RU2219760C1 - Drop irrigation system - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: proposed system includes water source, sedimentation tank, pumping station, filter with pressure gauges, irrigation net and drip feeds, group of drip feeds is hydraulically coupled with water through connecting pipes. Group of drip feeds is formed to provide wide range of watering norms at equal rate of rising. Each water outlet is installed along watering pipeline of irrigation net. Water outlet has hydraulic spool valve with control rod to provide its turning around axis of symmetry and displacing along axis. Hydraulic spool valve is fitted in sleeve in housing. Flexible member is arranged in sleeve space between bottom part of housing and end face part of plunger. Free end of control rod is provided with eccentric and lever to turn and displace hydraulic spool valve. Cover of water outlet housing provided with nipple is connected by pipeline with system watering pipeline. Nipples are mounted on water outlet housing in tiers and with angular displacement. Axial channels of nipples are aligned with radially orientated channels of sleeve and spool. Said spool is coupled with intake space of hydraulic spool valve by in-tier radially orientated channels and axial and parallel channels. EFFECT: increased capacity and enlarged range of watering norms in process of drilling and cultivation. 1 tbl, 31 dwg

Description

 The invention relates to agriculture, in particular to drip irrigation systems.

 A known drip irrigation system for sheltered soil, containing a water source, a pump, a fertilizer feed with mineral fertilizers, a water filter with pressure gauges, main, distribution and irrigation pipelines, fittings and valves, remote control valves and valves, droppers and guide tubes (see. Advertising brochure Ministry of Land Reclamation and Water Resources of the USSR: Drip Irrigation System for Protected Soil. / Compiled by RT Balode, Ya.A. Karklis, A.B. Solodovnik, ZP Zeps. - Jelgava. - Latvian CCP. - 1987. - 4 c.). The output ends of the guide tubes are uniformly fixed along the length and width of the irrigated strip. Each dropper is hydraulically connected to four guide tubes.

 The disadvantages of this system include limited functionality and a narrow range of irrigation standards. A dropper serves as a water outlet.

A drip irrigation system is also known, including a water supply source, a supply network, a distribution network and humidifiers with injectors, in which, in order to improve the aeration of the moistened zone and to control the water supply to the soil, a hydraulic resistance is installed at the entrance to each injector, and under it , a hole is made in the wall of the injector; in order to stabilize and regulate the flow rate of air supplied to the soil, each injector is equipped with a water seal located below the hole; in order to evenly distribute water along the humidified zones when the pressure changes along the length of the humidifier, the injectors are connected to the humidifiers through tubular inserts of various lengths; hydraulic resistance is made in the form of a float-operated water level controller (SU, copyright certificate 545305, M.cl. ² A 01 G 25/02. Drip irrigation system. B. I. Zegelman and N. I. Kuzyakin (USSR). 2198288/15 Declared 12/10/1975, publ. 02/05/1977, bull. 5 // Discoveries. Inventions. - 1977. - 5).

 The disadvantages of this drip irrigation system are the high requirements for preparing the surface of the irrigated area with slopes of less than 0.001. At slopes greater than this value, there is a sharp difference in the norms for the delivery of irrigation water.

The closest analogue to the claimed drip irrigation system is the known drip irrigation system, including a water source, a settling pool, a pumping station and an irrigation network with droppers, which, in order to increase reliability and reduce operating costs, is equipped with linearly extended tubular filters laid in the ground along the shore of the water source and buried beneath the groundwater level, while the tubular filters are in communication with the settling pool, which is closed (SU, copyright with idetelstvo 1551265, M.kl. ⁵ A 01 G 25/02. drip irrigation system. / H. A. Kudelya, A. Shevchenko, MI Romashchenko (USSR). 443 850 / 30-15, it is stated 06.05. 1988; publ. 23.03.1990, bull. 11 // Discoveries. Inventions. - 1990. - 11). We have adopted this drip irrigation system as the closest analogue.

 The disadvantages of this system include low productivity, limited functionality and a strictly limited irrigation rate. When using the described system in open ground with a sharply continental climate in particularly dry periods (from July 10 to August 20 annually) there is an acute shortage of required water. The lower humidity threshold in the root layer, during the fruiting period of all vegetable crops, decreases to 50-60% HB. This inhibits the growth of plants, reduces the quality and productivity of cultivated agricultural crops. cultures.

