GIDROTEXNIK INSHOOTLARDA SUV HISOBINI RAQAMLASHTIRISHDA INNOVATSION TEXNOLOGIYALAR

Tojiboyev Suhrobxon Ja'far o'g'li; Jo'raboyev Ismoiljon Ilhomovich

Suv resurslarining aniq hisobini amalga oshirish, iste’molchiga kerakli suv miqdorini o‘z vaqtida yetkazib berish bugungi kunda eng dolzarb masalalardan biridir. Hozirda gidrotexnika inshootlaridan samarali foydalanishda innovatsion texnologiyalarning zarurati oshib bormoqda. Suv hisobini raqamlashtirishda turli xil qurilmalar mavjud bo‘lib, ulardan foydalanishda energiya, iqtisodiy texnologik muammolar qatorida gidravlik jihatlar ham alohida e’tibor talab etadi. Ma’lumki, gidrotexnik inshootlarda suv sarfi hisobini amalga oshirish va boshqarishda turli xil darvoza “zatvor”lardan keng foydalaniladi. Gidravlik nuqtayi nazaridan inshootlardagi darvozalardan suv o‘tishi ancha murakkab jarayon. Suv sathini nazorat qilish va о‘lchash uchun kо‘p funksiyali qurilmalardan foydalanish zarurati tug‘iladi. Mazkur maqola gidrotexnik inshootlardan o‘tayotgan suv sarfini aniqlashni raqamlashtirishga qaratilgan. Gidrotexnik inshootlar zatvorlari ostidan o‘tayotgan suv sarfini aniqlashda ham yuqori b’efdagi, ham pastki b’efdagi jarayonlarni inobatga olib, suv hisobini raqamlashtirishning gidravlik modeli ishlab chiqilgan. Gidrotexnik inshootlar zatvorlarining yuqori va pastki b’eflarida suv sathi o‘zgarishini vertikal harakatlanadigan yassi gidrotexnik zatvor ko‘tarilishiga bog‘liq ravishda aniqlashning hisoblash usuli tavsiya etildi. Gidrotexnik inshoot zatvorlarida suv sathi va sarfini nazorat qilish hamda о‘lchashni boshqarish tizimining strukturaviy sxemasi ishlab chiqildi.

Название журналаИЛМ-ФАН ВА ИННОВАЦИОН РИВОЖЛАНИШ
Номер выпускаИлм-фан ва инновацион ривожланиш илмий журнали 2024 йил 3-сон
Количество просмотров 7

Ссылка в интернете

DOI

Дата создание в систему UzSCI 13-11-2024

Количество прочтений 7

Дата публикации 28-06-2024

Язык статьиO'zbek

Страницы93-99

Ключевые слова

zatvor

Gidrotexnik inshoot

suv sarfi

gidravlik model

napor

sarf koeffitsiyenti

Ўзбек

Suv resurslarining aniq hisobini amalga oshirish, iste’molchiga kerakli suv miqdorini o‘z vaqtida yetkazib berish bugungi kunda eng dolzarb masalalardan biridir. Hozirda gidrotexnika inshootlaridan samarali foydalanishda innovatsion texnologiyalarning zarurati oshib bormoqda. Suv hisobini raqamlashtirishda turli xil qurilmalar mavjud bo‘lib, ulardan foydalanishda energiya, iqtisodiy texnologik muammolar qatorida gidravlik jihatlar ham alohida e’tibor talab etadi. Ma’lumki, gidrotexnik inshootlarda suv sarfi hisobini amalga oshirish va boshqarishda turli xil darvoza “zatvor”lardan keng foydalaniladi. Gidravlik nuqtayi nazaridan inshootlardagi darvozalardan suv o‘tishi ancha murakkab jarayon. Suv sathini nazorat qilish va о‘lchash uchun kо‘p funksiyali qurilmalardan foydalanish zarurati tug‘iladi. Mazkur maqola gidrotexnik inshootlardan o‘tayotgan suv sarfini aniqlashni raqamlashtirishga qaratilgan. Gidrotexnik inshootlar zatvorlari ostidan o‘tayotgan suv sarfini aniqlashda ham yuqori b’efdagi, ham pastki b’efdagi jarayonlarni inobatga olib, suv hisobini raqamlashtirishning gidravlik modeli ishlab chiqilgan. Gidrotexnik inshootlar zatvorlarining yuqori va pastki b’eflarida suv sathi o‘zgarishini vertikal harakatlanadigan yassi gidrotexnik zatvor ko‘tarilishiga bog‘liq ravishda aniqlashning hisoblash usuli tavsiya etildi. Gidrotexnik inshoot zatvorlarida suv sathi va sarfini nazorat qilish hamda о‘lchashni boshqarish tizimining strukturaviy sxemasi ishlab chiqildi.

