KR20200142964A - Micro bubble nozzle and micro bubble generator comprising same - Google Patents

Abstract

The present invention relates to a nozzle for generating microbubbles, comprising: a main body including an inlet and an outlet and having an inner chamber formed therebetween; a rotating ball located in the inner chamber, including a passage allowing flow of fluid (F+G) in which gas is dissolved, and installed to be able to rotate around a vertical rotation axis to open and close the passage; and a nozzle plate installed to be in close contact with an inner circumferential surface of the passage, and including one or multiple hollows allowing the flow of the fluid (F+G) in which the gas is dissolved. According to the present invention, the nozzle for generating microbubbles and an apparatus for generating microbubbles including the same have effects of preventing the nozzle from being blocked by foreign substance and forming microbubbles of high concentration by using the nozzle plate including the hollows in a double funnel form of a symmetrical structure and switching the direction according to a change in pressure.

Description

Micro-bubble generating nozzle and micro-bubble generating device including the same {MICRO BUBBLE NOZZLE AND MICRO BUBBLE GENERATOR COMPRISING SAME}

The present invention relates to a micro-bubble generating nozzle and a micro-bubble generating device including the same, and more particularly, by using a nozzle plate including a plurality of hollows in the form of a double funnel having a symmetrical structure, and changing the direction according to the pressure change. , To prevent clogging of the nozzle by foreign substances, and to a fine bubble generating nozzle capable of forming a high-concentration fine bubble, and a fine bubble generating device including the same.

In general, wastewater treatment devices of various principles and structures have been developed according to the properties of the wastewater to be treated, and wastewater treatment methods and devices using a physical method and a chemical method or a combination of a physicochemical method have been provided. One of the methods is a sedimentation method in which impurities are collected by sedimentation under the wastewater and a flotation method in which the impurities are collected by floating above the wastewater.

Among them, the wastewater treatment system by the flotation method passes through a mixing tank that adds chemicals to the wastewater, stores air and wastewater in a pressurized tank at a constant pressure with a pressure pump, and supplies the pressurized wastewater to the flotation tank, which is a wastewater treatment tank at atmospheric pressure. Then, pressurized wastewater generates bubbles in the wastewater of the wastewater treatment tank under atmospheric pressure, and these bubbles collect impurities in the wastewater and float the impurities by the buoyancy of the bubbles, thereby removing the impurities floating on the surface of the wastewater with a skimmer. Wastewater can be treated in this way.

However, the wastewater treatment device used in this flotation method is a method of dissolved air flotation, and a high pressure is required to obtain air for generating bubbles. Also, the required air due to bubble flotation is limited in solubility, so a large amount Since wastewater was required, the capacity of the flotation tank was increased, a large installation area was required, and operation cost was increased.

An object of the present invention is to solve the above problem, by using a nozzle plate including a plurality of hollows in the form of a double funnel of a symmetrical structure, and by changing the direction according to the pressure change, the nozzle is prevented from clogging by foreign substances. , To provide a micro-bubble generating nozzle capable of forming a high-concentration micro-bubble, and a micro-bubble generating device including the same.

According to an aspect of the present invention, a main body 210 having an inlet 211 and an outlet 213 and having an inner chamber 212 formed therebetween; It is located in the inner chamber 212, has a passage 221 that allows the flow of a fluid (F+G) in which gas is dissolved, and is rotatably installed around a vertical rotation axis to open and close the passage 221 Rotating ball 220; And a nozzle plate 230 installed in close contact with the inner circumferential surface of the passage 221 and including a single or a plurality of hollows 231 to allow the flow of the fluid (F+G) in which the gas is dissolved. A fine bubble generating nozzle 200 is provided.

The diameter of the hollow 231 may decrease and increase in the direction of the other end based on one end.

The diameter of the hollow 231 may decrease from one end to the center and then increase from the center to the other end.

The hollow 231 has a minimum diameter at the center and may be in the form of a double funnel.

The minimum diameter of the hollow 231 may be 1 to 3 mm.

The microbubble generating nozzle 200 further includes a stem 240 installed on the vertical rotation shaft, and rotates the rotation ball 220 in the left and right direction by 180° using the stem 240 to make the hollow Since one end of the 231 is positioned on the other end, the waste accumulated on the one end can be removed by the flow of the fluid F+G in which the gas is dissolved.

