KR100737435B1 - Micro Bubble Generator - Google Patents

Abstract

The present invention relates to a bath bubble microbubble generating device for generating ultra-fine bubbles by sucking the outside air in the form of a pulse wave by the negative pressure of the vacuum chamber opened and closed by the air supply valve and mixed with the bath water.

The micro-bubble generating device of the present invention is connected to the inlet pipe 111 to supply the water (W) of the water supply source 110, such as a bathtub to the pressure tank 107, between the water supply source 110 and the pressure tank 107 A pump 103 mounted to it; An air supply pipe 105 connected between the water supply valve 114 of the water supply pipe 111 and the pump 103 to supply external air to the water supply pipe 111; A pressure tank 107 connected to the connection pipe 112 and mounted between the pump 103 and the water supply source 110 to temporarily store the mixed water in the outside air; And a first spray nozzle 109 mounted at the end of the water discharge pipe 113 drawn out from the pressure tank 107 to inject the mixed air discharged from the pressure tank 107 to the water supply source 110. The air supply pipe 105 is equipped with a first vacuum chamber 117 which is opened and closed by the air supply valve 115 and sucks outside air in the form of a pulse wave by the negative pressure generated by the pump 103. The microbubble generating device of the present invention is not only easy to install and handle management, but also provides various bathing effects by the microbubbles.

Fine, ultrafine, bubble, outbreak, bathtub

Description

Fine bubble generating apparatus

1 is a perspective view showing a conventional micro bubble generator.

2 is a block diagram of a microbubble generating device according to a first embodiment of the present invention.

3 is a perspective view of removing the upper case in the microbubble generating device shown in FIG.

4 is a front sectional view of the first vacuum chamber shown in FIGS. 2 and 3;

FIG. 5 is a cross-sectional view of the first spray nozzle shown in FIGS. 2 and 3.

6 is a longitudinal sectional view of the pressure sensor shown in FIGS. 2 and 3;

FIG. 7 is a perspective view illustrating a first line storage unit having a serpentine shape by removing an upper case in a microbubble generating device according to a second embodiment of the present invention. FIG.

FIG. 8 is a perspective view of the water outlet valve instead of the second check valve of the water outlet pipe shown in FIG. 7.

FIG. 9 is a bottom view of a second line-shaped storage unit having a coil shape for a microbubble generator according to a third embodiment of the present invention; FIG.

FIG. 10 is a perspective view illustrating a third line type storage part having a bobbin shape for a microbubble generating device according to a fourth embodiment of the present invention; FIG.

11 is a perspective view showing a fourth doll storage unit of the hose shape for a micro-bubble generating device according to a fifth embodiment of the present invention.

12 is a perspective view showing an exploded state of the second vacuum chamber shown in FIG.

13 is a perspective view showing a second injection nozzle and the disassembled state of the present invention.

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

100: first embodiment 103: pump

105: supply pipe 107: pressure tank

109: first spray nozzle 110: water source

111: inlet pipe 112: connector

113: outlet pipe 114: inlet valve

115: air supply valve 117: first vacuum chamber

119 cylindrical body 121 vacuum bag

127: drive motor 128: male parallel

129: bleeder 130: electronic control unit

190: second injection nozzle 200: second embodiment

210: first line storage unit 300: third embodiment

310: second line storage 400: fourth embodiment

410: third line storage unit 500: fifth embodiment

510: fourth line type storage unit 570: second vacuum chamber

The present invention relates to a micro-bubble generating device, and more specifically, to generate ultra-fine bubbles by sucking the outside air in the form of a pulse wave from the air supply valve and mixing with the bath water by the negative pressure of the vacuum chamber opened and closed by the air supply valve. The present invention relates to a microbubble generator for bath water.

A foam bath used to generate bubbles in the bath water generally generates a small bubble with a motor in the lower part of the bath, and is a bath method to obtain the same effect as a massage by the bubble. Ultrasonic waves generated when bubbles are generated Compresses and relaxes the skin, giving it a warming effect.

Among them, especially when the diameter of the bubble is less than 1mm is called an ultrasonic bath, which is known to have a therapeutic effect on muscle pain, skin care, trauma aftereffects.

In addition, as the fine bubbles broken at the surface of the water adhere to the cations in the air and cause air ionization, relatively negative ions increase in the vicinity of the surface of the water.

These negative ions have a calming effect, which is known to have an effect of calming the mind and relieving stress.

The bubble generator used in such a foam bath has been proposed as a "circulation pump control bubble generation bath by an inverter" of Korean Patent Application No. 1989-0020628.

As shown in FIG. 1, the bubble generating bath includes a tub body (A), a circulation pump (P), a warm water circulation passage (D), a jet nozzle (2, 3), an inlet (5), an inverter, and an insulation device. Consists of

Here, the tub body (A) is a tub container containing the bath water, the circulation pump (P) is mounted to the outside of the tub body (A) is driven by a power operated motor.

In addition, the hot water circulation passage (D) is disposed between the tub body (A) and the circulation pump (P) and the hot water forced supply passage and the hot water suction passage having at least one end opening to the tub body (A). consist of.

In addition, at least one jet nozzle (2, 3) is attached to the end of the hot water forcing supply passage, the intake port (5) from the jet nozzle (2, 3) to the tub body (A) It is connected to the said hot water forced supply passage so that bubble generation hot water may be ejected.

In addition, the inverter is disposed between the power operation motor and the power supply of the circulation pump (P) to easily and smoothly change the rotation speed of the power operation motor by the frequency modulation to control the operation of the circulation pump to eject the amount of hot water And the blowout pressure can be adjusted in several different modes.

