KR101282388B1 - Micro bubble generator using water supply pressure - Google Patents

Abstract

The present invention can be used for various purposes such as showering, washing water, agriculture and fishing with water containing micro bubbles by generating micro bubbles in water by using a constant pressure, can save water and detergent, and separate power No need to use the present invention relates to a micro bubble generator using only a constant pressure.
The present invention is a pipe in the form of a water supply pipe, a water supply port is formed in the upper portion of the water supply pipe to supply constant water, a drain hole formed in the lower portion of the water supply pipe to discharge water, the inner diameter is suddenly narrowed and gradually formed in the drain opening Bubble nozzle, a pipe-type air supply port formed on one side of the water supply pipe, is formed at the end of the air supply port is configured to include an air check valve to allow the air flow only from the outside to the air supply port.

Description

Micro bubble generator using water pressure {Micro bubble generator using water supply pressure}

The present invention can be used for various purposes such as showering, washing water, agriculture and fishing with water containing micro bubbles by generating micro bubbles in water by using a constant pressure, can save water and detergent, and separate power No need to use the present invention relates to a micro bubble generator using only a constant pressure.

Generally, water is used for various purposes in various fields such as homes, businesses, factories, and farms.

As described above, if the water discharged from the water supply is used as it is, a large amount of water is unnecessarily used. For example, in order for the water to be discharged at a high pressure from the head of the shower, the water supply must be fully opened to increase the pressure. In this case, the water can be discharged at a high pressure from the head of the shower. There is a problem that is consumed.

In addition, in order to use water for washing, a problem arises in that a large amount of cleaning agent must be used for effective cleaning.

In recent years, many micro bubble generators which generate fine micro bubbles in water have been widely used.

The use of micro bubbles in water not only saves water but also improves washing power, and free radicals such as OH ^- are used to sterilize bacteria in water during the extinction process by the self-pressing effect of micro bubbles. There is.

In particular, when showering with water containing micro bubbles, negative ions are generated by the instantaneous crushing of the water, so when applied to a shower or a bathtub, a forest bath effect can be produced. Ultrasonic waves generated by micro vibration gently stimulate the whole body to Fatigue can be recovered quickly by promoting relaxation and metabolism, improve atopic skin disease and have a skin moisturizing effect.

Due to the various effects as described above, the microbubble spawning device has been widely used in recent years, and the conventional microbubble generating device has to be supplied with a separate electric motor for forced supply of air to generate microbubbles. Therefore, there is a risk of electric shock, the amount of microbubbles is small, the proper effect is not seen, or after a certain period of use, the water inside the shower is filled with water, the microbubble is no longer generated, so microbubbles through a separate drain valve There was a problem such as restarting after discharging all the water inside the generator.

Republic of Korea Patent Publication No. 1011295 (2011.12.01.)

The present invention has been made to solve the above problems, does not require an electric motor for forced supply of air, it is possible to generate fine micro bubbles than the conventional micro bubble generator, the water inside the micro bubble generator It is an object of the present invention to provide a microbubble generating device capable of continuously generating microbubbles without having to periodically discharge them.

