KR101113375B1 - Micro bubble gererating device - Google Patents

Abstract

PURPOSE: A micro bubble generating device is provided to generate a large amount of micro bubbles at low coast and high efficiency, by discharging bubbles through the outlet stage of a exhaust pipe after miconizing the bubbles by a nozzle hole. CONSTITUTION: A micro bubble generating device comprises an external casing(110), an inner casing(120), a supply pipe(130), and an exhaust pipe(140). The outlet of the supply pipe is arranged in the inner casing through the external casing. The supply pipe comprises a rotating wing(132) in the middle of a supply oil path. The rotating wing generates a first micro bubble by mixing water and air. The inlet of the exhaust pipe is arranged in the external casing. The exhaust pipe has a valve type nozzle part(142) in the middle part. The valve type nozzle part controls the opening and the closing of a exhaust oil path, and generates micro bubbles at opening. The exhaust pipe generates second micro bubbles by passing the first micro bubbles and water through the valve type nozzle part. The exhaust pipe comprises a valve body, a ball valve, and a nozzle plate.

Description

Micro Bubble Gererating Device

The present invention relates to a device for generating micro-bubbles, and more particularly to a micro-bubble generating device capable of generating a large amount of various micro-bubbles with a low cost and high efficiency.

In general, microbubbles are environmentally friendly energy sources that use only water and air and are made in the device from tiny bubbles of 1/100 millimeters to 1/1000 millimeters.

Such microbubbles, unlike ordinary bubbles, are very fine bubbles having a diameter of 50 μm (micrometers) or less and micro bubbles having a micro bubble diameter of 1 to 50 μm.

The color is milky, with micro bubbles bursting out of water and then disappearing and disappearing at the same time, rising at a very slow speed. Shock waves including 40KHz ultrasonic waves generate 400km per hour, generate large amounts of negative ions and instantaneous high heat. It is known that there are properties that cause various effects, and it can be used to develop various application technologies.

As a result of the experiment that microbubbles can help blood circulation of human body, the hot spring using microbubbles is recognized as the bactericidal effect and the active effect on living organisms with ozone-containing water, so it can be used in medical, health, food processing, agricultural water, fish farm, etc. It is expected to be utilized.

In addition, the washing technology of vegetables and fruits can remove various pesticides remaining on the surface, and by easily discharging waste products remaining on the skin of the human body, it is not only excellent effect for skin beauty, but also fatigue by muscle massage and relaxation of the human body. Functions to help recovery are known.

Microbubble generating devices for using various functions of such microbubbles are disclosed in various forms.

Republic of Korea Patent No. 10-0748580 is a micro-sized fine due to friction while passing through a porous hole nozzle while compressing at high pressure while injecting a small amount of water and injecting a small amount of air with a pump while injecting a small amount of air It is disclosed to generate bubbles.

The conventional micro-bubble generating device has a pump for pumping and circulating water in a tank, an air supply valve for supplying air to the circulating water, and a compression cylinder, and at the same time, the high-pressure compressed water is discharged to the exhaust side and is rubbed. In order to generate a large amount of microbubbles, a specially manufactured micro nozzle must be separately configured.

However, the conventional microbubble generator has a limitation of generating a large amount of microbubbles in a limited time because it has to pass high pressure water through a specially manufactured micro nozzle, and has a limitation in reducing manufacturing costs due to the complicated structure of the overall apparatus. there was.

In addition, when it is necessary to adjust the size of the micro-bubble according to the use of the application technology, there was a problem that it is difficult to control it easily and finely.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to provide a micro-bubble generating device that can generate a large amount of micro-bubbles at low cost and high efficiency, and the overall structure is simple to reduce the manufacturing cost. .

As a specific means for achieving the above object, the present invention is an outer casing having a sealed inner space of a certain size; An inner casing disposed in an inner space of the outer casing such that an upper end opened from a closed ceiling surface of the outer casing is spaced at a predetermined interval, and a lower end is spaced at a predetermined interval from a bottom surface of the outer casing; An outlet end is disposed in the inner casing through the outer casing, and a supply flow of water and air supplied into the inner space of the inner casing is provided in the middle of a length of a supply passage through which a water is supplied with water through a motor pump. A supply pipe having at least one rotary wing that rotates in one direction and mixes water and air to generate microbubbles primarily; And an outlet pipe having an inlet end disposed in the outer casing, and having a valve-shaped nozzle part formed in the middle of the length while opening and controlling the discharge flow path through which water and bubbles filled in the outer casing are discharged, to generate micro-bubbles when opened. A valve body mounted in the middle of the length of the discharge pipe by discharging the microbubbles generated primarily by the internal pressure of the outer casing through the valve-type nozzle unit together with water to generate the microbubbles in the secondary, and discharged to the outside; The ball valve is rotated by a handle of rotation of the handle inside the valve body, the ball valve is formed through the inner hole coinciding with the central hole of the valve body, inserted and assembled through the incision cut in the ball valve, A nozzle plate through which a nozzle hole is formed on a corresponding outer surface, wherein the outer casing can measure an internal pressure. A pressure gauge, and when the internal pressure of the outer casing is increased by a pressure gauge to be greater than a preset pressure value, the ball valve is rotated 180 degrees by a reverse rotation operation of the knob to penetrate the nozzle plate. It provides a micro-bubble generating device, characterized in that to remove the foreign matter blocked in the end of the nozzle hole by the discharge pressure of the water by switching the position 180 degrees.

