JP3403722B1 - Treatment method of harmful substances using soil melting and solidification method - Google Patents

Abstract

An object of the present invention is to provide a method for advantageously decomposing an organic compound in soil contaminated with the organic compound by utilizing a soil melting and solidification method. SOLUTION: A filling step of filling a soil contaminated with an organic compound into a heat-resistant container having an opening at the top, which is movably arranged on the ground, heating and melting the soil to thermally decompose the organic compound. Decomposition treatment of organic compounds using a soil melting and solidification method including a heating and melting step to remove decomposition products as gaseous substances, and a cooling and taking out step of cooling the melted soil to a vitrified body and removing it from the heat-resistant container Method.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for decomposing organic compounds by utilizing a soil melting and solidifying method. The present invention also relates to a method for immobilizing radioactive material utilizing the soil solidification method. The present invention also relates to a heating and melting apparatus that can be suitably used for heating and melting soil or synthetic minerals, and a heat resistant container that can be preferably used for performing the heating and melting.

[0002]

2. Description of the Related Art In recent years, soils and solids contaminated with harmful substances that have a negative effect on the human body and the environment have become a problem. For example, around the municipal waste incinerator, soil contaminated by dioxins that are unintentionally generated due to the incineration of garbage or solid matter such as incineration ash and fly ash has become an environmental problem. . In addition, soil contaminated by organic compounds that have been used as pesticides such as p, p'-dichlorodiphenyltrichloroethane (DDT) has become a problem. Furthermore, the treatment of solid matter (radioactive waste) contaminated with radioactive substances emitted from nuclear power plants is also a problem.

As one of the methods for treating soil or solid matter polluted with the above organic compounds and radioactive waste, a method utilizing a soil melting and solidifying method is known. For example, in Japanese Examined Patent Publication (Kokoku) No. 2-43847, two or more electrodes are embedded in the soil in which radioactive waste is embedded, and Joule heat generated by passing an electric current between the electrodes is used to remove the soil. Disclosed is a method of immobilizing a radioactive substance that is heated and melted, and then the melted soil is cooled to a vitrified body and the radioactive substance in the radioactive waste is confined in the vitrified body.

In the soil polluted with an organic compound, the soil is heated and melted to thermally decompose the organic compound, the decomposition products are removed as a gaseous substance, and the molten soil is cooled to be a vitrified body. Decomposition products of organic compounds are decontaminated with a gas furnace consisting of a heating furnace such as a thermal oxidizer, a dust remover such as a Venturi scrubber, a HEPA filter and an activated carbon filter, and become harmless gas (eg carbon dioxide). Exhaust into the atmosphere. Further, in the case of a solid substance contaminated with an organic compound, the contaminated solid substance is heated together with the soil to melt the soil and thermally decompose the organic compound.

[0005]

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention The treatment of soil or solid matter contaminated with organic compounds and solid matter contaminated with radioactive substances using the soil melting and solidification method is a problem (in- Situ) is generally performed. However, when the treatment is carried out at each place where pollution is a problem, there is a problem that it takes time to install a heating and melting apparatus for soil and the like. In particular, when performing decomposition treatment of organic compounds, the organic compounds volatilize,
In order to prevent the diffusion, it is common to take in the surroundings of the contaminated soil to be treated with a metal plate having low gas permeability, but there is a problem that the work also takes time.

[0006] It is an object of the present invention to provide a method for industrially advantageously decomposing organic compounds by utilizing the soil melting and solidification method. Another object of the present invention is to provide a method for industrially advantageously fixing radioactive substances by utilizing the soil melting and solidification method. Another object of the present invention is to provide a heating and melting apparatus that can be preferably used for heating and melting the soil, and a heat resistant container that can be preferably used for performing the heating and melting.

[0007]

According to the present invention, a heat-resistant container movably arranged on the ground and having an opening at the top is filled with soil contaminated with an organic compound, and the soil is heated and melted. Soil melting and solidification including a heating and melting step of thermally decomposing the organic compound and removing the decomposition products as gaseous matter, and a cooling and extracting step of cooling the molten soil into a vitrified body and then taking it out of a heat resistant container. There is a method for decomposing organic compounds using the method. Here, in the present invention, the term “soil” means an inorganic substance generated by decomposition of rocks or the like on the surface of the crust, and it does not matter whether or not an organic substance such as a corrosive substance is present.

