KR102618636B1 - Photocatalytic-based photo fusion air purifier - Google Patents

Abstract

The present invention relates to a photocatalyst-based light fusion air purifier, in which additional photocatalyst modules, UV sterilization modules, and photoplasma modules can be attached and detached from a single body, and each module can be combined and exchanged according to function, thereby providing photolysis and light fusion technology. By performing air purification and sterilization, photolysis and sterilization according to the standards, it is designed to remove fine dust, sterilize and decompose viruses, and decompose harmful substances without replacing filters to provide clean air.
The present invention is provided with an outer case (2) and an inner case (3) coated and applied with a photocatalyst within one body (1), and a module guide portion is provided on the inside of the outer case (2) and the outside of the inner case (3), respectively. (4) and the module fixing protrusion (5) are formed to form the photocatalyst module (6), UV sterilization module (7), photoplasma module (8), and ozone sterilization module (13) in the main body (1). The position is determined by the part (4) and the module fixing protrusion (5) and is configured to be detachable, and the photocatalyst module (6), UV sterilization module (7), photoplasma module (8), and ozone sterilization module ( 13) is electrically controlled by the controller 9 installed in the inner case 3. If the case is made of organic material, inorganic material is first applied and secondarily the photocatalyst (Tio2) is coated and applied, The photocatalyst module (6), UV sterilization module (7), and photoplasma module (8) are installed facing each other in a single row, and the main body (1) is structured so that they face each other in various plural arrangements such as two or three rows. It can be modified and applied.

Description

Photocatalytic-based photo fusion air purifier {Photocatalytic-based photo fusion air purifier}

The present invention relates to a photocatalyst-based photofusion air purifier. In particular, the photocatalyst module, UV sterilization module, photoplasma module, and ozone sterilization module are detachably mounted on a single body to purify, sterilize, and decompose air according to photolysis photofusion technology. and sterilization are performed in combination to remove fine dust, sterilize and decompose viruses in the air, and efficiently decompose harmful substances without changing filters to provide clean air.

In general, air purifiers remove pollutants from air containing fine dust, various harmful gases, germs, mold, viruses, etc. through a purifying medium and emit clean air.

The global market size of air purifiers is expected to increase from USD 9.2 billion in 2020 at an average annual growth rate of 8.2%, reaching USD 13.6 billion in 2025, and the domestic market size is expected to increase from KRW 413.3 billion in 2014 to KRW 1,156.5 billion in 2019. It showed a high increase of 22.9%, and assuming the same growth rate, it is expected to reach KRW 2.8969 trillion in 2023.

Air purifiers have a variety of functions, including air purification, odor removal, removal of small particles such as mites, pollen, and pet hair, and prevention of diseases caused by air infections. Recently, as problems caused by fine dust have become a major issue, air purifiers have become increasingly popular. Its importance is growing further.

In addition, conventional air purifiers use a filter method or an electrostatic dust collection method. The filter method has an excellent purification ability to remove fine dust, but the sterilization is insufficient and the filter must be replaced, so maintenance costs are high, and the electrostatic dust collection method is used. This method has excellent sterilization and odor removal functions, but it generates by-products and residual ozone, which can cause damage to the human body when used for a long time, and when dust accumulates on the electric dust collection plate, the purification and dust removal abilities are reduced.

However, conventional air purifiers as described above are mainly limited to air purification, filter adsorption, and filter combination technology, and have the drawback of photocatalyst progressing in only one direction. They do not have multiple functions within a single body, so they provide efficient air quality. There is a drawback in that purification cannot be performed.

Patent Application No. 10-2018-0007907 Patent Application No. 10-2006-0121468

The present invention is intended to solve the above-described conventional shortcomings. The purpose of the present invention is to apply a photocatalyst to the inner wall of a main body case to achieve photocatalyst-based air purification according to air flow, and to achieve photocatalyst-based air purification in the main body. The module, UV sterilization module, photoplasma module, and ozone sterilization module are detachably installed and controlled through a controller to remove fine dust through photocatalyst, sterilize viruses in the air through UVC, and clean the air through photoplasma and ozone generation. The goal is to provide a photocatalyst-based light fusion air purifier that can efficiently sterilize the air.

The present invention to achieve this purpose is characterized by being constructed in a single body to purify and sterilize fine dust, heavy metals, microplastics, viruses, etc. through photocatalyst, UVC, photoplasma, and ozone sterilization.

The present invention relates to a typical air purifier, which has an outer case and an inner case in one main body, and a module guide portion and a module fixing protrusion are formed on the inside of the outer case and the outside of the inner case, respectively, to form a photocatalyst module and a UV sterilization module. In addition, the photoplasma module and the ozone sterilization module are configured to be detachable at designated positions by the module guide portion and the module fixing protrusion formed in the main body, and the photocatalyst module, UV sterilization module, photoplasma module, and ozone sterilization module are attached to the inner case. It is characterized by being electrically controlled by a controller installed within it.