Finally, the insulating device serves to prevent the current generated by the inverter is transferred to the hot water of the bath body (A).

However, since the bubble generating device of the conventional bubble generating bath as described above ejects the bubble generating hot water by the ejection nozzles (2, 3), it is possible to obtain only the massage effect by bubbles as in the general bubble generating device, and other special effects. It is hard to expect.

In addition, as shown in FIG. 1, since the size of the entire apparatus is large and the structure is complicated, management such as construction and maintenance has been difficult.

The present invention has been proposed to solve the problems of the conventional bubble generator as described above, the entire component, such as a pressure tank, a pump, a drive motor for pump operation to temporarily receive the bath water generated microbubbles Miniaturization and simplification facilitate the installation, handling, and management of the entire device, while opening and closing the intake port through which the outside air is introduced by the air supply valve, allowing the outside air to flow in the form of a pulse wave, and then mixing the bath water. The present invention aims to provide a microbubble generating device that diversifies the functionality of the bath water by generating ultra-bubbles in water.

In addition, another object of the present invention is to provide a microbubble generating device of a lightweight and miniaturized coupling structure.

Therefore, the present invention, to achieve the above objects, the pump is connected to the inlet pipe to supply the water of the water supply to the pressure tank and mounted between the water supply and the pressure tank; A supply pipe connected between the inlet valve of the inlet pipe and the pump to supply outside air to the inlet pipe; A pressure tank connected to the connection pipe and temporarily installed between the pump and the water supply source to temporarily store the mixed air air; And a first injection nozzle mounted at an end of the water discharge pipe drawn out from the pressure tank and spraying the outdoor mixed water discharged from the pressure tank to a water supply source, wherein the air supply pipe includes an air supply valve. It provides a micro-bubble generating device, characterized in that the vacuum chamber is mounted to open and close by suction the outside air in the form of a pulse wave by the negative pressure generated by the pump.

In addition, according to the present invention, the micro-bubble generating device is connected to the inlet pipe to supply the water of the water source to the pressure tank, the pump is mounted between the water source and the line storage having a line-shaped storage structure; A second spray nozzle mounted at an end of the discharge pipe drawn out from the line storage unit and spraying the mixed air discharged from the pressure tank to a water supply source; And a second vacuum chamber connected between the one side and the other side of the air supply pipe connected between the inlet valve of the inlet pipe and the pump to supply the outside air to the inlet pipe, based on the direction of the arrow marked on the outer surface. It provides a micro-bubble generating device.

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

First embodiment

As shown in FIG. 2, the microbubble generating device of the present invention is understood as the first embodiment 100, and will be understood in more detail and clearly by the following description.

The first embodiment 100 is a pump 103 for generating a pumping force for suctioning the water supply and the outside air, and discharge the outside air mixed water, the air supply pipe 105 for supplying the outside air to the inlet pipe 111, the outside air is mixed A pressure tank 107 for temporarily storing the supplied water (eg, outdoor mixed water), and a first spray nozzle 109 for spraying the outdoor mixed water of the pressure tank 107 toward the water supply source 110. . Here, the water supply is made through the inlet pipe 111. The air supply pipe 105 is equipped with an air supply valve 115 and a first vacuum chamber 117 for supplying the outside air in the form of a pulse to the inlet pipe 111.

First, the pump 103 is a general pump such as a centrifugal pump operated by the drive motor 127. The pump 103 serves to absorb water W through an absorption port 145 immersed in water W on one side of the water supply 110; Bubbles are mixed with the sucked water (W) and serves to provide the driving force necessary for spraying through the first spray nozzle 109, which is immersed in the water supply source 110 on the opposite side of the absorber 145 in the form of foam. .

To this end, the pump 103 is mounted on the inlet pipe 111 between the first check valve 151 and the inlet valve 114.

Inlet valve 114 is an electronic on-off valve whose opening and closing is controlled by the electronic control unit 130.

In addition, one end of the air supply pipe 105 is pumped between the inlet valve 114 of the inlet pipe 111 and the pump 103 to supply external air to the inlet pipe 111 by the pumping force of the pump 103. It is connected adjacent to 103, and the other end of the air supply pipe 105 is open to the outside air.

The air supply pipe 105 is equipped with a first vacuum chamber 117 in which negative pressure is generated by the pumping force of the pump 103.

The lower end of the first vacuum chamber 117 is connected to the air supply pipe 105. The upper end of the first vacuum chamber 117 is coupled to the air supply valve 115. The air supply valve 115 is a means for controlling the interconnection and the short circuit between the first vacuum chamber 117 and the outside air.

As shown in FIG. 4, the first vacuum chamber 117 has a cylindrical body 119 mounted between the air supply pipe 105 and the air supply valve 115, and coaxially with the outer side of the cylindrical body 119. It has a vacuum bag 121 having a hollow inner space mounted thereon.

One side wall of the cylindrical body 119 has a through hole 125 formed therein, and the through hole 125 is equipped with a vacuum valve 123 for opening and closing the through hole 125 according to the pressure in the cylindrical body 119. It is.

The vacuum valve 123 is a compression spring 147 is attached to the end of the stem (stem) extending into the vacuum bag 121 is to open and close the through hole 125 in accordance with the internal pressure of the cylindrical body 119. .

As shown in FIGS. 2 to 4, the air supply valve 115 is an electronic on / off valve capable of high speed operation controlled by the electronic controller 130, and is disposed on the upper end of the cylindrical body 119 of the first vacuum chamber 117. Screwed together.

