JP2003089696A - Method for removing dioxin by catalyst ion-plasma reaction and device for removing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device for removing dioxins, which can decompose various kinds of toxic gas such as dioxin-based gas, whose catalyst-filled layer cassette has excellent durability and can be used for a long period, and which can be compacted with a compact catalyst-filled layer cassette. SOLUTION: This method for removing the dioxins by a catalyst ion-plasma reaction comprises cooling an exhaust gas exhausted from an incinerator 1, spraying water on the cooled exhaust gas to neutralize and remove Hcl-based, Nox-based and Sox-based toxic gas components together with smut, spraying cooling water to remove smut and mist, allowing the smut and mist-removed exhaust gas to pass through a metal-based granular catalyst 23-filled layer 19, and decomposing off the dioxins by the ion effect and by the radical corona state of the catalyst reaction.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and a device for removing dioxin by a catalytic ion / plasma reaction for decomposing and removing dioxin system in exhaust gas of an incinerator for wastes using a catalyst. is there.

[0002]

2. Description of the Related Art Dioxin is a common name for polychlorinated dibenzoparadioxin (PCDD _S ), and there are 8 kinds of homologues and 75 kinds of isomers depending on the substitution number and substitution position of chlorine. is there. Of these 75 isomers, 2,3,7,8-4 dibenzoparadioxin chloride (2,3,7,8-T ₄ CDD) has the strongest toxicity. In addition, there is polychlorinated dibenzofuran (PCDF _S ) as a compound having the same structure and properties, and there are 8 kinds of homologues and 135 kinds of isomers depending on the substitution number and substitution position of chlorine.

Generally, dioxin and furan are collectively called dioxin-based. Dioxins are widely known to have strong acute toxicity. Since the toxicity of this dioxin is greatly different among homologues and isomers, the toxicity of the most toxic 2,3,7,8-T ₄ CDD is converted and evaluated as the total toxicity. . 2,3,7,
The relative value with the toxicity of 8-T ₄ CDD as 1 is the toxicity equivalent conversion factor (TEF), and the sum of the values obtained by multiplying the measured concentration of each isomer by each TEF is the toxicity equivalent concentration (TEF).
It is called Q) and is used as an index of toxicity.

It is known that this dioxin system is generated from the exhaust gas of an incinerator for general waste or industrial waste, and various methods for removing the dioxin system generated from the incinerator from the exhaust gas have been proposed. That is, a method for lowering the temperature of the dust collector, a method for decomposing and removing a dioxin-based material, a method for removing by adsorption, and the like have been proposed. For example, this method for decomposing and removing dioxins is a method for decomposing dioxins by passing exhaust gas that has passed through an electrostatic precipitator through a catalyst-packed layer as shown in the treatment process of FIG.
As the catalyst, those based on titanium, vanadium, and tungsten denitration catalysts are generally used.

[0005]

In the conventional method for decomposing and removing dioxins described above, the higher the exhaust gas treatment temperature, the higher the catalytic activity, but the exhaust gas temperature is about 200 to 2
Since the temperature is about 30 ° C., there is a problem that the effect of the catalyst cannot be sufficiently obtained due to the attachment of soot and dust in the exhaust gas.

Further, in the conventional catalyst packed bed, the decomposition effect of dioxins by the catalyst disappears in a short time, and it is necessary to replace the catalyst in the catalyst packed bed several times a year, which makes maintenance of the processing apparatus complicated. Had the problem of being. Furthermore, the conventional decomposition and removal method using a catalyst-packed layer has a problem that the apparatus tends to be large-scale.

The present invention was devised to solve the above-mentioned problems. That is, an object of the present invention is to use a catalyst-packed bed cassette composed of a granular catalyst to decompose various toxic gases including dioxin-based catalysts, and the catalyst-packed bed cassette has excellent durability and can be used for a long period of time. Another object of the present invention is to provide a dioxin removing method by a catalytic ion-plasma reaction and a removing apparatus thereof, which can realize the downsizing of the entire dioxin removing apparatus with a compact catalyst packed bed cassette.

