KR20100104973A - Micro bubble nozzle and bubble generating module - Google Patents

Abstract

PURPOSE: A micro-bubble type nozzle and a module for generating bubbles are provided to prevent the risk of electric-shocks by performing a micro-scale bubble generating process without electronic devices. CONSTITUTION: A bubble module(200) includes a nozzle(100) and a housing. The nozzle is installed in the housing. A pipe for inhaling air is installed on the lateral side of the housing. An impeller(175) is formed in the housing. Fluid through the impeller and the air are mixed to generate bubbles in a bubble generating unit(160). A valve(185) prevents the escape of bubbles from the housing. A guiding unit guides the bubbles to the nozzle.

Description

Micro bubble nozzle and Bubble generating module

The present invention relates to a microbubble nozzle and a bubble generating module, and more particularly, to a microbubble nozzle and a bubble generating module capable of generating bubbles and micro-sized bubbles in a low pressure environment such as general water pressure through pressure control. will be.

In general, a large amount of oxygen is contained in the water can inhabit aquatic plants or animals, if the oxygen is insufficient in the water, the water is contaminated because eutrophication proceeds.

In other words, if a lot of oxygen in the water, the nutrients contained in the water is decomposed by the oxygen can be purified to clean water, the amount of dissolved oxygen that can be contained in the water is limited because the amount of pollutants in the water Self-cleaning becomes difficult when introduced to

Water with a high amount of dissolved oxygen, the amount of oxygen contained in the water, may also act as a bactericidal action such as hydrogen peroxide to inhibit the generation of bad bacteria in the water.

On the other hand, as described above, the use of oxygen in the water has been conventionally used mainly in water purification facilities, fish farms and washing machines, etc. In the purification facilities, oxygen bubbles are aerated inside the septic tank to activate the decomposition of waste water by oxygen.

In addition, aquaculture farms disintegrate feed wastes or wastes deposited on the bottom, or decompose pollutants generated from excreta or feed, and sterilize the water to prevent fish from being contaminated by germs.

In addition, the washing machine sterilizes the laundry by supplying micronized microbubbles to the washing water. In the washing or rinsing process, the microbubble contacts the laundry and the cloth is sterilized by the microbubble.

In recent years, the application of the microbubble has been diversified, and the microbubble has expanded its application to not only the skin beauty field such as skin pore cleaning and massage action but also the health field such as diet effect. Bathtubs which generate microbubbles are also emerging.

However, in order to generate micro bubbles as described above, it has been common to use a pressure pump.

In other words, in order to generate the micro bubbles as described above, the micro bubbles must be introduced into the micro bubble generating nozzle or the micro bubble generating device in a state in which water and oxygen are pressurized.

In order to provide such a pressurized environment, a pressurized pump and an electric device for driving the pressurized pump are also essential.

Therefore, the product generating the micro bubble itself or applying the generated micro bubble has a weight with a large volume, there is a problem that it is difficult to miniaturize and light weight.

The present invention for solving the problems described above, and a microbubble nozzle and bubble module for generating bubbles and micrometer-sized bubbles in a low pressure environment, such as general water pressure without the pressure pump and the electric device for driving the pressure pump will be.

In order to achieve the above object, according to the present invention, the microbubble nozzle and module,

It consists of a plate and a first hole formed in the plate,

A microbubble nozzle formed on the plate, the guide part having a second hole formed of a large diameter part and a small diameter part, wherein a cross-sectional area of the first hole is larger than a second hole;

A nozzle, a housing having the nozzle therein, a pipe for sucking air formed on a side of the housing, and an impeller formed inside the housing,

A valve for forming a bubble by mixing the fluid passing through the impeller and the air passing through the pipe to form a bubble, and a valve for preventing a bubble formed from the bubble forming part from flowing out of the housing;

Extended passages are provided to allow the bubbles formed in the bubble forming unit to pass to the nozzles,

The nozzle is characterized in that it comprises a plate, a first hole formed in the plate, a guide portion having a second hole formed in the plate, a large diameter portion and a small diameter portion having a cross-sectional area smaller than the cross-sectional area of the first hole.