 The invention consists in the following.

 The problem to which the invention is directed is the expansion of the functionality of the drip irrigation system.

 EFFECT: increased productivity and expansion of the range of irrigation norms during planting and cultivation of plants with a wide range of crops.

 The specified technical result in the implementation of the invention is achieved by the fact that in a drip irrigation system including a water source, a settling basin, a pump station, a filter with pressure gauges, an irrigation network and droppers, according to the invention with a large range of water flow rate, the dropper group is hydraulically connected through connecting pipes to a water outlet , each of which is installed along the irrigation pipeline of the irrigation network, while the water outlet has the ability to rotate around the axis of symmetry and cm along it, a hydroshock with a control rod located in the body cavity by means of a sleeve, and in its cavity between the bottom part of the body and the end part of the plunger an elastic element is placed on the control rod, its free end is equipped with an eccentric and a control lever, and the body cover is equipped with a nipple with a pipe connected to with irrigation piping, nipples are arranged in tiers and with angular displacement on the said housing, the axial channels of which are combined with radially oriented channels of the sleeve and spool, called the trunk is tiered with radial-oriented channels connected by an axial channel and made parallel to it with a receiving cavity of the hydroshock.

 Due to the fact that each group of droppers is formed with large individual discrete values of the flow rate of irrigation water and connected to the hydraulic network of the drip irrigation system by means of a controlled outlet with fixed positions of the hydroshale, the above technical result is achieved.

 The invention is illustrated by drawings.

 Figure 1 schematically shows a drip irrigation system.

In Fig. 2, place A in Fig. 1, the positions of water outlets on irrigation pipelines and injectors on the surface of irrigated strips, for example, when cultivating Novichok tomatoes in open ground with machine technology for plant care and harvesting, indicating moisture zones α, β, γ, δ and ε.
In FIG. Figure 3 schematically shows a drip outlet from the receiving cavity of the hydroshale when supplying irrigation water to a group of droppers with indices q ₈ , q ₆₆ , q ₂₂ and q ₄ (irrigation of zones β and δ).

Figure 4 shows a section B-B in figure 3, a diametrical section of the body, sleeve, cover with a nipple, a waterwell with axial and parallel channels and radial channels intersecting with them when irrigation water is supplied to dropper groups with even indices q ₈ and q ₂ , equally in droppers with indices q ₄ and q ₆ , from the whole group q ₁ -q ₉ with increasing flow rates according to arithmetic progression (an example of water supply through the upper tier of the body nipples).

In FIG. Figure 5 shows the position of the waterwell and the sleeve in the cavity of the body of the water outlet when irrigation water is supplied to the group of droppers with indices q ₁ , q ₇ , q ₉ and q ₃ (outflow of purified water through the middle tier of the body nipples during irrigation of the moisture zones α, γ and ε).

In FIG. 6 is a cross-section BB in FIG. 5, a diametrical section of the outlet at the upper position of the hydroshock: combined positions of the radial channels of the body, sleeve and spool when irrigation water is directed to the dropper group with odd indices q ₁ , q ₇ , q ₉ and q ₃ ( humidification by irrigation water of zones α, γ and ε).

In FIG. 7 shows the position of the nipples on the body of the outlet when irrigation water is supplied to the group of droppers with indices q ₆ , q ₇ , q ₂ , q ₉ , q ₄ , q ₃ , q ₅ , q ₈ , q ₁ .

In FIG. 8 is a cross section GG in FIG. 7, a vertically oriented diametrical section of a drip outlet at the upper position of the hydroshock for supplying water to nipples with indices q ₆ , q ₈ , q ₁ and q ₅ (moistening of the zones α, β and γ).

In FIG. 9 is a section DD in FIG. 8, a horizontal section of the upper part of the body, the sleeve and the hydroshock of the water outlet when water is supplied to the droppers with indices q ₈ and q ₆ .

In FIG. 10 is a cross-section EE in Fig. 8, a horizontal section of the middle part of the body, the sleeve and the hydroshock of the water outlet when irrigation water is supplied to the dropper with the index q ₁ .

In Fig.11 - section FJ in Fig.8, a section of the lower part of the housing, the sleeve and the hydroshock of the water outlet when irrigation water is supplied to the dropper with index q ₅ .

