RU2719029C1 - Low-pressure drip irrigation watering system - Google Patents

Abstract

FIELD: pipelines.

SUBSTANCE: low-pressure system for irrigation of slope lands includes distribution pipeline, to which through pressure regulator are connected irrigation pipelines with control pipes of different length, made in form of droppers of elastoplastic elements. Inner cavity of branch pipes is equipped with tubular porous element. Adjustable branch pipes are arranged on external surface of irrigation pipes and cover drilled outlets in tube. At some distance with a gap from the free end of the droppers a reflector-screen is coaxially fixed in the form of a resilient plastic fixing plate with bent edges along the circumference towards the water outlet from the dropper end. Inserted tubular porous elements are made with possibility of water flow motion braking and provision of water outlet at dropper drop end. Irrigation pipelines are suspended with possibility of movement in horizontal plane between posts with a positive slope. Head section of each irrigation pipeline is equipped with a reduction gear, a pressure gauge, a standard plastic filter with a cylindrical grid and a counter. Counter is made in the form of water flow measurement unit. Distributing pipeline is additionally equipped with controller with possibility of water flow rate, duration and irrigation intervals programming and is connected via communication line with personal computer.

EFFECT: invention provides uniformity of falling drops with the help of a reflector-screen towards plants planting on terraces in conditions of positive inclination of irrigation tubes and taking into account the drops relative to the ground surface.

5 cl, 5 dwg

Description

The invention relates to a comprehensive reclamation of the agrolandscape on the slopes of the ravine and will find application in the irrigation of shrubs of fruit and berry purposes, as well as flower and other plants in places where terraces are used when developing slopes and irrigation with small irrigation rates on sloping lands, as well as vineyards, in greenhouses , forest nurseries and household plots.

The proposed technical solution is intended, first of all, to create new and reconstruct exploited irrigation systems for organizing drip irrigation during plant growing.

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

In general, for the right choice of method, watering with small doses is necessary. Here should be taken into account the structure of the soil, the degree of slope, the difference in terrain, the proximity of groundwater, the likelihood of landslides, washings, shedding.

The design of the slope of a closed or semi-enclosed ravine by plants by an artificial method of protection against shedding, the strengthening of the slope brought to short sections (platforms) of terraces can occur naturally, however, watering with small irrigation rates can occur using progressive drip irrigation.

A device for watering plants is known. The device includes a reservoir for irrigation fluid, a supply line of irrigation fluid connected to the tank via a drain pipe with a locking unit, adapter hoses connected to the supply line, and porous hoses for immersion in the soil around the root of each watering plant connected to adapter hoses . The supply line is basically a horizontal pipeline made of a material whose rigidity prevents the pipe from sagging along its length and is equipped with vertical supports equally spaced from each other (Patent PM RU No. 74756, A01G 25/00 of 07.20.2008).

The disadvantage of this device is the high material consumption associated with the presence of adapter hoses and porous hoses, and as a consequence, the high cost of the device. In addition, with the sequential withdrawal of water by droppers, the filling of the pressure-free pipeline decreases, respectively, the water pressure decreases through the droppers at the end sections of the irrigation pipe (pipeline). In addition, adapter hoses and porous hoses make it difficult to perform inter-row processing of various stands, the lack of water supply over the upper zone of the plant, as well as the limited functionality and low operational reliability of such outlets of drip water supply to plants. At the same time, it is not adapted to sharp changes in the surface of the earth's relief, in particular, to sloping ravines and complex relief territories (terrain), which reduces the efficiency of work on the slopes of the ravine as a whole, and also complicates the process of cleaning the working cavities of porous hoses. Another disadvantage is that this device does not take into account not only the distance between the drip lines, depending on the type of watering plants, connecting them to a distribution pipe, which is equipped with adjustable ball valves connected to the drip lines, and the water discharge along the length of the drip line will be different, in particular in the middle and end of the drip line.

