RU2849960C1 - Fine dispersion raining-sprayer - Google Patents

Abstract

FIELD: agricultural machinery.

SUBSTANCE: invention relates to fine-spray and drip irrigation technology. It describes a fine-spray sprinkler that includes a deflector mounted on a water pipe and secured to a stand, and a nozzle with a central opening. The body of the nozzle with a central opening is connected in height to the jet outlet channels and has a height extension, and is made in the form of a nozzle with a variable cross-section, including sequentially coaxial sections of conical narrowing, a cylindrical section in the form of a nozzle and a section of conical expansion, in which a divider with a mixing chamber is located, the mixing chamber is partially integrated into the nozzle and connected to a replaceable nozzle, in addition, the divider is made in the form of a truncated cone, with its smaller base facing the cylindrical section of the nozzle and its larger base facing the central opening of the replaceable nozzle in the nozzle, the air supply channel communicates with the conical expansion section through openings located opposite the side surface of the truncated cone of the divider, the replaceable nozzle in the nozzle serves to form a jet of flow at the outlet, the conical deflector is located above the replaceable nozzle of the nozzle, the base of the deflector is fixed to a vertical post in the form of a bracket, the lower end of which is attached from the outside to the side wall of the nozzle housing, the angle of the cone deflector being 120° in the direction of the vertical axis of the water outlet of the replaceable nozzle.

EFFECT: invention provides fine sprinkling, increased crop yields when growing plants during irrigation, increased operational reliability of the fine sprinkler-sprayer, and improved operating conditions.

9 cl, 2 dwg, 2 ex

Description

The invention relates to the technique of fine-dispersed and drip irrigation and can be used in mobile and stationary sprinkler installations or spraying to produce rain with droplet sizes acceptable for irrigating a wide range of cultivated agricultural crops.

Currently, the task is underway to restore irrigation equipment and create new high-tech designs of irrigation devices (apparatus, nozzles) that ensure safe irrigation and energy savings.

As a result, sprinkler systems are undergoing repeated modernization. However, literature indicates that ongoing research has not yet fully addressed the issue of improving irrigation quality or creating new, high-tech sprinkler and nozzle designs.

In this regard, the task is very relevant and has great practical, scientific and economic significance.

A sprinkler machine is known that includes a fixed support with a hydrant, a pressure pipeline installed on self-propelled supports, and irrigation devices with spray nozzles in each inter-support section. In each inter-support section of the pressure pipeline, five irrigation devices are installed, each of which consists of three vertical pipes installed, connected to each other by couplings, the upper of which is fixed in the lower part of the pressure pipeline, and on the lower 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, wherein the deflector of all nozzles of sector irrigation is equipped with a divider, the end of which is located on the axis of the nozzle of the sector irrigation nozzle, in addition, each horizontal tube between the lower pipe and the additional nozzle is equipped with a shut-off valve (Patent RU No. 74033, A01G 25/00 dated 20.06.2008).

The disadvantages of the described sprinkler system include the limited use of each individual nozzle due to the inability to ensure low irrigation water flow rates at high pressure in the pressure pipe, especially at the initial section. This slows down the breakdown of the liquid into droplets, as well as the design complexity. Furthermore, having more than two liquid spray nozzles on each pipe increases the cost of the sprinkler system.

Also known is a short-jet sprinkler nozzle, comprising a housing with a longitudinal passage channel made in the form of a confuser, turning 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 to be less than 0.5d, and the angle between the tangents to the surface of the internal recess at the points of intersection with the deflector housing is selected to be equal to 155-160°, while the distance from the top of the confuser cone to the plane of liquid outflow 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 the calibrated cylindrical hole (Author's certificate SU No. 1729603, B05B 1/04 dated 30.04.1992).

A disadvantage of the well-known short-range sprinkler nozzle is its limited technical use due to the impossibility of reducing the calibrated orifice diameter to less than 2.5 mm, which is necessary for irrigation water purification under high pressure in the pressure pipeline, especially in its initial section. Furthermore, it does not provide effective air ejection with the ability to draw air from the atmosphere through the air supply tube, thereby expanding the spray pattern of the nozzle.

A well-known sprinkler system should be provided, which includes a base, a body with a rod, a main stop and additional trunks, a main and additional nozzles and a rocker arm with a stop and a pendulum wedge-shaped deflector. The rocker arm is provided with a flexible tube, one end of which is connected to the cavity of the housing, and the other end is fixed on the rocker arm against a pendulum wedge-shaped deflector mounted on a rod with the possibility of rolling and a limited angle of inclination to the axis of the end of the flexible tube by means of a limiter, wherein the deflector has upper and lower limiting flanges, a wedge with reaction blades located at the ends of the diverging planes of the wedge, the main barrel is made with an additional stop with two ends in different directions with the possibility of interaction with the lower limiting ends with the possibility of interaction with the lower limiting flange of the wedge-shaped deflector on both sides (Patent RU No. 2799652, A01G 25/00, B05B 3/02 dated 07.07.2023).

