RU2664834C1 - Integrated method of creation of microclimate for growing and protection of vineyards and stationary technological system of transport air pipelines for the creation of microclimate on vineyards - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: group of inventions belongs to the field of agriculture and can be used in the cultivation, irrigation and protection of vineyard plantations. When implementing the method of creating a microclimate for growing and protecting vineyards, transport technological solutions or water to the working areas of the site. Transportation is carried out using a piping system. For transportation, a pipeline system is prepared and blown through with air. When steady values of pressure are reached, technological components, solutions or water are introduced into the airflow in the system. Resulting mixture is fed into the working zone through open process openings.EFFECT: improved irrigation, reliable protection of plants and maintenance of optimal growth conditions, vegetation and fruiting of vineyards.8 cl, 5 dwg

Description

The invention relates to agriculture; namely, viticulture, and is intended for cultivation, irrigation and protection of vineyard plantations.

Increasing grape production is one of the most important tasks that can be solved by intensifying viticulture, improving the technology of cultivating crops, and also by managing climate resources associated with regulating the influence of meteorological factors on the development, growth, formation, protection of grapes, increasing productivity and quality improvement. At present, a comprehensive system has not been formed that provides a solution to all technological agricultural practices that take into account the results of wintering, conditions of vegetation, flowering and ripening of grapes. Industrial viticulture is often located in regions with clearly insufficient formation of a soil and air humidity regime. In view of this, a set of measures is required for the maintenance and cultivation of soil, aimed at the optimal and economical use of moisture.

The most promising method of irrigation and creating an optimal microclimate is fine dispersion irrigation, which consists in lowering the temperature of the air and the plant itself on hot dry days, increasing the humidity of the surface air layer at critical moments, which helps to increase the photosynthetic activity of the leaves. For fine sprinkling irrigation use units DDA - 100 MA, TOU - 7, sprayers OP - 450, KSID - 50, DSHI - 77.

A known method of growing crops and a vegetation system for creating a microclimate (patent RU No. 2338368), comprising a wind-shelter around the perimeter of the land, valves supplying a pipe, a water reservoir, a hydraulic accumulator, a flow heater, a column having a movable part to house at least two distribution pipes, distribution pipes equipped with humidifying nozzles, an automated control system comprising a control controller and humidity and temperature sensors. The disadvantage of this method and system is the limited use due to the use for crops located on a small area.

A known processing method and the Golden Spray irrigation system, including fine-dispersed irrigation of plantings by using a working body in the form of a hose, which contains holes made by a laser at different angles (Internet resource http://kazap.ru/water_garden/471, date appeal 04/09/2015). The hose can trap a strip of up to 10-12 meters, 5-6 meters on each side of the hose, with fine-dampened humidification. This system is distinguished by reliability and quality and is intended both for large agricultural enterprises, farms, and for suburban areas. Easy installation and dismantling of the piping system and valves, simple operation, moderate consumption of water and electricity makes the Golden Spray system economically attractive. The disadvantage of such a system is narrow focus, i.e. the ability to carry out only irrigation and the difficulty of using thickened planting of vineyards, the possibility of waterlogging of the soil during prolonged or frequent operation of the system; the impossibility of heating the environment due to the heat of moisturizing water during periods of cooling, and also does not provide the required high quality crop and does not exclude the possibility of damage to the grapes by fungal diseases.

A known method of irrigation, including the distribution of water over a site in the piping system, and an irrigation system, including a water source, a pumping station with shut-off valves and a manometer, a main pipeline, sequentially installed distribution pipelines of subsurface and drip irrigation, parallelly distributed along the length of the distribution pipelines, irrigation pipelines and perpendicular humidifiers in the form of polyethylene pipes with perforations of the soil Nia and flexible irrigation pipes with drippers drip irrigation (patent RU №2346427).

The disadvantage of this method and system for its implementation is also the inefficiency of application for growing vineyards due to the possibility of waterlogging of the soil during prolonged or frequent operation of the system; the impossibility of heating the environment due to moisturizing water during periods of cooling, high water consumption.

A known method of sprinkling, in which the piping system is located throughout the vineyards. Working pipes are installed above the rows of landings, stationary short-jet nozzles mounted in a checkerboard pattern every 7.5 meters are mounted on the pipes. Such a narrowly targeted system is used for irrigation and foliar feeding of plants. Does not perform the complex task of plant protection. (UDC 634.87.631.117 "Modern and promising methods of irrigation of grapes in Ukraine", A.D. Lyannoy, Ph.D. of the Tairov UniiviV, p. 162).