A low-pressure drip irrigation network is known, including a distribution pipe, to which irrigation pipelines with drip outlets and a bypass device are connected through pressure regulators, each irrigation pipe suspended from a horizontal plane to a wire stretched by struts with a positive slope of 0.001-0.0015 while the head section of this pipeline is fixed on the first rack, the end section is equipped with a tension device in the form of a clamp with a lanyard, through the spring to the additional drain, and the bypass device is made in the form of a pipe, using a flexible coupling connected to the end of the irrigation pipeline and connected to it by a cable through a system of blocks mounted on the extreme drain (Patent RU No. 2653550, A01G 25/02 of 11.05. 2018).

The disadvantage of this system is the difficulty of calibrating the holes for small droppers, and the increased material consumption associated with the presence of additional cable-block system, filters and, as a result, the increased cost of the system. Another disadvantage is that this system is not adapted to differences along the length of the route, and to tie to the steep slopes of the ravine with terracing sites to adapt their work to various plantations. At the same time, it is difficult to perform inter-row processing for personnel for various plantings in their growth, in addition, caring for plants is difficult (pruning, etc.), and as noted in the known solution, the irrigation system is not adapted to sudden changes in the relief of the earth’s surface, in particular to sloping ravines, where the pressure should not exceed 0.02-0.03 m, thereby ensuring the movement of water in the irrigation pipeline in a low-pressure mode due to the slope of the upper wire specified during installation. Moreover, if in a known solution, dropper tubes 1.5–2.0 mm in diameter are used inside the irrigation pipeline, then their fastening inside the irrigation pipeline is narrowed in advance, the passage section is narrowed, which means that there is a possibility of resistance along the length of the pipeline and blockage of droppers gradually watering process, the washing process itself after watering is also difficult to operate.

It should be noted that the best execution is when the irrigation pipeline itself has a cross section along the entire length (drip line of the tube) with virtually no resistance and narrowing, which in turn provides simplicity and manufacturability of the production of drip irrigation tubes on the production line in the factory ( with the possibility of absence inside the droppers themselves). Those. eliminate water resistance inside irrigation pipes, clogging of the latter during the operation of such a drip system. Currently, the new proposed technical solution will eliminate these shortcomings, for example, in polyethylene pipes (lines) with a diameter of 15 or 20 mm. The length of irrigation pipes also depends on the location of the terraces on the slope of the ravine, a positive slope during operation of the drip irrigation line.

The closest prototype to the inventive low-pressure drip irrigation system for sloping lands is a low-pressure drip irrigation network for irrigation of sloping lands, including a distribution pipe to which irrigation pipelines with drip outlets and a bypass device are connected through the pressure regulator at the end, while each irrigation pipe is suspended with the possibility horizontal movement between racks with a positive slope, while the head section of this pipeline mounted on the first pillar, the end section is equipped with a pillar with a fixed end of the irrigation pipeline with a bypass device in the form of a pipe and a flexible coupling, while the irrigation pipeline is first equipped with an adjustable ball valve and a soothing tank in the form of a cylinder made of transparent plastic material of high strength, inside of which there is a lower parts of it are fixed to the inlet pipe and a valve stroke limiter is introduced, made in it with a tension return spring fixed to it, fixing a valve with a runner, while the irrigation pipeline is initially additionally equipped with a pressure gauge, a standard plastic filter with a cylindrical mesh and a counter made in the form of a unit for measuring water flow, and the irrigation pipeline is divided into separate sections along the length taking into account differences between the earth's surface and hydraulically connected between transverse devices, made in the form of flexible pipe inserts fixed by clamps, and planting terraces, with each section of the irrigation pipe the positive-slope gadfly is suspended by means of a clamping clamp with a locking screw and fixed to the uprights, the end section of each irrigation section of the pipeline at the drop point 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 pipe is additionally connected to a discharge ball a crane laid on the surface of the earth and equipped with a jet damper (Patent RU No. 2686231, A01G 25/00 of 04.24.2019).

