KR102511676B1 - Nano-bubble generator device - Google Patents

Abstract

The present invention is to generate nanobubble water by nanonizing the gas contained in the process of transporting mixed water mixed with water and air, and in particular, it can be applied to small-sized nanobubble facilities or devices through structural simplification and miniaturization. to be able to;
It has a supply port for receiving mixed water having a transfer pressure and a discharge port for discharging it to the outside, and a space between the supply port and the discharge port is sealed against the outside to form a dissolving pressure of gas for water. Equipped with a dissolving space with a melting tank; The mixing water supplied from the supply port is sprayed into the dissolving space, and the lower end is spatially connected to the supply port to receive the mixing water. A spraying means having an exterior made of a 'tube' shaped 'tube' connected to the inner tube while forming an inlet hole through which mixed water flows in between the outer surface of the inner tube; In the nanobubble generator; In the dissolving space, a nanobubble generating device is provided with a collision means for spraying and colliding with the mixing water to reflect and scatter in a space sprayed by the injection means.

Description

Nano-bubble generator device

The present invention relates to a nanobubble generator that generates nanobubbles, which are microbubbles having a microscopic diameter, and more particularly, by converting a gas contained in a mixed water of water and air into nanoparticles in the process of transporting the nanobubbles. It relates to a nanobubble generating device that generates bubbled water and, in particular, can be applied to a small-sized nanobubble facility or device through structural simplification and miniaturization.

In general, nanobubbles are ultra-fine air bubbles that cannot be seen with the naked eye, and are fine air particles with a size of 1/2,000 of normal bubbles and pores of the skin of 25㎛ or less. It generates high sound pressure of 140db, and 3) instantaneous high heat of 4,000 to 6,000 degrees is generated.

In other words, normal bubbles rise in water and rupture on the surface, but nanobubbles are contracted by pressure in water and generate various energies and disappear.

These nanobubbles are microscopic bubbles that are mainly generated when water and air are vigorously rotated.

Such nanobubbles are used in various fields due to their physical and chemical properties such as "gas dissolution effect, self-pressurization effect, and electrification effect", and recently they are used in various aquaculture and hydroponic cultivation, especially in the fields of fishery and agriculture, In the medical field, it is used for precise diagnosis, and it is used in physical therapy, high-purity water treatment, and environmental devices in various fields.

In other words, it is widely used from hot spring bath to cancer diagnosis, and it is known that it regenerates skin and has excellent sterilization effect.

The nanobubbles as described above are generated in various ways such as a swirling liquid flow method, a state mixer method, an ejector method, a banturi method, a pressure dissolution method, an ultrasonic method, an electrolysis method, and a micropore filter method.

In order to generate nanobubbles through these various nanobubble generating facilities or devices, a gas-mixed liquid (supply water) is supplied and the gas is converted into microbubbles to generate nanobubbles.

The mixed water containing these nanobubbles increases the gas dissolution rate in the liquid while suppressing degassing of the nanobubbles in the case of a separate gas dissolving device.

As is known from Korean Patent Application No. 10-2007-0106679 (Name: Gas Dissolving Device/October 23, 2007), the nanobubble dissolving device as described above includes a supply unit including a liquid supply unit and a gas supply unit. ; Dissolving tank coupled to the supply unit; And it is configured to include a discharge coupled to the other side of the dissolving tank; The end of the supply unit is configured to face the inner wall of the melting bath; The mixed water discharged from the end of the supply unit collides with the inner wall of the dissolving tank to receive a collision pressure to increase nanobubble generation.

Korean Patent Application No. 10-2007-0106679

However, such a conventional nanobubble dissolving device has problems in that it is structurally disadvantageous for miniaturization, so that it cannot be economically provided due to poor productivity as well as poor usability, and it is difficult to maximize the generation efficiency of nanobubbles.

The present invention has been proposed to solve the above conventional problems, and an object of the present invention is structurally simple, suitable for miniaturization, and in particular, generating nanobubbles by applying increased collision pressure while mixing water is supplied. An object of the present invention is to provide a nanobubble generating device designed to promote the dissolution of nanobubbles by maximizing the dissolution of the nanobubbles.