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Preferably, the lower end of the inner casing is opened via a spacer provided on the closed bottom surface of the outer casing.

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Preferably, the supply pipe is connected to the motor pump so as to increase the supply pressure of air together with the water supplied to the inner space of the outer casing and the inner casing, respectively, the first and second supply pipes for supplying air together with the water. Connect the pipes.

According to the present invention as described above, the air supplied to the inside of the inner casing together with the water through the supply pipe is primarily mixed through a rotary blade provided in the middle of the supply pipe, and filled in the inner space of the outer casing through the inner casing In addition to the water, the air passes through the valve-type nozzle portion and generates microbubbles as the air is passed through the valve-type nozzle portion when the internal pressure of the outer casing is higher than atmospheric pressure. Since it can be refined to the outside and discharged to the outside through the outlet end of the discharge pipe, it is possible to generate a large amount of fine bubbles at low cost and high efficiency.

In addition, since the size of the bubbles can be easily and accurately adjusted by adjusting the internal pressure of the outer casing, the effect of varying the size of the microbubbles in accordance with the intended use can be utilized in various applications.

1 is a longitudinal sectional view showing a microbubble generating device according to a preferred embodiment of the present invention.
2 is a perspective view showing a micro-bubble generating device according to a preferred embodiment of the present invention.
3 is a detailed view showing a nozzle unit employed in the microbubble generating device according to the preferred embodiment of the present invention.
4 is a longitudinal sectional view showing another form of the microbubble generating device according to the preferred embodiment of the present invention.
5a to 5c is a process diagram showing an operating state of the micro-bubble generating device according to a preferred embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, it will be described in detail a preferred embodiment of the present invention.

Microbubble generating device 100 according to a preferred embodiment of the present invention, as shown in Figures 1 to 3, the outer casing 110, the inner casing 120, the supply pipe 130 and the discharge pipe 140. do.

The outer casing 110 is formed of a substantially cylindrical structure having an internal space of a predetermined size, the outer surface is provided with a pressure gauge 111 to measure the internal pressure to know the pressure state, and is provided with a pressure switch 112 can do.

Here, the upper surface of the outer casing 110 is easy to assemble the inner casing 120, it may be provided with a cover type to seal the inner space when closed.

In addition, the outer casing 110 includes a drain pipe 115 having a valve member 115a in the middle of the length so as to discharge the water filled therein during the non-operation.

The inner casing 120 is disposed in the inner space of the outer casing 110, and the bottom surface is a substantially cylindrical structure that is closed and opened upward.

The open upper end of the inner casing 120 is spaced apart from the closed ceiling surface of the outer casing 110 at a predetermined interval, and the lower end of the inner casing 120 is the bottom surface of the outer casing 110. Spacer 122 is raised through the medium so as to be spaced apart from the spacer 122.

Accordingly, the water supplied to the inside of the inner casing 120 is gradually filled from the bottom surface of the inner casing, overflows through the open upper end is gradually filled from the bottom surface of the outer casing 110.

Here, the outer casing 110 and the inner casing 120 is preferably made of a metal to withstand the internal pressure.

In addition, the outer casing 110 and the inner casing 120 is illustrated and described as being made of a cylindrical structure, but is not limited thereto, and may be made of a polygonal box structure such as an oval or a triangle or a quadrangle according to a design.

The supply pipe 130 is the inlet end is connected to the motor pump (P), the outlet end is a pipe member of a predetermined length that is disposed at any position of the inner space of the inner casing 120 through the outer casing (110). .

The supply pipe 130 has at least one rotary blade 132 so as to mix the water and air in the supply passage through which the air is supplied with water through the motor pump (P) connected to the inlet end.

