KR20190038500A - Ari pollution abatement device using bubble - Google Patents

Abstract

The present invention relates to an air pollution reduction apparatus using bubbles. The apparatus comprises: a main body unit installed in a target area and having an inner space; a bubble liquid storage unit installed in the main body unit and storing a bubble liquid; a bubble generating unit for converting the bubble liquid into bubbles; a bubble ejecting unit installed to extend from the main body unit and configured to eject the generated bubbles in a direction of the atmosphere; and a control unit for controlling driving of the bubble generating unit according to input information. By ejecting the bubbles into the atmosphere, air pollutants can be adsorbed and removed.

Description

TECHNICAL FIELD [0001] The present invention relates to an air pollution abatement apparatus using bubbles,

The present invention relates to an air pollution abatement apparatus using bubbles.

In recent years, damage from air pollution has been increasing rapidly.

Air pollution is caused by flooding pollutants generated by the use of fossil fuels such as industrialization and traffic in the air.

Air pollution has been constantly arising from the past, and various regulations and discussions have been made. Recently, however, the seriousness of air pollutants generated in China has been increasing as the air pollutants are transferred to the Korean peninsula through the atmospheric currents.

Air pollutants from China are being directly transmitted to the Korean peninsula due to the influence of the northwestern wind in winter due to the mass concentration of factory complexes and fossil power plants in the eastern area of China.

As this situation has arisen, there has been an emergency in securing the health of the citizens of the country caused by air pollution.

Particularly, it is pointed out that there is no way to solve this problem in Korea, because it is the main cause of air pollution in China.

Since air pollutants are being identified as the cause of respiratory diseases and brain diseases, it is necessary to develop an intensive response system for securing the health of the people.

An object of the present invention is to provide an air pollution abatement apparatus using a bubble capable of absorbing and removing air pollutants present on the atmosphere by floating the bubble on the atmosphere.

According to an embodiment of the present invention, there is provided an apparatus for reducing air pollution using bubbles, the apparatus comprising: a main body unit having an internal space formed in a target area; A bubble liquid storage unit installed in the main body unit and storing bubble liquid; A bubble generating unit for converting the bubble liquid into bubbles; A bubble ejection unit installed to extend from the main body unit and configured to eject the generated bubble in a waiting direction; And a control unit for controlling the driving of the bubble generation unit according to the input information.

Here, the bubble generating unit may include a bubble screen configured to spread the bubble liquid delivered from the bubble liquid storage unit in a predetermined shape and store the air, And a blower blowing air toward the bubble screen.

Here, the bubble ejection unit may include a coating liquid injector for spraying the coating liquid so that the coating liquid flows along the inner wall surface.

Here, the temperature control unit may be configured to control the temperature of the bubble.

The bubble generation unit may further include a gas supply unit for supplying a floating gas to the bubble generation unit, and the bubble generation unit may generate the bubble by blowing the floating gas.

Here, the bubble liquid may include at least one of water, a thickener, and a surface active agent.

The bubble liquid may be selected from the group consisting of purified water, starch, sugar, starch syrup, honey, glycerin, sodium lauroamphoacetate, sodium trideceth sulfate, hydroxyethyl cellulose ), Taxonomy, and polyvinyl alcohol (PAV).

According to the air pollution abatement apparatus using the bubble of the present invention configured as described above, it is possible to suck and remove the air pollutant suspended in the air by spraying the bubble.

In addition, the life of the bubble and the height of the flotation can be further improved by diversification of the bubble generation method and the injection method.

In addition, the efficiency of removing air pollutants can be further improved by generating multiple bubbles.

