KR102590440B1 - Nozzle assembly for pesticide spraying device - Google Patents

Abstract

Since the present invention does not require separate components such as pumps to spray chemicals, it is possible to miniaturize and lighten the pest control device, thereby reducing production costs, and also enables control and control regardless of work site conditions through miniaturization and lightweighting. As it allows you to perform tasks efficiently;
In constructing a nozzle assembly installed to spray chemicals onto crops at the rear of the pest control device, which has a frame with wheels for driving and steering, a chemical tank for pest control, and a controller for control, and is closed with a cover;
a nozzle chamber provided in a semicircular shape and mounted at the rear of the frame;
a blowing fan installed inside the nozzle chamber to generate wind for spraying;
a plurality of air nozzles mounted on an edge of the nozzle chamber in communication with the nozzle chamber to discharge high-pressure and high-speed wind to the outside of the nozzle chamber;
It is characterized by including a chemical nozzle installed in the middle of the air nozzle, connected to the chemical tank and a feed pipe, and allowing the chemical in the chemical tank to be sprayed according to the Venturi principle by wind discharged at high pressure and high speed.

Description

Nozzle assembly for pest control device {NOZZLE ASSEMBLY FOR PESTICIDE SPRAYING DEVICE}

The present invention relates to a nozzle assembly for a pest control device. More specifically, the present invention relates to a nozzle assembly for a pest control device. It is applied to a pest control device used to control crops and improves the nozzle assembly for spraying chemicals to expand the spray range and spray distance to increase the efficiency of the pest control operation. This is about providing an improved nozzle assembly to maximize performance.

In order to grow crops, it is necessary to spray chemicals to prevent diseases and pests that may occur during the growth process, as well as spraying nutrients (including moisture, etc.) to aid growth. This work is usually done. This is done by a control device.

The pest control device used for the above purpose is of the type that the worker operates while driving, but in recent years, technology has developed into a type that operates wirelessly or unmanned to prevent the worker from inhaling the sprayed chemicals and causing harm to the human body. This is being done.

The nozzle is applied to the above-mentioned pest control device and actually performs the role of spraying the chemical to the crops. These nozzles have also been developed and used in various ways, and the contents of the representative prior art are examined through the patent literature as follows.

Patent Document 1 includes a branch pipe having an upper inlet connected to the lower end of a chemical solution supply pipe and a plurality of branch discharges formed at the lower end of the upper inlet to communicate with the upper inlet; An elastic clip portion extending on both sides from the upper inlet portion of the branch pipe and fitted to the outside of the chemical solution supply pipe; A fixing clip that is detachably coupled to both ends of the elastic clip portion and binds both ends of the elastic clip portion; And a spray nozzle coupled to each branch discharge portion of the branch pipe,

The injection nozzle includes: a first connection pipe fastened to each branch discharge portion of the branch pipe; a filter body inserted into the first connection pipe; a second connector connected to an end of the first connector; a nozzle tip fastened to an end of the second connector and having a nozzle hole in the center communicating with the second connector; It has a head portion located inside the second connection pipe and a pin portion inserted into the nozzle hole of the nozzle tip, and a spiral groove is formed on the outer peripheral surface of the pin portion to communicate with the nozzle hole and acts on the nozzle pin and the second connection pipe. It is characterized by having a valve that opens and closes the inlet of the second connection pipe depending on the presence or absence of pressure of the chemical liquid.