The disadvantage of this system is the increased drainage of water from the dropper holes towards the positive slope of the suspended irrigation pipe on its outer surface (outside) on a plastic droplet tube with holes, water is closed with the subsequent dropper hole, as a result of which excess water is connected to the surface of the irrigation line water (drops). This is due precisely to the positive slope of the irrigation pipeline, when a drop of water does not have time to fall down on a specific watering plant completely. Hence, it is necessary to eliminate this drawback with droppers, the formation of closure (fusion) of water droplets and an increase in the discharge of water to another plant in the direction of a positive slope of the pipeline with holes for the dropper. Another disadvantage is that the droppers are rigidly built to the walls inside the irrigation pipeline, they are not accessible for inspection or replacement, i.e. in case of their exit, it is necessary to change the section of the irrigation tube with droppers to a new section of the tube and dropper, as well as the possibility of their long-term operation, there may be deposits in the grooves of chemical elements in the form of excess content of ferrous, saline and other clogging components, i.e. accumulation of deposits is formed in these places, clogging during long-term operation, and reducing the supply of water with a specific type of watering plant, and this increases the cost of the system.

The aim of the present invention is to provide a low-pressure drip irrigation system on sloping lands with a positive slope with terraces, which would retain the positive qualities of the known system, but at the same time more reliable, economical and universal in design, installation and use, which also would provide water saving during spot irrigation without water fusion on the lower part of the surface of the irrigation tube with new droppers.

The specified technical result is achieved in that a low-pressure drip irrigation system for sloping lands, including a distribution pipe, to which irrigation pipelines with drip outlets and a transfer device at the end are connected through a pressure regulator, each irrigation pipe is suspended with the possibility of moving in a horizontal plane between racks with a positive slope while the head section of the pipeline is fixed on the first rack, equipped with an adjustable ball valve, pressure gauge, layer a mass filter with a cylindrical mesh and a counter made in the form of a unit for measuring water flow, and the end section is equipped with a bypass device in the form of a pipe with a flexible coupling and is also fixed to the rack, each irrigation pipe is divided in length taking into account differences from the surface of the earth and planting terraces on separate sections with hydraulically interconnected bypass devices, made in the form of flexible pipe inserts fixed with clamps, each section of the irrigation pipeline is fixed racks by means of a clamping clamp with a locking screw, the end section of each irrigation section of the pipeline at the drop point is equipped with an adjustable ball valve, and the last end section of the section of the pipeline with a drain device in the form of a pipe is additionally connected to a relief ball valve laid on the ground, and equipped with a jet damper, according to the proposed invention, the irrigation pipe is a drip plastic tube with holes on the surface of which is externally on the mouth of each outlet is provided with elastic elastomeric covering elements surrounding the ring in the form of put-on nozzles of different lengths, the inner part of which is provided with a tubular porous material, which makes it possible to decelerate the flow and exit of water through the end along the length of the put-on nozzle, to which a reflector-screen in the form of elastic a plastic fixing plate with bent towards the direction of water outlet through the end of the put on pipe in the form of a dropper with the edges, and the reflector en with locking screw also sealingly covers the outside surface of the plastic tube with a dropping horizontally movable thereon.

In addition, the distance between the drip lines is established depending on the type of watering plants with their connection to the distribution pipe-riser equipped with an adjustable ball valve connected to the drip irrigation pipes.

In addition, water outlets were drilled in a drip irrigation tube at a distance depending on the location from each other and the type of watering plants.

In addition, a gearbox is installed between the ball valve and the pressure gauge.

In addition, a controller is installed between the main pipeline and the distribution pipeline, configured to program the water flow, the duration and intervals of irrigation, and to communicate with a personal computer.

