KR200449102Y1 - Micro Bubble Nozzle - Google Patents

Abstract

The present invention relates to a micro bubble nozzle.

The present invention is a micro-bubble nozzle, the lower opening is formed in the inner circumferential surface coupling portion for preventing water tightness, the fluid is introduced into the upper, the fluid inlet for increasing the pressure of the introduced fluid, and the fluid inlet and the inner surface An external bubble nozzle having a first bubble generating unit formed of a first expansion inducing unit connected to the primary unit by a pressure change of the introduced fluid; And an impact generating portion which is combined with the coupling portion of the external bubble nozzle, is formed to collide with the fluid discharged from the fluid inlet to separate dissolved oxygen contained in the fluid, and the inner peripheral surface and the bottom surface are perpendicular to each other. And a bubble inlet port through which the fluid including the micro bubbles generated by the first bubble generator is introduced, and a second expansion induction part extending to a lower end of the bubble inlet port to second expand the fluid including the micro bubbles. And it provides a micro bubble nozzle comprising an inner bubble nozzle consisting of an outlet through which the fluid containing the micro bubble flows out.

According to the present invention, there is an effect of maximizing the purification and disinfection efficiency of the dissolved oxygen by the micro bubble nozzle that can bubble the dissolved oxygen contained in the water to the size of the micrometer.

Bubble, nozzle, bubble, shower, micro, dissolved oxygen

Description

Micro Bubble Nozzle

The present invention relates to a micro bubble nozzle. More specifically, the present invention relates to a bubble nozzle that generates micro bubbles by performing super-saturation saturation of the dissolved oxygen contained in the tap water to the size of a micrometer using tap water pressure.

In general, various methods using bubbles are used in relation to daily life and environment, but the generation of bubbles is not easy, and due to the large size of bubbles generated, the efficiency of bubbles has to be low, and in particular, purification and dissolution of water quality In order to increase oxygen, bubbles were generated by using various fountains, waterfalls, and oxygen aeration in closed waters such as lakes, swamps, dams, etc., but the effects were insignificant.

Since the particle size of the bubble to be brought into contact with water was large and floated immediately, the effect of increasing dissolved oxygen in the water cannot be expected, and gas such as oxygen (O) or ozone (O₃) cannot be expected. In the case of inlet and contact with the fluid, the particle size of 0.2 ~ 3mm corresponds to the large bubble, so the contact area with the fluid is not only small but also the floating speed of the gas is short, so the contact time with the fluid is short. The rate was very low.

1 is a view showing a micro bubble nozzle according to the prior art.

As shown, the microbubble nozzle 100 according to the prior art is composed of the inner receiving member 120 and the outer bubble generating member 130, the inner receiving member 120 is open on one side so that the mixed fluid is predetermined An inner cylinder 122 inserted into the pressure and blocked at the other side is provided. The inner cylinder 122 is connected to the first through-hole 124 and the first through-hole 124 for compressing and discharging the mixed fluid at a high pressure, the second through the eccentric through the inner cylinder 122 to discharge the mixed fluid at high pressure A through hole 126 is formed.

In addition, the outer bubble generating member 130 is coupled to the outer peripheral surface of the inner cylinder 122 of the inner receiving member 120, the coupling portion 132 and the inner receiving member 120 fixed by the coupling portion 132 is The outer cylinder 136 and the one side of the outer cylinder 136, which is accommodated and the mixed fluid discharged from the inner accommodating member 120 collides and is received, are opened to open the outlet portion 138 which discharges the micro bubbles. It is configured to include.

However, the microbubble nozzle according to the related art has a collision occurring only at a predetermined portion of the inner cylinder 122 of the inner accommodating member 120 to generate a separation phenomenon. There was a slight problem

In order to solve this problem, the present invention is to provide a micro-bubble nozzle that generates a micro bubble by bubbling the contained dissolved oxygen contained in the water to a micrometer size.

In addition, the present invention simplifies the assembly of the microbubble nozzles, which facilitates assembly, maximizes productivity, enables mass production, and enables easy installation in nozzles and pipelines of various purifiers, farms, and cleaning devices. Its purpose is to.

