KR101071220B1 - Air jet nozzle - Google Patents

Abstract

The present invention relates to an air jet nozzle capable of purifying an anaerobic anaerobic layer deposited in stagnant bodies of water, such as lakes, dams, and seas. The present invention relates to an air jet nozzle for promoting organic decomposition and oxidation.
Air jet nozzle according to the present invention is coupled to one side of the air pipe for supplying compressed air is a nozzle for injecting compressed air is in communication with the space groove therein;
The injection hole is characterized in that a plurality of inclined upwardly outward with respect to the vertical direction.

Description

Air Jet Nozzle {AIR JET NOZZLE}

The present invention relates to an air jet nozzle capable of purifying an anaerobic anaerobic layer deposited in stagnant bodies of water, such as lakes, dams, and the sea, and more particularly, to increase dissolved oxygen in the anaerobic anaerobic layer deposited in lake water, The present invention relates to an air jet nozzle for promoting organic decomposition and oxidation.

Where there are stagnant waters such as lakes, reservoirs, golf courses, and harbors (hereinafter called 'hoso'), the organic matter contained in the water decomposes and consumes oxygen, resulting in anaerobic waters, which leads to the development of odors and anaerobic decomposition of bottom sediments. And there is a problem such as turbidity due to the rise of suspended solids in the sediment layer by the generated gas and acceleration of water pollution by pollutants introduced from the outside of the appeal.

In particular, due to the loss of self-cleaning ability of the appeal can be a structure that is vulnerable to external pollution due to initial rainwater.

In the general appeal, the water temperature is increased by the solar heat in the shallow water depth, and the water is deeper and heated faster than the place where sunlight does not reach directly, and the water temperature difference occurs according to the water depth. The appealing water of stays in the upper part, and if this phenomenon continues, the water temperature rises, accumulating the latent heat, and the heat exchange between the appealing water (surface water) of the upper part that accumulated the latent heat and the appealing water of the deep part that is not heated. As the latent heat accumulated in the upper part is transferred to the deep part, the appeal water of the upper layer and the appeal water of the deep part are mixed.

The mixing of the appeal water by the heat exchange phenomenon continues until the temperature of the upper layer and the deep layer is the same, and the latent heat of the upper layer is moved to the lower layer by the thermal equilibrium phenomenon.

On the contrary, if the air is cooled after sunset, rapid cooling occurs in the upper part, but latent heat is still accumulated in the lower part, which is opposite to the daytime, and convection of the lake water by heat exchange continues at night.

Of course, if the surface water is cooled by the movement of the air, that is, the wind, the above phenomenon proceeds more quickly.

However, the low depth appeal is warmed temporarily by solar heat during summer, and the water temperature difference by the depth is small, so that the stagnant temperature zone does not form as in the deep depth appeal, and the wind does not blow due to the movement of the atmosphere. It is difficult to expect the convection phenomenon due to the specific gravity difference or heat exchange phenomenon caused by the forced circulation due to the wind wave or the water temperature difference through the cooling action on the water surface.

Therefore, the convection or circulation does not occur in the appeal, so the identity of the appeal water becomes, and eventually, anaerobic phenomenon occurs in the deep appeal zone.

In other words, there is almost no water flow in the lake or stagnant water, it is stagnant, and the anaerobic anaerobic layer is formed by the organic material introduced every year.

If the anaerobic anaerobic layer is not dredged, odorous gas contained in the anaerobic anaerobic layer is generated.

As the organic matters accumulate, the anaerobic anaerobic layer and the increase of the odorous gas are increasing.

The present invention has been made to solve the above problems, by increasing the amount of dissolved oxygen in the anaerobic anaerobic layer deposited in the lake water by spraying compressed air by a nozzle installed on one side of the rod-shaped air pipe, the physical action of the strong air jet In order to provide an air jet nozzle that can make the anaerobic organic layer into small particles and float it with anaerobic gas to remove it, while supplying numerous voids to the anaerobic layer to reduce the aerobic layer and ultimately clean the soil. There is this.