In order to achieve the object of the present invention as described above, the nanobubble generator according to the present invention has a supply port for receiving mixed water having a transfer pressure and a discharge port for discharging it to the outside, and a space between the supply port and the discharge port is formed. A dissolving tank sealed against the outside and equipped with a dissolving space to form a dissolving pressure of gas for water; The mixing water supplied from the supply port is sprayed into the dissolving space, and the lower end is spatially connected to the supply port to receive the mixing water. A spraying means having an exterior made of a 'tube' shaped 'tube' connected to the inner tube while forming an inlet hole through which mixed water flows in between the outer surface of the inner tube; In the nanobubble generator; It is characterized in that a collision means is provided in the space sprayed by the injection means in the dissolving space to collide with the mixed water while being sprayed so as to be reflected and scattered.

The nanobubble generating device according to the present invention made as described above is structurally simple, has high production efficiency, is economical, and is particularly suitable for miniaturization, and thus has an effect that can be suitably applied to a small household nanobubble water supply device.

In addition, while the mixing water is injected into the melting space at high pressure through the injection means, the mixed water received in the melting space is re-supplied to the injection means through the inlet hole and re-injected, so that the convection of the mixture water is naturally generated inside the melting space. Formation has the effect of improving the nanobubble generation efficiency

In addition, as the mixed water injected into the dissolving space through the dispensing means collides with the colliding means in the dissolving space of the dissolving tank to be reflected and scattered, the nano-bubble generation efficiency is maximized while promoting fine particles.

1 is a schematic illustration showing a nanobubble generator according to an embodiment of the present invention.
2 is a schematic illustration showing a colliding means constituting the nanobubble generator according to the present embodiment.
3 is a schematic illustration showing a state of use of the nanobubble generator according to the present embodiment.
4 is a schematic illustration of some excerpts showing the coupling structure of the collision means constituting the nanobubble generator according to the present embodiment.
5 is a schematic illustration of some excerpts showing another coupling structure of the collision means constituting the nanobubble generator according to the present embodiment.
6 is a schematic illustration of some excerpts showing another coupling structure of the collision means constituting the nanobubble generator according to the present embodiment.
7 to 9 are schematic views showing various other examples of collision means constituting the nanobubble generator according to the present embodiment.
10 to 13 are schematic views showing various other examples of collision means constituting the nanobubble generator according to the present embodiment.
14 and 15 are schematic views showing other examples of colliding means constituting the nanobubble generator according to the embodiment.

Hereinafter, a nanobubble generator according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the examples described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shapes of elements in the drawings may be exaggerated to emphasize a clearer description. It should be noted that in each drawing, the same members are sometimes indicated by the same reference numerals. Detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention are omitted.

1 to 4 are views showing a nanobubble generator 1 according to an embodiment of the present invention. In the nanobubble generator 1 according to the present embodiment, water and air having transfer pressure are It has a supply port 21 for receiving mixed mixed water and a discharge port 22 for discharging it to the outside, and the space between the supply port 21 and the discharge port 22 is sealed against the outside so that the gas for water A dissolving tank (2) equipped with a dissolving space (A) to form a dissolving pressure of;

That is, the mixed water (for example, a mixture of tap water and air) having a transfer pressure is moved via the dissolution space (A) of the dissolution tank 2 through the transfer pressure forcefully formed on the nanobubble generating system In the process, as the gas contained in the mixed water is dissolved and nano-sized through the dissolution pressure formed in the dissolution space (A), nano-bubble water is generated and supplied to the place of use through the discharge port 22.

In the nanobubble generating device 1 according to this embodiment, in the dissolving tank 2, the supply port 21 and the discharge port 22 are spatially connected to each outer end and each upper side surface. Dissolving bodies 23 provided respectively while being; It may include; a dissolving container 24 having a lower portion open and coupled so that the dissolving body 23 is spatially connected to the upper part of the dissolving body 23 to form the dissolving space A.

That is, the mixed water supplied through the supply port 21 of the dissolution body 23 collides with the inner circumferential surface of the dissolution container 24 while being supplied to the dissolution space A and moves to the discharge port 22 via In the process of dissolving, the gas contained in the mixed water is dissolved through the dissolution pressure formed in the dissolution space (A) to form nanobubbles, and then discharged through the discharge port (22).

The nano bubble generating device 1 according to the present embodiment configured as described above is disposed in the dissolution tank 2 and connects the supply port 21 and the dissolution space A, and is supplied from the supply port 21. and a spraying means (3) configured to spray mixed water into the dissolving space (A).

