JP3822093B2 - Apparatus and method for purifying polluted air by photolysis - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an air purification apparatus and method for photolyzing pollutants contained in air. More specifically, the present invention relates to a polluted air purification apparatus and method for oxidizing and decomposing pollutants such as ammonia, amines, mercaptans, and organic chlorine compounds contained in air by the action of a photocatalyst and ultraviolet irradiation.
[0002]
[Prior art]
Odorous components such as ammonia, amines, mercaptans, etc. generated from garbage disposal plants and industrial waste disposal plants have been a problem of pollution for many years, leaving discomfort to the residents around the treatment plants. In addition, organic chlorine compounds such as trichlorethylene and tetrachlorethylene have been used in large quantities in dry cleaning factories, metal degreasing processes, substrate cleaning processes, etc., but some of them penetrated underground and further mixed into groundwater. It is reported that there are health concerns. As a method for removing volatile organic chlorine compounds contained in groundwater, the present applicant has proposed a method in which an organic chlorine compound is vaporized by an appropriate means and then decomposed (Japanese Patent Application No. 2001-238785). ).
As a general method for removing organochlorine compounds contained in the air, for example, a method of adsorbing to an adsorbent such as activated carbon, a method of decomposing by contacting with a catalyst under heating, a method by plasma discharge, etc. are known. . However, the adsorption method requires post-treatment of the adsorbent, the catalytic cracking method requires considerable energy to heat the catalyst, and the plasma discharge method requires a large amount of power. It was.
[0003]
In recent years, a photodegradation technique for oxidatively decomposing an organic substance by combining a photocatalyst and ultraviolet irradiation has been developed, and many proposals have been made using this for a method for removing an organic chlorine compound. A few examples are as follows.
For example, a method has been proposed in which a photocatalyst film is fixed to a tube wall or the like that is a contact surface with exhaust gas, and the organic catalyst is decomposed by irradiating the photocatalyst film with ultraviolet rays. However, this method has a problem that the surface area of the photocatalyst film is small and the decomposition efficiency is not good. In order to increase the contact area with the exhaust gas, it is conceivable that the photocatalyst has a honeycomb structure, but in that case, it is difficult to irradiate ultraviolet rays to the back of the photocatalyst film, and the improvement of the decomposition efficiency can also be expected. It is not considered.
[0004]
In addition, the photocatalyst powder is blown into the exhaust gas to adsorb the organochlorine compound, and the photocatalyst is irradiated with ultraviolet rays by an ultraviolet lamp installed in a space partitioned by a bag filter in the dust collecting part to decompose the organochlorine compound. A method has been proposed (Japanese Patent Laid-Open No. 10-32853). However, in this method, since it is necessary to install an ultraviolet lamp (ultraviolet irradiation source) inside the photodecomposition apparatus, the irradiation intensity of the ultraviolet rays decreases due to contamination of the irradiation source, and degradation efficiency is unavoidable. There is a problem.
Furthermore, a method has been proposed in which a granular photocatalyst carrier is used to decompose an organochlorine compound while flowing the photocatalyst carrier by blowing air to be treated and stirring by feeding water to be treated (Japanese Patent Laid-Open No. 2001-79351). JP, 2001-191067, A). However, in this method, the fluidity of the photocatalyst carrier is not so good, so a very small amount of the organic chlorine compound in the thin film concentration is not adsorbed on the photocatalyst carrier, and is released from the reactor system in a short pass without being treated. There is a possibility that.
[0005]
[Problems to be solved by the invention]
As described above, in the method for decomposing and removing organic substances by the combination of photocatalyst and ultraviolet irradiation, the irradiation intensity from the ultraviolet irradiation source gradually decreases to deteriorate the decomposition efficiency of pollutants, and the contamination of extremely low concentration is also reduced. In the case of decomposing and removing the substance (organochlorine compound), there is a problem that the contaminant is not sufficiently adsorbed by the photocatalyst.
Accordingly, an object of the present invention is to eliminate the above-mentioned problems of the prior art, and it is possible to sufficiently irradiate the photocatalyst with ultraviolet rays from an ultraviolet irradiation source, and the concentration of pollutants in the air is several hundred ppb. Even at extremely low concentrations, it is possible to prevent pollutants from being discharged outside the system without being treated, and to purify polluted air by photolysis with excellent pollutant decomposition efficiency. It is to provide an apparatus and a method thereof.
