KR101015477B1 - Micro buble creating device - Google Patents

Abstract

PURPOSE: A micro bubble generating device is provided, which can be used for sewage and wastewater treatment, water purification process, water purification of lake and river and the like. CONSTITUTION: A micro bubble generating device comprises: a power unit(1) applying rotation power; a first bubbling operation portion generating first bubbling action by fixing a rotation pumping member corresponding to a fixed pumping member after fixing the fixed pumping member between upper and lower bodies; and a second bubbling acting portion which forms a contact protrusion on the upper side and lower side. The second bubbling acting portion includes a rotating member and a circular plate body.

Description

Micro buble creating device

The present invention relates to a microbubble forming apparatus, and more particularly, to a microbubble forming apparatus having improved efficiency of forming a microbubble by mixing water and air more finely.

Recently, microbubbles (hereinafter, referred to as micro-foams) having excellent effects such as washing, beauty, heat, massage, and anion have been generated and widely used in various fields.

Micro-bubbles are less than 50㎛ in diameter are included in the general water is not visible to the naked eye. And, if the microbubble contains a large amount of water, a phenomenon that appears bluish milky appears.

On the other hand, the microbubble has a washing effect. The microbubble cleansing action helps the micropore to be easily penetrated into the pores due to its smaller size than the pores, helping to clean up the wastes and debris in the pores. Decreases the old keratin of, the microbubbles are attached to the negatively charged (-) charged residues slowly rise to the surface of the water, easy to remove, and does not use soap or bath towel, so it does not irritate It is safe for people with weak skin.

In addition, the microbubble has excellent skin beauty action to remove old dead skin cells of the skin and to remove the wastes blocking the pores, so that the moisture can penetrate more, and the microbubble of the microbubble gently stimulates the skin and elasticity. It helps to nourish and shine your skin. Furthermore, the microbubbles are reduced by the surface tension and the vibrations are generated due to the increasing pressure and the force to return the microbubbles to their original state, and the generation of the ultrasonic wave due to the rupture and the resulting micro-vibration gently massage the whole body. By releasing muscles and helping to improve blood circulation, the massage is excellent. In addition, due to the general renade effect (a phenomenon in which water molecules generate an anion with a weak current while water molecules generate instantaneous crushing, water droplets are charged with positive ions; Lenard Effect). It generates a lot more negative ions than water. Various microbubble generators (hereinafter, microbubble generators) for applying the effect of such microbubbles are variously known.

As such a microbubble generator, a tubular microbubble generator is known from Korean Patent No. 10-0491364. It should be noted that the inner diameter of the air feed pipe is much smaller than the diameter of the hole of the air inlet as shown in FIG. 1A, which means that the coarse two-phase flow of the air bubble-containing water flowing into the inlet of the pump, This is to avoid the flow phenomenon of mixed water and air. Such coarse anomalies can induce the so-called "sponge effect" of the pump, resulting in the manifestation of negative performance such as an intermittent pumping action of the pump.

In addition, the fine bubble generating impeller of the micro-foam forming device of the registered patent 10-0528104 shown in Figure 1b, 1c is installed in two stages with a predetermined interval on the output rotation shaft of the underwater motor, which is a bubble having a large particle diameter A plurality of rotary blades having a stepped radially when viewed from the bottom to be crushed is formed in a sawtooth shape. The lower part of the submersible motor is equipped with an impeller protecting member for discharging the microbubbles while wrapping the impeller for generating the microbubbles. Has a filter on it. Since the partition wall is to efficiently discharge the fine bubbles generated by the rotary blades of the fine bubble generating impeller, slits are formed. Particularly, the partition wall of the fine bubble generating impeller located at the lower portion has only the fine bubbles. Bubbles are discharged through the upper part of the formed partition wall and the remaining large particle size is formed as a partition without a slit so that the flow is directed to the upper microbubble generating impeller. It has a problem, and its life is short, which is not suitable for a microbubble forming apparatus.

