KR101179885B1 - Nano-buble generator and method of using the same - Google Patents

Abstract

PURPOSE: A valve for a nano-bubble generation apparatus, and a usage method thereof are provided to enable users to easily control the generation quantity of nano-bubbles by freely choosing bamboo filterers. CONSTITUTION: A valve for a nano-bubble generation apparatus comprises the following: a body unit(110) for inserting and discharging gas; a bamboo filter member(120) installed inside the body unit for changing the inserted gas into nano-bubbles; a filter fixing member(130) fixing the bamboo filter member to the body unit; a gas inlet receiving the high pressure gas from the outside; a filter mounting unit(114) and a filtering coupling groove(118) forming the insertion space of the bamboo filter member; a gas outlet dissolving the nano-bubbles to water; and a second coupling groove(138) coupled with the bamboo filter member. The bamboo filter member is obtained by cutting bamboo materials into a circular shape, a square shape, a rectangular shape, a parallelogram shape, or an oval shape. The filter mounting unit includes filter sliding grooves on the inner surface.

Description

Nano-buble Generator and Method of Using the Same

The present invention relates to a valve for a nano-bubble generating device and a method of using the same, and more particularly, a nano-bubble generating device which can freely select and use a bamboo filter for generating nano-bubbles in water and can easily control the amount of nano-bubble generated. The valve | bulb and the method which can use the valve more efficiently are related.

Today, many techniques have been developed for producing fine bubbles in water and dissolving the fine bubbles in water. When bubbles are generated in water, the bubbles generally float above the water, but minute bubbles are dissolved in the water and remain. The smaller the size of the bubbles in water, the smaller the size of the bubbles, the more they do not float on the surface of the liquid, but remain in the liquid as it is, or are reduced by external pressure in the liquid and finally rupture, It is known to dissolve into the liquid.

In addition, recent experiments have shown that when the size of microbubbles is larger than 50 micrometers, they float on the surface within a few seconds and diffuse into the atmosphere, but when the size is 50 micrometers to several hundred nanometers, It has been reported to remain in the water without being injured immediately and to be able to remain underwater for up to six months.

On the other hand, if the introduction of a method for generating micro-bubbles generally known today, it can be exemplified below, such as pressure dissolution method, ultra-high speed rotation method, water spray method and membrane method.

Dissolved gas method (Dissolved gas method) is a method of dissolving the gas in the water or beverage by filling the gas of high pressure in a state filled with water or beverage in the sealed container. However, this method has a disadvantage in that the gas dissolved in the water or the beverage is released from the inside of the container at the moment of opening the sealed container and released to the outside. In addition, this method has a disadvantage in that the fine bubbles cannot be dissolved at the source.

Hydrodynamic method is a method in which water and oxygen are simultaneously sprayed on a motor propeller (rotational speed: about 10,000 to 20,000 rpm) that rotates at high speed so that oxygen gas is forcibly adsorbed on the surface of water particles. However, this method has a disadvantage in that the fine physicochemical structure of the liquid material is broken by the high-speed rotational force, and in particular, drinking water is not preferable because the water is stressed during the manufacturing process. In addition, such a method has a disadvantage in that a large amount of energy must be supplied in order to obtain a high speed rotational force, and has a disadvantage of limiting the dispersion force of the gas by the high speed rotation.

Water exposure method is a method of injecting water into the upper space of the oxygen tank in order to make water contact with oxygen, it is repeatedly sprayed until the desired oxygen concentration is reached. However, this method has a disadvantage in that it is difficult to produce a high concentration of oxygen water in terms of commercial use, and the productivity is low and the utilization is very low. On the contrary, it becomes a so-called dissolved air flotation method, which generates fine air bubbles in the water, bubbles are dissolved in the water while the air bubbles move upwards, and are dissolved in the water at the same time. Contaminants (flocs) are raised with bubbles to purify the water. However, this method has a disadvantage in that the above bubbles must be largely formed and cannot be formed to 50 microns or less.