A known system for the automated control and cultivation of crops such as grapes, including computer control of irrigation and the delivery of chemicals using a multi-channel pipeline. The system performs precise control of the dosage of water and chemicals such as insecticides, fungicides, etc. Materials incompatible in their characteristics are transported through the general assembly of a multi-channel pipeline, each separately along its own channel. Sensors located on the pipeline monitor and regulate the manufacturing process. Pipes can be raised above the ground or lowered below ground level. The system is placed between the rows of the vineyard, and the solutions are moved along a set of flexible capillary tubes with holes that are equipped with emitters for spraying reagents or water. The user can configure the distribution of each chemical at a predetermined time in certain quantities (patent US 6874707, published 05.04.2005)

All analogues of the described methods and systems of pipelines have similar tasks and elements of systems, but solve the narrow problems of irrigation, spraying and plant nutrition and partially fulfill the functions of control and management. They do not solve the problem of an integrated approach to the implementation of all necessary technological measures for growing and protecting vineyards. The working pipes of pipelines are installed at one level, or not high above the soil, or in an underground position, or over rows of landings, so they are not effective enough. Pipes are provided with perforations in the form of small holes used for drip or fine-dispersion irrigation. The holes are equipped with drip outlets or droppers, nozzles, emitters, short-jet nozzles and other types of sprayers, which have a complex structure, are also often clogged and are not reliable.

The objective of the invention is to provide a comprehensive method for creating a microclimate for growing and protecting vineyards using a stationary system of transporting air pipelines to create a microclimate in the vineyards.

The technical result of using the method and device for its implementation is the implementation of improved irrigation, more reliable plant protection, maintaining optimal conditions for growth, vegetation and fruiting of vineyards.

The technical result is achieved by the fact that in an integrated method of creating a microclimate for growing and protecting vineyards, which includes measures in which technological solutions or water are transported and distributed over the working areas of the site, while prepared solutions or water are pumped through the piping system and delivered to the workers' final points pipelines of the system, to create a microclimate, a set of measures is carried out using air, which is injected under pressure into the piping system, mix ayut and / or sprayed technology components, solutions or water, is transported through the pipe system is fed into the work zone and discarded through the open hole working process piping system; moreover, technological components, solutions, or water are introduced into the air stream in the mixing chamber of the preliminary part of the piping system, where they are mixed and / or sprayed to obtain an air or water-air mixture, and the piping system is preliminarily brought to operating conditions of the process with a pressure of 1 to 20 atmospheres and more, depending on the area of the treated area and the type of technological operation, while the system is first prepared and purged with one air, and when stable pressure values are reached into the flow in zduha administered in a mixer technology components, solutions or water, and the prepared mixture is fed into the work zone and discarded through open access ports in diameter from 3 to 20 millimeters, depending on growth conditions and plant architecture crown vine,

For effective ventilation and spraying, the flows of air or air-water mixture from the upper and lower pipelines are directed towards each other at different angles, creating a turbulent medium in the processing zone. For optimal processing efficiency, forced variable pressure control of the injected air in the treatment zone is used from its minimum to the maximum possible value with a frequency of 1 to 5 seconds.

Depending on weather conditions, to protect plants from winter frosts, icing, spring frosts, drizzling rains, fogs, strong cold winds, dry winds, high temperatures, air alone at a different temperature and humidity is supplied through a piping system to the working area under different pressures.

To carry out a complex of technological measures, all necessary components are used for this: dry ground materials, bulk solids, chemicals, solutions, water - in the form of air or water-air mixtures; or air alone. And the same channel of the piping system is used to work with dissimilar chemicals separately or together, and after each technological operation the system is cleaned with neutralizing agents and / or washed with water and / or purged with air.