According to another aspect of the present invention, the gas dissolving device 100 for dissolving the gas G in the fluid F; The microbubble generation nozzle 200 for generating microbubbles by receiving the fluid (F+G) in which gas is dissolved from the gas dissolving device; A pump 300 for supplying the fluid F to the gas dissolving device; And an air compressor 400 for supplying gas G to the gas dissolving device.

The gas dissolving device 100 includes an injector 110, a flow amplification unit 120, a gas-liquid mixing unit 130, a dissolution tank 140 and a discharge unit 150, and the injector 110 is a fluid Includes a supply pipe 111 and a gas supply pipe 112, and the gas supply pipe 112 is an internal gas supply pipe 1121 located inside the fluid supply pipe 111, and is positioned at an upper side of the fluid supply pipe 111 It includes an upper exposed gas supply pipe 1122 and a lower protruding gas supply pipe 1123 protruding from the lower side of the fluid supply pipe 111 and a gas flow path 114 formed inside the gas supply pipe 112 And a fluid flow path 113 formed between an inner circumferential surface of the fluid supply pipe 111 and an outer circumferential surface of the internal gas supply pipe 1121, and the flow amplification part 120 is a cylindrical shape with an upper end and an open lower end, and the lower side A protruding gas supply pipe 1123 is accommodated in the upper part, and the gas-liquid mixing part 130 is a cylindrical shape with an open upper end and a closed lower end, accommodates the flow amplification part 120 at the upper part, and the lower protruding gas supply pipe 1123 , The flow amplification unit 120, and the gas-liquid mixing unit 130 are accommodated in the dissolution tank 140, and the discharge unit 150 may be located under the dissolution tank 140.

The gas supply pipe 112 includes a gas inlet 1124 and a gas outlet 1125, a gas inlet 1124 is located at one end of the upper exposed gas supply pipe 1122, and the gas outlet 1125 is at the lower side. It may be located at one end of the protruding gas supply pipe 1123.

The fluid supply pipe 111 includes a fluid inlet 1111, a fluid passage pipe 1112 and a fluid outlet 1113, and the fluid inlet 1111 is located at one end of an upper portion of the fluid supply pipe 111, The fluid outlet 1113 may be located at the other end of the lower portion of the fluid supply pipe 111.

The fluid supply pipe 111 has a cylindrical upper portion, and a lower portion of the fluid supply pipe 111 continuous at the upper portion is a funnel-shaped, and decreases as the diameter of the lower portion of the fluid supply pipe 111 approaches the fluid outlet 1113. I can.

In the injector 110, the fluid F flows through the fluid passage 113 and is injected to the outside of the fluid outlet 1113, thereby introducing the gas G into the gas inlet 1124 and the gas outlet 1125 Can be released as.

During operation, the gas inlet 1124 may contact the gas G, and the gas outlet 1125 may contact the fluid F.

The flow rate amplifying unit 120 is for receiving fluid (F) and gas (G) from the injector 110 from the top, increasing the amount of the fluid, and discharging it to the lower portion of the flow rate amplifying unit 120 I can.

The gas-liquid mixing unit 130 may be for dissolving the gas G supplied from the flow rate amplifying unit 120 in the fluid F and discharging it to the outside.

The discharge unit 150 may be for discharging the mixture (F+G) including the fluid F in which the gas G is dissolved to the outside.

Each of the cylinders may be independently cylindrical, oval, polygonal, or a combination thereof.

The fluid F may flow into the fluid inlet 1111 at a flow rate of 10 to 20 m/s.

The gas dissolving device 100 may further include a level sensor 160, and the level sensor 160 may detect the level of the fluid in the dissolution tank 140.

The gas dissolving device 100 further includes a solenoid valve 170, and the solenoid valve 170 adjusts the pressure of the gas G accommodated in the dissolution tank 140 to the dissolution tank 140 It is possible to control the level of the fluid (F) accommodated.

The gas dissolving device 100 includes a check valve 180 between the solenoid valve 170 and the dissolution tank 140, and the check valve 180 is a fluid (F) accommodated in the dissolution tank 140. ) Can be prevented from flowing backward in the direction of the solenoid valve 170.

