JP4276688B2 - Detoxification method for waste materials containing asbestos - Google Patents

Description

  The present invention relates to a detoxification method for asbestos-containing waste materials, and more particularly to a detoxification method for asbestos-containing waste materials that contributes to the practical use of the detoxification treatment of waste materials such as slate materials that have been used as building materials.

  Due to a delay in recognition of the danger of asbestos, materials containing asbestos have been widely used for building materials such as spray materials, heat insulating materials and slate plates until recently, and the amount thereof is enormous. At present, when the risk of asbestos has become clear and its use has been banned, it is an extremely important issue to safely treat a huge amount of waste material containing asbestos. In particular, waste materials of non-scattering asbestos-containing building materials such as slate materials that have been widely used as building materials in recent years have a large amount of generation, and their treatment becomes a problem. Currently, most non-scattering asbestos-containing waste materials are disposed of in landfills at the final disposal site. However, in recent years, the development of new disposal methods is awaited because of the large amount of processing. The slate material contained about 15 to 20% asbestos in the cement reinforcement.

  Here, in the disposal of asbestos, it is necessary to detoxify asbestos. However, in order to reliably detoxify asbestos, it is necessary to achieve both non-asbestos and non-fibrosis. Among the technologies for detoxifying asbestos-containing waste materials, only the melting furnace method is in practical use at present. In this method, the asbestos-containing waste material is melt-treated at an extremely high temperature of 1,500 ° C., and therefore, there is an eager desire to develop a new method for treating asbestos-containing waste material that can be easily processed in large quantities at a lower temperature. ing.

  On the other hand, in recent years, it has been disclosed that the asbestos-containing waste material can be rendered harmless by low-temperature heat treatment by heating the asbestos-containing waste material with an inorganic salt (see Patent Document 1 and Patent Document 2). In Patent Document 1, asbestos-containing waste materials such as sprayed asbestos are immersed in a reaction solution containing calcium chloride, and then fired at 600 to 800 ° C., whereby fibrous asbestos is decomposed into particles or powders and rendered harmless. I can do it. Further, in Patent Document 2, the slate waste containing asbestos is pretreated by placing it under reduced pressure in a state where it is immersed in an aqueous solution of a melting agent composed of a specific mixed component without being pulverized. The asbestos in the slate waste material is vitrified by immersing the waste material in a melting furnace filled with a melting agent and heating the waste material in a range of 780 to 1,000 ° C.

Japanese Patent No. 3747246 Japanese Patent No. 3830492

  However, according to the study by the present inventors, the technique described in Patent Document 1 in which an asbestos-containing waste material is immersed in a reaction solution such as calcium chloride, which is an asbestos decomposing agent, is porous in which the reaction solution easily penetrates. It is suitable for the treatment of waste materials that decompose asbestos-containing composite materials and asbestos fibers themselves, but it is not suitable for non-scattering asbestos-containing waste materials such as slate materials. That is, the slate material is water resistant, and the cementitious solidified material is firmly attached and covered around the asbestos fiber. Therefore, the impregnating agent is asbestos by simply impregnating the slate material with the reaction solution. It was difficult to make sufficient contact with the fibers. For this reason, when heat treatment is performed after impregnating a slate material or the like into a reaction solution containing a decomposing agent, a portion where the reaction is insufficient occurs, and asbestos fibers in the slate material may not be completely decomposed. The problem of this impregnation failure is also improved in the method according to Patent Document 2 in which the pressure is reduced in a state where the slate waste material is immersed in an aqueous solution of a melting agent for the treatment of the slate waste material, and then the heat treatment is performed. The same thing happens. Moreover, in the method by patent document 1 mentioned above, since the calcium component required in order to decompose | disassemble asbestos relies on decomposition agents, such as calcium chloride, about twice as much decomposition agent is contained in the molar ratio of the amount of asbestos to contain. What was needed was also a big issue. That is, in order to impregnate a large amount of waste material with the technique described in the above-mentioned patent document, a large facility and a special facility for decompression are required, and a large amount of a decomposition agent such as calcium chloride is required. This requires a lot of running costs and increases the amount of waste. In addition, even if chemicals such as reaction liquids can be sufficiently impregnated in the asbestos-containing waste material, the active ingredients in the liquid accumulate on the surface of the waste material (migration) as the moisture moves during drying, and are effective in the waste material. There is also a problem that the distribution of components becomes non-uniform and the processing is not uniform.