In order to achieve the above object, the present invention provides a microbubble nozzle, in which a lower part is opened, a coupling part for preventing watertightness is formed on an inner circumferential surface, a fluid is introduced into the upper part, and a fluid inlet for raising the pressure of the introduced fluid; An external bubble nozzle formed with a first bubble generating part including a first expansion induction part connected to the fluid inlet and the inner surface, the first expansion induction part having a slope of 1 ° to 5 ° so as to firstly expand by a change in pressure of the introduced fluid. ; And an impact generating part coupled to the coupling part of the external bubble nozzle and recessed to collide with the fluid discharged from the fluid inlet to separate dissolved oxygen contained in the fluid, and having an inner circumferential surface and a bottom surface perpendicular to each other. A bubble inlet through which the fluid including the micro bubbles generated by the first bubble generator is introduced, one end of which is formed at the lower end of the bubble inlet, and the other end is provided with a frictional resistance in the fluid introduced from 1.5 to 1.8; An inner side consisting of a second expansion induction part formed at a slope of 1 ° to 5 ° to inflate the fluid containing the microbubbles secondly by a friction force generating part having a diameter of mm and an outlet through which the fluid containing the microbubble flows out. It provides a micro bubble nozzle comprising a bubble nozzle.

In addition, in the present invention, the fluid inlet is formed at least one or more at the top of the outer bubble nozzle, the diameter is formed of 6mm ~ 12mm to be formed so that the fluid to be introduced to change the pressure due to the high flow rate A micro bubble nozzle is provided.

In addition, in the present invention, 10 to 15 bubble inlets are formed on the upper portion of the inner bubble nozzle, the diameter is formed of a diameter of 0.5 ~ 0.8mm to increase the pressure of the fluid containing the micro bubble A micro bubble nozzle is provided.

In addition, in the present invention, the impact generating unit provides a microbubble nozzle, characterized in that the fluid discharged from the fluid inlet is formed in a diameter of 10mm ~ 15mm so that a smooth collision with the impact generating unit.

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In addition, in the present invention, the inclination between the 30 ° to 35 ° from the center of the bottom surface to improve the impact force of the fluid discharged from the fluid inlet to the inner circumferential surface of the impact generating portion, and to efficiently create micro bubbles It provides a micro bubble nozzle characterized in that the inclined surface having a.

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As described above, according to the present invention, there is an effect of maximizing the purification effect and the sterilization effect of the dissolved oxygen by the micro bubble nozzle which can bubble the dissolved oxygen contained in the water to the size of the micrometer.

In addition, according to the present invention, it is possible to separate from the dissolved oxygen due to the frictional resistance, pressure resistance, water and dissolved oxygen expansion caused by the change of the pressure according to the flow rate of the water itself, the oxygen bubble of the micrometer size by itself There is an effect that can generate.

In addition, according to the present invention, by providing a micro bubble nozzle made of a single component, there is an effect capable of maximizing productivity and mass production.

In addition, according to the present invention, by providing a miniaturized micro-bubble nozzle, there is an effect that can be installed very easily, such as nozzles and pipes, such as various purification apparatus, aquaculture farm and cleaning apparatus.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the elements of each drawing, it should be noted that the same reference numerals are used to refer to the same elements even though they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

2 is an exploded perspective view showing a microbubble nozzle according to a preferred embodiment of the present invention, Figure 3 is a cross-sectional view showing a microbubble nozzle according to a preferred embodiment of the present invention, Figures 4a and 4b are preferred It is a state diagram of the operation of the micro bubble nozzle according to the embodiment. In addition, Figure 5 is a view showing a state in which the micro bubble nozzle is installed in the shower in accordance with a preferred embodiment of the present invention.

As shown in the drawing, the microbubble nozzle 200 of the present invention has a primary separation phenomenon due to the inflow of a fluid such as water containing dissolved oxygen, and bubbles of dissolved oxygen to the size of a micrometer to form micro bubbles (micro An outer bubble nozzle 202 having a first bubble generator 210 for generating a meter size bubble) and a lower portion of the outer bubble nozzle 202, which are generated by the first bubble generator 210. The secondary separation phenomenon is generated to maximize the effect of the micro-bubbles, and comprises an inner bubble nozzle 204 is formed with a second bubble generating unit 220 for outflowing the generated micro-bubbles.