In the accompanying drawings, the micro-foam forming apparatus of FIG. 1D according to FIG. 1D has a rotary impeller installed in a chamber and a motor shaft fixed inside the housing and rotated through the rotational force of the motor in multiple stages to suck in water. It is provided with a multi-stage pump for discharging, discharge motor is configured on one side of the cylindrical horizontal pump housing, and a horizontal axis using a coupling is formed. In addition, a plurality of rotating bodies formed with a body, a fan, and a cover are formed in the axial direction on the horizontal axis, and the body is cylindrical and has one side open, and a hole is formed in the center of the opposite surface to be opened. A plurality of guides and holes for guiding the flow of fluid to one side to both sides of the surface, that is, to the inner side in the circumferential direction, are formed. The multi-stage pump type microbubble forming device configured as described above sucks fluid to the inside of the housing while the impeller installed on the shaft and the axis is rotated by the rotation of the motor, and the sucked fluid flows through the chamber and the impeller stacked in multiple stages. While compressing in the process, the pressure and speed are gradually increased to discharge the fluid to the discharge port at high power, but there is a problem in that it cannot provide a greater amount of microbubble water.

Such a conventional bubble generating device requires a lot of power because the operating pressure is operated in the range of 4 ~ 7kg / ㎠, since the diameter of the bubble generated is about 50 ~ 100㎛, the ability to remove the pollutants of the bubble is reduced and operating costs There are a lot of drawbacks. In addition, in the water treatment, river and lake water purification, it was difficult to apply the conventional method in terms of efficiency and economic efficiency.

In particular, such microbubble-related apparatuses known in the art have only weak mechanical operation of microbubble and are inadequate for use with substantial mixed water.

The present invention has been devised in view of the above-mentioned matters, and it is possible to produce a large amount of gas at low power by microbubbling water such as air, ozone, and oxygen into water having a diameter of 1 to 10 μm at a pressure of relatively low tank pressure. High concentration of bubble water (water containing fine bubbles) to be used for sewage / wastewater treatment, water purification, water purification of rivers and lakes, sterilization of water bodies, oxygen supply, beauty water for food hygiene industry, etc. It is an object of the present invention to provide a microbubble generator.

An object of the present invention is to provide a micro-bubble forming apparatus in which a fine bubble is discharged through a discharge port by mixing water and air more finely over three orders.

Another object of the present invention is to provide a fixed member and a rotating member of a bubbling action structure for tertiary bubble formation in a microbubble forming apparatus.

The present invention provides a second bubbling action structure in which contact protrusions of the rotating member are inserted between the contact protrusions of the fixing member of the third foam forming device of the micro-bubble forming device to evenly contact the three protruding surfaces of the contact protrusions. It also has a purpose.

The microbubble forming apparatus as a means for achieving the above object,

A power unit made of a motor and a drive shaft and made of a cover to block the outside; A first housing, a blocking plate half-spaced at the inner lower end of the housing, a first and a second space keeping member located between the flange portions of the support plate from the flange portion of the first housing and blocking the outside; The second housing located outside the first space holding member, the third housings blocking the outside of the second space holding member, and are supported between the flange portion of the support plate from the flange portion of the first housing to assemble and fix them. Fixing assembly consisting of the support rod, the upper and lower fixing nuts for locking the upper and lower sides of the support rod; A housing having a plurality of rotary pumping members arranged on a rotating shaft of the motor, a plurality of fixed pumping members stacked between the rotary pumping members, a suction inlet for receiving the fluid and a discharge port for discharging the fluid; The air supply hose into which the outside air is sucked is introduced into the multistage pump, and the outside air is self-sucked by the rotational force of the rotary pump member, and the sucked air is contained in the water and flows through the inside of the multistage pump. It consists of a first bubbling operation unit having a pressure change plate is formed on the inner circumferential surface of the rotary pumping member located on the outer surface, several fixing members, and a rotating member axially fixed to the rotating shaft so as to rotate inside the fixing member. The rotating member is rotatably installed in the fixing member, and the pressure of the water is strengthened through the contact interval (a) and at the same time The second bubbling is made to be strong but the fixing member and the rotating member are made up of several stacked structures again, passing through the contact interval (a) between the other fixing member and the rotating member while the pressure is increased, and the bubbling efficiency is maximized. It may include a ring action part.

