Hostname: page-component-848d4c4894-4rdrl Total loading time: 0 Render date: 2024-07-04T02:33:13.719Z Has data issue: false hasContentIssue false
  • English
  • Français

Advantages and Limitations of Models

Published online by Cambridge University Press:  04 July 2016

A. J. Sobey
A. J. Sobey*
Affiliation:
Structures Department, Royal Aircraft Establishment
Get access Rights & Permissions [Opens in a new window]

Summary:

The use of models for structural test investigations in the presence of kinetic heating effects is examined. The principal features of the complex process to be represented are discussed under the classifications external air flow, internal heat transfer, elastic response. Of these the second is found to influence most model design, and an analysis of a typical structure is included to illustrate the various contributions to internal heat transfer.

Type
The Structural Effects of Kinetic Heating
Information
The Aeronautical Journal , Volume 63 , Issue 587 , November 1959 , pp. 646 - 656
Copyright
Copyright © Royal Aeronautical Society 1959

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1.Barzelay, Martin E. and Hollow Ay, George F. (1957). Effect of an Interface on Transient Temperature Distribution in Composite Aircraft Joints. N.A.C.A. T.N. 3824, April 1957.Google Scholar
2.Barzelay, M. E., Tong, N. N. and Hollo, G. (1954). Thermal Conductance of Contacts in Aircraft Joints. N.A.C.A. T.N. 3167, March 1954.Google Scholar
3.Bernard, J. J. (1958). La Resistance Thermique des Joints. A.G.A.R.D. Structures and Materials Panel, Copenhagen, October 1958.Google Scholar
4.Biot, M. A. (1957). New Methods of Heat Flow Analysis with Applications to Flight Structures. Journal of the Aeronautical Sciences 24, 12, pp. 857-73, December 1957.CrossRefGoogle Scholar
5.Bosworth, R. C. L. (1952). Heat Transfer Phenomena. Associated General Publications, Sydney, 1952.Google Scholar
6.Broglio, L. and Santini, P., High Temperature Effects in Aircraft Structures. AGARDograph 28, Chapter 10.Google Scholar
7.Duncan, W. J. (1953). Physical Similarity and Dimensional Analysis. Edward Arnold & Co., 1953.Google Scholar
8.Durelli, A. J., Phillips, E. A. and Tsao, C. H. (1958). Introduction to the Theoretical and Experimental Analysis of Stress and Strain. McGraw-Hill, New York, pp. 278302M, 1958.Google Scholar
9.Fishenden, M. and Saunders, O. A. (1950). An Introduction to Heat Transfer. Oxford University Press, 1950.Google Scholar
10.Green, A. E., Radok, J. R. M. and Rivlin, R. S. (1958). Thermo-elastic Similarity Laws. Quarterly of Applied Mathematics, XV, 4, pp. 381393, 1958.CrossRefGoogle Scholar
11.Heldenfels, R. R. Models and Analogs, AGARDograph 28, Chapter 16.Google Scholar
12.Hemp, W. S. (1956). Fundamental Principles and Theorems in Thermoelasticity. Aeronautical Quarterly, Vol. 7, p. 184, August 1956.Google Scholar
13.Hetenyi, M. (ed.) Handbook of Experimental Stress- Analysis, Appendix II. GOODIER, J. N., Dimensional Analysis, pp. 1035-1045. Also Chapter 16, Analogies, by Mindlin, Raymond D. and Salvadori, Mario G.Google Scholar
14.Hoff, N. J. (1951). Structural Problems of Future Aircraft. Proceedings of the Third Anglo-American Aeronautical Conference, Royal Aeronautical Society, London, 1951. Appendix I by TORDA, P. and HOFF, N. J., pp. 103110.Google Scholar
15.Hoff, N. J. (1956). Comparison of Radiant and Conductive Heat Transfer in a Supersonic Wing. Journal of the Aeronautical Sciences, 23, 7, pp. 694-5, July 1956.Google Scholar
16.Lucks, C. F. and Deem, H. W. (1958). Thermal Properties of Thirteen Metals. American Society of Testing Materials, Philadelphia, 1958.Google Scholar
17.Mcadams, W. H. (1954). Heat Transmission, 3rd Edition. McGraw-Hill, 1954.Google Scholar
18.Madejski, Jan (1957). Rozprawy Insynierskie, LXXVI pp. 487-91, 1957.Google Scholar
19.Meikle, G., Binning, M. S. and Wright, M. E. (1948). The Properties of some Aluminium Alloys at Elevated Temperatures. R.A.E. Tech. Note Met. 96, December 1948.Google Scholar
20.O'Sullivan, William J Jr. (1957). Theory of Aircraft Structural Models subject to Aerodynamic Heating and External Loads. N.A.C.A. T.N. 4115, September 1957.Google Scholar
21.Parkes, E. W. (1953). Transient Thermal Stresses in Wings. Aircraft Engineering, XXV, 298, pp. 373-8, December 1953.Google Scholar
22.Pohle, Frederick V. Heat Transmission in the Structure. AGARDograph 28, Chapter 3.Google Scholar
23.Pohle, F. V. and Oliver, H. (1954). Temperature Distribution and Thermal Stresses in a Model of a Supersonic Wing. Journal of the Aeronautical Sciences, 21, 1, pp. 816, January 1954.Google Scholar
24.Sokolinkoff, I. S. (1956). Mathematical Theory of Elasticity, 2nd Edition. McGraw-Hill, 1956Google Scholar
25.James, Taylor (1958). General Introduction to Thermal Structures. Paper presented to A.G.A.R.D. meeting on 21st October 1958.Google Scholar
26.Taylor, J. (1957). Research Equipment for the Investigation of Aircraft Structures at Elevated Temperatures. Aircraft Engineering, pp. 228232, August 1957.CrossRefGoogle Scholar
27.Walker, P. B. (1955). The Structural Effects of Kinetic Heating in Supersonic Flight. Journal of the Royal Aeronautical Society, Vol. 59, September 1955.Google Scholar
28.Zemansky, Mark W. (1951). Heat and Thermodynamics. McGraw-Hill, 1951.Google Scholar