KR20230000069U - Nano bubble generation system - Google Patents

Abstract

The present invention is to stably maintain a suitable air pressure to efficiently generate nanobubbles with respect to the dissolution pressure in the dissolution space;
It has a supply port 21 for supplying mixed water in which raw water having transfer pressure and air supplied from the outside are supplied and a discharge port 22 for discharging to the outside, and between the supply port 21 and the discharge port 22 there is an external a dissolving means (2) provided with a dissolving space (A) sealed against the dissolving water to form a dissolving pressure of air for the mixed water; an air supply means (6) driven by a control means (5) to control the power of the power supply unit (51) and forcibly supplying air to the raw water; In the nano bubble generating system including; a pressure detection sensor (7) configured to detect the dissolution pressure in the dissolution space (A) and transmit the detected pressure data to the control means (5);
The control means (5) receives the pressure data detected through the pressure detection sensor (7), calculates it through set data, and controls and drives the air supply means (6) based on the calculated data, It provides a nanobubble generating system in which the supply pressure of the supplied air is greater than the pressure greater than the dissolution pressure in the dissolution space (A) and is made smaller than the transfer pressure (water pressure) of the raw water.

Description

Nano bubble generation system {Nano bubble generation system}

The present invention relates to a nanobubble generating system configured to generate nanobubbles, which are microbubbles having microscopic units in diameter, through air dissolving pressure in raw water.

Specifically, it relates to a nanobubble generating system designed to improve the nanobubble generation efficiency by stably maintaining an appropriate air pressure for efficiently generating nanobubbles against the dissolution pressure in the dissolution space.

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 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 the above, the process of converting the supply water into microbubbles is performed through a process in which the supply water containing bubbles (a mixture of water and air) is separated and compressed while passing through the microtube passage of the generating unit equipped with the microtube 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 equipped with a water inlet through which water flows in, an air inlet through which air flows in, and a discharge hole through which air is discharged, provided between the water inlet, air inlet, and discharge of the bubble generating chamber, and rotated by being inserted into the shaft of the motor, and the water inlet And a rotating disk provided with a plurality of induction holes through which water introduced through the air inlet is guided, provided to be in close contact with the moving direction of the water and air of the rotating disk, and branching the water and air induced through the induction holes outwardly It consists of a fixed disk equipped with a plurality of stirring pieces protruding in the direction of the rotating disk so as to stir water and air according to the rotation of the rotating disk at the same time.

Accordingly, since the water and air are rubbed while rubbing with the agitating pieces and rubbing while passing between the agitating pieces in a jig jack, the water and air are strongly agitated and compressed at the same time as being crushed.

This impact-type microbubble generator not only requires a high pressure of 5 to 20 bar, but also has a large flow loss, requires a large number of nozzles and a bulky mixing tank, so the structure and equipment of the device are complicated. .

On the other hand, the swirling liquid flow type microbubble generator, like the impact nozzle type, generates nanobubbles through the transfer pressure introduced in the process of transferring the mixed water of water and air through the space in a spiral shape. It is designed to generate nanobubbles by the vortex pressure generated while the mixed water is transported while forming a vortex by forming a spiral conduit.

However, such a swirling liquid flow type microbubble generator does not generate microbubbles through a single nozzle and requires a high pressure as well as a bulky mixing tank.

Recently, a nano-bubble generation system capable of generating nano-bubbles by dissolving air contained in a mixed water of water and air supplied from the outside through a dissolving means having a dissolving space to form an air-dissolving pressure therein. This is currently being proposed.

That is, as the air pressure continuously increases in the dissolving space according to the supply of mixing water, the dissolving pressure for dissolving the air remaining in the dissolving space is generated.

