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Indication, Measurement and Control of Ice Accretion

Published online by Cambridge University Press:  28 July 2016

D. F. Lucking
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Extract

The rate of ice accretion on an aircraft depends upon meteorological factors and aircraft characteristics. There are on the one hand atmospheric pressure and temperature; water content; droplet size; electrostatic conditions. On the other hand, there is the collection efficiency made up of aircraft component design characteristics such as size; shape; material; surface finish. Finally, there are aircraft flight variables such as speed; attitude; skin temperature; vibratory state.

Meteorologists are able to define potential icing intensity if they can forecast the ambient factors mentioned. The intensity may be defined as light, moderate, or severe, or by some such broad adjective, with reference to a hypothetical collector. Similarly, the air-worthiness authority, e.g. the Air Registration Board, must be satisfied that an aircraft can be operated safely in the appropriate meteorological conditions. Therefore the probable association of each meteorological factor with the others needs to be known.

Type
Research Article
Information
The Aeronautical Journal , Volume 55 , Issue 486 , June 1951 , pp. 382 - 385
Copyright
Copyright © Royal Aeronautical Society 1951

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References

1. Bottger, R. Suitability of Disc and Cone for Ice Layer Measuring by Aerodynamic Drag. A.A.F. Translation Report No. F-TS-767-RE. 27th August 1946.Google Scholar
2. Jones, A. R. and Lewis, W. A review of Instruments Developed for the Measurement of the Meteorological Factors Conducive to Aircraft Icing. N.A.C.A. Research Memorandum No. A9C09. 26th April 1949.Google Scholar
3. Beard, M. G. and North, D. Operational Results of Thermal Anti-icing. S.A.E. Preprint for Presentation 9th-13th January 1950.CrossRefGoogle Scholar
4. Orr, J. L., Fraser, D., Lynch, J. A. and Rush, C. K. Electro-thermal Methods of Protecting Aircraft against Ice Formation. National Research Council of Canada. 24th July 1950 (restricted).Google Scholar