However, as the operating pressure in the discharge pipeline increases, the flow cross-section of the main and auxiliary nozzles is limited in diameter, from 0.6 mm and 3.2 mm, respectively. Furthermore, the design is complex and insufficient in reliability in the event of sediment intrusion with irrigation water, and the inability to achieve a finer spray pattern is impossible. Furthermore, maintaining a certain operating pressure is necessary.

Also known is a turbine-type sprinkler apparatus comprising a hollow cylindrical body with a guide rod, a conical deflector with curved grooves, an adjusting nut and a lock nut, in which the body is additionally provided with a partition, and the conical deflector with a fluoroplastic gasket, wherein the conical deflector is made with the possibility of moving along the guide rod depending on the selected flow rate, wherein the guide rod is rigidly fastened to the body partition, and the curved grooves are made not reaching the edge of the surface of the body deflector by an amount equal to the width of the ring of the outlet opening (Patent RU No. 2257051, A01G 25/02, B05B 1/26 from 05/27/2005).

The disadvantages of the described turbine-type sprinkler include a small range of raindrop size variation, unsatisfactory rain quality, and low operational reliability.

A sprinkler head (taken as a prototype) is known, supporting a housing mounted by means of a nipple of a water supply pipeline, fixed on a stand, a deflector and a nozzle with a central hole, wherein the deflector is made in the form of a concave bowl facing the nozzle with a bulge in its middle part and a threaded hole aligned with the axis of symmetry, divided by stiffening ribs into compartments and an undercut with a curved surface of the bowl between its peripheral annular edge and the bulge, each of the compartments along the height of the deflector has a variable cross-section, while the deflector is provided with the possibility of stepless movement and is coaxially connected by means of a stand (Patent RU No. 2173584, B05B 1/18, 1/26 dated 09.20.2021).

The prototype's drawbacks include its complex design, low operational reliability, and the inability to achieve fine-mist irrigation (spraying). Furthermore, the concave surface of the underside of the bowl is formed by the rotation of a catenary branch, described by a complex calculation equation. The body of the catenary is secured to the threaded portion of the nipple by a shaped nut, and the deflector on the threaded portion of the post is locked with a wing screw.

The essence of the claimed invention is as follows.

The problem, which is aimed at solving the claimed, is the creation of a universal fine-dispersed sprinkler-sprayer, providing a fine-dispersed water-air mist with irrigation water and preventing the destruction of the soil structure, as well as eliminating the influence of differences in the pipeline of the sprinkler machine on the operation of the sprinkler-sprayer and ensuring the effective irrigation of agricultural crops, in addition, with the purpose of differentiating sprinklers by water consumption, where the main replaceable nozzle can be made with a diameter of 3 to 14 mm with regulation of the parameters of its opening.

The proposed fine-mist sprinkler/sprayer features a simple design, secured to the liquid supply pipeline body along a vertical axis. The sprayer consists of a series of coaxial conical constriction sections with an additional cylindrical nozzle and a conical expansion section of the mixing chamber with a located divider. The air supply channel communicates with the conical expansion section through openings located opposite the truncated cone surface of the divider and serves to enhance the formation of a stream of water toward the water outlet of a replaceable nozzle, above which a deflector is located at the desired height. Furthermore, the operating principle is based on varying the spray pattern's flight length during spraying, regulating the spray pattern's opening parameters, which entrains air, breaks the water stream into fine droplets, and disperses it with air.

The technical result is fine-dispersed sprinkling and increased crop yields when growing plants during the irrigation process, increased operational reliability of the fine-dispersed sprinkler-sprayer, water taken from open canals with sediments and a high content of mineral impurities, and improved operating conditions.

The said technical result is achieved in that in the known fine-dispersed sprinkler-sprayer, including a deflector mounted on a water supply pipeline, secured to a stand and a nozzle with a central opening, according to the invention, the body of the nozzle with a central opening is connected along the height with the jet outlet channels and has a continuation along the height, and is made in the form of a nozzle of variable cross-section, including successively coaxial sections of a conical narrowing, a cylindrical section in the form of a nozzle and a section of a conical expansion in which a divider with a mixing chamber is located, wherein the mixing chamber is partially built into a nozzle with a replaceable nozzle, in addition, the divider is made in the form of a truncated cone, facing with its smaller base to the cylindrical section of the nozzle, and with its larger base to the central opening of the replaceable nozzle in the nozzle, wherein the air supply channel communicates with the section of the conical expansion by means of openings located opposite the lateral surface of the truncated cone of the divider, and the replaceable nozzle in the nozzle serves to form a stream of flow on At the outlet, the conical deflector is located above the replaceable nozzle of the nozzle, the base of the deflector is made on a vertical stand in the form of a bracket, which is attached with its lower end on the outside to the side wall of the nozzle body, while the angle of the conical deflector torch is made 120° in the direction of the vertical axis of the water outlet of the replaceable nozzle of the nozzle.