The outer bubble nozzle 202 is formed in the shape of the lower opening, the coupling portion 230 is coupled to the inner bubble nozzle 204 and the watertight prevention is formed along the inner peripheral surface.

In addition, a first bubble generator 210 is formed inside the outer bubble nozzle 202 to generate a primary separation phenomenon in which dissolved oxygen is separated from a fluid to generate bubbles, and the first bubble generator 210 is formed. Is inclined by a predetermined angle such that the fluid inlet 212 into which the fluid containing dissolved oxygen is introduced and one side thereof are connected to the lower end of the fluid inlet 212 and the other side thereof are connected to the inner surface 250 of the outer bubble nozzle 202. It is configured to include a first expansion induction portion 214 is formed in the form of a connection and expands the fluid introduced by the pressure change.

Here, the fluid inlet 212 generates a pressure change between the fluid supplied to the external bubble nozzle 220 and the fluid discharged from the fluid inlet 212, and the pressure of the fluid discharged is increased, thereby increasing the fluid inlet ( It is formed to be discharged to the outside of the 212, the pressure change is generated by the difference in the flow rate of the fluid flowing into the central side of the fluid inlet 212 and the fluid flowing into the inner wall surface of the fluid inlet (212).

One or more fluid inlets 212 may be formed in the external bubble nozzle 202 according to a required flow rate. That is, in the present invention, but is shown as being formed as one in the center of the outer bubble nozzle 202, but not limited to this will vary depending on the amount of water inlet or the location of the installed fluid inlet 212 will vary .

In addition, the fluid inlet 212 is preferably formed with a diameter of 6mm ~ 12mm, depending on the use of the micro bubble nozzle 200, such as a small product, household cleaning device, the lower end from the top of the fluid inlet 212 By forming the same diameter, it is preferable to allow the fluid flowing through the fluid inlet 212 has a fast flow rate, but is not limited to this, the upper and lower diameters of the fluid inlet 212 is formed differently You can also adjust the amount of change in pressure.

The first expansion induction part 214 expands the pressure of the fluid discharged from the fluid inlet 212 to separate the dissolved oxygen contained in the fluid to be inclined by a predetermined angle to generate a bubble, in the present invention 1 ° ~ It is formed with a slope in the range of 5 °.

In addition, the coupling portion 230 of the outer bubble nozzle 202 is formed on the lower inner circumferential surface of the outer bubble nozzle 202, and serves as a medium for coupling with the inner bubble nozzle 204 to be described later, the outer bubble nozzle 202 and the inner bubble nozzle 204 to maximize the sealing force.

The coupling portion 230 is formed in the outer bubble nozzle 202 in the present invention to form a female thread, and the inner bubble nozzle 204 to form a male thread corresponding to this is configured to be screwed to be limited to this Or, it may be combined in a variety of ways, such as the interference fit method using the micro-tolerance, the insertion method through the projection structure, O-ring, sealing, etc. between the outer bubble nozzle 202 and the inner bubble nozzle 204 to maximize the sealing force Watertight members may be provided.

The inner bubble nozzle 204 is coupled to the opened lower portion of the outer bubble nozzle 202, the impact generating unit 240 so that the fluid introduced from the fluid inlet 212 collides with the separation of dissolved oxygen to occur Is formed recessed.

As shown in (a) of FIG. 3, the impact generator 240 has a bottom surface and an inner circumferential surface formed perpendicular to each other, and a bubble is generated by collision of fluid discharged from the fluid inlet 212 with the first bubble. The first expansion guide part 214 of the generator 210 and the inner surface 250 of the outer bubble nozzle 202 is caused to friction to produce a bubble of the first micrometer size.

On the other hand, the impact generating unit 240, as shown in Figure 3 (b), the inner peripheral surface is formed to be inclined by a predetermined angle toward the center side of the bottom surface, the inclination between 30 ° ~ 35 ° from the center of the bottom surface The inclined surface 242 is formed to improve the impact force of the fluid discharged from the fluid inlet 212, and after the collision, smooth refraction occurs to the first expansion induction portion 214 and the inner surface 250, the primary micro Meter size bubble generation can be made efficiently. However, it is not limited thereto.

