CALCULATION OF GEOMETRIC PARAMETERS AND HYDRODYNAMIC PROPERTIES OF VENTURI PIPES IN SELF-DRAINING SOLAR HEAT SUPPLY

This research work is aimed at ensuring the improvement of energy efficiency and reliability of self-directed solar heating by optimizing the hydrodynamic modes of operation. Proceeding from this purpose, the tasks of the research are to analyze existing methods of protecting solar collectors of water heating and hot water supply systems from freezing and to reveal the most perspective methods. One of the tasks is also to determine the laws of hydrodynamics in the self-draining of solar heat supply

Название журналаИЛМ-ФАН ВА ИННОВАЦИОН РИВОЖЛАНИШ
Номер выпускаИлм-фан ва инновацион ривожланиш илмий журнали 2022 йил 6-сон
Количество просмотров18

Ссылка в интернете https://ilm.mininnovation.uz/index.php/journal/article/view/333

DOIhttps://dx.doi.org/10.36522/2181-9637-2022-6-5

Дата создание в систему UzSCI26-02-2024

Количество прочтений18

Дата публикации11-11-2022

Язык статьиIngliz

Страницы47-53

Ключевые слова

Venturi tube

geometric dimensions

hydrodynamic characteristics

self-draining

solar heat supply

solar heating systems

English

This research work is aimed at ensuring the improvement of energy efficiency and reliability of self-directed solar heating by optimizing the hydrodynamic modes of operation. Proceeding from this purpose, the tasks of the research are to analyze existing methods of protecting solar collectors of water heating and hot water supply systems from freezing and to reveal the most perspective methods. One of the tasks is also to determine the laws of hydrodynamics in the self-draining of solar heat supply

Ключевые слова

Venturi tube

geometric dimensions

hydrodynamic characteristics

self-draining

solar heat supply

solar heating systems

Ўзбек

Ушбу тадқиқот иши гидродинамик иш режимларини оптималлаштириш орқали ўзини ўзи дренаж қилувчи қуёш иссиқлик таъминотида энергия самарадорлиги ва ишончлилигини оширишни таъминлайди. Шундан келиб чиқиб, мазкур тадқиқотнинг мақсади сув иситиш ва иссиқ сув таъминоти тизимларининг қуёш коллекторларини музлашдан ҳимоя қилишнинг мавжуд ва энг истиқболли усулларини таҳлил этиш, шунингдек, ўзини ўзи дренаж қилувчи қуёш иссиқлик таъминотида гидродинамика қонуниятларини аниқлашдан иборатдир.

Ключевые слова

геометрик ўлчамлар

гидродинамик хусусиятлар

Вентури қувур

ўзини ўзи дренаж қилиш

қуёш иссиқлик таъминоти

қуёш иситиш тизимлари

Русский

Исследовательская работа направлена на обеспечение повышения энергоэффективности и надежности самоотводящего солнечного теплоснабжения за счет оптимизации гидродимических режимов работы. Исходя из этой цели, задачами исследования являются анализ существующих методов защиты солнечных коллекторов систем водяного отопления и горячего водоснабжения от замерзания и выявление наиболее перспективных методов. Одна из задач также заключается в определении законов гидродинамики при самоотводе солнечного теплоснабжения.

Ключевые слова

геометрические размеры

гидродинамические характеристики

труба Вентури

самоотвод

солнечное теплоснабжение

системы солнечного отопления

№ Имя автора Должность Наименование организации

1 Qarshiyev S.S. doktorant Toshkent arxitektura-qurilish instituti

№ Название ссылки

1 Karshiev Sh.Sh. Improving efficiency of solar heating systems with flat solar collectors: key reserves and possible ways of their implementation. International Journal of Advanced Research in Science, Engineering and Technology (IJARSET), India, 2019, August, vol. 6, iss. 8, pp. 10361– 10364. Available at: http://www.ijarset.com/upload/2019/august/08-usovoxaus-20.pdf/.

2 Karshiev Sh.Sh., Khayrullaev R.S., Nasibullayevna N.Z. Self-draining solar devices to protect modern solar collectors from destruction. International Engineering Journal For Research & Development, India, 2020, May, vol. 5, iss. 3, pp. 140–142. ISSN: 2349-0721. DOI: 10.17605/OSF. IO/EZM45/.

