KR20050099726A - Air purification appliance - Google Patents

Abstract

The present invention improves the air sterilizer of No. 323011 registered by the applicant of the utility model registration application, and more particularly relates to an air sterilizer is provided with a brush bush on the photocatalyst member to significantly improve the photocatalytic activity efficiency.

Description

Air sterilizer

The present invention improves the air sterilizer of No. 323011 registered by the applicant of the utility model registration application, and more particularly relates to an air sterilizer is provided with a brush bush on the photocatalyst member to significantly improve the photocatalytic activity efficiency.

In the air sterilizer of Japanese Patent No. 323011, deodorization is performed by activating the photocatalyst of the photocatalyst member by receiving light of black light.

By the way, the stagnation wall in the photocatalyst member cannot sufficiently hold the air, and thus the light activation efficiency is lowered and the deodorization efficiency is also lowered.

On the other hand, formaldehyde, called sick house syndrome, is a harmful gas causing various cancers and atopic dermatitis. In order to decompose and remove this formaldehyde, photocatalytic activation must be continuously performed.

However, in the above-described air sterilizer, there is no structure in which the sucked air can stay sufficiently inside the case, and there is a problem in that formaldehyde removal efficiency is significantly lowered.

The present invention has been made in order to solve the above problems, and an object thereof is to provide an air sterilizer capable of maximizing deodorization efficiency by giving sufficient time to activate photocatalyst of air.

Another aspect of the present invention is to provide an air sterilizer capable of removing formaldehyde gas in a sick house syndrome.

Air sterilizer of the present invention for achieving the above object is an air inlet and the air outlet is formed; A fan disposed at at least one of the air intake port and the air discharge port; A photocatalyst member installed in the case; Black light for irradiating ultraviolet rays to the photocatalyst member; It comprises a brush bush disposed on the photocatalyst member.

According to this structure, the brush bush can give sufficient time to activate photocatalyst of air, and can maximize deodorization efficiency.

In the above-described configuration, when titanium dioxide (TiO ₂ ) is coated on the brush bush, the surface area of the photocatalyst may be increased to further maximize the deodorization efficiency.

If the air flow retardation piece is further installed on the photocatalyst member to delay the flow of sucked air, the photocatalytic activation efficiency can be further increased.

When the photocatalyst member has a structure in which air is introduced into a narrow space and diffused into a wide space, the flow of air can be delayed.

On the other hand, it is preferable that the formaldehyde removal member is further installed in the case. The formaldehyde removal member may be implemented as a plurality of ceramic balls containing titanium dioxide (TiO ₂ ), the accommodating part accommodates the ceramic balls, and has an air inlet and an air outlet.

The air outlet may be disposed such that the area of the air outlet is wider and wider as the air introduced into the air inlet passes through the ceramic ball. Thus, the introduced air may be sufficiently adhered to the ceramic ball.

On the other hand, when the ultraviolet sterilization lamp is further installed, it can sterilize the air bacteria.

BEST MODE Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view illustrating an air sterilizer separated according to a preferred embodiment of the present invention, FIG. 2 is a perspective view illustrating the inside of the photocatalyst member and the formaldehyde removing member in FIG. 1, and FIG. 3 is a photocatalyst member of FIG. 2. It is an enlarged perspective view.

1 to 3, the air sterilizer of this embodiment is composed of a case forming an appearance, a photocatalyst member 30 embedded in the case, and a black light 40 for activating the photocatalyst member 30. .

The case is largely composed of a mounting case 10a and a cover (not shown). Air inlets 11 and air outlets 13 are formed at both ends of the mounting case 10a. The air suction port 11 or / and the air discharge port 13 is preferably provided with a suction fan 50a or / and a discharge fan 50b in order to increase the flow efficiency of air. In addition, it is preferable that a filter 55 is provided between the air suction port 11 and the suction fan 50a. In other words, it is to increase the purification effect of the air by filtering in advance fine particles such as dust.

The photocatalyst member 30 is preferably composed of a copper plate coated with titanium dioxide (TiO ₂ ). The copper plate is fixed to the mounting case 10a by screws or the like.

Black light 40 is a UV-A lamp having a wavelength of 320nm to 400nm, preferably 380nm (titanium dioxide activation is most active at this wavelength), between the air inlet 11 and the air outlet 13, More preferably, it is disposed to correspond to the photocatalyst member 30. When the ultraviolet light of the black light 40 is irradiated to the photocatalyst member 30, the odor in the air is decomposed and extinguished by the oxidation of the photocatalyst.

