RU2652829C1 - Drip irrigation method - Google Patents

Abstract

FIELD: land reclamation.

SUBSTANCE: invention relates to the field of reclamation and can be used in irrigation of crops. During the implementation of the drip irrigation method of vegetable and berry crops, water is supplied to the plants by means of distribution pipelines. Pipelines are equipped with droppers. Water is fed directly to the root zone of plants at a rate of irrigation from 0.2 to 0.4 l/h. Water supply is carried out during the day during irradiation of plants by solar radiation. Supply of water to plants is carried out from special storage tanks. Storage tanks are equipped with siphons with pipelines connected to them.

EFFECT: efficiency of irrigation increases due to soil moistening only in the root zone.

1 cl, 6 dwg

Description

The invention relates to agricultural reclamation, in particular to drip irrigation, and can be used for irrigation of crops, especially for regions with an arid climate and southern regions with large average monthly insolations.

Watering plants is a determining factor for obtaining a good harvest throughout the entire cycle of plant development (growing season) from sowing seeds and / or planting tubers to ripening the crop.

Currently, for vegetable and fruit crops, mainly the following three methods of irrigation are used.

- Sprinkling, in which water is sprayed in the form of rain over the surface of the soil and plants. It is the most common type of irrigation due to its low cost and simplicity. However, with such irrigation, water is consumed uneconomically, a significant amount, as a rule, is wasted.

- Intrasoil irrigation, in which water flows directly to the roots of plants through pipes laid in the soil. It is very effective in the consumption of water and fertilizers. But it is expensive, it requires serious maintenance costs, therefore it is not applicable in private garden plots.

- Drip irrigation, in which water is supplied to plants using special drip tapes or tubes. It is characterized by high efficiency of using irrigation moisture and liquid fertilizers, which allows not only to reduce water consumption by 3-5 times compared to sprinkling, but also to significantly increase productivity [http://www.yug-poliv.ru/oroshenie/capelnoe/; http://parnikiteplicy.ru/poliv/kapelnoe-oroshe-nie-2.html.].

The closest prototype is drip irrigation, in which water is supplied to plants, and water is supplied almost directly to the root zone of plants at fairly low speeds. There are two main types of drip irrigation systems that use elastic tubes and droppers or special drip tapes with water outlets to supply moisture to plants.

Systems on a drip tape - between the rows of plants a flexible hose (tape) of a special design is laid in which there are built-in or mounted water outlets with a fixed moisture consumption. Most often, a tape with a slotted or emitter internal structure of water outlets is used. The first has a built-in labyrinth channel, which slows down the water supply rate and normalizes its flow rate through the outlet openings cut into the walls of the tape. The emitter tape is made with droppers built-in with a given step. As a rule, the flow rate of water is from 2 to 8 liters per hour. The distance between the emitters in the tape varies from 10 to 50 cm. Most drip tape systems are designed to be connected to a water supply with a nominal pressure of 0.8 bar.

Elastic tube systems with droppers - PVC elastic tube extends along ridges. With the help of special fittings, bends equipped with droppers are organized with the required frequency from it, through which water is supplied to plants at a speed of 2 to 8 liters per hour [Russian Academy of Agricultural Sciences, GNU All-Russian Research Institute of Vegetable Production. Irrigation regime, methods and techniques for watering vegetables and melons in various zones of the Russian Federation. Leadership. Moscow, - 2010, p. 72 and 77. Yasonidi O.E. Water-saving technologies for crop irrigation in the North Caucasus: dis. ... Dr. S.-kh. sciences. Novocherkassk, NGMA, 2004].

The disadvantage of this method is the relatively high speed of water supply, which can lead to an increase in one-time watering rates for vegetable and berry crops due to evaporation from the surface and the spread of moisture outside the root zone of the plant.

The problem to which the invention is directed is the creation of a drip irrigation method that allows to increase the drip irrigation efficiency due to rational moistening of the soil only in the root zone of plants and reducing the surface area of the wetting spot.

The problem is solved by the proposed method of drip irrigation of vegetables and berries, including water supply to plants using distribution pipelines equipped with droppers, and water is supplied directly to the root zone of plants with an irrigation rate of 0.2 to 0.4 l / h during the day during irradiation of plants with solar radiation, and water is supplied from storage tanks equipped with siphons with distribution pipelines connected to them.

The technical result of the proposed invention is that the irrigation rate is 5 ... 10 times lower than in existing systems. Due to this, the following results are achieved:

- daily drip irrigation with low speeds at the level of 0.2-0.4 l / h with a watering rate of not more than 1.2-1.8 l / plant, provides during the day an almost complete metabolism of vegetable and berry crops, as well as high transpiration rates. At the same time, an increase in the volume of absorbed moisture by 1.4-1.5 times as compared with other irrigation modes and methods is realized with water saving of not less than 1.5 times compared with the classic drip;

- the possibility of local application of fertilizers to the root zone along with water is realized, reduction of fertilizer consumption by 25-40% in relation to classical drip irrigation systems;

- provides a reduction in water consumption for evaporation up to 20-30% compared with classical drip irrigation due to a decrease in the surface area of evaporation by 2 or more times;

- reduced the cost of processing the site in connection with less development of weeds;

- there is no danger of secondary salinization and the exclusion of the risk of sunburn of leaves due to small irrigation rates;

- increases the yield of vegetable and berry crops by 20-40% (relative to peers) due to the stable moistening of the root zone at a level of not less than 90% HB (the lowest moisture content of the soil).