The membrane method is a method of forming a porous filter using a porous ceramic as a material capable of forming fine bubbles, and forming a fine bubble using a porous membrane by the porous filter. However, this method still has technical limitations that cannot form nanoporous microporous membranes as ceramic or metal materials to this day.

Today, experiments using various methods have gradually revealed that drinking water with fine bubbles of several tens of micrometers or nanoscales provides a very useful effect that has not been known so far. However, liquids containing such microbubbles are present only theoretically yet, and appear to have not been substantially developed. If you look at the products shipped to the market today, you can exemplify water containing oxygen bubbles on the order of hundreds of micrometers, but the oxygen bubbles are relatively large, and people and animals generally drink them. There is a disadvantage that the effect as known is not provided. The fundamental reason why today's liquid products containing nanometer microbubbles cannot be shipped is the failure to develop filters that can produce such microbubbles.

On the contrary, in recent years, the inventors of the present invention, using a bamboo as a natural material to form nanometer-level micro-bubbles, based on this technology to establish a nanometer-sized micro-bubble forming technology by the bamboo filter method It came to the following. This method was first developed by one of the inventors of the patent application, and a number of patent applications have been filed using this method.

By the way, the bamboo filter method developed by the present inventors should use a cylinder between each node and the bark of bamboo, or split the cylinder in half and use a connection device suitable for the diameter of the bamboo cylinder. There is a characteristic. At this time, if the bamboo cylinder is constant, there is no big problem in using the connection device, but in reality, the bamboo grows in the wild, each having a different diameter, even in the case of the same bamboo diameter of the bamboo belonging to the bottom On the other hand, since the diameter of the bamboo belonging to the top is small, it is very difficult to select and use the bamboo of the same diameter with each other.

As a result, in order to use a single connection device, it is necessary to select a large number of bamboos and find a bamboo of a suitable diameter. Therefore, there is an irrationality that must be discarded without using a large number of bamboos. They have had to develop connecting devices of various sizes, and in that case, they still faced the problem of throwing away many bamboos.

[Document 1] Korean Patent Application No. 10-2010-97260 "Method for generating microbubbles in liquid and apparatus for generating microbubbles suitable for the method" (October 7, 2010); [Document 2] Korean Patent Application No. 10-2011-2263 "Method of removing green algae and red algae using nano bubble generator" (2011. 1. 10.).

The present invention is to solve the above problems of the prior art, more specifically, the nano-bubble generating device that can be used to freely select the bamboo filter for generating nano-bubbles in water and can easily control the amount of nano-bubbles An object of the present invention is to provide a method for more efficiently using the valve for the nano-bubble generator and the valve for the nanobubble generator.

In order to achieve the above object, the present invention provides a bamboo filter which forms an overall basic shape and is responsible for the inflow and outflow of gas, and converts the gas introduced into the micro-bubble while being installed inside the body. It provides a valve for the nano-bubble generating device comprising a member and a filter fixing member for firmly coupling the bamboo filter member to the body portion.

In the present invention, the body portion is a gas inlet functioning as a passage for receiving a high-pressure gas from the outside, and a filter seating portion that is formed inside the body portion to insert the bamboo filter member, and the bamboo It comprises a gas outlet that is formed in the nano-level fine bubbles by the filter member and the fine bubbles are dissolved in water; The bamboo filter member is formed by processing natural bamboo, and is formed by cutting the bamboo wall surface formed by breaking the natural bamboo cylinder into various shapes, inserted into the filter seat portion of the high-pressure gas at the nano level It is converted into a fine bubble of; The filter fixing member is to stably fix the bamboo filter member to the body portion.

In addition, the present invention can modularize the valve for the nano-bubble generating device, it is possible to provide a set of nano-bubble generating device valve by collecting several of the valve module for the nano-bubble generating device.

