تعداد نشریات | 31 |
تعداد شمارهها | 748 |
تعداد مقالات | 7,112 |
تعداد مشاهده مقاله | 10,245,903 |
تعداد دریافت فایل اصل مقاله | 6,899,609 |
Regulation of hydrocyclone parameters to improve the quality of water purification on drip irrigation systems | ||
Caspian Journal of Environmental Sciences | ||
دوره 21، شماره 4، دی 2023، صفحه 787-799 اصل مقاله (1.35 M) | ||
نوع مقاله: Research Paper | ||
شناسه دیجیتال (DOI): 10.22124/cjes.2023.7129 | ||
نویسندگان | ||
A.A. Kalashnikov* ؛ N.A. Abduramanov؛ P.A. Kalashnikov؛ A.E. Baizakova؛ N.V. Denisyuk | ||
Kazakh Scientific Research Institute of Water Economy, LLP, Taraz, Kazakhstan | ||
چکیده | ||
The reliability of drip irrigation systems depends on the quality of water purification of the water sources used. The degree of its purification is a particularly important factor affecting the performance of all components of irrigation systems, including droppers. The purpose of the study was to assess the applicability of a hydrocyclone with adjustable parameters to improve the quality of water purification in drip irrigation systems. The research was carried out using the method of comparative tests of various configurations of sections of the inlet pipe of the hydrocyclone, considering changes in their angle of inclination along the vertical plane and changes in the depth of immersion of the drain pipe. By changing the configuration of the inlet pipe of the hydrocyclone, the angle of deviation along the vertical (θº) and horizontal (φº) planes, as well as the depth of immersion of the drain pipe (ac), the effect on the distribution of the flow rates between the discharge holes required for the quality of cleaning has been established. It has been found that the greatest clarification of water is provided with the semicircular shape of the inlet pipe, with the inclination of the inlet pipe along the vertical plane θº = 20 ... 40, with the immersion of the drain pipe to the interface plane of the cylindrical and conical parts of the hydrocyclone. | ||
کلیدواژهها | ||
Drip irrigation system؛ Hydrocyclone؛ Cleaning quality | ||
مراجع | ||
Abduramanov, AA & Abduramanov, NA 2006, Equation of characteristics of two-surface hydraulic elevators. In: Problems of water management: Proceedings of the international research and practice conference dedicated to 95th Anniversary of Academician RJ Zhulaev, TarGU im, MKh Dulati, Taraz, Kazakhstan, pp. 35-37, [In Russian].
Abduramanov, NA 2012, Hydroclones and hydroclone pump installations in agricultural water supply and watering pastures systems. Format-Print, Taraz, Kazakhstan, 136 p.
Abramov, NN 1982, Vodosnabzhenie (Water supply). Stroiizdat, Moscow, USSR, 440 p.
Alwin, A, Cahyono, T, Sya’ban, A & Dahlia, S 2023, Ground water quality in Ciracas sub-district, East Jakarta, Indonesia. Caspian Journal of Environmental Sciences, 21: 349-354.
Angold, YeV & Zharkov, VA 2014, Special features of drip-sprinkler irrigation technology. Water Science and Technology-Water Supply, 14: 841-849, http://dx.doi.org/10.2166/ws.2014.041.
Angold, YeV, Zharkov, VA, Kalashnikov, AA & Balgabayev, NN 2016, Features of impulse sprinkling technology. Water Science and Technology-Water Supply, 16: 1178-1184.
Banerjee, C, Dubey, RK & Majumder, AK 2017, Phenomenological study on fine particle misplacement behavior in hydrocyclone. Transactions of the Indian Institute of Metals, 70: 313-322, https://doi.org/10.1007/s12666-016-0993-6.
Bing, L, Luncao, L, Huajian, W, Zhenjiang, Z & Yaoguang, Q 2020, Numerical simulation and experimental study on internal and external characteristics of novel Hydrocyclones. Heat and Mass Transfer, 56: 1875-1887, https://doi.org/10.1007/s00231-020-02825-w.
Fatih Ali, S, Hamud Hays, H, Abdul-Jabar, R 2021, Application of CCME water quality index for drinking purpose in Tigris River within Wasit Province, Iraq. Caspian Journal of Environmental Sciences, 19: 781-787.
Fominykh, AM 1985, Intensification of suspension separation processes in natural water treatment technology. Author's abstract of a Dr. Tech. Sci. Dissertation, All-Union Research Institute of Water Supply, Sewerage, Hydraulic Structures and Engineering Hydrogeology, Moscow, USSR, 44 p, [In Russian].
Gartsiyanova, K, Gencev, S & Kitev, A 2023, Transboundary river water quality as a core indicator for sustainable environmental development in Europe: A case study between republics of Bulgaria and Serbia. Caspian Journal of Environmental Sciences, 21: 291-300.
Jabagiyeva, KR, Abduramanov, A, Zhundibaeva, BK & Zhumadilova, AK 2016, Theoretical basis of head loss definition in hydrocycle. Global Journal of Pure and Applied Mathematics, 12: 575-584.