[0008]

According to the method for removing dioxin of the present invention, the exhaust gas discharged from the incinerator (1) is cooled and the cooled exhaust gas is sprayed with H 2
Cl, Nox, Sox and other harmful gases are neutralized and removed together with soot and dust, and then soot and mist are removed by spraying cooling water, and the exhaust gas from which this soot and mist is removed is removed. A catalyst which is characterized in that dioxins are decomposed and removed by passing through a catalyst packed bed (19) composed of a metal-based granular catalyst (23) to generate a radical corona state of the ionic effect and catalytic reaction. A method for removing dioxins by an ion-plasma reaction is provided. The granular catalyst (23) is made of platinum-based spherical metal.

Further, the catalyst packed bed (19) is irradiated with an ultraviolet beam, or the catalyst packed bed (19) is radiated.
Radical vibrations can be propagated to.

In the method of the above invention, the exhaust gas discharged from the incinerator (1) flows into the cooling tower (2) at an average temperature of 800 ° C., is cooled to about 550 ° C. and is discharged. The heat-exchanged heat energy is released as vapor into the atmosphere. The heat-exchanged white smoke-like vapor is reduced to water droplets in the steam separator, and decomposed into water and vapor. The steam is discharged, but the water is returned to the water supply tank again or is blown into the next reaction cooling tower (3) as spray reaction water. The Hcl-based harmful gas contained in the exhaust gas discharged from the incinerator (1) adversely affects the facility due to corrosion and the like. Therefore, in the reaction cooling tower (3), this Hcl-based harmful gas is converted into dust. A neutralization reaction is carried out together with the removal.

Next, the exhaust gas from which the harmful gas and soot and dust have been removed is subjected to temperature distribution and cooling water spraying, soot and soot (fly ash).
And remove the mist. Finally, the pretreated exhaust gas is
In the catalyst packed bed (19) composed of the metal-based granular catalyst (23) packed in the catalyst decomposition reaction tower (6), dioxins and Nox are decomposed and removed into a radical corona state by an ionic effect and a catalytic reaction.

According to the dioxin removing apparatus of the present invention, a cooling tower (2) having a water pipe for cooling the exhaust gas having an average temperature of 800 ° C. discharged from the incinerator (1) to about 550 ° C. A reaction cooling tower (3) having a limestone reaction tank (9) for removing harmful gas such as Hcl-based, Nox-based or Sox-based gas in the exhaust gas cooled by the cooling tower (2) and a spray nozzle (10). ), And a mist demister (4) having a backwash nozzle (16) for spraying cooling water onto the exhaust gas that has passed through the reaction cooling tower (3), and for decomposing and removing the exhaust gas from the mist demister (4) On the surface of the alumina ball (24), the catalytic reaction film (2
And (5) a catalyst-decomposing reaction tower (6) in which a catalyst packed bed cassette (19) filled with a granular catalyst (23) forming 5) is exchangeably provided, by a catalytic ion-plasma reaction. A dioxin removal device is provided. The catalyst-packed layer cassette (19) is a ball-shaped granular catalyst (23) having a catalytic reaction film (25) formed by active deposition of a white metal alloy on the surface of an alumina ball (24). The alumina balls (24) preferably have a diameter of about 5 mm to 20 mm.

Further, the catalyst decomposition reaction tower (6) is provided with an ultraviolet beam irradiation device (20) toward the catalyst packed bed cassette (19) in the device, or a catalyst packed bed cassette (20) in the device. A high frequency generator (21) can be attached to 6). Further, the catalyst decomposition reaction tower (6)
Allows a plurality of catalyst packed bed cassettes (19) to be juxtaposed.

In the removing apparatus having the above structure, since the cooling tower (2) is provided with auxiliary equipment such as a steam separator, a level sensor, and an electrothermometer, the heat-exchanged white smoke-like vapor is vaporized. It is reduced to water droplets in a water separator and decomposed into water and steam. In addition, the water is automatically supplied to the water supply tank by the level sensor so that the necessary water is always maintained.
Since the reaction cooling tower (3) is equipped with a limestone reaction tank (9) and a spray nozzle (10), harmful gas and soot are neutralized and removed. The mist system generated at this time is discharged from the mist drain (12).
Further, since a controlled and required amount of water is sprayed, unlike the conventional cleaning type scrubber, a large amount of chemical liquid is not required and a water treatment circulation tank is not required, and the exhaust gas in a dry state can be used for management.