In addition, the present invention can be used in various household goods used in general home life, school life or social life by using the valve for the nano bubble generator or the set nano bubble generator.

When using the valve for the nano-bubble generating device according to the present invention, since it can be used to produce a plurality of filter members by collecting bamboo grown in the natural state, except the bamboo filter suitable for the connection device as in the prior art, the rest of the bamboo There is an advantage that can be solved at the source of the absurdity to discard the material.

In addition, when using the valve for the nano-bubble generator according to the present invention, it is not necessary to use a cylindrical bamboo, it is sufficient to utilize the bamboo material, there is an advantage that can be used more efficiently using the bamboo material grown in a natural state .

In addition, when using the valve for the nano-bubble generator according to the present invention, since the filter member deposited in the water can be easily replaced and used, there is also an advantage that can greatly improve the efficiency of the filter.

In addition, when using the valve for the nano-bubble generator according to the present invention, since it can be used by combining a plurality of generators, there is an advantage that can greatly increase the amount of nano-bubbles.

1 shows a first embodiment of a valve for a nano-bubble generator according to the present invention,
1A is an exploded perspective view of a valve for a nano bubble generator,
Figure 1b is a cross-sectional view of the assembled state of the valve for the nano-bubble generator of Figure 1a,
2 shows a first embodiment of a valve for a nano bubble generator according to the present invention,
2A is an exploded perspective view of a valve for a nano bubble generator,
Figure 2b is a cross-sectional view of the assembled state of the valve for the nano-bubble generator of Figure 1a,
3 shows a third embodiment of a valve for a nano bubble generator according to the present invention,
3A is an exploded perspective view of a valve for a nano bubble generator,
Figure 3b is a cross-sectional view of the assembled state of the valve for the nano-bubble generator of Figure 1a,
Figure 4 is a conceptual diagram showing an embodiment showing a state of use of the valve for nano-bubble generator according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the accompanying drawings are only intended to describe the technical spirit of the present invention in more detail, the technical spirit of the present invention is not limited thereto, and various modifications are possible in advance.

In addition, in the accompanying drawings, the same reference numerals are used for parts performing the same function or equivalent function in realizing the technical idea of the present invention, even when they look different in form.

Figure 1 shows a first embodiment of the nano-bubble generator valve 100 according to the present invention, Figure 1a is an exploded perspective view of the nano-bubble generator valve 100, Figure 1b is the nano-bubble generation It is sectional drawing which showed the assembly state of the valve 100 for apparatuses.

Valve 100 for the nano-bubble generating device according to the present invention comprises a body portion 110 to form the overall basic shape and is responsible for the inflow and outflow of gas.

The body portion 110 includes a gas inlet 112 that serves as a passage for receiving a high pressure gas from the outside. The gas inlet 112 is a passage through which high pressure gas is supplied from the outside. There is no restriction on the manner in which the gas is supplied at a high pressure. The gas may be supplied by a high pressure compressor in a conventional manner, and may also be supplied by a high pressure gas container. The former has the advantage of being supplied in large quantities and continuously, while the user cannot move freely. On the other hand, in the latter case, it is a relatively small amount of supply and after a certain amount of consumption has to be replaced again with a new high-pressure gas container, but there is an advantage that can be freely portable, easy to install and use .

In the present invention, the above-mentioned gas is not particularly limited, but is preferably limited to a gas having a beneficial effect on the human body or animals and plants. As such a gas, any one selected from oxygen, hydrogen, nitrogen, and a carbon dioxide gas can be illustrated.

The body portion 110 includes a filter seating portion 114 that is present in the interior thereof and forms a space for inserting the bamboo filter member 120. The filter seat 114 is present in the body portion 110, it is inserted into the bamboo filter member 120 to be firmly fixed in place. At this time, it is very important that the bamboo filter member 120 and the body 110 are in close contact with each other, and no space is generated between them. If there is any space between them, the gas supplied at high pressure will leak into the above fine space, in which case it will not be possible to form microbubbles or the amount of microbubbles forming may be significantly reduced. Because.

