KR20220023247A - Gas diffuser in the water for plasma type water treatment device and the like - Google Patents

Abstract

The present invention provides an underwater gas diffuser having a structure in which a passage through which a plurality of gases are sucked is dispersed around a gas mixing pipe, so that the manufacturing process can be made more easily, and the diffusion of the gas can be made more smoothly in the water. According to the present invention, at one end of the gas mixing pipe, a gas intake groove connected from an outer surface of the gas mixing pipe to an inner passage in a furrow shape is formed, and one end of the gas mixing pipe is inserted into a coupling groove of one side coupling member so that the one side coupling member covers the gas intake groove from the outside, thereby forming a passage through which the gas is sucked from the outside to the inside.

Description

Underwater gas diffuser used in plasma water treatment equipment, etc. {GAS DIFFUSER IN THE WATER FOR PLASMA TYPE WATER TREATMENT DEVICE AND THE LIKE

The present invention relates to an underwater gas diffuser used in a plasma water treatment device, and more particularly, a plasma water treatment device that oxidizes and decomposes pollutants by dispersing a gas containing ozone, radical substances, etc. in the water of polluted water by plasma treatment , a sterilizing water manufacturing device that produces sterilizing water with sterilizing power by including such a gas in water, a sewage treatment facility that removes pollutants by floating air bubbles in the water, etc. It relates to an underwater gas diffuser that can be used in the necessary equipment.

As a water treatment method to efficiently purify contaminated water such as industrial wastewater and to remove microorganisms such as bacteria, air is plasma-treated to diffuse gas containing ozone and radical substances into the water in the form of microbubbles. Methods for purification are known.

1 relates to an apparatus for water treatment as described above, and is described in Korean Patent Registration No. 10-1882424.

Referring to FIG. 1 , it includes a plasma processor 1 that generates plasma and processes it by passing air, and a gas diffuser 6 that diffuses the gas processed by the plasma processor 1 into water.

In the plasma processing machine (1), plasma discharge is generated from the coil-shaped discharge electrode (3) wound around the dielectric tube (2), and air sucked in through the suction port (5) passes around the coil-shaped discharge electrode (3). While plasma treatment is performed, a gas containing ozone and radical substances is generated accordingly.

The generated gas flows into the gas diffuser 6 through the connection pipe 9 and can be diffused in the flowing polluted water, and the gas diffused in the water comes into contact with the pollutants in the polluted water and oxidizes and decomposes. , purification can be achieved.

2 shows the configuration of the gas diffuser 6 in more detail.

The gas diffuser 6 is accompanied by a pressure drop as the flow rate of the contaminated water remarkably increases in the gas mixing pipe 7 having the flow path 7a narrowed due to the reduced cross-sectional area to flow, and the pressure drop is reduced by the gas flow rate. Gas is naturally sucked into the water through the suction hole (8).

The gas naturally inhaled through the gas suction hole 8 is mixed in the water in the form of microbubbles at the time of moving to the polluted water and is diffused while flowing with the polluted water.

Looking at the above configuration, the gas mixing pipe 7 in which the contaminated water, which is the water to be treated, is passed through and in which a plurality of gas intake holes 8 are formed, a plurality of gas intake holes 8 finely penetrated along the circumference of the curved outer circumferential surface. Therefore, there is a very difficult problem in its manufacture.

That is, since it is necessary to process a plurality of gas intake holes 8 by drilling each with a fine diameter around the gas mixing pipe 7, which is a curved surface as a tubular shape, and disperse them at a plurality of points, processing is difficult in a normal machine tool. There is a problem in that the production efficiency is also reduced.

The present invention has been devised from the above point of view, and an object of the present invention is that the process in which a passage through which a plurality of gases are sucked is dispersed around the gas mixing pipe can be made more easily, and the diffusion of the gas is thereby It is to provide an underwater gas diffuser having a structure that can be made more smoothly in the water.

