KR101155133B1 - Compact apparatus generating bubble water - Google Patents

Abstract

The present invention relates to a small bubble water generator, more specifically, it is easy to move to use for various purposes such as skin care, face-washing, oral sterilization, washing at home, etc. by using the bubble water in which the micronized bubbles are dissolved in a high concentration. Possible and miniaturized bubble water generator.

Bubble water generator of the present invention for achieving the above object is a port formed with a handle on one side to follow the water stored therein; A cylindrical housing coupled to the lower portion of the port; A bubble water generating unit installed inside the housing to suck water stored in the port to circulate to the port and to generate bubbles in the water sucked in the circulation process; It is installed in the housing and an operation unit for operating the bubble water generating unit; characterized in that it comprises a.

Bubble, bubble water, bubble, washing, beauty, sterilization

Description

Compact apparatus generating bubble water

The present invention relates to a small bubble water generator, more specifically, it is easy to move to use for various purposes such as skin care, face-washing, oral sterilization, washing at home, etc. by using the bubble water in which the micronized bubbles are dissolved in a high concentration. Possible and miniaturized bubble water generator.

Bubbles, which are fine air bubble particles, have been used for various purposes. For example, in the case of a washing machine, bubbles are used in a washing tank to improve washing power. In addition, bubbles are used in processes such as cleaning, etching, and stripping in manufacturing processes of semiconductors or liquid crystal displays.

In particular, bubbles are widely used in cleaning processes. For example, bubbles are used to generate bubbles using ultrasonic waves, to clean the surface of the semiconductor wafer through the generated bubbles, or to remove suspended matters remaining after the coating process on the metal.

In recent years, the use of fine bubbles has been diversified by using it in a cleansing device, various bath apparatuses, and a sterilizing apparatus. In general, a foam bath used to generate bubbles in a bathtub is a bath method that generates a small bubble by a motor installed in the lower part of the bathtub, and obtains the same effect as a massage by this bubble. Ultrasonic waves generated when bubbles are generated give the skin a stimulation of compression and relaxation, giving a warming effect. Among these, in particular, when the diameter of the bubble is 1 mm or less, it is known to have a therapeutic effect on muscle pain, skin care, traumatic sequelae and the like.

In addition, since bubbles that are broken at the surface of the water adhere to the positive ions in the air, negative air ions increase in the vicinity of the surface of the water. At this time, negative air ions are known to have a calming effect to stabilize the mind and relieve stress.

Many washing apparatuses and various bath apparatuses using bubbles having the above effects are known. In Korea Patent Application No. 1989-0020628, a circulation pump control bubble generation bath by an inverter has been proposed. The bubble generating bath disclosed above is composed of a bath body, a circulation pump, a hot water circulation passage, a jet nozzle, an intake port, an inverter, and an insulation device. Bath tub body is a bath vessel containing the bath water, the circulation pump is mounted to the outside of the tub body is driven by a power-operated motor. In addition, the hot water circulation passage is composed of a hot water forced supply passage and a hot water suction passage disposed between the tub body and the circulation pump and having at least one end opening to the tub body.

However, since the bubble generating device generates bubbles by the circulation pump, the bubble is large and the effect is insignificant, and thus, the cleaning effect, the skin treatment and the cosmetic effect by the bubble are difficult to expect.

In addition to the bubble generator, Korean Patent Registration No. 0905916 discloses a multi-purpose microbubble massage bath device, and Utility Model Registration No. 0380615 discloses a bubble half-body bath system. In addition, Japanese Patent Application Laid-Open No. 2008-0011878 discloses various techniques such as a head massage device and a driving control method thereof.

However, the conventional techniques disclosed above are all fixedly installed in one place, so there is a problem in that they cannot be used except for a specific purpose.

The present invention has been created to improve the above problems, it is possible to move the bubble water dissolved in a high concentration of micronized bubbles are generated inside the miniaturized port, such as skin care, facial cleansing, oral disinfection, washing, etc. at home The purpose is to provide a bubble water generator that can be used easily.

Bubble water generator of the present invention for achieving the above object is a port formed with a handle on one side to follow the water stored therein; A cylindrical housing coupled to the lower portion of the port; A bubble water generating unit installed inside the housing to suck water stored in the port to circulate to the port and to generate bubbles in the water sucked in the circulation process; It is installed in the housing and an operation unit for operating the bubble water generating unit; characterized in that it comprises a.

Further comprising a lid coupled to the opening and closing of the upper portion, the upper side of the port is characterized in that the guide portion for guiding the discharge of water when following the water stored in the port.