Air jet nozzle according to the present invention for achieving the above object is coupled to one side of the air pipe for supplying compressed air is a nozzle for injecting compressed air is in communication with the space groove therein;

The injection hole is characterized in that a plurality of inclined upwardly outward with respect to the vertical direction.

According to the above-mentioned means for solving the above problems, the compressed air is injected by a nozzle provided on one side of the rod-shaped air pipe to increase the amount of dissolved oxygen in the anaerobic anaerobic layer deposited in the lake water, and the organic layer anaerobicized by physical action by the powerful air jet. Can be made into small particles, floated together with anaerobic gases to remove them, while supplying numerous voids in the anaerobic layer to reduce the aerobic layer and ultimately purify the soil.

1A and 1B are a perspective view and an internal structure diagram of an air jet nozzle according to a first embodiment of the present invention;
FIG. 2 is a state diagram of use of the air jet nozzle shown in FIG. 1A; FIG.
3A and 3B are a perspective view and an internal structure diagram of an air jet nozzle according to a second embodiment of the present invention;
4A and 4B are a perspective view and an internal structure diagram of an air jet nozzle according to a third embodiment of the present invention;
5A and 5B are a perspective view and an internal structure diagram of an air jet nozzle according to a fourth embodiment of the present invention;
FIG. 6 is a use state diagram of the air jet nozzle shown in FIG. 5A; FIG.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

1A and 1B are a perspective view and an internal structure diagram of an air jet nozzle according to a first embodiment of the present invention.

As shown, the nozzle 10 of the air jet according to the first embodiment is a portion where the upper surface 10a and the side 10b abut in a substantially conical shape where the side surface 10b is pointed downward and the upper surface 10a is flat. The inclined surface 10c is formed in the shape.

A space groove 11 is formed in a central portion at a predetermined depth on the upper surface 10a of the nozzle 10, and the air pipe 20 is coupled to an inner circumferential surface of the nozzle 10 in which the space groove 11 is formed. Coupling portion 12, for example a female screw portion, is formed.

A plurality of injection holes 13 communicating with the space groove 11 from the lower portion of the coupling portion 12 to the upper surface 10a are formed (six in the drawing), and the injection holes 13 inject the compressed air inclined upwardly. It is formed to be inclined at a predetermined angle (for example, the opening angle of the two injection holes 13 is 38 ~ 48 °).

FIG. 2 is a state diagram of use of the air jet nozzle shown in FIG. 1A. FIG.

The air pipe 20 is open at both sides in a rod shape having an empty space therein.

The air pipe 20 is a pipe capable of withstanding high pressure, and in some cases, has an elongated shape.

Coupler 21 is coupled to an open side of the air pipe 20 is connected to the air hose (not shown) for supplying compressed air, the on-off valve to intermittently supply the compressed air to the air pipe 20 22 is installed.

The nozzle 10 is screwed to the other side (lower side) of the open air pipe 20, the coupling portion 12 on the inner circumferential surface to quickly accelerate the compressed air supplied from the air pipe 20 through the injection hole 13 Spray inclined upwards.

In addition, the air pipe 20, the coupling pipe 30 having an inner diameter larger than the outer diameter of the air pipe 20 is extrapolated and fixed by the fixing means 31 and the scarf 32 in the lower portion of the coupling pipe 30 Is joined by welding or the like.

The fixing means 31 is a nut 31b which is joined to the outside of the coupling pipe 30 by welding, for example, and the coupling pipe 30 is screwed on the side of the nut 31b and the coupling pipe 30. ) Is made of a bolt for fixing the air pipe (20).

The scarf 32 has a narrow shape that is joined to the lower portion of the coupling pipe (30) and spread toward the bottom.

After moving the scarf 32 to a desired position of the air pipe 20, it is possible to adjust the gap with the nozzle 10 coupled to the bottom by tightening and fixing with a fixing means 31, such as bolts / nuts.