In addition, the body of the nozzle with a replaceable nozzle with a water outlet has a flange in the form of a flat ring and is connected by a flat ring at the upper end of the vertical branch pipe, which covers along the perimeter the coaxial sections of the conical narrowing, the nozzle and part of the mixing chamber with a divider, by means of bolted connections rigidly with the help of fixing nuts from the upper and lower sides, while the lower end of the vertical branch pipe has a fixed nut screwed onto the pressure pipeline, which is a continuation of the beginning of the conical section of the nozzle.

In addition, the distance L from the beginning of the conical expansion section to the smaller base of the divider cone is from d to 2d, where d is the diameter of the cylindrical section of the nozzle, and the angle α at the apex of the truncated cone of the divider is in the range of 50° to 70°.

In addition, the side wall of the truncated cone of the divider is parallel to the side surface of the conical expansion section of the mixing chamber.

In addition, a replaceable pressure regulator is additionally installed in the upper part of the housing pipeline in front of the screwed nut.

In addition, the replaceable nozzle attachment is made with an outlet diameter from 3 to 14 mm, but not more than 0.7 of the diameter of the deflector base.

In addition, the replaceable nozzle is made of plastic or high-density polyethylene.

In addition, the conical deflector and its holder in the form of a stand with a thickening at the lower end are made of aluminum and its alloys.

In addition, the nozzle body and divider are made of galvanized steel.

The novelty of the claimed technical solution also derives from its use of an additional nozzle in the mixing chamber, a dual-effect design based on the "De Laval nozzle" principle. The first acceleration of the flow occurs when the narrowed end of the air supply channel in the expansion section meets the divider via openings located opposite the lateral surface of the divider's truncated cone with the mixing chamber. A second, additional acceleration is achieved at the junction of the mixing chamber's water outlet opening of the replaceable nozzle (the nozzle assembly) toward the sharp end of the control deflector above the replaceable nozzle. Both nozzles are positioned sequentially along the vertical axis of the vertical pipeline. The ejection effect consists of a high-pressure, high-velocity water flow entraining atmospheric air into the chamber, which contains an annular gap created by the placement of the divider's cone, with its smaller base facing the additional cylindrical nozzle and its larger base facing the central water outlet opening of the replaceable nozzle in the nozzle assembly. Atmospheric air enters the liquid spray cone as air exits upward through the mixing chamber, supplied from the atmosphere by a control ball valve. This arrangement creates hydraulic water-air jets at the mixing chamber outlet. Due to the presence of air microbubbles, these jets flow more intensely upward into the water outlet of the replaceable nozzle (the replaceable nozzle can be designed in several different ways – not shown). This reduces water pressure from the discharge pipeline toward the conical deflector, whose spray angle is 120° toward the axis of the water outlet of the replaceable nozzle. In addition, this promotes the active fragmentation of droplets upwards, as a result of which the streams descending from the surface of the round deflector are further broken up into smaller raindrops, which do not lead to crop damage, significant washout and water erosion, and also contribute to the uniform distribution of rain by cone-type irrigation deflectors, since a more saturated spray torch of liquid is created over the irrigation area at any flow rate.

The quality of artificial rain is also determined by the placement of a truncated cone-shaped divider in the mixing chamber. The divider is a truncated cone with parameters L ranging from d to 2d from the beginning of the conical expansion to the smaller base of the divider cone. Where d is the diameter of the cylindrical section, designed as an additional nozzle, and the angle α of the divider ranges from 50 to 70°, with the divider wall parallel to the side surface of the expanding section of the conical expansion. It should be noted that the distance L is calculated based on the formation of jets downstream of the divider in the mixing chamber and the minimal loss of kinetic energy required for initial fragmentation upon impact with the smaller base of the conical divider.

The body of the nozzle with a replaceable nozzle in its lower part has a flange on the outside in the form of a flat ring along the perimeter of the circle and is connected accordingly to the flange in the form of a flat ring on the outside of the vertically installed branch pipe by means of bolted connections rigidly with the help of locking nuts on the upper and lower sides, while the lower end of the vertical branch pipe has a locking nut screwed onto the pressure pipeline, while the vertical branch pipe along its length covers the coaxial sections of the conical narrowing, the additional nozzle and part of the mixing chamber with a divider.

The deflector cone's spray angle is 120° in the direction of the vertical axis of the main replaceable nozzle's water outlet. The deflector cone's upper base is rigidly connected to a stand (leg) with a thickened lower end. The stand is made of aluminum and its alloys and secured with a pin lock in a screw groove. This allows for varying the deflector body's height above the main replaceable nozzle, thereby changing its vertical position and, consequently, the fine spray droplet size.