The stationary piping system used to implement the method to create a microclimate in the vineyards, including trunk pipelines, intermediate pipelines and working pipelines with perforations installed below or above the rows of plantings, a water source, a pump station with a pressure tank, a water heater, shutoff valves, dispensers, sensors, measuring equipment, control panel, automated control system and computer control of the piping system; additionally contains a compressor, heater and air cooler, stationary tanks for solutions of chemicals and bulk materials, equipped with feeding equipment and supply piping with shut-off valves, and also further comprises a mixing chamber located in the preliminary part of the system, after the compressor receiver, into which air, all technological components, solutions, water, from which there are several main conclusions with shutoff valves for several main t pipelines connected through intermediate pipelines with their shutoff valves installed in front of the working pipelines, with working pipelines located at the bottom and top of each row of stands and provided with perforations in the form of open technological holes with a diameter of 3 to 20 millimeters, made along the entire length of the working pipelines individually or belts, perpendicular or under an arbitrary angle to the surface of the pipes, at equal distances, from 20 to 100 millimeters, moreover, on the lower working pipelines hole holes and hole belts are made only on the upper part, at 150 ° of the pipe cross-section, and on the upper working pipelines, holes are made either doubled, located opposite to one plane, or belts, circularly, over the entire surface of the pipes, through the same distances, twice as much, and half the cross-sectional area than the lower working pipelines, while the total cross-sectional area of the technological holes on the lower pipeline and on the upper pipeline is the same a, and for working pipelines with a cross section from 1 inch to 4 inches, technological holes on them with a diameter of 3 mm correspond. up to 20 mm., depending on the area of vineyards and planting patterns and plant formations.

In known devices for irrigation and spraying, compressed air is used as a means for expelling liquids and solutions. In the inventive method, the pressure pumped air is a transport for moving small amounts sprayed in the air volume of the line of technological components at a very high speed, creating a spray effect in the form of fog through relatively large pipe openings.

The stationary technological system can operate in forced alternating mode with a changing pressure of the air pumped into the line. This creates the effect of "gusts of wind", directed from the bottom up and improves the conditions of ventilation and, especially, spraying grape bushes.

When the pressure changes, the effect of “gusts of wind” will intensify, shoots with leaves will be set in motion, randomly moving, rising and falling, turning with different surfaces, and the substances sprayed in the caudal volume of the vineyard will evenly settle on all sides of the vine, leaves and bunches. The consumption of substances will be minimal, since the process itself will occur in a very short time, within 10-30 seconds at the same time on the entire plantation area. After spraying, suspended in the air particles of the substance will still settle for some time on different surfaces of the bushes.

The use of the system allows not only fine irrigation, but also use all kinds of options for moisture thermal macro - and microelement processing to improve the microclimate in the above- and ground air layer, establish optimal temperature and humidity conditions, save irrigation water and increase the yield of vineyards.

In FIG. 1 shows a schematic view of a stationary technological system of transporting air pipelines located in a vineyard.

In FIG. 2 shows working pipelines mounted on trellis supports.

In FIG. Figure 3 shows the grape processing scheme using the example of thickened nozzles of promising formations placed on a two-level eight-cordon trellis.

In FIG. 4 shows a scheme for processing the vineyard from the aisle.

In FIG. 5 shows a diagram of an intensive type vineyard farm using highly productive formations.

The stationary technological system of transporting air pipelines (Fig. 1 and Fig. 2) includes a compressor 4, a heater 3 and an air cooler 5, a pump 10 for supplying water, a water heater 13, reservoirs 7 for containing solids with a dispenser 8 for introducing granular substances into mixing chamber 9. reservoirs 11 for the content and preparation of solutions, a dispenser 14 for supplying solutions to the mixing chamber 9. The air is pumped from the compressor 4, through the mixing chamber 9 through the main pipe 21 laid in There are blocks of 19 stands, intermediate pipelines 22, and working pipelines of smaller diameters 16 and 18, laid in each row. Water is taken from the production well 15 and, if necessary, can be heated by a heater 13. All pipelines are equipped with shut-off valves 20 and pressure and temperature control devices 12.

Sensors 6 of atmospheric temperature and humidity are located throughout the plantation area at the most characteristic points of the plots.

The system is operated both in manual, semi-automatic mode, and in automatic mode from the control and control panel 1 located in the control room 2 and operated by one operator - a technologist.

The sprayed solution and / or bulk substances are transported to the working area through working pipelines 16, 18, laid along each row in two lines at the top and bottom of the trellis 17. The optimal parameters of the pipeline (diameter, length) are selected depending on the size of the plantation and the required pumping capacity water and air. The preferred diameters of the working pipeline 1-4 inches. The working pipeline is perforated in the form of open holes of a sufficiently large diameter - from 3 to 20 mm. The holes are located at 30 ° along the pipe cross-section with belts, perpendicular or under the corner to the pipe surface, at equal distances, every 20-100 centimeters. On the upper pipeline, the hole belts are made uniformly, circularly, and on the lower pipeline in the same order, but only on the upper surface, 150 ° of the cross section, in an amount half as small. Due to the fact that the lower pipeline has half the holes of larger diameter with the same total cross-sectional area, the volume of air flow from the lower pipes directed upward is twice as much as from the upper ones. Air flows from the upper and lower working pipelines, directed towards each other at different angles, create a turbulent medium in the treatment zone, cause shoots with leaves to move in a chaotic manner, which ensures effective ventilation and spraying of plants.

