##plugins.themes.academic_pro.article.sidebar##

Download
pdf
Statistic
Read Counter : 20 Download : 17

##plugins.themes.academic_pro.article.main##

Abstract

This paper discusses one of the operational challenges faced by pumping station forechambers during exploitation: the cleaning of silt deposits from the bottom of the structures. A scheme for a silt cleaning device designed to remove silt deposits from the bottom of the forechamber using a slurry pump is proposed. The device transports the silt mixture through the pumping station's pressure pipeline to an upper reservoir, from where it is then distributed to irrigation fields. A methodology has been developed to determine the key pressure-water consumption parameters and the energy performance indicators of the silt cleaning device. Calculations performed using this methodology indicate that when this device is used to clean silt deposits in the forechamber, the total energy consumption of the pumping station is only 0.051% for cleaning 30 cubic meters of silt.

Keywords

Pumping station forechamber slurry pump

##plugins.themes.academic_pro.article.details##

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

How to Cite
Nosirov Fakhriddin Jaylovovich. (2024). Purification Of The Settling Chamber Of A Pumping Station From Silt Sediments Using A Slurry Pump. Texas Journal of Engineering and Technology, 30, 29–33. Retrieved from https://zienjournals.com/index.php/tjet/article/view/5356

References

  1. Urishev B.U., Mukhammadiev M.M., Nosirov F.J. Management of the movement of turbid particles in the vanes of irrigation pumping stations. Monograph. Karshi, "Intellect" publishing house, 2022. - 160 p.
  2. Urishev B.U. Improving the operation and energy efficiency of pumping stations. Monograph/ Karshi, "Intellect" publishing house, 2021. - 132 p.
  3. Mukhammadiev M.M., Urishev B.U., Nosirov F.J. Predotvrashchenie zailenia vankamery pump station, raspolojennyx na tupikovykh canalax. Vestnik TashGTU, No. 4, 2005. p. 47-53.
  4. Patent R.Uzb. FAR 00239. Vodopryomnoe soorujenie/ Mukhammadiev M.M., Urishev B.U., Nosirov F.J.// Ofitsialnyy vestnik. - 2006. - No. 2. - p. 187
  5. Nosirov F. J. et al. IMPLEMENTING A SOLAR PHOTOVOLTAIC STATION IN WATERING SYSTEMS UTILIZING COMPLEX SOFTWARE //Technical science and innovation. – 2024. – Т. 2024. – №. 1. – С. 44-51.
  6. Urishev B. Nosirov F. Ruzikulova N 2023 Hydraulic energy storage of wind power plants E3S Web of Conference Volume 383, 04052, https://doi.org/10.1051/e3sconf/202338304052
  7. Urishev B. Eshev S, Nosirov F. Kuvatov U 2021 A device for reducing the siltation of the front chamber of the pumping station in irrigation systems, 274, 03001, https://doi.org/10.1051/e3sconf/202127403001
  8. Turabdjanov S, Dungboyev Sh. Nosirov F. Juraev A, Karabaev I 2023 Application of a two-axle synchronous generator excitations in small hydropower engineering and wind power plants AIP Conference Proceedings 2552, 050024, (AIP Publishing), https://doi.org/10.1063/5.0130649
  9. Nosirov F. Juraev A. Karabaev I. Kerimzatov N 2023 Economic calculation of a photoelectric station for degradation processes AIP Conference Proceedings 2552, 050035, (AIP Publishing). https://doi.org/10.1063/5.0130642
  10. Urishev B. Nosirov F 2023 Hydraulic Energy Storage of Wind Power Plants J. Proceedings of International Conference on Applied Innovation in IT. (Anhalt University of Applied Sciences) Volume 11, Issue 1, pp.267-272, doi: 10.25673/101947
  11. Photovoltaic Plants for Water Lift Systems // Mirzabaev, A.M., Sytdykov, O.R., Makhkamov, T.A., Verchenko, P.E., Mirzabekov, S.M. // Applied Solar Energy (English translation of Geliotekhnika), 2018, 54(5), p. 346–349.