RU2793352C1 - Sprinkling device for irrigation machine - Google Patents

Abstract

FIELD: irrigation system.

SUBSTANCE: sprinkle-forming device of a sprinkling machine, which includes a short-jet sprinkling nozzle, containing a body with a longitudinal passage channel made in form of a confuser, passing into a cylindrical calibrated hole in form of a nozzle, and a deflector with a reflective surface, made in form of an ellipsoid surface, with an internal recess. At the same time, the body of the sprinkling nozzle with a longitudinal channel is additionally provided with a nozzle in form of a confuser on the outside, forming a circular gap with the walls, connected to the air inlet pipe, which is made through. The applied inlet pipe in the device is installed in such a way that the air flow is introduced into the liquid spray jet coming out of the device nozzle in form of a short-jet sprinkler nozzle, and an additional nozzle in form of a confuser with a nozzle made with a central angle α=13-15° and the angle of the generating nozzle are directed to one point on the surface of the deflecting reflector.

EFFECT: regulation of drop sizes and sprinkle intensity during irrigation.

3 cl, 3 dwg

Description

SUBSTANCE: invention relates to fine and drip irrigation technique and can be used in mobile and stationary sprinkler systems to produce rain with droplet sizes acceptable for irrigating a wide range of cultivated crops.

Known sprinkling machine, including a fixed support with a hydrant, a pressure pipeline mounted on a self-propelled support, irrigation devices with spray nozzles in each mezhopornaya section. Five irrigation devices are installed in each intersupport section of the pressure pipeline, each of which consists of three vertical pipes connected to each other by couplings, the upper of which is fixed in the lower part of the pressure pipeline, and on the lower branch pipe through a tee two horizontal tubes are installed, three middle irrigation devices are equipped with main and additional deflector nozzles of circular irrigation, and the horizontal tubes of the two extreme irrigation devices are equipped with main and additional deflector nozzles of sector irrigation, and the deflector of all sector irrigation nozzles is equipped with a divider, the end of which is located on the nozzle axis of the sector irrigation nozzle, in addition, each the horizontal tube between the lower branch pipe and the additional nozzle is equipped with a shut-off valve (Patent RU No. 74033, A01G 25/00 dated 06/20/2008).

The disadvantages of the described device of the sprinkling machine include the limited technological use of each individual nozzle due to the impossibility of providing a small flow rate of irrigation water at its high pressure in the pressure pipeline, especially in its initial section, and the breakdown of the liquid into drops slows down, as well as the complexity of the design. generally. In addition, if the design of the sprinkling machine has devices on each tube, more than two liquid spray nozzles increase the cost of its design.

A short-jet sprinkler nozzle is also known, comprising a body with a longitudinal passage channel made in the form of a confuser that passes into a cylindrical calibrated hole, a deflector with a reflective surface made in the form of an ellipsoid surface with an internal recess, the height of the calibrated cylindrical hole is selected less than 0.5d, and the angle between the tangents to the surface of the inner recess at the points of intersection with the deflector body is chosen equal to 155-160°, while the distance from the top of the cone of the confuser to the plane of the outflow of the liquid is (3.3-3.6)d, and to the point of the reflective surface of the deflector is equal to (2 ,2-2,3)d, where d is the diameter of a calibrated cylindrical hole (Author's certificate SU No. 1729603, V05V 1/04 dated 04/30/1992).

A disadvantage of the well-known short-jet sprinkler nozzle is the limited technical use due to the impossibility of reducing the diameter of the calibrated hole less than 2.5 mm in diameter under the conditions of irrigation water purification at high pressure in the pressure pipeline, especially in its initial section. In addition, it does not allow for effective ejection of air with the possibility of entering through the air supply tube from the atmosphere, thereby obtaining an extension of the liquid spray range in the nozzle torch.

The task to be solved by the claimed invention is the expansion of technological capabilities under operating conditions.

EFFECT: regulation of droplet size and intensity of rain during irrigation, creating a vacuum in the inflow zone by capturing air flowing out of the air through the opening of the air-conducting pipe towards the annular gap between the side walls, forming an additional nozzle in the form of a confuser from the outside, i.e. increasing the reliability of the cascade of confusers coaxially installed to each other and asymmetrically towards the deflector.

