An innovative idea : Injection valves for irrigation ducts

• Autorzy: Benin Dmitrii M. , Snezhko Vera L.

Identyfikatory

DOI

10.24425/jwld.2022.141575

• Języki publikacji: EN

Abstrakty

EN

More than 4.6 mln ha in the Russian Federation are irrigated. Their culvert hydraulic structures are part of network structures and are the most widespread. After the crisis of the 1990s, proper maintenance of many reclamation systems was impossible due to a lack of funds. This led to the loss of about half of the water taken from irrigation sources in irrigation canals. The planned increase in the technical level of irrigation systems requires the automation of the operation of both the entire system as a whole and separately located culverts. This will avoid significant losses of water supply for irrigation and prevent water shortages with the insufficient discipline of water users. Means of hydraulic automation of water supply are being installed on small irrigation canals in Russia. A water flow regulating valve is proposed, with no mechanical movinparts, and gates are not involved in the control process. The operation of the structure is based on the injection effect, in which excess water entering the downstream with a decrease in water consumption begins to circulate between the outlet section of the transit pipe and the diffuser at the end section of the valve. Using the methods of measuring hydrodynamics and the theory of jet devices, theoretical dependences were obtained, which make it possible to determine the main hydraulic characteristics of the structure. The design form of the flow part of the regulator has been developed and a physical model has been made. In a mirror hydraulic flume, the operation modes of the water outlet were studied with and without regulation. The actual values of hydraulic parameters were obtained, which confirmed the validity of the use of theoretical dependencies. The discrepancy between the theoretical and experimental results is within the experimental error. It has been proven that it is possible to circulate excess water between the downstream and intermediate pools of the regulator.

Słowa kluczowe

EN

automation; hydraulic engineering; hydraulic structure; hydraulics; irrigation; irrigation canal; valve

• Wydawca: Wydawnictwo ITP
• Czasopismo: Journal of Water and Land Development
• Rocznik: 2022
• Tom: no. 54
• Strony: 220--224
• Opis fizyczny: Bibliogr. 29 poz., rys., wykr.

Twórcy

autor

Benin Dmitrii M.

• Russian State Agrarian University – Moscow Timiryazev Agricultural Academy, Timiryazevskaya St, 49, Moscow, 127550, Russia

• https://orcid.org/0000-0003-1265-4071

autor

Snezhko Vera L.

• Russian State Agrarian University – Moscow Timiryazev Agricultural Academy, Timiryazevskaya St, 49, Moscow, 127550, Russia