(1) While a conventional micro bubble generating product requires a pressurized pump and an electric device for driving the same, the present invention uses a bubble module and a micro bubble nozzle to make microbubbles refined even in a low pressure environment such as general water pressure. Enable the generation of

(2) By controlling the pressure applied to the nozzle by using the hole for pressure adjustment in the nozzle for the micro bubble, the bubble formed in the first millimeter size is passed through the hole for refining the micro size to the second size. The generation of bubbles can be maximized.

(3) The generation and the amount of micro-sized bubbles can be controlled by simple membership of nozzles.

(4) According to the adjustment of the water pressure, only the primary refinement bubble can be generated, and the primary refinement bubble and the secondary refinement bubble can be generated simultaneously.

(5) Since the pressure pump and the electric device for driving the same are not used, the product can be miniaturized and reduced in weight, and noise is not generated by the pressure pump.

(6) It is easy to use because it does not need a separate control unit for micro bubble generation.

(7) Since electric devices are not required, there is no danger of electric shock by water and space restrictions of place of use.

(8) In operation, power such as electricity is not required, so maintenance costs are almost insignificant.

(9) The structure of the microbubble nozzle and bubble module is simple, and maintenance and repair are easy.

(10) When high concentration of oxygen is injected into the air intake unit that draws air into the bubble module, the concentration of oxygen contained in the water may be increased by 15 ppm or more, and ozone (O 3) may be injected into the air intake unit. In this case, ozone can be dissolved by dissolving ozone in water.

(11) The bubble module according to the present invention is applied to a process of making oxygen shochu containing a large amount of oxygen by injecting a high concentration of oxygen into an air intake while passing the shochu at a constant pressure into the module. Not only this is possible, but by injecting a separate ozone (O3) to the air intake can automatically sterilize and clean the pipeline by the sterilization ability of ozone.

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

1A is a front view of a preferred embodiment of a microbubble nozzle according to the present invention, FIG. 1B is a sectional view, and FIG. 1C is a perspective view.

2A is a perspective view of a preferred embodiment of a bubble module according to the present invention, and FIG. 2B is a partial cross-sectional view of the bubble module.

Figure 3a is another preferred embodiment of the microbubble nozzle according to the present invention, Figure 3b is another preferred embodiment of the microbubble nozzle according to the present invention, Figure 3c is a preferred embodiment of the microbubble nozzle according to the present invention Another embodiment.

Hereinafter, a bubble module for generating bubbles will be described with reference to FIGS. 1A and 1B, and FIGS. 1C and 2A and 2B.

Bubbles are generated by the microbubble nozzle and bubble module according to the present invention as follows.

First, generating the first micronized bubble is as follows.

The water coupling part 310 of the water supply line 300 and the lower housing 230 of the bubble module are coupled by screw coupling.

Water supplied from the water supply line 300 collides with the impeller 175 located at the end of the water coupler 231 of the lower housing 230.

Water supplied from the water supply line 300 is disturbed by the normal flow by the collision with the impeller 175, so that the vortex is formed.

The impeller 175 is as follows.

The impeller 175 is formed with a wing (not shown), the center is the air intake passage 189 of the impeller.

The impeller 175 is in contact with the air intake portion 180 has a thick cross section, the opposite side of the air intake portion 180 is made of a thin cross section.

The thick portion of the cross section is a portion in which water flowing from the water supply line 300 collides to form a vortex in the water.

The thin section is introduced into the bubble generator 160 through the inclined portion (not shown) in which the vortex is formed in the thin section, and the cross section is formed in the thin section. .

The air intake passage 189 of the impeller is T-shaped in cross section, a portion of the passage forms a straight portion parallel to the discharge direction of the fluid, one side is open, the other side is blocked.

A part of the air intake passage 189 of the impeller that runs vertically from the straight portion of the passage communicates with the intake pipe 181 of the air intake portion, which will be described later.

The air intake passage 189 of the impeller is in communication with the air intake passage 188 of the lower housing formed in the lower housing 230.

When the impeller 175 is mounted to the lower housing 230, a groove is formed to mount the O-ring 192.