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

In Korea Patent Registration No. 10-2105794 (name: nano bubble generator), as described in the publication, it has a supply port through which mixed water having a transfer pressure is supplied and a discharge port through which the mixed water is discharged to the outside, and a gap between the supply port and the discharge port is provided. A nanobubble generating device comprising: a dissolving means sealed against the outside and equipped with a dissolving space configured to form a dissolving pressure of gas against water; In the dissolving means, in a state where the inlet of the supply port is disposed on the outer surface, the outlet of the supply port is disposed on the upper surface so that the supply pipe through which the mixed water is supplied from the outside is connected to discharge to the upper surface, and the inlet of the discharge port is on the upper surface. Dissolving bodies discharged to the outside by being connected to a discharge pipe through which the mixed water is discharged from the outside with the outlet of the discharge port disposed on the outer surface in the arranged state; A dissolving container having a dissolving space having a dissolving space so as to form a dissolving pressure with respect to the mixed water supplied through the outlet of the supply port; ; At the outlet of the supply port on the upper surface of the dissolving body, the injection pipe has a vertical length and has a transfer pipe through which the mixed water is transported, and sprays the mixed water to the upper surface of the dissolving container to apply collision pressure. A nanobubble generating device equipped with a binding tube to be bound is described.

Korean Patent Registration No. 10-1146040 Korean Patent Registration No. 10-2105794

However, conventional nanobubble generators and systems as described above have a problem in that nanobubble generation efficiency is not maximized because suitable air pressure cannot be customized in the dissolution space where nanobubbles are formed through dissolution pressure.

That is, when the generation efficiency of nanobubbles decreases due to the decrease in the amount of air relative to the dissolution pressure in the dissolution space, the quality of the generated nanobubbles deteriorates as this cannot be corrected.

In addition, there is a problem in that nanobubble generation efficiency is lowered as air pressure tailored to various moving pressures (supply water pressure) of the raw water constituting the mixed water cannot be properly formed.

The present invention is proposed to solve the above conventional problems, and the purpose of the present invention is to generate nanobubbles, which are microbubbles having microunits in diameter, through the dissolving pressure of air in raw water, It is an object of the present invention to provide a nanobubble generation system to improve nanobubble generation efficiency by stably maintaining an appropriate air pressure for efficiently generating nanobubbles against the dissolution pressure in a dissolution space.

In order to achieve the object of the present invention as described above, the nano-bubble generating system according to the present invention includes a supply port 21 through which a mixture of raw water having conveying pressure and air supplied from the outside is supplied and a discharge port through which it is discharged to the outside. Dissolution means (2) having a dissolution space (A) having a dissolution space (22) and sealed against the outside between the supply port (21) and the discharge port (22) to form a dissolution pressure of air for the mixed water. class; an air supply means (6) driven by a control means (5) to control the power of the power supply unit (51) and forcibly supplying air to the raw water; In the nano bubble generating system including; a pressure detection sensor (7) configured to detect the dissolution pressure in the dissolution space (A) and transmit the detected pressure data to the control means (5); The control means (5) receives the pressure data detected through the pressure detection sensor (7), calculates it through set data, and controls and drives the air supply means (6) based on the calculated data, It is characterized in that the supply pressure of the supplied air is greater than the larger pressure than the dissolving pressure of the dissolving space (A) and smaller than the transfer pressure (water pressure) of the raw water.

The nanobubble generating system according to the present invention made as described above is configured to supply the air pressure of the air supplied to the raw water according to the dissolution pressure detected in real time through the pressure detection sensor configured to detect the dissolution pressure in the dissolution space. In addition, it is possible to stably maintain an appropriate air pressure for efficient generation of nanobubbles, thereby improving the nanobubble generation efficiency.

1 is a schematic illustration showing a nanobubble generating system according to an embodiment of the present invention;
Figure 2 is a schematic illustration showing a nanobubble generating system according to this embodiment.
3 to 4 are schematic diagrams showing a nanobubble generating system according to another embodiment of the present invention.
5 to 7 are schematic views showing a nanobubble generating system according to another embodiment of the present invention.
8 is a schematic illustration showing a control state of the nanobubble generating system according to the present embodiment.

