KR20090012284A - Apparatus for decomposing harmful substance - Google Patents

Abstract

Disclosed is a method for decomposing harmful substances wherein a supporting member such as a ceramic filter to which a photocatalyst such as titanium oxide is applied is used in combination with a light source which generates light for inducing a photocatalytic reaction. For efficiently utilizing the light emitted from the light source for the photocatalytic reaction in the photocatalyst layer, two pieces of members such as ceramic filters supporting the photocatalyst are arranged opposite to each other and the light source is placed between the two members for irradiating the photocatalyst with light. A harmful substance is introduced to the surface of the photocatalyst which has attained a power for decomposing the harmful substance through the irradiation of light.

Description

Apparatus for decomposing harmful substance

The present invention relates to a technique for collecting and purifying harmful gases such as odors, and more particularly, to a technique for collecting and purifying harmful gases using a photocatalyst.

When light having energy above the band gap of the photocatalyst is irradiated to the photocatalyst represented by titanium oxide or the like, holes and electrons are generated inside the photocatalyst. The holes and electrons diffuse to the surface of the photocatalyst and react with a material adsorbed on the photocatalyst surface or a material present near the photocatalyst surface. Many air purifiers using such photocatalyst properties are commercialized, and there are many patent applications. Note that titanium oxide, which is excellent in oxidizing power and chemical stability, is widely used among many kinds of photocatalysts. The titanium oxide photocatalyst absorbs light having a wavelength of 400 nm or less, and performs the photocatalytic reaction as described above.

3 is a plan view of a conventional air purifier using ozone and a photocatalyst in combination. As shown in FIG. 3, such an air purifier includes a filter unit 31, an ozone generator 32, and a photocatalyst in order from the upstream to the downstream of the air flow path in accordance with the flow of air, which is the fluid to be treated. 33), and an activated carbon portion 34. The photocatalyst 33 includes a case for forming an air flow path, a photocatalyst filter for supporting a photocatalyst functional layer provided on a substrate having a plurality of holes, and an ultraviolet ray for irradiating ultraviolet rays to the photocatalyst filter. Means; The photocatalyst filter is arranged such that the total amount of air to be processed flows through the photocatalyst filter.

When the air introduced into the air purifier passes through the case of the photocatalyst 33, the photocatalyst filter is activated by ultraviolet rays irradiated by the ultraviolet irradiation means to decompose harmful substances contained in the air. . Therefore, the air is purified, and the purified air is discharged. (See, for example, Patent Reference 1 and Japanese Patent Laid-Open No. 2002-272824)

4 is a longitudinal cross-sectional view of another conventional air purifier having a deodorizing filter using an adsorbent containing at least one of activated carbon and zeolite and a photocatalyst. As shown in FIG. 4, a tubular deodorizing filter 41 including a photocatalyst is provided inside the air purifier, and is excited near the deodorizing filter 41 on the upstream side of the deodorizing filter 41. A light source 42 is disposed, and the deodorizing filter 41 is provided to rotate to change the light irradiation position from the excitation light source 42. Therefore, since the gas adsorbed on the deodorizing filter 41 can be processed and decomposed, the regeneration rate of the deodorizing filter 41 can be improved and the initial excellent performance can be maintained for a long time. (See Patent Reference 2, Japanese Patent Application Laid-Open No. 2002-263175, for example)

On the other hand, the photocatalytic reaction occurs only at or near the surface of the photocatalyst. Therefore, in the case of decomposition and purification of extremely rare concentrations of harmful gases at the ppm or ppb level through a photocatalyst, the process of diffusion of harmful gases onto the surface of the photocatalyst tends to be a reaction rate determining step of the decomposition purification reaction. In particular, when the harmful gas having less adsorption to the photocatalyst is subjected to decomposition purification, the decomposition purification rate is significantly slowed down.

As described above, Patent Reference 1 describes a method of using ozone and a photocatalyst in combination. However, the fact that the purification rate is improved by the combination of ozone and photocatalyst is not clearly understood.

In addition, Patent Reference 2 describes a method of using a photocatalyst with an adsorbent containing at least one of activated carbon and zeolite. However, even with this method, when the adsorbent reaches the adsorption saturation state, no more harmful substances are adsorbed and the purification power is lowered. Therefore, when the purification power is reduced in this way, the adsorbent needs to be replaced. Eventually, the used adsorbent becomes a general waste or an industrial waste and has the disadvantage of increasing waste.

