KR102595802B1 - Micro nanobubble generator - Google Patents

Abstract

The present invention relates to a means for generating micro-nano bubbles in which protrusions are formed, and is characterized in that micro-nano bubbles are generated by protrusions (21) formed on a vortex plate (20) installed in a fluid.
In addition, the protrusions 21 are formed at intervals in the longitudinal direction in which the fluid flows, and the present invention has the remarkable effect of generating a large number of micro-nano bubbles in the fluid and smoothly through the vortex plate.

Description

Micro nanobubble generator {Micro nanobubble generator}

The present invention relates to a micro-nano bubble generating means in which protrusions are formed on the inner and outer plates. More specifically, a micro-nano bubble generator that generates micro-nano bubbles that allow waste (factory wastewater, domestic wastewater, pig hair, etc.) to pass through without being caught. It's about.

In general, when supplying oxygen or ozone gas to remove various types of wastewater or farm manure and odors, gas must be injected into the bubble to be effective. However, if only gas is injected into the liquid, the gas will simply fly away. The effect is minimal and the result is meaningless. Gas must be injected into proper nano/micro bubbles, but the essential condition is bubble creation. However, the fine bubble generator must have a mechanical structure, and foreign substances such as trash can easily get caught and accumulate, which can grow and block the waterway, ultimately causing the treated water pump to overload and stop. .

Then, if the machine is not dismantled and cleaned, it can no longer be used and will just stand in a stopped state.

As a device that generates micro-nano bubbles to purify the polluted water, as an example of the prior patent technology, publication number 10-2021-0136526 is coaxially connected to the axis 20 of the motor 10 and rotates to generate nano-micro bubbles. In the nano-micro water bubble supply pump including an inner rotating body forming an outer casing 30 that accommodates the inner rotating body and forms an inflow and outflow passage for water, the outer casing 30 has water on one side. It includes a suction pipe 31 through which water is sucked and a discharge pipe 32 through which water is discharged on the other side, and a suction impeller 41, several bubble generation plates 43, and a discharge impeller ( 42) includes, wherein the water sucked from the suction pipe 31 formed on the left side of the outer casing 30 moves a distance corresponding to the body length of the outer casing and then forms on the right side of the outer casing 30. A nano-micro water bubble supply pump is disclosed, which is characterized in that it is discharged through a discharge pipe 32.

In addition, registration number 10-1947084 includes a plurality of rotors arranged along the axis of one or more rotational axes inside a housing through which fluid can flow in and out, and fixed to the inner wall of the housing with a certain distance from each rotor. It includes a plurality of stators facing each other in the form of surface contact, and at least the rotor of the rotor and the stator has a mesh-type structure having a plurality of openings for fluid to pass through, and the mesh-type structure has a plurality of cross bars and a plurality of A nano-micro bubble generator has been disclosed, which is characterized in that the vertical bars have a certain height difference from each other and are provided in an unevenly stepped form.

However, the above-described prior technologies had problems in that foreign substances such as hair or thread were caught inside the micro-nano bubble generator, which lowered the efficiency of the device or caused it to malfunction.

Therefore, the present invention was developed to solve the above problems. Even if small waste enters the bubble generator, the liquid and waste are pushed out of the machine by the water pressure pushed by the pump, and bubbles must be generated. Therefore, the aim is to provide a micro-nanobubble generator configured to simultaneously generate bubbles and remove waste.

The present invention relates to a means for generating micro-nano bubbles in which protrusions are formed, and is characterized in that micro-nano bubbles are generated by protrusions (21) formed on a vortex plate (20) installed in a fluid.

In addition, the protrusions 21 are characterized in that they are formed at intervals in the longitudinal direction through which fluid flows.

Therefore, the present invention has the remarkable effect of generating a large number of micro-nanobubbles in the fluid and smoothly through the vortex plate.

1 is a conceptual diagram of the present invention
Figure 2 is a model photo of a micronanobubble generator using a stacked vortex plate of the present invention.
Figure 3 is a top view of the vortex plate of the present invention
Figure 4 is a bottom photo of the vortex plate of the present invention.
Figure 5 is a side photo of the vortex plate of the present invention.
Figure 6 is a front and rear perspective view of a vortex plate of another embodiment of the present invention.
Figure 7 is a perspective view of a vortex plate combination in another embodiment of the present invention.
Figure 8 is a perspective view of a vortex plate of another embodiment of the present invention.
Figure 9 is a perspective view of a vortex plate lamination of another embodiment of the present invention.
Figure 10 is a modified view of Figure 8
Figure 11 is a top view of a vortex plate of another embodiment of the present invention
Figure 12 is a bottom view of a vortex plate of another embodiment of the present invention.