On Fig presents the displaced position of the hydroshale when supplying irrigation water to the group of droppers with indices q ₈ , q ₄ , q ₃ and q ₅ (moistening zones β, γ and δ).

In FIG. 13 is a section DD in Fig. 8, a horizontal section of the upper part of the body, the sleeve and the hydraulic outlet of the water outlet when water is supplied to the dropper with indices q ₈ and q ₄ .

In FIG. 14 is a cross-section EE in FIG. 8, a horizontal section of the middle part of the body, the sleeve and the hydraulic outlet of the water outlet when water is supplied to the dropper with an index of q ₃ .

In Fig.15 is a section FJ in Fig.8, a section of the lower part of the body, sleeve and hydroshale when supplying irrigation water to a dropper with an index of q ₅ .

In FIG. 16 shows the displaced position of the hydroshock in the water outlet housing when irrigation water is supplied to the group of droppers with indices q ₂ , q ₄ , q ₉ and q ₅ (moistening of the zones γ, δ and ε).

On Fig - cross section DD in Fig.8, the cross section of the upper part of the housing, the sleeve and the hydroshock of the outlet when water is supplied to the droppers with indices q ₂ and q ₄ .

On Fig - section EE in Fig.8, the cross section of the middle part of the housing, the sleeve and the hydroshock of the outlet when water is supplied to the dropper with index q ₉ .

In Fig.19 is a section FJ in Fig.8, a section of the lower part of the housing, the sleeve and the hydroshock of the outlet when water is supplied to the dropper with index q ₅ .

In Fig.20 shows a new changed position of the hydroshock in the water outlet housing when irrigation water is supplied to a group of droppers with indices q ₆ , q ₂ , q ₇ and q ₅ for moistening the soil in zones β, γ and δ.
In Fig.21 - section DD in Fig.8, the cross section of the upper part of the housing, the sleeve and the hydroshock of the water outlet when water is supplied to the droppers with indices q ₆ and q ₂ .

In Fig.22 is a cross-section EE in Fig.8, a cross section of the middle part of the housing, the sleeve and the hydraulic outlet of the water outlet when water is supplied to the dropper with index q ₇ .

In Fig.23 is a section FJ in Fig.9, a section of the lower part of the housing, the sleeve and the hydroshock of the outlet when water is supplied to the dropper with index q ₅ .

In FIG. 24 is a cross-section ЗЗ in Fig. 20, a diametrical section of a water outlet when irrigation water is supplied to a group of droppers with indices q ₆ , q ₂ , q ₇ and q ₅ (humidification zones β, γ and δ).

 In FIG. 25 - the same when moving the hydroshock into the "Locked" position: the flag of the control knob of the hydroshock is oriented vertically downward.

In FIG. 26 schematically shows the position of the water outlet hydroshore when irrigation water is supplied to dropper groups with indices q ₁ -q ₉ .

 In FIG. 27 is a cross-section II in FIG. 26, the position of the hydroshock in the case sleeve when distributing purified water simultaneously to all droppers to ensure maximum irrigation rate.

In FIG. 28 is a section KK in FIG. 27, a horizontal section of a water outlet of the upper tier of nipples for supplying water to a group of droppers with indices q ₈ , q ₄ , q ₂ and q ₆ .

In FIG. 29 is a section LL in FIG. 27, a horizontal section of a water outlet of the middle tier of nipples for supplying water to a group of droppers with indices q ₁ , q ₃ , q ₉ and q ₇ .

On Fig - section MM in Fig.27, the cross section of the outlet of the lower tier to supply water to the nipple associated with a dropper index q ₅ .

 On Fig presents a soil injector for supplying irrigation water to the root horizon, a vertical diametrical section.

 Information confirming the possibility of implementing the claimed invention are as follows.

 The drip irrigation system (see Fig. 1) includes a water source 1, a settling basin 2, a pump station 3 with a suction sleeve 4 and a floating mesh valve 5, a filter 6 with pressure gauges 7 and 8, an irrigation network in the form of a main 9, distribution 10 and irrigation 11 pipelines, outlets 12, droppers or injectors 13 (see figure 2).

With a large range of flow rate of irrigation water, a group of droppers or injectors 13 (see Fig. 31) with water flow indices q ₁ ... q _{9 are} hydraulically connected via connecting tubes 14, 15, 16, 17, 18, 19, 20, 21, 22 with a water outlet 12 (figure 2). Each outlet 12 is installed along the irrigation pipe 11 of the irrigation network and is connected to it by means of a supply pipe of the corresponding section. With an increase in the index number q _i , the flow rate of the dropper or injector 13 increases discretely.

