KR20220094024A - Air supply device of nano bubble generation system - Google Patents

Abstract

The present invention relates to an air supply device of a nanobubble generation system. In accordance with the present invention, in order to supply air into a bubble generation space by selectively controlling an air amount in a nanobubble generation system, in the nanobubble generation system including a raw water pipe made to supply raw water having transfer pressure and a bubble generation means provided with a bubble generation space into which the raw water supplied from the raw water pipe is introduced and in which nanobubbles are generated, the air supply device is formed to be spatially connected to a flow path of the raw water of the raw water pipe and the bubble generation means to supply the air from the outside. The air supply device includes: an air supply pipe spatially connected to the flow path of the raw water of the raw water pipe and the bubble generation means; an air introduction pipe spatially connected with the air supply pipe to introduce the air from the outside; a control valve provided on a flow path of the air between the air supply pipe and the air introduction pipe to selectively control the amount of air supplied to the air supply pipe per unit time by selectively controlling a space area of the flow path of the air; and an air pressure indicator including a penetration pipe provided on the flow path of the air such that the inside thereof can be seen through between the air supply pipe and the control valve, and a floating body provided in the penetration pipe and floated by air pressure flowing via the inside of the penetration pipe while being influenced by gravity due to a dead load thereof.

Description

Air supply device of nano bubble generation system

The present invention relates to an air supply device configured to selectively control and supply the amount of air to a bubble generating space in a nano-bubble generating system configured to generate nano-bubbles, which are micro-bubbles with micro-bubbles in diameter, by dissolving air in raw water. .

Specifically, the supply pressure (water supply pressure) of the raw water supplied to the bubble generating space through the raw water pipe is to be supplied by sucking the external air, and the user can selectively control the amount of supplied air to improve the nanobubble generation efficiency. It relates to the air supply device of the nano-bubble generating system to be maximized.

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 1/2 the size of normal bubbles. It generates a 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 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 utilized 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 precise diagnosis, and in various fields, it is used for physical therapy, high-purity water treatment, and environmental devices.

In other words, it has a wide range of uses, from hot spring baths to cancer diagnosis, and is known to regenerate the skin as well as 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 in which the feed water is converted into microbubbles is made through a process in which the feedwater containing air bubbles (a mixture of water and air) is separated and compressed while passing through the microtubules of the generating means provided with the microtubules.

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 provided to be in close contact with the moving direction of water and air of the rotary disk, the water and air induced through the guide holes are branched outward 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 spiral shape, 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.

Recently, a dissolution means provided with a dissolution space configured to form a dissolution pressure of air therein; a nanobubble generating system configured to generate nanobubbles by dissolving air contained in a mixture of water and air supplied from the outside This is currently being proposed.

That is, as the air pressure in the dissolution space continuously increases according to the supply of the mixed water, a dissolution pressure at which the air remaining in the dissolution space is dissolved is generated.

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

In Korea Patent Registration No. 10-2105794 (name: nano bubble generating device), as described in the publication, it has a supply port to which mixed water having a conveying pressure is supplied and a discharge port for discharging to the outside, and between the supply port and the discharge port In the nanobubble generating device comprising; The dissolving means, in a state in which the inlet of the supply port is arranged on the outer surface, the outlet of the supply port is arranged on the upper surface, 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 outlet on the upper surface is In the disposed state, the outlet of the outlet is disposed on the outer surface, and the dissolution body is connected to a discharge pipe through which the mixed water is discharged from the outside and discharged to the outside; The lower part is opened and the open lower part is assembled while being bound to the upper part of the dissolution body and has a dissolution container having a dissolution space therein to form dissolution pressure with respect to the mixed water supplied through the outlet of the supply port; ; At the outlet of the supply port from the upper surface of the dissolution body, the injection pipe has a vertical length and has a conveying pipe through which the mixed water is transported therein to spray the mixed water to the upper surface of the dissolution barrel to apply a collision pressure A nanobubble generating device provided with a binding tube to be bound is described.

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

However, the conventional nano-bubble generation systems as described above have a problem in that it is difficult to control the amount of air supplied to the raw water constituting the mixed water according to the user's selection.

That is, there was a problem in that it was difficult for the user to visually check the amount of air supplied to the mixed water, so that the use efficiency was lowered.

Accordingly, there was a problem in that the nanobubble generation efficiency was lowered as the moving pressure (supply water pressure) of various raw water did not properly form an air supply amount tailored in different environments.]

The present invention has been proposed to solve the problems of the prior art, and an object of the present invention is to dissolve air in raw water to generate nanobubbles, which are microbubbles having a micro-unit in diameter. The amount of air supplied is to be supplied by selectively controlling the amount of air from the source water pipe to the bubble generation space. It is to provide an air supply device of a nano-bubble generating system to maximize the nano-bubble generating efficiency by allowing the user to selectively control the .