In order to achieve the above object, the microbubble generating device using the constant pressure according to the present invention includes a water supply pipe 101 having a pipe shape, a water supply hole 102 formed at an upper portion of the water supply pipe 101 to receive constant water, and the water supply pipe. Drain port 103 formed in the lower portion of the 101 to discharge water, the bubble nozzle 109 formed in the drain port 103 in a form that the inner diameter suddenly narrowed and gradually widened formed on one side of the water supply pipe 101 It is configured to include an air check valve 110 in the form of a pipe, the air check valve 110 is formed at the end of the air supply port 104 so that air flows only from the outside to the air supply port 104.
In addition, the micro-bubble generating device using the constant pressure of the present invention comprises a case 151 having a discharge pipe 153 at the bottom; A lid 152 fastened to the case 151; A water supply pipe 101 formed at an upper portion of the lid 152 to supply constant water from the outside; An air check valve (110) formed at one side of the water supply pipe (101) to allow air to flow only from the outside into the lid (152); A bubble nozzle 109 formed at an end portion of the water supply pipe 101 positioned inside the lid 152 and formed at a lower end of the water supply pipe 101 in a form in which the inner diameter suddenly narrows and then gradually widens; And a bubble tank 158 having an upper portion opened and inserted into the case 151 so as to be spaced apart from the inner wall of the case 151 through the supporting means. Furnace first tank 150a; And a second tank 150b;
The water supply pipe 101 of the second tank 150b is connected to the discharge pipe 153 of the first tank 150a.
At this time, the air check valve 110 has a cover 108 that is a predetermined number of holes 107 to cover the air supply port 104, and the membrane 106 is in close contact with the inside of the cover 108 and elastic Characterized in that consisting of.
In addition, the axis of the air supply port 104 and the axis of the water supply pipe 101 is characterized in that configured to form an acute angle (銳角).
In addition, the reverse flow prevention port 111 is characterized in that the water supply pipe 101 side end of the air supply port 104 is formed.
In addition, the inner circumferential surface of the water supply pipe 101 is characterized in that the screw 112 for inducing rotation of water protrudes.
In addition, the two micro-bubble generating device 100 is characterized in that it is configured in series connected vertically.
In addition, the hose 130 is fastened to the drain hole 103, the inner diameter of the hose 130 is characterized in that the bubble nozzle 131 that is gradually reduced in size and gradually widened.
In addition, the inside of the middle of the hose 130 is characterized in that the inner diameter of the bubble nozzle 131 is gradually reduced and gradually widened.
In addition, the support means protrudes radially outward of the bubble tank 158 so that the overflow hole 161 is formed, and is mounted on the upper end of the case 151 at the end of the support bar 159. Characterized in that consisting of the support (160).
In addition, the lower portion of the bubble tank 158 is characterized in that the drain hole 163 is formed.
In addition, the first tank (150a) and the second tank (150b) is characterized in that configured in series in the vertical direction.
In addition, the discharge pipe 153 of the second tank (150b) is connected to the discharge pipe 205, the inner end of the discharge pipe 205 is rapidly narrowed and the bubble nozzle 207 is gradually widened Characterized in that formed.
In addition, the inside of the discharge pipe 205 is characterized in that the inner diameter of the bubble nozzle 207 of the form which is rapidly narrowed and gradually widened.
In addition, a drain pipe 156 is formed at a lower portion of the second tank 150b to communicate with the inside of the second tank 150b to discharge the water in the first tank 150a and the second tank 150b.
The lower portion of the second tank (150b) is characterized in that the direction switching valve 155 for selectively discharging the water in the case 151 through the discharge pipe 153 or the drain pipe 156 is installed.
In addition, the water supply pipe 101 is characterized in that the water pump is installed to supply high pressure water to the water supply pipe (101).

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The present invention configured as described above can generate microbubbles using a constant pressure discharged from the faucet without the need for an electric motor for forced supply of air, it can generate a microbubble than conventional microbubble generating device For example, it is possible to generate microbubbles continuously for a long time without having to periodically discharge water inside.

In addition, the microbubble generating device according to the present invention can reduce the production cost because of the simple structure, the construction and installation is simple, and the maintenance is very easy because the volume is small.