A fluid flow contact b is formed between the rotating member and the fixing member, and a flow path b is formed.

In addition, it is possible to implement a microbubble device in which only the contact gap a is formed as the projection of the rotating member rotates along the space c between the contact protrusions of the fixing member.

The present invention has an effect of providing a fine foam forming apparatus that is made of finer mixing of water and air to be discharged through the discharge port. According to the present invention, by sucking and circulating the hot water stored in the bathtub to generate a large amount of micro-bubbles with the hot water in the bathtub, washing, beauty, heat, massage, anion, etc. by the microbubbles have an excellent effect.

The present invention has been devised in view of the above-mentioned matters, and it is possible to produce a large amount of gas at low power by microbubbling water such as air, ozone, and oxygen into water having a diameter of 1 to 10 μm at a pressure of relatively low tank pressure. High concentration of bubble water (water containing fine bubbles) to be used for sewage / wastewater treatment, water purification, water purification of rivers and lakes, sterilization of water bodies, oxygen supply, beauty water for food hygiene industry, etc. One microbubble generator is provided.

As described above, according to the micro-bubble generating device according to the present invention, the gas melts into the fluid in the maximum amount by the strong vortex (swirl) of the fluid introduced through the pump, and guided by the flow of the fluid in the pressurized tank As the formed fluid performs centripetal spiral (rotary passage) movement, the flow velocity of the fluid in the pressurized tank is maximized so that water molecules are aligned and consolidated in order, and negative pressure (relatively low) on the axis of the centripetal motion (center line) Pressure) is formed and dissolved gas molecules start to separate from the water molecules, and at the last bubble water discharging means, instantaneously high concentrations of microbubbles are formed by cavitation and fast flow due to cavitation and rapid flow rate, which leads to milky bubble water. Will be generated. In addition, the micro-bubble generating device according to the present invention generates a large amount of high-concentration bubble water with a small power by small bubbles in the water to a size of 1 ~ 10㎛ diameter in the water at a low pressure of 1.5 ~ 3kg / ㎠ to generate sewage and wastewater It is a device that can be effectively used in various industries such as water treatment, water treatment, water purification of rivers and lakes, sterilization of water bodies, oxygen supply, and food hygiene industry.

1A to 1D are views of a conventionally known fine bubble forming apparatus,
Figure 2 is a perspective view of the microbubble forming apparatus of the present invention,
Figure 3 is an exploded perspective view of the microbubble forming apparatus of the present invention,
4 is a cross-sectional view of the combination of the present invention micro-foam forming device,
5a to 5d are excerpts and a front view of the main portion of the fixing member and the rotating member constituting the tertiary bubbling portion of the present invention,
6A and 6B are cross-sectional views and enlarged views illustrating the operation of the second bubbling portion of the present invention;
7 to 8a, 8e shows an embodiment of the rotating member and the holding member of another embodiment of the present invention microbubble forming apparatus,
10 to 12a, 12d shows an embodiment of the rotating member and the holding member of the third embodiment of the present invention microbubble forming apparatus,
13A to 13C show an embodiment of an air injection unit of the present invention microbubble forming apparatus.

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

2 is a perspective view of the microbubble forming apparatus of the present invention, FIG. 3 is an exploded perspective view of the microbubble forming apparatus of the present invention, FIG. 4 is a cross-sectional view of a combination of the microbubble forming apparatus of the present invention, and FIGS. Excerpts and front views of the main parts of the fixing member and the rotating member constituting the second bubbling action of the present invention.

The present invention microbubble forming apparatus according to the drawings is largely the power unit 1, the upper body (2), the first bubbling action (3), the second bubbling action (4), the lower It is divided into a body (5).

The power unit 1 is composed of a motor 11 and the motor shaft (11a), forming a flange (12) is formed a bolt hole 121 for assembly and a cover for blocking the outside of the motor 11 ( 13).

The upper body 2 connects power transfer between the power unit 1 and the first and second bubbling action units 3 and 4 to enable power transmission.