The gas dissolving device 100 may further include a pressure gauge 190, and the pressure gauge 190 may measure the pressure of the gas G accommodated in the dissolution tank 140.

The microbubble generator further includes a regulator 500 between the solenoid valve 170 and the air compressor 400, and the regulator 500 includes a gas pressure of the dissolution tank 140 and a solenoid valve ( 170) may be for maintaining a constant pressure differential with the gas pressure.

The micro-bubble generating nozzle and the micro-bubble generating device including the same of the present invention use a nozzle plate including a plurality of hollows in the form of a double funnel having a symmetrical structure, and change the direction according to pressure change, so that the nozzle is clogged by foreign substances. It has the effect of preventing and forming high-concentration microbubbles.

1 is a longitudinal cross-sectional view of a fine bubble generating nozzle according to an embodiment of the present invention cut along the length of the passage.
2 is a longitudinal cross-sectional view of a fine bubble generating nozzle according to an embodiment of the present invention cut along a vertical direction in the length direction of the passage.
3 is a cross-sectional view illustrating a state in which the fine bubble generating nozzle is changed in direction according to an embodiment of the present invention.
4 is a perspective view of a rotating ball according to an embodiment of the present invention.
5 is a structural diagram of a micro-bubble generating nozzle and a micro-bubble generating apparatus including the same according to an embodiment of the present invention.
6 is a structural diagram of a gas dissolving apparatus according to an embodiment of the present invention.
7 is a detailed structural diagram of an injector according to an embodiment of the present invention.
8 is a view showing the maximum and minimum values of the distance between the inner circumferential surface of the fluid supply pipe and the outer circumferential surface of the gas supply pipe according to an embodiment of the present invention.

Since the present invention can apply various transformations and have various embodiments, specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. However, this is not intended to limit the present invention to a specific embodiment, it is to be understood to include all conversions, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the present invention, when it is determined that a detailed description of a related known technology may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are used only for the purpose of distinguishing one component from another component.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and in the description with reference to the accompanying drawings, the same or corresponding components are given the same reference numbers, and redundant descriptions thereof will be omitted. do.

1 is a longitudinal sectional view of the microbubble generating nozzle according to an embodiment of the present invention cut along the lengthwise direction of the passage, and FIG. 2 is a vertical cross-sectional view of the microbubble generating nozzle according to an exemplary embodiment of the present invention. It is a longitudinal cross-sectional view cut along the line, and FIG. 3 is a cross-sectional view showing a state of changing the direction of the fine bubble generating nozzle according to an embodiment of the present invention. In addition, Figure 4 is a perspective view of a rotating ball according to an embodiment of the present invention.

Hereinafter, the fine bubble generating nozzle 200 will be described in detail with reference to FIGS. 1 to 4. However, this is presented as an example, and the present invention is not limited thereby, and the present invention is only defined by the scope of the claims to be described later.

The present invention includes a main body 210 having an inlet 211 and an outlet 213 and having an inner chamber 212 formed therebetween; It is located in the inner chamber 212, has a passage 221 that allows the flow of a fluid (F+G) in which gas is dissolved, and is rotatably installed around a vertical rotation axis to open and close the passage 221 Rotating ball 220; And a nozzle plate 230 installed in close contact with the inner circumferential surface of the passage 221 and including a single or a plurality of hollows 231 to allow the flow of the fluid (F+G) in which the gas is dissolved. It provides a fine bubble generating nozzle 200.

The fluid (F+G) in which the gas is dissolved may contain foreign matter or waste.

Referring to the enlarged view of the nozzle plate 230 inserted in FIG. 1, the diameter of the hollow 231 may decrease and increase in the direction of the other end based on one end.

The diameter of the hollow 231 may decrease from one end to the center and then increase from the center to the other end.

The hollow 231 has a minimum diameter at the center and may be in the form of a double funnel. d ₁ is the largest diameter of the hollow in the form of a double funnel and d ₂ is the smallest diameter.

The minimum diameter of the hollow 231 may be 1 to 3 mm. If the minimum diameter is less than 1 mm, wastes are accumulated too often, which is not preferable, and if it exceeds 3 mm, the effect of generating microbubbles is reduced, which is not preferable.