Patent Document 2 includes a chemical supply unit (100), an air supply unit (200), a main supply pipe (300), a multi-branch pipe (400), a chemical injection line (500), a multi-recovery pipe (600), and a main recovery pipe (700). , The control unit 800 is the main component, and the nozzle unit 530, which constitutes the chemical spray line 500, is connected to the main pipe body to generate a vortex and spray the chemical liquid into fine particles,

The nozzle portion 530 includes a nozzle pipe body 531 connected to the outer peripheral surface of the main pipe body 522 at an inclined angle, a check valve hole 532a formed on the inside, and a check valve hole 532a inserted into the nozzle pipe body 531 at the end. A filter bush 532 on which a filter sheet 532b is installed, a nozzle cap 533 screwed to the end of the nozzle pipe body 531, and a nozzle cap 533 installed in the nozzle cap 533 and fixed in position by an O-ring 534a. A guide shaft hole (534b) is formed in the center, a plurality of chemical liquid passages (534c) are formed radially around the guide shaft hole (534b), and a plurality of spiral engraved lines (535a) are formed on one side and protrude on the outer peripheral surface. A nozzle core portion 534 provided with a conical protrusion 535, a nozzle tip 536 having a conical hole 536a penetrating therein so as to be fitted into the conical protrusion 535 of the nozzle core portion 534, and It is inserted into the filter bush 532 to open and close the check valve hole 532a, and the guide shaft pin 537a is protruded at one end and inserted into the guide shaft hole 354b of the nozzle core 534, and the elastic body 537b is formed. It is characterized by including a conical check valve key 537 provided to generate an operating force in the direction of closing the check valve hole 532a.

Utility Model Registration No. 20 - 0492258 - 0000 Patent No. 10 - 2231015 - 0000

None.

The nozzle for the pest control device to which the above prior art is applied is configured to pump the chemical contained in the chemical tank through a pump and spray it through a nozzle connected to the end of the hose in order to spray the chemical.

Of course, the structure of the nozzle may vary depending on the purpose of pest control or the type of crop, but in general, the chemical is supplied at high pressure through a pump and then sprayed through the nozzle.

In this way, since a pump is essential for spraying chemicals and controlling pest control, the configuration of the control device becomes complicated, and the size also increases, which not only increases the production cost of the control device, but also increases the number of assembly workers required for production. This happens.

In particular, in line with the trend toward miniaturization and unmanned control, it is necessary to install a pump and a separate power source required for pump operation by installing a battery in a small frame to generate the power necessary for pest control as well as driving. Not only is it realistically difficult to reduce weight, but it also serves as another cause of making unmanned and autonomous driving difficult.

Because the chemical applied to the plant for pest control is pressurized by a pump, there is a limit to reducing the particle size of the chemical, so the sprayed chemical adheres closely to the surface of the crop and cannot be maintained continuously for a long time. It sticks to the surface of the crop only at the beginning of spraying. It takes the same form, but as time passes, it rapidly falls apart and separates.

Moreover, if external pressure such as rain or wind blows after spraying the chemical, the sprayed chemical will not be able to remain in close contact with the crop or continue for a long time, resulting in insufficient control effect.

For this reason, frequent pest control is required and many chemicals are sprayed, so there is a very high risk that excessive pesticide residues will remain when harvested crops are harvested, damaging the health of users who consume them. Low-pesticide and no-pesticide pesticides are used. It is not free from various problems, such as being inconsistent with the intended crop cultivation decoration.

Accordingly, the present invention was invented to solve the above problems, and has a cover ( In constructing a nozzle assembly 100 installed to spray chemicals to crops at the rear of the pest control device 105, which is finished with 104);

a nozzle chamber 106 provided in a semicircular shape and mounted at the rear of the frame 102;

a blower fan (107) installed inside the nozzle chamber (106) to generate wind for spraying;

A plurality of air nozzles (110) mounted on the edge surface of the nozzle chamber (106) in communication with the nozzle chamber (106) to discharge high-pressure and high-speed wind to the outside of the nozzle chamber (106);

The medicine is installed in the middle of the air nozzle 110 and connected to the medicine tank 103 and the feed pipe 111, so that the medicine in the medicine tank 103 is sprayed according to the Venturi principle by the wind discharged at high pressure and high speed. Including nozzle 130;

Since there is no need for separate components such as pumps to spray chemicals, it is possible to miniaturize and lighten the pest control device, thereby reducing production costs, and through miniaturization and weight reduction, pest control work can be performed efficiently by controlling it regardless of work site conditions. It is possible to achieve the goal of eliminating the cause of workers being exposed to chemicals and harming their health through unmanned control during the pest control process.

