KR102618660B1 - Nano bubble generator - Google Patents

Abstract

The present invention relates to a nanobubble generator, which includes a pump (30) for sucking water from an inlet (1), a nanobubble generator (10) in which a water outlet (2) is formed, and a motor (20). Water entering the pump passes through the nanobubble generator to generate nanobubbles, and the water containing the nanobubbles is discharged from the water outlet of the nanobubble generator (10).
In addition, the nanobubble generator 10 has a hollow tube 12, which is a rotating axis, installed inside a cylinder 11 installed in a vertical direction on the upper surface of the case, and a plurality of perforated plates 13 are sequentially installed from the top to the bottom. However, in the perforated plate, fine holes are formed to generate nanobubbles,
In addition, a venturi part equipped with a venturi tube is installed between the pump 30 and the nanobubble generating part 10 to break the injected air bubbles into small pieces.
The present invention has a simple structure and has a remarkable effect in that the air bubbles injected by the venturi are broken into small pieces and a large amount of fine-sized nanobubbles are generated by the nanobubble generating section where the perforated plate is installed.

Description

Nano bubble generator

The present invention relates to a nanobubble generator, and more specifically, it has a simple structure, the air bubbles injected by the venturi are broken into small pieces, and a large amount of fine-sized nanobubbles are generated by the nanobubble generator where the perforated plate is installed. It is about the nanobubble generator that is generated.

Devices for generating nanobubbles, which are generally used for water quality and air purification, have been developed, and as an example of conventional patent technology, Publication No. 10-2020-0074579 has an inlet at both ends through which mixed water of water and air flows in from the outside. A body in the shape of a ‘pipe’ having a discharge outlet;

A nanobubble generator comprising: a generating means provided between the inlet and the outlet in the body and configured to generate nanobubbles by applying collision pressure and shear pressure to the mixed water and having a transport space through which the mixed water is transferred;

in;

The generating means includes a 'pipe'-shaped nozzle pipe having an inlet through which the mixed water flows in and an outlet through which the mixed water is discharged at both ends; a 'plate'-shaped base plate that is bound to the outer peripheral surface of the nozzle pipe where the inlet is disposed and has an outer diameter and shape that contacts the inner peripheral surface of the transport space through which the mixed water is transported; It is disposed with a gap between it and the discharge port of the nozzle pipe in the direction of movement of the mixed water in the transfer space and has an outer diameter smaller than the outer diameter of the base plate, so that the gap between the two is on the inner peripheral surface of the transfer space through which the mixed water is transferred. a collision plate having a 'plate' shape having an outer diameter and shape through which the mixed water passes; A nanobubble generator characterized in that it includes a binding member that connects and couples the collision plate and the base plate has been disclosed.

Additionally, registration number 10-2105794 discloses a nanobubble generator.

However, the above conventional technologies had the disadvantage of having a complicated structure of the nanobubble generator and low effectiveness due to the small amount of nanobubbles generated compared to the size.

Therefore, the present invention was devised to solve the above problems. It has a simple structure, the air bubbles injected by the venturi are broken into small pieces, and a large amount of fine-sized nanobubbles are generated by the nanobubble generating section where the perforated plate is installed. The aim is to provide a nanobubble generator that generates this.

The present invention relates to a nanobubble generator, which includes a pump (30) for sucking water from an inlet (1), a nanobubble generator (10) in which a water outlet (2) is formed, and a motor (20). Water entering the pump passes through the nanobubble generator to generate nanobubbles, and the water containing the nanobubbles is discharged from the water outlet of the nanobubble generator (10).

In addition, the nanobubble generator 10 has a hollow tube 12, which is a rotating axis, installed inside a cylinder 11 installed in a vertical direction on the upper surface of the case, and a plurality of perforated plates 13 are sequentially installed from the top to the bottom. However, the perforated plate is characterized in that fine holes are formed to generate nanobubbles.

In addition, a venturi part equipped with a venturi tube is installed between the pump 30 and the nanobubble generating part 10, so that the injected air bubbles are broken into small pieces.

Therefore, the present invention has a simple structure and has a remarkable effect in that the air bubbles injected by the venturi are broken into small pieces and a large amount of fine-sized nanobubbles are generated by the nanobubble generating section where the perforated plate is installed.

Figure 1 is a front view of the nanobubble generator of the present invention.
Figure 2 is a side view of the nanobubble generator of the present invention.
Figure 3 is a plan view of the nanobubble generator of the present invention.
Figure 4 is a water flow chart of the nanobubble generator of the present invention.
Figure 5 is a configuration diagram of the convex portion of the perforated iron plate of the nanobubble generator of the present invention.
Figure 6 is a configuration diagram of the perforated plate of the nanobubble generator of the present invention
Figure 7 is a water flow diagram through a spiral groove formed on the inner peripheral surface of the hollow tube of the nanobubble generator of the present invention.
Figure 8 is a water flow diagram by a spiral groove formed on the inner peripheral surface of the hollow tube of the nanobubble generator of the present invention in another embodiment.
Figure 9 is a state diagram in which the double tube of the nanobubble generator of the present invention is rotated.
Figure 10 is a cross-sectional view of the nanobubble generator of the present invention
Figure 11 is a front view of the conical fan of the present invention.
Figure 12 is a side view of the conical fan of the present invention
Figure 13 is a rear view of the conical fan of the present invention.
Figure 14 is a cross-sectional view of the friction plate of the present invention
15 is a cross-sectional view of another embodiment of the present invention.