The specified technical result is achieved by the fact that the known rain-forming device of the sprinkling machine, including a short-jet sprinkler nozzle, containing a body with a longitudinal passage channel made in the form of a confuser, passing into a cylindrical calibrated hole in the form of a nozzle, a deflector with a reflective surface, made in the form of an ellipsoid surface, with an internal recess, according to the invention, the body of the sprinkling nozzle with a longitudinal channel is additionally equipped with a nozzle in the form of a confuser on the outside, forming an annular gap with the walls, communicated by a hole with an inlet air duct, which is made through, the inlet used in the device is installed in such a way that the air the flow is introduced into the spray jet of the liquid coming out of the nozzle of the device in the form of a short-jet sprinkling nozzle, and an additional nozzle in the form of a confuser with a nozzle made with a central angle α=13-15°, and the angle of the forming nozzle is directed to one point to the side on the surface of the deflector reflector.

In addition, the end part of the liquid inlet pipe towards the nozzle of the short-jet nozzle in the form of a confuser is made with flow stabilizers in the form of flat plates located radially relative to the longitudinal axis of the pipe and fixed with the end part to the inner walls of the pipe.

In addition, as an embodiment, the end part of the nozzle of the short-jet nozzle in the form of a confuser after the liquid inlet pipe, the longitudinal axis of which coincides with the longitudinal axis of the nozzle, is equipped with an air-conducting tube made coaxially with the nozzle and the nozzle inside them, while the air-conducting tube is connected by an inlet communicated with the atmosphere.

In addition, the air outlet has a control ball valve.

In order to change the pressure of the water-air mixture in the inlet chamber of the additional nozzle in the form of a conical confuser, it has, due to the threaded connection, the possibility of changing its altitude position relative to the short-jet nozzle made in the form of a confuser and connected to the irrigation water inlet pipe.

The novelty of the proposed technical solution is also due to the fact that an additional nozzle in the form of a cone confuser creates the possibility of operation of the mixing chamber, while the main short-jet nozzle is located with the inner chamber, created with an annular gap, and the nozzle (hole) of the short-jet nozzle is made coaxially with the outlet nozzle ( hole) of the mixing chamber with an additional nozzle. Placing the plane of the outlet nozzle of the short-jet nozzle under the outlet of the air inlet pipe allows for efficient air ejection, where the flow is introduced into the spray jet of the liquid leaving the nozzle, the air that enters through the control ball valve from the atmosphere. This arrangement makes it possible to form hydraulic water-air jets at the outlet of the mixing chamber, which, due to the presence of air microbubbles, more intensively pass upwards into the nozzle of an additional nozzle in the form of a cone confuser, which means reducing the water pressure from the pressure pipeline to the side with a reflective surface made in the form of a surface an ellipsoid, with an internal recess, of the deflector, while the nozzle of the additional conical confuser is made with a central angle α=13-15°, its top is on the surface of the reflective screen of the deflector. In addition, this contributes to the active crushing of drops upwards, as a result, the jets descending from the deflector are still broken into smaller raindrops, which do not damage crops, significant leaching and water erosion of the soil, and also contribute to the uniform distribution of rain by deflector nozzles of sectoral irrigation, so how a more saturated torch of liquid spraying over the irrigation area arises at any flow rate.

The quality of artificial rain is determined by its intensity, the size of drops, layers of sediment in one cycle and the uniformity of distribution over the irrigated area based on the creation of an improved rain-forming device. In this case, the input parameters are the characteristics of the water flow from the pressure pipeline and the parameters of the incoming air from the atmosphere with a control ball valve on the branch pipe, which means that this allows for effective air ejection, and the possibility of its entry using a control ball valve, the air that comes from the atmosphere along the air intake pipe, and the setting parameters of the two confusers, their cross section of each other (shape, static chamber with an annular gap, its geometry and location, nozzle execution angle towards the surface of the deflector reflector, flow shape (and flow characteristic (speed, direction, droplet diameter Thus, the proposed device revealed a new technical solution, depending on the use of two jointly working nozzles, made in the form of a number of confusers from the receiving water-air chamber for the first time for the nozzle of sector irrigation of a sprinkling machine.

Theoretical justification of the proposal.

For short-jet sprinkler nozzles used on wide-cut machines, like the sprinkler nozzle selected for the prototype, the optimal value of the confuser taper angle α=13-15° is provided. Therefore, the nozzle with a nozzle is made with a central angle of 13-15°, that is, with the same angle as the confuser of the sprinkler nozzle.

