KR20230045708A - Bubble reneration apparatus - Google Patents

Abstract

The present invention relates to a bubble generation apparatus. The bubble generation apparatus comprises: a body formed so that an upper part and a lower part communicate with each other, wherein the upper part has a closed upper end part and a hollow inside, and is oriented perpendicular to the ground, and the lower part has one end coupled to a lower end part of the upper part and has a hollow inside, and is oriented horizontally with respect to the ground; a pressurized water inlet member installed on the outer surface of the body to communicate with the upper part at a predetermined distance from the upper end part of the body; a collision cap installed on the outer surface of the body at a position opposite to the pressurized water inlet member, and installed to communicate with the upper part; a water outlet member installed at the other open end of the lower part; and an air vent member installed on an upper side of the lower part spaced a predetermined distance from the water outlet member to communicate with the lower part from the outer surface of the body. According to the present invention, fine bubbles of a desired size can be discharged without the flow being interrupted by large-sized bubbles.

Description

Bubble generator {Bubble generation apparatus}

The present invention relates to a bubble generator. More specifically, the liquid obtained is crushed by impact to generate bubbles, but large-sized bubbles are separated to facilitate the flow of fine bubbles, and finally, fine bubbles of the desired size are discharged, and the structure is simple. It relates to a bubble generator that can be easily applied to any bathtub.

A bubble generator is known to have a sterilization and massage effect by converting water obtained from a bathtub or the like into fine bubbles and generating negative ionized air generated when the bubbles burst in the bathtub due to the air contained in the bubbles.

Various methods of generating bubbles are known. Representative methods include a method of splitting the incoming water into small pieces by installing a mesh on the water outlet nozzle, a method of splitting the incoming water into small pieces as it hits the impact plate, or a method of making small water clusters by irradiating the water flowing through the pipe with microwaves, etc. this is known.

As an invention in which water hits an impact plate to generate bubbles, an oxygen microbubble supply device for a bathtub is disclosed in Korean Patent Publication No. 10-2008-0092750 (published on October 16, 2008).

As shown in FIG. 7, in the disclosed invention, one to three orifice inlets 232a of the micronozzle unit 130 may be formed in the central portion of the inlet plate 232, and the outlet 234 A plurality of are formed around the outer circumferential surface of the opposite side of one side on which the orifice inlet 232a is formed to be connected to the inner space of the micronozzle unit 230. In addition, a plane 233 facing the orifice inlet 232a is formed on an inner side of the micronozzle unit 230 opposite to the orifice inlet 232a. The mixed water of water and oxygen is injected into the inner space 231 of the micronozzle unit 230 while passing through the orifice inlet 232a of the micronozzle unit 230, and the inner surface of the opposite side formed to face the orifice inlet 232a. It collides with the negative plane 233, whereby the oxygen bubbles in the mixing water are broken more finely.

The disclosed invention has a configuration in which the mixed water of introduced water and oxygen collides with the flat surface of the inner surface to generate microbubbles. However, the mixed water hitting the plane creates bubbles of various sizes, and large-sized bubbles and fine bubbles are mixed. In this case, the flow of the bubbles generated due to the buoyancy of the large-sized bubbles is not smooth, However, there is a problem in that large-sized bubbles burst before being drained, interfering with the discharge of small-sized bubbles.

In addition, the Korean Utility Model Registration No. 20-0450938 (registration date: November 05, 2010) has disclosed a micro-bubble generator.

In the spray nozzle body of the registration design, a male screw is formed around the outer edge so that one side is coupled to the end of the discharge tube formed long in the longitudinal direction, and a female screw is formed so that the microbubble generating filter member to be described later is screwed to the other inner edge. The micro-bubble generating filter member is screwed to a female screw formed on the inner edge of the spray nozzle body, and is configured to generate a large amount of micro-bubbles by rupturing the air mixture water sprayed inward through the discharge pipe. The micro-bubble generating filter member is a mesh-like material that has a disk-shaped fine mesh structure that breaks water into small pieces when water passes through it, and is installed below the burst filter so that the water ruptured in the burst filter is secondary. It is a configuration including a spherical rupture filter in which a hole is formed to be ruptured.