The present invention allows the spray of a pesticide for control to be spread and sprayed in the form of ultra-fine particles without a pump, allowing the drug to remain attached to the surface of crops for a long period of time, thereby increasing the control effect without frequent pesticides, and allowing an unnecessarily large number of drugs to be applied to crops. It has the effect of preventing accumulation.

The present invention expands the spray range and increases the spray distance by changing the structure of the nozzle applied to the pest control device, enabling pest control to a greater range than conventional pest control devices or nozzles with the same agent, and miniaturizing the entire pest control device. And it has the effect of contributing to weight reduction and enabling unmanned operation.

The present invention improves the nozzle to miniaturize and lighten the pest control device, thereby increasing production efficiency and reducing production costs, which not only reduces the economic burden on farmers wishing to purchase a pest control device, but also increases external competitiveness. It is an invention that has various effects.

Figure 1 is a perspective view showing the front of a pest control device shown to explain the present invention.
Figure 2 is a perspective view showing the rear of the pest control device shown to explain the present invention.
Figure 3 is an overall perspective view showing a nozzle assembly for a pest control device to which the technology of the present invention is applied.
Figure 4 is a fractured perspective view showing a nozzle assembly for a pest control device to which the technology of the present invention is applied.
Figure 5 is a cross-sectional configuration diagram showing a nozzle assembly for a pest control device to which the technology of the present invention is applied.
Figure 6 is a configuration diagram showing another example of a nozzle assembly for a pest control device to which the technology of the present invention is applied.
Figure 7 is a configuration diagram showing the use state of the nozzle assembly for a pest control device to which the technology of the present invention is applied.

Hereinafter, the preferred configuration and operation of the present invention for achieving the above object will be described in relation to the accompanying drawings.

Figure 1 is a perspective view showing the front of a pest control device shown to explain the present invention, Figure 2 is a perspective view showing the back of the control device shown to explain the present invention, and Figure 3 is a pest control to which the technology of the present invention is applied. An overall perspective view showing the nozzle assembly for the device, Figure 4 is a fractured perspective view showing the nozzle assembly for the control device to which the technology of the present invention is applied, and Figure 5 is a cross-sectional view showing the nozzle assembly for the control device to which the technology of the present invention is applied. , FIG. 6 is a configuration diagram showing another example of a nozzle assembly for a pest control device to which the technology of the present invention is applied, and FIG. 7 is a configuration diagram showing the use state of the nozzle assembly for a pest control device to which the technology of the present invention is applied, which are explained together. .

The nozzle assembly 100 for a pest control device to which the technology of the present invention is applied includes a chemical tank 103 for pest control and a control frame 102 having wheels 101 that receive power from a motor and steer while traveling. It has a controller for spraying chemicals onto crops at the rear of the control device 105, which is closed with a cover 104.

The nozzle assembly 100 generates a predetermined pressure by installing a blower fan 107 to generate wind for spraying inside the nozzle chamber 106, which is provided in a semicircular shape, and the nozzle chamber 106 ), a plurality of air nozzles 110 are arranged radially on the edge surface in communication with the nozzle chamber 106 so that high-pressure wind can be discharged to the outside of the nozzle chamber 106.

In the drawing of the present invention, the nozzle chamber 106 is illustrated as being configured in a semicircular shape, but it can be configured in various shapes such as circular, square, and polygonal, and the inside of the nozzle chamber 106 is also formed as a single body. Since it can be implemented in a form that is divided into several parts and configured, the present invention is not limited to those illustrated in the drawings or description.

When the nozzle chamber 106 is divided into several parts using partition walls, it is natural to install a blower fan 107 to generate pressure inside each divided space.