The microbubble generating nozzle 200 may further include a stem 240 installed on the vertical rotation shaft, and the stem 240 may be for inducing rotation of the rotation ball 220.

The rotating ball 220 is rotated 180° in the left and right direction using the stem 240 so that one end of the hollow 231 is located at the other end, so that the waste accumulated on the one end is removed from the fluid in which the gas is dissolved ( It can be removed by flow of F+G). As described above, since the microbubble generating nozzle 200 is easy to remove wastes, the hollow is not blocked, and can be applied in a wide range of environments.

4 is a structural diagram of a gas dissolving device according to an embodiment of the present invention and a microbubble generating device including the same, FIG. 5 is a structural diagram of a gas dissolving device according to an embodiment of the present invention, and FIG. It is a detailed structural diagram of an injector according to an embodiment. 7 is a view showing the maximum value (L ₁ ) and the minimum value (L ₂ ) of the distance between the inner peripheral surface of the fluid supply pipe and the outer peripheral surface of the gas supply pipe according to an embodiment of the present invention.

Hereinafter, the microbubble generating apparatus 10 including the microbubble generating nozzle 200 will be described in detail with reference to FIGS. 4 to 7.

The present invention comprises a gas dissolving device 100 for dissolving a gas G in a fluid F; The microbubble generating nozzle 200 for generating microbubbles by receiving the fluid (F+G) in which gas is dissolved from the gas dissolving device; A pump 300 for supplying a fluid F to the gas dissolving device; And an air compressor 400 for supplying the gas G to the gas dissolving device.

The gas dissolving device 100 includes an injector 110, a flow amplification unit 120, a gas-liquid mixing unit 130, a dissolution tank 140 and a discharge unit 150, and the injector 110 is a fluid supply pipe (111) and a gas supply pipe 112, and the gas supply pipe 112 is exposed to the upper side of the internal gas supply pipe 1121 and the fluid supply pipe 111 located inside the fluid supply pipe 111 It includes an upper exposed gas supply pipe 1122 and a lower protruding gas supply pipe 1123 protruding from the lower side of the fluid supply pipe 111, and a gas flow path 114 formed inside the gas supply pipe 112. And a fluid flow path 113 formed between an inner circumferential surface of the fluid supply pipe 111 and an outer circumferential surface of the internal gas supply pipe 1121, and the flow amplifying unit 120 is a cylindrical shape with an upper end and an open lower end, and the A lower protruding gas supply pipe 1123 is accommodated in the upper part, and the gas-liquid mixing part 130 is a cylindrical shape with an open upper end and a closed lower end, accommodates the flow amplification part 120 at the upper part, and the lower protruding gas supply pipe 1123 ), the flow amplification unit 120, and the gas-liquid mixing unit 130 are accommodated in the dissolution tank 140, and the discharge unit 150 may be located under the dissolution tank 140.

The gas supply pipe 112 includes a gas inlet 1124 and a gas outlet 1125, a gas inlet 1124 is located at one end of the upper exposed gas supply pipe 1122, and the gas outlet 1125 is at the lower side. It may be located at one end of the protruding gas supply pipe 1123.

The fluid supply pipe 111 includes a fluid inlet 1111, a fluid passage pipe 1112 and a fluid outlet 1113, and the fluid inlet 1111 is located at one end of an upper portion of the fluid supply pipe 111, The fluid outlet 1112 may be located at the other end of the lower portion of the fluid supply pipe 111.

The fluid supply pipe 111 has a cylindrical upper portion, and a lower portion of the fluid supply pipe 111 continuous at the upper portion is a funnel-shaped, and decreases as the diameter of the lower portion of the fluid supply pipe 111 approaches the fluid outlet 1113. I can.

In the injector 110, the fluid F flows through the fluid passage 113 and is injected to the outside of the fluid outlet 1113, thereby introducing the gas G into the gas inlet 1124 and the gas outlet 1125 Can be released as.

The gas (G) may include air or oxygen, preferably air.

Referring to FIG. 6, in detail, this is based on the Bernoulli principle, and the fluid F supplied by high pressure spraying to the fluid inlet 1111 flows through the fluid flow path 113 to the outside of the fluid outlet 1113. By spraying into, the gas (G) accommodated by the dissolution tank 140 due to the difference in pressure is introduced into the gas inlet 1124 and discharged through the gas outlet 1125, thereby dissolving efficiency of air Can improve.