1 is a perspective view showing a micro bubble generating apparatus according to an embodiment of the present invention.
2 is a cross-sectional view showing a micro bubble generating apparatus according to an embodiment of the present invention.
Figure 3 is an embodiment of the present invention formed in the backflow prevention port in the air inlet.
Figure 4 is an embodiment of the present invention a screw is formed inside the water supply pipe.
5 is a perspective view showing a state in which the micro bubble generator is connected in series.
6 is a sectional view showing another embodiment of the present invention.
7 is a perspective view showing another embodiment of the present invention.
8 is a block diagram of another embodiment of the present invention.
9 is an exploded perspective view showing a second tank of another embodiment of the present invention.
10 is a cross-sectional view of a second tank according to another embodiment of the present invention.
11 is a view showing a state in which microbubbles are generated according to another embodiment of the present invention.
12 is an enlarged cross sectional view showing a main part of another embodiment of the present invention;
Figure 13 illustrates another embodiment of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a micro bubble generating apparatus according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a micro bubble generating apparatus according to an embodiment of the present invention, Figure 3 is a countercurrent flow in the air inlet An embodiment of the present invention formed on the earth, Figure 4 is an embodiment of the present invention is a screw formed inside the water supply pipe, Figure 5 is a perspective view showing a state in which the micro bubble generator is connected in series, Figure 6 7 is a cross-sectional view showing another embodiment of the present invention, FIG. 7 is a perspective view showing another embodiment of the present invention, FIG. 8 is a configuration diagram of another embodiment of the present invention, and FIG. 9 is another embodiment of the present invention. An exploded perspective view showing a second tank of an example, Figure 10 is a cross-sectional view of a second tank according to another embodiment of the present invention, Figure 11 shows a state in which micro bubbles are generated by another embodiment of the present invention. One 12 is an enlarged cross-sectional view of a main part of still another embodiment of the present invention, and FIG. 13 is a view showing another embodiment of the present invention.

Microbubble generating device using a constant pressure according to an embodiment of the present invention is a water supply pipe 101 is formed in the upper portion and the drain port 103 is formed in the upper portion as shown in Figure 1 and 2 and , It is composed of an air supply port 104 of the pipe shape protruding on one side of the water supply pipe (101).

An air check valve 110 is formed at the end of the air supply port 104 to allow air to flow in only one direction, so that the air inside the air supply port 104 does not flow out to the outside and the outside air is supplied to the air supply port. (104) can only flow into the interior.

The air check valve 110 formed at the end of the air supply port 104 covers the cover 108 having a predetermined number of holes 107 to seal the end of the air supply port 104. At this time, the inside of the cover 108 is installed so that the membrane 106 of a thin film form in close contact with the inner surface of the cover 108.

Since the membrane 106 is elastic and adheres to the inner surface of the cover 108, air may flow into the air supply port 104 from the outside, but the air of the air supply port 104 may cover the cover 108. It does not leak out through the hole 107 of the.
The air supply port 104 of the water supply pipe 101 to prevent the water supplied to the water supply port 102 to flow back to the air supply port 104 and to suck the air more smoothly from the air supply port 104 It is preferable to configure so as to form an acute angle with the axis.

In addition, a bubble nozzle 109 is installed at the drain port 103 under the water supply pipe 101. The bubble nozzle 109 has a form in which the inner diameter suddenly decreases and then the inner diameter gradually widens so that the bubble nozzle 109 induces high-pressure injection of water to generate micro bubbles more abundantly.

One embodiment of the present invention configured as described above is connected to the water supply to the water inlet 102 and open the faucet, the water flows through the water supply port 101 through the water supply port 102 by the constant pressure, air supply ( The negative pressure acts on the 104 and the membrane 106 of the air check valve 110 bends as shown in FIG. 2, whereby air is introduced through the hole 107 of the cover 108 to supply a water supply pipe through the air supply port 104. 101 flows to the drain 103 with the flowing water.

The water flowing with the air reaches the bubble nozzle 109 formed in the drain hole 103. The bubble nozzle 109 has a shape in which the inner diameter sharply narrows and the inner diameter gradually widens as described above. Water and air is strongly sprayed from the) to generate a micro bubble is discharged through the drain 103.

And as shown in Figure 3 by installing the backflow prevention 111 in the end of the air supply port 104 in contact with the water supply pipe 101, the high pressure water flowing through the water supply pipe 101 is the air supply port 104 To prevent backflow.

In addition, as shown in FIG. 4, water flowing through the water supply pipe 101 forms a rotational flow by the screw 112 by forming a spiral screw 112 on the inner circumferential surface of the water supply pipe 101, thereby rotating the flow. By the water is configured to be sprayed more strongly through the bubble nozzle (109).

And, as shown in Figure 5 by connecting the two bubble generators in series, it is possible to generate a finer and richer microbubble by generating a bubble of water in the bubble again.

6 is a view showing a micro bubble generating apparatus using a constant pressure according to another embodiment of the present invention.