An object of the present invention for solving the problems as described above is to provide a device for decomposing harmful substances having a high efficiency of decomposition and removal of harmful substances while reducing the amount of waste.

An apparatus for decomposing harmful substances according to an aspect of the present invention is an apparatus for purifying a gas containing harmful substances, the inlet being provided at a lower portion thereof; A fan installed at an upper portion of the intake port and configured to suck a gas containing the harmful substance; A light source installed in a flow path of the gas sucked from the fan; Two or more members provided with a photocatalyst, the same distance from the light source with the light source interposed therebetween; And a gas passage formed between the light source and the at least two members such that the gas sucked from the fan is discharged to the outside through the member positioned in the opposite direction of the light source. When initially passing through the surface of the member, the light intensity from the light source to the surface of the member is provided to be the strongest.

Here, a rectifying plate may be provided in the gas passage of the hazardous substance decomposition device.

An apparatus for decomposing toxic substances according to another aspect of the present invention is an apparatus for purifying a gas containing a toxic substance, the inlet being provided at a lower portion thereof; A fan installed at an upper portion of the intake port to suck gas containing the harmful substance; A light source installed in a flow path of the gas sucked from the fan; Two or more members provided with a photocatalyst, the two or more members being disposed such that light irradiated to the surface of one member from the light source is reflected to the surface of the other member; And a gas passage formed between the light source and the two or more members such that gas sucked from the fan passes through the member positioned in an opposite direction to the light source and is discharged to the outside. And located in an area surrounded by the surfaces of the light source, when the gas sucked from the fan first passes through the surface of the member, the light intensity from the light source to the surface of the member is strongest.

An apparatus for decomposing toxic substances according to another aspect of the present invention is an apparatus for purifying a gas containing a toxic substance, the inlet being provided at a lower portion thereof; A fan installed at an upper portion of the intake port and configured to suck a gas containing the harmful substance; A light source installed in a flow path of the gas sucked from the fan; Two or more members provided with a photocatalyst, the two or more members being disposed to face each other with the same distance from the light source with the light source therebetween; And a gas passage formed between the light source and the at least two members such that the gas sucked from the fan is discharged to the outside through the member positioned in the opposite direction of the light source. When initially passing through the surface of the member, the light intensity from the light source to the surface of the member is provided to be the strongest.

An apparatus for decomposing harmful substances according to another aspect of the present invention is an apparatus for purifying a gas containing a harmful substance, the inlet being installed at a lower portion thereof; A fan installed at an upper portion of the intake port and configured to suck a gas containing the harmful substance; A light source installed in a flow path of the gas sucked from the fan; A photocatalyst is provided, The tubular member is installed so that the light source is located in the central portion of the inside; And a gas passage formed between the light source and the tubular member such that gas sucked from the fan passes through the tubular member located in an opposite direction of the light source to the outside. When the gas to be sucked first passes through the surface of the tubular member, the light intensity from the light source to the surface of the tubular member is provided to be the strongest.

Here, the member provided with the photocatalyst may be a filter-shaped member, a porous member, or other member through which gas can pass. The member on which the photocatalyst is installed may be ceramic.

According to the apparatus for decomposing harmful substances of the present invention, the amount of waste can be reduced, and the efficiency of decomposition and removal of harmful substances can be improved.

To this end, as described above, the apparatus for decomposing harmful substances of the present invention,

1) Arrangement or structure of a member equipped with a photocatalyst to minimize light leaking out

2) a light source surrounded by members having photocatalysts or tubular members

3) Gases containing harmful substances are introduced to the location of the light source

Includes configurations such as

By the way, 3) "the gas containing the harmful substance is introduced into the place where the light source is located" means that when the gas to be sucked first passes through the surface of the member, the light intensity from the light source to the surface of the member is most strongly Configuration "is achieved. Specifically, a gas containing harmful substances must pass in the direction of the surface located on the opposite side from the surface of the member that is directly irradiated with light from the light source, for this purpose, a gas containing harmful substances is introduced to the place where the light source is located This is because it must be provided. 3) increases the efficiency of decomposition and removal of harmful substances by using the introduction (pass) direction of a gas containing harmful substances.