The mist demister (4) is soot dust (fly ash).
And remove the mist. In this mist demister (4), the gas flows in at about 250 ° C., is cooled to about 200 ° C., and is discharged. In the activated carbon adsorption tower (5), soot and Hc
It is possible to adsorb harmful gases such as 1-based, Sox-based, and Nox-based gases, odors, and dioxins and process them into clean gas.

The pretreated exhaust gas is brought into contact with a catalyst packed bed cassette (19) of a platinum-based metal packed in the catalytic decomposition reaction tower (6) to be converted into a radical corona state due to an ionic effect and a catalytic reaction to form a dioxin. And Nox are decomposed and removed. In particular, since the granular catalyst (23) of the present invention has a substantially spherical shape in which the catalytic reaction film (25) in which the white metal alloy is activated and vapor-deposited is formed on the surface of the alumina ball (24), it has strong hardness and residual compression. Due to the electromagnetic characteristics from the outside due to the stress, the charged "+ ions and-ions" are in an electromagnetic (plasma) state and react with the catalytic reaction coating (25) on the surface of the alumina ball (24). In addition, the granular catalyst (23) of the present invention is photoenergy active and produces a strong oxidizing power, the exhaust gas that has flowed in is radically separated, and dioxin chemically reacts with an oxidase to be catalytically decomposed. Furthermore, in the catalytic decomposition reaction tower (6), Nox gas can also be oxidized and decomposed.

Since the catalyst packed bed cassette (19) has a compact design, it has excellent durability as a catalytic reactant and does not need to be replaced for a long period of time. Further, since it has a compact structure, it can be installed in a small site, and since it is a cassette type, it can be used for facilities with various structures.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described below with reference to the drawings. In each drawing, common parts are denoted by the same reference numerals, and redundant description will be omitted. FIG. 1 is a flow chart of processing steps of a method for removing dioxins by catalytic ion plasma reaction according to the present invention. FIG. 2 is an overall configuration diagram of an apparatus for removing dioxin by catalytic ion / plasma reaction. FIG. 3 is a system explanatory view of the temperature control of the dioxin removing device by catalytic ion plasma reaction. As shown in FIGS. 1 and 2, the method for removing dioxin of the present invention cools exhaust gas discharged from an incinerator 1 for incinerating general waste, industrial waste, etc. in a cooling tower 2 and cools it. The exhaust gas is a method of neutralizing and removing harmful gas together with soot and dust by spraying water in the reaction cooling tower 3. Next, soot and mist are removed by spraying cooling water with a mist demister 4, and the exhaust gas from which this soot and mist has been removed is treated with an activated carbon adsorption tower 5 to remove soot, Hcl-based, Sox-based, Nox-based, etc. Adsorbs and removes harmful gases, odors and dioxins efficiently. The exhaust gas pretreated in this manner is brought into contact with the granular catalyst 23 in the platinum-based metal catalyst-packed layer cassette 19 provided in the catalytic decomposition reaction tower 6 to be converted into a radical corona state due to an ionic effect and a catalytic reaction to form dioxins. , Noxes are decomposed and removed.

First, in the cooling tower 2, the exhaust gas having an average temperature of 800 ° C. discharged from the incinerator 1 is introduced, cooled to about 550 ° C., and discharged. At this time, the heat energy that has undergone heat exchange in the heat exchanger 7 is released as vapor into the atmosphere. The heat-exchanged white smoke-like vapor is reduced to water droplets in the steam separator, and decomposed into water and vapor. The steam is discharged, but the water is returned to the water supply tank again or is blown into the next reaction cooling tower 3 as spray reaction water. Reaction cooling tower 3
In the above, the Hcl-based harmful gas is neutralized and removed together with soot and dust. This is to prevent Hcl-based harmful gas contained in the exhaust gas discharged from the incinerator 1 from corroding the facility. A cyclone dust collector 8 is arranged between the heat exchanger 7 and the reaction cooling tower 3 to make it
The above-mentioned coarse particles of soot and dust are collected and removed.