That is, the mixing water supplied from the supply port 21 is sprayed into the dissolving space A through the dispensing means 3 and the spray pressure generated when spraying is applied to the inner surface of the dissolving container 24. The nanobubble generation efficiency is increased by the collision pressure formed through collision.

In addition, it is economical due to its simple structure and high production efficiency, and is particularly suitable for miniaturization, so it can be suitably applied to a small household nanobubble water supply device.

In the above, the injection means 3 includes an inner tube 31 made of a 'pipe' shaped 'tube' whose lower end is spatially connected to the supply port 21 to receive the mixed water, and a lower end An exterior composed of a 'tube' shaped 'tube' connected to the inner tube 31 while forming an inlet hole 32 through which mixed water flows in between the outer surface of the inner tube 31 and the outer surface of the inner tube 31. (33).

That is, according to the difference between the ejection pressure of the mixed water ejected into the exterior 33 through the inner pipe 31 and the fluid pressure of the dissolving space (A), the mixed water accommodated in the dissolving space (A) It is re-injected while being pushed into the exterior 33 through the inlet hole 32 .

Accordingly, convection of the mixing water is naturally formed inside the dissolving space (A), thereby improving nanobubble generation efficiency.

In this way, while the mixing water is injected into the dissolving space (A) at a high pressure through the dispensing means 3, the mixed water received into the dissolving space A passes through the inlet hole 32 to the dispensing means ( 3), it is re-injected while being re-supplied, and convection of the mixed water is naturally formed inside the dissolving space (A), so that the nano-bubble generation efficiency is improved.

In the above, the lower end of the inner tube 31 may be fitted and screwed to the end of the supply port 21, and on the outer circumferential surface of the lower end of the inner tube 31, a nut provided at the end of the supply port 21 Screw protrusions screwed into are formed so that they can be attached and detached, and it is preferable to apply according to the user's choice.

In the nanobubble generating device 1 according to the present embodiment formed as described above, the mixing water is sprayed and collided with the space sprayed by the spraying means 4 in the dissolving space A to reflect and scatter. A collision means 4 is provided.

That is, the collision means 4 is bound to be disposed at the upper inner portion of the melting tank 24 of the melting tank 2 where the mixed water injected from the injection means 3 primarily collides; The mixed water injected into the dissolving space A through the spray means 3 is reflected and scattered while colliding with the collision means 4, thereby promoting microparticles and maximizing nanobubble generation efficiency.

In the nanobubble generator 1 according to the present embodiment made as described above, the collision means 4 is provided while extending outward from the center, and a plurality of wedge-shaped collision pieces 42 are provided at the outer end It may be formed of a collision plate 41 formed of a 'plate body' in the shape of a 'plate' formed radially.

That is, after the mixing water is injected by the injection means 3, it collides with each of the plurality of collision pieces 42 to improve the collision efficiency, thereby promoting the atomization of the mixing water.

On the other hand, the collision plate 41 may be bound while being fitted into a coupling pin 51 having a 'pin' structure extending from the inner surface of the upper end of the melting container 23; As shown in FIG. 4, it can be coupled while being screwed to the coupling pin 51 having a 'pin' structure with screw protrusions formed on the outer circumferential surface, and is preferably applied according to the user's choice.

As shown in FIG. 5, the collision plate 41 above can be detached while being bolted through the fastening bolt 52 that is bolted while passing through the dissolution tube 24, the user It is preferable to apply according to the selection of.

In addition, the collision plate 41 may be force-fitted to the inner circumferential surface of the dissolution tube 24; In this case, as shown in FIG. 6, at the outer end of the collision plate 41, a coupling ring 53 configured to be elastically supported and forcefully fitted to the inner circumferential surface of the melting container 23 may be provided. It is preferable that it is applied according to the user's choice.

At this time, it can be bound and detached while being elastically supported on the inner circumferential surface of the dissolution tube 24 through the binding ring 53, and is preferably applied according to the user's choice.

In the above, the collision plate 41 may be made of a 'metal material' having a different material so as to be adhered to the melting container 24, and is preferably applied according to the user's choice.

In addition, the collision plate 41 can be bonded to the melting cylinder 24 through 'fusion' such as 'thermal fusion' and 'high frequency fusion', and is preferably applied according to the user's choice.

In the nanobubble generator 1 according to the present embodiment configured as described above, as shown in FIG. 7, the collision plate 41 extends outward from the center and has a plurality of collisions having a length. The rods 43 may be formed of a 'plate body' provided radially. As the mixed water collides with the collision rods 43, the nanobubble generation efficiency is improved.

