RU2686231C1 - Low-pressure drip irrigation network for watering slope lands - Google Patents

Abstract

FIELD: land reclamation.SUBSTANCE: invention relates to the field of complex reclamation of agrolandscape on slopes of ravine and will find application in irrigation of shrub plantations of fruit and berry use, as well as flower and other plants in places of use of sections of terraces. Low-pressure network includes distributing pipeline (2), to which watering pipelines (3) with drip water outlets (11) and bypass device (25) at the end are connected through pressure regulator. Each irrigation pipeline (3) is suspended with possibility of movement in horizontal plane between posts (19) with a positive slope. Head section of this pipeline is fixed on first post (19). End section is equipped with post (19) fixed to the end of the irrigation pipeline with a bypass device in the form of branch pipe (25) and a flexible coupling. In the beginning, irrigation pipeline (3) is equipped with an adjustable ball valve (5) and soothing container (9) in the form of a cylinder from a transparent plastic material of high strength. Inside container (9) in its lower part inlet pipe is fixed and valve stroke limiter is introduced. Limiter is made in the form of a plug with a shank, with a return tension spring fixed on it. Spring fixes valve with limit stop. In addition, irrigation pipeline (3) is additionally equipped with pressure gage (6), standard plastic filter (7) with cylindrical grid and counter (8). Counter is made in the form of water flow measurement unit. Irrigation pipeline (3) is divided in length into separate sections taking into account differences with respect to ground surface, with hydraulically connected bypass devices and terraces of plantations. Bypass devices are made in the form of flexible inserts of branch pipes (22) fixed with yokes. Each section of pipeline (3) with positive slope is suspended by means of clamping clamp (20) with locking screw (21) and fixed to stands (19). End section of each irrigation section of pipeline (3) at the drop point is equipped with an adjustable ball valve. Latter end section of pipeline section (3) with discharge device in form of branch pipe (25) is additionally connected with discharge ball valve (26) laid on the ground surface, and is equipped with jet damper (27).EFFECT: creation of optimal conditions for growth and development of shrub plantations, increased yield.1 cl, 6 dwg

Description

The invention relates to the complex reclamation of agrolandscape on the slopes of the ravine and will be used for irrigation of shrub plantations of fruit and berry purposes, as well as flower and other plants in places of use of terraces in the development of slopes and irrigation with small irrigation norms on sloping lands, as well as vineyards, in greenhouses and forest nurseries.

The proposed technical solution is intended primarily for creating new and reconstructing exploited, for example, within urban recreation parks and in suburban areas, where it is difficult to use only natural terrain, and where special platforms with a smooth surface in the form of narrow terraces along the slope slope are needed ravine; construct a cascade of such terraces from the top to its foot.

An example is the “Patriarchal Garden” of the city of Vladimir, whose area is about 4 hectares of land, where nature has created a unique ravine ravine. Here grow cherries, apples, a variety of gooseberry and black currant varieties. In addition, varieties of ornamental plants and many flower species grow, which generally make the garden complete for the use of a new technical proposal. The proposed technical solution will complement a kind of design that sucks in the general background of such ravines, where the steepness of the ravine slope is divided into terraces from top to bottom, and concrete pedestrian staircases with handrails run along the whole height. Thus, it can be noted that the “Patriarchal Garden” is a good example of a multi-level slope ravine of not a closed type towards r. Vladimir Klyazma is a “green kingdom”. The garden itself is located on steep terraces with terraces and is designed in the form of an agrolipshaft design, where the applicant proposed to exclude manual non-productive watering of plants from hoses when operating this area, which is used mainly in spring-summer-autumn periods for tourism, recreation of people, excursion visits of schoolchildren , students, etc., and also care of plants.

The dependence of plant growth is associated with the soil using the root system for various plants, their sizes.

The main requirement is also to eliminate interference to service personnel, namely, mowing grass, weeding, cleaning weeds, cutting grass and caring for park plants, in general, serving the park workers; preservation of the surface structure of terraces from erosion and erosion on the slopes of the ravine, etc.

