JPH1110114A - Waste disposal device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to efficiently remove heavy metals, an alkali metal chloride, an alkali earth metal chloride and dioxine from a fly ash with marked results. SOLUTION: This waste disposal device comprises an incinerator body 1, an exhaust gas channel 2, as a passageway for exhausting a combustion exhaust gas, which is connected to the incinerator body 1 and a bag filter 3. Further, an organic waste dry distillation furnace 4 is provided halfway through the exhaust gas channel 2. In addition, an intake duct 7 connecting the exhaust gas channel 2 with a reaction furnace 6 and a first confluence pipe 8 for making a reflux of the exhaust gas from the reaction furnace 6 into the exhaust gas channel 2 are installed on the reaction furnace 6. Before and after the bag filter 3, a filter 11 for a dry distillate and an active carbon filter 12 are provided respectively.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a processing apparatus for removing heavy metals, alkali metal chlorides, alkaline earth metal chlorides, dioxins, and the like from fly ash for detoxification.

[0002]

Of the industrial waste and waste from city life, combustibles are collected and then incinerated in an incinerator to be disposed of in the form of incinerated ash for dumping and burial disposal. . On the other hand, when such waste is burned, the low-boiling substances in the various components are volatilized to form so-called fly ash, which is more lead, cadmium, chromium, zinc, arsenic than the incinerated ash. Since it contains a lot of heavy metals such as mercury, it cannot be landfilled as general waste, and is collected by a bag filter carrying slaked lime or the like so as not to diffuse as a combustion gas into the external environment. Since such fly ash contains a large amount of heavy metals as described above, it must be strictly controlled for environmental hygiene. They have been dumped at disposal sites.

However, in recent years, the amount of industrial waste and waste from general households has been increasing steadily, and it has become difficult to secure land for disposal sites due to saturation of existing disposal sites and problems of environmental pollution. The use of concrete compacts containing incinerated ash, fly ash, etc. as a foundation is being considered, but heavy metals sealed in concrete compacts in a state insolubilized in water, such as acid rain In consideration of the influence of water, it is not necessarily stabilized, and there is a concern about environmental pollution due to elution of heavy metals, so that it is not suitable for reuse. For this reason, it has become necessary to sufficiently remove heavy metals from fly ash.

By the way, for example, when burning plastic garbage or the like, chlorine gas or dioxin is generated by chlorine-containing plastics such as polyvinyl chloride, and if this diffuses into the external environment such as the atmosphere or soil, it is serious. May cause environmental pollution. For this reason, chlorine gas and dioxin are currently trapped by the above-mentioned bag filter.However, dioxin is so highly toxic that it is not desirable to leak it to the external environment even in trace amounts. More stringent collection means are desirable. For collecting such dioxins, a filter using activated carbon is effective, but in order to actually collect dioxins to a concentration sufficiently low so as not to affect the external environment, a large amount of activated carbon was used. It is necessary to use a large-scale filter while replacing it successively, and there is a problem that the current waste treatment system is not practical in terms of cost.

As a method of removing heavy metals from the incinerated ash or fly ash as chlorides, Japanese Patent Application Laid-Open No.
Japanese Patent No. 3965 discloses a method of incinerating waste containing heavy metals and treating the combustion exhaust gas with a bag filter. The waste before incineration is mixed with chloride and incinerated, and the heavy metals in the waste are converted into metal chlorides. A method for treating waste which disperses into a flue gas and sprays a heavy metal collecting agent into the flue gas to remove a metal chloride of the heavy metal with a bag filter is disclosed.

[0006] However, in this waste treatment method, a large amount of chloride is mixed in the waste before incineration, and then incineration is performed. Therefore, there is a problem that generation of harmful dioxins is concerned. . Further, the incineration process of converting heavy metals into metal chlorides is performed at 800 to 900 ° C. At such a high temperature, heavy metals not only react with chlorides, but lead reacts with silicon dioxide, for example. It reacts with silicon oxides, such as lead silicate, and also exists as a silicate compound. Since the silicate compound such as lead silicate has a high boiling point of, for example, about 1700 ° C., it is difficult to remove the silicate compound, and there is a problem that heavy metals cannot be completely removed.