1 is a conceptual diagram illustrating the principle of use of the air pollution control apparatus 100 according to an embodiment of the present invention.
Fig. 2 is a view for explaining the structure of the air pollution reduction device 100 of Fig.
Fig. 3 is a view for explaining the detailed structure of the bubble generating unit 130 and the bubble generating unit 160 in Fig.
FIG. 4 is a view for explaining the structure of the blowers 133a and 133b for generating multiple bubbles according to another embodiment.
FIG. 5 is a diagram for explaining an implementation of an air pollutant abatement system through the arrangement of the air pollution abatement apparatus 100. FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an air pollution reduction apparatus using bubbles according to a preferred embodiment of the present invention will be described in detail with reference to the drawings. In the present specification, different embodiments are given the same or similar reference numerals, and the description thereof is replaced with the first explanation.

1 is a conceptual diagram illustrating the principle of use of the air pollution control apparatus 100 according to an embodiment of the present invention.

As shown in the figure, there may be an air pollutant (D) composed of fine dusts and various chemical substances discharged from a factory, a construction site, an automobile, a ship, and a residence.

Such an air pollutant D does not stay at the place of generation, but moves according to the flow of the atmosphere. An example is the situation in which air pollutants (D) from China now affect the Korean Peninsula.

The atmospheric flow occurs naturally, and its range is so wide that it is difficult with current technology to change an artificial corresponding flow. Therefore, during the Northwest wind season, the Korean Peninsula is directly affected by the air pollutants (D) generated in China.

Accordingly, the air pollutant D can be reduced through the air pollution reduction device 100 that can generate the bubble B and spray it to the atmosphere as in the present embodiment.

The air pollution control apparatus 100 has a structure that is installed in an installation area to receive bubble B liquid to generate bubbles B and to bubble the generated bubbles B into the atmosphere.

At this time, due to the injection structure and the generated components, the air pollutant D can be moved to the atmosphere in which the air is moved and floated along the atmosphere without disappearing for a predetermined time.

As the surface of the bubble (B) is formed with the liquid component, the air pollution material of a minute size can be absorbed on the surface of the bubble (B). Further, the bubble B can be moved along the atmosphere, not staying in one region of the atmosphere as the weight is lightly generated. Therefore, when moving, a large number of air pollutants D can be sucked through one bubble B, and the life of the bubble B can be lowered to a liquid phase.

According to the air pollution abatement apparatus having such a constitution and principle, the air pollutant can be sucked and removed efficiently through the burbles. Hereinafter, the detailed configuration of the air pollution abatement apparatus will be described.

FIG. 2 is a view for explaining the structure of the air pollution reduction apparatus 100 of FIG. 1, and FIG. 3 is a view for explaining the detailed structure of the bubble generating unit 130 and the bubble jetting unit 160 of FIG. FIG.

As shown in the figure, the air pollution control apparatus 100 includes a main body unit 110, a bubble liquid storage unit, a bubble generation unit 130, a gas supply unit 140, a temperature regulation unit 150, 160, and a control unit 170.

The main body unit 110 may be a means for accommodating other configurations or being installed in a target area. Accordingly, the main body unit 110 has an inner space, and one surface may be formed with an opening for communicating the structures described later. Although the opening is formed in a circular shape in this embodiment, it can be applied in various shapes depending on experiment and process conditions.

In addition, the main body unit 110 may be provided with a fixing portion for fixing to a target area (ground, building, ship) or the like. In addition, a moving portion such as a roller may be further provided on the floor surface so as to be movable by an external force. At this time, the moving unit may be configured to be driven by power supply.

The bubble liquid storage unit 120 may be a means for storing the bubble liquid W. [ The bubble liquid W may include at least one of water, a thickener, and a surface active agent as a material for generating the bubble B. To this end, the bubble liquid storage unit 120 may include a mixing unit for mixing a plurality of storage units for each type of bead liquid W and a bubble liquid (W) material provided in each storage unit.

At this time, the bubble liquid W may be specifically purified water, starch, sugar, starch syrup, honey, glycerin, sodium lauroamphoacetate, sodium trideceth sulfate, Cellulose, hydroxyethyl cellulose, taxolone, and polyvinyl alcohol. In addition, various materials that are environmentally friendly can be mixed and applied while maintaining the viscosity and elasticity of the bubble (B).