  As described above, according to the technology described in the above-mentioned patent document, although it is possible to perform processing at a lower temperature than the currently performed melting furnace method in which processing is performed at an extremely high temperature, complicated pretreatment and In addition to the need for large-scale equipment and devices and a large amount of chemicals, there is a risk that asbestos will not be rendered harmless depending on the type of waste material and the conditions of the impregnation treatment. For this reason, the technique described in the above-mentioned patent document is an improvement as a practical technique for waste material treatment that requires a stable and efficient and reliable detoxification treatment of a large amount of asbestos-containing waste material at a lower cost. There was room for.

  Accordingly, an object of the present invention is to make asbestos-containing waste materials that can be practically used, capable of reliably and stably detoxifying the asbestos-containing waste materials such as slate materials at a lower temperature, in an inexpensive and simple manner. Is to provide a detoxifying method.

The above object is achieved by the present invention described below. That is, the present invention is a detoxification method for asbestos-containing waste material that is detoxified by thermally decomposing asbestos, and a pulverization step for pulverizing non-scattering asbestos-containing waste material so that the particle size of the pulverized product is 500 μm or less And a pressure molding step of pressing the obtained pulverized product at 20 to 2,000 kg / cm ² to obtain a molded product, and a thermal decomposition step of heating the molded product, and the pulverization In the process, by adding an asbestos decomposing agent to the pulverized asbestos-containing waste material, the asbestos decomposing agent in the pressure-molded molded product is 1 to 5 parts per 100 parts of the pulverized product on a mass basis. The asbestos-containing waste material is detoxified by adding and mixing and heating the molded product at a temperature equal to or higher than the melting temperature of the asbestos decomposition agent in the heat decomposition step.

The following are mentioned as a preferable form of this invention. The method for detoxifying the above asbestos-containing waste material, wherein the asbestos decomposing agent contains calcium chloride, and the heating temperature in the heat decomposing step is 800 ° C to 1,000 ° C. The method for detoxifying the above asbestos-containing waste material, wherein the pressure condition in the pressure molding step is 50 to 1,000 kg / cm ² .

According to the present invention, for example, even a waste material such as a non-scattering asbestos-containing waste material such as a slate material can be reliably detoxified and stably processed at a lower temperature by a simpler method. Provided is a method for detoxifying waste material containing asbestos that can be put into practical use. More specifically, the following effects can be obtained.
(1) The method of the present invention is an asbestos-free non-scattering asbestos-containing waste material, such as a slate material, which is considered to have a large amount in the future among the asbestos-containing waste materials whose treatment has become a social problem. It is effective for the conversion process.
(2) For forming the pressure-molded product (pellet) constituting the method of the present invention, a widely used industrial dosage machine such as a briquetting machine can be used. Therefore, a large amount of slate material can be obtained by the method of the present invention. Asbestos-containing waste materials such as can be treated industrially.
(3) In the method of the present invention, the amount of asbestos decomposing agent used is much smaller than that of the conventionally proposed method, and asbestos is easily decomposed at a temperature lower than the melting point of the asbestos decomposing agent. Therefore, the heating temperature can be remarkably lowered as compared with the melting furnace method, and economical treatment is possible.
(4) In the method of the present invention, it becomes possible to recycle the processed material obtained by decomposing asbestos into raw materials for cement, etc., making it an ideal practical technology that meets the needs of society seeking environmental protection. Can be.
(5) In the method of the present invention, the asbestos-containing waste material is processed in the form of pellets, so that it is easy to handle at the time of heat treatment or after the treatment, and also easy to handle when recycled and reused after the treatment.