The present invention also relates to a filling step of filling a solid material contaminated by an organic compound together with soil or synthetic minerals into a heat-resistant container movably arranged on the ground and having an opening at the top, and the solid material is soiled. Alternatively, by heating with a synthetic mineral, the soil or the synthetic mineral is melted, the organic compound is also thermally decomposed, and the heating and melting step of removing the decomposition product as a gaseous substance, and the molten soil or the synthetic mineral. there is also the cracking process of organic compounds using a soil vitrification method comprising the cooling takeout step of taking out from the cooled heat-resistant container as vitrified. Here, the synthetic mineral in the present invention means an artificially produced mineral. Zeolite can be mentioned as an example.

The present invention further comprises a soil-resistant or synthetic mineral and an organic compound or a liquid, powder or lump containing the organic compound in a heat-resistant container movably arranged on the ground and having an opening at the top. Filling step for filling the mixture, heating the mixture to melt the soil or the synthetic minerals, and at the same time, to thermally decompose the organic compound and remove the decomposition products as gaseous matter, and to melt There is also a method of decomposing an organic compound using a soil melting and solidifying method including a cooling and taking out step of taking out from a heat-resistant container after cooling a soil or a synthetic mineral into a vitrified body.

In the method for decomposing an organic compound according to the present invention, the filling step, the heating and melting step, and the cooling and extracting step may be carried out after the heat-resistant container is moved and arranged at different positions. preferable. Then, it is preferable to prepare two or more heat-resistant containers and perform the filling step, the heating and melting step, and the cooling and extracting step in parallel. In this case, the heat-resistant container is equipped with wheels, and it is preferable to move the heat-resistant container to the place where the filling step, the heating / melting step, and the cooling / unloading step are performed by the wheels.

In the decomposition treatment method of the present invention, the heating and melting of the soil in the heating and melting step is preferably performed by utilizing Joule heat generated by passing an electric current between two or more electrodes embedded in the soil. For example, the heating and melting of the soil in the heating and melting step, fixed on the ground, two or more columnar electrodes for supplying an electric current to the soil, a hood for covering the opening of the heat-resistant container, and the electrode. It is preferable to use a heating and melting apparatus that is an electric energy supply apparatus that supplies electric energy. When using this heating and melting device, the hood has an exhaust port,
It is preferable to include a step of heat-treating the decomposition product of the organic compound discharged from the exhaust port.

In the decomposition treatment method of the present invention, the heat-resistant container is composed of a bottom plate and a side plate removably installed on the bottom plate, and the inside surface of the heat-resistant container is filled before the filling step. To form a granular refractory layer consisting of granular refractory, take out the vitrified body in the cooling and taking out step, separate the bottom plate and the side plate of the heat-resistant container, and turn the granular refractory layer into granular refractory. It is preferable to carry out by breaking.

The present invention also relates to a filling step of filling a solid substance contaminated by a radioactive substance together with soil or synthetic minerals into a heat-resistant container movably arranged on the ground and having an opening at the top, and the solid substance is soiled. Alternatively, by heating with a synthetic mineral, a heating and melting step of melting the soil or the synthetic mineral, and cooling the molten soil or the synthetic mineral into a vitrified body, and confining the radioactive substance in the vitrified body, There is also a method of immobilizing radioactive materials using a soil melting and solidifying method including a cooling and extracting step of taking out from a heat resistant container.

Also in the radioactive substance immobilization method of the present invention, the heat-resistant container is moved through the filling step, the heating / melting step, and the cooling / extracting step in the same manner as in the above-mentioned method for decomposing an organic compound. It is preferable to carry out after arranging in different places different from each other. Then, it is preferable to prepare two or more heat-resistant containers and perform the filling step, the heating and melting step, and the cooling and extracting step in parallel. In this case, the heat-resistant container is equipped with wheels, and it is preferable to move the heat-resistant container to the place where the filling step, the heating / melting step, and the cooling / unloading step are performed by the wheels.