The O-ring 192 serves to seal air or bubbles sucked into the housing 210 from the air intake unit 180 so as not to be discharged to the outside of the housing 210.

A check valve 185 is formed between the lower housing 230 and the air intake unit 180 to prevent backflow.

The configuration of the check valve 185 is as follows.

A second seal 195 of the check valve is provided at an end of the air intake passage 188 of the lower housing, and an air intake passage 188 of the lower housing is provided at the center of the second seal 195 of the check valve. Hole is formed so as to communicate with.

The second sealing 195 of the check valve is in contact with the check valve 185 in accordance with the operation of the bubble module 200, to block or allow the intake of air.

That is, when the pressure of the air suction unit 180 is relatively high, air flows through the suction pipe 181 of the air suction unit 180.

At this time, the check valve 185 is moved to the inside of the housing 210, the air passes through the air intake passage 188 of the lower housing, and through the air intake passage 189 of the impeller the housing 210 is introduced into.

On the contrary, when the pressure inside the housing 210 is the same or relatively higher than the pressure of the air intake unit 180, the air outside the bubble module 200 is an air intake passage of the lower housing. It is impossible to pass 188, rather, water supplied from the water supply line 300 or bubbles formed from the bubble forming unit 160 may be discharged to the outside of the housing 210.

However, in the above case, the check valve 185 is moved to the outside of the housing 210, that is, the suction pipe 181 side of the air intake portion, in accordance with the movement of the check valve 185, Since the suction pipe 181 of the air suction unit is closed, water or bubbles are not discharged to the outside of the housing 210.

The air intake unit 180 is as follows.

The air suction unit 180 has the suction pipe 181, and a thread is formed on an outer circumferential surface of the suction pipe 181.

A portion of the thread formed on the outer circumferential surface of the suction pipe and the air suction amount adjusting screw 182 for adjusting the amount of air introduced into the housing 210 are coupled by screwing.

According to the degree of rotation of the air suction amount adjusting screw 182, the cross-sectional area of the suction pipe 181 is changed, it is possible to adjust the amount of air introduced into the housing 210.

A portion of the thread formed on the outer circumferential surface of the suction pipe is coupled to the air suction pipe connecting portion 186 by screwing to form a coupling portion 184 between the air suction pipe 181 and the lower housing 230.

The air inlet pipe connecting portion 186 has a circular cross section, and a thread is formed on the inner circumferential surface thereof.

There is a first sealing 187 of the check valve between the air intake 180 and the air intake pipe connection 181 screwed.

The cross-section of the first seal 187 of the check valve is circular, and the cross-section of the first seal 187 may be different according to the shape of the connection portion 181 of the air intake pipe.

The first seal 187 of the check valve is moved to the outside of the housing 210 when the check valve 185 moves to the outside of the lower housing 230 in response to a change in pressure. Prevent exit

The first sealing 187 of the check valve preferably uses an elastic member that can be slightly deformed by an applied pressure or force.

The impeller 175 is in contact with the bubble forming unit 160, and the impeller 175 is in contact with the lower housing 230.

The cross section of the bubble forming unit 160 is circular, the cross section is the shape of a streamlined tube formed with a large diameter portion and a small diameter portion.

The large diameter portion 161 of the bubble forming portion 160 is in contact with the end of the impeller 175, by the contact between the impeller 175 and the bubble forming portion 160 to form an impeller and bubble A negative connection 202 is formed.

The connecting portion 202 between the impeller 175 and the bubble forming unit 160 has an end portion of the impeller 175 having a larger cross-sectional area than that of the bubble forming unit's large diameter portion 161. They are piled up by wealth and fit together.

The impeller 175 is seated on the lower housing 230 and forms a first contact portion 201 and a second contact portion 203 in the process of being in contact with the inner space of the lower housing 230.

The cross section of the first contact portion 201 between the impeller and the lower housing 230 forms a straight line, and the longitudinal cross section has a circular shape.

The second contact portion 203 between the impeller and the lower housing 230 is formed as the impeller 175 is seated in a place (not shown) where the cross-sectional area of the lower housing 230 is narrowed, and the longitudinal section is circular. Shape.