  Hereinafter, the present invention will be described in more detail with reference to the best mode for carrying out the present invention. As a result of earnestly examining the practical application technology capable of reliably detoxifying and stably processing non-scattering asbestos-containing waste materials such as a large amount of slate materials by a simpler method, the present inventors It has come. The inventors first pulverized a waste material containing asbestos such as a slate material (hereinafter simply referred to as a slate waste material) to expose the asbestos fibers as much as possible, and an asbestos decomposing agent in the pulverized product. It was found that the above-mentioned object can be achieved by adding and mixing the mixture and press-molding the mixture to obtain a molded product (pellet), which is then heat-treated. That is, by configuring as described above, the slate waste material contains asbestos at a high content of about 15 to 20%, and the cement-based solidified material is firmly attached around the asbestos fibers. Nevertheless, it has been found that asbestos fibers in slate waste can be completely decomposed and detoxified with a small amount of decomposing agent and at a temperature much lower than that by the melting furnace method. The present inventors consider this reason as follows. According to the study by the present inventors, first, by configuring in this way, the contact rate between the asbestos fiber and the decomposing agent is remarkably increased as compared with the case where the slate waste material is processed as it is, and it is uniform. It will be something. Furthermore, by pressure forming and pelletizing the slate waste and asbestos decomposer, the volatilization of the decomposer that melts when heat-treated is suppressed, so that the function of the decomposer is effectively exhibited. Become. As a result, it is inferred that the decomposition of asbestos fibers could be further promoted.

Although the present invention relates to an improvement in a method for detoxifying asbestos by thermally decomposing asbestos-containing waste material, in the present invention, by making the asbestos-containing waste material to be heat-treated into a specific state, reliable detoxification treatment at low temperature To achieve. Specifically, the asbestos-containing waste material is pulverized to obtain a pulverized product having a particle size of 500 μm or less. The obtained pulverized product is pressure-molded into a molded product (pellet), and an asbestos decomposing agent is added to the molded product. The mixture is brought into a mixed state, and the obtained molded product is heated and decomposed by heating. These will be described in detail below. Although the following description is conducted mainly slate waste, asbestos containing waste material which the present invention is to Target is not limited thereto, can be also similarly processed blowing wastes, etc. asbestos It is.

(1) Grinding In the present invention, as means for solving the above-described problems, first, asbestos-containing waste materials such as slate waste materials are finely ground to 500 μm or less. Since the asbestos-containing waste material, particularly asbestos fibers mixed in the slate material, are covered with cement-based solids in a bundled state, it is effective to finely pulverize the asbestos fibers. The present inventors examined the relationship between the size of the pulverized material when the slate waste material was pulverized and the certainty of the subsequent heat treatment. As a result, when the particle size of the pulverized product was 1 mm (1,000 μm) or more, a large bundle of fibers remained, and even when the decomposition agent was mixed and heated, some fibers remained. As a result of further studies, it has been concluded that it is necessary to make the asbestos 500 μm or less, more preferably 250 μm or less, from the viewpoint of detoxifying the asbestos even when a large amount is processed. In addition, the finer the pulverized particle size, the easier it is to decompose and the smaller the amount of decomposing agent can be reduced. On the other hand, if the asbestos-containing waste material is pulverized to submicron, the pulverization cost is increased and the particle size is fine. If too much, another problem that the moldability at the time of pressurization deteriorates also arises. Therefore, in putting the asbestos-containing waste material into practical use, it is preferable to determine the optimum particle size of the pulverized product obtained in the pulverization step in consideration of the above-mentioned facts and the cost for the processing.