Japanese Patent Application Laid-Open No. 7-214029 discloses that incinerated ash or fly ash containing a heavy metal is heat-treated in the presence of at least 2% by weight of chloride in terms of chlorine to convert the heavy metal component into chloride. After the first step of concentrating heavy metals in fly ash by volatilization, and dissolving the obtained fly ash in an aqueous liquid, and further neutralizing the heavy metals to collect them in a solid precipitate, There is disclosed a method of recycling heavy metals by detoxifying incinerated ash or fly ash, comprising a second step of performing solid-liquid separation and recovering heavy metal components in solid precipitates.

[0008] However, this method of recycling heavy metals has not solved the problem of removing dioxin efficiently and effectively. Moreover,
In this conventional technique, heavy metals are heat-treated in the presence of chloride to form metal chlorides. However, in order to react heavy metals with chlorides, electric furnaces, arc furnaces, burner furnaces, plasma furnaces and the like are also used. Since it is necessary to heat to 800 to 900 ° C. in a low-frequency furnace or a high-frequency furnace, not only heavy metals react with chlorides, but also with silicon oxides such as silicon dioxide, resulting in silicon dioxide. There is a problem that removal of the acid compound becomes difficult. Further, Na is used to neutralize calcium hydroxide contained in fly ash.
The problem is that chlorides such as Cl are required in a much larger amount than those reacting with heavy metals, and in the long term, more chlorides are used, which leads to an increase in the amount of chlorides remaining during the treatment cycle. There was a point.

Further, Japanese Patent Application Laid-Open No. 8-35018 discloses a method for recovering metal from fly ash containing chlorine generated by combustion of waste as CaCl ₂ immobilized therein. Heat is applied while applying a shearing force in an oxidizing atmosphere to cause chlorine and hydrogen chloride generated by the decomposition of CaCl ₂ to react with the metal component contained in the fly ash. And c) dissolving and recovering by contacting with an absorbing solution, and c) a method for recovering dissolved metals from fly ash by separating and recovering dissolved metals from the obtained recovered solution.

However, even in this method of recovering metals from fly ash, there is no special means for solving the problem of efficiently and effectively removing dioxin. Moreover, in this prior art, Ca
Since it reacts chlorine-based gas such as chlorine and hydrogen chloride obtained by decomposing Cl ₂ with metal components,
In order to decompose aCl ₂ , it is necessary to heat to 600 to 1000 ° C., but there is a problem that CaCl ₂ does not decompose at 600 to 1000 ° C. depending on its atmosphere. At a high temperature of 600 to 1000 ° C., the reaction between heavy metals and silicon oxide such as silicon dioxide cannot be completely prevented, so that heavy metals cannot always be sufficiently removed. Further, in this conventional technique, CaCl ₂ contained in fly ash is used as a chlorine-based gas source.
Since fly ash contains calcium hydroxide (Ca (OH) ₂ ) in addition to CaCl ₂ , heavy metals are reduced to CaCl ₂ at high temperatures of 600 to 1000 ° C.
_After reacting with ₂ to form chloride, the chloride of heavy metals generated by reacting with Ca (OH) ₂ may be converted to hydroxide. Furthermore, when chlorine and hydrogen chloride generated by the decomposition of CaCl ₂ react with Ca (OH) ₂ , the amount of chlorine and hydrogen chloride may be insufficient to convert all heavy metals into chloride. In order to prevent such harmful effects due to calcium hydroxide, it is necessary to add chlorine in excess of Ca (OH) ₂ , and therefore, a chlorine source such as NaCl has been further added. As a result, as Ca (OH) ₂ accumulates during the processing cycle, the chlorine source such as NaCl added in the long term increases, and the amount of chloride during the processing cycle increases. there were.

The present invention has been made in view of the above-mentioned problems, and is capable of efficiently and effectively removing heavy metals, alkali metal chlorides, alkaline earth metal chlorides, dioxins and the like from fly ash. An object of the present invention is to provide a waste treatment device.