As described above, the apparatus for decomposing harmful substances of the present invention has a structure in which a gas containing harmful substances is introduced into the members each provided with the photocatalysts such that photocatalysts are respectively installed and first pass through the surface of one member having the strongest light intensity. Has

Therefore, in the hazardous substance decomposition apparatus of the present invention, immediately after the gas containing the hazardous substance is introduced into the apparatus, it passes through the surface of the member provided with the photocatalyst located at the position where the intensity of the hazardous substance is highest and the strongest light intensity. The efficiency of the purification reaction can be maximized. That is, since the concentration of the harmful substances contained in the gas is the highest, the photocatalyst is activated first and passes through the places having the highest harmful substance removal effect, so that most of the harmful substances are removed at the initial stage when the gas passes through the member. Thus, the decomposition removal efficiency of the harmful substance is greatly improved.

Typically, concentrations of odorous substances occurring in residential spaces range from ppb levels to several ppm levels. When the gas of such thin concentration is decomposed, it is known that the decomposition rate of the gas increases in proportion to the concentration of the gas.

In addition, in the case of light intensity of several mW / cm ² emitted from black light or a cold cathode lamp for photocatalyst, the higher the light intensity, the faster the decomposition rate. Therefore, as the light intensity is increased and the concentration of gas is increased, the decomposition rate is increased, and the effect of removing harmful substances such as deodorizing effect is naturally increased.

Therefore, in the apparatus for decomposing harmful substances such as a deodorizing apparatus composed of a light source and a member including a photocatalyst such as a ceramic filter coated with a photocatalyst, the apparatus for decomposing harmful substances includes a gas containing harmful substances such as odor gas. A photocatalyst, such as a ceramic filter provided, is provided to pass through a member provided.

Therefore, a gas or the like containing harmful substances such as malodorous gas is brought into contact with the surface of a member provided with a photocatalyst such as a ceramic filter located at a position where the intensity of gas is highest, with the highest concentration of gas. Therefore, the reaction efficiency is improved.

In addition, the light irradiated to the photocatalyst is not absorbed entirely to the photocatalyst and contributes to the reaction, but part or most of the light is reflected by the photocatalyst layer and leaks out. Light leaking outside does not contribute to the deodorizing reaction, so the energy is wasted.

In order to reduce this energy waste as much as possible, a structure should be provided to make it difficult for light from the light source to leak out. For example, one method is to place a light source between a pair of members provided with a photocatalyst such as a ceramic filter. In this case, the light reflected from the member provided with the photocatalyst such as one ceramic filter is incident on the member provided with the photocatalyst such as the ceramic filter on the opposite side, so that the photocatalytic reaction proceeds at the photocatalyst coated on the surface of the ceramic filter on the opposite side. It is used to Therefore, it is possible to improve the utilization efficiency of light.

More specifically, according to the harmful substance decomposition method of decomposing harmful substances by using the photocatalyst irradiated with light from the light source installed in the area surrounded by the surface of the member, the surface of the member is irradiated to the surface of the one member The light emitted is reflected to the surface of the other member, and the light irradiated onto the surface of each of the members on which the photocatalyst is installed contributes to the photocatalytic reaction or even though the light is reflected on the surface of the one member on which the photocatalyst is installed, The reflected light is irradiated to the surface of the other members provided with the photocatalyst. Therefore, light utilization efficiency is improved.

In addition, according to the method of decomposing harmful substances using the photocatalyst in which the surfaces of the members provided with the photocatalyst face each other and irradiated with the light of the light source provided between the surfaces, the light irradiated onto the surface of the one member provided with the photocatalyst Silver contributes to the photocatalytic reaction, or even if the light is reflected at the surface of the one member, the reflected light is irradiated to the surface of the other member. Therefore, light utilization efficiency is improved.

In addition, according to the method for decomposing harmful substances using the photocatalyst irradiated with light from a light source installed inside the tubular member provided with the photocatalyst, the light irradiated onto the surface of the photocatalyst-installed member that decomposes the harmful substances passing through the photocatalyst. Silver contributes to the photocatalytic reaction, or even if light is reflected, because it is irradiated to the surface of the other member provided with the photocatalyst can improve the utilization efficiency of the light energy.