(2) Addition and mixing of asbestos decomposing agent In the method of the present invention, the pulverized product having the particle size as described above is pelletized and then heat-treated. At that time, the asbestos decomposing agent is added to the heat-treated pellet. It is characterized by being in a mixed state. In this invention, the pellet for heat-processing should just be an above-described state, It does not limit about the method for obtaining such a pellet, Any method may be sufficient. In order to perform a more reliable and satisfactory treatment, it is important to ensure that the asbestos decomposing agent is in a state of being uniformly mixed with the pulverized asbestos-containing waste material as much as possible. As a general method of adding and mixing the asbestos decomposing agent in the pellets, the asbestos decomposing agent is added to the pulverized product obtained by pulverization with a pulverizer using a mixing device and mixed. What is necessary is just to pelletize the obtained mixture by mixing with a machine. As a more preferred embodiment, the coarsely pulverized asbestos-containing waste material is charged into a fine pulverizer, and at the same time, an asbestos decomposing agent such as powdered or aqueous solution such as calcium chloride is charged into the fine pulverizer for fine pulverization. By mixing at the same time, the asbestos decomposing agent can be uniformly added to the pulverized product. Examples of the industrial pulverizer that can be used in such a case include a vibration mill, a roller mill, an impact mill, a hammer mill, and a ball mill. In the case of continuous grinding, it is preferable that the residence time of the raw material is long because the dispersibility of the decomposition agent is improved and uniform mixing is possible. Moreover, since asbestos fibers may be bundled, in order to solve this, it is preferable to use a pulverization method having as strong an impact force as possible. From such a purpose, a vibration mill is preferable among the above-mentioned pulverizers. In addition, in order to prevent scattering of asbestos fibers, the asbestos-containing waste material may be put into a pulverizer after being appropriately moistened with water. In this case, the water content is preferably about 10%.

(3) Pressure molding In the method of the present invention, asbestos-containing waste material is finely pulverized to a specific particle size to expose asbestos fibers as much as possible, and then pressure-molded and pelletized. It contributes to. At the time of pelletization, it is preferable that the asbestos decomposing agent is uniformly dispersed and mixed in the pulverized product by the method exemplified above. According to the study by the present inventors, by making the pellet, the contact rate between the asbestos fiber and the asbestos decomposing agent during the heat treatment is further increased, compared with the case where the heat treatment is performed without pelletization. Detoxification is promoted at a lower temperature, and the processing efficiency is remarkably increased. However, if the pressure applied during pelletization is too high, the gaps between the particles of the waste material and the asbestos fibers will be too small, which will inhibit the spread of the asbestos decomposing agent melt in the pellets that melt when heated. Therefore, it is preferable to pelletize by an appropriate pressure. According to experiments conducted by the present inventors, the above-described effects can be obtained effectively if the molding pressure is in the range of ^{20 to} 2,000 kg / cm ² , preferably 50 to 1,000 kg / cm ^2. Was confirmed. In this case, as the pressurizing apparatus, a compression granulation method such as a tableting machine, a briquetting machine or a compacting machine, or an apparatus such as a molding machine such as a tile press can be used. Since these apparatuses are widely used in the same manner as the above-described pulverizer, the method of the present invention can be industrially put into practical use by using these various apparatuses.

  Also, the size of the pellet to be molded is not particularly limited, but if the molded pellet is too large in block shape, it is difficult for heat to be transferred to the inside of the pellet during heating in the next heat treatment step, and the apparatus is enlarged. Since there is a problem, it is desirable to obtain compact pellets by compression molding using a compression granulation method. Specifically, for example, the size is about 0.5 to 10 cm square, more preferably about 1 to 5 cm square. Among the compression granulation methods, the briquetting machine is easy to process in large quantities and is economical. Moreover, even if a vacuum extrusion molding machine is used, it is possible to produce molded pellets with a certain degree of density. However, in this case, since the water content is higher than that of the compression granulation method, a problem of migration is likely to occur. .