Irrigation can be carried out with small rates and low intensity with a minimum soaking depth to avoid the leaching of nutrients and loss of humus, as this leads to a decrease in soil fertility.

The fine-mist sprinkler/sprayer is additionally equipped with a pressure regulator, which is connected to the discharge line of the housing. The pressure regulator ensures a uniform water flow through the internal cavity, which includes a sequence of coaxial constriction sections, an additional nozzle section, and a conical expansion section connected to a displacement chamber housing a truncated cone divider. The required irrigation intensity is linked to the capture of a constant atmospheric air pressure for a given flow rate. The installation of a flow regulator also eliminates the impact of water pressure fluctuations in the sprinkler's pipeline on the overall operation of the universal device.

The quality of artificial rain is determined by its intensity, the size of the drops, the layer of precipitation per cycle and the uniformity of distribution over the irrigation area based on the creation of an improved fine-dispersed sprinkler-sprayer.

The applicant's proposed analysis of the state of the art, including a search of patent and scientific and technical sources of information and the identification of sources containing information on analogues of the claimed invention, made it possible to establish that the applicant has not found an analogue characterized by features identical to all the essential features of the claimed invention.

Consequently, the claimed invention meets the criteria identical to all essential features of the claimed invention.

From the manufacturing technology point of view, the authors' proposal for a fine-dispersed sprinkler-sprayer is more rational: it uses fine-dispersed sprinkling with high-quality watering, allowing the use of non-fertilizing feeding of crops with a fine-dispersed fertilizer solution and pesticides to destroy pathogenic microbes and pests, which increases crop yields.

The mixing chamber, with its truncated cone-shaped divider, utilizes a dual effect, initially based on the "De Laval nozzle" principle, as noted above, and also entraining atmospheric air. At the outlet of the mixing chamber (the detachable, two-part design remains unknown), and then from the water outlet of the removable nozzle in the nozzle assembly, the water and air flow velocities are equalized, forming a spray by placing a conical deflector at a specific angle above it. This spray is a finely dispersed water-air flow that is atomized at high speed.

Example 1. Theoretical justification of the proposal

The design of the proposed fine-mist sprinkler-sprayer meets agricultural requirements. It is known that the equation for the trajectory of a water jet flowing from a nozzle in the absence of air resistance is described by the relationship:

X=x⋅tgθ - x ² /4H⋅cos ² θ, where x is the coordinates of the jet trajectory, m; H is the pressure at the outlet in the nozzle, m; θ is the jet departure angle, deg.

In reality, jets of water emitted from the nozzle almost immediately disintegrate into water-air raindrops, which must overcome the resistance of the surrounding environment. This action reduces the radius of the raindrop's flight (R _k ) according to the law:

R _k =λS⋅ρV _o ² /2, where λ is the drag coefficient for the jet moving in air; S is the cross-sectional area of the droplet, perpendicular to the direction of its movement, m ² ; ρ is the air density, kg/m ³ ; V _o is the droplet velocity, m/s.

Then, taking into account the impact of the environment on the raindrop, the sprinkler's irrigation radius will be equal to:

R=2(H-λS⋅ρV _o ² /2)sin2θ ₀ .

Since all the design parameters of a fine-dispersed sprinkler-sprayer are interconnected, they must be considered as a whole.

The raindrop's throw is affected by the cone angle of the deflector and the design of its upper base, positioned above the water outlet of the replaceable nozzle in the nozzle. Using a deflector with a predetermined cone angle and nozzle ensures wind resistance and a highly uniform distribution of artificial rain, without compromising the quality of the spray.

The diameter of the outlet replaceable nozzle (hole) of the attachment, which has a round shape, will be determined by the formula:

where Q is the water flow rate through the nozzle, ^m3 /s; μ is the flow coefficient, depending on the shape of the incoming edges of the hole (taken as μ=0.8); g is the acceleration due to gravity, m/s; H is the pressure in front of the nozzle, m.

Rain intensity is one of the main indicators characterizing the operation of a sprinkler machine.

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

ρ=60Q/πR ² ⋅10 ³ , mm/min, where Q is the water flow rate of the sprinkler machine, m ³ /s; R is the irrigation radius of the sprinkler nozzle, m.

The formula for determining the irrigation rate to runoff for a nozzle with a droplet diameter of 0.3-0.5 mm is as follows:

m -=45.3⋅K' ₁ ⋅K ₂ , m ³ /ha, where K' ₁ =1+0.0147(70-ω) is the coefficient taking into account pre-irrigation soil moisture before sprinkling; ω is the soil moisture from the lower moisture capacity; K ₂ =1-15.11⋅i is the coefficient taking into account the magnitude of the field surface slope; i is the field surface slope; ρ is the rain intensity, mm/min.