The filter seat 114 may be appropriately modified according to the external shape of the bamboo filter member 120. For example, when the external shape of the bamboo filter member 120 is circular, quadrangular, or parallelogram, it may be formed in a circular, quadrangular, or parallelogram.

The body portion 110 includes a gas outlet 116 on the opposite side of the gas inlet 112. The gas outlet 116 refers to a portion in which the high pressure gas is formed into nano bubbles by the bamboo filter member 120. The gas outlet 116 is also a portion in which the fine bubbles are dissolved in the water in a state submerged in the water. The body part 110 may be coupled to the connection member 101 to which the high pressure gas is supplied.

The valve 100 for nano-bubble generating device according to the present invention includes a bamboo filter member 120 mounted inside the body 110.

The bamboo filter member 120 performs a function of converting the high-pressure gas supplied to the gas inlet 112 of the body portion 110 into its own micro-bubble while being transmitted through its filter member. . The bamboo filter member 120 is formed by processing natural bamboo. The reason is that in the case of artificial ceramic filter, it is possible to obtain bubbles of several hundred micrometers level, but it is not possible to obtain nano-level micro bubbles, whereas when the filter member is made of bamboo, This is because bubbles can be obtained.

Bamboo filter member 120 used in the present invention is preferably used to select from among the bamboos grown in natural conditions for one year or more. Bamboo, which has not passed one year in its natural state, is not preferable because the bamboo fiber layer therein has not sufficiently matured, so the gas permeability is weak. In general, bamboo has a different density of tissues of the inner bamboo fibrous layer depending on the number of years of growth. In addition, when bamboo is cut at right angles to its longitudinal direction, the texture of the bamboo fiber layer tends to become more dense from the center of the cylinder to the outside, and the outermost outer layer is a thin and hard enamel layer. Although bamboo contains a small amount of moisture, it is preferable to dry it. The bamboo filter member 120 preferably removes all or part of the enamel layer constituting the outer shell thereof. This is because the enamel layer has a property of hindering the permeation of bubbles. The bamboo fibrous layer is less dense toward the center of the bamboo filter, while the outer fibrous layer forms a more dense structure toward the outside thereof, so that the high-pressure gas is discharged from the inner bamboo fibrous layer (ie, the inner layer). It is more preferable to transmit in the direction of the layer (ie, the outer layer).

The bamboo filter member 120 does not use the natural bamboo in the form of a cylinder as in the prior art, but breaks the cylinder and cuts the bamboo plate formed in a slightly flat shape into various shapes. The manner of cutting is not particularly limited. For example, it may be performed by hand, may be performed by a lathe operation or a milling machine operation operated by a computer program, or may be performed by a circular mill cutter. Therefore, the bamboo filter member 120 may be processed into various shapes, and in general, may be manufactured in a circular, square, rectangular, parallelogram, or oval shape. In the accompanying drawings, a circular shape is illustrated.

The bamboo filter member 120 is inserted into the filter seat 114, it is preferable to be firmly coupled and fixed there.

The valve 100 for nano-bubble generating device according to the present invention includes a filter fixing member 130 for firmly coupling the bamboo filter member 120 to the body portion 110.

The filter fixing member 130 is a coupling and fixing means for stably and firmly fixing the bamboo filter member 120 in a state of being inserted into the filter seating portion 114 of the body 110. Since the filter fixing member 130 is a means for fixing the bamboo filter member 120 in a stable state, there may be various ways of fixing the filter. For example, as shown in the accompanying drawings, it may be performed by a screw coupling method, may be performed by a conventional locking projection coupling method, may be performed by a mixing method of the sliding coupling by a screw method, a plurality of It may also be carried out in a compression bonding method using bolts and screws. In addition, the filter fixing member 130 may use a packing member for tighter adhesion.