(4) Asbestos decomposer The asbestos decomposer used in the present invention will be described. As the asbestos decomposing agent, as described in Japanese Patent No. 3747246, calcium chloride, a mixture of calcium chloride, and other calcium compounds such as calcium carbonate and calcium hydroxide can be used. A major feature of the present invention is that the required amount of a decomposing agent can be greatly reduced as compared with the conventional method due to the effect of promoting decomposition by fine pulverization and pressure molding as described above. The present inventors consider the reason why such an effect is obtained as follows. By configuring as described above, the asbestos decomposition is not dependent on all the calcium in the decomposing agent such as calcium chloride added to the waste material, for example, calcium contained in the cement component constituting the slate material etc. This is thought to be because it has become easier to contribute to the decomposition reaction of asbestos. That is, as described above, by finely pulverizing the slate material and the like, and by pressure molding this, the calcium component contributing to its decomposition can be sufficiently supplied around the asbestos fibers. Inferred.

  The required amount of the asbestos decomposing agent used in the method of the present invention is, for example, as follows. According to the study by the present inventors, the amount of the asbestos decomposing agent added to the molded product of the asbestos-containing waste material to be heat-treated is about 1 to 5 parts with respect to 100 parts of the pulverized product on a mass basis. As a result, asbestos could be sufficiently decomposed. The amount of asbestos decomposing agent added is preferably as small as possible from the viewpoint of reducing running costs and reducing the amount of waste, but according to the study by the present inventors, the degree of detoxification depends on the particle size of the pulverized product. In addition, since it is also affected by the pelletizing pressure and the heat treatment temperature, in practical use, an optimal amount may be determined in consideration of these factors.

  The reason why asbestos can be decomposed at a much lower temperature than the melting furnace method by adding and heating an asbestos decomposing agent such as calcium chloride will be described by taking calcium chloride as an example. The melting point of calcium chloride is 772 ° C., which is lower than that of commonly used melting agents, but as described below, asbestos can be decomposed when heated to a melt state. First, asbestos crystals (such as chrysotile) are dehydrated to form forsterite and become non-asbestos. This forsterite is a more brittle crystal than asbestos, but retains the fibrous form of asbestos. From the viewpoint of the environment, it is not preferable that forsterite is present in a fibrous form. The presence or absence of forsterite can be confirmed by X-ray diffraction. In contrast, in the present invention, heat treatment is performed in a state where an asbestos decomposing agent such as calcium chloride is contained. Therefore, when the decomposing agent is heated to the melting point to form a melt, the calcium in the melt is converted to forsterite. It reacts with silica to form calcium silicate, and the chemical bonds of forsterite are broken down, defibrated and rendered harmless. As described above, at this time, due to the action of the decomposing agent melt, not only calcium of the decomposing agent added and mixed, but also calcium components such as finely pulverized slate material can easily contribute to the decomposition reaction. Even if the amount of the decomposing agent to be added is less than the theoretical value, the asbestos fiber can be completely decomposed.

(5) Heat treatment In the method of the present invention, pellets containing an asbestos decomposing agent such as calcium chloride obtained by pressure-molding the pulverized product are heat-treated. The heating temperature at that time is not particularly limited, but from the viewpoint of running cost, it is preferable to treat at a temperature as low as possible as compared with the conventional melting furnace method treating at 1,500 ° C. However, if the heating temperature is too low, there is a possibility that sufficient treatment cannot be reliably performed, which is not preferable. According to the study by the present inventors, the heat treatment temperature is preferably at least the melting temperature of the main asbestos decomposing agent. Specifically, heat treatment is preferably performed at a temperature of 800 ° C. to 1,000 ° C. For example, when an asbestos decomposition agent containing calcium chloride is used, heat treatment is performed at a temperature of about 800 ° C. to 900 ° C., which is equal to or higher than the melting point of calcium chloride. In this way, since the asbestos decomposing agent is uniformly dispersed and mixed in the molded product to be heat-treated as described above, the asbestos decomposing agent when heated above the melting temperature of these components. Melts completely and penetrates uniformly into the molded product. As a result, the asbestos fibers in the molded article start to decompose by touching a melt such as calcium chloride as an asbestos decomposing agent.