Kalashnikov, A, Balgabaev, N, Zharkov, V, Angold, Y & Kalashnikov, P 2022, Water saving with combined irrigation methods. OnLine Journal of Biological Sciences, 22: 415-424.
Kalashnikov, AA, Kalashnikov, PA & Baizakova, AE 2017, Resource-saving technology and an efficient drip irrigation system based on renewable energy sources. Ecology, Environment and Conservation, 23: 766-779.
Kalashnikov, AA, Kalashnikov, PA, Baizakova, AE & Kurtebayev, BM 2020, Application of energy efficient drip irrigation system in foothill districts of Almaty region. Journal of Advanced Research in Dynamical and Control Systems, 12: 180-190.
Kasymbekov, ZhK 1999, Hydrocyclone-ejector technologies for lifting water and cleaning water supply facilities. IC “Akva”, Taraz, Kazakhstan, 210 p, [In Russian].
Krokhina, AV, Lvov, VA & Pavlikhin, GP 2017, A probabilistic-statistical model of the particle classification process in small hydrocyclone classifiers. Chemical Engineering and Technology, 40: 967-972, http://dx.doi.org/10.1002/ceat.201600602.
Kryazhevskikh, NF & Kryazhevskikh, FN 2000, Intensification of the work of group water pipelines. Sovetskaya Kuban, Krasnodar, Russia, 365 p, [In Russian].
Matkovskii, KA 1966, Hydrocyclone for soil classification and pulp thickening. In Hydromechanization and prospects for its further development in agriculture. Moscow, 17 p, [In Russian].
Naidenko, VV 1976, Application of mathematical methods and computers to optimize and control the processes of suspension separation in a hydrocyclone. Volgo-Vyatskoye kn. izd-vo, Gorkii, USSR, 285 p, [In Russian].
Naidenko, VV 1981, Research and industrial application of hydrocyclones. NP, Gorkii, USSR, 267 p, [In Russian].
Ongayev, M, Denizbayev, S, Umbetkaliyev, N, Yesmagulova, B, Shadyarov, T & Ozhanov, G 2022, The zonality of underground water supply sources for pastures in the West Kazakhstan region. Journal of Ecological Engineering, 23: 56-65. https://doi.org/10.12911/22998993/150612.
Povarov, AI 1971, The technological foundations of centrifugal classification. Author's abstract of a Dr. Tech. Sci. Dissertation, Leningrad Mining Institute named after G. V. Plekhanov, Leningrad, USSR, 52 p, [In Russian].
Rietema, K 1961, Performance and design of hydrocyclones. Chemical Engineering Science, 15: 298-325.
Romenskii, AA 1971, Research of hydrodynamics and separation in hydrocyclones. Author's abstract of a Cand. Tech. Sci. thesis, Leningrad Polytechnic Institute named after M. I. Kalinin, Leningrad, USSR, 20 p, [In Russian].
Sabbagh, R, Koch, CR, Lipsett, MG & Nobes, DS 2017, Hydrocyclone equivalent settling area factor at higher concentrations and developing a performance chart. Separation and Purification Technology, 182: 171-184. http://dx.doi.org/10.1016/j.seppur.2017.02.054.
Skirdov, IV & Ponamarev, VG 1975, Wastewater treatment in hydrocyclones. Stroiizdat, Moscow, USSR, 176 p, [In Russian].
Vakamalla, TR, Koruprolu, VBR, Arugonda, R & Mangadoddy, N 2017, Development of novel hydrocyclone designs for improved fines classification using multiphase CFD model. Separation and Purification Technology, 175: 481-497, http://dx.doi.org/10.1016/j.seppur.2016.10.026.
Wang, H, Ling, G, Hu, M, Wang, W & Hu, X 2022, Physical clogging characteristics of labyrinth emitters under low-quality (sand-laden water) irrigation. Agronomy, 12: 1615. https://doi.org/10.3390/agronomy12071615.
Xu, Y, Song, X, Sun, Z, Tang, B & Yu, J 2017, Steady-state distribution of air-core in a hydrocyclone. Canadian Journal of Chemical Engineering, 95: 757-766. https://doi.org/10.1002/cjce.22720.
Yakovlev, SV & Kalitsun, VI 1972, Mechanical wastewater treatment. Stroiizdat, Moscow, USSR, 199 p, [In Russian].
Yakubovich, VV & Meshcheryakov MP, 2012, The technology of complex irrigation water purification with resource-saving irrigation methods for agricultural crops. News of the Nizhnevolzhsky Agro-University Complex: Science and Higher Professional Education, 2: 1-5, [In Russian].
Yufin, AP 1974, Hydromechanization. Stroiizdat, Moscow, USSR, 223 p, [In Russian].
Zhou, B, Li, Y, Liu, Y, Xu, F, Pei, Y & Wang, Z 2015 Effect of drip irrigation frequency on emitter clogging using reclaimed water. Irrigation Science, 33: 221-234. http://dx.doi.org/10.1007/s00271-015-0461-9.
Zhurba, MG 2003, Water intake and treatment facilities and devices. Astrel i Ast., Moscow, Russia, 569 p, [In Russian]. | ||
آمار تعداد مشاهده مقاله: 374 تعداد دریافت فایل اصل مقاله: 416 |