[0006]
[Means for Solving the Problems]
The inventors of the present invention have made extensive studies in order to solve the above-described problems of the prior art. In an air purification apparatus in which a plurality of photo-oxidation reaction chambers and activated carbon packed layers are formed, a light transmissive vertical By forming a triangular ultraviolet irradiation chamber composed of a transparent plate and an inclined transparent plate in each photooxidation reaction chamber, the photocatalyst filled in the photooxidation reaction chamber is maintained in a good circulation state, and this flow state As a result of sufficiently irradiating the photocatalyst with ultraviolet rays, it was found that the pollutants were efficiently decomposed, and the present invention was made.
[0007]
That is, the polluted air purification apparatus by photolysis of the present invention is provided with an air inlet and an air outlet respectively below and above the apparatus main body, and a plurality of photooxidation reaction chambers are formed at the lower part inside the apparatus main body. In the purification apparatus for polluted air by photolysis, an activated carbon packed layer is formed on the top, and each upper and bottom of each photooxidation reaction chamber and the activated carbon packed layer are partitioned by a partition plate having a large number of ventilation holes. Inside the photo-oxidation reaction chamber, an ultraviolet irradiation chamber having a substantially triangular cross-sectional shape composed of a light-transmitting vertical transparent plate, an inclined transparent plate, and a partition plate at the bottom of the photo-oxidation reaction chamber is formed. At the same time, an ultraviolet irradiation source is disposed inside the ultraviolet irradiation chamber, the photooxidation reaction chamber excluding the ultraviolet irradiation chamber is partially filled with a granular photocatalyst, and the activated carbon packed bed has a granular shape. Filled with activated carbon It is characterized in.
[0008]
Further, in the method for purifying polluted air by photolysis according to the present invention, air containing pollutants is introduced into the lowermost photooxidation reaction chamber through a partition plate at the bottom of the apparatus main body having a large number of ventilation holes, and a plurality of stages are provided. While the oxidative decomposition of the pollutant is caused by the action of the photocatalyst and ultraviolet irradiation in the photooxidation reaction chamber, the activated carbon packed bed is filled with undegraded pollutants contained in the air that has passed through the uppermost photooxidation reaction chamber. after adsorption on activated carbon, in the above method for purifying polluted air by photolysis to release the purified air from the apparatus body, in the interior of the photooxidation chamber, a light-permeable vertical transparent plate and inclined transparent plate A granular photocatalyst in which an ultraviolet irradiation chamber having a substantially vertical cross-sectional shape composed of a partition plate at the bottom of the photooxidation reaction chamber is formed and partially filled in the space of the photooxidation reaction chamber excluding the ultraviolet irradiation chamber Air flow rising from below Ri while fluidizing, contaminants from placed ultraviolet radiation source ultraviolet irradiation chamber is irradiated with ultraviolet light catalyst adsorbed, characterized by oxidative decomposition of pollutants in the air.
[0009]
[Action]
As described above, the device for purifying contaminated air by photolysis of the present invention comprises a plurality of photooxidation reaction chambers and activated carbon packed layers each partitioned by a partition plate having a large number of ventilation holes, and is a light-transmitting vertical transparent plate Are formed in each photooxidation reaction chamber.
The method for purifying polluted air according to the present invention comprises a method of adsorbing undegraded pollutants to activated carbon while oxidizing and decomposing pollutants by the action of a photocatalyst and ultraviolet irradiation in a plurality of photooxidation reaction chambers. The photocatalyst fluidized by the air flow is irradiated with ultraviolet rays from the ultraviolet irradiation chamber.
[0010]
Therefore, the pollutant is first surely adsorbed on the granular photocatalyst at the bottom deposition portion of the photooxidation reaction chamber. Moreover, the photocatalyst is blown up and diffused upward by the air flow rising along the vertical transparent plate and the inclined transparent plate, and the scattered photocatalyst portion is efficiently irradiated with ultraviolet rays, so that the pollutant adsorbed on the photocatalyst is absorbed. Can be efficiently oxidized and decomposed. Furthermore, since the fluidized bed is composed of the bottom partition plate and the inclined transparent plate so that the photocatalyst falls along the inclined transparent plate and deposits on the bottom partition plate, the photocatalyst is good in the photooxidation reaction chamber. Circulation is maintained.
