KR101168330B1 - Device for making ozonic nano buble with applying pressure - Google Patents

Abstract

The pressurized nanobubble ozone growth growth unit is provided with an ozone generating unit for supplying ozone to a water valve, and a drainage part of the water valve generates bubbles by forming a vortex in the water by a rotating screw, and the water in which the bubble is formed is a plurality of mesh nets. It comprises a nanobubble generating unit for generating a nanobubble while passing through. According to the pressurized nanobubble ozone generating device configured as described above, the nanobubble is generated in the water containing ozone by using the nanobubble generating unit, thereby maximizing the effect of ozone and the effect of nanobubble.

Description

Pressurized nanobubble ozone generator {DEVICE FOR MAKING OZONIC NANO BUBLE WITH APPLYING PRESSURE}

The present invention relates to a pressurized nanobubble ozone generating device, and more particularly, to a device for producing and supplying nanobubble and ozone to water supplied from a faucet.

Nanobubble means very fine bubbles having a diameter of 1 μm or less, and water containing nanobubble ozone can maintain a sterilizing effect for one month or more. Nanobubbles are prepared by a method of pulverizing by applying pressure to water containing electrolyte ions, and can be stabilized by instantaneously crushing nanobubbles in water containing electrolyte ions.

Such nanobubbles are known to have an effective effect on odor removal effect, antibacterial effect, exfoliation, skin aging, fatigue recovery, prevention of various skin diseases, asthma, bronchitis and nervous system.

In addition, ozone has a strong oxidizing power as an allotrope of oxygen, and has effects such as sterilization, deodorization, and detoxification. As a method of artificially generating such ozone, there are a silent discharge method, an electrolytic method, and a photochemical method, but the silent discharge method is most widely used.

As described above, the nanobubbles have an odor removal effect, an antibacterial effect, and ozone have effects such as sterilization, disinfection and deodorization. It is not developed.

The present invention is to solve such a conventional problem, it is an object of the present invention to provide a device having a sterilization and cleaning effect by generating nanobubbles and ozone.

According to a feature of the present invention for achieving the above object, the pressurized nanobubble ozone growth value of the present invention is connected to the water valve, ozone generating unit for generating ozone and supplying ozone to the water valve by high pressure air; It is preferable to include a nanobubble generating unit which is provided in the drain of the water valve to which the ozone generated by the ozone generating unit is supplied, and forms a nanobubble by a rotating body and a mesh net provided therein.

The ozone generating unit of the present invention preferably includes an air pump unit for generating high pressure air and an ozone generating unit for generating ozone.

The ozone generating unit of the present invention is preferably connected to the lower surface of the central barrel portion of the water valve.

The nanobubble generating unit of the present invention includes a unit body installed inside the shower case; Rotation screw is installed in the inner chamber of the unit body; and preferably at least one mesh net is installed in the mesh network chamber in communication with the inner chamber.

In the inner chamber of the present invention, it is preferable that a converging chamber is formed, the width of which narrows toward the mesh network chamber.

Preferably, the unit body of the present invention includes a screw ring mounted to the inner chamber and assisting rotation of the rotating screw.

The rotating screw of the present invention preferably includes a radially formed inlet hole and a plurality of moving paths communicating with the inlet hole and passing through the rotating screw in an oblique direction.

Preferably, the unit body of the present invention includes a mesh net holder provided in the mesh net chamber and including four mesh nets.

In the mesh net holder of the present invention, it is preferable that a relatively large mesh net and a relatively small mesh net are alternately installed.

The mesh net of the present invention is preferably composed of a mesh net diameter of 400mm and a mesh net diameter of 100mm.

Preferably, the unit body of the present invention includes a mesh net ring for preventing the mesh net holder from being separated.

According to the pressurized nanobubble ozone generating device according to the present invention, by using the nanobubble generating unit to generate nanobubbles in water containing ozone has the advantage of maximizing the effects of ozone and the effects of nanobubbles. have.