The registration design has a structure in which bubbles are generated by performing a primary rupture with a plurality of rupture filters made of mesh and a secondary rupture with a spherical burst filter having holes formed on a curved surface, and the structure is complicated and the configuration of a nozzle installed in a bathtub , there is a problem that is difficult to apply as a bubble generator for various purposes.

Therefore, as a microbubble generator applied to inject microbubbles into bathtubs for various purposes, bubbles are generated by pulverizing the liquid obtained by impact, and the bubbles of large size are separated to facilitate the flow of microbubbles. Finally, it is desired to develop an invention that allows microbubbles of a desired size to be discharged and has a simple structure so that it can be easily applied to any bathtub.

Republic of Korea Patent Publication No. 10-2008-0092750 (published date: October 16, 2008) Republic of Korea Utility Model Registration No. 20-0450938 (registration date: November 05, 2010)

The present invention is to solve the problems of the prior art, and an object of the present invention is to generate bubbles by impacting a fluid, and among the generated bubbles, fine bubbles of a desired size are not obstructed in flow by bubbles of a large size. It is to provide a bubble generator that can be discharged without water.

Another object of the present invention is to provide a bubble generator having a simple structure without intervening any parts therein.

As a technical solution for achieving the object of the present invention, in the first aspect of the present invention, an upper part of a cylinder having a predetermined length and a predetermined diameter in a vertical direction with respect to the ground and having a closed upper end, and a length greater than the length of the upper part a main body having a short and identical diameter and including a tubular lower part integrally formed with one end of the lower part of the upper part so as to communicate with the upper part in a horizontal direction from the lower part of the upper part to the ground; It is installed on the outer surface of the main body at a position spaced downward by a predetermined distance from the upper end of the main body, is installed in an inlet through hole formed from the outside to the inside of the main body, and has a pressurized hole of a predetermined diameter formed in the center to increase the pressure of the fluid supplied to the main body. a pressurized acquisition member for injecting fluid into the interior; a collision cap installed in a collision through-hole formed on an outer surface of the main body at a position facing the pressurization member so that the fluid ejected from the pressurization member collides with the fluid and breaks the fluid into small pieces; an air vent member installed on an upper surface of the lower part spaced a predetermined distance from an end of the lower part of the main body toward the upper part and installed in an air passage formed from the outside to the inside of the main body to discharge air separated from bubbles; It is installed in the water outlet hole formed at the end of the lower part of the main body and includes a water outlet member for discharging air bubbles;

The main body includes an air buffer portion filled with air formed in a closed space above the inlet through hole and the collision through hole; It is formed on the lower side of the upper inlet through hole and the collision through hole, and the fluid and air finely divided from the collision through hole meet to form mixed fluid bubbles of various sizes and fall, but the large-sized bubbles are separated from the fine-sized bubbles by buoyancy. a first bubble separation unit for the mixed fluid positioned to move to the air buffer unit; a separator bubble buffer part formed at a lower part of the first bubble separator and at a position where the upper and lower parts of the main body meet, and in which the microbubbles of the mixed fluid separated by the first bubble separator are located; The lower part of the main body connected to the separator bubble buffer part, and large-sized bubbles mixed in the fine bubbles of the mixed fluid in the separator bubble buffer part are separated and discharged as air through the upper air passage hole, and only the fine bubbles are discharged through the water outlet hole. A bubble generating device including a second bubble separator for discharging is provided.

