KR200476056Y1 - Nano-bubble generator - Google Patents

Abstract

The present invention relates to a nano bubble generating device, and more particularly, to a bubble filter using a bamboo filter which removes a part or all of an enamel layer and uses a crumb fibrous layer therein as a component of a filter; A reinforcing member connected to the outer circumferential surface of the bamboo filter in a rectangular shape; A reinforcing member insertion groove formed corresponding to the reinforcing member so that the bamboo filter coupled with the reinforcing member can be coupled to the reinforcing member insertion groove; A main body including a gas supply groove formed in a shorter width and a longer length, and an insertion hole formed to communicate with the gas supply groove so as to supply gas into the gas supply groove; A cover coupled to an upper end of the main body and formed in a shape corresponding to the reinforcing member such that an outer circumferential surface of the bamboo filter is opened; And a gas supply member for supplying gas to the bamboo filter, wherein the bamboo filter removes organic substances in the tissue and increases the number of nano bubbles Wherein the nano bubble generating device is connected to the fixing member after being exposed to the gamma ray.

Description

[0001] NANO-BUBBLE GENERATOR [0002]

The present invention relates to a nano bubble generating device, and more particularly, to a bubble filter using a bamboo filter which removes a part or all of an enamel layer and uses a crumb fibrous layer therein as a component of a filter; A reinforcing member coupled along an outer peripheral surface of the bamboo filter; A reinforcing member insertion groove formed corresponding to the reinforcing member so that the bamboo filter coupled to the reinforcing member can be coupled to the reinforcing member insertion groove; A main body including a gas supply groove formed in a shorter width and a longer length, and an insertion hole formed to communicate with the gas supply groove so as to supply gas into the gas supply groove; A cover coupled to an upper end of the main body and formed in a shape corresponding to the reinforcing member so that an outer circumferential surface of the bamboo filter is opened; And a gas supply member for supplying gas to the bamboo filter, wherein the bamboo filter removes organic substances in the tissue and increases the number of nano bubbles After being exposed to the gamma ray, to be fixed to the fixing member.

Generally, a gas newly generated in the liquid or injected from the outside forms fine bubbles and is dissolved into the liquid to be absorbed or remain as bubbles in the liquid. The bubbles remaining in the liquid tend to have a lower specific gravity than the liquid, so that the bubbles rise upward.

However, when the bubbles exist below a certain size, they do not float above the surface of the liquid but rather remain in the liquid, or are reduced by the external pressure in the liquid, and eventually rupture. It is known to dissolve in liquids.

Thus, when specific microbubbles are produced in a particular liquid, it means that the particular liquid on the one hand contains the microbubbles of the gas while dissolving the specific gas on the other hand. At this time, when the above-mentioned specific gas is selected as a gas beneficial to an organism and the above-mentioned specific liquid is also selected as a beneficial or harmless liquid for an organism, a liquid substance in this state can have a very beneficial effect on an organism.

In addition, when the above-mentioned specific gas is selected as a gas useful for industry, such a liquid material can be used as a material which is also useful for industry. Accordingly, in the present invention, the liquid is most preferably water harmless to the human body, means an aqueous solution prepared by adding a small amount of another substance to the above-mentioned water, and may mean other liquids.

In general, when the size of the bubbles dissolved in water is larger than 50 micrometers, the bubbles float on the surface within a few seconds and diffuse into the atmosphere, whereas when the size is 50 micrometers to several hundreds of nanometers , The microbubbles can remain in water for up to six months and gradually become shrinking and rupturing in the remaining portion to dissolve the gas at a saturation concentration or higher.

When a large amount of air bubbles are produced at a minute size, it is possible to increase the concentration of dissolved gas in the water, and if it is left in water for a long time, it can be used as drinking water in which gas such as oxygen or hydrogen is dissolved at a high concentration There is an advantage.

Conventional techniques and applicable techniques for producing drinking water by increasing the solubility of gas (oxygen) by generating fine bubbles in water are known as follows.