The present invention is characterized in that when coating and applying a photocatalyst to the inside of a case, if the case is an organic material, an inorganic material is first coated and a photocatalyst is secondarily coated and applied.

The present invention is characterized in that the position of each module is determined through guide portions and protrusions formed on the inner wall of the inner case and outer case of the main body, so that the module can be easily mounted.

The present invention is characterized in that terminals are installed in the main body and terminals are also installed in the modules, so that when each module is mounted in the main body, electrical contact is made automatically and each module is electrically controlled by a controller installed in the center of the main body. .

The present invention is characterized by mounting each module in a main body facing each other in a row, as well as mounting them in various forms such as a double layer while facing each other in two or three rows.

The present invention, as explained in detail above, is to install the photocatalyst module, UV sterilization module, and photoplasma module in a detachable order in a certain compartment within one main body, and to control the photocatalyst-based photofusion through a controller. It removes dust, sterilizes viruses in the air through a UV sterilization module, sterilizes the air through a photo plasma module, and additionally purifies the air by generating ozone through an ozone sterilization module. All functions are mounted on a single body to perform complex functions. And, if necessary, each module can be replaced to achieve continuous, efficient air purification.

In addition, when the case is made of an organic material, the present invention has the effect of preventing the photocatalyst light source from affecting the case by first coating the inorganic material and secondarily coating and applying the photocatalyst.

Figure 1 is a diagram showing the module of the hybrid light-fusion air purifier sterilizer of the present invention.
Figure 2 is a diagram showing the state in which the photocatalyst module, UV sterilization module, and photoplasma module are installed in the hybrid light-fusion air purifier sterilizer of the present invention.
Figure 3 is a diagram showing a photocatalyst module according to the present invention.
Figure 4 is a diagram showing the actual photocatalyst module of Figure 3
Figure 5 is a diagram showing the photoplasma module of the present invention
Figure 6 is a block diagram showing the electrical control relationship between each module by the controller of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a diagram showing the module of the hybrid optical fusion air cleaner and sterilizer of the present invention. The air cleaner and sterilizer main body (1) of the present invention consists of an outer case (2) and an inner case (3), and the outer case (2) A module guide part (4) and a module fixing protrusion (5) are formed on the inside and outside of the inner case (3), respectively, so that each module can be easily positioned within the main body (1) and the module guide part (4) and module fixing protrusion are formed. It is configured to be fixed by (5), and is configured as a multi-channel type in which air flows in and out in one direction or in multiple directions. The air movement direction of the main body (1) is unidirectional or in the form of multiple flow paths. The wall of the case is coated with a photocatalyst. If the case is an organic material, the inorganic material is first coated, and the photocatalyst is secondarily coated and applied so that the photocatalyst does not affect the plastic case.

However, the fan that introduces air into the main body (1) can be located on the side, top, or inside of the main body (1) as needed.

Figure 2 is a diagram showing the state in which the photocatalyst module, UV sterilization module, and photoplasma module are mounted in the hybrid optical fusion air purifier sterilizer of the present invention. The plasma module 8 is installed to be detachable, and a controller 9 is installed inside the inner case 3 to electrically contact each module to perform control. The light source of the photocatalyst module 6 is , is composed of LEDs of UV-A wavelength, and the light source of the UV sterilization module 7 is composed of LEDs of UV-C wavelength, which is the deep ultraviolet ray wavelength, and the light source of the photoplasma module 8 is VUV (vacuum ultraviolet rays). ) It is composed of LEDs.

In particular, the photoplasma module (8) has a foam-molded porous filter (10) formed on the inlet and outlet sides, so that when air enters, the air passes through the porous filter (10) and is split and decomposed at the same time.

In addition, the photoplasma module (8) uses the photoplasma air purification principle, which is a photoreaction technology created based on the reaction principle of sunlight, to induce photoionization and photochemical reactions with vacuum ultraviolet rays of powerful and short light wavelength, and primary and secondary . By purifying the air three times, bacteria, viruses, mold, volatile organic compounds, etc. can be efficiently removed.

However, when the photocatalyst module (6), UV sterilization module (7), and photoplasma module (8) are inserted into the main body (1), they are automatically connected to the electrical terminals installed in the outer case (2) and inner case (3). It can be controlled by the controller (9), and the connection terminal pulled out from each module can also be used by connecting to the terminal of the controller (9).

Figures 3 and 4 show the photocatalyst module 6 according to the present invention, which is formed of a porous filter 10 and an LED module 11 is installed on the upper surface, and is primarily coated with an inorganic material, and 2 Second a photocatalyst (eg Tio2) is coated and applied.

However, in the case of the UV sterilization module 7, it has the same configuration as the photocatalyst module 6 of FIG. 3, but only the wavelength is different, so the drawing for this is omitted.