The present invention relates to a micronanobubble generator in which protrusions are formed, and is characterized in that micronanobubbles are generated by protrusions 21 formed on a vortex plate 20 installed in a fluid.

In addition, the protrusions 21 are characterized in that they are formed at intervals in the longitudinal direction through which fluid flows.

In addition, grooves are formed on the lower surface of the vortex plate 20 to correspond to the protrusions formed on the upper surface of the lower vortex plate, and the ends of the protrusions and the grooves are spaced at a certain distance to allow water to flow.

The present invention will be described in detail with the accompanying drawings as follows. Figure 1 is a conceptual diagram of the present invention, Figure 2 is a photograph of a model of a micro-nanobubble generator using the stacked vortex plate of the present invention, and Figure 3 is a view of the vortex plate of the present invention. A top view, Figure 4 is a bottom view of the vortex plate of the present invention, Figure 5 is a side view of the vortex plate of the present invention, Figure 6 is a front and rear perspective view of another embodiment of the vortex plate of the present invention, and Figure 7 is another view of the vortex plate of the present invention. A perspective view of a combined swirl plate of an embodiment, Figure 8 is a perspective view of a swirl plate of another embodiment of the present invention, Figure 9 is a perspective view of a swirl plate lamination of another embodiment of the present invention, Figure 10 is a modified view of Figure 8, and Figure 11 is a view of the present invention. Figure 12 is a top view of a vortex plate of another embodiment of the present invention, and Figure 12 is a bottom view of a vortex plate of another embodiment of the present invention.

In the present invention, bubbles are created by injecting gas into the vortex plate in the form of concave and convex teeth and irregularities, and the large bubbles are shattered into small bubbles when they hit the convex surface.

The concave and convex shape allows liquids to collide easily and repeatedly, and the concave and convex shape has a great effect in widening the surface area, and since the area is much larger, the effect of friction in creating bubbles is also much greater. You lose. Ultimately, fine bubbles are easily created through collision and friction, so serrated or uneven shapes can greatly increase the effect.

From there, the concave and convex surface is treated with corrosion (like small holes) in the mold, and as the liquid flows, friction occurs heavily against the small grooves and small protrusions, causing collisions, and the bubbles at the level of microbubbles are split into fine nano-level bubbles. It is to maximize efficiency.

You can use multiple sheets by stacking them at regular intervals (about 1mm) between the boards made in this way, enough to allow the waste to escape. At this time, the waste is pushed by the water pressure of the pump and out of the bubble generator. Therefore, bubble creation and garbage cleaning occur simultaneously.

Large trash can be filtered out initially with a net such as a mosquito net at the pump's inlet to prevent it from entering when the pump suctions.

Soon, in the present invention, the liquid passes through the inlet into the liquid plate containing waste, and the waste sticks to the overlapping plate. If this is not removed in time, the entrance of the overlapping plates will become clogged with waste. So, when you rotate something like a motor or blade, it flows like liquid through the gap between the plates. When the waste enters the inlet, the liquid is pushed by a pressurized pump, and the waste passes through and falls out together.

The vortex plate of the present invention is particularly subjected to corrosion (empo) treatment to form irregularities on the surface. The vortex plate is made in the shape of a plate, and a plurality of protrusions 21 are formed on one or both surfaces to form a flow path.

The protrusion is formed to protrude into a hexahedral shape. Or it can be of various shapes, such as triangles or circles.

If you look at the vertical cross section, they cross in a zigzag pattern, so the fluid hits them in a zigzag pattern as it flows from the inlet to the outlet, increasing the bubble generation efficiency. The bubble generating plate has micro-concave-convex portions formed on its surface to make micro-bubbles more effective. The micro-concave-convex portion has a circular, triangular, or square cross-section.

A plurality of the vortex plates are installed inside the body.

The upper and lower spacing of the vortex plates is installed to be spaced apart from 0.1 to 0.6 mm. Pin holes are formed on both sides of the upper surface to be joined by pins, or a concave groove is formed so that the engaging protrusions formed on the lower surface of the upper vortex plate are coupled to the concave groove to prevent the upper and lower vortex plates from moving. And in another embodiment, the protrusions adjacent to each other are formed offset in the width direction, so that the flow path is formed in a zigzag pattern, and micro-nano bubbles can be easily generated.