The bubble liquid storage unit 120 includes a bubble liquid supply pipe and a bubble liquid supply valve 121 and transfers the bubble liquid W to the bubble liquid supply valve 121 through the bubble liquid supply pipe, 121 can supply the bubble liquid W to the bubble screen 131 to be described later. The supply of the bubble liquid from the bubble liquid storage unit 120 can be controlled under the control of the control control unit 170. [

In this embodiment, the bubble liquid storage unit 120 is installed inside the main body unit 110. However, the bubble liquid storage unit 120 may be installed to be coupled with the main body unit 110 from the outside. Further, the bubble liquid storage unit 120 may be configured to communicate with other large-capacity bubble liquid storage units so that a continuous supply of the bubble liquid W is performed.

The bubble generating unit 130 can generate the bubble B by receiving the bubble liquid W from the bubble liquid storing unit 120 as a means for generating the bubble B. [ For this purpose, the bubble generating unit 130 may include a bubble screen 131 and a blower 133.

3, the bubble screen 131 may be formed to unfold and store the bubble liquid W transferred from the bubble liquid storage unit 120 to allow air to pass therethrough. In other words, the bubble screen 131 may be installed to correspond to the opening of the main body unit 110, communicate with the bubble jetting unit 160 at the upper part, and correspond to the blower 133 at the lower part. At this time, when the bubble liquid W is supplied from the bubble liquid valve 121 of the bubble liquid storage unit 120, the bubble liquid W may be formed in a plate shape so as to accommodate the bubble liquid W and to spread the bubble liquid W flat. In addition, the bubble screen 131 may have a plurality of pores through which the gas can pass though the liquid bubble liquid W can not pass therethrough. Accordingly, the supplied bubble liquid W can be spread and stored through the upper surface of the bubble screen 131. [

In addition, the bubble screen 131 may have a screen wall 131a protruding in the height direction along the periphery to prevent the bubble liquid W received therein from flowing to the periphery. Accordingly, the bubble screen 131 forms a concave space by the screen wall 131a, and can receive the bubble liquid W through the space.

The shape of the bubble screen 131 may be formed to correspond to the shape of the blower 133, the bubble ejection unit 160, and the opening.

The blower 133 may be a means for blowing air toward the bubble screen 131. For this purpose, the blower 133 may be installed at a lower portion of the bubble screen 131 to blow air toward the upper surface of the bubble screen 131. The blower 133 may be a fan driven by a motor or a pneumatic injector 165 for compressing and injecting a gas.

When air is blown by the blower 133, the base body can be transmitted to the bubble liquid W stored in the upper portion of the bubble screen 131 through the pores of the bubble screen 131. The bubble liquid W maintains the viscosity and the bubble B can be generated by the gas delivered from the lower portion of the bubble screen 131. [ The bubble B thus generated can be raised to the top by blowing air.

Further, although not specifically shown in the present embodiment, the blower 133 can generate a vortex. To this end, the blower 133 is composed of a plurality of blowers, and blowing is performed in multiple directions, and a vortex can be formed by the multi-direction blowing.

Although the bubble screen 131 and the blower 133 are separated from each other in the present embodiment, they may be installed to be coupled to each other and an additional protective screen (not shown) may be installed between the bubble screen 131 and the blower 133 Bubble liquid settling prevention) may be provided.

The gas supply unit 140 may be means for supplying a floating gas to the blower 133. [ The blower 133 may blow gas such as air present in the outside, but it may blow air through the flotation gas to improve the lifting force of the bubble B. To this end, the gas supply unit 140 may store gas that is lighter than air such as helium gas and may supply the gas to the blower 133. At this time, the floating gas to be used may be volatile, inert gas or the like.

The temperature adjusting unit 150 is a means for adjusting the temperature of the bubble B. In this embodiment, the temperature adjusting unit 150 is provided around the blower 133 to adjust the temperature of the gas discharged from the blower 133. Alternatively, the temperature of the bubble jetting unit 160 can be adjusted by installing the bubble jetting unit 160 in another manner. At this time, the temperature control can be performed by the heating operation for raising the temperature.