Also in the immobilization method of the present invention, the heating or melting of the soil or the synthetic mineral in the heating and melting step,
It is preferable to use Joule heat generated by passing an electric current between two or more electrodes embedded in soil or synthetic minerals . For example, for heating and melting the soil or the synthetic mineral in the heating and melting step, two or more columnar electrodes fixed on the ground for supplying an electric current to the soil or the synthetic mineral , and for covering the opening of the heat-resistant container It is preferable to use a heating and melting apparatus including a hood and an electric energy supply apparatus for supplying electric energy to the electrode.

Also in the immobilization method of the present invention, a container having a bottom plate and a side plate removably installed on the bottom plate is used as the heat-resistant container, and the heat-resistant container is filled with the heat-resistant container before the filling step. Form a granular refractory layer consisting of granular refractory on the inner surface, and take out the vitrified body in the cooling take-out step,
It is preferable to separate the bottom plate and the side plate of the heat resistant container and break the granular refractory layer into granular refractories.

The present invention is further installed and fixed on the ground,
Two or more columnar electrodes for supplying electric current to soil or synthetic minerals filled in a heat-resistant container having an opening at the top,
There is also an electric energy supply device for supplying electric energy to the electrode, and a heating and melting device for soil or synthetic minerals, which comprises a hood covering the heat-resistant container. It is preferable that the heating and melting apparatus has a gas treatment apparatus in which the hood has a gas introduction port and an exhaust port and is connected to the gas introduction port, and a heating furnace connected to the exhaust port. .

The present invention also resides in a heat-resistant container for heating and melting soil or synthetic minerals, which comprises a bottom plate and a side plate removably installed on the bottom plate, the bottom plate having wheels. This heat-resistant container preferably has a granular refractory layer formed of a granular refractory material on its inner surface.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION First, a method for decomposing an organic compound according to the present invention will be described. In the method of the present invention, the organic compound to be decomposed is not particularly limited. The method of the present invention is particularly useful for decomposing a chlorine atom-containing organic compound. As typical examples thereof, hexachlorobenzene (HCB), hexachlorocyclohexane (BHC), p, p'-dichlorodiphenyltrichloroethane (DDT), chlordane, organochlorine pesticides such as endrin, and polychlorinated biphenyl (PHC).
CB), and dioxins can be mentioned.

One of the features of the method of the present invention is that the heating and melting of soil is carried out using a heat-resistant container movably arranged on the ground and having an opening at the top. Therefore, first, a heat-resistant container that can be advantageously used in the method of the present invention will be described with reference to FIGS. 1 and 2 of the accompanying drawings.

FIG. 1 is a sectional view of an example of a heat-resistant container having an opening at the top which can be advantageously used in the method of the present invention. In FIG. 1, the heat-resistant container 1 includes a bottom plate 2 and
Side plate 3 that is detachably installed on the bottom plate 2, and the bottom plate 2
The wheel 4 is provided for the vehicle.

Each of the bottom plate 2 and the side plate 3 of the heat-resistant container 1 is formed of a material having a low gas permeability and a high heat-resistant and heat-retaining property so that decomposition products of organic compounds do not diffuse to the outside. Is preferred. As an example of the material,
Fireproof bricks, fireproof castables, and various heat insulating materials (eg:
Ceramic fiber, calcium silicate, perlite,
Rock wool, asbestos, diatomaceous earth, glass wool, magnesium carbonate).

The heat-resistant container 1 preferably has a granular refractory layer made of granular refractory formed on the inner surface thereof.

An example of a heat resistant container having a granular refractory layer formed on its inner surface is shown in FIG. In FIG. 2, the granular refractory material layer 5 is formed by filling the granular refractory material between the heat resistant container 1 and the cylindrical partition plate 6. Examples of granular refractory materials include silica sand (silicon dioxide powder), crushed stone, and composite ceramics. Among these, silica sand is preferable, and silica sand having a particle size of 0.5 to 5 mm is particularly preferable.

The cylindrical partition plate 6 is not particularly limited in its material as long as it has a rigidity such that it does not deform when filled with granular refractory material. Examples of such materials include paper, plastics, ceramics, wood, and metals such as iron.

Next, the method of the present invention will be described with reference to the accompanying drawings, taking the soil contaminated with a typical organic compound as an example of its treatment.