Further, in the polluted air purifying apparatus and method of the present invention, a plurality of photooxidation reaction chambers having the above-described structure and an activated carbon packed bed are disposed above them. Therefore, a short path of pollutants is avoided in the photooxidation reaction chamber, and the undecomposed pollutants contained in the air passing through the uppermost photooxidation reaction chamber are adsorbed by the granular activated carbon packed in the activated carbon packed bed. Therefore, it is possible to prevent the pollutant from being released out of the purification apparatus without being treated.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Next, the present invention will be described in detail.
The pollutant to be treated according to the present invention is not particularly limited as long as it is a volatile substance that is harmful to health or emits a bad odor even at a very low concentration. For example, organic substances such as trichloroethylene, tetrachloroethylene, and trichloroethane can be used. In addition to chlorine-based solvents, amines such as ammonia and trimethylamine, mercaptans such as hydrogen sulfide and methyl sulfide, and odorous substances such as formaldehyde can be used.
As described above, the apparatus and method for purifying contaminated air by photolysis according to the present invention has a plurality of photooxidation reaction chambers formed in the lower part of the apparatus body, and an activated carbon packed bed formed in the upper part. Each photo-oxidation reaction chamber and activated carbon packed bed has a bottom portion and an upper portion having a large number of ventilation holes so that air containing contaminants introduced from the lower part of the apparatus main body can be vented and purified air is discharged from the upper part of the apparatus main body. It is partitioned by a partition plate. As the partition plate, a metal mesh or a punching metal in which pores such as a circle, an ellipse, a square, and a star are formed is preferably used. The size of the mesh or pores may be such that the granular photocatalyst or activated carbon does not fall out of the partition plate.
[0012]
The photo-oxidation reaction chamber takes into account the concentration of pollutants contained in the air, the volume of air per unit time, the amount of photocatalyst, the decomposition efficiency of pollutants, etc. Can be increased.
In each photo-oxidation reaction chamber, an ultraviolet irradiation chamber composed of a light-transmitting vertical transparent plate and an inclined transparent plate is formed together with the bottom partition plate. The partition plate portion that forms the ultraviolet irradiation chamber is a plate-like member that closes the mesh or pores or does not previously have pores so that the fine photocatalyst generated during operation does not enter the ultraviolet irradiation chamber. It is preferable. Further, the ultraviolet irradiation chamber may be further formed by combining the side wall of the apparatus main body of the photooxidation reaction chamber and the inclined transparent plate. Thus, a plurality of ultraviolet irradiation chambers are usually formed in one photooxidation reaction chamber, and one or a plurality of ultraviolet irradiation sources are arranged inside each ultraviolet irradiation chamber.
[0013]
It is preferable that the ultraviolet irradiation chamber has a substantially triangular cross-sectional shape, and the inclined angle of the inclined transparent plate inclined toward the ultraviolet irradiation chamber with respect to the bottom partition plate is in the range of 50 to 70 °.
The inclination angle is more preferably in the range of 55 to 65 °, and particularly preferably in the range of 57 to 63 °. When the inclination angle is less than 50 °, the total opening area of the partition plate through which air flows from below is small, and the fluidity of the photocatalyst decreases. On the other hand, when the angle is larger than 70 °, the inflowing air is not diffused so much in the upper part of the photooxidation reaction chamber, and the oxidative decomposition efficiency of pollutants due to the fluidization of the photocatalyst decreases. In addition, the space of the ultraviolet irradiation chamber is small, and the maintenance and inspection work of the ultraviolet irradiation source disposed inside the chamber becomes difficult.
[0014]
A vertical transparent plate and an inclined transparent plate are disposed between the bottom partition plate and the upper partition plate, and no gap is provided between the upper end portion of the ultraviolet irradiation chamber where both transparent plates abut and the upper partition plate. preferable. Thereby, since the photocatalyst filled in one space of the photo-oxidation reaction chamber does not move to the other space, the contaminant can be stably oxidatively decomposed for a long period of time.