Next, as shown in FIG. 3, the exhaust gas from which harmful gas and soot have been removed removes soot (fly ash) and mist by temperature distribution of each device and spraying of cooling water. . Finally, the exhaust gas is adsorbed in the activated carbon adsorption tower 5 to remove soot and Hc.
Adsorbs harmful gases such as 1-type, Sox-type, and Nox-type, odor and dioxin, and further decomposes dioxin.

The cooling tower 2 has a water-cooled steel structure of a water pipe cooling type. The cooling tower 2 has auxiliary equipment such as a steam separator, a level sensor, and an electrothermometer.
The heat-exchanged white smoke-like vapor is reduced to water droplets in the steam separator, and decomposed into water and vapor. Steam is exhausted,
The water is returned to the water supply tank again or is blown into the next reaction cooling tower 3 as spray reaction water. The water level of the water tank is automatically supplied by the level sensor so that the required water is always maintained.

FIG. 4 is a sectional view showing a reaction cooling tower constituting a dioxin removing device. Although various harmful substances are mixed in the exhaust gas discharged from the incinerator 1, particularly harmful Hcl-based gas has a problem in facility management due to corrosion and the like. Therefore, in the reaction cooling tower 3, the Hcl-based harmful gas is sprayed by the compressor 11 from the spray tank 10 of the limestone and the spray nozzle 10 for mixing, and neutralized with soot and dust to be removed. The neutralization reaction in the reaction cooling tower 3 is as shown in chemical formula 1. The mist system generated at this time is discharged from the pipe of the mist drain 12. In the reaction cooling tower 3, the gas flows in at about 550 ° C., is cooled to about 250 ° C., and is discharged.

[0023]

[Chemical 1]

The water spray nozzle 10 sprays an appropriate amount by means of a water supply pump in which the amount of water spray required for cooling the exhaust gas is set and the temperature control as shown in FIG. Because a controlled amount of water is needed,
Unlike the conventional cleaning type scrubber, it does not require a large amount of spraying of chemicals or a water treatment circulation tank, and it can be managed with exhaust gas in a dry state.

When the composition of the exhaust gas of the incinerator 1 is a dry type,
As the gas reaction and cooling method, gas cooling sprinkling and gas reaction layer are used. Limestone or slaked lime is used as the neutralizing agent.
When the composition of the exhaust gas of the incinerator 1 is a semi-dry type, slurry spray cooling is used as the gas reaction and cooling method. A slaked lime slurry is used as the neutralizing agent at this time.

FIG. 5 is a sectional view showing a mist demister that constitutes a dioxin removing device. The exhaust gas discharged from the incinerator 1 passes through the cooling tower 2 and the reaction cooling tower 3, and due to the temperature distribution and the cooling water spray, soot (fly ash) becomes a vapor-like fume state, and the fly ash of mist is generated. Occurs. Therefore, the mist demister 4 removes the soot dust (fly ash) and the mist. In this mist demister 4, the gas flows in at about 250 ° C., is cooled to about 200 ° C., and is discharged.

In this mist demister 4, the mist drain bit 13, the exhaust gas inlet 14, the lashing layer 15, the reverse cleaning nozzle 16, from the lower layer to the upper layer in the apparatus,
The special metal fiber 17 and the discharge port 18 are provided.
Further, fly ash and the like adhering to the inside of the apparatus is constantly washed by the back washing nozzle 16 and removed. The lashing layer 15 is formed by laminating ceramic short pipe-shaped contact members in order to increase the contact area between the exhaust gas and the cleaning water. The special metal fiber 17 is made of glass wool having durability to protect the inside of the apparatus from high temperature exhaust gas and high temperature washing water.