The water in which the vortex is formed by the contact with the impeller 175 is rapidly increased in speed, and according to Bernoulli's law, the water enters the bubble forming unit 160 which will be described later with the pressure lowered.

The bubble forming unit 160 forming a large bubble is as follows.

The bubble forming unit 160 includes a large diameter portion 161 through which water supplied from the water supply line 300 flows and a small diameter portion 162 through which fluid is discharged.

An inclined portion 163 is formed between the large diameter portion 161 of the bubble forming portion and the small diameter portion 162 of the bubble forming portion, and the bubble forming portion 160 is formed from the large diameter portion 161 to the small diameter portion 162. ), The cross-sectional area of the streamlined pipe 168 becomes smaller.

Water in which the vortex is formed by the impeller 175 flows into the large diameter portion 161 of the bubble forming portion 160.

An air suction unit 180 is formed on an outer surface of the lower housing 230 to communicate with the bubble forming unit 160 to introduce air for forming bubbles into water flowing into the bubble forming unit 160. It plays a role.

As described above, the air suction unit 180 is formed with a suction pipe 181, and the suction pipe 181 passes through the check valve 185 and communicates with the air suction passage 189 of the impeller. .

The vortex is formed by the collision with the impeller 175, and the large diameter portion 161 of the bubble forming portion 160, into which the water with a lower pressure flows, instead of a sudden increase in speed, has a low pressure, which is according to Bernoulli's law. Due to the Venturi effect.

Due to the Venturi effect, air flows into the large diameter portion 161 of the bubble forming portion 160 from the suction tube 181 of the air suction portion.

As such, air sucked into the bubble forming unit 160 from the suction pipe 181 of the air suction unit 180 and water supplied into the bubble forming unit 160 from the water supply line 300 are By mixing, large bubbles are formed in the bubble forming unit 160.

As described above, the bubble generated in the bubble forming unit 160 or the water in the bubble forming unit 160 is the suction pipe 181 of the air suction unit 180 is the air intake passage 189 of the impeller ), There is a possibility to flow back to the outside of the bubble module 200 through the suction pipe 181 of the air suction unit 180.

Therefore, as described above, the check valve 185 for preventing the back flow is formed between the suction pipe 181 of the air intake unit 180 and the bubble forming unit 160 to prevent the back flow.

Water flowing from the large diameter portion 161 of the bubble forming portion 160 and passing through the streamlined tube 168 in which the small diameter portion 162 of the bubble forming portion 160 is formed has a mass in which the inflow amount and the flow rate must be the same. By the law of conservation, the speed of the water passing through the small diameter portion 162 is increased.

In addition, the water passing through the small diameter portion 162 of the bubble forming unit 160 having a streamlined tube shape is increased in the water pressure during the passage through the small diameter portion 162, the expanded passage (169) Maximize the effect of cavitation impact on

Water containing large bubbles formed from the bubble forming unit 160 passes through a narrow passage including a small diameter portion 162 of the bubble forming portion and a straight portion 164 of the bubble forming portion.

Water containing large bubbles passing through the passage is introduced into the expanded passage 169.

The expanded passage 169 is as follows.

The expanded passage 169 has a connecting portion 165 of the expanded passage connected to the straight portion 164 of the bubble forming portion through which bubbles and water are discharged.

The connecting passage 165 of the expanded passage and the large diameter portion 166 of the expanded passage are connected, and the connecting passage 165 of the expanded passage and the large diameter portion 166 of the expanded passage of the expanded passage. The inclined portion 167 of the connection portion is formed.

The diameter of the large diameter portion 166 of the expanded passage is equal to the diameter of the expanded passage 169.

As the water containing the large bubbles formed from the bubble forming unit 160 passes through the expanded passage 169, the shock wave generated in the process of moving the fluid from the passage having the small cross-sectional area to the large passage is generated. As a result, bubbles with large particles are finely divided to form bubbles that are primarily micronized.

Hereinafter, referring to FIGS. 1A, 1B, and 1C, a microbubble nozzle 100 for refining a bubble firstly refined by a shock wave in an enlarged passage 169 to a second micro size will be described. Explain.