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

The time it takes for a drop to accelerate, taking into account the momentum of the drop:

mV _B =F _B ⋅Δt ₂ .

The mass of a droplet is determined by its volume, which is its diameter d and the density of water ρ, then we get: m=πd ³ /6ρ. By rearranging the equation, we also get: F _B =P _B ⋅q⋅V _B =Р _B (πd ² )⋅V/4, where Р _B is the air density equal to 1.29 g/cm ³ ; d is the nozzle diameter; V _B is the wind speed; F _B is the wind density; q is the droplet flow rate.

This means that by applying small quantities and at low intensity with minimal soil wetting depth, it is possible to avoid the leaching of nutrients and loss of humus, as this leads to a decrease in soil fertility.

It is well known that the yield and value of cereals, legumes, and other agricultural crops depend on the amount of available fertilizer and adequate soil moisture. Therefore, sprinkler irrigation can be economically feasible when irrigated fields are well-organized and the mineral nutrition level is sufficient for irrigation by machines (units), i.e., when water is drawn from a ready-made water source. It also allows for the application of readily soluble mineral fertilizers for vegetation feeding, which is crucial for increasing crop yields, as well as the ability to apply pesticides to control pests, weeds, and plant diseases.

The main parts can be made of a polymeric material, as well as other materials noted in the invention materials.

It's also worth noting that fine mist sprinklers deposit water mist on the leaves, stems, and topsoil of plants. This moisture reduces stress on plants. The ambient and plant temperatures decrease. Each plant adapts to the changing temperature.

Example 2. Research shows that increasing the distance L above 2d and correspondingly decreasing the angle α to less than 50° degrades the effectiveness of the initial impact of the jet fragmentation in the mixing chamber against the end impact surface of the splitter due to a significant decrease in the kinetic energy of the jet with increasing distance from the discharge point to the impact surface. Furthermore, the median equivalent diameter of the droplets toward the mixing chamber may increase, and the size of the droplets increases before discharge through the orifice of the replaceable nozzle in the nozzle. Therefore, the angle α at the apex of the splitter's truncated cone preferably lies in the range from 50° to 70°.

This confirms that the stated range of geometric characteristics of the internal design of the proposed fine-mist sprinkler-sprayer allows for the practical achievement of fine raindroplet particle sizes with a conical deflector above the replaceable nozzle, ultimately achieving a positive operating effect. Furthermore, it is necessary to take into account the distinctive split-type design of the mixing chamber and its fastening elements, and, as noted above, the use of a dual-effect Laval nozzle.

The invention is illustrated by drawings: Fig. 1 shows a longitudinal section of a fine-dispersed sprinkler-sprayer installed on a pressure pipeline; Fig. 2 shows a fine-dispersed sprinkler-sprayer equipped with a pressure regulator.

The information confirming the feasibility of implementing the claimed technical solution is as follows.

The fine-dispersed sprinkler-sprayer includes a pressure pipeline 1, successively including a coaxial section 2 of a conical narrowing, and section 3 of the conical expansion of the unit has a continuation with an additional cylindrical nozzle of section 4. The conical expansion of section 3 has a detachable mixing chamber 5, in which a divider 6 is located. The water supply channel of the pressure pipeline 1 is coaxially connected to section 2 of the conical narrowing, section 3 of the conical expansion of the unit is coaxially connected to the mixing chamber 5. Divider 6 is made in the form of a truncated cone, facing with its smaller base to the cylindrical section in the form of an additional nozzle 4, and is provided with a through channel 7 on the side of the large base. In this case, the diameter of the smaller base of the conical divider practically corresponds to the diameter of the opening of the additional nozzle 4. When the conical stream of liquid hits the impact end surface. The jet is partially fragmented and partially flows around the conical side surface of the divider, forming a layer of liquid, and moves along the impact side surface at a speed close to the speed of the jet upon impact with the impact end surface of the divider.

The distance L from the beginning of section 3 (or the end of the additional nozzle 4) of the conical expansion to the smaller base of the cone of the divider 6 is preferably from d to 2d, where d is the diameter of the cylindrical section 4 in the form of an additional nozzle. The angle α at the apex of the truncated cone of the divider 6 lies in the range from 50° to 70°. The distance L is calculated based on the conditions of jet formation and the minimum loss of its kinetic energy, the description of which is noted above in example 2. The air supply channel 8 communicates with section 3 of the conical expansion of the unit through openings 9 located opposite the lateral surface of the truncated cone of the divider 6. The lateral surface of the truncated cone of the divider 6 is preferably parallel to the lateral surface of section 3 of the conical expansion, and can be represented as using a double effect, initially according to the "Laval nozzle" principle. The first acceleration occurs at the junction of the narrowed end of the cylindrical opening of the additional nozzle 4 for feeding liquid towards the mixing chamber 5, and the third additional acceleration occurs through the water outlet opening of the main replaceable nozzle 10 of the nozzle 11, connected to the mixing chamber 5 and towards the location of the sharp end of the deflector 12.

