KR101232340B1 - Airfog spray apparatus - Google Patents

Abstract

PURPOSE: An air fog generator is provided to increase the speed of a gas passing through a gas-liquid mixing unit by using an air guide groove to minimize an ejected water droplet even when the supplied air is at a low pressure, thereby minimizing damage to plants. CONSTITUTION: An air fog generator includes a cylindrical first housing(12), a cone-shaped second housing(14), a hydraulic adjustor(20), and a gas-liquid mixing unit(30). The cylindrical first housing comprises an inlet port(1) prepared with a mutual screw-coupling. The cone-shaped second housing comprises an air supply port(2) and a nozzle hole(3). The gas-liquid mixing unit is provided in the inside of the housing and controls water pressure to uniformly supplied to the nozzle hole. The gas-liquid mixing unit is prepared inside the housing to mix liquid discharged from the hydraulic adjustor and air flowing in through the air supply port, thereby ejecting the same in the form of minute water droplets through the nozzle hole. The discharge pressure of the hydraulic adjustor is greater than the air pressure of the gas-liquid mixing unit. The gas-liquid mixing unit includes a nozzle body, a pin capacitor, and a cone-shaped nozzle tip. The nozzle tip includes multiple air guide grooves in a generatrix direction.

Description

Airfog Spray Apparatus

The present invention relates to an air fog generator, and more particularly, to an air fog generator that sprays a constant spray amount at low air pressure and prevents residual water remaining inside the nozzle when the spray stops.

In general, since greenhouses and barns are closed spaces disconnected from the external environment, workers must properly adjust the indoor environment to ensure the growth of the plants or animals to be reared properly.

 The air fog generator is effectively used to maintain the indoor humidity and temperature of the greenhouse properly or to control the greenhouse or the barn chemicals. Control using air fog generators can save time and money compared to the use of manpower, and can minimize the risk of human injury due to drugs.

Conventional air fog generators include a spray method (see literature below) including a pump for transporting liquid at high pressure and a fine nozzle for spraying the transport liquid in the form of droplets, and a pump and injection pressure control for transporting liquid at low pressure. There is a spray method using an air compressor for. The former method is often troubled because the spraying distance is short and the fine nozzle is easily clogged by foreign matter contained in the liquid. The latter method is large in particle of water and the unsprayed water is easily damaged by the plants. Due to the structure, it is not easy to control the spray amount constantly.

Korea Utility Model Registration No. 20-0636828 (2004.09.23.)

The air fog generating device according to an embodiment of the present invention can control the spray amount constantly and to prevent the remaining water inside the nozzle when the injection stops flowing down.

An air fog generator according to an aspect of the present invention is a cylindrical first housing having a water supply port is provided to be screwed to each other and a second housing of the conical shape having an air supply port and a nozzle port, and is provided in the housing A liquid pressure adjusting unit for adjusting the water pressure to be supplied to the nozzle port, and a gas-liquid mixing unit which mixes the liquid discharged from the liquid pressure adjusting unit and the air flowing through the air supply port to spray fine droplets through the nozzle hole. It may include.

In addition, the discharge pressure of the hydraulic pressure adjusting portion may be greater than the air pressure of the gas-liquid mixing portion.

In addition, the hydraulic pressure adjusting unit includes a circumferential flow path, wherein the circumferential flow path is arranged in a zigzag form of a plurality of partition walls on the circumferential surface of the cylindrical body to provide a fine flow path and partition the inlet and outlet of the fine flow path, the liquid is When the inlet is provided at the center of the front side of the circumferential flow passage may move along the micro-channel and exit to the exit provided at the center of the rear side.

In addition, the gas-liquid mixing portion is a nozzle body having an orifice protrusion protruding toward the nozzle port side, a pin cap to elastically wrap the orifice protrusion of the nozzle body, and a cone-shaped nozzle covering the pin cap and spaced apart from the inner wall of the second housing. Including a tip, the liquid exiting the outlet of the circumferential flow passage can be released while expanding the pin cam to elastically wrap the orifice projection.

In addition, the nozzle tip may be provided with a plurality of air guide groove in the bus bar direction.

The air fog generating device according to an embodiment of the present invention is to ensure that the liquid is always supplied to the nozzle at a constant pressure irrespective of the pressure of the liquid supplied to the hydraulic pressure adjustment unit, the gas-liquid mixture is adjusted to supply the air pressure inside the nozzle when the injection stops This can effectively prevent the residual water from flowing down.