On the other hand, according to the method for decomposing harmful substances in which the member or the tubular member provided with the photocatalyst is a filter, porous material, or other member through which gas can pass, the harmful component is a filter member, a porous member, or a gas that can pass therethrough. It is disassembled and removed when passing through the other members. When the porous member is used, since the surface area is increased, the amount of photocatalyst is also increased, thereby increasing the decomposition removal efficiency of harmful substances. It is particularly noteworthy that even if the member is not a filter-shaped member or a porous member, any member can be applied to the harmful substance decomposition method as long as the harmful substance can pass therethrough.

Efficient in accordance with the harmful substance decomposition method of introducing the gas into the member having the photocatalyst or the tubular member so that the gas containing the harmful substance first passes through the member having the photocatalyst or the surface having the strongest light intensity of the tubular member. Hazardous substances can be decomposed and removed.

In addition, in the method of decomposing harmful substances in which the member having the photocatalyst or the tubular member is formed of ceramic, the member can be recovered by washing the member with water, thereby reducing the waste amount.

In addition, the hazardous substance decomposition apparatus according to each hazardous substance decomposition method as described above can be implemented.

The hazardous substance decomposition apparatus includes an intake port installed under the hazardous substance decomposition device, a fan installed on the upper portion of the intake port, a gas passage provided on the upper portion of the fan, a light source installed on the gas passage, and the light source therebetween. And a photocatalyst provided on each of the members, wherein the suction port, the fan, the gas passage, and the light source include a gas containing harmful substances, the surface of one member having the photocatalyst and the strongest light intensity. It is provided to pass through the first.

In addition, the harmful substance decomposition apparatus provided with the rectifying plate is provided in the flow path of the gas in the hazardous substance decomposition apparatus, even if the gas circulation resistance is increased and the gas flow rate is low, the gas can be circulated throughout the member, so that the harmful substance and the photocatalyst The contact efficiency of the liver may be increased, thereby improving the ability to decompose and remove harmful substances.

In addition, the apparatus for decomposing harmful substances according to the present invention includes an inlet provided in a lower portion of the hazardous substance decomposing device, a fan installed in an upper portion of the intake port, a gas passage provided in an upper portion of the fan, a light source installed in the gas passage, And a photocatalyst provided on each member provided to sandwich the light source, wherein the surfaces of the members on which the photocatalyst is installed are arranged so that light irradiated to the surface of one member from the light source is reflected to the surface of the other member, The light from the light source installed in the area surrounded by the surfaces is irradiated to the photocatalyst, and the gas containing noxious substances is first passed through the surface of the one member of which the photocatalyst is respectively installed and the strongest light intensity. The photocatalyst is introduced into the members respectively provided.

In addition, the apparatus for decomposing harmful substances according to the present invention includes an inlet provided in a lower portion of the hazardous substance decomposing device, a fan provided in an upper portion of the inlet, a gas passage provided in an upper portion of the fan, a light source installed in the gas passage, And a photocatalyst provided on each of the members provided to sandwich the light source, wherein the surfaces of the members on which the photocatalyst is respectively installed are disposed to face each other, and the light from the light source disposed between the surfaces is irradiated to the photocatalyst. And a gas containing harmful substances is introduced into the members in which the photocatalyst is installed such that the photocatalysts are respectively installed and first pass through the surface of the one of the strongest and strongest light.

In addition, the apparatus for decomposing harmful substances according to the present invention includes an inlet provided in a lower portion of the hazardous substance decomposing device, a fan installed in an upper portion of the intake port, a gas passage provided in an upper portion of the fan, and a light source installed in the gas passage. And a photocatalyst installed on each member provided to sandwich the light source, wherein the light source is installed inside the tubular member on which the photocatalyst is installed, and the light from the light source is irradiated onto the photocatalyst, The gas containing is introduced into the tubular member so that the photocatalyst is first installed and first passes through the inner surface of the tubular member having the strongest light intensity.

Each of the members or the tubular member provided with the photocatalyst may be provided as a filter member, a porous member, or other member that allows gas to pass therethrough.

