KR101235663B1 - Apparatus for nano-bubble forming - Google Patents

Abstract

PURPOSE: A nanobubble forming apparatus is provided to form a large amount of nanobubbles by using a bubble generating member. CONSTITUTION: A nanobubble forming apparatus comprises a driving motor, a centrifugal impeller, a bubble generating unit(170), and a casing. The bubble generating unit comprises an outer wheel(171), an inner wheel(175), and a plurality of ribs(178). The outer wheel is formed to a ring shape. A plurality of first bubble protrusions(173) are formed on the outer circumference of the outer wheel. A plurality of second bubble protrusions(177) are installed on the outer circumference of the inner wheel. The second bubble protrusions sprays fluid to the side direction, and generate nanobubbles. The plurality of ribs connects the outer wheel and the inner wheel.

Description

Apparatus for nano-bubble forming

The present invention relates to a nanobubble forming apparatus for forming a nanobubble to increase the amount of dissolved oxygen to improve the efficiency of water treatment.

In general, the microbubbles are increased to increase the amount of dissolved oxygen in the fluid to promote the decomposition of microorganisms, foreign matter is easily adsorbed and floated on the surface of the water, it is injected to perform water treatment, such as sewage, wastewater treatment, water treatment and rivers, lakes.

An example of a device for injecting microbubbles for such water treatment has been disclosed in the "fine foam forming device" of Korean Patent No. 10-1015477 (registered on February 11, 2011).

Conventional microbubble forming device is fixed to the rotating pumping member corresponding to the fixed pumping member after fixing the fixed pumping member between the power unit, the upper and lower body (b), and the upper and lower body (b) to apply the rotational power In the microbubble forming device consisting of a bubbling action to generate a first bubbling action, and the air supply means, the contact projections are formed on the upper and lower surfaces, but the bubbling member to form a bubble ball fixed to the rotating shaft 41 And a second bubbling action formed of a fixing member 42 formed of a circular plate body formed on upper and lower surfaces of the contact protrusions and the contact protrusions which are rotated in contact with the contact protrusions and the micro contact gap a, and formed bubble balls. The mixed fluid having bubbles formed in the water by the air blowing was configured to form a third bubbled mixed fluid through the first bubbling action and the second bubbling action.

In the conventional microbubble forming apparatus having such a configuration, the microbubbles are generated by the fixing member 42, the first bubbling action and the second bubbling action, thereby performing water treatment.

However, in the conventional micro foam forming apparatus, the rotation member 41 is installed at the upper and lower portions of the fixing member 42 to generate the micro bubbles, and thus, the manufacturing cost is increased because the configuration is complicated, and the fixing member 42 has a fluid. There is a problem that the discharge amount is reduced because the passage is sealed.

In addition, when foreign matter is included in the fluid, there is a problem that a failure occurs in the microbubble forming apparatus by blocking the bubble hole formed in the fixing member 42.

In addition, since the contact protrusions formed on the rotating member 41 form the fine bubbles in the form of turbulence, the size of the fine bubbles is relatively large, and there is a problem in that a large amount of fine bubbles are formed.

In addition, the rotating member 41 and the two fixing members 42 are installed so as to overlap, and each of the contact projections are installed in the form of protruding to the upper and lower portions of each of the members 41 and 42 to create a wide internal space. There is a problem in that the size of the device increases.

The present invention is to solve the problems as described above, the problem to be solved by the present invention is a relatively simple structure to reduce the manufacturing cost, increase the discharge amount, can be miniaturized, and more than a fine foam The present invention provides a nanobubble forming apparatus capable of forming a nanobubble of a smaller size and a larger amount, and preventing the occurrence of a breakdown by cutting foreign substances contained in the fluid.

Nanobubble forming apparatus according to an embodiment of the present invention for achieving the above object is a drive motor, a centrifugal impeller is provided on the drive shaft of the drive motor to suck and discharge fluid, and the drive shaft is provided to rotate with the centrifugal impeller A nanobubble forming apparatus comprising a bubble generating member for generating nanobubbles in a fluid, and a casing surrounding the circumference of the centrifugal impeller and the bubble generating member, wherein the bubble generating member is formed in a ring shape, and the fluid is formed on an inner circumferential surface of the casing. The first bubble projection which injects the fluid in the lateral direction so that the nano-bubble is generated, the outer ring is provided with a plurality of radially around the outer ring, the diameter smaller than the diameter of the outer ring is located inside the outer ring and the drive shaft in the center The fluid is laterally coupled so that the nanobubbles are generated by the fluid passing through the inner circumferential surface of the outer ring. The second bubble protrusion for spraying includes a plurality of inner rings provided radially around the outer ring, and a plurality of ribs connecting the outer ring and the inner ring to each other.