Such a shock generating unit 240 is formed in the inner bubble nozzle 204 by a predetermined depth so that the fluid discharged from the fluid inlet 212 is a smooth collision, the diameter is formed of a diameter of 10 ~ 15mm Preferred but not limited to this.

In addition, between the outer circumferential surface of the inner bubble nozzle 204 and the impact generator 240, the first bubble generator 210 including the fluid inlet 212 and the first expansion guide 214 of the outer bubble nozzle 202 may be provided. As a result, the first-generated microbubble is introduced to form a second bubble generator 220 that generates microbubbles of a finer size.

The second bubble generating unit 220 collides with the impact generating unit 240 and secondary expansion of the fluid passing through the bubble inlet 222 and the bubble inlet 222 through which the fluid in which the first micro bubble is generated is introduced. It comprises a second expansion guide portion 224 for generating a fine micrometer-sized bubble to the outlet and the outlet 226 for exiting the micrometer-sized bubbles generated by the second expansion guide portion 224.

The bubble inlet 222 penetrates from the upper portion of the inner bubble nozzle 204 to the lower portion so that the secondary micro bubbles having a finer size than the primary micro bubbles generated in the outer bubble nozzle 202 are formed in the second bubble generator 220. The fluid containing this primary microbubble flows in such a way that it can be produced by

Such bubble inlet 222 is preferably formed at least 10 to 15 on the upper side of the inner bubble nozzle 204, but is not limited thereto, and may be formed in consideration of the components, water pressure, etc. installed, The diameter is smaller than the fluid inlet 212 is preferably formed with a diameter of 0.5 ~ 0.8mm. However, it is not limited thereto.

One end of the second expansion induction part 224 is formed to extend at the lower end of the bubble inlet 222 and is formed to be inclined by a predetermined angle so that the primary micro bubble introduced into the bubble inlet 222 is separated by the secondary expansion. Is formed to occur.

The second expansion induction part 224 expands the pressure of the fluid discharged from the bubble inlet 222 to separate dissolved oxygen contained in the fluid and is formed to be inclined by a predetermined angle so that bubbles are generated. It is formed with a slope in the range of ˜5 °.

In addition, the other end of the second expansion induction part 224 is formed to a diameter of at least two times larger than the diameter of the bubble inlet 222, the fluid in which the primary microbubble introduced through the bubble inlet 222 is friction A frictional force generating unit 260 is formed to cause a frictional resistance while causing a.

That is, the friction force generator 260 is formed to generate frictional resistance to the fluid flowing through the bubble inlet 222 and the second expansion induction part 224, and the fluid introduced through the bubble inlet 222 may be the friction force generator ( The fluid that flows through 260 and is refracted by this frictional resistance slows down due to the rapid turbulence caused by the pressure resistance acting in the direction opposite to that of the fast-flowing unidirectional fluid flowing through the central side of the bubble inlet 222. Generated and expanded, and the fluid flowing through the bubble inlet 222 is maintained in a state where a plurality of turbulent layers are formed until it flows out through the outlet 226 and the frictional force generating unit 260. ) To separate the dissolved oxygen contained in the water several times.

The friction force generating unit 260 is preferably formed to be at least two times longer than the bubble inlet 222 so as to provide the maximum friction when generating the secondary bubble.

On the other hand, the diameter of the outlet 226 is formed at the lower end of the friction force generating unit 260 and the second micrometer-sized bubbles generated by the second bubble generating unit 220 is discharged is the diameter of the bubble inlet 222 It is preferable to be formed at least two times larger than, but in the present invention, it is preferable to form a diameter of 1.5 ~ 1.8mm.

As shown in FIG. 4A, the microbubble nozzle 200 according to the present invention has a configuration in which a pressure is increased due to a narrow diameter of the fluid inlet 212. While being discharged into the space of the outer bubble nozzle 202, the pressure is changed by the first expansion induction part 214 to cause the expansion of the fluid, the impact fluid 240 formed in the inner bubble nozzle 204 ) And the first separation occurs due to the collision of) and creates a bubble of micrometer size.

