THEORETICAL AND EXPERIMENTAL ANALYSIS OF DRYING KINETICS OF COLLOID CAPILLARY-POROUS MATERIALS AS DRYING OBJECTS
Abstract
Considering the current situation in the energy sector of Ukraine, the urgent need to improve and develop energy-efficient thermal technologies for dehydration of plant raw materials is urgent and timely, which would ensure minimal energy consumption and high quality of the final product. The processing of vegetable raw materials into dried products is important for the sustainable development of the food industry. Cultivated Pleurotus eryngii mushrooms, which are valued for their high content of protein, carbohydrates, unsaturated fatty acids, vitamins and other nutrients, etc., are increasingly relevant in the mushroom industry on the world food market.
It is important, in order to optimize energy consumption during dehydration and to select rational equipment, in addition to experimental studies, to perform theoretical calculation analysis of heat and mass transfer based on mathematical models.
The article provides a theoretical and experimental analysis of the drying kinetics of colloidal capillary-porous materials. To determine the characteristics of the convective drying process, in addition to experimental studies, numerical modeling of this process was performed, which is performed on the basis of the numerical solution of the system of heat and mass transfer equations in colloidal capillary-porous materials. The calculation model can be used for the approximate determination of the main characteristics of the drying process of colloidal capillary-porous materials.
References
2. Zhang, B.; Li, Y.; Zhang, F.; Linhardt, R.J.; Zeng, G.; Zhang, A. (2020) Extraction, structure and bioactivities of the polysaccharides from Pleurotus eryngii: A review. Int. J. Biol. Macromol. 150, p. 1342–1347. [CrossRef]
3. Rui-LinYang, Qin Li & Qing-Ping Hu (2020) Physicochemical properties, microstructures, nutritional components, and free amino acids of Pleurotus eryngii as afected by diferent drying methods. Scientific Reports 10:121 https://doi.org/10.1038/s41598-019-56901-1
4. He Liu, Junhua Jiao, You Tian, Jia’ao Liu, Pei Yuan, and Xuehong Wu (2022) Drying kinetics of Pleurotus eryngii slices during hot air drying. Open Physics; 20: p. 265–273. https://doi.org/10.1515/phys-2022-0029
5. Tong Li1 . Jo-Won Lee1 . Li Luo1 . Jongkee Kim2 . BoKyung Moon (2018) Evaluation of the effects of different freezing and thawing methods on the quality preservation of Pleurotus eryngii. Appl Biol Chem, 61(3), p. 257–265.
6. Dolinskiy A. A., Dorfman A. Sh., Davydenko B. V. (1991) Conjugate heat and mass transfer in continuous processes of convective drying. Int. J. Heat Mass Transfer. 1991.V.34, № 11. Р. 2883– 2889.
7. M. A. Mikheev, I. M. Mikheeva. (1977) Fundamentals of heat transfer. M. "Energy", 320 p. (in rus).
8. Kalitkin N.N. (1978) Numerical methods. M. "Science". 1978. 512 p. (in rus).
9. Ginzburg A.S., Gromov M.A., Krasovskaya G.I. (1980) Thermophysical characteristics of food products. Directory. M.: "Food Industry", 288 p. (in rus).
10. Sniezhkin Yu.F., Petrova Zh.O. (2007) Heat and mass exchange processes during the production of carotene-containing powders. Kyiv: VD "Akademperiodika". 162 p. (in Ukr).
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