Accordingly, the underwater gas diffuser according to the present invention, a tubular gas mixing pipe having a water passage to be treated therein, and a coupling groove into which one end of the gas mixing pipe is inserted are formed, and a treatment target connected to the coupling groove inside A water passage is formed, and in a state where one end of the gas mixing pipe is inserted into the coupling groove, a one-side coupling member for communicating the water to be treated passage and the water passage to be treated to flow the water to be treated, the gas At one end of the mixing pipe, a gas suction groove connected from the outer surface of the gas mixing pipe to the water passage to be treated in a furrow shape is formed, and one end of the gas mixing pipe is inserted into the coupling groove so that the one-side coupling member is connected to the By covering the gas intake groove, when the water to be treated continuously flows through the water passage to be treated and the water passage to be treated, gas is sucked from the outside of the gas mixing pipe through the gas intake groove and mixed with the water to be treated characterized in that

In addition, the underwater gas diffuser according to the present invention, the gas suction groove, one end of the gas mixing pipe, an outer groove formed in the longitudinal direction of the gas mixing pipe on the outer circumferential surface, and the path so that the outer groove is continuous on the front surface Another feature is that it includes an inner groove that communicates with the water passage to be treated by being bent.

In addition, in the underwater gas diffuser according to the present invention, a plurality of the gas intake grooves are installed at regular intervals along the circumference of the water passage to be treated, and a plurality of the gas intake grooves are cross-sections of the water passage to be treated Another feature is that the gas enters the water to be treated in a vortex shape by being connected to the water passage to be treated in a state deflected along one rotational direction when viewed as a reference.

On the other hand, the underwater gas diffuser according to the present invention from another point of view, a tubular gas mixing pipe having a water passage to be treated therein, a water passage to be treated connected to the water passage to be treated and one end of the gas mixing pipe are inserted A one-side coupling member having a coupling groove formed at the end of the water passage to be treated, and a cover member having a gas supply hole for supplying gas to a space between the gas mixing pipe and the gas mixing pipe, At one end of the gas mixing pipe, a gas suction groove having a furrow shape connected from the outer surface to the water passage to be treated through the front is formed, and one end of the gas mixing pipe is inserted into the coupling groove so that the one side coupling member is It is characterized in that by covering the gas intake groove, a passage for sucking the gas from the outside of the gas mixing pipe to the inside is formed.

In addition, in the underwater gas diffuser according to the present invention, a head having a larger outer diameter than the middle part of the gas mixing pipe is formed at one end of the gas mixing pipe, and the gas intake groove is, the gas mixing pipe on the outer peripheral surface of the head an outer groove formed to pass through the head along the longitudinal direction of the inner groove, and an inner groove communicating with the water passage to be treated by bending a path so as to be continuous with the outer groove and formed on the front surface of the head; Another feature is that it is in close contact with the inner circumferential surface of the groove.

On the other hand, the underwater gas diffuser according to the present invention from another point of view, a tubular gas mixing pipe having a water passage to be treated therein, and a coupling groove into which one end of the gas mixing pipe is inserted are formed therein, and in the coupling groove A connected treatment target water passage is formed, and in a state in which one end of the gas mixing pipe is inserted into the coupling groove, a one-sided coupling member for communicating the treatment target water passage and the treatment target water passage to flow the treatment target water. , In the one-side coupling member, a gas intake groove connected from the outer surface of the one-side coupling member to the water passage to be treated in a furrow shape is formed, and one end of the gas mixing pipe is inserted into the coupling groove, and one end of the gas mixing pipe By covering the gas suction groove, when the water to be treated continuously flows through the water passage to be treated and the water passage to be treated, gas from the outside of the gas mixing pipe is sucked through the gas intake groove to be added to the water to be treated characterized by mixing.

In addition, the above-described underwater gas diffuser, a dielectric ball located in the gas supply hole and in contact with the outer surface of the gas mixing pipe, is coupled to the gas supply hole gas to be supplied around the dielectric ball through the internal passage A supply pipe, a discharge electrode located in the internal passage of the gas supply pipe and in contact with the dielectric ball on the opposite side to the side on which the gas mixing pipe is located, respectively connected to the discharge electrode and the gas mixing pipe to mix the discharge electrode and the gas Another feature is that by including a power source for generating plasma between the tubes, the plasma generated from the discharge electrode is generated in a dispersed state along the surface of the dielectric ball.

