RU2350074C1 - Compressed air liquid sprinkler - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention deals with design of devices for humidification of air over agricultural plantations and is fit for both small-capacity watering and moistening of crops and outspraying water solutions of fertilisers, pesticides and other chemical preparations. The device consists of a housing containing liquid and air delivery fixtures installed inside it. The housing is designed as double-sectioned. The lower section is equipped with a liquid discharge faucet, a filler port and an injector element. The upper section is equipped with a detachable lid having a nipple for discharge of monodisperse medium, inspection ports arranged in the side walls, a diaphragm and a sprayer. The injector element and the sprayer are pneumatically connected to the air pressure control. The upper and the lower sections are hydraulically interconnected via the upper section liquid level control. The sprayer, hollow inside, has axial apertures and is equipped with a flange. The nozzle housing cavity contains a stepped threaded bushing, an airflow swirler and a nozzle, all oriented in the air delivery direction. On the housing butt-end surface there are radial slots arranged and blade mounted designed for film separation of a thin water layer. The injector element has a housing. The injector housing inner cavity contains a needle that has a de Leval nozzle mounted on its thinned end and a diffuser, both coaxially installed. The diffuser is connected to the intake hose. Via the mixing chamber the diffuser is conjugated with the boss on the upper section rear wall.

EFFECT: device enables improved energy efficiency and yield capacity of water-and-air monodisperse medium production which medium is fit for small-capacity watering and moistening of agricultural crops.

17 cl, 15 dwg, 1 tbl

Description

The invention relates to the field of humidification of air over plantations of agricultural crops and can be used both for low-volume irrigation and humidification of plants, and for spraying fertilizers and pesticides in the form of aqueous solutions.

An aerosol generator is known that includes a rectangular inlet and cone-shaped outlet pipe with a tube for supplying liquid between them, in which, in order to obtain a monodisperse mixture, a vibrating plate is installed behind the tube for supplying liquid, and there is a slot in the tube across the width of the plate for liquid exit; in order to regulate the degree of dispersion of the liquid at the outlet pipe, a regulator of the amplitude of oscillations of the vibrating plate; in order to regulate the amount of air entering the outlet pipe, a slide gate is installed in it (see SU, copyright certificate No. 343670. M. class A01M 7/00. Aerosol generator / A.D. Aleksandrov, B.K. Rassolov, A.A.Shmyglya et al. - Application No. 1653225 / 30-15; claimed on 05/03/1971; publ. 07/07/1972, bull. No. 21).

The disadvantages of the described aerosol generator include the need for an energy-rich and expensive turbojet engine, aviation fuel, a large staff apparatus, in the absence of the possibility of reinstallation from one greenhouse to another, in the long length of the communication network and air ducts with thermal insulation.

Also known is a pneumatic sawing body to the sprayer, including a nozzle with film-forming agents located in it, in which, in order to improve the quality of liquid spraying, the film-forming agents are made with side ribs (SU, copyright certificate No. 561546. M. cl ^2. A01M 7/00. Pneumatic spraying body to the sprayer / V.P. Chaly, M.I. Gubarev, M.I. Shterental and others - Application No. 2172662/15; claimed on 09.15.1975; publ. 15.06.1977, bull. No. 22).

The disadvantages of the described pneumatic spraying working body to the sprayer include an unstable supply of dissolved pesticide from the tube (2) for supplying liquid. At high liquid pressure in the tube (2), the solution splashes onto the inner surface of the nozzle (1), partially touching the film former (3). With a decrease in the solution pressure in the tube (2), the water flow does not reach the surface of the film former (3). This leads to a high degree of uneven dispersion of the liquid.

A device for creating fog is known, comprising a rotor with outlet openings and a spraying means installed in a holder, in which, in order to increase the dispersion of the fog, the spraying means is made in the form of a set of wave-like filaments, and the holder is made in the form of a glass (SU, copyright certificate No. 874006. M. cl ^3. A01M 7/00, B05B 3/08. Device for creating fog / B. S. Ermakov, S. V. Nesterovich - Application No. 2710049 / 30-15; claimed 04.01.1979; publ. . 10.23.1981, bull. No. 39).