[0012]

According to a first aspect of the present invention, an organic waste carbonization furnace and a bag filter are sequentially disposed in a discharge path of combustion exhaust gas discharged from an incinerator body. On the other hand, a reactor for heating the fly ash collected by the bag filter and a merging pipe for introducing exhaust gas from the reactor to the discharge path are provided, and the organic waste is disposed before or after the bag filter. A filter made of carbide or carbon generated in a dry distillation furnace is provided.

By adopting such a configuration, a carbonization furnace for carbonizing organic waste is provided in a discharge path of combustion gas from the incinerator main body. Therefore, the carbonization of organic waste is performed by the calorific value of the combustion gas. Things can be created. And the filter using the carbonized matter generated in this way exhibits a function like activated carbon, so by providing this before or after the bag filter, dioxin and other fine particles can be efficiently and effectively removed. Can be removed. In addition, this filter is inexpensive because it uses carbide or carbon produced in a carbonization furnace, and can be used in large quantities because it can be produced during the incineration cycle.

According to a second aspect of the present invention, there is provided a waste treatment apparatus, wherein the reactor is provided with an inlet pipe for introducing combustion exhaust gas from the discharge path. Therefore, heavy metal compounds contained in fly ash and chlorine-based gas such as chlorine gas or hydrogen chloride gas contained in exhaust gas react directly or indirectly to convert heavy metals into chloride. As a result, the efficiency of volatilization and removal of not only dioxins but also heavy metals can be improved.

In a third aspect of the present invention, there is provided a waste treatment apparatus for melting a fly ash treated in the reactor at a higher temperature to form a slag, and discharging the molten exhaust gas from the melting furnace to the exhaust gas. And a merging pipe introduced into the path. For this reason, dioxin and the like contained in the molten exhaust gas from the melting furnace can also be efficiently and effectively removed by the filter using carbide or carbon.

Further, the waste treatment apparatus of claim 4 is
A filter made of the above-mentioned carbide or carbon is disposed in a merging pipe from the reactor or a merging pipe from a melting furnace. For this reason, dioxin and the like contained in the exhaust gas from the reaction apparatus and the molten exhaust gas from the melting furnace can be quickly collected by a filter made of carbon or carbon in a merging pipe serving as an outlet thereof.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the apparatus for treating fly ash waste according to the present invention will be described in detail. First, the waste to be treated in the present invention refers to the entire waste such as industrial waste and general waste, and is disposed by burning in an incineration plant. Further, in the present invention, fly ash, the above-mentioned waste, when incinerated, low-boiling substances in various components of the waste are volatilized, and this is collected by a filter or the like. Lead, compared to
It contains a lot of heavy metals such as zinc, arsenic, and mercury. Since this fly ash is collected from the combustion exhaust gas of the waste by a bag filter carrying slaked lime (calcium hydroxide), slaked lime (calcium hydroxide) and its neutralized calcium chloride are contained in the components. Contains a lot of Further, in addition to the heavy metals and calcium chloride, they contain a large amount of alkali metal chlorides such as sodium chloride and potassium chloride, and alkaline earth metal chlorides other than calcium chloride. Although the present invention basically deals with this fly ash, incineration ash generated from a municipal waste incineration plant, a groundwater treatment plant or an industrial waste treatment plant,
Other components such as sludge may be contained. Further, in the present invention, the organic waste is waste mainly composed of a compound containing carbon and hydrogen, and is classified into a synthetic product such as plastic and a natural product such as waste wood and food waste. They are roughly classified, and any of these can be used. In the present invention, it is preferable to use a natural product because the amount of harmful substances contained in the exhaust gas generated when the organic waste is carbonized is small. As this natural organic waste,
Wood chips, fir husks, soybean scum, coffee bean scum, corn starch, and other food material squeeze can be used. Such a natural organic waste may be collected, for example, free of charge from a manufacturer or a farmer who uses the above-described food.