The openings 9 in the side walls of the expansion section are circular and uniformly spaced around the circumference of the side surface of the conical expansion section 3 of the mixing chamber 5, and their axes are directed perpendicular to the surface of the cone of the divider 6 in the middle. This perpendicularity is necessary for the maximum effect of the impact crushing of the incoming atmospheric air from the channel 8, limited by the vertical branch pipe 13, the cavity of which is connected by an inlet opening 14 in the side wall of the housing of the vertical branch pipe 13 and communicates via an air-conducting branch pipe 15 with a control valve 16 communicating with the atmosphere. In this case, the upper end (end) of the vertical branch pipe 13 is provided on the outside with a rigidly welded seam with a flat ring 17, which is connected to the flat ring 18 rigidly outside the body of the nozzle 11, and in its lower part along the perimeter of the circumference of the side walls by means of bolted connections 19 with the help of fixing nuts from the upper and lower sides, and the lower end of the vertical branch pipe 13 has a fixing nut 20, screwed onto the body of the pressure pipeline 1. In addition, the nozzle 11 has an internal thread with the possibility of installing a replaceable nozzle 10 of different flow cross-sections with its external thread and are connected in contact with each other, above which a deflector 12 is placed, having a working surface in the form of a circle with a conical top directed downwards. The base of the deflector 12 is secured to the vertical support 21 (leg) in the form of a bracket, the lower end of which, with its thickened end, is attached by pin 22 with lock 23 to a screw groove 24 on the outer side in the side wall of the housing of the nozzle 11, which is suitable for changing the height of the adjustment position of the conical deflector 12 above the replaceable nozzle 10 of the nozzle 11 using holes (not shown) on the side of the thickened surface of the support 21 (leg). In this way, it is possible to change the fine spray size of the liquid for plants.

In the upper part of the pressure pipeline 1 of the housing, a replaceable pressure regulator 25 can be additionally installed (Fig. 2).

Additionally, the replaceable nozzle 10 can be made of plastic or high-strength polyethylene. The replaceable nozzle 10 can have an opening diameter of 3 to 14 mm, but no greater than 0.7 times the diameter of the deflector base 12.

In addition, the stand 21 (leg) in the form of a bracket and the deflector 12 with a base on top are made as a single part with a thickening of the lower end, and can be made of aluminum or its alloys.

In addition, the nozzle body and divider can be made of galvanized steel.

The rigid frame of the stand 21 with the deflector body 12 protects the attachment 11 with the replaceable nozzle 10 from external influences and mechanical damage, and also ensures convenient installation, assembly/disassembly and replacement of parts.

A replaceable pressure regulator 25 can be installed on pressure pipe 1, upstream of locking nut 20, which is screwed onto the pressure pipe. The pressure regulator maintains a uniform water flow rate for the fine-mist sprinkler/sprayer. Its use eliminates the influence of pressure fluctuations in the sprinkler's pipeline on the flow rate and quality of the artificial rainfall. It also maximizes the kinetic energy of high-speed spray jets, thereby increasing its flow rate and supplying air to the mixing chamber. This is due to pressure fluctuations in the sprinkler's irrigation pipeline during operation, which can occur for various reasons. One such cause is elevation changes along the route of the sprinkler. Pressure regulator 25 is selected based on the flow rate characteristics of the sprinkler/sprayer. Moreover, the production of a replaceable nozzle 10 or attachment 11 with an outlet diameter from 3 to 14 mm makes it possible to differentiate sprinklers and sprayers by water consumption.

It should be noted that the base of the deflector housing 12 is provided along the perimeter with a protruding flat ring in the form of a flange, the working reflective surface of which is located perpendicular to the axis of the conical deflector 12. The width of the ring is equal to (1.8-1.12)d, where d is the protruding diameter of the flat ring, equal to the diameter of the cone of the deflector 12.

A flat ring (not shown) of the base of the deflector housing 12 in the upper part can be secured with bolted connections to support the deflector together with it, the deflector, which is coaxially facing the opening of the replaceable nozzle 10.

In order to minimize the impact on the water film, the cross-section of the post 21 (leg), which provides rigidity for fastening the conical deflector 12, the lower end with a thickening is connected to the thread of the body of the nozzle 11, represents the minimization of the thickness of the post 21 and the impact on the formation of raindrops and the flight radius necessary so that its thickness could only hold the conical body of the deflector 12 as a whole above the nozzle 11, has minimal friction losses, and good streamlining, accordingly, when moving the post up or down, and therefore, changing the gap between the sharp end of the conical deflector 12 and the end of the replaceable nozzle 10 of the opening of the nozzle 11. All this as a whole ensures a given position in height above the soil surface.