In the underwater gas diffuser according to the present invention, a gas intake groove connected from the outer surface of the gas mixing pipe to the water passage to be treated in a furrow shape is formed at one end of the gas mixing pipe, and one end of the gas mixing pipe is inserted into the coupling groove and one side The coupling member covers the gas intake groove from the outside to form a passage through which the gas is sucked.

In this configuration, it is not necessary to separately process a number of fine holes by drilling each of the circumferences of the gas mixing pipe or to manufacture a dedicated processing machine, and to form a furrow shape, which is an easy processing, on the outer surface of one end of the gas mixing pipe. Since this is possible, a process in which a passage through which a plurality of gases are sucked is dispersed around the gas mixing pipe can be made more easily. That is, the processing of forming a furrow shape on the surface can be processed relatively easily and quickly even if the processing portion is fine.

In addition, diffusion of gas according to such a structure can be made very smoothly in water.

In addition, in the underwater gas diffuser according to the present invention, a plurality of gas intake grooves are installed at regular intervals along the circumference of the water passage to be treated, and when the gas intake groove is viewed based on the cross section of the water passage to be treated, one rotation By being connected to the water passage to be treated in a state deflected along the direction, the gas enters the water to be treated in a vortex shape.

This configuration can induce an even mixing of the gas in the form of microbubbles and the water to be treated together while the water to be treated flows, so that the contact between pollutants in the water to be treated, ozone, radical substances, etc. This can be promoted or induced to evenly mix and distribute the gas in the form of microbubbles in the water to be treated.

In addition, the underwater gas diffuser according to the present invention, the dielectric ball is located in the gas supply hole of the cover member and by installing a discharge electrode to plasma discharge, it is configured to plasma-treat the gas flowing into the gas supply hole.

In this configuration, since the plasma generated from the discharge electrode is generated in a dispersed state along the surface of the dielectric ball, the gas passing around the dielectric ball can contact the plasma in a large area to have high plasma processing efficiency.

1 and 2 are diagrams illustrating the configuration of a water treatment device that diffuses a gas treated with plasma in the form of microbubbles in the prior art.
3 is an exploded perspective view showing the configuration of an underwater gas diffuser according to an embodiment of the present invention;
Figure 4 is a cross-sectional configuration diagram showing the configuration of an underwater gas diffuser according to an embodiment of the present invention
Figure 5 (a) and (b) is a cross-sectional configuration diagram showing the configuration of the gas intake groove is installed in the underwater gas diffuser according to an embodiment of the present invention
6 is a configuration and operation explanatory diagram for explaining the action of the gas intake groove is installed to be deflected in one rotational direction in the underwater gas diffuser according to the embodiment of the present invention, the gas flows in a vortex shape;
7 is an underwater gas diffuser according to another embodiment of the present invention, and is a cross-sectional view showing a configuration in which a gas intake groove is installed only at one end of a gas mixing pipe.
Figure 8 is an underwater gas diffuser according to another embodiment of the present invention, a perspective view showing a configuration in which a gas intake groove is installed on one side of the coupling member
9 is a cross-sectional configuration diagram showing the cross-sectional configuration of the underwater gas diffuser of FIG.
FIG. 10 is a cross-sectional view showing a configuration in which a dielectric ball is positioned in a gas supply hole of a cover member and a discharge electrode is installed to discharge plasma as an underwater gas diffuser according to another embodiment of the present invention; FIG.
11 is a configuration and operation explanatory diagram for explaining the operation of generating a plasma and a portion in which a dielectric ball and a discharge electrode are installed in FIG.
12 is an explanatory view for explaining the configuration and operation in which the dielectric ball is not provided in FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

3 to 5 , the underwater gas diffuser according to an embodiment of the present invention includes a tubular gas mixing pipe 10 having a processing target water passage 15 formed therein, and the processing target water passage 15 . One side coupling member 20 having a coupling groove 21 formed at the end of the treatment target water passage 23 so that one end of the treatment target water passage 23 and the gas mixing pipe 10 connected to is inserted, and the gas; It includes a cover member 30 surrounding the mixing pipe 10 and having a gas supply hole 32 for supplying gas to the space 33 between the gas mixing pipe 10 and the gas mixing pipe 10 .