In the case of the use of a working pipeline made of plastic, the system can be operated without repair for many years.

The described stationary system makes it possible to carry out the entire cycle of agricultural operations and obtain guaranteed grape harvests.

Before starting work, the technological system of pipelines is brought into working condition. For this, the piping system is preliminarily flushed with one air and brought to the operating modes of the process with a pressure of 1 to 20 atmospheres, depending on the area of the treated area and the type of technological operation. The pressure value is controlled by the readings of the instruments. As soon as the pressure reaches stable values, the system is ready for operation, then the necessary technological components are fed into the mixing chamber into the air stream, mixed or sprayed, and through the piping system, the finished mixture is fed into the working area.

The main technological measures solved by the application of technical methods using a stationary technological system are:

- protection of plants in winter and spring from critical temperatures, fogs, drizzling rains, strong cold winds, icing;

- airing and maintaining optimal conditions in the summer;

- Protecting plants from pests and diseases;

- fertilizer in the vineyards;

- irrigation of vineyards;

- additional activities. Examples of specific performance.

Protection of plants in winter and spring from critical temperatures.

Example 1. For non-covering zones of viticulture in winter at temperatures below -15 ° in a stationary technological system include heating vineyards with warm air. The air temperature on the plantations is monitored around the clock.

Example 2. For shelter zones, frost protection is more effective. The vines are laid along a row, pinned to the soil and covered with a dense "breathing" fabric. The upper working pipeline is closed for the winter. In a stationary technological system, warm air is slowly fed into the shelter zone through the lower working pipeline, maintaining the set temperature.

Example 3. In winter, there are often prolonged thaws, which, ahead of the set time, bring plants out of dormancy.

In these cases, cold air is supplied through a stationary technological system to smooth out a sharp temperature drop and maintain an optimum temperature.

Example 4. With the beginning of the growing season, with the threat of matinees, in a stationary technological system, the mode of heating with warm air with high humidity is used. For this, a stream of water is introduced into the air stream in the mixing chamber 7. At the end of the work, the piping system is dried by a stream of air, cleaning the pipes from moisture and contaminants.

Airing and maintaining optimal conditions in the summer.

Example 5. Airing is carried out on hot calm days by pumping cool air through a stationary technological system. To increase humidity in the mixing chamber 7 serves a stream of water. Temperature and humidity are monitored using sensors. At the end of the work, the piping system is dried.

Example 6. During the flowering of grapes, it is necessary to maintain optimal temperature and humidity for better fertilization of the ovaries. Therefore, they conduct observations around the clock and, if necessary, include a stationary technological system, adjusting temperature and humidity during the day and night hours.

Example 7. During the ripening of the crop maintain the temperature in the required range around the clock, especially at night, avoiding large drops.

Protecting plants from pests and diseases.

Example 8. Spraying with liquid chemical solutions. The pre-prepared solution is fed through the dispenser 9 into the mixing chamber 7, where the solution is sprayed with a stream of injected air and supplied through the pipelines to the working area. The process is best done under variable pressure. After spraying, water with a chemical neutralizer is supplied to a stationary technological system for purification of residual reagents under slight pressure. Then, air is injected under pressure to dry the pipeline.

Example 9. The spraying of bulk substances (sulfur, ash, etc.). To do this, pre-ventilate the vineyard by supplying water to a stationary technological system to increase air humidity. In this case, a moisture film is created on the leaves. Then the system is dried with a stream of air. After that, the prepared dry substances are fed through the dispenser into the mixing chamber, sprayed and transferred to the working area by pressure pumped by pressure. The process is best done in variable pressure mode. A cloud of dust (atomized substance) evenly settles on all surfaces of the vine and leaves. At the end of spraying, the system is washed and dried.

Example 10. Spraying leaves and bunches with a solution of organic fertilizer (liquid, fresh manure) for protection from oidium. The process is carried out similarly to process 8.

Example 11. Spraying pesticides to kill weeds. The process is carried out analogously to example 9.

Fertilizer in the vineyards.