In general, for the correct choice of method, is watering with small doses. Here should be taken into account: the structure of the soil, the degree of slope, the terrain difference, the neighborhood of groundwater, the likelihood of natural destruction - landslides, scour, sloughing.

Making the slope of a closed or semi-closed ravine by plants artificially protecting against falling out, strengthening the slope is taken to short areas (terrace areas), can occur naturally, however, irrigation with small irrigation rates can occur with the help of progressive drip irrigation.

Known design low pressure drip irrigation system, including a water source, distribution pipe and irrigation tubes with water outlet holes located in their upper part, the tubes are made of hollow stalks of plants and installed using support racks Horizontal (Copyright Certificate SU №1653647, A01G 25 / 02 from 07.06.1991).

Also known is the design of a drip irrigation system, including a distribution pipeline, to which irrigation pipes with drip outlets are connected, made of a single pipe suspended with a positive slope to the wire stretched between the racks. End sections of irrigation pipelines are bred into short grooves through which water flows to several trees (Patent RU No. 2384996, A01G 25/00 dated 03/27/2010).

The disadvantage of this system is the sagging of irrigation pipelines after the end of irrigation as a result of their linear expansion when heated by the sun. At the end of irrigation, the remaining water in the pipeline accumulates in the sagging area, where microalgae infest droppers multiply during subsequent irrigation. In addition, with successive water extraction with droppers, the filling of the free-flow pipeline decreases, respectively, the water pressure through the droppers at the end section of the irrigation pipeline decreases. In addition, tubes with dispensers exclude the ability to perform inter-row processing of various plantings, lack of water supply over the upper zone of the plant, thereby uneven moistening of the soil above the upper zone of the plant, as well as limited functionality and low operational reliability of such droplet water supply to plants. At the same time, the drip system is not adapted to abrupt differences in the surface of the land relief, in particular, to sloping ravines in difficult relief areas (terrain), which reduces the overall performance on the slopes of the ravine as a whole, and the process of cleaning the working cavities of outlets from clogging is difficult.

A well-known construction of a low-pressure network of drip irrigation, including a water distribution pipeline and irrigation pipelines connected to it through pressure regulators. These pipelines are installed on telescopic racks and are made of segments of rigid pipes connected to the socket. Each pipeline is equipped with drip water outlets and an end bypass device (Patent RU No. 2365096, A01G 25/02 of August 27, 2009).

This design makes it possible to give the pipeline any given slope, only straightforwardly and in certain quiet relief areas, to compensate for temperature fluctuations in the length of the tubes and to perform using the bypass uniformity of filling the pipeline with water at a short distance along its length.

The disadvantages of this design are: low reliability due to the large number of telescopic racks, the deviation of any of which from a given position can lead to changes in the mode of operation of the entire irrigation pipeline; the complexity of the installation of irrigation pipelines with the installation of telescopic racks with a given amount of slope only the straight section of the pipeline, in addition, a significant complexity of manual overlapping bypass devices at the beginning and at the end of each irrigation. Another disadvantage is that the connection of rigid pipes is connected directly with their socket connection through sealing elements, which is costly; sealing elements age and lead to water leaks in the joints at water pressures; in addition, such joints cause large pipe end resistances for water movement, which means loss of water pressure and uneven drip along the length of the irrigation pipeline, as well as a capacity for settling water. In addition, in the presence of diverted irrigation tubes, it excludes the ability to perform inter-row processing of various plantings, lack of water supply over the upper zone of the plant and low operational reliability for servicing such water outlets of droplet water supply to plants, the system itself is not adapted to sudden drops of the surface of the land relief, in particular, to sloping ravines in difficult relief areas (terrain), which reduces the efficiency of work on the slopes of the ravine as a whole, as well as the process of cleaning the working cavities of the waters starts from clogging.