Dissolved gas method is a method in which gas is filled at a high pressure in a state in which water or beverage is filled in a sealed container to dissolve the gas inside the water or beverage. According to this method, the gas dissolved in the water or the beverage is released as if it is blown out, while opening the sealed container. Using such gas properties, it is utilized in a method of using carbon dioxide gas in a soft drink at high pressure. However, according to this method, the gas dissolved in the water or the beverage is released from the inside of the sealed container at the moment of opening the sealed container, so that the gas is dissolved in water or beverage for a long time Can not be maintained.

The hydrodynamic method is a mechanical mixing method in which water and oxygen are simultaneously injected into a motor propeller rotating at a high speed of about 10,000 to 20,000 rpm to force oxygen gas to be adsorbed on the surface of water particles. Usually, the inside of the container is filled with a liquid such as water, and the gas and the liquid are mixed with each other by using a high rotational force while externally applying the gas. However, this method is disadvantageous in that the fine physical and chemical structure of the liquid material is broken because the liquid material is rotated using the high-speed rotation force, and in particular, water may be stressed during the manufacturing process in the case of drinking water. In addition, this method has a disadvantage in that a large amount of energy must be supplied in order to obtain a high rotational torque, and there is a disadvantage in that it limits the dispersing ability of the gas due to high-speed rotation. Therefore, this method has a certain limit in reducing the size of the gas dissolved in the liquid material. According to this method, when the rotation of the liquid material is stopped, the size of the gas dissolved in the liquid material can not be finely formed, so that the gas dissolved in the water floats easily and escapes over time .

The water exposure method is a method of injecting water into the upper space of an oxygen tank so that water can be brought into contact with oxygen, and repeatedly injects until a desired oxygen concentration is reached. However, this method is disadvantageous in that it is difficult to produce a high concentration of oxygen water from the viewpoint of commercial application, and productivity is low and utilization is very low.

On the other hand, the dissolved air flooding method is a method in which air is first dissolved in water at a high pressure to prepare supersaturated air-dissolved water, and the air-dissolved water is re-injected into water for treatment such as sewage. In this method, fine bubbles of air are generated from the air-dissolved water, and then the air bubbles are moved upward while being combined with the flocs dissolved in the water for water treatment, thereby purifying water for treatment . However, since the above-mentioned dissolved air lifting method utilizes the property that the bubbles dissolved in water float upwards, the above-mentioned bubbles must be formed large and can not be formed to be 50 microns or less.

On the other hand, a membrane method has been introduced. In this method, a porous material made of ceramic or metal is formed, and a porous material filter is formed, and oxygen bubbles are formed through the porous membrane of the filter. However, this method still has a technical limitation that it is impossible to form a nano-sized fine porous film as a ceramic or metal material to this day.

In order to solve such a problem, Korean Patent Registration No. 10-01123136 entitled " Method for generating minute bubbles in a liquid and a generator of a minute bubble suitable for the method "

The bubble filter element using the bubble fiber layer as a component of the filter to remove part or all of the enamel layer; A fixing member for supporting and fixing the bamboo filter member in a predetermined shape; And a gas supply member for introducing an external gas into the bamboo filter member through the fixing member, wherein the bamboo filter member is used as a cylindrical shape by cutting the bamboo to a predetermined length in the longitudinal direction, Cylindrical bamboo is divided into two to four and is used as a semi-cylindrical or plate-like shape.

Since the micro-bubble generator uses naturally grown bamboo as a filter member, it has an advantage that gas can be easily generated and dissolved in a liquid at a much lower cost than a method using a ceramic raw material or other artificial raw materials as a filter member.

However, the micro-bubble generator described above has different diameters of nodes and nodes of bamboo, and even in the case of the same bamboo, there is a problem that it takes much time to sort bamboo because of the difference in diameter between the bottom and the top.

This design is intended to solve the problems caused by using a circular bamboo filter when creating bubbles of nanoparticle size that contain bubbles below the micrometer level size in water containing bubbles in the water It is an object of the present invention to provide a micro bubble generator which is easy to install on a fixing member regardless of the diameter of the bamboo.

