The present invention relates a device which cleans the air and which comprises a microbubble generator.

Today, the need for ventilation and the need for fresh air becomes more important in environments such as homes and offices especially in high-rise buildings. Plants can be a temporary solution for daytime but when the sunlight disappears, plants also start to produce carbon dioxide like human beings and the air quality of the environment decreases. Especially in high-rise buildings, it is not always possible to continuously keep the windows open and ventilate the environment. The continuously rising carbon dioxide amount in the air adversely affects human health. The amount of oxygen in a closed environment directly affects the metabolic rate of people and the lack thereof creates weakness and fatigue in humans. Ensuring that the amount of oxygen in the closed environment does not fall below a certain level while reducing the amount of carbon dioxide generated in the environment makes the human metabolism much more vivid and vigorous.

In the state of the art Korean Patent Document No. KR100377020B1, a microbubble generator is disclosed, which is used in water treatment systems. However, it is not stated in the document that said microbubble generator is related to an air purifier.

The aim of the present invention is the realization of an air purifier with increased carbon dioxide adsorption capacity.

The air purifier of the present invention comprises an air inlet and a clean air outlet which are provided on the body. The air purifier further comprises a base supply unit and an acid supply unit. In the air purifier, the air taken through the air inlet by means of a fan is delivered to the CO2 adsorption unit together with the basic liquid solution by means of a pump via microbubble generator.

In the CO2 adsorption unit, a carbonation reaction occurs between the basic liquid solution and the carbon dioxide (air) passing through the solution. In order to increase the efficiency of the reaction, the air passed through the liquid solution must have a high number of small bubbles. For a carbon dioxide adsorption process at maximum efficiency, it is required that the basic solution and air contact each other for as long as possible, and the bubbles formed by this contact are small. Therefore, it is possible to increase the reaction surface area in the CO2 adsorption unit by decreasing the diameter of the air bubbles pumped into the basic liquid solution while increasing the number thereof. By means of the microbubble generator provided in the air purifier of the present invention, a high number of bubbles at micro scale are generated such that the basis liquid solution and the carbon dioxide contact each other for a longer time and the reaction speed is increased.

By means of the present invention, an air purifier is realized, wherein a higher amount of carbon dioxide is adsorbed to clean the closed environment air by increasing the contact surface area between the carbon dioxide in the closed environment air and the basic liquid solution and thus increasing the efficiency of the reaction.

The model embodiments that relate to the air purifier realized in order to attain the aim of the present invention are illustrated in the attached figures, where:

Figure 1 - is the perspective view of the air purifier in an embodiment of the present invention.

Figure 2 - is the perspective view of the CO2 adsorption unit and the plurality of microbubble generators in the air purifier in an embodiment of the present invention.

Figure 3 - is the view of the CO2 adsorption unit and the flow separators in the air purifier in an embodiment of the present invention.

Figure 4 - is the perspective view of the plurality of microbubble generators, the air delivery and liquid delivery pipes in the air purifier in an embodiment of the present invention.

Figure 5 - is the detailed view of the air and liquid delivery pipes in the air purifier in an embodiment of the present invention.

Figure 6 - is the top view of the flow in the air and liquid delivery pipes in the air purifier in an embodiment of the present invention. Figure 7 - is the perspective view of the microbubble generator in the air purifier in an embodiment of the present invention.

Figure 8 - is the front view of the cross section A-A of the microbubble generator in Figure 7.

Figure 9 - is the view showing the widths and lengths in the microbubble generator in the cross section in Figure 8.

The elements illustrated in the figures are numbered as follows:

1. Air purifier

2. Body

3. CO2 adsorption unit

4. Microbubble generator

5. Air inlet port

6. Liquid inlet port

7. Duct

8. Channel

9. Outlet tube

10. Air delivery tube

11. Liquid delivery tube

12. Nozzle

13. Flow separator

14. Connection member

I: Air inlet

O: Clean air outlet

D 1 : Channel width D3 : Outlet tube width

D4: Outlet tube length

The air purifier (1) comprises a body (2) having an air inlet (I) through which the air in the environment is sucked and a clean air outlet (O) through which the cleaned air is released, and a CO2 adsorption unit (3) which is provided on the body (2), which chemically adsorbs the carbon dioxide in the air taken into the body (2) by being supplied with air together with a basic solution.