Rainfall intensity is one of the main indicators characterizing a fine-dispersed sprinkler-sprayer.

The methodology for determining the performance indicators of sprinklers is based on the requirements of RD 70.11.1-89 "Irrigation machines and installations. Test program and methodology" (VTR-0-81).

The angle α is selected for the divider 6 of a truncated cone, here one should proceed from the angle of expansion of the liquid stream flowing out of the cylindrical section in the form of an additional nozzle 4 of the spray unit and the limiting lateral surface of the section 3 of the conical expansion of the unit, in such a way as to ensure a continuous flow of liquid around the lateral surface of the truncated cone of the divider 6. At smaller values of the angle between the surface of the divider 6 and the liquid layer at the intersection with the jets of the atomizing medium (air) coming from the openings 14 communicating with the channel 8 with the air-conducting branch pipe 15 with the regulating valve 16 with the atmosphere, an unfilled space of the mixing chamber 5 can be formed, which will negatively affect the continuity of the liquid pressure and the efficiency of its flow towards the replaceable nozzle 10 of the attachment 11, i.e. it is necessary to maintain a liquid layer continuously adjacent to the solid surface during flow.

The design of the fine-mist sprinkler/sprayer, consisting of all removable fastening components (nozzles, deflector, vertical pipe mounting unit, variable-section nozzles, and sequentially connected sections), ensures extremely simple assembly/disassembly and high technological efficiency, increasing operational reliability. Thus, the device is compact when assembled.

The fine mist sprinkler works as follows.

The sprinkler-sprayer is mounted on the pressure pipeline of the irrigation machine according to the proposed flow chart. The pressure pipeline body 1 is secured to the locking nut 20 using a coupling. Irrigation water under operating pressure is first delivered through pipeline 1 to the primary spray unit, which includes a coaxial section 2 of the conical constriction. From the cavity of section 2, the water flow then enters cylindrical section 4 in the form of an additional nozzle. Upon exiting, it collides with the smaller base of the truncated cone of divider 6 facing this section, partially breaking up into droplets, and flowing around its lateral surface. From additional nozzle 4, the liquid enters section 3 of the conical expansion of this spray unit. In this case, through the openings 9, located opposite the side surface of the truncated cone of the divider 6, air enters from the channel 8, limited by the vertical branch pipe 13, the cavity of which is communicated by the inlet opening 14 in the side wall of the housing of the branch pipe 13 communicating with the channel of the air-conducting branch pipe 15 with the control valve 16 communicating with the atmosphere, which allows the incoming air from the openings 9 to be directed perpendicular to the side surface of the cone of the divider 6 and when the air collides with it, under the action of the turbulence of the water jet, the air flow is captured, flows around the divider 6, forming a water-air mixture. The resulting mixture passes through channels 7 at the larger base of the truncated cone of divider 6 into mixing chamber 5, equipped with a nozzle 11 with a replaceable nozzle 10. This flow, with a certain water velocity where the effective cross-section of the flow decreases and its velocity increases, enters under pressure onto the reflective surface of deflector 12. The water-air mixture, in this layer, at this velocity and in a thin film no more than 0.1...0.5 mm thick, is ejected into the atmosphere at a distance of 2 to 6 m. It moves into the surface air layer, fragments, and settles downward, providing the specified flow rate and the required quality, forming a fog cloud. This cloud moistens the surface layer and reduces the temperature. This creates a microclimate in the irrigated area. The outgoing high-speed water-air flow, leaving replaceable nozzle 10, nozzle 11, is sprayed into small droplets by deflector 12 and ejected into the atmosphere.

With the help of two sprayers made in the form of an additional nozzle 4 and a replaceable nozzle 10, a mixing chamber 5, in which a divider 6 of a truncated cone with optimal dimensions is located, in front of the static deflector 12 it is possible to distribute significant flow rates within the standard intensity limits, ensuring a soft irrigation regime.

It should be noted that the novelty of the proposed fine-mist sprinkler-sprayer and its components, along with the stated range of geometric characteristics of the internal component of the proposed sprinkler-sprayer, allows for droplet sizes of 1–2 mm to be achieved in practice. These droplets settle on the foliage of plants and the irrigation area.

Thus, the replaceable nozzle produces a spray pattern that enters the deflector plane with a finely dispersed water-air flow, which is then delivered to the irrigated area at high spray velocity. Using a replaceable nozzle in a straight-channel (hole) attachment allows for a smaller spray pattern angle toward the sharp end of the deflector.