The air supply device of the nano-bubble generating system according to the present invention for achieving the object of the present invention as described above, a raw water pipe to which raw water having a transport pressure is supplied, and raw water supplied from the raw water pipe is introduced into the inside In a nanobubble generating system having a bubble generating means provided with a bubble generating space configured to generate nanobubbles, the nanobubbles are spatially connected to the raw water pipe and the movement path of the raw water of the bubble generating means to supply air from the outside. An air supply device for a generation system; an air supply pipe spatially connected to the raw water pipe and a movement path of the raw water of the bubble generating means; an air inlet pipe which is spatially connected to the air supply pipe and through which external air is introduced; A control valve provided on the movement path of air between the air supply pipe and the air inlet pipe to selectively control the space area of the air movement path to selectively control the amount of air supplied to the air supply pipe per unit time Wow; A see-through tube provided to see through the inside on the movement path of air between the air supply pipe and the control valve, and floating by air pressure provided in the see-through tube and moving through the inside of the see-through tube It is characterized in that it comprises a; air pressure indicator having a floating body to be affected by gravity by its own load.

The air supply device of the nano-bubble generating system according to the present invention made as described above by sucking the external air through the air supply pipe through the supply pressure (water supply pressure) of the raw water supplied to the bubble generating space through the raw water pipe to obtain water and air. The mixed water is supplied to the bubble generating space to generate nano bubbles, and the user visually recognizes the air pressure supplied through the air pressure display device and selectively adjusts the control valve to control the amount of air supplied to the bubble generating space. is selectively controlled, so that the nanobubble generation efficiency is maximized.

At this time, according to the difference in the supply pressure (supply pressure) of the raw water in the use environment, the air supply amount is adjusted appropriately and the quality of use is improved.

1 is a schematic perspective view showing a nano-bubble generating system to which the air supply device of the nano-bubble generating system according to an embodiment according to the present invention is applied.
Figure 2 is a schematic perspective view showing the air supply device of the nano-bubble generating system according to the present embodiment.
Figure 3 is a schematic cross-sectional view showing the air supply device of the nano-bubble generating system according to the present embodiment.
Figure 4 is a schematic illustration showing the air supply device of the nano-bubble generating system according to the present embodiment.
5 to 7 are schematic exemplary views showing the state of use of the air supply device of the nano-bubble generating system according to the present embodiment.

Hereinafter, with reference to the accompanying drawings, the air supply device of the nano-bubble generating system according to a preferred embodiment according to the present invention will be described in detail as follows.

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 shapes 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 7 are views showing the air supply device 1 of the nano-bubble generating system according to an embodiment according to the present invention, and the air supply device 1 of the nano-bubble generating system 10 according to the present embodiment. ) is to dissolve air in raw water to generate nanobubbles by dissolving air contained in mixed water in raw water in the nanobubble generating system 10, which is designed to generate nanobubbles, which are microbubbles with micro-bubbles in diameter, by dissolving air in raw water. It is particularly applied to those that are to be supplied by selectively controlling the supply amount of air to the bubble generating space (A).

That is, the quality of use is improved by adjusting the appropriate amount of air supply while being customized according to the difference in the supply pressure (water supply pressure) of the raw water in the nanobubble generating environment.

The raw water pipe 100 configured to supply raw water from the nano-bubble generating system 10 is provided with a supply pump 300 configured to forcibly pump and supply raw water, thereby increasing the dissolution pressure in the bubble generating space (A). It can be formed appropriately, and it is preferable to be appropriately applied according to the user's selection.

The air supply device 1 of the nano-bubble generating system 10 according to this embodiment includes a raw water pipe 100 to which raw water having a conveying pressure is supplied, and raw water supplied from the raw water pipe 100 flows in. and is applied to the nano-bubble generating system 10 having the bubble generating means 200 provided with the bubble generating space A to generate nano-bubbles therein.

That is, it is spatially connected to the movement path of the raw water of the raw water pipe 100 and the bubble generating means 200 to supply air from the outside. Through the raw water pipe 100 to which (including tap water) is supplied, raw water having a transfer pressure generated by the raw water supply facility is supplied to the bubble generating space A according to the user's selection.

At this time, as the water pressure in the bubble generating space (A) is continuously increased according to the continuous supply of the mixed water, a dissolution pressure for air is generated by the high pressure water pressure in the bubble generating space (A).

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

In the above, the raw water pipe 100 may include a 'water supply pipe' connected to a water pipe and/or 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 purifying device' and/or a 'water valve' connected to the water supply pipe, and is preferably applied according to the user's selection.

The air supply device 1 of the nano-bubble generating system 10 according to the present embodiment made as described above is an air supply pipe spatially connected to the raw water pipe 100 and the raw water movement path of the bubble generating means 200 . (3) and; an air inlet pipe (4) spatially connected to the air supply pipe (3) through which external air is introduced; It is provided on the movement path of air between the air supply pipe 3 and the air inlet pipe 4 to selectively adjust the space area of the air movement path, and is supplied to the air supply pipe 3 per unit time. a control valve (5) configured to selectively control the amount of air; A see-through tube 61 provided to see through the inside on the movement path of air between the air supply pipe 3 and the control valve 5, and the see-through tube 61 provided inside the see-through tube 61 ( 61) is floated by the air pressure moving through the interior, but the air pressure indicator 6 having a floating body 62 to be affected by gravity due to its own load; is made including.