The advantage of such an improvement in the low-pressure drip irrigation system for sloping lands is the elimination of water (merging) compounds flowing out of the dropper holes when watering each other along the outer surface, the droppers of which are in the form of tubular nozzles fixed to the outer surface of the tubes or hoses, the holes being drilled in the latter for water discharge, holes are drilled with a diameter of 1-2 mm, then they are blocked from the outer surface of the walls with short tubular pipes of different lengths, performing their function as droppers, the inner part of which has a porous surface with the possibility of braking the flow and ensuring the exit of water through the end along the length of the tubular pipe (dropper). In this case, after it, an annular reflector-screen is fixed in the form of an elastic plastic fixing screw with a locking screw at a predetermined position by a gap from the end of the tubular pipe at the water outlet, while the reflector-screen is made in the form of a plate, the edges of which have a side wall bent around the circumference towards the exit water from the opening of the end of the short tubular nozzle, which provides protection against the confluence of each drop of water coming from it, while the irrigation drip tube itself has a positive slope. And that means providing (reflector-screen) uniform and spot watering of each plant through a given distance. In addition, the presence of a controller that provides programming of water flow and the ability to communicate with a personal computer, the duration and intervals of irrigation with a personal computer, which also confirms the versatility of the system. The possibility of connecting drip tubes or hoses with different distances allows you to vary the distance depending on the type of watering plants and connecting them to a distribution pipe-riser equipped with adjustable ball valves, also confirms the expanded functionality of the system, which consists in the possibility of using the system for different types of plants, t .to. the distance between neighboring planted plants can be different, since for water discharge holes are drilled at predetermined points on the outer surface of the wall of a dropping polyethylene tube (or a hose made of modern materials in terms of rigidity and strength). The absence of drip tubes inside the cavity along the length of special droppers provides through holes covered by annular female elements in the form of short tubular fittings with water outlet at the end of them, ensures no clogging of holes, longer operating time and lower cost of the system without loss of quality.

The implementation of a device of a similar design has not been identified from the studied scientific and technical information, patent documentation, is innovative, which allows us to judge the inventive step of the claimed technical solution.

The invention is illustrated by drawings.

In FIG. 1 shows a low-pressure system of drip irrigation of plants on sloping lands; in FIG. 2 - irrigation pipeline in the form of a drip plastic tube with droppers; in FIG. 3 is a view of an elastic member illustrating a drip of drip irrigation (a section of an irrigation drip tube is not shown); in FIG. 4 is a side view of a portion of the reflector-screen (irrigation drip tube not shown); in FIG. 5 is a sectional view of a droplet tube with a short tubular nozzle acting as a dropper.

The low-pressure drip irrigation system for sloping lands consists of a laid polyethylene trunk pipe 1, laid on the surface of the earth and connected to a water pipe, for example, an urban type, pipe 1 is divided into separate sections of a given length with connection of polyethylene distribution pipelines 2, starting from the top of the ravine to its sole, planned in this way, on separate irrigation irrigation sections with differences in the irrigation pipeline, which represents apelny plastic tube 3 with a diameter of from 6 to 24 mm. With drilled holes 4 with a diameter of 1 ... 2 mm for water discharge from 1.6 to 2.5 l / h.

The droppers are made in the form of short tubular nozzles 5, 6 and 7 of different lengths and covering the surface of the outside of the irrigation tube 3 opposite the outlet openings 4. The tubular nozzles 5, 6 and 7 (droppers) of an elastic element (material), for example, in the form of individual rubber nozzles or from polymers, plastics, etc., the internal flowing part of the casing of short nozzles 5, 6 and 7 (droppers) is equipped with a tubular porous element 8. The length of each of the short tubular nozzles 5, 6 and 7 is made of different design lengths, based on their location along the length of the irrigation tube 3 with holes 4 for discharging water in the direction of overlapping them with short tubular droppers 5, 6 and 7. Immediately after installing the droppers 5, 6 and 7 at a certain distance with a gap from the end of the water outlet from droppers 5, 6 and 7 the reflector-screen 9 is tightly fixed in the form of an elastic plastic fixing tubular plate with edges bent around the circumference in the direction of the water jet exit from the openings of the end of the short tubular droppers 5, 6 and 7. The reflector-screen 9 is also made to cover a smooth surface from the outside willow tube 3 with the possibility of horizontal movement along it in a longitudinal arrangement, as the droppers 5, 6 and 7 themselves have the possibility of their longitudinal movement in one direction or another with respect to the overlapped drill holes 4. Thus, with the final installation of droppers 5, 6 and 7 one end of them is fixed (clamped) with a clamp 10 with screw 11, and the other end of tubular droppers 5, 6 and 7 with porous internal material is free to supply water, and which is blocked by a tight on the surface of the irrigation tube 3, a reflector-screen 9 in the form of an elastic-elastic plate with the edges bent to the direction of water outlet through the end of the put-on nozzle in the form of a dropper, moreover, the reflector-screen with a locking screw also hermetically covers the surface of the drip plastic tube from the outside with the possibility of horizontal movement along it .

