KR20210157293A - External type 2 fluid fog forming device - Google Patents

Abstract

An object of the present invention is to provide a dual-flow fog device capable of generating fine fog only by supplying compressed air without a separate liquid fluid supply pump. The present invention comprises: an external nozzle body (10) in which a liquid passage (12) is formed; an internal nozzle body (20) disposed on the upper side of the external nozzle body (10), having a liquid inlet (22) communicating with the liquid passage (12) in the center thereof, and having a nozzle tube body (21) with a plurality of air valleys (24) in the longitudinal direction on the outer circumferential surface on the upper side thereof; an air nozzle body (30) disposed on the upper side of the external nozzle body (10) and having a pneumatic chamber (34) to be filled with air supplied through a supply tube body (32) formed in the vertical direction to the liquid passage (12) while accommodating the internal nozzle body (12) therein; and a mixing chamber (40) communicating with the pneumatic chamber (34), formed on the upper part of the liquid inlet (22) of the internal nozzle body (20) and partially accommodating the end of the nozzle tube body (21) to mix liquid and air and generate fog, and formed with a fog injection port (42) at one end. When using the external type dual-flow fog device, some of the air moving from the pneumatic chamber to the mixing chamber is injected in an oblique direction, and the remaining part is injected in a straight direction to form two types of airflows. Therefore, by improving the liquid shearing efficiency, fine fog can be generated even with a small amount of air.

Description

External type 2 fluid fog forming device}

The present invention is a two-fluid fog forming device that generates fine fog using compressed air and a liquid fluid. To explain this in more detail, it is a fog device capable of generating fine fog only by supplying compressed air without a separate liquid fluid supply pump. it's about

In general, fog forming devices use liquid particles such as mist for the purpose of spraying chemicals or controlling humidity and temperature in greenhouses, livestock houses, industries, government buildings, offices, agricultural products warehouses, factories, etc. where various vegetables and horticultural crops are grown. As a spraying device, an injector-type high-pressure compressed air injection type is used to subdivide liquid particles, but it is expensive and complicated in structure, so maintenance is difficult due to failures including clogging. Because it is a configuration that forms fog by doing so, there is a limit to subdividing a large amount of water.

Accordingly, the present applicant in Patent Registration No. 10-1525600, a low-pressure fog that forms fog at low pressure, an inlet hole through which compressed air is introduced, and an expansion part connected to the inlet hole and throttling inside the injection pipe. The first coupler and the injection tube are formed in a straight line on the body to form the venturi tube, the second coupler is formed at a right angle to the first coupler, and the flow path communicated with the coupling tube of the low pressure fog so as to communicate with the throttling inside. It is composed of a combination of a venturi nozzle that subdivides water particles discontinuously supplied from the low-pressure fog by forming a A technology that maximizes water subdivision efficiency while minimizing water and compressed air (fluid) usage by configuring to fit into the second coupling port of the venturi nozzle to provide fine fog formation has been previously registered. Due to the nature of the masonry, the particles generated in the low-pressure fog generator, the primary subdivision process, pass through the long nozzle tube and aggregate into coarse particles and flow into the venturi, so there is a limit to crushing a large amount of water. There were cases where this was not good.

In order to overcome the above problem, in another patent registration No. 10-1965427 of the present applicant, a low-pressure fog generator is provided so that the liquid is first subdivided through the primary subdivision nozzle hole of the nozzle body and sprayed into micro particles; Installed on the upper part of the nozzle body, a conical pneumatic chamber filled with compressed air is formed, and a secondary subdivision nozzle hole is provided so that the fog mixed with compressed air and liquid micro particles is sprayed at a position concentric with the primary subdivision nozzle hole fog generation unit; is made, and the liquid micro-particles sprayed from the first sub-division nozzle hole are moved to the second sub-division nozzle hole via the pneumatic chamber, and the first sub-division in the section where the liquid micro particles pass through the pneumatic chamber A technology has been previously proposed in which a composite shearing force according to the compressed air flow rate acts in a 360° direction around the nozzle hole, causing the secondary pulverization to spray the fog into the second subdivision nozzle hole.

