UYURMALI APPARATLAR SAMARADORLIGINING EKSPERIMENTAL  TADQIQOTLARI VA SANOAT SINOVLARI NATIJALARI

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22 октябр 2025

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UYURMALI APPARATLAR SAMARADORLIGINING EKSPERIMENTAL TADQIQOTLARI VA SANOAT SINOVLARI NATIJALARI

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MAQOLA ANNOTATSIYASI

Mazkur maqolada sanoat chiqindi gazlarini tozalashda qo‘llanayotgan uyurmali apparatlar samaradorligi, konstruksiyaviy afzalliklari va ularning ilmiy-tadqiqot hamda sanoat sinovlaridan olingan natijalari yoritilgan. Navoiy viloyatidagi ekologik muammolarni hal etish maqsadida ishlab chiqilgan texnologik yechimlar asosida chiqindi gazlardan chang, zaharli gazlar va ortiqcha issiqlik ajratib olish imkonini beruvchi uyurmali qurilmalarning modellari ishlab chiqilgan hamda keng ko‘lamli sinovlardan o‘tkazilgan. Tadqiqotlar davomida gaz va suyuqlik fazalarining turli holatdagi harakati, markazdan qochma kuchlar yordamida amalga oshirilgan modda va issiqlik almashinuvi, gazlarni karbonat angidrid gazidan tozalash, quritish jarayonlari hamda sovitish va isitish jarayonlarining intensivligi tahlil qilingan. Uyurmali apparatlar orqali jarayonlar tezligi 4–10 martagacha oshishi, energiya tejamkorligi 2–3 baravar yaxshilanishi va gidravlik qarshilikning nisbatan past bo‘lishi tajribalar asosida aniqlangan. Qurilmalar oddiy va ixcham tuzilishga ega bo‘lib, ekspluatatsiya qilishda kam xarajat talab etadi. Shuningdek, gazlarning suyuqliklar bilan kontaktlashuvi asosida issiqlik almashinuvi va absorbsiyalash jarayonlari samaradorligi ham yuqori ekanligi eksperimental isbotlandi. Tadqiqot natijalariga ko‘ra, ushbu qurilmalar changni 99 %gacha, zaharli gazlarni esa 90–98 %gacha samarali ushlab qoladi. Maqolada keltirilgan ilmiy asoslangan yondashuvlar uyurmali apparatlarning mahalliy va xalqaro sanoat tarmoqlarida keng joriy etilish imkoniyatini tasdiqlaydi. Xulosa sifatida uyurmali texnologiyalar ekologik xavfsizlikni ta’minlashda istiqbolli yechim sifatida tavsiya etiladi.

MUALIFLAR

Teglar

# hydraulic resistance# гидравлическое сопротивление# массообмен# mass transfer# отходящие газы# теплообмен# энергоэффективность# heat exchange# gidravlik qarshilik# вихревой аппарат# vortex apparatus# exhaust gases# modda almashinuvi# issiqlik almashinuvi# uyurmali apparat# chiqindi gaz# changni tozalash# energiya samaradorligi.# очистка от пыли# dust removal# energy ef�iciency

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https://eroi.uz/11.0094/A1025-0011

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Foydalanilgan adabiyotlar

Abdollahi, H., Shahraki, S., & Motahari-Nezhad, M. (2017). A review on the effects of different parameters on contact heat transfer. Thermophysics and Aeromechanics, 24, 499–512. https://doi. org/10.1134/S0869864317040011

Bakhronov, Kh. Sh., Levdanskiy, A. E., & Akhmatov, A. A. (2025). Effektivnostʹ primeneniya vikhrevykh apparatov dlya provedeniya gidrodinamicheskikh, teplo- i massoobmennykh protsessov [Effectiveness of vortex devices for hydrodynamic, heat and mass transfer processes]. Navoi: Science Algorithm.

Bakhronov, Kh. Sh., Sanakulov, K. S., & Akhmatov, A. A. (2021). Vikhrevoy skrubber dlya ochistki i okhlazhdeniya gazov [Vortex scrubber for gas purification and cooling]. Patent No. FAP 01755. Agency for Intellectual Property, Tashkent.

