KR102379697B1 - Dualcyclone Filter - Google Patents

Abstract

The present invention relates to microbubble generator dual cyclone filtration and comprises: a venturi stirring part that generates a suction force when a fluid passes through the venturi stirring part and selectively sucks air and an oxidizer to generate a stirring flow and create a mixed fluid; a dual cyclone filter body part that is disposed on one side of the venturi stirring part, stirring the mixed fluid supplied from the venturi stirring part while passing through a fluid mixing part, rotates counterclockwise of the dual cyclone introduced in both directions to generate microbubble water by the cyclone phenomenon, separates and filters micropollutants, and discharges the micropollutants to the outside from one side; a disk filtering part that is installed inside microbubble water mixing discharge pressurization, has a plurality of disks to be stacked to filter the microbubble water, which is a substance to be filtered from the outside to the inside, and discharges the microbubble water through an outlet of a microbubble water discharge pipe; and a dual cyclone filtration part that is supported on one side of the inner side of the dual cyclone filter body part, generates microbubble water by the cyclone phenomenon caused by rotation at each distributed position by distributing the mixed fluid mixed in the fluid mixing part to radial positions, separates and filters the micropollutants, discharges the microbubble water on one side, and discharges the micropollutants on the other side. Accordingly, productivity is improved.

Description

Dualcyclone Filter

The present invention is a dual cyclone filter that can simultaneously generate microbubbles and separate and filter out microcontaminants more efficiently than a general microbubble generating device. It relates to a dual cyclone filter that separates and filters gas-liquid mixing using a plurality of dual cyclone filters arranged in a radial pattern to separate and filter the generation of bubbles and microcontaminants.

The micro-bubble generation and micro-contaminant separation filtration device is composed of a plurality of dual cyclones, and the flow path of the gas-liquid mixed liquid is arranged in a radial pattern to remove micro-bubbles and micro-contaminants. With a venturi structure that can suck air, the mixed fluid that becomes a gas-liquid mixture as air is sucked in when the fluid is introduced. Used to separate microcontaminants. A typical cyclone is injected at an angle to the cyclone separator, so that the fluid is established in a generally circulating rotational flow. Centrifugal force mixes air and fluid and acts on fine pollutants that are denser than the mixed fluid, separating and discharging substances with high specific gravity toward the lower part of the separation chamber of the cyclone filter. The conical shape of the dual cyclone filter separator element separates and discharges the denser microcontaminants and separates the microcontaminants from escaping to the top of the cylinder. The filtered gas-liquid mixture exits to the top of the cylinder. Instead, a substantially microcontaminant-free gas-liquid mixture surrounding the center of the vortex is extracted, while the microcontaminants are collected and concentrated in the lower collection bin and discharged to the lower outlet.

A typical disc filter strainer has a separate filtration housing and a separate contaminant collection tank used in the component system. Systems incorporating these components require cleaning or replacement of the filtration housing and filtration filter after shutdown on a regular basis to improve filtration performance. This affects system uptime due to filter downtime and increases the amount of reserve required to manage.

Dual cyclone filters are used in vacuum cleaners to remove fine and large debris from the air stream created by the vacuum. The inhaled fine dust is injected tangentially into the dual cyclone filter chamber, and the resulting vortex rotates to separate the fine dust by the wall of the cyclone chamber, and the filtered clean air is discharged to the top.

Cyclone separation filtration technology is also used to separate and filter pollutants in the water treatment sector. Centrifugal separators and hydrocyclone filters are also used for sand separation and sludge separation filtration and concentration in general water treatment fields. The dual cyclone filter treatment design is designed for treatment flow, specific flow rate, operating pressure, and solids load. Filtration devices produced according to predefined design factors can effectively handle the filtration target. However, devices designed according to general design factors are not kept constant as in the above design conditions. A typical cyclone filter describes a cyclone separator for separating solids from liquids. Cylindrical cylinder with cyclone inlet and outlet and lower conical shape to trap and discharge the segregated material. The inflow fluid creates a vortex in the cylindrical inner cylinder, and the solids contained in the liquid are separated by centrifugal force. The separated and filtered pollutants are discharged through the conical outlet along the inner surface of the body. Micro-bubble water, a gas-liquid mixture that has been separated and filtered, is discharged through the upper outlet.

The dual cyclone filter is a dual cyclone filter in which air is sucked by the venturi device when the fluid flows in from the inlet and the mixed gas-liquid mixed liquid generates microbubble water and separates and filters microcontaminants. As for the gas-liquid mixed liquid, which is mixed and separated and filtered with strong rotational force in the cyclone rotating part, aeration in the vortex chamber creates local high pressure to generate microbubble water and separate filtration of microcontaminants. Mixing is done by discharging the top in a counterclockwise direction. In the first stage, the liquid sucks air as it passes through the venturi, and the mixed liquid passes through the flow path of the radial inlet and passes through the cyclone vortex chamber of the dual cyclone filter. are mixed. The vortex chamber contains a vortex passageway through which a centrifugal flow of incoming material is dispersed outwardly from the chamber. The vortex chamber has an upper cover having an upper conical opening for discharging microbubble water and a conical outlet at the bottom for separate filtration discharge of substances heavier than the gas-liquid mixed liquid, a central opening of the upper cover, and a lower cover for discharging heavy contaminants and an upper cover and a lower cover that substantially close the upper and lower cylinders except for the central opening of the .