However, the aforementioned two types of fog devices are internal (internal type) fog devices in which the position of the liquid fluid inlet is located inside the air injection port, which subdivides fluid particles with a relatively small amount of compressed air consumption to create micro Although it can be supplied as a unit of fine particles, a separate pump was required to supply liquid fluid, a separate water (liquid) line had to be supplied and supplied to several nozzles. Accordingly, there was a disadvantage that the installation cost was high.

For example, when spraying a small number of nozzles, about 10 or so, in a narrow space, the equipment cost is high to use a separate pump, and design difficulties follow. That is, if pneumatic and hydraulic pressure are not properly designed, it is very difficult to provide granular water particle quality.

Therefore, an external type (external type) that can provide fine fog with only compressed air and an air conditioner at low facility cost without a separate pump The need for a device arose.

KR 10-1525600 B1 (2015.05.28.) KR 10-1965427 B1 (2019.03.28.)

In the present invention, a new technology has been devised to solve the problems of the prior art, some of the air moving from the pneumatic chamber to the mixing chamber is sprayed in an oblique direction, and the remaining part is sprayed in a straight direction. It is an object of the present invention to provide an external type two-way fog device capable of atomizing the fog spray particle size as much as possible.

Another object of the present invention is to provide an external type dual flow fog device capable of generating fog by sucking a liquid without a pump by lowering the pressure of a mixing chamber that is an inlet space of a liquid inlet.

As a specific means for solving the problems of the present invention, the present invention constitutes an external-type transfer fog device, and an external nozzle body 10 having a liquid flow path 12 penetrating vertically in the center; The nozzle body is disposed on the upper side of the outer nozzle body 10, the liquid inlet 22 communicating with the liquid passage 12 is formed in the center, and the nozzle tube body having a plurality of air valleys 24 on the outer circumferential surface in the longitudinal direction on the upper side (21) the inner nozzle body 20 is formed; It is disposed on the upper side of the outer nozzle body 10, and while accommodating the inner nozzle body 20 inside, the air supplied through the supply pipe body 32 formed in the vertical direction to the liquid passage 12 is pneumatic so that it is filled. Air nozzle body 30 in which the seal 34 is formed; And it communicates with the pneumatic chamber 34, is formed in the upper portion of the liquid inlet 22 of the inner nozzle body 20, the end of the nozzle tube body 21 is partially accommodated to mix the liquid and air to generate fog, and at one end It characterized in that it comprises a; mixing chamber 40 in which the fog injection port 42 is formed.

The outer diameter of the nozzle tube body 21 is expanded compared to the inner diameter of the mixing chamber 40, and the inclined surfaces 23 and 41 formed at the end of the nozzle tube body 21 and the inlet of the mixing chamber 40, respectively, are spaced apart from each other in a non-contact state. An inclined flow path 100 for spraying the air of the pneumatic chamber 34 into the mixing chamber 40 at an inclination angle is formed, and the virtual circle C connecting the inner floor of the air valley 24 is the mixing chamber 40 It is formed with a small size compared to the inner diameter, and is provided to form a straight flow path 200 that is linearly sprayed when the air in the pneumatic chamber 34 rides the air trough 24 and flows into the mixing chamber 40. .

At this time, the fog injection hole 42 is formed to have a smaller size compared to the inner diameter of the mixing chamber 40, and the mixing chamber 40 has a partition wall 44 at the end of the fog injection hole 42 due to the difference in inner diameter with the fog injection hole 42. is formed, and the oblique airflow and the linear airflow injected into the mixing chamber 40 through the inclined passage 100 and the straight passage 200 are blocked by the partition wall 44 to form a compressed velocity gradient. characterized in that

In addition, a fastening protrusion 13 is formed on the upper end of the external nozzle body 10 concentrically with the liquid passage 12,

A fastening hole 15 into which the fastening protrusion 13 is fitted is formed in the lower inner side of the air nozzle body 30, and a plurality of outward protrusions 38 are protruded from the lower outer side, and the air nozzle body 30 ) and the nut 16 provided to mutually fasten the outer nozzle body 10 has an open upper portion, and a plurality of nut 16 for pressing the outward projection 38 of the nozzle body 30 from the upper side of the nut 16 is provided. The binding rim 18 is formed to protrude inward, and a plurality of fastening grooves 17 are formed between the binding rims 18 for the outward projection 38 of the air nozzle body 30 to pass therethrough. do.

