KR200497600Y1 - Connector for nano bubble generator - Google Patents

Abstract

In this design, while supplying raw water from the raw water pipe to the dissolution space, external air is sucked in and mixed with the raw water through the moving pressure of the raw water, thereby stably supplying air without a separate air supply device. to maximize economic benefits and space use efficiency through structural simplification;
For a nanobubble generator that is spatially connected to a raw water pipe for supplying raw water with conveying pressure and a nanobubble generator having a dissolving means provided with a dissolving space for forming a dissolving pressure in a mixed state of raw water and air. In the connector; A vacuum pressure forming space is provided in which the internal diameter gradually decreases and then increases along the movement path of the raw water provided inside, forming a local vacuum pressure due to the supply pressure of the raw water supplied from the raw water pipe, and the vacuum pressure forming space is provided. A connector for a nanobubble generator in which an air supply hole is formed to spatially connect the space and the outside, and when raw water is supplied from the raw water pipe, external air is supplied inside through the air supply hole and mixed with the raw water. provides.

Description

Connector for nano bubble generator {Connector for nano bubble generator}

The present invention is a nanobubble generator that generates nanobubbles, which are fine bubbles with a microscopic diameter, by dissolving air in raw water, and spatially connects the raw water pipe to which raw water is supplied and the dissolution space to supply raw water to the dissolution space. It relates to a connector for a nanobubble generator to be connected.

Specifically, while supplying raw water from the raw water pipe to the dissolution space, external air is sucked in through the moving pressure of the raw water and mixed with the raw water, thereby ensuring a stable supply of air without a separate air supply device. This relates to a connector for a nanobubble generator that maximizes economic benefits and space use efficiency through structural simplification.

In general, nanobubbles are ultra-fine bubbles that cannot be seen with the eye. They are 1/2,000 the size of regular bubbles and are fine air particles in skin pores less than 25㎛. When they disappear, 1) 40KHz ultrasound is generated, 2) It generates a high sound pressure of 140db, and 3) generates instantaneous high heat of 4,000 to 6,000 degrees.

In other words, normal bubbles rise in water and burst at the surface, but nanobubbles shrink under pressure under water and disappear while generating various types of energy.

These nanobubbles are ultra-fine bubbles that mainly occur when water and air are violently 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 in recent years, they have been used in various aquaculture and hydroponic cultivation, especially in the fishing and agricultural fields. In the medical field, it is used for precise diagnosis, and is currently being used in various fields such as physical therapy, high-purity water treatment, and environmental devices.

In other words, its field of use is wide ranging from hot spring bathing to cancer diagnosis, and it is known to regenerate the skin and also has an excellent sterilizing effect.

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

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

In the above, the process of converting feed water into microbubbles is accomplished through a process in which feed water containing bubbles (a mixture of water and air) is separated and compressed while passing through a micropipe passage of a generating means equipped with a micropipe passage.

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, as described in the publication, A bubble generating chamber is provided with a water inlet through which water flows in, an air inlet through which air flows in, and an outlet through which air is discharged, and is provided between the water inlet, air inlet, and discharge port of the bubble generating chamber, and is rotated by being fitted on the shaft of a motor. and a rotating disk equipped with a plurality of guide holes through which water introduced through the air inlet is guided, and which is provided to be in close contact with the moving direction of the water and air of the rotating disk and diverts the water and air guided through the guide holes 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 as the rotating disk rotates.

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

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

On the other hand, the swirling liquid retention type microbubble generator generates nanobubbles through the inflowing transfer pressure in the process of transferring mixed water of water and air through the space in a spiral shape, like the impact nozzle type. It is designed to generate nanobubbles due to the eddy pressure generated while the mixed water is being transported while forming a vortex by forming a vortex-shaped pipe.

However, this swirling liquid retention type micro-bubble generating device has the problem of not being able to generate micro-bubbles through a single nozzle and not only requiring high pressure but also requiring a large mixing tank.

Recently, a nanobubble generating system is used to generate nanobubbles by dissolving the air contained in the mixed water of water and air supplied from the outside through a dissolving means provided with a dissolving space internally designed to create dissolution pressure of the air. This is currently being proposed.

That is, as the air pressure in the dissolution space continues to increase due to the supply of mixed water, a dissolution pressure that causes dissolution of the air remaining in the dissolution space is generated.

Therefore, in the dissolution space, nanobubble water is smoothly formed by the generation of mixed water due to mixing of raw water (tap water) and air and the dissolution of air contained in the mixed water.

Korean Patent Registration No. 10-1146040

However, the conventional nanobubble generating devices as described above have a connector that spatially connects the raw water pipe and the dissolution space to receive the raw water constituting the mixed water, and supplies air constituting the mixed water to the dissolution space. There was a structural problem in that each air supply device had to be provided.