In order to double this deodorization efficiency, it is preferable that the brush bush 20 is provided in the photocatalyst member 30, as shown in FIG. The brush bush 20 causes the air passing through to cause the vortex phenomenon in the photocatalyst member 30. This vortex phenomenon gives a sufficient time for photoactivation of air, and the oxidation of the photocatalyst can be continuously performed. Therefore, the decomposition power of the odor can be significantly increased, and the deodorization efficiency can be maximized. The brush bush 20 can be implemented in iron or plastic material.

In addition, the brush bush 20 is preferably coated with titanium dioxide. This is because there is an effect of increasing the surface area of the photocatalyst and the deodorizing power can be further increased.

Furthermore, the photocatalyst member 30 is preferably further provided with an air flow retardation piece 30a for delaying the flow of sucked air. Air flow retardation piece (30a) of this embodiment is made of S-shape, it is possible to delay the flow of air. In addition, the air flow retardation piece 30a functions as a partition of the photocatalyst member 30, and the brush bush 20 may be built in the compartment. One end of the air flow retardation piece 30a is provided with a wing piece 30b for guiding air to the brush bush 20 smoothly.

In this way, the deodorizing power is given to a sufficient time for photoactivation, such as the delay of air flow by the photocatalyst coated brush bush 20 and the air flow retardation piece 30a, the increase of the surface area of the photocatalyst, and the increase of the photocatalytic decomposition force in the vortex phenomenon. This can significantly improve. Of course, the air flow retardation piece 30a is also preferably implemented by a copper plate coated with titanium dioxide.

In addition, as a structure for delaying the flow of air, it may be implemented by the through hole 33 of the photocatalyst member 30. That is, air flows into the through hole 33 of the photocatalyst member 30 by the wing piece 30b. At this time, the through hole 33 is narrower than the space where the brush bush 20 is disposed. Therefore, since air flows from a narrow space to a wide space, it causes a delay due to diffusion, thereby giving sufficient photocatalytic activation time.

On the other hand, it is preferable that a formaldehyde gas removing member 60, which is called a sick house syndrome, is further installed. As shown in FIG. 4, the formaldehyde gas removing member 60 includes a porous ceramic ball 61 containing titanium dioxide (TiO ₂ ) and a receiving portion 63 accommodating the ceramic ball 61. It is preferred to be configured.

This ceramic ball 61 is porous and has a strong adsorption force. Therefore, the air sucked into the accommodating part 63 is adsorbed to the ceramic ball 61, and continuously removes formaldehyde harmful substances by the photocatalyst of titanium dioxide in the adsorbed state, thereby greatly increasing the removal efficiency. . In addition, it functions to continuously decompose and remove moisture and harmful substances adsorbed on the ceramic by heat and light emitted from the ultraviolet lamp. On the other hand, by containing a small amount of natural anions in the ceramic ball 61 can improve the quality of the air.

The accommodating part 63 is box-shaped containing many ceramic balls 61, The air inlet 63a and the air outlet 63b are perforated. Air inlet (63a) is preferably disposed in close contact with the suction fan (50a) in more detail. This is to increase the disinfection efficiency by introducing the air sucked through the suction fan 50a into the accommodation portion 63. At this time, it is preferable that the receiving portion 63 on the side of the air inlet 63a has no ceramic balls 61 or a space portion 64 filled slightly. The space 64 forms a gap between the air inlet 63a and the ceramic ball 61 to induce smooth inflow of air.

On the other hand, as shown in Figure 5, the air outlet port 63b of the receiving portion 63 is preferably arranged so that the area is gradually wider toward the arrow direction on the air inlet (63a) side. This is to allow the introduced air to remain in the ceramic ball 63 sufficiently to adhere.

On the other hand, it is preferable that the ultraviolet sterilization lamp 90 which is a UV-C lamp is further installed in the mounting case 10a. That is, by sterilizing and erasing the bacteria in the air by the ultraviolet sterilization lamp 90 having a wavelength of 100nm to 300nm, preferably 280nm, it is possible to double the deodorizing effect and the sterilizing effect according to the photocatalyst activation.

The controller 70 controls the black light 40, the ultraviolet sterilization lamp 90, and the fans 50a and 50b to be driven.

Hereinafter, the operation according to the configuration of the present embodiment will be described.

First, when the switch knob is turned ON, the control unit 70 controls the black light 40, the ultraviolet sterilization lamp 90, and the fans 50a and 50b to drive and control the black light 40 and the ultraviolet sterilization lamp. Lights up, and the fans 50a and 50b are driven.

The suction fan 50a sucks air, and once the fine particles are filtered by the filter 55, the suction fan 50a sucks the air. The sucked air is introduced into the ceramic ball 61 through the air inlet 63a and the space 64. This inflow air is adsorbed to the ceramic ball 61, and decomposes and removes formaldehyde gas in the air by a photocatalyst. The air from which the formaldehyde gas is removed is discharged to the air outlet 63b. The discharged air passes around the ultraviolet sterilization lamp 90 to kill and eliminate bacteria in the air. This sterilized air flows into the through hole 33 of the photocatalyst member 30.