Preferably, the air supply valve 115 may be a solenoid valve capable of opening and closing at a high speed. The air supply valve 115 opens and closes the first vacuum chamber 117 at high speed to suck outside air in the form of a pulse wave in the cylindrical body 119 subjected to the negative pressure by the suction force of the pump 103.

As shown in Fig. 3, the pressure tank 107 has a water supply downstream of the pump 103 so as to temporarily store the outdoor air mixed water corresponding to the feed water in which the external air in the form of a pulse wave is mixed from the air supply pipe 105 as described above. It is coupled to the end of the connector 112 drawn out from the parallel unit 128. The connecting pipe 112 is connected between the male parallel unit 128 and the pressure tank 107.

The pressure tank 107 is a container having an appropriate volume or more so as to accommodate the outdoor air mixed water pumped by the pump 103.

The pressure tank 107 is equipped with a bleeder 129 (bleeder) at its upper end. As can be seen from FIG. 2, the bleeder 129 is a kind of relief valve that opens only when the pressure inside the pressure tank 107 is higher than or equal to a predetermined value. This bleeder 129 serves to maintain the internal pressure of the pressure tank 107 below a predetermined value.

The pressure sensor 149 is installed at a mounting position capable of measuring the internal pressure of the pressure tank 107, for example, at the other side of the place where the bleeder 129 is mounted.

The pressure sensor 149 transmits the measured pressure value to the electronic controller 130 to maintain the internal pressure of the pressure tank 107 at an appropriate value according to the control of the electronic controller 130.

On the other hand, the first spray nozzle 109 is attached to the end of the water discharge pipe 113. The first spray nozzle 109 serves to spray the outdoor mixed water extruded from the pressure tank 107 through the water discharge pipe 113 to the bath water to cause foaming, such as the water supply source 110.

As shown in FIG. 5, the first spray nozzle 109 has a multilayer structure in which a plurality of permeable membranes are mounted therein.

The first spray nozzle 109 is a mesh filter 33, a nozzle plate 35, a filtration filter 37, and a filtration cap that are sequentially stacked in the inner case 31 having a funnel form consisting of two or three stages. 39, and an intermediate cap 40.

Here, the outer case 31 can be disassembled and assembled into three stages, for example, the outer cap 31-1, the inner cap 31-2, and the cone cap 31-3, as shown. The mesh filter 33, the nozzle plate 35, the filtration filter 37, the filtration cap 39, and the intermediate cap 40 are sequentially stacked and mounted therein.

Inside the inner cap 31-2, the mesh filter 33, the nozzle plate 35, the filtration filter 37, and the filtration cap 39 are sequentially inserted into and fixed to the intermediate cap 40 to be detachably screwed together. The inner end of the intermediate cap 40 is closed by the valve cover 42.

The intermediate cap 40 has a plurality of through-holes 44 formed at equal intervals on the top of the side wall to spray the outside air mixed water discharged from the filtration cap 39 to the outside through the outer cap 31-1.

In addition, the mesh filter 33 fitted to the innermost of the outer case 31 is in contact with the valve cover 42 in a state of being fitted to the intermediate cap 40, the outer case 31 through the water outlet pipe 113. The outdoor mixed water flowing into) is crushed by a small mesh.

The nozzle plate 35 stacked directly on the mesh filter 33 is a button-shaped disk, which is gently curved so that its center portion is convex outward, and at least two nozzle holes 41 are formed on the same radius of the body. It is penetrated with equal angular spacing.

In addition, the filtration filter 37 mounted on the nozzle plate 35, that is, outside the nozzle plate 35, blows out through the nozzle hole 41 of the nozzle plate 35 in the same manner as the mesh filter 33. It serves to crush the mixed water through fine pores inside again.

In addition, the filtration cap 39 in close contact with the outside of the filtration filter 37 has at least two or more openings 43 penetrating through the top of the hemispherical cylinder.

As shown in FIG. 2, the electronic controller 130 is electrically connected to the inlet valve 114, the air supply valve 115, the drive motor 127, the pressure sensor 149, and the temperature sensor 150. .

The electronic controller 130 has a microcomputer and various circuit configurations mounted on a circuit board inside the casing, and controls the operation and stop of the driving motor 127 and sets the inlet valve 114 and the air supply valve 115 for a predetermined time. While opening and closing at intervals, the internal pressure and temperature of the pressure tank 107 sensed by each of the pressure sensor 149 and the temperature sensor 150 are checked, and the drive motor corresponds to the line pressure of the outlet pipe 113. The operation of 127 and the valve opening and closing operation are controlled.

In addition, a water balancer 128 may be installed between the pump 103 and the pressure tank 7. The first check valve 151 may be disposed at an adjacent position upstream of the water parallelizer 128. By installing, the water parallelizer 128 can be supplied with a predetermined amount or more even when the operation of the microbubble generating device according to the first embodiment 100 is stopped, so that the microbubble generating device can be operated again when the microbubble generating device is restarted. By using the water supply stored in 128, bubble generation by the pump 103 can be executed without delay.

On the other hand, as described above, the pressure sensor 149 is mounted on the pressure tank 107 top to sense the internal pressure of the pressure tank 107.

As shown in FIG. 6, the pressure sensor 149 is largely composed of upper and lower cases 61 and 62, an elastic membrane 63, a pressure pin 65, a hydraulic pin 67, and an on / off switch 69. It is.