The gas mixing pipe 10 is a tubular member in which the water to be treated passage 15 is formed therein, and is a gas for supplying gas to the water to be treated passing through the water passage 15 to be treated and mixing it with the water to be treated. A suction groove 12 is formed.

Here, the gas is to be mixed and dispersed in water, and may be plasma-treated air depending on the purpose of dispersing the gas in water, or may simply be air inhaled from the atmosphere.

One side coupling member 20 is coupled to one end of the gas mixing pipe 10 , and the other coupling member 40 is coupled to the other end of the gas mixing pipe 10 .

Accordingly, the treatment target water passage 43 of the other coupling member 40, the treatment target water passage 15 of the gas mixing pipe 10, and the treatment target water passage 23 of the one side coupling member 20 are sequentially By being connected and communicating, the water to be treated can flow continuously.

The one-side coupling member 20 is a coupling formed at the end of the treatment target water passage 23 connected to the treatment target water passage 15 and the treatment target water passage 23 so that one end of the gas mixing pipe 10 is inserted. A groove 21 is formed.

The coupling groove 21 is a portion in which a groove having a larger diameter than that of the treatment target water passage 23 is machined at the end of the treatment target water passage 23, and is formed so that the treatment target water passage 23 is located in the center. The treatment target feeding passage 23 and the coupling groove 21 are connected.

When one end of the gas mixing pipe 10 is inserted into the coupling groove 21 , the processing target water passage 23 and the processing target water passage 15 are coupled to each other.

For reference, in this specification, one end of the gas mixing pipe 10 is only illustrated as the left end in the drawing and does not necessarily mean the left end shown in the drawing, so the right end shown in the drawing may be viewed as one end. of course there is

At one end of the gas mixing pipe 10, a gas intake groove 12 having a furrow shape or a valley shape connected from the outer surface to the water passage 15 to be treated through the front surface is formed, and the gas mixing pipe ( 10) is inserted into the coupling groove 21 so that one side coupling member 20 covers the gas intake groove 12 from the outside, so that the passage for sucking the gas from the outside of the gas mixing pipe 10 to the inside is is formed

Referring to the enlarged part of FIG. 3 , one end of the gas mixing pipe 10 preferably includes a head 11 having a larger outer diameter than the middle part of the gas mixing pipe 10 is formed and included. A gas intake groove 12 is formed on the outer peripheral surface and the front surface of the part 11 .

That is, the gas intake groove 12 has an outer groove portion 12a formed to pass through the head portion 11 in the longitudinal direction of the gas mixing pipe 10 on the outer circumferential surface of the head portion 11, and the outer groove portion 12a. The path is bent so as to be continuous with the water passage from the outer surface of the gas mixing pipe 10, including the inner groove portion 12b that communicates with the water passage 15 to be treated by being formed on the front surface of the head 11. 15) is connected.

In addition, in a state where one end of the gas mixing pipe 10 is fitted in the coupling groove 21 of the one side coupling member 20, the head 11 is in close contact with the inner circumferential surface of the coupling recess 21, one side coupling member 20 It may be in a state in which the gas intake groove 12 is covered from the outside.

Accordingly, in the structure of the furrow shape in which the gas intake groove 12 is entirely open to the outside, the one side coupling member 20 covers the outside and connects the inside and outside of the gas mixing pipe 10, such as a cave. structure can be converted.

Accordingly, when the water to be treated continuously flows through the water passage 15 and the water passage 23 to be treated, the gas is sucked from the outside of the gas mixing pipe 10 due to the pressure drop due to the flow rate. It may be sucked through the groove 12 and mixed with the water to be treated.