The vertical transparent plate and the inclined transparent plate are made of a material excellent in light transmittance, that is, ultraviolet light transmittance, such as glass or polymethyl methacrylate. As the ultraviolet irradiation source, an ultraviolet lamp that irradiates ultraviolet rays having a wavelength of 390 nm or less is usually used. In addition, a reflective thin film is deposited or a reflecting plate is stretched on the surface of the inner wall of the apparatus main body constituting the photooxidation reaction chamber, particularly the ultraviolet irradiation chamber, and further on the surface of the bottom partition plate. Hereinafter, it can also be represented by a reflector. In that case, it is preferable that the ultraviolet rays irradiated from the ultraviolet irradiation source are irregularly reflected by, for example, a roughened reflector or the like, and the photooxidative decomposition action is further enhanced.
[0015]
The inside of the photooxidation reaction chamber excluding the ultraviolet irradiation chamber is partially filled with a particulate photocatalyst. Examples of the photocatalyst include titanium oxide, zinc oxide, and tungsten oxide. These photocatalysts are carried on the surface and inside of a granular porous carrier such as zeolite, silica gel, alumina, and porous glass. The particle size of the photocatalyst carrier is in the range of 1.5 to 10 mm, and preferably in the range of 2 to 4 mm. Moreover, it is preferable that the apparent filling rate of the photocatalyst with respect to the photo-oxidation reaction chamber except an ultraviolet irradiation chamber exists in the range of 20-70 volume%.
When the particle size of the photocatalyst is less than 1.5 mm, it is necessary to make the meshes or pores of the bottom and the upper partition plate smaller than the particle size of the photocatalyst support, and the opening area per unit area of the partition plate is small. The resistance of the partition plate with respect to the air supplied from below by the blower increases. On the other hand, when the particle size is larger than 10 mm, the fluidity of the photocatalyst decreases. When the filling rate is less than 20% by volume, the oxidative decomposition efficiency of the pollutant per unit volume of the photooxidation reaction chamber excluding the ultraviolet irradiation chamber cannot be ensured sufficiently. On the other hand, when the filling rate is larger than 70% by volume, the fluidity of the photocatalyst is lowered and the photocatalyst is not sufficiently circulated in the photooxidation reaction chamber.
[0016]
The activated carbon packed bed is filled with granular activated carbon formed by activating carbonaceous material. The activated carbon packed bed can be divided into a plurality of layers as appropriate. Moreover, it is not always necessary to fill the entire inside of the packed bed with activated carbon.
The activated carbon packed bed is preferably filled with activated carbon for basic gas, neutral gas, and acidic gas alone or in combination depending on the nature of the pollutant contained in the contaminated air. For example, when the pollutant to be treated is an organic chlorine compound, when the air passes through the photocatalyst, it is decomposed into HCl, CO ₂ and H ₂ O, and the treated air tends to contain an acidic gas. In that case, it is preferable to fill the granular activated carbon modified to be basic for acid gas adsorption.
The particle size of the activated carbon is in the range of 2-6 mm. When the particle size of the activated carbon is less than 2 mm, the resistance of air passing through the activated carbon packed bed is increased. On the other hand, if the particle size is larger than 6 mm, the surface area of the activated carbon per unit volume becomes small, and the adsorption efficiency of the pollutant decreases, which is not preferable.
[0017]
Furthermore, it is preferable to form an air reservoir below the lowermost photooxidation reaction chamber so that the flow rate of air flowing into the photooxidation reaction chamber filled with the photocatalyst is made uniform. Similarly, between the upper partition plate of the photooxidation reaction chamber located below and the bottom partition plate of the photooxidation reaction chamber located above, and the upper partition plate of the uppermost photooxidation reaction chamber and the activated carbon packed bed It is preferable to form an air reservoir between each of the bottom partition plates.
If at least one of these air pockets is formed, uneven adsorption of contaminants on the photocatalyst and / or activated carbon is reduced. For example, when an air pool is formed between the partition plates of different photo-oxidation reaction chambers, the photocatalyst flows and circulates almost uniformly, and the oxidative decomposition efficiency of pollutants is improved.
[0018]
【Example】
Hereinafter, the present invention will be described more specifically with reference to the drawings.
In FIG. 1, reference numeral 1 denotes an air purification device main body formed from a tower having a substantially square shape. Four legs 2 are attached to the bottom of the device main body 1 to support it. In addition, a lower air reservoir 3 that expands upward is formed in the lower part of the apparatus body 1, an air inlet 4 that communicates with the lower air reservoir 3 is formed in the lower center, and a blower (not shown) is located behind the air inlet 4. ) Is arranged.