The organic compound in the contaminated soil can be decomposed by a method including the following steps (1) to (3), for example. (1) A filling step of filling contaminated soil in a heat-resistant container movably arranged on the ground and having an opening at the top. (2) A heating and melting step of heating and melting the contaminated soil to thermally decompose the organic compound and remove the decomposition product as a gaseous substance. (3) A cooling and taking out step of taking out from the heat resistant container after cooling the melted soil into a vitrified body.

The filling step will be described with reference to FIG. FIG. 3 shows a cross-sectional view of an example of the heat resistant container after the filling process. The heat resistant container 1 is supported by rails 7. The rail 7 connects the places where the filling process, the heating and melting process, and the cooling extraction process are performed. That is, by moving on the rail 7, the heat resistant container 1 can be moved to the place where each process is performed.

In the filling step, the heat-resistant container 1 is filled with the contaminated soil 8. On the contaminated soil 8, as shown in FIG. 3, it is preferable to form a covered soil layer 9 made of soil that does not practically contain an organic compound. Examples of the contaminated soil 7 to be treated in the method of the present invention include soils of agricultural land where organic chlorine-based pesticides are sprayed, soils around factories where organic compounds are manufactured or used, and around municipal waste incinerators. The soil can be mentioned. The amount of organic compound in the contaminated soil is preferably in the range of 0.01 to 50% by mass.

Additives may be added to the contaminated soil 8 to accelerate the thermal decomposition reaction of organic compounds. For example, when the organic compound to be decomposed is a chlorine atom-containing organic compound, aluminum oxide (particularly activated alumina),
It is preferable to add one kind or a mixture of two or more kinds of zeolite or aluminum hydroxide. Water also promotes the thermal decomposition reaction of organic compounds. Examples of the method of allowing water to exist in the soil include a method of adding water or a compound that generates steam by heating to the soil. Examples of compounds that generate water vapor when heated include water-retaining substances such as bentonite and metal hydroxides. Examples of metal hydroxides include sodium hydroxide, magnesium hydroxide, calcium hydroxide, and aluminum hydroxide.

When the melting point (vitrification temperature) of the contaminated soil 8 is higher than the melting point of the granular refractory layer 5, an alkali metal compound or an alkaline earth metal compound acting as a melting point depressant for soil is added. Is also preferable. Examples of alkali metal compounds or alkaline earth metal compounds include sodium carbonate, magnesium carbonate, and calcium carbonate, sodium hydroxide, magnesium hydroxide, and calcium hydroxide. The amount of the melting point depressant added to the soil is the melting point of the contaminated soil 8 (vitrification temperature).
And the difference from the melting point of the granular refractory material is 100 ° C. or higher (preferably in the range of 200 to 300 ° C.).

The coated soil layer 9 has a function of melting before the contaminated soil 8 and heating the entire surface of the contaminated soil 8 uniformly. By providing the coated soil layer 9, the contaminated soil 8 is uniformly melted and stabilized. The thickness of the coated soil layer 9 is generally in the range of 1-100 cm, preferably 10-60 cm. The composition of the soil used for the coated soil layer 9 is not particularly limited as long as it is a soil substantially free of organic compounds. Here, the phrase "substantially free of organic compound" means that the content of the organic compound is 0.
It means less than 01% by mass.

The partition plate 6 may be melted or burned by being heated together with the contaminated soil in the next heating and melting step.
It is preferable to remove the contaminated soil before heating and melting.

Next, the heating and melting step will be described with reference to FIG. FIG. 4 shows a heating and melting apparatus that can be advantageously used in the method of the present invention. The heating and melting apparatus 10 includes two or more columnar electrodes 11 for supplying an electric current to the soil, an electric energy supplying apparatus 12 for supplying electric energy to the electrodes 11, and a hood 13 a for covering the opening of the heat resistant container 1. The hood 13a is fixed by the hood support 13b. The electrode 11 is fixed to an electrode feed device (not shown) whose tip is movable in the vertical direction.

The hood 13 has a gas introduction port 14 and an exhaust port 15
It has and. A gas supply device 15 is provided at the gas inlet 14.
Are connected. The gas supply device 15 supplies room temperature or heated air (800 ° C. or lower) to the gas introduction port 14. A gas processing device 17 is connected to the exhaust port 16. The gas processing device 17 is a heating furnace (thermal oxidizer) 1
8. Cooling dust remover (Venturi scrubber) 19.
It is composed of a HEPA filter 20 and an activated carbon filter 21.