Next, a waste treatment apparatus according to the present invention using the above-described various substances will be described. FIG. 1 is a schematic view showing a waste treatment apparatus according to one embodiment of the present invention. As shown in FIG. 1, the waste treatment apparatus includes an incinerator main body 1 and a flue gas communicated with the incinerator main body 1. An exhaust gas passage 2 serving as an exhaust passage for the fuel cell and a bag filter 3. An organic waste dry distillation furnace 4 is provided in the exhaust gas passage 2. Reference numeral 5 denotes an ash bunker for storing fly ash collected by the bag filter 3 and the like. The ash bunker 5 is provided with a heating means, a pressure reducing means, a control mechanism, and the like from the ash bunker 5 via a supply device (not shown). Fly ash is supplied to a reaction furnace 6 as a reaction device. The reactor 6 includes an inlet pipe 7 and a first
The exhaust gas in the reactor 6 is returned to the exhaust gas channel 2 from the first junction tube 8 while the combustion exhaust gas is allowed to flow in from the introduction pipe 7. It is possible. These introduction pipe 7 and first merging pipe 8
Each is provided with an opening / closing valve, a check valve, etc., so that the flow of each gas does not go backwards and can be opened and closed as needed. Further, the solid residue S in the reaction furnace 6 is configured to be supplied to a melting furnace 9 via a feeder (not shown).
Is provided to join the molten exhaust gas to the exhaust gas channel 2. In the waste treatment apparatus as described above, a filter 11 made of carbide and carbon and an activated carbon filter 12 are provided before and after the bag filter 3, respectively. System waste carbonization furnace 4
Also communicates with. Reference numeral 13 denotes a cooling device provided in the first merging pipe 8.

The operation of the above configuration will be described. First, waste is burned in the incinerator body 1. On this occasion,
The above-mentioned organic waste is put into the organic waste dry distillation furnace 4 in advance. The combustion exhaust gas of the waste incinerated in the incinerator main body 1 has a temperature of about 300 to 600 ° C., which flows through the exhaust gas passage 2, so that the organic waste is carbonized and carbonized with activated carbon while being activated. Become. This carbide and carbon
Exhibits the function of activated carbon. At this time, zinc chloride, phosphoric acid, or the like may be appropriately added as an activator to the organic waste. Then, the carbonized material obtained in this manner is subjected to filter 11 (hereinafter, referred to as a carbonized material filter).
Fill and use.

On the other hand, fly ash collected by the bag filter 3 is stored in an ash bunker 5 and supplied from the ash bunker 5 to a reaction furnace 6. Thereafter, the introduction pipe 7 and the first merging pipe 8 are opened, and the combustion exhaust gas G flowing through the exhaust gas flow path 2 is introduced into the reaction furnace 6. After the combustion exhaust gas G circulates in the reaction furnace 6, the exhaust gas G is discharged from the first merging pipe 8 and is discharged from the exhaust gas passage 2.
Therefore, new combustion exhaust gas flows from the introduction pipe 7 into the reaction furnace 6 one after another. By introducing the combustion exhaust gas G into the reaction furnace 6 as described above, the following effects can be obtained. In other words, when burning waste, a large amount of chlorine-based gas such as chlorine and hydrogen chloride is generated. Therefore, in order to prevent this from diffusing into the external environment, it is usually collected by a bag filter carrying slaked lime (calcium hydroxide). ing. The present invention utilizes the exhaust gas of an incinerator rich in chlorine-based gas as a chlorine source, and reacts the chlorine-based gas in the exhaust gas with the heavy metal compound in the fly ash to remove the heavy metal chloride. Cause. For example, the following reaction occurs between hydrogen chloride or chlorine gas and oxides of heavy metals (M).

MO + 2HCl → MCl ₂ + H ₂ O 2MO + 2Cl ₂ → 2MCl ₂ + O ₂ The sulfate of heavy metals (M) reacts as follows by contact with calcium chloride.

MSO ₄ + CaCl ₂ → MCL ₂ + CaSO _{4 In} this reaction, calcium chloride is originally contained in fly ash, or is generated by reaction of calcium hydroxide with chlorine-based gas in exhaust gas.