The apparatus main body 1 is partitioned by a first bottom partition plate 5a made of a 10-mesh wire mesh and a first upper partition plate 5b made of the same wire mesh as the partition plate 5a with a predetermined interval therebetween. The photo-oxidation reaction chamber 6 and the intermediate air reservoir 7 thereabove are formed in a plurality of stages. FIG. 1 shows an example in which the photooxidation reaction chamber 6 and the intermediate air reservoir 7 are formed in two stages.
[0019]
Between the first partition plates 5a and 5b of the photooxidation reaction chamber 6, a plurality of vertical transparent plates 8 and inclined transparent plates 9 made of light-transmitting glass are arranged, and the transparent plates 8 and 9 and the bottom partition plate 5a. The space partitioned by is an ultraviolet irradiation chamber 10. The partition plate 5a constituting the ultraviolet irradiation chamber 10 is closed with a reflecting plate 11. The upper ends of the transparent plates 8 and 9 are in contact with each other at an inclination angle of 30 ° (thus, the inclination angle of the inclined transparent plate 9 with respect to the bottom partition plate 5a is 60 °). An ultraviolet lamp 12 that irradiates near ultraviolet rays is disposed inside the ultraviolet irradiation chamber 10.
In FIG. 1, three ultraviolet irradiation chambers 10 are formed by three inclined transparent plates 9, a reflection plate 11, two vertical transparent plates 8, and a reflection plate on the inner wall surface of the apparatus body 1. Two ultraviolet lamps 12 are disposed inside. In addition, the vertical transparent plates 8 located on different stages are arranged on the same vertical plane.
[0020]
The photo-oxidation reaction chamber 6 excluding the ultraviolet irradiation chamber 10 is a photocatalyst filling chamber 14 filled with a photocatalyst 13 made of titanium oxide supported on a granular carrier having a particle diameter of 3 mm. The granular photocatalyst 13 occupies 40% by volume of the filling chamber 14 and is fluidized by the air flow blown from below. Therefore, not only the bottom partition plate 5a but also the inclined transparent plate 8 functions as a fluidized bed.
Above the uppermost intermediate air reservoir 7, second partition plates 15 a and 15 b made of a 10-mesh wire mesh are fixed to the apparatus main body 1 through a predetermined interval. The inside is an activated carbon packed layer 17 filled with granular activated carbon 16 having a particle diameter of 3 mm. Further, an activated carbon outlet 18 for taking out the activated carbon 16 having a reduced ability to adsorb contaminants is provided on the side wall of the main body 1 of the packed bed 17. Above the second upper partition plate 15b, an upper air reservoir 19 that is reduced in diameter upward is formed, and an air discharge port 20 that communicates with the air reservoir 19 is formed at the upper center thereof.
[0021]
Next, the operation of the air purification device shown in the embodiment will be described.
First, when the blower is driven to rotate, air containing pollutants flows from the inlet 4 at the bottom of the air purification device main body 1 and contaminated air in the lower air reservoir 3 formed so as to rise inside the device at a substantially constant flow rate. Is rectified. The contaminated air that has passed through the air reservoir 3 flows into the lowermost photocatalyst filling chamber 14 from the mesh of the first partition plate 5a.
The photocatalyst 13 is densely deposited in the filling chamber 14, and contaminants in the air are adsorbed by coming into contact with the photocatalyst 13. Further, the granular photocatalyst 13 rises upward by the air blown from below, and is diffused apart at the upper part of the filling chamber 14 where the horizontal interval between the transparent plates 8 and 9 spreads upward. The fluidization of the photocatalyst 13 is balanced by its own weight and the upward flow of air by the blower.
[0022]
On the other hand, the ultraviolet irradiation chamber 10 is surrounded by light transmissive transparent plates 8 and 9 and a reflecting plate 11 from three directions, and the photocatalyst filling chamber 14 is irradiated with ultraviolet rays from an ultraviolet lamp 12 disposed therein. . Therefore, the contaminant adsorbed on the photocatalyst 13 particles is decomposed by the strong oxidizing action of ultraviolet rays and the photocatalyst. For example, the odorous ammonia is decomposed into water and nitrogen gas, and formaldehyde is decomposed into water and carbon dioxide gas to change to odorless materials.