In order to further increase the suction amount of gas by increasing the pressure drop of the water to be treated, it is necessary to increase the speed of the water to be treated passing through the water passage 15 to be treated, and for this purpose, the treatment target of the other coupling member 40 is As the water passage 43 approaches from a larger diameter than the water passage 15 to be treated, it may be formed in a tapered shape in which the diameter gradually decreases.

This is because the same flow rate has to pass while the target water passes through the passage whose diameter is gradually reduced, so that the passage speed is gradually increased.

In addition, referring to FIGS. 3 and 6 , a plurality of the gas intake grooves 12 are provided at regular intervals along the circumference of the water passage 15 to be treated, and the inner groove 12b is a water container to be treated. When viewed with reference to the cross section of the furnace 15, it is connected to the treatment target water passage 15 in a deflected state along one rotational direction.

Accordingly, when the gas sucked through the gas suction groove 12 is introduced to be mixed with the water to be treated, the water to be treated can be rotated in one direction by the speed of the inflow while flowing in a vortex shape, and the number of objects to be treated can be rotated in one direction. In the process of flowing, the gas in the form of microbubbles and the water to be treated rotate together to achieve even mixing as a whole.

In particular, in the case where the gas is plasma-treated to include ozone, radical substances, etc., and the purification treatment is performed while in contact with contaminants in the water to be treated, the action of the gas and the water to be treated while rotating and flowing together is the action of the gas and the contaminants. Since a wide contact is induced, the efficiency of the purification process can be improved.

In addition, even if it is not the purpose of the purification treatment, the above action can induce the gas in the form of microbubbles to be evenly mixed and distributed in the water to be treated in a short time.

On the other hand, the cover member 30 is a tubular member surrounding the gas mixing pipe 10, both ends are respectively spirally coupled to one side coupling member 20 and the other coupling member 40, respectively, the gas mixing pipe (10) A space (33) between the condyles is formed.

In addition, the gas supply hole 32 for receiving the plasma-treated gas is formed through to connect the inside and the outside, and the connector 35 is coupled, so that the plasma-treated gas can be supplied to the space.

In this embodiment, the gas intake groove 12 is formed in the same manner not only at one end of the gas mixing pipe 10 but also at the other end, and the coupling groove 41 into which the other end of the gas mixing pipe 10 is inserted is provided on the other side. It is also formed in the coupling member 40 so that the gas mixing pipe 10 and the other coupling member 40 are coupled to each other.

Accordingly, the gas supplied to the space 33 between the gas mixing pipe 10 and the cover member 30 is processed through each gas intake groove 12 at one end and the other end of the gas mixing pipe 10 , respectively. Since it can be mixed by being sucked into the target water, it has a structure in which a large amount of gas can be mixed.

Meanwhile, FIG. 7 shows a configuration according to another embodiment of the present invention, and may be configured such that the gas intake groove 12 is formed only at one end of the gas mixing pipe 10 .

Referring to FIG. 7 , the gas mixing pipe 10 is a structure in which the gas mixing pipe 10 and the other side coupling member 40 of the above-described embodiment are integrated to form the gas mixing pipe 10 , and the gas mixing pipe 10 ), the head 11 is formed at one end, and the gas intake groove 12 is formed in the same manner.

In addition, as shown in FIG. 7 , based on the direction in which the water to be treated passes through the water passage 15 to be treated, the diameter of the flow path immediately before the water to be treated passes through the gas intake groove 12 is the diameter of the flow path immediately after passing. It is preferable that the difference d1 in diameter occurs so as to be smaller.

This is to allow the pressure drop and suction action through the gas intake groove 12 to be performed more smoothly while the water to be treated passes through the portion where the gas intake groove 12 is formed, and is applicable to the above-described embodiment.

On the other hand, FIGS. 8 and 9 show the configuration of an underwater gas diffuser according to another embodiment of the present invention. A gas intake groove 22 is formed on the inner surface of the coupling groove 21 of the one side coupling member 20 . The formation position is changed so as to be possible, and the gas suction groove 22 is connected from the outer surface of the end of the one-side coupling member 20 to the treatment target water passage 23 in a furrow shape.