In other words, it is accompanied by ozone, which helps to disinfect, disinfect, deodorize and completely remove contaminants and maintain cleanliness by removing secondary contaminants or toxic residues. By supplying oxygen and oxygen, it has the effect of skin beauty, germ removal, pore reduction, etc. It is beneficial to atopy and skin disease. It is a device that can be sanitized or sanitized at home or restaurant by combining ozone and nanobubbles. It can be used as a function to remove the virus of fish and shellfish fragile due to inflammation, there is an advantage that can be applied to processed products or livestock industry.

1 is a perspective view showing a preferred embodiment of the pressurized nanobubble ozone generating device according to the present invention.
Figure 2 is a schematic view showing the configuration of the pressurized nanobubble ozone generating device according to the present invention.
Figure 3 is a front view showing the ozone generating unit of the pressurized nanobubble ozone generating device according to the present invention.
Figure 4 is a cross-sectional view showing a preferred embodiment of the nanobubble generating unit of the pressurized nanobubble ozone generating device according to the present invention.
Figure 5 is a plan view showing a rotating screw of the pressurized nanobubble ozone generating device according to the present invention.
Fig. 6 is a sectional view of Fig. 5; Fig.
Figure 7 is a plan view showing a screw ring of the pressurized nanobubble ozone generator according to the present invention.
8 is a cross-sectional view of FIG.
Figure 9 is a plan view showing a mesh of the pressurized nanobubble ozone generating device according to the present invention.
Figure 10 is a plan view showing a mesh net ring of the pressurized nanobubble ozone generating device according to the present invention.
11 is a cross-sectional view of FIG. 10.

Hereinafter, a preferred embodiment of the pressurized nanobubble ozone generating device according to the present invention will be described in more detail with reference to the accompanying drawings.

1 to 11 show a preferred embodiment of the pressurized nanobubble ozone generating device according to the present invention.

As shown, the ozone generating unit 10 and the nanobubble generating unit 40 of the present invention are connected to the water valve 1 manufactured to control cold water and hot water. The ozone generating unit 10 is to generate ozone to supply ozone to water by high pressure air, and the nanobubble generating unit 40 is water mixed with ozone generated by the ozone generating unit 10. To generate nanobubbles.

The ozone generating unit 10 is connected to the water valve 1, the ozone generating unit 10 is connected to the lower surface of the central barrel portion 5 is provided with the on-off valve 3 of the water valve 1 It is preferable.

Alternatively, a separate connecting portion 7 is provided on the lower surface of the central barrel portion 5, and the ozone generating unit connecting pipe 9a and the nanobubble generating unit are connected to the ozone generating unit 10 at the connecting portion 7. The nanobubble generating unit connector 9b connected to the shower case 41 provided with the 40 may be connected.

2 shows the configuration of the ozone generating unit 10. The ozone generating unit 10 generates ozone to supply ozone to the water valve 1 by high pressure air. As shown, the ozone generating unit 10 is provided with an air pump part 11 for forming high pressure air.

The high pressure air generated by the air pump 11 is supplied to the ozone generator 20. A control valve 15 for controlling the air flow may be provided between the air pump unit 11 and the ozone generator 20.

The ozone generator 20 generates ozone, and the generated ozone is discharged to the outside through high pressure air generated by the air pump 11. The ozone generator 20 may be configured as a general ozone generator. As shown in FIG. 3, the ozone generator 20 includes a tubular dielectric 21 having inlets 25 and outlets 27 formed on both sides of the hollow part 23.

An outer electrode 31 is provided on an outer circumferential surface of the dielectric 21, and a coil-shaped inner electrode 33 coupled to the hollow part 23 at a predetermined interval is provided inside the dielectric 21. Therefore, the internal electrode 33 and the external electrode 31 generate ozone by silent discharge by discharge power supplied from the outside. The control valve 15 may also be provided in a pipe through which ozone generated by the ozone generator 20 is discharged to the outside.