 The water outlet 12 is provided with the ability to rotate around the axis of symmetry and displacement along it with a hydraulic ram 23 with the control rod 24.

 Hydrosholnik 23 is placed in the cavity of the housing 25 of the outlet 12 by means of a sleeve 26. In the cavity of the sleeve 26 between the bottom part 27 of the housing 25 and the end part 28 of the hydroshank 23 is an elastic element 29 on the control rod 24. The free end of the rod 24 of the hydraulic actuator 23 is equipped with an eccentric 30, which is pivotally connected to the lever 32 for controlling the positions of the hydraulic actuator 23 in the cavity of the body 25 of the water outlet 12 via the axis 31. The lever 32 is provided with a pointer 33 for determining the working position of the hydraulic well 23 relative to the housing 25 of the water outlet 12. On the housing 25 in its bottom part 27 marks are made with equal angular displacement. The bottom part 27 of the housing 25 has a tide, in the cavity of which rings of the packing ring 34 are placed to prevent water leakage between the stem 24 and the housing 25. The upper part of the housing 25 is provided with a threaded cover 35. The cover 35 of the housing 25 provided with a nipple 36 is connected to the irrigation pipe 11 The nipples 37, 38, 39, 40, 41, 42, 43, 44, 45 are arranged in tiers and with an angular displacement on the casing 25. The axial channels of the nipples 37-45 are aligned with the radially oriented channels 46 of the sleeve 26 and the radially oriented channels 47- 55 hydraulic rams and 23. Said gidrozolotnik 23 formed therein bunk radially oriented channels 47-55 is connected through axial channel 56 and parallel thereto executed channels 57, 58, 59 and 60 with a receiving cavity 61 gidrozolotnika 23.

 To equalize the pressure in the rod cavity of the sleeve 26 and in the receiving cavity 61 of the hydroshale 23, its radial channel 55 is communicated by channels 62 with the cavity of the sleeve 26.

 To transfer the water outlet 12 to the operating mode of the highest delivery of irrigation water, i.e. for the case when all the nipple cavities 37-45 are in communication with the receiving cavity 61 of the housing 25, grooves 63 and grooves 64, 65 are made on the outer surface of the sleeve 26 mating with the inner surface of the housing 25.

 An integral part of the drip irrigation system are droppers made either in irrigation pipelines 11, or as individual soil injectors 13, connected via tubes 14-22 to water outlets 12.

 Each injector 13 (see FIG. 31) is hydraulically connected via a tube 14 (15-22) to a drip outlet 12 (see FIG. 2). The injector 13 comprises a housing 66, a cover 67, a locking element 68, an abutment 69, a sectional water distributor 70, a needle 71, an injector frame 72 made of a permeable material and a lug 73. A threaded section is made on the outer surface of the housing 66 for interfacing with the cover 67. In a sealed cavity case 66 under the cover 67 posted by the locking element 68. It is presented in the form of a hollow ball. In the cover 67 there is a nipple 74 for supplying water with a connecting tube 14 (15-22) from the nipple 37 (38-45) of the water outlet 12. The lower part of the injector body 66 is provided with a stop 69, which prevents excessive injection of the injector 13 into the soil. The frame 72 made of permeable material has a cavity 75. A replaceable sectional water distributor 70 is installed in it. A needle 71 is installed in the lower part of the frame 72 in its cavity 75 for introducing the injector 13 into the soil horizon. Lugs 73 hold the injector 13 upright on loosely coupled soils. The water distributor 70 is made in the form of a perforated pipe, on the outer surface of which the discs are made as a single part. Perforations are made between adjacent discs. The diameter of the disks is equal to the diameter of the opening of the cavity 75.

 The drip irrigation system operates as follows.