As described above, the large bubbles formed from the bubble forming unit 160 pass through the extended passage 169 and are first refined by the shock wave generated at this time.

Some of the bubbles firstly micronized are micronized into bubbles of a second micro size while passing through the second hole 153 formed in the guide part 150 of the microbubble nozzle 100.

Some of the bubbles, which are primarily micronized, do not pass through the microbubble nozzle 100, but pass through the first hole 111 having a larger cross-sectional area than the second hole 153, which will be described later, and the bubble module 200. Ejected to the outside.

The shape of the microbubble nozzle 100 is as follows.

The microbubble nozzle 100 includes a plate 113 having one end open, a guide part 150 formed at the center of the plate 113, and a second hole 111 formed in the plate 113. It is.

The plate 113 has a front portion 110 through which water containing bubbles flows in and discharges the bubbles.

The plate 113 has a side portion 120, and the side portion 120 of the plate is in contact with the upper housing 220, and the water containing the large bubbles formed from the bubble forming portion 160 includes the micro. The expanded passage 169 leads to a bubble nozzle.

The front portion 110 of the plate 113 is formed with a guide portion 150 and the first hole 111 for adjusting the internal pressure.

The guide unit 150 guides the first micronized bubbles formed in the extended passage 169 to the second hole 153 to micronize the micronized bubbles.

The guide part 150 is formed with a second hole 153 for generating micro-sized bubbles.

The second hole 153 has a large diameter portion 152 having a relatively large cross-sectional area in a portion where the fluid flows, and a small diameter portion 151 having a relatively small cross-sectional area in a portion where the fluid is discharged.

The first refinement bubble passing through the extended passage 169 flows into the large diameter portion 152 of the second hole.

The first primary microbubble flows through the small diameter part 151 of the second hole through the large diameter part 152 of the second hole.

Since the small diameter portion 151 of the second hole has a very small cross-sectional area compared to the large diameter portion 152 of the second hole, the instant shear force is applied in the process of passing the first miniaturized bubble through the second hole 153. , Micronized into smaller micro sized bubbles.

Compared to the large diameter portion 152 of the second hole, the small diameter portion 151 of the second hole has a relatively small cross-sectional area of the bubble outlet, and the difference between the small diameter portion 151 and the large diameter portion 152 is different. It can be made by using slope or step between).

A part of the first micronized bubble passing through the expanded passage 169 passes through the first hole 111 for internal pressure control, not the microbubble nozzle 100, according to proper water pressure control. The bubble module 200 is discharged to the outside.

When the first micronized bubble passes through the bubble forming unit 160 in the expanded passage 169 and the second micronized bubble in the microbubble nozzle 100, the first micronized bubble is inclined to improve the shear force. Alternatively, when the hydraulic pressure is weakened because it must pass through the small diameter portion 151 of the second hole 153, which is a narrow flow path having a step, it may be difficult to discharge the secondary finely bubbled to the outside.

That is, when the water pressure supplied from the water supply line 300 is weak, the first micronized bubble having a millimeter size is discharged to the outside of the bubble module 200 through the first hole 111 for adjusting the internal pressure. Through the second hole 153, it may be difficult for the micro sized bubble to be discharged to the outside.

For this reason, the first hole 111 used for the internal pressure control in the plate 113 of the microbubble nozzle 100 is formed in the front part 110 of the plate, thereby adjusting the water pressure.

As the water pressure is controlled in this way, the firstly refined bubble passes through the second hole 153, which is a second hole finely refined to the second, and enables the generation of micro-sized bubbles and is maximized.

The second micronized bubble generated by the microbubble nozzle 100 or the fluid containing the first micronized bubble of millimeter size makes the flow of the fluid uniform and makes the distribution of the bubble uniform. The filter passes through the filter part 240 formed with the mesh.

The filter part 240 may be formed using a plurality of filter nets 241 and 242 as necessary.

The first sieve 241 is coupled to the first groove 251 formed in the upper housing 220, and the second sieve 242 is coupled to the second groove 252 formed in the upper housing 220. do.

Micro-sized bubbles passing through the filter portion 240 is discharged to the outside of the bubble module 200.