Hereinafter, a nanobubble generating system according to a preferred embodiment according to 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 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 8 are diagrams showing a nanobubble generating system according to an embodiment of the present invention. The nanobubble generating system 1 according to the present embodiment dissolves in mixed water in which raw water and air are mixed. By dissolving air through pressure, nanobubbles, which are microbubbles with a microscopic diameter, are generated. In the process of transporting the mixed water while passing through the dissolving space (A) closed to the outside, the air (gas) contained It is made to be suitably applied to generating nanobubbles by being dissolved and microbubble.

In particular, it is intended to be suitably applied to a use site where a plurality of water usage places such as laundry facilities, bath facilities, kitchen facilities, etc. are respectively equipped.

The nanobubble generating system 1 according to this embodiment has a supply port 21 for supplying mixed water in which raw water having conveying pressure and air supplied from the outside are mixed, and a discharge port 22 for discharging to the outside. It has a dissolving means (2) provided with the dissolving space (A) which is sealed against the outside between the supply port (21) and the discharge port (22) to form a dissolving pressure of air for the mixed water.

That is, after the mixed water supplied to the dissolving space (A) of the dissolving means (2) is supplied through the feed pressure of the raw water, nano bubbles are generated through the dissolving pressure formed inside the dissolving space (A). After that, the nanobubble water can be suitably acted upon and used in various places (not shown) where nanobubble water is used.

In the above, the raw water may be supplied through the raw water pipe 3 made of a 'water supply pipe' as shown in FIG. 1, and may be supplied while having a transfer pressure according to the water pressure; As shown in Figure 3, it can be supplied while having a transfer pressure through the pump 4 designed to pump raw water supplied from the outside, and is suitably applied according to the user's selection in a structure to which a conventionally known technique is applied. it is desirable to be

In the above, the dissolving space (A) of the dissolving means (4) may be formed in the 'interspace' in which the supply port 21 and the discharge port 22 are each spatially connected.

That is, the dissolving space A and the outside are spatially connected through the supply port 21 and the discharge port 22 .

Accordingly, after the mixed water introduced from the outside of the dissolving means 2 is nano-bubbled, it can be supplied to the outside for use.

In the nanobubble generating system 1 according to the present embodiment configured as described above, the supply pressure of the air supplied to the raw water is greater than the dissolution pressure in the dissolution space A.

That is, as the air pressure of the air supplied to the raw water is adjusted to the melting pressure that is varied in real time in the dissolving space (A), dissolution of the air contained in the mixed water can occur efficiently.

Accordingly, the air pressure suitable for nanobubble generation is stably maintained in the dissolution space (A), and the nanobubble generation efficiency is improved.

In the nanobubble generating system 1 according to the present embodiment made as described above, the air supply is driven through the control means 5 to control the power of the power supply unit 51 to forcibly supply air to the raw water. means (6); A pressure detection sensor 7 configured to detect the dissolution pressure in the dissolution space A and transmit the detected pressure data to the control means 5; may be further included.

At this time, the control means 5 receives the pressure data detected by the pressure detection sensor 7, calculates it through set data, and controls the air supply means 6 based on the calculated data to control and drive the raw water It can be supplied with air.

That is, the melting pressure formed in the melting space (A) is detected in real time through the pressure detection sensor (7) and the driving of the air supply means (6) is controlled in real time by the control means (5) in real time. The air pressure of the air may be supplied in a customized manner for the dissolving pressure that is varied by .

Accordingly, the saturation of the air contained in the mixing water is increased according to the application of an appropriate pressure of the air contained in the mixing water, so that the dissolution of air in the dissolving space (A) can occur efficiently.

Therefore, nanobubble generation efficiency can be improved.

In the above, the air supply means 6 may be composed of an 'air pump' that is driven by receiving the power controlled by the control means 5 to pump air, and in a structure to which a conventionally known technology is applied, the user It is preferable to be suitably applied according to the selection of.