That is, the cylindrical body 214, the upper flange 213 of the upper portion and the lower flange 215 of the lower portion consisting of the bottom portion 216 through the hole 216a through which the rotating shaft passes through the center ) Is formed. In particular, the inner side of the coupler 23 is connected to the motor shaft 11a and the rotating shaft 29 of the power unit 1, the lower end of the lower flange 215 is a bubbling action (3) (4) The upper edge of the cylindrical body 22 and the ring-shaped cylinders 31, 43, 43a forms a joint.

The structure of the 1st, 2nd bubbling action part 3 (4) is demonstrated.

The first bubbling action (3) is a rotating shaft of the rotating pumping member 32 for fixing the fixed pumping member 33 to be described later on the inside of the plurality of ring-shaped cylinders 31 are laminated and performs the corresponding rotational pumping It is fixed to the 29 and the rotating pumping member 32 rotates between the fixed pumping member 33, the high-pressure fluid rises as a bubble forming structure, a plurality of ring-shaped cylinder 31 in a double tube structure in the cylindrical body (22) These are stacked in a structure consisting of a support jaw (not shown) in the upper edge portion of each ring-shaped cylinder (31).

The fixed pumping member 33 includes a lower plate body 331 fixed to the inner side of the ring-shaped cylinder 31 and a fixed wing 332 assembled thereto. The rotary pumping member 32 fixes the rotary plate body 331 through the shaft tube 34 between the rotary shaft 29 and the shaft portion 333, and a rotary blade 332 is formed on the rotary plate body 331. .

The fixed pumping member 33, the rotary pumping member 32, and the ring-shaped cylinder 31 of this structure are stacked several times to form a fine bubble by rotating the pressurized fluid mixed with air at high speed.

As a fixed pumping member 33, a kind of diffuser is formed as the ring-shaped cylinder 31, and the rotary pumping member 32, impeller, which is arranged on the rotating shaft 29, is positioned between the fixed pumping member 33. The outside air is sucked by the rotational force of the rotary pumping member 32, and the sucked air is mixed with water (fluid) to rotate the multi-stage first bubbling action part 3 and fix the pumping members 32 and 33. The microbubbles are formed through the mixed fluid by forcibly moving the narrow outflow space (flow path) at a high pressure in the interior thereof.

The second bubbling action portion 4 is composed of a central fixing member 42 and a rotating member 41 which is axially fixed to the rotating shaft 29 so as to rotate on the upper and lower layers of the fixing member 42.

As shown in FIGS. 5A and 5B, the fixing member 42 is a circular plate body 425 having a circular opening portion 423 formed at the center thereof, thereby forming a fixing hole 421 at a predetermined position at the end of the plate body. It is fixed to the inner wall, by forming a plurality of contact projections 422 and the bubble hole 424 on the upper and lower surfaces. The bubble ball 424 is a through hole of upper and lower light beams (a narrow upper side and a wide lower side).

Corresponding rotating member 41 forms a central hole 413 fixed to the rotating shaft 29 while being small in size, as shown in FIGS. 5C and 5D, which will be described later. It is formed, but the rotating plate body 415 formed bubble holes 414 of the upper and lower light.

The contact interval a between the contact protrusions 412 and 422 between the fixing member 42 and the rotating member 41 forms a flow path through which the mixed fluid forming the primary microbubbles passes. The contact gap a is formed and an assembly set of the fixing member 42 and the rotating member 41 is provided.

The microbubble formed primarily through the contact interval a between the contact members 412 and 422 of the rotating member 41 and the fixing member 42 has a more pressurized fluid flow, which will be described later with reference to FIGS. More fine bubbles are formed through 6b. The lower end of the rotary shaft 29 is fastened as a nut to the end 29b for assembling and disassembling the rotary pumping members 32 of the first bubbling action part 3.

The assembly configuration of the present invention microbubble forming apparatus,

It is installed on the lower body (5). The lower body 5 is supported on the pedestal 7 and the primary bubble forming part 6 is installed at the lower portion of the body 50 so as to eject oxygen to the space side.