The air introduced into the photocatalyst member 30 doubles the photocatalytic activity efficiency to the photocatalyst brush bush 20 and the air flow retardation piece 30a. That is, the air flow retardation piece 30a delays the flow of air in a curved form. The brush bush 20 increases the surface of the photocatalyst and causes vortex to increase the resolution of the photocatalyst. This creates a gentle flow of air and gives sufficient time to activate the photocatalyst, so that the decomposition and removal ability of the odor, that is, the deodorizing power, is very excellent.

As such, the sterilized and deodorized air is forcibly discharged to the air discharge port 13 by the fan 50b.

As described above, since the air sterilizer of the present embodiment does not remove sterilization, deodorization, and formaldehyde gas by the filter, the air sterilizer is very excellent in terms of handling and cost due to filter replacement.

Air sterilizer according to an embodiment of the present invention is not limited to the above-described embodiment can be carried out in a variety of modifications within the range allowed by the technical idea of the present invention.

As apparent from the above description, the air sterilizer of the present invention has the following effects.

First, the brush bush is installed in the photocatalyst member, so that the flowing air vortex inside the photocatalyst member, and a sufficient time for photoactivation is continuously formed, thereby increasing the resolution of the photocatalyst to significantly increase the deodorization efficiency.

Second, since titanium dioxide (TiO ₂ ) is coated on the brush bush, the deodorization efficiency may be further increased due to an increase in the surface area of the photocatalyst due to sufficient photoactivation.

Third, if the air flow retardation piece is further installed on the photocatalyst member to delay the flow of sucked air, the air flow may be further delayed to further increase the odor decomposition ability by the oxidation of the photocatalyst.

Fourth, the photocatalyst member has a structure in which air flows into a narrow space and diffuses into a wide space, thereby delaying the flow of air.

Fifth, the formaldehyde removal member for removing the formaldehyde gas is further provided, it is possible to prevent the sick house syndrome after death.

Sixth, the formaldehyde removing member is composed of a porous ceramic ball containing titanium dioxide (TiO ₂ ), and the housing containing the ceramic ball, the air inlet and the air outlet is formed, the ceramic ball only without replacing the filter It can be used at low cost because it is cleaned.

Seventh, the air outlet is formed such that the area is gradually wider as the air flowing into the air inlet passes through the ceramic ball, the air is discharged sufficiently adhered to the ceramic ball, it is possible to increase the formaldehyde removal efficiency. .

Eighth, the ultraviolet sterilization lamp is further installed, it is possible to sterilize the air bacteria.

1 is a perspective view showing the separation of the air sterilizer according to a preferred embodiment of the present invention.

Figure 2 is a perspective view showing the inside of the photocatalyst member and formaldehyde removal member in Figure 1;

3 is an enlarged perspective view of the photocatalyst member of FIG. 2;

4 is an enlarged perspective view of the formaldehyde removing member of FIG.

Figure 5 is a side view showing the receiving portion of the formaldehyde removing member according to another embodiment.

<Description of the symbols for the main parts of the drawings>

10a: mounting case 11: air intake

13: air outlet 20: brush bush

30: photocatalyst member 30a: air flow delay

30b: wing piece 33: through hole

40: black light 50a: suction fan

50b: discharge fan 60: formaldehyde gas removing member

61: ceramic ball 63: accommodating part

63a: air inlet 63b: air outlet

70: control unit 90: UV sterilization lamp

Claims (8)

A case in which an air inlet and an air outlet are formed; A fan disposed at at least one of the air intake port and the air discharge port; A photocatalyst member installed in the case; Black light for irradiating ultraviolet rays to the photocatalyst member; A brush bush disposed on the photocatalyst member; Air sterilizer made, including. The air sterilizer of claim 1, wherein the brush bush is coated with titanium dioxide (TiO ₂ ). 3. An air sterilizer according to claim 2, wherein an air flow retardation piece for retarding the flow of sucked air is further installed in the photocatalyst member. 4. The air sterilizer of claim 3, wherein the photocatalyst member has a structure in which air is introduced into a narrow space and diffused into a wide space. The air sterilizer according to claim 1, wherein a formaldehyde removing member is further installed in the case. The method of claim 5, wherein the formaldehyde removing member Porous ceramic ball containing titanium dioxide (TiO ₂ ), An air sterilizer for accommodating the ceramic ball and comprising an air inlet and an air outlet. 7. The air sterilizer of claim 6, wherein the air outlet is disposed such that its area is gradually distributed as the air flowing into the air inlet passes through the ceramic ball. The air sterilizer according to claim 5, further comprising an ultraviolet sterilization lamp.