Based on the multi-phase system analysis, we determined general pneumatic separation regularities of the dried crushed target product and detected the main interrelationships between physical and chemical effects and phenomena that takes an important place in the process of pneumatic separation with simultaneous crushing of the target product (calcium carbonate) of chalk in bulk materials and on this basis identifies the possibilities of the pneumatic separation process in the flowing fluidized volume, and proposes rational methods for intensifying the process. The principal device here is the fluidized volume moving unit. The fluidized length, the fluidized layering zone and the inlet area. The volume zone that is fluidized is divided into two components: the gas phase and the solid phase. The solid phase, in turn, consists of the first, second, third crushed target product particles, etc. components.
Ushbu ishda ko‘p bosqichli, tizimli tahlil yordamida yirik, mayda-butun mahsulotlar pnevmo separatsiya qonuniyati ko‘rib chiqildi hamda karbonat kalciy ya'ni bor mahsulotining pnevmo separatsiyasi yordamida hosil bo‘ladigan fizik-kimyoviy effekti va hodisalarning bog‘liqligi aniqlangan.Ushbu jarayonlaning asosini chala kuydirilgan hajmli mahsulotninng aralashmasidir.Modellashtirishda chala kuydirilgan zona 1 ya'ni, gazli va qattiq fazalardan qismlardan ekanligi aniqlangan. Modellashtirish jarayonida raqamli ekranda hisobotlar, vaqtinchalik grafiklar orqali namayon bo‘lishi kuzatildi.Grafiklar shuni ko‘rsatadiki umumiy massa ichidagi maydalangan mahsulotlar koncentratsiyasi ma'lum bir intervalda to‘g‘ri chiziqda ya'ni to'yingan holatda bo‘lar ekan. Tajriba shuni ko‘rsatadiki, yuqori sifatli maydalangan mahsulotlarni olish nazarda tutilgan.
Based on the multi-phase system analysis, we determined general pneumatic separation regularities of the dried crushed target product and detected the main interrelationships between physical and chemical effects and phenomena that takes an important place in the process of pneumatic separation with simultaneous crushing of the target product (calcium carbonate) of chalk in bulk materials and on this basis identifies the possibilities of the pneumatic separation process in the flowing fluidized volume, and proposes rational methods for intensifying the process. The principal device here is the fluidized volume moving unit. The fluidized length, the fluidized layering zone and the inlet area. The volume zone that is fluidized is divided into two components: the gas phase and the solid phase. The solid phase, in turn, consists of the first, second, third crushed target product particles, etc. components.
В статьена основе многоступенчатого системного анализа отражены общие закономерности пневмосепарации сушенного измельченного целевого продукта и выявлены основные взаимосвязи физико-химических эффектов и явлений, имеющих важное место при протекании процессапневмосепарации с одновременным измельчением целевого продукта– мела(карбоната кальция) в сыпучих материалах и на этой основе определены возможности процесса пневмосепарации в фонтанирующем псевдоожиженном объеме, а также предложены рациональные пути интенсификации режимов функционирования процесса пневмосепарации с одновременным измельчением целевого продукта в фонтанирующем псевдоожиженном объеме. Основным объектам исследования здесь является аппарат с фонтанирующим псевдоожиженным объемом, имеющим зону псевдоожижения и зону уноса. Зона псевдоожижения разделяется на две составляющие: газовая и твердая фазы. В свою очередь, твердая фаза состоит из частиц первого, второго, третьего измельченного целевого продукта и др. компонентов
№ | Muallifning F.I.Sh. | Lavozimi | Tashkilot nomi |