In other words, there is a problem of being uneconomical due to the complexity of the structure and low productivity. In particular, there is a problem of design limitations due to low space use efficiency due to the increased space use range due to the separate air supply device.

The present invention was proposed to solve the above-described conventional problems. The purpose of the present invention is to mix raw water with raw water by sucking in external air through the moving pressure of raw water while supplying raw water from the raw water pipe to the dissolution space. The goal is to provide a connector for a nanobubble generator that supplies air stably without a separate air supply device, thereby maximizing economic benefits and space use efficiency through structural simplification.

In order to achieve the purpose of the present invention as described above, the connection pipe for the nanobubble generator according to the present invention is composed of a raw water pipe for supplying raw water with a transfer pressure, and a raw water pipe to form a dissolution pressure in a mixed state of raw water and air. In the connection pipe for a nanobubble generator that spatially connects a nanobubble generator having a dissolving means provided with a dissolution space; A vacuum pressure forming space is provided in which the internal diameter gradually decreases and then increases along the movement path of the raw water provided inside, forming a local vacuum pressure due to the supply pressure of the raw water supplied from the raw water pipe, and the vacuum pressure forming space is provided. An air supply hole is formed to spatially connect the space and the outside, so that when raw water is supplied from the raw water pipe, external air is supplied inside through the air supply hole and mixed with the raw water; At one end, an inlet is provided that is spatially connected to the raw water pipe to receive raw water, and at the other end, a supply port is spatially connected to the nanobubble generator to supply raw water to the dissolution space, and the inlet and A connecting body having a movement path along which raw water moves between the supply ports; The moving path in the connection body is provided with a vacuum pressure forming space in which the inner diameter gradually decreases and then increases to form a local vacuum pressure due to the supply pressure of raw water supplied from the raw water pipe, and the vacuum pressure forming space is formed. The air supply hole is formed to spatially connect the space and the outside, so that when raw water is supplied from the raw water pipe, external air is supplied inside through the air supply hole and mixed with the raw water.

The connection pipe for the nanobubble generator according to the present invention, which is configured as described above, connects the raw water pipe and the nanobubble generator to both ends of the connection body and connects them spatially, so that raw water is supplied from the raw water pipe to the dissolution space, The vacuum pressure generated in the vacuum pressure forming space is formed by the moving pressure of the raw water on the movement path of the raw water formed inside the connection body, and as the external air is drawn into the air supply hole and mixed with the raw water, nano It has the effect of stably supplying the air consumed when bubbles are generated without the need for a separate air supply device.

Accordingly, it has the effect of maximizing economic benefits and space use efficiency through structural simplification.

Figure 1 is a schematic exploded perspective illustration showing a connector for a nanobubble generator according to an embodiment of the present invention.
Figure 2 is a schematic perspective view showing a connection pipe for a nanobubble generator according to this embodiment.
Figure 3 is a schematic cross-sectional illustration showing a connector for a nanobubble generator according to this embodiment.
4 to 7 are schematic illustrations showing the use state of the connector for the nanobubble generator according to this embodiment.

Hereinafter, with reference to the attached drawings, a connector for a nanobubble generator according to a preferred embodiment of the present invention will be described in detail as follows.

The 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 with average knowledge in the art. Therefore, the shapes of elements in the drawings may be exaggerated to emphasize a clearer description. It should be noted that identical members in each drawing may be indicated by the same reference numerals. Detailed descriptions of known functions and configurations that are judged to unnecessarily obscure the gist of the present invention are omitted.

1 to 3 are diagrams showing a connector 1 for a nanobubble generator according to an embodiment of the present invention. The connector 1 for a nanobubble generator according to this embodiment is a transfer pressure A nanobubble generator (200) having a raw water pipe (100) for supplying raw water and a dissolving means (210) provided with a dissolving space (A) to form a dissolving pressure in a mixed state of raw water and air. It is applied to selectively supply raw water to the dissolution space (A) by spatially connecting it.

That is, raw water having a transfer pressure generated by the raw water supply equipment is supplied through the raw water pipe 100, which is connected to the raw water supply equipment (including water supply equipment), not shown, and supplies raw water (including tap water) to the dissolution space ( A) It is supplied according to the user's choice.

At this time, as the water pressure in the dissolution space (A) continues to increase due to the continuous supply of the mixed water, a dissolution pressure against air is generated in the dissolution space (A) due to the high pressure of water.

Accordingly, nanobubble water is smoothly formed by the generation of mixed water due to mixing of raw water and air in the dissolution space (A) and the dissolution of air contained in the mixed water.