In addition, an auxiliary protrusion 39 having a shorter protrusion length than the outward protrusion 38 is formed on the upper side of the outward protrusion 38 , and the auxiliary protrusion 39 is caught on at least one of the binding rims 18 . It is characterized in that the locking protrusion 19 is protruded so that the binding rim 18 of the nut 16 can be stably positioned on the outward projection 38 of the air nozzle body 30 .

In addition, a key 26 is formed to protrude from the center of the inner nozzle body 20 in the longitudinal direction, and a key groove 36 is provided in the lower portion of the air nozzle body 30 to accommodate the inner nozzle body 20 . The fastening hole 35 is formed so that the nozzle tube body 21 having an inclined surface 23 formed at the upper end is always assembled toward the supply tube body 32 .

According to the specific means for solving the above-mentioned problems, the present invention forms two types of airflows in which some of the air moving from the pneumatic chamber to the mixing chamber is sprayed in an oblique direction, and the remaining part is sprayed in a straight direction. By varying the pressure and speed of the airflow, the liquid shearing efficiency is improved, and a small amount of air is used to make the fog spray particle size ultra-fine.

In addition, as the flow rate of compressed air flowing from the pneumatic chamber to the mixing chamber is increased, the pressure in the mixing chamber is lowered, so that the fluid is easily sucked into the liquid inlet without a separate pump device, thereby simplifying the facility.

1 is a perspective view showing a preferred embodiment of the external type transfer fog device provided in the present invention.
2 is an exploded perspective view showing an external type transfer fog device according to an embodiment of the present invention;
3 is a cross-sectional view of FIG.
4 is a longitudinal cross-sectional view showing the internal structure of an external type transfer fog device according to an embodiment of the present invention;
Figure 5 is a state diagram showing the coupling structure of the nut and the air nozzle body in the external type two-way fog device provided in the present invention.
6 is a configuration diagram independently showing an inclined flow path and a straight flow path of the external type transfer fog device of this nickname.
7 is a state diagram illustrating a velocity gradient of compressed air formed at a fog injection port of a mixing chamber in an external type dual flow fog device.
8 is a configuration diagram showing an extended connection structure of an external type of transfer fog device of this nickname.

Hereinafter, the present invention will be described in more detail according to specific embodiments of the accompanying drawings. Technical terms used in this specification are terms selected in consideration of functions in embodiments, and the meaning of the terms may vary according to specific embodiments of the present invention. And throughout the specification, when a part is "connected" with another part, this includes not only the case where it is "directly connected" but also the case where it is "indirectly connected" with another member interposed therebetween. do.

1 is a perspective view of an external transfer fog device according to an embodiment of the present invention as a whole, FIG. 2 is an exploded perspective view showing an external transfer fog device of the present invention, and FIG. 3 is an external transfer fog device It is a cross-sectional view of the fog device disassembled.

The present invention relates to a two-fluid fog forming device used for spraying fine water particles such as mist by applying to facilities such as plastic houses, livestock houses, industries, landfills, sewage treatment plants, etc. Part of the air moving to the mixing chamber is injected in an inclined direction, and the remaining part forms two types of airflows that are injected in a straight direction, and the liquid shearing efficiency is improved by varying the pressure and speed of the two types of airflows. In order to make the fog spray particle size ultra-fine by using positive air, the main configuration includes an external nozzle body 10, an internal nozzle body 20, and an air nozzle body 30 with a mixing chamber formed inside the upper part. is done

2 to 3, in the external nozzle body 10 according to the present invention, a liquid flow path 12 is formed vertically through the center, and a fastening protrusion 13 concentric with the liquid flow path 12 at the upper end. is formed

A hose for supplying liquid to the liquid passage 12 is coupled to the lower end of the external nozzle body 10, and the external nozzle body 10 and the air nozzle body 30 to be described below are mutually coupled to the upper outer circumferential surface. A male threaded portion is formed to be screwed with a nut 16 for.