Barabash, P. A., Solomakha, A. S., Gurov, A. I., & Panchenko, O. A. (2020a). Regimes of motion of water-air flow in a short vertical tube with the underfeed of phases. Journal of Engineering Physics and Thermophysics, 93(2), 443–451. https://doi.org/10.1007/s10891-020-02139-y

Barabash, P. A., Solomakha, A. S., Kudelya, P. P., & Panchenko, O. A. (2017). UA Utility Model Patent No. 121684. http://uapatents.com/4-121684-kontaktnijj-teploobminnik.html

Barabash, P., Solomakha, A., & Sereda, V. (2020b). Experimental investigation of heat and mass transfer characteristics in direct contact exchanger. International Journal of Heat and Mass Transfer, 162, 120359. https://doi.org/10.1016/j.ijheatmasstransfer.2020.120359

Bezrodnyy, M. K., Rachinskiy, A. Yu., Goliyad, N. N., & Barabash, P. A. (2015). Eksperimentalʹnoe issledovanie koeffitsientov teplo- i massoobmena pri utilizatsii teploty parogazovogo potoka v fakele kapelʹ mekhanicheskoy forsunki [Experimental investigation of heat and mass transfer coefficients during heat recovery of a steam-gas flow in the spray of a mechanical nozzle]. Vostochno-Evropeyskiy Zhurnal Peredovykh Tekhnologiy [Eastern-European Journal of Enterprise Technologies], 6(78), 50–59. https://doi.org/10.15587/1729-4061.2015.55484

Dalluge, D. L., Whitmer, L. E., Polin, J. P., Choi, Y. S., Shanks, B. H., & Brown, R. C. (2019). Comparison of direct and indirect contact heat exchange to improve recovery of bio-oil. Applied Energy, 251, 113346. https://doi.org/10.1016/j.apenergy.2019.113346

Farakhov, T. M., Afanas’ev, E. P., & Laptev, A. G. (2016). Intensifikatsiya i raschet teploobmena v kanalah s khaotichnymi nasadkami (upakovkami) [Intensi�ication and calculation of heat transfer in channels with chaotic packings]. Nadezhnostʹ i Bezopasnostʹ Energetiki [Reliability and Safety of Energy], (2), 31–33. https://doi.org/10.24223/1999-5555-2016-0-2-42-46

Fei, Y., Xiao, Q.-T., Xu, J.-X., Pan, J.-X., Wang, S.-B., Wang, H., & Huang, J.-W. (2015). A novel approach for measuring bubbles uniformity and mixing efficiency in a direct contact heat exchanger. Energy, 2313–2320. https://doi.org/10.1016/j.energy.2015.10.126

Frolov, A. S., Voinov, N. A., Bogatkova, A. V., et al. (2021). Resistance of tangential swirlers with rectilinear channel walls. Theoretical Foundations of Chemical Engineering, 55, 914–922. https://doi. org/10.1134/S0040579521040254

Kakaç, S., Liu, H., & Pramuanjaroenkij, A. (2020). Heat exchangers (4th ed.). CRC Press. https:// doi.org/10.1201/9780429469862

Lapteva, E. A., & Laptev, A. G. (2016). Models and calculations of the effectiveness of gas and liquid cooling in foam and �ilm apparatuses. Theoretical Foundations of Chemical Engineering, 50(4), 430–438. https://doi.org/10.1134/S0040579516040394

Prodanuks, T., Vitolins, V., Veidenbergs, I., & Blumberga, D. (2017). Comparison of theoretical and practical energy ef�iciency values in indirect contact gas condensing unit. Energy Procedia, 128, 520–524. https://doi.org/10.1016/j.egypro.2017.09.072

Rao, N. M., Maiti, B., & Das, P. K. (2005). Comparison of dynamic performance for direct and fluid coupled indirect heat exchange systems. International Journal of Heat and Mass Transfer, 48, 3244–3252. https://doi.org/10.1016/j.ijheatmasstransfer.2005.02.021

Voinov, N. A., Zemtsov, D. A., Zhukova, O. P., et al. (2019). Hydraulic resistance of tangential swirlers. Chemical and Petroleum Engineering, 55, 51–56. https://doi.org/10.1007/s10556-019- 00584-y

Xu, J.-X., Xiao, Q.-T., Chen, Y., Fei, Y., Pan, J.-X., & Wang, H. (2016). A modified L2-star discrepancy method for measuring mixing uniformity in a direct contact heat exchanger. International Journal of Heat and Mass Transfer, 97, 70–76. https://doi.org/10.1016/j. ijheatmasstransfer.2016.01.064

Xu, J.-X., Xiao, Q.-T., Lv, Z., Huang, J., Xiao, R., & Pan, J. (2019). New metrics for measuring multiphase mixing effects in a direct-contact heat exchanger. Applied Thermal Engineering, 147, 592– 601. https://doi.org/10.1016/j.applthermaleng.2018.10.074

Yusupbekov, N. R., Zokirov, S. G., & Nurmuhamedov, H. S. (2023). Kimyoviy texnologiya asosiy jarayon va qurilmalar (Narziya, hisob, loyiha) [Chemical technology: Basic processes and devices (Theory, calculation, design)]. Tashkent: Sharq.

Zeng, Z., Sadeghpour, A., & Ju, Y. S. (2018). Thermohydraulic characteristics of a multi-string direct-contact heat exchanger. International Journal of Heat and Mass Transfer, 126, 536–544. https:// doi.org/10.1016/j.ijheatmasstransfer.2018.05.060