The bubble water generating unit is connected to the inside of the port and the first connection pipe to suck the water stored in the port to discharge to the second connection pipe, and the water flow path is installed in the first connection pipe formed inside The gas-liquid mixing portion that passes through, the air inlet tube is installed in the gas-liquid mixing portion so as to communicate with the flow path, and is connected to the second connecting tube and separated from the bubble water discharged from the second connecting tube It is characterized in that it comprises a gas-liquid separator for discharging the air to the outside, and the injection unit is connected to the gas-liquid separator and the third connecting tube to finely crush the bubble water and to spray into the port.

The injection unit has a flow passage communicating with the third connecting tube therein and the end is closed, the nozzle is injected through a plurality of injection holes formed in the side after the bubble water entering the flow path hit the end, and the nozzle It is characterized in that it is provided so as to be spaced apart from the side of the nozzle and the impingement sprayed from the injection hole is impinged on the inner surface and discharged to the outlet.

The bubble water generating unit is further provided with a vortex portion which is installed on the second connecting tube to generate vortex in the bubble water generated by the pump, the vortex portion is a tubular body formed therein a flow path communicating with the second connecting tube And a spiral protrusion formed from one end to the other end of the inner circumferential surface of the tube.

As described above, according to the present invention, according to the present invention, the bubble water generated inside the pot with the handle can be conveniently used for various purposes such as skin care, face wash, oral disinfection, and washing according to a cup, a wash basin, and a sink. It can be usefully used.

In addition, the present invention can be usefully used in the food, medical field requiring safety.

Hereinafter, a small bubble water generator according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail.

1 is a perspective view showing a bubble water generator according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing the interior of Figure 1, Figure 3 is a cutaway perspective view showing a gas-liquid mixing unit applied to the bubble water generator of Figure 1, 4 is an exploded perspective view illustrating an injection unit applied to the bubble water generator of FIG. 1, and FIG. 5 is a cross-sectional view of FIG. 4.

1 to 5, the bubble water generator 3 according to an embodiment of the present invention includes a port 10, a housing 20, a bubble water generating unit, and an operation unit 70.

The port 10 has a storage space in which an upper portion thereof is opened and a predetermined amount of water may be stored therein. Although the port 10 is illustrated as being formed in a cylindrical shape, the structure having a storage space therein may be formed in various shapes such as a rectangle and a triangle. Metal, resin, or the like can be used as the material of the pot 10. Preferably, a transparent material is used so that the inside can be seen. When the material of the port 10 is formed of an opaque material, a light-transmitting window that can look inside may be formed on one side of the port 10.

A handle 11 is formed at one side of the port 10 so as to pour water stored in the port 10 into a cup or a bowl. The handle 11 may have various structures known in the art. And the opposite side of the handle 11 is formed with a guide 13 for guiding the discharge of water when pouring the water stored in the port 10. The guide portion 13 is formed to protrude sharply outward from the upper end of the port 10. The inside of the guide portion 13 is formed with a recessed groove so that water can be easily discharged. The guide 13 may have a structure of a conventional spout formed in the kettle, unlike the illustrated.

The lid 15 is coupled to the opened upper portion of the port 10. Under the edge of the lid 15 is formed a jaw 16 protruding downward. A mounting groove is formed inside the upper end of the port 10 corresponding thereto. In the center of the lid 15 is formed a gripping portion 17 protruding to hold the lid. The lid 15 is preferably made of a transparent material. In the illustrated example, the lid 15 has a structure in which the jaw 16 is fitted to the upper portion of the port 10 to be coupled to the port 10, and is detachably coupled to the port 10.

Unlike this, as shown in FIG. 8, the lid 110 may be hinged to the port 100. Referring to FIG. 8, the lid 110 coupled to the upper portion of the port 100 is hinged to the port 100. To this end, a hinge coupling part 115 is formed at one side of the lid 110, and a coupling groove 123 is formed at one side of the handle 120 so as to be coupled to the hinge coupling part 115, and the handle 120. And hinge coupling portion 115 has a structure that is coupled by the fixing pin 117. In the present invention, the lid may be omitted. In addition, the upper portion of the port may be a closed structure. In this case, an inlet for injecting water into the port may be formed.

Again, referring to FIGS. 1 to 5, the housing 20 is coupled to the lower portion of the port 10. The housing 20 is formed in a cylindrical shape with an open top. The port 10 and the housing 20 may be combined or integrally formed to be separated from each other. An empty space is formed inside the housing 20 so that the bubble water generating unit can be installed.