Ключевые слова

zatvor

Gidrotexnik inshoot

suv sarfi

gidravlik model

napor

sarf koeffitsiyenti

Русский

Точный учёт водных ресурсов, доставка нужного количества воды потребителю в нужное время стали сегодня актуальной проблемой. Сейчас возрастает потребность в цифровых инновационных технологиях для эффективного использования гидротехнических объектов. Существуют различные цифровые устройства для учёта воды, и при их использовании требуют внимания не только энергетические, экономические и технологические задачи, но и гидравлические. Известно, что в гидротехнических сооружениях широко применяются различные затворы для осуществ ле ния учёта и контроля расхода воды. С гидравлической точки зрения прохождение воды через затворы в сооружениях – довольно сложный процесс. Возникает необходимость использования многофункциональных приборов для контроля и измерения уровня воды. Данная статья направлена на цифровизацию процесса определения расхода воды, проходящей через гидротехнические сооружения. При определении расхода воды, проходящей через затворы гидротехнических сооружений, разработана гидравлическая модель цифровизации процесса учёта воды, принимая во внимание процессы как в верхнем, так и в нижнем бьефе. Предложен расчётный метод определения уровня воды в верхнем и нижнем бьефах затворов гидротехнических сооружений в зависимости от подъёма вертикально движущегося плоского гидротехнического затвора. Разработана конструктивная схема системы контроля уровня и расхода воды, а также контроля измерений в затворах гидротехнических сооружений.

Ключевые слова

затвор

расход

водопотребление

гидротехническое сооружение

гидравлическая модель

коэффициент водопотребления

English

Accurate calculation of water consumption and timely supply of right amounts of water to consumers have become urgent nowadays. Currently, there is an increasing need for innovative digitalization technologies for effective use of hydraulic facilities. As well as, there are various devices for digitalization of water metering, and when using them, among energy, economic and technological tasks, hydraulic aspects also require attention. It is known that various gate valves are widely used in hydraulic structures to generate and regulate a water flow. From a hydraulic point of view, passage of water through gates in structures is a very complex process, therefore the role of multifunctional devices controlling and measuring water levels is important. The purpose of this article is to discuss digitalization of readings of the water flowing through hydraulic structures. A hydraulic model for digitalization of water metering has been developed, taking into account processes ongoing both – in the upper and lower baffles when determining the flow of water passing under the gates of hydraulic structures. A calculation method is recommended for determining changes in water levels in the upper and lower banks of hydraulic structure gates depending on the elevation of a vertically moving flat hydraulic gate. A block diagram of a control system for monitoring and measuring the levels and flows of water in the gates of hydraulic structures, has been developed.

Ключевые слова

water consumption

dam

hydraulic model

flow rate

hydrotechnical structure

consumption coefficient

№ Имя автора Должность Наименование организации

1 Tojiboyev S.J. texnika fanlari bo‘yicha falsafa doktori (PhD), dotsent Qarshi muhandislikiqtisodiyot instituti

2 Jo'raboyev I.I. o‘qituvchi-stajyor “Toshkent irrigatsiya va qishloq xo‘jaligini mexanizatsiyalash muhandislari instituti” Milliy tadqiqot universiteti

№ Название ссылки

1 Arifjanov, A. M., & Tojiboyev, S. J. (2021). Qarshi magistral kanalidagi PK-792 to‘suvchi inshootning suvni chiqarish qismida sathni avtomatik rostlab suv isrofini kamaytirish [Reducing water wastage by automatically adjusting the level in the water discharge part of the PK-792 barrier structure in the opposite main channel]. (In Uzbek). Problems and solutions of effective use of water resources in Uzbekistan: Proceedings of the republic-wide scientific-practical conference, 247–252. Karshi.

2 Arifjanov, A. M., & Tojiboyev, S. J. (2022). Gidrotexnika inshootlaridagi zatvorlar uchun elektr yuritmasini tanlash [Selection of electric control for valves in hydraulic facilities]. (In Uzbek). Uzbek Hydropower, 14, 47–49. Tashkent.

