KR102299550B1 - A nano bubble generator - Google Patents

Abstract

The present invention provides not only effective impact pressure and shear pressure in the process of moving mixed water in which water and air are mixed, but also to implement structural simplification and miniaturization; It has an inlet hole through which the mixed water mixed with water and air is introduced and a discharge hole through which the nanobubbles are generated by applying a collision pressure and a shear pressure while the mixed water is moving in the space between the inlet hole and the discharge hole. In the bubble generator; an inlet body having the inlet hole formed at the front end and having an open rear end; The discharge body is provided with the discharge hole at the front end, and the inlet body is bound so that the opening of the inlet body is spatially connected, and the discharge body is formed with a discharge opening through which the mixed water is discharged to the outside at the rear end; forming a bubble generating space configured to generate nano-bubbles while the mixed water is moved by spatially connecting the inlet duct and the discharging hole at a binding portion of the inlet body and the discharging body; On the surface of the discharge body in contact with the bubble generating space, a collision surface is formed in which the mixed water introduced through the inlet hole collides as the dry end approaches the inlet hole while having a length extending in the direction toward the inlet hole. The collision protrusion is integrally formed; The discharge hole provides a nano-bubble generator which is formed while being disposed radially at a position spaced apart from the outer circumferential surface of the collision protrusion in the bulkhead in which the collision protrusion is integrally formed in the discharge body.

Description

A nano bubble generator

The present invention relates to a nano-bubble generator for generating nano-bubbles, which are microbubbles having a nano-unit in diameter, and more particularly, to efficiently control collision pressure and shear pressure in the process of moving mixed water in which water and air are mixed. It relates to a nanobubble generator that not only improves the efficiency of generating nanobubbles, but also can be applied to small nanobubble facilities or devices through structural simplification and miniaturization, thereby realizing economic benefits.

In general, nanobubbles are ultra-fine bubbles that cannot be seen with the naked eye. They are microscopic air particles less than 25㎛ in pores of the skin with 1/2000 of the size of normal bubbles. 3) Instantaneous high heat of 4,000 to 6,000 degrees is generated.

In other words, normal bubbles rise in water and burst on the surface, but nanobubbles are reduced by pressure in the water, generating various energy and disappearing.

These nanobubbles are microscopic bubbles that occur mainly when water and air are violently rotated.

Such nanobubbles are being used in various fields due to their physical and chemical properties such as "gas dissolution effect, self-pressurization effect, and electrification effect". In the medical field, it is used for precision diagnosis, and in various fields, it is used for physical therapy, high-purity water treatment, and environmental devices.

In other words, its use ranges from hot spring baths to cancer diagnosis, and it is known to regenerate the skin and to have an excellent sterilization effect.

Nanobubbles as described above are generated in various ways, such as a swirling liquid flow type, a state mixer type, an ejector type, a venturi type, a pressure dissolution type, an ultrasonic type, an electrolysis type, and a micropore filter type.

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

The process of converting the feed water into microbubbles in the above is made through the process of separating and compressing the feedwater (a mixture of water and air) containing bubbles while passing through the microtubule of the generating means provided with the microtubule.

As one of the nanobubble generators that generate nanobubbles as described above, there is Korean Patent Registration No. 10-1146040 (name: nanobubble generator), and the nanobubble generator is, as described in the publication, A bubble generating chamber provided with a water inlet through which water is introduced, an air inlet through which air is introduced and an outlet through which air is discharged, is provided between the water inlet and the air inlet and the outlet of the bubble generating chamber and is rotated by being inserted into the shaft of the motor and rotated through the water inlet. and a rotating disk provided with a plurality of guide holes through which water introduced through the air inlet is guided, and a rotation disk provided to be in close contact with the movement direction of water and air of the rotary disk, and branch the water and air induced through the guide hole in an outward direction It consists of a fixed disk provided with a plurality of stirring pieces protruding in the direction of the rotating disk to stir water and air according to the rotation of the rotating disk at the same time.