The primary bubble forming unit 6 blows air in the body 50 of the connector 62 and the lower body 5 which are connected to the supply hose (not shown), as shown in FIGS. 13A to 13C to be described later. The blowing pipe 61 is formed as a porous body to be made, and the blowing hole 63 is implemented in various forms.

The lower body 5 forms an inlet 51 and an outlet 52 centering on the body 50 forming a floor and a space in the middle, and flanges 51a toward each inlet and outlet 51, 52. 52a), and the blocking wall 53 is formed inside the outlet port 52 side so that the introduced fluid is mixed with air to form the first bubbling action part 3 and the second bubbling action part 4, respectively. It moves upwards by the pressurized rotational force and then descends and is discharged.

In addition, the lower body 5 forms an opening upwards, but the blocking wall 53 and the ring-shaped support end portion are formed so that the lower end of the first bubbling action portion 3 is seated inside each of the flanges 51a and 52a. On the 55, the supporting jaws 53a and 55a are formed.

The first bubbling action (3) is assembled on the support step (53a, 55a) three stages in the set state, that is, the fixed pump member 33 is fixed in the ring-shaped cylinder 31, the rotating shaft 29 The rotary pumping member 32 is rotatably stacked in a state in which the rotary pumping member 32 is arranged thereon, and the second bubbling action portion 4 is disposed therein in the ring-shaped cylinder 43 or 43a. ) Is installed in a state of assembling, and is rotated and fixed pumping members (32, 33) forming a diffuser and a ring-shaped cylinder (31) which forms an outlet hole (31a) of the first bubbling action (3) thereon. It is assembled, and the mixed fluid in which the microbubble is formed along the flow path b formed between the cylindrical body 22 positioned outside thereof through the outlet hole 31a is lowered.

On the upper end of the rotary shaft 29 in which the first and second bubbling action portions 3 and 4 are installed, the elastic member 28 is interposed on the end 29a side through the coupler 23 on the motor shaft 11a. Connected.

6A and 6B of the accompanying drawings are cross-sectional views and enlarged views illustrating the operation of the first and second bubbling action portions of the present invention.

The microbubble forming apparatus of the present invention according to the drawings acts as follows.

As the inflow fluid (water) is introduced through the inlet 51, the bubbling action of the first and second bubbling action units 3 and 4 is started by the rotation of the rotary shaft 29. At this time, the known air, concentrated oxygen, etc. are blown out to form bubbles in the fluid primarily through the blow holes 63 of the primary blow holes 61 of the primary bubble forming unit 6, and upwards as a mixed fluid. Pumped.

Rotation of the rotary pumping member 32 of the first bubbling action part 3 over three stages increases the pressure of the mixed fluid in which the primary bubble is formed.

The raised bubble mixed fluid rises in a state in which a fine bubble is formed by repeating foam formation over three stages of the second bubbling action part 4, and a plurality of contact protrusions 412 are formed through the second bubbling action part 4. The finer bubbles are formed while passing through the contact gap (a) between the (422). The final microbubble mixed fluid is bubbled by the first bubbling action part 3 of the final stage 1 and the cylindrical body 22 and the ring-shaped cylinders 31, 43, 43a through the outlet hole 31a. It descends to the outlet port 52 side while flowing in the flow path b formed between them.

7 to 9a and 9b of the accompanying drawings as another embodiment of the second bubbling action of the microbubble forming apparatus of the present invention, Figure 7 is a microbubble forming device to which the second bubbling action of the present invention microbubble forming device 8A to 8E are side views and plan views of the second bubbling action portion of the microbubble forming apparatus of the present invention, and FIGS. 9A and 9B are explanatory views of the second bubble action portion of the microbubble forming apparatus of the present invention. .

The rotating member 41 and the fixing member 42 of the second bubbling action 4 of another embodiment of the present invention microbubble forming apparatus according to the drawings will be described.

The second bubbling action portion 4 of the microbubble forming apparatus of the present invention comprises a holding member 42 and a rotating member 41 rotating above and below the holding member 42.

As described above, the microbubble forming apparatus of the present invention includes the above-described power unit 1, the upper body 2, the first bubbling action 3, the second bubbling action 4 and the lower portion. Made of a body (5).