One end of the gas mixing pipe 10 is inserted into the coupling groove 21 of the one side coupling member 20, and one end of the gas mixing pipe 10 covers the gas suction groove 22 by the inserted coupling, and the outside Make a cave-like passage that sucks the gas inside.

Accordingly, during the continuous flow of the water to be treated through the water to be treated passage 15 and the water passage 23 to be treated, gas is sucked from the outside of the one-side coupling member 20 through the gas suction groove 22 to be treated It can be mixed with the target water.

Meanwhile, in FIGS. 10 and 11 , the dielectric ball 51 is positioned in the gas supply hole 32 of the cover member 30 and the discharge electrode 52 is installed to generate the plasma 61 according to another embodiment of the present invention. By generating, it is configured to plasma-treat the gas flowing into the gas supply hole (32).

That is, when the gas is external air, it is plasma-treated while flowing into the gas intake groove 12 so that ozone and a gas containing radical substances can be generated and flowed, and the gas is plasma-treated by the plasma processor In the case of inflow, the concentration and activity of ozone and radical substances contained in the gas can be further increased by plasma treatment again in the gas intake groove 12 .

10 and 11 , the above configuration includes a dielectric ball 51 positioned in the gas supply hole 32 and contacting the outer surface of the gas mixing pipe 10 , coupled to the gas supply hole 32 and an internal passageway. A gas supply pipe 53 through which gas is supplied around the dielectric ball 51, and a dielectric ball ( A discharge electrode 52 in contact with 51 , and a power source connected to the discharge electrode 52 and the gas mixing pipe 10 , respectively, to generate a plasma 61 between the discharge electrode 52 and the gas mixing pipe 10 . do.

The dielectric ball 51 may be made of a ceramic material or a quartz material, and does not necessarily have a spherical shape, and may have a multi-sided or atypical block shape.

When the plasma 61 discharge is made from the discharge electrode 52 on the upper surface of the dielectric ball 51 by the power source, the plasma 61 flows down the surface of the dielectric ball 51 toward the gas mixing pipe 10 . A discharge area is formed in the form of creepage discharge.

This is generated in a state in which the plasma 61 is spread on the surface of the dielectric ball 51 , so that the gas supplied through the internal passage of the gas supply pipe 53 passes around the dielectric ball 51 , the cover member 30 and the gas When entering the space 33 between the mixing tube 10 and the dielectric ball 51 , it may be in contact with the plasma 61 in a wide range of the surface to be plasma-treated.

If the dielectric ball 51 does not exist, as shown in FIG. 12 , the plasma 61 by a single linear arc discharge or spark discharge from one point of the discharge electrode 52 toward the gas mixing pipe 10 is generated. Since it is generated, the passing gas comes into contact with the plasma 61 only in a very small area, and the plasma processing efficiency is very low.

However, in the configuration of this embodiment, since the plasma 61 generated from the discharge electrode 52 is generated in a dispersed state along the surface of the dielectric ball 51 , the gas passing around the dielectric ball 51 is the plasma 61 . It can have high plasma processing efficiency by contacting with a large area.

Although the preferred embodiment of the present invention has been described above, the above embodiment is only an embodiment within the scope of the technical spirit of the present invention, and for those skilled in the art, within the technical spirit of the present invention Of course, other modified implementations are possible.

10; gas mixing pipe 11; head
12; gas intake groove 12a; side groove
12b; inner groove 15; Treatment target water passage
20; one side coupling member 21; mating groove
22; gas intake groove 23; Treatment target feeding path
30; cover member 32; gas supplier
33; space 35; connector
40; the other coupling member 51; dielectric ball
52; discharge electrode 53; gas supply pipe

Claims (7)