To increase the width of the sector irrigation deflector nozzle at least 6 m, the deflector is equipped with a reflective surface made by milling and is a part of the surface of the ellipsoid of rotation in the vertical plane. The central angle of the cone with the nozzle of the additional confuser is α=13-15°, its value is at a distance from the top of the cone (nozzle) of the confuser to the plane of the outflow of the water-air flow is h _k = (3.5 ... 3.7) d, where d - nozzle diameter (calibrated cylindrical hole).

The design of the proposed device meets the agrotechnical requirements. It is known that the equation of the trajectory of a water jet flowing out of a sprinkler nozzle in the absence of air resistance is described by the dependence:

x=xtgθ _o -x ² /4H⋅cos ² θ, where z and x are the coordinates of the jet trajectory, m; H - head at the nozzle inlet, m; θ - jet departure angle, deg.

где

-коэффициент сопротивления при движении струи в воздухе; S - площадь поперечного сечения капли, перпендикулярного направлению его движения, м²;

- плотность воздуха, кг/м³; V_o - скорость капли, м/с.In reality, the jets of water released from the nozzle break up almost immediately into drops of water-air rain, which must overcome the resistance of the environment. This effect reduces the radius of the raindrop flight (R _k ) according to the law:

Where

- resistance coefficient when the jet moves in the air; S - cross-sectional area of the drop, perpendicular to the direction of its movement, m ² ;

- air density, kg / m ³ ; V _o - drop speed, m/s.

Then, taking into account the impact on the raindrop of the environment, the radius of irrigation with a sprinkler nozzle will be equal to:

Due to the fact that all the design parameters of the rain-forming device are interconnected, they must be considered as a whole.

The flight range of a raindrop is influenced by the angle of inclination of the generatrix of the deflector cone. The use of deflector nozzles with a given taper provides wind resistance of artificial rain, high uniformity of its distribution, while not deteriorating the quality of the rain.

The diameter of the deflector cone is related to the diameter of the outlet nozzle (hole) nozzle dependence: D _k =(d ² _resp -δ)2δ, where D _k and d _resp . - respectively, the diameters of the base of the deflector cone and nozzle nozzle, mm; δ is the thickness of the water film at the exit from the deflector cone, mm.

где Q - расход воды через насадку, м³/с; μ - коэффициент расхода, зависящий от формы входных кромок отверстия (принимается равным μ=0,8); g - ускорение свободного падения, м/с; Н - напор перед насадком, м'.The diameter of the outlet nozzle (hole) of the nozzle, which has a round shape, will be determined by the formula:

where Q - water flow through the nozzle, m ³ / s; μ - flow coefficient depending on the shape of the input edges of the hole (assumed to be μ=0.8); g - free fall acceleration, m/s; H - head in front of the nozzle, m'.

The intensity of rain is one of the main indicators characterizing the operation of the sprinkler.

The average rain intensity is determined by the well-known formula:

ρ _ϕ =60Q/πR ² ⋅10 ³ , mm/min,

where Q is the water consumption of the sprinkling machine, m / ³ s; R - radius of irrigation with a sprinkler nozzle, m.

The formula for determining the irrigation rate before runoff with sprinkler nozzles with a droplet diameter of 0.3-0.5 mm is:

m=45.3⋅K' ₁ ⋅K _2, m ³ ha,

where K' ₁ =1+0.0147(70-ω) - coefficient taking into account pre-irrigation soil moisture before sprinkling; ω - soil moisture from lower moisture capacity: k ₂ =1-15.11⋅i - coefficient taking into account the slope of the field surface; i - slope of the field surface, in fractions; ρ - rain intensity, mm/min.

At a pressure H=1.5…4.5 m, the jet breaks up into small drops and is more evenly distributed along the irrigation radius of the deflector nozzle.

The time during which the drop accelerates, taking into account the momentum of the drop: mV _B =F _B ⋅Δt ₂ .

The mass of a drop is determined by its volume, it is the diameter d and the density of water ρ, then we get:

m=πd ³ /6ρ. Transforming the equation, we also get: F _B \u003d P _B ⋅q⋅V _B \u003d P _B (πd ² )⋅V / 4, where P _B - air density is 1.29 g / cm ³ ; d - nozzle diameter; V _B - wind speed; F _B - wind density; q is the flow rate of the drop.