Example 12. Fertilizing vineyards by applying foliar top dressing, for example, urea, is carried out by spraying. At the same time, for better adhesion of the granular reagent, washing powder is added to the water and the plants are treated. After that, the stationary technological system is washed with water and dried. Then, the prepared powdery substance is sprayed in a variable pressure mode. After the work is completed, the stationary technological system is briefly washed with water and dried with pumped air.

Example 13. In the pre-winter period for root top dressing, bulk mineral fertilizers and ashes are added. Prepared process components are sprayed as usual. After spraying, briefly turn on the variable pressure mode in order to shake off the remaining technological components on the soil and feed only water into the stationary technological system, wash the plants and water the soil until the fertilizers are completely absorbed. After the work is completed, the vineyards and the system are air dried.

Example 14. Fertilizing vineyards with the introduction of rotted manure - "grape" is carried out by spraying through a stationary technological system of dry crushed raw materials as in example 13.

Example 15. Fertilizing vineyards with liquid organic fertilizers diluted with water, carried out analogously to example 8.

Irrigation of vineyards includes several types of irrigation.

Example 16. Fine dispersion irrigation. It is carried out by mixing water in a mixing chamber (7) with a stream of injected air at various pressure values and in various water-air ratios, depending on the purpose and the growing season.

Example 17. Jet spraying. It is carried out by supplying only water at the optimum pressure to the system.

Example 18. Water-charging irrigation is carried out only with water at low pressure and long-term water inlet only through the lower working pipeline. After watering, the system is dried.

Carrying out additional events.

Example 19. If necessary, after prolonged prolonged rains, I dry the bushes by supplying air flows to a stationary technological system. If necessary, the bushes are sprayed with reagents in variable pressure mode, then dried, and the system is washed and dried in the usual way.

Example 20. Using a stationary technological system carry out the preparation of bunches of grapes for harvesting. Immediately before harvesting, bushes with bunches of grapes are washed with moderate in intensity jets of water supplied to the system using a gentle alternating air supply. Then the bushes with grapes are dried by feeding warm air under pressure in a variable pressure mode into the pipeline.

Example 21. Using a stationary technological system carry out the sowing of seeds. In spring or autumn, for sodding or cultivating the soil, sow the seeds of grass or siderite. To do this, the seeds pass through the dispenser into the mixing chamber 7 and are dispersed in the normal mode by flow of injected air in the normal mode. After sowing, irrigation is carried out in a finely dispersed manner. Then, using the same dispersal method, the soil is mulched with finely ground materials, such as sunflower husks, straw, sawdust, dry, rotted manure. After mulching, the irrigation is carried out using a low-intensity jet method and, until seedlings appear, they keep the soil moist.

Example 22. Using a stationary technological system for preserving moisture during the growing season, the soil is mulched with any crushed and suitable material.

Example 23. Using a stationary technological system during the ripening of grapes, birds and wasps are scared away, spraying toxic drugs in the daytime that repel or destroy pests.

The introduction of a stationary technological system of transporting air pipelines and a method for creating a microclimate realized with its help is also designed for small farms in the form of intensive type farms for growing vineyards with highly productive plantings, thickened plantings with a high concentration of leaf mass of shoots in the trellis space. The productivity of such plantations, depending on the type of formations, according to preliminary estimates, is 3-13 times higher than existing ones. The proposed system can be used in greenhouses and industrial gardens.

As an example, figure 5 shows a farm on which there are 10 vineyard plots of 1 ha each, a residential complex of 10 apartments and the entire complex of necessary services: 3-entry gates from 4 sides of the plot; 4 - weight; 5 - garages: 6 - mehdvor; 7 - parking of trucks and agricultural machinery: 8 - mechanical workshops; 9 - warehouses; 10 - technological laboratory; 11 - refrigerator; 12 - fruit storage; 2 - hardware, management and control; 13 - a school for growing grape seedlings; 14 - access roads; 21 - trunk pipelines; 15 - garden 1 ha; 17 - well; 16, 18 - working pipelines; 19-10 sites with I-X size of 100 m. × 100 m. And an area of 1 ha; 20 - a garden for 10 plots of 0.05 ha; 30 - residential building for 10 apartments; 23 - household units for 10 owners; 24 - office checkpoint; 25 - garages for vehicles; 26 - yard; 27 - entry road; 28 - tree planting (chestnut, poplar, spruce, linden, walnut, pine); 29 - entrance gate. The farm garden can be cultivated in the same way as a vineyard; the garden and school can only be processed from the bottom pipeline.

