KR102329429B1 - Micro bubble generator for faucet with water-save function - Google Patents

Abstract

The present invention relates to a microbubble generating device having a water saving function. In the present invention, a first chamber of a cylindrical shape that can be coupled to a tap such as water supply; a cylindrical second chamber coupled to a lower portion of the first chamber; a cylindrical third chamber coupled to a lower portion of the second chamber; The inside of the first chamber is formed with a pressurized space for increasing the pressure and flow rate of the supplied water and a nozzle unit for discharging water of the increased flow rate, and the inside of the second chamber coupled to the first chamber is of the first chamber. A mixing space for mixing water and air discharged from the nozzle unit and a mixing outlet for discharging the mixed water are formed, and the inside of the third chamber coupled to the second chamber is formed with the mixed outlet of the second chamber and a predetermined predetermined space. A mesh member made of at least one mesh for generating microbubble water is installed at a location spaced apart from each other, and a drain hole for discharging the generated microbubble water is formed in the lower portion of the mesh member, the first chamber and the A water saving function, characterized in that an air inlet through which air is introduced from the outside is formed in the coupling portion of the second chamber, and a bubble outlet through which internal bubbles (air) are discharged are formed in the coupling portion of the second chamber and the third chamber. A water-only microbubble generating device having a

Description

Micro bubble generator for faucet with water-save function

The present invention relates to a water-only microbubble generating device having a water saving function. More particularly, it relates to a water faucet-only microbubble generating device coupled to the end of the tap (faucet) of the water supply and having a non-motorized, non-powered water saving function that generates water flowing through the tap of the water supply as microbubble water.

Microbubbles Mercury consists of microbubbles (bubbles) with a size of 1-50㎛. In particular, microbubbles are negatively charged (-) due to free radicals and have strong adsorption power, so surfactants such as detergents and residues It has a cleaning effect that removes foreign substances such as pesticides. In addition, when microbubbles are generated, the amount of dissolved oxygen increases, and OH radicals (hydroperoxy radicals, HO2) and anions are generated, which is known to be effective in sterilization and beauty.

OH radical (Hydroperoxy radical, HO2) is a natural substance that is harmless to the human body, is involved in the sterilization and disinfection of pollutants, has excellent oxidation power and oxidation rate, and has no ozone smell from water.

A number of devices for generating microbubble water have been developed. There are powered devices or non-powered devices. Among them, the non-powered microbubble water generator is of high interest from the point of view of eco-friendliness.

A device for generating microbubbles using a constant pressure of Republic of Korea Patent Publication No. 10-2013-0054090 (published on May 24, 2013) has been disclosed.

The disclosed invention, a water supply pipe in the form of a pipe; a water supply port formed in the upper portion of the water supply pipe to receive water; a drain hole formed in the lower portion of the water supply pipe to discharge water; a bubble nozzle formed in the drain hole in a form in which the inner diameter is suddenly narrowed and then gradually widened; an air supply port in the form of a pipe formed on one side of the water supply pipe; An air check valve formed at the end of the air supply port to allow air to flow only through the air supply port from the outside;

The disclosed invention pulverizes the water by making the supplied water collide with the screw inside, and mixes it with the air introduced from the air supply port and sprays it. There is a problem.

A micro-bubble generator of Chinese Patent Publication No. 108178224 (published date: June 19, 2018) has been disclosed.

In the disclosed invention, the cylindrical tube is divided into upper and lower parts by a narrowed portion as a boundary, a water supply part is formed at the upper end, an exhaust pipe is formed in the lower part of the water supply part, and a pressing means is formed on the outside of the boundary part, and the lower part It is a configuration in which screw-type parts are installed on the

The disclosed invention is an invention in which an external device such as a pressurizing device is installed, so that the structure is complicated, and there is a limit in generating substantial microbubbles in the structure. In addition, the disclosed inventions have a problem in that they have a structure that is very inappropriate for cleaning pollutants such as water scale according to use.

Therefore, it has a simple structure that does not have a separate configuration for inflow of air required to generate microbubble water, and is easy to manufacture, can generate substantial microbubble water with a bubble size of 1-50 μm, has water purification and water saving functions, An invention that facilitates cleaning of internal contaminants according to use is desired.

Republic of Korea Patent Publication No. 10-2013-0054090 Chinese Laid-Open Patent No. 108178224

The present invention is to solve the problems of the prior art, and an object of the present invention is to have a simple structure without a separate configuration for air inflow required to generate microbubble water, which is easy to manufacture, and has a bubble size of 1-50 μm. An object of the present invention is to provide a microbubble generating device capable of generating substantial microbubble water.

