Mazkur ilmiy ishda Samarqand viloyatida tomchilatib sug‘orish tizimidan foydalanishda tuproq namligini masofadan aniqlas bo‘yicha ishlab chiqilgan texnologiyaning sinov natijalari ko‘rsatilgan. Tadqiqot olib borilgan hududning o‘rtacha yillik yog‘ingarchilik miqdori 370 mm, maydon kengligi 240 000 m2ni tashkil etadi. O‘rganilayotgan texnologiya asosida sinovdan o‘tkazilayotgan obyekt Samarqand viloyati Payariq tumanida dengiz sathidan 634 m yuqorida joylashgan 40°00’43.97’’ 66°54’51.35. Obyekt jami 12 ta kichik maydonlarga bo‘lib o‘rganildi. Bunda har bir kichik obyektga bir donadan namlikni o‘lchash sensorlari o‘rnatilib, ularning aloqa almashishi uchun GSM modullardan foydalanildi. Natijalar samaradorligi va aniqligini tahlil etish uchun har bir sensordagi ma’lumotlar ikki kunda bir marta klassik usul orqali termostatlarda ham tekshirildi. Klassik usulda o‘lchangan namlik va sensorlardagi namliklar farqi bo‘yicha grafi k va maksimal sensorlarning o‘zaro masofalari jadvali ishlab chiqildi. Olib borilgan ilmiy ishning amaldagi tajribalardan asosiy farqi namlik monitoringi tuproqning 3 xil chuqurligida va yengil qumoq, o‘rta qumoq, og‘ir qumoq, gilli qatlamlarda olib borilganligida. Hozirgi kunda bu kabi texnologiyalarga talab o‘ta yuqori. Tomchilatib sug‘orish tizimidagi yer maydonlar o‘rtacha 15-20 gektarni tashkil etib, bunda sug‘orish oralig‘i va sug‘orish me’yorini aniqlashda daladagi tuproq namligi yuqori o‘rin tutadi. Har doim ham tuproq namunalarini klassik, ya’ni termostat yoki bosh quritish usullari bilan aniqlashning vaqt jihatdan imkoni yo‘q. Quyidagi biz ikki turdagi tuproqni aniqlash usuliga sarflangan vaqt va uning aniqlik darajalarini ham ko‘rib o‘tamiz. Klassik va zamonaviy usulda olingan namlik natijalaridagi xatoliklar klassikda 1%, zamonaviy usulda 10%, zamonaviy usulda olingan ma’lumotlar aniqligini 90 foizdan 97,5-98,5 foizga ko‘tarish bo‘yicha yechimlar ko‘rib chiqiladi.
Mazkur ilmiy ishda Samarqand viloyatida tomchilatib sug‘orish tizimidan foydalanishda tuproq namligini masofadan aniqlas bo‘yicha ishlab chiqilgan texnologiyaning sinov natijalari ko‘rsatilgan. Tadqiqot olib borilgan hududning o‘rtacha yillik yog‘ingarchilik miqdori 370 mm, maydon kengligi 240 000 m2ni tashkil etadi. O‘rganilayotgan texnologiya asosida sinovdan o‘tkazilayotgan obyekt Samarqand viloyati Payariq tumanida dengiz sathidan 634 m yuqorida joylashgan 40°00’43.97’’ 66°54’51.35. Obyekt jami 12 ta kichik maydonlarga bo‘lib o‘rganildi. Bunda har bir kichik obyektga bir donadan namlikni o‘lchash sensorlari o‘rnatilib, ularning aloqa almashishi uchun GSM modullardan foydalanildi. Natijalar samaradorligi va aniqligini tahlil etish uchun har bir sensordagi ma’lumotlar ikki kunda bir marta klassik usul orqali termostatlarda ham tekshirildi. Klassik usulda o‘lchangan namlik va sensorlardagi namliklar farqi bo‘yicha grafi k va maksimal sensorlarning o‘zaro masofalari jadvali ishlab chiqildi. Olib borilgan ilmiy ishning amaldagi tajribalardan asosiy farqi namlik monitoringi tuproqning 3 xil chuqurligida va yengil qumoq, o‘rta qumoq, og‘ir qumoq, gilli qatlamlarda olib borilganligida. Hozirgi kunda bu kabi texnologiyalarga talab o‘ta yuqori. Tomchilatib sug‘orish tizimidagi yer maydonlar o‘rtacha 15-20 gektarni tashkil etib, bunda sug‘orish oralig‘i va sug‘orish me’yorini aniqlashda daladagi tuproq namligi yuqori o‘rin tutadi. Har doim ham tuproq namunalarini klassik, ya’ni termostat yoki bosh quritish usullari bilan aniqlashning vaqt jihatdan imkoni yo‘q. Quyidagi biz ikki turdagi tuproqni aniqlash usuliga sarflangan vaqt va uning aniqlik darajalarini ham ko‘rib o‘tamiz. Klassik va zamonaviy usulda olingan namlik natijalaridagi xatoliklar klassikda 1%, zamonaviy usulda 10%, zamonaviy usulda olingan ma’lumotlar aniqligini 90 foizdan 97,5-98,5 foizga ko‘tarish bo‘yicha yechimlar ko‘rib chiqiladi.
