KR101203117B1 - Nano-bubble generator - Google Patents

Abstract

The present invention relates to a nanobubble generating device capable of generating nano-sized bubbles. In particular, the present invention is characterized in that it comprises a plurality of mixing pumps are connected to each other in series so that the microbubbles are generated by shearing the gas by mixing and pressurizing the fluid and the gas, respectively, so that the microbubbles can be further finely sequentially. It presents a nanobubble generating device.

Description

Nano-bubble generator

The present invention relates to a nanobubble generating device capable of generating nano-sized bubbles.

By using the biological activity effect, physical chopping effect, and droplet effect of microbubbles, microbubbles are applied in various fields such as water purification and hydroponic cultivation, fish farming, cleaning / cleaning, medical care, bathing facilities, washing machines, etc. It is applied.

Therefore, research on the method for generating microbubbles more effectively has been actively conducted.

In particular, in order to increase the biological activity (activity), physical chopping (dropping effect), droplet effect, etc. of the microbubble to generate the microbubble in the finest size as possible, so that the microbubble to maintain a stabilized form for a long time, The focus is on creating a.

However, in order to generate finer microbubbles, very strong shearing force is required, and technical implementation of capacity and driving speed is limited in reality.

In addition, time is required to physically make the bubbles sufficiently fine, and there is an urgent need for research on a method for stably generating micro bubbles in a sufficiently fine size in a short time.

The present invention has been made to solve the above problems, it is possible to generate a nano-sized micro-bubbles, that is, nanobubbles, nanobubble generating device that can maintain the generated nanobubbles in a stabilized form for a long time To provide for that purpose.

Still another object of the present invention is to provide a nanobubble generating device capable of stably generating nanobubbles in a short time.

In order to solve the above problems, the present invention shears the gas by mixing and pressurizing the fluid and the gas, respectively, to generate microbubbles, and a plurality of mixing pumps connected in series to each other so that the microbubbles can be further miniaturized sequentially. It proposes a nanobubble generating device comprising a.

The plurality of mixing pumps may include: a first mixing pump supplied with the fluid and a gas and generating the micro bubbles; And a second mixing pump supplied with a gas-liquid mixed stream in which microbubbles are generated by the first mixing pump, and further miniaturizing the microbubbles.

The first mixing pump may be connected to a fluid supply pipe to which the fluid is supplied and a gas supply pipe to which the gas is supplied.

It may further include a gas ejection unit for ejecting the gas to the gas-liquid mixture flow generated microbubble flowing from the previous mixing pump.

The gas blowing unit may be connected in the middle of a mixing pump connection line connecting the mixing pump and the mixing pump.

The gas blowing unit is blown in a state inclined in the flow direction on the mixing pump connection line toward the end of the mixing pump connection line with respect to the vertical direction of the flow direction on the mixing pump connection line connecting the mixing pump and the mixing pump. It may include a tube.

The gas blowing unit may include a blowing tube consisting of a small diameter portion is relatively reduced in the inner diameter of the end portion from which the gas is ejected.

The ejection pipe may have a larger inner diameter than the small diameter portion to include a large diameter portion connected to the small diameter portion, and the inner diameter of the small diameter portion side end portion of the large diameter portion may be gradually reduced.

The small diameter part of the jet pipe is connected to a mixing pump connecting line connecting the mixing pump and the mixing pump, and an inner diameter thereof may be smaller than an inner diameter of the mixing pump connecting line.

As described above, according to the present invention, various effects including the following can be expected. However, the present invention does not necessarily achieve the following effects.

First, since microbubbles are further refined, nano-sized bubbles, that is, nanobubbles can be easily generated.

In addition, nanobubbles can be generated stably in a short time.

In addition, each component for generating the nanobubble, that is, the load, such as the capacity or driving speed required for the mixing pump, the gas blowing unit, etc. do not act in the limit, it is easy to implement the technical.

1 is a block diagram of a nanobubble generating device according to an embodiment of the present invention.
2 and 3 is a graph of the relative molecular weight of the microbubbles generated by the nanobubble generating device according to an embodiment of the present invention.

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

However, in describing the present invention, a detailed description of known functions or configurations will be omitted in order not to disturb the gist of the present invention.

As shown in FIG. 1, the nanobubble generating device according to an embodiment of the present invention includes mixing pumps 10 and 20 that generate fine bubbles by shearing a gas by mixing and pressurizing a fluid and a gas. In particular, the mixing pump (10, 20) may be characterized in that a plurality of in series, that is, connected in series structure so that the fine bubbles can be further finer in sequence.