The electrode 11 is electrically connected to the initial conductive resistance band 22 for converting the electric energy embedded in the coated soil layer 9 into heat energy (Joule heat). Examples of the material of the electrode 11 include graphite and metals such as molybdenum. The material of the initial conductive resistance band 22 is not particularly limited as long as it has a function of converting electric energy into heat energy (Joule heat). Examples thereof include graphite and mixtures of graphite with soil melting temperature reducing agents. Examples of the melting temperature lowering agent for soil include alkali salts such as sodium hydroxide and sodium carbonate, and glass frit.

The heating and melting apparatus 10 is installed in the heat resistant container 1 in the following manner, for example. The heat-resistant container 1 in which the initial conductive resistance band 22 is embedded in the coated soil layer 9 in advance is moved to below the hood 13a of the heating and melting apparatus 10. Next, heat-resistant container 1 is jacked (not shown).
To lift. As a result, the side plate 3 of the heat-resistant container comes into contact with the hood 13a, and the opening of the heat-resistant container is covered with the hood 13a. Finally, the electrode feed device (not shown) moves the tip of the electrode 11 downward so that the electrode 11 and the initial conductive resistance band 22 are in electrical contact with each other.

The heating and melting of soil is carried out, for example, as follows. The electric energy sent from the electric energy supply device 12 passes through the electrode 11 and passes through the initial conductive resistance band 2
Sent to 2. The initial conductive resistance band 22 converts electric energy into heat energy (Joule heat). The heat causes the soil in the coated soil layer 9 to be heated and melted. Due to the melting of the coated soil layer 9, the conductivity of the soil increases, and thereafter, the continuous melting of the soil expands the melting region of the soil downward and the contaminated soil 8 melts. The decomposition product of the organic compound moves to the upper part of the heat resistant container 1 together with the water vapor in the soil, and is sent to the gas treatment device 17 as an exhaust gas from the exhaust port 15 of the hood 13a. When decomposing the organic compound, the inside of the hood 13a is heated by the heated air supplied from the gas supply device 15 so that harmful substances such as dioxins are not generated from the decomposition products of the organic compound.
The temperature is maintained in the range of 00 to 800 ° C.

The heating furnace 18 heats the exhaust gas to a temperature of 850 ° C. or higher (normally 900 to 1000 ° C.) for 2 seconds or longer. As a result, organic compounds such as undecomposed volatile gas of the organic compounds in the exhaust gas are thermally decomposed by oxidation. The cooling dust remover 18 removes the exhaust gas heated in the heating furnace 18 at 100 ° C.
It is rapidly cooled to the following, the acidic gas contained therein is neutralized, and the particle content is removed. The HEPA filter 20 and the activated carbon filter 21 further collect fine particles in the exhaust gas. The exhaust gas processed by the gas processing device 17 is exhausted to the atmosphere.

When all the contaminated soil is heated and melted, the supply of electric energy is stopped. Then, the heat resistant container 1 and the hood 13a are separated.

Next, the cooling extraction step will be described with reference to FIG. FIG. 5 schematically shows an example of an operation for taking out the vitrified body obtained by cooling the melted soil. In FIG. 5, the bottom plate 2 and the side plate 3 of the heat resistant container 1 are separated by the crane 23. The granular refractory layer is collapsed into the original granular refractory 5a. The vitrified body 24 is exposed to the outside.

Since the vitrified body 24 does not substantially contain an organic compound and is physically and chemically stable, it can be crushed and used as recycled crushed stone or the like. The granular refractory 5a can be reused as a material for the granular refractory layer formed in the heat-resistant container.

In the present invention, when the filling step, the heating and melting step, and the cooling and unloading step are carried out in mutually different places, two or more heat-resistant containers (preferably three or more) are prepared. , Filling process, heating and melting process,
It is preferable to carry out the cooling and taking-out step in parallel.

FIG. 6 shows one embodiment of a method for thermally decomposing an organic compound in contaminated soil, in which the filling step, the heating and melting step, and the cooling and extracting step are carried out in parallel. In FIG. 6, three heat resistant containers 1a, 1b, 1c are used,
An example is shown in which the filling step, the heating and melting step, and the cooling extraction step are performed in parallel. Here, the heat-resistant containers 1a, 1b, 1c move on the rails 7 by the wheels 4, but the method of moving the heat-resistant containers is not particularly limited. For example, the heat resistant container may be moved using a crane or a lift. The filling step, the heating and melting step, and the cooling and extracting step are usually performed in one site, but the filling step may be performed in a place where contaminated soil exists.