This means that it is carried out with low rates and low intensity with a minimum depth of soil wetting, and leaching of nutrients and loss of humus can be avoided, as this leads to a decrease in soil fertility, on the example of the Republic of Belarus.

It is known that the growth, yield and value of both cereals and legumes, as well as other agricultural crops, depend on the amount of available fertilizer and availability with sufficient moisture in the soil. Therefore, it is sprinkling that can be economically justified with a high organization of the use of irrigated fields and a sufficient level of mineral nutrition for the movement of sprinkling by machines (aggregates), i.e. water intake from a ready water source, as well as the ability to supply easily soluble mineral fertilizers with irrigation water for vegetative top dressing, which is very important for increasing crop yields, as well as the ability to introduce pesticides to control pests, weeds and plant diseases.

The main parts can be made of polymeric material. It should be noted that irrigation water through nozzles made in the form of two confusers with their nozzles, then enters the inner surface of the reflective screen of the deflector in the form of tiny particles, is thrown into the surface air layer and, under the action of gravitational forces, in the form of water dust settles on leaves, stems. plants and topsoil. This moisture relieves stress from plants. There is a slow decrease in the temperature of the environment and plants. Each plant adapts to changing temperatures.

The extensive analysis of the prior art carried out by the applicants, including the search for patent and scientific and technical sources of information and the identification of sources containing information about analogues of the claimed invention, allows us to establish that the applicants have not found an analogue characterized by features identical to all essential features of the claimed invention.

Therefore, the claimed invention meets the requirement of "novelty" under the current legislation.

To verify the compliance of the claimed invention with the requirement of "inventive step", the applicant conducted an additional patent search for known solutions in order to identify features that match the distinguishing features of the claimed invention from the closest analogue, the results of which show that the claimed invention does not follow for a specialist explicitly from the prior art and technologies, since from the state of the art and technologies defined by the applicant, no influence of the transformed invention provided for by the essential features of the invention on the achievement of the technical result has been revealed.

Therefore, the claimed invention meets the requirement of "inventive step" under the current legislation.

The invention is illustrated by drawings: Fig. 1 shows a longitudinal section of a rain-forming device installed on the pressure pipe of a sprinkler machine; in fig. 2 is a section 1-1 in FIG. 1; in fig. 3 - design of a nozzle in the form of a confuser, equipped with an air-conducting tube, made coaxially to it towards the outlet chamber of an additional nozzle in the form of a confuser.

Information confirming the possibility of implementing the proposed technical solution is as follows.

The rain-forming device of the sprinkling machine comprises a body of nozzle 1 in the form of a short-jet confuser with a nozzle 2 and fixed coaxially with a thread with an additional nozzle 3 in the form of a confuser with a conical cone and with a nozzle 4, with an outlet chamber 5. The body of the additional nozzle 3 has a deflector above its upper part 6 sectoral irrigation action with a reflective surface 7. The body of the main nozzle 1 in the form of a short-jet confuser has a connecting section 8 for connecting to the water pipe 9 and is fixed with a shaped nut 10. Nozzles 1 and 3 with nozzles 2 and 4 are made coaxial to each other. The nozzle 3 is provided inside with a mixing chamber 5, and the nozzle with its outlet end with a nozzle 2 is located inside the chamber 5, while the diameter of the mixing chamber 5 is larger than the outer diameter of the outlet end of the nozzle 2 of the short-jet nozzle 1. In addition, in the area of the outlet end, the nozzle 1 is made there is an annular gap 11 around it. The plane of the nozzle 2 of the nozzle 3 can be shifted inside the mixing chamber 5 and located under the outlet 12 in the side wall of the casing of the nozzle 3 of the air pipe 13 with a control ball valve 14 communicating with the atmosphere. At the same time, the end part of the pipe 9 of the water is made with flow stabilizers 15 in the form of flat plates located radially relative to the longitudinal axis of the pipe 9 and fixed with the end part to the inner walls of the pipe 9.

According to an embodiment, the inner hole of the short-jet branch pipe 1 towards the nozzle 2, when the longitudinal axis of the water branch pipe 9 coincides with the longitudinal axis of the branch pipe 1, can be provided with an air supply tube 16 with a ball valve 14. confuser with a conical cone with a chamber 5, inside them, the inlet of which communicates with the atmosphere.