3 Arifjanov, A. M., Fatxulloyev, A. M., Rakhimov, K. T., Otakhonov, M. Y., & Allayorov, D. S. (2022). Changes in hydraulic parameters in canals with sides lining. IOP Conference Series: Earth and Environmental Science, 1112 (1). https://doi.org/10.1088/1755-1315/1112/1/012129

4 Arifjanov, A., & Fatxullaev, A. (2020). Natural Studies for Forming Stable Channel Sections. Journal of Physics: Conference Series, 1425 (1). https://doi.org/10.1088/1742-6596/1425/1/012025

5 Bonilla, C., Brentan, B., Montalvo, I., & Izquierdo, J. (2023). Digitalization of Water Distribution Systems in Small Cities, a Tool for Verification and Hydraulic Analysis: A Case Study of Pamplona, Colombia. Water, 15 (21), 3824. https://doi.org/10.3390/w15213824

6 Dulhoste, J. F., Georges, D., & Besancon, G. (2004). Nonlinear control of openchannel water flow based on collocation control model. Journal of Hydraulic Engineering, 254–266.

7 Erbisti, P. C. F. (2014). Design of hydraulic gates. CRC Press, 231–234.

8 HC-SR04 ultrasonic rangefinder. (2024). Amperca Ltd. https://amperka.ru/product/hc-sr04- ultrasonic-sensor-distance-module

9 Kubrak, E., Kubrak, J., Kiczko, A., & Kubrak, M. (2020). Flow Measurments Using a Sluice Gate. Analysis of Applicability. Water, 12 (3), 819. https://doi.org/10.3390/w12030819

10 Monem, M. J., & Hosseinzade, Z. (2011, October 15–23). Construction and Evaluation of Automatic pivot weir control system. ICID 21st International Congress on Irrigation and Drainage, 450. Tehran, Iran.

11 NM-R Magnetostrictive float level gauge KOBOLD Germany. (2024). Research and Production Association RIZUR. https://rizur.ru/catalog/poplavkovye-urovnemery-kobold/poplavkovyy-datchikurovnya-nm/

12 Rajaratnam, N., & Subramanaya, K. (1967.) Flow equations for the sluice gate. Irrig. Drain. Eng. ASCE, 93, 167–186.

13 Rao, R. V., & Zhmud, V. A. (2010). The review of the Indo-Russian Joint Workshop on Computional Intelligence and Modern Heuristics in Automation and Robotics. Scientific Bulletin of NSTU, 4 (41), 179–182.

14 Sauida, M. F. (2014). Calibration of submerged multi-sluice gates. Alexandria Engineering Journal, 53 (3), 663–668.

15 Serikbaev, B. S., Barayev, F. A., Sherov, A. G., Serikbaevа, E. B., Omarova, G. E., & Djumanazarova, A. T. (2014). Gidromeliorativ tizimlardan foydalanish [Use of hydromelioration systems]. Tashkent: TIMI.

16 Silva, C. O., & Rijo, M. (2017). Flow rate measurements under sluice gates. Irrig. Drain. Eng., 143.

17 Suntaranont, B., et al. (2015). Energy aware flash flood monitoring stations using a ga-fuzzy logic control mechanism. 2015 IEEE Tenth International Conference on Intelligent Sensors, Sensor Networks and Information Processing (ISSNIP), 1–6. IEEE.

18 Tojiboyev, S. (2018). Modeling of the process of protection of hydrotechnical structures from pumps. Scientific Knowledge of the Present, 6, 70–74. Kazan.

19 Tojiboyev, S. J, & Ochilov, M. A. (2021). Gidrotexnika inshootida zatvorlar xolatini raqamlashtirishda qo‘llanuvchi sath datchigi tanlash [Selection of a level sensor used in the digitalization of the status of valves in a hydraulic facility]. Problems and solutions of effective use of water resources in Uzbekistan: Proceedings of the republic-wide scientific-practical conference, 273–276. Karshi.

В ожидании

№	Имя автора	Должность	Наименование организации
1	Tojiboyev S.J.	texnika fanlari bo‘yicha falsafa doktori (PhD), dotsent	Qarshi muhandislikiqtisodiyot instituti
2	Jo'raboyev I.I.	o‘qituvchi-stajyor	“Toshkent irrigatsiya va qishloq xo‘jaligini mexanizatsiyalash muhandislari instituti” Milliy tadqiqot universiteti

