DEVELOPMENT OF AN INNOVATIVE IRRIGATION SYSTEM FOR DRAGON FRUIT FARMING

<p class="Abstract">Proper watering system will increase plant growth. Water become important part of dragon fruits growth, it should be fullfilled and controlled. A village with soil characteristic mostly hilly topography, dry, less of water, rocky, and limited plant (dry plant only) need special treatment for being a planting land. But it has some local wisdom exists, the most popular are dragon fruits. A drip irrigation system is applied as an innovation of watering plants method. Water distribute through capillary tube, driply through the plant and controlled, called drip irrigation system. The aim of this reseach to explain the use of drip irrigation system on dragon fruit plant. Observation and experimental studies has conducted, the community considers drip irrigation as a new technology, presentations show that it is suitable to be applied in their area. This implementation able to improve the efficiency and effectiveness of irrigation through dragon fruits in the village. Futhermore, the implementation of this technology can be used as a real work example to build a better Indonesia.</p>

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Red beet in the Republic of Dagestan

Kartofel` i ovoshi ◽

10.25630/pav.2021.14.27.003 ◽

2021 ◽

pp. 20-22

Author(s):

А.Ш. Халимбеков ◽

С.А. Курбанов ◽

Д.С. Магомедова

Keyword(s):

Drip Irrigation ◽

Irrigation System ◽

Water Flow Rate ◽

Experimental Studies ◽

Drip Irrigation System ◽

Water Control ◽

Optimal Scheme ◽

Working Solution ◽

The Republic ◽

Factor C

Представлены материалы экспериментальных исследований по разработке элементов технологии возделывания столовой свеклы на луговых среднесуглинистых почвах сухостепной равнинной зоны Дагестана. Цель исследований – повышение урожайности свеклы столовой на основе выбора оптимальной схемы и густоты посева свеклы сорта Бордо 237, а также применения регулятора роста Биостим Универсал с использованием системы капельного орошения. Фактор А – схемы посева с двумя вариантами: А1 – широкорядный посев с междурядьем 45 см (контроль) и А2 – двустрочный ленточный посев по схеме 20+50. Фактор В – густота посевов с тремя вариантами: В1 – расстояние в ряду через 6 см, В2 – через 8 см и В3 – через 10 см соответственно, что в зависимости от схемы посева обеспечивало густоту посева столовой свеклы от 222 до 473 тыс. шт/га. Фактор С – обработка растений с двумя вариантами: С1 – опрыскивание водой (контроль) и С2 – некорневая подкормка биостимулятором-антистрессантом Биостим Универсал (в фазе 4–6 листа) и при 50%-ном смыкании рядков (в фазе 8–10 листа). Доза применения препарата – 2,0 л/га с расходом рабочего раствора 200–400 л/га. Система капельного орошения состояла из поливных трубопроводов с расстоянием между ними 0,7 м, между капельницами – 0,3 м с расходом воды 2 л/ч. Средний срок посева – первая декада апреля. Поддержание необходимого режима орошения свеклы столовой обеспечивали вегетационными поливами с нормой 125 м3/га при оросительной норме 2875 м3/га. Выявлено, что наиболее оптимальная схема посева столовой свеклы: двустрочный ленточный посев – 20+50 см с расстоянием в ряду через 8 см, которая при двукратной некорневой подкормке препаратом Биостим Универсал в дозе 2,0 л/га с расходом рабочего раствора 200–400 л/га обеспечивает урожайность 59,8 т/га корнеплодов при их высоком качестве. The materials of experimental studies on the development of elements of the technology of cultivation of table beets on meadow medium loamy soils of the dry-steppe plain zone of Dagestan are presented. The purpose of the research is to increase the yield of table beet based on the selection of the optimal scheme and the density of sowing of Bordo 237 beet, as well as the use of a Biostimulator growth regulator using a drip irrigation system. Factor A is a seeding scheme with two options: A1 is a wide-row seeding with a row spacing of 45 cm (control) and A2 is a two-line ribbon seeding according to the scheme 20+50. Factor B is the density of crops with three options: B1 – the distance in a row after 6 cm, B2 – after 8 cm and B3 – after 10 cm, respectively, which, depending on the sowing scheme, provided the density of table beet sowing from 222 to 473 thousand pcs/ha. Factor C – treatment of plants with two options: C1 – spraying with water, control and C2 – foliar feeding with biostimulator-antistressant Biostim Universal (in the phase of 4–6 leaves) and with 50% closure of rows (in the phase of 8–10 leaves). The dose of the biostimulator is 2.0 l/ha with a working solution consumption of 200–400 l/ha. The drip irrigation system consisted of irrigation pipelines with a distance of 0.7 m between them, 0.3 m between droppers with a water flow rate of 2 l/h. The average sowing period is 1 decade of April. Maintenance of the necessary irrigation regime of the canteen beet was provided by vegetation irrigation with a rate of 125 m3/ha with an irrigation rate of 2875 m3/ha. It was revealed that the most optimal scheme for sowing table beets: two-line ribbon sowing – 20+50 cm with a distance in a row through 8 cm, which, with two-fold foliar top dressing with a Biostim Universal at a dose of 2.0 l/ha with a working solution consumption of 200–400 l/ha, provides a yield of 59.8 t/ha of root crops with their high quality.