The scarf 32 having the shape of the shade increases the spraying effect of the compressed air by interacting with the nozzle 10.

That is, the conical nozzle 10 continues to inject compressed air while penetrating the sedimentary layer of sand or ground, but when the compressed air is inclined to the upper portion of the nozzle 10 through the injection port 13, the compressed air is fresh While hitting the scarf 32 of the shape is sprayed toward the bottom sand or ground.

At this time, as the vortex is formed in the water by the compressed air, the sand or soil at the bottom rises from the bottom and moves along the vortex, thereby increasing the amount of dissolved oxygen, thereby improving the cleaning effect.

The nozzle 10 according to the first embodiment is developed for the purpose of spraying by digging into the sedimentary layer where it does not have a mechanical action when the source of contamination is deep, and the depth of the sedimentary layer that can penetrate is compressed. It depends on the pressure of the air.

The reason why the nozzle 13 of the nozzle 10 is directed upward is to block the inflow of the contaminant into the lower part, whereby the contaminant in the lower part rises quickly to the upper part by the flow of compressed air.

3A and 3B are a perspective view and an internal structure diagram of an air jet nozzle according to a second embodiment of the present invention.

As shown, the nozzle 40 of the air jet according to the second embodiment has a hexagon shape having a longer left and right length than the bottom surface 40d when viewed from the front, and inclined surfaces 40b and 40c facing each other from side to side. A cylindrical shape is formed as a whole, which extends from the upper surface 40a and the lower surface 40d, respectively.

A space groove 41 is formed in a central portion at a predetermined depth from the bottom surface 40d of the nozzle 40, and an air pipe (not shown) is coupled to an inner circumferential surface of the nozzle having the space groove 41 formed therein. A portion 42, for example a female screw portion, is formed.

That is, the nozzle 40 according to the second embodiment is coupled to the upper side of the air pipe to inject compressed air.

A plurality of first and second injection holes 43 and 44 communicating with the space groove 41 from the inner circumferential surface of the upper part of the coupling part 42 to the upper surface 40a and the inclined surfaces 40b or 40c (40c in the figure), respectively. Is formed.

The first injection hole 43 is formed to be inclined at a predetermined angle (for example, the opening angle of the two first injection holes 43 is 38 to 48 °) so as to inject compressed air inclined upwardly, and the second injection hole ( 44 is formed to be inclined at an angle greater than the opening angle of the first injection hole 43 (for example, the opening angle of the second injection hole 44 is 150 to 170 °) so as to inject compressed air inclined to the side portion. .

At this time, the first injection port 43 is formed to be spaced apart from the upper surface 40a at a predetermined angle (120 ° in the drawing), and the second injection port 44 is positioned between the first injection port 43 on the inclined surface 40c. It is formed so as to be spaced apart from the first injection port 43 at a predetermined angle (120 ° in the drawing), and compressed air is evenly injected at almost the same pressure to the upper portion and the upper side of the nozzle 40.

In the second embodiment of the present invention, it is shown that each of the first jet sphere 43 and the second jet sphere 44 is formed.

When the scarf to adjust the height on the top of the nozzle 40 is installed as shown in Figure 2 by the interaction of the nozzle 40 and the scarf, the water flows in a circular shape as the vortex is formed, the sand or soil particles are finely It breaks down and sinks in the order of the weight of the particles, and the contaminated oil is separated from the sand or soil and rises.

The nozzle 40 according to the second embodiment is effective for purifying stagnant water bodies such as sediment and harbor.

4A and 4B are a perspective view and an internal structure diagram of an air jet nozzle according to a third embodiment of the present invention.

As shown, the nozzle 50 of the air jet according to the third embodiment has a substantially conical shape in which the side surface 50b is pointed downward and the top surface 50a is flat, and the top surface 50a and the side surface 50b abut. The inclined surface 50c is formed in a site | part.