It should be noted that before the irrigation drip tube 3 is installed along the length of the planted plants, its holes 4, and which serve as outlet openings in the direction of the overlapping tubular pipes 5, 6 and 7 (droppers), are drilled in the walls of the irrigation tube 3 by the corresponding drilling mechanism, for example, drills with a diameter of 1-2 mm (not shown), but holes can be drilled in the tube 3 during installation of the irrigation drip tube opposite the planted plant, the distance when there are between them different when planting in the ground. These holes 4, drilled by a drilling mechanism (not shown) serve as water outlets and enter it freely into the droppers 5, 6 and 7 on the irrigation tube 3 with respect to the location of the free end of the droppers 5, 6 and 7 with a gap, and provides , avoiding the closure of the flowing drops (water) on the outer surface from the bottom of the tube 3, then each drop of water freely falls (flows) directly to a given place of planting of each individual plant. The location of the reflector-screen 9 on a stationary irrigation drip tube 3 can be selected so as to create a water outlet (drop) without merging with a subsequent dropper, in which water is also discharged, since the irrigation drip tube 3 itself is always made with a positive slope of terraced areas of sloping lands, i.e. in this case, there is now no fusion of the outgoing water and its draining to close on the lower surface of the tube wall 3. The bent edges of the reflector-screen 9 in the form of an elastic plastic fixing plate with bent towards the direction of the water outlet through the end of the worn nozzle in the form of a dropper direct water, flowing from the free ends of short tubular pipes 5, 6 and 7 (droppers), then water in the form of separate drops enters directly to the side of planting with its root system (regardless of the slope the tube 3), i.e. without spreading to the bottom of the wall of the tube 3 itself, in which holes 4 are drilled and blocked droppers 5, 6 and 7. In this case, on the lower part outside the tube 3 body there is no undesirable connection of several drops of water, which means that these water drops are disconnected from each other, and they strictly fall on the planted plant in the soil.

The drip irrigation system also contains a distribution pipe 2, a riser 12 is connected, the controller 13 is fixed to the distribution pipe 2 and controlled by the irrigation mode, which provides programming of water flow, duration and interval of irrigation and is connected via a communication line with a personal computer (not shown). The riser 12 has a ball valve 14, a gearbox 15, a pressure gauge 16, showing the water pressure (pressure) at the outlet of the polyethylene distribution pipe 2, a fixed fine filter 17 with a cylindrical mesh placed in its cavity. To determine the total flow rate of water coming from the distribution pipe 2, a water flow meter 18 is installed in the direction of the irrigation drip tube 3 with droppers 5, 6 and 7, made in the form of short bending pipe with increased bending and tensile strength, the inner cavity of which is made of a porous material that provides inhibition of the movement of the water flow for the leakage of water from the drilled holes 4 in the walls of the tube 3 with the same speed along the entire length of the tube 3 with droppers 5, 6 and 7, then the water supply to the soil surface with a water discharge of up to 2.5 l / h over the planting zone for irrigating crops and plants at a temperature of + 5 ° to + 40 ° C, at a pressure of not more than 2 MPa (20 kgf / cm ² ) The meter data is resistant to external magnetic fields. The pressure loss on the meter at the maximum flow rate (Q _max ) does not exceed 0.1 MPa (1 kgf / cm ² ). The service life of the meter is 8-12 years. The principle of operation of the counter is to measure the speed of the impeller in proportion to the volume of flowing water. The rotation of the impeller is transmitted to the counting mechanism, which, due to the reduction gear, provides the ability to measure the volume of water entering the irrigation pipe 3 (irrigation drip tube) with droppers 5, 6 and 7. The integrator of the counting mechanism makes it possible to determine with sufficient accuracy the indications of water volumes for any specific the period of time at a given object of irrigation of the ravine terrace. This accounting is important for calculating the payment for water taken, for example, from a city pipeline, for example, irrigation of an open slope ravine with planting terraces of the Patriarchal Garden in Vladimir.