The sprinkler is installed in the working position so that the reflective surface 7 with the point of convergence at an angle towards nozzles 1 and 3 with nozzles 2 and 4 are directed perpendicular to the axis of the water supply pipeline of the sprinkler machine (not shown).

Additional nozzle 3 in the form of a confuser, having an inner surface of the cone, is made with a central angle α = 13-15°, and the central angle of the nozzle 3 cone with an angle α=13-15°, its top of the confuser cone to the plane of liquid outflow is h _k = (3.5 ... 3.7) d, where d is the diameter of the nozzle (calibrated cylindrical hole) from the plane of expiration 17 of nozzle 3 from the water-air environment, nozzle 4. It should be noted that due to the threaded connection of the cone nozzle 3 with a short-jet nozzle 1 (confusers) it is possible to regulate the pressure of the water-air medium in the inlet chamber 5 of the nozzle 3.

The methodology for determining the quality indicators of the operation of the rain-forming device of a sprinkling machine is based on the requirements of RD 70.11.1-89 “Sprinkler machines and installations. Test program and methodology” VTR-0-81.

Sprinkling device sprinkling machine works as follows.

The device is being installed on the pressure pipeline of the sprinkling machine according to the proposed technological scheme, the pipe body 9 is attached to the pressure pipeline (not shown) of the sprinkling machine, into which water is supplied, by means of a threaded connection 8. In this case, water from the nozzle 9 first enters the short-jet nozzle 1 in the form of a confuser, which is oriented with its end of the nozzle 2 coaxially towards the mixing chamber 5 of the additional nozzle 3 in the form of a confuser with a conical cone and are installed in the working position, the latter is installed so that the water-air mixture entered the reflective surface 7 of the sector deflector 6 for irrigation. In this case, the mixing chamber 5 with an annular gap 11 of the end of the short-jet nozzle 1 with a nozzle 4 is located inside the chamber 5 with an outlet 12 of the air pipe 13 with a control ball valve 14, which communicates with the atmosphere with a control ball valve 14, which allows for a given effective ejection of air, coming through the pipe 13 from the atmosphere. This arrangement makes it possible to form a hydraulic water-air jet at the outlet of the mixing chamber 5 due to the presence of air microbubbles, it more intensively affects the reflective surface 7 of the deflector 6, destroys the structure of water and contributes to active removal into the atmosphere, in the form of tiny particles it is thrown into the surface layer of air and under the action gravitational forces in the form of water dust settles on the leaves, stems of plants. There is a slow decrease in the temperature of the environment and plants. Each plant adapts to changing temperatures. After that, it is possible to temporarily increase the working pressure of water in the water supply pipeline after irrigation by finely dispersed sprinkling, raising it to 4.5 ... 5.0 m. 0.1 ... 0.5 mm is released into the atmosphere at a distance of 2 to 6 m, moves into the surface layer of air, crushes and settles down, providing a given flow rate and the required quality of the rain formed. When moving upward, the water-air flow in the nozzle 3 is gradually compressed in the cone of the diffuser with a nozzle, increases its speed to the maximum in front of the calibrated hole (nozzle 4) with the highest kinetic energy, its water-air mixture through the nozzle 4 hits the reflective surface 7 of the deflector 6, changes the direction of movement and , disintegrating into separate jets and drops, turns into artificial rain, distributed over the surface of the irrigated area. In this case, the water flow, passing through the chamber 5, nozzle 3 in the form of a confuser, is actively saturated with air with a control ball valve 14, the resulting water-air mixture is smoothly and freely sprayed from the deflector into the atmosphere. Both arrangements of variants of the rain-forming devices make it possible to create favorable hydraulic conditions in the chamber of the additional nozzle 3 with a nozzle 4 towards the reflective surface 7 of the deflector 6 and to ensure a reliable design of the rain-forming device as a whole of the sprinkling machine.

With the help of cascade nozzles (double) in front of the static deflector, it is possible to distribute significant flows within the normative intensity limits, providing a soft irrigation regime.

It should be noted that another main factor of novelty is that when leaving the hydraulic short-jet nozzle in the form of a confuser with a nozzle, the liquid formed into a jet enters the ejector chamber with an additional nozzle in the form of a confuser with a nozzle and into the gap between the end of the short-jet nozzle, then enters the additional the conical confuser through the nozzle, hitting the surface of the deflector, is ejected into the atmosphere in the form of a torch. When hitting the deflector, the jet forms a liquid film on it, which is further crushed at the deflector edge.