The rotary blade 132 is provided in the middle of the length of the supply pipe 130 to mix the water and air supplied by the motor pump supply of water and air supplied to the inner space of the inner casing 120 It naturally rotates in one direction by the flow, and firstly mixes them to generate bubbles.

The rotary blade 132 is preferably installed to be orthogonal to the supply direction of the water containing air in the shaft member of the support bar installed on the inner surface of the supply pipe, a plurality of spaced at a predetermined interval in the longitudinal direction of the supply pipe 130 Can be installed.

Here, the contact portion where the supply pipe 130 and the outer casing 110 are in contact with each other and the contact portion where the supply pipe 130 and the inner casing 120 are in contact with each other are welded or sealed so that external flow of water and air is difficult. It is preferable to be.

Accordingly, water and air are primarily mixed while passing through the impeller 132 to generate bubbles, and the bubbles generated at this time are discharged through the outlet end of the supply pipe 132 together with the water to form the inner casing 120. It will be slowly filled from the bottom of the to the open top end.

At this time, since the supply flow rate of water and air supplied into the outer casing is larger than the fluid discharge flow rate discharged to the outside through the discharge pipe 140, the internal pressure of the outer casing 110 gradually increases. In addition, the internal pressure applied to the water surface of the outer casing 110 is also increased.

The discharge pipe 140 is an inlet end is located at any position of the inner space of the outer casing 110, the outlet end is a certain length of the tubular member extending from the inside of the outer casing to be located outside.

Here, the inlet end of the discharge pipe 140 is shown and described as being installed close to the bottom surface of the outer casing 110, but is not limited thereto, and may be located at various heights.

In the middle of the length of the discharge pipe 140 is exposed to the outside of the outer casing 110 is filled from the bottom surface of the outer casing 110, and the opening and closing control of the discharge flow path that the air bubbles are discharged with the water by the internal pressure The valve-type nozzle unit 142 is further provided to further refine the size of bubbles passing through to generate fine bubbles having a size smaller than the bubbles in the outer casing 110.

The valve-type nozzle unit 142 is the valve body 142a mounted in the middle of the length of the discharge pipe 140 and the valve to be rotated manually by the handle 144 or automatically by the control signal of the pressure switch A ball valve 142d provided inside the body 142a and penetrating the inner hole 142c coinciding with the central hole 142b of the valve body 142a, and cut into the ball valve 142d. The nozzle plate 143 is inserted and assembled through the cutout 142e and penetrates through the nozzle hole 143a on an outer surface corresponding to the inner hole 142c.

The ball valve 142d is connected to the handle 144 via a key member 142f assembled to an outer surface of the body, and thus the inner hole 142c is formed in accordance with a rotation operation of the handle 144. The discharge passage is opened in accordance with 142b or the body outer surface of the ball valve 142d is aligned with the central hole 142b to block the discharge passage.

Then, when the inner hole 142c and the central hole 142b coincide with each other by the rotation operation of the handle 144, the nozzle plate 143 through the nozzle hole 143a formed of a porous body by laser processing. As air passes along with water, a large amount of fine bubbles are generated, and the fine bubbles generated while passing through the nozzle hole 143a are discharged to the outside through the outlet end of the discharge pipe 140.

In addition, when the nozzle hole 143a is blocked by the foreign matter contained in the water, the amount of generation of micro bubbles decreases and the internal pressure of the outer casing 110 becomes larger than a preset pressure value. The ball valve 142d is rotated by 180 degrees by a reverse rotation operation to change the position of the nozzle hole 143a formed through the nozzle plate 143 by 180 degrees to remove foreign substances blocked at the end of the nozzle hole 143a. It can be removed naturally by the discharge pressure of water.

Here, the ball valve 142d is to visually check the pressure gauge 111 that is raised when the internal pressure of the outer casing 110 is higher than the reference pressure value to switch the handle 180 degrees or the outer casing 110 When the internal pressure of the higher than the reference pressure value can be rotated 180 degrees by an actuator (not shown) electrically connected to the pressure switch for generating a control signal.

When the handle is rotated 90 degrees while the inner passage 142c of the ball valve is aligned with the central hole 142b of the valve body 142a, the outlet flow path is opened. The surface coincides with the central hole 142b to block the discharge flow path.

On the other hand, the supply pipe 130 is connected to the motor pump (P), respectively, as shown in Figure 4 so as to increase the supply pressure of air together with the water supplied to the inner space of the outer casing and the inner casing and the water and In addition, the first and second supply pipes 130a and 130b supplied with air may be configured by connecting the tee pipe 135.

When operating the motor pump (P) connected to the inlet end of the supply pipe 130 in the microbubble device 100 of the present invention having the above configuration, as shown in Figure 5a, the air together with the water is the outer casing ( It is supplied to the inner casing 120 through the supply pipe 130, the outlet end is located in the interior of the inner casing 120 through the 110.