3 Karshiev Sh.Sh. Solar collector’s development drain back systems. International Journal of Research, 2020, September, vol. IX, iss. IX, pp. 229–233. ISSN: 2236-6124.

4 Karshiev Sh.Sh. Devices for protecting modern solar collectors. Universum technical science, 2020, vol. 6, no. 7, pp. 96–99. ISSN: 2311-5122.

5 Karshiev Sh.Sh. Self-drainage of solar collectors and seasonal testing in different conditions energy saving innovative laboratory stand. Ilm sarchashmalari – Science knowledge, Urganch State University, 2021, no. 2, pp. 25–28.

6 Jiang H. et al. A review on bubble generation and transportation in Venturi-type bubble generators. Experimental and Computational Multiphase Flow, 2020, vol. 2 (3), pp. 123–134.

7 Borgbjerg J.M. et al. In silico screening of venturi designs and operational conditions for gas-liquid mass transfer applications. Chemical Engineering Journal, 2020, vol. 383, p. 123119.

8 Rashidov Yu.K., Makhmutalieva S.N. Influence of the location of the Venturi pipe on the hydrodynamic characteristics of a self-draining solar circuit of the heating system. Architecture and construction science in the 21st century. Proceedings of the XXIV Scientific and practical conference (2-TIACE). Tashkent, 2015, pp. 21–23.

9 Rashidov Yu.K., Makhmutalieva S.N. Energy efficiency of a self-draining solar circuit of a heating system with a Venturi tube. Architecture and construction science in the 21st century. Proceedings of the XXIV Scientific and practical conference (TIACE). Tashkent, 2015, pp. 150– 152.

10 Khabibullin M.Ya. Managing the processes accompanying fluid motion inside oil field converging-diverging pipes. Journal of Physics: Conference Series, IOP Publishing, 2019, vol. 1333, no. 4.

11 Rashidov Yu.K., Rashidov K.Yu., Mukhin I.I., Suratov Kh.T., Rakhimov Z.Z. Features of the design of a self-draining solar power plant with an active element. Applied Solar Energy, 2018, vol. 54, no. 3, pp. 182–186.

12 Rashidov Yu.K., Rashidov K.Yu., Mukhin I.I., Suratov Kh.T. Features of the design of a selfdraining solar plant with an active element. Heliotechnics, Tashkent, 2018, no. 2, pp. 21–27.

13 Rashidov Yu.K., Karshiev Sh.Sh., Mukhin I.I., Rashidov K.Yu. Calculated dependencies for designing a self-draining solar plant with an active element. Environmental, Industrial and Energy Security – 2018. Proceedings of the International Scientific and Practical Conference. Sevastopol, 2018, September 24-27, pp. 1002–1006.

14 Rashidov Yu.K., Rashidov K.Yu., Mukhin I.I., Suratov Kh.T. Increasing the efficiency of the use of solar thermal energy in heat supply systems by improving their circuit solutions and operating parameters through the use of active elements. The Use of Renewable Energy Sources: New Research, Technologies and Innovative Approaches. Proceedings of the Conference. Tashkent, 2018, September 25-26, pp. 128–133.

15 Rashidov Yu.K., Rashidov K.Yu., Mukhin I.I., Suryatov Kh.T., Orzimatov Zh.T., Karshiev Sh.Sh. The main reserves for increasing the efficiency of using solar thermal energy in heat supply systems. Heliotechnics, Tashkent, 2019, vol. 55, no. 1, pp. 19–37.

16 Rashidov Yu.K., Sultanova Sh.Yu., Suratov Kh.T. Increase in dependability and efficiency of selfdraining water systems of solar heat supply. Applied Solar Energy, 2017, vol. 53 (1), pp. 16–22.

17 Gogate P.R., Aniruddha B.P. A review and assessment of hydrodynamic cavitation as a technology for the future. Ultrasonics sonochemistry, 2005, vol. 12 (1-2), pp. 21–27.