In the above, the collision plate 41, as shown in FIGS. 8 and 9, is composed of a 'plate body' formed of a plurality of penetrating impact holes, and the mixed water may be atomized while penetrating the impact holes; As shown in FIG. 8, the impact holes may be formed of 'circular impact holes 44' having a 'circular' shape, and as shown in FIG. 9, 'long impact holes 45' having a length. It can be made of, and it is preferable to apply according to the user's selection.

In the nanobubble generator 1 according to the present embodiment made as described above, as shown in FIGS. 10 to 13, the mixing water injected from the injection means 3 passes through the collision plate 41, A through-hole 46 may be formed so as to directly collide with the inner surface of the melting container 24.

That is, the mixed water injected from the injection means 3 passes through the through hole 46 and collides with the inner surface of the dissolving container 24, and then is reflected to the upper surface of the collision plate 41 secondarily. After repeatedly performing multiple reflections and multiple collisions by collision, the nanobubbles can be generated into fine particles while being scattered to the lower part of the collision plate 41, so that the generation efficiency of nanobubbles can be improved.

At this time, the collision plate 41 may be disposed so that the other portion where the through hole 46 is not located is bound to the dissolving tank 24 .

Meanwhile, in the nanobubble generator 1 according to the present embodiment, the collision plate 41 is a 'ring' having an inner diameter and an outer diameter centered on the center, as shown in FIGS. 14 and 15, respectively. ' Shaped collision ring 47 and; It may include a plurality of inner protruding pieces 48 protruding radially around the hem while having a length inward from the inner circumferential surface of the collision ring 47 .

That is, the mixed water injected from the injection means 3 passes through the inner side of the collision ring 47 and collides with the inner surface of the melting container 24, and then is reflected to the upper surface of the inner protruding piece 48. After repeatedly performing multiple reflections and multiple collisions by secondarily colliding with the particles, they are scattered to the lower part of the collision plate 41 and become fine particles, so that the generation efficiency of nanobubbles can be improved.

At this time, some parts of the collision ring 47 can be fixed by being bound to the dissolving tank 24, and it is preferable to apply according to the user's choice.

One embodiment of the present invention described above is only exemplary, and those skilled in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. . Therefore, it will be well understood that the present invention is not limited to the forms mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents and alternatives within the spirit and scope of the present invention as defined by the appended claims.

1: nano bubble generator 2: dissolving tank
21: supply port 22: discharge port
23: dissolving body 24: dissolving tube
3: injection means 31: inner tube
32: inlet hole 33: exterior
4: collision means 41: collision plate
42: crash piece 43: crash bar
44: circular impact ball 45: long impact ball
46: through hole 47: collision ring
48: inner protruding piece 51: coupling pin
52: Fastening bolt 53: Binding ring
A: melting space

Claims (1)

The dissolving body 23 provided with the supply port 21 for receiving the mixed water having the transfer pressure and the outlet port 22 for discharging it to the outside are spatially connected to each outer end and each upper side, respectively, and , The lower part is open and the upper part of the dissolution body 23 is coupled so that the inner space is spatially connected, and the space between the supply port 21 and the discharge port 22 is sealed against the outside, dissolving gas for water a dissolving tank (2) having a dissolving cylinder (24) to form a dissolving space (A) to form a pressure; The mixing water supplied from the supply port 21 is injected into the dissolving space A, and the lower end is spatially connected to the supply port 21 to receive the mixing water in a 'pipe' shape. A 'tube ( A spraying means (3) having an exterior (33) made of a 'tube' in the shape of 'pipe'; In the nano-bubble generating device (1) including; collision means (4) provided in the space sprayed by the injection means (3) in the dissolving space (A) and colliding with the mixed water to reflect and scatter;
The collision means 4,
It is made of a collision plate 41 formed of a 'plate body' in the shape of a 'plate' formed by a plurality of penetrating impact holes and forcefully fitted to the inner circumferential surface of the melting cylinder 24;
The impact holes are
It consists of a 'circular impact hole 44' in a 'circular' shape and a 'long impact hole 45' having a length;
In the collision plate 41,
A nanobubble generator, characterized in that a penetrating through hole 46 is formed so as to directly collide with the inner surface of the melting container 24 while the mixed water injected from the spraying means 3 passes through.

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