The average size of liquid spray droplets depends on the thickness of this film and its energy. These parameters can be changed by changing the point of contact of the jet relative to the point on the surface of the deflector, then the contact of the jet relative to the edge of the deflector: the decomposition of a thin film with a significant kinetic energy makes it possible to obtain small drops, with the decomposition of a thick film retarded on the passed in the chamber additionally in a cone nozzle in the form confuser along the way, it turns out a large-drop spray.

The ejected air partly serves as an additional medium for spraying, partly aerates the liquid, forming foam in the presence of small amounts of foaming agent.

The implementation of the rain-forming device of the sprinkling machine according to the invention makes it possible to adjust the spray pattern according to the droplet diameter over a wide range at constant liquid parameters in front of the hydraulic nozzle of an additional nozzle in the form of a conical confuser, it also involves taking into account the possibility of using the device for irrigation (strong wind, high temperature, etc. .) and setting the rainmaker to the required operating mode.

Adjusting the width of the sector watering allows you to use the same rainmaker for both wide and other watering machines.

When considering the proposed technical solution for a normalized rain layer along the capture radius of the sprinkler, depending on the diameter of the nozzle, it can be seen that with increasing pressure, the distribution of the rain layer along the capture radius becomes more uniform. In this case, the principle of distribution of the rain layer does not depend on the diameter of the nozzle.

All design parameters of the rain-forming device are interconnected, and therefore they must be considered as a whole.

The theoretical part of determining the operation of the device is described in detail above.

It should be noted that the use of this device provides wind resistance of artificial rain at a wind speed of 3.5 ... 4 m / s, while the irrigation efficiency coefficient is in the range of 0.75 ... 0.80. The rain cloud rises, while the loss of water for evaporation and drift along the pipeline is reduced to 12.3% instead of 14.1% for serial medium jet devices. The water consumption when changing the nozzle diameter from 4 to 9 mm varies within (0.12…1.5)⋅10 ^-3 m ³ /s, and corresponds to the norms of the radius of irrigation of sprinkler nozzles to ensure normalized overlap and will be at least 6 m. Increasing crop yields by 5.5…18% is ensured by more uniform irrigation water supply, reduced water losses for evaporation and drift, reduced droplet size and water-air rain.

The presence of impurities and fine sediments in irrigation water does not prevent the nozzles from carrying out the technological process - the creation of water-air droplets of a given size and the required rain intensity.

Sprinkler devices are made of polymeric material, in particular, of high-strength plastic, easy to manufacture (stamping method), reliability of operation is increased, high-quality fine rain is obtained, and the possibility of maintenance is simplified.

Claims (4)

1. A rain-forming device of a sprinkling machine, including a short-jet sprinkling nozzle, containing a body with a longitudinal passage channel made in the form of a confuser, passing into a cylindrical calibrated hole in the form of a nozzle, a deflector with a reflective surface, made in the form of an ellipsoid surface, with an internal recess, characterized in that that the body of the sprinkling nozzle with a longitudinal channel is additionally equipped with a nozzle in the form of a confuser on the outside, forming an annular gap with the walls, communicated with the air inlet pipe, which is made through, the inlet pipe used in the device is installed in such a way that the air flow is introduced into the spray jet of the liquid outgoing from the nozzle of the device in the form of a short-jet sprinkler nozzle, and an additional nozzle in the form of a confuser with a nozzle made with a central angle α=13-15°, and the angle of the forming nozzle are directed to one point on the surface of the deflector reflector. 2. A rain-forming device according to claim 1, characterized in that the end part of the liquid inlet pipe towards the nozzle of the short-jet nozzle in the form of a confuser is made with flow stabilizers in the form of flat plates located radially relative to the longitudinal axis of the pipe and fixed with the end part to the inner walls of the pipe. 3. A rain-forming device according to claim 1, characterized in that, as an embodiment, the end part of the nozzle of the short-jet nozzle in the form of a confuser after the liquid inlet pipe, the longitudinal axis of which coincides with the longitudinal axis of the nozzle, is equipped with an air-conducting tube made coaxially with the nozzle and nozzle inside them, while the air-conducting tube is connected by an inlet communicated with the atmosphere. 4. A rain-forming device according to claim 1, characterized in that the air pipe has a control ball valve.

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