The chemical nozzle 130 connected to the chemical tank 103 and the feed pipe 111 is placed in the middle of the air nozzle 110, and the chemical in the chemical tank 103 is discharged at high pressure by the wind discharged into the chemical nozzle 130. ) and is configured to be sprayed according to the Venturi principle to prevent pest control.

The air nozzle 110 is a cylindrical tubular type with a fastening end 112 at the bottom to maintain airtightness by being fastened to the nozzle chamber 106 by a method such as screwing, and is provided with an air nozzle body 113. , A blowing passage 114 is formed at the center of the inner axis of the air nozzle body 113 so that the wind generated by the high pressure of the nozzle chamber 106 can be discharged to the outside.

The blowing passage 114 is formed at a position adjacent to the nozzle chamber 106 and is formed at an intermediate position between the air nozzle body 113 and the discharge pipe 115 for discharging the wind inside the nozzle chamber 106. An air nozzle body ( It consists of a diffusion pipe 118 connecting to the end of 113).

The high pressure pipe 116 is formed to have a diameter smaller than the diameter of the discharge pipe 115 so that it is converted to high pressure and high speed when wind passes through. In the case of the diffusion pipe 118, the diameter of the outer end is changed to the diameter of the discharge pipe 115. It is formed to have a diameter larger than the diameter of so that the final discharged wind can spread widely.

The chemical nozzle 130 is configured by connecting a nozzle tip 133 having a chemical passage 132 to a cylindrical nozzle body 131 connected to the end of the feed pipe 111, and the nozzle tip 133 The tip 135 of is exposed to the high pressure pipe 116 so that the drug in the chemical tank 103 can be sprayed through the diffusion pipe 118 according to the Venturi principle by the wind discharged at high pressure and high speed.

The distal end 135 of the nozzle tip 133 is installed in an inclined form rather than being installed at right angles to the axial center (P) of the high pressure pipe 116, and the chemical passage 132 is installed in the high pressure pipe 116. ) and be fully exposed to the effects of high-pressure and high-velocity wind.

More preferably, the distal end 135 of the nozzle tip 133 is maintained at a right angle to the axial center (P) of the high-pressure pipe 116, so that the medicine is discharged by high-pressure, high-speed wind and at the same time, the high-pressure and high-speed wind is discharged. It is advisable to help the drug become fine or ultra-fine particles by hitting it, and the tip 135 of the nozzle tip 133 is also configured in a diffusion shape to allow the drug to spread, so that the drug can be further reduced to fine particles. It will also be okay.

The state of use of the nozzle assembly 100 for a pest control device to which the technology of the present invention is applied as described above is as follows.

The chemicals required for pest control work on crops are prepared in the chemical tank 103 constituting the pest control device 105, moved to the work site, and controlled while operating the pest control device 105 while driving unmanned or by remote control. Just get the job done.

Then, the blower fan 107 mounted inside the nozzle chamber 106 operates to maintain the inside of the nozzle chamber 106 at a constant pressure, and this pressure is generated by the nozzle assembly (radially mounted on the outer surface of the nozzle chamber 106). It is discharged to the outside through the air nozzle 110 constituting 100).

In the process of releasing high-pressure and high-speed wind to the outside through the air nozzle 110, the drug is sprayed together according to the Venturi principle through the drug nozzle 130, which is mounted on the air nozzle 110 and connected to the drug tank 103. This makes it possible to carry out pest control work.

In this process, the chemical in the chemical tank 103 is released at high pressure and high speed through the air nozzle 110 through the tip 135 of the chemical nozzle 130 mounted on the high pressure pipe 116 constituting the air nozzle 110. Due to the wind discharged from the nozzle chamber 106, the drug is discharged to the tip 135 of the nozzle tip 133 constituting the drug nozzle 130 through the Venturi principle. The drug is discharged at high pressure and high speed by the wind discharged from the nozzle chamber 106. As it is discharged together, it is finely broken and atomized and discharged.