• https://orcid.org/0000-0002-3968-0563

Bibliografia

• ALI W., MUSHTAQ N., JAVED T., ZHANG H., ALI K., RASOOL A., FAROOQI A. 2019. Vertical mixing with return irrigation water the cause of arsenic enrichment in groundwater of district Larkana Sindh, Pakistan. Environmental Pollution. Vol. 245 p. 77–88. DOI 10.1016/j.agwat.2017.08.023.
• BOGY D.B., TALKE F.E. 1984. Experimental and theoretical study of wave propagation phenomena in drop-on-demand ink jet devices. IBM Journal of Research and Development. Vol. 28(3) p. 314–321. DOI 10.1147/rd.283.0314.
• CHANDEL S.S., NAIK M.N., CHANDEL R. 2015. Review of solar photovoltaic water pumping system technology for irrigation and community drinking water supplies. Renewable and Sustainable Energy Reviews. Vol. 49 p. 1084–1099. DOI 10.1016/j.rser.2015.04.083.
• DO AMARAL L.G., RIGHES A.A., ESOUZA FILHO P.D.S., DALLA COSTA R. 2005. Automatic regulator for channel flow control on flooded rice. Agricultural Water Management. Vol. 75(3) p. 184–193. DOI 10.1016/j.agwat.2004.12.012.
• DÖRRE A. 2020. Collaborative action and social organization in remote rural regions: Autonomous irrigation arrangements in the Pamirs of Tajikistan. Water. Vol. 12(10), 2905. DOI 10.3390/w12102905.
• ERTSEN M.W., VAN NOOIJEN R. 2009. The man swimming against the stream knows the strength of it: Hydraulics and social relations in an Argentinean irrigation system. Physics and Chemistry of the Earth. Parts A/B/C. Vol. 34(3) p. 200–208. DOI 10.1016/j.pce.2008.06.009.
• FGBNU 2020. Doklad o sostoyanii i ispol’zovanii zemel’ sel’skokhozyaystvennogo naznacheniya v Rossiyskoy Federatsii v 2018 godu [Report on the state and use of agricultural land in the Russian Federation in 2018]. Moskva. FGBNU «Rosinformagrotekh» pp. 340.
• GIDENSTAM A., PAPATRIANTAFILOU M., SUNDELL H., TSIGAS P. 2008. Efficient and reliable lock-free memory reclamation based on reference counting. IEEE Transactions on Parallel and Distributed Systems. Vol. 20(8) p. 1173–1187. DOI 10.1109/TPDS.2008.167.
• GRUPPING A.W., COPPES J.L.R., GROOT J.G. 1988. Fundamentals of oilwell jet pumping. SPE Production Engineering. Vol. 3(01) p. 9–14. DOI 10.2118/15670-PA.
• HATZLAVRAMIDIS D.T. 1991. Modeling and design of jet pumps. SPE Production Engineering. Vol. 6(04) p. 413–419. DOI 10.2118/19713-PA.
• KANG M., PARK S. 2014. Modeling water flows in a serial irrigation reservoir system considering irrigation return flows and reservoir operations. Agricultural Water Management. Vol. 143 p. 131–141. DOI 10.1016/j.agwat.2014.07.003.
• KIM J.H., KIM K.Y. 2012. Analysis and optimization of a vaned diffuser in a mixed flow pump to improve hydrodynamic performance. Journal of Fluids Engineering. Vol. 134(7). DOI 10.1115/1.4006820.
• LEAT M.E., FISHER J. 1994. A synthetic leaflet heart valve with improved opening characteristics. Medical Engineering & Physics. Vol. 16 (6) p. 470–476. DOI 10.1016/1350-4533(94)90071-X.
• LONG X., YAO H., ZHAO J. 2009. Investigation on mechanism of critical cavitating flow in liquid jet pumps under operating limits. International Journal of Heat and Mass Transfer. Vol. 52(9–10) p. 2415–2420. DOI 10.1016/j.ijheatmasstransfer.2008.11.018.
• LONG Y., AN C., ZHU R., CHEN J. 2021. Research on hydrodynamics of high velocity regions in a water-jet pump based on experimental and numerical calculations at different cavitation conditions. Physics of Fluids. Vol. 33(4), 045124. DOI 10.1063/5.0040618.
• MOHAMMADI A., PARVARESH RIZI A., ABBASI N. 2019. Perspective of water distribution based on the performance of hydraulic structures in the varamin irrigation scheme (Iran). Irrigation and Drainage. Vol. 68(2) p. 245–255. DOI 10.1002/ird.2301.
• MUELLER N.H.G. 1964. Water jet pump. Journal of the Hydraulics Division. Vol. 90(3) p. 83–113. DOI 10.1061/JYCEAJ.0001059.
• PARDO-BOSCH F., AGUADO A. 2015. Investment priorities for the management of hydraulic structures. Structure and Infrastructure Engineering. Vol. 11(10) p. 1338–1351. DOI 10.1080/15732479.2014.964267.
• REDDY Y.R., KAR S. 1968. Theory and performance of water jet pump. Journal of the Hydraulics Division. Vol. 94(5) p. 1261–1282. DOI 10.1061/JYCEAJ.0001873.
• ROMANOVSKAYA A.A., KOROTKOV V.N., POLUMIEVA P.D., TRUNOV A.A., VERTYANKINA V.Y., KARABAN R.T. 2020. Greenhouse gas fluxes and mitigation potential for managed lands in the Russian Federation. Mitigation and Adaptation Strategies for Global Change. Vol. 25(4) p. 661–687. DOI 10.1007/s11027-019-09885-2.
• SADAT S., MANSOUR H., MEKKAOUI A., MERZOUGUI T. 2020. Identification and evolution of the Turonian aquifer case study: Cretaceous basin of Béchar, southwestern Algeria. Journal of Water and Land Development. No. 46 p. 190–199. DOI /10.24425/jwld.2020.134213.
• SANGER N.L. 1968. Noncavitating performance of two low-area-ratio water jet pumps having throat lengths of 7.25 diameters [online]. Washington, D.C. National Aeronautics and Space Administration pp. 34. [Access 28.06.2022]. Available at: https://ntrs.nasa.gov/api/citations/19680022488/downloads/19680022488.pdf
• TRUBETSKOY K.N., IOFIS M.A., ESINA E.N. 2015. Geomechanical service in mining under gas-and-dynamic phenomena. Journal of Mining Science. Vol. 51(3) p. 506–512. DOI 10.1134/S1062739115030114.
• VOGEL R. 1956. Theoretical and experimental investigation of air ejectors. Maschinenbautechnik. Vol. 5 p. 619–637.
• WRIGHT J., MARCHESE D. 2018. Briefing: Continuous monitoring and adaptive control: The ‘smart’ storm water management solution. Proceedings of the Institution of Civil Engineers-Smart Infrastructure and Construction. Vol. 170(4) p. 86–89. DOI 10.1680/jsmic.17.00017.
• WU D., CUI Y., LUO Y. 2019. Irrigation efficiency and water-saving potential considering reuse of return flow. Agricultural Water Management. Vol. 221 p. 519–527. DOI 10.1016/j.agwat.2019.05.021.
• YAKYMCHUK O., YAKYMCHUK D., BILEI-RUBAN N., NOSOVA I., HORIASHCHENKO S., HORIASHCHENKO K., ... T UZ V. 2020. Development equipment for hydro-jet forming of women designer’s headwear. International Review of Applied Sciences and Engineering. Vol. 11(3) p. 261–268. DOI 10.1556/1848.2020.00096.
• YAN H., HUI X., LI M., XU Y. 2020. Development in sprinkler irrigation technology in China. Irrigation and Drainage. Vol. 69 p. 75–87. DOI 10.1002/ird.2435.
• YU J., CHEN H., REN Y., Li Y. 2006. A new ejector refrigeration system with an additional jet pump. Applied Thermal Engineering. Vol. 26(2–3) p. 312–319. DOI 10.1016/j.applthermaleng .2005.04.018.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).