Here, the upper and lower cases 61 and 62 form an outer body of the pressure sensor 149 and are coupled to be opened and closed at an intermediate portion. In the upper case 61, the electrode terminal 85 connected to the on / off switch 69 on the upper surface of the upper case 61 protrudes at intervals of 120 degrees, and a spring hole 81 protrudes from the center thereof. The lower case 62 has a through hole 73 protruding from the bottom of the lower surface toward the pressure tank.

In addition, the elastic membrane 63 fitted inside the through-hole 73 of the lower case 62 is forcibly fitted to the inner wall surface of the lower case 62 to maintain the airtightness of the through-hole 73 with a cylindrical rubber membrane. A pleat band 87 is formed on the upper surface to expand and contract up and down according to the pressure P of the pressure tank acting through the 73, and the projection 89 for fitting the pressing pin 65 to the central portion of the upper surface is provided. It protrudes.

The pressing pin 65 inserted into the projection 89 on the upper surface of the elastic membrane 63 is a hollow rod having a pointed end, and is provided by the lower case 62 through a fixing plate 91 coupled to the lower case 62 by a screw 93. Bar) to secure a space capable of moving up and down by the depth of the recess formed in the center of the bottom of the fixing plate (91).

The hydraulic pin 67 is inserted into the spring hole 81 so as to protrude toward the center of the bottom surface of the upper case 61 so as to be movable up and down, the pressure pin 65 of the pressure pin 65 when the pressure pin 65 is raised. When the pressing force by the pressing pin 65 is released, the upper side is brought into contact with the distal end and lowered to the original position by the reaction force of the rebound spring 79. In addition, the hydraulic pin 67 adjusts the reaction force against the pressure pin 65 by elevating the adjustment screw 83 screwed to the upper end of the spring hole 81 of the upper case 61 to press the rebound spring (79). It is supposed to be.

Finally, the switch 69, which is turned on and off according to the upward and downward movement of the pressing pin 65, is attached to the bottom of the upper case 61 so that it is pressurized together when the hydraulic pin 67 is pressed to bend upward. The fixed piece 76 attached to the piece 75 and the movable piece 75 of the upper case 61 so that the contact 77 with the movable piece 75 falls when the movable piece 75 is bent. ) At this time, the movable piece 75 and the fixed piece 76 are electrically connected to the electrode terminal 85, respectively.

Referring to the operation of the first embodiment 100 according to the present invention configured as described above are as follows.

The microbubble generating device understood as the first embodiment 100 of the present invention operates in a power-on state.

In this case, the electronic controller 130 operates the drive motor 127 to drive the pump 103, and at the same time, opens the inlet valve 114.

Accordingly, the bath water or water (W) contained in the water supply source 110 is pumped by the pumping force of the pump 103 to absorb the inlet 145, the inlet pipe 111, the inlet valve 114, the inside of the pump 103 The flow path, the first check valve 151 and the male parallel to the flow through the connection pipe 112 (128).

In particular, when passing through the inlet pipe 111 and the inlet valve 114, the water (W) passes through the air supply pipe 105, at this time is mixed with the outside air introduced from the air supply pipe 105.

To this end, the electronic control unit 130 opens the air supply valve 115 to allow the outside air to be sucked into the first vacuum chamber 117. The air supply valve 115 repeats opening and closing at a high speed to thereby open the pump 103. By allowing the outside air to intermittently flow into the cylindrical body 119 of the first vacuum chamber 117 in a vacuum negative pressure state.

At this time, when the pumping force of the pump 103 is increased or the pumping interval is shortened so that excessive negative pressure is applied to the inside of the cylindrical body 119, the suction force acting on the vacuum valve 123 is increased by this negative pressure.

Accordingly, the vacuum valve 123 overcomes the repulsive force of the compression spring 147 and moves into the cylindrical body 119 to open the through hole 125, and the first vacuum chamber 117 has a cylindrical body 119 as well. In addition, the inside of the vacuum bag 121 is also in a vacuum state.

On the contrary, when the operation of the pump 103 is momentarily stopped, or the pumping interval or the pumping force is low, a large amount in the cylindrical body 119 of the first vacuum chamber 117 by the continuous opening of the air supply valve 115. The outside air may be introduced into the vacuum negative pressure inside the relatively small cylindrical body 119 may be lost.

However, since the outside air introduced into the first vacuum chamber 117 is also introduced into the vacuum bag 121 through the through hole 125, the first vacuum chamber 117 may have a margin for maintaining the inside of the first vacuum chamber 117 in a vacuum state. Can be.

Therefore, even if the pumping force of the pump 103 is temporarily lost, since the first vacuum chamber 117 can be maintained in a vacuum state for a considerable time, the intermittent inflow of outside air due to the opening of the air supply valve 115 is continued. You can do it.

In this way, the feed water containing the outside air introduced into the connecting pipe 112 (for example, the mixed air) is temporarily stored in the pressure tank 107 by the pumping force of the pump 103, wherein After the outside air is sufficiently mixed, the pumping force of the pump 103 is transmitted to the first spray nozzle 109 along the outlet pipe 113.

At this time, the overpressure generated in the pressure tank 107 is removed to the outside through the bleeder 129.

Nevertheless, when the inside of the pressure tank 107 is maintained in an overpressure state, the pressure P inside the pressure tank 107 is applied from the through hole 73 in the lower case 62 of the pressure sensor 149.

As a result, the elastic membrane 63 expands to raise the pressing pin 65 fitted to the protrusion 89.