In addition, the air fog generating device according to an embodiment of the present invention by increasing the flow rate of the gas passing through the gas-liquid mixing unit to the air guide groove, even if the pressure of the supplied air is low, the sprayed water droplets can be minimized to minimize plant damage have.

1 is a perspective view of a combined air fog generator according to an embodiment of the present invention.
2 is an exploded perspective view of the air fog generator according to an embodiment of the present invention.
3 is a cross-sectional view illustrating a non-operation state as a combined cross-sectional view of the air fog generator according to an embodiment of the present invention.
4 is a diagram illustrating an operating state as a combined cross-sectional view of the air fog generator according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below are provided by way of example so that those skilled in the art will be able to fully understand the spirit of the present invention. The present invention is not limited to the embodiments described below, but may be embodied in other forms. In order to clearly explain the present invention, parts not related to the description are omitted from the drawings, and the width, length, thickness, etc. of the components may be exaggerated for convenience. Like numbers refer to like elements throughout.

1 is a perspective view showing an air fog generator according to an embodiment of the present invention, Figure 2 is an exploded perspective view of Figure 1, Figures 3 and 4 is a combined cross-sectional view.

Referring to the drawings, the air fog generating device 100 of the present embodiment is a housing 10 is provided with a water supply port 1, the air supply port 2 and the nozzle port 3, respectively, in the housing 10 The liquid-pressure adjusting unit 20 for adjusting the pressure of the water to be supplied and supplied to the nozzle port and the gas-liquid mixing part for spraying fine water droplets through the nozzle hole 3 by mixing water and air supplied into the housing ( 30).

The housing 10 includes a cylindrical first housing 12 in which a water supply port 1 is provided, and a second conical housing 14 in which an air supply port 2 and a nozzle port 3 are provided. The nozzle port 3 is provided in the housing 10 in the horizontal direction with respect to the water inlet 1, and the air supply port 2 is provided in the vertical direction. The first housing 12 and the second housing 14 each have a hollow inside and are coupled to each other through the spirals 16 and 18. In the internal hollow of the housing 10, the hydraulic pressure adjusting unit 20 and the gas-liquid mixing unit 30 are sequentially provided from the water supply port 1 toward the nozzle port 3.

The hydraulic pressure adjusting unit 20 includes an inflow passage 22, a circumferential flow passage 24, and an outgoing flow passage 28 in which the interior is in communication with each other. The introduction passage 22 and the extraction passage 28 are provided in the form of a pipe, and the circumferential passage 24 arranges a plurality of partitions 26 in a zigzag form on the circumferential surface of the cylindrical body to provide a fine passage 27. The inlet and the outlet of the fine flow passage 27 are partitioned, and when the liquid flows from the inlet flow passage 22 into the inlet provided at the front center of the main flow passage 24, the liquid flows along the micro flow passage and is provided at the rear center. Exit to the exit. The outlet of the circumferential flow passage 24 is in communication with the withdrawal flow passage 28. In addition, a soft diaphragm 25 is provided in front of the main flow passage 24 so that the liquid flows into the main flow passage 24 through the diaphragm 25 only when the liquid is supplied above a proper hydraulic pressure.

Cylindrical seal rings 21 and 29 are provided in front and rear of the hydraulic pressure adjusting unit 20, respectively.

The gas-liquid mixing unit 30 covers the cylindrical nozzle body 32, the pin cap 35 elastically surrounding the orifice protrusion 34 of the nozzle body 32, and the second housing 14 covering the pin cap 35. Conical nozzle tip 37 is provided spaced apart from the inner wall of the).

 The nozzle body 32 has one end in contact with the cylindrical seal ring 29 and is fixed in the housing 10. The nozzle body 32 has a protrusion pin 33 protruding in the other end (nozzle mouth side) direction. Protrusion pin 33 has a pin hole (33a) in the middle portion and has an orifice protrusion (34) at the end.

The pin cap 35 has a cap shape and has a pin cap flow path 36 formed in the center in the longitudinal direction with a large diameter and a small diameter, the projection pin 33 is fitted in the large diameter and the orifice protrusion 34 in the small diameter Is forced fit. The liquid flowing into the pin cap 35 is changed from the inside of the protrusion plate 33 to the outside while passing through the pin hole 33a on the large diameter side, and the small diameter closed by the orifice protrusion 34 according to the hydraulic pressure. The side pin cap flow path 36 is selectively opened.