The inner nozzle body 20 according to the present invention is disposed on the upper side of the outer nozzle body 10, the liquid inlet 22 communicating with the liquid passage 12 is formed in the center, and a plurality of air on the outer circumferential surface on the upper side A nozzle tube body 21 having a valley 24 is formed.

Specifically, the nozzle tube body 21 is formed to protrude in a cylindrical shape in the upper center of the inner nozzle body 20, and a liquid inlet 22 having a lowering light structure is formed inside the inner nozzle body 20. In addition, the nozzle tube body 20 is provided with a plurality of air troughs 24 in the longitudinal direction on the outer circumferential surface, and the air troughs 24 are provided in a radial shape and arranged conformally.

Although the embodiment of the present invention exemplifies the case in which there are four airgols 24, it is natural that the number may be increased or decreased in the range of two to six.

In addition, a key 26 is formed to protrude in the longitudinal direction on the outside of the center side of the inner nozzle body 20 so that it is always coupled to the air nozzle body 30 to be described later in a constant direction.

The air nozzle body 30 according to the present invention is arranged on the upper side of the outer nozzle body 10, and while accommodating the inner nozzle body 20 inside, the air supplied through the supply pipe body 32 is filled with pneumatic pressure. A seal 34 is formed.

The air nozzle body 30 is a supply pipe body 32 formed on one side is formed in the vertical direction to the liquid flow path 12, compressed air is supplied through a compressor (not shown), and the nozzle pipe body 20 inside A pneumatic chamber 34 having an expanded size compared to the outer diameter is formed.

At this time, the air filled in the pneumatic chamber 34 is injected into the mixing chamber 40 to be described later in a 360° direction around the nozzle tube body 20 .

2, the lower portion of the air nozzle body 30 accommodates the inner nozzle body 20, the fastening hole 35 for inserting the fastening protrusion 13 of the outer nozzle body 10 is provided. , a key groove 36 coupled to the key 26 formed in the inner nozzle body 20 is formed in the fastening hole 35 .

The coupling structure of the key 26 and the key groove 36 is for assembling the nozzle tube body 21 with the inclined surface 23 formed at the upper end in a state in which the supply tube body 32 is always arranged in the direction, such an arrangement structure In the present invention, which provides fine fog in micro-particle units, it is possible to provide a stable and uniform fog of particles.

The mixing chamber 40 according to the present invention communicates with the pneumatic chamber 34 and partially accommodates the end of the nozzle tube body 20, mixes liquid and air to generate fog, and a fog nozzle 42 is formed at one end do. Here, the fog injection hole 42 is cut in a straight line so that the fog is sprayed in a fan shape, so that the diffusion direction of the fog can be adjusted according to the coupling direction of the air nozzle body 30 .

The mixing chamber 40 communicates with the pneumatic chamber 34 and is a space formed above the injection hole 22 of the nozzle tube body 20 , and includes liquid injected through the liquid inlet 22 of the nozzle tube body 20 and Air sprayed from the pneumatic chamber 34 is mixed to generate fog in the form of particulates.

4 is a longitudinal cross-sectional view showing the internal structure of the coupled state of the external type transfer fog device of the present invention. When the internal nozzle body 20 is inserted into the fastening hole 35 of the air nozzle body 30 to the end, the nozzle tube body The end of 21 is disposed at a position extending to the inlet of the mixing chamber 40 via the pneumatic chamber 34 of the air nozzle body 30, and thus the fluid supplied through the liquid inlet 22 is mixed with the mixing chamber ( 40) It is provided to be supplied only to the inside.

5 is a state diagram showing the coupling structure of the nut and the air nozzle body in the external type two-way fog device provided in the present invention.

A plurality of outward projections 38 are formed to protrude from the lower outer side of the air nozzle body 30 , and auxiliary projections 39 having a shorter projection length than the outward projections 38 are formed on the upper side of the outward projections 38 . .