The first bubble protrusion and the second bubble protrusion may be formed as an inclined surface inclined in a direction opposite to the direction in which the bubble generating member rotates when the bubble generating member rotates to face the fluid.

The first bubble protrusion and the second bubble protrusion may be formed as a curved surface in which a surface facing the fluid when the bubble generating member rotates is concave inward.

The bubble generating member may be located at a portion where a discharge passage hole through which the nanobubble generated fluid is discharged by the bubble generating member is formed.

The rib is formed in the shape of a cutter blade, the discharge passage hole may include a cutter portion for cutting foreign matter by interacting with the rib.

The outer ring may further include a third bubble protrusion that radially protrudes inwardly to the inner circumferential surface of the outer ring so that the fluid hits the outer circumferential surface of the inner ring to inject the fluid laterally to generate nanobubbles.

The third bubble protrusion may be positioned to deviate from the second bubble protrusion.

The centrifugal impeller may be provided in plurality in the drive shaft in multiple stages.

According to the present invention, since the nanobubble is formed only by the bubble generating member, the configuration is relatively simple, thereby lowering the manufacturing cost, minimizing the installation space of the bubble generating member, and miniaturizing the discharge volume by minimizing the resistance of the fluid. Can be increased.

In addition, by generating nanobubbles due to the impact of the fluid hitting the casing, not only the nanobubbles of a smaller size can be formed, but also a large amount of nanobubbles can be formed.

In addition, by cutting the foreign matter by interacting with the cutter portion provided in the rib of the bubble generating member and the discharge flow path hole, it is possible to prevent the failure caused by the foreign matter.

1 is a cross-sectional view of a microbubble forming apparatus according to the prior art.
2 is a cross-sectional view showing a nanobubble forming apparatus according to an embodiment of the present invention.
3 is a perspective view of a bubble generating member constituting the nanobubble forming apparatus according to an embodiment of the present invention.
Figure 4 is a plan view of a bubble generating member constituting the nanobubble forming apparatus according to an embodiment of the present invention.
5 is a perspective view of the cutter part forming the nanobubble forming apparatus according to the embodiment of the present invention as viewed from the bottom.
6 is a schematic cross-sectional view of a portion in which a bubble generating member constituting the nanobubble forming apparatus according to an embodiment of the present invention is installed.
7 is a plan view showing a bubble generating member constituting the nanobubble forming apparatus according to another embodiment of the present invention.

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

As shown in FIG. 2, the nanobubble forming apparatus 100 according to an embodiment of the present invention may include a driving motor 110.

The drive motor 110 may provide a driving force for rotating the centrifugal impeller 150 to be described below.

On the other hand, the drive motor 110 is composed of a stator and a rotor provided with a drive shaft 115 inside the stator, the rotor is configured to rotate the drive shaft 115 by the electric magnetic force inside the stator.

Here, the drive motor 110 may be implemented as an electric motor operated by electricity, the electric motor is a known configuration, so further detailed description thereof will be omitted.

In addition, the driving motor 110 may be positioned above the casing 120 to be described below.

Nanobubble forming apparatus 100 according to an embodiment of the present invention may include a centrifugal impeller (150).

The centrifugal impeller 150 can suck and discharge fluid by rotating centrifugal force.

On the other hand, the centrifugal impeller 150 is disposed in the form of a plurality of wings radially protruding in the lower portion of the disc, the drive shaft 115 is coupled to the center of the disc can be rotated by the drive shaft 115.

The centrifugal impeller 150 of such a configuration may be fluid is sucked into the center of the plurality of wings to discharge the fluid in the lateral direction by the wing.

In addition, the centrifugal impeller 150 may be coupled in a multi-stage manner, that is, the plurality of centrifugal impellers 150 are spaced apart from each other at a predetermined distance to the drive shaft 115.