This describes a dual cyclone filter assembly that installs a disk filter at the inner discharge part of the upper cone of the dual cyclone filter and filters the contaminants once again by installing a disk filter for the filtered microbubble water of the cyclone filter. The cyclone filter uses centrifugal force to separate contaminants with high specific gravity from the fluid, and filters the remaining microcontaminants using a filter with a disk filter to filter microbubble water. The dual cyclone filter of the present invention does not require washing, backwashing, or replacement of the filter, but the disk filter requires cleaning and replacement. It can thus be contained in a compact single housing that can be disassembled for cleaning and replacement of the disc strainer. The cyclone filter has a cylindrical cylinder structure that can separate the inflow of a gas-liquid mixed fluid that can separate and filter the inflow of heavy fine pollutants by rotational force. When the inlet gas-liquid mixture rotates inside the cylindrical cylinder, gas-liquid mixing and separation occur at the same time, and the gas-liquid mixture rotates outside the cylindrical inner cylinder. The heavy microcontaminants are rotated around an inner circular cylinder by centrifugal force, causing them to move outward from the center of the vortex. At the center of the rotational force is an upper outlet that discharges the filtered microbubble water, and the heavy contaminants are separated, separated in a conical opening and concentrated in a collection bin. The present invention has a filtration chamber for accommodating a disk filter used to filter microbubbles remaining in a gas-liquid mixture with a disk filter after cyclone filtration.

(Patent Document 0001) Korea Registered Patent No. 10-2114545

The present invention has been devised to solve the above-described problems, and an object of the present invention is to rotate the fluid flow in a radial direction during the inflow movement and in different directions during the dual cyclone and dual cyclone mixed filtration and discharge. It is to provide a dual cyclone filter that improves productivity by securing various uses by removing impurities inside while selectively generating the desired number of microbubbles and oxidation water in the process while transforming it into various forms such as stirring during discharge.

Objects of the present invention are not limited to the objects mentioned above, and other objects not mentioned will be clearly understood from the description below.

In order to achieve the above object, in the dual cyclone filter according to the embodiment of the present invention, a liquid is supplied and a stirring flow occurs while passing through the venturi consisting of a plurality of holes installed in the inlet, and air and a venturi stirring unit for selectively supplying an oxidizing agent to generate microbubble water and oxidized water and mixing as necessary to produce a gas-liquid mixture; It is disposed on one side of the venturi agitator, and an air and oxidizer suction part composed of a plurality of suction holes inside the venturi, a venturi agitator that mixes the fluid and air while passing the fluid through a plurality of pipe structures, flows into the inlet of the dual cyclone filter a filtration body for generating microbubbles by rotating the gas-liquid mixture in a counterclockwise direction and separating, filtering, collecting and discharging microcontaminants; It is supported on one side of the inner side of the filtration body, and the gas-liquid mixture mixed in the venturi agitator is distributed through the radial flow path and introduced into a plurality of dual cyclone filters to generate microbubble water and separate and filter microcontaminants through a cyclone by rotation. a dual cyclone filter for discharging gas-liquid mixed microbubbles to one side and discharging microcontaminants to the other side; includes

In addition, the venturi agitator is connected to supply a fluid, has a mixing space through which the fluid passes inside a plurality of pipe structures, and a plurality of holes in which the pressure is lowered due to the occurrence of agitation flow to one side of the venturi agitator and sucked an air suction unit having a configured suction space; A supply pipe for supplying air and an oxidizing agent is installed outside the suction part, and a plurality of passage suction parts are configured in a flow path of a pipe structure through which a fluid passes through a plurality of pipe structures inside the venturi part, so that air and an oxidizing agent are sucked while the fluid flows. A venturi stirring unit to stir.; It is connected from the outside to the inside of the venturi stirring unit, and the suction space is installed at an outside position of one of the plurality of flow paths of the pipe structure of the venturi stirring unit, and when the fluid flows into the flow path of the pipe structure in which a plurality of holes are drilled, air an air supply pipe for selectively supplying air so that the air is sucked and the fluid and air are mixed to generate microbubbles; an oxidizer supply pipe connected from the outside to the inside of the supply pipe and installed at one of the plurality of flow paths in the suction space to selectively supply an oxidizing agent so that oxidized water is generated therein; may include

And the venturi agitator, the venturi agitator is formed of a plurality of flow passages in a radial shape including a suction portion centered on one flow passage therein. Agitation flow is generated by sucking air while passing through the flow path, and the fluid passing through different flow paths is stirred and supplied while being mixed.