The pressure pin 65 thus raised pushes up the hydraulic pin 67 and simultaneously pushes the movable piece 75 of the switch 69 to short the contact 77. The switch 69 signal generated at this time is a pressure tank. It is transmitted to the electronic controller 130 that an overpressure has occurred at 107, whereby the electronic controller 130 immediately controls the internal pressure of the entire first embodiment 100.

As shown in FIG. 5, the outdoor mixed water reaching the first spray nozzle 109 is crushed finely while passing through the mesh filter 33, and then collides with the nozzle plate 35 to pass through the nozzle hole 41. It collides with the filter 37 at high speed.

The outside air mixed water, which is crushed into ultrafine particles again by the collision with the filter 37, is injected into the intermediate cap 40 through the plurality of openings 43 of the filtration cap 39. Foam is made of bubbles of ultra-fine particles in the water (W) that is sprayed to the water supply source 110 as shown in FIG. 2 through the outer cap (31-1), and is contained in the water supply source (110). Causes

At this time, the filters 33 and 37 are made of a material containing minerals, silver nano materials, and materials selected from any one or a combination of far-infrared radiation materials, and accordingly, antibacterial, deodorizing function and Anion and far infrared radiation function can be expected.

Second embodiment

This embodiment includes a configuration that is the same as or similar to that of the first embodiment except for the first line storage unit 210 having a line-shaped storage structure. Accordingly, throughout the description of the present invention, similar or identical configurations will be used for the sake of understanding.

7 is a perspective view illustrating a serpentine-shaped first line storage unit 210 by removing an upper case from the microbubble generating device according to the second embodiment 200 of the present invention.

As shown in FIG. 7, the first line-type storage 210 of the second embodiment 200 uses all of the water balancer, the connecting pipe, the pressure tank, and the bleeder described in detail in the first embodiment. Even if it is not, it has the characteristic that a problem does not arise in whole operation.

As the first line storage unit 210 stores and flows water in the line-shaped flow path, the first line storage unit 210 solves problems such as an increase in internal pressure by air in an existing pressure tank.

Since the first line-type storage 210 is made of a tubular member 211 bent to have an S-shape as a serpentine shape, it occupies a small installation space.

In particular, the first line storage unit 210 is further installed between the bent pipe member 211, the well-known permanent magnet 220 used to guide the plurality of water magnetization water. Permanent magnet 220 is a conventional installation method (for example, the adhesive method, the fixing using a fixing strip, the intervening method to be inserted between the first line-type storage unit 210 using a separate magnetic bracket, etc.) It is coupled to the first line-type storage unit 210 by. The permanent magnet 220 exerts a magnetic force on the water passing through the inner conduit of the first line-type storage 210 to influence the magnetized water.

Hereinafter, the line-shaped storage structure of the first line-type storage unit 210 will be described in detail.

In the line storage structure according to the present invention, an inlet pipe 111 through which water from a water supply source such as a bathtub is received is connected to an inlet of the inlet valve 114.

The intake valve 114 is an electronic on / off valve, and its opening / closing operation is controlled by the above-described electronic controller.

Water enters the pump 103 through the intake valve 114 and its outlet side pipe 114a.

At this time, the first vacuum chamber 117 of the air supply pipe 105 described above is connected to the pipe 114a to mix the outside air with water. That is, the first vacuum chamber 117 supplies the outside air to the pipe 114a, and finally, the water mixed with the outside air flows into the pump 103, and the outdoor air mixed water subjected to the pumping force of the pump 103 is the first. Pass the check valve 151 to enter the first line-type storage 210.

Thereafter, the outdoor air mixed water containing the microbubbles, which are temporarily stored in the first line-type storage unit 210, passes through the second check valve 230 by the pumping force of the pump 103 to discharge the water outlet pipe 113. ) Is transferred to the first spray nozzle 109 or the second spray nozzle to be described below.

Here, the second check valve 230 is to prevent the water flowing out through the first spray nozzle 109 or the like back flow when the operation stop or pause of the present invention.

In addition, Figure 8 is a perspective view of the replacement valve instead of the second check valve of the outlet pipe shown in FIG.

As shown in FIG. 8, the second check valve 230 of FIG. 7 existing between the first line storage 210 and the outlet pipe 113 may be replaced with a outlet valve 240.

This outlet valve 240 is an electronic on-off valve whose opening and closing operation is controlled by the above-mentioned electronic control unit, as well as the reverse flow of water, the outdoor air mixed water magnetized in the first line-type storage unit 210 as it is the outlet pipe 113 ) To prevent release in vain.

Third embodiment

9 is a bottom view illustrating a second line storage unit 310 having a coil shape for a microbubble generator according to a third embodiment 300 of the present invention.

As shown in FIG. 9, unlike the second embodiment, the second line storage unit 310 has a tubular member 311 wound in a coil shape from the center to the outside.

Between the wound tube member 311 is also provided with a plurality of permanent magnets 220 to induce the magnetization of water. In addition, in the third embodiment 300, the mounting bracket 330 for restraining the permanent magnet 220 and the wound pipe member 311 in the coil shape is used to maintain the coil shape.

In addition, the second line-type storage part 310 is surrounded by the heat insulator 340 and has a feature of minimizing the influence of the atmospheric temperature.

Fourth embodiment

FIG. 10 is a perspective view illustrating a bobbin-shaped third line storage unit 410 for a microbubble generating device according to a fourth exemplary embodiment of the present invention.