Nanobubble forming apparatus 100 according to an embodiment of the present invention may include a casing (120).

The casing 120 forms a flow path through which the fluid moves, and may be configured to surround the circumference of the centrifugal impeller 150.

On the other hand, the casing may be composed of the inner casing 140 and the outer casing 130.

The inner casing 140 surrounds the circumference of the centrifugal impeller 150, and an inflow passage hole 141 through which fluid is introduced is formed in the lower portion of the inner casing 140, and the circumference in the opposite direction of the inflow passage hole 141. The discharge passage hole 142 may be formed to be discharged.

The inner casing 140 includes a partition plate 143 partitioned into a pressure increase space 144 and a discharge space 145, and the partition plate 143 includes a pressure increase space 144 and a discharge space 145. A discharge passage hole 143a through which the fluid moves may be formed.

Here, a plurality of centrifugal impellers 150 are positioned in the pressure increasing space 144 to increase the pressure of the introduced fluid, and the discharge space 145 is provided with a discharge impeller (not shown) to be described below. At 144, the pressure-increased fluid may be discharged to the outside of the inner casing 140 through the discharge passage hole 143a.

On the other hand, the inner casing 140 forming the pressure increasing space 144 may be divided into a plurality of partitions to form a plurality of centrifugal impeller 150, respectively, and each of the centrifugal impeller 150 A portion may have a distribution hole 146 through which fluid flows to each centrifugal impeller 150.

The outer casing 130 may be formed to surround the inner casing 140, and an inlet 131 through which fluid is introduced is formed at a lower portion of the outer casing 130, and is opposite to the inlet 131. In the direction, a discharge port 133 through which the fluid is discharged may be formed.

Here, the inlet 131 and the outlet 133 of the outer casing 130 are partitioned from each other so that the inlet 131 is in communication with the inlet passage hole 141 of the inner casing 140, the outlet 133 is the inner casing ( It may be configured to communicate with the discharge flow path hole 142 through which the fluid is discharged from 140.

As shown in Figure 3 and 4, the nanobubble forming apparatus 100 according to an embodiment of the present invention may include a bubble generating member (170).

The bubble generating member 170 is configured to form a nanobubble by injecting fluid to the side wall, and may include an outer ring 171, an inner ring 175, and a rib 178.

The outer ring 171 may be formed in a ring shape, and a plurality of first bubble protrusions 173 may be radially formed around the outer ring 171.

On the other hand, the first bubble projection 173 may inject the fluid in the outer direction of the outer ring 171 so that the nanobubbles are generated by the impact of the fluid hit the inner peripheral surface of the casing more specifically the inner casing (120).

Here, the first bubble protrusion 173 may form the nanobubble by the force that the first bubble protrusion 173 impacts the fluid when the bubble generating member 170 rotates.

In addition, the first bubble protrusion 173 is formed as an inclined surface inclined in a direction opposite to the direction in which the surface facing the fluid rotates when the bubble generating member 170 rotates to face the fluid that has hit the first bubble protrusion 173. It can be guided to be injected in the direction.

In addition, the surface of the first bubble protrusion 173 facing the fluid during the rotation of the bubble generating member 170 may be formed as a concave surface inwardly so as to guide and eject a larger amount of fluid accurately laterally. (See enlarged portion of FIG. 3).

The inner ring 175 is formed to a diameter smaller than the diameter of the outer ring 171 is located inside the outer ring 171, the drive shaft 115 may be coupled to the center of the inner ring 175 in a penetrating manner.

In addition, a plurality of second bubble protrusions 177 may be radially formed around the inner ring 175, and the second bubble protrusions 177 may have a fluid such that nanobubbles are generated by hitting the inner circumferential surface of the outer ring 171. To spray in the outward direction of the inner ring 175.

In addition, similar to the first bubble protrusion 173, the second bubble protrusion 177 may be in an opposite direction in which the surface facing the fluid rotates when the bubble generating member 170 rotates so that the fluid is guided outward. It may be formed as an inclined surface inclined.

In addition, a surface of the second bubble protrusion 177 that faces the fluid when the bubble generating member 170 rotates may be formed as a curved surface which is concave inward to guide and spray more fluid.

