KR20230057101A - A Nano bubble generator - Google Patents

Abstract

To enhance the use quality by homogenizing the size of nano-bubbles contained in generated nano-bubble water and improving the quality, the present invention provides a nano-bubble generator comprising: a dissolution tank having a supply hole for receiving mixed water having transport pressure and a discharge hole for discharge to the outside, and including a dissolution space formed in a space between the supply hole and the discharge hole to be sealed to the outside, and forming dissolution pressure for gas in water; and a spray means configured to spray the mixed water, which is supplied from the supply hole, to the dissolution space. Division members having guide wings are provided respectively between a supply space part, into which the mixed water is sprayed and supplied from the dissolution space through the spray means, and a drainage space part for drainage through the discharge hole to divide the dissolution space into a plurality at intervals, to be formed radially around a center by the penetration of the mixed water, and to have a downward inclined angle, thereby guiding the mixed water in the shape of an eddy.

Description

Nano bubble generator {A Nano bubble generator}

The present invention relates to a nanobubble generating device for generating nanobubbles, which are microbubbles having a diameter of microscopic units.

Specifically, in the process of transporting the mixed water mixed with water and air, the contained gas is nano-sized to generate nano-bubble water. It relates to a nanobubble generator that enables

More specifically, it relates to a nanobubble generating device in which the quality of use is increased by homogenizing the size of nanobubbles contained in generated nanobubble water to improve quality.

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 mainly generated when water and air are vigorously rotated in ultra-fine bubbles.

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 venturi 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.

In addition, the mixed water containing the nanobubbles increases the gas dissolution rate inside the liquid while suppressing the degassing of the nanobubbles via 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, the conventional nanobubble dissolving device as described above has problems in that it cannot be economically provided due to poor productivity as well as poor usability due to structural disadvantages to miniaturization, and it is difficult to maximize the generation efficiency of nanobubbles. .

The present invention has been proposed to solve the conventional problems as described above, and an object of the present invention is to generate nanobubbles, which are microbubbles having a microscopic diameter, in which water and air are mixed. It is to provide a nanobubble generating device capable of generating nanobubble water by nanonizing the gas contained in the process of being transported and, in particular, being applicable to small-sized nanobubble facilities or devices through structural simplification and miniaturization. .

Another object of the present invention is to provide a nanobubble generating device that increases the quality of use by homogenizing the size of nanobubbles contained in generated nanobubble water to improve quality.

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; In the nanobubble generating device comprising a; injection means for injecting the mixing water supplied from the supply port into the dissolving space; In the dissolving space, the dissolving space is divided into a plurality of compartments with a gap between the supply space portion through which the mixing water is sprayed and supplied through the spraying means and the drainage space portion drained to the discharge port, and the mixing water passes through the center at the center. It is characterized in that dividing members having guide vanes formed radially and having a downward inclination angle to guide the mixing water in a vortex shape are respectively provided.

The guide holes formed in the space between each of the guide vanes adjacent to each other in the dividing member are each formed in a size gradually decreasing from the supply space part to the drain space part; The number of each of the guide vanes is gradually increased from the supply space to the drainage space, so that the mixing water penetrating area for each of the dividing members has the same size as each other.

The nanobubble generator 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 small household nanobubble facilities.

In addition, while the mixing water is injected at high pressure into the dissolving space through the spraying means, it collides with the inner wall of the dissolving tank to receive an impact load, thereby improving the nanobubble generation efficiency.

In addition, as the mixed water injected into the supply space of the dissolving space through the spraying means passes through the induction holes of the dividing member, the size of the bubbles gradually decreases and finally moves to the drainage space. As the size is homogenized and discharged through the discharge port for use, the quality of the nanobubbles contained in the nanobubble water is improved, and at the same time, the quality of use at the place of use is increased.

That is, while the mixed water passes through each induction hole in each compartment space formed through the dividing member, bubbles having a relatively large inner diameter are prevented from being discharged, as well as nanobubble generation quality is promoted by promoting atomization. This has a maximizing effect.