In addition, as a second aspect of the present invention, an upper part of a cylinder having a predetermined length and a predetermined diameter in a direction perpendicular to the ground and having a closed upper end, and a predetermined diameter shorter than the length of the upper part and smaller than the diameter of the upper part A first lower part of a tubular shape having one end integrally formed with the lower end of the upper part so as to communicate with the upper part in a horizontal direction from the lower part of the upper part to the ground; a second lower part installed at a lower end of the upper part opposite to the first lower part and having the same shape as the first lower part; a main body including a partition member protruding upward from the lower surface of the upper part by a predetermined length and separating the first lower part and the second lower part within the upper part; It is installed on the outer surface of the main body at a position spaced downward by a predetermined distance from the upper end of the main body, is installed in an inlet through hole formed from the outside to the inside of the main body, and has a pressurized hole of a predetermined diameter formed in the center to increase the pressure of the fluid supplied to the main body. a pressurized acquisition member for injecting fluid into the interior; a collision cap installed in a collision through-hole formed on an outer surface of the main body at a position facing the pressurization member so that the fluid ejected from the pressurization member collides with the fluid and breaks the fluid into small pieces; First air that is installed on the upper surface of the first lower part spaced apart from the end of the first lower part of the main body by a predetermined distance in the upper direction and is installed in a first air hole formed from the outside to the inside of the main body to discharge air separated from bubbles. a vent member; a first water outlet member installed in a first water outlet hole formed at an end of the first lower part of the main body to discharge air bubbles; Second air is installed on the upper surface of the second lower part spaced apart from the end of the second lower part of the main body by a predetermined distance in the upper direction and is installed in a second air hole formed from the outside to the inside of the main body to discharge air separated from bubbles. a vent member; It is installed in the second water outlet hole formed at the end of the second lower part of the body and includes a second water outlet member for discharging air bubbles;

The main body includes an air buffer portion filled with air formed in a closed space above the inlet through hole and the collision through hole; It is formed on the lower side of the upper inlet through hole and the collision through hole, and the fluid and air finely divided from the collision through hole meet to form mixed fluid bubbles of various sizes and fall, but the large-sized bubbles are separated from the fine-sized bubbles by buoyancy. a first bubble separation unit for the mixed fluid positioned to move to the air buffer unit; a first separator bubble buffer part below the first bubble separator, formed at a position where the upper part of the main body and the first lower part meet, and in which the microbubbles of the mixed fluid separated by the first bubble separator are located; It is the first lower part of the main body connected to the first separator bubble buffer part, and large-sized bubbles mixed in the micro-bubbles of the mixed fluid in the first separator bubble buffer part are separated and discharged as air through the first air passage on the upper side. a second bubble separator for discharging only the fine bubbles through the first water outlet hole; a second separator bubble buffer part below the first bubble separator, formed at a position where the upper part of the main body and the second lower part meet, and in which the microbubbles of the mixed fluid separated by the first bubble separator are located; It is the second lower part of the main body connected to the second separator bubble buffer part, and large-sized bubbles mixed in the fine bubbles of the mixed fluid in the second separator bubble buffer part are separated and discharged as air through the second air hole on the upper side. and a bubble generator including a third bubble separator for discharging only fine bubbles through the second outlet hole.

According to the present invention, the fluid is broken into small pieces by impact, and bubbles of the mixed fluid mixed with air are generated, and among the generated bubbles, fine bubbles of a desired size can be discharged without being hindered by large bubbles. , there is an effect that can be implemented as a structure without intervening any internal parts.

1 is a schematic cross-sectional configuration diagram of an embodiment of a bubble generator of the present invention.
FIG. 2 is a plan configuration diagram of FIG. 2 .
3 is a schematic cross-sectional configuration view of an embodiment of a collision cap (a in FIG. 1), which is a main part of the bubble generator of the present invention.
Figure 4 is a schematic configuration diagram for explaining the operation of the embodiment of the bubble generator of the present invention.
5 is a schematic cross-sectional configuration view of another embodiment of the bubble generator of the present invention.
FIG. 6 is a plan configuration diagram of FIG. 5 .
7 is a configuration diagram related to the prior art of a bubble generator.
8 is a schematic configuration diagram of a bathtub system to which the bubble generator of the present invention is applied.