The shape of the guide portion 150 of the microbubble nozzle 100 and the shape of the second hole 153 which makes the first micronized bubble into a micronized bubble of secondary micronization are shown in FIGS. 3A, 3B, and FIG. Various configurations can be made as shown in 3c.

Hereinafter, the bubble module 200 according to the present invention is combined with the water supply line 300 as follows.

The interior of the housing 210 is a space for mounting the bubble forming unit 160 and the female coupling portion 231 of the lower housing to be coupled to the water supply line 300, the male coupling portion 221 of the upper housing ) Is formed.

The outside of the housing 210 is a hexagonal shape of the cross-section of the housing 210, to facilitate the connection with the water supply line 300 by a coupling tool such as a wrench (wrench) or the like. It is preferable.

The female coupling part 231 formed at one end of the lower housing 230 is connected to the water supply line 300 by screwing the male coupling part 310 formed in the water supply line 300.

The male coupling part 221 formed at the other end of the upper housing 220 is connected to the water supply line 300 by screwing the female coupling part 320 formed at the water supply line 300.

The housing 210 is easily connected to the water supply line 300 by the screw coupling as described above, and consequently facilitates the coupling of the bubble module 200 and the water supply line 300.

In addition, since the housing 210 may be separated into the upper housing 220 and the lower housing 230, in the process of coupling with the water supply line 300, the housing 210 is separated as necessary. It is possible to facilitate the connection with the water supply line 300.

Hereinafter, the separation of the housing 210 will be described.

The upper housing 220 is formed with a screw portion 171 of the inner peripheral surface of the upper housing.

The lower housing 230 has a threaded portion 172 on the outer circumferential surface of the lower housing.

Since each of the screw parts 171 and 172 is threaded to be engaged with each other, the coupling part 170 of the upper housing and the lower housing is formed by screwing.

As the housing 210 is separated into the upper housing 220 and the lower housing 230, the expanded passage 169 forming the primary micronized bubble with the bubble forming unit 160 forming particles having large bubbles. ) Are also separated.

As described above, the bubble forming unit 160 and the expanded passage 169 extend through the connecting portion 165 of the expanded passage 169 that is connected to the straight portion 164 of the bubble forming portion.

The expanded passage 169 is formed by the side portion 120 of the plate of the microbubble nozzle 100, and is separated from the connecting portion 165 of the expanded passage 169 which is connected to the bubble forming portion 160. do.

The expanded passage 169 separated as described above is seated in the inner space of the upper housing 220.

Also, the connection part 165 and the bubble forming part 160 of the extended passage are separated into the inner space of the lower housing 230.

The stepped portion 130 of the housing is installed so that the separated connecting portion 165 and the bubble forming portion 160 of the extended passage can be stably seated on the lower housing 230 or can be easily separated for maintenance. It is formed in the lower housing 230.

The step portion 130 is formed in the lower housing 230, the connecting portion connecting the first surface portion 131 and the second surface portion 133, the first surface portion 131 and the second surface portion 133 ( 132).

The first surface portion 131 is formed in parallel with the extended passage 169 so that the connection portion 165 of the extended passage can be stably seated on the lower housing 230, the first surface portion 131 ) Is in contact with the extended passage (169).

The second surface portion 133 is formed in parallel with the straight portion of the bubble forming portion 160 so that the bubble forming portion 160 can be stably seated on the lower housing 230, the second surface portion ( 133 is in contact with the outer surface of the bubble forming unit 160.

The first surface portion 131 and the second surface portion 132 may have the first surface portion 131 and the second surface portion according to the size or shape of the bubble forming portion 160 and the expanded passage 169. The length of 132 and the angle formed by the first surface portion 131 and the second surface portion 133 may be different.

The connecting portion 132 connecting the first surface portion 131 and the second surface portion 133 is inclined to be in contact with a surface formed by the inclined portion 167 of the connecting portion 165 of the extended passage. desirable.

However, the inclination of the inclined portion 167 of the connection portion 165 of the extended passage is difficult to assemble and process the lower housing 230, so that the first surface portion 131 and the first surface portion 131 are inclined. Similar to the second surface portion 133 is formed in a straight line.

