KR101292601B1 - Micro-bubble generator - Google Patents

Abstract

PURPOSE: A microbubble generating device is provided to prevent the corrosion of mechanical parts due to a cavitation phenomenon generated by the rotation of an impeller and to generate fine bubbles by generating the vortexes of water and inflow air to opposite directions. CONSTITUTION: A microbubble generating device comprises a pump (10), an ejector (20), a discharging pipe (30), a spiral groove socket (40), and an air injecting pipe. The pump comprises a fluid inlet (12) and an outlet. Fluid flows through the inlet and is discharged by the torque of an impeller (16) in connection with a motor (14). One side of the ejector is in connection with the outlet of the pump. The discharging pipe is installed on another side of the ejector. One part in the spiral groove socket with a spiral groove is in connection with one end of the ejector. The air injecting pipe is in connection with another part of the spiral groove socket. Another part of the spiral groove socket is expanded on the surface of water.

Description

Micro Bubble Generator {MICRO-BUBBLE GENERATOR}

The present invention relates to a microbubble generating device, and more particularly, for aeration of a septic tank (to dissolve oxygen in the air into the water to supply oxygen into the water) or in contaminated water in rivers, lakes and swamps. The present invention relates to a microbubble generating device for supplying microbubbles to improve water quality.

In farms and wastewater purification facilities, the amount of dissolved oxygen must be increased to purify water. To this end, by using a device that artificially generates oxygen-containing bubbles, the amount of dissolved oxygen is increased by supplying bubbles into the water.

Patent registration No. 100298007000 is a conventional technology for increasing the dissolved oxygen by supplying bubbles in the water.

Patent registration No. 100298007000 is a device that is installed so that the pump is submerged under the surface of the water and sucks water through the suction port and pressurizes it to the discharge port. When the air inlet pipe is connected and the pump is operated while the open end of the air inlet pipe is protruded out of the water surface, the impeller rotates to suck water through the pump inlet to discharge water through the discharge pipe.

At this time, when the suctioned water is pressurized and passes through the discharge pipe, air is sucked from the outside through the air inlet pipe by the negative pressure formed in the discharge pipe, and the sucked air is discharged together with water while being mixed in a bubble form in the flowing water. do.

In order to increase the amount of dissolved oxygen in the water, air intake must be increased and the size of bubbles containing oxygen must be minute, but the above-mentioned patent registration No. 100298007000 simply introduces air by the negative pressure caused by the flow rate of the impeller The flow rate is weak, there is a problem that the air inflow is not enough and the size of bubbles generated in the water is also large.

If the air suction force is weak, it slows down the generation of bubbles and the size of the bubbles is large, so that the dissolved time in the water is short and bubbles rise and rise vertically.

When the impeller rotates, the cavitation phenomenon (increasing the velocity of the fluid lowers the pressure near the surface of the object that is in contact with the fluid, causing the fluid to turn into less dense water vapor, resulting in a physical effect that is like creating an empty space in the water). Part of the bubbles generated by the change phenomenon gather on the impeller to form a large bubble space, which also causes the corrosion of the mechanism.

Patent 1 100298007000 (2001.09.22)

The technical problem to be achieved by the present invention to solve the above problems is to strongly inflow air only by the flow of water by the power to operate the impeller, the corrosion of the mechanical device due to the cavitation phenomenon caused by the rotation of the impeller It is to provide a micro-bubble generating device for preventing and, by vortexing the flow of water and inlet air to each other to generate more fine bubbles.

Micro-bubble generating device according to the present invention for achieving the above object is a pump having a suction port for suctioning the water and the discharge port for discharging the water introduced through the suction port by the rotational force of the impeller connected to the motor; An ejector having one side connected to an outlet of the pump; A discharge pipe installed at the other side of the ejector; A spiral groove socket having one side of which a spiral groove formed therein is connected to one end of the ejector; One side portion is connected to the other side portion of the spiral groove socket, the other side portion is formed in the air inlet pipe extending on the water surface.

The apparatus may further include an air inflow promoting device having a spiral wing formed on a surface of the cylindrical member to correspond to the spiral groove in the spiral groove socket, and generated through the spiral groove to strengthen the flow of water discharged from the discharge pipe. It further includes a microbubble generating network that installs a spiral groove and an impeller so that the direction of the vortex of the air and the vortex of the water generated by the rotation of the impeller is opposite to each other, and splits the bubbles between the ejector and the discharge pipe. It is also possible.