In order to solve the above problems, the present invention provides a bamboo filter which removes a part or all of the enamel layer and uses the bamboo fiber layer 112 as a component of the filter; A reinforcing member coupled along an outer peripheral surface of the bamboo filter; A reinforcing member insertion groove formed corresponding to the reinforcing member so that the bamboo filter coupled with the reinforcing member can be coupled to the reinforcing member insertion groove; A main body including a gas supply groove formed in a shorter width and a longer length, and an insertion hole formed to communicate with the gas supply groove so as to supply gas into the gas supply groove; A cover coupled to an upper end of the main body and formed in a shape corresponding to the reinforcing member such that an outer circumferential surface of the bamboo filter is opened; And a gas supply member for supplying gas to the bamboo filter, wherein the bamboo filter removes organic substances in the tissue and increases the number of nano bubbles After being exposed to the gamma ray, to be fixed to the fixing member.

The bamboo filter is characterized in that a cylindrical bamboo is divided into two to four equal parts and used in an arc shape.

Further, the main body and the cover are bolted together.

delete

When the bubble of nanoparticle size including bubbles below the micrometer level size is generated in the water containing bubbles in the water, the diameter of the upper part and the lower part of the bamboo are different from each other, There is an advantage that it is difficult to fix the bamboo to the member and it is easy to install on the fixing member regardless of the diameter of the bamboo.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a conceptual diagram of a method for dissolving microbubbles in water according to the present invention; FIG.
Fig. 2 is an exemplary view of a bamboo filter according to the present invention; Fig.
3 is an exemplary view of a nano bubble generating device according to the present invention;
4 is an exploded perspective view of the apparatus for generating nano bubbles according to the present invention;

Hereinafter, the embodiments will be described on the basis of embodiments best suited to understand the technical features of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, And that the present invention may be implemented with other embodiments. Accordingly, the present invention is capable of various modifications within the technical scope of the present invention through the embodiments described below, and these modified embodiments will be within the technical scope of the present invention. In order to facilitate understanding of the embodiments to be described below, in the reference numerals shown in the accompanying drawings, among the components that perform the same function in the embodiments, the related components are denoted by the same or an extension line number.

In order to facilitate understanding of the features of the present invention as described above, the nano bubble generating device related to the embodiments of the present invention will be described in more detail.

The nano bubble generator 100 according to the present invention comprises a bamboo filter 110 composed of bamboo material, a main body 120 to which the bamboo filter is fixed, and a gas supply member 140).

The nano bubble generator 100 according to the present invention comprises a bamboo filter 110 made of a bamboo material. The bamboo filter 110 is manufactured by selecting and drying the bamboo which has grown for about one year to four years, removing the enamel layer 114 of the bamboo filter 110, and using the porosity fibrous layer 112 therein as an essential component .

In the present invention, the bamboo filter 110 is formed by cutting bamboo into a predetermined length with respect to the longitudinal direction, and dividing the bamboo into two to four halves.

Bamboo that has not undergone a natural year in the natural state is not preferable because the bamboo fiber layer 112 is not sufficiently mature and has a poor permeability to gas. Generally, bamboo has a different texture density of the bamboo fiber layer 112 depending on the number of years of growth. In addition, when the bamboo is cut at right angles to the longitudinal direction, the texture of the porcelain fibrous layer 112 tends to become more and more dense from the center of the cylinder to the outside, and the outermost layer of the bamboo has a thin and hard enamel layer 114 ). Although bamboo is small in quantity, it contains moisture, so it is preferable to dry it. When bamboo is dried, moisture is separated from the above-mentioned porridge fibrous layer 112 to shrink, and the structure becomes more dense. In case of excessive drying, the bamboo fiber layer 112 may be cut and the bamboo itself may be split.

In the present invention, it is preferable to remove all or part of the enamel layer 114 constituting the outer shell of the bamboo. This is because the enamel layer 114 has a large property of interfering with permeation of bubbles. The removal of the enamel layer 114 may be performed using a tool such as a blade or a grinder. The manner of removing the enamel layer 114 is not particularly limited.