In addition, the microbubble generating unit is disposed on one side of the venturi agitator, and a radial dispersion space in which a mixing space in which the fluid mixing and radial dispersion is made is installed on the other side as the inner center and the microbubbles on one side It has a dual cyclone filter support partition in the form of a partition wall that supports each while being divided into a dual cyclone filtration space in which the microbubbling filter of the dual cyclone filter is installed, and through the dual cyclone filtration space on one side to the separation filtration material collection space a dual cyclone filtration body including a filtration and discharge hole provided in the form of a discharge hole to discharge the collected microcontaminants to the outside; It is disposed in the center of the filtration body, and is provided in the form of a partition wall inclined toward the inner surface of the filtration space in the other direction around the outer periphery of the microbubble generating device dual cyclone filtration of the filtration support partition wall supported. a microcontaminant discharge hole provided to guide the microcontaminants filtered in the filtration in the direction of the filter discharge hole and discharge; a discharge actuator installed on the discharge hole for discharging the fine pollutants and operated at a preset time to discharge the concentrated fine pollutants separated and filtered through the filter discharge hole; and a tube-shaped micro-bubble water discharge pipe disposed on one side of the right side of the micro-bubble generator and for discharging the micro-bubble water filtered in the filtration space of the dual cyclone filter of the micro-bubble generator to the outside; may include

In addition, the venturi agitator is supported on the inlet of the filtration body of the microbubble generator, the other side is connected to the venturi agitator at the inlet, and one side is connected to the microbubble generator dual cyclone filtration unit and supplied a dispersion space in a radial form in the center of which a mixing space in which the fluid mixing and radial dispersion is made is installed on the other side to the inner center having a mixing space so that the agitated flow is mixed by the agitation of the fluid; a bidirectional flow path disposed on one side of the and the dispersion space, provided in a radial form from the center to one side of the mixing space, and flowing into a dual cyclone to change the gas-liquid mixture moving to one side into a swirling flow form; may include

In addition, the dual cyclone filtration unit is supported on one side of the inner side of the microbubble generation and filtering body, and is connected to the microbubble water pressurizing unit on the other side in the inner center and the supplied mixed swirl flow is distributed radially at each position A dual cyclone filter body having a dual cyclone swirling flow mixing filtration space for separating and filtering microbubbles and microcontaminants while rotating in a counterclockwise direction while moving in both directions; A filtration supply pipe in the form of a water channel disposed inside the dual cyclone filter body and connected to the fluid mixing unit in the center of the filtration space to supply a gas-liquid mixed flow from the other side to one side: Agitating flow is generated by the agitation of the fluid a dispersion space in a radial form at the center in which a mixing space in which the fluid is mixed and dispersed along a flow path in a radial form is installed on the other side as an inner center having a mixing space to mix; A dual cyclone inlet flow path dispersion space part which is connected and disposed in a plurality of radial positions at one end of the filtration supply pipe in an outward direction, and disperses the gas-liquid mixture supplied from the filtration supply pipe along a radial flow path: the dual cyclone filtration body Each inlet in both directions is disposed at a plurality of positions in a radial form, is located on one side connected to each of the bidirectional dual cyclone branch pipes, and is provided with an internal microbubble water discharge cylinder that blocks a part in the center of the internal flow path. It has a dual cyclone rotation space in which a cyclone is generated in the other direction while the gas-liquid mixed swirl flow swirls along the outer periphery of the microbubble water discharge cylinder. a dual cyclone cyclone rotating body having a microbubble water discharge space through which microbubble water from which microcontaminants are separated and filtered is discharged to one side, and one side is provided in a dual cyclone form; It is arranged connected to the other side of the rotating body of the cyclone, the upper part is cylindrical and the lower part is in the form of a cone, and an opening is provided at the lower part. Micro-bubble generator filter with a cyclone space as the micro-pollutants are separated and filtered and the separated micro-pollutants are concentrated by a reduced cross-sectional area from the inside of the cylinder to the lower cone-shaped lower part. filter body; It is disposed on the other side of the filter body of the microbubble generator and collects and stores the concentrated microcontaminants including a concentration discharge space for concentrating and discharging the microcontaminants separated and filtered by the filter of the microbubble generator therein. The micro-pollutant collecting unit having an outlet in the part: the filter body of the micro-bubble generating device having a concentration discharge space for collecting and storing micro-contaminants and having the micro-contaminants stored in the micro-pollutant collecting unit at the other end of the filter body A fine pollutant collecting unit having a through-hole type discharge hole for discharging to the unit: and disposed on one side of the filter body of the microbubble generator, each of which is filtered from the outside to the inside of the mixing pressurizing unit of the microbubble water discharge space a disk filter provided to filter the microbubble water discharged to one side of the disk filter; may include

And according to another embodiment of the present invention, it is arranged to be connected to the outer position of one side of the mixing pressure unit, the state measuring unit for measuring the residual chlorine and ph of the microbubbles; may further include.

