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Мақолада пахта тозалаш корхоналаридан чиқаётган чанг ҳаво тозалаш циклонлари чуқур таҳлил қилинган. Пахта тозалаш корхоналаридан чиқаётган чанг ҳаво оқимининг таркиби, ҳарорати ва тезликлари ўрганилган. Чанг ҳаво таркибига қараб, циклон сепараторигача бир неча такомиллаштирилган янги агрегат лойиҳаланган. “SOLIDWORKS Flow Simulation” дастури орқали циклонда ҳаво оқимини чангдан тозаловчи агрегат конструкциясининг янги модели ишлаб чиқилиб, лойиҳаланган янги моделлар ичидан энг юқори тозалаш самарадорлигига эга бўлган агрегат танлаб олинган. Такомиллаштирилган циклон сепараторининг ишлаш жараёни “SOLIDWORKS” дастуридаги “Flow Simulation” функцияси орқали симуляция қилиниб, натижалар қўлга киритилган. “SOLIDWORKS Flow Simulation” моделидаги тезлик конструктив қийматлар Navier-Stokes тенгламалари ёрдамида назарий ҳисоб-китоб қилинган. Шунингдек, агрегат ичидаги чанг заррачалари босими, ҳарорати, тезлиги ва уларга кўра динамик ёпишқоқлиги ўрганилиб, натижалар олинган.

  • O'qishlar soni33
  • Nashr sanasi14-04-2023
  • Asosiy tilO'zbek
  • Sahifalar30-41
Ўзбек

Мақолада пахта тозалаш корхоналаридан чиқаётган чанг ҳаво тозалаш циклонлари чуқур таҳлил қилинган. Пахта тозалаш корхоналаридан чиқаётган чанг ҳаво оқимининг таркиби, ҳарорати ва тезликлари ўрганилган. Чанг ҳаво таркибига қараб, циклон сепараторигача бир неча такомиллаштирилган янги агрегат лойиҳаланган. “SOLIDWORKS Flow Simulation” дастури орқали циклонда ҳаво оқимини чангдан тозаловчи агрегат конструкциясининг янги модели ишлаб чиқилиб, лойиҳаланган янги моделлар ичидан энг юқори тозалаш самарадорлигига эга бўлган агрегат танлаб олинган. Такомиллаштирилган циклон сепараторининг ишлаш жараёни “SOLIDWORKS” дастуридаги “Flow Simulation” функцияси орқали симуляция қилиниб, натижалар қўлга киритилган. “SOLIDWORKS Flow Simulation” моделидаги тезлик конструктив қийматлар Navier-Stokes тенгламалари ёрдамида назарий ҳисоб-китоб қилинган. Шунингдек, агрегат ичидаги чанг заррачалари босими, ҳарорати, тезлиги ва уларга кўра динамик ёпишқоқлиги ўрганилиб, натижалар олинган.

Русский

В статье выполнен подробный анализ циклонов очистки запыленного воздуха, выходящего из хлопкоочистительных предприятий. Исследованы состав, температура и скорость пылевоздушного потока, выходящего из хлопкоочистительных предприятий. В зависимости от состава запыленного воздуха разработан новый агрегат с рядом усовершенствований вплоть до циклонного сепаратора. При помощи программы SOLIDWORKS Flow Simulation разработана новая модель конструкции агрегата очистки запыленного воздушного потока в циклоне, и среди новых разработанных моделей выбран узел с наибольшей эффективностью очистки. Проект усовершенствованного нового агрегата циклонного сепаратора был симулирован с использованием программного обеспечения SOLIDWORKS Flow Simulation, получены результаты. Конструктивные значения скоростей в модели SOLIDWORKS Flow Simulation были теоретически рассчитаны с использованием уравнений Navier – Stokes. Также были изучены давление, температура, скорость и на их основании динамическая вязкость частиц пыли внутри установки, получены соответствующие результаты.

English

A detailed analysis of cyclones for cleaning dusty air coming out of ginneries has been provided in this article. The composition, temperature and speed of the dusty airflow coming out of ginneries have been studied. Depending on the composition of the dusty air, a new unit has been developed with a number of improvements up to the cyclone separator. With the help of the SOLIDWORKS Flow Simulation program, a new model for the design of a unit for cleaning a dusty air flow in a cyclone was developed, and a unit with the highest cleaning efficiency was selected among the new developed models. The design of an improved new cyclone separator unit has been simulated using SOLIDWORKS Flow Simulation software and the results were obtained. The design values of speeds in the SOLIDWORKS Flow Simulation model were theoretically calculated using the Navier-Stokes equations. The pressure, temperature, speed, on their basis, the dynamic viscosity of dust particles inside the unit have been studied, and the results have been obtained.