The closest analogue (prototype) to the stated low-pressure network of drip irrigation on the slopes and agroladshaft decoration is a low-pressure network of drip irrigation, including a distribution pipeline, to which irrigation pipelines with drip outlets and an overflow device are connected via pressure regulators, each irrigation pipe being suspended with possibility displacements in the horizontal plane to the wire stretched between the posts with a positive slope of 0.001-0.0015, with the head the section of this pipeline is fixed on the first stand, the end section is equipped with a tension device in the form of a yoke with a lanyard attached via a spring to an additional stand, and the bypass device is made in the form of a nipple using a flexible coupling connected to the end of the irrigation pipeline and connected with a cable through the system blocks mounted on the extreme rack (Patent RU №2653550, A01G 25/02 from 05/11/2018).

The disadvantages of this system include the location of irrigation pipelines above the ground in only one straight position relative to the ground and attached to racks, eliminates the possibility of performing them with differences along the length of the route and binding to the steep slopes of the ravine with terracing sites to adapt their work to various plantings. The presence of a lower trellis wire between all racks excludes the ability to perform inter-row processing to staff for different plantings in their growth. As well as caring for plants (pruning, etc.). In addition, such a system is not adapted to abrupt differences in the surface of the earth, in particular to ravines, as noted in the well-known decision, where the head should not exceed 0.02-0.03 m, thereby ensuring the movement of water in the irrigation pipeline in low pressure mode due to the inclination of the upper wire, specified during installation. Moreover, if in the well-known solution they use inside the irrigation pipe of a 1.5-5-2 mm diameter tubule, then they are already fixed inside the irrigation pipe to narrow the flow area, which means that there is a likelihood of resistance along the length of the pipeline and the obstruction is gradually irrigation process, the washing process itself after the end of irrigation is also difficult to operate.

It should be noted that the best performance is when the irrigation pipeline itself has a cross-section along its entire length with practically no resistances and narrowings, and therefore the fixing of the droppers inside it should be taken into account when operating such a drip system, i.e. they should be placed inside the pipeline and not interfere with the movement of water along the length of the pipeline, and after the completion of irrigation, water should quickly be released at the end of it. Currently used polyethylene pipes 15 or 20 mm. The length of the pipeline depends on the location of the terraces on the slope of the ravine, and is limited to a length of no more than 60 m.

Therefore, another additional disadvantage is that the system creates difficulty on the rear rack fixing fasteners and stretching the spring, which eventually rust from climatic changes, and over time begins to age (sun, rain, etc.), which will lead to its breakdown in the open air This fastener is unreliable and accessible to strangers for its breakdown and the withdrawal of low-pressure drip irrigation from irrigation. The difficulty of fastening fasteners and cables with the transmission of force through the blocks complicates the end section of this pipeline, which reduces the efficiency of work on the slopes of the ravine as a whole, and the regulation of the end section of the pipe will depend on solar heating, which is not always possible in our climatic latitudes variable to temperature conditions in different periods of the year.

The task for which the claimed invention is directed is the expansion of the functional capabilities of low-volume irrigation of dwarf and shrub plantations of fruit and berries and flowers, which allow for inter-row processing, as well as flushing the system with the possibility of laying plantings on steep slopes with the construction of terraces and planning works, using for irrigation urban conditions tap water with fine cleaning of iron and other impurities and reducing costs for the design and installation of drip irrigation pipelines Tsami. In addition, reducing the complexity of the control by reducing the elements of control of water flow when feeding in irrigation pipelines with droppers from a source of urban pipelines and expanding the scope.

The technical result is the creation of optimal conditions for the growth and development of shrub plantations of fruit and berry purposes and flowers, increased yields and agro-landscape design.