FIG. 6 is a sectional view showing a catalytic decomposition reaction tower which constitutes a dioxin removing device. FIG. 7 shows a granular catalyst, and is a partially enlarged sectional view (a) in a state of being filled in a catalyst packed bed and an enlarged sectional view (b) of one granular catalyst. FIG. 8 shows a state in which dioxin is decomposed by a catalyst, and is an explanatory view (a) showing a positional relationship between a catalyst filling layer, an ultraviolet beam and radical vibrations, and an explanatory view (b) showing a decomposition mechanism. In the catalyst decomposition reaction tower 6, a plurality of catalyst packed bed cassettes 19 are exchangeably arranged in parallel. Since the catalyst packed bed cassette 19 can be easily replaced, when the catalyst function thereof deteriorates due to long-term use, the whole catalyst packed bed cassette 19 can be easily replaced with a new one. An ultraviolet beam irradiation device 20 and a high-frequency generation device 21 are provided for each catalyst packed bed cassette 19. In the illustrated example, three catalyst packed bed cassettes 19 are arranged in parallel, but depending on the amount of exhaust gas processed,
It is possible to increase or decrease the number of the catalyst-packed bed cassette 19, the ultraviolet beam irradiation device 20, and the high-frequency generator 21 installed.

The catalyst packed bed cassette 19 is formed by packing a granular catalyst 23 having the physical properties shown in Table 1 in a case 22 made of a porous plate material. The granular catalyst 23 is formed by forming a catalytic reaction film 25 on a surface of an alumina ball 24 by active vapor deposition of a white metal alloy.
This alumina ball 24 has a diameter of 5 mm to 20 mm.
The thing of about mm was optimal. However, the size is not limited as long as it is formed in a granular shape. In this way, in the present invention, by making the shape of the catalyst into a substantially spherical shape that is larger than the particle size of soot and the like in the exhaust gas, it is possible to avoid the clogging due to the soot and the like in the exhaust gas for a long-term catalytic decomposition function. Can be maintained. The granular catalyst 23 is not limited to the spherical shape in the illustrated example, and can be modified into various shapes such as a cubic shape, a rectangular parallelepiped shape, a conical shape, and a cylindrical shape.

The catalyst decomposition reaction tower 6 is provided with an exhaust gas inlet 26, a three-stage replaceable catalyst packed bed cassette 19 and an outlet 27 in the apparatus from the upper layer toward the lower layer. The mist system generated at this time is discharged from the pipe of the mist drain 28 at the bottom. In the illustrated example, the state where the catalyst packed bed cassettes 19 are vertically arranged in three stages has been described, but this is a vertical type in consideration of a narrow space. But,
If you have a large space, you can arrange more than three rows side by side.

[0031]

[Table 1]

As shown in Table 2, the catalytic reaction film 25 formed on the surface of the alumina ball 24 of the granular catalyst 23 contains, in addition to platinum-based materials, palladium-based metals, other platinum-based metals, or titanium, nickel and tungsten. It can be formed by vapor deposition.

[0033]

[Table 2]

As shown in Table 1, the alumina balls 24 forming the granular catalyst 23 of the present invention have strong hardness and residual compressive stress, and are charged with "+ ion and -ion" due to electromagnetic characteristics from the outside. Becomes an electromagnetic (plasma) state and reacts with the catalytic reaction coating 25 on the surface of the alumina ball 24. Furthermore, it is photoenergetic and produces strong oxidizing power.
The exhaust gas that has flowed in is radical-separated, and dioxin chemically reacts with an oxidase to be catalytically decomposed. At the same time, the Nox gas can also be oxidized and decomposed. Further, since the alumina balls 24 have a substantially spherical shape, it is possible to avoid clogging due to soot and the like in the exhaust gas and maintain the decomposition catalyst function for a long period of time.

According to the method for removing dioxin by the catalytic ion-plasma reaction of the present invention, the soot and dust concentration can be calculated by the formula 1
97.5% in the reaction cooling tower 3 according to the formula shown in
And the activated carbon adsorption tower 5 has a removal rate of 99%. Further, the dioxin concentration has a decomposition and removal rate of 80% in the catalytic decomposition reaction tower 6 and a 99% removal rate in the activated carbon adsorption tower 5 according to the mathematical expression as shown in Expression 2.