№	Название ссылки
1	Arifjanov, A. M., & Tojiboyev, S. J. (2021). Qarshi magistral kanalidagi PK-792 to‘suvchi inshootning suvni chiqarish qismida sathni avtomatik rostlab suv isrofini kamaytirish [Reducing water wastage by automatically adjusting the level in the water discharge part of the PK-792 barrier structure in the opposite main channel]. (In Uzbek). Problems and solutions of effective use of water resources in Uzbekistan: Proceedings of the republic-wide scientific-practical conference, 247–252. Karshi.
2	Arifjanov, A. M., & Tojiboyev, S. J. (2022). Gidrotexnika inshootlaridagi zatvorlar uchun elektr yuritmasini tanlash [Selection of electric control for valves in hydraulic facilities]. (In Uzbek). Uzbek Hydropower, 14, 47–49. Tashkent.
3	Arifjanov, A. M., Fatxulloyev, A. M., Rakhimov, K. T., Otakhonov, M. Y., & Allayorov, D. S. (2022). Changes in hydraulic parameters in canals with sides lining. IOP Conference Series: Earth and Environmental Science, 1112 (1). https://doi.org/10.1088/1755-1315/1112/1/012129
4	Arifjanov, A., & Fatxullaev, A. (2020). Natural Studies for Forming Stable Channel Sections. Journal of Physics: Conference Series, 1425 (1). https://doi.org/10.1088/1742-6596/1425/1/012025
5	Bonilla, C., Brentan, B., Montalvo, I., & Izquierdo, J. (2023). Digitalization of Water Distribution Systems in Small Cities, a Tool for Verification and Hydraulic Analysis: A Case Study of Pamplona, Colombia. Water, 15 (21), 3824. https://doi.org/10.3390/w15213824
6	Dulhoste, J. F., Georges, D., & Besancon, G. (2004). Nonlinear control of openchannel water flow based on collocation control model. Journal of Hydraulic Engineering, 254–266.
7	Erbisti, P. C. F. (2014). Design of hydraulic gates. CRC Press, 231–234.
8	HC-SR04 ultrasonic rangefinder. (2024). Amperca Ltd. https://amperka.ru/product/hc-sr04- ultrasonic-sensor-distance-module
9	Kubrak, E., Kubrak, J., Kiczko, A., & Kubrak, M. (2020). Flow Measurments Using a Sluice Gate. Analysis of Applicability. Water, 12 (3), 819. https://doi.org/10.3390/w12030819
10	Monem, M. J., & Hosseinzade, Z. (2011, October 15–23). Construction and Evaluation of Automatic pivot weir control system. ICID 21st International Congress on Irrigation and Drainage, 450. Tehran, Iran.
11	NM-R Magnetostrictive float level gauge KOBOLD Germany. (2024). Research and Production Association RIZUR. https://rizur.ru/catalog/poplavkovye-urovnemery-kobold/poplavkovyy-datchikurovnya-nm/
12	Rajaratnam, N., & Subramanaya, K. (1967.) Flow equations for the sluice gate. Irrig. Drain. Eng. ASCE, 93, 167–186.
13	Rao, R. V., & Zhmud, V. A. (2010). The review of the Indo-Russian Joint Workshop on Computional Intelligence and Modern Heuristics in Automation and Robotics. Scientific Bulletin of NSTU, 4 (41), 179–182.
14	Sauida, M. F. (2014). Calibration of submerged multi-sluice gates. Alexandria Engineering Journal, 53 (3), 663–668.
15	Serikbaev, B. S., Barayev, F. A., Sherov, A. G., Serikbaevа, E. B., Omarova, G. E., & Djumanazarova, A. T. (2014). Gidromeliorativ tizimlardan foydalanish [Use of hydromelioration systems]. Tashkent: TIMI.
16	Silva, C. O., & Rijo, M. (2017). Flow rate measurements under sluice gates. Irrig. Drain. Eng., 143.
17	Suntaranont, B., et al. (2015). Energy aware flash flood monitoring stations using a ga-fuzzy logic control mechanism. 2015 IEEE Tenth International Conference on Intelligent Sensors, Sensor Networks and Information Processing (ISSNIP), 1–6. IEEE.
18	Tojiboyev, S. (2018). Modeling of the process of protection of hydrotechnical structures from pumps. Scientific Knowledge of the Present, 6, 70–74. Kazan.
19	Tojiboyev, S. J, & Ochilov, M. A. (2021). Gidrotexnika inshootida zatvorlar xolatini raqamlashtirishda qo‘llanuvchi sath datchigi tanlash [Selection of a level sensor used in the digitalization of the status of valves in a hydraulic facility]. Problems and solutions of effective use of water resources in Uzbekistan: Proceedings of the republic-wide scientific-practical conference, 273–276. Karshi.