The present invention has a technical feature in that it is used as a filter material in which a bamboo fiber layer 112 existing inside the bamboo passes through a gas. The porphyristic fibrous layer (112) has a plurality of sherds formed therein. The bamboo sucks water from its roots and is used as a passage for moving water upward through a plurality of shafts formed in the bamboo fiber layer 112, and is considered to finally feed the leaves. At this time, a plurality of the water pipe portions are formed in parallel in the longitudinal direction of the bamboo, and they exist in the porcelain fibrous layer 112. However, in the present invention, the gas is not transmitted through the above-described material pipe, and the gas is transmitted through the fine gaps of the porcelain fibrous layer 112. In FIG. 1, arrows indicate a state where the above-mentioned gas passes through a fine gap of the porous fibrous layer 112.

The method of generating nano bubbles in the liquid through the nano bubble generator 100 according to the present invention is a method in which a predetermined gas to be dissolved in the inside of the porcelain fibrous layer 112 is pressurized to atmospheric pressure or higher, Is permeated outwardly from the inside of the porous fibrous layer (112) to form fine bubbles. The liquid refers to a liquid substance, and preferably includes water, an aqueous solution, an emulsion, a drink, an alcohol, a soju and an oil, and most preferably water.

The bamboo filter 110 is inserted into the main body 120 to be described later and receives gas from the gas supply member 140 to form fine bubbles. The bamboo filter 110 is exposed to gamma rays, The reinforcing member 111 is coupled to the outer circumferential surface of the bamboo filter 110, and then the reinforcing member 111 is coupled to the inside of the main body 120.

Since the bamboo structure is irregular in nature, it is possible to maintain the uniform gap between the water tube and the water tube by removing the organic substances in the tissue with the gamma ray, thereby increasing the number of nano bubbles.

Also, by exposing the bamboo filter to the gamma ray, it is possible to improve the function of the bamboo filter by the complete sterilization treatment.

On the other hand, the gamma rays supplied to the bamboo filter are directly decomposed in the natural world and disappear.

The reinforcing member 111 is formed along the outer circumferential surface of the bamboo filter 110 and has a rectangular shape corresponding to the body 120 so as to be inserted into the body 120.

Next, a main body 120 to which the bamboo filter 110 according to the present invention is coupled will be described.

The main body 120 is formed in a rectangular shape and includes a reinforcing member insertion groove 121 having a shape corresponding to the reinforcing member 111 so that the bamboo filter 110 having the reinforcing member 111 coupled thereto can be inserted therein. And a gas supply groove 122 having a width and a length shorter than that of the reinforcing member inserting groove 121 is further formed in the lower portion of the reinforcing member inserting groove 121.

A first step 124 forming a boundary between the reinforcing member insertion groove 121 and the gas supply groove 122 is formed at a predetermined height in the body so that the lower end peripheral surface of the reinforcing member 111 is located at the step And the second step 125 is formed by forming the reinforcing member insertion groove 121 at a position spaced apart from the upper end of the main body by a predetermined distance so that the cover to be described later is seated .

The cover 130 is formed in a shape corresponding to the reinforcing member 111 and a portion corresponding to the bamboo filter 110 is opened so that the outer circumferential surface of the bamboo filter 110 is not blocked.

The reason why the cover 130 is partially opened is because the nano bubbles are discharged from the inner circumferential surface of the bamboo filter 110 to the outer circumferential surface as described above so that the cover 130 does not interfere with the release of the nano bubbles .

The body 120 and the cover 130 are bolted to each other. To this end, a plurality of fastening holes 126 are vertically formed in the second step 125, A plurality of fastening holes 126 are formed in the body, and a bolt is inserted in the upper or lower direction of the body to fasten the bolts.

However, a bolt may be provided with a nut corresponding to the bolt, and a thread may be formed on the outer circumferential surface of the fastening hole 126 formed in the cover 130 so that bolts are fastened without a separate nut.