As shown in FIG. 10, the third line-type storage unit 410 includes a hollow bracket 411 having a plurality of bobbin-type seating grooves arranged outside and a hollow seating space formed at an axial center thereof in order to improve installation space efficiency; A hose member 412 wound around the bobbin seating groove; It consists of a bar-shaped permanent magnet 420 inserted into the hollow seating space of the hollow bracket 411.

Similar to the first and second line storage units described above, the third line storage unit 410 linearizes the flow of water, improves the efficiency of the installation space, and mixes the air with micro bubbles for a relatively long time. Induce the flow of water to increase the dissolution rate, and in the meantime, the outdoor mixed water can be efficiently led to the magnetized water, and by using the existing pressure tanks and additives, it is possible to reduce the overall weight to reduce the weight.

Fifth Embodiment

FIG. 11 is a perspective view illustrating a hose-shaped fourth line storage unit 510 for a microbubble generating device according to a fifth embodiment 500 of the present invention, and FIG. 12 is a second view shown in FIG. It is a perspective view showing the vacuum chamber 570 and its disassembled state.

As illustrated in FIG. 11, the fourth line storage unit 510 includes a hose 511 of a flexible material wound in a plurality of times to form a circle; At least one coil spring 512 inserted into the hose 511; A plurality of strips (513) for fixing the wound portion of the hose (511); And a ball tank 520 connected to the water outlet side end of the hose 511.

The ball tank 520 preferably includes a plurality of ceramic balls or a plurality of silver-containing members 521 having far infrared rays and anion radiation functions. Here, the silver-containing member 521 maximizes the sterilization and purification function to the outdoor mixed water.

In the line-shaped storage structure of the fourth line storage unit 510, an inlet pipe 111 through which water from a water supply source such as a bathtub is also connected is connected to an inlet of the inlet valve 114.

The temperature sensor 150 is installed at the outlet side pipe 114a of the inlet valve 114, and the water temperature can be measured. For more efficient temperature measurement, the outlet side pipe 114a of the inlet valve 114 is preferably formed of a metal material. Water flows into the outlet side pipe 114a of the inlet valve 114.

At this time, a second vacuum chamber 570 of the air supply pipe 105, which will be described in detail below, is installed in the outlet pipe 114a. Accordingly, the water immediately before flowing into the pump 103 is mixed with the outside air by the second vacuum chamber 570, and then flows into the pump 103. Thereafter, the pump 103 flows along the conduit of the fourth line-type storage part 510 past the first check valve 151 by the pumping force of the pump 103.

At this time, the external air mixed water is maintained or increased while colliding with the coil spring 512 in the fourth line-type storage unit 510, or changed to more fine micro bubbles, and then flows into the ball tank 520. .

Inside the ball tank 520, the fine outside air mixed water comes into contact with the silver-containing member 521 and becomes a nano fine outside air mixed water having a sterilizing function, and then flows toward the water outlet pipe 113.

As shown in FIG. 12, the second vacuum chamber 570 has a relatively small size (layout) compared to the first vacuum chamber described above. For example, the second vacuum chamber 570 is very compact, as has a diameter equal to or equivalent to that of a conventional rubber or plastic hose.

The second vacuum chamber 570 is interposed and connected between one side and the other side of the air supply pipe so as to correspond to the inflow direction of the air, such as the direction of the 'arrow' displayed on its outer surface.

The second vacuum chamber 570 may include a hollow inlet portion 571 having an inlet formed at an upper end of a hemispherical shape; A first disk 572 formed with a plurality of fine holes disposed below the inlet portion 571; The hollow part of the upper part having an inner diameter into which the inlet part 571 and the first disk 572 can be inserted, the venturi space part of the center and the hollow part of the bottom part are integrally formed. And a body portion 573 in which threads are formed on the outer side of the lower hollow portion. A center pin 574 inserted into the venturi space portion of the body portion 573 to maintain a fine clearance; A shaded rubber diaphragm 575 in contact with a lower end of the center pin 574; A coil spring 576 inserted around a lower protrusion of the rubber diaphragm 575; A second disk 577 having a plurality of fine holes disposed at the bottom of the coil spring 576; The hollow outlet portion 579 is inserted into the inner diameter of the hollow portion of the lower portion of the body portion 573.

The second vacuum chamber 570 is repeatedly operated to the rubber diaphragm 575 to the extent that the inside of the air supply pipe intermittently becomes a negative pressure state in accordance with the operation of the pump 103 described above, to overcome the elastic force of the coil spring 576. Pulling and releasing are repeated. As a result, the outside air is sucked through the hollow inlet portion 571 in the form of a pulse wave, and then discharged through the hollow outlet portion 578.

13 is a perspective view showing the second spray nozzle 190 and its disassembled state of the present invention.

Similar to the installation relationship of the first spray nozzle described above, the second spray nozzle 190 of the present invention is mounted at the end of the outlet pipe and discharged from the pressure tank or the first to fourth line type storage units described above. It is responsible for spraying the mixed water to the water supply.

At this time, unlike the first spray nozzle, the second spray nozzle 190 is very small and has a ring flange shape in which the lower part of the ring shape and the upper part of the flange shape are integrally formed in order to reliably discharge microbubbles. Nozzle hollow portion 192 of the; A first inserting portion 191 inserted into and fixed to the inner diameter of the upper side of the nozzle hollow portion 192 by a fitting method; And a second inserting portion 193 inserted into and fixed to the inner diameter of the lower side of the nozzle hollow portion 192 by a fitting method.