An air hole 21 is formed at a side of the housing 20 so that air can flow between the inside and the outside of the housing 20. A plurality of air holes 21 are formed along the circumference of the housing 20 at regular intervals. And the other side of the housing 20 is formed with the insertion hole is inserted into the wire 23 is connected to the external power source.

The bubble water generating unit is installed inside the housing 20 to suck some of the water stored in the port 10 to generate bubbles, and then introduce the bubble into the port 10 again. That is, the bubble water generating unit generates bubbles in the water in the water circulation process. Therefore, the inside of the port 10 and the bubble water generating unit are interconnected. When the power is supplied by the bubble water generating unit, the fine water bubbles are filled in the port 10.

In the illustrated example, the bubble water generating unit includes a pump 27, a gas-liquid mixing unit 30, an air inlet pipe 67, a gas-liquid separator 90, and an injection unit 80.

The pump 27 and the port 10 are connected by the first connecting pipe 5. The first connection pipe 5 is connected to the outlet port (not shown) formed at one side of the bottom of the port 10 so as to be detachable. Preferably, the first connecting tube 5 is formed of a flexible tube. In addition, the first connecting pipe 5 is formed longer than the distance between the pump 27 and the outlet. This is to facilitate the separation of the port 10 from the housing 20.

The first connecting pipe 5 connected to the outlet is connected to the inlet of the pump 27 for pressurizing and transferring water. The first connection pipe 5 is provided with a first automatic valve 6 for opening and closing the flow path of the first connection pipe (5). The gas-liquid mixing part 30 is installed in the middle of the first connecting pipe 5. Both ends of the gas-liquid mixing portion 30 is formed with a screw thread so as to be connected to the first connecting pipe (15). The gas-liquid mixing part 30 is formed in a cylindrical shape, and a flow path through which water flows is formed therein. Preferably, the flow path includes an introduction flow passage 31, a throttle flow passage 33, and a turbulence chamber 35 sequentially formed along the water flow direction. The introduction passage 31 is formed at the front end of the gas-liquid mixing portion 30 to extend a predetermined length. The introduction passage 31 is connected to the first connecting pipe 5 so that water flows in at a constant speed. The introduction passage 31 has the same diameter as the inner diameter of the first connecting pipe 5. The throttle passage 33 extends from the introduction passage 31 and is formed to have a smaller cross-sectional area than the introduction passage 31. The turbulence chamber 35 extends from the throttle passage 33 and has a larger diameter than the throttle passage 33.

The air inlet pipe 67 is installed in the gas-liquid mixing part 30 so as to communicate with the throttle passage 33. The air inflow pipe 67 is supported by the socket 69 provided through the wall of the gas-liquid mixing part 30. One end of the air inlet pipe 67 is exposed to the atmosphere so that air in the atmosphere is introduced. Preferably the upper height of the air inlet pipe is formed higher than the height of the first valve. The air inlet pipe 67 may be provided with a valve for opening and closing the passage of the air inlet pipe (67).

The lower portion of the pump 27 is provided with a dustproof rubber 28 that can absorb vibration. The pump is then electrically connected to a conventional electric inverter 25. When the pump 27 operates to suck water through the first connecting pipe 5, the water flows into the gas-liquid mixing unit 30, and at this time, the water flowing at a constant speed along the introduction passage 31 passes through the throttle passage ( When passing through 33), the flow velocity is faster and the pressure is lower. Therefore, the gas is strongly sucked into the throttle passage 33 through the air inlet pipe 67 and mixed with water. Bubbles are generated during the mixing of water and gas. After passing through the turbulence chamber 35, the flow rate is slowed down and the pressure is increased, so that more gas is dissolved in water. In addition, the water introduced into the turbulence chamber 35 is a turbulence is formed and the water and the gas continuously contact to improve the dissolution efficiency of the gas.

Bubble water flowing out of the pump 27 through the second connecting pipe 7 is introduced into the gas-liquid separator 90. The gas discharge valve 95 is installed at the upper end of the gas-liquid separator 90. Bubbles separated from the water in the bubble water introduced into the gas-liquid separator 90 by the operation of the gas discharge valve 95 are discharged into the atmosphere.

The third connecting pipe 9 connected to the lower portion of the gas-liquid separator 90 extends into the port 10 through a through hole (not shown) formed at the bottom of the port 10. In the middle of the third connecting pipe (9) is provided a second automatic valve (8) for opening and closing the flow path of the third connecting pipe (9). An end portion of the third connecting pipe 9 extending into the port 10 is connected to the injection unit 80.

