СПОСОБЫ УСОВЕРШЕНСТВОВАНИЯ ТРОЙНИКОВ В СИСТЕМЕ ВОДОСНАБЖЕНИЯ
Keywords:
сужение, расширение, диафрагма, гидравлическое сопротивление, местный сопротивление, коэффициент сопротивления, тройник
Abstract
Местные потери напора обусловливаются преодолением местных сопротивлений, создаваемых фасонными частями, арматурой и прочим оборудованием трубопроводных сетей. Движение в трубопроводе при наличии местных сопротивлений является неравномерным. Местные сопротивления вызывают изменение величины или направления скорости движения жидкости на отдельных участках трубопровода, что связано с появлением дополнительных потерь напора. В результате этого часть напора удельной энергии затрачивается на преодоление сопротивлений движению жидкости, вызванных трением внутри жидкости, а другая часть механической энергии переходит в тепловую. В данной работе исследовано способы уменьшения потери давления в системе водоснабжения и предложен новый тройник.
References
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29. Muminov, O., & Maksudov, R. (2022). HIDROTECHNICS PREVENT VIBRATIONS THAT OCCUR IN CONSTRUCTIONS. Science and innovation, 1(A7), 762-766.
30. Abdullayev, B. X., & Rahmankulov, S. A. (2021). Modeling Aeration in High Pressure Hydraulic Circulation. CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES, 2(12), 127-136.
31. Abdullayev, B. X., & Rahmankulov, S. A. (2021). Movement of Variable Flow Flux Along the Path in a Closed Inclined Pipeline. CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES, 2(12), 120-126.
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35. Azizovich, N. I. (2022). On The Accuracy of the Finite Element Method on the Example of Problems about Natural Oscillations. European Multidisciplinary Journal of Modern Science, 116-124.
2. Usmonova, N. A. (2021). Structural Characteristics of the Cavern at a Fine Bubbled Stage of Cavitation. Middle European Scientific Bulletin, 18, 95-101.
3. Usmanova, N., & Abdukhalilova, S. (2022). SHELL-AND-TUBE HEAT EXCHANGER DESIGN WITH INCREASED TURBULENCE OF THE HEATED LIQUID FLOW. Science and innovation, 1(A7), 726-731.
4. Madaliyev, E., Makhsitalayev, B., & Rustamova, K. (2022). IMPROVEMENT OF SEWAGE FLATS. Science and innovation, 1(A7), 796-801.
5. Madaliyev, E., & Maksitaliyev, B. (2022). A NEW WAY OF GETTING ELECTRICITY. Science and innovation, 1(A7), 790-795.
6. Koraboevich, U. M., & Ilhomidinovich, M. G. (2021, June). Calculation of the free vibrations of the boxed structure of large-panel buildings. In " ONLINE-CONFERENCES" PLATFORM (pp. 170-173).
7. Аббасов, Ё. (2020). Роль солнечных воздухонагревателей в теплоэнергетической отрасли и перспективы их развития в Республике Узбекистан. Общество и инновации, 1(1), 1-13.
8. Abbasov, E. S. (2004). Calculation of the turbulized boundary layer in diffusor-confusor solar receivers. Applied Solar Energy, 40(1), 92-94.
9. Abbasov, E. S. (2004). Heat exchange intensification in solar heat collectors of solar air heaters. Applied solar energy, 39(4), 20-23.
10. Mamatisaev, G., & Muulayev, I. (2022). ECOLOGICAL AND TECHNOLOGICAL PROBLEMS IN WATER COLLECTION FACILITIES. Science and innovation, 1(A7), 767-772.
11. Mullaev, I. (2022). ҚУЁШ-ҲАВО ИСИТИШ ҚУРИЛМАСИНИНГ САМАРАДОРЛИГИНИ ОШИРИШ. Science and innovation, 1(A7), 756-761.
12. Abbasov, Y., & Usmonov, M. (2022). CALCULATION OF THEIR POWER AND HEATING SURFACE IN IMPROVING THE EFFICIENCY OF AIR HEATING SYSTEMS. Science and innovation, 1(A7), 738-743.
13. Abbasov, Y. S., & ugli Usmonov, M. A. (2022). Design of an Effective Heating System for Residential and Public Buildings. CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES, 3(5), 341-346.
14. Ismailov, M., & Xolmatov, I. (2022). КАНАЛИЗАЦИЯ ТАРМОҚЛАРИНИ ЛОЙИХАЛАШНИНГ АПТИМАЛ УСУЛЛАРИ. Science and innovation, 1(A7), 744-749.
15. Abobakirovich, Abdukarimov Bekzod, Abbosov Yorqin Sodikovich, and Mullayev Ikromjon Isroiljon Оgli. "Optimization of operating parameters of flat solar air heaters." Вестник науки и образования 19-2 (73) (2019): 6-9.