In addition, air contained in the water supplied to the inner casing 120 through the supply pipe 130 collides with the rotary blade 132 provided in the middle of the supply pipe 130 and is mixed with water to have bubbles having a small size. The first is generated, the generated bubbles are gradually filled from the bottom surface of the inner casing 120 to the open upper end.

At this time, the internal pressure of the outer casing 110 is gradually increased to have a pressure higher than the atmospheric pressure by the air supplied through the supply pipe, the rising internal pressure can be visually confirmed through the pressure gauge 111.

The ball valve 142d of the valve-type nozzle unit 142 provided in the discharge pipe 140 opens the discharge passage by matching the inner hole 142c in which the nozzle plate 143 is disposed with the center hole 142b. As the air in the outer casing 110 is discharged to the outside through the nozzle hole (143a) of the nozzle plate 143, the discharge of the fluid including the air discharged to the outside through the nozzle hole (143a) is Since the supply amount of the fluid including the air supplied to the inside of the outer casing 110 through the supply pipe 130 is relatively smaller than the internal pressure of the outer casing is raised above atmospheric pressure.

Subsequently, bubbles including water to be filled from the bottom surface of the inner casing 120 to the open upper end flow over the open upper end of the inner casing 120, as shown in FIG. 5B. It is gradually filled from the bottom surface of the outer casing, the water level is raised to a position higher than the end of the discharge pipe 140.

In addition, as the internal pressure higher than atmospheric pressure is added to the surface of the water including bubbles to be filled in the outer casing 110, the water including the bubbles is shown in FIG. 5C, the discharge pipe 140. It is discharged to the outside through the inlet end of.

In addition, through the nozzle hole 143a formed in the nozzle plate 143 of the valve-type nozzle unit 142 provided in the middle of the discharge pipe 140, the bubble passes along with the water while generating a frictional force and having a smaller size. Micro bubbles are generated, and the generated micro bubbles are discharged to the outside through the outlet end of the discharge pipe together with the water.

In the above, although one preferred embodiment of the present invention has been described, it is clear that the present invention may use various changes, modifications, and equivalents, and may be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

110: outer casing 120: inner casing
120: inner casing 122: spacer
130: supply pipe 132: rotary wing
140: discharge pipe 142: valve type nozzle portion
143: nozzle plate 144: handle

Claims (5)

An outer casing having a sealed inner space of a predetermined size;
An inner casing disposed in an inner space of the outer casing such that an upper end opened from a closed ceiling surface of the outer casing is spaced at a predetermined interval, and a lower end is spaced at a predetermined interval from a bottom surface of the outer casing;
An outlet end is disposed in the inner casing through the outer casing, and a supply flow of water and air supplied into the inner space of the inner casing is provided in the middle of a length of a supply passage through which a water is supplied with water through a motor pump. A supply pipe having at least one rotary wing that rotates in one direction and mixes water and air to generate microbubbles primarily; And
An inlet end is disposed in the outer casing, and includes a discharge pipe having a valve-type nozzle portion formed in the middle of the length to open and control the discharge flow path through which water and bubbles filled in the outer casing are discharged, and generate micro bubbles at the time of opening. The microbubbles generated primarily by the internal pressure of the high external casing pass through the valve-type nozzle unit together with the water to generate microbubbles in the secondary and discharge them to the outside,
A valve body mounted in the middle of the discharge pipe, a ball valve which is rotated by a rotary operation of a handle inside the valve body, and penetrates an internal hole coinciding with the central hole of the valve body; It is inserted through the cut portion is assembled and comprises a nozzle plate through the nozzle hole formed on the outer surface corresponding to the inner hole,
The outer casing is provided with a pressure gauge to measure the internal pressure,
When the internal pressure of the outer casing is increased by a pressure gauge greater than a preset pressure value, the ball valve is rotated 180 degrees by the reverse rotation operation of the handle to change the position of the nozzle hole formed through the nozzle plate by 180 degrees. By removing the foreign matter blocked in the end of the nozzle hole by the discharge pressure of the water. delete The method of claim 1,
The inner casing is a micro-bubble generating device, characterized in that the lower end is opened through the spacer provided on the closed bottom surface of the outer casing. delete The method according to any one of claims 1 to 3,
The supply pipe is connected to the motor pump so as to increase the supply pressure of air together with the water supplied to the inner space of the outer casing and the inner casing, respectively, the first and second supply pipes through which the air is supplied together with the water through the tee pipe. Microbubble generating device, characterized in that connected to.

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