The ozone generated by the ozone generator 20 is delivered to the connector 7 through the ozone generator unit connecting pipe 9a by high pressure air. The connecting portion 7 mixes the ozone provided by the ozone generating portion 20 with the water supplied by the water valve 1.

The connection part 7 may be provided with a one-way valve so that water supplied by the water valve 1 does not flow into the ozone generating unit connecting pipe 9a.

Water mixed with ozone in the connecting portion 7 is introduced into the nanobubble generating unit 40 through the nanobubble generating unit connecting pipe (9b). The nanobubble generating unit 40 serves to generate nanobubbles in water mixed with ozone generated by the ozone generating unit 10.

The nanobubble generating unit 40 may be provided in the shower case 41, as shown in FIG. Alternatively, it may be installed directly on the water valve 1, it may be applied to any device having a drain through which the water drained from the water valve 1 passes. The nanobubble generating unit 40 includes a unit body 43 formed to correspond to an inner shape of the shower case 41.

One end of the unit body 43 connected to the nanobubble generating unit connecting pipe 9b is formed with an inserting chamber 45 for inserting the connecting pipe 9b. An inner chamber 47 is formed below the inserting chamber 45 to rotate the fluid drawn into the unit body 43 to form a vortex in the fluid.

The inner chamber 47 is provided with a rotating screw 50 that is a rotating body for forming a swirl in the fluid. The rotating screw 50 is formed in a cylindrical shape as shown in Figure 5, the upper surface of the rotating screw 50 is formed with a plurality of inlet holes 51 extending radially.

In addition, a plurality of moving paths 53 are formed in the rotation screw 50 to communicate with the inlet hole 51 and penetrate the rotation screw 50 in an oblique direction. Therefore, the fluid flowing into the inlet hole 51 of the rotating screw 50 is injected downward of the rotating screw 50 while moving in an oblique direction along the moving path 53.

In addition, a screw ring 60 is provided above the rotary screw 50 to assist smooth rotation of the rotary screw 50. The screw ring 60 is fixed to the fastening end 49 provided in the inner chamber 47.

The screw ring 60 is formed in a circular ring shape as shown in Figs. According to the cross-sectional shape of the screw ring 60 shown in Figure 8, the surface located in the direction in contact with the rotating screw 50 in the outer peripheral portion of the screw ring 60 is formed relatively narrower than the opposite surface do. Therefore, since the area in contact with the rotating screw 50 is relatively small, the rotating screw 50 can be smoothly rotated.

In addition, a converging chamber 47 'is formed in the inner chamber 47 below the rotating screw 50 so as to decrease in diameter downward. The fluid in which the vortex flow is formed by the rotating screw 50 converges in the convergence chamber 47 'and is injected downward.

Below the inner chamber 47, a mesh network chamber 70 communicating with the inner chamber 47 is formed. The mesh net chamber 70 is provided with a mesh net holder 71 for mounting a plurality of mesh nets. A total of four mesh nets may be mounted on the mesh net holder 71.

A mesh net 73 mounted to the mesh net holder 71 is shown in FIG. 9. The mesh net holder 71 may be provided with a mesh net 73a having a relatively large diameter and a mesh net 73b having a relatively small diameter. It is preferable that the diameter of the relatively large mesh net 73a is 400 mm, and the diameter of the relatively small mesh net 73 b is 100 mm.

The mesh net chamber 70 may be alternately mounted with a 400 mm mesh net 73a and a 100 mm mesh net 73b in the vertical direction. As such, by alternately installing meshes having different diameters, nanobubbles may be more easily formed in the fluid.

The mesh net ring 75 is provided below the mesh net holder 71 to prevent the mesh net holder 71 from being separated. The mesh net ring 75 is configured to be detachable to exchange the mesh net 73.