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

1 is a schematic cross-sectional configuration diagram of an embodiment of a bubble generator of the present invention. 2 is a plan configuration diagram of FIG. 2 .

As shown in FIGS. 1 and 2, the bubble generator 100 of the present invention has a cylindrical upper part 100a having a predetermined length and a predetermined diameter in the vertical direction with respect to the ground and having a closed upper end, and the upper (100a) having the same diameter and having one end integrally formed at the lower end of the upper part (100a) so as to communicate with the upper part in the horizontal direction from the lower part of the upper part (100a) to the ground. Including a cylindrical lower part (100b) With the main body 110; It is installed on the outer surface of the main body 110 at a position spaced downward by a predetermined distance from the upper end of the main body 110 and is installed in the water inlet through hole 112 formed from the outside to the inside of the main body 110 and has a pressurizing hole 121 having a predetermined diameter in the center. ) is formed to increase the pressure of the fluid to be supplied and pressurized water intake member 120 to inject the fluid into the main body 110; It is installed in the collision through hole 113 formed in the main body 110 at a position facing the pressurization member 120, and the fluid injected from the pressurization member 120 enters through the collision through hole 113 and collides with the fluid. a collision cap 130 having a flat surface or a closed surface of a protrusion for splitting into small pieces; An air through hole 117 formed from the outside to the inside of the main body 110 on the upper surface of the lower part 100b at a predetermined distance from the end of the lower part 100b of the main body 110 is installed so as to face upward, so that air bubbles an air vent member 140 for discharging air separated from; It is installed in the water outlet hole 118 formed at the end of the lower portion 100b of the main body 110 and includes a water outlet member 150 for discharging air bubbles;

The body 110 includes an air buffer part 111 filled with air formed in a closed space above the inlet through hole 112 and the collision through hole 113 of the upper part 100a; It is formed on the lower side of the inlet through hole 112 and the collision through hole 113 of the upper part 100a, and the fluid and air finely divided from the collision through hole 113 meet to form mixed fluid bubbles of various sizes and fall, but the size is large a first bubble separation unit 114 for the mixed fluid, which is positioned so that bubbles are separated from fine-sized bubbles by buoyancy and move toward the air buffer unit 111; It is the lower part of the first bubble separator 114 and is formed at the position where the upper part 100a and the lower part 100b of the main body 110 meet, and the fine bubbles of the mixed fluid separated from the first bubble separator 114 are a separator bubble buffer unit 115 positioned thereon; The lower part 100b of the main body connected to the separator bubble buffer part 115, and large-sized bubbles mixed in the fine bubbles of the mixed fluid in the separator bubble buffer part 115 are separated and go up to the upper separation space. a second bubble separation unit 116; Large-sized bubbles separated from the second bubble separator 116 are discharged into the air through the upper air through hole 117 and the air vent member 140, and only the fine bubbles are discharged through the water outlet through hole 118. It is a configuration characterized by discharging to (150). The water outlet member 150 may further include a swirling flow forming nozzle 151 that rotates the water to maintain bubbles or form smaller bubbles.

In the embodiment of FIG. 2, the main body 110 has been described as a tubular shape having a predetermined diameter, but is not limited thereto. The upper part 100a and the lower part 100b of the main body 110 may be configured as a polygon having a rectangular parallelepiped shape having a predetermined width and height, respectively. In addition, the main body 110 may have a polygonal shape including a rectangular parallelepiped shape, but the internal through hole may be configured in a cylindrical shape.

In the embodiment of FIG. 2 , the overall length of the upper part 100a of the main body 110 is 150 mm and the total length of the lower part 100b is 120 mm, whereby the lower part of the upper part 100a and the lower part 100b are separated. The bubble buffer unit 115 has a width and a height of 50 mm, and may be a part commonly included in the upper and lower parts. The outer diameters of the upper part 100a and the lower part 100b may be configured to have a ratio of 50 mm.