1 is a schematic perspective view illustrating a nanobubble generator according to an embodiment of the present invention.
2 is a schematic perspective view illustrating a nanobubble generator according to the present embodiment.
3 and 4 are schematic diagrams showing the nanobubble generator according to the present embodiment.
5 is a schematic illustration showing the operating state of the nanobubble generator according to the present embodiment.
6 and 7 are schematic views showing a dividing member constituting the nanobubble generating device according to the present 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 explanation. 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 7 are views showing a nanobubble generator 1 according to an embodiment of the present invention, wherein the nanobubble generator 1 according to the present embodiment supplies mixed water having a transfer pressure. It has a supply port 10 to be received and a discharge port 11 for discharging to the outside, and the space between the supply port 10 and the discharge port 11 is sealed against the outside to form a gas dissolution pressure for water. It consists of including; a dissolving tank (2) provided with a dissolving space (A).

That is, the process in which 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. As the gas contained in the mixed water is dissolved and nano-sized through the dissolution pressure formed in the dissolution space (A) in the dissolution space (A), nano-bubble water is generated.

In addition, the generated nanobubble water is supplied to the place of use through the discharge port 11.

In the above, the dissolving tank 2 includes a dissolving body 21 provided respectively while spatially connected to the respective outer ends and respective upper surfaces of the supply port 10 and the discharge port 11; A dissolving container 22 having a lower portion opened and coupled to form the dissolving space A by coupling the inner space to the upper part of the dissolving body 21 to be spatially connected.

That is, the mixed water supplied through the supply port 10 of the dissolution body 21 collides with the inner circumferential surface of the dissolution tube 22 while being supplied to the dissolution space A and moves to the discharge port 11 via In the process, the gas contained in the mixed water is dissolved through the dissolution pressure formed in the dissolution space (A) to become nanobubbles, and then discharged through the discharge port 11 and supplied to the place of use.

The nanobubble generating device 1 according to the present embodiment configured as described above is disposed in the dissolving tank 2 and spatially connects the supply port 10 and the dissolution space A, and in the supply port 10 and an injection means (3) for injecting the supplied mixed water into the dissolving space (A).

That is, the mixing water supplied from the supply port 10 is sprayed into the dissolving space A through the dispensing means 3, and the dissolution tube 22 has a contact with the inner surface of the dissolution tube 22 through the spray pressure generated when spraying. 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 having a 'pipe' shape with a lower end spatially connected to the supply port 10 to receive mixed water, and a lower end of the inner tube ( 31) may include an exterior 32 formed of a 'pipe' shape connected to the inner tube 31 while forming an inlet hole through which mixed water flows in between the outer surface of the tube 31).

That is, according to the difference between the ejection pressure of the mixed water ejected into the exterior 32 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 pressed into the exterior 32 through the inlet hole.

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 accommodated in the dissolving space (A) is returned to the dispensing means (3) through the inlet hole. As it is supplied, it is re-injected, and convection of the mixed water is naturally formed inside the dissolving space (A), so that the nanobubble generation efficiency is improved.

The lower end of the inner tube 31 may be fitted and screwed to the end of the supply port 10; On the outer circumferential surface of the lower end of the inner tube 31, screw protrusions screwed to the nut provided at the end of the supply port 10 are formed to be detachable; It is preferable that the configuration and structure according to the user's selection among conventionally known technologies are suitably applied.

The nano-bubble generating device 1 according to the present embodiment configured as described above includes the supply space portion B and the discharge port 11 in which mixed water is sprayed and supplied from the dissolution space A through the injection means 3. ), the dissolving space (A) is partitioned into a plurality while having a gap, and the mixing water is formed radially around the center while passing through, and has a downward inclination angle so that the mixing water Dividing members 4 each having guide vanes 41 induced in a vortex shape are provided.

That is, the dissolving space (A) is divided into a plurality of partitions through the dividing member (4); After the mixed water is injected and supplied to the melting space (A) through the spraying means (3), the discharge port is passed through the space between each of the guide vanes (41) of each of the dividing members (4). After moving to (11), it is discharged to the outside and supplied to the place of use.

In the nano-bubble generating device 1 according to the present embodiment made as described above, the guide holes 42 formed in the space between each of the guide vanes 41 adjacent to each other in the dividing member 4 are connected to the supply space. It is formed in a size that gradually decreases as it goes from the portion (B) to the drainage space portion (C).

That is, while the mixed water injected into the supply space part (B) of the dissolving space (A) through the injection means (3) passes through each of the induction holes (42) of the branch members (4), respectively. As the size of the contained bubbles 100 gradually decreases and finally moves to the drainage space C, the size of the contained fine bubbles is homogenized.

In addition, the nanobubble water moved to the drainage space part (C) is discharged through the discharge port (11) and supplied to a place of use and used.