In addition, a pipe-type measuring circulation unit disposed outside one side of the dual cyclone filter and circulating to measure the state while circulating the number of microbubbles generated in the dual cyclone filtration body of the microbubble generator; a microbubble water inlet pipe disposed on the other side of the measurement circulation unit, connected to one side of the pressure mixing unit of the measurement circulation pipe and the dual cyclone filtration of the microbubble generator, through which the microbubble water flows into the measurement circulation unit; a residual chlorine measuring device disposed on one side of the measuring circulation pipe and inserted into the measuring circulation part to measure the residual chlorine in the microbubble water introduced into the pipe; a ph meter disposed on one side of the measurement circulation unit and inserted into the measurement circulation unit pipe to measure the ph of the introduced microbubbles; and a microbubble recovery pipe disposed on one side of the measurement circulation unit, connected to one side of the measurement circulation unit and the dual cyclone filter mixing and pressing unit, to recover the measured fine bubble water to be circulated to the dual cyclone filter mixing and pressing unit; may include

In addition, according to another embodiment of the present invention, it is disposed on one side of the inner side of the dual cyclone filter and is connected to one side of the dual cyclone cyclone filter unit to mix and pressurize the filtered microbubble water. Fluid mixing for pressurizing the microbubble water pressurizing part; may further include.

In addition, the fluid mixing pressurization unit is disposed on one side of the inner side of the dual cyclone filter, the other side is connected to the dual cyclone microbubble generation and dual cyclone filter unit inside, and the other side is a microbubble generator dual cyclone A mixing pressure unit having a mixing pressure space connected to the microbubble water discharge part of the filter and the microbubble water supplied in both directions is discharged while rotating in different rotation directions in a counterclockwise direction to mix by collision agitation; a disk filtering unit disposed on the other side of the mixing pressurizing unit and including a disk filtering space in the center of the other side of the mixing pressure space; may include

Specific details for achieving the above object will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, and may be configured in a variety of different forms. It is provided to fully inform the person of the scope of the invention.

According to one of the problem solving means of the present invention described above, the direction of rotation of the fluid of the dual cyclone filter in which the flow of the fluid is stirred, swirled, collided, and the mixed fluid rotates counterclockwise during the generation and filtration of microbubble water is mutually It provides the effect of improving productivity by securing usage diversity by removing impurities inside while selectively generating the desired number of microbubbles and oxidation water in the process while transforming it into various forms such as bidirectional inflow water for other phenomena.

1 ab is a cross-sectional view showing a dual cyclone filter according to an embodiment of the present invention.
Figure 2 is an exploded view showing the dual cyclone filter of Figure 1.
Figure 3 is an assembly view showing the disk filter showing the dual cyclone filter of Figure 1.
4 is a configuration diagram and an exploded view of the disk filter of the dual cyclone filter of FIG.
5 is a venturi of the dual cyclone filter of FIG.
6 is a plan view of the dual cyclone filter of the dual cyclone filter of FIG.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and will be described in detail through detailed description. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

In describing the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, numbers (eg, first, second, etc.) used in the description of the present specification are merely identification symbols for distinguishing one component from other components.

Also, in this specification, one component is "connected" to another component. or "connected." When referred to as such, the one component may be directly connected or directly connected to the other component, but unless specifically stated to the contrary, it may be connected or connected through another component in the middle. It should be understood that there may be

The suffixes "module" and "part" for the components used in the following description are given or mixed in consideration of the ease of writing the specification, and do not have a meaning or role distinct from each other by themselves. In addition, in order to clearly explain the present invention, parts irrelevant to the description are omitted from the drawings, and in the drawings, the width, length, thickness, etc. of components may be exaggerated for convenience. Like reference numerals refer to like elements throughout.

Hereinafter, detailed contents for practicing the present invention will be described with reference to the accompanying drawings.

1 a b is a cross-sectional view showing a dual cyclone filter according to an embodiment of the present invention.

Figure 2 is an exploded view showing the dual cyclone filter of Figure 1.

Figure 3 is an assembly view showing the disk filter showing the dual cyclone filter of Figure 1.

4 is a configuration diagram and an exploded view of the disk filter of the dual cyclone filter of FIG.

5 is a venturi of the dual cyclone filter of FIG.

6 is a plan view of the dual cyclone filter of the dual cyclone filter of FIG.

1 to 6, the dual cyclone filter 100 according to an embodiment of the present invention can selectively generate the number of microbubbles and oxidation water while separating and filtering microcontaminants from the microbubble water, thereby purifying the microbubble water. As it is possible to generate various types of microbubble water, productivity can be improved. This dual cyclone filter 100 includes a venturi agitator 112 , a dual cyclone filter body 120 , and a dual cyclone filter 140 .

