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Surface tension of whole and skim-milk between 18 and 135 °C

Published online by Cambridge University Press:  01 June 2009

Antonio J. Bertsch
Antonio J. Bertsch
Affiliation:
Unité de Génie Alimentaire, Institut National de la Recherche Agronomique, 78350 Jouy-en-Josas, France
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Summary

The surface tension (γ) of whole milk (4% fat) and skim-milk was determined in the temperature range 18–135 °C by the drop number method. Measurements were carried out in a temperature-controlled chamber under pressure. Above 90 °C, the mean residence time of the milk at the test temperature was 15 s. Surface tension values were calculated by the Harkins and Brown method, corrections being made to account for the kinetic energy of the drops. The results for whole and skim-milk were not significantly different and the combined data (66 values) could be represented by the equation:

γ =1·8 10-4θ2–0·163θ+55·6,

(where γ is in mN. m-1 and θ is the temperature in °C) with a residual s.d. of 2·1 mN. m-1 (mean relative error 9·6 % at the 5 % level of significance).

Type
Original Articles
Information
Journal of Dairy Research , Volume 50 , Issue 3 , August 1983 , pp. 259 - 267
Copyright
Copyright © Proprietors of Journal of Dairy Research 1983

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References

REFERENCES

Adamson, A. W. 1976 Physical chemistry of surfaces, 3rd edn.New York:John Wiley & Sons.Google Scholar
Aschaffenburg, R. 1946 Surface activity and proteins of milk. Journal of Dairy Research 14 316329Google Scholar
Belle, G. 1936 [The surface tension of cows milk.] Lait 16 1320CrossRefGoogle Scholar
Bertsch, A. J. 1982 [The specific heat of whole milk and skim-milk from 50 °C to 140 °C.] Lait 62 265275Google Scholar
Bertsch, A. J., Bimbenet, J. -J. & Cerf, O. 1982 [The density of milk and of cream from 65 °C to 140 °C.] Lait 62 250264CrossRefGoogle Scholar
Bertsch, A. J. & Cerf, O. 1983 Dynamic viscosities of milk and creams from 70 to 135 °C. Journal of Dairy Research 50 193200Google Scholar
Bowker, A. H. & Lieberman, G. J. 1965 Méthodes statistiques de l'ingénieur. Paris: DunodGoogle Scholar
Calandron, A. & Grillet, L. 1964 [Measurement of the surface tension of some milks with a Du Noüy tensiometer.] Lait 44 505509CrossRefGoogle Scholar
Chandan, R. C. & Dastur, N. N. 1959 Surface tension of milk of Indian cows and buffaloes. 15th International Dairy Congress, London 3 15761582Google Scholar
Collier, J. G. 1981 Convective boiling and condensation 2nd edn.New York: McGraw-HillGoogle Scholar
Delhaye, J. M., Giot, M. & Riethmuller, M. L. (Eds) 1981 Thermohydraulics of Two-phase Systems for Industrial Design and Nuclear Engineering. Washington: Hemisphere Publishing CorporationGoogle Scholar
Dunkley, W. L. 1951 Hydrolytic rancidity in milk. I. Surface tension and fat acidity as measures of rancidity. Journal of Dairy Science 34 515520Google Scholar
Guastalla, J., Lizé, A. & Davion, N. 1971 [On the stirrup tensiometer method: use of the maximum of the traction curve.] Journal de Chimie Physique el de Physico-chimie biologique 68 822830Google Scholar
Harkins, W. D. 1952 The physical chemistry of surface films. New York: Reinhold Publishing CorporationGoogle Scholar
Kopaczewski, W. 1936 [The surface tension of milk.] Lait 16 356359CrossRefGoogle Scholar
Kramer, A. & Twigg, B. A. 1973 Quality control for the food industry, 3rd edn.Westport, Conn.: Avi Publishing Co. Inc.Google Scholar
Mohr, W. & Brockmann, C. 1930 [Surface tension measurements with milk.] Milchwirtschaftliche Forschungen 10 7295Google Scholar
Monteil, C. 1955 Techniques de l'ingénieur K 480 7. Paris: Techniques de l'ingénieurGoogle Scholar
Parkash, S. 1963 Studies in physico-chemical properties of milk. XIV. Surface tension of milk. Indian Journal of Dairy Science 16 98100Google Scholar
Peeples, M. L. & Urban, H. 1961 Relationship of surface tension to variations in composition and temperature of fluid milk products. Journal of Dairy Science 44 972Google Scholar
Sharma, R. R. 1963 Determination of surface tension of milk by the drop method and the ring method. Indian Journal of Dairy Science 16 101108Google Scholar
Sharp, P. F. & Krukovsky, V. N. 1939 Differences in adsorption of solid and liquid fat globules as influencing the surface tension and creaming of milk. Journal of Dairy Science 22 743751Google Scholar
Wallis, G. B. 1969 One-dimensional two-phase flow. New York: McGraw-Hill Book CompanyGoogle Scholar
Watson, P. D. 1958 Effect of variations in fat and temperature on the surface tension of various milks. Journal of Dairy Science 41 16931698CrossRefGoogle Scholar
Weast, R. C. & Astle, M. J. 1980 CRC Handbook of Chemistry and Physics, 61st edn.Boca Raton: CRC PressGoogle Scholar
Webb, B. H., Johnson, A. H. & Alford, J. A. 1974 Fundamentals of Dairy Chemistry, 2nd edn.Westport, Conn.: Avi Publishing Co. Inc.Google Scholar
Whitnah, C. H. 1959 The surface tension of milk. A review. Journal of Dairy Science 42 14371449CrossRefGoogle Scholar
Whitnah, C. H., Conrad, R. M. & Cook, G. L. 1949 Milk surfaces. I. The surface tension of fresh surfaces of milk and certain derivatives. Journal of Dairy Science 32 406417Google Scholar