Sir Frank Whittle passed away on August 8, 1996, at the age of 89, in Maryland. His work in developing the turbojet can truly be said to represent one of the greatest mechanical engineering achievements in the last 70 years. The development of the turbojet demanded that Whittle face almost insurmountable technical and institutional challenges. The technical challenges included developing centrifugal compressor pressure ratios of 4:1 from the prevailing technology level of 2.5:1, increasing compressor efficiencies from 65 to 80 percent while designing for combustion intensities that were 10 times the prevailing state of the art in boiler technology. He was also responsible for utilizing a vortex turbine design approach. The institutional challenges that he faced included changing a paradigm on aircraft propulsion technology and nurturing Power Jets Ltd. to produce excellent engine designs with minimal resources in terms of money, technical manpower, and governmental support. It is the object of this paper to document the epic long-drawn-out struggle fought by Sir Frank against entrenched technical opinion, which ultimately resulted in the turbojet revolution. The technical aspects of his pioneering work with emphasis on the problems he encountered will also be discussed.

1.
Boyne, W., and Lopez, D., eds., 1979, The Jet Age: 40 Years of Jet Aviation, Smithsonian Institute, Washington.
2.
Constant, E. W., II, 1980, The Origins of the Turbojet Revolution, John Hopkins Univ. Press.
3.
Constant, H., 1948, Gas Turbines and Their Problems, Todd Publishing Group, UK.
4.
Ford, D., 1992, “Gentlemen, I Give You the Whittle Engine,” Air and Space, Oct./Nov.
5.
Golley, J., 1987, Whittle—The True Story, Smithsonian Institution Press, Washington DC.
6.
Gunston, B., 1995, The Development of Jet and Turbine Aero Engines, Patrick Stephens, Ltd., UK, 1995.
7.
Gunston, B., 1995, World Encyclopedia of Aero Engines, Patrick Stephens, Ltd., UK, 1995.
8.
Hooker, Sir Stanley, 1984, Not Much of an Engineer, Airlife Publishing.
9.
Jones, G., 1989, The Birth of Jet Powered Flight, Methuen, London.
10.
Meher-Homji
C. B.
,
1997
, “
The Development of the Junkers Jumo 004B—the World’s First Production Turbojet
,”
ASME JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER
, Vol.
119
, pp.
783
789
.
11.
Neville, L. E., and Silsbee, N. F., 1984, Jet Propulsion Progress, McGraw-Hill.
12.
Schlaifer, R., 1950, Development of Aircraft Engines, Graduate School of Business Administration, Harvard University, Boston.
13.
Scott, P., 1995, “Birth of the Jet Engine,” Mechanical Engineering, Jan., pp. 66–71.
14.
Shacklady, E., 1962, The Gloster Meteor, Macdonald and Co., London.
15.
Singh, R., 1996, “Fifty Years of Civil Aero Gas Turbines,” Fiftieth Anniversary Lecture, Cranfield University, U. K., June 5.
16.
Von Ohain, H., 1979, “The Evolution and Future of Aeropropulsion Systems,” 40 Years of Jet Engine Progress, Boyne, W. J., and Lopez, D. S., eds., National Air and Space Museum, Smithsonian, Washington.
17.
Vosey, R. G., 1945, “Some Vibration Problems in Gas Turbine Engines,” Proc. Institution of Engineers, Vol. 153, 1945—Lectures on the Development of the Internal Combustion Turbine.
18.
Whittle, Sir Frank, 1954, Jet—The Story of a Pioneer, Philosophical Library, Inc. 1954.
19.
Whittle, F., 1945, “The Early History of the Whittle Jet Propulsion Gas Turbine,” First James Clayton Lecture of the Institution of Mechanical Engineers, UK, Oct. 5.
20.
Whittle, Sir Frank, 1979, “The Birth of the Jet Engine in Britain,” in: The Jet Age: 40 Years of Jet Aviation, Smithsonian Institute, Washington, Boyne, W., and Lopez, D., eds.
21.
Whittle, Sir Frank, 1981, Gas Turbine Aerothermodynamics, Pergamon Press.
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