Before laying irrigation drip tubes 3 or hoses with a solid wall surface, drill holes 4 used to discharge water into short tubular nozzles 5, 6 and 7 (droppers) using an appropriate drilling mechanism (not shown), but holes can be drilled and at the time of laying out the irrigation pipes 3. The manufactured tubular pipes 5, 6 and 7 of different respective lengths (droppers) are worn on the irrigation pipes 3, and they are also worn and a reflector screen 9, fixed on it, then divided into separate sections (sections) a predetermined design length with differences with respect to the slope of the earth's surface and leveled using columns 19 with a positive slope of the irrigation tube 3 with droppers 5, 6 and 7, tubes 3 that provide movement of water (hose) with a positive slope, with a water speed that excludes siltation of the tube 3 (hose) with droppers 5, 6 and 7, with a clearance of reflector-screen 9, and placed simultaneously near the plant or above it. Separate sections of polyethylene irrigation pipes 3 arranged at differences between each other are connected in the form of clamps fixed by clamps from flexible inserts of nozzles 20 of the same diameter coaxially with pipes 3 with planting terraces. The pressure and, accordingly, the flow rate of each section of the irrigation drip tube 3 to its end is provided with adjustable ball valves 21. To the end of the last irrigation tube 3 (hose with a solid wall surface) by means of a clamp 22, a bypass device in the form of a pipe 23 equipped with a relief ball valve 24 is connected laid on the surface of the earth, and its end is equipped with an extinguisher 25 jets, when it is necessary to flush the irrigation tube 3 (hose) or to drain the water before the end of the irrigation, as well as with the onset of the cold season (Winter). Thus, the pressure in front of the irrigation pipe is controlled by both a manometer 16 and a controller 13 with programming the water flow and communication with a personal computer (not shown), the duration and intervals of irrigation.

It should be noted that one of the important components of the drip irrigation system is also the design of the cylindrical filter 17 of fine cleaning, marked 8 and the prototype, so its work affects the overall reliability of the system and the flow of clean water into the drip irrigation system with adjustable covering tube 3 s holes 4, elastic elements in the form of droppers 5, 6 and 7 of different lengths, made of short tubular pipes. The fine filter 17 is made prefabricated from polyethylene material resistant to corrosion in the factory (workshops) in the form of stamping from polyethylene heated chips, as one of the main link before assembling the system as a whole. The filter device 17 for first connecting in front of the counter 18, includes adapters with seals (not shown), inside its cylindrical part, which is installed a freely mesh streamlined cylindrical filter having a diameter equal to an additional pipe in the form of an external protrusion, and the length of the round mesh filter is not less than the length of the pipe itself. Inside the filter housing 17 itself, respectively, there is a water outlet with a socket made with fixing internal tides. The top of the additional filter pipe 17 is mated with a blind nut, which presses the vertical strainer to the slot, blocking the hole in the form of a tubular strainer. The cover of the filter 17 itself is removable in the form of a hollow cylinder with an internal thread that covers an additional pipe covering the top with an external protrusion with a strainer (not shown) 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 operation with a mounted drip network, having previously closed the adjustable ball valve 14 on the riser 12 without stopping the operation of the distribution pipe 2 itself.

The top of the nut limits the stroke of the streamlined cylindrical mesh filter inserted by the lower end into the socket of the adapter (pipe of the pipe) with the filter device 17 to its extreme lower position due to the pressing when screwing the nut. The depth of the nut is such that when the strainer is locked in the casing, the water flow enters the water outlet in the adapter (tubing) and through the round strainer into an additional nozzle, which further contributes to the maximum value of the opening of the adjustable ball valve 14 on the riser 12 for feeding water through the gear 15, the meter 18, then into the irrigation pipe 3 (hose).