The rib 178 may connect the outer ring 171 and the inner ring 175 to each other, and a plurality of ribs 178 may be formed between the outer ring 171 and the inner ring 175.

The bubble generating member 170 configured as described above is rotated together when the driving shaft 115 is rotated, so that the first bubble protrusion 173 and the second bubble protrusion 177 impact the fluid, and the fluid is injected laterally. Thus, the nanobubbles may be formed by the impact force of the fluid against the inner casing 140 and the outer ring 171.

In this case, the bubble generating member 170 may be provided in the form of sealing the discharge flow path hole 143a in a portion in which the discharge flow path hole 143a through which all fluids introduced into the inner casing 120 pass.

5 and 6, the nanobubble forming apparatus 100 according to an embodiment of the present invention may include a cutter unit 190.

The cutter unit 190 may cut foreign substances by interacting with the bubble generating member 170 to cut foreign substances contained in the fluid.

On the other hand, the cutter unit 190 may be configured to include a shaft support 191 and the support (193).

The shaft support part 191 is a part for supporting the drive shaft 115, and is formed in a ring shape to support the drive shaft 115 in a form in which the shaft is inserted in the inner circumference thereof, and the shaft support part 191 has a discharge passage hole 143a. It can be located in the center of.

In addition, the support 193 may connect the shaft support 191 to the inner casing 120, more specifically, the discharge passage hole 143a, and the support 193 may be disposed radially around the shaft support 191. Dogs may be provided.

In addition, the support 193 is protruded further downward than the shaft support 191, the edge of the protruding lower end may be formed in the shape of a sharp cutter blade.

Here, the cutter unit 190 cuts the foreign matter by interacting with the bubble generating member 170, at this time, the rib 178 of the bubble generating member 170 protrudes to the top, to the top of the rib 178 An edge facing the direction in which the bubble generating member 170 rotates among the corners of the protruding upper end may be formed in a sharp shape such as a cutter blade.

The bubble generating member 170 configured as described above is positioned at the lower portion of the cutter unit 190 provided in the discharge passage hole 143a so that the support 193 and the rib 178 interact as if the scissors are together. Foreign matter contained can be cut.

At this time, the bubble generating member 170 may be configured to be located on the upper portion of the cutter unit 190, the support 193 and the rib 178 protrudes in a direction facing each other is configured to cut foreign matter by interaction Of course, it may be (see Fig. 6).

Nanobubble forming apparatus 100 according to an embodiment of the present invention may further include a discharge impeller (not shown).

The discharge impeller is located in the discharge casing 145 in the inner casing 120, more specifically, the inner casing 120 and discharges the fluid flowing into the discharge space 145 through the discharge passage hole 143a. The ball 142 may be discharged to the outside of the inner casing 120.

On the other hand, the discharge impeller may be configured in the same manner as the centrifugal impeller 150, detailed description thereof will be omitted.

The operation and effect of each of the components described above will be described.

In the nanobubble forming apparatus 100 according to an embodiment of the present invention, the inner casing 140 is installed inside the outer casing 130, and the inner casing 130 and the inner casing 140 are disposed on the inner casing 140. The drive motor 110 is installed to seal the upper end of the 140 and the outer casing 130.

At this time, the inlet 131 through which the fluid flows from the outer casing 130 is in communication with the inflow passage hole 141 of the inner casing 140, and the discharge port 133 is a discharge passage through which the fluid is discharged from the inner casing 140. In communication with the ball 142.

On the other hand, the drive shaft 115 of the drive motor 110 passes through the center of the inner casing 140, the drive shaft 115 is located in the discharge space 145 of the inner casing 140 partitioned by the partition plate 143. The discharge impeller (not shown) is coupled to a portion of the bubble generating member 170 is coupled to a portion of the drive shaft 115 located in the discharge passage hole 143a formed in the partition plate 143.

Here, the drive shaft 115 is supported through the shaft support portion 191 of the cutter portion 190 in the discharge passage hole (143a), the bubble generating member 170 is located below the cutter portion 190.

In addition, a plurality of centrifugal impellers 150 are coupled to the portion of the drive shaft 115 positioned in the pressure increasing space in multiple stages, and the centrifugal impellers 150 may be partitioned from each other in the inner casing 140.