An o-ring 190 is formed between the bubble forming unit 160 and the lower housing 230 in contact with and seated on the bubble forming unit 160.

The O-ring 190 is located in a groove (not shown) formed in a portion of the bubble forming unit 160, and the bubble forming unit 160 is fitted with the O-ring 190 in the groove (not shown). It is seated in the lower housing 230.

The O-ring 190 not only makes the bubble forming unit 160 and the lower housing 230 more stable, but also bubbles generated from the bubble forming unit 160 or the water supply line 300. It serves to seal the water supplied from the discharged to the outside of the lower housing (230).

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or variations of the present invention without departing from the spirit and scope of the invention described in the claims below Can be carried out.

1A is a front view of a preferred embodiment of a nozzle for microbubbles according to the present invention.

1B is a cross-sectional view of a preferred embodiment of a nozzle for microbubbles according to the present invention.

1C is a perspective view of a preferred embodiment of a nozzle for microbubbles according to the present invention.

Figure 2a is a perspective view of a preferred embodiment of the bubble module according to the present invention.

2b is a partial cross sectional view of a preferred embodiment of a bubble module according to the present invention;

Figure 3a is another preferred embodiment of a nozzle for microbubble according to the present invention.

Figure 3b is another preferred embodiment of a nozzle for microbubble according to the present invention.

Figure 3c is another preferred embodiment of a nozzle for microbubble according to the present invention.

DESCRIPTION OF REFERENCE NUMERALS

100: microbubble nozzle

111: Hall 1 113: Edition

110: front part of the plate 120: side part of the plate

130: stepped portion of the housing

131: first side portion 132: connection portion

133: second side

150: guide portion 151: small diameter portion of the second hole

152: large diameter of the second hole 153: second hole

160: bubble forming portion 161: large diameter portion of the bubble forming portion

162: small diameter portion of the bubble forming portion 163: inclined portion of the bubble forming portion

164: straight portion of the bubble forming portion 165: connection portion of the expanded passage

166: large diameter of the connection of the expanded passage

167: inclined portion of the connection of the expanded passage

168 streamlined tube 169 expanded passage

170: coupling portion of the upper housing and the lower housing

171: screw portion formed on the inner peripheral surface of the upper housing

172: screw portion formed on the outer peripheral surface of the lower housing

175 impeller

180: air suction unit 181: suction tube of the air suction

182: air intake adjustment screw

183: coupling portion between the adjustment screw and the suction pipe

184: coupling portion between the air suction pipe and the lower housing

185: check valve 186: air suction pipe connection

187: First Seal of Check Valve

188: air intake passage of the lower housing 189: air intake passage of the impeller

190: O-ring between bubble formation and lower housing

191: O-ring between the upper and lower housing

192: O-ring between impeller and lower housing 195: Second sealing of check valve

200: bubble module

201: first contact between impeller and lower housing

202: connection between the impeller and the bubble forming portion

203: second contact portion between the impeller and the lower housing

210: housing

220: upper housing 221: male coupling portion of the upper housing

230: lower housing 231: female coupling portion of the lower housing

240: filter 241: the first filter

242: second sieve 250: groove

251: first groove 252: second groove

300: water supply line

310: male coupling portion of the water supply line 320: female coupling portion of the water supply line

Claims (2)

plate; A first hole formed in the plate; A guide part formed in the plate and having a second hole formed of a large diameter part and a small diameter part, Microbubble nozzle, characterized in that the cross-sectional area of the first hole is larger than the second hole Nozzle; A housing having the nozzle therein; A tube for sucking air formed in a side of the housing; An impeller formed inside the housing; A bubble forming portion including a large diameter portion and a small diameter portion in which the fluid passing through the impeller and the air passing through the pipe are mixed to form a bubble; A valve to prevent bubbles formed from the bubble forming portion from flowing out of the housing; Extended passages are provided to allow the bubbles formed in the bubble forming unit to pass to the nozzles, The nozzle includes a plate, a guide portion having a first hole formed in the plate and a second hole formed in the plate and having a large diameter portion and a small diameter portion having a cross-sectional area smaller than that of the first hole. Bubble module to generate bubbles by

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