Another object of the present invention is to provide a microbubble generator having functions of water purification and water saving of 20 to 50% in water use.

Another object of the present invention is to provide an apparatus for generating microbubbles that facilitates cleaning of internal contaminants according to use.

As a technical solution for achieving the object of the present invention, in the aspect of the present invention, the first chamber having a predetermined length of the upper side of the tubular; a tubular second chamber having a predetermined length coupled to a lower portion of the first chamber by means such as screw coupling; a tubular third chamber having a predetermined length coupled to a lower portion of the second chamber by means such as screw coupling; The first chamber may include: a water supply port for supplying water obtained by being connected to a tap of a water supply to the apparatus; a pressurized space for water composed of an inner space whose diameter becomes smaller toward the lower part; a nozzle unit for spraying water with increased water pressure at the lower end; a first coupling means formed outside corresponding to the position of the nozzle part; The second chamber is formed with a second coupling means coupled to the first coupling means of the first chamber at an upper portion, and a mixing space in which water and air sprayed from the nozzle of the first chamber are mixed; ; a mixed export water unit through which water mixed with air is discharged from the mixing space; a third coupling means formed outside corresponding to the position of the mixed export water part; The third chamber includes a fourth coupling means coupled to the third coupling means of the second chamber is formed in the upper portion, and a drain hole formed in the lower portion of the fourth coupling means;

a filtering net for filtering foreign substances in water supplied to a lower portion of the water supply port of the first chamber; an air inlet having a gap formed therein so that air can be introduced into the mixing space of the second chamber from the outside in a state in which the first coupling means of the first chamber and the second coupling means of the second chamber are coupled; a mesh member having at least one micro-hole installed in the third chamber spaced apart from the mixed export water unit of the second chamber by a predetermined distance in a state in which the second chamber and the third chamber are coupled; In a state in which the third coupling means of the second chamber and the fourth coupling means of the third chamber are coupled, the bubbles generated in the space between the mixed export water unit of the second chamber and the mesh member of the third chamber are released to the outside. There is provided a water-saving microbubble generating device having a water saving function including a bubble discharging part formed between the second chamber and the third chamber to be discharged.

According to the present invention, it is easy to manufacture as a simple structure without a separate configuration for introducing air necessary to generate microbubbles, and it is possible to generate substantial microbubble water with a bubble size of 1-50 μm, and in the use of water There is a function of water purification and water saving of 20 to 50%, and there is an effect of easy cleaning of internal contaminants according to use.

1 is a schematic configuration diagram of an embodiment of a water-saving microbubble generating device having a water saving function of the present invention.
2 is a schematic configuration diagram of an embodiment of the main part of the water-saving microbubble generating device having a water-saving function of the present invention.
3 is a schematic configuration diagram of the operation of an embodiment of the main part of the water-saving microbubble generating device having a water-saving function of the present invention.
4 is a schematic configuration diagram of another main part of the water-saving microbubble generating device having a water saving function according to an embodiment of the present invention.
5 is a schematic configuration diagram of an embodiment of another main part of the water-saving microbubble generating device having a water saving function of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic configuration diagram of an embodiment of a water-saving microbubble generating device having a water saving function of the present invention.

As shown in FIG. 1, the apparatus for generating microbubbles for water use having a water saving function according to the present invention includes: a first cylindrical chamber 100 having a predetermined length on the upper side; a tubular second chamber 200 having a predetermined length coupled to the lower portion of the first chamber 100 by means such as screw coupling; and a tubular third chamber 300 having a predetermined length coupled to a lower portion of the second chamber 200 by means such as screw coupling; The first chamber 100 includes a water supply port 110 for supplying water obtained by being connected to a tap of a water supply to the apparatus; The pressure space 120 of water consisting of an inner space whose diameter becomes smaller toward the lower part; a nozzle unit 130 for spraying water with increased water pressure at the lower end; a first coupling means 140 formed outside corresponding to the position of the nozzle unit 130; The second chamber 200 has a second coupling means 210 coupled to the first coupling means 140 of the first chamber 100 formed therein, and the first chamber 100 is formed therein. a mixing space 220 in which water and air sprayed from the nozzle unit 130 are mixed; a mixed export water unit 230 through which water mixed with air is discharged from the mixing space 220; a third coupling means 240 formed outside corresponding to the position of the mixed export water unit 230; The third chamber 300 has a fourth coupling means 310 coupled to the third coupling means 240 of the second chamber 200 formed on the upper portion, and the fourth coupling means 310 is formed. and a drain hole 320 formed at the bottom;