Looking at the effect on the micro-bubble generating device according to an embodiment of the present invention,

First, by forming a strong vortex with the spiral groove and the air inlet acceleration device inside the spiral groove socket, the air can be introduced only by the flow of water by the power to operate the impeller to strengthen the suction force of the air.

Second, a strong vortex is formed inside the spiral groove socket with a spiral groove and an air inflow facilitator, and the incoming air strengthens the flow of water. The amount is significantly reduced, which can extend the life of the machine.

Third, if the vortex direction of the inlet air and the vortex direction of the water formed by the rotation of the impeller are different from each other, a strong and rapid flow will be formed. That is, it becomes like a tornado phenomenon. The longer the time, the better the processing efficiency.

1 is a side view of a microbubble generating device according to the present invention
Figure 2 is a cross-sectional view of the microbubble generating device according to the present invention
3 is a cross-sectional view of the ejector shown in FIG.
4 is a cross-sectional view of the spiral groove socket shown in FIG.
5 is an explanatory diagram showing a state in which the apparatus of the present invention is installed;

Hereinafter, the micro-bubble generating device according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings, but some components irrelevant to the gist of the invention will be omitted or compressed, but the omitted configuration is not necessarily required in the present invention The configuration is not without, and can be used in combination by those skilled in the art.

1 is a side view of a microbubble generating device according to the present invention, Figure 2 is a cross-sectional view of the microbubble generating device according to the present invention.

In Fig. 2, "□" is water and "○" is bubble.

3 is a cross-sectional view of the ejector shown in FIG.

As shown, the micro-bubble generating device 1 according to the embodiment of the present invention is composed of a pump 10, an ejector 20, a discharge pipe 30, a spiral groove socket 40, an air inlet pipe 50. .

The pump 10 is installed to be submerged under the water surface, and water is sucked into the inside through the inlet 12 by the rotational force of the impeller 16 connected to the motor 14, and the sucked water is discharged to the outlet 18. It is provided to discharge through.

Rotation of the impeller 16 creates bubbles in the cavitation phenomenon.

The ejector 20 is one portion is connected to the outlet 18 of the pump 10, the other side corresponding to the one portion is provided to be connected to the discharge pipe (18).

The ejector 20 is a type of jet pump that sucks and discharges the fluid into the apparatus. The first fluid 28a ejected at high speed from the nozzle 24 is the second fluid 28b in the suction chamber 22. While entering, it enters the cross-sectional reduction portion 26a of the diffuser 26.

Therefore, the pressure in the suction chamber 22 is reduced, and the second fluid 28b is sucked again.

Both fluids are mixed in the cross-sectional reduction portion 26a and ejected past the cross-sectional enlargement portion 26b.

When both fluids are mixed, the kinetic energy possessed by the first fluid 28a becomes the kinetic energy of the entire mixed fluid, and then is converted to pressure as the speed decreases in the cross-sectional enlargement section 26b.

Therefore, the second fluid 28b obtains a pressure higher than the pressure in the suction chamber 22 and can be easily discharged to a place at a higher pressure than the pressure at the suction chamber 22 or the place where the second fluid 28b is present. have.

The water discharged through the outlet 18 of the pump flows more strongly while passing through the ejector 20.

The discharge pipe 30 is connected to one side portion of the ejector 20, the other portion corresponding to the one side discharges the fine bubbles to the outside.

The microbubble generating network 32 is installed between the ejector 20 and the discharge pipe 30.

In addition, the micro-bubble generating network 32 may be installed in the discharge pipe (30).

The reason why the microbubble generating network 32 is installed is to suppress the flow of strong and accelerated bubbles due to the tornado phenomenon and serve to microbubble the microbubbleed fluid once again.

Depending on the location of the micro-bubble generating network 32, the speed of the micro-bubbles vary, and the amount of the micro-bubbles may also vary.

The microbubble generating network 32 may be circular or rectangular, and may change the position of the net and the size of the net so that water and bubbles pass through and control the amount of bubbles generated.

4 is a cross-sectional view of the spiral groove socket shown in FIG.

One side of the spiral groove socket 40 having a spiral groove 42 formed therein is connected to the ejector 20, and the other side corresponding to the one side is connected to the air inlet pipe 50.