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Developing a Hybrid Solar/Wind Powered Drip Irrigation System for Dragon Fruit Yield

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/180/1/012034 ◽

2017 ◽

Vol 180 ◽

pp. 012034 ◽

Cited By ~ 1

Author(s):

I Widiastuti ◽

D S Wijayanto

Keyword(s):

Solar Wind ◽

Drip Irrigation ◽

Irrigation System ◽

Fruit Yield ◽

Drip Irrigation System ◽

Dragon Fruit

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Design of a Drip Irrigation System for the Dragon Fruit Cultivation

Jurnal Keteknikan Pertanian ◽

10.19028/jtep.06.1.1-8 ◽

2018 ◽

Vol 6 (1) ◽

pp. 1-8

Author(s):

Indah Widiastuti ◽

◽

Danar Susilo Wijayanto ◽

Keyword(s):

Drip Irrigation ◽

Irrigation System ◽

Drip Irrigation System ◽

Fruit Cultivation ◽

Dragon Fruit

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ESTIMATION OF CONSUMPTIVE USE OF POTATO CROP PIANTED UNDER DRIP IRRIGATION SYSTEM BY USING SWRT TECHNOLOGY

Al-Qadisiyah Journal For Agriculture Sciences (QJAS) (P-ISSN 2077-5822 E-ISSN 2617-1479) ◽

10.33794/qjas.vol10.iss1.109 ◽

2020 ◽

Vol 10 (1) ◽

pp. 271-282

Author(s):

J.N. Abedalrahman ◽

R.J. Mansor ◽

D.R. Abass

Keyword(s):

Water Consumption ◽

Drip Irrigation ◽

Soil Depth ◽

Irrigation System ◽

Potato Crop ◽

Block Design ◽

Organic Fertilizer ◽

Control Treatment ◽

Drip Irrigation System ◽

Spring Season

A field experiment was carried out in the field of the College of Agriculture / University of Wasit, located on longitude 45o 50o 33.5o East and latitude 32o 29o 49.8o North, in Spring season of the agricultural season 2019, in order to estimate the water consumption of potato crop using SWRT technology and under the drip irrigation system. The experiment was designed according to Randomized Complete Block Design (RCBD) with three replications and four treatments that include of the SWRT treatment (the use of plastic films under the plant root area in an engineering style), and the treatment of vegetal fertilizer (using Petmos), organic fertilizer (sheep manure), and the control treatment . Potato tubers (Solanum tuberosum L.) var. Burin was planted for spring season on 10/2/2019 at the soil depth of 5-10 cm. The highest reference water consumption for the potato crop during the season was calculated by Najeeb Kharufa, which was 663.03 mm. The highest actual water consumption for the potato crop during the season for the control treatment was 410.1 mm. The results showed increase in the values of the crop coefficient (Kc) in the stages of tubers formation and tubers filling stage as compared to the vegetative and ripening stages, ranged from 1.37-1.92 for the two stages of tubers formation and tubers filling. The SWRT treatment gave the highest water use efficiency during the season, was 3.46 kg m-3 .

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