Fluid and gas flowing into the mixing pump (10, 20) can be used in various ways depending on the use of the nanobubble generated by the nanobubble generating device of the present invention, it is used for water purification, shellfish culture, bathing, etc. Examples of water include water and gases such as air and oxygen.

The mixing pumps 10 and 20 rotate the fluid and the gas vigorously at high speed, thereby forming a strong vortex due to the action of the centrifugal force and centripetal force, and the collision and disturbance caused by the high flow rate, thereby mixing the fluid and the gas. In addition, the gas is pressurized, sheared to generate microbubbles. As the mixing pumps 10 and 20, the turbine mixing pumps 10 and 20 and the vortex mixing pumps 10 and 20 having excellent mixing and pressurizing actions may be used. Hereinafter, the mixing pumps 10 and 20 for generating microbubbles are well known in the technical fields, such as water purification and fish farming, and bathing, and the present invention proposes a method for making microbubbles more fine. In order to not obscure the subject matter of the present invention, further detailed description is omitted.

The plurality of mixing pumps 10 and 20 include, in particular, a first pump 10 to which fluid and gas are supplied and to generate micro bubbles; The first pump 10 is supplied with a gas-liquid mixed stream in which the micro-bubbles are generated, the second pump 20 for further miniaturizing the micro-bubbles; may include.

That is, the first pump 10 may be connected to the fluid supply pipe 12 is supplied with the fluid and the gas supply pipe 14 is supplied to the gas separately structurally so that the fluid and the gas can be introduced separately. . In addition, the first pump 10 may be connected to the second pump 20 through a mixing pump connecting line 16 structurally separated from the fluid supply pipe 12 and the gas supply pipe 14. The second pump 20 has a mixing pump connecting line 16 connected to one side of the first pump 10 and a gas-liquid mixed flow in which microbubbles are generated from the second pump 20 on the other side of the second pump 20. The discharge line 22 to be discharged may be connected. In this case, the first pump 10 may separately mix the gas and the fluid introduced separately and pressurize to generate microbubbles, and the second pump 20 is a gas-liquid mixed flow in which microbubbles are generated. By further pressing the microbubbles can be further refined.

On the other hand, the nanobubble generating device according to an embodiment of the present invention may further include a gas ejection unit for ejecting the gas to the gas-liquid mixture flow in which the micro-bubbles flowing from the previous mixing pump (10,20) is generated. .

That is, the gas-liquid mixed flow generated by the microbubbles flowing from the first pump 10 to the second pump 20 flows strongly by the pumping force of the first pump 10 and the second pump 20. In the meantime, by intensely colliding with and disturbing the gas ejected by the gas ejection unit, the fine bubbles on the mixing pump connecting line 16 can be further refined.

The gas ejection part is connected to the mixing pump connection line 16 so that the ejection pipe 30 for ejecting gas is not mixed with the microbubble generating action by the mixing pumps 10 and 20. It may be connected in the middle of the mixing pump connecting line 16 for connecting the mixing pump (10, 20). At this time, the blowoff pipe 30 may be connected to a pump for gas pumping to facilitate gas ejection, but the gas may be introduced into the mixing pump connecting line 16 by a negative pressure on the mixing pump connecting line 16. It does not need to be connected to a separate power source such as a pump. In addition, the ejection pipe 30 may be installed in such a state that an end in which the gas ejected into the mixing pump connection line 16 is introduced, that is, the inlet end is opened in the air so that air in the atmosphere may be ejected through the gas ejection part. When the gas ejected through the gas ejection unit is limited to oxygen or nitrogen, the gas may be connected to a tank in which oxygen or nitrogen is stored.

Further, the blowoff pipe 30 has a mixing pump connecting line 16 toward the end of the mixing pump connecting line 16, that is, the inlet end of the mixing pump connecting line 16, that is, the end of the mixing pump connecting line 16. With respect to the vertical direction (V) in the upward flow direction), it may be connected in a state inclined at a predetermined angle (θ) in the flow direction on the mixing pump connecting line 16. Accordingly, since the ejection direction of the gas ejected from the gas ejection part to the mixing pump connecting line 16 may be directed toward the flow direction of the gas-liquid mixed flow in which the microbubbles on the mixing pump connecting line 16 are generated, It is possible to prevent the flow resistance on the mixing pump connecting line 16 due to the gas blowing by the blowing unit, as well as to accelerate and pressurize the flow on the mixing pump connecting line 16, thereby being ejected by the gas blowing unit. The gas and the gas-liquid mixed flow generated by the microbubbles flowing on the mixing pump connecting line 16 are more intensely collided and disturbed, so that the microbubbles can be made more fine.