Each of the members or the tubular member in which the photocatalyst is installed may be provided in ceramic.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention.

1 is a block diagram of a deodorizing apparatus according to a first embodiment of the present invention. Figure 1 (a) is a cross-sectional configuration of the deodorizing device according to a first embodiment of the present invention, Figure 1 (b) is a side configuration diagram of a deodorizing device according to a first embodiment of the present invention.

In the deodorizing apparatus according to the first embodiment of the present invention, a pair of ceramic filters provided with a photocatalyst and a light source for causing a photocatalytic reaction are disposed in combination, and the light source is used for efficient use of light emitted from the light source. It is characterized in that it is installed between the pair of ceramic filters. The gas containing the malodorous gas is introduced between the pair of ceramic filters so as to first pass through the surface of the pair of ceramic filters having the strongest light intensity.

More specifically, as shown in Figure 1, the deodorizing device, the inlet port (1) is installed in the lower portion of the harmful substance decomposition apparatus for introducing a gas; A fan (2) installed at an upper portion of the inlet (1) to provide power for introducing gas; A plurality of lamps 3 installed in parallel in the deodorizing device and serving as a light source; A pair of ceramic filters (4, 5) installed to face each other with a plurality of the lamps (3) therebetween; Side chambers 6 and 7 provided adjacent to the ceramic filters 4 and 5; Side chambers (8, 9) connected to the side chambers (6, 7) and for discharging gas to the exhaust port; And exhaust ports 10 and 11 connected to the side chambers 8 and 9 and for discharging gas.

In the hazardous substance decomposing device, when the fan 2 is operated, gas is introduced through the inlet port 1 to reach a central portion of the harmful substance decomposing device in which a plurality of lamps 3 serving as a light source are installed. do. The gas passes through the ceramic filters 4, 5 provided on both sides of the plurality of lamps 3. When the gas passes through the ceramic filters 4 and 5, it is provided on the surfaces of the ceramic filters 4 and 5, and comes into contact with the photocatalyst irradiated with light to decompose the malodorous component gas contained in the gas. The gas from which the malodorous component gas is decomposed and removed through the ceramic filters 4 and 5 reaches the side chambers 8 and 9 through the side chambers 6 and 7, and the exhaust ports 10 and 11 are closed. Is discharged through.

In this method, as the gas passes from the plurality of lamps 3 to the pair of ceramic filters 4 and 5, the gas is paired with the ceramic filter at the highest concentration of the malodorous component gas. The light intensity of (4, 5) passes through the surface with the strongest, and harmful components are efficiently decomposed and removed. Further, the light source is provided between the pair of ceramic filters 4 and 5 so that the light reflected from the ceramic filter on one side to which light is irradiated can be irradiated onto the ceramic filter on the other side. Therefore, the utilization efficiency of light energy is improved.

In addition, as long as the plurality of lamps 3, which are light sources, can irradiate a uniform light to the pair of ceramic filters 4 and 5, they may be provided without being parallel to each other vertically. Do.

In addition, the photocatalyst included in the pair of ceramic filters 4 and 5 is most preferably titanium oxide. Can be used.

In addition, the ceramic filter is not limited to a pair, and if there is a relationship in which the light irradiated by the ceramic filter on one side is reflected by the ceramic filter on the other side, a purchase may be provided. In addition, a plurality of the lamps 3 as light sources may be installed inside a cylindrical or tubular ceramic filter.

2 is a cross-sectional view of a deodorizing apparatus according to a second embodiment of the present invention. Figure 2 (a) is a cross-sectional configuration of the deodorizing device according to a second embodiment of the present invention, Figure 2 (b) is a side configuration diagram of a deodorizing device according to a second embodiment of the present invention.

Deodorizer according to the second embodiment of the present invention, compared to the deodorizer according to the first embodiment of the present invention, located in the side chamber (6, 7), is perpendicular to the gas moving in the upward direction A plurality of rectifying plates 12 are further provided.

As the plurality of rectifying plates 12 are additionally provided in the side chambers 6 and 7, the circulation resistance of the gas increases. Therefore, even if the gas flow rate is low, the gas flows uniformly throughout the side chambers 6, 7. Therefore, a uniform gas circulation throughout the pair of ceramic filters 4 and 5 is formed, resulting in a high contact efficiency between the malodorous component gas and the photocatalyst, thus improving the deodorizing effect.