The bubble ejection unit 160 is installed to extend from the main body unit 110 and can eject the generated bubble B in the atmospheric direction. The bubble jetting unit 160 may be formed as a tubular body so as to correspond to the opening of the main body unit 110. Therefore, the bubble B generated in the bubble generating unit 130 can be received in the inner space and guided to the atmosphere through the upper open outlet.

The bubble ejection unit 160 may include a position adjustment unit 161 at a position where the bubble ejection unit 160 is coupled to the main body unit 110 to adjust the angle with respect to the main body unit 110. The bubble ejection unit 160 may be composed of a plurality of bubbles, and accordingly, the bubble generation unit 130 and the opening of the main body unit 110 may correspond to a plurality of bubble generation units.

Further, the bubble ejection unit 160 may be formed so that the length extending in the height direction is adjusted. The length adjustment can be adjusted automatically through the electric motor.

In addition, the bubble ejection unit 160 may include a coating liquid injector 165 for spraying the coating liquid C so that the coating liquid C flows through the inner wall surface. The coating liquid injector 165 receives the coating liquid C from a coating liquid storing unit (not shown) and can spray the coating liquid C onto the inner wall surface of the bubble jetting unit 160. The coating liquid (C) contains a lubricant component, or the same or similar components as the above-mentioned bubble liquid may be used singly or in combination. In this case, the inner wall surface of the bubble ejection unit 160 may be coated with a lubricant to minimize the friction with the bubble B, or to give the bubble B an additional coating effect.

Further, a spiral protrusion 163 may be formed along the inner wall surface of the bubble discharge unit. The bubble B ejected to the outside by the spiral protrusion 163 can have a rotational force.

The control unit 170 may be means for controlling the above-described configurations. First, when the input information is received through the user input unit or the communication unit (not shown), the control unit 170 can control the above-described configurations to operate according to the input information. When the input information on the operation is received, the representative control unit 170 generates bubbles B by driving the bubble generating unit 130 and controls the generated bubbles B to be emitted toward the atmosphere have.

Also, the control unit 170 can generate status information on the operation status of each configuration through a sensor unit (not shown) and transmit the status information to the external terminal as a communication unit. In addition, the operation of other components may be automatically controlled according to the status information of each sensor unit. In addition, the control unit 170 may control the operation of the above-described configurations when air pollution information related to the generation and movement of air pollutants through the communication unit is received.

Also, although not shown in this embodiment, a power supply unit, a memory unit, a display unit, a speaker unit, and the like for supplying power to the air pollution reduction apparatus 100 may be provided.

The detailed configuration of the air pollution reduction device has been described above. 4, a configuration and a method for generating multiple bubbles will be described.

FIG. 4 is a view for explaining the structure of the blowers 133a and 133b for generating multiple bubbles according to another embodiment.

As shown, the blowers 133a and 133b of the present embodiment may have a different structure from the blower of FIG. 3 to generate multiple bubbles B1 and B2.

The blowers 133a and 133b include a first blower 133a for generating the first bubble B1 and a second blower 133b for generating the second bubble B2 inserted into the first bubble B1, .

The first blower 133a may have substantially the same structure as the blower of FIG.

The second blower 133b may be formed to have a smaller diameter than the first blower 133a for generating the second bubble B2.

In this case, the multiple bubbles B1 and B2 in which blowing is performed in different areas when the first and second blowers 133a and 133b simultaneously blow air, and the second bubble B2 is generated in the first bubble B1, Can be generated.

Further, as shown in the drawing, the second blower 133b can be arranged closer to the bubble screen than the first blower 133a.

The first and second blowers may generate multiple bubbles by controlling the blowing pressure and the blowing speed according to the control of the control unit.

Although the first and second blowers 133a and 133b have been described in the present embodiment, a larger number of blowers may be disposed to generate multiple bubbles in which more bubbles are continuously inserted.

