Кемерово, Кемеровская область, Россия
The precise and objective estimation of the beginning of gelation in milk is topical for both laboratory studies and industrial dairy production. In this work, the principles of the thermographic method of monitoring milk coagulation are formulated. This method has evolved from the well-known hot-wire method; it is based on the measurement of the temperature difference between two thermometers, one of which is heated. Unlike the hot-wire method, the thermographic method can even be used in processes that require significant changes in milk temperature, for example, during heat–acid milk coagulation. Two basic designs of thermographic systems, using as thermometers either differentially connected thermocouple junctions or two identical thermistors connected as two legs of a bridge circuit, are described. In both cases, the temperature difference between the heated and unheated thermometers at about 0.5 W of thermal power supply is about 3°C for incoagulated milk and 8–10°C after clot formation. The qualitative agreement of the results of rheological and thermographic methods has been demonstrated. A thermographic research technique for heat–acid or heat–calcium milk coagulations has been developed. Within the effective viscosity model, the numeric solution of the problem of temperature field simulation in the vicinity of the heated thermometer has been obtained. On the basis of the simulation results, the possibility of studying structure formation in milk during its coagulation has been analyzed using the thermographic data. Experimental results obtained during thermographic research of milk coagulation are presented.
milk coagulation control, heat convection, thermographic method
INTRODUCTION
It is common knowledge that the process of milk coagulation represents the transition of a micellar colloidal system of caseins to a gel-like state. This process underlies many dairy technologies, particularly, cheese making, largely predetermining cheese quality [1]. The latter circumstance makes the coagulation of milk proteins the subject of thorough research for scientists specializing in the properties of milk and dairy products.
The estimation of the beginning of gelation in milk is topical both for scientific research and for process monitoring in industry. Suffice it to note that the exact estimation of the beginning of coagulation directly in the cheese vat makes it possible, in principle, to adjust automatically the process schedule as the physic-chemical indicators of milk change (for example, the protein content) in order to economize on both milk-clotting preparations and cheese production times. Very important is also the correct and unambiguous determination of the duration of the main coagulation stages for research purposes, in particular, for building adequate models of the coagulation process.
Despite the very long history of dairy technology, the methods of objective monitoring of the milk coagulation process appeared relatively recently. We may say that the main method of determining the time of coagulation was visual observation using a cheesemaking knife or a cheesemaker's finger practically until the mid-20th century. Note that the first experience of objective observation over the rennet clotting of milk with a viscometer dates back to 1932 [2].
At present, there are a large number of various methods for objective monitoring of milk coagulation. They all may conventionally be divided into several groups characterized by the choice of milk parameters that undergo changes during coagulation [3–5]. Basically, these are certainly rheological and optical methods, based on observing changes in milk structure during its coagulation. In addition, the rheological methods record structural changes by the system's response to applied mechanical stresses or deforma-tions, and the optical methods, by the change in the absorption or dissipation of visible light, as well as in the emission of the infrared band. The wide use of these two methods depends, primarily, on the possibility of their use directly online. Moreover, these methods ensure obtaining well-correlated data [6–8].
Another quite widespread method to monitor milk coagulation due to the possibility to use it online is the hot-wire method, developed in 1985 [9]. Its essence is that the temperature of an electric current–conducting wire placed in milk increases during coagulation because of a decrease in a convective heat sink resulting from the formation of a structure in milk. This method is indirect rheological in essence; therefore, the results obtained with it correlate well with data obtained both rheologically and optically [10]. Thanks to its simplicity and possibility to be used online, this method continues to be topical nowadays [11].
1. Fox, P.F., Guinee, T.P., Cogan, T.M., and McSweeney, P.L.H., Fundamentals of Cheese Science (Aspen, 2000), 639 p.
2. Holter, H., Über die Labwirkung, Biochemische Zeitschrift, 1932. V. 255. P. 160.
3. O´Callaghan, D.J., O´Donnell, C.P., and Payne, F.A., A comparison of on-line techniques for determination of curd setting time using cheesemilks under different rates of coagulation, Journ. Food Eng., 1999. V. 41(1). P. 43.
4. O´Callaghan, D.J., O´Donnell, C.P., and Payne, F.A., Review of systems for monitoring curd setting during cheesemaking. Int. Journ. Dairy Technol., 2002. V. 55(2). P. 65.
5. Lucey, J.A., Formation and physical properties of milk protein gels, Journ. Dairy Sci., 2002. V. 85, P. 281.
6. Klandar, A.H., Lagaude, A., and Chevalier-Lucia, D., Assessment of the rennet coagulation of skim milk: A comparison of methods, Int. Dairy Journ., 2007. V. 17(10). P. 1151.
7. Sandra, S., Cooper, C., Alexander, M., and Corredig, M., Coagulation properties of ultrafiltered milk retentates measured using rheology and diffusing wave spectroscopy, Food Res. Int., 2011. V. 44(4). P. 951.
8. Cipolat-Gotet, C., Cecchinato, A., De Marchi, M., Penasa, M., and Bittante, G., Comparison between mechanical and near-infrared methods for assessing coagulation properties of bovine milk, Journ. Dairy Sci., 2012. V. 95(11). P 6806
9. Hori, T., Objective measurements of the process of curd formation during rennet treatment of milks by the hot wire method, Journ. Food Sci., 1985, V. 50. P. 911.
10. O´Callaghan, D.J., Mulholland, E.P., Duffy, A.P., O´Donnell, C.P., and Payne, F.A., Evaluation of hot wire and optical sensors for on-line monitoring of curd firmness during milk coagulation, Irish Journ. Agric. Food Res., 2001. V. 40(2). P. 227.
11. Sbodio, O.A. and Revelli, G.R., Milk’s coagulation. Development of a device for online “monitoring” of the process. Progress made in Argentina. Revista de Investigaciones Agropecuarias (Agricultural Research Journal), 2012. V. 38(3) (published online: http://ria.inta.gov.ar/english/wp-content/uploads/2013/06/By-Sbodio-ingles-4.pdf)
12. Upreti, P., Mistry, V.V., and Acharya, M.R., Characterization of rennet coagulation of milk concentrated by vacuum condensing and ultrafiltration, Dairy Sci. Technol., 2011. V. 91(3). P. 383.
13. Gebhart, B., Jaluria, Yo., Mahajan, R.L., and Sammakia, B., Buoyancy-Induced Flows and Transport (Hemisphere, New York, 1988), 971 p.
14. Osintsev, A.M., Gromov, E.S., and Braginsky, V.I., A phenomenological model of milk coagulation, Foods Raw Mater., 2013. V. 1(1). P. 11.
15. Osintsev, A.M., Braginsky, V.I., Chebotarev, A.L., Osintseva, M.A., and Syrtseva, A.P., Investigation of heat-acid milk coagulation by the thermographic method. Tekhn. tekhnol. pishchevykh proizvodstv (Food Processing: Techniques and Technology), 2013. № 4. P. 69.