In the above, the raw water pipe 100 may be composed of a 'water supply pipe' connected to a water pipe or/and a 'water valve' connected to the water supply pipe; It may consist of a 'water supply pipe' connected to a separate water supply device such as a 'water purification device' or/and a 'water valve' connected to the water supply pipe, and is preferably applied appropriately according to the user's selection.

The connection pipe (1) for the nanobubble generator according to this embodiment has an inner diameter that gradually decreases along the movement path of the raw water provided therein and then increases, thereby increasing the supply pressure of the raw water supplied from the raw water pipe (100). A vacuum pressure forming space (B) in which local vacuum pressure is formed is provided, and an air supply hole (2) is formed that spatially connects the vacuum pressure forming space (B) to the outside.

That is, when raw water is supplied from the raw water pipe 100, a vacuum pressure is formed in the vacuum pressure forming space (B) by the moving pressure of the raw water.

Accordingly, external air is sucked in through the air supply hole 2, supplied inside, mixed with raw water, and supplied to the dissolving means 210 of the nanobubble generator 200.

Therefore, the air consumed when nanobubbles are generated in the dissolution space (A) can be stably supplied without a separate air supply device; In particular, economic benefits and space use efficiency are maximized through structural simplification.

In the above, the vacuum pressure forming space (B) is formed in a portion of the movement path whose diameter is reduced and enlarged, and is formed in a space with a shrinking diameter according to 'Pascal's principle' and 'Bernoulli's theorem'. ‘Kebiteisen (cavitation)’ occurs..

That is, the vacuum pressure forming space (B) is naturally formed when raw water moves, and accordingly, a vacuum suction force is generated to the air supply hole (2), and external air is naturally supplied.

The connection pipe 1 for the nanobubble generator according to the present embodiment, which is configured as described above, is provided with an inlet 31 that is spatially connected to the raw water pipe 100 to receive raw water at one end, and the nanobubble generator at the other end. A supply port 32 is spatially connected to the bubble generator 200 to supply raw water to the dissolution space (A), and raw water moves between the inlet 31 and the supply port 32. It includes a connected body (3) having a movement path.

That is, the raw water pipe 100 and the nanobubble generator 200 are respectively connected to the inlet 31 and the supply port 32 provided at both ends of the connection body 3 to spatially connect them. .

Accordingly, raw water is supplied from the raw water pipe 100 to the dissolution space (A).

In the above, the inlet 31 and the supply port 32 can be connected to the raw water pipe 100 and the nanobubble generator 200 by screwing, respectively, and can be appropriately applied according to the user's selection. It is desirable to be

To this end, the inlet 31 and the supply port 32 may be integrally formed with a 'screw-shaped' screw portion.

Meanwhile, in the connection pipe (1) for the nanobubble generator according to this embodiment, the moving path of the connection body (3) has an inner diameter that gradually decreases and then increases to allow the water supplied from the raw water pipe (100) to be supplied from the raw water pipe (100). The vacuum pressure forming space (B) is provided in which a local vacuum pressure is formed by the supply pressure of raw water, and the air supply hole (2) is formed to spatially connect the vacuum pressure forming space (B) to the outside. You can.

That is, when raw water is supplied from the raw water pipe 100, as vacuum pressure is formed in the vacuum pressure forming space (B) due to the moving pressure of raw water, external air flows through the air supply hole (2). As it is inhaled, it is supplied inside and mixed with raw water, and is also supplied to the dissolving means (A) of the nanobubble generating device (200).

In the connector 1 for the nanobubble generator according to the present embodiment configured as described above, the connection main body 3 has an internal portion with the inlet 31 and the supply port 32 provided at both ends, respectively. It consists of a 'pipe' shaped 'tube body' through which is penetrated; The air supply hole 2 may be formed to penetrate and spatially connect the outside of the connecting body 3 and the vacuum pressure forming space B, respectively.

That is, the connecting body 3 can be made into a design structure suitable for mass production through a molding process, so it can be provided economically.

The connector 1 for the nanobubble generator according to the present embodiment configured as described above is connected to the air supply hole 2 from the outside of the connection body 3 and is connected to the vacuum pressure forming space B. Depending on whether vacuum pressure is formed, the one-way check valve 4, which is designed to open and close the supply of air, may be connected.

That is, when raw water is supplied from the raw water pipe 100, when vacuum pressure is formed in the vacuum pressure forming space (B) due to the moving pressure of raw water, the one-way check valve (4) is opened and external air flows into the It is supplied to the vacuum pressure forming space (B) via the air supply hole (2), mixed with raw water, and then supplied to the dissolution space (A) of the nanobubble generator (200).

