The process of fish salting is based on patterns associated with the diffusion of salt in the fish tissue and the diffusion-osmotic transfer of water from the tissues of fish to the brine or in the opposite direction. Atlantic herring is an object of research. The character of the spatial-temporal distribution of salt within the product (herring) was established. As a method of experimental research was used a modern method of non-destructive testing, called photon correlation spectroscopy. The theoretical model of the process was obtained on the basis of the second Fick's law as a solution of a differential equation by the method of separation of variables. The qualitative nature of the mathematical model is interpreted as an exponential approach to the equilibrium value of salt concentration in the process of fish salting. Experimental dependences of the diffusion coefficient on the depth of salt penetration into the muscle tissue of fish were obtained. The mass transfer rate of salt in the first stage of the salting process is about 3·10-4 mm/s. The experimental value of the mass transfer rate is compared with the theoretical value of the proposed model. A satisfactory coincidence is obtained. The qualitative character of the advancement of the salt critical concentration (8.0%) in the form of a front has been established. This is consistent with the theory of P.B. Crean. The causes associated with the apparent increase in the diffusion coefficient at the second stage of the fish salting process are analyzed, which have been noted by many researchers. The expediency of using the effective diffusion coefficient in studies was expressed, which to a greater extent corresponds to the actual course of the process of mass transfer of salt and moisture. It is noted that the most recognized modern theoretical and empirical models of the process of salting fish are models that reflect an exponential approach to the equilibrium of substances involved in the process The acceptability of using the empirical model of salting fish Zugarramurdi and Lupine was confirmed as qualitatively corresponding to the theoretical model proposed in the article..

fish salting, «frontal» theory, mass exchanging process, diffusion coefficient, salt concentration

1. Technologiya ryby i rybnych produktov [Technology of fish and fish products: textbook]. Moscow, Kolos, 2010. 1064 p. (in Russian)

2. Barat J.M., Baigts D., Alino M., Fernanandez F.J. et al. Kinetics studies during NaCl and KCl pork meat brining. Journal of Food Engineering. 2011. vol. 106. no. 1. pp. 102–110.

3. Vestergaard C., Risum J., Adler-Nissen J. Quantification of salt concentrations in cured pork by computed tomography. Meat Science. 2004. vol. 68. no. 1. pp. 107–113.

4. Fortin A., Tong A.K.W., Robertson W.M., Zawadski S.M. et al. A novel approach to grading pork carcasses: computer vision and ultrasound. Meat Science. 2003. vol. 63. no. 4. pp. 451–462.

5. Bertram H.S., Engelsen S.B., Busk H., Karlsson A.H. et al. Water properties during cooking of pork studied by low-field NMR relaxation: effects of curing and RN-gene. Meat Science. 2004. vol. 66. no. 2. pp. 437–446.

6. Shumanova M.V., Fatykhov Ju.A., Shumanov V.A. The results of experimental and theoretical studies the process of herring salting. Vestnik VGUIT [Proceedings of VSUET]. 2015. no. 2. pp. 30–34 (in Russian).

7. Gomez-Salazar J.A., Clemente-Polo G., Sanjuan-Pelliccer N. Review of mathematical models to describe the food salting process. DYNA. 2015. vol. 82. no. 190. pp. 22–30. doi: 10.15446/dyna.v82n190.42016

8. Shumanov V.A., Shumanova M.V. Determining the duration of herring salting using a mathematical solution of the diffusion equation. Progressivnyye tekhnologii, mashiny i mekhanizmy v mashinostroyenii i stroitel'stve [Progressive technologies, machines and mechanisms in mechanical engineering and construction: IV International Baltic Sea Forum. II International Scientific Conference]. Kaliningrad, BGARF publishing house, 2016. vol. 5. pp.61–63. (in Russian).

9. Costa-Corredor A., Munoz I., Arnau J., Gou P. Ion uptakes and diffusivities in pork meat brine-salted with NaCl and K-lactate. LWT – Food Science and Technology. 2010. vol. 43. no. 8. pp. 1226–1233.

10. Corzo O., Bracho N. Osmotic dehydration kinetics of sardine sheets using Zugarramundi and Lupin’s model. Journal of Food Engineering. 2005. vol. 66. pp. 51–56.