Meanwhile, in the case of a triangular vortex plate as another embodiment, upper protrusions are formed on the vortex plate spaced apart in a direction perpendicular to the flow direction, and the upper protrusions range from a triangular sawtooth shape to an arrow shape and the space between the next serrated shape. A vortex is generated (then there is an obstacle that cannot easily be overcome, so a vortex is created), and at this time, the gas and liquid are evenly mixed and has the effect of increasing the gas dissolution rate, which is the purpose of the bubble. In addition, the gas is spread evenly throughout the vortex space to proceed to the next step, and the evenly mixed gas is broken into smaller microbubble-level bubbles through collision and friction at the serrated concave-convex stage. To make this more effective, the next stage is In the arrow-shaped convex stage, the liquid first gathers in the center. Then the pressure of the liquid increases, causing collisions and friction to become stronger. Then, the generation rate of nanobubbles increases. After going through a few steps, we move on to the vortex space. The three triangular upper protrusions may be formed one after another without any spacing, and the cross section may be straight, and then three triangular upper protrusions may be formed repeatedly.

That is, three triangular upper protrusions are formed one after another without any spacing, and then three rod-shaped upper protrusions are formed adjacent to each other at regular intervals. At this time, the vertex of the triangular upper protrusion located downstream is connected to the adjacent rod-shaped upper protrusion by a straight protrusion.

If this process is repeated several times, a large number of very fine nanobubbles are effectively generated.

In the present invention, several vortex plates are overlapped, and the concave and convex upper protrusions must be kept constant from the inlet to the outlet so as not to get caught in the space through which the liquid passes, especially the size of trash (0.3 to 1.5 mm).

As another example, in the case of a complex-shaped vortex plate, upper protrusions are formed on the vortex plate spaced apart in a direction perpendicular to the flow direction, and the upper protrusions are square or circular bar-shaped, with short and long lengths alternating in the width direction. A vortex is formed in the side direction as well.

The lower protrusion has a circular cross-section, and a circular groove is formed at the top, and two circular grooves are also formed between the lower protrusion and the lower protrusion. The two circular grooves are formed to have a longer horizontal length than the one circular groove. Therefore, when fluid flows with the vortex plates stacked up and down, vortices are generated due to the long and short transverse lengths of the upper protrusions on the upper surface of the lower vortex plate and the 1 and 2 circular grooves of the lower protrusions on the lower surface of the lower vortex plate. Fluids collide between the constituent flows, generating larger vortices and creating micro-nanobubbles.

Therefore, the present invention has the remarkable effect of generating a large number of micro-nanobubbles in the fluid and smoothly through the vortex plate.

20: Bubble generating plate (vortex plate) 21: Protrusion
10: body
30: outlet
32: discharge path
40: inlet
42: inlet
44: motor

Claims (3)

Micro-nano bubbles are generated by protrusions 21 formed on the vortex plate 20 installed in the fluid. The protrusions 21 are formed at intervals in the longitudinal direction through which the fluid flows, and the vortex plate 20 ), the lower surface of which is formed with grooves corresponding to the protrusions 21 formed on the upper surface of the lower vortex plate, and the tip of the protrusion and the groove are spaced at a certain interval to form protrusions through which water can flow. A micro-nano bubble generator. In
The vortex plate 20 is corroded to form micro-concave-convex portions on its surface. The vortex plate is made of a plate shape, and a plurality of protrusions 21 are formed on one or both surfaces to form a flow path,
The protrusions 21 are formed in a hexahedral, triangular, or circular shape, and when viewed in vertical cross-section, are intersected in a zigzag manner, so that the fluid strikes in a zigzag manner as it flows from the inlet to the outlet, increasing bubble generation efficiency, and the vortex plate. In (20), the micro-concave-convex portions formed on the surface are more effective in generating micro-bubbles. The micro-concave-convex portions are formed in a circular, triangular, or square cross-section, and a plurality of vortex plates (20) are installed inside the body. But,
The upper and lower spacing of the vortex plates 20 is installed at a distance of 0.1 to 0.6 mm, and pin holes are formed on both sides of the upper surface to connect with pins, or a concave groove is formed so that the engaging protrusions formed on the lower surface of the upper vortex plate 20 are concave. The upper and lower vortex plates are coupled to the grooves so that they do not move, and the protrusions 21 adjacent to each other are formed offset in the width direction to form a zigzag flow path and facilitate the generation of micro-nano bubbles. nano bubble generator delete delete