Figure 5 shows the photoplasma module (8) of the present invention. The plasma lamp (12) is installed vertically in the center of the upper surface of the photoplasma module (8), and a foam-molded porous filter (10) is installed at the inlet and outlet sides. It is composed.

Figure 6 is a block diagram showing the control relationship of each module by the controller of the present invention. The controller (9) is configured to electrically control the photocatalyst module (6), UV sterilization module (7), and photoplasma module (8). , it can be configured by adding an additional ozone sterilization module (13), or can be configured with only the photocatalyst module (6) and UV sterilization module (7), and can be configured by adding or limiting additional modules as needed.

The operation of the present invention configured as described above will be explained.

The present invention is a means for air purification and includes a main body (1) as shown in Figures 1 and 2, and the main body (1) consists of an outer case (2) and an inner case (3). The outer case (2) and the inner case (3) are installed at regular intervals.

That is, on the inner wall of the outer case (2), a plurality of module guide parts (4) for inserting and fixing the module are formed at regular intervals, and the inner case (3) has projections (5) for fixing the module at regular intervals. Since a plurality of modules are formed, each module is mounted at a certain position by the module guide portion (4) and the module fixing protrusion (5).

Here, a module for removing and sterilizing fine dust in the air is detachably mounted on the main body 1. First, a photocatalyst module 6 for removing fine dust is mounted on one side, and the photocatalyst module 6 ) is mounted on one side of the UV sterilization module (7), which generates UV (ultraviolet rays) to sterilize viruses in the air, and on one side of the UV sterilization module (7) is a photoplasma module that generates photoplasma. (8) is installed.

Here, although not shown in the drawing, an ozone sterilization module (13) that generates ozone can be additionally installed on one side of the photo plasma module (8), and the controller (9) installed inside the inner case (3) Each module can be controlled electrically through .

In addition, the photocatalyst module (6), UV sterilization module (7), and photoplasma module (8) are installed facing each other in only one row in the drawing, but the main body has a structure in which they face each other in various plural arrangements such as two or three rows. (1) The structure can also be modified and applied.

The photocatalyst module 6 can be coated with a solution mixed with titanium oxide (TiO2) powder to activate oxidation/reduction reactions in ultraviolet rays and visible light.

However, the UV sterilization module 7 can selectively use UV-C and UV-A, and since UV-C is expensive, sufficient sterilization can be performed even by using low-cost UV-A.

When the photocatalyst module (6), UV sterilization module (7), and photoplasma module (8) are inserted into the space between the outer case (2) and the inner case (3) in the main body (1), these modules are inserted into the outer case ( Each position is determined by the module guide part (4) formed in 2) and the module fixing protrusion (5) formed in the inner case (3), so that it does not move and remains fixed, and the cover is placed on the main body (1) to form an external shape. It can be configured to look good.

And, as shown in FIG. 4, the photoplasma module 8 has a VUV (vacuum ultraviolet) lamp 12 installed in the center, and porous filters 10 in the form of foam molding are installed at the inlet and outlet, so that the incoming air It is set to split and disintegrate when hit.

On the other hand, when it is necessary to replace the module due to malfunction or malfunction of the module, if you pull the module mounted on the main body (1), the module can easily come off from the module guide part (4) and the module fixing protrusion (5) and be replaced by another module. It can be used interchangeably.

As described above, the present invention shows an embodiment in which the photocatalyst module 6, UV sterilization module 7, and photoplasma module 8 are sequentially mounted in the main body 1, but the present invention is limited to the above embodiment. However, through various modifications in the technical field to which the present invention belongs, two photocatalyst modules (6) and one UV sterilization module (7) are used, or only the photocatalyst module (6) and the photoplasma module (8) are used. Of course, it can be usefully applied and used by configuring it or modifying it in various ways according to various variables.

1: Main body 2: External case
3: Inner case 4: Module guide part
5: Projection for fixing module 6: Photocatalyst module
7: UV sterilization module 8: Photo plasma module
9: Controller 10: Porous filter
11: LED module 12: Plasma lamp
13:Ozone sterilization module

Claims (7)

In a typical air purifier,
In one main body, an external case and a cassette-type internal case are provided so that the air flow through the fan has a multi-directional flow path,
A plurality of module guide parts and module fixing protrusions are formed on the inside and inner case of the outer case, so that the photocatalyst module, UV sterilization module, photo plasma module, and ozone sterilization module are formed in the main body by the module guide part and module fixing protrusion. It is fixed to form an air flow path and is designed to be detachable.
A photocatalyst-based light fusion air purifier characterized in that the photocatalyst module, UV sterilization module, photoplasma module, and ozone sterilization module are electrically controlled by a controller installed in the inner case to perform air purification and sterilization to remove fine dust. . delete delete delete delete delete delete