a filtering net 400 for filtering foreign substances in water supplied to the lower portion of the water supply port 110 of the first chamber 100; In a state in which the first coupling means 140 of the first chamber 100 and the second coupling means 210 of the second chamber 200 are coupled, air from the outside flows into the mixing space of the second chamber 200 . an air inlet 10 having a gap formed therein so as to be introduced into the 220; In a state in which the second chamber 200 and the third chamber 300 are coupled, the mixed export water unit 230 of the second chamber 200 and the third chamber 300 are spaced apart from each other by a predetermined distance. at least one mesh member 500 having installed fine holes; Mixed export water unit 230 of the second chamber 200 in a state in which the third coupling means 240 of the second chamber 200 and the fourth coupling means 310 of the third chamber 300 are coupled. and a bubble discharging part 20 formed between the second chamber 200 and the third chamber 300 so that bubbles generated in the space between the mesh member 500 of the third chamber 300 are discharged to the outside. ) is included.

The water 1000 supplied to the water supply port 110 of the first chamber 100 is pressurized while passing through the pressurized space 120 of the first chamber 100 as foreign substances are filtered in the filtering net 400 , and the It flows into the second chamber 200 in a state in which the flow rate is increased while passing through the nozzle unit 130 . Through the air inlet 10 formed between the first chamber 100 and the second chamber 200 due to the flow rate of the water having an increased flow rate through the nozzle unit 130 of the first chamber 100, the outside Air is introduced into the second chamber 200 . In the mixing space 220 of the second chamber 200 , water introduced through the nozzle unit 130 of the first chamber 100 and the air introduced through the air inlet 10 are mixed to form air. A mixed water 2000 in which and water are mixed is generated. The mixed water is introduced into the third chamber 300 through the mixed export water unit 230 of the second chamber 200 . The mixed water 2000 having a high flow rate introduced into the third chamber 300 strongly collides with the mesh member 500 in the third chamber 300, so that the mixed water 2000 is pulverized to supply air therein. It creates microscopic bubbles containing Since the hole of the mesh member 500 is fine, when the mixed water 2000 collides with the surface of the mesh member 500 , crushed air bubbles may be excessively generated. In this case, excessively generated air bubbles may interfere with passing through the mesh member 500 . A portion of the excessively generated bubbles is discharged to the outside through the bubble discharge unit 20 formed between the second chamber 200 and the third chamber 300 . Of course, the discharged bubbles may burst in the process of being discharged, and the air in the bubbles may be discharged to the bubble discharging unit 20 . The mixed water 2000 is pulverized into finer bubbles while passing through the second and third mesh members in which the bubbles generated while colliding with the uppermost layer of the mesh member 500 are overlapped to obtain the desired number of microbubbles (3000). generated and drained through the drain hole 320 of the third chamber 300 .

2 is a schematic configuration diagram of an embodiment of the main part of the water-saving microbubble generating device having a water-saving function of the present invention.

As shown in FIG. 2 , as a combined configuration of the first chamber 100 and the second chamber 200 , the water 1000 supplied to the water supply port 110 of the first chamber 100 is supplied to the first chamber. The water pressurized through the pressure space 120 whose diameter decreases from the inside of 100 to the lower part is pressurized and the flow rate is increased, and the water pressurized through the nozzle unit 130 formed at the lower end of the first chamber 100 is It is introduced into the second chamber 200 at a high flow rate. At this time, due to the fast flow rate of the water discharged from the nozzle unit 130, the first coupling means 140 of the first chamber 100 and the second coupling means 210 of the second chamber 200 are coupled to the coupling portion. External air is introduced from the air inlet 10 into the formed gap 11 . In the mixing space 220 of the second chamber 200, the water introduced from the nozzle 130 of the first chamber 100 and the air introduced from the air inlet 10 are mixed (2100) to form water. Mixed water 2000 in which air and air are mixed is generated. The first coupling means 140 of the first chamber 100 and the second coupling means 210 of the second chamber 200 may be configured in various forms. For example, when it is made by a method such as screwing, binding or fitting, it may be configured to form a gap through which air introduced from the air inlet 10 can pass. The mixed water 2000 generated in the mixing space 220 of the second chamber 200 is discharged through the mixed export water unit 230 of the second chamber 200 .