The air purifier (1) of the present invention comprises at least one microbubble generator (4) having

- an air inlet port (5) which provides the delivery of the air sucked into the body (2) to the CO2 adsorption unit (3),

- a liquid inlet port (6) which provides the delivery of the basic liquid solution to the CO2 adsorption unit (3),

- a duct (7) where the air and the basic liquid solution are mixed,

- a channel (8) which delivers the air from the air inlet port (5) to the duct (7) such that the basic liquid solution and the air are mixed, and

- an outlet tube (9) through which the air-basic liquid solution mixture is taken into the CO2 adsorption unit (3).

The air purifier ( 1) of the present invention comprises at least one microbubble generator (4) which enables the basic liquid solution and the air the in the environment to be mixed so as to be delivered to the CO2 adsorption unit (3). By means of an air inlet port (5) and a liquid inlet port (6) provided on the microbubble generator (4), the air and the basic solution enter the microbubble generator (4) through separate lines. The channel (8) which delivers the air is arranged at the air inlet port (5). The microbubble generator (4) further comprises a duct (7). Said duct (7) has a width narrower than the width of the liquid inlet port (6), and the air flowing through the channel (8) and the basic solution taken through the liquid inlet port (6) meet first time at the duct (7) and get mixed. Thus, microbubbles are formed in the liquid-air mixture due to pressure, and the resulting mixture is transferred to the CO2 adsorption unit (3) through the outlet tube (9). The microbubbles forming in the mixture increase the efficiency of the reaction occurring between the basic solution and the carbon dioxide in the air, thus ensuring that a higher amount of carbon dioxide is converted to carbonate so as to clean the air.

In an embodiment of the present invention, in the microbubble generator (4), the width (D2) of the duct (7) is three to five times the width (DI) of the channel (8). Thus, the microbubbles generated in the microbubble generator (4) have the optimum dimensions for improved reaction efficiency.

In an embodiment of the present invention, in the microbubble generator (4), the width (D3) of the outlet tube (9) is 10 to 15 times the width (DI) of the channel (8). Thus, the microbubbles generated in the microbubble generator (4) have the optimum dimensions for improved reaction efficiency.

In an embodiment of the present invention, in the microbubble generator (4), the length (D4) of the outlet tube (9) is 40 to 50 times the width (DI) of the channel (8). Thus, the basic solution-air mixture formed in the microbubble generator (+) can be efficiently delivered to the CO2 adsorption unit (3) by maintaining the bubbles.

In an embodiment of the present invention, the air purifier (1) comprises at least one air delivery tube (10) having at least one nozzle (12) which can be connected to the air inlet port (5) at the microbubble generator (4). Thus, the air sucked into the body (2) is transferred to the microbubble generator (4).

In an embodiment of the present invention, the air purifier (1) comprises a connection member (14) which connects at least two air delivery tubes (10). Thus, a plurality of microbubble generators (4) can be connected to a plurality of air delivery tubes (10) respectively. Moreover, the volume of air cleaned in unit time in the air purifier (1) is increased.

In an embodiment of the present invention, the air purifier (1) comprises at least one liquid delivery tube (11) which can be connected to the liquid inlet port (6) at the microbubble generator (4). By means of the liquid delivery tube (11), a plurality of microbubble generators (4) can be connected side by side in series. In an embodiment of the present invention, the air purifier (1) comprises at least one flow separator (13) which regulates the flow of the air-basic liquid solution mixture in the CO2 adsorption unit (3). Thus, the liquid-air mixture with bubbles coming from the microbubble generator (4) is prevented from further mixing in the CO2 adsorption unit (3) such that the size of bubbles is prevented from increasing.

By means of the present invention, an air purifier (1) is realized, with increased carbon dioxide adsorption capacity and rate.