RU219212U1 - BIOLOGICAL SPRAYER - Google Patents

Abstract

The nebulizer of a biological preparation consists of a nebulizer body, inside which there are two channels having the shape of a cylindrical helix, not intersecting with each other. In the upper part there are fittings located at an angle of inclination of the central axis of the channel spiral. In the lower part of the nozzle body there is a nozzle having the shape of a truncated cone with a hole at the top. Such a constructive solution of the atomizer provides a complete uniform treatment of seeds and an increase in the efficiency of the use of biological preparations. 2 ill.

Description

The utility model relates to agricultural engineering, in particular to devices for spraying liquid.

Known nozzle with a parabolic swirler [1]. It contains a cylindrical chamber for gas supply, an axial sprinkler with throttle holes for liquid supply and a gas-liquid flow swirler. The sprinkler with throttle holes 6 is plugged from the outlet end by a centrifugal element consisting of profiled disks connected in series and on the end part of which protrusions and recesses are made in the form of an Archimedes spiral. The protrusions on one disk enter with a gap into the depressions on the other disk to form a channel in the form of an Archimedes spiral, which communicates with the cavity of the cylindrical chamber, in the end part of which there is a disk with a perforation for gas entry, which is rigidly connected to the cylindrical chamber with its outer surface, and the inner surface - with a sprinkler. Two swirlers are installed in series in the cylindrical chamber. The swirler located at the gas flow inlet is rigidly attached to the sprinkler tube. The outlet swirler is rigidly attached to the inner surface of the cylindrical chamber. Between the swirlers and there are gaps for interaction with gas and liquid: a tangential gap and an axial gap. Each of the swirlers is made in the form of an elliptical paraboloid, the guide vanes of which are curved along the helical surface and form curvilinear confusing channels.

The disadvantage of this design is the high level of liquid pressure, which is unacceptable when spraying a liquid with a biological drug.

Also known pneumoacoustic rod nozzle [2], in which the Central rod is made with a diameter equal to the diameter of the nozzle. Longitudinal slots in the central rod are located at distances not exceeding a quarter of the wavelength of the operating frequency of the nozzle.

The disadvantage of this device is that the exiting liquid hits the reflector, which is also detrimental to the microorganisms included in the preparations for biological plant protection.

The prototype is the atomizer of the working composition of the biological product [3], which contains a body, fittings, an adjusting cone and a hollow nozzle. Inside the housing there is a channel for air supply and a channel for supplying the working composition. The fittings are installed in the upper part of the housing to the inlets of the channels for supplying air and working composition. The adjusting cone is installed coaxially in the lower part of the housing. The hollow nozzle has the shape of a truncated cone with a hole at the top and is fixed to the lower part of the housing by means of a threaded connection. The axes of the channels for supplying air and the working composition are in the form of a cylindrical helical line, the axis of which coincides with the axis of the body. The inlet openings of the channels are arranged symmetrically relative to each other and the body axis. The diameter of the channel for supplying air is 1.5 times greater than the diameter of the channel for supplying the working composition.

The disadvantage of this device is that during the operation of the sprayer, the working solution of the biological product is fed through a fitting located coaxially with the axis of the housing, and the line of movement of the working fluid turns at an angle close to 90°, which leads to a decrease in the flow rate, additional resistance, as well as partial death of microorganisms.

The essence of the proposed utility model is as follows.

The technical result is an increase in the efficiency of the use of biological preparations for dressing seeds and processing crops.

This is achieved by the fact that in the sprayer of the working composition of the biological product, which includes a housing, inside which there is a channel for supplying air and a channel for supplying the working composition, the axes of which are in the form of a cylindrical helical line, and the diameter of the air supply channel is larger than the diameter of the channel for supplying the working composition to 1.5 times, fittings installed in the upper part of the body to the inlets of the channels, a hollow nozzle located coaxially with the body in its lower part, having the shape of a truncated cone with a hole at the top and forming a conical chamber inside, the fittings are installed at an angle α to the central body axis, equal to α = 90-ψ, where ψ is the angle of elevation of the helical lines of the axes of the channels for supplying air and working composition.

Atomizer of a biological preparation, illustrated by a diagram.