In the present invention, when the bamboo filter 110 with the reinforcing member 111 is inserted into the main body 120, when the cover 130 is seated and then bolted, the reinforcing member 111 An O-ring 150 having elasticity is further inserted to prevent breakage.

An O-ring insertion groove 151 having a shape corresponding to the reinforcing member 111 is formed at an upper end of the first step 124 and a reinforcing member 111 is coupled to the inside of the body 120 The bamboo filter 110 is inserted into the O-ring insertion groove 151 formed in the first step 124 before inserting the bamboo filter 110 and the cover 130 An O-ring insertion groove is also formed in the bottom surface of the main body so that the O-ring 150 is inserted. Then, the cover 130 is seated on the top of the main body and then bolted.

When the main body 120 and the cover 130 are bolted to each other with the O-rings 150 positioned at the upper and lower ends of the reinforcing member 111, the O-rings 150 absorb the impact, The O-ring 150 may be made of a silicone material having an elastic force and capable of absorbing shock.

The main body 120 and the cover 130 may be formed of various materials but they are preferably formed of a metal material which is not easily corroded, The materials of the main body 120 and the cover 130 are not limited to the right scope of the present invention.

An insertion hole 123 is formed in a lower portion of the main body 120 to receive and connect the connection hose 141 connected to the gas supply member 140.

The insertion hole 123 is formed to communicate with a position corresponding to the gas supply groove 122 and the gas supplied from the gas supply member 140 is introduced into the gas supply groove 122 through the connection hose 141 And supplies it to the bamboo filter 110.

The present invention provides a bamboo filter 110 that removes some or all of the enamel layer 114 and utilizes a porous fibrous layer 112 therein and a bamboo filter 110 that is robust And a main body 120 for accommodating the bamboo filter 110 with the reinforcing member 111 coupled to the outer circumferential surface of the bamboo filter 110 so that the bamboo filter 110 can be maintained in a fixed state, And a cover 130 that is firmly coupled to the main body 120. In order to generate bubbles having a nanoparticle size including bubbles of a micrometer size or less in water containing water bubbles The diameter of the upper part and the lower part of the bamboo may be different from each other to solve the problem that it is difficult to fix the bamboo to the fixing member and it is possible to install the bamboo irrespective of the diameter of the bamboo.

100: Nano bubble generator 110: Bamboo filter
111: reinforcing member 112: corrugated fibrous layer
114: enamel layer
120: main body 121: reinforcement member insertion groove
122: gas supply groove 123: insertion hole
124: First stage 125: Second stage
126: fastening ball
130: cover 140: gas supply member
141: Connection hose 150: O-ring
151: O-ring insertion groove

Claims (4)

A bamboo filter 110 that removes some or all of the enamel layer 114 and uses the porosity fibrous layer 112 therein as a component of the filter;
A reinforcing member 111 coupled along the outer circumferential surface of the bamboo filter 110;
A reinforcing member insertion groove 121 formed to correspond to the reinforcing member 111 so that the bamboo filter coupled to the reinforcing member can be coupled to the reinforcing member insertion groove 121; A gas supply groove 122 formed to have a width and a length shorter than that of the reinforcing member insertion groove so as to supply the gas supply groove and an insertion hole 123 formed to communicate with the gas supply groove so as to supply the gas into the gas supply groove (120);
A cover 130 coupled to an upper end of the main body 120 and corresponding to the reinforcing member 111 so as to open the outer circumferential surface of the bamboo filter 110; And
And a gas supply member 140 provided with a connection hose 141 fitted to the insertion hole 123 and supplying gas to the bamboo filter,
Wherein the bamboo filter (110) is exposed to gamma rays so as to remove organic substances in the tissue and increase the number of nano bubbles, and then is bonded to the fixing member (111).
2. The nano bubble generator according to claim 1, wherein the bamboo filter (110) uses an arc-shaped bamboo cylinder divided into two to four equal parts.
The nano bubble generator of claim 1, wherein the body (120) and the cover (130) are bolted together.
delete

Images