In the above, the method of the present invention has been described by taking a contaminated soil, which is a typical example thereof, as an object to be treated, but it is a solid matter contaminated with an organic compound, or a liquid containing an organic compound or an organic compound. Objects, powders or agglomerates can likewise be treated.

That is, the organic compound in the polluted solid matter is
For example, it can be decomposed by a method including the following steps (1) to (3). (1) A filling step of filling a contaminated solid material together with soil or synthetic minerals into a heat-resistant container movably arranged on the ground and having an opening at the top. (2) A heating and melting step in which the soil is melted by heating the polluted solid matter together with the soil or the synthetic mineral, and the organic compound is also thermally decomposed, and the decomposition product is removed as a gaseous matter. (3) A step of cooling and extracting molten glass or synthetic minerals from the heat-resistant container as a vitrified body.

It is preferable that the soil used here contains practically no organic compound or contains a small amount of organic compound. Here, "the content of the organic compound is low" means that the content of the organic compound is in the range of 0.01 to 1% by mass. Additives that accelerate the thermal decomposition reaction of organic compounds, water or compounds that generate steam by heating, and alkali metal compounds or alkaline earth metal compounds may be added to soil or synthetic minerals.

Examples of polluted solids to be treated in the present invention include PCB-containing containers, incinerator ash discharged from municipal waste incinerators, fly ash, refractories (brick) in the municipal waste incinerators, And sludge discharged from a factory that produces or uses organic compounds.

The organic compound or the organic compound in the liquid, powder or lump containing the organic compound can be decomposed by a method including the following steps (1) to (3). (1) Filling in which a heat-resistant container movably arranged on the ground and having an opening at the top is filled with a mixture of soil or a synthetic mineral and an organic compound or a liquid, powder or lump containing an organic compound. Process. (2) A heating and melting step in which the soil or synthetic mineral is melted by heating the mixture, and the organic compound is also thermally decomposed, and the decomposition product is removed as a gaseous substance. (3) A cooling and taking out step of taking out from the heat resistant container after cooling the molten soil or the synthetic mineral to form a vitrified body.

It is preferable that the soil used here also contains practically no organic compound or contains little organic compound. Additives that accelerate the thermal decomposition reaction of organic compounds, water or compounds that generate steam by heating, and alkali metal compounds or alkaline earth metal compounds may be added to soil or synthetic minerals.

In the method of the present invention, when an organic compound or a liquid, powder or lump containing an organic compound is contained in a container, the container can be treated by mixing with the soil. For example, a transformer or capacitor in which PCB is used can be mixed with soil as it is for processing. In the present invention, an organic chlorine-based pesticide (insecticide) can be mentioned as an example of a liquid, powder or lump containing an organic compound to be treated.

Next, the method for immobilizing the radioactive substance of the present invention will be described. As an example of the solid matter (radioactive waste) contaminated by the radioactive material to be treated by the present invention, radioactive waste discharged from a nuclear power plant can be mentioned.

The radioactive substance in the radioactive waste is, for example,
It can be fixed by a method including the following steps (1) to (3). (1) A filling step of filling radioactive waste together with soil or synthetic minerals into a heat-resistant container movably arranged on the ground and having an opening at the top. (2) A heating and melting step of melting the soil or the synthetic mineral by heating the radioactive waste together with the soil or the synthetic mineral. (3) A cooling and extracting step of cooling the molten soil or the synthetic mineral to form a vitrified body, confining the radioactive substance in the vitrified body, and taking out the heat-resistant container.

Also in the method for immobilizing a radioactive substance of the present invention, a method similar to the method for decomposing an organic compound is used,
Soil or synthetic minerals can be heated and melted.

The case where the soil is heated and melted by using Joule heat has been described so far. However, if the soil filled in the heat-resistant container can be gradually heated or melted in one direction, the soil can be heated. There is no particular limitation on the heating and melting method. For example, plasma may be used to heat and melt the soil.