This is an example, and is not limited to these values, and it is preferable to change and apply the values of each part to have a ratio corresponding to the above-mentioned values.

3 is a schematic cross-sectional configuration view of an embodiment of a collision cap (A in FIG. 1), which is a main part of the bubble generator of the present invention.

As shown in FIG. 3, FIG. 3 (a) is a cross-sectional view of an embodiment of the collision cap 130 of the present invention, and FIG. 3 (b) shows a longitudinal cross-sectional view. As shown in FIG. 3, the collision cap 130 of the present invention includes a cylindrical cap body portion 131 having a predetermined diameter and length with one end open and the other end closed, and the cap body portion 131 closed. It is configured to include a collision wall portion 132 at the other end and a fluid crushing portion 133 formed with one of a plurality of protrusions or various protrusion patterns formed inside the collision wall portion 132.

Figure 4 is a schematic configuration diagram for explaining the operation of the embodiment of the bubble generator of the present invention.

As shown in FIG. 4, in the bubble generator of the present invention, the fluid 10 circulated in the water supply pipe 170 for supplying the fluid supplied from the water supply pump (not shown) to the bubble generator 100 is the body 110 While passing through the pressurized hole 121 formed in the pressurized intake member 120 coupled to the water inlet through hole 112 of the injection fluid 20 while passing through the water inlet through hole 112 in a state where the water pressure of the fluid 10 is increased It passes through the collision through hole 113 at a position opposite to the inlet through hole 112 and collides with the fluid breaking portion 133 formed on the inner surface of the collision wall portion 132 of the collision cap 130, and the fluid is finely crushed, For example, when the fluid is water, the cluster size of the water is split into small pieces and scattered into the upper space of the upper part 100a of the main body 110 through the collision through hole 113 . The finely divided and scattered fluid is mixed with the air in the air buffer unit 111 to generate bubbles 30 of various sizes. In addition, the spray fluid 20 is mixed with the air in the air buffer unit 111, and the mixed fluid passes through the collision through hole 113 to form a fluid crushing portion 133 formed on the inner surface of the collision wall portion 132 of the collision member 130. ), the mixed fluid is crushed into small pieces, and bubbles of various sizes are generated and scattered into the upper space of the upper part 100a of the main body 110 through the collision hole 113. The generated bubbles 30 of various sizes are directed upwards by their buoyancy and the size is relatively As a result, the small bubbles 50 are directed downward due to their mass, and the bubbles 30 of various sizes are separated from the bubbles 40 having a large size and the bubbles 50 having a relatively small size.

The relatively small-sized bubbles 50 separated from the first bubble separator 114 are temporarily placed in the separator bubble buffer 115, which is a common space between the upper part 100a and the lower part 100b of the main body 110. It is pushed into the lower part 100b of the main body 110 due to the separated air bubbles 50 that are located and continuously falling from the upper part. Bubbles 50 pushed into the lower part 100b are mixed with large-sized bubbles that are not separated by the first bubble separator 114 . A space is formed above the lower part 100b, so that the bubbles 70 having a relatively large size mixed in the bubble 50 are separated and raised by buoyancy to the upper space, and the second bubble of the lower part 100b In the separator 116, the desired air bubble 60, which is relatively small in size, remains. Large-sized bubbles 70 separated and raised to the upper side of the second bubble separator 116 are reduced to air and discharged through the air vent member 140 through the air through hole 117 . The air bubbles 60 having a small size separated from the second bubble separator 116 are discharged to the water outlet member 150 through the water outlet hole 118 formed at the end of the lower portion 100b.

As described above, according to the embodiment of the bubble generator of the present invention, only the desired fine bubbles can be separated and discharged without interference of the flow by bubbles of different sizes in the bubble generator having a simple and unique physical structure. can

5 is a schematic cross-sectional configuration view of another embodiment of the bubble generator of the present invention. 6 is a plan configuration diagram of FIG. 5 .