The holes 4 in the drip tube 3 are made at a predetermined distance from each other and are overlapped by the elastically elastic droppers 5, 6 and 7 covering them around the circumference of the tube 3 from the outside, the free end of the droppers 5, 6 and 7 on the water supply side with a gap fasten the reflector the screen 9 with its fixing screw 26 in accordance with the specific type of watering plants droppers 5, 6 and 7.

The droppers themselves are made with short nozzles encircling the tube 3 with the outlet openings 4, in the form of resiliently elastic elements with a tubular inside a porous element with corresponding equal lengths and fastening of the nozzles 5, 6 and 7 (droppers) themselves with clamps in one piece, as well as installation with the gap, and mounting the reflector-screen 9 with a screw 26. In general, this facilitates the manufacture and assembly of their elements, the dropper device is simple, compact, the cost of all parts is reduced. Because. That pressure irrigation tubes 3 and nozzles 5, 6 and 7 (droppers) during installation expect to give them a positive slope above the ground. The presence of fixed reflector screens 9 at the end of it with a gap eliminates the fusion of the water supply (drops) on the lower part of the surface of the tube 3 with the water coming out of the droppers, i.e. there is no merging along the outer lower wall of the smooth tube 3 in the direction of direct location to the next dropper, i.e. there is no water closure due to the presence of a fixed reflector-screen 9, even in the presence of a positive slope of the irrigation tube 3 relative to the surface of the terraces on the slope, which eliminates this drawback in the prototype (even possible with a greater allowable slope), based on the possibility and inaccuracy of installation irrigation network, and therefore now, the influence of a positive slope for pressure irrigation pipes 3 will not have a negative flow during the delivery of water to irrigation, associated respectively with the distances between the holes of the droppers a specific type of water the plants.

Production of an irrigation drip line from tubes 3 (or a hose) of small thickness of solid walls with a diameter of 6 to 24 mm, a water outlet of 1.6 to 2.5 l / h with tubular droppers 5, 6 and 7 of short and different lengths, covering the outer side of the (outer) surface of the tube wall with the hole is taken for reasons of accuracy and reliability, both the fastening and operation of the reflector-screen 9 in the lightened state of the drip line, even if it can be laid with a positive slope at different heights from the ground or over the rasta iyami without sagging of the track sections, and hence the operation of the release of water from drippers 5, 6 and 7 will coincide with a particular type of water the plants. There is no risk of clogging even with such droppers 5, 6 and 7, and if it is necessary to wash them, it will be enough to move them to another place along the length of the tube 3 and the holes 4 will be completely open, whereas in the known drip irrigation systems they are complicated structurally (droppers do not fix movable to the holes). At the end of irrigation, the water supply to the irrigation tubes 3 is stopped, and the water discharge is completely provided by a drain device in the form of a pipe 23 with a ball valve 24 laid on the ground surface with an absorber 25. It is possible to additionally ensure water discharge by moving the pipe pipes 5, 6 and 7 (droppers), freeing the holes 4 drilled in the wall of the irrigation tube 3. The design of droppers 5, 6 and 7 becomes mobile in nature of construction, and can also be self-washed during movement and irrigation, and its reg sizing along the length coaxially, respectively, on the surface of the tube 3 with the hole 4, regardless of their location along the length of the irrigation tube 3.