The venturi agitator 112 is a gas-liquid mixed fluid is supplied and passes through the radially located venturi agitator 112, a stirring flow is generated, and the air and oxidizing agent are selectively sucked by the suction force generated at the fluid passing position to remove microbubbles. , it is provided to generate the micro-bubble oxidation water by mixing as needed. Such, the venturi 110 includes an inlet pipe 111 , a venturi agitator 112 , an air supply pipe 113 , and an oxidant supply pipe 114 . The inlet pipe 111 is connected so that a gas-liquid mixed fluid is supplied, has an inlet 111a through which the fluid passes, and the pressure is lowered due to the flow of the fluid to one side of the venturi 110 and is sucked in. (111b) is provided. The venturi 110 has a cylindrical shape of a plurality of pipe structures inside the inlet pipe 111 and is mixed with the sucked air and the oxidizing agent while passing through the gas-liquid mixed fluid passing through the plurality of pipes to generate agitation flow. provided

Such, the venturi 110 includes an air supply pipe 113, an oxidant supply pipe 114, and a suction part 111b. The venturi 110 is provided in a cylindrical shape of a plurality of pipe structures inside the inlet pipe 111. As described above, the venturi 110 through which the supplied fluid passes has a cylindrical shape of a plurality of pipe structures inside the inlet pipe 111, and the fluid is mixed with the sucked air and the oxidizing agent while passing through the plurality of pipes. As one gas-liquid mixed fluid is combined, it is provided to generate and supply while being integrated The air supply pipe 113 is connected from the outside to the inside of the inlet pipe 111, and the air intake of the suction part 111b has a pipe structure It is composed of a plurality of holes in the cylinder of the pipe and is provided to selectively supply air to generate a gas-liquid mixture when the fluid passes through the pipe-shaped cylinder. The oxidizer supply pipe 114 is connected from the outside to the inside of the inlet pipe 111, , the oxidizing agent suction of the suction part 111b is provided with a plurality of holes in the cylinder of the pipe structure to selectively supply the oxidizing agent so that oxidized water is generated when the fluid passes through the pipe-shaped cylinder. Here, the oxidizing agent is chlorine dioxide, hypochlorous It can be used for purification because it contains an oxidizing material that can oxidatively decompose organic substances such as sodium chlorate, etc. The dual cyclone filter body 120 is disposed on one side of the venturi stirring unit 112, and is a venturi stirring unit inside The fluid supplied from (112) passes through, mixes with air, rotates counterclockwise due to the cyclone phenomenon of the dual cyclone, separates and filters microcontaminants by centrifugal force, and discharges from one side to the outside.

Such a dual cyclone filter body 120 includes a micro-bubble water mixed discharge and pressure unit 121, a micro-contaminant discharge pipe 123 and a micro-bubble water discharge pipe 125. The microbubble water mixed discharge pressurizing unit 121 is disposed on one side of the inlet pipe 111, and a radial distribution flow path of the mixed liquid in which a pipe-shaped cylindrical tube of the mixed liquid is installed on the other side as the inner center is installed and dual The gas-liquid mixed liquid flowing into the cyclone bidirectional flow path is divided into a microbubble water discharge cylinder 141 having a dual cyclone filtration unit 140 installed on one side, and has a partition wall-shaped microcontaminant concentration unit 121a to support each, and one side to the fine pollutant collecting unit 121b that is concentrated and discharged from the fine pollutant concentration unit 121a that concentrates the pollutants separated and separated by the cyclone phenomenon inside the dual cyclone rotation separation space 144b of the dual cyclone filter. It is provided to have a microcontaminant discharge pipe 123 provided in the form of a through hole to discharge the collected and concentrated microcontaminants to the outside. The microcontaminant discharge pipe 123 is disposed on the other side of the microbubble water mixing and discharging pressurizing part 121, and is provided in the form of a tube to discharge the impurities collected in the microcontaminant collecting part 121b to the outside. The microbubble water discharge pipe 125 is disposed on the upper right side of one side of the dual cyclone filter body 120, and is provided in the form of a tube for discharging the microbubble water generated and separated and filtered in the microbubble water generating space to the outside. The venturi agitator 112 is disposed on the upper left side of one side of the dual cyclone filter body 120 of the microbubble generator, is installed inside the inlet pipe 111, and the venturi agitator 112 installed inside the venturi 110 ) is supplied while the fluid passes in a cylindrical shape of a plurality of pipe structures inside the inlet pipe 111 and selectively sucks air and an oxidizing agent and mixes them. be prepared to do so The microbubble generator dual cyclone filter unit 140 is supported on one side of the inner side of the dual cyclone filter body unit 120, and the mixed water mixed in the venturi stir unit 112 is distributed to a radial position so that each bidirectional dual cyclone It is provided to discharge microbubble water to one side and to discharge microcontaminants to the other side by separating and filtering microbubble water generation and microcontaminants by the cyclone phenomenon rotating counterclockwise of the. The micro-bubble generator dual cyclone filtration unit 140 includes a micro-bubble water discharge cylinder 141, a gas-liquid mixing supply unit 142, a radial cyclone 143, a cyclone rotation unit 144, a micro-bubble generating cyclone generating body 145, concentration Consists of a discharge body 146, the radial cyclone inlet 143 is arranged in a radial direction at one end of the gas-liquid mixing supply unit 142 at a plurality of radial positions, respectively, connected to the outside, the gas-liquid mixture supply unit 142 is supplied from the gas-liquid mixture It is provided so as to flow in both directions of a dual cyclone that distributes to a plurality of radial positions.