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1 | Artikov A.A. | профессор | Тошкент кимё-технология институти |
2 | Karabaev D.T. | доцент | Тошкент кимё-технология институти |
3 | Akobirova L.X. | asistent | Бухарского инженерно-технологический институт,.кафедра "Машины и оборудования пищевой и химической промышленности" |
4 | Abdirova M.T. | katta o’qituvchi | Алмата энергетика ва электрон технологияси колледжи |
5 | Akbarxo'jaev Z.A. | доцент | Тошкент кимё-технология институти |
6 | Oymirov S.. | докторант | Тошкент кимё-технология институти |
№ | Havola nomi |
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1 | 1. Artikov A. Introduction to systematic analysis. Certificate of Deposit of Copyright objects № 000300. Agency for Intellectual Property of the Republic of Uzbekistan, 10.11.2016. |
2 | 2. Artykov A. Computer methods of analysis and synthesis of chemical and technological systems. Tashkent "Voris Nashriet" 2010.. 160 p. |
3 | 3. System analysis of pneumoseparation of bulk materials in fluidized layer. / Yunusov B.I., Karabaev D.T., Artikov A.A. TashGTU // Kimeviy Tekhnologii. Nazat va Boshkaruv. 1/2011. |
4 | 4. Formalization of mathematical model of process of air separation of loose materials / D.T. Karabaev, B.I. Yunusov, A.Artikov... // Sixth World Conference on Intelligent Systems for Industrial Automation.- Tashkent, Uzbekistan November 25-27, 2010. |
5 | 5. The Mathworks Inc., "MATLAB - The Language of Technical Computing", http://www.mathworks.com/products/matlab. |
6 | 6. Lees, F. P. (1984). Process computer alarm and disturbance analysis: Outline of methods for systematic synthesis of the fault propagation structure. // Computers and Chemical Engineering, 8(2), 91-103. doi:10.1016/0098-1354(84)87016-7 |
7 | 7. Tula, A. K., Eden, M. R., & Gani, R. (2019). ProCAFD: Computer-aided tool for sustainable process synthesis, intensification and hybrid solutions doi:10.1016/B978-0-12-818634-3.50081-3 Retrieved from www.scopus.com |
8 | 8. Tula, A. K., Babi, D. K., Bottlaender, J., Eden, M. R., & Gani, R. (2017). A computer-aided software-tool for sustainable process synthesis-intensification. // Computers and Chemical Engineering, 105, 74-95. doi:10.1016/j.compchemeng, 2017.01.001 |
9 | 9. Rakhmonov, I.U.; Niyozov, N.N.; and Ли, К. (2019) DEVELOPMENT OF CORRELATION AND REGRESSION MODELS OF ELECTRIC ENERGY INDICATORS OF THE EQUIPMENT WITH CONTINUOUS NATURE OF PRODUCTION, // Technical science and innovation: Vol. 2019 : Iss. 4 , Article 2. Available at: https://uzjournals.edu.uz/btstu/vol2019/iss4/2 |
10 | 10. Usmonov, N.O.; Sanayev, Sh.S.; and Yusupov, Z. (2019) CALCULATION OF TEMPERATURE OF ROUTINE WATER COOLED IN IRRIGATED LAYERS, // Technical science and innovation: Vol. 2019 : Iss. 3 , Article 7. Available at: https://uzjournals.edu.uz/btstu/vol2019/iss3/7 |
11 | 11. Misrikhanov, M. Sh. and Khamidov, Sh.V. (2019) MATHEMATICAL POWER FLOW MODEL IN AN ELECTRICAL SYSTEM CONTAINING A SERIAL COMPENSATOR THRISTOR CONTROLLED REACTIVE COMPONENT,//Technical science and innovation: Vol. 2019 : Iss. 3 , Article 5. Available at: https://uzjournals.edu.uz/btstu/vol2019/iss3/5 |
12 | 12. Eshbaeva, U.J.; Shin, I.G.; and Djalilov, A.A. (2019) OPTIMIZATION OF COLOR PERCEPTION PROCESS IN THE PRINT PRODUCT BY THE STEEP CLIMBING METHOD BY BOX-WILSON, Technical science and innovation: Vol. 2018 : Iss. 4 , Article 2. Available at: https://uzjournals.edu.uz/btstu/vol2018/iss4/2 |
13 | 13. Bobomurodov, Q.H.; Razakov, J.Kh.; Bobomurodov, S.Q.; and Shokirov, R.A. (2019) METHODS FOR RESEARCHING THE LOCALIZATION AND DELOCALIZATION OF CARRIERS IN YBA2CU3O6+X FILMS, // Technical science and innovation: Vol. 2019 : Iss. 4 , Article 7. Available at: https://uzjournals.edu.uz/btstu/vol2019/iss4/7. |