The nut 16 is for coupling the air nozzle body 30 and the external nozzle body 10 to each other, and the upper part is opened to accommodate a part of the lower part of the air nozzle body 30 .

In addition, a female screw portion is formed on the inner circumferential surface of the nut 16 to be screw-coupled to the male screw portion formed on the outer nozzle body 10 , and a plurality of for pressing the outward projection 38 of the nozzle body 30 from the upper side The dog binding rim 18 is formed to protrude inward.

At this time, the outward projection 38 of the air nozzle body 30 is penetrated by the plurality of fastening grooves 17 formed between the binding rims 18 and the air nozzle body 30 passes through the upper part of the nut 16 . ) of the lower end can be accommodated.

At least one of the binding rims 18 is formed to protrude a locking protrusion 19 so that the auxiliary protrusion 39 of the air nozzle body 30 described above can be caught.

The coupling method of the nut 16 and the air nozzle body 30 configured as described above will be described with reference to FIG. 5 .

First, in the state in which the inner nozzle body 20 is coupled to the fastening hole 35 of the air nozzle body 30 and the direction of the outward protrusion 38 and the position of the fastening groove 17 are matched, as shown in Fig. 4(a). The outward projection 38 is coupled through the upper opening of the nut 16 .

Then, as shown in FIG. 4(b), when the auxiliary protrusion 39 of the air nozzle body 30 is caught by the locking protrusion 19 formed on the binding rim 18 by turning the air nozzle body 30 counterclockwise, The air nozzle body 30 is no longer rotated and has a constrained state on the horizontal plane, so the binding rim 18 of the nut 16 is stably located on the outward projection 38 of the air nozzle body 30. It has a solid assembly state and vertical restraint force.

Then, when the nut 16 is fastened to the external nozzle body 10 together with the air nozzle body 30 of which the angle is constrained, the final assembly of the external type fogging device as shown in FIGS. 1 and 5 is completed.

On the other hand, the air filled in the pneumatic chamber 34 rides on the outer circumferential surface of the nozzle tube body 20 and the air valley 24 to form two types of jet streams at an inclination angle and a straight line. A detailed description will be given with reference to FIGS. 6 (a) to 6 (b) to be described later.

6 (a) is a configuration diagram showing an inclined flow path in the external type transfer fog device of the present invention, wherein the outer diameter of the nozzle tube body 20 is expanded compared to the inner diameter of the mixing chamber 40 . And at the end of the nozzle tube body 20 and the inlet of the mixing chamber 40, inclined surfaces 23 and 41 are formed, respectively, and these inclined surfaces 23 and 41 are spaced apart from each other in a non-contact state to provide 360 air in the pneumatic chamber 34. An inclined flow path 100 for spraying into the mixing chamber 40 at an inclination angle in the ° direction is formed.

The inclined surfaces 23 and 41 are formed at an inclination angle of 20 to 80 ° with respect to the longitudinal direction of the nozzle tube body 20. If the inclination angle is less than 20 °, the effect on the inclined air flow is insignificant, and when it exceeds 80 ° Since air is not smoothly introduced through the inclined passage due to the steep inclination, it is preferable to form the inclination angle of 20 to 80°.

The inclined surfaces 23 and 41 include a curved surface as well as a flat surface in cross-section.

And, as the inclined air provided through the inclined flow path 100 is sprayed and supplied to pass through the front of the liquid inlet 22 in an oblique direction, the inclined airflows introduced along the inclined flow path 100 in the mixing chamber 40 are collide with each other

6 (b) is a configuration diagram showing a straight flow path, and the virtual circle C connecting the inner bottom of the air valley 24 is formed to have a smaller size compared to the inner diameter of the mixing chamber 40 . And the pneumatic chamber 34 is provided to form a straight flow path 200 through which air is linearly introduced into the mixing chamber 40 while riding the air valley 24 .

At this time, when the cross-sectional area of the linear flow path 200 is formed to be small compared to the cross-sectional area of the inclined flow path 100 , the linear air flow rate injected into the linear flow path 200 is increased compared to the inclined direction air flow rate injected into the inclined flow path 100 .