An air inflow promoting device 44 having a spiral blade 46 formed on the surface of the cylindrical member so as to correspond to the spiral groove 42 in the spiral groove socket 40 is installed.

The air inlet pipe 40 is connected to one side of one end of the ejector 20, the other side is formed to extend over the water surface.

According to the prior art patent registration 1010107290000, the water is discharged only by the rotational force of the impeller, so the flow of water is weak, so that some of the bubbles generated by the cavitation phenomenon are gathered toward the upper part of the impeller to form a large bubble space. Will be imported.

However, when the micro-bubble generating device 1 according to an embodiment of the present invention, the surface of the cylindrical member so as to correspond to the spiral groove 42 formed in the spiral groove socket 40 and the spiral groove 42. A strong vortex is formed by the installation of the air inflow facilitator 44 in which the spiral blade 46 is formed in the air, and the inflow air makes the water flow stronger, so the bubbles generated by the cavitation phenomenon are almost sucked into the water flow and collect at the top. This is significantly reduced.

Thus, the life of the machine can be extended.

The spiral groove 42 is formed inside one side of the spiral groove socket 40 so that the inflow air forms a vortex, and the air inflow promoting device 44 is accelerated by the action of water by the rotational force of the impeller 16. Further promote the inflow of air;

The direction of the vortex is reversed so that the tornado phenomenon occurs in the water already bubbled by the vortex air and the cavitation phenomenon.

When the vortex direction of the inlet air and the vortex direction of the water forming the vortex due to the rotation of the impeller 16 are different from each other, a strong and rapid flow is formed, that is, a tornado phenomenon. This lengthens the processing efficiency.

In addition, due to the installation of the spiral groove 42 and the air inlet accelerator 44 formed inside the spiral groove socket 40, the inflow of air is made naturally, and noise due to the inflow of air is reduced.

The spiral groove 42 and the air inflow promoting device 44 may be installed inside the air inlet pipe 50.

5 is an explanatory diagram showing a state in which the apparatus of the present invention is installed.

A lift chain (not shown) is connected to the lift chain ring 10b to fix the microbubble generating device 1, and a power cable 10a is connected and installed.

What has been described above is only one embodiment for implementing the micro-bubble generating device 1 according to the present invention, the present invention is not limited to the above-described embodiment, as claimed in the following claims Without departing from the gist of the invention, anyone of ordinary skill in the art to which the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

1: micro bubble generator 10: pump
10a: power cable 10b: lift chain hook
12 pump inlet 14 motor
16 impeller 18 pump outlet
20: ejector 22: suction chamber
24: nozzle 26: diffuser
26a: section reduction part 26b: section expansion part
28a: first fluid 28b: second fluid
30: discharge pipe 32: fine bubble generating network
40: spiral groove socket 42: spiral groove
44: air inlet accelerator 46: spiral wing
50: air inlet pipe

Claims (5)

A pump 10 having a suction port 12 for sucking the fluid and a discharge port 18 for discharging the fluid introduced through the suction port 12 by the rotational force of the impeller 16 connected to the motor 14;
An ejector 20 having one side connected to the outlet 18 of the pump 10;
A discharge pipe (30) installed at the other side of the ejector (20);
A spiral groove socket 40 having one side of the spiral groove 42 formed therein and connected to one end of the ejector 20; And
An air inlet pipe 50 connected to the other side of the spiral groove socket 40 and the other side of which is formed on the water surface;
Microbubble generating device comprising a.
The method of claim 1,
Microbubble generating device further comprises an air inlet accelerator 44 formed with a spiral blade 46 on the surface of the cylindrical member to correspond to the spiral groove 42 in the spiral groove socket 40 .
The method of claim 1,
In order to strengthen the flow of water discharged from the discharge pipe 30, the spiral of the air generated through the spiral groove 42 and the direction of the swirl of water generated by the rotation of the impeller 16 are opposite to each other Microbubble generating device, characterized in that for installing the groove 42 and the impeller (16).
The method of claim 1,
Microbubble generating device further comprises a microbubble generating network (32) which serves to split the bubble between the ejector (20) and the discharge pipe (30).
The method of claim 1,
Microbubble generating device further comprises a microbubble generating network (32) which serves to split the bubbles inside the discharge pipe (30).

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