Accordingly, water and air are not only stirred while rubbing with the stirring pieces, but also rubbed while passing between the stirring pieces with a jig jack, so that the water and air are strongly stirred and compressed at the same time as if crushed.

Such an impact-type microbubble generator not only requires a high pressure of 5 to 20 bar, but also has a large flow loss, and requires a large number of nozzles and a large mixing tank, thereby complicating the structure and equipment of the device. .

On the other hand, the swirling liquid flow type microbubble generator generates nanobubbles through the conveying pressure introduced in the process of conveying the mixed water mixed with water and air through the space in a vortex, like the impact type nozzle method. Nanobubbles are generated by the vortex pressure generated while the mixed water is transported while forming a vortex by forming a vortex-type pipe.

However, the device for generating microbubbles of the swirling liquid flow method has a problem in that it cannot generate microbubbles through a single nozzle and requires a high pressure as well as a bulky mixing tank.

1. Korea Patent Registration No. 10-1146040

The present invention has been proposed to solve the problems of the conventional nano-bubble generators as described above, and an object of the present invention is to efficiently control the collision pressure and shear pressure in the process of moving mixed water in which water and air are mixed. It is to provide a nano-bubble generator that can be applied to small-sized nano-bubble facilities or devices through structural simplification and miniaturization, as well as to realize economic benefits.

The nano-bubble generator of the present invention for achieving the object of the present invention as described above has an inlet hole through which the mixed water mixed with water and air is introduced and a discharge hole through which the mixed water is disposed in a space between the inlet hole and the discharge hole. A nanobubble generator configured to generate nanobubbles by applying impact pressure and shear pressure while moving; an inlet body having the inlet hole formed at the front end and having an open rear end; The discharge body is provided with the discharge hole at the front end, and the inlet body is bound so that the opening of the inlet body is spatially connected, and the discharge body is formed with a discharge opening through which the mixed water is discharged to the outside at the rear end; forming a bubble generating space configured to generate nano-bubbles while the mixed water is moved by spatially connecting the inlet duct and the discharging hole at a binding portion of the inlet body and the discharging body; On the surface of the discharge body in contact with the bubble generating space, a collision surface is formed in which the mixed water introduced through the inlet hole collides as the dry end approaches the inlet hole while having a length extending in the direction toward the inlet hole. The collision protrusion is integrally formed; The discharge hole is characterized in that it is formed as a plurality of radially arranged at a position spaced apart from the outer circumferential surface of the collision protrusion in the bulkhead in which the collision protrusion is integrally formed in the discharge body.

The nano-bubble generator according to the present invention configured as described above, while the mixed water introduced into the bubble generating space through the inlet hole of the inlet body is discharged through the discharge hole of the discharge body, the collision pressure with the collision surface of the collision protrusion is applied. Of course, it has the effect of efficiently generating nanobubbles by applying shear pressure while guiding the outer peripheral surface of the collision protrusion.

In addition, production efficiency is improved through structural simplification, miniaturization, and convenience of the manufacturing process, and it can be applied to small nano-bubble facilities or devices, thereby realizing economic benefits and improving usage efficiency.

1 is a schematic exploded perspective view showing a nano-bubble generator according to an embodiment according to the present invention.
Figure 2 is a schematic cross-sectional view showing a nano-bubble generator according to the present embodiment.
Figure 3 is a schematic illustration showing the application state of the nano-bubble generator according to the present embodiment.
4 is a schematic illustration of some excerpts showing a bubble generating space constituting a nano-bubble generator according to the present embodiment.
5 is a schematic cross-sectional view showing a state of use of the nano-bubble generator 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 embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those of ordinary skill in the art. Accordingly, the shape of elements in the drawings may be exaggerated to emphasize a clearer description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals. Detailed descriptions of well-known functions and configurations determined to unnecessarily obscure the gist of the present invention will be omitted.