Irrigation water during the growing season of cultivated agricultural crops crops are taken from any water source 1 (river, lake, pond, well, canal or storage pond). Water from an open reservoir is sent to a settling basin 2. Suspensions and sediments sediment to its bottom under the influence of gravitational forces. Light deposits from a water mirror are periodically collected by one of the known techniques. From the settling basin 2, the settled water is sent to the filter cavity 6 with a pressure of 0.3-0.8 MPa by means of a floating mesh valve 5 and a suction hose 4 by a pump station 3 into the filter cavity 6. Suspensions and mineral debris with particle sizes up to 0 are collected in the filter 6. 1 mm. The normal operation of the system and filter 6 is judged by the readings of the pressure drops in the networks recorded by pressure gauges 7 and 8. With an open valve, water from the main pipeline 9 is sent to the distribution pipelines 10. The latter are laid along the boundaries of the irrigated sections. Irrigation pipelines 11 are laid along the long side of the irrigated field in increments of T (see FIG. 2). Water outlets 12 are installed at each irrigation pipe 11 with equal distance from each other. Water outlets 12 serve along the irrigation pipelines 11 strips b ₁ with a width of 0.6 ... 0.8 m. The strips are mutually spaced at a distance T (1.2-1, 4 m), sufficient for the tractor to pass when transporting boxes with seedlings during the planting period and for moving the tomato harvester during continuous harvesting.

Рассмотрим семь наиболее характерных случаев работы водовыпуска 12, обслуживающего группу капельниц или инъекторов 13 с расходами воды q₁...q₉, размещенных по длине орошаемой полосы шириной b₁.On a strip of width b _1, droppers or injectors 13 are arranged as follows:

Consider the seven most typical cases of the outlet 12 serving a group of droppers or injectors 13 with water flows q ₁ ... q ₉ located along the length of the irrigated strip of width b ₁ .

Второй случай в системе предусматривает работу инъекторов 13 с нормами расхода

охватывая капельным орошением участки β и δ.
Третий случай включает в работу капельницы с номерами индексов

Четвертый случай предусматривает орошение капельницами в зонах увлажнения β,γ и δ:

Пятый случай предназначен для увлажнения почвы в зонах орошения γ,δ и ε:

Шестой случай рассмотрим на примере орошения центральной части зоны увлажнения β,γ и δ:

Седьмой вариант предусматривает одновременную работу всех почвенных инъекторов 13 по длине орошаемой полосы шириной b₁ в период посадки и засух (суховеи в сочетании с высокими температурами воздуха и почвы):

Максимальная ширина увлажненной полосы Вп достигается при поливной норме 45 л/ч.The first case of installation in a drip irrigation system involves the operation of droppers with consumption rates

The second case in the system involves the operation of injectors 13 with consumption rates

covering drip irrigation sections β and δ.
The third case includes droppers with index numbers

The fourth case involves drip irrigation in the humidification zones β, γ and δ:

The fifth case is designed to moisten the soil in the irrigation zones γ, δ and ε:

The sixth case will be considered using the example of irrigation of the central part of the humidification zone β, γ, and δ:

The seventh option provides for the simultaneous operation of all soil injectors 13 along the length of the irrigated strip of width b ₁ during planting and droughts (dry winds in combination with high air and soil temperatures):

The maximum width of the wetted strip Bp is achieved with an irrigation rate of 45 l / h.

 Let us consider several examples of cultivating Novichok tomato in the Volgograd region on heavy mechanical soils (light chestnut soils with solonetzic complexes (Kotelnikovsky, Oktyabrsky and Kalachevsky districts), on light and sandy soils (Ilovlinsky and Surovikinsky districts), on chernozems (Nekhaev , Mikhailovsky, Novoanninsky, Novonikolaevsky and other areas), on floodplain and meadow soils (Akhtubinsky, Leninsky, Bykovsky, etc.). For these zones during tomato growing season with drip irrigation full-time total irrigation rate, respectively 2.0; 20.0; 10.0 and 1.6 l / h, while during the mass planting period, respectively; 4.5; 45.0; 22.5 and 3.6 l / h (see table data).

 It has been experimentally established that with drip irrigation, agricultural crops in open ground, the greatest effect of irrigation water is achieved when adjacent droppers or injectors 13 give a different amount of irrigation norm, and between the boundaries of water closure in the root layer there is an air layer from dry or low-moist soil 60% HB. This achieves the saturation of the roots of tomatoes with atmospheric air. The presence of accessible moisture and atmospheric air in the soil of the root-inhabited layer ensures an intensive growth of the vegetative mass of tomatoes, their flowering and maximum crop yield during fruiting and ripening.