Fig. 1 - scheme of the atomizer.

Fig. 2 - top view of the atomizer.

The atomizer of the working composition of the biological product (Figs. 1 and 2) consists of a body 1 and a nozzle 2. Inside the body 1 there are a channel for supplying the working composition 3 and a channel for air supply 4 that do not intersect each other. The axes of the channels 3 and 4 have the form of a cylindrical helical line , the axis of which coincides with the axis of the housing 1. The inlets of the channels 3 and 4 are located symmetrically relative to each other and the axis of the housing 1. In this case, the diameter of the air supply channel 4 is 1.5 times larger than the diameter of the working composition supply channel 3. In the upper part of the housing, to the inlets of channels 3 and 4, at an angle of inclination of the central axis of the spiral of the channels, fittings 5 are installed at an angle α to the central axis of the housing, equal to α = 90-ψ, where ψ is the angle of elevation of the helical lines of the axes of the channels for supplying air and working composition. A cone 6 is installed in the lower part of the housing coaxially with it. The nozzle 2 has the shape of a truncated cone with a hole at the top, is hollow and is a continuation of the lower part of the housing 1.

The atomizer of the working composition of the biological product works as follows. The atomizer of the working composition of the biological product is installed in the treater or sprayer. In the process of operation, through fittings 5 located at an angle of inclination of the central axis of the spiral of channels, the working composition of the biological product is supplied to channel 3, and warm air is supplied to channel 4. At the same time, the working composition of the biological product is supplied under a pressure of not more than 2 atm., and the air pressure is at least 4 atm. The working composition and air, passing through the screw channels 3 and 4, respectively, change the rectilinear motion to rotational and break out of the outlets at an angle to the inner cone-shaped surface of the nozzle 2. Further, they are mixed in the chamber formed by the inner cone-shaped surface of the nozzle 2 and cone 6 At the same time, the working composition of the biological product, picked up by a warm air flow due to a higher pressure, moves along a cone-shaped surface, is enriched with air and additionally twists. Having reached the top of the nozzle, the air-enriched working composition of the biological product passes through the gap formed between the nozzle opening 2 and the cone 6 and is sprayed into the external environment. This design of the sprayer allows you to feed into the sprayer and spray the working composition of the biological product at a lower pressure and thereby reduce the negative impact of high pressure on the vital activity of biological agents of biological products. And the enrichment of the working composition with warm air will increase the activity of biological agents of biological products. Moreover, fittings, located at an angle of inclination of the central axis of the channel helix, make it possible to reduce the resistance to the movement of the working fluid and eliminate the shock effect of biological preparations on microorganisms. Thus, such a constructive solution of the sprayer of the working composition of the biological product provides an increase in the efficiency of the use of biological preparations for plant protection.

List of used literature

1. RF patent No. 2636721, IPC B05B 1/34, B05B 7/00, B01F 3/04, B01F 5/02. Nozzle with a parabolic swirler /O.S. Kochetov, dec. 2016143959, 09.11.2016, publ. Bull. 27.11.2017 No. 33.

2. RF patent No. 2536957, IPC B05V 1/00. Pneumoacoustic rod nozzle / A.N. Dubrovsky, app. 2013134991/05, 07/26/2013, publ. Bull. 27.12.2014 No. 36.

3. RF patent No. 2681640, IPC B05B 7/10. Atomizer of the working composition of the biological product / R.F. Sabirov, A.R. Valiev, R.I. Safin et al., Appl. 2018113215, 04/11/2018, publ. 03/11/2019 Bull. No. 8.

Claims (1)

A sprayer of a biological preparation, including a housing, inside which there is a channel for supplying air and a channel for supplying a working composition, the axes of which are in the form of a cylindrical helix, and the diameter of the channel for air supply is 1.5 times larger than the diameter of the channel for supplying the working composition, fittings, installed in the upper part of the body to the inlet openings of the channels, a hollow nozzle located coaxially with the body in its lower part, having the shape of a truncated cone with a hole at the top and forming a conical chamber inside, characterized in that the fittings are installed at an angle α to the central axis of the body, equal to α = 90-ψ, where ψ is the angle of elevation of the helical lines of the axes of the channels for supplying air and working composition.

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