[0036]

[Equation 1]

[0037]

[Equation 2]

In the above-described example, the incinerator 1, the cooling tower 2, the reaction cooling tower 3, the mist demister 4, the catalytic ion / plasma reaction 6 and the activated carbon adsorption tower 5 are arranged in this order in the removing device. The present invention is not limited to such an embodiment. For example, as shown in FIG. 9, it is possible to arrange the catalytic decomposition reaction tower 6, the mist demister 4 and the activated carbon adsorption tower 5 of the present invention in the existing exhaust gas treatment equipment. Since it can be installed and is of a cassette type, it can be used in facilities of various configurations. Further, it goes without saying that various changes can be made without departing from the scope of the present invention.

[0039]

As described above, the catalyst ion of the present invention
The method of removing dioxin by the plasma reaction can easily replace the catalyst packed bed cassette in the catalytic decomposition reaction tower, reduce the maintenance cost, and because the catalyst is spherical, it is clogged with soot and dust in the exhaust gas. By avoiding the above, it is possible to maintain the catalytic decomposition function for a long time and decompose the dioxin system for a long time.

Further, the apparatus for removing dioxin by the catalytic ion / plasma reaction according to the present invention is a dioxin removing apparatus for an existing dioxin, only by incorporating a reaction cooling tower, a mist demister or a catalytic decomposition reaction tower in the exhaust gas. Can be removed efficiently, so that the cost of equipment investment can be reduced. Further, since the entire apparatus has a compact structure, it can be installed in a small site, and since it is a cassette type, it has an excellent effect that it can be used in facilities having various structures.

[Brief description of drawings]

FIG. 1 is a flow chart of processing steps of a method for removing dioxins by catalytic ion plasma reaction of the present invention.

FIG. 2 is an overall configuration diagram of a device for removing dioxin by a catalytic ion / plasma reaction.

FIG. 3 is a system explanatory view of a temperature control of a dioxin removing device by a catalytic ion / plasma reaction.

FIG. 4 is a cross-sectional view showing a reaction cooling tower that constitutes a dioxin removing device.

FIG. 5 is a cross-sectional view showing a mist demister that constitutes a dioxin removing device.

FIG. 6 is a cross-sectional view showing a catalytic decomposition reaction tower which constitutes a dioxin removing device.

FIG. 7 shows a granular catalyst, and is a partially enlarged cross-sectional view (a) in a state of being filled in a catalyst packed layer and an enlarged cross-sectional view (b) of one granular catalyst.

FIG. 8 is a diagram showing a state in which dioxin is decomposed by a catalyst, and is an explanatory view (a) showing a positional relationship between a catalyst filling layer, an ultraviolet beam and radical vibration, and an explanatory view (b) showing a decomposition mechanism.

FIG. 9 is an overall configuration diagram showing a state in which the catalyst decomposition reaction tower of the present invention and the like are incorporated into existing exhaust gas treatment equipment.

FIG. 10 is a flow chart showing a treatment step of a conventional method for removing dioxin by a catalyst layer.

[Explanation of symbols]

1 incinerator 2 cooling tower 3 Reaction cooling tower 4 Mist demister 5 Activated carbon adsorption tower 6 Catalytic decomposition reaction tower 9 reaction tanks 10 Water spray nozzle 12 Mist drain 15 Lashing layer 16 Reverse cleaning nozzle 19 Catalyst packed bed cassette (catalyst packed bed) 20 Ultraviolet beam irradiation device 21 High frequency generator 23 Granular catalyst 24 Alumina ball 25 Catalytic reaction film

