Physical processes occurring during dehydration of heterogeneous materials in a thermal vacuum system have been analyzed. It has been demonstrated that the thermal-vacuum method provides dehydration and simultaneous wet-stock dispersion due to thermal diffusion, shock-wave and ionization effects, thereby leading to formation of novel-type nanodispersed material at minimum energy input. In recent years the intensification of production processes, as well as the solution of energy- and resource-saving problems have taken on great significance. For the sake of dehydration working-cycle improvement, combination of several process procedures in a single installation is used, resulting in both the intensification of the production process and the reduction in capital expenditures. There are the facilities, where the simultaneous use of mechanical grinding operation and the drying process is practiced. In this case, a preheated air is used as a drying agent, and this considerably increases the energy demands of the technological process. This phenomenon is attributed to the impact action and friction of material particles against grinding surfaces of the mill, to the appearance of new surfaces at crushing, and also, to the dust-gas mixture turbulence in the mill working area. That requires substantial power consumption and prevents from obtaining the product with desirable indicators, in particular, the with dispersion and moisture content, which substantially affect the quality of materials produced from fine-grained products. The analysis of fine grinding methods has shown that the most rational method of material grinding is the combination of impact loads. The impact loads facilitate the structure destruction of wet stock, while the abrasion loads acting in the field of high turbulent flows lead to the material destruction. The aim of the present work has been to define the physical processes in the thermal vacuum system, which can efficiently provide dehydration along with simultaneous dispersion of wet material, yielding a dried and ground feedstock in a short span of time.
| Published in | American Journal of Physics and Applications (Volume 10, Issue 1) |
| DOI | 10.11648/j.ajpa.20221001.11 |
| Page(s) | 1-7 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2022. Published by Science Publishing Group |
Intensification, Heat Transfer, Dehydration, Dispersion, Energy Efficiency
| [1] | Shishkov N. I., Oparin S. A., Soroka P. I., Zrazhevskij V. I. Issledovanie sovmeshhennyx processov izmelcheniya i sushki v melnice udarnootrazhatelnogo dejstviya // Materіali v mіzhnarodnoї naukovo-praktichnoї konferencії “Nauka і osvіta – 2002”. — Tom 19. — Dnіpropetrovsk - Doneck. — 2002. — P. 49-50. |
| [2] | Oparin S. A., Soroka P. G. Sovmeshhennyj process tonkogo izmelcheniya i sushki rastitelnyx otxodov // Nakovі procі odeskoї nac. akademії xarchovix texnologіj. 2014. - Vip. 45. - t. 3 – P. 4-9. |
| [3] | Pat. №88108, Ukraina. MPK S 01 V31/36. Sposіb oderzhannya karbіdu kremnіyu / Soroka P. I., Bіla A. O. and others. Patentovlasnik DVNZ «UDXTU». № a 200802934; Zayavl. 06.03.08; Opubl. 10.09.09, Byul. № 17. — 6 p. |
| [4] | A. Oparin, E. V. Leshhenko, P. I. Soroka. Raschet texnologicheskix parametrov processa izmel'cheniya v mel'nice udarno-otrazhatel'nogo dejstviya // Naukovі pracі ONAXT. – 2010. - №37. – P. 118-122. |
| [5] | Pat. №96082, Ukraina. MPK V02S13/14 Vіdcentrovij mlin udarnoї dії / Soroka P. I., Oparin S. O.; Zayavnik ta patentovlasnik DVNZ «UDXTU». – № a 2001096302. Zayavl. 25.05.2010. – Opubl. - 27.12.2010. — Byul. №18. |
| [6] | Pat. 81138 Ukraїna. MPK F26B9/06. Pristrіj dlya termovakuumnogo sushіnnya / Kutovij V. O. - №a200507488; zayavl. 27.07.2005; opubl. 10.12.07. Byul. №20. – 5 p. |
| [7] | Kutovoj V. A., Kazarinov Yu. G., Lucenko A. S., and others. Termovakuumnyj metod polucheniya nanodispersnyx materialov // Voprosy atomnoj nauki i texniki. – 2014. – №2 (90). – Vip. 103. – P. 153-157. |
| [8] | Bulanov N. V. Vzryvnoe vskipanie dispergirovannyx zhidkostej. / Ekaterinburg, 2011. — 232 p. |
| [9] | Landau L. D., Lifshic E. D. Gidrodinamika / M.: Fizmatlit, 2001. — 736 p. |
| [10] | Sysoev N. N. Udarnye Volnyv gazax i kondensirovannyx sredax. / M.: Universitet, 1987. — 133 p. |
| [11] | Zeldovich Ya. B., Rajzner Yu. P. Fizika udarnyx voln i vysokotemperaturnyx gidrodinamicheskix yavlenij. / M.: Nauka, 1966. – 686 p. |
| [12] | Lukyanov A. B. Fizicheskaya i kolloidnaya ximiya. / M.: Ximiya, 1988. — 288 p. |
| [13] | Naumenko I. A., Petrovskij I. G. Udarnaya volna atomnogo vzryva / M.: Voenizdat, 1956. — 160 p. |
| [14] | Kutovyi V. O., Malykhin D. G., Kalchenko O. S. and others. Effect of Thermal-Vacuum Dispertion of Graphite // East European Journal of Physics. – 2020. – #2. – P. 111-117. |
| [15] | Mesyac G. A., Bychkov Yu. I., Kremnev V. V. Impulsnyj nanosekundnyj elektricheskij razryad v gaze // Uspexi fizicheskix nauk. 1972. T. 107. Vip. 6. — P. 201-228. |
| [16] | Myshkin V. F., Vlasov V. A., Han V. A. Struktura i svojstva vody' obluchennoj SVCh izlucheniem // Nauchnyj zhurnal Kub GAU. №8 (07), 2012. - P. 1-11. |
APA Style
Volodymyr Kutovyi. (2022). Physical Processes in the Thermal Vacuum System. American Journal of Physics and Applications, 10(1), 1-7. https://doi.org/10.11648/j.ajpa.20221001.11
ACS Style
Volodymyr Kutovyi. Physical Processes in the Thermal Vacuum System. Am. J. Phys. Appl. 2022, 10(1), 1-7. doi: 10.11648/j.ajpa.20221001.11