As shown in FIGS. 5 and 6, the bubble generator 100 of the present invention has a cylindrical upper part 100a having a predetermined length and a predetermined diameter in the vertical direction with respect to the ground and the upper end closed ( 100a) has a predetermined diameter smaller than the diameter of the upper part 100a, and one end is connected to the lower end of the upper part 100a so as to communicate with the upper part 100a in the horizontal direction from the lower part of the upper part 100a to the ground. a tubular first lower portion 100b integrally formed; a second lower part 100c installed at the lower end of the upper part 100a opposite to the first lower part 100b and having the same shape as the first lower part 100b; A main body 110 including a partition member 160 protruding upward from the bottom surface of the upper part 100a by a predetermined length to separate the first lower part 100b and the second lower part 100c within the upper part 100a. )and; It is installed on the outer surface of the main body 110 at a position spaced downward by a predetermined distance from the upper end of the main body 110 and is installed in the water inlet through hole 112 formed from the outside to the inside of the main body 110 and has a pressurizing hole 121 having a predetermined diameter in the center. ) is formed to increase the pressure of the fluid to be supplied and pressurized water intake member 120 to inject the fluid into the main body 110; A collision cap installed in the collision through hole 113 formed on the outer surface of the main body 110 at a position opposite to the pressurization member 120 so that the fluid injected from the pressurization member 121 collides and breaks the fluid into small pieces ( 130) and; A first air hole 117a installed on the upper surface of the first lower part 100b spaced apart from the end of the first lower part 100b by a predetermined distance in the direction of the upper part 100a and formed from the outside to the inside of the body 110 ) and a first air vent member 140a for discharging air separated from bubbles; a first water outlet member 150a installed in the first water outlet through hole 118a formed at the end of the first lower portion 100b of the main body to discharge air bubbles; A second air hole 117b installed on the upper surface of the second lower part 100c spaced apart from the end of the second lower part 100c by a predetermined distance in the direction of the upper part 100a and formed from the outside to the inside of the main body 110 ) and a second air vent member (140b) for discharging air separated from bubbles; a second water outlet member 150b installed in the second water outlet hole 118b formed at the end of the second lower portion 100c of the main body to discharge air bubbles;

The body 110 includes an air buffer part 111 filled with air formed in a closed space above the inlet through hole 112 and the collision through hole 113 of the upper part 100a; It is formed on the lower side of the inlet through hole 112 and the collision through hole 113 of the upper part 100a, and the fluid and air finely divided from the collision through hole 113 meet to form mixed fluid bubbles of various sizes and fall, but the size is large a first bubble separation unit 114 for the mixed fluid, which is positioned so that bubbles are separated from fine-sized bubbles by buoyancy and move toward the air buffer unit 111; It is formed on the lower side of the first bubble separator 114 and is formed at a position where the upper body 100a and the first lower part 100b meet, and the fine bubbles of the mixed fluid separated by the first bubble separator 114 are located. a first separator bubble buffer unit 115a; The first lower part 100b of the main body connected to the first separator bubble buffer part 115a and large-sized bubbles mixed in the microbubbles of the mixed fluid in the first separator bubble buffer part 115a are separated and a second air bubble separation unit 116a for discharging air through the first air through hole 117a and discharging only fine bubbles through the first water outlet through hole 118a; It is formed on the lower side of the first bubble separator 114 and is formed at a position where the upper body 100a and the second lower part 100c meet, and the fine bubbles of the mixed fluid separated by the first bubble separator 114 are located. a second separator bubble buffer unit 115b; The second lower part 100c of the main body 110 connected to the second separator bubble buffer part 115b and large-sized bubbles mixed in the microbubbles of the mixed fluid in the second separator bubble buffer part 115b It is configured to include a third bubble separator 116b for separating and discharging air through the upper second air through hole 117b and discharging only the fine bubbles through the second water outlet through hole 118b.

8 is a schematic configuration diagram of a bathtub system to which the bubble generator of the present invention is applied.