Figure 2 shows a second embodiment of the nano-bubble generator valve 100 according to the present invention, Figure 2a is an exploded perspective view of the nano-bubble generator valve 100 according to the second embodiment, 2b is a schematic cross-sectional view showing an assembled state of the valve 100 for a nano bubble generator according to the second embodiment.

The valve 100 for the nano-bubble generator according to the second embodiment of the present invention is completed by deforming the filter seat 114 and the filter fixing member 130 of the body portion 110.

In the second embodiment of the present invention, the filter seat 114 is formed in a direction perpendicular to the body portion 110, and includes a filter sliding groove 117 on both sides of the inner surface. The filter sliding groove 117 forms a passage through which the bamboo filter member 120 is inserted while sliding. At this time, the filter seat 114 has an inclination angle with respect to the gas inlet 112 and the gas outlet 116, preferably be installed in the body portion 110 to form a right angle with each other.

In the second embodiment of the present invention, the filter fixing member 130 is to be coupled to the filter seat 114. The filter fixing member 130 pushes the bamboo filter member 120 from its side and seals it. The filter fixing member 130 may use a packing ring 132 to improve the sealing efficiency.

3 shows a third embodiment of the nano-bubble generator valve 100 according to the present invention, Figure 3a is an exploded perspective view of the nano-bubble generator valve 100 according to the third embodiment, 3b is a schematic cross-sectional view showing the assembled state of the valve 100 for a nano bubble generator according to the third embodiment.

In the third embodiment of the present invention, the filter seat 114 is made detachably with respect to the body portion 110, and includes a plurality of filter coupling grooves (118). The filter coupling groove 118 is formed to suit the shape of the bamboo filter member 120, it illustrates the case of a circular in the accompanying drawings. The filter coupling groove 118 forms a space in which the bamboo filter member 120 is inserted and coupled therein.

At this time, the plurality of coupling grooves 118 may form a screw portion (not shown) therein as a preferred embodiment, in which case the bamboo filter member 120 is inserted in the first embodiment Each filter fixing member 130 may be screwed together.

In addition, the plurality of coupling grooves 118 may be paired with the second coupling groove 138 formed in the filter fixing member 130 to correspond to each other, the coupling groove 118 and The bamboo filter member 120 is inserted into and coupled to the second coupling groove 138. At this time, the coupling groove 118 and the second coupling groove 138 may use the packing ring 132 to strengthen the adhesion of each other. In addition, the filter seat 114 and the filter fixing member 130 can be firmly coupled using a separate screw 134.

The valve 100 for the nano-bubble generating device according to the present invention may be used separately one by one, or may be used by tying a number of pieces to one another. In addition, the valve 100 for the nano-bubble generating device may be used in various household items that are used in general home life, school life or social life.

4 is a schematic conceptual view showing a state of use of the valve 100 for nano-bubble generating device according to the present invention.

The nano bubble generator valve 100 may be used in a variety of household goods. For example, look at the case to be used to convert the purified water to oxygen water applied to a household water purifier.

First, the nano bubble generator valve 100 according to the present invention is coupled to the gas supply module 200. At this time, the gas supply module 200 is an adapter 212 for coupling the high concentration oxygen tank 150, the module body 214 for coupling one or a plurality of adapters 212, and And a regulator 216 coupled to the front of the module body 214 and an on / off valve 218 coupled to the front of the module body 214. It is preferable to combine the valve 100 for nano-bubble generating device according to the present invention to the end of the on-off valve 218. When the nano-bubble generator valve 100 is combined, it is put into the water bottle 300 of the household water purifier.

Subsequently, a high concentration oxygen tank 150 is coupled to the adapter 212. The regulator 216 of the oxygen gas supply module 200 is adjusted to a required pressure, and then the on / off valve 156 is opened to supply oxygen to the nano bubble generator valve 100.