1 to 6 is a view showing a nano-bubble generator 1 according to an embodiment according to the present invention. The nano-bubble generator 1 according to this embodiment is a mixed water in which water and air are mixed. It has an inlet hole 21 and a discharge hole 31 through which it is discharged, and a collision pressure and a shear pressure are applied to the space between the inlet hole 21 and the discharge hole 31 while the mixed water is moving to generate nanobubbles. applied to making

The nano-bubble generator 1 according to this embodiment includes an inlet body 2 having the inlet hole 21 formed at the front end and having an open rear end; The discharge hole 31 is provided at the front end, and the inlet body 2 is bound so that the opening of the inlet body 2 is spatially connected, and the discharge opening 32 through which the mixed water is discharged to the outside is formed at the rear end. Body (3); is made including.

That is, the rear end of the inlet body 2 is bound to each other and assembled to the front end of the discharge body 3, and as shown in FIG. 3, the transfer space of the machine body 10 having a transfer space to which the mixed water is transferred. The mixed water introduced through the inlet hole 21 of the inlet body 2 in a state coupled to the inlet is discharged to the outlet opening 32 via the outlet hole 31 of the outlet body 3 .

In the nano-bubble generator 1 according to this embodiment made as described above, at the binding portion of the inlet body 2 and the discharge body 3, the inlet hole 21 and the discharge hole 31 are spatially formed. A bubble generating space (A) is formed to generate nano-bubbles while the mixed water is moved by connection.

That is, the front end of the discharge body (3) and the rear end of the inlet body (2) are assembled by binding to each other while forming the bubble generating space (A); When the mixed water is introduced through the inlet hole 21 and discharged to the discharge hole 31, it is applied with a collision pressure and a shear pressure while moving through the bubble generating space (A) to form nano-bubbles.

In the above, the rear end of the inlet body 2 and the front end of the discharge body 3 are preferably formed with a nut portion and a screw portion to be coupled through screw coupling, respectively.

Accordingly, the production efficiency is improved through structural simplification, miniaturization, and convenience of the manufacturing process, as well as being applicable to a small nano-bubble facility or the machine body 10 and device, thereby realizing economic benefits and improving the use efficiency. .

In the nano-bubble generator 1 according to this embodiment made as described above, the surface in contact with the bubble generating space A in the discharge body 3 extends while having a length in the direction toward the inlet hole 21 . The collision protrusion 4 is integrally formed so as to form a collision surface 41 on which the mixed water introduced through the inlet hole 21 collides while the dry end approaches the inlet hole 21 .

That is, while the mixed water introduced into the bubble generating space (A) through the inlet hole (21) of the inlet body (2) is discharged through the outlet hole (31) of the discharge body (3), the collision protrusion (4) ) of the collision surface 41 is applied, as well as the shear pressure is applied while guiding the outer circumferential surface of the collision protrusion 4 to efficiently generate nanobubbles.

In the above, the interval between the inlet hole 21 and the collision surface 41 can be selectively adjusted by the user when assembling the discharge body 3 and the inlet body 2 by manipulating the screwed state. It creates an impact pressure of magnitude.

In the nano-bubble generator 1 according to this embodiment made as described above, the discharge hole 31 is the collision protrusion in the partition wall 33 in which the collision protrusion 4 is integrally formed in the discharge body 3 . (4) is formed as a plurality of radially arranged at a spaced apart position from the outer circumferential surface.

That is, the mixed water guided along the outer circumferential surface of the collision protrusion 4 in the bubble generating space A is stably discharged through the discharge opening 32 while penetrating the plurality of discharge holes 31 .

On the other hand, in the nanobubble generator 1 according to this embodiment, the collision surface 41 is preferably formed to have an outer diameter larger than the inner diameter of the inlet hole 21; It is most preferable that the 'diffusion groove' of the 'arc' shape is formed in the direction in which the mixed water moves,

That is, the mixed water flowing in through the inlet hole 21 through the diffusion groove collides and is diffused (scattered) while being reflected radially at the same time to increase the nanobubble generation efficiency.