The pressure detection sensor 7 may be composed of a 'pressure sensor' configured to transmit detection data to the control means 5 by applying the melting pressure of the dissolution space A, and a structure to which a conventionally known technology is applied It is preferable to be suitably applied according to the user's selection.

In the nanobubble generating system 1 according to the present embodiment made as described above, the supply pressure of the air supplied to the raw water is greater than the dissolution pressure of the dissolution space A and is smaller than the transfer pressure (water pressure) of the raw water. It can be done with pressure.

That is, after being supplied to the raw water through the air supply means 6 and mixed, the supply pressure of the air supplied to the dissolution space (A) is smaller than the feed pressure of the raw water, so that the raw water is not hindered and the raw water is dissolved. As the stable transfer and supply to the space A is achieved, the mixed water can be stably supplied.

In addition, as the supply pressure of air is made greater than the dissolution pressure in the dissolution space (A), the saturation of air with respect to the mixing water in the dissolution space (A) is increased to efficiently dissolve the air, The nanobubble generation efficiency can be improved.

In the nanobubble generating system 1 according to the present embodiment configured as described above, the dissolution means 2 is a dissolution tank provided with the supply port 21, the discharge port 22, and the dissolution space A. (23); The pressure detection sensor 7 may be arranged to detect the pressure of the dissolution space (A) in the dissolution tank (23).

That is, the pressure detection sensor 7 may be coupled to the dissolution tank 23 to detect the dissolution pressure of the dissolution space A provided inside the dissolution tank 23 in real time.

On the other hand, in the nanobubble generating system 1 according to this embodiment, the dissolving means 2, as shown in FIGS. 5 to 7, the dissolving tanks 23 are spatially connected to, so that a plurality of the dissolution spaces (A) are spatially arranged in series, so that the mixing water passes through the plurality of dissolution spaces (A) while generating nanobubbles in each of the dissolution spaces (A). It can be made to perform the nanobubble generation steps of a multi-stage process.

Accordingly, the generation quality of generated nanobubbles can be improved.

In addition, in the nanobubble generating system 1 according to the present embodiment, the pressure detection sensor 7 is provided in each of the plurality of dissolution tanks 23 spatially connected to each other, so that each dissolution space ( Each of the dissolving pressures for A) is detected, respectively, and each of the detected detection data of the control means 5 is transmitted, so that the dissolution pressure for a plurality of the dissolving spaces A can be detected in real time. there is.

Accordingly, air is supplied through an air pressure higher than the maximum melting pressure among the detected melting pressures for the plurality of melting spaces A, so that nanobubbles can be generated more stably.

One embodiment of the present invention described above is merely an example, 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 above detailed description. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended 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: Nanobubble generation system 2: Dissolving means
21; Supply port 22: discharge port
23: melting tank 24: connection pipe
3: raw water pipe 4: pump
5: control means 51: power supply unit
6: air supply means 7: pressure detection sensor

Claims (1)

It has a supply port 21 for supplying mixed water in which raw water having transfer pressure and air supplied from the outside are supplied and a discharge port 22 for discharging to the outside, and between the supply port 21 and the discharge port 22 there is an external a dissolving means (2) provided with a dissolving space (A) sealed against the dissolving water to form a dissolving pressure of air for the mixed water; an air supply means (6) driven by a control means (5) to control the power of the power supply unit (51) and forcibly supplying air to the raw water; In the nano bubble generating system including; a pressure detection sensor (7) configured to detect the dissolution pressure in the dissolution space (A) and transmit the detected pressure data to the control means (5);
The control means (5) receives the pressure data detected through the pressure detection sensor (7), calculates it through set data, and controls and drives the air supply means (6) based on the calculated data, The nanobubble generating system, characterized in that the supply pressure of the supplied air is made to be greater than the dissolution pressure of the dissolution space (A) and smaller than the transfer pressure (water pressure) of the raw water.

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