The cyclone rotating unit 144 of the dual cyclone is disposed at a plurality of radial positions of the radial cyclone inlet 143, and is located on one side connected to each of the radial cyclone inlet 143 to separate a part of the inner center. Due to the cyclone phenomenon of the gas-liquid mixture supplied with the catcher discharge cylinder 141, the mixed swirl flow rotates along the inner wall of the cylindrical outer cylinder centered on the microbubble water discharge cylinder 141 to generate a cyclone in the other direction. It is provided to have a cyclone rotating part (144). In addition, the inside of the cyclone rotating part 144 is provided with a micro-bubble water discharge cylinder 141 in which the other side and one side are opened and the micro-bubbles from which the micro-contaminants are separated and filtered are discharged to one side. Here, the cyclone rotating part 144 provided with a dual cyclone on one side rotates counterclockwise in the shape of a cyclone on one side, and the number of microbubbles and microcontaminants generated using the cyclone phenomenon are separated and discharged. The microbubble generating cyclone generating body 145 is connected to the other side of the cyclone rotating unit 144 and provided with a lower opening in the form of a cone whose cross-sectional area is reduced in the other direction, so that the gas-liquid is rotated through the cyclone rotating unit 144 therein. The mixed solution is provided to have a cyclone generating unit 145a through which micro-bubble water generation and micro-contaminants are separated and filtered by the cyclone phenomenon, and the micro-contaminants are concentrated and discharged by the reduced cross-sectional area while moving to the other side. Concentrated discharge body 146 is disposed on the other side of the microbubble generating cyclone generating body 145, the microcontaminants through the microbubble cyclone generating body 145 inside the microcontaminants through the concentration and discharge space (146a) The concentrator 121a is provided to have a fine pollutant discharge pipe 123 in the form of a hole to be discharged to the outside by the operation of the discharge actuator 124 after moving toward the microcontaminant collecting unit 121b. The disk filter 147 is disposed on one side of the microbubble water mixing and discharging pressurizing part 121, and the number of microbubbles in each microbubble water outlet 144c rotates counterclockwise while discharging occurs and agitation occurs to mix and form a plate A plurality of inclined guide disk filter layers are stacked from the outside to the inside of the disk filter so that the filtered microbubbles are discharged.

1 is a cross-sectional view showing a dual cyclone filter according to an embodiment of the present invention.

Figure 2 is an exploded view showing the dual cyclone filter of Figure 1.

Figure 3 is an assembly view showing the disk filter showing the dual cyclone filter of Figure 1.

4 is a configuration diagram and an exploded view of the disk filter of the dual cyclone filter of FIG.

5 is a venturi of the dual cyclone filter of FIG.

6 is a plan view of the dual cyclone filter of the dual cyclone filter of FIG.

1 is a cross-sectional view showing a dual cyclone filter according to an embodiment of the present invention.