The disadvantages of the described device for creating fog, despite the declared droplet size of 25-150 microns with a spray range of up to 7-8 m from the axis of rotation, is that the device for creating fog must move along the longitudinal axis of the greenhouse, warehouse, above the rows with . x crops or along the aisles of tree plantations, shrubs and vineyards.

A pneumatic atomizer is known, comprising a housing with a mixing chamber having an air and liquid fitting, a reflector, a gripping regulator and a liquid flow regulator, in which, in order to improve the quality of work, the atomizer is equipped with a centrifugal chamber with a pressure reducing ball valve and a swirl chamber mounted in series after the mixing chamber with a conical liner located in it and mounted movably in the axial direction, on the periphery of which helical grooves are made, while reflecting the spruce is made conical and is rigidly connected to the liner, which interacts with its top with a pressure reducing valve, the fluid nozzle of the mixing chamber mounted tangentially to it and the air nozzle along the longitudinal axis of the sprayer (SU, copyright certificate No. 1192761. A. M class ^4. A01M 7/00, B05V 3/00. Pneumatic atomizer / BC Smirnov. - Application No. 3747125 / 30-15; claimed 05/30/1984; publ. 11/23/1985, bull. No. 43).

The disadvantages of the described pneumatic atomizer include a low degree of dispersion of the liquid.

An aerosol nozzle is also known, comprising a cylindrical angular housing, an injection pipe and a diffuser nozzle arranged coaxially with it, in which, in order to improve the dispersion quality and increase the range of the directed aerosol, the diffuser nozzle is provided with an annular turbulent ledge and the ratio of the inner diameter of the supply neck air to the inner diameter of the fluid supply tube is 4.4-4.6; an annular turbulizing ledge is formed by the wall thickness of the neck of the air supply, and the ratio of the outer diameter of the neck to the inner is 1.1-1.2 (SU, copyright certificate No. 1197621. AM class ^4. A01M 7/00, B05B 7/30. Aerosol nozzle / V.D. Kuznetsov, A.M. Sergienko - Application No. 3719614 / 30-15; claimed on 02.01.1984; publ. 15.12.1985, bull. No. 46).

The disadvantages of the described aerosol nozzle include poor spray quality of irrigation water.

Known working body of the sprayer, comprising a housing, a drive, a rotating disk atomizer installed in the housing by means of a hollow axis, provided at the end with metering holes with a deflector to the shut-off valve and enclosed in the support and sealing units, in which, with the aim of increasing durability and reliability, the spray equipped with a conical reflector mounted on the hollow axis and a helical run-out of cold-flowing material with a low coefficient of friction, and the run-off is set with a gap relative to the sealing evil, and the reflector is located between the sleeves and the deflector, wherein the body is provided with drainage holes located between the sleeves and the reference node; the conical reflector is directed towards the disk nozzles, and a drainage ring is installed in the gap between the drive and the support assembly, provided with annular grooves on the outer and inner surfaces connected by radial openings, the drainage holes in the housing being aligned with the annular grooves, and the discharge and the drainage ring are made of fluoroplastic (SU, copyright certificate No. 1515424. A1M. class A01M 7/00. Working body of the sprayer / V.A. Pluzhnikov, V.V. Rychik, V.E. Zadorozhny and others - Application No. 4054983 / 30-15 ; claimed 04/11/1986; publ. 1989, Bulletin No. 38).

The disadvantages of the described working body of the sprayer include the complexity of the design and low quality of the spray liquid.