The injection unit 80 includes a nozzle 81 and a collision cover 87. The nozzle 81 has a flow passage communicating with the third connecting pipe 9 therein, and the lower end thereof is closed. An insertion portion 83 is inserted into the third connecting pipe 9 at the nozzle. Although not shown in the insert portion 83 is inserted into the third connecting pipe (9) by mounting the clamp on the outside of the third connecting pipe (9). Threads are formed on the outer circumferential surface of the nozzle 81. In addition, a plurality of injection holes 85 are formed below the nozzle 81. The injection hole 85 is formed radially with respect to the center of the nozzle 81. The size and number of injection holes 85 may be appropriately adjusted according to the amount of bubble water flowing into the nozzle 81. However, when the injection hole 85 is too large, since the spraying effect of the bubble water is lowered, the diameter of the injection hole 85 is preferably maintained at about 1.5 to 0.5 mm.

The collision cover 87 accommodates the nozzle 81 therein but is spaced apart from the side surface of the nozzle 81. On the inner circumferential surface of the upper side of the collision cover 87, a thread is formed to engage with the thread formed in the nozzle 81. The collision cover 87 is formed in a cylindrical shape, and the lower portion thereof is open. The collision cover 87 is fixed inside the port 10.

Bubble water entering the nozzle 81 is injected into the side direction through a plurality of injection holes 85 formed on the side after colliding with the closed end of the nozzle (81). The bubble water injected in the lateral direction through the injection hole 85 again collides with the inner surface of the collision cover 87, and the bubbles are finely crushed. The fine bubble water generated in this way is discharged into the inside of the port 10.

On the other hand, the bubble water generating unit according to another embodiment of the present invention is a vortex portion for generating a vortex in the bubble water discharged from the outlet side of the pump 27, and a pulverized portion for pulverizing the bubble water flowed out from the vortex portion more finely It is further provided.

The vortex part 40 shown in FIG. 6 is coupled to the rear end of the gas-liquid mixing part, and the pulverization part is coupled to the rear end of the vortex part 40. The vortex portion 40 includes a tubular body 45 formed therein with a flow passage 41 communicating with the second connecting tube 7, and a spiral protrusion 43 formed from one end to the other end of the inner circumferential surface of the tubular body 45. do. A thread is formed at the front end of the tubular body 45 and a flange 49 is formed at the rear end. A spiral flow path 41 is formed inside the vortex portion 40 by the protrusion 43. The spiral flow passage 41 may be formed in various structures. As shown, the projections 43 formed on the inner circumferential surface of the vortex portion 40 are spirally formed from the front end of the vortex portion 40 to the rear end of the vortex portion 40. The bubble water flowing from the gas-liquid mixing part 30 moves while forming the vortex along the spiral direction while passing through the vortex part 40. This vortex flow increases the contact area between the gas and water and extends the residence time, thereby dissolving some of the undissolved gases in water, thereby increasing the overall dissolution efficiency.

The flange 59 formed at the front end of the crushing part 50 shown in FIG. 7 is connected to the flange 49 formed at the rear end of the vortex part 40 shown in FIG. The crushing unit 50 includes a conical first case 51 and a cylindrical second case 61. The first case 51 has a conical inner space in which the inner diameter gradually increases along the direction in which the bubble water flows. The second case 61 is formed at the rear end of the first case 51. The second case 61 has a cylindrical inner space having an inner diameter larger than the inner diameter of the rear end of the first case 51. The collider 52 is installed inside the first case 51. The collision body 52 is arrange | positioned in the internal space of the 1st case 51 by the support rod 57 in which the one end was fixed to the 2nd case 61. As shown in FIG. The collider 52 has the same conical shape as the inner space of the first case 51, but has an outer diameter smaller than that of the first case 51. The outer circumferential surface of the collider 52 is installed to be spaced apart from the inner circumferential surface of the first case 51 by a predetermined distance. And the front end of the collision body 52 is formed with a collision surface 53 formed perpendicular to the longitudinal direction of the vortex portion. On the outer circumferential surface of the collider 52 is provided a spiral forming wing 55 formed in a spiral. Vortex forming blades 55 are formed in two or more.