This technical result is achieved by the fact that a low-pressure network of drip irrigation during irrigation of sloping lands, including a distribution pipeline, to which irrigation pipelines with drip outlets and an overflow device are connected through a pressure regulator, each irrigation pipeline hanging suspended in a horizontal plane between racks with a positive slope, while the head section of this pipeline is fixed on the first rack, the end section is equipped with with an irrigation pipeline fixed with the end with an overflow device in the form of a pipe and a flexible coupling, according to the invention, the irrigation pipe is first equipped with an adjustable ball valve and a soothing cylinder-shaped container of high-strength plastic material, inside which an inlet pipe is fixed in its lower part and inserted a valve stroke stop made in the form of a plug with a shank with a fixed return spring of tension stretching between the valve and the stroke stop when this The irrigation pipeline is equipped with an additional pressure manometer, a plastic standard filter with a cylindrical grid and a counter made as a water flow measurement unit, the irrigation pipe is divided into separate sections along the ground surface and hydraulically connected by-pass devices fixed with hose clamps of flexible inserts nozzles with terraces of planting, each section of the irrigation pipeline with a positive bias, hung by means of a clamping clip with a locking screw and fixed to the racks, the end section of each irrigation section of the pipeline at the differential location is equipped with an adjustable ball valve, and the last end section of the pipeline section with a drain fitting in the form of a spout is additionally connected to a waste ball valve laid on the surface of the earth and provided with a jet damper.

The implementation of the device of such a design is not identified from the studied scientific and technical information, patent documentation, which allows to judge about the inventive step of the proposed technical solution.

The invention is illustrated by drawings.

FIG. 1 is a schematic diagram of a low pressure drip irrigation network. FIG. 2 - irrigation pipeline.

FIG. 3 - cross-section of the irrigation pipeline (the dropper is located with its mounting base almost flush with the wall in the pipeline cavity).

FIG. 4 is a diagram of the connection of a water source in the form of a stilling tank to the distribution and irrigation pipelines.

FIG. 5 is a photograph of a general view of drip irrigation.

Low-pressure network of drip irrigation for irrigation of sloping lands consists of a laid polyethylene pipeline 1 on the ground and connected to a city-type water pipeline, pipeline 1 is divided into separate sections with a length of not more than 60 m with connection to it of distribution polyethylene pipelines 2, starting from the top a ravine up to its bottom, thus planned, to separate irrigated irrigation areas with differences along the length of the irrigation pipeline 3. To the distribution pipelines 2, the riser 4 is connected through an adjustable ball valve 5 and is connected to a pressure gauge 6, showing water pressure (pressure) at the outlet of the polyethylene distribution pipe 2, fixed small standard plastic filter 7 of fine size with a cylindrical mesh placed in its cavity. To determine the water flow, the ball valve 5 has a graduation of water flow depending on the water pressure coming from the city water supply through the water flow meter 8 to the side of the still tank 9, made in the form of a transparent cylinder of high strength plastic material with a lid 10. Soothing tank 9 connected to the irrigation piping 3 in the form of a low-pressure flexible hose, which has thickened walls with its increased bending and breaking strength (compared to the known small-size irrigation hoses size) with droppers 11, fixed with their bases in the cavity of the hose 3 in the direction of supplying water to the soil surface with a water outlet of up to 2.5 l / h above the planting zone of irrigated crops and plants with the root system.

The meter 8 measures water with a nominal diameter of 15 or 20 mm type (CXB), can be used as a meter to measure the volume of cold water, the approaching and distribution pipe 2 at a temperature of +5 to + 40 ° C, with a pressure of not more than 1 MPa (10 kgf / cm ² ). These meters are resistant to external magnetic field. The pressure loss at the meter with a maximum water flow (Q _max ) does not exceed 0.1 MPa (1 kgf / cm ² ). The service life of the counter 8-12 years. The principle of the counter is to measure the number of revolutions of the impeller is proportional to the volume of flowing water. The rotation of the impeller is transmitted to the counting mechanism, which, due to the reduction gearbox, makes it possible to measure the volume of water that has entered the calming tank 9 for the irrigation pipe 3 (hose) with droppers 11. The counting integrator allows determining the volume of water for any specific period of time on a given object irrigation terraces gully. This water metering is important for calculating the payment for water taken from the city pipeline.