A device for spraying liquid with compressed air is also known, including a housing inside which means for supplying liquid and radial guide plates are installed, in which, in order to increase the range of liquid ejection, the guide plates are streamlined, hollow, perforated and connected to the means for supplying liquid (see SU, copyright certificate No. 377130. M. class A01G 25/00, A01M 7/00, B05B 1/14. Device for spraying liquid with compressed air / B. B. Babinsky, Yu. I. Gusev, V. G. Zilbert et al. - Application No. 167 4154 / 30-15; claimed 06/28/1971; publ. March 17, 1973, bull. No. 18).

The disadvantages of the described device for spraying liquid with compressed air include excessive design complexity, high energy intensity of the process, a high degree of uneven dispersion of the liquid.

The essence of the claimed invention is as follows.

The problem to which the claimed invention is directed is to improve the quality of a monodisperse medium from air and water, acceptable for low-volume irrigation and moistening of plants with both macro- and microelements, and pesticides.

The technical result is a reduction in energy consumption and increased productivity.

The specified technical result is achieved by the fact that in the known device for spraying liquid with compressed air, comprising a housing, inside of which there are installed means for supplying liquid and air, according to the invention, having handles for transferring the housing is made two-section: the lower section, located on the base, is equipped with a valve for discharge of liquid, filler neck and an ejector pneumatically connected to the air pressure regulator, the upper section, placed by means of the adapter plate on the lower section, sleep wife with a detachable lid with a nozzle for discharging monodispersed medium, viewing windows on the side walls, a partition, a nozzle mounted on the adapter plate with a stepped sleeve with a flange and a bonk on the rear wall for supplying liquid, while the upper section with the lower section is hydraulically connected by a level control fluid in the upper section, pneumatically connected to an air pressure regulator, said nozzle has a complete housing with axial holes and a flange fixed by means of a In the stepped adapter sleeve of the adapter plate, in the cavity of the housing with the possibility of dismantling in the direction of air supply, there is a stepped adapter screw thread connected by a fitting with an air pressure regulator, an air flow swirl and a nozzle, the outlet of which is connected to the hole in the nozzle body, and on the end part the casing is made of radial slots and blades for separating a thin layer of water into a film; means for regulating the liquid level in the upper section is made in the form of a U-shaped flexible transparent pipe, one end of which is inserted by means of a screw plug into a bonkot on the adapter plate and fixed with a collet grip, the other end of the flexible transparent pipe is connected with a square on the side wall of the lower section, while the lower section of the U-shaped part of the flexible transparent pipe is placed 40 ... 80 mm below the bottom of the lower section; the nozzle air flow swirl is made in the form of a disk with slots on the peripheral part, with each slit 2.5 ... 3.5 mm wide inclined to the disk plane at an angle of 18-23 °; the nozzle nozzle is made in the form of a washer with a thickness of 25-35 mm and a cavity with a conical surface, the generatrix of which is inclined to the axis of the washer at an angle of 55-65 °, while the nozzle cavity is connected with an outlet with a diameter of 1 ± 0.2 mm with an opening in the nozzle body the nozzle body flange facing the step sleeve flange on the adapter plate between the upper and lower sections of the body, an annular groove for gasket installation is made; radial slots on the end of the nozzle body are made in the width of 3.5 ... 5.5 mm; blades for separating a thin layer of water into a film at the end of the casing are formed by the intersection of radial slots and a conical surface formed by the rotation of the generatrix, inclined to the axis of symmetry of the casing at an angle of 55 ... 65 °, and the outlet of the casing is made with a diameter of 8 ... 12 mm; the junction of the detachable cover on the upper cut of the upper section is made with a frame having a groove around the perimeter to accommodate the sealing tape; the transfer handles installed in the center of the body mass are made in the form of a hollow rod, which is interfaced with the rear wall of the upper section and the adapter plate between the upper and lower sections; the filler neck of the lower section is placed on the adapter plate; the ejector placed on the adapter plate with a sleeve with a flange has a housing in the cavity of which a needle with a Laval nozzle is installed coaxially at the end and a diffuser mated with a threaded section with an intake sleeve mounted in the axial bore of the housing, while the housing cavity is connected via a fitting with a sleeve with a pressure regulator air, and the diffuser through the mixing chamber is paired with a bonk on the rear wall of the upper section; the ejector housing with a flange of the adapter plate bushing is connected by a landing belt, a sealing ring and fixed to the flange by means of a disk and fastening means; in the tide of the ejector body, a threaded hole with a plug installed to control the operation of the ejector is aligned with the axial holes of the needle and diffuser; a needle located in the cavity of the diffuser with a Laval nozzle is provided with an axial channel and radial ducts on the end part for air supply; the mixing chamber, the diffuser and the needle with the Laval nozzle are fixed on the ejector body by means of a step sleeve and fastening means; the partition in the upper section is installed with a gap above the adapter plate orthogonal to the axis of symmetry of the mixing chamber; the lower section of the body is equipped with a level gauge.