The present invention relates to a nanobubble generator, which includes a pump (30) for sucking water from an inlet (1), a nanobubble generator (10) in which a water outlet (2) is formed, and a motor (20). Water entering the pump passes through the nanobubble generator to generate nanobubbles, and the water containing the nanobubbles is discharged from the water outlet of the nanobubble generator (10).

In addition, the nanobubble generator 10 has a hollow tube 12, which is a rotating axis, installed inside a cylinder 11 installed in a vertical direction on the upper surface of the case, and a plurality of perforated plates 13 are sequentially installed from the top to the bottom. However, the perforated plate is characterized in that fine holes are formed to generate nanobubbles.

In addition, a case 40 is installed at the lower part of the motor, the nanobubble generator, and the pump, and the lower part of the hollow tube 12 is connected to gears inside the case, and the gears are connected to the motor shaft. do.

In addition, the inner surface of the hollow tube 12 is characterized in that a spiral groove is formed.

In addition, the water flowing into the pump penetrates the inside of the case through the water supply pipe at the bottom of the case, then flows into the nanobubble generator through the hollow pipe entrance on the bottom of the cylindrical nanobubble generator, and then flows upward through the hollow pipe. It flows in, collides with the upper inner wall of the cylinder at the top, and then flows downward, passing through a plurality of porous plates at the bottom to generate nanobubbles.

In addition, a convex portion is formed on the upper inner wall of the cylinder toward the bottom, so that when water hits it, the direction of the water is evenly distributed in various directions and flows toward the bottom.

In addition, there is a gap between the perforated plate and the cylinder, so that water flows through the gap.

In addition, a venturi part equipped with a venturi tube is installed between the pump 30 and the nanobubble generating part 10, so that the injected air bubbles are broken into small pieces.

The present invention will be described in detail with the accompanying drawings as follows. Figure 1 is a front view of the nanobubble generator of the present invention, Figure 2 is a side view of the nanobubble generator of the present invention, Figure 3 is a top view of the nanobubble generator of the present invention, Figure 4 is a water flow diagram of the nanobubble generator of the present invention, Figure 5 is a configuration diagram of the perforated steel plate convex portion of the nanobubble generator of the present invention, Figure 6 is a configuration diagram of the perforated plate of the nanobubble generator of the present invention, and Figure 7 is a hollow nanobubble generator of the present invention. Figure 8 is a water flow diagram due to a spiral groove formed on the inner circumferential surface of the pipe, Figure 8 is a water flow diagram due to a spiral groove formed on the inner circumferential surface of the hollow tube of the nanobubble generator of the present invention in another embodiment, Figure 9 is a diagram of the water flow caused by the spiral groove formed on the inner circumferential surface of the hollow tube of the nanobubble generator of the present invention in another embodiment. State diagram, Figure 10 is a cross-sectional view of the nanobubble generator of the present invention, Figure 11 is a front view of the conical fan of the present invention, Figure 12 is a side view of the conical fan of the present invention, Figure 13 is a rear view of the conical fan of the present invention, and Figure 14 is a front view of the conical fan of the present invention. Figure 15 is a cross-sectional view of another embodiment of the present invention.

The nanobubble generator of the present invention is installed with a pump 30 that sucks water from the water inlet 1, a nanobubble generator 10 in which the water outlet 2 is formed, and a motor 20. Therefore, the water that enters the water inlet passes through the pump and nanobubbles are generated in the nanobubble generator, and the water containing the nanobubbles is discharged through the outlet of the nanobubble generator (10).

A case 40, which is a gearbox, is installed at the lower part of the motor, nanobubble generator, and pump, the lower part of the rotating shaft is connected to gears for power transmission inside the case, and the gears are connected to the motor shaft.

In particular, the nanobubble generating unit 10 has a hollow tube 12, which is a rotating axis, installed inside a cylinder 11 installed in a vertical direction on the upper surface of the case, and a plurality of perforated plates 13 are placed on the outer periphery of the hollow tube. It is installed sequentially from the bottom to the bottom, and the perforated plate has fine holes formed in perforations to generate nanobubbles.

In addition, a spiral groove is formed on the inner surface of the hollow tube 12, which helps generate nanobubbles by forming a vortex.

Therefore, in the present invention, the water flowing into the pump penetrates the inside of the case through the water supply pipe at the bottom of the case, then flows into the nanobubble generator through the hollow tube inlet at the bottom of the cylindrical nanobubble generator, and then flows into the upper part through the hollow tube. It flows in one direction, collides with the upper inner wall of the cylinder from the top, and then flows downward, passing through a plurality of perforated plates at the bottom, generating nanobubbles.