Preferably, the length of the first chamber 100 is about 26 mm, and the portion coupled to the second chamber 200 is configured to be about 10 mm. In addition, the length of the second chamber 200 is preferably configured to be about 22mm.

3 is a schematic configuration diagram of the operation of an embodiment of the main part of the water-saving microbubble generating device for water-saving function of the present invention.

For example, tap water pressure varies depending on the location. Accordingly, the distance to the nozzle unit 130 of the first chamber 100 and the mixed export water unit 230 of the second chamber 200 and, as a result, the mesh member 500 of the third chamber 300 is fixed. If the water pressure is low, the amount of air introduced into the air inlet 10 is small, so the desired microbubble water cannot be obtained, and in the water supply with excessively high water pressure, the air introduced into the air inlet 10 There may be a problem in that the desired number of microbubbles cannot be obtained because there are too many.

The present invention proposes a configuration for solving such a problem. As shown in FIG. 3 , the coupling of the first coupling means 140 of the first chamber 100 and the second coupling means 210 of the second chamber 200 may be configured such that the length thereof is adjusted. For example, when the coupling of the first coupling means 140 and the second coupling means 210 is a screw coupling, the coupling of the first chamber 100 and the second chamber 200 by the length of the screw tightening. By adjusting the length, the distance between the nozzle unit 130 of the first chamber 100 and the mesh member 500 of the third chamber 300 may be adjusted. When the water pressure of tap water is low, the first chamber 100 and the second chamber 100 increase the distance between the nozzle part 130 of the first chamber 100 and the mesh member 500 of the third chamber 300 . When the chamber 200 is coupled, and when the water pressure of the tap water is high, the first chamber 100 narrows the distance between the nozzle part 130 of the first chamber 100 and the mesh member 500 of the third chamber 300 . It is configured to couple the chamber 100 and the second chamber 200 .

Preferably, the distance between the nozzle part 130 of the first chamber 100 and the uppermost mesh member of the third chamber 300 is determined in the range of 5 mm to 21 mm.

4 is a schematic configuration diagram of an embodiment of another main part of the water-saving microbubble generating device having a water-saving function of the present invention.

FIG. 4 is for explaining the concept of a configuration for generating microbubble water 3000 in the second chamber 200 and the third chamber 300 . As shown in FIG. 4 , the mixed water 2000 of air and water having a high flow rate discharged from the mixed export water unit 230 of the second chamber 200 is the uppermost mesh member 500 in the third chamber 300 . ) is pulverized while strongly colliding with the air bubbles 3100 . This causes a cavitation phenomenon in which when a high-velocity water stream collides with the mesh member, the flow rate is rapidly lowered, and the pressure of water flowing through the mesh member is rapidly lowered to a state below the saturated water vapor pressure, whereby the water is vaporized and bubbles are generated.

At this time, when the mixed water 2000 flowing in from the nozzle unit 130 of the second chamber 200 contains excessive air, excessive air bubbles may be generated in the mesh member, and large particles of air bubbles are formed. Due to this, there is resistance to the inflow of air bubbles into the mesh member 500 , which may interfere with the generation of the desired number of microbubbles. In this case, some bubbles or air is discharged to the bubble discharge unit 20 through the gap 21 between the coupling portion of the second chamber 200 and the third chamber 300 . Thereby, the target microbubble water 3000 is generated while the air bubbles 3100 smoothly pass through the mesh member 500, and through the drain hole 320 of the third chamber 300, milky 1-50 μm. Microbubbles of the size are drained.

5 is a schematic configuration diagram of an embodiment of another main part of the water-saving microbubble generating device having a water-saving function of the present invention.

As shown in FIG. 5 , the mesh member 500 installed inside the third chamber to generate microbubble water may have, for example, a configuration in which a plurality of meshes made of a metal material are overlapped. Preferably, the uppermost layer mesh 510 adopts 100 mesh (0.154×0.154), and the meshes 520 to 540 stacked under the uppermost layer mesh 510 have a smaller hole size than the uppermost layer mesh 200 mesh ( 0.074×0.074) is recommended.

The mixed water 2000 in which the air and water introduced into the third chamber 300 are mixed strongly collides with the mesh 510 of the uppermost layer to generate primary bubbles, and the generated bubbles are generated by the mesh 510 of the uppermost layer. Generates smaller bubbles while passing through the meshes 520 to 540 having smaller holes than the uppermost mesh 510 stacked under .