As shown in FIGS. 8A and 8B, the fixing member 42 is a circular plate body 425 having a circular opening portion 423 formed at the center thereof, and a fixing hole 421 is formed at a predetermined position at the end of the plate body to form a ring-shaped cylinder 43. It is fixed to the inner wall, and by forming a plurality of contact projections 422 and the bubble hole 424 on the upper and lower surfaces. The bubble ball 424 is a through hole of upper and lower light beams (a narrow upper side and a wide lower side).

Correspondingly, the rotating member 41 rotating in one fixing member 42 forms a central hole 413 fixed to the rotating shaft 29 while being small in size, as shown in FIGS. 8C and 8D. The projection 412 is formed on the upper and lower surfaces, and is a rotating plate body 415 in which bubble holes 414 of upper and lower light are formed.

The fixing member 42 forms a predetermined circular space c in addition to the contact protrusion 422 fixed in a circular shape. The contact protrusions 422 of the rotating members 41 are inserted into the space c to some depth to rotate, and fine bubbling is formed between the rotating contact protrusions 412 and the fixed contact protrusions 422. The contact gap a is formed.

Therefore, the mixed fluid in which the primary and third bubbles are formed by the high-speed rotation of the rotary shaft 29 is the contact protrusions 412 and 422 of the fixed member 42 and the rotary member 41, and the bubble balls 414 and 424. As they pass through them, they act more finely bubbling (bubble forming).

This differs from Example 1 in that the contact area of the mixed fluid is widened, which leads to a significant increase in the bubbling effect.

10 to 12b illustrate another embodiment of the second bubbling action portion of the microbubble forming apparatus of the present invention. FIG. 10 is a cross-sectional view to which the second bubbling action portion of the microbubble forming apparatus of the present invention is applied. 11D are side views and plan views of the rotating member and the fixing member of the second bubbling action portion of the microbubble forming apparatus of the present invention, and FIGS. 12A and 12B are explanatory views of the operation of the second bubbling action portion of the microbubble forming apparatus of the present invention.

The description of another embodiment of the present invention microbubble forming apparatus according to the drawings is the same as most of the above-described embodiment, except for the second bubbling action (4), so the same description is omitted.

The microbubble forming apparatus of the present invention is divided into a power unit (1), an upper body (2), a first bubbling action (3), a second bubbling action (4) and a lower body (5) Hereinafter, only the second bubbling action unit 4 will be described.

The second bubbling action 4 is composed of only a plurality of rotating members (41).

As shown in FIGS. 11A to 11D, the rotating member 41 forms a central hole 413 fixed to the rotating shaft 29, and forms contact protrusions 412 on the upper and lower surfaces thereof, and the bubble hole of the upper and lower light beams ( A rotary plate body 415 having a 414 formed therein is provided with contact recess grooves 416 intermittently at the edge of the rotary plate body 415 to generate pressure and contact frictional force between the rotary plate body 415 and the ring-shaped cylinder 43. Done.

The rotating member 41 is bubbling along the gap a between the contact protrusions 412 or through the bubble hole 414, but between the inner wall of the ring-shaped cylinder 43 and the contact injection groove 416. Even in the high-speed rotation is formed a large amount of fine bubbles.

12A and 12B, the rotating member 41 can be enlarged and expanded in the shape of the bubble hole 414, and can be appropriately adjusted according to the bubble effect.

13A to 13C of the accompanying drawings are sectional views showing an embodiment of the injection hole 61 of the primary bubble forming part 6 of the microbubble forming apparatus of the present invention.

The blowoff pipe 61 of the primary bubble forming part 6 shown in FIG. 13A forms a plurality of blowout holes 63 and is drilled in the vertical and horizontal directions, and the blowout hole 63 of FIG. 13B has an inner side. It is this wide and narrow narrow hole of the inner and outer narrow, and the blow hole 63 of FIG. 13C forms the blow hole which inclined in the direction which rises from the inner side to the outer side.