The soothing container 9 in the form of a cylinder of plastic transparent material in its lower part has an insert of a metal tube 12. The upper end of the tube 12 is closed by a valve 13 of polyethylene. The valve 13 consists of two parts: the shank 14 and the plug 15 (the hatched part of the valve). The valve 13 in the upper part is attached to the stretching return spring 16, which in the upper part has a connection with its stroke limiter 17 located above the valve 13, which is attached to the plug 18 with the screw tube inserted into the metal tube 12 and can be turned around this screw (for example, into the tube 12).

Laying irrigation piping in the form of a flexible hose 3 with a solid wall surface with droppers 11 is divided into separate sections (sections) with a length of no more than 60 m each, with differences in respect to the slope of the earth's surface and leveled by means of posts 19 in height, to which the clamping brackets fix clamps 20 with locking screw 21, ensuring the movement of water through the irrigation hose 3 with a positive slope, with the speed of water, eliminating the siltation of the hose 3 (pipeline) with droppers 11 and placed near the plants. Separate arranged sections of the hose 3 on the differences between each other, are connected in the form fixed by clamps bypass device of flexible inserts nozzles 22 of the same diameter coaxially with hoses 3 with terraces planting. Supports and, respectively, the flow of each section of the irrigation pipe 3 to the end of its supply adjustable ball valves 23. To the end of the last irrigation pipe 3 (hose with a solid wall surface) using a clamp 24 attach bypass device in the form of a pipe 25 provided with a waste ball valve 26, laid on the surface of the earth, and the end of it is supplied with a jet suppressor 27 when it is necessary to flush hose 3 or flush before the end of irrigation, as well as with the onset of the onset of the cold season (winter). Thus, the pressure in front of the irrigation pipeline with a stilling tank is controlled both by a pressure gauge 6 and a water meter 8, and regulation is performed by means of a ball valve 5 additionally, taking into account the measurement of the water pressure in the soothing transparent tank 9.

It is necessary to describe the design of the cylindrical fine filter 7, since its operation affects the flow of clean water (even when water is supplied from the water supply network) to the irrigation pipe 3 with droppers 11. Fine filter 7 is made of corrosion-resistant polyethylene material factory-made (in the form of stamping from a polyethylene heated crumb), as one of the main link before installing the soothing container 9 of the drip irrigation system. A filter device 7 for connecting initially in front of the counter 8 includes adapters with seals (not shown), inside its cylindrical part, which is installed with a free-flowing streamline cylindrical screen, having a diameter equal to the additional nozzle in the form of an outer lip, and the length of a round screen filter is not less than the length of the pipe itself. Inside, between the outlet to the soothing container 9 and the filter housing 7 itself, respectively, there is a water outlet port with a socket made with locking internal tides. The top of the additional filter nozzle 7 is mated with a blind nut, which presses the vertical strainer to the socket, blocking the hole in the shape of a tubular strainer. The cover of the filter 7 itself is removable in the form of a hollow cylinder with an internal thread that closes the top of the additional pipe in the form of an external protrusion with a strainer (Fig. 5) with a blind nut, i.e. The mesh filter can be easily cleaned at any time of the day, flush the filter or replace it even during the operation of the droplet network, having previously closed the adjustable ball valve 5 on the riser 4 of the distribution pipe 2.

The top of the nut limits the stroke of the mesh filter of a streamlined cylindrical shape, inserted with its lower end into the adapter socket (nozzle pipe) with the device of the filter 7 to its extreme lower position due to pressing while tightening the nut. The depth of the nut is such that when the mesh filter is locked in the housing, the water flow enters the outlet hole in the adapter (tubular nipple) and through the round mesh filter into the additional nipple, which further contributes to the maximum value of opening the adjustable ball valve 5 on the riser 4 for water supply through the meter 8 in the soothing tank 9, then to the irrigation pipe 3 (hose).