(см. фиг.2).When supplying irrigation purified water to a subgroup of droppers or injectors 13 in the first case with indices q ₁ -q ₇ -q ₃ -q ₉ (see their position in figure 2) with irrigation water consumption respectively 0.1; 0.7; 0.3 and 0.9 l / h, the total water flow rate is 2.0 l / h. The water supplied is the moistening of the root layer in the zones

(see figure 2).

When pressurized with irrigation water, the latter through the supply pipe from the irrigation pipe 11 enters the nipple 36 of the cover 35 and fills the receiving cavity 61 of the hydroshock 23 (see FIGS. 5 and 6). From the receiving cavity 61 through the channels 58, 60 of the hydraulic well 23, the water is directed by radially oriented channels 51-54 of the spool 23 into the channels 46 of the sleeve 26, and from it into the nipples 37, 39, 45 and 43. From the nipples 37, 39, 45, 43 of the housing 25 of the outlet 12 through the connecting pipes 21, 14, 18 and 22, the water purified by the filter 6 is sent to the injectors 13 with indices q ₁ ; q ₇ ; q ₃ ; q _9, respectively, with an expense of 0.1; 0.7; 0.3; 0.9 l / hr.

 When irrigation water enters the injector 13 with a flow rate, for example, 0.9 l / h, into the nipple 74 of the cover 67, the water is discharged into the cavity of the housing 66, and the ball locking element 68 floats above the cavity 75 of the frame 72 of a permeable material. As the volume of water in the cavities of the casing 66 and the frame 72 increases, thanks to the sectional water distributor 70, artificial sediments uniformly along the height of the frame 72 through microchambers in the water distributor 70 penetrate through the porous material of the frame 72 into the root layer of the soil, maximally covering the skeletal and sucking roots of planted seedlings or seedlings for fruit and berry plantations. The water dispensers 70 are interchangeable with different flow rates. The type of water distributor 70 is selected taking into account the soil and climatic conditions of the zone in which agricultural crops are cultivated. plants.

When irrigation water is supplied to a group of droppers or injectors 13 in the second case with indices q ₆ -q ₂ -q ₄ -q ₈ (see their positions in FIG. 2) with irrigation water flow rates of 0.6, respectively; 0.2; 0.4; 0.8 l / h the total flow of water from the outlet 12 should be 2.0 l / h. In this case, the soil is moistened in zones β and δ. Hydrosholnik 23 in the housing 25 should take the position shown in figures 3 and 4. At the upper position of the hydroshock 23 in the sleeve 26, water from the irrigation pipe 11 through the nipple 36 of the cover 35 of the housing 25 enters the receiving cavity 61. Then, under pressure, the water through the channels 57 -60 is sent to the radial channels 47, 48, 49 and 50 of the hydraulic well 23, and then through the combined radial channels 46 of the sleeve 26 into the channels of the nipples 38, 42, 44 and 40 of the housing 25 of the outlet 12. The nipples 38, 42, 44 and 40 are connected 16, 17, 20 and 19 are hydraulically coupled to the nipples 74 of the covers 67 on the housings 67 injectors 13 (see Fig. 31). In each injector 13, the distribution of water occurs as described above.

When you turn the hydroshale 23 at an angle of 90 ^o from the starting position (I), its radially oriented channels 47-55 and axial channels 56, 57-60 will occupy the position shown in Fig.7-11. In this case, the nipples 42, 44, 37 and 41 will be used to connect with the injectors 13 models q ₆ ; q ₈ ; q ₁ ; q ₅ . Injectors 13 with the described indices, connecting tubes 17, 20, 21 and 15 with outlet 12 irrigate the portion α, β and γ (see figure 2). Water from the receiving cavity 61 of the hydraulic well 23 enters through its axial channels 57 and 60 and through radially oriented channels 47 and 49 into the channels 46 of the sleeve 26, and through them into the channels of the nipples 44 and 42 of the housing 25.

 Water from the receiving cavity 61 through the axial channel 56 of the hydraulic 23 and radial channels 55 and 46 enters the nipple 41 of the lower tier of the housing 25.