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) B01D 53/74 B01J 19/12 C 4G075 53/86 35/08 Z B01J 8/02 37/02 301P 19 / 08 B01D 53/34 134A 19/10 ZAB 19/12 132Z 35/08 53/36 G 37/02 301 (72) Inventor Isamu Kato 1-1-1 Kachidoki, Chuo-ku, Tokyo Plaza Kachidoki 1225 F Term ( (Reference) 4D002 AA02 AA12 AA19 AC04 BA02 BA04 BA09 BA11 BA14 BA16 CA01 DA05 DA11 DA12 EA02 4D032 AC07 BB07 BB08 4D048 AA11 AB03 BA03X BA07X BA27X BA30X BA31X BA32BAA03B01A01A02 BA01B01A02 BA03B01A01 BA03B01A01 BA03B01A01 CD03 DA39 CD02 CD33 CD39 CD02 CD03 CD01 CD01 CD02 CD01 BC50B BC60B BC68B BC69A BC70B BC71B BC72B BC75B DA05 EA04X EA04Y EB18X EB18Y FA01 FA03 FB02 4G070 AA01 AB01 BB06 CA01 CA30 CB19 4G075 AA03 AA37 BA05 B D14 CA23 CA33 CA47 DA01 EA01 EB09 EB31

Claims (10)

[Claims] 1. An exhaust gas discharged from an incinerator (1) is cooled, and the cooled exhaust gas is sprayed with Hcl-based N 2
Toxic gas such as ox or Sox is neutralized and removed with soot and dust, and then soot and mist are removed by spraying cooling water, and the exhaust gas from which this soot and mist is removed Through a catalyst packed bed (19) consisting of the granular catalyst (23) of
A method for removing dioxin by catalytic ion-plasma reaction, characterized in that dioxins are decomposed and removed by making the radical effect of the ion effect and catalytic reaction into a corona state. 2. The granular catalyst (23) is made of platinum-based spherical metal.
Method for removing dioxin by catalytic ion-plasma reaction of the above. 3. The method for removing dioxin by catalytic ion plasma reaction according to claim 1 or 2, wherein an ultraviolet beam is irradiated toward the catalyst packed layer (19). 4. The method for removing dioxin by catalytic ion-plasma reaction according to claim 1, 2 or 3, wherein radical vibration is propagated to the catalyst packed bed (19). 5. Average temperature 8 discharged from the incinerator (1)
A cooling tower (2) having a water pipe for inflowing the exhaust gas of 00 ° C. and cooling it to about 550 ° C., and an Hcl system in the exhaust gas cooled by the cooling tower (2), N
A reaction cooling tower (3) having a limestone reaction tank (9) and a water spray nozzle (10) for removing harmful gases such as ox-based or Sox-based cooling, and cooling to exhaust gas passed through the reaction cooling tower (3) A mist demister (4) having a backwash nozzle (16) for spraying water, and a catalytic reaction film (25) on the surface of the alumina ball (24) for decomposing and removing exhaust gas from the mist demister (4). And a catalyst decomposition reaction tower (6) in which a catalyst packed bed cassette (19) filled with the formed granular catalyst (23) is exchangeably provided.
Dioxin removal device by plasma reaction. 6. The spherical granular catalyst (2) in which the catalyst packed bed cassette (19) has a catalytic reaction film (25) formed by active deposition of a white metal alloy on the surface of an alumina ball (24).
It is what was filled up with 3), It is characterized by the above-mentioned.
Of dioxin removal by catalytic ion / plasma reaction of 7. The dioxin removing device by catalytic ion plasma reaction according to claim 5, wherein the alumina balls (24) have a diameter of 5 mm to 20 mm. 8. The catalyst decomposition reaction tower (6) is provided with an ultraviolet beam irradiation device (20) toward the catalyst packed bed cassette (19) in the device. Item 5. A device for removing dioxin by the catalytic ion plasma reaction of 6, or 7. 9. The catalyst decomposition reaction tower (6) is characterized in that a high frequency generator (21) is attached to the catalyst packed bed cassette (19) in the apparatus. A device for removing dioxins by 6, 7 or 8 catalytic ion plasma reaction. 10. The catalyst decomposition reaction tower (6) comprises a plurality of catalyst packed bed cassettes (19) arranged in parallel.
The dioxin removing device by catalytic ion plasma reaction according to claim 5, 6, 7, 8 or 9.