Muallifning F.I.Sh. Lavozimi Tashkilot nomi
1 Murodov O.J. texnika fanlari bo‘yicha falsafa doktori (PhD), dotsent Toshkent to‘qimachilik va yengil sanoat instituti
2 Saidova N.A. doktorant Buxoro muhandislik-texnologiya instituti
Havola nomi
1 Abbazov, I., Sarimsakov, O., Hodzhiev, M. & Mardonov, B., 2018. Effective Cleaning of Cotton Waste Produced at Cotton Cleaning Factories. AASCIT Communications, 23 March, 5(2), pp. 22-28.
2 ACHK Limited Liability Company, 2022. Official website of ACHK LLC. [Online] Available at: https:// acnkru.ru/ [Accessed 5 February 2022].
3 Elsayed, K. & Lacor, C., 2010. Optimization of the cyclone separator geometry for minimum pressure drop using mathematical models CFD simulations. Chemical Engineering Science, 65(22), pp. 6048-6058.
4 Gaziyeva, S.A., Kurbonov, B.D., Nurov, M.E. & Ibrogimov , K., 2013. Izmeneniye strukturnogo pokazatelya hlopka-syrtsa po tehnologicheskim perekhodam ego pererabotki. Izvestiya of Higher Educational Institutions. Textile Industry Technology, Volume 5 (347), pp. 131-135.
5 Hoekstra, J. A., Derksen, J. J. & Van Den Akker, A. H. E., 1999. An experimental and numerical study of turbulent swirling flow in gas cyclones. Chemical Engineering Science, Volume 54, pp. 2055-2065.
6 Ilkhom, A., Muksin, X., Orof, A. & Ruxsora, K., 2019. The composition of releasing passion of dusty in the process of pat. International Journal of Engineering and Advanced Technology, 8(3S), pp. 279-283.
7 Khodjiev, M., Abbazov, I., Alimov, O. & Karimov, J., 2019. Fraction structure of cotton cleaning equipment in cotton enterprises and their cleaning effectiveness. International Journal of Advanced Research in Science, Engineering and Technology, January, 6(1), pp. 2350-0328.
8 Khodjiev, M.T., Murodov, O.J., Eshmurodov , D. D. & Eshnazarov, D. A., 2020. Tests in the insulating cameras of the improved separator. s.l., IOP Publishing Ltd, p. 032025.
9 Korabelnikov, A., Lebedev, D. & Shutova, A., 2012. Allocation of trash impurities from the surface of a layer of fibrous material. Proceedings of higher educational institutions. Textile industry technology, 4(340), pp. 143-147.
10 Morsi, S.A. & Alexander, A.J., 1972. An investigation of particle trajectories in two-phase flow systems. Journal of Fluid Mechanics, 55(02), pp. 193-208.
11 Murodov O.Zh., Saidova N.A., Adilova A.Sh., 2022. Analiz teoreticheskikh i prakticheskikh issledovaniy po ochistke vozdukha ot pyli pri pervichnoy pererabotke khlopka. Kursk, Southwestern State University, pp. 283-286.
12 Murodov, O., 2021. Development of an effective design and justification of the parameters of the separation and cleaning section of raw cotton. Journal of Physics: Conference Series, Apr, 1889(4), p. 042012.
13 Murodov, O. & Adilova , A.S., 2022. Pahtani qayta ishlashda chiqayotgan changli chiqindilarni tarkibini tahlili. Tashkent, Tashkent Textile and Light Industry Institute, pp. 289-292.
14 Murodov, O. & Adilova, A., 2022. Primeneniye formuly Eylera – Lagranzha dlya rascheta potoka chastits v tsiklone. Kursk, Southwestern State University, pp. 57-61.
15 Murodov, O.D., Khojiev, M.T., Juraev, A.D. & Rakhimov, A.K., 2019. Development of design and substantiation of the parameters of the separator for fibrous materials. International Journal of Recent Technology and Engineering, 8(2), pp. 5806-5811.
16 Murodov, O.J. & Adilova, A.S., 2022. Tolali chiqindilar bo’lgan changli havo tarkibini organishda olib borilgan nazariy tadqiqotlar. Tashkent, Tashkent Institute of Light and Textile Industry, pp. 262-263.
17 Murodov, O.J., 2022. Sovershenstvovaniye konstruktsii i obosnovaniye parametrov separatora khlopka-syrtsa. Proceedings of Higher Educational Institutions, Series Technology of the Textile Industry, 1(397), pp. 248-253.