That is, by sucking external air through the air supply pipe 3 through the supply pressure (water supply pressure) of the raw water supplied to the bubble generating space A through the raw water pipe 100, water and air are mixed. Nanobubbles are generated by supplying the mixed water to the bubble generating space (A).

At this time, the user selectively adjusts the control valve 5 while visually recognizing the air pressure supplied through the air pressure indicator 6 so that the user selectively adjusts the amount of air supplied to the bubble generating space A. Nanobubble generation efficiency is maximized,

On the other hand, in the raw water movement path of the raw water pipe 100 and the bubble generating means 200 connected to the air supply pipe 3 by the moving pressure of the raw water when the raw water is supplied from the raw water pipe 100, A vacuum suction pressure is established.

Accordingly, external air is supplied to the inside while being sucked in through the air supply pipe 3 , mixed with raw water, and supplied to the nano-bubble generating means 200 .

Therefore, it is possible to stably supply the air consumed when the nano-bubbles are generated in the bubble generating space (A) without a separate air supply; In particular, economic benefits and space use efficiency are maximized through structural simplification.

In the above, the space in which the vacuum suction pressure is formed in the movement path of the raw water of the raw water pipe 100 and the bubble generating means 200 may be formed in a portion having a shape in which the diameter is reduced and enlarged on the movement path, According to 'Pascal's Principle' and 'Bernoulli's Theorem', a 'Cevite line (cavitation)' can be generated in a space with a reduced diameter.

That is, as the vacuum suction pressure is formed naturally during the movement of raw water, a vacuum suction force is generated to the air supply pipe 3 , so that external air can be naturally supplied.

In the air supply device 1 of the nano-bubble generating system 10 according to the present embodiment made as described above, the air pressure indicator 6 is the see-through tube 61 while the user sees through the see-through tube 61 . to recognize the position of the floating body 62 disposed inside the; It is controlled while recognizing the floating position of the floating body 5 through the supply pressure of air controlled through the control valve 5 .

Accordingly, the air supply amount is adjusted while correcting for the variation of the air suction pressure according to the difference in the vacuum suction pressure due to the moving pressure pressure of the raw water in the raw water pipe 10 .

In the above-described viewing tube 61, 'marking scales' for schematically recognizing the position of the floating body 62 are engraved, so that the recognition of information can be made clearer.

In the air supply device 1 of the nano-bubble generating system 10 according to the present embodiment made as described above, in the air supply pipe 3, the vacuum pressure is formed in a space where the vacuum pressure is formed on the movement path of the raw water. Depending on the presence or absence, a one-way check valve 7 to open and close the supply of air may be provided.

That is, when a vacuum pressure is formed by the moving pressure of the raw water when the raw water is supplied from the raw water pipe 100 , the one-way check valve 7 is opened and external air is supplied via the air supply pipe 3 . After being mixed with raw water, it is supplied to the bubble generating space (A) of the nano-bubble generating means (200).

In addition, according to the user's selection, when the supply of raw water in the raw water pipe 100 is stopped, the vacuum pressure is released from the movement path of the raw water, and the bubble generating space (A) of the nanobubble generating means 200 As the one-way check valve 7 is closed by the mixed water flowing backward in the , leakage to the outside does not occur.

Accordingly, a stable supply of air is made naturally, and leakage of raw water or/and mixed water from the air supply pipe 3 to the outside is prevented, thereby realizing stability.

One embodiment of the present invention described above is merely exemplary, and those of ordinary skill in the art to which the present invention pertains 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 form mentioned in the above detailed description. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. Moreover, it is to be understood that the present invention covers all modifications, equivalents and substitutions falling within the spirit and scope of the invention as defined by the appended claims.

1: air supply device 10: nano-bubble generating system
100: raw water pipe 200: nano-bubble generating means
300: supply pump
3: air supply pipe 4: air inlet pipe
5: Control valve 6: Air pressure indicator
61: sight tube 62: floating body
7: One-way check valve

Claims (1)

In a nanobubble generating system having a raw water pipe to which raw water having a conveying pressure is supplied, and a bubble generating means provided with a bubble generating space configured to generate nanobubbles therein, raw water supplied from the raw water pipe is introduced. An air supply device for a nano-bubble generating system that is spatially connected to a water pipe and a movement path of the raw water of the bubble generating means to supply air from the outside;
an air supply pipe spatially connected to the raw water pipe and a movement path of the raw water of the bubble generating means; an air inlet pipe which is spatially connected to the air supply pipe and through which external air is introduced; A control valve provided on the movement path of air between the air supply pipe and the air inlet pipe to selectively control the space area of the air movement path to selectively control the amount of air supplied to the air supply pipe per unit time Wow; A see-through tube provided to see through the inside on the movement path of air between the air supply pipe and the control valve, and floating by air pressure provided in the see-through tube and moving through the inside of the see-through tube The air supply device of the nano-bubble generating system, characterized in that it comprises;

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