As shown in FIG. 6, another embodiment of the present invention removes the bubble nozzle 109 from the drain hole 103 in the microbubble generating apparatus 100 according to the embodiment of the present invention shown in FIG. 2. The flexible hose 130 is connected to the drain hole 103, and an inner diameter of the hose 130 is rapidly narrowed to form a bubble nozzle 131 that gradually expands.

Another embodiment of the present invention configured as described above is the water and air is discharged through the drain port 103 through the water supply pipe 101 and the air supply port 104 flows through the hose 130 to the end of the hose 130 Micro bubbles are generated in the water and discharged through the formed bubble nozzle 131.

At this time, by forming one or more bubble nozzles 131 whose inner diameters are rapidly narrowed and gradually widened inside the hose 130, more fine and rich micro bubbles can be generated.

7 is a view showing a micro bubble generating apparatus 200 according to another embodiment of the present invention.

In the microbubble generating device 200 according to another embodiment of the present invention, the first tank 150a and the second tank 150b are installed in the housing 201 as shown in FIG. Water is supplied to the water supply pipe 101 of the first tank 150a through the water supply pipe 204, and water passes through the first tank 150a and the second tank 150b to generate micro bubbles, thereby discharging the discharge pipe 205. Through the outlet 206) is connected to the use, such as shower head.

A drain pipe 203 is formed below the micro bubble generator 200, and the knob 202 formed on the front surface of the housing 201 is operated to discharge pipe 205 inside the micro bubble generator 200. The discharge pipe may be selected to be discharged or discharged to the drain pipe 203.

Inside the outlet 206 of the discharge pipe 205, a microbubble discharged to the outlet 206 is generated by installing a bubble nozzle 207 in which the inner diameter is rapidly narrowed and gradually widened as shown in FIG. When the discharged water is discharged to the outlet 206, the bubble nozzle 207 is configured to generate micro bubbles again.

At this time, by installing at least one bubble nozzle (not shown) having the same configuration as the bubble nozzle 207 in the discharge pipe 205 is configured to generate more fine and rich micro bubbles while passing through the discharge pipe 205 do.

As shown in FIG. 8, the first tank 150a and the second tank 150b are connected in series in the housing 201. That is, the discharge pipe 153 of the first tank 150a is connected to the water supply pipe 101 of the second tank 150b.

The first tank 150a and the second tank 150b have the same internal configuration, except that only the discharge pipe 153 is formed below the case 151 of the first tank 150a, while the second tank 150 The lower part of the case 151 of the 150b through the drain pipe 156 for discharging the water inside to the outside in addition to the same discharge pipe 153 as the first tank 150a, and through the discharge pipe 153 and the drain pipe 156 There is a further configured difference between the directional valve 155 to selectively operate to discharge the water.

The configuration of the second tank 150b will be described in detail with reference to FIGS. 9 and 10.

The second tank 150b includes a case 151, a bubble tank 158 inserted into the case 151, and a lid 152 that seals the inside of the case 151 by covering and fastening the upper portion of the case 151. It is composed of

As shown in FIG. 9, a discharge pipe 153 and a drain pipe 156 communicating with the inside of the case 151 are formed below the case 151, and through the drain pipe 156 and the discharge pipe 153. A diverter valve 155 for selectively discharging water is formed.

The directional valve 155 is formed with a shaft 154 and the knob 202 of FIG. 7 is coupled to the shaft 154 so that the user operates the knob 202 to operate the directional valve 155.

Since the direction switching valve is a known technique, a detailed description thereof will be omitted.

In addition, a bubble bath 158 is inserted into the case 151, and the bubble bath 158 is inserted into and fixed inside the case 151 to have a predetermined distance from the inner wall of the case 151 through fixing means. do.

As shown in FIG. 9, as shown in FIG. 9, a support bar 159 is radially protruded from an upper outer surface of the bubble tank 158 having an open top, and a support tool 160 is formed at an end of the support bar 159. When the bubble bath 158 is inserted into the case 151, the supporter 160 is caught by the upper end of the case 151. When the lid 152 is bolted to the case 151 in this state, FIG. As described above, the bubble bath 158 is fixed at a predetermined distance from the inner wall of the case 151.

