NEFT-GAZ SANOATIDA ALYUMINIY SAQLOVCHI  ADSORBENTLARNI QAYTA ISHLASH TEXNOLOGIYASINI ISHLAB CHIQISH

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16 декабр 2025

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NEFT-GAZ SANOATIDA ALYUMINIY SAQLOVCHI ADSORBENTLARNI QAYTA ISHLASH TEXNOLOGIYASINI ISHLAB CHIQISH

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MAQOLA ANNOTATSIYASI

Ushbu tadqiqotda neft-gaz sanoati alyuminiy saqlovchi chiqindilaridan sintez qilingan polialyuminiyxlorid olish va uning tabiiy hamda oqava suvlar-ni koagulyatsiya qilishdagi samaradorligi baholandi. Xomashyo sifatida ishlatilgan alyuminiy saqlovchi adsorbentlarga natriy gidroksid va xlorid kislotasi eritmalari bilan nazorat ostidagi harorat rejimida kimyoviy ishlov berildi. Sintez natijasida faol alyumo-oksixlorid fazasi hosil bo‘ldi, bu termogravimetrik, differensial-termik va mikrotuzilma tahlillari bilan tasdiqlandi. Olingan koagulyant bir jinsli mikrotu- zilma va barqaror fazaviy tarkibga ega bo‘lib, koagulyatsiya jarayonlarida yuqori samaradorlikni ta’minlaydi. Polialyuminiyxloridning optimal dozasi taxminan 1,25 g/dm³ ni tashkil etadi, biroq u boshlang‘ich suv tarkibiga, xususan, suspenziya zarrachalari konsentratsiyasi va pH qiymatiga bog‘liq. Optimal sharoitlarda tozalash natijasida 95 %gacha suspenziya zarrachalari olib tashlanadi. Ishlab chiqilgan texnologiya barqarorligi va iqtisodiy maqsadga muvofiqligi bilan ajralib turadi hamda alyuminiy saqlovchi chiqindilarni qayta ishlash imkonini beradi. Olingan natijalar mahalliy polialyuminiyxloridni tabiiy va oqava suvlarni tozalashda qo‘llash istiqbolliligini tasdiqlaydi. Texnologiya barqarorligi, ekologik maqsadga muvofiqligi va suv tayyorlash korxonalari uchun import o‘rnini bosish salohiyati bilan tavsiflanadi.

MUALIFLAR

Teglar

# коагуляция# coagulation# эффективность# сточные воды# очистка# wastewater# samaradorlik# ekologiya# tozalash# взвешенные вещества# ef�iciency# алюмосодержащие отходы# aluminum-containing waste# полиалюминийхлорид# природные воды# экология термогравиметрический а# SEM/EDS.# polialyuminiyxlorid# alyuminiy saqlovchi chiqindilar# koagulyatsiya# tabiiy va oqava suvlar# suspenziya zarrachalari# termogravimetrik tahlil# polyaluminumchloride# natural water# puri�ication# suspended solids# environmental impact# thermogravimetric analysis

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https://eroi.uz/11.0094/A1225-0011

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Foydalanilgan adabiyotlar

Aghyani, R., et al. (2023). Comparative study of poly aluminum ferric and polyaluminum chloride coagulants in industrial wastewater. Environmental Engineering & Environmental Research.

Boykova, T. E., Bogdanovich, N. I., & Vorontsov, K. B. (2019). Efficiency of coagulant application in water treatment for pulp and paper industry in northern conditions. Lesnoy Zhurnal [Forestry Journal], 1, 141. https://doi.org/10.17238/issn0536-1036.2019.1

Domashenko, Yu. E., & Vasiliev, S. M. (2020). Studies on optimizing coagulation treatment of livestock wastewater using oxychloride coagulant. Russian Research Institute of Land Reclamation.

GOST 32170-2013. (2013). Drinking water: Methods for determining residual aluminum. Standartinform.

Guamán-Lozada, D. F., et al. (2025). A hybrid genetic algorithm–neural network approach to optimize PAC dosage in wastewater treatment. Mathematics, 13(8), Article 179.

He, J., et al. (2023). Preparation and coagulation performance of a highly efficient coagulant for wastewater treatment and phosphate removal. Scientific Reports, 13, Article 9957236.

Karim, M. A., et al. (2024). Economically viable liquid polyaluminum chloride (PAC) formulations for industrial effluent treatment. Journal of Water and Environmental Technology.

Kaunisto, K., et al. (2023). Evolution of alumina phase structure in thermal plasma processing. Journal of Thermal Analysis and Materials.

Kolova, A. F., Pazenko, T. Ya., & Fedotova, Yu. V. (2014). Development of local wastewater treatment technology at a synthetic rubber plant. Bulletin of IrGTU [Bulletin of Irkutsk State Technical University], 10, 156–164.

Kononchuk, V. I. (2019). Thermal transformations and structural evolution of transition aluminas. Materials Chemistry Series.

Kononchuk, V. I., & Smirnov, A. Yu. (2021). Chemistry of activated alumina: Phase transitions and surface reactivity. Industrial Chemistry Review.

Kovarik, L., Bowden, M. E., & Szanyi, J. (2021). High temperature transition aluminas in γ-Al₂O₃: A review. OSTI Report.

Krupińska, I., & Kowalski, P. (2023). Preparation and performance evaluation of highly polymerised PACs. Applied Water Science.

Krupińska, I., et al. (2023). Suitability of highly polymerised polyaluminium chlorides for wastewater treatment. Water.

Kuzin, E. N. (2019). Complex coagulants in the processes of wastewater treatment from suspended solids. D. I. Mendeleev University of Chemical Technology. https://doi.org/10.25702/ KSC.2307-5252.2019.10.1

Li, H., et al. (2019). Thermal treatment of γ-Al₂O₃ for the preparation of dense alumina parts. Frontiers in Materials, 6, Article 295. https://doi.org/10.3389/fmats.2019.00295

Sajath, S. H. M., et al. (2022). Handling the sludge when using polyaluminum chloride: Aluminum levels and reuse strategies. NEPT Journal.

Tashlanov, A. N., & Khamraev, D. U. (2021). Production of coagulants from technogenic raw materials and their application in water purification. Chemical Technology, 3, 45–52.

Vorobeva, L. A., & Chernyshev, S. V. (2020). Adsorption and coagulation methods of water purification. Politek-Press.

Yakovlev, A. S. (2018). Coagulants based on aluminum salts: Properties and applications. Khimiya.

Youssef, H. H., Younis, S. A., El-Fawal, E. M., Ali, H. R., Moustafa, Y. M., & Mohamed, G. G. (2023). Synthesis of polyaluminum chloride coagulant from waste aluminum foil and utilization in petroleum wastewater treatment. Separations, 10(11), Article 570. https://doi.org/10.3390/ separations10110570

Yusupov, K. A. (2022). Study of thermogravimetric properties of aluminum oxides obtained from oil refinery waste. Water Chemistry and Technology, 2, 30–36.