During operation, the gas inlet 1124 may contact the gas G, and the gas outlet 1125 may contact the fluid F.

The flow rate amplifying unit 120 is for receiving fluid (F) and gas (G) from the injector 110 from the top, increasing the amount of the fluid, and discharging it to the lower portion of the flow rate amplifying unit 120 I can.

The gas-liquid mixing unit 130 may be for dissolving the gas G supplied from the flow rate amplifying unit 120 in the fluid F and discharging it to the outside.

The discharge unit 150 may be for discharging the mixture (F+G) including the fluid F in which the gas G is dissolved to the outside.

Each of the cylinders may be independently cylindrical, oval, polygonal, or a combination thereof.

Since the dissolution tank 140 has a cylindrical structure, it provides an efficient space for dissolving gas and may have a rigidity capable of sustaining a certain pressure.

The fluid F may flow into the fluid inlet 1111 at a flow rate of 10 to 20 m/s.

The gas dissolving device 100 may further include a level sensor 160, and the level sensor 160 may detect the level of the fluid in the dissolution tank 140.

The gas dissolving device 100 further includes a solenoid valve 170, and the solenoid valve 170 adjusts the pressure of the gas G accommodated in the dissolution tank 140 to the dissolution tank 140 It is possible to control the level of the fluid (F) accommodated.

The gas dissolving apparatus 100 of the present invention maximizes the dissolution efficiency of air and the generation amount of microbubbles, and a constant water level is formed by the level sensor to maintain uniform performance over time.

The level sensor 160 controls the solenoid valve 170 according to the level of the fluid accommodated in the dissolution tank, thereby forming a constant level to maintain uniform performance over time, and the solenoid valve 170 Interlocking with the level sensor 160 may adjust the amount of gas flowing into the dissolution tank 140. Specifically, when the level sensor 160 detects that the level of the fluid accommodated by the dissolution tank 140 is high, the solenoid valve 170 is opened to inject gas, and in the opposite case, the solenoid valve 170 is opened. Close it to control the amount of gas.

The gas dissolving device 100 includes a check valve 180 between the solenoid valve 170 and the dissolution tank 140, and the check valve 180 is a fluid (F) accommodated in the dissolution tank 140. ) Can be prevented from flowing backward in the direction of the solenoid valve 170.

The gas dissolving device 100 may further include a pressure gauge 190, and the pressure gauge 190 may measure the pressure of the gas G accommodated in the dissolution tank 140.

The microbubble generator further includes a regulator 500 between the solenoid valve 170 and the air compressor 400, and the regulator 500 includes a gas pressure of the dissolution tank 140 and a solenoid valve ( 170) may be for maintaining a constant pressure differential with the gas pressure.

The gas dissolving device includes an injector having a double tube structure, a flow amplification unit, and a gas-liquid mixing unit, thereby improving the dissolution efficiency of air, and separating and reusing undissolved residual air.

The micro-bubble generating nozzle and micro-bubble generator according to the present invention are an oxygen supply device that replaces the air diffuser of an aeration tank in a high-concentration wastewater treatment plant, a pressurized floating separator (DAF) in a water purification plant or a sewage treatment plant, and supply of microbubbles from a lake or river It can be applied to control of the occurrence of green algae, direct removal of green algae, and dissolution of various gases by self-purification by

Hereinafter, a method of generating microbubbles using a microbubble generating device will be described.

