With the development of food processing and storage at near-cryoscopic temperatures, more and more attention is being paid to the development of methods for frozen out moisture and cryoscopic temperature calculating based on their component composition data. There is a significant dispersion among the existing experimental data of various researchers and calculation methods for beef thermophysical properties. In the study given, the authors determined the enthalpy of phase transitions, beet heat capacity with different moisture content and its cryoscopic temperature with the method of differential scanning calorimetry. With the analysis of the phase transitions enthalpy, it was found out that the share of non-freezing water for beef is n = 0.35 (g of water per 1 g of dry matter). The presence of the vitreous phase in the temperature range of about -85 ° С was established, most noticeably manifested when the moisture content of the samples is w = 37–45.8%, which indicates the formation of amorphous solutions in the process of food products freezing. Beginning of moisture melting peak Tm.b. takes place at temperatures range from -35 ° C till -25 ° C for the samples with low and normal moisture content respectively. Acccording to the theoretical Heldman ratio, a dependence for cryoscopic temperature calculating was proposed . The given semi-empirical dependences of the phase transitions enthalpy and the frozen moisture fraction provide an increase in the accuracy of calculations at low values of moisture content in the product. The research results can be used as input data in mathematical modeling of heat exchange processes and the development of calculating methods for the thermophysical properties of food products based on their composition.

beef, phase transition, moisture content, outfrozen water, cryoscopic temperature

1. Ginzburg A.S. Teplofizicheskie harakteristiki pishchevyh produktov. Spravochnik [Thermophysical characteristics of food products]. Moscow, Agropromizdat, 1990. 288 p. (in Russian).

2. Dibirasulaev M.A. et al. Effect of sub-cryoscopic storage temperature on the amount of frozen water in nor and DFD beef. Teoriya i praktika pererabotki myasa [Theory and practice of meat processing]. 2016. vol. 1. no. 2. pp. 18–23. (in Russian).

3. Latyshev V.P., Tsirulnikova N.A. Rekomenduemye spravochnye materialy dlya provedeniya teplovyh raschyotov pishchevyh produktov [Recommended reference materials for conducting thermal calculations of foods]. Moscow, NPO «Agroholodprom», 1992. 86 p. (in Russian).

4. Ryutov D.G. Influence of bound water on the formation of ice in food products during their freezing. Holodil'naya tekhnika [Refrigeration equipment]. 1976. no. 5. pp. 32–37. (in Russian).

5. ASHRAE Handbook. Refrigeration. 2014.

6. Belozerov A.G. et al. A Study of the Thermophysical Properties of Human Prostate Tumor Tissues in the Temperature Range from160 to+ 40° C. Biophysics. 2018. vol. 63. no. 2. pp. 268–273.

7. Kaale L.D. et al. Superchilling of food: A review. Journal of food engineering. 2011. vol. 107. no. 2. pp. 141–146.

8. Pongsawatmanit R., Miyawaki O. Measurement of temperature-dependent ice fraction in frozen foods. Bioscience, biotechnology, and biochemistry. 1993. vol. 57. no. 10. pp. 1650–1654.

9. Riedel L. The problem of bound water in meat. Refrigeration. 1961. vol. 13. pp. 122.

10. Sanz P.D., Alonso M.D., Mascheroni R.H. Thermophysical properties of meat products: General bibliography and experimental values. Transactions of the ASAE. 1987. vol. 30. no. 1. pp. 283–290.

11. Thermal Properties of Meat – Tabulated Data. Agricultural Research Council, 1972.

12. Van der Sman R.G.M., Boer E. Predicting the initial freezing point and water activity of meat products from composition data. Journal of Food Engineering. 2005. vol. 66. no. 4. pp. 469–475.