  According to the study by the present inventors, when the heat treatment is performed, the finer the asbestos fibers in the molded product, the faster the decomposition rate. Further, as described above, since the molded product is pressurized, volatilization of the decomposition agent melted at the time of heating is suppressed, and asbestos fibers are efficiently decomposed. For this reason, if the decomposition is attempted to the same extent, the amount of decomposition agent added is smaller when pelletized than when not pelletized. In the method of the present invention, since the pulverized particles are pressurized to some extent, the continuous gap between the particles is smaller than when not pelletized. During the heat treatment of the pellet, the melt of the decomposing agent spreads through the fine gaps, so that it becomes easy to uniformly contact the asbestos fibers. In addition, since the gaps between the particles are small, it is possible to prevent the melt of the decomposing agent from flowing down and volatilizing from the molded product, and asbestos is sufficiently decomposed and reliably detoxified. In addition, as described above, if the applied pressure is too high, the gaps between the particles and the asbestos fibers may be too small, which may hinder the spread of the melt. It is preferable to pelletize at a moderate pressure.

Next, the present invention will be specifically described with reference to examples and comparative examples. Unless otherwise specified, parts are based on mass.
[Examples 1 to 9]
In Examples 1 to 9, a slate waste material containing 15% of asbestos fibers was processed. At that time, the particle size of the pulverized slate waste material and the amount of calcium chloride hydrate as an asbestos decomposing agent added thereto were changed as shown in Table 1, and the treatment was performed according to the following procedure. First, in order to prevent scattering during pulverization, the slate waste was moistened with water to a water content of about 10%. Next, after coarsely pulverizing this with a crusher, the coarsely pulverized product was put in a vibration mill pulverizer, and further calcium chloride hydrate was added to each of 100 parts of the pulverized product in Table 1 in terms of CaCl _2. It added so that it might become the number of copies described. In this state, the mixture was pulverized and mixed so as to have the particle size shown in Table 1. The obtained mixed powder was uniaxially pressure-molded at a pressure in the range of 50 to 2,000 kg / cm ² shown in Table 1 using a φ23 mm mold to obtain a molded product. Thereafter, the obtained molded product was subjected to thermal decomposition treatment at each temperature in the range of 800 to 900 ° C. shown in Table 1 using an electric furnace to obtain a sample for a treatment test.

(Evaluation)
The sample obtained after processing under each condition was pulverized and observed with a scanning electron microscope (SEM), and the presence or absence of asbestos fibers was confirmed and evaluated. The evaluation results were evaluated as x when the fiber was clearly present and ◯ when there was no fiber at all. The treated sample was analyzed by XRD (X-ray diffractometer) to confirm the presence or absence of forsterite. When there is forsterite, the fibers remain as described above, and it is difficult to say that the forsterite has been completely processed. The obtained results are shown in Table 1.

[Examples 10 and 11]
Also in Examples 10 and 11, the slate waste material containing 15% asbestos fibers was treated in the same manner as in the other examples. In Examples 10 and 11, the treatment was performed by crushing to a finer particle size of 11 μm or less. First, the slate waste material was moistened with water to prevent scattering, and the water content was about 10%. After roughly pulverizing this with a crusher, it was put in a vibration mill and pulverized to 105 μm or less, then placed in a ball mill, and wet crushed with water to make it 11 μm or less. The pulverized slurry was dried at 200 ° C. and placed in a ball mill, and 1 part of calcium chloride as an asbestos decomposing agent was added to 100 parts of the pulverized product in terms of CaCl ₂ and dry pulverized and mixed. Then, the mixed powder, using mold Fai23mm, and uniaxial pressing at a pressure of 400 kg / cm ² and 1,000kg / cm ^2, the molded product obtained by using an electric furnace at a predetermined temperature Heat treatment was performed. Evaluation of the obtained processed material was performed by the same method as Examples 1-9. The results are shown in Table 1. FIG. 1 is a photograph of the fired product after the treatment obtained in Example 11 when observed with an SEM (scanning electron microscope), but no fibers were observed.