1 to 8, when the fluid F is flowed into the fluid flow path 112 of the injector 100 at a speed of 10 to 20 m/s using the pump 300, the gas flow path 114 is caused by Bernoulli's phenomenon. Gas (G) is forced to flow, gas and fluid flow to the flow amplification unit 120, and between the flow amplification unit 120 and the injector 110 from the top of the flow amplification unit 120 by the flow of the fluid and gas. More fluid flows in and the flow rate is amplified. The fluid and gas flow into the gas-liquid mixing unit 130 through the lower portion of the flow amplification unit 120, and then the gas is mixed with the fluid under the gas-liquid mixing unit 130, and the gas-liquid mixing unit 130 In the process of colliding with the bottom of) and flowing upward, the gas becomes a dissolved liquid and is discharged from the gas-liquid mixing part 130 through the upper part of the gas-liquid mixing part 130. On the other hand, when the fluid continues to flow and the level of the fluid in the dissolution tank 140 rises to a predetermined level and is detected by the level sensor 160, the solenoid valve 170 is opened and a high pressure, for example about 9, through the air compressor 400. Atmospheric pressure gas is introduced into the regulator and decompressed through the regulator to introduce, for example, about 6 atmosphere gas into the dissolution tank 140. The fluid in which the gas is dissolved due to the pressure of the gas flowing into the dissolution tank is discharged through the microbubble generating nozzle 200, and is transmitted to the fluid by the pressure difference between the high pressure dissolution tank pressure and the low external pressure, for example, atmospheric pressure. The dissolved gas is separated from the fluid and microbubbles are generated.

Meanwhile, when the discharge of the fluid in which the gas is dissolved continues through the microbubble generating nozzle 200 and the level of the fluid in the dissolution tank 140 is lowered to a predetermined level, the level sensor 160 detects it and the solenoid valve 170 ) Is closed and the inflow of high-pressure gas stops. In this way, the inflow of gas is repeated according to the change in the water level in the dissolution tank 140, and accordingly, generation of microbubbles is repeated.

In addition, when the pressure of the pressure gauge 190 exceeds a predetermined pressure, for example, 5 to 6 atmospheres, the operation is not stopped, and the nozzle plate 230 is rotated 180° by rotating the stem left and right. After removing the waste by pushing out the trapped waste with a high pressure fluid, the microbubble generator can be operated continuously. Here, since the hollow of the nozzle plate has a narrow double funnel shape as described above, wastes can be removed simply by rotating the nozzle plate 180°.

In the above, embodiments of the present invention have been described, but those of ordinary skill in the art will add, change, delete or add components within the scope not departing from the spirit of the present invention described in the claims. Various modifications and changes can be made to the present invention by means of the like, and it will be said that this is also included within the scope of the present invention. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may also be implemented in a combined form. The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

10: microbubble generator
100: gas dissolving device 110: injector
111: fluid supply pipe 112: gas supply pipe
113: fluid flow path 114: gas flow path
1111: fluid inlet 1112: fluid passage pipe
1113: fluid outlet 1121: internal gas supply pipe
1122: upper exposed gas supply pipe 1123: lower protruding gas supply pipe
1124: gas inlet 1125: gas outlet
120: flow amplification unit 130: gas-liquid mixing unit
140: dissolution tank 150: discharge
160: level sensor 170: solenoid valve
180: check valve 190: pressure gauge
200: fine bubble generating nozzle 210: main body
211: inlet 212: inner chamber
213: outlet 220: rotating ball
221: passage 230: nozzle plate
231: hollow 240: stem
300: pump 400: air compressor
500: regulator

Claims (20)

