The study proposes filtration drying for drying match splints. Experimental methods for investigating heat exchange between the heat agent and the material are presented. Theoretical aspects of heat transfer during filtration drying are analyzed. The effect of the heat agent's velocity on heat exchange efficiency is determined within the Reynolds number range of 200 ≤ Re ≤ 500. The experimentally obtained data are generalized using a dimensionless complex. A dependency for determining the heat transfer coefficient is proposed. A correlation between theoretical and experimental values of the heat transfer coefficient is provided.
1. Atamanyuk, V. M., & Humnytskyi, Ya. M. (2013). Naukovi osnovy filtratsiinoho sushinnia dyspersnykh materialiv. Vydavnytstvo Natsionalnoho universytetu "Lvivska politekhnika", Lviv.
2. Bandura, V., & Yaroshenko, L. (2019). Rationale of parameters of the process of drying sunflower green in the vibro-suspended layer on the basis of infrared risk. Scientific Works, 83(1), 110–116. doi: https://doi.org/10.15673/swonaft.v83i1.1427
3. Cavallaro, F., Ciraolo, L., Mavrotas, G., & Pechak, O. (2013). Assessment and simulation tools for sustainable energy systems. Green Energy and Technology, 129, 333–356.
4. Gnativ, Z. Ya., Ivashchuk, O. S., Hrynchuk, Yu. M., Reutskyi, V. V., Koval, I. Z., & Vashkurak, Yu. Z. (2020). Modeling of internal diffusion mass transfer during filtration drying of capillary-porous material. Mathematical Modeling and Computing, 7(1), 22–28. doi: https://doi.org/10.23939/mmc2020.01.022
5. Holubets, V. M., Ozarkiv, I. M., & Atsberher, Y. L. (2003). Heat exchange during the drying of wood-based bulk materials in a fluidized bed. Scientific Bulletin of UNFU, 13(1), 93–100.
6. Ivashchuk, O. S., Atamanyuk, V. M., Chyzhovych, R. A., Manastyrska, V. A., Barabakh, S. A., & Hnativ, Z. Ya. (2024). Kinetic regularities of the filtration drying of barley brewer’s spent grain. Chemistry & Chemical Technology, 18(1), 66–75. doi: https://doi.org/10.23939/chcht18.01.066
7. Kindzera, D. P., Atamanyuk, V. M., Hosovskyi, R. R., & Symak, D. (2021). Heat transfer process during filtration drying of grinded sunflower biomass. Chemistry & Chemical Technology, 15(1), 118–124. doi: https://doi.org/10.23939/chcht15.01.118
8. Kumar, A., Kandasamy, P., Chakraborty, I., & Hangshing, L. (2022). Analysis of energy consumption, heat and mass transfer, drying kinetics, and effective moisture diffusivity during foam-mat drying of mango in a convective hot-air dryer. Biosystems Engineering, 219, 85–102. doi: https://doi.org/10.1016/j.biosystemseng.2022.04.026
9. Koukouch, A., Bakhattar, I., Asbik, M., & et al. (2020). Analytical solution of coupled heat and mass transfer equations during convective drying of biomass: Experimental validation. Heat and Mass Transfer, 56, 1971–1983. doi: https://doi.org/10.1007/s00231-020-02817-w
10. Kuzminchuk, T. A., Atamanyuk, V. M., Duleba, V. P., & Janabayev, D. (2023). Kinetics of drying of match splints. Chemistry, Technology and Application of Substances, 2, 119–125.
11. Lawrence, A., Thollander, P., Andrei, M., & Karlsson, M. (2019). Specific Energy Consumption/Use (SEC) in Energy Management for Improving Energy Efficiency in Industry: Meaning, Usage and Differences. Energies, 12(2), 247. doi: https://doi.org/10.3390/en12020247
12. Messai, S., El Ganaoui, M., Sghaier, J., & Belghith, A. (2014). Experimental study of the convective heat transfer coefficient in a packed bed at low Reynolds numbers. Thermal Science, 18(2), 443–450.
13. Mosyuk, M. I., Psiuk, Yu. Ya., & Rudei, I. A. (2015). Kinetics of filtration drying of crushed wood. Scientific Works Odessa National Academy of Food Technologies, 47(1), 194–198.
15. Mykychak, B., Biley, P., & Kindzera, D. (2013). External heat-and-mass transfer during drying of packed birch peeled veneer. Chemistry & Chemical Technology, 7(2), 191–195.
16. Obleshchenko, A. D., & Hulevskyi, V. B. (2021). Comparison of wood drying technologies: Vacuum and microwave. In Technical support of innovative technologies in the agro-industrial complex: Proceedings of the III International Scientific and Practical Internet Conference (Melitopol, November 1–26, 2021) (pp. 223–227).
17. Pazyuk, V. (2018). Investigation of low-temperature drying modes of plant capillary-porous materials with spherical shape. Ceramics: Science and Life, 4(41), 7–14. doi: https://doi.org/10.26909/csl.4.2018.1
18. Salah, S. A., & Mustafa, A. (2021). Integration of energy saving with lean production in a food processing company. Journal of Machine Engineering, 21(4), 118–133. doi: https://doi.org/10.36897/jme/142394
19. Sokolovskyi, I. A. (2019). Energy characteristics of drying modes of beech lumber. Scientific Bulletin of UNFU, 29(1), 106–109. doi: https://doi.org/10.15421/40290123