VERTIKAL DRENAJ TIZIMLARIDA ENERGIYA TEJAMKOR TEXNOLOGIYA

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26 декабр 2024

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VERTIKAL DRENAJ TIZIMLARIDA ENERGIYA TEJAMKOR TEXNOLOGIYA

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MAQOLA ANNOTATSIYASI

Maqolada oqim energiyasidan foydalanadigan oqimchali nasosning sug‘orish va melioratsiya tizimidagi vertikal drenajlarning energiya samaradorligini oshirish maqsadida amaliyotda qo‘llanishi bo‘yicha o‘tkazilgan tadqiqot natijalari bayon etilgan. Bugungi kunda elektr energiyasiga bo‘lgan talabning ortib borishi va narxining oshishi melioratsiya hamda sug‘orishda ishlatilayotgan nasoslarning energiya sarfini kamaytirish uchun energiya tejamkor mexanizmlardan foydalanish zaruratini taqozo etmoqda. Oqimchali nasosni amaliyotda qo‘llash ishlari Sirdaryo viloyati Guliston shahar hududidagi vertikal drenajda amalga oshirilib, tabiiy dala sharoitida gidravlik parametrlar suv sarfining 0,8–1,6 l/s gacha va quvurdagi bosimi 0,5–1,0 atm gacha oralig‘ida sinov ishlari olib borildi. Dala va laboratoriya tadqiqot natijalari o‘zaro qiyosiy baholanib, nisbiy sarf va nisbiy napor orasidagi bog‘lanishlar olingan. Ularning aniqlilik darajasi koreliatsiya koeffitsiyenti (R2 = 0,91) orqali asoslangan. Oqimchali nasoslarni vertikal drenajlarda qo‘llash bo‘yicha shartlar va tavsiyalar qayd etilgan.

MUALIFLAR

Teglar

# энергоэффективность# groundwater level# energiya tejamkor# nisbiy sarf# струйный насос# jet pump# vertikal drenaj quduq# sizot suvlar sathi# oqim energiyasi# oqimchali nasos# injeksiya koeffitsiyenti# вертикальная дренажная скважина# уровень грунтовых вод# энергия потока# коэффициент инжекции# относительный расход# vertical drainage well# flow energy# energy efficient# coefficient injection# relative efficiency

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https://eroi.uz/11.0094/A1224-0001

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Foydalanilgan adabiyotlar

A khmedov, I., & Mirkhasilova, Z. (2021). Construction of vertical drainage wells using corrosion resistant materials. E3S Web of Conferences (CONMECHYDRO-2021), 264, 04016. https://doi. org/10.1051/e3sconf/20212640401

An, Zh., & Liang, W. (2015). Research on Status and Development of Jet Pump. Proceedings of the International Conference on Mechatronics, Electronic, Industrial and Control Engineering (MEIC-2015). https://doi.org/10.2991/meic-15.2015.348

Arifjanov, A. M., Rahimov, Q. T., & Abduraimova, D. A. (2017). Hydrotransport of exceptional flow in pipelines with various pulls. European Science Review, 124-126. Austria, Vienna.

Boehmer, W. K., & Boonstra, J. (1994). Tubewell Drainage Systems (Chapter 22, pp. 931–964.). In: H. P. Ritzema (ed.). Drainage Principles and Applications (16th ed.).,Wageningen, The Netherlands: International Institute for Land Reclamation and Improvement (ILRI).

El-Sawaf, A., Halawa, M. A., Younes, M. A., & Teaima, I. R. (2011). Study of the different parameters that influence on the performance of water jet pump. Proceedings of the 15th International Water Technology Conference (IWTC-15). Alexandria, Egypt.

Gasanov, S. T. (2012). Vacuum wells and their calculation. (In Russian). Science Perspectives, 7 (4).

Hassan, A. H., Eissa, M. Sh., & Aissa, W. A. (2021). Parametric Study of Water Jet Pump Performance. International Journal of Applied Energy Systems, 3 (2), 35-41. http://dx.doi. org/10.21608/ijaes.2021.80330.1003

Li, Ch. Shi, W. & Cao, W (2006). The principle and design of waste gas jet self-priming device. Pump Technology, 1, l3–14.

Long, X., Zhang, J., Wang, Q., Xiao, L., Xu, M., Lyu, Q., & Ji, B. (2016). Experimental investigation on the performance of jet pump cavitation reactor at different area ratios. Experimental Thermal and Fluid Science, 78, 309-321. https://doi.org/10.1016/j.expthermflusci.2016.06.018

Rakhimov, K., Otakhonov, M., & Sultonov, R. (2024a). Importance of vertical drainage wells in irrigated fields. Proceedings of the International Conference on Thermal Engineering (ICTEA), 1 (1). https://journals.library.torontomu.ca/index.php/ictea/article/view/2285/1920

Rakhimov, K. T., Otakhonov, M. Yu., & Sultonov, R. S. (2024b). Technology of 100 jet pump application to improve efficiency of vertical drainage. (In Uzbek). Science and Innovative Development, 7 (3), 100-109. https://cyberleninka.ru/article/n/vertikal-drenaj-samaradorliginioshirishda-oqimchali-nasos-qo-llash-texnologiyasi

Rakhimov, K., & Sultanov, R. (2023). Use of jet pump in vertical drainage systems. E3S Web of Conferences (CONMECHYDRO-2023), 401, 03074. https://doi.org/10.1051/ e3sconf/202340101048

Rakhimov, Q., Ahmedkhodjaeva, I., Rakhimov, A., Abduraimova, D., & Latipov, N. (2022). Influence of kinematic flow parameters on vacuum in jetters. AIP Conf. Proc., 2432, 030068. https:// doi.org/10.1063/5.0089505

Raximov Q., & Abduraimova D. (2020). Determination of water consumption of a jet device taking into account turbidity. (In Uzbek). Irrigation and Land Reclamation, 1 (19), 41-44.

Raximov, Q., Otaxonov, M., Xudoyshukurov, Q., Abduraimova, D., & Ataqulov, D. (2020). Determination of water consumption in the suction pipe of a jet apparatus. (In Uzbek). Agriculture and Water Management of Uzbekistan, 9, 44-45.

Song, X., Park, J., Kim, S., & Park, Y. (2013). Performance comparison and erosion prediction of jet pumps by using a numerical method. Mathematical and Computer Modelling, 57 (1–2), 245-253. https://doi.org/10.1016/j.mcm.2011.06.040

Teamia, I. R., Younes, M. A., El-Sawaf, I. A., & Halawa, M.A. (2012). Experimental study of the effect of mixing chamber length and diffuser angle on the performance of dredging jet pump. Proceedings of the 16th International Water Technology Conference (IWTC-16). Istanbul, Turkey. https://www.semanticscholar.org/paper/EXPERIMENTAL-STUDY-OF-THE-EFFECT-OF-MIXINGCHAMBER-Teamia-Younes/1b1db0722929e19a571bc503d67fabaa851c62cf?utm_source=direct_link

Winoto, S. H., Li, H., & Shah, D. A. (2000). Efficiency of Jet Pumps. Journal of Hydraulic Engineering, 126 (2). https://doi.org/10.1061/(ASCE)0733-9429(2000)126:2(150)

Zhang, F., & Yang, J. (2000). Concrete jet pump device theory design. Fluid Machinery, 28 (2), 26-28.

Zhu, X., Wang, D., Xu, C., Zhu, Y., Zhou, W., & He, F. (2018). Structure influence on jet pump operating limits. Chemical Engineering Science, 192, 143-160. https://doi.org/10.1016/j. ces.2018.05.054