A tubular gas mixing pipe having a water passage to be treated therein;
A coupling groove into which one end of the gas mixing pipe is inserted is formed, and a treatment target water passage connected to the coupling groove is formed therein, and with one end of the gas mixing pipe inserted into the coupling groove, the treatment target water passage and Including a one-side coupling member for communicating the treatment target water passage to flow the treatment target water,
At one end of the gas mixing pipe, a gas suction groove connected from the outer surface of the gas mixing pipe to the water passage to be treated in a furrow shape is formed,
One end of the gas mixing pipe is inserted into the coupling groove so that the one-side coupling member covers the gas intake groove,
When the water to be treated continuously flows through the water passage to be treated and the water passage to be treated, gas is sucked from the outside of the gas mixing pipe through the gas suction groove and mixed with the water to be treated. According to claim 1,
The gas intake groove is formed by bending an outer groove formed in the longitudinal direction of the gas mixing tube on an outer circumferential surface of one end of the gas mixing tube, and the path being bent so as to be continuous with the outer groove on the front surface, thereby communicating with the water passage to be treated. Underwater gas diffuser, characterized in that it comprises an inner groove to be 3. The method of claim 1 or 2,
A plurality of the gas intake grooves are installed at regular intervals along the circumference of the water passage to be treated;
A plurality of the gas intake grooves are connected to the treatment target water passage in a state deflected along one rotational direction when viewed with respect to the cross section of the treatment target water passage, so that the gas enters the treatment target water in a vortex shape. Underwater gas diffuser, characterized in that A tubular gas mixing pipe having a water passage to be treated therein;
One side coupling member including a treatment target water passage connected to the treatment target water passage and a coupling groove formed at an end of the treatment target water passage so that one end of the gas mixing pipe is inserted;
A cover member surrounding the gas mixing pipe and having a gas supply hole for supplying gas to a space between the gas mixing pipe and the gas mixing pipe,
At one end of the gas mixing pipe, a gas intake groove connected from the outer surface to the water passage to be treated through the front surface is formed in a furrow shape,
Underwater gas diffuser, characterized in that one end of the gas mixing pipe is inserted into the coupling groove and the one-side coupling member covers the gas intake groove, thereby forming a passage for sucking the gas outside the gas mixing pipe to the inside. 5. The method of claim 4,
A head portion having a larger outer diameter than the middle portion of the gas mixing tube is formed at one end of the gas mixing pipe,
The gas intake groove includes an outer groove formed to pass through the head along the longitudinal direction of the gas mixing pipe on the outer circumferential surface of the head, and the path is bent so as to be continuous with the outer groove and formed on the front surface of the head to be treated. It includes an inner groove in communication with the passage,
Underwater gas diffuser, characterized in that the head is in close contact with the inner circumferential surface of the coupling groove A tubular gas mixing pipe having a water passage to be treated therein;
A coupling groove into which one end of the gas mixing pipe is inserted is formed, and a treatment target water passage connected to the coupling groove is formed therein, and with one end of the gas mixing pipe inserted into the coupling groove, the treatment target water passage and Including a one-side coupling member for communicating the treatment target water passage to flow the treatment target water,
A gas suction groove is formed in the one-side coupling member from the outer surface of the one-side coupling member to the treatment target feeding passage in a furrow shape,
One end of the gas mixing pipe is inserted into the coupling groove so that one end of the gas mixing pipe covers the gas intake groove,
When the water to be treated continuously flows through the water passage to be treated and the water passage to be treated, gas is sucked from the outside of the gas mixing pipe through the gas suction groove and mixed with the water to be treated. 6. The method according to claim 4 or 5,
a dielectric ball located in the gas supply hole and in contact with the outer surface of the gas mixing pipe;
a gas supply pipe coupled to the gas supply hole to supply gas around the dielectric ball through an internal passage;
a discharge electrode located in the inner passage of the gas supply pipe and in contact with the dielectric ball on the opposite side to the side on which the gas mixing pipe is located;
By including a power source connected to each of the discharge electrode and the gas mixing pipe to generate plasma between the discharge electrode and the gas mixing pipe,
Underwater gas diffuser, characterized in that the plasma generated from the discharge electrode is generated in a dispersed state riding on the surface of the dielectric ball

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