The greatest effectiveness of the application of the present invention for irrigation of vegetables and berries in the open field is achieved in southern regions with a large number of sunny days in a year and regions with an arid climate.

The method is as follows.

Between the rows of plants or near them from the storage tanks equipped with siphons, distribution pipelines equipped with droppers are laid. Water is supplied directly to the root zone of plants with an irrigation rate of 0.2 to 0.4 l / h and an irrigation rate of not more than 1.2-1.8 l / plant. Watering is carried out in the daytime during periods of irradiation of plants with solar radiation. The incoming moisture from irrigation is spent on evaporation from the surface of the soil, changing the moisture content of the soil and transpiration. It protects the plant from overheating, participates in the creation of a continuous flow of water with dissolved mineral and organic compounds from the root system to the aboveground organs of the plant, that is, it actually ensures the metabolism or metabolism of the plant. Typically, the transpiration rate ranges from 15 to 250 g / m ² × h, and at night it decreases to 7-20 g / m ² × h. The intensity of daytime transpiration follows a change in the main meteorological factors: total solar radiation, temperature, air humidity. The main in this complex of external influences is solar radiation. In clear sunny weather, its value is about 1000 W / m ² , and in cloudy weather, depending on the thickness and nature of the clouds, it decreases to about 400-100 W / m ² [Gubatenko NG, Miroshnichenko MM "Garden. Practical Guide ”, Rostov-on-Don: Rostov Book Publishing House, 1991; Litvinov SS, “Scientific Foundations of Modern Vegetable Production” Russian Agricultural Academy, 2008; Obukhov D.L. “Linear parameters of humidification contours during drip irrigation”, Novocherkassk State Reclamation Academy (Novocherkassk)].

Example 1

In 2016, at a special experimental site, experimental studies of various modes of focal drip irrigation of medium-varietal varieties of cucumbers and pumpkins were carried out. An example is illustrated by images, where in FIG. 1 shows a photograph of a test site as of May 2016, and FIG. 2 - photograph of the experimental site as of August 2016.

Daytime irrigation was carried out at low irrigation rates of 0.2-0.3 l / h. Night watering was carried out at speeds of 0.2-1 l / h. Observations of the state of plants were carried out around the clock.

In the daytime, the leaf absorbs about 75% of the solar energy incident on it, but only about 3% of the absorbed light is used in the process of photosynthesis. The rest is converted into thermal energy, which leads to an increase in the temperature of the sheet. Therefore, it must be removed to avoid overheating and death of leaf tissue. The main mechanism of removal is transpiration. In the sun, a plant evaporates about 50 cm ^{3 of} water per 1 m ^{2 of} leaf surface in 1 h. Under conditions of a deficit of moisture in the root zone, for each leaf, salvation from overheating is the realization of a decrease in the absorbed solar energy by reducing the effective absorption area, that is, by wilting it.

In FIG. 3, 4, 5, 6 as an example, photographs of pumpkin plants (Figs. 3 and 5) and cucumbers (Figs. 4 and 6) are given during daytime irrigation with a single irrigation rate of not more than 1.2-1.6 l / plant (Fig. 3 and 4), and night watering with a watering rate of 2.2-2 l / plant (Figs. 5 and 6) carried out on the eve of the day of shooting.

From the above photos it can be seen that daily drip irrigation with low speeds of 0.2-0.3 l / h, with a watering rate of 1.6 l / plant, provides a clear metabolism of vegetable crops of the pumpkin family at clear maximum daylight speeds at the highest transpiration rates.

It was experimentally confirmed that daily drip irrigation with low speeds at the level of 0.2-0.4 l / h with an irrigation rate of no more than 1.2-1.6 l / plant provides almost complete metabolism of vegetable crops and, accordingly, high transpiration rates during the day.

Example 2

Similarly to example 1, a drip irrigation system was developed according to the proposed method for 40 plants of the family Rosaceae, namely strawberries. The irrigation rate was 0.2 l / h with a single irrigation rate of 1.2 l per plant. Some plants were not included in the drip irrigation system and were watered by sprinkling from a watering can. Results: water consumption during irrigation was reduced by at least 5 times compared with the previously irrigation method used by irrigation.

Claims (1)

A method of drip irrigation of vegetables and berries, including the supply of water to plants using distribution pipelines equipped with special droppers, characterized in that water is supplied directly to the root zone of plants with an irrigation rate of 0.2 to 0.4 l / h during the day during periods of plant irradiation with solar radiation, and water is supplied from storage tanks equipped with siphons with distribution pipelines connected to them.

Images