In particular, if the above-described effect can be obtained, the plurality of the rectifying plate 12 is not necessarily perpendicular to the gas moving in the upward direction, each one of the rectifying plate in the side chamber (6, 7) It does not matter even if it is provided.

1 is a block diagram of a deodorizing apparatus of the present invention,

2 is a block diagram of another deodorizer of the present invention,

3 is a plan view of an air purifier using a combination of a conventional ozone and a photocatalyst,

4 is a longitudinal cross-sectional view of an air purifier using a combination of a photocatalyst and an adsorbent containing at least one of conventional activated carbon and zeolite.

＊ Explanation of symbols for main part of drawing ＊

1: intake vent 2: fan

3: lamp 4, 5: ceramic filter

6, 7, 8, 9: side chamber 10, 11: exhaust port

12: rectification plate

Claims (8)

In the harmful substance decomposition device for purifying a gas containing harmful substances, An air inlet installed at a lower portion thereof; A fan installed at an upper portion of the intake port and configured to suck a gas containing the harmful substance; A light source installed in a flow path of the gas sucked from the fan; Two or more members provided with a photocatalyst, the same distance from the light source with the light source interposed therebetween; And A gas passage formed between the light source and the two or more members such that gas sucked from the fan is discharged to the outside through the member positioned in the opposite direction of the light source; Including but not limited to: And when the gas sucked from the fan first passes through the surface of the member, the light intensity from the light source to the surface of the member is the strongest. The method of claim 1, And said rectifying plate is provided in said gas passage of said hazardous substance decomposing device. In the harmful substance decomposition device for purifying a gas containing harmful substances, An air inlet installed at a lower portion thereof; A fan installed at an upper portion of the intake port and configured to suck a gas containing the harmful substance; A light source installed in a flow path of the gas sucked from the fan; Two or more members provided with a photocatalyst, the two or more members being disposed such that light irradiated to the surface of one member from the light source is reflected to the surface of the other member; And A gas passage formed between the light source and the two or more members such that gas sucked from the fan is discharged to the outside through the member positioned in the opposite direction of the light source; Including but not limited to: The light source is located in an area surrounded by surfaces of the two or more members, And when the gas sucked from the fan first passes through the surface of the member, the light intensity from the light source to the surface of the member is the strongest. In the harmful substance decomposition device for purifying a gas containing harmful substances, An air inlet installed at a lower portion thereof; A fan installed at an upper portion of the intake port and configured to suck a gas containing the harmful substance; A light source installed in a flow path of the gas sucked from the fan; Two or more members provided with a photocatalyst, the two or more members being disposed to face each other with the same distance from the light source with the light source therebetween; And A gas passage formed between the light source and the two or more members such that gas sucked from the fan is discharged to the outside through the member positioned in the opposite direction of the light source; Including but not limited to: And when the gas sucked from the fan first passes through the surface of the member, the light intensity from the light source to the surface of the member is the strongest. In the harmful substance decomposition device for purifying a gas containing harmful substances, An air inlet installed at a lower portion thereof; A fan installed at an upper portion of the intake port and configured to suck a gas containing the harmful substance; A light source installed in a flow path of the gas sucked from the fan; A photocatalyst is provided, The tubular member is installed so that the light source is located in the central portion of the inside; And A gas passage formed between the light source and the tubular member such that gas sucked from the fan passes through the tubular member located in a direction opposite to the light source and is discharged to the outside; Including but not limited to: And when the gas sucked from the fan first passes through the surface of the tubular member, the light intensity from the light source to the surface of the tubular member is the strongest. The method according to any one of claims 3 to 5, The member provided with the photocatalyst, An apparatus for decomposing harmful substances using the photocatalyst, characterized in that it is a filter member, a porous member, or other member which allows gas to pass therethrough. The method according to any one of claims 3 to 5, The harmful substance decomposition apparatus using the photocatalyst, characterized in that the member provided with the photocatalyst is a ceramic. The method of claim 6, The harmful substance decomposition apparatus using the photocatalyst, characterized in that the member provided with the photocatalyst is a ceramic.

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