KR200339670Y1 - Spraying tool for mass mist in portable air blowing spray machine. - Google Patents

Abstract

The present invention provides a plurality of nozzles arranged in a structure having a low air resistance to the blower and a spray device configured to prevent the liquid particles injected from the nozzles from colliding with the mesh member 51 so as to generate a large amount of fine particles. The present invention relates to a spray device designed to be able to control the water in a short time.

Description

Spraying tool for mass mist in portable air blowing spray machine.

The present invention relates to a spray device for generating a large amount of fine particles through a portable power sprayer.

1 (A) is a perspective view showing a conventional portable power sprayer (11), the portable power sprayer (11) is a blower 13, the engine 12 is coupled to the body 21, usually the suspenders are coupled to Is combined, the blower 20 is combined with the medicine container 25 is combined with the top 20, and the blower 13 and the medicine container 25 is a pressure hose 14 is connected. The blower tube 15 is connected to the side of the blower 13, and the granules or powder such as fertilizer are injected into the medicine container 25 and sprayed. On the other hand, in the case of spraying a liquid such as pesticide into the medicine container 25, the sprayer 16 is combined with the spraying device 16, and the medicine container 25 and the spraying device 16 is connected to the liquid hose (19). .

1 (B) is a perspective view illustrating an example of the spray device 16 of the conventional portable power sprayer 11 as described above, the spray device 16 is a liquid control valve 18 and the connecting pipe (18a) ) Is combined with the tubular body (16a), the diffusion control tube 17 in the form of a fallopian tube configured to adjust the diffusion angle of the liquid spray, and the diffusion control while adjusting the length of protruding the diffusion control tube from the body (16a) It consists of an O-ring 416 configured to secure the tube 17 to the body 16a, a nut 417, and a nozzle 41.

In the portable power sprayer 11 as described above, the air pressure generated from the blower 13 when the liquid is sprayed is introduced into the chemical container 25 through the pressurized hose 14, and the liquid is the liquid hose 19, the liquid control valve ( 18 is transmitted to the nozzle 41 to be pulverized and sprayed into small particles by a high speed blower. Normally, when spraying with such a structure, the particle size is about 400 microns (micrometers) in diameter and requires a large amount of water to wet the control crop.

On the other hand, the smaller the size of the spray particles, the smaller the amount of water required for the control work, and thus, the control time and labor can be saved.

FIG. 2 is a partial cross-sectional view showing a nozzle portion of the spray device 16 of the conventional portable power sprayer 11, and a conical nozzle which spreads the particles to be spread in order to atomize the size of the particles, and grinds them by a blower stream. 411a, a rotating nozzle 411b for colliding and atomizing the liquid particles injected into the nozzle hole by the rotating blades rotated by the blower airflow, and a micronozzle 411c for spraying the liquid material into the minute hole. It is.

In these cases, the particle size is less than 100 microns, it is difficult to form, the air resistance to the blower air flow by each nozzle is large, the vortices generated by the blower air flow in front of the nozzle to form a thick particle tend to be sprayed It is also big.

3 is a partial cross-sectional view of a spray device configured to solve such a problem, the mesh holder 50 having a mesh member 51 formed with a vent hole 52 in the diffusion control tube 17 of the conventional spray device of FIG. As a combination of the particles, the particles pulverized by the nozzle 41 are configured to be secondaryly pulverized through the mesh member 51. In this case, however, the air resistance by the mesh member 51 causes the speed of the blower air to be partially lowered, so that the ventilation holes 52 are necessary for the mesh members 51, and the ventilation holes also allow the particles to pass through the mesh members 51. It will play the role of sending away.

When the existing nozzle 41 and the mesh member are combined as shown in FIG. 3, when the distance between the nozzle 41 and the mesh member 51 increases, the width of the particles dispersed in the nozzle 41 becomes too large and the mesh member 51 Large particles are drawn out through the vent hole 52 around the air, and when the distance between the mesh member 51 and the nozzle 41 approaches, air deflection is doubled by the nozzle 41 and the mesh member 41 having a large diameter. As the speed of the blower is greatly reduced, large particles are increased on the back of the nozzle 41, and the size of the particles passing through the mesh member 41 is also increased.

This phenomenon becomes more severe as the amount of liquid to be sprayed increases, which is not a structure suitable for atomizing a large amount of liquid.

4 is a partial cross-sectional view illustrating an improved spraying device for a portable power sprayer, in which the nozzle 43 is assembled to the wall of the body 16a, and the spraying angle is the size of the particles that are crushed by spraying at right angles to the blower stream. It is made to make small particles primarily by making the particles pulverized by the blower air flow through the mesh member 51 in a state where the resistance of the air is small. Even in the case of such a spraying device, when the amount of the liquid to be sprayed is increased to a certain amount or more, as shown in FIG. 3, it is concentrated on a part of the mesh member by a strong blower and passes only a specific portion 71 of the mesh member 51. The phenomenon occurs. Therefore, there is a problem to atomize more than a certain amount of liquid, and the limit injection amount is usually about 1 liter per minute.

The present invention has been made to improve the conventional method for producing fine particles as described above, and is intended to produce a large amount of fine particles (MIST-100 microns or less) per minute or more.

Figure 1 (A) is a conventional portable power sprayer, Figure 1 (B) is a perspective view showing an example of a conventional spraying device.

2 is a partial cross-sectional view showing a nozzle portion of the spraying device 16 of the conventional portable power sprayer 11.

3 is a partial sectional view illustrating the spraying apparatus of the improved portable power sprayer.