[0056]

The method for decomposing an organic compound utilizing the soil melting and solidifying method of the present invention facilitates the work such as installation of a heating and melting apparatus, thus shortening the time required for the processing.
Further, in the method of the present invention, two or more heat-resistant containers are prepared, and the filling step, the heating and melting step, and the cooling extraction step are performed in parallel to continuously decompose the organic compound. It becomes possible.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of an example of a heat resistant container that can be advantageously used in the method of the present invention.

FIG. 2 is a cross-sectional view of another example of a heat-resistant container that can be advantageously used in the method of the present invention.

FIG. 3 is a cross-sectional view of the heat resistant container after the filling step according to the present invention.

FIG. 4 is a diagram showing a state in which a heat melting apparatus used in a heat melting step according to the present invention is installed in a heat resistant container.

FIG. 5 is a diagram showing an operation of taking out the vitrified body from the heat resistant container in the cooling and taking out step according to the present invention.

FIG. 6 is a diagram schematically showing one embodiment of a method for thermally decomposing an organic compound in a polluted soil according to the present invention.

[Explanation of symbols]

1, 1a, 1b, 1c Heat resistant container 2 Bottom plate 3 Side plate Four wheels 5 Granular refractory layer 5a Granular refractory 6 partition boards 7 rails 8 contaminated soil 9 Covered soil layer 10 Heating and melting equipment 11 electrodes 12 Electric energy supply equipment 13a hood 13b hood support 14 Gas inlet 15 exhaust port 16 Gas supply device 17 Gas processing equipment 18 heating furnace 19 Cooling and dust cleaning machine 20 HEPA filter 21 Activated carbon filter 22 Initial conductive resistance band 23 cranes 24 Vitrified

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI G21F 9/02 551 G21F 9/30 551A 9/30 519 B09B 3/00 303P 551 303L 303Z (56) Reference JP 2002-71894 (JP, A) JP 2001-62422 (JP, A) US Pat. No. 6120430 (US, A) Konoikegumi JV, Detoxification treatment of dioxins / geomelt method, environmental facility, Japan, Public Investment Journal Co., Ltd. , 2001, No. 86, p. 32-34 (58) Fields surveyed (Int.Cl. ⁷ , DB name) B09C 1/06 B09B 3/00 C02F 11/10 F23G 5/00 F23G 7/14 G21F 9/02 G21F 9/30 JISST file ( JOIS) WPI (DIALOG)

Claims (21)

