine, after he moved in 1939 from leading the engine department at the
Royal Aircraft Establishment
The Royal Aircraft Establishment (RAE) was a British research establishment, known by several different names during its history, that eventually came under the aegis of the Ministry of Defence (United Kingdom), UK Ministry of Defence (MoD), bef ...
to start work at
Rolls-Royce.
Early work
A. A. Griffith took a first in mechanical engineering, followed by a master's degree and a Doctorate from the
University of Liverpool. In 1915 he was accepted by the
Royal Aircraft Factory as a trainee, before joining the Physics and Instrument Department the following year in what was soon be renamed as the Royal Aircraft Establishment (or RAE).
Some of Griffith's earlier works remain in widespread use today. In 1917 he and
G. I. Taylor suggested the use of soap films as a way of studying stress problems. Using this method a soap bubble is stretched out between several strings representing the edges of the object under study, and the coloration of the film shows the patterns of stress. This method, and similar ones, were used well into the 1990s when computer power became generally available that could do the same experiment numerically.
Fracture mechanics
Griffith is more famous for a theoretical study on the nature of stress and failure due to crack propagation in brittle materials such as glass. His crack propagation criterion also applies to elastic materials. At the time it was generally taken that the strength of a material was E/10, where E was the
Young's modulus for that material. However it was well known that those materials would often fail at just a thousandth of this predicted value. Griffith discovered that there were many microscopic cracks in every material, and hypothesized that these cracks lowered the overall strength of the material. This was because any void in a solid, or scratch on the surface, concentrates stress, a fact already well known to machinists at the time. This concentration would allow the stress to reach E/10 at the tip of the crack long before it would seem to for the material as a whole.
From this work Griffith formulated his own theory of
brittle fracture, using elastic
strain energy concepts. His theory described the behaviour of crack propagation of an elliptical nature by considering the energy involved. Griffith described crack propagation in terms of the internal energy of the system in relation to the increase in the crack length described by the equation
where U
e represents the elastic energy of the material, U
s represents the surface area of the crack, W represents the work applied to the sample and dc represents the increase in crack length.
This relation was used to establish
Griffith's criterion
Fracture mechanics is the field of mechanics concerned with the study of the propagation of cracks in materials. It uses methods of analytical solid mechanics to calculate the driving force on a crack and those of experimental solid mechanics ...
, which states that when a crack is able to propagate enough to fracture a material, that the gain in the surface energy is equal to the loss of strain energy, and is considered to be the primary equation to describe brittle fracture. Because the strain energy released is directly proportional to the square of the crack length, it is only when the crack is relatively short that its energy requirement for propagation exceeds the strain energy available to it. Beyond the critical Griffith crack length, the crack becomes dangerous.
The work, published in 1920 ("The phenomenon of rupture and flow in solids"),
resulted in a new awareness in many industries. The "hardening" of materials due to processes such as
cold rolling was no longer mysterious. Aircraft designers were better able to understand why their designs had failed even though they were built much stronger than was thought necessary at the time, and soon turned to polishing their metals to remove cracks. This work was later generalised by
G. R. Irwin
George Rankin Irwin (February 26, 1907 – October 9, 1998) was an American scientist in the field of fracture mechanics and strength of materials. He was internationally known for his study of fracture of materials.
Early life and education ...
and by
R. S. Rivlin and
A. G. Thomas, in the 1950s, applying it to almost all materials, not just brittle ones.
Turbine engines
In 1926 he published a seminal paper, ''An Aerodynamic Theory of Turbine Design''. He demonstrated that the woeful performance of existing turbines was due to a flaw in their design which meant the blades were "flying stalled", and proposed a modern
airfoil
An airfoil (American English) or aerofoil (British English) is the cross-sectional shape of an object whose motion through a gas is capable of generating significant lift, such as a wing, a sail, or the blades of propeller, rotor, or turbine.
...
shape for the blades that would dramatically improve their performance. The paper went on to describe an engine using an
axial compressor
An axial compressor is a gas compressor that can continuously pressurize gases. It is a rotating, airfoil-based compressor in which the gas or working fluid principally flows parallel to the axis of rotation, or axially. This differs from other ...
and two-stage turbine, the first stage driving the compressor, the second a power-take-off shaft that would be used to power a propeller. This early design was a forerunner of the
turboprop engine. As a result of the paper, the
Aeronautical Research Committee supported a small-scale experiment with a single-stage axial compressor and single-stage axial turbine. Work was completed in 1928 with a working tested design, and from this
a series of designs was built to test various concepts.