From the axial channel 58 of the hydroshock 23, water is directed into the radial channels 46 and 51, and then enters the nipple 41. Thus, irrigation with different water flow rates in the zones α, β and γ is carried out.
When transferring the hydro-well 23 (see FIGS. 12-15) to the fourth position from the source, water from the injectors 13 will be directed to the humidification zones β, γ and δ with water flow rates in the said zones of 0.8; 0.8 and 0.4 l / h. For this case, water under pressure from the receiving cavity 61 of the hydraulic well 23 through the axial and radial channels enters the nipples 40, 44, 39 and 41, and from them through the pipelines 20, 15, 18 and 19 it is sent to the injectors 13 with indices q ₈ , q ₄ , q ₃ , q ₅ .

Humidification in the zones γ, δ, ε in the bands In _p with planted seedlings is carried out by injectors 13 with indices q ₂ , q ₄ , q ₅ and q ₃ (see Figs. 16-19). To do this, the operator hydroshock 23 translates into a new position by turning it around the axis of symmetry at an angle of 45 ^o from the position shown in Fig.12-15. The supply and distribution of water from the irrigation pipe 11 through the outlets 12 to the groups of injectors 13 with indices q ₂ , q ₄ , q ₅ , q _{3 is} carried out in a similar way.

The water is supplied to the injectors 13 in the sixth, previously indicated case, through the water outlet 12 at the position of the hydroshock 23 shown in Figs. 20-23 and 24. Water comes from the injectors 13 with indices q ₆ , q to the humidification zones β, γ and δ ₂ , q ₇ , q ₅ , with 0.8 l / h of irrigation water being supplied to the humidification zones β, γ and δ, respectively; 0.7 l / h and 0.5 l / h, and a total of 2.0 l / h.

  To exclude the supply of water to a group of nine injectors 13, regardless of the initial position of the hydroshaft 23, the control lever 32 with the pointer 33 is translated by turning around the axis 31, orienting the pointer 33 to its lowest position (see Fig. 25). In this case, the hydroshock 23 in the sleeve 26 will occupy a position preventing the ingress of water into at least one of the nipples 37-45 on the body 25 of the water outlet 12. The pressure in the receiving cavity 61 of the hydroshock 23 and the pressure in the cavity of the sleeve 26 with a rod and an elastic element placed therein 29 are balanced due to the made axial channel 56 in the hydroshock 23, radial channel 55 and channels 62.

To maximize the supply of irrigation water through the outlet 12 to the injectors 13, the control lever 32 (see Fig. 27) is rotated 90 ^° from the position shown in Fig. 25. Figures 26-30 show horizontal sections along the upper, middle and lower tiers of the water supply to the nipple groups (42, 44, 40, 46), (37, 39, 45, 43) and 41. Injectors 13 with indices q ₁ - q _{9 the} soil is moistened in the habitable horizon in the zones α, β, γ, δ and ε (see figure 2).

Thus, a group of injectors 13 with indices q ₁ -q ₉ , hydraulically connected by connecting pipes 14-22 with a water outlet 12 and an irrigation pipe 11, provides the supply of purified water to the addressable humidification zones (α, β, γ, δ, ε) or produces irrigation with the maximum consumption of the entire strip during the planting period or in the season of the dry winds.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed invention:
drip irrigation system embodying the claimed invention in its implementation, is intended for use in agriculture and agricultural machinery;
for the claimed invention as described in the independent clause of the claims below, the possibility of its implementation using the means and methods described above or known prior to the priority date is confirmed;
means embodying the claimed invention in its implementation, is able to ensure the achievement of the perceived by the applicant technical result.

 Therefore, the claimed invention meets the requirement of "industrial applicability" under applicable law.

Claims (1)

A drip irrigation system including a water source, a settling basin, a pump station, a filter with pressure gauges, an irrigation network and droppers, characterized in that with a wide range of irrigation norms, the dropper group is hydraulically connected through connecting pipes with a water outlet, each of which is installed along the irrigation irrigation pipe network, while the outlet has the ability to rotate around the axis of symmetry of displacement along it with a hydraulic ram with a control rod located in the cavity of the housing by means of a sleeve, and in its cavity between the bottom part of the body and the end part of the hydroshaft there is an elastic element on the control rod, its free end is equipped with an eccentric and a control lever, the cover of the case equipped with a nipple is connected to the irrigation pipe with the irrigation pipe, in the above-mentioned case it is tiered and angularly nipples are placed, the axial channels of which are aligned with the radially oriented channels of the sleeve and the spool, called a hydroshale with the tiered radially oriented anal connected by axially parallel thereto and executed with channels gidrozolotnika reception cavity.

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