В данной научной работе приведены результаты испытаний разработанной технологии дистанционного определения влажности почвы при использовании системы капельного орошения в Самаркандской области. Среднегодовое количество осадков в районе исследований составляет 370 мм, площадь – 240 000 м2. Объект, на котором проходят испытания изучаемой технологии, расположен на высоте 634 м над уровнем моря в Пайарыкском районе Самаркандской области с координатами 40°00’43.97’’ 66°54’51.35. Всего объект был разделен на 12 небольших участков, где в каждом небольшом объекте были установлены датчики измерения влажности, а для их связи использовались GSM-модули. Для анализа эффективности и точности результатов данные с каждого датчика проверялись один раз в 2 дня в термостатах по классической методике. График и таблица максимальных взаимных расстояний датчиков были построены на основе влажности, измеренной классическим способом, и разницы влажности в датчиках. Основное отличие проведенной научной работы от практических экспериментов заключается в том, что мониторинг влажности проводился на 3-х разных глубинах почвы в легко-, средне- и тяжелосуглинистых слоях глины. В настоящее время спрос на такие технологии очень высок, как известно, площадь земель в системе капельного орошения составляет в среднем 15-20 га, а влажность почвы на поле играет основную роль в определении интервала поливов и поливной нормы. Не всегда есть возможность по времени определить пробы почвы классическими, т. е. термостатными или напорными методами. В данной статье рассмотрены методы, используемые для определения двух типов грунта, и уровни их точности.
This scientific piece of work shows findings from tests of the technology designed for remote determination of the soil moisture in the use of drip irrigation system in Samarkand region. The average annual rainfall of the research area is 370 mm, the area is 240 000 m2. The site where the technology was subject for tests, is located 634 m above the sea level in Payariq district of Samarkand region 40°00’43.97’’ 66°54’51.35. The area was divided into 12 smaller sites, humidity measuring sensors were installed in each of the sites and GSM modules were used for their communication. To ensure efficiency and accuracy of the results, we would check the data collected by each sensor once every 2 days by thermostats, using a classical method. A graph and a table of maximum sensor mutual distances were developed based on the humidity levels measured in the classical way as well as applying the humidity difference in the sensors. The main difference between the conducted scientific work and practical experiments is that monitoring of the moisture levels was carried out at 3 different depths of the soil and in layers of the light-, medium- and heavy loams. As a matter of fact, currently, such technologies are highly demanded as the area of lands in the drip irrigation system covers in average 15-20 hectares, and the soil moisture is important for determining the irrigation intervals and time. However, it is not always possible, time-wise, to determine the soil samples using the classic-, thermostat- or head drying methods. This article will review the methods applied for determining the two types of soil and their accuracy levels.
№ | Муаллифнинг исми | Лавозими | Ташкилот номи |
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1 | Arifjanov A.M. | texnika fanlari doktori, professor, “Gidravlika va gidroinformatika” kafedrasi mudiri | “Toshkent irrigatsiya va qishloq xo‘jaligini mexanizatsiyalash muhandislari instituti” Milliy tadqiqot universiteti |
2 | Samiyev L.N. | texnika fanlari doktori, “Gidravlika va gidroinformatika” kafedrasi dotsenti | “Toshkent irrigatsiya va qishloq xo‘jaligini mexanizatsiyalash muhandislari instituti” Milliy tadqiqot universiteti |
3 | Otaxonov M.Y. | texnika fanlari bo‘yicha falsafa doktori (PhD), “Gidravlika va gidroinformatika” kafedrasi dotsenti | “Toshkent irrigatsiya va qishloq xo‘jaligini mexanizatsiyalash muhandislari instituti” Milliy tadqiqot universiteti |
4 | Jalilov S.M. | “Gidravlika va gidroinformatika” kafedrasi magistranti | “Toshkent irrigatsiya va qishloq xo‘jaligini mexanizatsiyalash muhandislari instituti” Milliy tadqiqot universiteti |
№ | Ҳавола номи |
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