Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-29T16:03:54.076Z Has data issue: false hasContentIssue false

On The Correlation and Presentation of Information on Turbulent Variable Property Heat Transfer in Tubes

Published online by Cambridge University Press:  04 July 2016

A. J. Ward Smith*
Affiliation:
Technical Department, Royal Aeronautical Society

Extract

This note is concerned with the correlation and presentation of information on heat transfer under conditions of turbulent forced convection for the flow of gases in tubes. Discussion will be confined to the region where thermal entrance effects are absent and, furthermore, it will be assumed that the flow velocity is sufficiently low for compressibility effects to be neglected.

The subject matter will be discussed in general terms only and it is not intended to produce quantitative conclusions, which may, however, be found in reference 11.

Type
Technical Notes
Copyright
Copyright © Royal Aeronautical Society 1962

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.Barnes, J. F. and Jackson, J. D. (1961). Heat Transfer to Air, Carbon Dioxide and Helium Flowing Through Smooth Circular Tubes Under Conditions of Large Surface/Gas Temperature Ratio. Journal of Mechanical Engineering Science, December 1961, p. 303.Google Scholar
2.Wolf, H. (1959). Heating and Cooling Air and Carbon Dioxide in the Thermal Entrance Region of a Circular Duct with Large Gas to Wall Temperature Differences. Transactions of the American Society of Mechanical Engineers, Series C, November 1959, p. 267.Google Scholar
3.Humble, L. V., Lowdermilk, W. H. and Desmon, L. G. (1950). Measurements of Average Heat Transfer and Friction Coefficients for Subsonic Flow of Air in Smooth Tubes at High Surface and Fluid Temperatures. N.A.C.A. Report 1020, 1950.Google Scholar
4.Mccarthy, J. R. and Wolf, H. (1960). Forced Convection Heat Transfer to Gaseous Hydrogen at High Heat Flux and High Pressure in a Smooth, Round, Electrically Heated Tube. American Rocket Society Journal, April 1960, p. 423.Google Scholar
5.Desmon, L. G. and Sams, E. W. (1950). Correlation of Forced Convection Heat Transfer Data for Air Flowing in Smooth Platinum Tube with Long Approach Entrance at High Surface and Inlet Air Temperatures. N.A.C.A. RM E50M23, 1950.Google Scholar
6.Taylor, M. F. and Kirchgessner, T. A. (1959). Measurements of Heat Transfer and Friction Coefficients for Helium Flowing in a Tube at Surface Temperatures up to 5,900°R. N.A.S.A. T.N. D-133, 1959.Google Scholar
7.Fowler, J. M. and Warner, C. F. (1960). Measurements of the Heat Transfer Coefficients for Hydrogen Flowing in a Heated Tube. American Rocket Society Journal, March 1960, p. 266.Google Scholar
8.Deissler, R. G. and Eian, C. S. (1952). Analytical and Experimental Investigation of Fully Developed Turbulent Flow of Air in a Smooth Tube with Variable Fluid Properties. N.A.C.A. T.N. 2629, 1952.Google Scholar
9.Deissler, R. G. and Presler, A. F. (1961). Computed Reference Temperatures for Turbulent Variable-Property Heat Transfer in a Tube for Several Common Gases. International Developments in Heat Transfer, American Society of Mechanical Engineers, 1961-62, p. 579.Google Scholar
10.Bialokoz, J. E. and Saunders, O. A. (1956). Heat Transfer in Pipe Flow at High Speeds. Proceedings of the Institution of Mechanical Engineers, 1956, p. 389.Google Scholar
11. Heat Transfer Under Conditions of Forced Convection for the Flow of Gases in Smooth Straight Ducts of Constant Cross-Section. Royal Aeronautical Society Data Sheet 00.02.05 (To be published).Google Scholar