As described above, the present invention has been described with reference to preferred embodiments, but the present invention is not limited to these embodiments, and the embodiments are merely combined and applied to the known art in the claims and the detailed description of the present invention. Techniques that can be modified and used by those skilled in the art are included in the present invention.

1: power unit, 11: motor, 11a: motor shaft, 12: flange, 13: cover,
2: connecting portion, 29: rotating shaft, 3: first bubbling action,
32: rotary pumping member, 321: rotating plate body, 322: rotary blade, 33: fixed pumping member,
331: a fixed plate body, 332: a rotary wing, 4: the second bubbling action, 41: a rotating member,
412: contact projection, 413: opening, 414: bubble ball, 42: fixing member, 422: contact projection,
423: opening, 424: bubble ball, 5: bottom body, 51, 52: inlet and outlet, 53: blocking wall,
6: primary bubble forming part, 61: blowoff pipe, 63: blowout hole, 7; stand.

Claims (7)

A bubbling action unit for generating a first bubbling action by fixing a rotating pumping member corresponding to the fixed pumping member after fixing the fixed pumping member between the power unit applying the rotating power, the upper and lower bodies, and the upper and lower bodies. In the fine bubble forming device consisting of air supply means,
Contact protrusions 412 are formed on the upper and lower surfaces, but the bubbling holes 414 are formed to rotate in contact with the rotating member 41 fixed to the rotating shaft 29 and the contact protrusions 412 and the micro contact gap a. Forming a second bubbling action (4) consisting of fixing members (42) formed of circular plate bodies (425) having upper and lower contact protrusions (422) formed on upper and lower surfaces, and forming bubble holes (424),
The microbubble forming apparatus, characterized in that the mixed fluid having bubbles formed in the water by the primary air blowing to form a third bubbling mixed fluid through the first bubbling action, the second bubbling action. A power unit 1 for applying rotational power to the rotary shaft 29 connected to the motor shaft 11a,
An upper body 2 formed of a cylindrical body 214, an upper flange 213, and a lower flange 215 below the power unit 1,
The inlet 51 and the outlet 52 are formed around the body 50, and flanges 51a and 52a are formed at each of the inlet and outlet 51 and 52 sides, and inward of the outlet 52 side. A lower body 5 which forms a blocking wall 53 and moves the introduced fluid upward;
A cylindrical body 22 installed between the upper body 2 and the lower body 5,
The flow passage b is formed in the cylindrical body 22 by stacking the ring-shaped cylinders 31 to communicate with the outlet 31a. A first bubbling action portion (3) which is fixed to the rotary pump (32) corresponding to the rotary shaft (33);
The contact member 412 is formed on the inside of the cylindrical body 22 on the upper and lower surfaces, and the rotating member 41 is fixed to the rotating shaft 29, and the contacting member 412 is in contact with the rotating contact with a micro contact interval a. First bubbling action by providing a second bubbling action part 4 consisting of a fixing member 42 for fixing the circular plate body 425 formed on the upper and lower surfaces of the protrusions 422 to the inner wall of the ring-shaped cylinder 43. Through the bubbling portion 3 and the second bubbling action portion 4, a mixed fluid having fine bubbles is obtained, and the flow passage b inside the cylindrical body 22 is passed through the outlet hole 31a of the upper ring-shaped cylinder 31. Microbubble forming apparatus characterized in that the mixed fluid is discharged according to. The method according to claim 1 or 2,
The second bubbling action (4) is characterized in that the contact projection 422 of the rotating member 41 is inserted between the contact projections 422 of the fixing member 42 to form a circular space (c) to rotate Fine foam forming device. The method according to claim 1 or 2,
Microbubble forming apparatus characterized in that it further comprises a primary bubble forming portion (6) for forming a primary bubble by injecting air into the supply fluid (water) in the body (50) of the lower body (5). The method of claim 4, wherein
The second bubbling action portion (4) microbubble forming apparatus, characterized in that consisting of only the rotating member (41). The method of claim 3,
Microbubble forming apparatus, characterized in that to form a bubbling hole (414) (424) of the upper and lower light. The method of claim 5,
Microbubble forming apparatus for further forming a contact inlet groove 416 on the edge of the rotary member (41).

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