In an embodiment of the present invention, the first to third chambers can be coupled and separated using a coupling means such as a screw, and the internal filtering net and mesh member are also easily separated, so that the inside of the device can be easily cleaned.

The embodiments of the present invention described above are only some of the various embodiments of the present invention. The total length of the present invention is only 50-60mm, and is divided into a first chamber to a third chamber, a means through which air can be introduced between the first chamber and the second chamber is formed, and the second chamber and the third chamber A means for discharging air bubbles (air) is provided between the chambers, the first chamber and the second chamber are provided with a coupling means capable of adjusting the length, and a plurality of meshes are overlapped with mixed water mixed with air and water. It is natural that various embodiments included in the technical idea of generating the desired number of microbubbles while passing through the mesh member are included in the protection scope of the present invention.

10: air inlet
20: bubble discharge unit
100: first chamber
200: second chamber
300: third chamber
400: filter net
500: mesh member

Claims (10)

a tubular first chamber of a predetermined length that can be coupled to a tap such as a tap water and has an upper portion and a lower portion and an outer diameter of the upper portion is greater than an outer diameter of the lower portion; a cylindrical second chamber coupled to a lower portion of the first chamber and having an upper portion and a lower portion, the outer diameter of the upper portion corresponding to the outer diameter of the upper portion of the first chamber and having a predetermined length greater than the outer diameter of the lower portion; a tubular third chamber coupled to a lower portion of the second chamber and having an outer diameter corresponding to the outer diameter of the second chamber;
The inside of the first chamber is formed with a pressurized space for increasing the pressure and flow rate of the supplied water and a nozzle unit for discharging the water of the increased flow rate, and the inside of the second chamber coupled to the lower portion of the first chamber is the first A mixing space for mixing water and air discharged from the nozzle unit of the chamber and a mixing outlet for discharging the mixed water are formed, and the inside of the third chamber coupled to the lower part of the second chamber is the mixing space of the second chamber. A mesh member made of at least one mesh for generating microbubble water is installed at a position spaced apart from the export water part by a predetermined distance, and a drain port for discharging the generated microbubble water is formed in the lower portion of the mesh member,
An air inlet through which air is introduced from the outside is formed in the coupling part in which the lower part of the first chamber is coupled in a shape to be inserted into the upper part of the second chamber, and the coupling length of the coupling part is set at the height of the incoming water pressure. Accordingly, by adjusting the distance between the end of the nozzle part of the first chamber and the mesh member of the third chamber, the lower part of the second chamber is inserted into the upper part of the third chamber. Microbubbles for water faucet having a water saving function, characterized in that a bubble discharge part located above the mesh member from which air contained in some of the bubbles generated when the mixed water collides with the mesh member is discharged is formed Device. The method according to claim 1,
A water-saving microbubble generating device having a water saving function, characterized in that a filtering net for filtering foreign substances in water supplied to a predetermined position of the pressurized space inside the first chamber is installed. The method according to claim 1,
A water-saving microbubble generating device having a water saving function, characterized in that the pressurized space of the first chamber has a shape that becomes narrower toward the bottom. The method according to claim 1,
The coupling of the first chamber and the second chamber includes a coupling means, wherein the coupling means has a gap through which air can be introduced into the mixing space of the second chamber from the air inlet. A water-only microbubble generator with a function. The method according to claim 1,
The coupling of the second chamber and the third chamber includes a coupling means, and the coupling means is included in some of the bubbles generated when the mixed water discharged from the second chamber collides with the mesh member of the third chamber. A water-saving microbubble generating device having a water saving function, characterized in that a gap is formed through which air can be discharged to the outside through the bubble discharge unit. delete The method according to claim 1,
The mesh member of the third chamber is a water-saving microbubble generating device having a water saving function, characterized in that made of a plurality of overlapping metal mesh. The method according to claim 1,
The mesh member of the third chamber is formed of at least four overlapping metal meshes. The method according to claim 1,
The mesh member of the third chamber is for a water faucet having a water saving function, characterized in that the uppermost mesh of 100 mesh (0.154 0.154) and at least one 200 mesh (0.074 0.074) mesh are overlapped under the uppermost mesh. Microbubble generator. The method according to claim 1,
An apparatus for generating microbubbles for water use with a water saving function, characterized in that the total length is 50mm to 60mm in a state in which the first chamber, the second chamber and the third chamber are combined.

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