The use of a mixing chamber and interchangeable nozzles of varying shapes allows for variable spray pattern lengths in front of the deflector during spraying, as well as adjustable spray pattern opening parameters, ensuring the stated technical result. Furthermore, it significantly expands the application capabilities of this fine-mist sprinkler.

It should be noted that the ejected air partially serves as an additional medium for spraying, and partially aerates the liquid, forming foam in the presence of minor amounts of foaming.

All design parameters of a fine-dispersed sprinkler-sprayer are interconnected, and therefore they must be considered as a whole.

The theoretical part of the definition of the operation of a sprinkler-sprayer is described in detail above.

Crop yields can increase by up to 18%, thanks to a more uniform irrigation water supply, reduced water loss due to evaporation and runoff, smaller droplet sizes, and reduced rainfall intensity. Rainfall parameters can also be adjusted by adjusting the deflector's position relative to the outlet of the replaceable nozzle using a stand.

The simple design of a fine-mist sprinkler-sprayer makes it versatile in terms of intensive mixing of liquid and air. Furthermore, all other things being equal, it allows for smaller droplets and reduces the energy they exert on plants and soil, thereby increasing the yield and quality of agricultural produce through sprinkler irrigation, which in turn promotes biological processes in plants.

The invention proposed for patenting meets the criterion of “novelty” since the entire set of features of the formula is not known from the prior art cited in the relevant section of the description.

It meets the criterion of “inventive step” since it does not clearly follow from the state of the art for a specialist.

The original design of the fine-dispersed sprinkler-sprayer and the relative positioning of all the device components ensure durability and high reliability.

Thus, thanks to the two nozzles and the housings of the units as a whole, the water flow from the replaceable nozzle in the head is then broken into tiny particles and deposited on the surface of the irrigated area. This ensures high-quality irrigation of agricultural plants, reduces dynamic loads on them, and prevents soil erosion.

Claims (9)

1. A fine-dispersed sprinkler-sprayer, including a deflector mounted on a water supply pipeline, secured to a stand and a nozzle with a central opening, characterized in that the nozzle body with the central opening is connected along the height with the jet outlet channels and has a continuation along the height, and is made in the form of a nozzle of variable cross-section, including successively coaxial sections of a conical narrowing, a cylindrical section in the form of a nozzle and a section of conical expansion, in which a divider with a mixing chamber is located, wherein the mixing chamber is partially built into the nozzle and connected to a replaceable nozzle, in addition, the divider is made in the form of a truncated cone, facing with its smaller base to the cylindrical section of the nozzle, and with its larger base to the central opening of the replaceable nozzle in the nozzle, wherein the air supply channel communicates with the section of conical expansion by means of openings located opposite the lateral surface of the truncated cone of the divider, and the replaceable nozzle in the nozzle serves to form a stream of flow at the outlet, The conical deflector is located above the replaceable nozzle of the nozzle, the base of the deflector is fixed on a vertical stand in the form of a bracket, the lower end of which is attached on the outside to the side wall of the nozzle body, while the angle of the conical deflector torch is 120° in the direction of the vertical axis of the water outlet of the replaceable nozzle. 2. A sprinkler-sprayer according to claim 1, characterized in that the body of the nozzle with a replaceable nozzle with a water outlet has a flange in the form of a flat ring and is connected to the flat ring at the upper end of the vertical branch pipe, which covers along the perimeter the coaxial sections of the conical narrowing, the nozzle and part of the mixing chamber with a divider, by means of bolted connections rigidly with the help of fixing nuts from the upper and lower sides, wherein the lower end of the vertical branch pipe has a fixed nut screwed onto a pressure pipeline, which is a continuation of the beginning of the conical section of the nozzle. 3. A sprinkler-sprayer according to claim 1, characterized in that the distance L from the beginning of the conical expansion section to the smaller base of the divider cone is from d to 2d, where d is the diameter of the cylindrical section, and the angle α at the apex of the divider cone is located in the range of 50° to 70°. 4. A sprinkler-sprayer according to claim 1, characterized in that the side wall of the truncated cone of the divider is parallel to the side surface of the section of the conical expansion of the mixing chamber. 5. A sprinkler-sprayer according to item 2, characterized in that a replaceable pressure regulator is additionally installed in the upper part of the pipeline in front of the screwed nut. 6. A sprinkler-sprayer according to paragraph 1, characterized in that the replaceable nozzle is made with an outlet diameter of 3 to 14 mm, but not more than 0.7 of the diameter of the deflector base. 7. A sprinkler-sprayer according to item 1, characterized in that the replaceable nozzle is made of plastic or high-density polyethylene. 8. A sprinkler-sprayer according to paragraph 2, characterized in that the conical deflector and its holder in the form of a stand with a thickening at the lower end are made of aluminum or its alloys. 9. A sprinkler-sprayer according to item 1, characterized in that the nozzle body and divider are made of galvanized steel.