A main body having an inlet port and an outlet port and having an inner chamber therebetween;
A rotating ball positioned in the inner chamber, provided with a passage allowing the flow of a fluid (F+G) in which gas is dissolved, and installed rotatably about a vertical rotation axis to open and close the passage; And
A nozzle plate installed in close contact with the inner circumferential surface of the passage and including a single or a plurality of hollows allowing the flow of the fluid (F+G) in which the gas is dissolved;
A fine bubble generating nozzle containing. The method of claim 1,
A fine bubble generating nozzle, characterized in that the diameter of the hollow decreases in the direction of the other end relative to the one end and then increases. The method of claim 1,
A fine bubble generating nozzle, characterized in that the diameter of the hollow decreases from one end to the center and then increases from the center to the other end. The method of claim 1,
The hollow is a microbubble generating nozzle, characterized in that the diameter is the smallest at the center, and the form of a double funnel. The method of claim 1,
Microbubble generating nozzle, characterized in that the minimum diameter of the hollow is 1 to 3mm. The method of claim 1,
The microbubble generating nozzle further comprises a stem installed on the vertical rotation shaft,
Using the stem, the rotating ball is rotated 180° in the left-right direction so that one end of the hollow is located at the other end, and wastes accumulated on the one end are removed by the flow of the fluid (F+G) in which the gas is dissolved. Fine bubble generating nozzle, characterized in that. A gas dissolving device for dissolving the gas G in the fluid F;
The fine bubble generating nozzle according to claim 1 for generating fine bubbles by receiving the fluid (F+G) in which gas is dissolved;
A pump for supplying a fluid F to the gas dissolving device; And
An air compressor for supplying gas (G) to the gas dissolving device;
Micro-bubble generating device comprising. The method of claim 7,
The gas dissolving device,
It includes an injector, a flow amplification part, a gas-liquid mixing part, a dissolution tank and a discharge part,
The injector includes a fluid supply pipe and a gas supply pipe, and the gas supply pipe protrudes from an internal gas supply pipe located inside the fluid supply pipe, an upper exposed gas supply pipe exposed to the upper side of the fluid supply pipe, and a lower side of the fluid supply pipe. A lower protruding gas supply pipe positioned, including a gas flow passage formed inside the gas supply pipe, and a fluid flow passage formed between an inner peripheral surface of the fluid supply pipe and an outer peripheral surface of the internal gas supply pipe,
The flow amplification unit is a cylindrical open upper and lower ends, and accommodates the lower protruding gas supply pipe in the upper portion,
The gas-liquid mixing part is a cylindrical shape with an open upper end and a closed lower end, and accommodates the flow amplification part in the upper part,
The lower protruding gas supply pipe, the flow amplification part, and the gas-liquid mixing part are accommodated in the dissolution tank,
The device for generating microbubbles, wherein the discharge unit is located below the dissolution tank. The method of claim 8,
The gas supply pipe includes a gas inlet and a gas outlet, the gas inlet is located at one end of the upper exposed gas supply pipe, and the gas outlet is located at one end of the lower protruding gas supply pipe. The method of claim 8,
Characterized in that the fluid supply pipe includes a fluid inlet, a fluid passage pipe, and a fluid outlet, the fluid inlet is located at one end of an upper portion of the fluid supply pipe, and the fluid outlet is located at the other end of the lower portion of the fluid supply pipe A device for generating microbubbles. The method of claim 8,
The fluid supply pipe has a cylindrical upper portion, and a lower portion of the fluid supply pipe continuous to the upper portion is a funnel-shaped,
The microbubble generating device, characterized in that the diameter of the lower portion of the fluid supply pipe decreases as it approaches the fluid outlet. The method of claim 8,
The injector is characterized in that the fluid (F) flows through the fluid flow path and is injected to the outside of the fluid outlet, so that the gas (G) is introduced into the gas inlet and discharged to the gas outlet. The method of claim 12,
During operation, the gas inlet is in contact with the gas (G) and the gas outlet is in contact with the fluid (F). The method of claim 8,
The microbubble generator, characterized in that the flow amplification unit receives fluid (F) and gas (G) from the injector from an upper portion, increases the amount of the fluid, and discharges it to a lower portion of the flow amplification unit. The method of claim 8,
The gas-liquid mixing unit dissolves the gas G supplied from the flow amplification unit in the fluid F and discharges the gas to the outside. The method of claim 8,
The gas dissolving device further comprises a level sensor,
The microbubble generator, characterized in that the level sensor detects the level of the fluid in the dissolution tank. The method of claim 8,
The gas dissolving device further comprises a solenoid valve,
The microbubble generator, characterized in that the solenoid valve controls the level of the fluid (F) accommodated in the dissolution tank by controlling the pressure of the gas (G) accommodated in the dissolution tank. The method of claim 17,
The gas dissolving device comprises a check valve between the solenoid valve and the dissolution tank,
The check valve is a microbubble generator, characterized in that for preventing the fluid (F) accommodated in the dissolution tank from flowing backward in the direction of the solenoid valve. The method of claim 8,
The gas dissolution device further comprises a pressure gauge,
The microbubble generator, characterized in that the pressure gauge measures the pressure of the gas (G) accommodated in the dissolution tank. The method of claim 8,
The microbubble generating device further includes a regulator between the solenoid valve and the air compressor,
The microbubble generator, characterized in that the regulator is for maintaining a constant pressure differential between the gas pressure of the dissolution tank and the gas pressure of the solenoid valve.

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