Mathematical support of the drying process as a pre – stage of the new generation CAD dryers design

Objective. The aim of the study is the mathematical support of the vacuum microwave process, the design of the installation in CAD, the manufacture of a prototype, the modeling of temperature and moisture content fields.

Method. The mathematical model was implemented numerically by the finite element method in the Comsol Multiphysics environment on a grid of 3678 elements, using its deformation to change the height.

Result. Experimental data were obtained on a laboratory vacuum microwave installation, which made it possible to identify patterns in the drying of foamed materials. The drying parameters, as well as the properties of the initial and dried material, were analyzed. A pilot-type vacuum plant was designed using CAD and a working prototype was made. The modeling of the temperature field and moisture content zones in the dynamics of the process has been carried out.

Conclusion. Mathematical modeling of the drying process makes it possible to determine the temperature fields and moisture content of the material with a high accuracy with a relatively small amount of necessary experimental data.

1. Nesterenko, E. S. Fundamentals of computer–aided design systems [Electronic resource]: electron. Lecture notes / E. S. Nesterenko; Ministry of Education and Science of Russia, Samara State Aerospace. Un – t named after S. P. Korolev (National Research un – t) – Electron. text and graph. dan. (0.31 MB). Samara, 2013. (In Russ)

2. Lee K. CAD basics (CAD, CAM, CAE). St. Petersburg: Peter, 2004; 560. (In Russ)

3. Rogov I.A., S.V. Nekrutman Ultra – high – frequency heating of food products..: Agropromizdat, 1986; 351. (In Russ)

4. Rogov I.A. Electrophysical methods of food processing. M.: Agroprom – izdat. 1988; 272. (In Russ)

5. Ginzburg A.S. Calculation and design of drying plants of the food industry. M.: Agropromizdat, 1985; 336. (In Russ)

6. Teplyashin V.N. Technologies and equipment for drying vegetable raw materials [Electronic resource]: textbook. manual / V.N. Teplyashina, L.I. Chentsova, V.N. Nevzorov; Krasnoyar. State Agrarian. un – t. Krasnoyarsk. 2019; 173. (In Russ)

7. Abramov Y.K. Intensification of heat and mass transfer processes with continuous accumulation / Abstracts of the 3rd anniversary scientific – practical conference. Biysk: BTI, 1995; 76. (In Russ)

8. Pat. on the floor. Model No. 72536 RF, IPC F26B 5/06 (2006.01). Vacuum microwave installation for laboratory studies of the process of dehydration of food media [Text] /G.O. Magomedov, S.V. Shakhov, M.G. Magomedov, V.V. Tkach, V.V. Novikov. – applicant and patent holder: G.O. Magomedov, S.V. Shakhov, M.G. Magomedov, V.V. Tkach, V.V. Novikov. – No. 2007145105/22; application 04.12.2007; publ. 20.04.2008; 11. (In Russ)

9. Pat. No. 2755850 RF, IPC F26B 9/06. Installation for vacuum drying [Text] /C.V. Makeev, E.S. Bunin, A.A. Shevtsov, V.V. Tkach. – applicant and patent holder Voronezh. State. University. Engineering technol. – No. 2020141027; application No. 14.12.2020; publ. 22.09.2021; 27. (In Russ)

10. Lykov A.V. Theory of drying. M.: Energiya 1968; 471. (In Russ)

11. Nastaj, J. F. A parabolic cylindrical stefan problem in vacuum freeze drying of random SOLIDS. International Communications in Heat and Mass Transfer. 2003; 30(1): 93 – 104.

12. L.N. Gupta. An approximate solution to the generalized Stefan's problem in a porous medium, Int. J. Heat Transfer 17 1974; 313 – 321.

13. Tong, T.H., Lund, D.B. Microwave Heating of Baked Dough Products with Simultaneous Heat and Moisture Transfer. Journal of Food Engineering. 1993; 19: 319 – 339 – 286.

14. Bonacina, C., Comini, G., Fasano, F., Primicerio, V., Numerical solution of phase–change problems. International Journal Heat Mass Transfer. 1973; 16: 1825 – 1832.

15. Davies Brian "Heaviside step function". Integral Transforms and their Applications (3rd ed.). Springer.2002; 28.