When the nanobubble forming apparatus 100 according to an embodiment of the present invention configured as described above operates the driving motor 110, the centrifugal impeller 150 and the bubble generating member 170 coupled to the driving shaft 115 rotate together. Thus, the fluid is introduced through the inlet 131 of the outer casing 120.

In addition, the fluid introduced into the inlet 131 flows into the inner casing 140 through the inflow passage hole 141 and flows from the centrifugal impeller 150 located at the bottom to the centrifugal impeller 150 located at the top. The pressure of the fluid increases as it passes through 146 in turn.

Meanwhile, the fluid whose pressure is increased in the pressure increasing space where the centrifugal impeller 150 is located is introduced into the discharge space 145 through the discharge passage hole 143a.

In this case, before the fluid enters the discharge space 145, the fluid collides with the inner casing 120 or the first bubble protrusion 173 and the second bubble protrusion 177 by the rotating bubble generating member 170. Nanobubbles are formed by this impact.

In addition, when the foreign matter is included in the fluid, when the foreign material spreads over the support 193 of the cutter portion 190 or passes through the bubble generating member 170, the rib 178 and the cutter portion of the bubble generating member 170 ( Cut by a support 193 of 190.

In addition, the fluid containing the nanobubbles by the bubble generating member 170 is introduced into the discharge space 145, the fluid introduced into the discharge space 145 of the inner casing 140 by the discharge impeller (not shown) It is discharged to the discharge passage hole 142.

In addition, the fluid discharged through the discharge passage hole 142 may be discharged to the outside through the discharge port 133 of the outer casing 130 to supply the fluid having the nanobubbles to the water treatment apparatus.

Therefore, the nanobubble forming apparatus 100 according to an embodiment of the present invention can reduce the manufacturing cost by forming a nanobubble with a relatively simple structure, and minimizes the resistance of the fluid because it generates nanobubbles without going through various configurations The discharge amount can be increased.

In addition, the nanobubble forming apparatus 100 can be miniaturized by forming the nanobubbles with only the bubble generating member 170 to minimize the internal space.

In addition, the nanobubbles are formed by the bubble generating member 170 in the discharge passage hole 143a through which all the fluid passes, thereby increasing the generation amount of the nanobubbles, and forming the first bubble protrusion 173 and the second bubble protrusion 177. The nanobubbles may be generated by the impact force of the fluid impact on the inner casing 140 and the impact force of the impact on the inner casing 140 to form nanobubbles having a finer size.

In addition, by cutting the foreign matter contained in the fluid by the cutter unit 190 and the bubble generating member 170 can prevent the occurrence of failure due to the foreign matter.

Hereinafter, the nanobubble forming apparatus 100 according to another embodiment of the present invention.

The nanobubble forming apparatus 100 according to another embodiment of the present invention has the same configuration as the configuration of the nanobubble forming apparatus 100 of the embodiment, the same reference numerals, the same configuration and the same operation and effects are also the same Is omitted.

Nanobubble forming apparatus 100 according to another embodiment of the present invention is characterized in the bubble generating member (170).

The bubble generating member 170 of the nanobubble forming apparatus 100 according to another embodiment of the present invention may further include a third bubble protrusion 179 on the outer ring 171.

The third bubble protrusion 179 forms a nanobubble by impacting the casing by injecting fluid outwardly, and a plurality of third bubble protrusions 179 protrude radially from the inner circumferential surface of the outer ring 171 toward the inner side of the outer ring 171. It may be provided in the outer ring 171 in the form.

Meanwhile, like the first bubble protrusion 173 and the second bubble protrusion 177, the third bubble protrusion 179 is opposite to the direction in which the surface facing the fluid rotates when the bubble generating member 170 rotates. The fluid formed by the inclined inclined surface and hit the third bubble protrusion 179 may be guided so that the inner ring 175 is injected in the outer side direction.

In addition, the surface of the third bubble protrusion 179 facing the fluid during rotation of the bubble generating member 170 may be formed as a concave surface inwardly so as to guide and eject a larger amount of fluid accurately laterally. .

The third bubble protrusion 179 facing the second bubble protrusion 177 may be disposed to be offset from each other. That is, the fluid sprayed from the second bubble protrusion 177 toward the outer ring 171 and the fluid sprayed from the third bubble protrusion 179 toward the inner ring 175 may be disposed to be offset from each other.