And the lid 152 is bolted to the case 151, it is preferable to insert the sealing 162 for waterproofing the fastening surface of the lid 152 and the case 151.

A water supply pipe 101 through which water is supplied into the case 151 is formed at an upper portion of the lid 152, and air is supplied from the outside into the case 151 to generate micro bubbles on one side of the water supply pipe 101. The air supply port 104 is provided, the air check valve 110 is formed at the end of the air supply port 104, the inner diameter is sharply narrowed at the lower end of the water supply pipe 101 is gradually widened Bubble nozzle 109 is formed.

The configuration of the bubble nozzle 109 at the bottom of the water supply pipe 101, the air supply port 104, the air check valve 110, and the water supply pipe 101 formed on the lid 152 is illustrated in FIGS. 1 and 2. The same configuration as in the embodiment of the.
That is, as shown in FIGS. 10 and 12, a water supply pipe 101 and an air supply port 104 are formed at an upper portion (outside) of the lid 152 with the lid 152 as a boundary, The bubble nozzle 109 is formed in the lower part (inner side).
In addition, only the discharge pipe 153 is formed at the lower portion of the case 151, and the first tank 150a has the same structure as that of the case 151 and the lid 152.

The operation of the microbubble generating device according to the present invention configured as described above will be described in detail.

As shown in FIG. 11, when a user opens a faucet and supplies water to the water supply pipe 204, water flows into the water supply pipe 101 of the first tank 150a, and water flows through the water supply pipe 101 at a high pressure. In the process, the air is sucked through the air supply port 104 in communication with the water supply pipe 101 is injected into the case 151 together with the water.

Air and water injected at a high pressure into the case 151 strongly collide with the lower inner surface of the bubble tank 158 with the upper portion open to generate micro bubbles in the water. At this time, the water continuously sprayed from the bubble nozzle 109 of the lid 152 is sprayed earlier and collides strongly with the water remaining inside the bubble tank 158, thereby generating finer micro bubbles, as shown in FIG. Same as the cross-sectional view of the tank 150b or the internal structure of the first tank 150a) and overflows to the outside of the bubble tank 158 through the overflow hole 161 formed between the support bars 159 of the bubble tank 158. The water inside the case 151 in which the micro bubbles are generated is introduced into the water supply pipe 101 of the second tank 150b through the discharge pipe 153 of the first tank 150a.

As described above, the water introduced into the water supply pipe 101 of the second tank 150b flows through the water supply pipe 101 while negative pressure is applied to the air supply port 104 communicating with the water supply pipe 101 of the second tank 150b. It acts to suck air through the air supply port 104 and the air is injected together with a strong pressure from the nozzle 109.

The water strongly injected into the case 151 of the second tank 150b strongly collides with the inner bottom surface of the inner bottom of the bubble tank 158 of the second tank 130 to generate finer micro bubbles in the water, and the second tank It overflows through the overflow hole 161 formed in the bubble tank 158 of 150b.

As described above, the water containing the fine micro bubbles overflowing the bubble tank 158 of the second tank 150b is discharged through the discharge pipe 153 of the second tank 150b, and the discharge pipe 205 as shown in FIG. 7. It is used to be injected into the outlet 206 through.

All operations, including the supply of air, is performed by the water pressure injected from the tap, so no external power source is required.

When the user locks the faucet and turns the knob 202, the water inside the bubble tank 158 of the first tank 150a is drained through the drain hole 163 formed in the lower part of the bubble tank 158 so as to be inside the case 151. The remaining water flows into the water supply pipe 101 of the second tank 150b through the discharge pipe 153 and flows into the bubble tank 158 of the second tank 150b.

Water introduced into the bubble tank 158 of the second tank 150b is discharged through the drain hole 163 formed in the lower portion of the bubble tank 158 of the second tank 150b to drain the pipe of the second tank 150b. It is discharged to the outside through 156.

When the shower is finished as described above, by discharging all the water inside the micro bubble generator 200 to prevent the generation of scale in the micro bubble generator 200 and the growth of bacteria bacteria.