Coupling portion to form a space groove 51 in the central portion at a predetermined depth from the upper surface (50a) of the nozzle 50, the inner circumferential surface of the nozzle 50 in which the space groove 51 is formed to screw the air pipe 52, for example, a female screw portion is formed.

On the inner circumferential surface of the lower portion of the coupling portion 52, a plurality of first and second injection holes 53 and 54 communicating with the space groove 51 are formed on the upper surface 50a and the side surface 50b or the inclined surface 50c, respectively.

The first injection hole 53 is formed to be inclined at a predetermined angle (for example, the opening angle of the two first injection holes 53 is 38 to 48 °) so as to inject the compressed air inclined upwardly, and the second injection hole ( 54 is formed to be inclined at an angle greater than the opening angle of the first injection hole 53 (for example, the opening angle of the second injection hole 55 is 150 to 170 °) so as to inject compressed air inclined to the side portion. .

At this time, the first injection port 53 is formed to be spaced apart from the upper surface 50a by a predetermined angle (60 ° in the drawing), and the second injection port 54 is the first injection port 53 on the side surface 50b or the inclined surface 50c. ) Is formed to be spaced apart from each other by a predetermined angle (120 ° in the drawing) by a number smaller than the number of the first injection holes 54.

In the third embodiment, six first injection ports 53 and three second injection holes 54 are formed.

The first injection port 53 helps discharge of the pollutant source, the second injection port 54 serves as an auxiliary role of the first injection port 53 to create a flow of compressed air, while the scarf on the top as shown in FIG. When installed, it helps the penetration of the lower part at the same time as the vortex is formed by the upper compressed air.

The nozzle 50 according to the third embodiment has a structure that can penetrate the sedimentary layer by itself in the shape of a conical cone, and is mainly used when the source of contamination is in a deep place.

5A and 5B are a perspective view and an internal structure diagram of an air jet nozzle according to a fourth embodiment of the present invention.

As shown, the lower portion of the rotary tube 70 is screwed to the nozzle 60 of the air jet according to the fourth embodiment, and the upper portion of the rotary tube 70 is extrapolated to the lower portion of the connecting tube 71. A bearing 72 is interposed so as to support rotation therebetween.

The bearing 72 is preferably a rubber seal bearing so as to support the rotation of the rotary tube 70 while having a sealing effect that prevents leakage of compressed air.

The nozzle 60 has a substantially conical shape in which the side surface 60b is pointed downward and the top surface 60a is flat, and an inclined surface 60c is formed at a portion where the top surface 60a and the side surface 60b meet.

A space groove 61 is formed in a central portion at a predetermined depth on the upper surface 60a of the nozzle 60, and the lower portion of the rotary tube 70 is screwed to the inner circumferential surface of the nozzle in which the space groove 61 is formed. Coupling portion 62, for example a female screw portion, is formed.

On the inner circumferential surface of the lower portion of the coupling portion 62, a plurality of first and second injection holes 63 and 64 communicating with the space groove 61 are formed on the upper surface 60a and the side surface 60b or the inclined surface 60c, respectively.

The first injection hole 63 is formed to be inclined at a predetermined angle (for example, the opening angle of the two first injection holes 63 is 38 to 48 °) so as to inject the compressed air inclined upwardly, and the second injection hole ( 64 is formed to be inclined at an angle greater than an opening angle of the first injection hole 63 (for example, an opening angle of the second injection hole 44 is 150 to 170 °) so as to inject compressed air inclined to the side part. .

At this time, the first injection port 63 is formed to be spaced apart from the upper surface 60a at a predetermined angle (120 ° in the drawing), and the second injection port 64 is between the first injection port 43 on the side surface or the inclined surface 40c. It is formed at the position of the first injection port 43 and the same number spaced apart from the predetermined angle (120 ° in the figure).

In the fourth embodiment of the present invention, it is shown that three first injection holes 63 and two second injection holes 64 are formed.