[Comparative Example 1]
The slate waste material was treated under the same conditions and method as in Example 1 except that the particle size of the pulverized product was 1 mm (1,000 μm) or less. The obtained processed product was evaluated in the same manner as in the examples, and the results are shown in Table 1.

[Comparative Example 2]
The slate waste material was treated under the same conditions and method as in Example 1 except that the particle size of the pulverized product was 250 μm or less and the molding pressure was 10 kg / cm ² . The obtained processed product was evaluated in the same manner as in the examples, and the results are shown in Table 1.

[Comparative Example 3]
Also in this comparative example, the slate waste material containing 15% asbestos fiber was treated in the same manner as in the example. In this comparative example, the heat treatment was performed in the pulverized state without being pelletized as follows. It was. First, the slate waste material was moistened with water to prevent scattering, and the water content was about 10%. This was coarsely pulverized with a crusher, then pulverized with a vibration mill, and pulverized to 105 μm or less. Thereafter, a solution in which calcium chloride as an asbestos decomposing agent was dissolved in water was prepared, and the sample was impregnated. At this time, the concentration of the calcium chloride aqueous solution was adjusted so that the amount of calcium chloride in the impregnated product was 5 parts in terms of CaCl ₂ . The impregnated sample was placed in a crucible, dried, and then placed in an electric furnace and heat-treated at 900 ° C. The obtained processed product was evaluated in the same manner as in the examples. The results are shown in Table 1. FIG. 2 is a photograph of the fired product after the treatment obtained in Comparative Example 3 observed with an SEM (scanning electron microscope), and the remaining of the fibers was observed.

  As an effective utilization example of the present invention, non-scattering of slate materials etc. used for building materials, etc., among the asbestos-containing materials whose treatment has become a social problem, especially in the future A detoxification treatment for the asbestos-containing waste material. In the method of the present invention, not only a pulverizer for performing a pulverization process but also an industrial dose production machine such as a briquetting machine can be used for forming a pressure pellet, so that it can be processed industrially at a low cost. Easy to convert.

It is a figure which shows a photograph when the processed material obtained in Example 11 is observed with SEM (scanning electron microscope). It is a figure which shows a photograph when the processed material obtained in the comparative example 3 is observed with SEM (scanning electron microscope).

Claims (3)

A detoxification method for decomposing asbestos-containing waste material by decomposing asbestos by heat decomposition, and crushing the non-scattering asbestos-containing waste material so that the particle size of the pulverized product is 500 μm or less, and the obtained pulverization An asbestos-containing waste material having a pressure molding step of pressing a product at 20 to 2,000 kg / cm ² to obtain a molded product, and a thermal decomposition step of heating the molded product. By adding and mixing an asbestos decomposing agent to the pulverized product of 1 to 5 parts , the asbestos decomposing agent is added to and mixed with 100 parts of the pulverized product on a mass basis, and heated. A method for detoxifying an asbestos-containing waste material, wherein the molded product is heated at a temperature equal to or higher than a melting temperature of the asbestos decomposing agent in the decomposition step.   The method for detoxifying asbestos-containing waste materials according to claim 1, wherein the asbestos decomposing agent contains calcium chloride, and the heating temperature in the heat decomposing step is 800 ° C to 1,000 ° C. The method of detoxifying asbestos containing waste material according to claim 1 or 2 pressure condition is 50~1,000kg / cm ² in the pressure forming step.

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