The invention is illustrated by drawings.

Figure 1 presents a General side view of a device for spraying liquid with compressed air.

Figure 2 is the same plan view.

Figure 3 is the same front view.

Figure 4 is a section aa in figure 2, the pairing of the removable cover with the frame on the upper cut of the upper section.

In Fig.5 is a section bB in Fig.2, the placement of the threaded cap on the filler neck of the lower section.

In Fig.6 is a section bb In Fig.2, means for regulating the liquid level in the upper section.

In Fig.7 is a section GG in Fig.2, a longitudinal section of an ejector for supplying fluid from the lower section to the upper section.

On Fig - place D in figure 3, the pairing of the nozzle with the adapter plate on the bottom of the upper section (a union nut with a flexible sleeve and a fitting with a flexible sleeve for pneumatic communication with the air pressure regulator and ejector conditionally removed).

In Fig.9 is a cross-section EE in Fig.8, a diametrical section of the nozzle.

Figure 10 shows a diametrical section of the nozzle body.

In Fig.11 - place W in Fig.10, the position of the radial slots and blades on the end of the nozzle body.

On Fig shows a diametrical section of the nozzle of the nozzle.

In Fig.13 - place 3 in Fig.12, the outlet from the cavity of the nozzle of the nozzle.

On Fig presents a swirl of air flow, a view in plan.

On Fig is the same front view.

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

A device for spraying liquid with compressed air (see FIGS. 1-15) includes a housing, inside of which there are installed means for supplying liquid and air.

The case is made two-section. The lower section 1 is located on the base 2. The base 2 is represented by two unequal corners. The lower section 1 is presented in the form of a welded container of a rectangular configuration with vertical side, front and rear walls and the bottom. The bottom of the lower section 1 is welded to high shelves of the corners of the base 2.

The lower section 1 is equipped with a filler neck 3 with a threaded plug 4 (see FIGS. 2 and 5), a valve 5 for draining the liquid, pneumatically connected to the air pressure regulator 6 by an ejector 7

In the bottom of the lower section 1 (see Fig. 7), a threaded rod 8 is welded in, in which a valve 5 is located for draining the liquid. On the rear wall of the lower section 1 of the housing mounted level gauge 9 to determine the volume of fluid (see figure 1 and 2).

The upper section 10 is placed by means of the adapter plate 11 on the lower section 1. The upper section 10 is equipped with a removable cover 12 with a nozzle 13 for discharging a monodispersed medium, viewing windows 14 and 15 on the side walls, a partition 16 in the cavity of the upper section 10, an nozzle 17 mounted on the adapter plate 11 by means of a stepped sleeve 18 with a flange 19 and a bonk 20 on the rear wall of the section 10 for supplying fluid.

The upper section 10 of a rectangular configuration has front, side and rear vertical walls. The walls are connected by welds mutually and with the adapter plate 11. On the upper cut of the upper section 10 is made of a power frame from the corner 21 and strip 22 (see figure 4). Between the vertical shelf of the corner 21 and the strip 22, a groove is formed to accommodate the sealing tape 23. The removable cover 12 with the power frame of the upper section is fixed by means of fastening 24.