Accordingly, the quality of nanobubbles contained in the nanobubble water used at the place of use is improved in terms of homogenization and refinement, thereby increasing the quality of use at the place of use.

At this time, the air bubbles 100 having a relatively large inner diameter among the air bubbles 100 contained while the mixed water passes through each of the plurality of dividing members 4 are prevented from being finally discharged through the discharge port 11.

In addition, the bubbles 100 contained in the mixed water pass through each of the induction holes 42 to promote atomization, thereby maximizing the quality of generating nanobubbles.

In the above, the dividing member 4 has an inner ring 44 formed with an inner contact hole 43 to which the outer circumferential surface of the injection means 3 is aligned while being in close contact with the inner side, and the outer circumferential surface is the inner surface of the dissolution space (A) An outer ring 45 that is in close contact while being fitted is provided; The guide vanes 41 may be integrally formed while connecting the inner ring 44 and the outer ring 45 to each other.

That is, the inner contact hole 43 of the inner ring 44 seals and supports the space between the outer circumferential surface of the injection means 3, and the outer circumferential surface of the outer ring 45 is inside the melting space (A). It is disposed while supporting while sealing between the side surfaces, and may divide the melting space (A) while spatially partitioning the upper and lower parts of the dividing member (4).

At this time, the guide holes 42 spatially connect the upper and lower parts of the partitioned member 4; Mixed water may move through the guide holes 42 .

Accordingly, the bubbles 100 having a larger size than the inner diameter of the guide hole 42 cannot move through the perforated plate 4 .

Therefore, only the bubbles 100 having a size smaller than the inner diameter of the guide hole 42 move, so that the size of the bubbles 100 contained in the mixing water can be homogenized.

In the nano-bubble generator 1 according to the present embodiment configured as described above, the mixing water passing through the plurality of dividing members 4, respectively, is formed in the guide hole formed in the space between each of the guide vanes 41. (42), respectively.

That is, as the inner diameter of each of the guide holes 42 of each of the dividing members 4 disposed from the supply space portion B to the drain space portion C gradually decreases, the supply space portion The size of the bubbles 100 contained in the mixed water moving from (B) to the drainage space (C) gradually decreases.

At this time, the air bubbles 100 that do not pass through the guide holes 42 remain in the dissolving space A and are gradually melted and gradually reduced in size, and when the inner diameter of each guide hole 42 becomes smaller. , It can be moved to the partitioned space in the order while passing through each of the guide holes 42 .

Accordingly, the size of the air bubbles 100 contained while passing through each of the induction holes 42 of the dividing members 4 gradually decreases while finally moving to the drainage space portion C, The size of microbubbles can be homogenized.

On the other hand, in the nano bubble generator 1 according to the present embodiment, the number of each of the guide vanes 41 formed on each of the dividing members 4 is the drain hole in the supply space part B It gradually increases as it goes toward the intermediate portion C, so that the mixing water penetration area for each of the dividing members 4 may have the same size as each other.

That is, the area of the passage space for the mixing water in each of the partition spaces formed through each of the dividing members 4 is made the same, so that the movement of the mixing water in the dissolving space (A) is stably achieved. can

Accordingly, the nanobubble generation efficiency can be stably maintained.

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
10: supply port 11: discharge port
100: bubble 2: melting tank
21: dissolving body 22: dissolving vessel
3: injection means 31: inner tube
32: appearance 4: dividing member
41: induction wing 42: induction ball
43: inner close hole 44: inner ring
45: outer ring
A: melting space B: supply space
C: drainage space

Claims (2)

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 dissolving tank; In the nanobubble generating device comprising a; injection means for injecting the mixing water supplied from the supply port into the dissolving space;
Between the supply space portion in which the mixed water is injected and supplied through the injection means in the melting space and the drainage space portion drained to the discharge port,
The dissolving space is divided into a plurality of sections with intervals, and the mixing water penetrates and is radially formed around the center and has a downward inclination angle to guide the mixing water into a vortex shape. Dividing members having guide vanes are provided, respectively. A nanobubble generator, characterized in that. According to claim 1;
Induction holes formed in the space between each of the guide vanes adjacent to each other in the dividing member,
Doedoe each formed in a size that gradually becomes smaller as it goes from the supply space to the drainage space;
The number of each of the guide vanes,
The nano-bubble generator, characterized in that the area gradually increases from the supply space to the drainage space, so that the mixing water penetration area for each of the dividing members has a size matched with each other.

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