E,12 • CITED REFERENCES AND BIBLIOGRAPHY 



doubtful that general rules for the prediction of boiling heat transfer can 

 be formulated. If, on the other hand, the nuclei distribution is found to 

 be predictable, a correlation for boiling heat transfer can probably be 

 developed. Some encouragement for this latter view may be taken from 

 the fact that results obtained with distilled water by different investi- 

 gators and at different times have yielded essentially identical results. 

 Further hope may be derived from the result that the effective nucleus 

 size found in distilled carbon tetrachloride was about the same as that 

 found in distilled water under similar conditions. In any case, further 

 investigations on the problem of nucleation are beheved to be necessary 

 for a satisfactory solution of the problem.'^ 



E,12. Cited References and Bibliography. 



Cited References 



1. Howarth, L. Modern Developments in Fluid Dynamics. High Speed Flow, Vol. 1. 

 Oxford Univ. Press, 1953. 



2. Boussinesq, J. Essai sur la th^orie des eaux courantes. M^moires prisent^s par 

 divers savants a Vacad^mie des sciences 23, Paris, 1877. 



3. Reichardt, H. The principles of turbulent heat transfer. Archiv. Ges. Wdrmetech. 

 617, 129-142 (1951). 



4. Reynolds, O. On the Extent and Action of the Heating Surface of Steam Boilers. 

 Scientific Papers, Vol. 1. Cambridge Univ. Press, 1901. 



5. Eckert, E. R. G. Introduction to the Transfer of Heat and Mass, 1st ed. McGraw- 

 Hill, 1950. 



6. von Kdrm^n, Th. The analogy between fluid friction and heat transfer. Trans. 

 Am. Soc. Mech. Engrs. 61, 705-710 (1939). 



7. Murphree, E. V. Relation between heat transfer and fluid friction. Ind. Eng. 

 Chem. 24, 726-736 (1932). 



8. Boelter, L. M. K., MartineUi, R. C, and Jonassen, F. Trans. Am. Soc. Mech. 

 Engrs. 63, 447-455 (1941). 



9. MartineUi, R. C. Heat transfer to molten metals. Trans. Am. Soc. Mech. Engrs. 

 69, 947-959 (1947). 



10. Seban, R. A., and Shemazaki, T. T. Heat transfer to a fluid flowing turbulently 

 in a smooth pipe with walls at constant temperature. Am. Soc. Mech. Engrs. 

 Paper 50-A-128, 1950. 



11. Rannie, W. D. Heat Transfer in Turbulent Stream Flow. Ph.D. Thesis, Calif. 

 Inst. Technol., 1951. 



See also: Summerfield, M. Recent developments in convective heat transfer. 

 Heat Transfer Symposium, Univ. Mich. Eng. Research Inst. 164-169 (1953). 



12. Lin, C. S., Moulton, R. W., and Putnam, G. L. Mass transfer between solid walls 

 and fluid streams. Ind. Eng. Chem. 45, 636-640 (1953). 



13. Deissler, R. G. Investigation of turbulent flow and heat transfer in smooth 

 tubes, including the effects of variable fluid properties. Trans. Am. Soc. Mech. 

 Engrs. 73, 101-107 (1951). 



14. Deissler, R. G. Heat transfer and fluid friction for fully developed turbulent 

 flow of air and supercritical water with variable fluid properties. Trans. Am. Soc. 

 Mech. Engrs. 76, 73-86 (1954). 



15. Deissler, R. G. Analysis of turbulent heat transfer, mass transfer and friction 



^ The preceding chapter was revised in June, 1955. Several important advances 

 have been made since that time. A very few references are mentioned in the bib- 

 liography, which wiU serve to introduce the reader to more recent work. The list of 

 references is not meant to be complete. For additional pubUcations attention is 

 directed to the bibliographies at the end of the cited references. 



( 335 > 