The housing of the device has handles 25 for transfer (see figures 1, 2, 3, 6 and 7). Handles 25 transfer housing made in the form of a hollow rod. The hollow rod is installed in the center of the body mass. The rod is associated with the rear wall of the upper section 10 and the adapter plate 11 between the upper section 10 and the lower section 1. The rod is fixed to the wall and the adapter plate by welds. The filler neck 3 of the lower section 1 is placed on the adapter plate 11.

The upper section 10 and the lower section 1 are sealed. The upper section 10 with the lower section 1 are hydraulically connected by means 26 for regulating the liquid level in the upper section (see Figs. 1, 3 and 6). Means 26 for regulating the liquid level in the upper section 10 is made in the form of a U-shaped elbow from a flexible transparent pipe. The end 27 of the flexible transparent pipe by means of a threaded plug 28 is installed in the cavity of the upper section 10 above the adapter plate 11. For this, the threaded rod 29 is welded into the adapter plate. The upper section of the end of the flexible transparent pipe 27 at a predetermined height above the adapter plate 11 is fixed with a collet 30 (Fig. .6). The other end of the flexible transparent pipe is connected with the elbow 31 on the front wall of the lower section 11. The lower section of the U-shaped elbow from the flexible transparent pipe is placed 40 ... 80 mm below the bottom of the lower section 1. This allows you to visually control the operation of the tool 26 and the entire device.

The nozzle 17 (see Figs. 1, 3, 8-15) has a hollow body 32 with axial holes and a flange 33. The flange 33 is secured by means of fasteners 34 in a stepped sleeve 18 welded into the adapter plate 11. In the cavity of the housing 32 of the nozzle 17 with with the possibility of dismantling in the direction of supply of compressed air from the air pressure regulator 6, a stepped transitional threaded sleeve 35, an air flow swirl 36 (Figs. 14 and 15) and a nozzle 37 (Figs. 12 and 13) are placed. The outlet 38 of the nozzle 37 is coupled with an axial hole 39 in the housing 32 of the nozzle 17. The threaded sleeve 35 with the air pressure regulator 6 is connected by a fitting 40 (FIGS. 1, 3 and 8). A threaded hole 41 is made in the fitting 40 for connection with the ejector sleeve 42. The fitting 40 in the stepped threaded sleeve 35 is fixed with nuts 43.

On the end part of the hollow body 32, slots 44 and blades 45 are made for separating a thin layer of water into a film. Radial slots 44 on the end of the housing 32 of the nozzle 17 are made with a width of b = 3.5 ... 5.5 mm (Fig.11). The blades 45 for separating a thin layer of water into a film at the end of the housing 32 of the nozzle 17 are formed by the intersection of the radial slots 44 and the conical surface. The conical surface is formed by the rotation of the generatrix inclined to the symmetry axis of the housing 32 at an angle γ = 55 ... 65 °. The outlet 39 of the housing 32 is made with a diameter of d ₁ = 8 ... 12 mm This ensures the supply of compressed air on the surface of the blade 45. The swirl 36 of the air stream of the nozzle 17 is made in the form of a disk with slots 46 on the peripheral part. Each slot 46 is made of a width t = 2.5 ... 3.5 mm and is inclined to the plane of the disk at an angle α = 18 ... 23 ° (Figs. 14 and 15).

The nozzle 37 of the nozzle 17 (see Fig. 12 and 13) is made in the form of a washer 25 ... 35 mm thick and a cavity with a conical and cylindrical surfaces 47 and 48. The conical surface 47 is formed by the rotation of the generatrix, which is inclined to the axis of the washer of the nozzle 37 at an angle β = 55-65 °. The cavity of the nozzle 37 is associated with the outlet 38 d ₂ = 1 ± 0.2 mm with the hole 39 in the housing 32 of the nozzle 17. The height α _{1 of the} hole d ₂ in the housing 32 is 0.4 ± 0.05 mm (FIG. 13).