(57) [Claims] 1. A disposed movably on the ground, possess an opening on the top, the bottom and the bottom plate detachably installed sides plates
A granular refractory layer on the inner surface of a heat-resistant container made of
Step, filling step of filling the container with soil contaminated with an organic compound, heating and melting the soil to thermally decompose the organic compound and remove the decomposition products as gaseous matter, melting soil, molten soil After cooling to a vitrified body, the side plate of the heat resistant container is removed from the bottom plate, and
A method for decomposing an organic compound using a soil melting and solidifying method, which includes a cooling extraction step of removing a granular refractory layer from a heat resistant container. Wherein arranged movably on the ground, it possesses an opening on the top, the bottom and the bottom plate detachably installed sides plates
A granular refractory layer on the inner surface of a heat-resistant container made of
A step of filling a solid material contaminated with an organic compound with the soil or a synthetic mineral into the container, by heating the solid material with the soil or a synthetic mineral,
After melting the soil or synthetic minerals, the organic compound is also pyrolyzed together, a heating and melting step of removing the decomposition products as gaseous substances, and the molten soil or synthetic minerals are cooled to form a vitrified body, Is the side plate of the heat-resistant container the bottom plate?
A method for decomposing an organic compound utilizing a soil melting and solidifying method including a cooling and taking out step of taking out from a heat resistant container after removing the granular refractory layer and breaking the granular refractory layer . 3. disposed movably on the ground, possess an opening on the top, the bottom and the bottom plate detachably installed sides plates
A granular refractory layer on the inner surface of a heat-resistant container made of
Step, filling step of filling the container with a mixture of soil or synthetic mineral and an organic compound or a liquid, powder or lump containing the organic compound, melting the soil or synthetic mineral by heating the mixture Then, the organic compound is also thermally decomposed, and a heating and melting step of removing the decomposition product as a gaseous substance, and the melted soil or synthetic mineral is cooled to a vitrified body, and then the side surface of the heat-resistant container.
Remove the plate from the bottom plate and collapse the granular refractory layer
Then, a method for decomposing an organic compound using a soil melting and solidifying method including a cooling and taking out step taken out from a heat resistant container. 4. The filling step, the heating and melting step, and the cooling and unloading step are carried out after moving the heat resistant container and arranging them in different places different from each other. The decomposition treatment method described in the item. 5. The decomposition treatment method according to claim 4, wherein two or more heat-resistant containers are prepared, and the filling step, the heating and melting step, and the cooling extraction step are carried out in parallel. 6. The decomposition treatment method according to claim 4, wherein the heat resistant container is provided with wheels. 7. The decomposition treatment method according to claim 6, wherein the heat-resistant container is moved to a place where the filling step, the heating / melting step, and the cooling / unloading step are carried out by the wheels provided in the heat-resistant container. 8. The heating and melting of the soil in the heating and melting step is performed by using Joule heat generated by passing an electric current between two or more electrodes embedded in the soil. The decomposition treatment method described in the section. 9. Two or more columnar electrodes fixed and installed on the ground for heating and melting the soil in the heating and melting step, a hood for covering the opening of the heat resistant container, and The decomposition treatment method according to claim 8, which is performed by using a heating and melting device including an electric energy supply device that supplies an electric current to the electrodes. 10. The decomposition treatment method according to claim 9, wherein the hood has an exhaust port, and the process includes heat-treating the decomposition product of the organic compound discharged from the exhaust port. 11. A granular refractory layer comprising silica sand, crushed stone,
And refractory granules selected from the group consisting of composite ceramics
The decomposition treatment method according to any one of claims 1 to 3, wherein the decomposition treatment method is formed of any one of the objects . 12. is arranged movably on the ground, possess an opening on the top, bottom and detachably installed sides in the bottom plate
A granular refractory layer is formed on the inner surface of a heat-resistant container consisting of plates
A filling step of filling the container with a solid substance contaminated with radioactive material together with the soil or the synthetic mineral, a heating and melting step of melting the soil or the synthetic mineral by heating the solid substance with the soil or the synthetic mineral, Then, the molten soil or synthetic mineral is cooled to form a vitrified body, the radioactive substance is confined in the vitrified body, the side plate of the heat-resistant container is removed from the bottom plate, and
A method for immobilizing a radioactive substance using a soil melting and solidifying method, which includes a cooling and taking out step of taking out from the heat resistant container after destroying the granular refractory layer as described above . 13. The immobilization method according to claim 12, wherein the filling step, the heating and melting step, and the cooling and extracting step are carried out after moving the heat resistant container and arranging them in different places different from each other. 14. The immobilization method according to claim 13, wherein two or more heat resistant containers are prepared, and the filling step, the heating and melting step, and the cooling and extracting step are performed in parallel. 15. The heat resistant container is provided with wheels.
The immobilization method according to 3 or 14. 16. A wheel provided in the heat-resistant container,
The immobilization method according to claim 15, wherein the heat resistant container is moved to a place where the filling step, the heating and melting step, and the cooling and extracting step are performed. 17. The method according to claim 12, wherein the heating or melting of the soil or the synthetic mineral in the heating and melting step is performed by using Joule heat generated by passing an electric current between two or more electrodes embedded in the soil or the synthetic mineral. Immobilization method described. 18. Soil or soil in the heating and melting step
The heating and melting of the formed minerals, disposed fixed on the ground, the soil if
Or two or more columnar electrodes for supplying an electric current to the synthetic mineral , a hood for covering the opening of the heat-resistant container, and an electric energy supplying device for supplying an electric current to the electrodes. The immobilization method according to claim 17. 19. A granular refractory layer comprising silica sand, crushed stone,
And refractory granules selected from the group consisting of composite ceramics
The immobilization method according to claim 12, wherein the immobilization method is formed by any one of the objects . 20. A bottom plate and a detachably installed on the bottom plate
And a side plate, and the bottom plate is provided with wheels.
Heat resistant container for heating and melting soil or synthetic minerals. 21. Granular refractory comprising granular refractory on the inner surface
The heat resistant container according to claim 20, wherein a material layer is formed.