By flowing exhaust gas from an incinerator at a temperature of 600 ° C. or less, heavy metal compounds are chlorinated without reacting with silicon oxide or the like.
In addition, as described above, due to the presence of chlorine-based gas, calcium hydroxide (Ca (OH) ₂ ) contained in fly ash is converted into calcium chloride, and the calcium chloride contacts and reacts with sulfates of heavy metals. Thus, the sulfated oxide of heavy metals can be chlorinated. The exhaust gas from the incinerator contains sulfur oxide-based gas such as SO ₂ or NO
Such nitric oxide-based gases are also included, and they may also react with heavy metals to form nitrates or sulfates of heavy metals.Nitrate or sulfate of these heavy metals may be used as described above. Reacts with chlorine gas and calcium chloride to form heavy metal chlorides.

The flow rate of the exhaust gas as described above is preferably about 1 to 5 parts by weight in terms of chlorine with respect to 100 parts by weight of fly ash. If the amount of exhaust gas is less than 1 part by weight in terms of chlorine, it is difficult to chlorinate without leaving any heavy metals. On the other hand, if the amount exceeds 5 parts by weight, no more effect can be obtained. It is not preferable because the amount is too large and the apparatus becomes overwhelming or the processing time becomes long.

The time for flowing the exhaust gas through the fly ash depends on the amount of the fly ash to be treated, but is preferably 10 minutes or more. If the exhaust gas circulation time is less than 10 minutes, the heavy metals in the fly ash may not be sufficiently reacted with the chlorine-based gas in some cases. In consideration of the processing efficiency and the like, it is particularly preferable that the heating time is about 10 to 60 minutes.

In the present invention, the fly ash can be kneaded with water as a pre-treatment for flowing exhaust gas of 600 ° C. or less through the fly ash. The water is not limited to pure water, and may be sewage or steam as long as water can be supplied to fly ash. When the fly ash is kneaded with water in the presence of calcium hydroxide in this way, compounds such as heavy metals, oxides, sulfides and silicate compounds in the fly ash quickly react with calcium hydroxide. , Forming hydroxides and basic carbonates of heavy metals. For example, the following reaction occurs between lead sulfide and calcium hydroxide.

PbSO ₄ + Ca (OH) ₂ → CaSO ₄
+ Pb (OH) ₂ Other heavy metals also react with calcium hydroxide by a similar reaction to form hydroxides and the like. If fly ash collected by a conventional bag filter or the like is used as a concrete compact, heavy metals easily become hydroxides and become water-soluble, so that the elution of heavy metals has become a problem. Heavy metals easily react with calcium hydroxide to form hydroxides. The heavy metal hydroxide easily reacts with the chlorine-based gas in the exhaust gas to form a heavy metal chloride. Compounds of heavy metals, even if different compounds such as oxides and sulfates, can react sufficiently with chlorine-based gas in exhaust gas if they have enough time. After performing chlorination, a difference in reactivity with chlorine-based gas between compounds of different heavy metals such as oxides and sulfates can be eliminated. Further, there is an effect that the fine powdered fly ash is aggregated in a substantially granular form to improve the handleability. In particular, blow-up of fly ash under reduced pressure conditions described later can be suppressed.

The mixing ratio of fly ash and moisture is not particularly limited as long as it can be kneaded, but may be 3 to 100 parts by weight of water with respect to 100 parts by weight of fly ash. If the water content is less than 3 parts by weight, sufficient kneading properties and the effect of hydroxylating heavy metals cannot be obtained. On the other hand, if the water content exceeds 100 parts by weight, the water content becomes too large and the efficiency of the heating step described below decreases. In the case of wet ash (moist ash), it can be used as it is as long as the ratio of water to fly ash is within the above range.