In addition, the fluid, as shown in Figure 4b, the inner bubble nozzle 204 along the inner surface 250 of the outer bubble nozzle 202 with the primary micro bubbles generated by the impact with the impact generating unit 240. The fluid flowing into the bubble inlet 222 formed therein, including the introduced primary microbubble moves to the second expansion induction part 224 while the pressure is increased, and the expansion force generated by the second expansion induction part 224. And a second separation phenomenon due to the frictional force generated by the frictional force generating unit 260 extended to the other end of the second expansion induction part 224, and thus, a secondary micron having a finer size than the primary micrometer bubble. Bubbles are generated and are discharged through the outlet 226.

As shown in FIG. 5, the microbubble nozzle 200 of the present invention configured as described above is installed in the shower 310 to supply a fluid containing dissolved oxygen in which microbubbles are continuously generated when the shower is provided. Installed in the head portion 312 of the 310 or installed in the flow path formed inside the handle portion 314 is supplied to the fluid, such as tap water by generating a micro bubble by the micro bubble nozzle 200, and included in the tap water Due to the harmful bacteria, it will be able to prevent various skin diseases such as itching, allergies and atopy.

The description above is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas falling within the scope of the present invention should be interpreted as being included in the scope of the present invention.

1 is a view showing a micro bubble nozzle according to the prior art.

2 is an exploded perspective view showing a micro bubble nozzle according to a preferred embodiment of the present invention,

3 is a cross-sectional view showing a micro bubble nozzle according to a preferred embodiment of the present invention,

4a and 4b is an operating state of the micro bubble nozzle according to a preferred embodiment of the present invention,

5 is a view showing a state in which the micro bubble nozzle is installed in the shower according to a preferred embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

200: micro bubble nozzle 202: outer bubble nozzle

204: inner bubble nozzle 210: first bubble generating unit

212: fluid inlet 214: first expansion guide

220: second bubble generator 222: bubble inlet

224: second expansion induction part 226: outlet

230: coupling portion 240: impact generating portion

250: inner surface 260: friction force generating portion

Claims (7)

In the micro bubble nozzle, The lower part is opened to form a coupling part for preventing watertightness on the inner circumferential surface, and the fluid is introduced into the upper part, and the fluid inlet for raising the pressure of the introduced fluid is connected to the fluid inlet and the inner surface to change the pressure of the introduced fluid. An external bubble nozzle having a first bubble generating unit including a first expansion inducing unit formed at an inclination of 1 ° to 5 ° such that primary expansion is performed to generate bubbles; And An impact generating unit coupled to the coupling part of the external bubble nozzle, the impact generating unit having a recess formed to collide with the fluid discharged from the fluid inlet to separate dissolved oxygen contained in the fluid, and having an inner circumferential surface and a bottom surface perpendicular to each other; A bubble inlet through which the fluid including the micro bubbles generated by the first bubble generator is introduced and one end thereof are formed at the lower end of the bubble inlet, and the other end is 1.5 to 1.8 mm to generate frictional resistance. An inner bubble consisting of a second expansion inducing part formed with a slope of 1 ° to 5 ° to inflate the fluid containing the microbubble by the friction generating unit having a diameter of 2 ° and a outlet through which the fluid containing the microbubble flows out. Nozzle Micro bubble nozzle comprising a. The method of claim 1, The fluid inlet is formed at least one or more at the top of the outer bubble nozzle, the diameter is formed of 6mm ~ 12mm microbubble nozzle, characterized in that the inflow fluid is formed to generate a pressure change by a high flow rate. The method of claim 1, 10 to 15 bubble inlets are formed on top of the inner bubble nozzle, the diameter of which is formed to a diameter of 0.5 to 0.8mm microbubble nozzle, characterized in that to increase the pressure of the fluid containing the microbubble. The method of claim 1, The impact generating unit is a micro bubble nozzle, characterized in that the fluid discharged from the fluid inlet is formed in a diameter of 10mm ~ 15mm so that the collision with the impact generating unit. delete The method of claim 1, An inclined surface having an inclination between 30 ° and 35 ° from the center of the bottom surface is formed on the inner circumferential surface of the impact generating part to improve the collision force of the fluid discharged from the fluid inlet and to efficiently generate micro bubbles. Characterized by a microbubble nozzle. delete

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