In addition, according to the user's selection, when the supply of raw water from the raw water pipe 100 is stopped, the vacuum pressure is released in the vacuum pressure forming space (B), and the dissolution space of the nanobubble generator 200 is released. The one-way check valve (4) is closed by the mixed water flowing back from (A), preventing leakage to the outside.

Accordingly, a stable supply of air is naturally achieved, and leakage of raw water or/and mixed water from the air supply hole 2 to the outside is prevented, thereby realizing stability.

Meanwhile, the connection pipe (1) for the nanobubble generator according to this embodiment is spatially connected to the air supply hole (2) from the outside of the connection body (3) and is connected to the air supply hole (2) from the outside. ) may be provided with a control valve (5) to control the amount of movement of air per unit time.

That is, when vacuum pressure is formed in the vacuum pressure forming space (B) through the control valve (5) and external air is supplied to the air supply hole (2) via the one-way check valve (4), By selectively controlling the air supply amount to form an appropriate air pressure in the dissolution space (A), a suitable nanobubble generation environment can be formed by matching the supply environment of the raw water supplied from the raw water pipe 100. .

Accordingly, the nanobubble generation environment can be selectively controlled by the user, thereby improving the quality of use.

In the above, the control valve (5) may be connected between the air supply hole (2) and the one-way check valve (4); Each of the air supply holes (2), the control valve (5), and the one-way check valve (4) are each connected tube (6) formed in the shape of a 'pipe' that has a length and is penetrated at both ends. ) can be spatially connected by .

That is, by selectively adjusting the length of the connecting tubes (6), the control valve (5) and the one-way check valve (4) can be selectively positioned in the entire occupied space, thereby increasing space use efficiency. It can be done.

The embodiment of the present invention described above is merely illustrative, and those skilled in the art will be able to understand that various modifications and other equivalent embodiments are possible. . Therefore, it will be well understood that the present invention is not limited to the form mentioned in the detailed description above. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached claims. In addition, the present invention should be understood to include all modifications, equivalents and substitutes within the spirit and scope of the present invention as defined by the appended claims.

1: Connector 100: Raw water pipe
200: Nanobubble generator 210: Dissolution means
2: Air supply hole 3: Connection body
31: inlet 32: supply port
4: One-way check valve 5: Control valve
6: Connecting tube
A: Dissolution space B: Vacuum pressure forming space

Claims (1)

On the movement path of the raw water provided inside, the inner diameter gradually becomes smaller and then increases, and a vacuum pressure forming space (B) is provided in which a local vacuum pressure is formed by the supply pressure of the raw water supplied from the raw water pipe 100. , the vacuum pressure forming space (B) is spatially connected to the outside to form an air supply hole (2) through which external air is supplied inside and mixed with the raw water when raw water is supplied from the raw water pipe (100). The raw water pipe 100 through which raw water having a transfer pressure is supplied is spatially connected to the dissolving means 210 of the nanobubble generator 200;
At one end, an inlet 31 is spatially connected to the raw water pipe 100 to receive raw water, and at the other end, it is spatially connected to the nanobubble generator 200 to supply raw water to the dissolving means 210. A supply port 32 is provided to supply to the dissolution space (A), and raw water is moved between the inlet 31 and the supply port 32, and its inner diameter gradually decreases and then increases to the raw water pipe. A connection body (3) having a movement path through which the vacuum pressure forming space (B) and the air supply hole (2) are formed, where a local vacuum pressure is formed by the supply pressure of raw water supplied from (100); A one-way check valve that is connected to the air supply hole (2) from the outside of the connecting body (3) and opens and closes the supply of air depending on whether or not vacuum pressure is formed in the vacuum pressure forming space (B). (4) and; A control valve (5) that is spatially connected to the air supply hole (2) from the outside of the connecting body (3) and is configured to control the amount of air moving from the outside to the air supply hole (2) per unit time; Including;
The control valve (5) is connected between the air supply hole (2) and the one-way check valve (4);
The air supply hole (2), the control valve (5), and the one-way check valve (4) are each connected tube (6) in the shape of a 'pipe' that has a length and is penetrated at both ends. In the connector (1) for a nanobubble generator spatially connected by;
The connection body (3) is,
The inlet 31 and the supply port 32 are formed at both ends and are composed of a 'pipe' shaped 'pipe' with a penetrating interior;
The air supply hole (2) is,
It is formed to spatially connect the outside of the connecting body (3) and the vacuum pressure forming space (B) while penetrating each;
The inlet 31 and the supply port 32 are,
A connector for a nanobubble generator, characterized in that it is connected to the raw water pipe (100) and the nanobubble generator (200) by screwing, respectively.