On the flange 33 of the housing 32 of the nozzle 17 (see Fig. 10, 9 and 8), facing the flange 19 of the stepped sleeve 18 on the adapter plate 11 between the upper section 10 and the lower section 1, an annular groove 49 is made for installing the gasket 50.

The ejector 7 has a housing 51 and, by means of a sleeve 52 with a flange 53, is placed on the adapter plate 11 above the lower section 1. In the cavity of the housing 51 of the ejector 7 (see Fig. 7) there is a needle 54 with a Laval nozzle 55 at the thinned end and a diffuser 56. Diffuser 56, the threaded section is interfaced with the intake sleeve 57. The intake sleeve 57 in the form of a pipe segment is mounted in the axial hole of the housing 51. The lower section of the intake sleeve 57 is placed with a gap above the bottom of the lower section 1,

The cavity of the housing 51 of the ejector 7 by means of a fitting is connected by a sleeve 42 to the air pressure regulator 6. The air pressure regulator is equipped with a pressure gauge 58. The diffuser 56 of the ejector 7 by means of the mixing chamber 59 is connected to the bonk 20 on the rear wall of the upper section 10.

The housing 51 of the ejector 7 with the flange 53 of the sleeve 52 of the adapter plate 11 is connected with the seat belt and the sealing ring 60. The housing 51 of the ejector 7 is fixed to the flange 53 by means of the disk 61 and means of attachment 62. In the tide 63 of the housing 51 of the ejector 7 is made coaxial with the axial holes of the needle 54 diffuser 56 threaded hole with installed plug 64 to control the operation of the ejector 7.

Located in the cavity of the diffuser 56, the needle 54 with the Laval nozzle 55 is provided with an axial channel 65 and radial grooves 66 on the end part for supplying air from the pressure regulator 6. The mixing chamber 59, the diffuser 56 and the needle 54 with the Laval nozzle 55 are fixed to the ejector body 51 by means of a stepped sleeve 67 and fastening means 68. For this purpose, a group of through holes parallel to the horizontal axis of the cavity are made in the housing 51 of the ejector 7. The thinned portion of the needle 54 in the diffuser 56 forms a vacuum chamber 69.

The partition 16 in the upper section 10 is installed with a gap above the adapter plate 11 and orthogonal to the axis of symmetry of the mixing chamber 59.

The air pressure regulator 6 by a sleeve 70 is connected either to a compressor or to a receiver of compressed air.

A device for spraying liquid with compressed air works as follows.

The cavity of the lower section 1 is filled with water. The screw plug 4 is tightly closed on the neck 3 (figure 5). Check the tightness of the connection of the removable cover 12 with the power frame on the upper cut of the upper section 10. The threaded part of the pipe 13 is connected with a flexible corrugated sleeve. The free end of the sleeve is placed either in the greenhouse, or in the storage room, or in the aisles of a vineyard, tree and fruit plantations.

A flexible sleeve 70 is connected to a compressor. When the valve is opened in the pressure regulator 6, compressed air flows through the nozzle 40 into the nozzle 17 and along the sleeve 42 into the ejector body 51. The air pressure is controlled by the pressure gauge 58. The liquid level in the lower section 1 is fixed according to the marks of the level gauge 9.

When air enters under working pressure into the cavity of the body 51 of the ejector 7 (see Fig. 7) through the radial slots 66 and the axial channel 65 of the needle 54, the air mass is directed to the Laval nozzle 55 at the thinned end of the needle 54. In the nozzle 55, the air expands. Airflow rate increases. The compressed air mass is ejected into the ejector 56. In the ejector 56, the air mass outflow rate increases and enters the cavity of the upper section 10 through the bonnet 20 through the bonnet 20.