In addition, the ejection pipe 30 may be formed of a small diameter portion 34 in which the inner diameter of the end portion of the gas is ejected is relatively reduced. In this case, the ejection speed of the gas ejected from the gas ejection part to the mixing pump connecting line 16 by the fluid dynamics is accelerated, so that the gas ejected by the gas ejecting part and the microbubbles flow on the mixing pump connecting line 16. The shear force of the generated gas-liquid mixture flows largely, and the microbubbles can be further refined. At this time, the small diameter portion 34 of the ejection pipe 30 may be formed smaller than the inner diameter of the mixing pump connecting line 16, in order to increase the acceleration effect.

At this time, the ejection pipe 30 has a larger inner diameter than the small diameter portion 34 includes a large diameter portion 32 connected to the small diameter portion 34, and the small diameter portion of the large diameter portion 32 to minimize the flow resistance The inner diameter of the (34) side end portion 32A can be gradually reduced.

Therefore, increasing the driving speed, capacity, etc. of each of the mixing pumps 10 and 20 has limitations in miniaturizing the microbubbles due to limitations such as cost and technical implementation, but the nanobubble generating device according to the present invention has a first pump ( The microbubbles generated by 10) are further refined by the front end with the gas ejected from the gas ejection part and the front end with the second pump 20, thereby reducing the size of the nano-size as shown in FIGS. 2 and 3. It is possible to easily generate microbubbles, that is, nanobubbles. Since the nanobubbles are very fine bubbles, they are excellent in biological activity, physical chopping effect, and droplet effect, and can be maintained in a stabilized form for a long time.

In addition, time is required to apply a sufficient shear force to shear the gas to generate micro bubbles, the nanobubble generating device according to the present invention, as shown in FIG. Since it is possible to generate nanobubbles, it is possible to stably generate nanobubbles in a sufficiently fine size, that is, nanobubbles in a short time.

That is, the nanobubble generating device according to the present invention can easily and quickly generate the nanobubble, as well as the technical implementation of the mixing pump (10, 20) and the gas ejection unit capacity or driving speed for it.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

10; First pump 20; 2nd pump
30; Squirt tube

Claims (9)

A plurality of mixing pumps each of which mixes and pressurizes a fluid and a gas to shear the gas to generate microbubbles, and are connected in series to each other so that the microbubbles can be further miniaturized sequentially; And
A gas ejection unit for ejecting gas into the gas-liquid mixed stream in which the fine bubbles flowing from the mixing pump are generated;
Including;
The gas blowing unit is a nanobubble generating device, characterized in that connected to the middle of the mixing pump connecting line connecting the mixing pump and the mixing pump. The method according to claim 1,
The plurality of mixing pumps,
A first mixing pump supplied with the fluid and the gas to generate the micro bubbles;
A second mixing pump supplied with a gas-liquid mixed stream in which microbubbles are generated by the first mixing pump, and further miniaturizing the microbubbles;
Nanobubble generating device comprising a. The method according to claim 2,
The first mixing pump is a nanobubble generating device, characterized in that the fluid supply pipe and the gas supply pipe to which the fluid is supplied are connected, respectively. delete delete A plurality of mixing pumps each of which mixes and pressurizes a fluid and a gas to shear the gas to generate microbubbles, and are connected in series to each other so that the microbubbles can be further miniaturized sequentially; And
A gas ejection unit for ejecting gas into the gas-liquid mixed stream in which the fine bubbles flowing from the mixing pump are generated;
Including;
The gas blowing unit is connected to the mixing pump connected to the mixing pump in a state inclined in the flow direction on the mixing pump connecting line toward the end of the mixing pump connecting line with respect to the vertical direction of the flow direction on the mixing pump connecting line connecting the mixing pump Nanobubble generating device comprising a. A plurality of mixing pumps each of which mixes and pressurizes a fluid and a gas to shear the gas to generate microbubbles, and are connected in series to each other so that the microbubbles can be further miniaturized sequentially; And
A gas ejection unit for ejecting gas into the gas-liquid mixed stream in which the fine bubbles flowing from the mixing pump are generated;
Including;
The gas blowing unit is a nanobubble generating device comprising a blower tube consisting of a small diameter portion relatively reduced in the inner diameter of the end of the gas is ejected. The method of claim 7,
The blower pipe has a larger inner diameter than the small diameter portion, and includes a large diameter portion connected to the small diameter portion, wherein the inner diameter of the small diameter portion side end portion of the large diameter portion is characterized in that the nanobubble generating device. The method of claim 7,
The small diameter portion of the jet pipe is connected to the mixing pump connecting line for connecting the mixing pump and the mixing pump, the inner diameter of the nanobubble generating device, characterized in that the inner diameter is formed smaller than the inner diameter of the mixing pump connecting line.

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