Therefore, the chemical is discharged in the form of fine particles and, upon reaching the surface of the crop, not only forms a close contact with the crop, but also spreads and disperses evenly throughout the crop and adheres closely to the crop. The chemical is evenly attached (adsorbed) not only to the location close to the assembly 100 but also to the opposite location, thereby increasing the pest control effect.

In the present invention, an ion generator is further installed in connection with the chemical tank 103 or in connection with the supply pipe 111 connected to the chemical tank 103 to change the structure of water (ionization) to maintain viscosity for a long time and minerals. It is safe to say that the sprayed medicine or nutrient can provide greater help to crops by effects such as increase, production of anions, reduction of active oxygen, increase in solubility, and miniaturization of water molecules.

Since the present invention does not require separate components such as pumps to spray chemicals, it is possible to miniaturize and lightweight the pest control device, thereby reducing production costs. In addition, through miniaturization and lightweighting, it can be controlled regardless of work site conditions. It has various advantages, such as being able to carry out pest control work efficiently and eliminating the cause of workers being exposed to chemicals and harming their health through unmanned control during the pest control process.

100; Nozzle assembly for pest control device
105; Control device 106; nozzle chamber
107; Blowing fan 110; air nozzle
113; Air nozzle body 114; ventilation passage
115; discharge pipe 116; high pressure pipe
117; integrated conduit 118; diffusion pipe
130; Pharmaceutical nozzle 131; nozzle body
132; pharmaceutical passage 133; nozzle tip
135; tip

Claims (3)

The chemical is applied to crops at the rear of the pest control device (105), which has a frame (102) with wheels (101) for driving and steering, a chemical tank (103) for pest control, and a controller for control, and is closed with a cover (104). In constructing the nozzle assembly 100 installed to spray;
The nozzle assembly 100 includes a nozzle chamber 106 provided in a semicircular shape and mounted at the rear of the frame 102;
a blower fan (107) installed inside the nozzle chamber (106) to generate wind for spraying;
A plurality of air nozzles (110) mounted on the edge surface of the nozzle chamber (106) in communication with the nozzle chamber (106) to discharge high-pressure and high-speed wind to the outside of the nozzle chamber (106);
The medicine is installed in the middle of the air nozzle 110 and connected to the medicine tank 103 and the feed pipe 111, so that the medicine in the medicine tank 103 is sprayed according to the Venturi principle by the wind discharged at high pressure and high speed. Includes a nozzle 130;
The air nozzle 110 includes an air nozzle body 113 having a fastening end 112 to be fastened to the nozzle chamber 106;
It includes a blowing passage 114 formed around the inner axis of the air nozzle body 113 so that wind generated by the high pressure of the nozzle chamber 106 can be discharged to the outside;
The blowing passage 114 includes a discharge pipe 115 formed adjacent to the nozzle chamber 106 to discharge the wind inside the nozzle chamber 106;
A high-pressure pipe 116 formed at an intermediate position of the air nozzle body 113 and having a smaller diameter than the discharge pipe 115 to convert wind into a high-pressure and high-speed state;
a collection pipe 117 connecting the discharge pipe 115 and the high pressure pipe 116;
It further includes a diffusion pipe (118) connected from the top of the high pressure pipe (116) to the end of the air nozzle body (113) to spread the final discharged wind widely;
The drug nozzle 130 includes a nozzle body 131 connected to the end of the feed pipe 111;
It includes a nozzle tip 133 connected to the nozzle body 131 with a drug passage 132;
The tip 135 of the nozzle tip 133 is exposed to the high pressure pipe 116 so that the drug in the chemical tank 103 is sprayed through the diffusion pipe 118 according to the Venturi principle by the wind discharged at high pressure and high speed. do;
The distal end 135 of the nozzle tip 133 is inclined with respect to the axial center (P) of the high pressure pipe 116, and the drug passage 132 is completely exposed to the high pressure pipe 116. A nozzle assembly for a pest control device. delete delete

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