Therefore, the nanobubble forming apparatus 100 according to another embodiment of the present invention can reduce the manufacturing cost by forming nanobubbles with a relatively simple structure, and minimizes the resistance of the fluid because it generates nanobubbles without going through various configurations The discharge amount can be increased.

In addition, the nanobubble forming apparatus 100 can be miniaturized by forming the nanobubbles with only the bubble generating member 170 to minimize the internal space.

In addition, the nanobubbles are formed by the bubble generating member 170 in the discharge passage hole 143a through which all the fluid passes, thereby increasing the generation amount of the nanobubbles, and forming the first bubble protrusion 173 and the second bubble protrusion 177. And a nanobubble having a finer size by generating nanobubbles by the impact force of the fluid impacting the third bubble protrusion 179 and the impact force of the fluid impacting the inner casing 140, the inner ring 175, and the outer ring 171. Can be formed.

In addition, by cutting the foreign matter contained in the fluid by the cutter unit 190 and the bubble generating member 170 can prevent the occurrence of failure due to the foreign matter.

Although the embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and the present invention is easily changed and equivalent to those of ordinary skill in the art to which the present invention pertains. Includes all changes and modifications to the scope of the matter.

100: nano bubble forming apparatus 110: drive motor
115: drive shaft 120: casing
130: outer casing 131: inlet
133: discharge port 140: inner casing
141: flow inlet 142: discharge inlet
143: partition plate 143a: discharge flow path
144: pressure increase space 145: discharge space
146: flow hole 150: centrifugal impeller
170: bubble generating member 171: outer ring
173: first bubble protrusion 175: inner ring
177: second bubble projection 178: rib
179: third bubble projection 190: cutter portion
191: shaft support 193: support

Claims (8)

A drive motor, a centrifugal impeller provided on the drive shaft of the drive motor to suck and discharge a fluid, a bubble generating member which is provided on the drive shaft to rotate with the centrifugal impeller and generates nanobubbles in the fluid, and a centrifugal impeller and a bubble generating member. A nanobubble forming apparatus comprising a casing surrounding a circumference,
The bubble generating member
The outer ring is formed in a ring shape, the outer ring is provided with a plurality of radially around the first bubble projection to inject the fluid in the lateral direction so that the fluid hits the inner peripheral surface of the casing to generate nanobubbles,
The second bubble protrusion is formed to a diameter smaller than the diameter of the outer ring is located inside the outer ring, the driving shaft is coupled through the center and the fluid is injected laterally so that the fluid hits the inner circumferential surface of the outer ring to generate nanobubbles An inner ring having a plurality of radially circumferences thereof, and
Nanobubble forming apparatus comprising a plurality of ribs connecting the outer ring and the inner ring to each other. The method of claim 1,
The first bubble protrusion and the second bubble protrusion is
Nanobubble forming apparatus, characterized in that the surface facing the fluid when the bubble generating member is rotated inclined in the opposite direction to the direction in which the bubble generating member rotates. The method of claim 1,
The first bubble protrusion and the second bubble protrusion is
Nanobubble forming apparatus, characterized in that the surface facing the fluid when the bubble generating member is formed in a concave curved surface inward. The method of claim 1,
The bubble generating member
Nanobubble forming apparatus, characterized in that located in the portion formed with a discharge flow path hole is discharged fluid is generated nanobubble by the bubble generating member. 5. The method of claim 4,
The rib is formed in the shape of a cutter blade,
The discharge passage hole nanobubble forming apparatus comprising a cutter portion for cutting foreign matter by interacting with the rib. The method of claim 1,
The outer ring is
A plurality of nanobubble forming apparatus further comprises a third bubble projection radially spraying the inner circumferential surface of the outer ring to inject the fluid in a lateral direction so that the fluid hits the outer circumferential surface of the inner ring to generate nanobubbles. The method according to claim 6,
The third bubble projection
Nanobubble forming apparatus, characterized in that positioned to be offset from the second bubble projection. The method of claim 1,
The centrifugal impeller
Nanobubble forming apparatus characterized in that the drive shaft is provided with a plurality in multiple stages.

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