The proposed stationary technological system for processing grape plantations, unlike other irrigation systems, works around the clock throughout the year and comprehensively performs all the necessary technological operations, solving problems of optimizing the conditions for growing vineyards, and allows you to quickly manage the formation of a potential, inherent variety, crop. With the complex use of highly effective intensive volumetric formations saturated with green shoots and the creation of a healthy microclimate, plantation productivity can be significantly increased. The simple and reliable design of the system allows you to effectively manage the methods and parameters of the process, to save material resources and human labor costs, high cost recovery, operational efficiency, reducing the work of agricultural technology.

The described microclimate technological system can be successfully applied in modern industrial gardens, especially peach, apricot and plum.

Claims (8)

1. An integrated method of creating a microclimate for growing and protecting vineyards, including measures in which technological solutions or water are transported and distributed over the working areas of the site, while prepared solutions or water are pumped through the piping system and delivered to the terminal points of the system’s working pipelines, characterized in that to create a microclimate, a set of measures is carried out using air, which is injected under pressure into the piping system, mixed and / or sprayed dif- components, solutions or water, is transported through the pipe system is fed into the work zone and discarded through the open hole working process piping system; moreover, the technological components, solutions or water are introduced into the air stream in the mixing chamber of the preliminary part of the piping system, mixed and / or sprayed to obtain an air or water-air mixture, and the piping system is preliminarily brought to operating conditions of the process with a pressure of 1 to 20 atmospheres or more, depending on the area of the treated area and the type of technological operation, the system is first prepared and blown with one air, and when stable pressure values are reached into the air stream and introduced in the mixer technology components, solutions or water, and the prepared mixture is fed into the work zone, emit through open access ports in diameter from 3 mm to 20 mm, depending on growth conditions and plant architecture crown vine. 2. The method according to p. 1, characterized in that the flows of air or air-water mixture from the upper and lower pipelines are directed towards each other at different angles, creating a turbulent medium in the treatment zone for effective ventilation and spraying. 3. The method according to p. 1, characterized in that they apply forced variable control of the pressure of the injected air in the treatment zone from its minimum to the maximum possible value with a frequency of from 1 to 5 seconds, for optimal processing efficiency. 4. The method according to p. 1, characterized in that, depending on weather conditions, only air of different temperature and humidity, under different pressure is supplied to the working zone through the piping system to protect plants from winter frosts, icing, spring frosts, drizzling rains, fogs, strong cold winds, dry winds, high temperatures. 5. The method according to p. 1, characterized in that for carrying out a complex of technological measures apply all the necessary components for this: dry powdered materials, bulk solids, chemicals, solutions, water - in the form of air or water-air mixtures; or air alone. 6. The method according to p. 1, characterized in that the same channel of the piping system is used to work with dissimilar chemicals separately or together, and after each process step the system is cleaned with neutralizing agents and / or washed with water and / or purged by air. 7. A stationary piping system for creating a microclimate in vineyards, including trunk pipelines, intermediate pipelines and working pipelines with perforations installed below or above the rows of plantings, a water source, a pump station with a pressure tank, a water heater, shutoff valves, dispensers, sensors, and measuring equipment , control panel, automated control system and computer control of the piping system, characterized in that it further comprises a compressor, heating a heater and an air cooler, stationary tanks for solutions of chemicals and bulk materials, equipped with feeding equipment and feeding pipelines with shut-off valves, and also additionally contains a mixing chamber located in the preliminary part of the system, after the compressor receiver, into which air is supplied, all technological components , solutions, water, from which there are several main conclusions with shutoff valves on several main pipelines connected through an intermediate pipelines with their own shutoff valves installed in front of the working pipelines, with working pipelines located at the bottom and top of each row of stands and provided with perforations in the form of open technological holes with a diameter of 3 to 20 millimeters, made along the entire length of the working pipelines either singly or with belts, perpendicular to or at an arbitrary angle to the surface of the pipes, at equal distances, from 20 to 100 centimeters; moreover, on the lower working pipelines, single holes and belt of holes are made only on the upper part, at 150 ° of the pipe cross-section, and on the upper working pipelines, the holes are made either doubled, located opposite to one plane, or belts, circular, over the entire surface of the pipes, through the same distances, in an amount twice as large, and in cross-sectional area half as small as in the lower working pipelines, while the total cross-sectional area of the technological holes in the lower pipe the wire and the upper pipe is the same. 8. The system according to p. 7, characterized in that for working pipelines with a cross section of 1 inch to 4 inches correspond to technological holes on them with a diameter of 3 mm to 20 mm, depending on the area of the vineyards and the planting and plant formations.

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