Inside the water reservoir 300 of the household water purifier, nano-level oxygen bubbles are generated by the nano-bubble valve 100, and the nano-level oxygen bubbles are immediately dissolved in water. In this case, when observed with the naked eye, it can be seen that fine bubbles are formed.

Although the valve for the nano-bubble generating device according to the present invention and a method of using the same have been described in detail, this is only for describing the most preferred embodiment of the present invention, and the present invention is not limited thereto. The range is determined and defined by.

In addition, anyone of ordinary skill in the art will be able to make various modifications and imitations by the description of the specification of the present invention, but it will be apparent that this is also outside the scope of the present invention.

110: body portion, 112: gas inlet,
114: filter seat, 116: gas outlet,
120: bamboo filter member, 130: filter fixing member,

Claims (5)

delete Body part 110 to form an overall basic shape and responsible for the inflow and outflow of gas, and the bamboo filter member 120 that is installed inside the body portion 110 to convert the introduced gas into nano-level micro-bubbles and As the bamboo filter member 120 includes a filter fixing member 130 for firmly coupling to the body portion 110,
The body portion 110 has a gas inlet 112 that functions as a passage for receiving a high-pressure gas from the outside and a space for inserting the bamboo filter member 120 while being present inside the body portion 110 A filter outlet 114 to be formed, and a gas outlet 116 formed by the bamboo filter member 120 into nano-level fine bubbles while the fine bubbles are dissolved in water;
The bamboo filter member 120 is processed by using natural bamboo to cut into circular, square, rectangular, parallelogram, or oval, and is inserted into the filter seat 114 is a high-pressure gas of nano-level Convert to fine bubbles;
In the filter fixing member 130 to stably fix the bamboo filter member 120 to the body portion 110,
The filter seat 114 is formed in a direction perpendicular to the body portion 110, characterized in that it includes a filter sliding groove 117 on both sides of the inner surface, the gas nano-bubble generating device Valve.
Body part 110 to form an overall basic shape and responsible for the inflow and outflow of gas, and the bamboo filter member 120 that is installed inside the body portion 110 to convert the introduced gas into nano-level micro-bubbles and As the bamboo filter member 120 includes a filter fixing member 130 for firmly coupling to the body portion 110,
The body portion 110 has a gas inlet 112 that functions as a passage for receiving a high-pressure gas from the outside and a space for inserting the bamboo filter member 120 while being present inside the body portion 110 A filter outlet 114 to be formed, and a gas outlet 116 formed by the bamboo filter member 120 into nano-level fine bubbles while the fine bubbles are dissolved in water;
The bamboo filter member 120 is processed by using natural bamboo to cut into circular, square, rectangular, parallelogram, or oval, and is inserted into the filter seat 114 is a high-pressure gas of nano-level Convert to fine bubbles;
In the filter fixing member 130 to stably fix the bamboo filter member 120 to the body portion 110,
The filter seat 114 is made detachably with respect to the body 110, and includes a plurality of filter coupling groove 118, the filter coupling groove 118 is the bamboo filter member A valve for a nano-bubble generator of gas, characterized by forming a space into which 120 is inserted.
The method of claim 3, wherein
The coupling groove 118 of the filter seat 114 forms a pair corresponding to each other with the second coupling groove 138 formed in the filter fixing member 130, the coupling groove 118 and the second coupling The above-described bamboo filter member 120 is inserted into the groove 138, characterized in that coupled to the valve for the gas nano-bubble generating device.
The nano bubble generator valve of any one of claims 2 to 4 coupled to the gas supply module 200,
The gas supply module 200 includes an adapter 212 for coupling an external oxygen tank 150, a module body 214 for coupling one or more adapters 212, and the module body. A regulator 216 coupled to the front of 214, and an on / off valve 218 coupled to the front thereof,
Using the valve for the nano bubble generator coupled to the gas supply module 200, characterized in that for generating nano-level gas in the water, the method of using a nano bubble generator valve (100).

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