In the nano-bubble generator 1 according to the present embodiment made as described above, the collision protrusion 4 protrudes in the shape of a 'cylinder' when it has a length from the partition wall 33 to the inlet hole 21 side. It is preferably molded into a pressure control groove (42) spatially connected to the discharge opening (32) is formed therein; It is preferable that the gas degassed from the mixed water filled in the discharge opening 32 is guided to the air pressure control groove 42 to adjust the air pressure of the discharge opening 32 .

In addition, in the collision protrusion 4, as shown in FIG. 4, the air pressure control groove 42 and the bubble to guide the gas filled in the air pressure control groove 42 to the bubble generating space (A). It is preferable that the exhaust hole 43 for spatially connecting the generation space (A) is formed.

In the above, the exhaust hole 43 has a length from the inner circumferential surface of the air pressure control groove 42 to the outer circumferential surface side of the collision protrusion 4; It is most preferable to be provided while forming an inclination angle in the direction in which the mixed water is moved.

Accordingly, the mixed water is prevented from flowing backward from the bubble generating space (A) to the air pressure control groove (42).

In the above, the rear end inner surface of the inlet body 3 has a vortex inclined surface 22 in the shape of a 'funnel' that gradually decreases in inner diameter toward the discharge hole 31 in the lateral direction, It is desirable to form a vortex on the inner circumferential surface of 2) and to move while receiving shear pressure.

Although the present invention has been described with the above examples, the present invention is not necessarily limited to these examples, and various modifications may be made within the scope without departing from the technical spirit of the present invention. Therefore, the examples disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these examples. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1: nano bubble generator 2: inlet body
21: inlet hole 22: vortex slope
3: discharge body 31: discharge hole
32: exhaust opening 33: bulkhead
4: collision protrusion 41: collision surface
42: air pressure control groove 43: exhaust hole
10: Machine body A: Bubble generating space

Claims (1)

It has an inlet hole 21 through which the mixed water mixed with water and air is introduced and a discharge hole 31 through which the mixed water is discharged, and the collision pressure while the mixed water moves in the space between the inlet hole 21 and the discharge hole 31 and an inlet body 2 having the inlet hole 21 formed at the front end and having an open rear end so as to generate nano-bubbles by applying and shear pressure; The discharge hole 31 is provided at the front end, and the inlet body 2 is bound so that the opening of the inlet body 2 is spatially connected, and the discharge opening 32 through which the mixed water is discharged to the outside is formed at the rear end. Body (3); Doedoe including;
At the binding portion of the inlet body 2 and the outlet body 3, the inlet hole 21 and the outlet hole 31 are spatially connected to generate a nano bubble while the mixed water moves. forming space (A);
On the surface in contact with the bubble generating space (A) of the discharge body (3), the inlet hole (21) is formed to extend while having a length in the direction toward the inlet hole (21), and the front end is close to the inlet hole (21). 21) the collision protrusion 4 is integrally formed to form the collision surface 41 on which the mixed water introduced through the collision collides;
The discharge hole 31 is a plurality of radially disposed at a position spaced apart from the outer circumferential surface of the collision protrusion 4 in the bulkhead 33 in which the collision protrusion 4 is integrally formed in the discharge body 3 . In the nanobubble generator (1) to be formed;
The collision surface 41 is
a 'diffusion groove' having an outer diameter greater than the inner diameter of the inlet hole 21 and having a 'arc' shape digging in the direction in which the mixed water moves is formed;
The collision protrusion (4) is,
When the partition wall 33 has a length in the direction toward the inlet hole 21, a pressure control groove 42 spatially connected to the outlet opening 32 is formed therein while protruding in a 'cylinder'shape;
In the collision protrusion (4),
An exhaust hole 43 for spatially connecting the air pressure control groove 42 and the bubble generation space A to guide the gas filled in the air pressure control groove 42 to the bubble generation space (A) is formed Nano bubble generator, characterized in that.

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