1, the dual cyclone filter 100 according to another embodiment of the present invention is a venturi stirring unit 112, a dual cyclone filter body unit 120, a microbubble generator dual cyclone filter unit 140, and It includes a microbubble state measurement unit 150 . Here, the venturi agitator 112, the dual cyclone filter body 120, and the dual cyclone filter 140 are the same in the configuration of the dual cyclone filter 100 shown in Figs. Only the catcher state measuring unit 150 will be described as follows. The micro-bubble water state measurement unit 150 is disposed to be connected to the outer right position of one side of the micro-bubble water mixing and discharging pressurizing unit 121, and is provided to measure the residual chlorine and the ph of the micro-bubble oxidized water. This, the microbubble water state measurement unit 150 includes a measurement circulation tank 151, a microbubble water inlet pipe 152, a residual chlorine meter 153, a pH meter 154, and a microbubble recovery pipe 155. . The measurement circulation tank 151 is disposed on the outside of one side of the microbubble water mixed discharge pressurization unit 121, and the measurement circulation including a circulation flow path to measure the state while circulating the microbubble water generated in the dual cyclone filtration unit 140 The tank, the microbubble water inlet pipe 152 is disposed on the other side of the measurement circulation tank 151, and is connected to one side of the measurement circulation tank 151 and the microbubble water mixed discharge and pressurization unit 121 to measure the number of microbubbles. (151) is provided to be introduced into. The residual chlorine measuring device 153 is disposed on one side of the measuring circulation tank 151 and is inserted into the measuring circulation tank 151 to measure the residual chlorine in the introduced microbubbles. The pH meter 154 is disposed on one side of the measurement circulation tank 151 and is inserted into the measurement circulation tank 151 to measure the pH of the introduced purified water. According to the residual chlorine measurement value measured by the residual chlorine measuring device 153, the oxidizing agent is input from the oxidizing agent supply pipe 114, and the adsorption oxidizing agent is inputted through the adsorption oxidizing agent supply pipe 115 according to the Ph measurement value measured by the pH measuring device 154. provided to do The microbubble oxidation water recovery pipe 155 is disposed on one side of the measurement circulation tank 151, and is connected to one side of the measurement circulation tank 151 and the microbubble water mixed discharge pressurizing unit 121 to convert the measured number of microbubbles to the number of microbubbles. It is provided to be recovered and discharged to the discharge pipe 125 .

2 is a cross-sectional view showing a dual cyclone filter according to another embodiment of the present invention. 2, the dual cyclone filter 100 according to another embodiment of the present invention is a venturi stirring unit 112, a dual cyclone filter body unit 120, a microbubble generating device dual cyclone filter unit 140. include The above description is merely illustrative of the technical idea of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments.

The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

<Explanation of symbols for main parts of the drawing>
100: dual cyclone filter 110: venturi
111: inlet pipe 111a: inlet
111b: suction unit 112: venturi stirring unit
113: air supply pipe 114: oxidizer supply pipe
115: adsorption oxidizer supply pipe 120: dual cyclone filter body part
121: micro-bubble water mixing and discharging pressurizing part 121a: micro-pollutant concentration part
121b: micro pollutant collecting unit 122: micro pollutant concentration and discharge unit
123: fine pollutant discharge pipe 124: discharge actuator
125: fine bubble water discharge pipe 140: dual cyclone filtration unit
141: micro-bubble water discharge cylinder 142: gas-liquid mixing supply unit
143: radial cyclone inlet 144: cyclone rotating part
144a: cyclone rotation inlet 144b: dual cyclone rotation separation space
144c: microbubble water discharge part 144d: radial distribution flow path
145: microbubble generating cyclone generating body 145a: cyclone generating unit
146: concentrated discharge body 146a: concentrated discharge space
147: disk filter 150: micro-bubble number state measurement unit
151: measurement circulation tank 152: microbubble water inlet pipe
153: residual chlorine meter 154: ph meter
155: fine bubble collection pipe

Claims (9)