The bubble water flowing out from the vortex portion 40 collides with the collision surface 53 of the collider 52 and is pulverized finely. The collided bubble water is scattered around the collider 52 and travels in the direction of the second case 61 along the space between the inner circumferential surface of the second lower case 51 and the outer circumferential surface of the collider 52. At this time, the bubble water forms a vortex flow that orbits the collider 52 by the vortex guide vane 55. The number of bubbles accelerates as the turning radius gradually increases as it moves toward the second case 61 due to the shape of the conical collider 52, and the number of bubbles passing through the collider 52 in this state is the second case 61. Flows into).

A plurality of protrusions 65 are formed on the inner circumferential surface of the second case 61 at regular intervals as shown. The bubble water introduced into the second case 61 is rotated by inertia along the inner circumferential surface of the second case 61 in an accelerated state, and in the process, the bubble water continuously collides with the plurality of protrusions 65. While being ground, finer microbubbles are generated. Bubble water is discharged through the second connecting pipe (7) connected to the outlet formed in the rear end of the second case 61 and is injected through the injection through the gas-liquid separator.

An operation unit 70 for operating the bubble water generating unit is installed outside the housing 20. The operation unit 70 includes a button 71 for turning on / off the pump 27 and a lamp 75 for indicating an on / off state of the pump 27. Of course, although not shown, a conventional controller for controlling the pump 27 and the first and second automatic valves 6 and 8 by the setting of the operation unit 70 is installed inside the housing 20.

The bubble water stored inside the pot by the above-mentioned bubble water generating unit is used for various purposes such as skin care, face wash, oral disinfection, and washing. For example, it can be used for oral sterilization by holding a handle of a pot and pouring a bubble into a cup and then keeping it in the mouth. In addition, depending on the number of bubbles in the wash basin can be used for washing, depending on the sink can be used for washing fruit or dish.

On the other hand, in addition to the above-mentioned bubble water generating unit, it is a matter of course that the conventional bubble water generating device that can generate a fine bubble in the water stored in the port can be applied.

As described above, the present invention has been described with reference to one embodiment shown in the drawings, which is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments are possible. .

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

1 is a perspective view showing a bubble water generator according to an embodiment of the present invention,

2 is a cross-sectional view showing the interior of FIG. 1,

3 is a cutaway perspective view showing a gas-liquid mixing unit applied to the bubble water generator of FIG.

4 is an exploded perspective view illustrating an injection unit applied to the bubble water generator of FIG. 1;

5 is a cross-sectional view of FIG. 4,

6 and 7 are cutaway perspective views showing a vortex portion and a pulverization portion applied to the bubble water generator according to another embodiment of the present invention,

8 is a perspective view illustrating a bubble water generator according to still another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: water supply tank 15: first connector

20: gas inlet pipe 25: second connection pipe

30: gas-liquid mixing part 40: vortex part

80: injection unit 90: gas-liquid separator

100: bubble water storage tank

Claims (5)

A port formed with a handle at one side to pour water stored therein; A cylindrical housing coupled to the lower portion of the port; A bubble water generating unit installed inside the housing to suck water stored in the port to circulate to the port and to generate bubbles in the water sucked in the circulation process; A control unit installed in the housing and for operating the bubble water generating unit; The bubble water generating unit is connected to the inside of the port and the first connection pipe to suck the water stored in the port to discharge to the second connection pipe, and the water flow path is installed in the first connection pipe formed inside The gas-liquid mixing portion that passes through, the air inlet tube is installed in the gas-liquid mixing portion so as to communicate with the flow path, and is connected to the second connecting tube and separated from the bubble water discharged from the second connecting tube And a gas-liquid separator for discharging air to the outside, and an injection unit connected to the gas-liquid separator and a third connecting pipe to pulverize the bubble water to be injected into the port. According to claim 1, further comprising a lid coupled to open and close at the top of the port, Small bubble water generator, characterized in that the guide portion for guiding the discharge of water when following the water stored in the port on one side of the port. delete According to claim 1, wherein the injection portion is formed in the flow path communicating with the third connecting pipe therein and the end is closed so that the air bubbles entering the flow path is injected through a plurality of injection holes formed on the side after hitting the end A small bubble water generator, the nozzle being accommodated therein and spaced apart from the side surface of the nozzle, and having a collision cover which bubbles discharged from the injection hole impinge on an inner surface and are discharged to an outlet; . According to claim 1, The bubble water generating unit is provided on the second connecting pipe further comprises a vortex portion for generating a vortex in the bubble water generated in the pump, The vortex part includes a tubular body having a flow passage communicating with the second connecting tube therein, and a spiral projection formed from one end to the other end of the inner circumferential surface of the tubular body.

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