В ожидании

№	Название ссылки
1	Karshiev Sh.Sh. Improving efficiency of solar heating systems with flat solar collectors: key reserves and possible ways of their implementation. International Journal of Advanced Research in Science, Engineering and Technology (IJARSET), India, 2019, August, vol. 6, iss. 8, pp. 10361– 10364. Available at: http://www.ijarset.com/upload/2019/august/08-usovoxaus-20.pdf/.
2	Karshiev Sh.Sh., Khayrullaev R.S., Nasibullayevna N.Z. Self-draining solar devices to protect modern solar collectors from destruction. International Engineering Journal For Research & Development, India, 2020, May, vol. 5, iss. 3, pp. 140–142. ISSN: 2349-0721. DOI: 10.17605/OSF. IO/EZM45/.
3	Karshiev Sh.Sh. Solar collector’s development drain back systems. International Journal of Research, 2020, September, vol. IX, iss. IX, pp. 229–233. ISSN: 2236-6124.
4	Karshiev Sh.Sh. Devices for protecting modern solar collectors. Universum technical science, 2020, vol. 6, no. 7, pp. 96–99. ISSN: 2311-5122.
5	Karshiev Sh.Sh. Self-drainage of solar collectors and seasonal testing in different conditions energy saving innovative laboratory stand. Ilm sarchashmalari – Science knowledge, Urganch State University, 2021, no. 2, pp. 25–28.
6	Jiang H. et al. A review on bubble generation and transportation in Venturi-type bubble generators. Experimental and Computational Multiphase Flow, 2020, vol. 2 (3), pp. 123–134.
7	Borgbjerg J.M. et al. In silico screening of venturi designs and operational conditions for gas-liquid mass transfer applications. Chemical Engineering Journal, 2020, vol. 383, p. 123119.
8	Rashidov Yu.K., Makhmutalieva S.N. Influence of the location of the Venturi pipe on the hydrodynamic characteristics of a self-draining solar circuit of the heating system. Architecture and construction science in the 21st century. Proceedings of the XXIV Scientific and practical conference (2-TIACE). Tashkent, 2015, pp. 21–23.
9	Rashidov Yu.K., Makhmutalieva S.N. Energy efficiency of a self-draining solar circuit of a heating system with a Venturi tube. Architecture and construction science in the 21st century. Proceedings of the XXIV Scientific and practical conference (TIACE). Tashkent, 2015, pp. 150– 152.
10	Khabibullin M.Ya. Managing the processes accompanying fluid motion inside oil field converging-diverging pipes. Journal of Physics: Conference Series, IOP Publishing, 2019, vol. 1333, no. 4.
11	Rashidov Yu.K., Rashidov K.Yu., Mukhin I.I., Suratov Kh.T., Rakhimov Z.Z. Features of the design of a self-draining solar power plant with an active element. Applied Solar Energy, 2018, vol. 54, no. 3, pp. 182–186.
12	Rashidov Yu.K., Rashidov K.Yu., Mukhin I.I., Suratov Kh.T. Features of the design of a selfdraining solar plant with an active element. Heliotechnics, Tashkent, 2018, no. 2, pp. 21–27.
13	Rashidov Yu.K., Karshiev Sh.Sh., Mukhin I.I., Rashidov K.Yu. Calculated dependencies for designing a self-draining solar plant with an active element. Environmental, Industrial and Energy Security – 2018. Proceedings of the International Scientific and Practical Conference. Sevastopol, 2018, September 24-27, pp. 1002–1006.
14	Rashidov Yu.K., Rashidov K.Yu., Mukhin I.I., Suratov Kh.T. Increasing the efficiency of the use of solar thermal energy in heat supply systems by improving their circuit solutions and operating parameters through the use of active elements. The Use of Renewable Energy Sources: New Research, Technologies and Innovative Approaches. Proceedings of the Conference. Tashkent, 2018, September 25-26, pp. 128–133.
15	Rashidov Yu.K., Rashidov K.Yu., Mukhin I.I., Suryatov Kh.T., Orzimatov Zh.T., Karshiev Sh.Sh. The main reserves for increasing the efficiency of using solar thermal energy in heat supply systems. Heliotechnics, Tashkent, 2019, vol. 55, no. 1, pp. 19–37.
16	Rashidov Yu.K., Sultanova Sh.Yu., Suratov Kh.T. Increase in dependability and efficiency of selfdraining water systems of solar heat supply. Applied Solar Energy, 2017, vol. 53 (1), pp. 16–22.
17	Gogate P.R., Aniruddha B.P. A review and assessment of hydrodynamic cavitation as a technology for the future. Ultrasonics sonochemistry, 2005, vol. 12 (1-2), pp. 21–27.