16. Madaliev, M. E. U., Maksudov, R. I., Mullaev, I. I., Abdullaev, B. K., & Haidarov, A. R. (2021). Investigation of the Influence of the Computational Grid for Turbulent Flow. Middle European Scientific Bulletin, 18, 111-118.
17. Nasirov, I. (2022). АКТУАЛЬНОСТЬ ПРИМЕНЕНИЯ МЕТОДОВ МАТЕМАТИЧЕСКОГО МОДЕЛИРОВАНИЯ И МЕТОДОВ КОНЕЧНЫХ ЭЛЕМЕНТОВ В СТРОИТЕЛЬСТВЕ. Science and innovation, 1(A7), 711-716.
18. Nosirov, A. A., & Nаsirov, I. A. (2022). Simulation of Spatial Own of Vibrations of Axisymmetric Structures. European Multidisciplinary Journal of Modern Science, 107-115.
19. Akramovna, U. N., & Ismoilovich, M. R. (2021). Flow Around a Plate at Nonzero Cavitation Numbers. CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES, 2(12), 142-146.
20. Madaliev, E. U., & qizi Abdukhalilova, S. B. (2022). Repair of Water Networks. CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES, 3(5), 389-394.
21. qizi Abdukhalilova, S. B. (2021). Simplified Calculation of the Number of Bimetallic Radiator Sections. CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES, 2(12), 232-237.
22. Maqsudov, R. I., & qizi Abdukhalilova, S. B. (2021). Improving Support for the Process of the Thermal Convection Process by Installing. Middle European Scientific Bulletin, 18, 56-59.
23. Muminov, O. (2022). TYPES OF CAVITATION, CAUSING VIBRATION IN ENGINEERING AND WATER SUPPLY SYSTEMS. Science and innovation, 1(A7), 732-737.
24. Mo’minov, O. A., & O’tbosarov Sh, R. TYPE OF HEATING RADIATORS, PRINCIPLES OF OPERATION AND THEORETICAL ANALYSIS OF THEIR TECHNICAL AND ECONOMIC CHARACTERISTICS.
25. O‘tbosarov, S., & Xusanov, N. (2022). ASSEMBLY OF STRUCTURES AND WATER DIVIDERS. Science and innovation, 1(A7), 780-784.
26. Mo'minov, O. A., Abdukarimov, B. A., & O'tbosarov, S. R. (2021). Improving support for the process of the thermal convection process by installing reflective panels in existing radiators in places and theoretical analysis. In Наука и инновации в строительстве (pp. 47-50).
27. Рашидов, Ю. К. Орзиматов, Ж. Т. & Исмоилов, М. М. (2019). Воздушные солнечные коллекторы: перспективы применения в условиях Узбекистана. ББК 20.1 я43 Э 40.
28. Ismailov, M., & Xolmatov, I. (2022). OPTIMAL METHODS FOR DESIGNING SEWER NETWORKS. Science and Innovation, 1(7), 744-749.
29. Muminov, O., & Maksudov, R. (2022). HIDROTECHNICS PREVENT VIBRATIONS THAT OCCUR IN CONSTRUCTIONS. Science and innovation, 1(A7), 762-766.
30. Abdullayev, B. X., & Rahmankulov, S. A. (2021). Modeling Aeration in High Pressure Hydraulic Circulation. CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES, 2(12), 127-136.
31. Abdullayev, B. X., & Rahmankulov, S. A. (2021). Movement of Variable Flow Flux Along the Path in a Closed Inclined Pipeline. CENTRAL ASIAN JOURNAL OF THEORETICAL & APPLIED SCIENCES, 2(12), 120-126.
32. Xamdamaliyevich, S. A., & Rahmankulov, S. A. (2021, July). Investigation of heat transfer processes of solar water, air contact collector. In E-Conference Globe (pp. 161-165).
33. Husanov, N., & Abdukhalilova, S. (2022). HEAT EXCHANGE PROCESSES IN A SHELL-AND-TUBE HEAT EXCHANGER. Science and innovation, 1(A7), 721-725.
34. Madraximov, M. M., Nurmuxammad, X., & Abdulkhaev, Z. E. (2021, November). Hydraulic Calculation Of Jet Pump Performance Improvement. In International Conference On Multidisciplinary Research And Innovative Technologies (Vol. 2, pp. 20-24).
35. Azizovich, N. I. (2022). On The Accuracy of the Finite Element Method on the Example of Problems about Natural Oscillations. European Multidisciplinary Journal of Modern Science, 116-124.
Published
2022-12-17
How to Cite
Э.У, М., & Х. О., Р. (2022). СПОСОБЫ УСОВЕРШЕНСТВОВАНИЯ ТРОЙНИКОВ В СИСТЕМЕ ВОДОСНАБЖЕНИЯ. CENTRAL ASIAN JOURNAL OF MATHEMATICAL THEORY AND COMPUTER SCIENCES, 3(12), 90-96. https://doi.org/10.17605/OSF.IO/XHA2V
Section
Articles