As described above, abundantly generated microbubbles having a diameter of less than 10 μm are generated while passing through the first tank 150a and the second tank 150b, which are connected in series, to save water and to reduce noise. In addition, the cleaning power is excellent by the micro bubble.

In addition, anion is generated by the instantaneous crushing of water in the microbubble generator, which can produce a forest bath effect when applied to a shower or a bathtub, and free radicals such as OH ^- are generated during the extinction process due to the self-pressurization effect of the microbubble. To sterilize the bacteria in the water.

In addition, when the microbubble generator of the present invention is applied to the shower, the ultrasonic waves generated by the micro-vibration gently stimulate the whole body to promote muscle relaxation and metabolism, thereby quickly recovering fatigue, improving atopic skin disease, and improving skin. Moisturizing effect.

And since the present invention uses only a constant pressure and does not use electric power, there is no risk of electric shock, and installation and maintenance costs are saved.

In the above description, an embodiment in which the drain pipe 156 and the directional valve 155 are configured under the second tank 150b of the present invention has been described.

However, as shown in FIG. 13, the microbubble generating device can be configured without forming the drain pipe 156 and the direction switching valve 155 under the second tank 150b.

That is, as illustrated in FIG. 13, the second tank 150b is configured in the same configuration as the first tank 150a, and the water supply pipe 204 is provided with an on / off valve in the water supply pipe 101 of the first tank 150a. ) And fasten the water supply pipe 101 of the second tank 150b having the same configuration as the first tank 150a to the discharge pipe 153 of the first tank 150a, and discharge pipe of the second tank 150b. 153 is fastened to the discharge pipe 205.

According to the present invention configured as described above, when the user opens the valve of the water supply pipe 204, water containing microbubbles may be discharged and used through the discharge pipe 205, and the user discharges when the valve of the water supply pipe 204 is locked. The water containing the micro bubbles discharged from the pipe 205 is cut off.

At this time, since all the water inside is discharged through the discharge pipe 205 by the drain hole 163 formed in the bubble tank 158 of the first tank 150a and the second tank 150b as described above. All of the water inside can be drained without the drain pipe or the directional valve.

7 to 13, the present invention is configured by connecting the first tank 150a and the second tank 150b in series, but the third tank (not shown) having the same configuration as the first tank 150a. In addition, three tanks can be connected in series.

In addition, the present invention is a device for generating a micro bubble using a daily constant pressure, high pressure by installing a water pump (not shown) in the water supply pipe 101 of the first tank (150a) where the constant pressure is weak, such as high ground It is preferable to supply the water to the water supply pipe 114 of the first tank 150a.

And in the embodiment of the present invention shown in Figures 1 to 13, the bubble nozzle can be formed in plurality in parallel form according to the size of the inner diameter.

The microbubble generating device according to the present invention has been described above.

It will be understood by those skilled in the art that the technical features of the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof.

Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the appended claims rather than the foregoing description, and the meanings of the claims and All changes or modifications derived from the scope and the equivalent concept shall be construed as being included in the scope of the present invention.

100: micro bubble generator
101: water supply pipe
102: water supply port
103: drain
104: air supply port
105: hall
106: membrane
107: hall
108: cover
109 bubble nozzle
110: air check valve
111: backflow prevention device
112: Screw
130: hose
131: Bubble Nozzle
150a: first tank
150b: second tank
151: Case
152: lid
153: discharge pipe
154: axis
155: direction switching valve
156: drain pipe
158: bubble tank
159: support
160: support
161: overflow hole
162: sealing
163: drain hole
200: micro bubble generator
201: housing
202 knob
203: drain pipe
204: water supply pipe
205: discharge pipe
206: outlet

Claims (17)