At about this time
Frank Whittle wrote his thesis on turbine engines, using a
centrifugal compressor and single-stage turbine, the leftover power in the exhaust being used to push the aircraft along. Whittle sent his paper to the
Air Ministry in 1930, who passed it on to Griffith for comment. After pointing out an error in Whittle's calculations, he stated that the large frontal size of the compressor would make it impractical for aircraft use, and that the exhaust itself would provide little thrust. The Air Ministry replied to Whittle saying they were not interested in the design. Whittle was crestfallen, but was convinced by friends in the RAF to pursue the idea anyway. Luckily for all involved, Whittle patented his design in 1930 and was able to start
Power Jets in 1935 to develop it.
Griffith went on to become the principal scientific officer in charge of the new Air Ministry Laboratory in South Kensington. It was here that he invented the ''contraflow'' gas turbine, which used compressor/turbine discs alternately rotating in opposite directions. No stationary stator was required in between each spinning disc. It was difficult to design the blades for the correct amount of swirl and difficult to seal the compressor flow passage from the turbine flow passage. In 1931 he returned to the RAE to take charge of engine research, but it was not until 1938, when he became head of the Engine Department, that work on developing an axial-flow engine actually started.
Hayne Constant joined the Engine Department, which started work on Griffith's original non-contraflow design, working with steam turbine manufacturer
Metropolitan-Vickers (Metrovick).
After a short period Whittle's work at Power Jets started to make major progress and Griffith was forced to re-evaluate his stance on using the jet directly for propulsion. A quick redesign in early 1940 resulted in the
Metrovick F.2
The Metropolitan-Vickers F.2 is an early turbojet engine and the first British design to be based on an axial-flow compressor. It was an extremely advanced design for the era, using a nine-stage axial compressor, annular combustor, and a two- ...
, which ran for the first time later that year. The F.2 was ready for flight tests in 1943 with a thrust of 2,150 lbf, and flew as replacement engines on a
Gloster Meteor, the F.2/40 in November. The smaller engine resulted in a design that looked considerably more like the
Me 262, and had improved performance. Nevertheless, the engine was considered too complex, and not put into production.
Griffith joined
Rolls-Royce in 1939, working there until 1960, when he retired from his post as the company's Chief Scientist. He proposed an arrangement for a simple
turbojet engine, which used an axial compressor and single stage turbine, called the AJ.65 and renamed
Avon
Avon may refer to:
* River Avon (disambiguation), several rivers
Organisations
*Avon Buses, a bus operating company in Wirral, England
*Avon Coachworks, a car body builder established in 1919 at Warwick, England, relaunched in 1922, following ...
, the company's first production axial turbojet. He also proposed various bypass schemes, some too complex mechanically but including one which used 2 compressors in series, the arrangement subsequently used in the
Conway. Griffith carried out pioneering studies into
vertical take-off and landing (VTOL) technology, such as controlling in the hover using air jets. He proposed using batteries of small, simple, lightweight turbojets for lifting the aircraft in a horizontal attitude, a 'flat-riser'. Control in the hover was investigated using the
Rolls-Royce Thrust Measuring Rig but using conventional engines with deflected thrust. A battery of 4 lift engines was used in the
Short SC.1.
Legacy
Griffith is commemorated in the annual
A. A. Griffith Medal and Prize awarded by the
Institute of Materials, Minerals and Mining
The Institute of Materials, Minerals and Mining (IOM3) is a UK engineering institution whose activities encompass the whole materials cycle, from exploration and extraction, through characterisation, processing, forming, finishing and applicatio ...
for contributions to
materials science.
References
External links
Rolls-Royce: Dr Alan GriffithPhotograph of Dr A.A. Griffitha 1960 ''Flight'' news item reporting A.A. Griffith's retirement from Rolls-Royce
{{DEFAULTSORT:Griffith, Alan Arnold
1893 births
1963 deaths
Alumni of the University of Liverpool
English aerospace engineers
Fellows of the Royal Society
Rolls-Royce people
British materials scientists