A venturi agitator for generating agitation flow while passing a fluid supplied through the venturi agitator, and selectively supplying air and an oxidizing agent by suction pressure generated at the passage position to agitate microbubble water and microbubble oxidized water as needed; When the fluid passes through the venturi agitator unit, it has a suction unit composed of a plurality of holes for selectively sucking air and an oxidizing agent, and the venturi stirring unit through which the gas-liquid mixed fluid passes by stirring the fluid and air, and a plurality of the venturi stirring units are stirred to one side Venturi having a suction space in which pressure is lowered due to flow generation;
A plurality of the venturi agitating parts are disposed inside the venturi, and an air supply pipe and an oxidizer supply pipe are installed so that the suction part of the air and the oxidizer composed of a plurality of holes from the other side to one side and one side are directed from the outside to the inside surface. When the fluid passes through the venturi stirring unit, the air sucked into a plurality of holes, the oxidizing agent and the mixed fluid pass through the stirring unit, and the mixed fluid passing through the plurality of stirring units merges with each other to generate a stirring flow;
an air supply pipe connected from the outside to the inside of the venturi and installed at one of a plurality of positions of the venturi agitator to selectively supply air so that a gas-liquid mixed fluid is generated in the venturi agitator;
an oxidizer supply pipe connected from the outside to the inside of the venturi and installed at one of a plurality of positions of the venturi agitator to selectively supply an oxidizing agent so that a gas-liquid mixed fluid is generated in the venturi agitator;
a radial cyclone inlet that is disposed on one side of the venturi agitator and is provided with a gas-liquid mixing supply for supplying a gas-liquid mixed fluid to the other side to the inner center; A bidirectional inflow passage cyclone rotating part is installed on one side of the radial cyclone inlet, and the rotation direction of the cyclone rotating part of the dual cyclone filter rotates counterclockwise to perform mixing and separation filtration to generate microbubble water and microcontaminants, a dual cyclone filter body having a micro-bubble water discharge cylinder provided in the form of a hole to discharge the micro-pollutants discharged to the micro-pollutant collecting unit where the micro-contaminants are filtered and collected through the catcher discharge cylinder;
a fine pollutant collecting unit disposed under the dual cyclone filter body and supported by the conical lower opening of the dual cyclone filter unit for concentrating and discharging fine pollutants to concentrate and discharge the fine pollutants separated and discharged; It is provided in the form of a partition wall inclined toward the inner surface of the filtration space in the other direction around the outer periphery of the cyclone generating body for generating microbubbles. a fine pollutant discharge pipe equipped with a
a discharge actuator installed on the fine pollutant discharge pipe and operated for a preset time to discharge the pollutant to the outside through the fine pollutant discharge pipe; and a cylindrical tube-shaped micro-bubble water discharge pipe disposed on one side of the dual cyclone filter body and discharging the micro-bubble water filtered in the upper filtration space to the outside; A dual cyclone filter comprising a. delete delete delete According to claim 1, wherein the dual cyclone filter body is supported on one side of the inside, the mixed fluid is connected to the venturi agitator on the other side in the center of the inner center of the microbubble water mixing and discharging pressurization part is distributed radially to the other side at each position. a dual cyclone filtration unit having a plurality of dual cyclone filtration spaces while moving to the side;
It is disposed in the center of the dual cyclone filter body, and is connected to the gas-liquid mixing supply unit in the center of the inner center of the microbubble water mixing and discharging pressurization unit to supply a mixed swirl flow from the other side to one side at one end of the tube shape at a plurality of radial positions, respectively. a dual cyclone filter that is connected in an outward direction and includes the radial cyclone inlet for distributing the mixed swirl flow to a plurality of radial positions;
It is disposed at a plurality of radial positions in the center of the dual cyclone filter body, and it is located on one side connected to the inlet branch pipe of the radial cyclone inlet, and discharges microbubble water that blocks some of the microbubbles to the inside. A cylinder having a cyclone rotation space in which a cyclone is generated in the other direction while the mixed liquid flowing into the cylinder rotates the internal rotation space of the cyclone rotating part constraining the microbubble water discharge cylinder. A micro-bubble generating cyclone generating body having a micro-bubble water discharge space that is opened and the micro-bubble water separated and filtered of micro-contaminants is discharged to one side, and one side is provided in the form of a dual cyclone;
The microbubble generating cyclone generating body is disposed connected to the other side of the cyclone rotating part of the microbubble generating cyclone generating body and having a reduced cross-sectional area in the other direction. a cyclone generating unit having a cyclone generating space where the material is separated and filtered and concentrated by the reduced cross-sectional area of the microbubble generating cyclone generating body while moving to the other side;
The dual cyclone is disposed on the other side of the dual cyclone filtration unit, and a fine pollutant collection unit for filtering and collecting fine pollutants separated and filtered through the cyclone generating unit inside, a fine pollutant discharge pipe for discharging the collected pollutants, and the dual cyclone A dual cyclone filter comprising a; it is disposed on one side of the filtration unit, and the micro-bubble water mixing and discharging pressurizing unit for mixing the micro-bubble water discharged to the micro-bubble water discharge cylinder for each micro-bubble water discharge. delete According to claim 1, wherein the dual cyclone filter body portion is arranged to be connected to the position of the microbubble water discharge pipe on one side of the microbubble water mixing and discharging pressurization part, the microbubble water state measuring unit for measuring the residual chlorine and ph of the microbubble water;
a measurement circulation tank provided to measure the state while circulating the microbubble water generated by the dual cyclone filter;
a microbubble water inlet pipe disposed on the other side of the measurement circulation tank, connected to one side of the measurement circulation tank and the microbubble water discharge pipe, through which the microbubble water flows into the measurement circulation tank;
a residual chlorine measuring device disposed on one side of the measuring circulation tank and inserted into the measuring circulation tank to measure the residual chlorine in the introduced microbubbles;
a Ph measuring device disposed on one side of the measuring circulation tank and measuring the Ph of the microbubbles introduced into the measuring circulation tank;
a microbubble recovery pipe disposed on the other side of the measurement circulation tank and connected to one side of the microbubble water discharge pipe to recover the measured microbubble water to be circulated to the microbubble water discharge pipe; A dual cyclone filter comprising a. The method according to claim 1, wherein the dual cyclone filter body part is disposed on one side of the inside of the microbubble water mixing and discharging pressurization part, the other side inside is connected to the dual cyclone filter part, and the other side is connected to the microbubble water discharge part. a disk filtration unit having a disk filtration space to separate and filter the supplied microbubble water by a disk filter; The disk filter unit is a disk filter in which a plurality of disk-shaped disks are stacked and the microbubble water, which is a material to be filtered, is filtered from the outside to the inside and discharged to the microbubble water discharge pipe; A dual cyclone filter comprising a. delete

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