When the heavy metals in the fly ash are chlorinated in this way, the inlet pipe 7 is closed and the temperature in the reactor 6 is reduced to 600
The first volatile component G1 is discharged from the first merging pipe 8 by raising the temperature to not less than 850 ° C. and less than 850 ° C.
To collect chlorides of heavy metals. Subsequently, the temperature in the reaction furnace 6 is set to 850 ° C. or more and 1200 ° C.
By raising the temperature below, the second volatile component G2 is discharged from the first merging pipe 8, and is cooled by the cooling device 13, so that the alkali metal chloride or alkaline earth metal chloride (hereinafter, alkali metal chloride) is discharged. Chloride, etc.).
In this manner, heavy metals and alkali metal chlorides can be separated and collected.

The volatilization and recovery of the heavy metal chlorides and alkali metal chlorides as described above can be performed under reduced pressure. By performing the volatilization recovery under reduced pressure, the volatilization temperature of chlorides of heavy metals, alkali metal chlorides and the like is reduced, and the removal efficiency can be greatly improved and the time required for removal can be reduced. it can. The reduced pressure condition as described above does not need to be a high reduced pressure, and may be a reduced pressure of about 100 to 500 mmHg. Such a decompression function can be easily provided by providing the incinerator 6 with a suction pipe (not shown) connected to a pump, an induction fan, or the like.

On the other hand, the solid residue S remaining in the incinerator 6 is
Since heavy metals and alkali metal chlorides are removed and made harmless, they can be used as such as cement raw materials (in FIG. 1). Further, it is supplied to a melting furnace 9 such as an arc furnace or a plasma furnace and further heated to a high temperature, specifically, about 1200 to 1600 ° C., so that it hardly contains heavy metals, alkali metal chlorides and alkaline earth metal chlorides. It can be a slag (in FIG. 1). The molten exhaust gas g from the melting furnace 9 is returned to the exhaust gas channel 2 from the second merging pipe 10.

Thus, the flue gas G from the incinerator body 1, the flue gas G from the reactor 6, and the flue gas g from the melting furnace 9
All flow through the exhaust gas flow path 2, and the filter 11, bag filter 3 and activated carbon filter 12
The fly ash component is removed by the bag filter 3 and the filter 11 made of carbonized matter and the activated carbon filter
12 can collect dioxins and the like. In particular, the carbonized material used for the filter 11 is inexpensive because it is produced in the treatment cycle in the organic waste carbonization furnace 4 as described above, and the amount thereof is sufficiently abundant. A sufficient amount of the distillate enough to function as activated carbon can be used for the filter 11 with the distillate, and the filter 11 can be frequently replaced. For example, as shown in FIG. 2, the filter 11 made of these dry distillates has a structure in which a plurality of cartridges 21A, 21B, 21C... Are connected. If the cartridges 21 are successively replaced by removing them every period and assembling a new cartridge 21X to the terminal side and sequentially moving up, the dioxin collecting performance can be maintained at a high level. Bag filter 3 and activated carbon filter 12
Since the filter 11 made of dry distillate is disposed on the upstream side of the filter, the service life of these filters 3 and 12 can be lengthened, which is also economical.

As described above, according to the waste treatment apparatus of the present invention, dioxin removal efficiency is high and economical efficiency is excellent, and heavy metals, alkali metal chlorides and alkaline earth metal chlorides are removed. Fly ash or its slag can be provided. Such fly ash or its slag is suitable for being mixed with Portland cement, sand, gravel or the like to form a concrete molded body. In particular, in the present invention, the content of not only heavy metals but also sodium oxide and potassium oxide is reduced, so that it is suitable for use as a part of a cement raw material.
Since the heavy metals in the fly ash have been removed from the concrete molded body thus obtained, there is no risk of elution of these heavy metals. In addition, since alkali metal chlorides and alkaline earth metal chlorides are also removed, the strength of the concrete molded body does not decrease or become brittle due to salt damage. , Specifically roads, buildings, grounds,
It can be used effectively as a base for stadiums.
In addition, by drawing an appropriate color or pattern with a concrete paint on the concrete block, or adding a colorant at the time of kneading with Portland cement, by arranging this concrete to obtain a desired color or pattern. It can also be reused as a landscape material.