18 Murodov, O.J. & Adilova, A.S., 2021. Estimation of cyclone gas flow parameters and development of new technical solutions for dust collectors. Fergana, s.n., pp. 36-40.
19 Murodov, O.J. & Adilova, A.S., 2022. Evaluation of the performance of a cyclone dust collector used to reduce environmental pollution in cotton processing plants. Tashkent, IOP Publishing Ltd, p. 012150.
20 Murodov, O.J. & Adilova, A.S., 2022. Studying the effect of the incoming flow speed on the efficiency of cyclones. Science and innovative development. Science and Innovative Development, 5(4), pp. 28-35.
21 Murodov, O.J. & Adilova, A.S., 2022. The process of interaction of dust particles in a dusty air stream with equipment elements. Сhemical technology. control and management. International scientific and technical journal: Сhemical technology. control and management, 98(2), pp. 12-19.
22 Murodov, O.J. & Adilova, S.A., 2021. Analysis of harmful mixtures in air flow during cotton cleaning. Tashkent, Tashkent state technical university named after Islam Karimov, pp. 79-87.
23 Murodov, O. J. et al., 2021. Analysis of the vibrations of a console column made on a base with non-line protection in gin. Journal of Physics: Conference Series, 1889(4).
24 Murodov, O.J. & Rajabov, O.I., 2021. Rezul’taty eksperimental’nogo issledovaniya nagruzhennosti i kharaktera kolebaniy mnogogrannoy setki na uprugikh oporakh ochistitelya khlopka. Proceedings of Higher Educational Institutions, Series Technology of the Textile Industry, 395(5), pp. 191-197.
25 Murodov, O.J. & Rudovskiy, P.N., K.A.R., 2022. Obosnovaniye parametrov i konechno-elementnoye modelirovaniye dvizheniya khlopkovozdushnoy smesi v separatore khlopka. Proceedings of Higher Educational Institutions, Series Technology of the Textile Industry, 1(397), pp. 266-271.
26 Murodov, O.Z., 2022. Paxtani qayta ishlashda chiqayotgan changli chiqindilar tarkibining tahlili. Tashkent, Tashkent Textile and Light Industry Institute, pp. 289-292.
27 Murodov, O.Z., Saidova, N.A. & Adilova, A.S., 2022. Analiz teoreticheskikh i prakticheskikh issledovaniyh po ochistke vozdukha ot pyli pri pervichnoy pererabotke hlopka. Kursk, Peoples’ Friendship University of Russia, pp. 282-287.
28 Shukla, S.K., Shukla, P. & P., G., 2011. Evaluation of numerical schemes for dispersed phase modeling of cyclone separators. Eng. Appl. Comput. Fluid Mech., 5(2), pp. 235-246.
29 Tashpulatov, D. S. et al., 2018. Design development and parameters calculation methods of plastic diamond pattern bars on resilient supports in ginning machines. IOP Conference Series: Materials Science and Engineering, 459(1).
30 Warzecha, P. & Boguslawski, A., 2010. LES modelling of pulverized coal combustion in O2/CO2 mixture. Arch. Combust., 30(3), pp. 1-5.
31 Xiaodong, L. et al., 2003. Numerical simulation of the effects of turbulence intensity and boundary layer on separation efficiency in a cyclone separator. Chem. Eng. J., Volume 95, p. 235–240.
32 Yunusov, S. et al., 2021. Results of studies on extending the time operation of gin and linter grates. s.l., 2nd International Conference on Energetics, Civil and Agricultural Engineering (ICECAE 2021), pp. 1-14.
33 Zhao, B., 2005. Development of a new method for evaluating cyclone efficiency. Chem. Eng. Process., 44(4), pp. 447-451.
34 Zhao, B., Su, Y. & Zhang, J., 2006. Simulation of gas flow pattern and separation efficiency in cyclone with conventional single and spiral double inlet configuration. Chemical Engineering Research and Design, Volume 84, p. 1158–1165.
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