4 is a partial sectional view illustrating the spraying apparatus of the improved portable power sprayer.

5 is a partial cross-sectional view showing a configuration of the present invention.

6 is a perspective view showing the present invention.

7 is a partial cross-sectional view showing a portable power sprayer with a pump coupled thereto.

* Description of the symbols for the main parts of the drawings *

11: portable power sprayer 13: blower

16 spray device 51 mesh member

When explaining the present invention in more detail according to the accompanying drawings to achieve the above object Figure 5 is a partial cross-sectional view showing the present invention,

5 (A) is a plurality of hoses 47 and combined with the drug adjusting device 18,

A plurality of nozzles 45 connected to the hose 47,

The mesh member 51 in which the vent hole 52 is formed by the mesh holder 50 is combined with the spraying apparatus 16,

The distance between the nozzle 45 of the mesh member 51, the area of the mesh member 51, the injection amount of the nozzle, and the arrangement distance between the nozzle and the nozzle overlap the mesh member 51 with the chemicals dispersed in the nozzles 45. It is combined with the sprayer 16 so as not to collide.

In FIG. 5A, the spray particles are sprayed by four nozzles and dispersed in four places 72 of the mesh member 51 to pass the spray particles through the mesh member 51. The nozzle of FIG. 5 has a smaller injection volume than the nozzle of FIG. 4, and is closer to the mesh member 51 than the nozzle of FIG. 4 so as to collide with a predetermined position of the mesh member 51 without colliding with particles of the liquid injected from other nozzles. It is arrange | positioned in the appropriate position of the adjacent position, and the distance between nozzles is disperse | distributed by the same distance, in order to distribute liquid particle efficiently. In addition, the hose 47 is disposed outside the spray device to reduce the air resistance.

FIG. 5B shows that the sprayed particles pass through the mesh member 51 by being sprayed by three nozzles and dispersed in three places 73 of the mesh member 51. In this case, the injection amount of the nozzle is larger than that of Fig. 5A, and the distance from the mesh member is arranged to be a little farther.

FIG. 5C illustrates an application to a case in which the shape of the diffusion control tube 17 is not circular. For example, a rectangular diffusion holder 50 and a rectangular mesh holder combined in front of the diffusion control tube 17 are illustrated. 50, the two upper and lower nozzles 50 are assembled alternately so that the particles sprayed from each nozzle do not collide with the collision member 74 in four places on the mesh member 51. The distance from the nozzle 45 of 51, the area of the mesh member 51, the injection amount of the nozzle, and the arrangement distance between the nozzles and the nozzles do not collide with the mesh member 51 with the medicine dispersed in each nozzle 45. A spray device combined with the spray device 16.

5 (D) is a distance from the nozzle 45 of the mesh member 51 and the area of the mesh member 51, so as not to overlap the three collision parts 75 in the rectangular diffusion control tube 50, It shows that the injection amount of the nozzle and the arrangement distance between the nozzle and the nozzle are adjusted.

In this spray device, the liquid delivered from the medicine container 25 is transferred to the respective nozzles 45 through the plurality of hoses 47 through the liquid control valve 25 and the hose 47 is of the T shape The nipple 47a, the hose 47b, the L-shaped nipple 47c and the like can be configured. The liquid delivered to each nozzle 45 is sprayed into the diffusion control tube 17 through each nozzle 45, and the particles pulverized at the nozzle 45 are efficiently meshed due to the absence of protruding nozzles. After colliding with each impact site 72, 73, 74, 75 of 51, it is crushed into fine particles and transported away by a blower stream injected through the vent 52. Here, the nozzle 45 may be combined with the body 16a of the spraying device 16 instead of the diffusion control tube 17 as shown in FIG. 5.

FIG. 6 is a perspective view illustrating the present invention, in which a mesh member 51 including a hose 47 and a plurality of nozzles 45 and a vent hole 52 shown in FIG. 50) to the sprayer 16.

FIG. 7 is a partial cross-sectional view showing a portable power sprayer coupled to a pump, in which a pump 91 is coupled to the engine 12 together with a blower fan 13a of the blower 13 coupled to the engine 12. The liquid agent pressurized by the pump 91 as driven by the atomizer is further atomized and dispersed in the nozzle 45, thereby effectively generating fine particles.

The spray device of the portable power sprayer as described above is to generate more than 1 liter per minute (MIST) of fine particles (MIST) of less than 100 microns in the blower of the portable power sprayer and consequently the blower having a diameter of 60 mm. By reducing the air resistance inside the blower pipe and generating a large amount of fine particles through a plurality of nozzles, it is possible to control the operation within a short time by using a smaller amount of water compared to the conventional spraying, and the spraying amount is also increased, the control effect Is a design that can be doubled.

Claims (2)

In the spray device of a conventional portable power sprayer that drives a blower with an engine to spray liquid or powder, A plurality of hoses 47 combined with the drug adjusting device 18, A plurality of nozzles 45 connected to the hose 47, The mesh member 51 in which the vent hole 52 is formed by the mesh holder 50 is combined with the spraying apparatus 16, The distance between the nozzle 45 of the mesh member 51, the area of the mesh member 51, the injection amount of the nozzle, and the arrangement distance between the nozzle and the nozzle overlap the mesh member 51 with the chemicals dispersed in the nozzles 45. Spraying device of the portable power sprayer, characterized in that combined with the spraying device (16) so as not to collide. Spraying apparatus, characterized in that the liquid pressure pump (91) is connected to the engine (12).