The air containing the pollutant that has not been decomposed in the first-stage photocatalyst filling chamber 14 is rectified in the intermediate air reservoir 7 thereabove and is similarly subjected to the photooxidative decomposition action in the second-stage photocatalyst filling chamber 14. In this way, the contaminants are gradually decomposed as they rise into the upper photocatalyst filling chamber 14.
[0023]
Furthermore, the contaminated air flows into the activated carbon packed bed 17 from the mesh of the second bottom partition plate 15 a via the uppermost intermediate air reservoir 7, and the undecomposed contaminants almost completely enter the granular activated carbon 16. Adsorbed.
The air purified as described above is discharged into the atmosphere from the air outlet 20 at the top of the apparatus main body 1 via the upper air reservoir 19.
[0024]
【The invention's effect】
According to the present invention, as described above, the scattered state and the circulating state of the photocatalyst are good, and the photocatalyst is sufficiently irradiated with ultraviolet rays, so that the contaminant adsorbed on the photocatalyst is efficiently decomposed. In addition, according to the present invention, a short path of contaminants is avoided in the photooxidation reaction chamber, and the contaminants are prevented from being discharged out of the purification apparatus without being treated.
[Brief description of the drawings]
FIG. 1 is a sectional view of an apparatus for purifying contaminated air by photolysis according to the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Air purification apparatus main body, 4 ... Air inflow port, 5a, 5b ... 1st partition plate, 6 ... Photo-oxidation reaction chamber, 8 ... Vertical transparent plate, 9 ... Inclination Transparent plate, 10 ... UV irradiation chamber, 12 ... UV lamp, 13 ... Photocatalyst, 15a, 15b ... Second partition plate, 16 ... Activated carbon, 17 ... Activated carbon packed bed, 20 ... Air outlet.

Claims (5)

An air inlet and an air outlet are provided below and above the main body of the apparatus, a multi-stage photo-oxidation reaction chamber is formed in the lower part of the main body of the apparatus, and an activated carbon packed bed is formed on the upper part of each chamber. In each of the photo-oxidation reaction chambers, a light-transmitting vertical transparent material is provided in the purification device for contaminated air by photolysis in which the upper and bottom portions of the chamber and the activated carbon packed bed are partitioned by a partition plate having a number of ventilation holes. An ultraviolet irradiation source is disposed inside the ultraviolet irradiation chamber, while the vertical cross-sectional shape composed of the plate, the inclined transparent plate, and the partition plate at the bottom of the photooxidation reaction chamber forms a substantially triangular ultraviolet irradiation chamber. In addition, the photooxidation reaction chamber except for the ultraviolet irradiation chamber is partially filled with granular photocatalyst, and the activated carbon packed bed is filled with granular activated carbon. Air purification equipment   2. The polluted air purifier according to claim 1, wherein the inclined transparent plate inclined toward the ultraviolet irradiation chamber side with respect to the bottom partition plate of the photo-oxidation reaction chamber is in the range of 50 to 70 degrees.   The polluted air purifier according to claim 1, wherein the ultraviolet irradiation chamber is further formed of an inclined transparent plate, an inner wall of the device main body, and a partition plate.   The apparatus for purifying contaminated air according to claim 3, wherein the surface of the inner wall of the apparatus main body is configured as a reflecting surface. Air containing pollutants is introduced into the lowermost photooxidation reaction chamber through a partition plate at the bottom of the main body of the apparatus having a large number of ventilation holes, and pollutants are generated by the action of the photocatalyst and ultraviolet irradiation in the multiple photooxidation reaction chambers. Oxidative decomposition, and adsorbing undecomposed pollutants contained in the air that has passed through the uppermost photo-oxidation reaction chamber to the granular activated carbon packed in the activated carbon packed bed, and then purifying the air from the device body. In the method for purifying polluted air by photodecomposition to be released, each photooxidation reaction chamber has a longitudinal cross section formed by a light transmissive vertical transparent plate, an inclined transparent plate, and a partition plate at the bottom of the photooxidation reaction chamber. An ultraviolet irradiation chamber having a substantially triangular shape is formed, and ultraviolet irradiation is performed while the granular photocatalyst partially filled in the space of the photooxidation reaction chamber excluding the ultraviolet irradiation chamber is fluidized by an air flow rising from below. Purple placed in the room And contaminants from the line radiation source and irradiated with ultraviolet rays photocatalyst adsorbed, method for purifying polluted air by photolysis characterized by oxidative decomposition of pollutants in the air.

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