Although the waste disposal apparatus of the present invention has been described with reference to the accompanying drawings, the present invention is not limited to this, and various modifications can be made without departing from the spirit of the present invention. . For example, in FIG. 1 described above, the filter 11 made of carbonized matter and the activated carbon filter 12 are provided, but it is not always necessary to provide both.
May be further used as a filter 11 made of carbonized matter. Also, as shown in FIG. 3, the first merging pipe 8 and the second merging pipe
10 may be provided with filters 14 and 15 made of carbonized matter. With such a configuration, dioxin and the like contained in the exhaust gas from the reaction furnace 6 and the molten exhaust gas from the melting furnace 9 are subjected to dry distillation in the first joining pipe 8 and the second joining pipe 10 serving as outlets. The material can be quickly collected by the filters 14 and 15.

[0035]

According to a first aspect of the present invention, there is provided a waste treatment apparatus in which an organic waste carbonization furnace and a bag filter are sequentially arranged in a discharge path of a combustion exhaust gas discharged from an incinerator body, while the bag filter is disposed. A reactor for heat-treating the fly ash collected by the filter, and a merging pipe for introducing exhaust gas from the reactor to the discharge path are provided, and before or after the bag filter, in the organic waste carbonization furnace. Because it is arranged with a filter by generated carbide or carbon,
A large amount of carbide or carbon can be used for the filter and can be replaced frequently.
Thereby, dioxin and other fine particles can be efficiently and effectively removed.

In the waste treatment apparatus according to the second aspect of the present invention, since the reactor is provided with an inlet pipe for introducing combustion exhaust gas from the discharge path, the efficiency of volatilization and removal of not only dioxins but also heavy metals is provided. Can be improved.

In a third aspect of the present invention, there is provided a waste treatment apparatus for melting a fly ash treated in the reactor at a higher temperature to form a slag, and discharging the molten exhaust gas from the melting furnace to the exhaust gas. Since it has a merging pipe to be introduced into the path, dioxin and the like contained in the molten exhaust gas from the melting furnace can also be efficiently and effectively removed by a filter made of carbide or carbon.

Further, the waste disposal apparatus according to claim 4 is
Since the filter made of the carbide or carbon is disposed in the merging tube from the reactor or the merging tube from the melting furnace, dioxin or the like contained in the exhaust gas from the reactor or the molten exhaust gas from the melting furnace is discharged from the outlet. Can be quickly collected by the filter in the junction tube.

[Brief description of the drawings]

FIG. 1 is a system diagram showing one embodiment of the present invention.

FIG. 2 is a schematic view showing a filter 11 made of the dry distillate of the embodiment.

FIG. 3 is a system diagram showing another embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Incinerator main body 2 Exhaust gas flow path (discharge path) 3 Bag filter 4 Organic waste dry distillation furnace 6 Reactor (reactor) 7 Introductory pipe 8 First merge pipe (Merge pipe) 9 Melting furnace 10 Second merge Pipe (merging pipe) 11 Filter by dry distillate (filter by carbide or carbon) 12 Activated carbon filter 14.15 Filter by dry distillate

Claims (4)

[Claims] 1. A reaction apparatus for sequentially disposing an organic waste carbonization furnace and a bag filter in a discharge path of combustion exhaust gas discharged from an incinerator body, and heat-treating fly ash collected by the bag filter. And a merging pipe for introducing the exhaust gas from the reactor into the discharge path, and a filter made of carbon or carbon generated in the organic waste carbonization furnace is arranged before or after the bag filter. Waste treatment equipment. 2. The waste treatment apparatus according to claim 1, wherein an introduction pipe for introducing the combustion exhaust gas from the discharge path is provided in the reactor. 3. A melting furnace for melting the fly ash treated in the reactor at a higher temperature to form slag, and a merging pipe for introducing a molten exhaust gas from the melting furnace into a discharge path of the exhaust gas. The waste disposal apparatus according to claim 2, wherein 4. The waste treatment apparatus according to claim 3, wherein the filter made of the carbide or carbon is disposed in a merge pipe from the reactor or a merge pipe from a melting furnace.