E ■ CONVECTIVE HEAT TRANSFER AND FRICTION 



in smooth tubes at high Prandtl and Schmidt numbers. NACA Tech. Rept. 1210, 

 1955. (Supersedes NACA Tech. Note 3145, 1954.) 



16. Prandtl, L. Bericht iiber Untersuchungen zur ausgebildeten Turbudenz. Z. 

 angew. Math. u. Mech. 5, 136 (1925). 



17. Taylor, G. I. The transport of vorticity and heat through fluids in turbulent 

 motion. Proc. Roy. Soc. London A 135, 1932. 



18. von Karmdn, Th. Turbulence and skin friction. J. Aeronaut. Set. 1, 1-20 (1934). 



19. Goldstein, S. Modern Developments in Fluid Dynamics, Vol. II. Clarendon Press, 

 Oxford, 1938. 



20. Laufer, J. The structure of turbulence in fully developed pipe flow. NACA Tech. 

 Note 2954, 1953. 



21. Lin, C. C, and Shen, S. F. Studies of von Karmsin's similarity theory and its 

 extension to compressible flows. A critical examination of similarity theory for 

 incompressible flows. NACA Tech. Note 25^1, 1951. 



22. Deissler, R. G. Analytical and experimental investigation of adiabatic turbulent 

 flow in smooth tubes. NACA Tech. Note 2138, 1950. 



23. van Driest, E. R. On turbulent flow near a wall. Preprints of Papers for 1955 

 Heat Transfer and Fluid Mech. Inst., Stanford Press, 1955. 



24. Einstein, H. A., and Li, H. Shear transmission from a turbulent flow to its 

 viscous boundary sub-layer. Reprints of Papers for 1955 Heat Transfer and Fluid 

 Mech. Inst., Stanford Press, 1955. 



25. Cavers, S. D., Hsu, N. Y., Schlinger, W. G., and Sage, B. H. Temperature 

 gradients in turbulent gas streams. Behavior near boundary in two-dimensional 

 flow. Ind. Eng. Chem. 45, 2139-2145 (1953). 



26. Seban, R. A., and Shimazki, T. T. Temperature distributions for air flowing 

 turbulently in a smooth heated pipe. Proc. General Discussion on Heat Transfer, 

 Inst. Mech. Engrs., London, Sept. 1951. 



27. Isakoff, S. E., and Drew, T. B. Heat and momentum transfer in turbulent flow 

 of mercury. Proc. General Discussion on Heat Transfer, Inst. Mech. Engrs., London, 

 1951. 



28. Deissler, R. G. Analysis of fully developed turbulent heat transfer at low Peclet 

 numbers in smooth tubes with application to liquid metals. NACA Research Mem. 

 E52F05, 1952. 



29. Bernardo, E., and Eian, C. S. Heat transfer tests of aqueous ethylene glycol 

 solutions in an electrically heated tube. NACA Wartime Rept. El 36, 1945. 



30. Kaufman, S. J., and Isely, F. D. Preliminary investigation of heat transfer to 

 water flowing in an electrically heated inconel tube. NACA Research Mem. 

 E50G31, 1950. 



31. Eagle, A. E., and Ferguson, R. M. On the coefficient of heat transfer from the 

 internal surface of tube walls. Proc. Roy. Soc. London A 127, 540-566 (1930). 



32. Kreith, F., and Summerfield, M. Pressure drop and convective heat transfer with 

 surface boiling at high heat flux; Data for aniline and n-butyl alcohol. Trans. Ain. 

 Soc. Mech. Engrs. 72, 869-879 (1950). 



33. Grele, M. D., and Gedeon, L. Forced convection heat transfer characteristics 

 of molten sodium hydroxide. NACA Research Mem. E52L09, 1953. 



34. Hoffman, H. W. Turbulent forced convection heat transfer in circular tubes 

 containing molten sodium hydroxide. Oak Ridge Natl. Lab. Rept. 1370, 1952. 



35. Barnet, W. I., and Kobe, K. A. Heat and vapor transfer in a wetted-wall tower. 

 Ind. Eng. Chem. 33, 436-442 (1941). 



36. Chilton, T. H., and Colburn, A. P. Mass transfer (absorption) coefficients. Ind. 

 Eng. Chem. 26, 1183-1187 (1934). 



37. Jackson, M. L., and Ceaglske, N. H. Distillation, vaporization, and gas absorp- 

 tion in a wetted-wall column. Ind. Eng. Chem. 42, 1188-1198 (1950). 



38. Bonilla, C. F. Mass transfer in liquid metal and fused salt systems. U.S. Atomic 

 Energy Comm. Tech. Information Service, First Quarterly Progress Rept. NY 0-3086, 

 Oak Ridge, Sept. 1951. 



39. Linton, W. H., Jr., and Sherwood, T. K. Mass transfer from solid shapes to 

 water in streamline and turbulent flow. Chem. Eng. Progr. 46, 258-264 (1950). 



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