As shown in FIG. 8, a bathtub 1 including a bathtub for a foot bath, a water supply pipe 2 for sucking and supplying water from the bathtub 1, and water moving through the water supply pipe 2 An air mixing unit 3 for mixing air and a pump 4 for sucking water in the bathtub 1 through the water supply pipe 2 and supplying water to the bubble generator 100 at a predetermined water pressure; A configuration including a water supply pipe 5 for supplying water to the bubble generator 100 and a bubble supply pipe 6 for supplying water to the bathtub 1 by discharging the fine bubbles generated in the bubble generator 100 am. In addition, although not shown, a bubble spray nozzle connected to an end of the bubble supply pipe 6 to spray bubbles into the bathtub 1 may be further included.

The embodiments of the bubble generating device of the present invention described above are only some of various embodiments. For example, in the embodiments of FIGS. 5 and 6, the upper and two lower parts of the main body have been described in a “ㅗ” shape, but in another embodiment, three, four, and five upper parts are formed. Of course, an embodiment in which the lower part of the dog is coupled is also possible.

Therefore, a main body with a hollow inside formed so that the upper part in the vertical direction with respect to the ground and the lower end of the upper part of the present invention are coupled and the lower part in the horizontal direction with respect to the ground communicates with the upper part, and a pressurized intake part formed on the upper side of the main body And a collision part is formed at the part opposite to this, the water outlet is formed at the end of the lower part, and the air vent is formed on the upper side spaced a predetermined distance from the water outlet, and the length of the upper part is longer than the length of the lower bubble generator. It goes without saying that various embodiments included in the technical spirit of fall within the protection scope of the present invention.

100: bubble generator
110: body
100a: upper part
100b: lower
120: pressurized intake member
130: collision cap
140: air vent member
150: exit member

Claims (10)

The upper end is closed, the inside is hollow, the upper and one end vertical to the ground are coupled to the lower end of the upper, the inside is hollow, the other end is open, and the lower and horizontal directions with respect to the ground are circulated formed main body; a pressurized intake member installed on an outer surface of the body so as to communicate with the upper portion at a position spaced a predetermined distance from the upper portion of the body; a collision cap installed on the outer surface of the main body at a position opposite to the pressurized intake member and installed to communicate with the upper part; a water outlet member installed at the other open end of the lower part; A bubble generator comprising an air vent member installed on the upper side of the lower part spaced apart from the water outlet member by a predetermined distance so as to communicate with the lower part from the outer surface of the main body. The method of claim 1,
The bubble generator, characterized in that the length of the upper part of the main body is longer than the length of the lower part. The method of claim 1,
The pressure receiving member is a bubble generator, characterized in that the pressure hole for increasing the pressure of the fluid is formed in the central portion. The method of claim 1,
The collision cap is a bubble generator, characterized in that the collision wall portion is formed in which the fluid that is pressurized and injected collides. The method of claim 4,
A bubble generator, characterized in that a protrusion is formed on the inner surface of the colliding wall so that the colliding fluid is finely crushed. The method of claim 1,
The inside of the upper part of the main body includes an air buffer portion filled with air at an upper portion, a first bubble separator for separating large-sized bubbles and small-sized bubbles at the lower side of the air buffer unit, and the first bubble separator. A bubble generator comprising a separator bubble buffer portion in which the bubbles separated from the small size temporarily gather. The method of claim 6,
The lower part of the main body includes a second bubble separator for separating large-sized bubbles mixed with bubbles from the separator bubble buffer unit and discharging them to the air vent member. The method of claim 1,
The main body is a bubble generator, characterized in that two or more lower parts coupled to the lower end of the upper part. The method of claim 1,
The upper and lower portions of the main body have a cylindrical shape, an elliptical cylindrical shape, a quadrangular cylindrical shape, and a quadrangular or more polygonal shape. The method of claim 1,
The bubble generator, characterized in that the main body has a "b" shape.

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