From the cylindrical cavity 69 of the ejector 56 between the thinned part of the needle 54, the air mass is sucked. Due to the created vacuum along the intake hose 57, the liquid from the lower section 1 enters the cavity 69 and, together with the air stream, is supplied to the diffuser 56. The water stream mixed with the air stream enters the mixing chamber 59 and through the bonk 20 on the rear wall of the upper section 10 into her cavity. The air-water mass from the mixing chamber 59 is ejected at high speed onto the partition 16. Intensive mixing of the water and air masses takes place. The precipitated water through the gap between the adapter plate 11 and the partition 16 enters the front of the cavity of the upper section 10. When it is filled, the excess water, reaching the upper cut of the end 27 of the device 26, is discharged through a flexible transparent pipe through the elbow 31 into the cavity of the lower section 1 (see 6).

At the same time, air is supplied under pressure to nozzle 17 through nozzle 40. Air from the nozzle 40 enters the cavity of the transitional threaded sleeve 35 (see Fig. 8).

Due to the oblique slots 46 (Figs. 8, 9, 14 and 15), the rotational movement of the air mass around the vertical axis of symmetry of the nozzle 17 is imparted on the peripheral part of the swirl disk 36. The swirling air mass enters the nozzle cavity 37. The swirling air mass from the cavity the nozzle 37 through the combined holes 38 and 39 from the housing 32 breaks out into the cavity of the upper section 11 in the direction of the removable cover 12. A whirlpool is created by the rotating air flow in the cavity of the upper section 10. The slots 44 and the blades 45 on the end surface of the housing 32 breaks a thin film of water in the form of a number of small segments. These segments from a thin layer of water are caught in the air stream. Due to the rotational movement of the air-water mass, this flow is repeatedly broken into the walls of the upper section 10, the partition 16 and the removable cover 12. The water mass is divided into particles of 12 and 50 μm in size. Due to the created excess air pressure in the sealed cavity of the upper section, the misty mass through the nozzle 13 is supplied either to the greenhouse, or to the vineyard plantations, or to the rows of vegetable crops, thereby creating a microclimate.

When feeding and protecting agricultural products plants, tree plantations, shrubs, grapes in water are dissolved macro- and microelements, pesticides, pesticides. The process of low-volume irrigation and foliar top dressing is similar to the above. The technical characteristics of the installation for low-volume irrigation are given in the table.

Thus, the presented information quite fully proves the possibility of implementing the task and obtaining the specified technical result.

Technical characteristics of the installation for low-volume irrigation No. Name of indicator Units rev. Value one Water tank capacity l one hundred 2 Fog tank capacity l 120 3 Compressor performance m ³ / C 0.0026 four Air inlet pressure of the filter MPa > 0.15 5 The limits of regulation of air pressure MPa 0.05-0.80 6 Pressure gauge type - Lig 7 Ejector Performance l / h Up to 100 8 Compressor drive power Tue 800 9 Fog performance m ³ / h twenty 10 Fog humidity change limits % 40-95 eleven Installation Dimensions: length mm 533 width mm 372 height mm 878 12 Installation weight kg 32.6 13 Number of staff people 2

Claims (17)