All necessary parameters of the devices as a whole with the nodes connecting them to each other can be determined in a certain way when installing a low-pressure drip irrigation network, taking into account the specific conditions of each irrigated area, namely, the quality of irrigation water, no danger of dropping of droppers during irrigation, even high turbidity, while it is advisable to place on each vertical riser 4 plastic standard filters 7 (of the same size), produced by the factory casting method, as well as irrigation shl 3 ng plant with droppers 11 embedded in it on the production line and manufacturing all included (FIG. 5).

During the irrigation process, water from the water source 1 (main pipeline) enters the distribution pipeline 2, then through an adjustable ball valve 5 with flow rate calibration, and through the meter 8 it is judged on the amount of water consumed from the distribution pipeline 2 when it enters the stilling tank 9 at a given head , for example, with a pressure of 0.01-0.03 m, which ensures its regulation additionally in the soothing tank 9 and reduces the risk of its clogging and deposition of fine sediment particles or oozy deposits, depending the filter 7 from it. In order to prevent water from stagnating in the lower part of the soothing container 8 and its flowering, an outlet 28 with a tap 29 is made in the lower part 9, providing sanitary runoff for watering trees or shrubs. Due to the rigid fixation of the head section of the pipe 3 with fasteners to the soothing container 9 with the stand, a stable position of all the attachment points of the structure occurs. The lift height of the irrigation hose 3 (pipeline) can be adjusted by changing the attachment height only by using posts 19 with retaining clamps of the clamp-clamp 20 with a locking screw on posts 19 in height that allow water to move along the slope of the pipe 3 with droppers 11 and provide data water speeds near the plants, where they take into account the distance between the plantings, the terrain (differences) over the broken sections of the irrigation hose sections along the length with the bypass and adjustable ball valves manually - this simplifies em watering in general in difficult areas (ramps) of the ravine with terraces.

The droppers themselves are made of a polymer material of small thickness to the solid walls of the irrigation hose 3, the diameter of these tubes (hose) can be from 6 to 24 mm, the water release ratio is 1.6 to 2.5 l / h. The specified range of irrigation hose 3 with droppers 11 is taken from considerations to ensure durability and reliability, both fastening and working in lightweight and integrity of the irrigation pipeline without sagging along the road sections, and thus drastically reducing the weight and cost of such pipelines, in turn, this simplifies and installation of the entire drip irrigation system. The danger of clogging even with such droppers 11 is absent than in conventional drip irrigation systems, when in known ones they become more constructively complicated. At the completion of irrigation, the water supply to the pipeline 3 is stopped, and the discharge of water completely ensures the drain device in the form of a nozzle 25 with a ball valve 26, laid on the ground surface with a jet damper 27.

For the soothing tank 9, equipped with a tube 12 with a valve 13, consisting of two parts 14 and 15 for the valve 13, the following equalities must be observed: V ₁ γ> P, where V ₁ is the volume of the valve stem; P is the total weight of the valve (spring loaded); γ is the density of water; V ₂ γ <P, where V ₂ is the volume of the plug (valve).

Above the valve there is a travel stop 17 with a tension spring 16.

The operation of the valve is based on the pressure of the column in the water tank 9 h ₁ from above: F ₂ is the force with which the valve 13 is pressed by the water column with the height (pressure) below when the adjustable ball valve is opened and the spring force from above on the spring, respectively; P is the total weight of the valve, then the equilibrium equation of the valve has the form: F ₂ = F ₁ + P, or γSh ₂ = γ ₁ Sh ₁ + γSh _k , where γ ₁ is the specific gravity of the valve material; γ is the specific gravity of water; S is the cross-sectional area of the valve stem 14; h _k - valve opening height, or γh ₂ = γh ₁ + γh _k .

"It follows that the valve can also be closed if the force of the water column in the stilling tank 9 is sufficiently large after a certain time after the opening of the adjustable ball valve 5 on the riser 4. At the same time, the level in the soothing tank 9 will decrease due to the flow of water into the irrigation pipeline 11 (hose). The valve 5 stroke will also depend on the location of the height limiter 18 with the tension spring 18, so when calculating it is necessary to take the valve stroke and the internal diameter of the container, the diameter of the valve and the shank, as well as the internal diameter of the tube itself, in which the valve 14 is located.