Like the second housing 14, the nozzle tip 37 has a conical shape, and includes a nozzle hole 38 at a vertex of the cone. This nozzle hole 38 is provided narrower than other liquid flow paths in the housing. In addition, the conical surface of the nozzle tip 37 is provided to be spaced apart from the inner diameter of the second housing 14 to form an air passage therebetween. The air flow path communicates with the air supply port 2 provided in the second housing 14 to guide the air to the nozzle hole 38. The conical surface of the nozzle tip 37 is provided with a plurality of air guide grooves 39 for increasing the flow rate of air in the bus bar direction.

Next, the operation of the air fog generator according to the present embodiment provided as described above will be described.

Prior to operation description, a water storage tank (not shown) is connected to the water supply port 1 of the air fog generator. The water in the storage tank is supplied through the low pressure pump, and the water supplied is determined by the solenoid valve after the foreign matter is removed through the filter member. In addition, the air supply port 2 of the air fog generator is connected to the air compressor not shown. The proper pressure required to generate air fog is controlled by a regulator, and the solenoid valve determines whether air is supplied to each air fog generator. A plurality of air fog generators are installed at a predetermined distance in one greenhouse or barn, and each air fog generator may be collectively controlled through the above-described solenoid valves.

To generate air fog, air is supplied first, and water is supplied after about 10 seconds. If water is supplied first, water is not sprayed and flows down through the nozzle hole 38. On the other hand, if the supplied air pressure is high, the air pressure flows back into the pin cap flow path 36 of the nozzle tip 37 and the pin cap 35, so that the water supplied cannot pass through the orifice protrusion 34, so that the hydraulic pressure adjusting unit ( The hydraulic pressure output from 20 should be at least greater than the air pressure supplied to the hydraulic pressure adjusting unit 20.

As the liquid introduced into the housing 10 through the water inlet 1 passes through the diaphragm 25 and the circumferential flow passage 24 of the hydraulic pressure adjusting unit 20, the discharge pressure is constant. The constant discharge pressure enlarges and opens the pin cap flow path 36 of the pin cap 35 forcibly fitting the orifice protrusion 34, and the liquid passing through the pin cap flow path 36 is pressurized while exiting the fine nozzle hole 38. do. The pressurized liquid is mixed with the air supplied to the air flow path and discharged into the atmosphere, thereby rapidly expanding and spraying the droplets.

Here, in the above embodiment, but spraying the air fog by supplying water to the air fog generating device, the present invention is not limited to this, of course, it may be possible to control the operation when connecting the chemical tank.

1..Supply port 2..Air supply port
3. Nozzle 10. Housing
20.Hydraulic adjustment part 24.Wonder oil passage
25. Diaphragm 30. Pressure mixture
32. Nozzle body 35. Pin cap
37..Nozzle tip

Claims (5)

delete A cylindrical first housing having a water supply port provided to be screwed together and a second conical housing having an air supply port and a nozzle port, and constantly adjusting the pressure of water supplied in the housing to supply the nozzle port And a gas-liquid mixing unit for mixing the liquid discharged from the hydraulic pressure adjusting unit and the air introduced through the air supply port to spray fine water droplets through the nozzle hole,
And a discharge pressure of the hydraulic pressure adjusting part is greater than an air pressure of the gas-liquid mixing part. A cylindrical first housing having a water supply port provided to be screwed together and a second conical housing having an air supply port and a nozzle port, and constantly adjusting the pressure of water supplied in the housing to supply the nozzle port And a gas-liquid mixing unit for mixing the liquid discharged from the hydraulic pressure adjusting unit and the air introduced through the air supply port to spray fine water droplets through the nozzle hole,
The hydraulic pressure adjusting unit includes a circumferential flow path, wherein the circumferential flow path is provided with a plurality of partition walls arranged in a zigzag form on the circumferential surface of the cylindrical body to provide a micro flow path, and the inlet and the outlet of the micro flow path are partitioned so that the liquid flows into the main flow path. When the inlet is provided in the center of the front side of the airfog generator for moving along the micro-path and exit to the outlet provided in the center of the rear side. The method of claim 3, wherein
The gas-liquid mixing part includes a nozzle body having an orifice protrusion protruding toward the nozzle port, a pin cap elastically surrounding the orifice protrusion of the nozzle body, and a cone-shaped nozzle tip covering the pin cap and spaced apart from the inner wall of the second housing. And an air fog generator, wherein the liquid exiting the outlet of the circumferential flow path escapes while expanding the pin cam that elastically surrounds the orifice protrusion. 5. The method of claim 4,
The nozzle tip is an air fog generating device having a plurality of air guide groove in the bus bar direction.

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