Water pipe 101 in the form of a pipe ;,
A water supply port 102 formed at an upper portion of the water supply pipe 101 to receive a constant;
A drain port 103 formed at a lower portion of the water supply pipe 101 to discharge water;
A bubble nozzle 109 formed in the drain hole 103 in a form in which the inner diameter is suddenly narrowed and gradually widened;
An air supply port 104 in the form of a pipe formed on one side of the water supply pipe 101;
And an air check valve (110) formed at an end of the air supply port (104) to allow air to flow only from the outside to the air supply port (104).
A case 151 having a discharge pipe 153 at the bottom; A lid 152 fastened to the case 151; A water supply pipe 101 formed at an upper portion of the lid 152 to supply constant water from the outside; An air check valve (110) formed at one side of the water supply pipe (101) to allow air to flow only from the outside into the lid (152); A bubble nozzle 109 formed at an end portion of the water supply pipe 101 positioned inside the lid 152 and formed at a lower end of the water supply pipe 101 in a form in which the inner diameter suddenly narrows and then gradually widens; And a bubble tank 158 having an upper portion opened and inserted into the case 151 so as to be spaced apart from the inner wall of the case 151 through the supporting means.
Furnace first tank 150a; And a second tank 150b;
The water supply pipe 101 of the second tank (150b) is connected to the discharge pipe (153) of the first tank (150a) microbubble generating device using a constant pressure, characterized in that configured.
The method according to claim 1 or 2,
The air check valve 110,
Using a constant pressure, characterized in that the predetermined hole 107 is formed of a cover 108 covering the air supply hole 104 and the membrane 106 in close contact with the inside of the cover 108 and elastic Micro bubble generator.
The method according to claim 1 or 2,
The axis of the air supply port 104 and the axis of the water supply pipe 101 is a microbubble generating device using a constant pressure, characterized in that configured to form an acute angle (銳角).
The method according to claim 1 or 2,
Microbubble generating device using a constant pressure, characterized in that the back flow prevention 111 is formed at the end of the water supply pipe 101 side of the air supply port (104).
The method according to claim 1 or 2,
Microbubble generating device using a constant pressure, characterized in that the screw 112 for inducing the rotation of water protrudes on the inner peripheral surface of the water supply pipe (101).
The method of claim 1,
Microbubble bubble generator using a constant pressure, characterized in that the two micro-bubble generating device (100) is connected in series in the vertical.
The method of claim 1,
The hose 130 is fastened to the drain hole 103, and microbubbles are generated using a constant pressure, characterized in that a bubble nozzle 131 is formed in which the inner diameter of the hose 130 is rapidly decreased and gradually widened. Device.
9. The method of claim 8,
Inside the middle of the hose 130 is a microbubble generating device using a constant pressure, characterized in that the internal diameter of the hose is rapidly reduced, the bubble nozzle 131 is gradually widened.
delete The method of claim 2,
Wherein the support means comprises:
The supporter 159 protrudes outwardly from the bubble tank 158 so that the overflow hole 161 is formed, and the supporter 160 seated at the upper end of the case 151 at the end of the supporter 159. Micro bubble generator using a constant pressure, characterized in that consisting of.
The method of claim 2,
The microbubble generating device using a constant pressure, characterized in that the drain hole 163 is formed in the lower portion of the bubble tank (158).
The method of claim 2,
The first tank (150a) and the second tank (150b) is a micro bubble generating device using a constant pressure, characterized in that configured in series in the vertical direction.
The method of claim 2,
The discharge pipe 153 of the second tank (150b) is connected to the discharge pipe 205, the end of the discharge pipe 205 is formed with a bubble nozzle 207 of the form of the inner diameter is rapidly narrowed and gradually widened Micro bubble generator using a constant pressure characterized in that.
15. The method of claim 14,
The inside of the discharge pipe 205 is a microbubble generating device using a constant pressure, characterized in that the inner diameter is rapidly narrowed, the bubble nozzle 207 is gradually widened.
The method of claim 2,
A drain pipe 156 is formed at a lower portion of the second tank 150b to communicate with the inside of the second tank 150b to discharge water in the first tank 150a and the second tank 150b.
Under the second tank (150b) using a constant pressure, characterized in that the direction switching valve 155 is installed to selectively discharge the water in the case 151 through the discharge pipe 153 or the drain pipe 156 Micro bubble generator.
The method according to claim 1 or 2,
The water supply pipe 101 is a micro bubble generator using a constant pressure, characterized in that the water pump is installed to supply high-pressure water to the water supply pipe (101).

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