6 is a state diagram of use of the air jet nozzle shown in FIG. 5A.

The rotary tube 70 screwed to the top of the nozzle 60 is extrapolated to be fixed to the lower portion of the connecting tube 71 while being supported by the bearing 72.

The air pipe 80 is open at both sides in a rod shape having an empty space therein.

The air pipe 80 is a pipe capable of withstanding high pressure, and in some cases, has an elongated shape.

Coupler 81 is coupled to an open side of the air pipe (80) is connected to the air hose (not shown) for supplying compressed air, the on-off valve to intermittently supply the compressed air to the air pipe (80) 82 is installed.

The upper part of the connection pipe 71 is screwed to the other open side (lower side) of the air pipe (80).

As a result, when compressed air is supplied to the nozzle 60 through the air pipe 80, the compressed air is inclined to the upper part and the upper part through the first and second injection holes 63 and 64 by the strong pressure of the compressed air. The nozzle 60 rotates supported by the bearing 72 to form a vortex.

The nozzle 60 according to the fourth embodiment is suitable when the rock or gravel is contaminated with oil, and sprays compressed air while rotating by the strong injection pressure of the nozzle 60, thereby enabling finer air injection. Since the angles of the injection holes 63 and 64 are slightly inclined outward with respect to the vertical direction of the nozzle 60, a larger area of injection is possible.

As such fine air particles can be sprayed uniformly it can promote the purification of the pollutant.

10,40,50,60: nozzles 11,41,51,61: space groove
12,42,52,62: Coupling part 13,43,44,53,54,63,64: Injection port
20,80: Air pipe 32: scarf
70: rotary tube 71: connector
72: bearing

Claims (10)

In the air jet nozzle coupled to one side of the air pipe for supplying compressed air to inject compressed air in communication with the inner space groove, the plurality of injection holes are inclined upwardly outward with respect to the vertical direction;
The nozzle has a cylindrical shape each formed such that the inclined surfaces facing each other from the left and right in the hexagonal shape longer than the lower surface than the lower surface when viewed from the front, respectively extending from the upper and lower surfaces,
A space groove is formed in a central portion at a predetermined depth from the lower surface of the nozzle, and the injection hole has a plurality of first injection holes communicating with the space grooves and formed on the upper surface, and a second injection hole communicating with the space grooves and formed on the inclined surface. Air jet nozzle, characterized in that provided. The method of claim 1,
An air jet nozzle, characterized in that a vortex is formed between the nozzle and the scarf by installing a freshly shaped scarf provided with a height adjusting means in the air pipe above the nozzle. The method of claim 2,
The height adjustment means is an air jet nozzle, characterized in that the coupling pipe is extrapolated to the air pipe and the scarf is bonded to the lower portion, and the bolt and nut to be fixed so as not to move to the air pipe through the coupling pipe from the side. delete delete The method of claim 1,
And the first jet port and the second jet port are formed in the same number. In the air jet nozzle coupled to one side of the air pipe for supplying compressed air to communicate compressed air in communication with the space groove therein, the plurality of injection holes are inclined upwardly outward with respect to the vertical direction;
The nozzle is in the shape of the inclined surface formed in a portion where the upper surface and the side in contact with the conical shape is pointed toward the lower side and the flat upper surface,
The jet nozzle comprises a first injection port in communication with the space groove is formed in the upper surface a plurality, and a second injection hole in communication with the space groove is formed in the side or inclined surface a plurality. The method of claim 7, wherein
The first jet nozzle is the same as the second jet nozzle or more jet nozzle characterized in that the formed more than the second jet. The method of claim 7, wherein
A rotary tube coupled to the upper portion of the nozzle,
One side is coupled to the air tube and the other side is coupled to the rotary tube,
An air jet nozzle further comprising a bearing interposed between the connection pipe and the rotary tube to support rotation of the rotary tube. The method of claim 9,
And the bearing is a rubber seal bearing.

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