AMA Style
Volodymyr Kutovyi. Physical Processes in the Thermal Vacuum System. Am J Phys Appl. 2022;10(1):1-7. doi: 10.11648/j.ajpa.20221001.11
Share This Article
Twitter
Linked In
Facebook
Copy
Download@article{10.11648/j.ajpa.20221001.11,
author = {Volodymyr Kutovyi},
title = {Physical Processes in the Thermal Vacuum System},
journal = {American Journal of Physics and Applications},
volume = {10},
number = {1},
pages = {1-7},
doi = {10.11648/j.ajpa.20221001.11},
url = {https://doi.org/10.11648/j.ajpa.20221001.11},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajpa.20221001.11},
abstract = {Physical processes occurring during dehydration of heterogeneous materials in a thermal vacuum system have been analyzed. It has been demonstrated that the thermal-vacuum method provides dehydration and simultaneous wet-stock dispersion due to thermal diffusion, shock-wave and ionization effects, thereby leading to formation of novel-type nanodispersed material at minimum energy input. In recent years the intensification of production processes, as well as the solution of energy- and resource-saving problems have taken on great significance. For the sake of dehydration working-cycle improvement, combination of several process procedures in a single installation is used, resulting in both the intensification of the production process and the reduction in capital expenditures. There are the facilities, where the simultaneous use of mechanical grinding operation and the drying process is practiced. In this case, a preheated air is used as a drying agent, and this considerably increases the energy demands of the technological process. This phenomenon is attributed to the impact action and friction of material particles against grinding surfaces of the mill, to the appearance of new surfaces at crushing, and also, to the dust-gas mixture turbulence in the mill working area. That requires substantial power consumption and prevents from obtaining the product with desirable indicators, in particular, the with dispersion and moisture content, which substantially affect the quality of materials produced from fine-grained products. The analysis of fine grinding methods has shown that the most rational method of material grinding is the combination of impact loads. The impact loads facilitate the structure destruction of wet stock, while the abrasion loads acting in the field of high turbulent flows lead to the material destruction. The aim of the present work has been to define the physical processes in the thermal vacuum system, which can efficiently provide dehydration along with simultaneous dispersion of wet material, yielding a dried and ground feedstock in a short span of time.},
year = {2022}
}
TY - JOUR T1 - Physical Processes in the Thermal Vacuum System AU - Volodymyr Kutovyi Y1 - 2022/01/08 PY - 2022 N1 - https://doi.org/10.11648/j.ajpa.20221001.11 DO - 10.11648/j.ajpa.20221001.11 T2 - American Journal of Physics and Applications JF - American Journal of Physics and Applications JO - American Journal of Physics and Applications SP - 1 EP - 7 PB - Science Publishing Group SN - 2330-4308 UR - https://doi.org/10.11648/j.ajpa.20221001.11 AB - Physical processes occurring during dehydration of heterogeneous materials in a thermal vacuum system have been analyzed. It has been demonstrated that the thermal-vacuum method provides dehydration and simultaneous wet-stock dispersion due to thermal diffusion, shock-wave and ionization effects, thereby leading to formation of novel-type nanodispersed material at minimum energy input. In recent years the intensification of production processes, as well as the solution of energy- and resource-saving problems have taken on great significance. For the sake of dehydration working-cycle improvement, combination of several process procedures in a single installation is used, resulting in both the intensification of the production process and the reduction in capital expenditures. There are the facilities, where the simultaneous use of mechanical grinding operation and the drying process is practiced. In this case, a preheated air is used as a drying agent, and this considerably increases the energy demands of the technological process. This phenomenon is attributed to the impact action and friction of material particles against grinding surfaces of the mill, to the appearance of new surfaces at crushing, and also, to the dust-gas mixture turbulence in the mill working area. That requires substantial power consumption and prevents from obtaining the product with desirable indicators, in particular, the with dispersion and moisture content, which substantially affect the quality of materials produced from fine-grained products. The analysis of fine grinding methods has shown that the most rational method of material grinding is the combination of impact loads. The impact loads facilitate the structure destruction of wet stock, while the abrasion loads acting in the field of high turbulent flows lead to the material destruction. The aim of the present work has been to define the physical processes in the thermal vacuum system, which can efficiently provide dehydration along with simultaneous dispersion of wet material, yielding a dried and ground feedstock in a short span of time. VL - 10 IS - 1 ER -
Email: