KR101625059B1 - Liquid scattering apparatus - Google Patents

Abstract

Disclosed is a liquid scattering apparatus for spraying a liquid such as pesticide to be scattered to a long distance. The disclosed liquid scattering device includes a tank in which a liquid is contained, a nozzle tube through which liquid flows out of the tank, a nozzle which is provided to discharge liquid to the end of the nozzle tube and is rotatably coupled to the nozzle tube, A liquid supply unit including a nozzle actuator for rotating the nozzle so as to change the direction of spraying liquid, and an air blowing unit for blowing air upward at a high speed toward the nozzle.

Description

[0001] Liquid scattering apparatus [0002]

The present invention relates to, for example, a liquid scattering apparatus for spraying a liquid such as pesticide to be scattered to a long distance.

For example, an apparatus for spraying a liquid such as an agricultural chemical spreader is widely known. Devices for spraying liquids include portable equipment for spraying liquids while the operator is carrying them, devices for spraying liquids fixedly installed at specific locations, such as sprinklers, and devices for spraying liquids over a distance with strong blowing pressure do. The liquid scattering device may be configured to be movable in a place such as an automobile.

Korean Patent Publication Nos. 10-1235955 and 10-1371076 disclose conventional liquid scattering apparatuses. The liquid scattering device disclosed in the above-mentioned No. 10-1235955 has a problem that it is difficult to appropriately spray a liquid in a liquid jetting direction of a plurality of nozzles is fixed, where a liquid supply is further needed.

In addition, the liquid scattering device disclosed in the above-mentioned 10-1371076 has a blower installed inside a single air guide duct to scatter liquid only in one direction and to rotate the duct in order to change the direction, And tilting, and the liquid can not be sprayed in various directions at the same time.

Korean Patent Registration No. 10-1235955 Korean Registered Patent No. 10-1371076

The present invention provides a liquid scattering device capable of changing the spraying direction of liquid as needed and capable of scattering liquid simultaneously in various directions.

The nozzle includes a tank for containing liquid, a nozzle tube through which the liquid flows out from the tank, a nozzle rotatably coupled to the nozzle tube and adapted to eject the liquid at a distal end of the nozzle tube, A liquid supply unit including a nozzle actuator for rotating the nozzle so as to change a liquid jet direction of the nozzle, and a liquid fountain device having a blowing unit for blowing air at a high speed toward the nozzle do.

The nozzle actuator may include a motor and a nozzle coupling member coupled to the nozzle and rotated by the power of the motor.

Wherein the nozzle includes a nozzle body rotatably coupled to the nozzle tube and a nozzle protrusion protruding from an outer circumferential surface of the nozzle body and having a nozzle hole through which liquid is ejected, A nozzle protrusion through hole may be formed so that the nozzle protrusion penetrates through the nozzle fitting member and is exposed to the outside.

Wherein at least one of the motor, at least one of the motors is provided with at least two of the plurality of nozzles, at least one of the nozzles, at least one of the nozzles, And the nozzle coupling member may be configured to provide power for rotating the nozzle coupling member.

Wherein the plurality of nozzle tubes, the nozzles, and the nozzle actuators are correspondingly arranged in the same number in a one-to-one correspondence, wherein the blowing unit includes: a blowing fan for blowing air at a high speed by boosting air introduced from the outside; And a direction changing wall arranged in front of the air blowing fan and switching the traveling direction of the high speed air raised by the blowing fan to a radial direction, And the liquid ejected through the nozzle may be configured to fly in the discharged air.

Wherein the plurality of nozzle tubes, the nozzles, and the nozzle actuators are correspondingly arranged in the same number in a one-to-one correspondence, wherein the blowing unit includes a blowing fan for blowing air at a high speed by boosting the air introduced from the outside, And a plurality of curved bent ducts for guiding the discharged high-speed air to be discharged in a plurality of different directions, wherein the plurality of nozzles are disposed at air outlets of the plurality of ducts, The jetted liquid can be configured to fly on high-speed air discharged through the air outlet of the duct.

The liquid scattering apparatus of the present invention can spray the liquid in an appropriate amount by changing the spraying direction of the liquid by rotating the nozzle, and even when spraying the liquid simultaneously in various directions through the plurality of nozzles, It is possible to concentrate the point to a specific point, or to control the liquid dispensing direction so as to distribute more evenly.

1 is a perspective view showing a liquid scattering apparatus according to an embodiment of the present invention.
Fig. 2 is a schematic diagram for explaining an internal configuration of the liquid supply unit of Fig. 1. Fig.
3 is an enlarged perspective view of a portion III in Fig.
4 is an exploded perspective view showing the air blowing unit of Fig.
5 is an exploded perspective view showing a blowing unit according to a modified example of FIG.

Hereinafter, a liquid scattering apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The terminology used herein is a term used to properly express the preferred embodiment of the present invention, which may vary depending on the intention of the user or operator or the custom of the field to which the present invention belongs. Therefore, the definitions of these terms should be based on the contents throughout this specification.

FIG. 1 is a perspective view showing a liquid scattering apparatus according to an embodiment of the present invention, FIG. 2 is a schematic structural view for explaining an internal configuration of the liquid supply unit of FIG. 1, An enlarged view is a perspective view. 1 to 3, the liquid scattering apparatus 10 according to the embodiment of the present invention is an apparatus for spraying liquid pesticides or nutrients in various directions on a cultivated land, and includes a liquid supply unit 20, an air blowing unit 40 ), And a mobile unit (11). The liquid supply unit 20 is, for example, a unit for ejecting liquid such as agricultural chemicals and nutrients through a plurality of nozzles 30. The air blowing unit 40 is a unit for raising the air to blow air toward the plurality of nozzles 30 at a high speed and the moving unit 11 is configured to mount the liquid supply unit 20 and the air blowing unit 40 Unit. The mobile unit 11 is provided with a driver's seat 16 that can be operated by an operator and has four wheels 13 so as to be able to move to the wheel rolling like a car. Although not shown, the mobile unit 11 may include an engine (not shown) that generates power for rolling the wheels 13 and operating the pump 24 in the liquid supply unit 20.

The liquid supply unit 20 is installed behind the driver's seat 16 and inside the central case 18 at the center of the liquid scattering apparatus 10. [ The liquid supply unit 20 includes a tank 22, a pump 24 and a branch pipe 25 in the center case 18 and ten nozzle pipes 22 projecting out of the central case 18, (27), and ten valves (26), one for each nozzle tube (27). Liquid is received in the tank 22, and the liquid flowing out of the tank 22 flows through the nozzle pipe 27. The pump 24 increases the pressure so that the liquid contained in the tank 22 is discharged at a high pressure. The branch pipe 25 is connected in parallel with the ten nozzle pipes 27 so that the liquid discharged from the pump 24 is distributed and flowed along the ten nozzle pipes 27. [ The ten nozzle tubes 28 protrude rearward of the central case 18 through the direction changing wall 59 which is one side wall of the central case 18 and are provided with ten nozzle tubes A nozzle 30 is provided at one end of the nozzle 27 so as to eject liquid.

The ten nozzles 30 are rotatably coupled to the ten nozzle tubes 27, respectively. Specifically, each of the nozzles 30 has a cylindrical nozzle body 31 rotatably coupled to the nozzle tube 27, a nozzle hole 31 protruding from the outer circumferential surface of the nozzle body 31, And a nozzle protrusion 33 formed with a nozzle 34 formed thereon. The portion where the nozzle tube 27 and the nozzle body 31 are connected and the portion where the nozzle body 31 and the nozzle protrusion 33 are connected are opened but the end of the nozzle body 31 is closed, The liquid that has flowed into the pipe 27 is ejected to the outside only through the nozzle through-hole 34.

The liquid supply unit 20 further includes a nozzle actuator 36 that rotates the nozzle 30 so that the liquid ejection direction of the nozzle 30 is changed. The nozzle actuator 36 includes a motor 37 and a nozzle coupling member 38 coupled to the nozzle 30 and rotated by the power of the motor 37. The nozzle coupling member 38 is a cylindrical member surrounding the nozzle body 31. A nozzle protrusion through hole 39 is formed in the nozzle coupling member 38 such that the nozzle protrusion 33 penetrates through the nozzle coupling member 38 and is exposed to the outside.

When the nozzle engaging member 38 rotates in the direction of the arrow shown in Fig. 3 with respect to the longitudinally extending center line, the nozzle protruding portion 33 is pushed by the inner circumferential surface of the nozzle protruding through hole 39, And is rotated together with the engaging member 38. Therefore, when the nozzle coupling member 38 is rotated within a range of 360 degrees, the liquid ejection direction through the nozzle through-hole 34 is changed.

The nozzle coupling member 38 and the motor 37 are provided in the same number in a one-to-one correspondence. Therefore, the liquid ejection directions of the ten nozzles 30 can be removed so as to be changed differently from each other. The mechanical elements for transmitting the power of the motor 37 to the nozzle coupling member 38 are variously adoptable and are not described in detail in the drawings. Further, although not shown in detail in the drawing, the motor 37 may be installed inside the central case 18 or may be installed in the air blowing unit 40.

2, the motor 37 and the nozzle coupling member 38 are provided correspondingly in the same number. In contrast, in the embodiment shown in FIG. 2, the number of the motors 37 corresponds to the number of the nozzle coupling members 38 May be provided in a smaller number. In the case where only two motors are provided for the ten nozzle coupling members 38, two motors may be configured to provide power to rotate each of the five nozzle coupling members 38, One motor may be configured to provide the power to rotate the ten nozzle coupling members 38 when only one motor is provided for the motor 38. [

4 is an exploded perspective view showing the air blowing unit of Fig. Referring to FIGS. 1 and 4 together, the blowing unit 40 includes a blowing fan 43, an air inflow guide 41, a blowing guide 50, and a direction changing wall 59. The blowing fan 43 pressurizes the air introduced from outside and blows it at a high speed. The air inlet guide 41 guides the air outside the blowing unit 40 to the inside of the blowing fan 43. The direction changing wall 59 is a side wall of the center case 18 and is disposed in front of the blowing fan 43 so as to guide the traveling direction of the high speed air raised by the blowing fan 43 in the radial direction. . The airflow guide 50 guides high-speed air, which is interposed between the air blowing fan 43 and the direction changing wall 59, to the direction changing wall 59.

The air blowing fan 43 and the airflow guide 50 each have bodies 44 and 51 which are in tight contact with each other and central through holes 46 and 53 formed at the center of the bodies 44 and 51. The central through holes (46, 53) are connected in a line to form a passage through which the pressurized air flows in the blowing unit (40). A rotary vane 48 is disposed in the central through hole 46 of the blowing fan 43 and the rotary vane 48 is configured to be rotatable in one direction with respect to a rotation axis RCL1 parallel to the X axis. A motor (not shown) may be provided in the central case 18 to provide power to rotate the rotary vanes 48. [ A central vane 53 of the airflow guide 50 is provided with a fixed vane 55 for guiding to the direction changing wall 59 by minimizing the pressure drop of the raised high velocity air.

A high velocity air blown by the direction changing wall 59 emitted from the air guide 50 to the direction of rotation of the rotation axis RCL1 is formed between the body 51 of the air guide 50 and the direction changing wall 59, The air discharge guide vane 56 is fixedly installed. The air discharge guide vane 56 is provided with a plurality of air distribution vanes 57 spaced apart from each other to distribute the air flow unevenly.

The ten nozzle tubes 27 extend in the interior of the central case 18 through the direction changing wall 59 and protrude rearward and are provided with ten nozzles 30 ) Is disposed on the flow path of the air discharged in the radial direction. Specifically, each nozzle 30 is disposed between a pair of dispersing vanes 57 adjacent to each other. With this configuration, the liquid ejected through the nozzle through-holes 34 (see FIG. 2) of the respective nozzles 30 is carried by the air discharged in the radial direction, and then flows down to a long distance before falling. At this time, if the direction of the nozzle through hole 34 is changed by the operation of the nozzle actuator 36 (see FIG. 2), the liquid ejection direction is changed and the liquid flying direction and distance are changed.

FIG. 5 is an exploded perspective view showing a blowing unit according to a modification of FIG. 4. Referring to FIG. 5, the blowing unit 60 according to the modification of the present invention includes a blowing fan 63, , A ventilation guide (70), and a duct assembly (80). The air blowing fan 63 pressurizes the air introduced from the outside, flows at a high speed, and discharges the air toward the duct assembly 80. The airflow guide 70 is interposed between the air blowing fan 63 and the duct assembly 80 to guide the raised high-speed air to the duct assembly 80. The duct assembly 80 has ten ducts 87 through which the elevated high velocity air is discharged in ten different directions. The air inlet guide 61 guides the air outside the blowing unit 60 to the inside of the blowing fan 63.

The air blowing fan 63, the air blowing guide 70 and the duct assembly 80 are respectively provided with bodies 64, 71 and 81 which are in close contact with each other in a row and a central through hole 66 formed at the center of the bodies 64, , 73, not shown). And central passages 66 and 73 (not shown) are connected in series to form a passage through which the pressurized air flows in the air blowing unit 60. A rotary vane 68 is disposed in the central through hole 66 of the air blowing fan 63 and the rotary vane 68 is configured to be rotatable in one direction with respect to a rotation axis RCL2 parallel to the X axis. A motor (not shown) may be provided within the central case 18 (see FIG. 1) to provide power to rotate the rotating blades 68.

A central vane 73 of the airflow guide 70 is provided with a fixed vane 55 for guiding the pressurized high-velocity air to the central through hole 63 of the duct assembly 80 with a minimum pressure drop. The high speed air that has passed through the central through hole 73 of the airflow guide 70 and enters the central through hole (not shown) of the duct assembly 80 flows into the ten ducts 87 without loss of the flow rate. The ten ducts 87 are each a member in the form of a pipe having a larger cross-sectional area of the air outlet 88 than an air inlet (not shown), and the portion between the air inlet and the air outlet 88 is curved And is formed to bend. The ten ducts 87 are disposed between the center case 18 (see FIG. 1) and the body 81 of the duct assembly 80 and are arranged radially relative to the rotation axis RCL2 of the rotary vane 68 the air outlet 88 is opened toward the outside of the body 81 so as to discharge the air that has been increased in the direction of the arrows.

The nozzles 30 (see FIG. 2) at the distal end of the ten nozzle tubes 27 are respectively disposed in the air outlets 88 of the ten ducts 87. With this configuration, the liquid ejected through the nozzle through-holes 34 (see FIG. 2) of the respective nozzles 30 is carried by the high-speed air discharged through the air outlets 88, Further, the contact time with high-pressure high-speed air is increased, and the droplets are sprayed into smaller droplets. At this time, if the direction of the nozzle through hole 34 is changed by the operation of the nozzle actuator 36 (see FIG. 2), the liquid ejection direction is changed and the liquid flying direction and distance are changed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

10: liquid scattering device 11: mobile unit
20: liquid supply unit 22: tank
24: Pump 27: Nozzle tube
30: nozzle 36: nozzle actuator
37: motor 38: nozzle coupling member
40, 60: air blowing unit 43, 63: blowing fan

Claims (6)

delete delete A nozzle accommodating a liquid, a nozzle tube through which liquid flowing out of the tank flows, a nozzle rotatably coupled to the nozzle tube so as to eject the liquid at a distal end of the nozzle tube, A liquid supply unit having a nozzle actuator for rotating the nozzle so that the direction of ejection is changed; And
And an air blowing unit for raising the air and blowing the air toward the nozzle at a high speed,
Wherein the nozzle actuator includes a motor and a nozzle coupling member coupled to the nozzle and rotated by the power of the motor,
Wherein the nozzle has a nozzle body rotatably coupled to the nozzle tube and a nozzle protrusion protruding from an outer circumferential surface of the nozzle body and having a nozzle hole through which liquid is ejected,
Wherein the nozzle engagement member is a cylindrical member that surrounds the nozzle body, and a nozzle projection through hole is formed through the nozzle engagement member to expose the nozzle projection member to the outside. The method of claim 3,
Wherein the nozzle tube, the nozzle, and the nozzle coupling member are provided in a plurality of the same number in a one-to-
Wherein the motor is provided with a number smaller than the number of the nozzle engagement members so that at least one of the motors is configured to provide power for rotating at least two nozzle engagement members. The method of claim 3,
Wherein the plurality of nozzle tubes, the nozzles, and the nozzle actuators are provided in the same number in a one-to-
The air blowing unit includes a blowing fan for blowing air at a high speed by blowing air from the outside, and a fan disposed in front of the blowing fan, the direction of the high-speed air being raised by the blowing fan in a radial direction And a direction changing wall for changing the direction of rotation of the driving motor,
Wherein the plurality of nozzles are disposed on a flow path of the air discharged in the radial direction, and the liquid ejected through the nozzle is configured to fly on the discharged air. The method of claim 3,
Wherein the plurality of nozzle tubes, the nozzles, and the nozzle actuators are provided in the same number in a one-to-
The air blowing unit includes a blowing fan for blowing air at a high speed by blowing air from the outside, and a plurality of curved bent portions for guiding the high-speed air raised by the blowing fan to be discharged in a plurality of different directions A duct is provided,
Wherein the plurality of nozzles are disposed at air outlets of the plurality of ducts so that the liquid ejected through the nozzles is caused to fly by the high-speed air ejected through the air outlets of the duct.

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