On the upper inner wall of the cylinder, a convex portion made of perforated iron plate is formed in the downward direction, so that when water hits it, the direction of the water is evenly distributed in various directions and flows downward. There is a gap between the perforated plate and the cylinder, so water flows downward through the gap.

Meanwhile, the hollow tube of the present invention can be composed of a double pipe, and the inner pipe is fixed and the outer pipe is connected to the motor shaft to rotate. The inner diameter of the multi-cone plate is coupled to the external pipe and rotates together.

Additionally, a venturi unit is installed at the inlet of the pump inlet, and the venturi unit includes a venturi tube, a pump conical axial flow fan, and a friction plate. Friction plates are installed at small intervals behind the conical axial flow fan of the pump. The small gap becomes an injection hole or injection part for injecting air. Therefore, as the water passes through the venturi tube, the air mixes and rotates the conical axial fan at the rear of the pump at a faster flow rate, and the air passing through the extremely fine space formed between the rotating conical axial fan and the friction plate is broken into small pieces and merges to form nanobubbles. generates Micro grooves are also formed on the back of the axial flow fan to help generate nanobubbles.

Meanwhile, in another embodiment, two hollow tubes of the nanobubble generating unit are installed vertically side by side, and the perforated plates that are coupled to each other are installed staggered in the height direction in a zigzag manner. The hollow tube is driven by multiple power transmission pulleys from a single motor. Therefore, perforated plates attached to different hollow shafts cause water from different directions to collide, creating nanobubbles.

In addition, an auxiliary bubble generator can be made in the shape of a tube and inserted between the venturi unit and the water inlet where the nanobubble generator is supplied. In the auxiliary bubble generator, a number of disks are installed spaced apart in the direction of water flow, the flow path is zigzag, and grid pattern irregularities are formed on the surface of the disk so that water collides with the disk as it passes, making the bubbles smaller.

Therefore, the present invention has a simple structure and has a remarkable effect in that the air bubbles injected by the venturi are broken into small pieces and a large amount of fine-sized nanobubbles are generated by the nanobubble generating section where the perforated plate is installed.

1: Inlet 2: Outlet
11 ; cylinder
12: hollow pipe 13; Multi-valve plate (multi-valve plate)
14: Perforated steel plate convex part
10: Nanobubble generator 20: Motor
30: pump
40: case
50: Venturi unit 51: Venturi tube
52: conical fan 53: friction plate

Claims (3)

A pump 30 that sucks water from the water inlet 1, a nanobubble generator 10 in which the water outlet 2 is formed, and a motor 20 are installed, so that water entering the water inlet passes through the pump and generates nanobubbles. Nanobubbles are generated in the unit, and water containing the nanobubbles is discharged through the outlet of the nanobubble generator 10. The nanobubble generator 10 is a cylinder 11 installed in a vertical direction on the upper surface of the case. A hollow tube (12), which is a rotating axis, is installed inside, and a plurality of perforated plates (13) are installed sequentially from top to bottom, and a venturi tube is installed between the pump (30) and the nanobubble generating unit (10). In the nanobubble generator where the venturi unit is installed and the injected air bubbles are broken into small pieces,
A convex portion made of a perforated iron plate is formed in the downward direction on the upper inner wall of the cylinder 11, so that when water hits it, the direction of the water is evenly distributed in various directions and flows downward, and the perforated plate 13 and the cylinder 11 There is a gap in between, so water flows downward through the gap.
The hollow pipe 12 can be composed of a double pipe, and the inner pipe is fixed and the outer pipe is connected to the motor shaft to rotate. The inner diameter of the multi-cone plate is combined with the external pipe and rotates together.
A venturi unit 50 is installed at the inlet of the pump 30, and the venturi unit 50 includes a venturi tube 51, a conical fan 52, and a friction plate 53, and a friction plate behind the conical fan 52. (53) are installed at intervals, and the spaced portions are formed with injection holes or injection parts for injecting air. As the water passes through the venturi tube, the air is mixed and the rear conical fan 52 is rotated at an increased flow rate. The air passing through the space formed between the conical fan 52 and the friction plate 53 is broken into small pieces and joins to generate nanobubbles, and grooves are formed on the back of the conical fan 52 to help generate nanobubbles. Let it be like this,
Two hollow tubes (12) of the nanobubble generating section are installed vertically side by side, and the perforated plates that are connected to each are installed in a zigzag manner in the height direction. The hollow tubes are operated by a plurality of power transmission pulleys in one motor (20). As it is driven, the perforated plates 13 coupled to different hollow axes cause water from different directions to collide, creating nanobubbles.
An auxiliary bubble generator is formed into a tube shape and inserted between the inlet 1 through which the nanobubble generator is obtained from the venturi unit 50, and a plurality of disks are installed spaced apart in the water flow direction within the auxiliary bubble generator. A nanobubble generator characterized by zigzagging and forming lattice pattern irregularities on the surface of the disk so that water passes through and collides with the disk to make the bubbles smaller. delete delete