When the first inserting portion 191 and the second inserting portion 193 are coupled to the nozzle hollow portion 192 of the second spray nozzle 190, the first insert is based on the inner space of the nozzle hollow portion 192. A fast flow space 195 is formed between the portion 191 and the second insert 193 in which a high speed jet flow of water can be realized.

On the other hand, the second insertion portion 193 has a plurality of slits formed in a straight or spiral shape on its outer circumferential surface, and a bottleneck nozzle hole 194 is further formed therein.

On the other hand, the first inserting portion 191 does not form the nozzle hole 194 and has a cone-shaped inner surface with a closed end, and looks similar to the second inserting portion 193 in a plurality of outer peripheral surfaces. It forms a slit.

The second spray nozzle 190 formed as described above flows in outside air mixed water of the outlet pipe through the plurality of slits and the nozzle holes 194 formed on the outer circumferential surface of the second inserting portion 193.

The outdoor mixed water passing through the nozzle hole 194 has a high-speed jet flow form instantaneously in the high-speed flow space 195, but immediately afterwards, hits the inner surface of the cone shape of the first insertion portion 191 whose end is blocked. While being blown, it is changed into more fine ultra bubbles, and is injected through a plurality of slits formed on the outer circumferential surface of the first inserting portion 191.

The second spray nozzle 190 is installed between the outlet pipe and the outer case of the funnel form consisting of two or three stages, such as the well-known ring-shaped packing and the mounting method using the intermediate cap, as described above. .

According to the micro-bubble generating device according to the present invention as described above, it is possible to ultra-miniaturize the bubbles of the mixed air to be injected into the bathtub by intermittently inhaling the air mixed in the bath water intermittently like a pulse wave by the air supply valve for opening and closing at high speed. .

Therefore, it is possible to change the bath water to be alkaline by the ultra-mini strength cloth, and to softly change the bath water like milk by generating ultrasonic waves and anions.

In addition, the ultra-fine micropore's pore penetration and buoyancy draw out fat and impurities accumulated deep in the pores of the bather's pores and supply oxygen energy deep into the skin to clean the skin, exfoliate skin, moisturize and whiten skin, and enhance skin elasticity. The beauty of the skin can be obtained, and the effects of atopic dermatitis, acne, athlete's foot, eczema and other skin diseases, as well as fatigue recovery, hangover removal, body temperature rise, blood circulation improvement, insomnia can be obtained.

In addition, it is possible to expect the effect of promoting the metabolism of the bath by generating negative ions in a natural manner by ultra-miniature guns away from the artificial method using the electrical friction.

In addition, it is possible to miniaturize and simplify the entire device, such as the structure and components that generate microbubbles, thereby facilitating the handling and management, such as installation, movement, and use of the device.

In addition, the micro-bubble generating device of the present invention has the advantage that can be made to be lightweight and miniaturized in accordance with the adoption of various line-type storage, the second vacuum chamber, the second spray nozzle.

In addition, the micro-bubble generating device of the present invention by using the various line-type storage unit to induce the outdoor air mixed water containing the micro-bubble for a long time to increase the dissolved rate, so that the water is changed as magnetized water by using the magnetic force of the permanent magnet There is an inducible advantage.

In addition, the micro-bubble generating device of the present invention has the advantage that the sterilization and purification efficiency can be maximized by contacting the outside air mixed water containing the micro-bubbles with a plurality of silver-containing members in the ball tank.

Claims (15)