The fluid passing through the mesh network chamber 70 is injected outside the shower case 41 through the unit body 43.

Hereinafter, the operation of the pressurized nanobubble ozone generator according to the present invention having the configuration as described above will be described in detail.

First, ozone generated by the ozone generating unit 20 of the ozone generating unit 10 is supplied to the water valve 1 by the high pressure air generated by the air pump unit 11. The ozone supplied to the connection portion 7 of the water valve 1 is supplied to the nanobubble generating unit 40 in a mixed state with the water supplied by the water valve 1.

Water supplied to the nanobubble generating unit 40 is first introduced into the inner chamber 47. Then, the rotating screw 50 of the inner chamber 47 is automatically rotated by the water pressure, bubbles are generated in the water by the rotation of the rotating screw 50.

Water bubbled by the rotating screw 50 is compressed while passing through the convergence chamber 47 ', and the compressed water is introduced into the mesh network chamber 70 as it is. Since the mesh net chamber 70 has a total of four mesh nets 73, the water passing through the inner chamber 47 passes through the four mesh nets 73.

When water passes through the mesh net 73, bubbles contained in the water are crushed into nano bubbles by the mesh net 73. The nanobubbles generated by the mesh net 73 are discharged to the outside of the shower case 41.

In the scope of the basic technical spirit of the present invention, many modifications are possible to those skilled in the art, and the scope of the present invention should be interpreted based on the claims which will be described later. .

Description of the main parts of the drawing
10: ozone generating unit 11: air pump unit
20: ozone generating unit 40: nano bubble generating unit
43: unit body 45: inserting chamber
47: inner chamber 50; Rotary screw
47 ': Convergence chamber 60: Screw ring
70: mesh net chamber 71: mesh net holder
73: mesh net 75: mesh net ring

Claims (12)

An ozone generating unit connected to the water valve and generating ozone to supply ozone to the water valve by high pressure air;
And a nanobubble generating unit which is provided at a drain of the water valve to which ozone generated by the ozone generating unit is supplied, and forms nanobubbles by a rotating body and a mesh net provided therein,
The nanobubble generating unit
A unit body installed inside the shower case;
A rotating screw installed in the inner chamber of the unit body; and
At least one mesh net installed in the mesh net chamber communicating with the inner chamber;
Pressurized nanobubble ozone generator.
The method of claim 1,
The ozone generating unit
An air pump unit for generating high pressure air;
Including an ozone generating unit for generating ozone
Pressurized nanobubble ozone generator.
The method of claim 1,
The ozone generating unit
Is connected to the lower surface of the central barrel portion of the water valve
Pressurized nanobubble ozone generator.
delete The method of claim 1,
In the inner chamber, a convergent chamber is formed in which the width narrows toward the mesh network chamber.
Pressurized nanobubble ozone generator.
The method of claim 1,
The unit body is
A screw ring mounted to the inner chamber and configured to assist rotation of the rotating screw.
Pressurized nanobubble ozone generator.
The method of claim 1,
The rotating screw is
An incoming hole formed radially,
It includes a plurality of moving passages in communication with the inlet hole penetrating the rotating screw in an oblique direction
Pressurized nanobubble ozone generator.
The method of claim 1,
The unit body is
The mesh net chamber is provided, and includes a mesh net holder including four mesh nets.
Pressurized nanobubble ozone generator.
The method of claim 8,
The mesh net holder
Relatively large meshes and relatively small meshes are installed alternately
Pressurized nanobubble ozone generator.
10. The method of claim 9,
The mesh net
Mesh mesh with 400mm diameter and mesh mesh with 100mm diameter
Pressurized nanobubble ozone generator.
The method of claim 8,
The unit body is
A mesh net ring for preventing the mesh net holder from being separated
Pressurized nanobubble ozone generator.
The nanobubble generating unit according to any one of claims 1 to 3 and 5 to 11.

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