That is, some of the air moving from the pneumatic chamber 34 to the mixing chamber 40 is sprayed in an inclined direction through the inclined passage 100 , and the remaining part is injected in a linear direction (eg, a nozzle) through the linear passage 200 . As it is injected in the longitudinal direction of the tube body 20), two types of airflows divided into oblique air and linear air are generated inside the mixing chamber 40, and the jetting speed and pressure of the oblique air and the linear air are different from each other. is kept

Therefore, in the mixing chamber 40 of the present invention, as the liquid shearing efficiency is improved by two types of oblique airflows and linear airflows having different injection directions and different injection pressures and speeds, a small amount of compressed air is used. There is an advantage that the fog spray particle size can be ultra-fine.

In addition, the fog injection hole 42 is formed to have a smaller size compared to the inner diameter of the mixing chamber 40, and the mixing chamber 40 has a partition wall 44 at the end of the fog injection hole 42 due to the difference in inner diameter with the fog injection hole 42. this is formed

Accordingly, as shown in FIG. 6 (b), the inclined air and the linear air injected into the mixing chamber 40 through the inclined passage 100 and the linear passage 200 are blocked by the partition wall 44. As shown in Fig. 7, as it is provided to form a flow velocity having a compressed velocity gradient, the water particles and air subdivided in the mixing chamber 40 are discharged from the fog nozzle 42 to the outside. A shear force is generated to make finer particles. In addition, the collision phenomenon of repeated air (airflow) by airflows having different directions is actively performed, and accordingly, internal pressure vibration is generated in the air, which is a compressible fluid, and the action of subdividing the fog particles by the waves is made.

On the other hand, the compressed air filled in the pneumatic chamber 34 passes through the inclined passage 100 and the straight passage 200 having a narrow cross-sectional area to lower the pressure in the inlet space of the liquid inlet 22 , that is, the mixing chamber 40 . will make it

Therefore, simply by connecting the hose to the liquid flow path 12 and connecting it to the liquid to be supplied, the liquid suction efficiency is improved without using a separate supply power source such as a pump, and the liquid supply is used in constructing an external type transfer fog device. Since the pump is omitted, there is an advantage that the facility can be simplified.

8 is a configuration diagram showing an extended connection structure of an external type dual-flow fog device according to an embodiment of the present invention, wherein the external nozzle body 10 is connected to the expansion adapter 50 to spray the fog in multiple directions. provided And the expansion adapter 50 is composed of a main pipe 52 to which the liquid is supplied, and a plurality of multi-pipes 54 branched from the main pipe 52 and connected to the external nozzle body 10 .

As an example, Fig. 8 (a) shows a state in which two multi-pipes 54 are formed in the main tube 52, and the external nozzle body 10 is mounted on each multi-pipe 54, and Fig. 8 ( b) four multi-pipes 54 are formed in the main tube 52, and four external nozzle bodies 10 are mounted on each multi-pipe 54 to form a form capable of spraying fog in four directions. can

The number of applications of the nozzle body 10 is not limited to the shape of FIGS. 8 (a) to 8 (b), and it is also possible to radially expand the number or to arrange multiple layers in the longitudinal direction of the main tube 52 .

As described above, in the detailed description of the present invention, the most preferred embodiment of the present invention has been described, but various modifications are possible within the scope not departing from the technical scope of the present invention. Therefore, the protection scope of the present invention is not limited to the above embodiments, but the protection scope should be recognized from the techniques of the claims to be described later and equivalent technical means from these techniques.