1. A device for spraying liquid with compressed air, comprising a housing, inside which means for supplying liquid and air are installed, characterized in that the housing having transfer handles is made in two sections: the lower section, located on the base, is equipped with a valve for draining the liquid, a filler neck and pneumatically connected to the air pressure regulator by an ejector, the upper section, placed by means of the adapter plate on the lower section, is equipped with a detachable lid with a pipe for the discharge of monodisperse medium doors, viewing windows on the side walls, a partition, a nozzle mounted on the adapter plate with a stepped sleeve with a flange, and a bonk on the rear wall for supplying fluid, while the upper section with the lower section is hydraulically connected by means of regulating the liquid level in the upper section, pneumatically connected the air pressure regulator said nozzle has a hollow body with axial holes and a flange fixed by means of fastening in the stepped sleeve of the adapter plate, in the body cavity with with the possibility of dismantling in the air supply direction, a stepped transitional threaded sleeve is placed, connected by a fitting with an air pressure regulator, an air flow swirl and a nozzle, the outlet opening of which is interconnected with an opening in the nozzle body, and radial slots and vanes are made on the front part of the body to separate a thin layer of water on film. 2. The device according to claim 1, characterized in that the means for regulating the liquid level in the upper section is made in the form of a U-shaped elbow from a flexible transparent pipe, one end of which is inserted through a threaded plug into a bonk on the adapter plate and fixed with a collet grip, the other end a flexible transparent pipe is connected with a square on the front wall of the lower section, while the lower section of the U-shaped elbow from the flexible transparent pipe is placed 40 ... 80 mm below the bottom of the lower section. 3. The device according to claim 1, characterized in that the nozzle air swirl is made in the form of a disk with slots on the peripheral part, with each slit 2.5 ... 3.5 mm wide inclined to the disk plane at an angle of 18 ... 23 °. 4. The device according to claim 1, characterized in that the nozzle nozzle is made in the form of a washer with a thickness of 25 ... 35 mm and a cavity with a conical surface, the generatrix of which is inclined to the axis of the washer at an angle of 55 ... 65 °, while the nozzle cavity is conjugated by an outlet with a diameter 1 ± 0.2 mm. 5. The device according to claim 1, characterized in that on the flange of the nozzle body, facing the flange of the stepped sleeve on the adapter plate between the upper and lower sections of the housing, an annular groove for installing the gasket is made. 6. The device according to claim 1, characterized in that the radial slots on the end of the nozzle body are made in the width of 3.5 ... 5.5 mm. 7. The device according to claim 1, characterized in that the blades for separating the flow of the water layer into a film at the end of the nozzle body are formed by the intersection of the radial slots and the conical surface formed by the rotation of the generatrix, inclined to the axis of symmetry of the body at an angle of 55 ... 65 °, and the input the housing hole is made with a diameter of 8 ... 12 mm. 8. The device according to claim 1, characterized in that the junction of the detachable cover on the upper cut of the upper section is made with a frame having a groove around the perimeter to accommodate the sealing tape. 9. The device according to claim 1, characterized in that the transfer handles installed in the center of mass of the housing are made in the form of a hollow rod that is interfaced with the rear wall of the upper section and the adapter plate between the upper and lower sections. 10. The device according to claim 1, characterized in that the filler neck of the lower section is placed on the adapter plate. 11. The device according to claim 1, characterized in that the ejector located on the adapter plate by means of a sleeve with a flange has a housing in the cavity of which a needle with a Laval nozzle at a thinned end and a diffuser mated to a threaded section with a suction sleeve mounted in an axial hole are coaxially mounted housing, while the cavity of the housing by means of a fitting is connected by a sleeve to the air pressure regulator, and the diffuser by means of the mixing chamber is paired with a bonk on the rear wall of the upper section. 12. The device according to claim 11, characterized in that the ejector body with a flange of the adapter plate sleeve is interfaced with a landing belt, a sealing ring and is fixed to the flange by means of a disk and fastening means. 13. The device according to claim 11, characterized in that in the tide of the ejector body a threaded hole coaxial to the axial holes of the needle and diffuser is installed with a plug installed for monitoring for the operation of the ejector. 14. The device according to claim 11, characterized in that the needle located in the cavity of the diffuser with a Laval nozzle is provided with an axial channel and radial grooves on the end part for air supply. 15. The device according to claim 11, characterized in that the mixing chamber, diffuser and needle with a Laval nozzle are fixed on the ejector body by means of a stepped sleeve and fastening means. 16. The device according to claim 1, characterized in that the upper section is equipped with a partition, which is installed with a gap above the adapter plate. 17. The device according to claim 1, characterized in that the lower section of the housing is equipped with a level gauge.

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