A pump 103 connected to the water supply pipe 111 to supply water W of the water supply 110 to the pressure tank 107 and mounted between the water supply 110 and the pressure tank 107; An air supply pipe 105 connected between an inlet valve 114 of the inlet pipe 111 and the pump 103 to supply outside air to the inlet pipe 111; A pressure tank 107 connected to the connection pipe 112 and mounted between the pump 103 and the water supply source 110 to temporarily store the mixed water in the outside air; And It is configured to include a first spray nozzle 109 mounted to the end of the discharge pipe 113 withdrawn from the pressure tank 107 to inject the mixed air discharged from the pressure tank 107 to the water supply source 110 In the micro bubble generator, The air supply pipe 105 is equipped with a first vacuum chamber 117, which is opened and closed by the air supply valve 115 and sucks the outside air in the form of a pulse wave by the negative pressure generated by the pump 103 is characterized in that the fine Bubble generator. The method of claim 1, The first vacuum chamber 117 is cylindrical through the cylindrical body 119 mounted between the air supply pipe 105 and the air supply valve 115 and a through hole 125 opened and closed by a vacuum valve 123. Microbubble generating device comprising a vacuum bag 121 connected to the body 119. The method according to claim 1 or 2, Microbubble generating device characterized in that it comprises an electronic control unit 130 for controlling the operation of the inlet valve 114, the air supply valve 115, and the drive motor 127 for driving the pump 103 . The method according to claim 1 or 2, The pressure tank 107 is a micro-bubble generating device, characterized in that it comprises a bleeder (129) for maintaining the internal pressure below a predetermined value. The method according to claim 1 or 2, The pressure tank 107 includes a pressure sensor 149 for detecting an internal pressure, the pressure sensor 149 includes an upper and lower cases 61 and 62 constituting an outer body; An elastic membrane 63 forcibly fitted in the airtight state 73 in the lower case 62; A pressure pin (65) inserted into the elastic membrane (63) to move up and down in the lower case (62) by the elasticity of the elastic membrane (63); A hydraulic pin 67 pressurized by the pressing pin 65 to move up and down the upper case 61; And When the hydraulic pin (67) is pushed together by the pressing pin (65) to be bent upwards and to bend upward when the movable piece (75) and the movable piece (75) attached to the bottom surface of the upper case (61) Microbubble generating device characterized in that it comprises a switch (69) consisting of a fixed piece (76) attached to the opposite side of the movable piece (75) of the upper case (61) so that the contact (77). The method of claim 5, The hydraulic pin 67 is a reaction force against the pressing pin 65 in accordance with the lifting and lowering of the adjustment screw 83 screwed to the spring hole 81 of the upper case 61 is inserted into the reaction spring (79). Microbubble generating device, characterized in that for adjusting. The method according to claim 1 or 2, The pressure tank 107 is a micro bubble generator, characterized in that it comprises a temperature sensor 150 for sensing the internal temperature. The method according to claim 1 or 2, The first spray nozzle 109 has an outer case 31; A mesh filter 33 inserted into an innermost side of the outer case 31; At least two nozzle holes 41 passing through the same radius at equal angular intervals and disposed adjacent to the outside of the mesh filter 33; A filtration filter 37 disposed adjacent to the outside of the nozzle plate 35; A filtration cap 39 disposed adjacent to the outside of the filter 37 by passing through at least two opening holes 43; And The mesh filter 33, the nozzle plate 35, the filtration filter 37, and the filtration cap 39 are sequentially inserted to include an intermediate cap 40 fixed inside the outer case 31. Microbubble generating device, characterized in that. A pump connected to the inlet pipe 111 to supply the water W of the water supply 110 to the pressure tank 107 and mounted between the water supply 110 and the line storage having a line-shaped storage structure ( 103); A second spray nozzle 190 mounted at an end of the water discharge pipe 113 drawn out from the line-type storage unit and spraying the mixed air discharged from the pressure tank 107 to the water supply source 110; The direction of the arrow indicated on the outer surface between one side and the other side of the air supply pipe 105 connected between the inlet valve 114 and the pump 103 of the inlet pipe 111 to supply the outside air to the inlet pipe 111 Microbubble generating device comprising a second vacuum chamber (570) connected based on the. The method of claim 9, The line storage unit, Serpentine-shaped pipe member 211 bent to have an S-shape; Microbubble generating device, characterized in that the first line-type storage unit 210 including a plurality of permanent magnets 220 between the tubular member (211). The method of claim 9, The line storage unit, A pipe member 311 wound in a coil shape from the center to the outside; A plurality of permanent magnets 320 between the wound tubular members 311; A second line-type storage including an installation bracket 330 for restraining the permanent magnet 220 and the wound pipe member 311 in a coil shape to maintain a coil shape, and wrapped by a heat insulating material 340. Microbubble generating device, characterized in that the portion (310). The method of claim 9, The line storage unit, A hollow bracket 411 having a plurality of bobbin-type seating grooves arranged outside and forming a hollow seating space at an axis; A hose member 412 wound around the bobbin seating groove; Microbubble generating device, characterized in that the third line-type storage unit 410 including a bar-shaped permanent magnet 420 inserted into the hollow seating space of the hollow bracket (411). The method of claim 9, The line storage unit, A hose 511 of a flexible material wound in a plurality of times to form a circle; At least one coil spring 512 inserted into the hose 511; A plurality of strips (513) for fixing the wound portion of the hose (511); And a ball tank 520 connected to the water outlet side end of the hose 511, wherein the ball tank 520 includes a plurality of ceramic balls or a plurality of silver-containing members having far-infrared and anion radiation functions. Micro-bubble generating device, characterized in that the fourth line-type storage unit 510 is built-in. The method of claim 9, The second vacuum chamber 570, A hollow inlet portion 571 having an inlet formed at an upper end of a hemispherical surface shape; A first disk 572 formed with a plurality of fine holes disposed below the inlet portion 571; The hollow part of the upper part having an inner diameter into which the inlet part 571 and the first disk 572 can be inserted, the venturi space part of the center and the hollow part of the bottom part are integrally formed. And a body portion 573 in which threads are formed on the outer side of the lower hollow portion. A center pin 574 inserted into the venturi space portion of the body portion 573 to maintain a fine clearance; A shaded rubber diaphragm 575 in contact with a lower end of the center pin 574; A coil spring 576 inserted around a lower protrusion of the rubber diaphragm 575; A second disk 577 having a plurality of fine holes disposed at the bottom of the coil spring 576; Microbubble generating device comprising a hollow outlet portion (579) is inserted into the inner diameter of the hollow portion of the lower portion of the body portion (573). The method of claim 9, The second spray nozzle 190, A nozzle hollow portion 192 having a ring flange shape in which the lower portion of the ring shape and the upper portion of the flange shape are integrally formed; The first inserting portion 191 which is inserted and fixed to the inner diameter of the upper portion of the nozzle hollow portion 192 by a fitting method and has a plurality of straight or spiral slits formed on the outer circumferential surface thereof and has a cone-shaped inner surface with a closed end. Wow; The second insertion portion is inserted into and fixed to the inner diameter of the lower side of the nozzle hollow portion 192 in a fitting manner, and formed with a plurality of straight or spiral slits on the outer circumferential surface and further formed a bottle-shaped nozzle hole 194 therein. Including the (193), when the first insertion portion 191 and the second insertion portion 193 is coupled to the nozzle hollow portion 192 of the second spray nozzle 190, the nozzle hollow portion 192 Microbubble generating device, characterized in that the high-speed flow space (195) is formed between the first inserting portion (191) and the second inserting portion (193) relative to the inner space of the.

Images