About the amount of water consumed by the total drip irrigation and plant growth in the soil, judged by the amount of water received from the distribution pipe 2 with an adjustable ball valve 5 and the use of the counter 8.

Thus, during the entire period of operation of the drip network, the cold water meter 8 (CXW) is a universal measuring device (unit) and can be used to measure the volume of water in automatic mode (this is absent in the known), regardless of the time it is used for drip irrigation , and means that the payment for water consumption can be drastically reduced by saving water consumption during the entire period of operation, and by removing the water meter readings at any time. At the same time, the range of Nia water balance calculation (accelerated). The accuracy of calculating the parameters of the drip network application is maintained by the entire irrigation system as a whole, taking into account the water pressure. Consequently, the reliability of the quality of drip irrigation increases with irrigation of sloping lands.

It should be noted that depending on a given area of soil moistening around one plant, it is possible to install different number of droppers from one to six (not shown).

Thus, each design scheme of drip irrigation, depending on the design decisions, has its own requirements: head, flow rate, etc., therefore the question of such irrigation systems is determined at the design stage for specific terrain conditions, and this most often depends on natural and economic conditions.

The proposed low-pressure net of drip irrigation allows for regulated and standardized watering of perennial plantings of various plants, ensures its full release from water residues, improves distribution uniformity, allows inter-row treatment from grass and weeds, all nodes are under visual control. It also saves the system from damage, as well as simplifies all components of the system design for the operation of the whole drip irrigation network. Thus, there are no hindrances for the work of service workers, for example, the Patriarchal Garden Park, the city of Vladimir for various plants.

The proposed low-pressure net of drip irrigation can have wide functionality for an integrated approach, such as watering and decorating a given area, for example, such a relief in parks where it turns a ravine into a flowering garden. Watering can be carried out around the clock. An example may be the historical center of the city of Vladimir "Patriarchal Garden", which introduced the pilot plot of drip irrigation (see Fig. 5) with the given parameters of the present invention. Production tests of the irrigation test site were successfully carried out, which makes it possible to judge its applicability and practical utility.

The main part of the technical and economic effect is a significant reduction in the cost of building such a low-pressure network of drip irrigation, the possibility of open control of irrigation sites. Thus, the amount of water coming from the distribution piping for irrigation is judged using a water meter, which is placed in front of the stilling tank at the outlet of the adjustable ball valve in the irrigation piping with droppers in general.

Claims (1)

Low-pressure network of drip irrigation for irrigation of sloping lands, including a distribution pipeline, to which irrigation pipelines with drip water outlets and an overflow device are connected to the end of the regulator, each irrigation pipeline being suspended in a horizontal plane between racks with a positive slope, while the head section of this pipeline is fixed on the first rack, the end section is equipped with a rack with a fixed end of the irrigation pipeline with ne A venting device in the form of a pipe and a flexible coupling, characterized in that the irrigation pipe at the beginning is equipped with an adjustable ball valve and a soothing container in the form of a cylinder of transparent plastic material of high strength, inside of which a valve inlet is fixed in the lower part and a valve stroke stop is installed in the form of a plug with a shank, with a return tension spring fixed on it, fixing a valve with a travel stop between them, while the irrigation pipeline is at the beginning of the additional part It is equipped with a pressure gauge, a standard plastic filter with a cylindrical grid and a meter made in the form of a water flow measurement unit, the irrigation pipeline being broken down into separate sections taking into account differences on the ground surface, with by-pass devices hydraulically connected to each other. clamps of flexible inserts nozzles, and terraces of planting, with each section of the irrigation pipeline with a positive bias suspended by means of a clip - clamp with locking screw and fixed to the racks, with the end section of each irrigation section of the pipeline in the area of the differential is equipped with an adjustable ball valve, and the last end section of the pipeline section with a drain device in the form of a nozzle is additionally connected to a waste ball, laid on the ground, and equipped with a jet absorber.

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