The versatility of the design of meter 18 during the operation of the drip network is already an addition to universality with a measuring device (unit) and can be used to measure the volume of water in automatic mode, regardless of the time it was used for drip irrigation, which means that payment for consumption water can be drastically reduced by saving water consumption during the entire period of operation, and taking the volume of water at any time by meter 18. The controller 13 provides a general flow programming programming and water and can be controlled through a communication line with a personal computer (not shown) that meets today's innovations in these operating conditions of a simple, reliable and economical drip irrigation system. Consequently, the reliability of the quality of drip irrigation during irrigation of sloping lands, the transition to an integrated approach, both by irrigation and decorating the territory using the example of a large ravine (difference in elevation of the ravine up to 30 m from the top to its sole with terracing sites) of the historic city center, increases Vladimir "Patriarchal Garden", where it is possible to introduce irrigation drip network with new design elements in the form of a pilot plot, by the example of watering flower and other plants grown in and this territory, and therefore confirmation of the usefulness of the practical application of this invention.

However, it should be noted that the irrigation system can be made of modern materials based on existing technology, where the irrigation pipe can be used for many outlets and different openings, and according to the invention, it is well suited for drip irrigation with covering elastoelastic droppers outside the polyethylene irrigation tube (hoses with solid walls) with drilled holes of a given diameter, overlapping droppers of different lengths, at the end of which a reflector is fixed with a gap -Screen for sending down the water draining towards a particular type of water the plants.

Due to the described construction of a drip irrigation system for plants of the present invention, the preferred material for a tube (or hose) and special droppers with a reflective screen is low or high density (pressure) polyethylene, tape (linear) polyethylene, polypropylene mixtures thereof in appropriate quantities. You can use any other thermoplastic material, i.e. from modern materials.

The proposed improved low-pressure drip irrigation system can have wide functionality for an integrated approach, both watering and decorating in a certain territory, for example, the Patriarchal Garden of Vladimir or other drip irrigation sites.

Thus, the cost of manufacturing new droppers equipped along the length of the irrigation tube with reflective screens from the outside is reduced, where the laid irrigation pipes have a positive slope when terracing sites and land drops when growing plants and dosing irrigation water for various plants.

Claims (5)

1. A low-pressure drip irrigation system for sloping lands, including a distribution pipe, to which irrigation pipelines with drip outlets and a transfer device at the end are connected through a pressure regulator, each irrigation pipe is suspended with the possibility of moving in a horizontal plane between racks with a positive slope, while the head section the pipeline is fixed on the first rack, equipped with an adjustable ball valve, pressure gauge, a plastic filter with a cylindrical mesh and a counter ohm, made in the form of a unit for measuring water flow, and the end section is equipped with a bypass device in the form of a branch pipe with a flexible coupling and is also fixed to the rack, each irrigation pipeline is divided along the length taking into account differences from the surface of the earth and planting terraces into separate sections with hydraulically connected interconnected bypass devices made in the form of flexible pipe inserts fixed by clamps, each section of the irrigation pipeline is fixed to the racks by means of a clamp bracket-clamp with stop a screw, and the end section of each irrigation section of the pipeline at the differential point 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 pipe is additionally connected to a dump ball valve laid on the ground surface and is equipped with a jet damper, characterized in that the irrigation pipeline is a drip plastic tube with holes, on the surface of which, outside of each outlet, there are spanning rings durable elastic elements in the form of put-on nozzles of different lengths, the inner part of which is equipped with a tubular porous material, which makes it possible to decelerate the flow and exit of water through the end along the length of the put-on nozzle, to which a reflector-screen is fixed with a gap in the form of an elastic plastic fixing plate with bent to the side the direction of water outlet through the end of the fitting pipe in the form of a dropper with the edges, and the reflector-screen with a locking screw also tightly covers the outside on top awn dropping plastic tube with the possibility of horizontal movement thereon. 2. The system according to claim 1, characterized in that the distance between the drip lines is established depending on the type of watering plants with their connection to a distribution pipe-riser equipped with an adjustable ball valve connected to drip irrigation pipes. 3. The system according to claim 1, characterized in that the water outlet is drilled in the drip irrigation tube at a distance depending on the location from each other and the type of watering plants. 4. The system according to claim 1, characterized in that a gearbox is installed between the ball valve and the pressure gauge. 5. The system according to claim 1, characterized in that a controller is installed between the main pipeline and the distribution pipe, configured to program the flow of water, the duration and intervals of irrigation, and with the possibility of communication with a personal computer.

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