FIG. 5 is a diagram for explaining an implementation of an air pollutant D reduction system through the arrangement of the air pollution reduction apparatus 100. FIG.

The concept of reducing the air pollutant D through the actual arrangement and operation of the above-described air pollution reduction apparatus 100 will be described.

First, in order to more effectively block the air pollutants (D) delivered from China, the islands (I) of the west sea (Korea), which is closest to China, and the islands of the sea (ship, The air pollution abatement apparatus 100 can be installed first.

Secondly, the air pollution abatement device 100 can be installed on the roof of the building S of the land (near the west sea) of the home country.

In addition, although not shown, the air pollution abatement apparatus 100 may be installed in a mountain or a high-rise building in each city or region.

When the air pollution abatement device 100 is continuously constructed in such a manner that the air pollution abatement device 100 is formed differently from each other, multiple bubble (B) protective walls can be formed in the air when the bubble B is generated and injected. The bubble (B) protection wall thus formed can efficiently remove air pollutants (D) that float along the atmosphere and exist in the atmosphere as well as at the generation site.

The plurality of air pollution control apparatuses 100 may be configured to be linked with a management server or a management center (not shown), and may be implemented as a system that can individually or wholly control according to a pollution situation.

The bubble B is a temporary film formed of a liquid material, and even if it collides with a moving body (airplane, helicopter, algae) moving in the atmosphere, its volume and weight are insignificant and do not cause damage. Also, even if the bubble B has been kept for a long time and descends to the ground, it has stability that does not damage the vehicle, the human body, the plant, and the animal due to the above-mentioned reason.

According to the air pollution abatement apparatus 100 as described above, air pollutants D generated and transmitted from China are more subjectively and actively reduced, which will greatly help to maintain the health and external activities of the people stably. National support for device development and introduction is needed.

The air pollution abatement apparatus using the bubbles as described above is not limited to the configuration and the manner of operation of the embodiments described above. The above embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications can be made.

100: air pollution abatement device 160: bubble ejection unit
110: main body unit 170: control unit
120: Bubble liquid storage unit D: Air pollutant
130: Bubble generating unit B: Bubble
140: gas supply unit W: bubble liquid
150: Temperature control unit C: Coating liquid

Claims (8)

A main body unit formed to be installed in a target area and having an inner space;
A bubble liquid storage unit installed in the main body unit and storing bubble liquid;
A bubble generating unit for converting the bubble liquid into bubbles;
A bubble ejection unit installed to extend from the main body unit and configured to eject the generated bubble in a waiting direction; And
And a control unit for controlling the driving of the bubble generating unit according to the input information.
The method according to claim 1,
Wherein the bubble generating unit comprises:
A bubble screen configured to spread the bubble liquid delivered from the bubble liquid storage unit in a predetermined shape and store the air, And
And an air blower for blowing air toward the bubble screen.
3. The method of claim 2,
Wherein the blower comprises:
A first blower for generating a first bubble; And
And a second blower for generating a second bubble to be inserted into the first bubble.
The method according to claim 1,
The bubble ejection unit includes:
And a coating liquid sprayer for spraying the coating liquid so that the coating liquid flows along the inner wall surface.
The method according to claim 1,
And a temperature control unit configured to control the temperature of the bubble.
The method according to claim 1,
And a gas supply unit for supplying a floating gas to the bubble generating unit,
Wherein the bubble generating unit comprises:
And the blowing gas is blown to generate the bubble.
The method according to claim 1,
In the bubble liquid,
Wherein at least one of water, a thickener, and a surface active agent is used.
The method according to claim 1,
In the bubble liquid,
Sodium lauryl amphoacetate, sodium trideceth sulfate, hydroxyethyl cellulose, taxolone, PAV pulp, starch, starch, sugar, starch syrup, honey, glycerin, sodium lauroamphoacetate, sodium trideceth sulfate, (Polyvinyl alcohol). ≪ / RTI >

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