10: external nozzle body
12: liquid flow path 13: fastening protrusion
16: nut 17: fastening groove 18: binding rim 19: locking jaw
20: inner nozzle body
21: nozzle tube body 22: injection hole 23: inclined surface 24: air valley 26: key
30: air nozzle body
32: supply pipe body 34: pneumatic chamber 35: fastening hole 36: keyway
38: extroverted process 39: auxiliary process
40: mixing room
41: slope 42: fog nozzle 44: bulkhead
50: expansion adapter 52: main tube 54: multi tube
100: inclined passage 200: straight passage C: virtual circle

Claims (6)

an external nozzle body 10 through which the liquid passage 12 is vertically penetrating in the center;
The nozzle body is disposed on the upper side of the outer nozzle body 10, the liquid inlet 22 communicating with the liquid passage 12 is formed in the center, and the nozzle tube body having a plurality of air valleys 24 on the outer circumferential surface in the longitudinal direction on the upper side (21) the inner nozzle body 20 is formed;
It is disposed on the upper side of the outer nozzle body 10, and while accommodating the inner nozzle body 20 inside, the air supplied through the supply pipe body 32 formed in the vertical direction to the liquid passage 12 is pneumatic so that it is filled. Air nozzle body 30 in which the seal 34 is formed; and
It communicates with the pneumatic chamber 34, is formed on the upper portion of the liquid inlet 22 of the inner nozzle body 20, and the end of the nozzle tube body 21 is partially accommodated to mix the liquid and air to generate fog, and fog at one end The mixing chamber 40 in which the injection hole 42 is formed; an external type fogging device comprising:
The method of claim 1,
The outer diameter of the nozzle tube body 21 is expanded compared to the inner diameter of the mixing chamber 40, and the inclined surfaces 23 and 41 formed at the end of the nozzle tube body 21 and the inlet of the mixing chamber 40, respectively, are spaced apart from each other in a non-contact state. An inclined flow path 100 for spraying the air of the pneumatic chamber 34 into the mixing chamber 40 at an inclination angle is formed,
The virtual circle (C) connecting the inner floor of the air trough 24 is formed in a size smaller than the inner diameter of the mixing chamber 40, so that the air in the pneumatic chamber 34 rides the air trough 24 and the mixing chamber 40 ) when flowing into the interior, the external type of flow fog device characterized in that it is provided to form a straight flow path (200) that is sprayed in a straight line.
3. The method of claim 2,
The fog injection hole 42 is formed to have a smaller size compared to the inner diameter of the mixing chamber 40, and a partition wall 44 is formed at the end of the mixing chamber 40 due to the difference in inner diameter with the fog injection hole 42. becomes,
The inclined airflow and the linear airflow injected into the mixing chamber 40 through the inclined passage 100 and the linear passage 200 are blocked by the partition wall 44 to form a compressed velocity gradient, characterized in that External type fogging device.
The method of claim 1,
At the upper end of the external nozzle body 10, a fastening protrusion 13 is formed concentrically with the liquid passage 12,
A fastening hole 15 into which the fastening protrusion 13 is fitted is formed in the lower inner side of the air nozzle body 30, and a plurality of outward protrusions 38 are formed protruding from the lower outer side,
The nut 16 provided to mutually fasten the air nozzle body 30 and the external nozzle body 10 has an open top, and the outward projection 38 of the nozzle body 30 is formed on the upper side of the nut 16 from the top. A plurality of binding rims 18 for pressing are formed to protrude inward, and a plurality of fastening grooves 17 for passing through the outward projections 38 of the air nozzle body 30 are formed between the binding rims 18 . An external type fogging device, characterized in that it is formed.
6. The method of claim 5,
An auxiliary protrusion 39 having a shorter protrusion length than the outward protrusion 38 is formed on the upper side of the outward protrusion 38, and the auxiliary protrusion 39 may be caught on at least one of the binding rims 18. External type variant, characterized in that the locking jaw 19 is protruded so that the binding rim 18 of the nut 16 can be stably positioned on the outward projection 38 of the air nozzle body 30 Ryu fog device. 3. The method of claim 2,
A key 26 is formed to protrude in the longitudinal direction on the outside of the center side of the inner nozzle body 20,
A fastening hole 35 provided with a keyway 36 is formed in the lower portion of the air nozzle body 30 to accommodate the inner nozzle body 20, and the nozzle tube body 21 having an inclined surface 23 formed at the upper end thereof is formed. External type fogging device, characterized in that it is always assembled facing the supply pipe body (32).

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